l. Weld CG is the ASME Section XX category BH weld

2. Weld FR is an ASME Section III NF. Integral attachment to the pressure boundary and as such is not within the examination scope of Section XZ.

3. To evaluate the restrictions properly, the examination volumes will be calculated separately.

Weld CG was fully examined in accordance with the rules of ASME Section XI. No restriction due to curvature was noted on weld CG. Weld FR had restrictions to the ultrasonic examinations in the 0,0 45 60 beam angles.

The 0 examination of weld FR was restricted in a volume as shown in Figure 2d. This volume is 6837 in . The unexamined volume is 36.1%

of'he total 18,921 in for this weld.

45o The 45 examination of weld FR was restricted in a volume as shown in figure 2e. This volume is 8427 in . The unexamined volume is

~

44.5% of the total 18,921 in for this weld.

~

IV.4

REPORT f/1 0

60 The 60 examination of weld FR was restricted in a volume as shown in Figure 2f. This volume is 8137 in . The unexamined volume is 43. 0% of the total 18,921 in for this weld.

On welds DA, DB, DC, DD, DE, and DF, a 9.9" long area of each weld is shadowed by the FR weld buildup. This shadow affects the ultrasonic examination of each weld in the 0 base metal, 0 weld metal, 45, and 60 beam angles.

To simplify calculation of the affected volumes, yet remain conservative, the sound beam was treated as a single ray. Beam

spread, volumes.

if used, will reduce rather than increase the affected Credit was taken for lateral angulation of the search unit, where used since it resulted in a significant increase to the examined volume.

There is an overlap of examination volumes for FR and DA through DF welds. Credit was taken for the overlapping volumes where applicable.

00 The 0 0 base metal examination of a volume 9.9" long x 32.5 wide x 6.5" thick is shadowed on each weld (DA through DF). This 3 volume is 2091 in . There is an overlapping volume of 167 in from the FR examination, leaving an unexamined volume of 1924 in per weld. The unexamined volume is equal to 11.9% of the required 16,108 in per weld.

The 0 weld metal examination Figure 2a of a volume 9.9" long x

9. 2" wide x 6. 5" thick is shadowed on each weld (DA through DF).

Thjs volume is 592 in3. There is an overlapping volume of 47 in from the FR examination leaving an unexamined volume of 545 in pen weld. Tge unexamined volume is equal to 11.9% ot the recgxired 4560 in per weld.

45 The 45 examination of the volume shown in Figure 2b is shadowed.

This volume is 278 in . There is an overlapping volume of 121 IV.5

REPORT /I 1 in 3 from the FR examination leaving an unexamined volume of 156

~

in per weld. The unexamined volume is 3.4% of the required 4560 in per weld.

60o The 60 examination o$ a volume as shown in Figure 2c is shadowed.

This volume is 159 in - There is an overlapping volume of 85 in from the FR examination leaving an unexamined volume of 74 in per weld. The unexamined volume is 1.6% of the required 4560 in per weld.

Figure 2d shows a composite of the examinations of the shadowed portion of welds DA through DF. The total volume missed by all examination angles is 53 in . This is equal to 1.2% of the total examination volume per weld.

In an effort to increase the coverage of the unexamined volume partially examined volumes, the following analysis was used: and'he

1. No increase to the 0 examination volume was possible due to the curvature at, the FR to bottom head junction. This curvature caused loss of transducer contact. On Unit Nl, smaller transducers were tried but were'unable to generate sufficient output as noted in G.E. Lockyer's summary report on loss of contact.

2. All beam 0

angles in the range of shear waves, 35 to 68 , were considered. Angles below 45 were eliminated since the examination coverage would be reduced. The beam angles from 60 to 68 were analyzed. These angles would allow only a very small increase in the size of the partially examined volume and no increase in the size of the completely examined volume. No angles above' 68 were considered because o f the surface wave

~

generation phenomena described by Krautkramer and Schlengermann.

3. All pertinent vessel manufacturer's drawings were presented to K. B. Aerotech, who acted as a con-sultant. Utilizing the drawings, Aerotech suggested angles in the 40 45 and 55 60 range as being appropriate for the examination. It was noted IV.6

'0 REPORT //1 during the discussion that very little gain in examined volume was possible, within Section XI parameters, by an angle change.

4. The possibility of examination from the vessel I.D. was eliminated because of double refraction and scattering of the sound beam due to the cladding.

RESTRICTION TO EXAMINATION DUE TO CRD PENETRATIONS There are 15 CRD penetrations bored through the centerline of welds DG and DH. By angulation of the search units, the required volume for each weld was examined within the parameters of Section XI.

The limited scan noted on the data sheets was to point out that due to these penetrations, the transverse scan of the welds was limited to one direction near the holes.

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REPORT 82 SU!QfARY REPORT: RPV, Unit 81, Tophead Nozzle Welds H6A and H6B Resolution of Spurious UT Indications

REFERENCE:

Pennsylvania Power and Light Company Susquehanna Steam Electric Station Contract Ho. 8856-M-166 RPV Pre-Service UT Examination I INTRODUCTION In order to document the ideas, discussion and action taken throughout the analysis of the "spurious" indications detected in the subject nozzles, this report is presented in full detail at the request of Pennsylvania

'I Power and Light Company.

C II. DISCUSSIOH 4 On Dece mber 10, 1976, a routine UT examxnatxon on the subject nozzles .using a 60'ngle beam was conducted by S. Metta, UT Level II,

. and R. Hooper, UT Level I; using a Sonic MK1 (Serial Ho. 732203) and accessory equipment as specified and controlled by UT procedure Ho.

ISE-QA1-325, Rev. 2 Indications were detected of varying magnitude (25X DAC to as high as 5 dB above 100X DAC), ranging in apparent depth from approximately 1.5 inches to 3.0 inches (maximum magnitudes at 2.0 inches to 2.5 inches). Depths varied depending on transducer position on the surface of the head, which ranged from 4.5 to 8.0 inches from the center-line of the weld.

Figure 1 shows a plan view of the outside top head assembly, as well as an enlarged view of the surface scan pattern (typical of both nozzles) where the indications were detected. Figure 2 is a section through a nozzle along the 0 /180'eference line, and shows a typical transducer position for a 100 + X DAC indication at an apparent depth of 2.5 inches. This indication could be finger dampened on the inside surface of the head which was nominally 3.5 inches in depth or thickness.

. IV.17 GENERAL 'LECTR)C

i j

0 I

1 i

REPORT //2 Note: It is important to mention that procedure ISE-QA1-325, Rev. 2, required calibration of the UT inspection system in "depth",

rather than "metal path".

The obvious question is . . . how does one finger dampen an indication at an apparent depth of 2.5 inches on a surface which is equivalent to 3.5 inches in depth from the scanning surface. This question lead to the initial analysis involving mode conversion, which later proved to-I be incoxrect.

A. Initial Anal sis

.It is well-known, and recognised in the code, that mode conversion using 60 angle beam is often a problem, particularly with reflectors oriented perpendicular to an opposite reflecting surface which is parallel to the scanning surface. In order to illustrate this point,'onsider the case of oblique incidence of a shear wave at a free surface; i.e., a surface bounded by air. The directi'on of the re-flected shear and longit'udinal waves is given in terms of the incident wave by Snell's law:

where $ ~. incident S-wave angle e reflected L-wave angle Vs ~ S-wave velocity in the medium VL ~ L-wave velocity in the medium As illustrated in Figure 3, the angle of the reflected S-wave equals the incident S-wave up to the critical angle which is shown to be around 30 in the graph of Figure 3. The significance of this illustration is that at an incident S-wave angle approaching 30'ost of the energy is converted and reflected as an L-wave; the equations defining, the relative amplitudes of the respective waves are complez. and do not serve our purpose. Beyond the "critical" IV.18 GENERAL l<LECTRlC

REPORT 82 angle the L-wave disappears and all the energy reflected is in the form of an S-wave again.

This phenomenon has practical implications as it relates to the 2X milled notch in an ASME Section XI calibration. block. In order to amplify this point, consider the enlarged sketch of such a notch, and the incident S-wave at 60'hown in Figure 4. As depicted, after reflection. from the opposite surface of the block, the energy is'incident at the face of the notch at 30 , which is the angle for conversion of the S-wave to predominantly L-wave energy. Me have 1

indicated a single ray in our illustration. The reflection of a beam of sound containing a discrete range of angles near 30

~

produces an indication from the notch of relatively small magnitude; most of the energy being converted into an L-wave and I

lost to the system.

U Referring again to Figure 2, the initial analysis was that an S-wave traveling to the bottom surface of the head would arrive at a time corresponding to one-half the 3.5 inch depth or about 1.7

.inches. Reflection from a r'eflector oriented favorably (near'0 )

to the surface could produce mode conversion as described above.

The L-wave traveling back to the surface would require a time equivalent to about 0.8 inches, since the L-wave travels at approximately twice the velocity of the S-wave. The total time equivalent would then be 2.5 inches; 1.7 inches down as an S-wave and 0.8 inches back as

-an L-wave.

At this point, original final acceptance radiogrhphs of these welds were obtained for review. These radiographs were of excellent quality-, and shoved no indications of reflectors in the areas in IV.19 GENERAL ',ELECTRIC

0 REPORT /f2 question. Further, attempts to verify the above occurrence were unsuccessfu1, both graphically and analytically. Hindsight into the situation indicated that the initial analysis was, after all, rather weak.

In order to resolve the problem, other equipment was used to investigate the phenomenon. The use of a Branson 303 on one occasion, and a Branson 301 on another failed to produce the indications, which could still be reproduced with the original Sonic equipment.

It was obvious at this point that the phenomenon was equipment related. Colloboration with R. Holt; NED Level III, led to the following analysis regarding equipment pulse repetition rate.

B. Pulse Re etition Rate Anal sis

'efore beginning this analysis, it should be stated .that the intent here is to be descriptive rather than rigorous.

At the same time, the evidence presented vill substantiate the final conclusion as to the cause of the spurious indications.

't is well-known, but little observed as a practical problem~

that pulse repetition rates for certain sweep ranges can be critical in some UT applications. In UT pulse-echo equipment, sweep length or range control and pulse repetition are integrated so as to automatically provide uniform sweep trace brilliance with changes in range or sweep length. Moreover, some equipment provides for ranges of pulse repetition by way of a separate rep rate selector switch. Each rep rate range, in turn, is integrated with sweep length to provide variable pulse repetition with changes in sweep length.

IV.20 GENEIIALELECTRIC

0',,

REPORT /32 arith this in mind, the original Sonic equipment was calibrated using a different sweep range setting; i.e., a zero to 10 inch range instead of a zero to 5 inch range. The indications previously reported disappeaxed. The original calibration was repeated, and the indications returned. While the indications were visible on the screen the repetition rate selector switch 'was changed. from the 3000 range to the 1000 range; again the indications disappeared.

arith the equipment set up in this manner, the sweep was delayed to the left to reveal an indication from a geometric reflector at a metal path of approximately 27 inches.

'The "spurious" indications originally recorded at a depth of 1.5 to 3.0 inches were, in fact, caused by geometric reflection within the nozzle at a distance far beyond the range of interest.

The magnitude and depth varied with changes in transducer position but all were confirmed to have resulted from part geometry rathex than flaws. ,The high rep rate at the 3000 range created what, are referred to as a "wrap around" indications whose apparent depths were within the calibrated range of interest. The following discussion summarizes the essential aspects of a presentation made by the writer to personnel from PP&L, theix Authorized Inspectors, and G.E. I&SE.

Illustrated in Figure 5 is a square wave superimposed and in sync with a saw tooth voltage. The saw tooth causes the CRT

. sweep from left;to-right; a low and a high rep rate are compared.

The square wave provides sweep brilliance from left.-to-right and darkness on the return. Immediately below these voltage representations is the CRT presentation of the back surface reflection from the block shown at thy left. This "picture" is repeated at a frequency IV.21 GENERALO-ELECTRIC

~ '

e

REPORT 82 corresponding to the pulse repetition. At a rep rate of 1000 per second, for example, the "picture" repeats 1000 times per second, providing persistency of vision on the CRT. During the 1I dark II time between pulses, the sound reverberates back and forth in the block (illustrated by the dotted multiple order indications of the back surface), finally dying out before the next repetition as shown for the low rep rate illustrati'on. However, as shown in the lower portion of the figure, if the rep rate is too high the multiples of the back surface may not have completely died out before I

the next pulse is repeated. This results in superimposing the next "p'icture" over a distant multiple order of the back surface

~ I as illustrated.

'igure 6 shows the xeflection from the nozzle geometry which led to the pxoblem. A calibration in metal path was made as'llus-trated in order to verify the overall distance to the reflector; total metal path to the reflector was determined to be 27.2 inches.

The sound path to the reflector could be verified by damping the indication at reflection points on both'he inside and the outside of the nozzle. Careful graphical analysis confirmed these results.

Comparison of the effect of low and high rep rates is shown at the bottom of Figure 6 for this situation.

III. CONCLUSION Having proved the origin of the "spurious" indication to the" satis-faction of the customer and their Authorized Inspectors, it was decided to perform a complete 60'ngle beam reinspection of the N6 nozzles at an instrument rep rate of 1000. This inspection, which revealed no xecordable indications, is a part of the permanent record.

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G.. ockyer~Level III Manager, NDT Product Service IV.22 Building 6 Room 227 GEL: KFP C ER ERA LO-ELECTRIC

0' STUD No 99 STUD Mt REPORT 82 0

SERVICF. /~ AG(TOP HKAO TO FLANGE)

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'/0 1'igure 1. Plan view of top head and transducer scan pattern on typical N6 nozzle.

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Held Center Line 7~g IC Point Dampened Figure 2. Section through N6 nozzle at 0'/180', showing typical indication at apparent 2.5" depth.

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RZPORT /P2 SERVICE Normal ANYT(ME...

ANYWHERE IN5IAIIAIIONA 5NVIC5 INOINIIRINO PIVI5ION Xnterface Steel Air Oblique Incidence of Shear Wave 1.0 S-Wave L-Wave l0 20 30 40 Angle of Incidence Figure 3. Amplitudes of reflected components generated at a free surface by an incident shear wave in steel.

0 SERV(CE . REPORT 82 ANYTIME...

hNYWHERE IH5IALLAIIONA SIAVIC5 KNOINIIRINO DIVI5ION Sc.wM uL b5 4 SUE, F '<c:

S~4 Io~ e Y5: V~

EV. 26

I Figure 5. Square and saw tooth voltages, and CRT presentation of block reflections for a low and a high pulse repetition rate.

SFRV'CC REPORT P2 f

ANYTIME...

AHYWHCAC

+) L~i 1I LN 4 IION ~ I I I VICI

'NIIIW4 DIVI$ION Sc ~it geP 7a~6'o00 4o Sc fze<u RA&

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QgAMSo~ 3o 3, SoM~4 gee Chi~ 3 Figure 6. Illustration of geometric reflector, in N6 nozzle, and comparison of low and high pulse repetition rate.

IV.28

0 RFPORT 83

SUBJECT:

Summary Report Geometric UT Reflections in N3, N4, N5 Nozzles Using 60'ngle Beam, and in CG "Knuckle" Veld Using 45'ngle Beam

REFERENCE:

Pennsylvania Power and Light Co.

Susquehanna Steam Electric Station Contract Number 8856-?3-166 RPU Pre-Service Examination Xn ultrasonic weld testing, indi'cations from component con'figuration can be analyzed by pure geometric reflection concepts. While mode conversion at oblique incidence exists to a significant extent in these UT applications, the associated changes which take place in velocity and direction generally eliminate mode conversion as a consideration where reflections from component geometry are concerned. Therefore, the analysis 'of the geometric reflections in the subject welds follow's the basic incidence/reflection laws of. optics.

To illustrate the concepts involved'onsider Figure 1,"wherein a typical nozzle geometry and related weld locaticm, as well as transducer posi-tion and sound beam are Q.lustrated. As shown, normal (perp'endicular) geometric reflection from the inner radius of the nozzle occurs for only'hose rays which pass through the geometric center of the nozzle radius.

Of course, the greatest geometric reflection 'illustrated is associated with that transducer position (A) which directs the most intense portion of the beam (central ray) through the geometric center of the radius, at which point it returns directly back along the central ray to the transducer.

However, it is particularly significant to note that in this position the beam is no longer interrogating the material volume of interest for this scan direction. Within the scanning zone of interest, i,t is, the less intense rays toward the edge of the beam which produce the geometric incidence/

reflection causing the indications from the nozzle radius as shown for transducer positions B and C.

e IU.29 GENEIIAL ELECTRIC

REPORT 83 In order to verify the sub)ect weld geometry reflections by graphical means, it was necessary to calibrate the UT system in "metal path" rather than in "depth" as required by the applicable procedure. Calibration in metal path provides a graphical double check on the validity of transducer position, beam angle and sound distance traveled in relation to.component geometry. Accordingly, Figures 2, 3 and 4 show typical graphical r

presentations which verify the geometric reflections reported for the N3, N4 and N5 noza1es respectively..

The geometric reflection from the inside curvature of the CG weld I

using 45 angle beam is shown in Figure 5. As illustrated, the maximum I

indication'rom this inside surface occurs at that point where. the trans-ducer is in a position to provide pure geometric reflection from some portion of the beam.

The information above is presented to serve's a "base-line" against which geometric reflections detected in these welds during subsequent UT inspections can be compared. Obviously, variations in"magnitude of indication, as well as metal path distances, will occur with varying transducer position .

S and beam angle and should be considered I

~

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in future

. L lfanager, Building comparisons.

ckyer, Level

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III NDT Product Service 6 Room 227 GEL: KEF IV. 80

0 0

Transducer Index Point el CO Center of Nozzle Radius Vessel Wall

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Pigur e 4. Typical geometric reflection from radius of N5 nozzle MP 12.2" determined by UT measurement agrees well with graphical determination.

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gQ Weld Scale: 1 cm ~ 1 in.

1 Figure 3. Typical. geometric reflection from radius of N4 nozzle; HP = 12.4" determined by UT v~ r0 measurement agrees well with graphical determination.

5a

.N IJ ga gg gX o'r i E w L XX ~w r LIJ N

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l. Geometric reflections and related sound metal paths fear various Figure transducer positions in a typical nozzle.

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Figure 2. Typical geometric reflection from radius of N3 nozzle; HP ~ 15.8" determined by UT 0 OZ pR e measurement agrees well with graphical determination.

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SERVICE REPORT /l3 0'NYTIWIf...

At(YYIHfRf IN5IA55AIIONC 55CVICC Ql pg,h I15l)uC.PIC (HOINIICINO OIVIIIOH [,Uccx, Po(MT Ce t

Q> TT(@hJ bSULEIZ LlJbl~g PdtH7 IV. 35

PAGE 1 REPORT f!4 f~~l i o'cc AuYTr H... January 14, 1977 as;vyi r.=Pic

.JP IHOlALLAT<DII4 S RVICE CiiGINEfAIHGOIVISION

SUBJECT:

Acoustic Velocity and Attenuation Determinations:

Reactor Pressure Vessel Calibration Standards jjl; jj2 and jj3 (SA533) and Upper Vessel and Hating Top Head Flanges (SA508)

REFERENCE:

ASHE Boiler and Pressure Vessel Code,Section IX, 1974 Edi tion, Summer 1975, Paragraph I-3121 (Block Selection)

DRAWINGS: GE-160-76C-0087 Rev. 1 Reactor Pressure Vessel Std. g GE-160-76C-0088 Rev. 0 Reactor Press'ure Vessel Std. g2 GE-160-76C-0089 Rev. 0 Reactor Pressure Vessel Std. g3 CB IN-27 Rev. 3 Shel I Flange Detai s 1 Paragraph l-3121'referenced above) requires that "...(3) when it is not possible to fabricate the block from material taken from component, it may be fabricated from a material of a specification

'he included in the applicable examination volumes of the component.

The acoustic velocity and attenuation of such a block shall be demonstrated to fall within the range of straight beam longitudinal wave velocity and attenuation found in the unclad, component."

Accordingly, UT Examination Team jj4 (S. Hetta and R. Hooper) performed velocity and attenuation evaluations on the subject materials, VELOCITy COHPARISON

( January 11, 1977)

CALIBRATION: Calibrated the Sonic HK1 with 220 thickness Adapter to the 28.00" and'17.00" dimensions on Cal. Std. jjl and jj3 respectively.

NOTE: The 220 Adapter has a range of 20.00", In order to get the 28.00" range - the Velocity Adjustment was halved and the readings taken off the Digital Read Out were +> of the "real" readings.

IV. 36 0 E W E 8AL "';i'E L E 0 '7 Pi I C

I f

1

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l 0

Page 2 REPORT iI4 It<~tALLAT>b' h SLRVICt ticG:i<t thn.G 0>wS<C'M EXAMINATION:

MEASURED ON BLOCK DIGITAL READING MEASURE BY SONIC HKI 27.95>> 13.98 X 2= 27.96>>

6 95 I I 8.48 X 2~ 1.6.96>>

MEASURE ON VESSEL FLANGE DIG ITAL READ ING MEASURE BY SONIC HK1

~

26.00 13.00 X 2= 26.00>>

26.00 13.01 X 2~ 26.02>>

26.00 13. 02. X 2= 26.04<<

26 ~ 00 13.00 X 2= 26.00 NOTE: Readings taken on bottom side of" flange; ( No instument settings were changed. ) See Figure 1.

The, technique and results described above for velosity comparison are sufficient to show that the subject materials (SA533 and SA508) are. "...within the range..." of velocity required by the Code.

ATTENUATION COMPARISON

( January 13, 1977 )

, CALIBRATION: The transduer was positioned on RPV Standard g2 at approximately 1 3/4" from the edge as shown in Figure

2. The signal amplitude from the back surface was then set at 80% FSH. This was the. primary referance level.

EXAMINATION: The transducer was placed at 4 locations between the stud holes on the Top Head F.lange at approximately 3/4>> from the edge of the OD surface (See Figure 3).

The back surface signal was then adjusted to determine the db difference necessary to obtain the 80% FSH primary reference level (See Table 1 ).

IV. 37

'6 E f! E Pa AL f~;.~r'c;) E LE C7 R t C

'i:;. Page 3

~

REPORT II4

~Fvsicrg-r fJ AttYT1:..a..r Att Y Vt t r . r \6

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IHCTACCATIOII& CRVICC crrGIIrccAIIIGolvlslorI TABLE Position db Difference 1

2 3

4 NOTE: Hinus db readings correspond to a higher amplitude on the Top Flange which is on the " safe " side.

This technique, although not sufficent for a quantitative determination of aco'ustic attenuation, shows that these materials are "...within the range..." of attenuation required by the Code.

G.E. Lockyer Level 111 'DT cc B.W. Wi lkins IV. 38 GEtt 8 ttAL j"'(gi) ELECTR lC r ~

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0

REPORT II4 SERVICE AMYTV48...

JVSYW%RE i-INSTALLATION~ SShVICK SNGINSSNINO OIVISION rI I

I l

26" Q

<<Q CBlN-27 Rev. ¹3 Sect. A-A TRANSDUCER P gI (

g Plj F L QIU GlF IV. 39 I/ (4(T7 GENERAL@ ELECTRIC

I 1

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. IiyCpy REPORT /l4 Szi VlCK ()

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INSTALLATIONS SSRVICK SNGINSCRINQ DIVISION I

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EV. 41 GEIIERAL QOI ELECTRIC

e, 0

REPORT /$ 5 AEE~...

ANYWRKRK IHCTAI.LATIOH4 SKIIVICE fRQINEKIIINOOIVISION

Subject:

Sumnary Report of loss of UZ Transducer Contact Due to Curvature of CG Weld REFEfKNCE: Pennsylvania Power and Light Company Susquehax~a Steam Electric Station Contract Number 8856-4I-166 RPV Preservice lamination

'Ihe attached sketches illustrate the area of the base metal and adjacent weld in the vicinity of the CG weld which could not be inspected because of the loss, of UZ transducer contact at the curvatures as shown. Ihe centerline of the CO weld as painted on the vessel surface, is really at the edge of the CG weld shown on the sketch. 'Ihe area of no UZ inspection extended from 2" to 6" from the painted centerline during inspection of weld CG. 'Ihese curvatures to skirt and from ~

also caused loss of contact affecting welds to AJ.

DA, DB, DC, DD, DE, and DF from AA It should be noted that, although the use of smaller transducers veld have improved contact area, analler t~ucers were determined to be inadequate because of insufficient output.

George E. Lockyer, Level III Manager ASBD-NDZ IV. 42.

GENERAL ELECTRIC

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0 0

REPORT 86 COMPOSITE OF THE MANUAL AND REMOTE AUTOMATIC PRESERVICE EXAMINATIONS FOR SUSQUEHANNA UNIT /Pl Composite includes all exclusions to the baseline examination and the basis/justification for the exclusions.

General Electric Company Maschellmac Office Complex 1000 First Avenue King of Prussia, PA 19406 IV. 45

l ~ '

REPORT f/6 CATEGORY BA PRESSURE RETAINING WELDS IN REACTOR VESSEL CIRCUMFERENTIAL SHELL WELDS WELD SEAM AA AA TOP SIDE Remote Automatic Examination Covera e There were five (5) interferences on weld seam AA top that caused missed areas during the remote automatic examination. These were:

I Nozzle NIA 66" Missed Nozzle NIB 66" Missed Nozzle N8A 36" Missed Nozzle N8B 36" Missed Surface Gouge 4" Missed*

TOTAL 208"" Missed

'Ihe circumference of weld seam AA is 837".

The interferences caused 24.85 percent of weld seam AA top to be missed during the remote automatic examination. *The 4" missed due to the surface gouge will be examined during the first ISI. The surface has been conditioned to allow examination. The missed area will at that time become 24.37 percent.

Manual Examination Covera e The nozzle interferences listed for the automatic examination do not exist for the manual examination. The nozzles Nl's and N8's are far enough from the weld centerline to allow a complete examination in accordance with Paragraph I-5121 of Section XI, Appendix I.

AA BOTTOM SIDE Remote Automatic Examination - Not Performed Manual Examination Covera e No interferences. One hundred percent coverage.

IV, 46

'e REPORT 86

SUMMARY

WELD SEAM AA One hundred percent of weld seam AA was manually examined in accordance with Appendix I of ASME Section XI. In addition, 75.15 percent of the top side of weld seam AA was examined using remote automatic equipment. Manual data exists for the- 12s42 percent of the weld seam missed by the remote scanner and when combined with the remote examination data provides 100 'percent coverage.

Recommendation for ISI Examine the missed areas of AA top manually while examining AA bottom.

WELD SEAM AB Remote Automatic Examination Covera e Weld seam AB was examined 100 percent by the remote automatic equipment.

WELD SEAM AC Remote Automatic Examination Covera e Weld seam AC was examined 100 percent by the remote automatic equipment.

WELD SEAM AD AD TOP SIDE Remote Automatic Examination Not performed.

Manual Examination Covera e No interferences - 100 percent coverage.

AD BOTTOM SIDE Remote Automatic Examination Covera e There were two (2) interferences on weld seam AD hottom that caused missed areas during the remote automatic examination. These were:

IV. 47

4

REPORT /36 AD BOTTOM SIDE (Continued)

Nozzle N11A 47" Missed Nozzle N11B 41" Missed TOTAL 88" Missed The circumference of weld seam AD is 838". The interferences caused 10.5 percent of weld seam AD bottom to be missed during the remote automatic examination.

Manual Examination Covera e No interferences - 100 percent coverage.

SUMMARY

FOR WELD SEAM AD One=hundred percent of weld seam AD was manually examined in accordance with Appendix I of ASME Section XI. In addition, 89.5 percent of the bottom side of weld seam AD was examined using remote automatic equipment. Manual data exists

'for the 5.25 percent of the weld"seam missed by the remote scanner and w?yn combined with the remote examination data provides 100 percent coverage.

Recommendation for ISI Examine the missed areas of AD bottom manually while examining AD top.

WELD SEAM AE Manual Examination Covera e Weld seam AE was examined 100 percent by manual techniques.

IV.48

Si REPORT /f6 Manual Examination Covera e Weld seam AF was examined 100 percent from one side in accordance with Paragraph 1-5121 of ASME Section Xl, Appendix I. In addition, a 0 only examination of weld AF was performed from the top surface of the vessel flange.

EXCLUSIONS No exclusions are required for the reactor pressure vessel circumferential welds AA, AB, AC, AD,J AE and AF.

I'V.

49

I

REPORT f16 CATEGORY BA PRESSURE RETAINING NELDS IN REACTOR VESSEL LONGITUDINAL SHELL WELDS WELD SEAM BA Remote Automatic Examination Covera e There was one t,'1) interference,,on weld seam BA left side that caused a missed area during the remote automatic examination. This was:

Nozzle N2K 43" Missed The length of weld seam BA is 137".

The interference caused 31.38 percent of weld seam BA left side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

SUMhQRY WELD SEAM BA Eighty-four and three-tenth percent of weld seam BA was examined in accordance with Appendix I of ASME Section XI using remote automatic techniques. Manual data exists for the 15.7 percent of the weld seam missed by the remote scanner and when combined with the remote examination data provides 100 percent coverage.

Recommendation for ISI Exclude the 15.7 percent of weld seam BA missed by the remote scanner. Justification:

Radiation exposure and restricted access. The 84.3 percent examined provides adequate sampling to determine the condition of the weld seam.

IV. 50

REPORT 86 WELD SEAM BB BB LEFT SIDE CW Remote Automatic Examination Covera e There was one (1) interference on weld seam BB left side that caused a missed area during the remote automatic examination. This was:

Nozzle N2C 46" h1issed The length of weld seam BB is 137".

The interference caused 33.57 percent of weld seam BB left side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

BB RIGHT SIDE CCW Remote Automatic Examination Covera e No interference. One hundred percent coverage.

SUMMARY

WELD SEAM BB Eighty-three and two-tenth percent of weld seam BB was examined in accordance with Appendix I of ASh1E Section XI using remote automatic techniques. h1anual data exists for the 16.8 percent of the weld seam missed by the remote scanner and when combined with the remote examination, data provides 100 percent coverage.

Recommendation for ISI Exclude the 16.8 percent of weld seam BB missed by the remote examination.

Same logic as weld seam BA.

WELD SEAM BC Remote Automatic Examination Covera e There was one (1) interference on weld seam BC left side that caused a missed area during the remote automatic examination. This was:

Nozzle N2F 44" h1issed IV. 51

)',

I l

I I

REPORT /l6 WELD SEAM BC (Continued)

The length of weld seam BC is 137".

The interference caused 32.12 percent of weld seam BC to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

BC RIGHT SIDE CCW Remote Automatic Examination Covera e There was one (1) interference on weld seam BC right side that caused a missed area during the remote automatic examination. This was:

Nozzle N1B 69" Missed The interference caused 50.36 percent of weld seam BC right side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

SUMMARY

WELD SEAM BC Fifty-eight and eight-tenth percent of weld seam BC was examined in accordance Appendix I of ASME Section XI using remote automatic techniques. Manual 'ith data exists for the 41.2 percent of the weld seam missed by the remote scanner and when combined with the remote examination, data provides 100 percent coverage.

Recommendation for ISI Exclude the 41 ' percent of weld seam BC missed by the remote examination.

Same logic as weld seam BA.

IV. 52

e

REPORT /J6 WELD SEAM BD Remote Automatic Examination Covera e Weld seam BD was examined 100 percent by the remote automatic equipment.

WELD SEAM BE Remote Automatic Examination Covera e Weld seam BE was examined 100 percent by the remote automatic equipment.

WELD SEAM BF Remote Automatic Examination Covera e There was one (1) interference on weld on weld seam BF left side that caused a missed area during the remote automatic examination. This was: ~

Nozzle N16B 18" Missed The length of weld seam BF is 137".

The interference caused 13.14 percent of weld seam BF left side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

Remote Automatic Examination Covera e There was one (1) interference on weld seam BF right side that caused a missed area during the remote automatic examination. This was:

Nozzle N16B 44" Missed The interference caused 32.12 percent of weld seam BF right side to be missed during the remote automatic examination.

Manual Examination Covera e N16B interference. One hundred percent coverage*.

• NOTE: An area 15" long was examined in one direction only for parallel reflectors in accordance with the requirements of Paragraph I5121 of ASME Section XI, Appendix I.

Dt'..53

REPORT /j6

SUMMARY

WELD SEAM BF Seventy-seven and four-tenth percent of weld seam BF was examined in accordance with Appendix I of ASlK Section XI using remote automatic techniques. Manual data exists for the 22.6 percent of the weld seam missed by the remote scanner and when combined with the remote examination data provides 100 percent coverage.

Recommendation for ISI Exclude the 22.6 percent of weld seam BF missed by the remote examination.

Same logic as weld seam BA.

NELD SEAM BG Remote Automatic Examination Covera e There was one (1) interference on weld seam BG left side that caused a missed area during the remote automatic examination. This was:

RPV Stabilizer Bracket 8" Missed The length of weld seam BG is 137".

The interference caused 5.8 percent of weld seam BG left side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

BG RIGHT SIDE CCN Remote Automatic Examination Covera e There was one (1) interference on weld seam BG right side that caused a missed area during the remote automatic examination. This was:

RPV Stabilizer Bracket 8" Missed The interference caused 5.8 percent of weld seam BG right side to be missed during the remote automatic examination.

IV. 54,

4 REPORT /!6 WELD SEAM BG (Continued)

Manual Examination Covera e No interference. One hundred percent coverage.

SRMARY WELD SEAM BG Ninty-four and two-tenth percent of weld seam BG was examined in accordance with Appendix I of ASME Section XI using remote automatic techniques. Manual data exists for the 5.8 percent of the weld seam missed by the remote scanner, and when combined with the remote examination data provides 100 percent coverage.

Recommendation for ISI Exclude the 5.8 percent of weld seam BG missed by the remote examination. Same logic as weld seam BA.

WELD SEAM BH BH LEFT SIDE CW Remote Automatic Examination Covera e There was one (1) interference on weld seam BH left side that caused a missed area during the remote automatic examination. This was:

RPV Stabilizer Bracket 10" Missed The length of weld seam BH is 137".

The interference caused 7.3 percent of weld seam BH left side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

BH RIGHT SIDE (CCÃ Remote Automatic Examination Covera e There was one (1) interference on weld seam BH right side that caused a missed area during the remote atuomatic examination. This was:

IV. 55

REPORT 86 WELD SEAM BH (Continued)

RPV Stabilizer Bracket ll" Missed The interference caused 8.0 percent of weld seam BH right side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

SUMMARY

WELD SEAM BH Ninty-two and four-tenth percent of seam BH was examined in accordance with Appendix I of ASME Section XI using remote automatic techniques. Manual data exists for the 7.6 percent of the weld seam missed by the remote scanner and when combined with the remote examination data provides 100 percent coverage.

Recommendation for ISI Exclude the 7.6 percent o'f weld seam BH missed by the remote examination.

Same logic as weld seam BA.

WELD SEAM BJ BJ LEFT SIDE CW Remote Automatic Examination Covera e There was one (1) interference on weld seam BJ left side that caused a missed area during the remote automatic examination. This was:

RPV Stabilizer Bracket 9" Missed The length of weld seam BJ is 137".

The interference caused 6.6 percent of weld seam BJ left side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

IV. 56

REPORT 86 WELD SEAM BJ (Continued)

BJ RIGHT SIDE CCW Remote Automatic Examination Covera e There was one (1) interference on weld seam BJ right side that caused a missed area during the remote automatic examination. This was:

RPV Stabilizer Bracket 8" Missed The interference caused 5.8 percent of weld seam BJ right side to be missed during the remote automatic examination.

Manual Examination Covera e No interference. One hundred percent coverage.

SUMMARY

WELD SEAM BJ Ninty-three and eight-tenth percent of weld, seam BJ was examined in accordance with Appendix I of ASME Section XI using remote automatic techniques, Manual data exists for the 6.2 percent of the weld seam missed by the remote scanner and when combined with the remote examination data provides 100 percent coverage.

Recommendation for ISI Exclude the 6.2 percent of weld seam BJ missed by the remote examination. Same logic as weld seam BA.

WELD SEAM BK Manual Examination Covera e No interference. One hundred percent coverage.

WELD SEAM BM Manual Examination Covera e No interference. One hundred percent coverage.

IV. 57

REPORT 86 WELD SEAM BN Manual Examination Covera e No interference. One hundred percent coverage.

WELD SEAM BP Manual Examination Covera e No interference. One hundred percent coverage.

IV. 58

i 4

REPORT f/6 CATEGORY BA PRESSURE RETAINING WELDS IN REACTOR VESSEL CIRCUMFERENTIAL AND MERIDIONAL l<ELDS IN VESSEL HEADS CLOSURE HEAD TOP)

The following circumferential weld seams were examined manually with 100 percent coverage:

AG (Head to Flange)

AH (Dollar Plate to Side Plates)

The following meridional weld seams were examined manually with 100 percent coverage:

DJ (Side Plate to Side Plate)

DK (Side Plate to Side Plate)

DM'Side Plate to Side Plate)

DN (Side Plate to Side Plate)

DP (Side Plate to Side Plate)

DR (Side Plate to Side Plate)

SRMARY FOR CLOSURE HEAD lKLD SEAMS All weld seams in the RPV closure head were examined in accordance with Appendix I of ASME Section XI using manual examination techniques. There were no interferences to the examination.

BOTTOM HEAD The following circumferential weld seam was examined manually with 100 percent coverage:

AJ (Dollar Plate to Side Plates)

The following longitudinal weld seams were examined manually with 100 percent coverage:

DG (Dollar Plate Longitudinal Seam)

DH (Dollar Plate Longitudinal Seam)

IV. 59

'I

REPORT /!6 BOTTOM HEAD (Continued)

The following meridional weld seams were examined manually with partial coverage due to interference:

DA (Side Plate to Side Plate)

DB (Side Plate to Side Plate)

DC (Side Plate to Side Plate)

DD (Side Plate to Side Plate)

DE (Side Plate to Side Plate)

DF (Side Plate to Side Plate)

The weld buildup for the vessel skirt attachment caused an interference to the manual examination of weld seams DA - DF. The interference caused unexamined volumes as follows:

0 0 Base Metal Exam 12~a Missed 0- t'teld Metal Exam 12~~ Missed 4S Exam 4~~ Missed 60 Exam 2w Missed A composite of all examination angles shows that a volume equal to 2 percent of the required examination volume for welds DA - DF is completely unexamined.

An exclusion of this 2 percent will be required.

IV. 60

0 REPORT /36 CATEGORY BD PRIMARY NOZZLE-TO-VESSEL tbtELDS AND NOZZLE INSIDE RADIUSED SECTIONS The following nozzle-to-vessel welds were examined 100 percent using remote automatic examination techniques:

NIA and B - Recirculation Outlet Nozzles N2 A, B, E F G and K - Recirculation Inlet Nozzles N3 A B C and D Main Steam Outlet Nozzles N4 B, C E and F - Feedwater Inlet Nozzles NS A and B - Core Spray Inlet Nozzles The following nozzle-to-vessel welds were examined partially using remote automatic examination techniques:

Recirculation Inlet N2 Nozzles .

N2C 288. 8 Completely examined Examined with a short scan due to interference from nozzle N8A N2D 313.5 Completely examined 46.5 Examined with a short scan due to interference from nozzle N8A NZH 314.9 Completely examined 45.1 Examined with a short scan due to interference from nozzle N8B N2J 321.5 Completely examined 38.5 Examined with a short scan due to interference from nozzl'e N8B IV. 61

REPORT //6 SUMfARY OF N2 PARTIAL EXAMINATIONS The interferenc from the N8 nozzles caused a short scan of the affected areas.

A scan length of 16" from the weld centerline is needed to achieve a complete examination of the required examination volume. The N8 nozzle interference allowed only a 13.75" scan length. This caused a missed volume of 19 percent in the affected areas. (81 percent was examined)

Manual data exists for the 19 percent of the affected areas missed by the remote scanner and when combined with the remote examination data, provides 100 percent coverage.

Recommendation for ISI Exclude the affected areas of the N2 nozzles since only a partial code examination can be performed. Agree to perform the partial examination without full credit.

Basis for Exclusion Six (6) nozzles of the same configuration and location are being examined completely.

On the affected nozzles from 80.2 percent to 89.3 percent of the weld seam is being examined completely. In the remaining areas, 10.7 percent to 19.8 percent of the weld seam is being examined in 81 percent of the required volume.

The high radiation exposure associated with recirculation inlet nozzles makes manual examination of these areas to gain a small increase in examination coverage an ALARA violation.

FEEDWATER INLET N4 NOZZLES N4A 300 Completely examined 60 Not examined due to interference from nozzle N11A N4D 300 Completely examined 60 Not examined due to interference from nozzle N11B.

IV. 62

I

@I

REPORT //6 SUMQRY OF N4 PARTIAL EXAMINATIONS The proximity of nozzles Nll A and B to the affected feedwater nozzles precludes a complete Section XI examination of weld seams N4A and N4D. The spacing of 4.5" between the nozzles allows only a best effort manual examination of the areas. Partial manual data exists for the affected areas but does not provide 100 percent coverage. The 60 segments of weld seams N4A and N4D should be excluded from the baseline examination.

Basis for Exclusion The spacing of 4.5" between the Nll and N4 nozzles precludes a meaningful examination of the required examination volume.

The excluded area is 16.67 percent of the weld seam. 83.33 percent is completely examined.

Four (4) nozzles of the same configuration and location (N4 B, C, E, F) have been completely examined.

Due to configuration, manual examination yields no increase in examination coverage.

Recommendation for ISI Exclude the 16.67 percent of the weld seam as unexaminable. Same logic as baseline exclusion.

Manual Nozzle Examinations The following nozzle-to-vessel welds were examined 100 percent using manual examination techniques:

N6AJB Head Instrumentation Nozzles N7 Head Vent Nozzle N8AJB Jet Pump Instrumentation Nozzles N9 CRD Hydraulic Return Nozzle IV. 63

REPORT 86 CATEGORY BE PRESSURE RETAINING PARTIAL PENETRATION WELDS IN VESSELS The following partial penetration welds were examined for evidence of leakage during the system hydrostatic test on Susquehanna Unit ¹1.

NIO Core 6P and Liquid Control Nozzle Nll A 5 B Instrumentation Nozzles Shell Course ¹3 N12 A 5 B Instrumentation Nozzles Shell Cource ¹4 N13 Flange Seal Leak Detector Nozzle on Vessel Flange N15 RPV Bottom Head Drain Nozzle N16 A 5 B Instrumentation Nozzles Shell Course ¹2 Control Rod Drive Penetrations 185 In-Core Penetrations 55 e

IV. 64

0 REPORT 86 CATEGORY BF PRESSURE RETAINING DISSIMILAR METAL WELDS NOZZLE TO SAFE END WELDS Nozzle to safe end welds were examined in accordance with Table IWB 2600 of ASME Section XI.

The volumetric examination was manual ultrasonic testing in accordance with Appendix III of ASME Section XI.

The surface examination was liquid penetrant testing in accordance with Article 6 of ASME Section V.

The following safe end welds were completely examined in accordance with ASME Section XI:

Nl A 6 B Recirculation Outlet N2 A- K Recirculation Inlet N3 A- D Main Steam Outlet N4 A- F Feedwater Inlet NSA6 B (including extension) Core Spray Inlet N6 A 5 B Head Instrumentation N7 Head Vent B Jet Pump Instrumentation NBA'N9 CRD Hydraulic Return

• The N9 safe end has been removed and the nozzle has been capped.

The nozzle-to-cap weld has not yet been examined, but it can be completely examined.

IV. 65

REPORT 86 CATEGORY BG-1 PRESSURE RETAINING BOLTING TWO INCHES AND LARGER IN DIAMETER FLANGE CLOSURE NUTS Nut ¹1 - N ¹76 were completely surface examined in accordance with Table IWB-2600 of ASME Section XI. The examination was a wet magnetic particle examination in accordance with Article 7 of ASME Section V.

FLANGE CLOSURE STUDS Stud ¹1 - Stud ¹76 were completely examined by both volumetric and surface techniques.

The volumetric examination was ultrasonic in accordance with the requirements of Article 5 of ASME Section V. The surface examiation was a wet magnetic particle examination in accordance with Article 7 of ASME Section V.

LIGAMENTS BETWEEN FLANGE STUD HOLES The ligaments between stud holes 1 - 76 were volumetrically examined in accordance with Table IWB-2600 of ASME Section XI. The volumetric examination was ultrasonic in accordance with General Electric Company specifications.

FLANGE CLOSURE WASHERS Washer ¹1 - Washer ¹76 were visually examined in accordance with Table IWB 2600 of ASME Section XI. The visual examination was in accordance with Article 9 of ASME Section V.

'IV. 66

I l

~

REPORT 86 CATEGORY BH VESSEL SUPPORTS Weld *CG the support skirt to skirt knuckle attachment weld was completely examined volumetrically in accordance with Table IWB-2600 of ASME Section XI.

The volumetric examination was ultrasonic in accordance with Appendix I of ASME Section XI.

• NOTE:

The skirt knuckle was machined from a weld buildup designated as weld FR.

Weld FR was examined to the maximum extent possible as an addition to weld CG. Approximately 59 percent of weld seam FR was ultrasonically examined.

If FR is to be included in the baseline examination, an exclusion for the unexamined 41 percent is needed.

Recommendation for ISI Examine only weld CG, the ASME Section XI vessel support weld. If a decision is made to combine welds CG and FR for ISI, an exclusion will be needed for 41 percent of wel'd buildup FR.

IV. 67

REPORT 86 CATEGORY BI-1 INTERIOR CLAD SURFACES OF REACTOR VESSELS VESSEL CLADDING Six (6t) cladding examination patches were visually examined in accordance with Table INB-2600 of ASME Section XI. The visual examination was in accordance with Article 9 of ASME Section V.

Recommendation for ISI Cladding examination patches have been deleted from the examination requirements of ASME Section XI by later code years. If the code year selected by PPGL for the ISI plan allows, the cladding examination patches should be deleted from the ISI program.

IV. 68

REPORT 86 CATEGORY BN-1 INTERIOR OF REACTOR VESSELS VESSEL INTERIOR All items and surfaces above and below the core support plate were visually examined in accordance with Table INB-2600 of AS'ection XI. The visual examination was in accordance with Article 9 of AS'ection V. Items and surfaces normally accessible for ISI were also photographed to provide a comparison for ISI purposes.

IV. 69

REPORT 86 CATEGORY BN-2 INTEGRALLY WELDED CORE SUPPORT STRUCTURES AND INTERIOR ATTACHMENTS TO REACTOR VESSELS All core support and attachment welds were visually examined in accordance with Table IWB-2600 of ASME Section XI. The visual examination was in accordance with Article 9 of ASME Section V.

IV. 70

REPORT 86 CATEGORY BO PRESSURE RETAINING iYELDS IN CONTROL ROD HOUSINGS CRD HOUSING WELDS The welds in CRD housings were exempted from volumetric examination based upon plant makeup capacity. They were examined for leakage during the system hydro.

Recommendation for ISI Continue to examine the CRD housings as Category BO exempted components.

IV. 71

REPORT 86 CATEGORY BP COMPONENTS EXEMPTED FROM EXAMINATION BY ll(B-1220 EXEMPTED COMPONENTS All components exempted from examination were examined for leakage during the system hydro.

IV. 72

0 e

0

Engineers Constructors s

Fiity Beaie Street REPORT g1 San Francisco, Caiiiornia

. Mail Address: P.O. Box 3965. San Francisco. CA 941 t9 Pleose Reply To:

/

P.Q. Box 384 Berwick, Penna. 18503 August ll, 1977 General Electric Company ]' at-"

adjs ~

P.O. Box 382 "'AUG

.Berwick, Pennsylvania 18603 22 1977 Attent i on: Mr. E. A. Gus ta sonf -'";> = t Ig Q g Si te Manager

Subject:

Susquehanna Steam Electric Station Units 1 and 2 - Job 08856 Discrepant Threads in. Unit 1 RPF Flange 8856-M-1

Dear Mr. Gustafson:

Enclosed please tind one copy of GE/IPSE Preservice Visual Inspection Report, Control No. 750, for the Unit 1 PPV Flange. This report indicates apparent discrepancies in the. threads of stud holes Nos.

16 and 76. of Unit 1 RPV.

Please advise whether these discrepancies are acceptable per the technical requirements of your contract with CBFI and/or whether they have been previously documented and properly dispositioned during manufacture of the vessel.

Your response is requested by August 16, 1977.

Very truly yours, BECHTEL POWER CORPORATION E. E. Fel ton Field Construction Manager EEF/JEOS/hk cc." M. R. Mui r J. D. Green J. H. Galley S. E. Kni ght M. J. Lidl G. R. Shrader H. L. Harris Di'. 73

NUCLEAR ENERGY REPORT //7 DIVISION

" I BCt'II.ING WATER REACTOR GENERAl EI.ECTRIC COMPANY, S J QUEHANNA, SITE, P.O. BOX 382, BERWICK, PA 18603 Phon f717) 542-7391, Dial Comm 8'244-4231 PROJECTS DEPARTMENT August 15, 1977 EAG-461

>ifr. E. E. Felton Field Construction Manager Bechtel Power Corporatian Post Office Box 384 Pennsylvania 18603

'ersvick,

Subject:

Susquehanna Steam Electric Station, Unit ~1 RPV Stud Hole Examination, hfPL;r BllA001

Dear !Ir. Fel ton:

tI This will acknowledge receipt of your .August 11, 1977 letter

~ I (XI-1-241) regarding thy visual, examination findings of stud holes Nos. 16 and 76 by XRrSZ during their Xn-Service Xnspection.

Vi'e are enclosing copy of CBhX letter to the writer'.dated August 12, 1977, which .is self-explan'atory.. Ve condiser'he attache'd an acceptable explanation to the'.'IESE visual findings. 'etter Please advise immediately if you do not concu'r.

Very truly yours, GENERAL ELECTRIC CO./NZD

~ I Z... A. Gu'staf so Res'ident Site EAG/m.v Attachment (1)

.lanager'V.'4

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.!. union FAX 'Yilniing!on, Dcf.

August =12'977

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'-'~. E. J. Gu tafson Genera" Electric Comp~~v P.O. Boz 382 3 ~ic'~, ?ennsylvan'a 18603

/

Re: Stud Hole Inspection

'Susquehanna RPV Unit I CBI Contract 68-33316 Her;ric~, Pennsylvania hT"'<-355

Dear ~. Gustafson:

!.nis letter is in response to one'reservice Inspection Report, SQ1-761, dated August 2, 1977 reich you passed on to me for a. response. The report indicated thread damage on stud holes number 16 and 76.

The referenced damage c~waot correc ly be called damage. The missing and blunted thread conditions, as -;ve understand from Sl:etches:,Ill and g2 of the'eport, are ti e result of co<<~on too1 breakage thai occurs during the dr'ill,reaming and tapping operations. Zn the case of both holes, a spade blade cutter broke during the d-illing operation causing machine gouges in the side of the hole.

These i. re blended out before proceeding. The'esulting cavity'n some cases vali eztend beyond tn ream r size reich rn.ll result in blunt threads or no threads i the cavity .7as deep enough. 7 e vjere anare of these particular cases.

The resulting th"eeds in t¹s cases are acceptable as the effective thread length covers 8 3/8" minima~. These are evaluated on a case by case 'basis and revie',".ed vd.th the C" Inspector as reouired by CBI Dravring 4., General Note 15 if not evaluated as a nonconfo~'ty recuiring a RAD t,Request for Acceptanc o" Noncon ormity as a Deviation). These tv:o holes v,'ere not evaluated. to reouire a PLD. The missin~ a--oun of thread length in hole ~'76 is very mall and th blunted threao. in hole ~16 involves the"removal of material. beyond

t1 e pitch ciame er leaving effective thread strength. The darkened area mentioned is probab'y due to the v;ater that v:as in the hole and the onaes that result d.. The cha~/ge from the blunted threads could also cause this darkened effect. From the description given us, vie do not thin3- it is harmful.

The result of the acove response is that CBI originally found .he thread described ceptable

' ~ trulv yours, C:.-IC:DO CUPID"=.:. A!iD IRO?i C ';,-i'2 Q'pries L. Halfas I Pro-'ect ."~nager

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-~e 'astle 0"e"ations IV. 75

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D I VISION REPORT 87 GENERAL ELECTRIC COMPANY, SUSQUEHANNA SITE, P.O. BOX 382, BERWICK, PA 18603 BOILING WATER REACTOR Phone P17) 542.7391, Dial Comm 8'244-4231 PROJECTS DEPARTMENT I

.RECEt YED October 3, 1977 OCV 07 1977 EAG-517 NUCLEAR SERVICES/lKSE I

Mr. E. E. Fel ton-Field Construction Manager Bechtel Power Corporation Post Office Box 384 Berwick, Pennsylvania 18603

Subject:

Susquehanna Steam Electric Station, Unit 0'1 RPV Stud Hole Discrepancies; Bechtel NCR-1'952, Bechtel Letter No. h)-1-247

Dear Mr. Felton:

This will supplement our letter of August 15, 1977 (EAG-461) and will answer. your M-1-247 letter dated August 17, 1977 on the above subject.

We believe that Chicago Bridge h Iron Company has gone into co'nsiderable research and explanation of a facit of their manu-facturing cycle to explain the above stud hole discrepancies.

We are enclosing copy of CBKI letter to the writer dated September 28, 1977 and based upon data therein, we consider NCR-1952 closed.

Very truly yours, GENERAL ELECTRIC CO./NED I

/ ~g Ca 5 ..i f,1~~

E. A. Gustafsgn Resident Site Manager EAG/mw IV. 76

0' Chicago Bridge 8 Iron Company "al '."".l Sixth slrcCl i'l.. r'n".lie. Dcla::a~c l 0720 REPORT f17 Q I"i(i 0 5 464

. >>ninn FAX 'Nil:ninulon, Dcl.

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September 28, 1977 NED RECEIVED Mr. E. A. Gustafson gr.p 29 197T GE Site ?tanager General Electric Company Susquehanna Site P.O. Box 382 Berwick, Pennsylvania Re: Unit I - Stud Ho3.e Discrepancies Bechtel NCR No. 1952, Letter h(-1-247 Susquehanna Project CBI Contract 68-3331/2 Gent'lemen:

The above referenced letter from Bechtel found that our reply NEM-355, dated August 12, 1977 inadequately explained the discrepancies in stud holes 16 and

.76 of RPV Unit I. Bechtel's letter included a Bechtel nonconformance report which left the quality of the two (2) stud holes as indeterminate. The report indicates that documentation was not available to confirm that the discrepancies were properly addressed. Contrary to this, CBI has documented evidence that all the stud holes were inspected and properly r'eviewed.

In an effort to respond in more detail than we previous+ did, we offer the following:

First, as part ok the tapping sequence, immediately after tapping the hole and prior to moving the drill and tap unit to the next hole, each stud hole is checked with three ( 3) thread gauges. One is a "Go-Gauge", the second is a "No-Go Gauge" and the third is one with threads in between the "Go" and "No-Go" gauges. These gauges are the means of determining if the threads conform to ASA Bl.l and as indicated in ASA Bl.l (now ANSI Bl.l, paragraph 5.5) they are the means used in practice to accept thread tolerances. Each hole is checked before moving to the next hole as it is very difficult if not impossible to reset up exact~ over- a tapped hole. This tapping sequence is documented on the CBI traveler card set 14E, sequence 4F as completed correct~. Following tapping, all holes are checked dimensional~ to meet the CBI drawings. This is documented on CBI traveler card set 14E, sequence 8A. In the case of Unit I this inspection resulted in numerous nonconformities. These nonconformities were resolved through RAD 13, Rev. 1. The conditions general+ described in holes 16 and 76 of Bechtel's correspondence were not listed as nonconformities on the RAD.

To further document the inspection of the flange a final visual inspection of all machined areas was again made at the completion of all flange machining and signed off on card set 14E, sequence 8B without any additional nonconformities.

IV. 77

Chicago Bridge & iron Company REPORT //7 Mr. E. A. Gustafson September 28, 1977 Page Two I If you review RAD 13, you will see that hole 16 had one nonconformity, the counterbore diameter at the top of the hole was undersized. All other dimensions were found acceptable. As we explained earlier the thread was acceptable as the "Go-Gauge" would go down through the threads properly and the "No-Go Gauge" would not go.

During the dimensional ~inspection each hole is checked for length of thread and visually inspected for missing thread. CBI drawing 27 requires 8 3/8" minimum of thread meeting ASA B1.1-1960. Each hole is inspected for this and is evaluated knowing that normally more than 8 3/8" of thread results and that being a machined surface, General Note 15 on CBI drawing 4 will accept "tool marks and similar depressions isolated and minor in nature" provided they are not gas'ket seal surfaces or they do not-violate minimum design thicknesses. These areas must be reviewed by the GE inspector.

Evaluating the reference to ASA-B1.1, the ASA Bl.l standard does not determine how much effective thread length must meet ASA Bl.l. The design calculations determine this. If you review RAD 13, Rev. 1 and its attached engineering justification for stud 18 which had only 8 1/4" of thread you will find the static load report requires a minimum of 7.20". CBI drawing 27 requires a minimum of 8 3/8" to insure the 7.20".

ln the case of hole 76, the small amount of thread missing was evaluated as still leaving 8 3/8" effective length of thread remaining meeting drawing, requirements. The area was also isolated and minor in nature. It was therefore not,evaluated to be a nonconformity and requiring a RAD. A similar situation existed in a Unit II stud hole but in this case consisted of several small areas throughout the hole with missing thread. Because if it was not isolated and minor in nature and difficult to determine 8 3/8" of effective length of thread existed, a RAD was 'required to resolve the nonconformity. In the case of the flattened area mentioned in hole 16, the amount of thread that had material missing inside the maximum minor diameter of the internal thread did not decrease the effective length of thread below 8 3/8" or it would have been a nonconformity on the RAD.

In regard to the darkened area mentioned, there are no color requirements for the material or'hreads in any of the specifications, drawings, standards or codes.

CBI is confident the stud holes meet all requirements of the GE Specification and have been inspected, evaluated and documented properly. Qe further point out that studs have been installed in the holes, the studs tensioned, the vessel hydrotested, the studs untensioned and the studs removed.

EV. 78

Chicago Bridge & iron Company REPORT 87 Mr. E. A. Gustafson September 28, 1977 Page Three In conclusion, CBI recommends the proper disposition is to have Bechtel indicate that documentation exists in the RPV vendor records that all stud holes', including the two in question, were inspected.and evaluated with nonconformities accepted on CBI RAD 13, Rev. 1.

We hope this is not the beginning of a continual line of requests to respond to visual inspections by'hose who are not familiar with vessel fabrication and design. We certainly do not intend to respond in such detail or send documentation every time Bechtel has uncovered something they feel does not meet the specification or not explained to their satisfaction. CPI has built the vessel under a GE Specification and continual GE surveillance and inspection and cannot find where we are required to respond to the satisfaction of Bechte1.. However, we do wish to make it clearintothatit.if GE uncovers ~

something of concern, CBI wi11 be happy to look We are hopeful that the above explanation and recommended disposition will resolve Bechtel's NCR No. 1952.

Sincere> yours,

. CHICAGO BRIDGE AND IRON COXtPANY Charles L. Halfast:

project Manager New Castle Operations CLH/lfm cc: Mr. B. Y.. Lloyd, Buyer-MC/703 San Jose, California Dt', 79

REPORT //8 FINAL REPORT The final report contains the data required by Section XI of the code xegarding indications- The full report includes the. parameters necessary to evaluate the data as well as the final evaluations. The calibration and data sheets from the ox'iginal run list the needed information on calibration and recheck times and transducer information.

During the inspection of a nozzle or vessel weld all. data is preserved on files on one or more cassette tapes or floppy disks. These files will be referred to in the following discussion as the 'original files'.

The final report is generated from the original files by performing a several step procedure.

1. Post Editting of the original file The original file contains all the raw data which is required for reanalyzing any indications found during inspection. In addition, important information such as the setup values for system parameters and data from calibrations are included on the file.

The original file also includes a fair amount of information which is not necessary for post processing. It is customary for the system to print (and save on the file) lines of data relating to evaluation of the indications as they are found. This allows the operator to follow the inspection process as it occurs. These evaluations should be considered as preliminary and are not used in any way for generation of the final report by the post px'ocessor program. The lines printed during calibrations and rechecks are not kept: the calibration sheets list the times and amplitudes found at calibration, and RECHECK: UNKNOWN is printed if there is no accepted recheck. The original file also contains operator control and equipment setup commands which are not useful to post px'ocessing.

Another major area of unneeded information on the original file is due to the repetition of inspection passes or parameter lists.

These may occur for a variety of reasons; only the last lists before a run and non<<voided inspections are required for creation of the final report Thus, the ox'iginal file includes a conglomeration of raw data, calibrations, rechecks, important evaluation parameter values, operator comments, preliminary evaluations, aborted run data, extra lists, and hardware control commands. The significant data for a single weld may consist of several passes done in a non-specific order with intervening passes from other weld inspections The purpose.,of the post editting procedure is to extract the necessary and sufficient data for a single weld

,inspection and create a new 'interim'ile which contains all the data in a standard order. During the creation of the interim F.R. 5/12/81 -1 IV. 80

REPORT 88 file, the original file is used but is not altered in any way.

The post editor computer program automatically removes most of the superfluous data. This includes all lines relating to the preliminary evaluation of indications and operator commands used for controlling the inspection hardware. The post editor program automatically retains, unless otherwise directed by the operator, all evaluation parameter values and all raw data from the inspections-The post editor operator can delete or add lines to the data from the original file as necessary. He may delete lists which are repeated before .a run. He may also delete all the data from aborted inspection passes - those passes where the data was discarded and the inspection for the area repeated.

Added lines are usually made in the form of notes or comments.

These are sometimes necessary to explain situations that have arisen during post processing. Comments added during post editting are easily identifiable as they are the only lines contained in the final report which begin with an asterisk (*) or dash (-).

The most important Job for the post editor operator is to assemble all the data for a single nozzle or vessel weld in a standard order on the interim file. During the inspection, a pass completely around a nozzle or along an entire vessel weld may be interrupted several times by termination of inspection commands.

When the interim file is created, these separate parts of a pass are combined so that the post processor treats the data as if it were obtained without interuption'n this way, indications that were in progress at the time of a termination are not cut in half when evaluated by the post processor.

2.. Print the Interim File Although most of the clean up process of the original file data is done automatically by the. post editor computer program, the operator does have the responsibility of reorganizing as well as deleting and inserting information. To ensure that this procedure has not produced any errors, the interim file created during post editting is printed. This printout is compared with the printout of the data on the original file(s).

30 Post Process the Interim File: create the final report Post processing of'he interim file is a relatively easy procedure. The post processor reads the values for the evaluation parameters; then processes each line of raw data exactly as if it were coming from the Branson UT hardware. In this way, the entire indication evaluation process is duplicated as if the actual inspection were being performed.

F.R. 5/12/81 -2

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IV. 81

e 0

REPORT 88 The final report evaluations may differ from the preliminary evaluations obtained during the inspection. This is due to a number of causes:

ao The post processor combines data from several separate runs As described above, termiaations of runs during a pass may be eliminated during creation of the interim file. An indicatioas which was not completed at the time of the termination will show up as a. larger combined indication in the, final report.

b Post processing may be performed at a different evaluation level Inspections may be performed collecting and evaluating data at other than the Post Processor evaluation level. The final report can be generated using any evaluation DAC level above the collection level'bviously, far fewer and much smaller indications will be found in a final report evaluated at 50X DAC compared to the indications evaluated at 20X or 25X on the orignal file priated during inspection.

Co The locations of'ndications may change.

The locations of indications are based on measurements which depend on the scanner screw encoder readings at the time. the indication was observed As described below, the position of the transducer package aad the position correction distance for. angle beam transducers (A4 and E4 parameters) are determined based on the values entered for the calibration block and inspection scanner screw lengths and encoder readings- If these values did not correspond to the true scanner screw lengths and encoder readings, they may be corrected.

If the calibration length to full scale encoder reading ratio was entered incorrectly, it may be corrected for by a line iaserted before the UT channel list. If that line is present, the system:will print CALIBRATION SCANNER EQUIVALENTS: LENGTH ~ na.nn FULL SCALE nnnn and correct the A4 parameters for all channels The calibration scanner values. run with will be printed ia the parameter list If the inspection device scanner le'ngth and full scale ratio were entered incorrectly, they may be corrected for by a, line inserted after the UT channel list.. The correct length and full. scale will be printed on the parameter list. The line

'CORRECTED SCANNER PARAMETERS'ill be printed before the listi A second cause of different locations is due to round off of F R 5/12/81 -3 IV. 82

II REPORT /$ 8 numbers saved on the original file. The post processor has only these rounded numbers to work with in its evaluations.

Usually, a change in one value due to round off is offset by a compensatory change in another value. For example, if the maximum X location of an indication is 0.1 inch greater than the maximum X location of the preliminary report, it will be found that the minimum X location in the fina1 report is also O,l inch greater than the value in the preliminary evaluation.

Thus, the indication size does not change;= the indication location has merely been shifted 0 1 inch in the X direction.

A third cause is that in NOZZLE mode, the BX and EX lines are recalculated from the BX line azimuth, weld reference point, nozzle location, and scanner X offset. If any of these change, the location may change. In the original run, any azimuth change between the BX and EX lines could alter the EX,EY coordinates from what the Post Processor calculates d., Differences may occur due to data loss In rare cases, the data on the original file may be incomplete. In a few of these cases, it may be determined that significant data has been lost. In such cases of data loss, comments (beginning with asterisks) may be added to the interim file discussing the significance, if any, of the missing data. These discussions are based on the. data surrounding the dropout on the original file, the hardcopy printout obtained on the system terminal during the inspection, and a thorough understanding of the way the computer program analyzes and reports data.

The final report includes all the evaluation data for indications required by Section XI of the code. It also contains the values for all important parameters used in the collection or evaluation of the data.

An option has been made available to print partial reports These do not include UT channel software DAC parameters, scan lines (unless a scan is found out of sequence), scan limits, some notes and comments, crawler and nozzle stepsize settings, forced locations, indication combinations, average and maximum stepsizes, and CONTINUEs and following BEGIN lines, if the, responses were set in advance'f the evaluation level is less than 50XDAC, no evaluation tables or final evaluations will be printed.

The following material explains the significance of each type of line in the final report what the parameters mean and why the line is necessary. The explanation is usually not presented in a mathematical fashion; such a description is available in other documentation Rather, the approach is taken to indicate in general terms how each F.R. 5/12/81 -4 IV. 83

e REPORT f/8 value is used and each report can be interpreted Pa e Headers pAGE 0002 78 MAR 30 08:II: 14 yyyyyyyyyyyyyyyyyyyyyyyyyyyyy OF xxxx A line similar to the above appears at the top of each page after the first page. The y's represent a page heading chosen by the Post Processor Operator. The number xxxx is the total number of pages in the report, to be filled in by the operator.

The date and time are taken from the original file, ie. from the page headers on the hardcopy report generated during the

• inspection. When a new page is started on the final report,'t uses the time and date in effect at that point on the original file.

The final report pages will not coinci'de exactly with the original printouts, so the time listed is only approximate. Zt is possible for consecutive pages of the final report to have the same time and date. This would occur if more data was being printed in the final report than in the original. Similarly, the final report will not necessarily contain a time and date header for every time and date header of the original file. This occurs when the final report is generating less printout than the original.

Following the time is information chosen by the operator, generally the veld and vessel identification, and the procedure, xevision, and ACN numbers .

F.R. 5/12/81 -5

REPORT /38 I. EVALUATION PARAMETERS AND TEST SET-UP Evaluation Parameters TABLE IWB-3511. 1 ALLOWABLE PLANAR INDICATIONS ASPECT SURFACE SUBSURFACE RATIO INDICATIONS INDICATIONS A/L A/T,Z A/T, Z

0. 00 2.0 2.6 0.05 2. 1 2.8 TABLE IWB-3511. 3 ALLOWABLE LAMINAR INDICATIONS COMPONENT THICKNESS LAMINAR AREA T, IN+ A, SQ IN 0 . 12 4 12 6 18 The report includes the evaluation tables used in the original run to evaluate the data. The tables should be taken directly from Section XI of the code and differ only in that the laminar table has a line listed for a vessel thickness of 0 inches. The allowed area is the same as for the thinnest vessel thickness in the original table. This forces the interpolation of allowed indication areas to be constant over the first few inches This does not affect the evaluation of most runs since the plate thickness is generally not in the 0 - 4 inch range'V.

FoRo 5/12/81 6 85

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REPORT ij8 UT Q1ANNEL PAKQKTERS A set of parameters Al through A5, Bl through B5 are used to evaluate the, location and amplitude of reflectors. These are the

.software DAC parameters. Although they are not printed on the partial reports, they may be gleaned from the original or interim file.

The Al,B1 values are for the TCG formula for times of reflectors between the outer surface and the depth of the Tl/2 hole. They are the parameters of a straight line equation used to make a time based correction on the amplitudes reported from the UT hardware for. indications having times less than the time obtained for the Tl/2 hole during calibration:

Al

(

• tdme + Bl )

• amplitude ccttected amplitude 1000 In the process of a calibration, the times and amplitudes for the T3/4 and Tl/2 holes are retained. This is sufficient data for calculating the Al and Bl parameters for the above straight line equation.

Note that the value listed for Al is actually divided by 1000 before being used in the equation.. Thus the effect of the time on the TCG is almost insignificant. This is a result of the fact that the Branson hardware also has a three slope TCG adjustment for each channel The operator typically adjusts these hardware controls so that very little time based correction is required by the software.

Al/1000 is thus always small. It is printed with the *1000 factor to make the number more readable.

Most of the software TCG ad5ustment comes from the value for Bl for the angle beam channels. In setting the hardware TCG, the operator typically sets the amplitudes to read out at slightly over 80 for all the calibration holes. Thus a hardware reading of 80 corresponds to 100X DAC. As described below, the operator typically sets the software so the a report of an amplitude of 100 corresponds to 100X DAC. The Bl parameter has the affect the slightly higher than 80 readings of the Branson to the of'aising desired 100 value for amplitudes saved on the original file. If the operator set the harware to read exactly 80 at the Tl/4 and T1/2 holes, Bl would equal exactly 1.25 (1.25

• 80 100).

A2 and B2 are like Al and Bl except are derived from the time and amplitude data from the Tl/2 and T3/4 holes A3 and B3 are used for the third slope of the TCG and are derived from the data for the T3/4 hole and the calculated time and amplitude values based on measurments of the T5/4 hole made and entered by the operator PeR. 5/12/81 -7 IV. 86

REPORT f38 A4,B4 are used for lateral location correction of a reflector from the transducer location, as is needed for angle beams. During calibration, data is obtained at each hole for the time and the insufficient calibration apparatus scanner screw encoder reading. This is data for determining the values of the parameters of a straight, line equation relating time to the distance, measured along the surface, of an indication from the transducer position.

This position correction based on time is necessary when calculating the exact location of an indication. If the calibration length to full scale encoder reading ration has been altered since the run, the A4 parameter is multiplied by NEW CALIBRATION LENGTH

• OLD FULL SCALE NEW FULL SCALE + OLD CALIBRATION LENGTH If the inspection scanner length to full scale ratio is altered, the A4 value is mulitplied by an extra factor of NEW SCANNER LENGTH

• OLD FULL SCALE NEW FULL SCALE

• OLD SCANNER LENGTH A5,B5 are values used to calculate the depth of the reflector.

During calibration scanning, the times for each hole are retained.

This data, along with the known depths of the calibration block holes, discussed above, is sufficient data for the determination of a straight line equation relating time to depth for the transducer.

ACOUSTIC PARAMETERS When inspecting vessel welds two complementary location systems are used The odometer and azimuth encoders provide location data that is quite accurate over short distances Over longer distances (15-20 inches) the cumulative error inherent in this kind of measurement, aggravated by crawler slippage and manual location ad)ustments, becomes too large to keep accurate track of the location of the crawler The acoustic location system is used to determine a starting location and correct odometer the error accumulated over long distances Acoustic locations are taken whenever indications are seen or every n scans, where the operator sets n (see below).

F.R. 5/12/81 -8 IV. 87

0 REPORT (f8 The acoustic location system is generally accurate to within 0.25 inches except where there is mechanical or geometrical interference with data collection When an acoustic location is obtained, it is checked against the presumably nearly accurate odometer based location. If the acoustic location is within the operator-set acoustic location tolerance of the odometer location, it is used to update the. odometer.

If the acoustic ldcation is not close enough to the odometer location, the system assumes a mechanical problem (eg. poor contact of the acoustic pulser with the vessel surface) and tries up to three times at different pulser locations to obtain an agreeable acoustic location. If, after three tries, the acoustic location still does not agree with the odometer location, the system assumes some geometrical problem is interferring with the'data (eg. a nearby nozzle or bevel altering the sound transmission or path).

In such a case, the odometer location is kept as being the most reliable.

The system attempts to obtain locations frequently enough, even in the absence of indications, to 'miss'everal times before the cumulative error of the odometer would be unacceptable. Usually, after a few moves, the acoustic location and odometer location will agree sufficiently to allow updating the odometer location.

In some cases, especially where the operator has manually rotated the crawler to keep it on course, the odometer location will be known to have excessive error. In such a case, the operator may choose to 'FORCE'he acoustic location. When this command is used, the system prints all the data necessary to ensure that the acoustic data is good and, therefore, that the location determined from it will be dependable. This data on the original file includes a sensor by sensor report of its contribution to the location process.

In the final report, only the most significant data from this

'FORCE'ocation procedure is printed:

FORCE ACOUSTIC LOCATION

~ ~ ~

X 538 1 Y~ 529.7 DIF.SQ.~ 0 87 OK? Y The computer prints the acoustic location and asks "OK?". The operator responds with a "Y" if the location is to be used to update the odometer.

The final report includes the SCAN lines which precede and follow a FORCE operation. These contain the setting of the odometer location before and after the FORCE and, therefore, can be used to determine the magnitude of the correction that was necessary.. The F.R. 5/12/81 -9 IV. 88

0 REPORT /18 X,Y values are the acoustically determined coordinates and correspond to the scan line X,Y. The DIF.SQ. is the squared distance between the odometer- and acoustic-determined locations.

This can give an idea of the magnitude of the shift in locations It is not usually apparent from the data why the FORCE was necessary, ie. whether the crawler slipped, was moved by the operator, etc. The adjustment does not affect the analysis except when data for an indication was collected before and after the FORCE0 The computer checks to see if the change in odometer readings between scans is consistent with the change in X, Y location. This check is not done when the second scan of a pair is numbered 1. If an acoustic location is forced to a different value on scan N, the old value is used to compare to scan N-1 and the new value to compare to scan N+1. If the difference is greater than .9 inches, the system prints the message

• • • • • ODOMETERDISAGREES WITH CHANGE IN LOCATION ON SCAN n where n is the second scan of the pair. The program may be run with a patch to not perform this check if the irregularities have already been noted and accounted for.

Fe Ro 5/ 12/81 10 IV. 89

RAPPORT 88 Acoustic Location Parameters VELOCITY OF SOUND ~ 0.1172 LAG TIME ~ 0.400 DISTANCE C.F. ~ 0.0000 ACOUSTIC LOCATION TOLERANCE ~ 0. 250 CYLINDRICAL GEOMETRY, CIRCUMFERENCE ~ 842. 10 SHELL COURSE 8 2 THRESHOLD ~ 1518 CRAWLER PULSER LOCATION X ~ 538 68 Y ~ 383.60 REGION 1 SENSOR GLOBAL 8 X Y 1 1 443 720 196 '30 3 42 624 370 195 '30 When the acoustic location system is used, the above list of parameters will be printed. The primary importance of the listed data does not relate to, the current evaluation. The values are listed since the identical values must be used in later re-inspections for locations,to be reproducable.

The circumference allows "wrap-around": if the circumference is 842. 10, an indication at X 841. 9 may combine with an indication at X~0.3 ~

Ste size Commands SET CRAWLER MOTOR STEPSIZE SMALL ~ 0.40 ~ LARGE > 0+75 ~e65 UPPER LIMITT, ODo UNITS ~ 80 ~75 MAXIMUM ALLOWABLE STEP, INCHES ~ 0 8 ~

MAX CHANGE DURING SCAN, INCHES ~ 0 05 ~

8 SCANS/ACOUSTIC LOC ~ 5 ~

or SET NOZZLE STEPSIZE INCHES SMALL ~ Oo 40 ~ LARGE ~ Oo 70 ~o 6 BIG STEP, ODOMETER UNITS ~229 ~

UPPER LIMIT, OD. UNITS ~ 400 ~300 MAXIMUM ALLOWABLE STEP~ DEGREES ~ 1 2 ~le0 MAX CHANGE DURING SCAN, INCHES ~ 0.05 ~

These types of lines are printed whenever the operator sets the distance the crawler or nozzle apparatus attempts to move between scans. The small step is attempted after a scan where data has been seen. The large step is attempted after a scan where no data was seen The UPPER LIMIT is the largest number of odometer units it may attempt to step If it steps larger than the MAXIMUM ALLOWABLE, the syst: em terminates the run. The MAX CHANGE DURING SCAN is the most the bug or nozzle apparatus is allowed to move during a scan. The BIG STEP is the current estimate of the number of odometer units for the larger stepsize. The "8 SCANS/ACOUSTIC LOC" sets the maximum number of scans between acoustic locations.

F.Ro 5/12/81 -11 IV. 90

REPORT /18 NOTE: The computer system uses the following conventions for operator setting of parameter values. When the appropriate set command is executed, the system prints the current value of the parameter (eg. 0.05 inches in the above example) followed by an equals sign. The current value is retained if no operator entry is made or an entry ending in a is made.

If a new number is entered, that value is nozzle then used stepsize for. the has been parameter. For. instance, the above changed from 0.70 to 6 inches.

Evaluation Parameters EVALUATION PARAMETERS:

" or NOZZLE MODE T SCAN, P SCAN CLOCKWISE, or VESSEL MODE SCANNER bQKHSIONS: P SCAN COUNTER-CLOCKWISE CALIBRATION LENGTH~ 30.00 FULL SCALE~3000 VESSEL LENGTH~ 30 00 FULL SCALE~ 3000 POD UNITS PER INCH 100.00 or OFFSETS: x -20.74 SCANNER STEPSIZE ~ Oe050 STEP TOLERANCE ~ Oe020 MINSEP ~ 0.250 100K DAC ~ 100 EVALUATION LEVEL ~ 50 WELD REFERENCE POIVaZ: X~ 532.61 Y~ 388%4 THICKNESS ~ 6 ~ 53 SHELL COURSE 2 CIRQDPRENCE ~ 795. 69 EVALUATION ANGLE: LAMINAR~ 10 0 NONPLANAR~ 10 0 SURFACE TOLERANCE'ISTANCE~ 0 0000 REPORT B.E. DATA AT FULL B.E. AMP or REPORT B.E. DATA AT 1/2 B.E. AMP MAXIMUM B E XDAC FOR EVALUATION 15 or EVALUATE ALL B.E. DATA The above list contains all values, other than specific UT channel data, that are required for post processing raw data from the interim tape. An important feature of the inspection system computer program is that once the above list of parameters has been printed, it is impossible to alter the listed values Thus, the list specifically defines the conditions under which any inspection pass was performed If a parameter value needs changing,inspections the program automatically prints the list again before any can be started.

The mode, VESSEL or NOZZLE, is listed. The mode setting not only influences the way in which the computer drives the hardware, but causes the calculation of relative X and Y values to change (see end-of-scan printout discussion below). Within NOZZLE mode, there are T or P scans, clockwise or counterclockwise. Generally, the T, W, and B channels are on for a T scan, the negative angle P scan channels are on for a clockwise P scan, and the positive angle P scan channels are on for a counterclockwise P scan The B channel is generally only on for back echo monitoring on the P scans: its flaw gate is off.

F.R 5/12/81 -12 IV. 91

REPORT /38 The calibration and inspection scanner arm LENGTH and FULL SCALE reading are used to calculate the position of the transducer package on the arm. In the above example, the arm is 30.0 inches long with a full scale reading of 3000. This is equivalent to telling the computer that a change of one encoder unit corresponds to a movement of the package by 0.01 inches.

The SCANNER STEFSIZE is the distance the tranducer package is moved by the scanner screw between UT data sampling when significant data is found. For example, if no significant data is being reported by the UT transducers, the scanner screw moves the transducer package c'ontinuously. As soon as one channel sees a significant reflection, the package is stopped and all UT channels pulsed at that position. Then the package is moved according to the SCANNER STEPSIZE setting (0.050 in the example), stopped, and all UT transducers pulsed again. This continues until a p'osition is reached where none of the transducers obtain significant reflections, at which time the continuous motion is restarted.

The step tolerance is the amount of error possible in the stepsize.

This value is required by the computer for calculating the absolute maximum values that are used in separating indications that are near each other but not to be considered one.

MINSEP is the minimum separation between indications that can still be considered separate from each other. Thus,'he operator has indicated in the above example that any two reflectors seen by a given UT transducer that are calculated to be within 0-25 inches of each other are to be considered parts of a single large reflector including both.

The 100X DAC level is set to 100. As explained earlier, this setting, causes the calibration process to calculate TCG parameters such that the amplitude obtained at each of the calibration block holes (usually 80 or slightly higher) is raised to equal 100. This makes the amplitudes in the final report easy to interpret: a printed amplitude of 34 is equivalent to 34X DAC The evaluation level, 50K, is the operator-set amplitude level at which a reflection is to be considered significant for the post processed report The raw data on the original files includes data for each and every shear wave UT pulse that had a time corrected amplitude equal to or higher than this value or else the final report would have been aborted.

In VESSEL mode, the WELD REFERENCE POINT is a point selected by the operator, usually a weld intersection. It is used for computing the relative X and Y distances as described below for the end-of-scan printout In NOZZLE mode, the X weld reference value is the distance from the F.R 5/12/81 >>13 IV. 92

REPORT /38 center of the nozzle to the centerline of the weld (radial distance) ~ The Y value is not used.

.THICKNESS is the vessel thickness. This value is used in indication evaluation for the two X OF T columns in the end-of-scan printout, in determining the allowed size of indications, and in determining the SURFACE or SUBSURFACE nature of an indication in the final end-of-pass analysis.

The shell course number is printed but not used for analysis. The circumference is as in the acoustic list and allows indications to cross the X~O line.

The laminar evaluation angle is used to determine when an indication sighted by a P, T, or W type channel is to be considered LAMINAR It is LAMINAR if (THROUGH WALL DEPTH) tan(LAMINAR ANGLE) >

(INDICATION LENGTH)

The angle is set to 10.0 degrees to correspond to the value stipulated in Section XI of the code.

The nonplanar evaluation angle is used to differentiate between PLANAR and NON-PLANAR indications. An indication is PLANAR X (or Y) if (INDICATION X (or Y) LENGTH) tan(NONPLANAR ANGLE)

(INDICATION Y (or X) LENGTH)

The SURFACE TOLERANCE DISTANCE is included to allow the operator to respond to future clarifications of the inspection code.Section XI illustrates examples of indications lying near the surface which are considered to be semi-circular'his designation increases the size of the indication' It is not clear from the code how near the surface such an indication must be before it can be considered the smaller semi-elliptical shape. If this distance were known, it could be entered as the SURFACE TOLERANCE DISTANCE By setting this value to 0.0, all surface indications will be conservatively designated by the analysis process as being semi-circular unless they lie exactly on the surface.

The base metal data may be reported. at 1/2 or full back echo corrected amplitude. If the data was collected at full back echo amplitude, the post processor will not allo~ reporting at 1/2 amplitude. The base metal data may be analyzed for all reported reflectors, or only for those reflectors whose back echo corrected amplitude is less than or equal to a certain amount, 15XDAC in this example.

F.R. 5/12/81 -14 IV. 93

I REPORT k/8 UT Channel Data UT QVJlNEL DATA: SCANNER SEPo FACTOR ~ 13 CH 0, ANGLE . X OFFSET Y'FFSET BEGIN STOP MN BE TSEP T5/4A 2 -45.0 T &.80 2.61 200 2060 0 55 -5.00 Al~-0 1831 A2~ 0.0000 A3~ 1.2817 A4~ 4.463 A5~ 4.581 Tl/2~ 711 Bl~ 1 289

~ B2~ 1 ~ 164 B3~ W.204 B4~ 0.010 B5~ 0.002 T3/4~ 1067 3 -60.0 T 0 48 2.61 200 2060 0 78 -6 00 Al~ 0 0000 A2~ 0.0916 A3~ 1.1902 A4~ 5.526 A5~ 3.232 Tl/2~ 979 Bl 1. 156 B2 1.067 B3~ W 576 B4~ 0.010 B5~ 0.057 T3/4~ 1501 Like the Evaluation Parameters described above, the settings for the UT channels cannot be altered without re-printing the above type of list. This list consists of all important values for each of the channels which is ON, that is, channels which will be pulsed during an inspection pass.

The scanner separation factor is a translation of 1/2 MINSEP into scanner encoder units, rounded up.. Thus, with MINSEP ~ 0.250 and 1 encoder unit ~ 0.01 inches, the SCANNER SEP. FACTOR equals .13.

This value is used in determining whether two indications seen by a single channel in a scan should be combined during end-of-scan processing. If one indication is located such that its maximum scanner position + 1/2 MINSEP (ie. 13) overlaps a second indication's minimum scanner position - 1/2 MINSEP, then the two indications are candidates for combination on the basis of nearness in the direction of scanner motion. As described below for TSEP, the two indications must also meet nearness requirements in the depth measurement The channel number is listed under the CH 8 column.

The channel ANGLE is listed with the type of channel: transverse (T), parallel (P), weld metal (W), or base metal (B). The actual value entered- for the channel angle is not used in any of the important. to the post processor. Therefore, the angle is customarily entered as a nice round value rather than the actual beam angle measured by the operator in compliance with Section XZ of the code The X and Y OFFSETS are distances measured from the designated zero point on the package. This information is required for determining the exact location of the transducer and, hence, the exact location of a reflector seen by the transducer.

F.R. 5/12/81 -15

REPORT /18 The values for BEGIN and STOP are the encoder values between which the specified channel will be pulsed. These values are set by the operator in a manner which ensures that the required volume of plate is inspected as required by the code.

MN BE is the minimum back echo required for a B type channel. If the system detects that the back echo amplitude reported for a B type channel is less than the value for MN BE, it stops the transducer package. The system continues to pulse only the B type channel until back echo returns This may occur when momentarily lost couplant returns or, under operator control of the Branson hardware, the loss of back echo condition is overridden. During loss of back echo, no data is taken from other channels and the transducer package does not move.

TSEP is a measurement, in time units for the channel; equal to 1/2 MINSEP. This is thus based on the A5 value for the channel and is the depth equivalent of the SCANNER SEP. FACTOR described above for combining indications at the end of a scan.

T5/4A is the 5/4 T amplitude difference measured by the operator.

The Al,Bl . are listed only in the full report, not the partial.

These are the values used in evaluating the time, amplitude, depth, and position of a reflector seen by that channel.

II+ THE INSPECTION Start U Commands BEGIN UT INSPECTION AND CRAWLER MOTION SEQUENCE EVALUATION LEVEL << 50K DAC DISTANCE <<300 SCANNING LIMITS: LOW << 300 HIGH << 2110 WELD: BK or BEGIN UT INSPECTION AND NOZZLE ROTATION <<300 EVALUATION LEVEL << 50X DAC SCANNING LIMITS: LOW 30 HIGH 1800 NOZZLE LOCATION X <<

WELD:

7 '3 Y << 170+25 N4A-'n NOZZLE mode, the "NOZZLE ROTATION n" is important mainly for the sign of n., The operator may often terminate the run before n degrees are covered, but the sign tells in which direction rotation occurred. A positive number indicates increasing degrees and negative indicates decreasing.

F.R. 5/12/81 -16 IV. 95

I

~

REPORT /l8 For instance, if +300 was entered, the first azimuth reading was 355.4 degrees, and the last azimuth was 181.1, the area at 50 degrees was covered, but that at 250 was not.

In VESSEL mode, the DISTANCE has no significance except for the sign, which indicates the direction of travel. A positive distance indicates the crawler was traveling forwards; a negative distance indicates it was traveling backwards The EVALUATION LEVEL is set during post processing and must be greater than or equal to the test level.

The weld tested i's listed The nozzle location is listed. The scanning limits are listed on the first BEGIN of a series connected by 'CONTINUE? Y's or if they have changed since the last BEGIN.

The scan limits give the range of travel for the package, independent of the pulsing limits of the channels The scan limits are the attempted endpoints of the scan. The package may actually scan further up or lower down- than these numbers In the partial report, these numbers are not printed.

Combined with the channel offsets and pulsing limits, and the scan positions (X, Y and AZIMUTH), they determine the area of coverage.

The indication number for post processing is set automatically and may not ma'tch the original numbers'can Lines SCAN 8 2. AZ ~ 180 ' ODOM ~ 3482 X ~ 544 2 Y ~ 383 '

or SCAN 8 2 AZ ~ 134.4 ODOM ~ 2561 The first and last scan line of any run're always printed on a full report In NOZZLE mode, the scan line gives the scan number, the azimuth reading in degrees, and the odometer reading. VESSEL mode lists the scan number, azimuth reading in degrees, odometer reading, and the X and Y location. Thus it is possible to determine the extent of the inspection for a given pass by looking at the beginning and ending nozzle apparatus or crawler positions.

The azimuth is the=angle of the scanner screw. For VESSEL mode, 0 degrees is with the scanner horizontal and the crawler heading up the vessel. For NOZZLE mode, 0 degrees is with the scanner horizontal and to the right of the nozzle. Angles increase in the clockwise direction.

In VESSEL mode, the azimuth may be used to determine the angle of the scanner arm only, not to determine direction traveled. This is done with the FREEZE AZIMUTH command, where the operator sets the azimuth value to be used. FROZEN is written after the AZ 'reading'V.

F.R. 5/12/81 -17 96

REPORT j/8 on the scan lines.

Scan lines around a forced acoustic location are printed since a discontinuity in location readings may have occurred. Also, if scan numbers are out of order, the message "SCAN NUMBER OUT OF SEQUENCE" is printed This may indicate that some scan lines are missing but does not necessarily mean that data has been lost.

Sometimes there will be more than one scan 0 1; this occurs when one run is terminated and the next begun at the same place, in the same direction, without any gaps. In such a case, the "END OF PASS" and "BEGIN" lines are removed from between the two runs during post editing. The line "+END/BEGIN DELETED". may be inserted. Set>>up data may also be removed from between runs if no parameter values were altered.

End-of-Scan Processin Section XI of the code specifically requires certain data to be recorded for. each scan by a tranducer which reveals significant reflectors- These reports constitute the bulk of the final report for many welds.

Zt is unfortunate that Section Xy ~re uires this data since it is intended mainly as a necessary step to be taken in a manuai inspection process where evaluation and further analysis is not performed during the test'herefore, it will be found that study of the end-of-scan reports offers little information relevant to evaluation of indications The code requires two kinds of printout. The first of these is for shear wave analysis:

MAX AMPLITUDE -50X DAC +50X DAC X OF T IDiO XDAC DEP REL X RY/AZ DEP REL X RY/AZ DEP REL X RY/AZ DEP SDEP 4 19 81 3 ~ 7 308 ~ 7 546 3.9 309.4 54-6 3.7 307 F 7 54.6 2.4 48 ~ 8 98 4.0 309.1 55.5 4 1 309 9 55.5 4.1 308.8 55 5 0.4 46. 7 65 3 9 308 5 56 0 4 0 308.7 56 0 3 7 307.9 56.0 3 7 48mo The above end-of-scan printout for an indication is for P, T, and W type channels The channel and indication numbers are in the O and IDP columns. In the example above, indication 19 was observed on three successive scans as indicated by the three lines of data without additional channel or indication number values That is, when one indication is built from several scans, the channel and indication numbers are not relisted.

The information on each line corresponds to the data called for by Section XI of the code and illustrated in the sample table in section I-6330. In VESSEL mode, REL X and RY/AX are the X and Y distances, in inches, from the weld reference point. In NOZZLE F.R. 5/12/81 -18 IV. 97

0 REPORT jj8 mode, REL X is the distance between the given point of the reflector and the weld line. RY/AZ is the azimuth offset from 0 degrees to the given point of the reflector. 0 degrees is horizontal and to the right of the nozzle, and angles increase in the clockwise direction.

DEP is the depth of the given point in both VESSEL and NOZZLE modes REL X, RY/AZ, and DEP are recorded where the Z DAC was highest (MAX AMPLITUDE columns), when it first reached the test level (-50X DAC columns), and where it last reached (fell below) the test level

(+50X DAC columns).

It will be noted that the end-of-scan printout differs .from the sample table in section I-6330 in that it contains RY/AZ columns for all three recording positions rather than )ust for the MAX AMPLITUDE position This is necessary because the computer calculates and reports the REL X and RY/AZ positions of the actual indication which may change in both values The table in section I-6330 records only the location of the transducer which does not change in the RY/AZ value from one set of columns to the next.

The the last two columns list the depth as a percent of thickness (DEP) and the distance from surface as a percent of thickness (SDEP) ~

I The second type of end-of-scan printout is for the B type channels.

The code specifically requires that certain data be recorded for ever transducer osition for which the indication amplitude equals or exceeds the back echo amplitude:

CHd BET BEA IT IA RELX RY/AZ DEP SCNR 9 0 0 283 15 503 9 62.2 3 3 1686 9 0 0 283 22 503.8 62 ' 3.3 1698 9 593 13 284 18 503.7 62.2 3 3 1707 For B type channels, the data required in section I-6420(a) is included in the end-of-scan printout. Each pulse yielding data with a Z DAC at least as high as the evaluation level or the back echo level lists the channel number, back echo time and amplitude (BET and BEA), and indication time and amplitude (IT and IA). If data is to be reported at 1/2 B.E. amplitude, the pulses need only be at least 1/2 the back echo amplitude.

RELX and RY/AZ are as for the P, T, and W type printout. The depth in inches and the scanner position in encoder units follow.

F.R. 5/12/81 -19 IV. 98

REPORT //8 Data Brid es CONTINUE? Y or CONTINUE? N In post, processing, at the end of a run, a line will query "CONTINUE?". A "Y" answer means the current data will be combined with data from the next run, even if a calibration recheck lies between them. The indication number will not be reset. A "N" answer means the UT inspection data, if any, will be printed out, with its final combinations and evaluations.

The bridge between runs is necessary when several runs were made to.

complete a single inspection pass but the runs cannot be combined in a way so that the data simulates a continuous run. This is may be due to a recheck in the middle of the run, or combining -runs from different days, which means different channel parameters will be used It may also be due to running first in the postive direction, then the negative to cover both halves of a nozzle (ie.

runs of 0 degrees to 180 degrees and 360 degrees to 181 degrees).

The result of the 'CONTINUE? Y's that the computer will still combine any indication data obtained at overlap points (ie. at 0 degrees and 180 degrees).

At every 'CONTINUE? N'here will be printed on full reports AVERAGE STEPSIZE ~ x.xx MAXIMUM STEPSIZE ~ y.yy Where x.xx and y.yy are in degrees for NOZZLE mode and in inches for VESSEL mode. These give the average and maximum steps for all the scans combined for this evaluation, except that any step before a scan numbered 1 is ignored. In VESSEL mode, the step is calculated from the odometer readings on the scan lines and

,translated to inches using the 80DOMETER UNITS/INCH LAMINAR/PLANARCombing tions LAMINAR INDICATIONS JOINiNG PLANAR INDICATIONS CH8 LAMINAR O'LANAR 8 DISPOSITION 1 2 3 1 2 5 LAMINAR indications may appear which are so close to PLANAR indications that, had they been PLANAR too, they would have combined These LAMINAR indications and the nearby PLANAR ones are listed by channel and indication number. A space is left for a qualified operator to combination.

fill in an evaluation of the possible P.R. 5/12/81 -20 IV. 99

REPORT 88 Indication Combination Printout INDICATION COMBINATIONS CH8 INDI T HINX HAXX MINY HAZY DMIN DMAX 4 19 S N 325t 34 32?e 44 608m 74 610e 16 3'2 4. 10 4 104 L 311.01 331.22 653.72 653 72 4. 09 4.09 105 L 332.06 332.06 652 87 652t87 3?4 3.74 4 104 L 331.01 332.06 652.87 653.72 3. 74 4.09 5 24 S Y 244 32 244.44 198 98 199.87 5.75 6 42 26 S Y 244.53 244.63 198 02 198 35 6 21 6. 41 24 SMY 244 32 244.63 198.02 199.87 5.? 5 6. 42 27 S N 245.22 245.53 198.74 199.95 5. 61 6.50 5 24 S N 244.32 245.53 198 02 199.95 5 61 6. 50 The indication combinations printout has one i 1 io i th e fina I report: to account foxx thee d isappearance s of indication numbers durin ur ng tth e combination b process.

The first 1 ine belov the header contains the data f i di io Fo h corn i o bi nation that is m

~lt n e . e first of these head tt th d t r i i fo th e n dicat on to be combined with the The next line containss data a a for or the resultant combined indication.

If the re are more combinations for, the h en all combinations are complete, the li line begins with the channel nne numnumbeer instead of the axrow symbol,.

In the examples above, indications 104 and 105 w th result having the lower indicati and 27 vere combined in um r(o)of t nto indication 24, as vo.

shovn on the last combinations res u li lt i f

ne o the exam p le.. In this last case, the e d n a final indication tion vith an altered type (tvo SUBSURFACE PLANAR Y indications fi SUBSURFACE MULTIPLE PLANAR Y, then this combined inndication had a further combination with SUB URF NON-SUBSURFACE NON-PLANAR indication)

The system does not combine tvo indications then c indications are flagged s st gg , then the system p rforms t e actual n ombinations do not lead to combinations Indication combinations are given for thee P , T, T and V type channel indications After th e c h annel1 and indicattion numbers (or arrow symbols) t the typ e o f in d ication is listed in th T column. The n the main catagories axe PLANAR X (X) X), PLANAR Y (Y), NON-PLANAR (N), and F.R. 5ll2/81 -21 lV. 100

REPORT f38 LAMINAR (L). PLANAR X and Y are subdivided as MULTIPLE PLANAR X or Y (MX or MY), PARALLEL PLANAR X or Y (PX or PY), and, a third category where distinguishing ~i TIPLE from PARALLEL PLANAR X or Y is impossible by the computer (*X or *Y).

PLANAR and NON-PLANAR are further refined by the prefixed classifications OUTER SURFACE (0), INNER SURFACE (I), and SUBSURFACE (S) ~

The minimum and maximum- X, Y, and depth values are given in inches-COPLANAR Combinations COPLANAR X COMBINATIONS CHP IND. 0S 'INX MAXX MINY SUM A/TX AVo ALLOW/TX EVAL 4 7 8 118.34 118 74 554.99 556.'39 3 61 . 3.63 13 4 7 13 118.74 119 23 554.99 555.32 3.27 ****

Overlapping PLANAR indications are examined by the program to see if their combined depths are within the limits described in section IWB-3511 1(c) and figure IWB-3514.1 of the December, 1975 edition of the code. The process occurs after the indications have been combined but before the final evaluation., The algorithm used is described elsewhere. The PLANAR X combinations are checked, then PLANAR Y combinations.

In each case, if any combinations are found, the channel number is listed followed by the indication numbers Only 2 indication numbers are listed per line, so some indication numbers, like 13 above, may be listed without the other information, on the following lines. The X and Y boundaries of the overlapped area are given, followed by its value and allowed value. Asterisks appear in the last collumn if the value is not less than the allowed value Indication Evaluation Table FINAL EVALUATION TABLE CH INDI T MINX MAXX MINY MAZY DMIN DMAX VAL ALLOWED EVAL 4 19 S N 325 30 327.40 608.70 610 10 3. 60 4. 10 3. 10 3. 0 ****

3 10 3.4 4 104 L 331.00 332.00 652 80 653 70 3.70 4.10 0.9 23.1 The final evaluation table is similar to the combinations table, with the evaluation information added. Indications from all channels are listed; LAMINAR indications fall at the end.

Indications are listed so that those near each other in X or Y F.R. 5/12/81 -22

REPORT /38 location are near each other on the list. In the VAL column is the calculated inspection value for the indication (i.e. A/TX for PLANAR and NON-PLANAR indications, AREA for LAj3INAR). The ALLOWED column gives the allowed values, interpolated from the tables listed at the beginning of the report.

X and Y projections are evaluated separately for NON-PLANAR indications, with the X evaluation on the first line and the Y on the second.

The final column is left empty if the indication is within the allowed limit. Four asterisks are printed otherwise. The asterisks mean that the computer's evaluation of the data yields an indication whose size and location exceeds the allowable values; it does not im 1 that the indication is not allowable b the code.

Indications with asterisks require further evaluation: either explanation of the data (such as operator knowledge that a bracket or beveled weld caused spurious data to be obtained by the computer) or re-investigation of the area in question using standard manual UT scanning techniques The latter approach is required since Section XI of the code was designed for analysis of manually obtained data. The computer is much more diligent and precise in its data collection than is humanly possible and, thus, its evaluations will in general exceed those obtained by manual scanning.

END OF PASS This is printed after all indication evaluations have been printed

'If there were no indications, END OF PASS is the only line printed F.R. 5/12/81 -23 IV. 102

REPORT //8 Lon Printouts of Indications

)INDICATION COMMANDS: PRINT INDICATION: BN &019 INDICATION REPORT: CURRENT BN &019 UT CHANNEL 4 INDP: 19 CLASSIFICATION: SUB-SURFACE NON-PLANAR CHARACTER: (X) ELLIPTICAL (Y) ELLIPTICAL LOCATION:

MINX ~ 325.3 MAXX ~ 327.4 MINY ~ 608.7 MAZY ~ 610.1 MINDEP ~ 3.6 MAXDEP ~ 4.1 EVALUATION:

AXIS A L A/L A/TX ALLW LOW HZGH (X) 0 24 2.15 0.11 3 10 3.0 (0.1012.9) (0 15,3 2)

~*INDICATION REQUIRES FURTHER EVALUATION***

(Y) 0.24 1-41 0 17 3 '0 3 ' (0.15,3.2) (0.20 3 6)

NO FURTHER EVALUATION NECESSARY INDICATION REPORT: HISTORIC BN &019

~ ~ ~ ~ ~

If an indication requires further evaluation, the post processor operator may elect to print a long form version of the data contained in the Evaluation Table described above. This may be done by a command issued in the middle of the report which prints specific indications, or a command before the report which prints all indications requiring further evaluation.

The printout covers one page and contains the same information as was in the evaluation table, with more details The two sections, current and historic, contain identical information for the base line examination The UT channel and indication numbers are listed first, followed by the X" and Y character: CIRCULAR, SEMI-CIRCULAR,ELLIPTICAL, SEMI-ELLIPTICAL, or LAMINAR. The minimum and maximum X, Y, and depth values are listed.

PLANAR and NON-PLANAR indications list values for A, L, A/L, A/TX, and the allowed value (ALLW). The A/L and A/TX values used for F.R. 5/12/81 -24 IV. 103

)

REPORT /38 interpolation sre listed mithin parentheses in the LOP and HIGH columns. These values are taken from the evaluation table at the beginning of the final report.

LhNINAR indication reports liat the indication lengths Sn the X and Y directions (LX and LY), the true calculated area {RECT), the sd5usted area stipulated by the code (AREA), 'and the interpolated illoved area No ad)ustment of the RECT as allotted by the Minter of 1975 code has been made and so the value always equals the AREA.

"***lNDICATIONREQUIRES FURTHER EVALUATION*+*"Ss printed if the indication exceeds the allotted limit in that pra)ection (X or Y).

As discussed above, this is merely a sign that additional standard evaluation is required and in no vay implies unacceptability of the indication at this point.

"NO FURTHER EVALUATION NECESSARY" Ss printed Sf the values ars Sn bounds During post pracessing, only indications having at least one pro)ection requiring further evaluation vera selected for the long form evaluation printout.

III'ENERAL ITEHS COKED: XXXXXX Occasionally, contents are vritten Sn the report, either by the operator in the field, ar during post, editing, ta explain changes made. Comments made Sn the field start vith "COHERENT:."; those, made during post edittiug usually begin vith an asterisk or s dash A fev "p"s may appear in the printout, usually at the end or near comments These are figments of the past processing system and have no importance Occasionally, table headers appear in inappropriate places, e g. at the bottom of a page, vith the table headless on the next page This is due to the fact that the post processor must rely an the layout. of the data on the originaL tape and, in some instances, thic causes table headers vhich faLL at inopportune placesi l

MOTE: or,

• NOTE:

Notes may be inserted during post editing,raferenci'ng a "separate sheet'of explanatins. This may be used instead of an in-line comment which might be lengthy or repetitious: several notes msy reference the same explanation The note ID vill be follaved by a IV. 104

REPORT 88 page number, time, and date. These refer to the page, time, and date listed on the last page read before the note. This is to help the'eader relate the note to events shown on the original printout of the run. The Post Editor and Processor are set to always print notes starting with an asterisk, and only print notes starting with a dash on full reports. These choices may be altered during post editing..

F.R. 5/12/81 -26 IV. 105

~ '

Page 1

of 3 1/12/82 INllLi1AIION4 $ IIHCI INOllell~ NO OITINON SECTION V RECORDABLE lNDlCATlON LIST Project SUS UEHANNA UNIT /J1 325 (M) 2 BA lSl 'DA 3 9 ( ) Rev.

Category Procedure Identification Data Calibration System Number Indication Description Sheet No. Sheet No.

39 RPV AC ('A) AC IRCUMFERENTIAL 40 S ot Indicatio DS 27, 28.

AD (A) 29 30 Sot d V BA A BA 4 Indications ONGITUDINAL 7 2046 LDS BA (M) 2050 2045 S ot BC (A) BC 47, 49 16 Spot Indications BC (M) 2052 2045 2 Spot Indications BD (A) BD 44 1 S ot Indication BG (A) BG 37 11 Spot Indication BJ (A) 36 2 S ot Indications V. 1 SS. I 2744060 GEIIERAL OI ELECTRIC

GENERRL ELECTRIC POST PROCESSOR= VERSION 3 REV. ?.

SUSQUEHRNNR I MELD RC EVRLURTIGN LEVEL = 501 DRC VELOCITY GF SOUND = 0. 1164 LRG TIME = 1. 000 DISTFINCE C.F. = 0. 0000 RCOUSTIC LOCRTIQN TOLERRNCE = 0.250 CYL INDR I CRt GEOMETRY r CIRCUMFERENCE SHELL COURSE: 3 THRESHGL'D' 961 CRRMLER PULSER LGCRTIGN X = 0. 00 Y RESIGN 3.

SENSOR GLGBRL X ~" Y sr

~

3r'1 1 18 17 8

520. 392" 499;?43 501.647 150. 949 380. 676 356. 796 477.516 462. 156 5 15 81.555 373. 116 6 16 1 03. 545 377. 676 7 14. 781.748 478.596 8- 9 219.?43 478.836

'1"0 9-:

~

~

" ~

13" 7'8.270 717. 340 485 376 466. 356 13 12 611.356 479.976 1+ 1 0 364. 660 480. 816 TRBLE IMB-3510 RLLQMRBLE PLRNRP. IND ICRTIQNS RSPECT SURFRCE SUBSURFRCE RRTIQ -

INDICRTEGNS IHDECRTIGNS RrL =- ~

Rr T>r. Ri'Tr 8

0. 00 1. 88. 2. 32

0. 05 2-. 00 2 42

~

0. 10  ?. 18 2. 61

0. 15 2. 42 2 ~ 91 0- 20 2. 71 3. 25

0. 25 3. 08 3. 68

0. 30 3. 48 4. 13 0 35

~ 3.48 .

4 63 0.40 . 3.48 =

5.24 0.45 ' ---:= 3'."48 " 5.86 0.50- ' ~

"3.48 6 51

'"TRBLE IMB-352 0. 2 RLt OMRBLE LRMENRR- INDICRTIQNS COMPONENT THECKNESS LRMIHRR RRER.

--'>>')- IN, - '-. -~ Rw:SQ IN; r.5+I/,. *'e

• 10'0

. err-,r r . =

1P di'3 M r.A." .'i,p 12, a8 20

~ ~, r

$0 EVRLURTEQN PRPRMETEPS VESSEL MODE SCRNNER DIMENSIONS=

V. 2

~

0

PRGE 0002 80 DEC 10 19-'58-48 SUSQUEHRHHR I WELD RC OF 0 CRLIBRRTIGH LEHGTH= 36-. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE= 3000 QD. UNITS PEP. INCH= 100. 00-SCRHHER- STEPSIZE = 0. 050 STEP TOLERRHCE = 0. 020 l'IIHSEP = 0.250 100'RC = 100 EVRLURTIGN LEVEL = 50 WELD PEFEREHCE POINT- X= 558.48 Y= 400.50 THICKNESS = 6.520 SHELL COURSE 3 CIRCUNFERENCE = 837.72 EVRLURTIGH RNGLES." LRNINRR=" 10. 0 HGH-PLFIHRR= 10. 0.

SUPFRCE TGLERRNCE DISTRNCE=.. 0. 0000 REPORT B;E.. DRTR FIT FULL B.E. RNP NRXINUN- B.E; ~DRC FGR EVRLURTIQN = 5 UT CHRHHEL DRTR= SCRNNER SEP-. FRCTOR = -

13 CH RNGLE .-

X OFFSET Y OFFSET BEG.IH S'TGP '. NN. BE TSEP T5~4R.

2 0.0 W 2 ~ 55 0. 00" 1200 2150 0 .-11 0.

-2e 25 2. 65 0.00-00'8 45 ~ 0 T 450 2150 0 5 60.0 T -1. 05 2 65 150 2150 0 39 -7. 00 6 -45. 0 P -5. 45 0. 60 S50 1950 0 20 0. 00 7 -60 0 ~ P -5. 45 1. 75 850 1950 0 20 -6.00 10 0~ 0 B -2. 55 0. 00 10 2150- 7 11 . 0.

00'-'EGIN UT INSPECTION RND CRRWLER NOTION SEQUENCE"" -=

EVFlLURTIQH LEVEL = 50~ DRC WELD RC VELOCITY QF SOUND = 0.1164.

LRG TINE = 1. 000 DISTRNCE C.F.. = 0. 0000 RCQUSTIC LOCRTIQN TOLERRNCE = 0.250 CYLINDPICFIL GEONETPY CIRCUNFEREHCE =. 8 7. 72 SHELL COURSE - 3 THRESHOLD = 961 CRFIWLER PULSER LQCRTION X = 0 ~ 00 Y = 0. 00 PEG ION 3 SEHSOP. GLGBRL :- X Y 1 18 520. 392 380. 676 "2 17 499. 243 356. 796

3. 11 501.647 477.516 4., 8 150.949 462.156 5 15 81.555 373.116 6 -"" 16 103. 545 377. 676 "7"- "* 14 781. 748. 478; 596 9'19; -

8- - " ~

743 478. 836

,'wi a .7: 48 270 485.376 1 0' 13 =

71'7. 340 466. 356 18 12 611.356 474.976 14 10 " 364.660 480 816

~

EVRLURT ION PRRRNETERS-VESSEL NODE SCRNHER DINEHSIONS:

CRLIBRRTIGN LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE= 3000 QD. UNITS PER INCH= 100. 00

~ SCRHHER STEPSIZE = 0. 050 STEP TOLERRHCE = 0. 020-NIHSEP = 0. 250 V. 3

,0 PRGE 0003 80 DEC ll 11-40-47 SUSQUEHANNA I MELD RC 04 1 00'RC = 1 00 EVRLURT I GN. LEVEL = 50 MELD REFEPENCE POINT- X= 558.48 Y= 400.50 THICKNESS = 6. 520 SHELL COUPSE 3 CIRCUMFERENCE = 837.72 EVRLURTIQN RNGLES- LRNINRP.= 10. 0 NON-PLRNAR= 10. 0 SUPFRCE TOLERANCE DISTRNCE= 0.0000 PEPORT B.E. DRTR RT FULL B.E RNP MAXIMUM B.E. ~DRC FGR EVAN URTIGN = 5 UT CHRNNEL DRTR- SCRNNER SEP. FACTOR = 13 CH-"-'"'NGL'E--- ""X" OFFSET' OFFSET BEGI'N-">> STOP"NN"BE -TSEP T5i4R 2'" '" 0. 0 IJ . -2.55

• 0..-00 =

2150 0 '200 1-1 0. 00 4 -' 45. 0 T ~ -2.:25 - ~

2. 65 450 -.--2150" -- - 0. -- ~ -28 " 0 00.

5- 60.0 T -1.05 - 2.65 150 2150- . 0 39 7. 00, 6'45. 0 P -5.45 0. 60 850 -1950' 0- 20 0. 00>

7'-60. 0 P -5.45 1.75 850 1950 ~

0 ~

20 . 00<

10 - 0. 0 B- -2.55 0. 00 1 0- 2150 ~ 7' 11 0.

00'H::

BET BER IT IR RELX RYrR=- DEP SCNR 10 586 30 100 32 169. 36 3.68 1.16 1469 10 586 11 94 34 169. 36 3. 75 1. 09 1462 10 586 99 36 169; 36 3.82 I. 15 1455 .

10 58& 8 99" 41" 169.36 3.S9 1 . 15 "1448-10 586 11 41 169; 36 3.96 1. 15 . 1441" 10 586 9 39 169.36 4. 04 1. 09 1433

=

10 602 7 103 32 169. 36 4 11

~ 1. 20 1426 END GF PRSS VELOCITY OF SOUND = 0-1164.

LRG TINE = 1.000 DISTRNCE C.F. = 0.0000 RCQUSTIC LOCATION TOLEPANCE = 0.250 CYLINDRICAL GEGNETRYr CIRCUNFERENCE =- 83?.72 SHELL CGUPSE:- 2 THRESHOLD = 20000 CRRMLER PUt SEP. LQCRT I ON X = 0. 00 Y 0. 00 PEGIGN 3 SEl'lSOR GLOBRL Y 18 520. 392 380. 676 2, " 17 499; 243 356. 796 "3- ' "- -

11 501. 647 477 516.

~

8 "- -150.949- 462 156-

~ 5- ~ - 15' - 81.555 ~

373.116

'-'6 """--'~" "'..16' "377.676

~

7"'

8: >-

' "'4' ""1.03 545 781' 748'" '78e 596

~ 9'219;743 " 478.836

=9-"' -

• 7' -

48'.270 485.376 10 13 "71'7.340 466.356 1-3 12'1364.660 10 1'. 35& 479. 976 480.816 EVRLURTIGN PRRFINETEPS-VESSEL NODE SCFINNEP. D INENS IONS-CFILIBRATIGN LENGTH= 36. 00 FULL SCALE= 3600 VESSEL LENGTH= 30. 00 FULL SCRLE= 3000 V. 4

~,

e

PFIGE 0004 80 DEC 12 1 0: 24- 3~ SUSQUEHANNA I I!ELD RC OF p4

OD. UNITS PER INCH= 100. 00 SCRNNER STEPSIZE = 0. 050 STEP TOLERANCE = 0. 020 I'1 I NSEP = 0. 250 1008 DRC = 100 EVRLURTIGN LEVEL = 50 MELD REFERENCE POINT- X= 558.48 Y= 400.50 THICKNESS = 6. 520 SHELL COURSE 2 CIPCUMFERENCE = 837.72 EVRLURFIGN>> ANGLES LFIMINRR=- 1.0.0'GN-PLRNRR~ 10:. 0 SURFRCE TOLERFINCE-. DISTRNCE= 0'. 0000 PEPORT B.E. DRTR'T FULL B.E. RMP MRXIMUM= B.E. iDRC FOR EVFIl URTIGN = 5 UT CHRNNEL DRTR SCRNNER SEP. FRCTGR = 13 CH ANGLE OFFSET Y OFFSET BEGIN STOP MN BE TSEP T5r 4A 2 0-0 lrJ -2. 55 0 ~ 00 1200 2150 0 11 0. 00 45 0 T -2.25 2.65 450 2150 0 2S 0. 00 5

~

60.0 T -1. 05 2. 65 150 2150 0 39 -7. 00 6 ~5.0 P -5. 45 0 60 850 1950- 0 20 0 00

~

7 -60.0 P -5. 45 1. 75 850 1950 0 20 -6. 00 10 0.0- B -2.55 -

0; 00 1.0 2150 11 0. 00 t BEIHIN UT INSPFCTIQN FIND CRRMLER MOTION SEQUENCE EVRLURTION LEVEL =

MELD RC MRX RMPLITUDE ID-'- iDRC DEP REL X RYiRZ 50'RC

. -- " '50'FIC DEP PEL X RYiRZ

+50'. DRC.

DEP PEL X RY/RZ DEP r.QFT SDEP

=

4 1 51 0.8 iS3.9- -0.4 0.8 183.9 -0.4. 0. 8 183. 9 -0. 4 0. 0 12.0 <

FINAL EVRLURTIQN TRBLE

• CH TYPE IND-"- T MINX I'1RXX M INY MFIXY Dt'1IH Dl'1FIX VALUE RLLGM EVFIL 4 45T 1 S Y 742.35 742.35 400. 11 400. 11 0. 77 0. 77 0. 01 6. 51 EHD GF PRSS V. 5

0

IJELO NS QKLQ SD SUSQUEHAHNA L lJELD AC naa- 8.OSB NNi 742.3 Xl1Xi 742o3 YOI~ 488. 1 YIQ~ 488,1 2'

ZI1Xi 8.8 Bo8

~

0 0

X V SUSQUEHANNA I MELD AC NAG> O,OSQ NNi 748+3 XNXi 748.3 YllNi 481.i YNX 481 i ZNNi 1.8 2tlXi 8+8

0 0

GENERRL ELECTRIC POST PROCESSOR: VERSION 3 REV. 2 SUSQUEHRNNR I lJELD RD EVFILURTION LEVEL = 50'RC VELOCITY OF SOUND = 0. 1164.

LRG TII'IE = i. 000 DISTFINCE C. F. = 0. 0000 RCGUSTIC LGCRTION TGLEPFINCE = 0.250 CYLINDPICF}L C~EGMETRY~ CIRCUMFERENCE'.

SHELL - COURSE-:- 3.

THRESHOLD = 961 CRRMLER PULSER LOCRTIGN R = 0. 00 Y REGION -

1 SENSOR'- 6LOBRL.:- x Y

~

1 = - 30 269; 874 631. 000

'2 "" " 29 151. 791 632 544 3 28 689-.282 633.792

"' 7 6'1 5

'4" =- .

27 26 25 570.957 76.364 823. 164 495.783 194. 389-632.916 604. 092 604.642 604..548 522. 996

'. 9"="" . 23 103. 545 528. 756.

1 0 ' <<=

22 785. 653 514. 296 13 21 645. 783 520. 596 14 20 524.598 522.936 15 19 333.358 521. 016 TRBLE IMB-3510 RLLOMRBLE PLRNRR IND I CRT IGNS RSPECT SURFRCE SUBSURFRCE PRTIG, IND ICRT IGNS IND I CRTIONS RrL =-

Rr T>r. RiTwR 0 ~ 00 1. 88 2 ~ 32

0. 05 2. 00 2. 42 0.10 " 2.18 2. 61

0. 15 - .

2.42 2. 91 0 ~ 20 =

271 3. 25

0. 25 3. 08 3. 68

0. 30 -3. 48 4. 13 0.35 =

3.48 4. 63 50'.

0.40" -

3.48 5.24 0.45 . -

'3.48 "

5.86

0. 48 6. 51

~ '. -< -TRBLE- I(JB-351 0. 2 RL'LG4lRBLE LRMINRR IND I CRT IONS COMPONENT THICKNESS LRMINRR RRER T~- IN. Rr SQ IN.

~ ~, MP 0 10 6a 10.

8 20 10 30 12 40 EVRLURT ION. PRRRMETERS =

VESSEL MODE

f I

I i

I

PRGE 0002 80 NGV 24 10-26-06 SUSQUEHFINNR' MELD RD OF =p4 SCFINNER DINENSIONS-CRLIBRRTIGN LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE= 3000 ClD. UNITS PER INCH= 100. 00 SCRHNEP. STEPSIZE = 0.050 STEP TGLERRNCE = 0.020 NINSEP = 0. 250 inn<. DRC = 100 EVRLURTIGN LEVEL = 50 MELD REFERENCE POINT- X= 801.80 'Y= 537.50 THICKNESS = 6. 520 SHELL COURSE 3 CIRCUNFERENCE =-837.72 EVRLURTION RNGLES- LRNINRR= 10. 0 NOH-PLRNFIR= 10. 0" SURFRCE TOLERRNCE DISTRNCE=-' 0000 PEPORT B.E. DFITR RT FULL B.E. RNP HRXINUN B.E. ~DRC FGR EVRLURTION = 5 UT CHRNNEL DRTR- SCRHNER SEP- FRCTOR = 13 CH:- RNGLE OFFSET Y OFFSET BEGIN STOP I'lN BE TSEP T5~4R 2 0.0 M -2.55 0. 00 1200 215 0. 0 11 0. 00 45.0 T as 25 a. 65 450 2150 0 28 0. 00 5 60 0 T

~ -1 ~ 05 2. 65 150 2150 0 39 -7.-00 6 -45. 0 P -5. 45 0. 60 850 1950 0 20 0. 00 7 -60. 0 p -5'. 45 1.75 850 f950 0 20 -6.00 10 0.0 B -2. 55 0. 00 30 =2150 7 11 0. 00 BEGIN UT INSPECTION RND CRRULEP. NOTION SEQUENCE-EVFILURTIGN LEVEL = 50'RC MELD RD t'JR'NPL I TUDE -50<. DRC +508 DRC r. CIF T ID:: iDRC DEP PEL R RYrRZ DEP REL R RYiRZ DEP REL R RYiRZ DEP SDEP "

4 1 73 5.2 78.3 -2. 0 5.2 78.3 -2. 0 5.2 78.3 -2. 0 0.0'0.0 <

+NOTE. RD-3 (PRGE 10 80 NQV 25 09:35-35)

VELOCITY OF SOUND = 0. 1164.

LRG TitlE = 1.000 DI STRNCE C. F. = 0. 0000 RCOUSTIC LQCRTION TClLERRNCE = 0.250 CYL INDP. I CRL GEOMETRY. CIRCUMFERENCE = 837. 72 SHELL COURSE -- 3 THRESHOLD = 952 CRRlrJLEP. PULSER LGCRTIGH R = 0 00 Y 0. 00 REGIOH 1 SENSOR GLOBRL = Y 1 30 269. 874 631. 000 2 =

24 151.791" 632. 544-3 28 689; 282. 633. 792 4 27 570. 957 632. 916 5 26 76.364 604. 092 6

31 823.164 604. 642 7 25 495.783 604. 548 8 24 194.384 522 ~ 996 9 23 1 03. 545 528. 756 10 22 785 653

~ 514. 296 13 21 645. 783 520. 596 14 20 524.598 522. 936 15 19 333.358 521. 016 EVFILURTION PRRRI'JETERS- ~ .

V. 9

~f WW 'j~

t P

PFIGE 0003 80 HQV 25 10=45=03 SUSGUEHRNNR I" MELD RD OF p4 VESSEL thODE.

SCRHNEP, DINENSIONS-CRLIBRRTIGN LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FIJLL SCRLE= 3000 OD. UHITS PER IHCH= 100- 00 SCF}NNER STEPSIZE = 0. 050 STEP TQLERRNCE = 0. 020 NINSEP = 0. 250 100/ DRC = 100 EVRLURTION LEVEL = 50 MELD REFERENCE PG IHT- X= 801. 80 Y= 537. 50 THICKNESS = 6. 520 SHEL}=. COURSE 3 CIRCUNFERENCE = 837-72 ~

EVRLURTIGH. RNGLES= LRNINRR= 10-. 0 NGN-PLRHRR= 10. 0 SURFRCE- TGLERRNCE DISTRNCE= 0.0000 PEPGRT B.E. DRTR RT FULL B.E. RNP t'IFIXINIJN B. E. /DRC FGP." EVRLURTIGH = S UT CHRNNEL DRTF}- SCRNNER SEP FRCTQR = 13 . *.

CH  :-= ANGLE X OFFSET Y OFFSET BEGIN STOP NN BE TSEP TSr4R 4 45.0 T 2 25

~ 2. 65 450 2150 0 28 0. 00 5 60.0 T -1. 05 2. 65 150 2150 0 39 7. 00 6 -45.0 P -5. 45 0. 60 850 1950 0 20 0. 00 7 .-60.0 P -5. 45 1. ?S 850 1950 0 20 -6 00~

10.. -

0.0 B 2eSS 0. 00 30 2-i50 7 1 1 0. 00 t CH TYPE 4 45T EHD OF PRSS VELOCITY OF SOUND IND:-

1 S Y T

='.

FINAL EVALUATION TABLE NINX 42.40 NRXX l'1INY 42.40 535.46 535.46 1164 NRXY DNIN 5.21 DNRX VRLUE

5. 22 0. 01 RLLGM

6. 51 EVRL LRG TINE = 1. 000 DISTANCE C. F. = 0. 0000 FICQUSTIC LGCRTIGN TQLERRNCE = 0.250 CYLIHDRICRL GEONETRYr CIRCUNFERENCE = 837.72 SHELL COURSE '-- 3 THPESHOLD = 961 CRRMLER PULSER LGCRTIQN X REGION 1

='. 00 Y 0. 00 SENSOR GLQBRL X ~

Y 30 269. 874- 631 000

2. *'"- 'i 29: --151>. 791 632. 544

'-.3-" -' "28 689. 282 633. 792 2? 570.957 632;916

-'5 '"-=" " ?6;364"-" 604. 092

"""6 '.'"

. 26

'04

- ~

-31 823. 1'64 642 25 - 495. 783'04. 548 1'

8'" "

-9 '" ..

-24 2.3 22 194; 389 103.545 785- 6S3 522. 996 528.756 514. 296 13 21 645.783 520.596 1+ 20 524- 598

~ 522. 936 15 1. 333 . 358 521. 016 EVRLURT ION PFIRRNETERS:

VESSEL NODE SCFINNER D INENSIONS:

0 PRGE O004 80 DEC 03 09=14:45' 'USiuEWRNNR' WELD RD OF PP CRLIBRRTIOH LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30 '0 FULL SCRLE= 3000 OD. UNITS PER INCH= 100. 00-SCRNHEl? STEPSIZE = 0.050 STEP TOLERRNCE = 0.020 NINSEP. = 0. 250 100/ DRC = 100 EVRLURTION LEVEL = 50 MELD I?EFERENCE POINT: X= 801.80 Y= 537.50 THICKNESS = 6 520 SHELL COURSE 3 CIl?CUMFEPENCE ~ 837'. 72 EVRLURTIQN RNGLES- LRNINRR- 10. 0 NQH-PLRNRR=: 10..0 SURFRCE TQLERRNCE DISTRNCE= 0 0000 REPORT B.E. DRTR. RT FULLY =-B.E. RAP" t'1RXINUN B. E. iDRC FQl? EVRLURTIQH = 5 UT CHRNNEL DRTR= SCRNNEl? SEP-. FRCTOl? = 13--

CH:: RHGLE X OFFSET Y OFFSET BEGIN STOP NH BE TSEP T5i4R "

& 45.0 P -5.45 1.05 850 1950 0 20 0 00>

~

7 60. 0 P -5.45 2. 15 850 1950 0 20 -6. 00 10 0. 0 B -2.55 0. 00 800 2000 7 0. 00'

'1 BEGIH UT INSPECTION RHD CRRMt ER" NOTION SEQUENCE EVRLURTIQN LEVEL = 5M DRC MELD RD EHD QF PRSS

II 0

0

SUSQUEHANNA I LJELD AD VELD Br VELD SH N14 VELD BC PIAG~ 0.0<8 XNN~ 42.1 XNX~ I2.4 VI1Ni 535.4 VNXi 535.4 ZNN'o2 ZNX 5,2

0 0'

SUSQUEHANNA I VELD AD

+ ~B llAG~

SB B.BOB XNN~ 42.4 XllX~ 42.4 YNNQ 535.4 YNX0 535.I 2tlNi 5.2 ZllX~ 5.2

~,

I

SUSQUEHANNA I IJELD AD TiQe e

neo e.ceo NNi I2.4 XPlXi 42.4 YNNi 535'<

YNXi 535.1 ZNNi 5.2 ZNXi 5.2

GEHERFIL ELECTPIC POST PROCESSOR: VERSION 3 PEV. 2 SUSOUEHRNHR I MELD BA EVRLURTIGN LEVEL = 50/ DFIC

+NOTE- BR-1 (PFIGE 51 80 DEC 17 16:57- 07)

TRBLE I MB-351 0 RLLQWRBLE PLANRP. IND I CRT I QNS RSPECT SUPFRCE SUBSURFRCE PRTIQ IHDICRTIGHS IHDICRTIQNS RiL 0.00

0. 05

=

~"

'.88 RiTr >

2 00 -"

< ~:"

=

-'*~2~42'-*'.

RITrR 2.'32 10 "~ 2. 18 2 61-

0. 15 -

2.42 "- '

9.1-

0. 20 2. 71 3. 25.

0. 25 3. 08 3. 68

0. 30 3. 48

• 4:13

0. 35 3. 48 4 63 0~ 40 3. 48 5. 24

0. 45 3. 48 5. 86

0. 50 3. 48 6. 51 TRBLE EMB-351 0. 2 ALLQMRBLE LANENAR ENDECRTIGNS-CONPQHENT THICKNESS LAMINAR. AREA Tr IN. Rr SQ IN.

0 10

-10 8 20 10 30 12 . .

-40 EVFILURTION PARRNETERS-VESSEL MODE SCANNER DINENSIQNS-CALIBPRTIQN LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCALE= 3000 GD. UNETS PER INCH= 100. 00 SCAI'INES STEPSIZE = 0. 050 STEP TOLERANCE = 0. 020 ~

NINSEP = 0. 250 100'AC = 100 EVRLURTION LEVEL = 50 WELD REFEPENCE POINT- X= 737.82 Y= 126.50 THICKNESS = 6. 520 SHELL COURSE 1 CIRCUMFERENCE =.83& 58 EVRLURT ION ANGLES= LAMINAR=- 1 0. 0 NON-PLANRR= 1 0. 0 SURFACE- TOL'ERRNCE DISTRHCE= 0 0000 REPORT B.E. DRTR<<RT'Uf L B;E. AMP*

NRXENUN"B.E. /DRC FOR EVFILURTEQN ==' -"

UT CHANNEL DRTR-'CANNER SEP; FRCTGR = 13 CH .= ANGLE X OFFSET Y OFFSET BEGIN S.TGP NH- BE TSEP T5r4R-2 0.0 M -2.. 55 0. 00 1200 2150 0 1 1 0. 00 4 45.0 T 2a 25 2. 65 450 2150 0 28 0. 00 5 60.0 T -1. 05 2. 65 150 2150 0 40 -7. 00 6 -45.0 P -5. 45 0. 60 850 1950 0 20 0. 00 7 -60.0 P -5. 45 1. 75 850 1950 0 20 -6. 00 V. 15

f PFIGE 0002 80 DEC 17 16 07 SUSGUEHFINNR I MELD BR

<<)'6 CH- '-'. RNGLE X OFFSET Y OFFSET BEGIN STOP =NN" BE TSEP T5~4R-10 0. 0 B -2.55 0- 00 10 2}50 ~

7 11 0. 00 BEGIN UT INSPECTION RND CRRMLER NOTION SEQUENCE

~

EVRLURTIQN LEVEL =- 50'RC MELD BR CH:- BET'ER IT . IR RELX RYrRZ DEP " SCNR 10 583 . 14 299 -15 -5.30 }13.74 3. 49" 1202'<<-

10. 584'4'308~ -" 15- -W'.25 113..74

~ 3 60 - }207~""

1 0'- 584"'"-'" "f4'a9.<<:"<15~">>-'5 f 1:1 3'; 74 3 49~<<f P=f.4'." -.-

10- 12 . 300 --15'- -5. 11 113. 74. 3.50-579'.10'09-'4-8'84-==.

~ ~

5S4'.

}221'.

10. -5;.04* 113. 74. 61-"

-2. 49" 113.73

=1228'-'.

10 258 -

18 02 ~.f 483 10 578 -.. 8 257 18 * -2; 46 113.73 3., 01- --1486 10 579' 8'" 257' "18 -2.40 113.73 3. 01-- -'1492" '" .

10 578' 7 257'8 -2.33 113.73

-2.26 113.73

3. 01 '1499 10 578 7 258 15 3. 02 1506.

10 57a-- 25 144 27 --0.46 92.47 1.70 1686-NRX- RNPLITUDE" ' ' " '-50'RC .-. ': "~ -." +50'. DRC . -=-

C OF-T=-'

ID:"RDRC DEP REL X" RYiRZ - DEP REL X RYiRZ~*'"DEP"REL X RYiRZ. DEP" SDEP

~

2 1" 70 i. 7 -0.4-..92.5 1. 7 -0.5 92.5

-4.5 91.4

-=--1;7 -0.3 92.5' 0. 0" =25..9 2 58 4. 0 -4. 1 91.4 4- 0 -

4; 0 -4. 1 91'.4. 0. 0 39.1, CH:: BET BER- IT IFI RELX PYrRZ DEP- - -SCNR 1 0 563 12" 252 1& -4. 60 Sa. a4, 2. 95 '"1272:

10 563 13 252- " .16 "-4.56 89.95 2. 95---'1276" .

252'19. " -4; 49. 89. a5 1

10 10 0 563 563 577

'012 8

248 248 23 '-4;43 89; 95 23 -4;37 89 ~

2. 95" 1283" 2.90* . 1289

2. 90- -1 295 1 0 57? 8 243 20 -4. 31 95'9.95 2. 84- 1301 1 0 578 7 253 15 . 24. 2.96 - 1.308 NRX RNPLITUDE - ~:-50'RC --- --. '-='+50'RC r..OF T ID:-- rDFIC DEP PEL X RYiRZ DEP- REL X RYrFIZ 'DEP* REL X RYrRZ- DEP" SDEP )

2 3 50 2.S -4.3 89.9. 2-9 -4.4 89=9". 2 8 . -4.3 S9.9- 1.9" 42.2-<

CH::-

1 0 BET - BER-591" 587 13 IT."'R """RELX-238 -~""14"-'0.5i 83. 92 "233'20---0.58'-83.92 RYiRZ DEP -

2. 79- ~f

"-SCNR"-.

2.73-="}674i~ "

68}-"'0

'419'37'23'".

10 586 -0;65.- 83.92 2;77'".1667 10 -"586; " 23?""'"24"- -0.-73'83.,92.. = 2.".77<<'}659'-'"-.

": ~ NRX RNPLITUDE" .> " "'"=.>'-- ~="= >-50< DRC:-- ~>>>><>>>->+50( DFIC =- ">> ~ ~". QF"

. ID: RDAC DEP- REL X- RYrRZ - DEP- REL X RYrRZ--.'DEP=REL X RYiAZ i'.'EP "SDEP 4 59 2;6" -0.'c" 83.9" 2.6'0.8 "83'.:9-~ '2;6 :-0.6: 83.9. 0; 0 "- 39;.8" CH:: -

BET BER. IT "IR ~

RELX PYiRZ DEP" SCNR 10 586 19 192 19 -2.86 75. 47 2.25 F

-3. 25 75. 48 1446'.

10 591 27 194 29 28 1407 10 592 25 190 gf 3 ~ 38 75. 48 2. 23 1400 10 592- 22 190 28 3 ~ 38 75. 48 2. 23 1-394 10 592 20 194 21 -3. 44 75.48 2..28 - 1388 j, 10 5a3 . 16 202 18 -3. 57- 75.49 2.,37 -}.37.5." =

',10 596'15 ~ ~ },"98 -3. 64.- 75. 49- 2 >> << f~368g~: ..

0003 80 DEC 17 17 33-'32 'USQUEHRNNR I"= .tiIELD BR-OF I

)6

,'H:- BET BER ~

IT IR

• RELX RYiRZ DEP-- SCAR" .

10 597 14 194 20 -3.71 75.49 2.28 1361-10 592 12 202 18 -3.78 -75.49. 2.37 33.1'RI~E

-13541RX 2

ID:-

5

%DRC DEP REL X 50 80 Rt'1PL ITUDE

2. l.

2e 1 -

RYiRZ DEP PEL X

-3.3 75.9 2. 1 -3.3 75.9" .2. 1 . -3.3 75.9

-3.3 75.5 2.2: -3.6 75.5e< 2.2 '---3.2- 75.5

-50% DRC PYiRZ DEP PEL X RYiRZ

+50% DFIC DEP 0.

0.5 OF T SDEP 31.6>

CH:- BET: BER": ~ -IT " 'IFI'->> RELX DEP-'- SCNR-" "

1.0:~ 590'~-i" 7~ ~l-9-1<<+~<2 0>>>~-'-2.':72",-" 75;<0 -"-2~ 24-R-YiRZ'0

-1;460>>. "-

" "7 1'9l"-" -" '2l'"-2'7>> >>.75;.01. 10'591-"

2'. 24" -1465' 10 "590'"*- 7-- 190 *"-- 19" -2..60 . 75; 01 ..23 1472.->>

598:

'e " . 7'82: 23 --0.25:- 74.96 2. 14" "*1707 10 << -" 0' 1<78'.< -31. =-Oe,18 ~" 74e96 2..09'- 1714."

ip "-. 0'" -" 0 10 10 "0

0 0

=-

'178 "-3+'--0.'10>>=-74.96 179"= 46 179'5

-0. 74.95

0. 05 -74. 95 2e 09-""1722'" ---

2. 10-- 1?30

2. 1 0 -1737-

~ -"

10 0 0 179 42 0. 12 74. 95 2 ~ 1 0 1-744 10 0.- 0'80 184'8 30 -0. 18. 7495

2. 12 1750-10 0 0 0.25 "-

74e95 2. 16 ~ 1-757 10 - 0" -- 0- .186 -

23 * .

0. 07 74.51 2. 19"-"1739- "- ~

10 .-*" 0--'"" Oe 186- "=- 28 -.;00':"74;51 2. 19 =-.1732 "-

10- '"'0<<"""'- 0 1<85>>"- '36""-0'. 07 '74-.52 2; 17'- 1*725'-

10 0 0 1'82- 42 -0. 13'4. 52 2. 14 -.1719-10 0 0 182 42 -0. 20 74. 52 2.14 1712 10 0- 0 177 42 -0. 27 74. 52 2 ~ 08 37 -0. 35 74 52 1705'.

10 598 7 . 185 17 '169s-10

'590 593 8 10'86' 186- 3 1'0. 42.

23--0

74. 52 74.52

~

2.19- '1690 .

10 48 1 0 588 16 189- -

21'0. 54 74. 53 2.19-.~1684'.

22'-1678".

1 0 589 1 0 199. 16 . 61 74. 55 2. 34- .. 1571-10 589. 8 1.90 16- 1-. 68 " =

74;55 2. 23 -1564-10 589. 7 191 15'1.,74" 74. 55 2. 24 --155S 10 593 14. 199 ~

16 M.. 36. 74. 56 2.34 "1496" 10 593 11 199. - 18* .-2;43 74.57 2.34- 1489.

10 597 7 200'8" "

-2. 50 74. 57

-2. 57- 74e 57 2.35 1482 10 599 8* 191 20 2. 2+ 1475 10 594 .

16 196" 22 --2; 63 7+. 57 2. 30 - 1469.

l'1RX Rt1PLITUDE ~'"+ 50%e DFIC ' ~ 50%e DFIC'"" ~ i';i% OF T""

= '

~

-'D=-"%DRC. DEP REL -X'YiRZ'< - DEP REL- X'YiRZ'e'i:DEP" REL X RYrRZ'--'EP: 'SDEP'I 2, '6'"-5'1" - 2.2. "-2 7 " 75:0~'=2'2 '--2..7 75. 0"~2; 2 7 '75.>>p-e 0 '.33; 1:-

-61..".2.-1, " -2 6 "74. 6'. 2e 1>> -2.,8 7+. 6 '~'2;;2.. .-

4- -74. 6" - 1 032;. 1'..

C e CH:= >> BET:" =BER'<" IT~. ~-I'M~RELX< 'YiRZ' DEP--->>SCAR~'-i 10 . 582:-,-.;.15;~ f85>>..>> <<22'<.--3'.43~" 74..13 2. 17'- - 1"389---"

1.0 582 '1'1=" J.'94-'" 3 38 -74. 1.3

- =* 2;28.- "1394-=

582. " 1 0'194- "16: -3.-31" . 74. 13 28" 1:401- '.

10 -

17'-.56

=

10 5SS '17 .184- ' *74. 11 2.,16 -1476 "- ~

10 . 11 iSS" 18 -2. 49 74. 11 2. 21-10 586. 7'83 17 . 43 74. 11 1483-'.15 1489-

'5 10 582 8 192 17 -2. 36 74. 11 2 1496. '87 10 582 13 192 16 -2. 30 74-. 1 0 2.25 -1502'.

10 588 8 189= 16 -1. 37 74. 08 2.22 1595 ip 593 7-. 198" 15 -1. 31 - 74. 08 2. 32 "1601- ~ ~

(l.p 577' 1:0 ~ f&1- 1.9. -1.. 03 " 74'. 08 "2..24. '1629-- - .

0

.0 I

f

PRGE. 0004 80 DEC 1'7. 17:39..03 ~ - SUSQUEMRNl'<R I" IIELD BR

~ a ~ ~l' ~<<<<<<

aF 16

'H::" BET BER IT - IR RELX RYrRZ DEP - =SCHR-10 578- 14 188 26 -0. 96- 74. 08 2.21 1636.

10 577 15 187 29 -0. 89 74.. 07 2.20 1643 10 577 16 }87 29. -0. 83 74. 07 2-20 1649 10 577 17 187 ?7 -0. 77 74. 07 2-20 1655 10 574- 18 191 22 -0. 71 74; 07 2. 24" 1661 578 9- -0. 52 74: 07 2. 24 1680*

10 188'518 -0 191 =

~

10 580 7 46- 74.

06 2.21 ."}686= -.

-0. 40 74. 2. 21 1692 588 7 188 26 06 '

0 -

2.,2.1 - }699' 1

10 - 0: 188 - -28".-0.-.33'74-. 06 f 0~,~-)dt>04<<kva4 Q 4 fSkit ., 22. )tl 0 27$ Wv74<<06( I l? 22 Vt ig05blyf 10 --.<'-'0""'-'- 0}'8+'- '}6- '-0';,19-'-74'. 06 2'.1:6= }713" -:"-

~

10 ".'0"..- 0.'93 - '16" '-0. 12." 74'..06 2. 27- "1'720' f'IRX RNPLITUDE ~ " '"-<-.~-'-50/.. DRC--. ~".--. "- =.'+50'. DRC '" - i .-r. OF T- ~

ID::-'rDRC DEP-PEL'X RYrRZ-:" DER REL X RYrRZ" --DEP" REL" X RYrRZ- DEP'='DE 2 7 59" 2;2 '5" 74' 2.?-" -3.5 74.1'-""2-.2 '3 74-} '-0'-0':

33-6'H:-

BET BER. IT IR PELX RYr'RZ DEP . SCAR 10 583 23 199 26 -0. 23 73. 63 2.34 1709.

10 583 15 198 +} -0.30 -73.63 2.32 '1702 10 10 198- 54. -0. 38 73. 63 2. 32 1694.

10 584- 12 1 98 - -57

-0. 44- 73. 63- 2.32 1688-.

10 580 -17 1-98 " 62 -0; 5'1= 73. 63 = - " - 2. 32" - 168-}-'.---

10 580 24- 199 63 -0. 58 . 73. 64 2.34 1674-10 579 30 198 60 -0 64. 73 64-~ ~ 2.32 1668

~ >o 10 579 578 582 36 202 35 201 29 194.

51 -0. 71 73. 64.

35 -0. 78 73 64-37-- -2.14-

~

73.67 2.37 1661 2.36 1654"-

2. 28- '518'-

10 ~ 582 ~ 24- 1 94- 45:- '-2.21". 73.67 2..28.. 151 1'-

10 586 21 185 54.- "-2. 28 73.67 2. 17 '1504" 10 586 16 190 65 '36- 73.67 2.23.- 1496.

}0 587 15 191 71" -2. 42: 73. "

2. 2+ 1490 10 190 70 -2. 49.

67'3.

68 2. 23 1483 10 588. - 27 19 1 63 -2.56. -73.68 2. 2+ 1476-10 584- 36 . 190 57 -2.63 73.68 2. 23- 1469.

10 584.

46 191 58 -2. 69 73 68 ~ 2. 24 1463-10 584 50 190 53 -2. 76 73. 68 2. 23 1456 10 582. 13 198' 16. -3. 15'- 73.21

2. 32 -14.1 21 -3. 08: 73. 21 7';

10 583 12 194. 28 31'3

'01'. -73.2} 22.-" 1431-'="

1424'.

10 582 1? 189'89' 34 - -2;94 ".73.2}

10 582-10- 582' 10 582 12..

ii

l. 189-194'-

'5" -2".-.87-'=-73. 21, 29- "M.SO- 73. 21 2..22'-" }445-

<<f 438

2. 28 =1452-- -.-

10 i 583<<.r.., 9 20 ... Q', c<<-- f',c4;~~-,73~" 73.,2}~ "- 2;;.35".~1.459 ":"

10: "'583 '"~ 1 205.... }:&:.u 2, 6(.,"--73. 20 -" 2;-40 " 1465'-"

10. '- }'}'. 2.01 20* '.-2..60

• 73';20 ' 36 "~*'}"472<<

'l-l-0'583'-

~

10 -584t }97- 24:-'2;,53. 73.? Q>> 2. 31=- ~}479-

~

10 584 -- 1.4 193 2<'- -2" 46 73.'20 2. 27-.- 14S6- ~

10 ~ 584' 193 33. --2;40- '73.20 2.27 --1492.

}5 37 -2..34- 73. 20 2-.27. 1498 15'85 10 193 -

584- 16 193 37'2.,26. 73. 2 0 2. 27 -1506 584 15 192 3+ -2. 20 73. 19 2.25 1512

~ ','"

'10 584 584 583 14 13 12-193 193

}<2 34- -2. 13 73. 19 31 -2. 06 73. 19 2'4 -1.<9. 73. 19 2.27 2-. 27 1526--

2. 25 -1533 1519 Il 0 584- '; -10 192-

-?6'; - -1.,91 73;.}9 " 2;,25. 154.1 '." ~ kk *-II 0

• Ma I

>>>>+

'RGE 0005 80 DEC 17 17- 42-38 SUSQUEHRNNR. I >>!JELD. B&

OF CH:- BET BER" IT IR" PELX RY/RZ DEP - -SCNR=-

1 0 584 1 0 192 27 -1. 84. 73. 19 2.25 1548 10 584' 292 29 -1 77 ~ 73.18 2.25 1555 10 583 10 292 27 -1.71 73.18 2;25- 1561 25 -1.64 73.18 2.25 1568 10 10 10 58+

580 580'6 13 15 192 193 192 23 -1.58 26 -1.52 =

73.18 73.18 2 '7 2.25 1580-1574-10 580 26 193 2& -1.46 73.28 2.27 1586 18 -1.40 73.18 2.31 - 2592 10 580 15 197

'8" 0- " 2.08 "

=-. -0. 54- 73. 16 2. 44'1678--

1 0<

~

~ .

-" 2;40 ~-1.685'~"="

~ =

2.0 0:~".0 " 205.-'"-26."~~-0'7'"73".16.

10 "- - 0'." ' = 204"-- 30 <<--0;-41'= =. 73.15 2. 39.="-169 1-"

20-:>>>--.~0""-""-0'~202-" -"32" ~-0".:34 =.73 15 2 37-10 ~" 0"" 0 .202 -. 31 --027 73.15

-"1698"'"'.

~

37 2705'".

10 - ~0 ~

0 "-2.06"- 22'--0.19" 73.15. 2. 42 - " 1'7 1'3'--

NRX" RMPLITUDE " ' " -50'RC " "-""""'"'-+50'RC '/'F-T<<

2 ID:- iDRC DEP PEL X RY/RZ 8 115 112 2

2.

~ 0'.-0.2 0

0 75 74.5

~ 0 DEP PEL X RY>RZ

2. 1 -0.2. 75. 0

2. 0 -0.6 74.5" 2. 0

- DEP REL X RY/RZ

2. 0 0.2

0. 1 74.9 74.5 1.

1.

0 0

SDEP""

30.7 30.,2~

'EP

-"" 72. 2. -0.9 74.1- "'2. 1;- 9 74'1 '"2.2. --0.7 '4.. 1 0.5 *'2.6'>>

-0..3 74 1" '2.;li 4 74"'2 - 2. 1". 0.3 1

...j>> 2. 1 74.. i. 0..0. 32. 6.~

'-0.,6.. "73.,6'" 2;2,"" -0.8 "73..b ..2".3. -0; 1 '3;6" 2.-'.'0<'"33'.~

~

~,a~ 150; 78- 2>>

2.,2 3"'>>3'3 2. ' 2 3>> 0~ 4'3>>'2"" '>>+2 0 2'3 2. 2; 9'-- 32: 6-CH - BET BER IT =

IR RELX RYiRZ DEP = " SCNR 2 0 0-. -

0 209 18 =2. 26 -72. 74. 2. 45 1506-10 " 0": 0 204" 24- -2. 33 "72. 74. 2..39 "1499" -

~

7'04- '27 10 -.= 0-t '. 0. 204'" -"-2".40 .72..74- ~

2; 39-->>2 492.-

10 598 26 . -2.47 72.75 2.39- .1485 -

• 0 598 7 209  ? 1." -2. 54 72. 75 2. 45" 1478 1

10 594' 7 209 18'2. 60 72. 75 2.45. - 2472'-"

10 593 10 208 19 --2.66 72 75

~ 2. 44 1466 1 0 594. ~

12 209 2. 72 72. 75 2. 45 1460 10 593 - 15 200-17 -2. 79. 72. 75 2. 35- 1453 10 586. 15" 197 -3'.49" -72.77 2. 31 1383" 10 593 "

15 - 204-18 2. 39 2376.-

=

25 192" - 20 "-3. 76 72. 77

-3;56'2.77'0 588 2. 25" 1356"-

589.- ." 16- 193" '"26- 3..83 72.77 2. 27 1349"-"'

10

'6-'93

-=-

0- 589" -- 25'" "-3'; 90 "72;.78 2F='".2342"

~

1 1 0 -588- 28<" 293- -

18 '-3"; 97 -'72.-78  ?.. 27." 1'335" ~

10 58+ 29'=289"<<-29-" 3 77-'<-- 72.35 2. 22. ~ 2>>355~

10: ~584 "?5-- 1'89 '

27 3;;70 .>>r>>2.35=

~ -

2. 22 '2362',--

1 0'- ~588":.~-'P'~.~189:~~>>~22>>~-3" ~3'"- 72;.35 .

2;"2B'"~2-369 1'0 ~587: -'< -2'4"" -'1'97 "'~>>"2'7--""-3 " 17'""'72 -.34'-2-.32- i ~2425~'-"'"-

~

10 588:- 1'4' 2:98:. 1.7'-'- 3 .12 ---72;34- 2;..32.- 1:420.='-

1 0 "

~

-588"- '4-=""1'98 '" -

2?"- -3" 05: " 72...34 - 2. 32->> -1427 >>

- a 2 0 '587 2.3+ 1'98'i 24" H 98 '72>>'34' 2"e 32 1'4'34 ~

10 587"> 24" 198>>. 21 -2.92"-:72-.34 2.,32 . 2442-"

20 587 15 203 16 -2.84 72.34. 2.38 1448 -

587'4

=

10 202- 16 .77 72.34. 2.37 2455--

10 587 12 194- 18 -2.71 72.33 2-28 1461 10 10 588 588'l 11 194-

?03 20 -2.64 72.33 18 -2.56 72.33 2.28 -1468

2. 38 1476 10 588'.": 1'.0" .-204 - '--2".,50 -- 72;,33 2.,39-. 1,482-. "

20'- -589 "" "'9 .-'200.--m,'- 27 "-2;,43"" 72-.--33 2..35" 1489" "

r4 A,J>> ~4

>> ee 7f 4 ~~'W PAGE 0006-- 80 DEC 1'7'7e"44-23 -

SUSQUEHANNA .I--'ELD BR--

oF 16 CH:: BET BER IT'R 200 34.

RELX

-2; 37 RYiRZ

72. 33 DEP.-

2. 35 SCNR" 1495 10 593 7 1 0 597' 200 34- -2.. 31 72. 33 2. 35 1501 10 0 0 200 32 -2. 25 72 33

~ 2-. 35 -

1507 10 0 0 201 30 -2. 18 72.33 2. 36 -

1514.

10 0= ' 200 29 -2. 21 72.32 2.35 }521 590 7 201 27 -2. 04 72e32 2.36 152S 10 -

10* 586- "- 10" 201 23 -1.97' 72.32 2 '6- 1535 10 586- =

15- 205 -

19. -}.90 72..32 2.40" 1542.

10 - 585'" 8'>>* 252>>e '16. -1".'30*--72-.31 2.95 --1602*"-

}.0:.~582:. ~~" 20$ .;" 14 '~'.}6 * ~7>>2'31 - '-:.38"- }616>>>"

2'0" '582~'~"i 0'~ 206 "4 '2 8'"'. 1":.09"-"72; 3.}.- '- -2:.'42~ -$ 623+-->>

} 0-:>>58 0 "> =.1 0 ""}97- " -21 '" -1'. 02. -72'1- 2.31- "1630'.

10 '80. " 13 - 197: 22----0;95 -.72;30 2. 3 }- i 1 &37e 197'"" 21 -0; 88" 72.30 3 1- -2644-1.0 580 - 2'3' 1.0. .-580' -

22 206. 19. -0. 81

~ 72'. 30 2.42" 1651 10 "580 ee -11 207-"17' -0. 74"- 72..30 2.,43 -265S MRX AMPLITUDE. -50'AC "

. +50'. D RC z GF T ID:-"- iDAC DEP- REL X RYiRZ DEP REL X RYiRZ DER REL RYiRZ DEP SDEP 2 9 65 2. -3.8- 72.8 -3.9- 72'.8 " -2. 1- -3. r 72.8 0.0 32.1

" -'- 81. 2.

1 1, -3;8 =72';3'.2. 1 1"- -3.8 72.3 " '2". 1. 3 6( 7P. 3 0. 0= 32.6 BET"" BER= 'T- ~ IR-':""" RELX-

-1.42-RYiRZ DEP ~-.">>SCNR'-

2. 52. -1590 10 588 =

15 2}5 18 r 1'.90

-1. 71. 90 2 52 15S3 587 14- 215 18'1. 49 17 1 0 ~

1 0 588 15 212 ~ 68 71. 90 2. 49 1564 10 5S9 20 212 22 -1.75 71.90 2.49- 1557-

-1551'H:-

1 0 588 20 212 22 -1 81 71 91

~ ~ 2. 49 .

10 589-" 18 -222' 21;. -1..88'71, 91 2. 49" ~:2544- .-

1 0 589-". 14. 212 19. -1 . 95 71. 91. 2.49-.-}53(-- .-

10 588" 10 206 -

16 -2'. 02 -

71.91 2. 42- 2530>>- ~

1 0 603 7 204- 20 -2; 37 -71. 91 39- --1495-. '.

= .

1 0 608: 7 209. 27 -2. 44- 71. 92 2.45 - 1488 10 608 =

209"

• 29 -2.51 71.92 2. 45 1481-1 0 " ~

0 . 0-- 209. 26" -2. 57 71'. 92 2. 45- 1475 10 - -0" " 0 208 "- 19" -2 64= -71.92 '.44-'468 10

'" -- 0 0 212 17'2'70 7}e92 2. 49 1462 10 0-. 0 221.. - 0- -2.90'1e92 2. 59- "1442 1 0 596 ~

7 2}P.' 18 -2. 97 71-. 92 2-49""}485<<

10 592: -." 8- -P}2" - 2}" "-3-. 04.=- 71. 93 2 49 . 1428

}0 "592; "}P" 21-2"" 2P' -3. 12" 71.43. 8;49 <<}420" --:>>

10 592:""" -};4e->> 2}2>>- 19'>>-" -3;"}& .- ("1 93 ~ 2 49-'~24}4""~

"-':""~~"i~MRX'MPLETUDE- ~ '"'-.~~~~~-'-~>>>>-501 -

D geee eh>>e e+f >>eEIJkt>>+5 0 p, =D A Ce. ~ - e' Hl / Q Fe>> T>>

I.:D= 'RDAG'EP- REL-.X'YiRZ" DEP "REL RYiRZ'e~~" DEP "REL" X-" RYiRZ.'"" DEP'~"

1'64" ~2:".2". M""5-~~ 73".7.'~2.-B'-3. 0-X-',-}l e'7>>~e2e'1 e 63'e>7 ~ .'2~'e 4' '31 '&~

SDEP"'73

'- ~ ~'88>> '" "2'2." S<<" '73" 2' -2" ';2' . 3 l. -.73.;2 '2'.2.'- M;8-" 73.2."='." 0.'0'3.6'.)

2'73; <<0. '4'0")

- -'93'<<- 2e 2 --2e 2 ." 2e,2:" --i&e 5 73;2 ~~>>"2;2 -1;4" '73 2

~ ~

0

~ - 67 "2:,3 -2.4- 72.8 2.3 -2.5 72.8 2;2- ~.3 72.8 = - 2'.4- 33.6 <

84- 23 -23 723 23 -24" 72.3 ---2.2 -1.9 72.3

~ "- -

1.4. 34. 0-61 2. 3 -2 .8 71. 9 2. 3 -1. 9 2.3 -1.7 71.9 0. 0 35. 0 ~

'1.9 75 2.3 -2.5 71.9 2.3 -P.6 71.9 =

2.;3 -2.3 71.9 0. 0 34.5

' 12 57 2.2 -2.9 7i2e 3 2.2 -3. 0 72 3- 2 2- -2 9= 72 3 -

0 ~ 0 34. 0

- ~ e59-" 2 3 -3 1 71 ~ 9 2e2 3e 2 71.9 "-2"..3- -2.9 7}e.9 1 ~ 4 33.6

v. 20

PRIE 0007 80 DEC 17 17:44-23 SUSQUEHRNNR= I MEl 3 BR OF i6 NRX RNPLITUDE -SORY. DRC +50'RC %OFT ID:- ~DRC DEP REL X RYiRZ DEP REL X RY/RZ DEP- REL X RY/RZ DEP SDEP 2 13 53 2.3 -0. 9 72. 3 2~3 -1. 0 72-. 3 2.3 -0.8 72-3 0 ~ 0 35.9 63 2. 3 -0. 9 72. 9 2.3 -0.9 71.9 2.3 -0. 8 71. 9 0. 0 35.5 2 14 82 2. 0 -0 1 71.9 ~ 2~ 0 -01 71 9 ~ 2. 0 0. 2 71.9 0.5 30.2 2 15 50 2.3 1 ~ 4 71.9 2. 3 -1. 4- 71 9.~ 2.3 -2 . 4. 72. 9 0. 0 35.5 CH:- BET BER IT IR. PELX PYiRZ DEP 1 0 589 1 0 215 15 -1. 32 72. 01 2.52 1600 10 588 22 225 20 -2. 39 71. 01 2. 52 1593 10 588.

- - 14'- '205 22" -1 46 7'l. 01 2. 40 10" "584 ' '-'2-7'"~ 205'"?4-" -2.52 ="71- 01 =1582'--

-2586'.40

~

10 584i- " 18 206 ~

23 -1.57 71 01 ~ 2.42 1575 10 584- 15 215: 22-" -1. 64- 71. 01 2.52---1568 10 583 12- 209 27 -1..71 71 Oi 2.45 1561

~

MRX RNPLITUDE -50'. DRC l. +50<. DRC r.OF-T ~

ID:: iDRC DEP REL X RYiFIZ DEP REL X RY/RZ DEP REL X RYiRZ DEP 2 16 84 2.3 -0. 0 71. 0 23 -0 3 ?1.0 2.3 0.1 71.0 35.0 SDEP'.0 2 17 58 2.3 -2.5 71. 0 2.3 -1.6 71. 0 2a 3 -1 4

~ 71. 0 0.0 35 9 ~

CH:: BET BER IR PELX RYiRZ DEP- SCNR.

-2.28- 70 IT'0 590 2? 279 22 ~ 11 3 26 1-504-NRX RMPLITUDE SOi DRC +50% DRC r.OF T ID'-- RDRC DEP REL X RYrRZ DEP REL X RY~RZ DEP PEL X RYrRZ 3EP SDEP 2 19 60 3. 0 -2. 5 70. 2 3- 0 6 70. 1 3. 1 -2.3 70. 1 0.5 46.5 ~

2 20 82, 2.8 3.7 70. 1 2.8 -4. 0 70. 1 2 9 -3 3 70.1 1.0 43.1"'H::

BET BER -IT IFI- RELX RYiRZ DEP SCNR ll8

=-

10 585' 275 15 -1.79- 69. 21 3. 22 2553 10 585" -

270 14 -2.86 69. 21 3. 16 1546 10 588 13 253 25 1.86 65. 02 2. 96 1546 10 586 10 242 21 -1. 93 64. 61 2e 83 1539.

2 0 586 9 242 27 -1. 87 64. 61 2. 83 1545 10 591 7 238 33 -1. 80 64'2 2. 79

'55<"

1552 10 580 7 238 34 -2 . 73. 64.62 2. 79 10 580 10- 233 31 -1. 67 64. 62 2 ~ 73 1565 10 580 13 243 23 -2 . 60 64 62 2. 84. 1572 MRX FINPLITUDE - " ~ - -50/ DRC ~ - -" +50/ DRC %OFT ID'- rDRC DEP PEL X RYiRZ DEP REL X RY/RZ ='DEP. REL X RY~RZ DEP SDEP <

2 21 77 2 8 -2.7 .64;6 2.8 -2.8 64.6 "2.8 --1.6 =e4.6 0;0 42.2 i CH:-" BET BER'- " IT -" IR '-~ REEX-= RYiRZ DEP- =-SCNR "

20 '590'0. '296 ""20 --5'." 46 58. 12 3.46" 2.18&

1 0 59?- 20 303 -

25 "-5;44 58 12 3.54- 2288 ~

2 0 597 20 304 22- . -5.36 S8. 22 3.55 -"1196-1 0 595 21 -306 24 -5. 13 57. 71 3. 57 2219 1 0 595 17 302 30 -5. 20 57. 71 3.53 2222 10 595 13 302. 32 -5. 27 57.72 3.S3 1205 10 595 10 302 35 -5. 34. 57. 71 3.53 -1198 10 596 8 302 37 -5. 41 57. 71 3. 53 1191 10 600 7 302 38 -5. 47 57. 71 3. 53 1285 10 S95 7 302 37 -5. 54 57. 71 3.53 1278 10 596 7 302 32 -5. &2 57. 71 3.53 2171 10,595- "

8 306 25. -5.68 57. 71 3. 57 ~

• 1'164-

Pt'~ ' 'I r <<h ~ <<<<<<

-w PRGE 0008 80 DEC 17 "17- 57-'54'"- SUSQUEHRNNR ."I~:"MELD<<BR OF -16 CH:-'ET -BER IT '- IR . RELX RYr'RZ DEP .SCNR .

10 595' ll 301 16 " -5.-75'7.71 3..51 1157-MRX RMPLITUDE -50% DRC +50'. DRC OF T ~

ID:- iDRC DEP REL X RYi&Z DEP PEL X RYiRZ "DEP PEL X RYrRZ DEP SDEP 2 22 78 3. 4<< -5. 4 '57. 7 34 -57 577 '34- -52 577 0~ 5 47. 3 ~

2 23 . 68 2.3 -3.3 57.3 2 3~ -3. 4 57. 3 ~ 2'. 3 -3. 3 57. 3 0~ 0 34.5- ~

CM:-'ET BER IT IR. RELX RY/RZ DEP SCNR 10 604 7 316<<<< . 15. -12..02 55..33. 3.69 -530' 10 608 7 322 1S --11..99 "55.33 3.,76 "-"533 1-0 "613 "-"7"'322 '<<" 18"-H 92".'55'3. - 3.76- 's" *540'"<<--

,10'05-: . 9 -321: "<<'20.'-1<<l-.:.85" 55'..33 "3-75-~-54'7". ' -" <<

10 601"." 15 3&1 20- -11.78 '55 33 3~75 -'554""-

10 582 - 22 .- 199" '27-"'H.s77='54.40 .<<<<2. 34 1255"; ..i.

10 581'.18 --1 9

• 26 "-4 70- 54.40 2. 34 -<<1262."-

1 0 581 15, 194:s 23" ' 63' 54.<<40 2. 28': 1269 10 580 13 208 16- -4. 56'. 54.-40 2. 44' 127&" 1RX RMPt ITUDE -50'. DRC +50'. DRC OF T ID:- rDRC DEP REL X RYrRZ =

DEP REL X RYrRZ "-"DEP REL X RY~RZ DEP SDEP 2 24 68 2.3 -4.8 54.4 2.3 -4.S 54.4 -'.- 2.3'4.6 54.4 0.5 34-.5 -~

CH:-"

10 BET" ..'BER 591- .

'T'

'22.-294- ='2'~'-9';68

-IR"'-,,+ RELX

'2;88 RYiRZ'~ DEP""" SCHR*

3.43-"'~764'.*

10 591. ~

22 =293 s.22" -9.77 52.88 3.42- "-755-10 541 21 -

294- 22 -9.84 52.88 3.43 -748 10 591 20 294 -

21 -9.91 52.88 3.43= -"741.

MRX RMPLITUDE ." ""'- -50'RC .."~~ "-""+50'RC OF- T.

ID---'DRC DEP REL X RYrRZ."-- DEP REL X RYrRZ; "DEP REL- X RY~RZ " DEP- SDEP 2 25 59 1.8'0'.1- 44-.3'-.-1.8- 2 44-M" 1;8 ~ . 0.-0'4.3 0.5 27 8 '~

CH:- BET BER IT IR RELX RY/RZ DEP"-" -

10 0 0 271. 0 -4..13'2. 11 SCNR'.17

-4. 18 1319'.

1 0 0 0" 265 15 <<42. 11 10-"1314-1 0 606 7 269 18 -4. 25 42. 11 3. 14-. 1"3 07-.

~

10 606 7 269 20 -

-4.32 42. 11 3. 14- 1300"-

10 611 7 269 =

20 -4.38 42.11 3. 14 -'1294 1 0 0 0 264- 17 -4;.44 42. 11 3. 09- 1288 10 590 15 314. 15 -14.89." 41.77 3.66-:243 10 589 14 304- 14'-14 86. "-'.55--

589- -14.76=

4-1.77'0'. 2.46'3 18 <<303 .1S 41..76- 54's'<<<<s~" 25tF'<<+" '

3. 7 1'" 263

~

10 598" ~

19 318. -14.69'"41.76 .-

0 598 16 318- 30"-14..62- 41. 76 3,,7] ~<<<<<<<<27<<0~*

'98 -6 1 = ~ ~ ~

1 0 " 318: 's"s 31." ; 55 " 41.-76. s 3 ~ (.1<<~<<s<<27~(-'~ o, 10 = 598'--'5s- 322'"25"-14';.49" s"41:.76 .3. -,7g i.w.s283msa~

1 0 598

• 1 1'- -32(-- ~ 1;5'-l4'. 42'4'-1 76. 3" 82<<<< ~290', <<'ss s<<

10'96..- 18" 230 - "18-=<<'-4.P.O'39.56

~

69." 131-2"-".

10 596- -

12 230 . 18" -4';27'9.56 2..69- i 1305'""

10 604<<<<8'2516<<-'-4..33 '9;56 2. 64--" 1299- "

1 0 585 13 293 20 -5. 93 38. 31 3.42 "ls139 1 0 592 13 299 23 -5. 86 38 31 ~ 3..49-. 1 i46 -.

1 0 593 1 0 300 24. -5. 79- 38. 31 3 50

~

-5.72

.1153-'.

10 592 10 30S 15 38.31 60 1160 1 0 589 1 0 278 16 -5. 32 38. 31 3. 25 1200 10 585 .-

11 283 18 . -5.26 .3S.31 3. 31. 1206 V. 22

I PAGE 0009 80 DEC 17 18 AD }7-' SUSQUEHANNA I'ELD BR.

OF 16 CH:-'0 BET BER" IT IR RELX RYiRZ DEP "SCOP,.

589- 9 278 1T -5. 19 38. 32 3e 25 10 S89 10 278 }5 -4. 58 38. 32 3e 25 }274 10 589 10 277 16 -4. 52 38 ~ 33 3 ~ 24 1280 10 589 8=- 281 15 -4. 46 38 33

~ 3. 25'213 28 1286 10 S8S 1 0 291 15 -4. }4. 38 33

~ 3. 40 1318 10 584 ( 275 14 -4. 87 37. 86 3. 21 1245 10 596 7 273 19- -4. 94 37. 86 3. 19 1238 10 596 7 278 24- -5. 01 37. 86 3. 1231 10 596 7 278 25 -5. 08 37. 86 3- 25 1224 10 595 7 277 24 -5. 14 37.86 3- 24. 1218.

ln 595 8 277 22' -5.,2K". .3T. 86 3 24 }2}i1. ~ ~

10 596 8 282 20 --S. 28 3T. 3. 29.= 1-204.

10 596 8- 283 20= -5 34- 85'7.

3.31 -:}.}98 10 287 18 -5. 41 85'T.

85 3 35 ~+} 10 593 7 297 14- -5. 64 37. 85 3 47 1168. 10 0 0~ 299 20. -5. 70 3r.85 3. 49 1. 162:.- 10 0 0 294 16 -5. 78 37. 85 3- 43 1154 10 589 12 298 15 -6. 13 37. 84 3. 48 1}19 10 59S 13 309 18 -6. 20 37. 84 3. 61 1112 10 596 14 310 18 -6. 27 37. 84 3. 62 1105 10 595 15 310 17 -6. 34. 37. 84- 3. 62 1 098 l'1RX RI'1PLITUDE -508 DRC - -"- -'50~ DRC OF 7 t ID-"- iDAC DEP REL X RYiRZ DEP REL X RYiRZ DEP. REL X RYiRZ DEP- SDEP 2 27 54 3. 1 -5. 1 37.8 3.1 -5.1 37 8 3.0 -5.0 37 8

                                                                                                                                  ~  1.0       5 '6.

CH- BET BER IT IR RELX P.YiRZ DEP 10 593 13 285 16 -5. 70 37m 42 3.33 1162 10 599 14 287 24 -5. 64 37. 42 3.35 1168 10 600 }4 288 26 5% 57 37. 42 3.36- }}75

  }0       600            13           288      24- -5. 50               37. 42            3.36- 1182 10       599            13           292      22 -5. 44.               37. 42            3.41 1188 in       599            14=          292      18            -S. 38     37.42                3. 41       1194 NRX A11PLITUDE                                             -508           DRC                         +508   DRC         OF T ID-: rDAC DEP REL X RYiRZ                                      DEP REL X RY/RZ                        DEP REL X RYiRZ        DEP   SDEP.

2 28 56 3.2 -4.6 37.4. 3.2 -4.6 37.4 3.2 -4. 6 37. 4 n.n 48.9 I CH- BET BER IT IR RELX RYrRZ DEP SCOP, 10 590 11 280 15 -4.52 36.98 3. 27 1280

  }0       597            11           292      18            -4.59'- 36 98                   3. 41'273 10      601               9          292     :18 -4.66 -"36.98                              3. 41-.- -1266" 10      601               7          292      13= m. 73 36;9T                               3. 4}- 259" 10          0             0                                 -4; 99 36. 97                   3. 3} - 1233-10          Q, a.~=-=;. Q.     ~

290 18='-5-. Q6 =36 97 3 39 1226.".'- 10 Q

                    '""     Qu         289. 23 "-5. 1$                                    3.38- 1219 10 10 0-7 0'06 290 289" 27" 28   "-5.27'&
                                                              -5:. 20- '6.9r 36 97

3. 39 - 12}2 ~-

3.38- }205 10 602 7 289 -5.33 36.96 3. 38:1-199 =- 10 602 8 289 22 -5. 40 36. 96 3 38 ~ } }92. 10 598 9 289 -5. 46 36-. 96 3. 38 1186 10 598 10 290 16 -5. 54. 36 96

                                                                            ~                 3. 39 1178 le      598            10            294      14 -5. 61                36. 96               3. 43 1}71 10      602              8           290      15              5Q 73    36 96
                                                                            ~                 3. 39 1159 10      602              7           298      16 -5. 80                36. 96               3. 48 1152 10          0             0         298       18 -5. 88                36'5                 3. 48 1 144" V. 23

PRGE'010 OF= 80 DEC 17 18:20--13 SUSQUEHRNNR 'I - Is!ELD BR '! f 6 CH:- BET BER' IT -" IR. RELX .RY>RZ DEP "-- SCAR~' 10 Qi 0. 298 22 -5.97 36. 95 3. 48 1135 10 0 0 298 25 -6.04- 36.95 3. 48 1128 10 0 0 298 23 -6.12 36.95 3. 48 1120 '- 10 602 7 301 17 -6 20 36e95 3. 51 1112. I'1RX RNPLITUDE -50% DRC +50% DRC OF T

-. ID'-- rDRC DEP PEL X RYiRZ . DEP PEL X RY~RZ i~ DEP- PEL X RYrRZ DEP SDEP.

37.0"'.2 1 2 29 57 3.2 -5.3 -5.3 37. 0 .3.2 -5.2 -37.0 0. 0 49;4: 2 30. 51, 3'.3" -6.,0:- 36.9. 3.3. -6. 0 36.9~" "'3.3 -6. 0 36.9 ~

0. 0 49 CH-"'ET>> ~BER '~ -

                                                                                                                 --DER-                 >>SCARE 596>>"""286""-1:?'-' 30" .36.46 IT>><*~-iIR;+"~~RELX-~-RYiRZ.'Q                                                                                                             2'0 3-,34               '1"1       02" 10"         608 --'.7./ 298"-" 26" -'-6 23--'36;47                                                                3    ",48/ <<i.i>>1 09 ii.<<"               ~

1 0 -"- 0 . 0 294" 32. -6. 15 36 ..47 3 43'" 1 1 33" -6; 08' 36. 47 1'7'. 0 - 0 294- ~ 43- 11-124-'" 10 0" "" 0- 29S -'/30" -6. 01 -36.,47 3. 48 -1~1'31:"". 10 600  ?'97 28" -5 93 '36. 47 3. 47- 113'9 10 601 10 601 7 295 7 294. 26 -5 '6 23 -5. 79 36. 47 36.47 3. 45

3. 43 1146/

1153 10 601 7 295 22. -5. 73 36. 47 3 ~ 45 - 1-159-10 298 17 -5.65 36'48 3. 48 1167 0

                             '0  0                                      -
                                                                                                   =

10 - 0 ~ 300 -19. -5..58 36.48 3.50 --1174-10 . - "0-"/-. "0 295'" "23 "--5;51 36.48 3.45-"1181-10 599' 7 29& -'23 -5.44 36 ~ 48 3.46 - 1'188 10 599. 7 296 21 -5. 38 36- ~ 48 3. 46 1194-10 599 7 296 " 21 -5. 32 36. 48 3 46

                                                                                                                        ~                     1200 10 588                         8 289                                          22 -5. 24 36. 48                     3. 38 -1208 10 588                         9 293                                           17 -5. 17, 36. 48                   3.42 --1-215 10 596 10 10 594
           -594:           -

12- 307 8 7 305

                                      -309.                                 '5   17 -'5. 11
                                                                                       " 5.1S 36. 02 15 -5. 24". 36. 02

36. 02 3..58" 1221

3. 61-'= 1214 "

3. 56. 1208'.

10 0 0 305 15 -5. 38 36. 01-3.56 ~ 1194" 10 0= 0--'96 18/. -5. 45 36. Oi 3. 46 <<1187 10 0 0 ': 287 20 -5. 51 36. Oi 3. 35 1181 10 Q

                            --   0-    291                                   -5'.58 36. Oi                      3. 40 1-174.".    -

10 0 0 291 -

20. -5..65 36. 01 3.40- - 1167 10 -

0 0" '287 1'6 . -5.71 36. 01 3.35. -"1161 '-= 10 582 14 326 20 -6. 59 35. 57 3. 80 ~1 073 10 589 13 329 28 -6. 51 35. 57 3. 84 1081 = 10 589 . 12 330' "28 -6. 45 35. 57 - - 3.85'-1087= 10 589 12" 330 -- 25 '-6. 37 .-35'.57 3. 85- "1095-10 - 589' 1 10 10= 0 589" - 589- " '" 11"- -'333 1:1-'" 329'"".-14 301.- :.-16;" -5;36 "595 "~/->>7..'06-'.<20>><'90'-'~35;59

                                                                          .-'20'-6.30-.
                                                                                                    '35.57
                                                                                        -6.'23"-3%. 57
                                                                                                    =35; 59

3. 88 -..+102'i'--

3. 84-.~1109'"

3 ..51 3; 57.'-'1202"" ".".* 1~196.- io 589- ~"-:7: .300Ph~~~-5';23'35;59 -3..50--1209 "'- 10 584' "'-- 300~ --2'-'5.-16---35;.59 . 3.50 "-<<121& -"" 10 585'- " 10 305. - .- 16': *-,5. "35..59

3. 56- -1223-10 584 " 12" 279>> -15/ -5'; 01- 35 59. 3.26 "1231:'.

10 584 12-.'279'- "22" ~.94'5.59 3. 25 -4. 87 35. 59 2'1'238'. 10 5S4. 13 271 17. =1245-1 10 586 13 285 16 -4. 80 35. 60 3. 33 =1 252 10 58 28 278 32 -4. 81 35. 19 3 ~ 25

                                                                                        -4. 89 1251'.

10 587 26 283 36 35. 19 3 1- 1243. 10 587 28 283 39 -4. 97 35. 19 3. 31 1235-10 587 30 283 40 "-5.,04. 35. 19 3. 31 - ~ 1228+ V. 24

p ' UT ~ & O'~~% )0 I'ELD I 0011 80 I}EC 17 18-22=12-t PRGE SUSGUEHRHNR i6 BF}'F CH:- BET BER IT IF} RELX RYiRZ DEP SCNR'- 2 0 588 32 284'6 -5. 11 35. 19 3. 32. 1221

                      }'1RX   RMPLITUDE                                   -Sor. DRC                          +50'FIC                           GF T ID - /DRC DEP PEL                 X RYr'F}Z            DEP- REL X        RYiFIZ            DEP REL X RY>FIZ                    DEP     SDEP 2           31    51      3 2      -48         35 6           3.2      -4.8 35.6                  3.2         -4      ~ 8  35.6        0. 0  48.9 82      3.2      -5. 0 35.2                 3.2      -5.2 35.2                  3.2         -4      ~ 7  35.2        1 ~ 0  48 4
                                                                                                                                                    ~

EVRLURTION PFIRRNETERS VESSEL NODE SCRNNER DINENSIGHS-CRLIBRRTIGN- LENGTH= 36. 00- ~ FULL SCRLE= 3600~~ ~"- VESSEL LENGTH= 30" 00 FUL'L SCFILE= 3000

-'D. UNITS PEP. INCH= 100 00 SCRNNEP.- STEPSIZE = 0.050 STEP TGLERRNCE = 0.020 NINSEP = 0 250 200~ DRC = 100 EVRLURTIGN LEVEL = 50 WELD REFERENCE POINT- X= 737. 82 Y= 126. 50 THICKNESS = 6. S20 SHELL COUPSE 1 CIPCUI'1FERENCE = 836.58 EVRLURTION FINGLES- LRNINRR= 10. 0 HGN-PLRNRR= 10 0 ~

SURFF}CE TGLERRHCE DISTRNCE= 0.0000 PEPORT B.E. DRTR RT FULL BE E. RIP I'1FIXIthUN B E ~DRC FOR EVRLURTIGH =

                        ~                                                       5 UT CHRNNEL DRTR- SCRNNER SEP. FRCTOR                                                 13 ~

CH:-. RNGLE X OFFSET Y OFFSET BEGIN STOP }'1N BE TSEP TSr4R 2 0.0 M 2 ~ 55 0. 00 1200 2150 0 11 0. 00 45.0 T -2. 25 2. 6S 450 2150 0 0. 00 5 60.0 T -1. 05 2,.es 150 225o 0 40 -7. 00

                    -45. 0 P                -5. 45            -   0.60         8SO         1950                    0         - ~

20 0. 00

               ?    -60. 0 P               -5. 45.                1.75         850         1950                    0             20    -6. 00 io            0.0 B              -2. 55               -

0 ~ 00 10 2150 7 11 0~ 00 CH:'BET BER IT IR RELX RYrRZ DEP SCNR 10 589 8 347 10 -2.51 32. 01"

4. 06 1479 1 0 S89- 11 339 28 -2. 44 32. 01 3. 97 1486 1O 596 27 342 27 3. 32 31. 57 3. 99 1398 10 596 20 341 24 -3. 39 31. S7 3. 99 1392 10 596 16 336 19 -3.46 '32.57 3. 94. 1384 10 601 7 343 16 -3.63 31.57 4. 02 "1367 10 602 601 7 342 333 20 -3. 69- 31. 57 22 -3.75 31.57 4'0 ~

2361 10 3. 90 -1355 10 602 338 30'3.82" 31.57 3 ~ 96 1348. 10 10 = 602 602 8

                               \

333 329 =-. 38 -3.90 31

49. -3.98--"32.57

                                                                         '7        3. 90

3. 85 1-340

                                                                                               .1332'--

10 602 7 328" 53"" -4 05 31.57 3. 84- " 1.325 10 602 7 324- 50:" "-4. 12. "31.57 3. 80 ~ 1319 " ~ 10 602 324. 46 -4. 17 31. 5? 3. 80. 23 2-3. 10 597 324 42 -4.24 31.57 3. 80 1306 10 597 7 325 40 -4 30 31.57 3. 81 1300 o 596- 9 324 39- -4.36 31.5? 3. 80 1294 1 io 596 10 596 ll 14 325 329 36 31

                                                       -4.42-
                                                       -4. 49 32. S?

31.57 3. 81

3. 85

                                                                                            " 1288.

1281 10 10 596 596 18 24 329 319 23 18

                                                       -4.55 31
                                                       -4 '0             '7 31.58 3.85

3. 74 1275 1260 10 59S 12 319 20 -4.77 31.58 3. 74. 1253 V. 25

i I t

                                                                                                                  ~m E 0012       80 DEC 17             22-38 34-            SUSQUEHRNNR                  I='MEk D   BR" F    16                                                                                                                  tt CH:    BET       BER         IT        IR     P.ELX       RYiRZ                        -SCNP,.

io 595 8 320 21 -4 ~ 84. 31. 58 3. 75 1246. 10 590 11 320 18 -4.. 91 31 ~ 58 3. 75 1239. 10 582 27 313 31 -4. 92 31. 13 3 ~ 67 1238 ln 581 28 312 38 7a 31. 13 3. 66 1251 10 581 22 308 4a -4. 72 31. 13 3. 61 1258 10 581 16 308 58 -4. 65 31. 13 3. 61 1265 10 582 12 189 14 . 58 31.13 2. 22 1272 10 582 12 308 61 -4. 58 31.13 3. 61 1272 10 585 8 30r 62 -4. 51 31.13 3.60 1279. lo 585 7 307 57 -4, 44 31.13 3.60 1286 10 0 ~ 0 308- 45 -4.38 31.13 3 61 1292-10 ~ '0 p~ 309. ~ 33* '4.31 31.13 3.62" 10 592 f ~ 308 26 -4; 25 31.13 3. 61 1305 '- 10 592 .7 3Oa 23 4. la 31. 13 3. 62. 1'31 1 10 592 7 313 26 ~.

                                            -4.

12 31. 12 3e 67 1318 10 592 7 314 05 31. 12 3. 68 1325 10 592 7 328 -3 a8 31. 12 3. 84 1332 '1299'RX 10 592 7 328 34 -3 a0 31. 12 3. 84. 1340 10 592 7 328 33 3 83~ 31. 12 3 84 1347

                                                                       ~

10 0 324 27 -3. 77 31. 12 3. 80 1353 10 10 592 0 0 0 7 325 317 21 21

                                            -3. 70
                                            -3. 63 31.

31. 12 12 3 '1 3.71 " 1367 1360 10 591 7 307 -3 55~ 31. 12 3.60 1375 10 587 9= 313 28 -3. 49 31. 3. 6 r-" " 1381 10 586 11 316 27 -3. 42 12'1. 12 3. 70 1388 10 586 12 317 22 -3. 36 31. 12 3. 71 1394 10 586 12 321 18 3. 29 31. 12 3r 76 1401 10 587 15 322 17 -3. 23 31. 12 3 77 1407

                                                                       ~

RMPL I TUDE= =" -50<. DRC '- ~--- +-50K DRC r.OFT ID-- rDRC DEP REL X RY/RZ DEP REL X PYiRZ DEP" REL X RYiRZ DEP 2 33 84 3.7 -4. 0 31.6 -4.5 31.6 -3. 9 31. 6 SDEP-'. 3.8 0 41.5" 8a 3.6 -4.5 31. 1 3.7 -4.8 31. 1 3.7 -4 3 31. 1

                                                                                                     ~        0.5    43. 4 51    3.8        -3.9 31.        1       3.8     -3.9 31. 1                    3.8 -3. 9 31. 1   0~ 0   42. 0 CH:-   BET       BER        IT         IR     RELX        RY>RZ      DEP               SCNR-1O    585        22-   303                  -3. 07       30. 70                          1423 10    591        13    308                  -3. 15       30. 71     3 ~ 61               1415 10    592        10    3 09.          30    -3. 22       30. 71     3-62                 1408 10    592          8   309            34    -3. 28

30. 71 3 ~ 62 1402 10 592 7 309. 34. -3. 35 30 ~ 71 3 ~ 62 1395 10 593 8 309 33 -3. 4-1 30 71 3. 62 1389" 10 593 8 3 09- 30 -3 48 30. 71 3.62 "1-382 10 5a3 8 313 25 3e 55 30. 71 3. 67- 13r5 10 593 8 313 "- 24'3. 62 30. 71 3. 67-= ""&368 in 593 8 323 28 ~" -3. 69- .30. 71 3- 7.8 ~*" 1361..

10 593 8- 323 29"'"~ 76. 30. 72 3 78 ~ 1.354. 10 593 9:- 3i23 .- 26 "-3.82 30 r2 3- 78348 10 593 10* 20 -- 3.89. 30. 72 3. 78 134 i. 10 10 593 584-li 15 323'23'02 14. -3 97 15 3. 78 30 72

30. 33

3. 78 3 54

                                                                      ~

1333 1352 io 580 14 313 22 3 33

                                                ~        30. 32     3. 67   .          1397 20 -3. 27 (4v 10    580        13 313

30. 32 3. 67 1403 10 584- 10 313 20 -3 20 ~ 30. 32 3. 67 1410 10 583 12 313 18 -3. 13 30. 32 3. 67 1417 10 584 15 314. 17 -3. 05 30. 32 3 ~ 68 1425 V. 26

lt t PAGE 0013 LAMINAR CH:- 2 2 16 80 DEC 17 INRR ll 11 22:40-51 INDICRTIONS JOINING PLANAR

                        - PLANAR:-

f2 15 I D SPOS SUSQUEHANNA. IT ION INDICATIONS'RI'1 I IrjEf D BR-FINRL EYFILURTION TRBLE CH TYPE IND- T t1 INX I1RXX I ] INY I'1RXY'l'1 IN DMRX VRLUE RLLOlJ EVFIL 2 OM 33 S,"I 733. 03 733.92 157.62 158. 07 3.63 3.83 1. 53 2i 68

1. 53 3. 43 OM 30 S Y 731. 78 731. 78- f 6 3. 45 163. 45 3.. 32 3. 32 0. 01 6. 51 OM 27 S X 732.68 73B.Sf- 164.36 f 64; 36~ -." 3 02 3. 10= 0. 64. 4. 32 2 'M-*-.-"24 S X- 733. 05 733..19" 180.. 90 180.90 '"2.25 2; 30" "0.37 ~

3. 06. ""

                                                                                                                           ~

2 19 S X 735.21 735. 54. 1 96. 61 196. 62 2. 97 3. 08 0. 81 2.98-

                                                                                  '2 '2 OM 2 . OM       15 S Y 736.40 736. 40 198. 40 198.40                                             i2 e 3i2  0. Oi     6. 51 S N 734.64 734.85 198.42 198. 84.                                 2. 19      2. 30     0. 82-    3.72 t                                              I~                        0. SB     2.78 OM         S N   736.86 738.      00-   199. 65 201. 46                   . 1. 92      2. 32     3. 05     3. 08 3 05
                                                                                                            ~       2. 67    ++++

OW S N 734. 18 734.64 201 98 202.40 2. 05 2. 18 1. 00 2 ~ 86

1. 00 2. 95 2 OM 3 S X 733.39 733.45 216.45 216. 45 2. 76 2. 87 0. 81 6. 51 2 OM 31 L 732.64 733. 08 161.69 162. 09. =3. 16 3. 21 0. 18 12. 60 2 OM 28 L 732.49 733-23 163.4& 163. 94- 3. 18 3a 22 0. 35 f2.60 OW 25 L 737.64 737. 79- 170. 77 170. 78 "f.83 1'. 84 0. 00 12. 60 OM 23 L 734..42 734.55 183.75 183. 75 2 25

                                                                                       ~        2. 25     0. 00    12. 60 OIAI    22     L 732.14- 732.62 184.21 184.21                                 3 37       3. 43     0. 00    12. 60 OW     21     L  735.95 736.22 191.11 191.12                                 2. 74. 2. 76     0. 00    12. 60 OlJ    20     L 733. 8 1 734.43 196.62 196.62                                2. 81      2. 87     0. 00    12. 60 OlJ     6     L 733.92 737.98 197.50 201 51                         ~        1. 96      2. 35    16. 28    12. 60 2'    OW      4     L 737. 03 737. 17 2i 0. 42 21 0. 42                            Be  59     2 59
                                                                                                   ~      0. 00    12. 60 OM      2     L 733.27 733.73 217.88 217. 89                                 3.96       3. 9S     0. 00    12. 60          'I 2     OM      1     L 737 29- 737.44 218.97 218. 98
                               ~
                                                                                   ~

1. 67 1. 69 0. 00 12. 60 10 34 L 733.44 734.12 157.62 157.63 3. 61 3. 81 0. 00 12. 60 10 10 OB OB OB 32 26 L 731.67 732.83 162.51 164 L 733.38 733.69 168.61 les.el

                                                                            '5       3. 31

3. 09

3. 56 3 17

                                                                                                   ~

2. 14

0. 00

12. 60

12. 60 10 OB 18 L 734.92 735.71 198.42 199. 24. 2. 35 2. 59 0. 65 12. 60 10 OB 10 L 737. 28 738. 07 199.65 201. 46 2. 08 2. 44 f.43 12. 60 END OF PRSS V. 27

PAGE 001+ 80 DEC 1? 22-52-06 SUSQUEHANNA. I WELD BFI. GF 'f 6 INDICATION REPORT= CURRENT BR -0008 UT CHRNNEL 2 0 W INDICRTIGN '-'= 8 CLASSIFICATION- SUB-SURFRCE NON-PLRNRR CHARACTER- (X) ELL IPTICFIL (Y) ELLIPTICRL LOCATION= ' ' MINX =. 736.86 MRXX = 738. 00

     - -'~ MINY =" 199. 65                 MRXY =    201. 46 MINDEP =             1.92      MRXDEP    =     2.32 EVRLURTI ON =

RXIS R L RiL RiTi FILLOM LGM HIGH (X) 0.20 1. 1+ 0. 17 3. 05 3. 08 (0. 15 2.91) (0.20,3.25) NQ FURTHER EVRLURTIGN NECESSARY (Y). 0 20, =

1. 81 0 1 1 3'5 2. 67 (0. 1 0r 2 61) (0 15r 2 91)-~

 +++INDICATION REQUIRES FUPTHER EVRLURTION+++-

INDICRTION REPORT HISTORIC BR -0008 UT CHRNNEL 2 0 M INDICRTIGN:-= 8 CLRSSIFICRTION- SUB-SUPFRCE- NGN-PLANAR CHRRRCTER: (X) ELLIPTICRL (Y) ELL IPT I CRL LQCRTI QN =- MINX = 736. 86 MRXX = 738. 00 MINY = 199.65 MRXY = 201. 46

         '- MINDEP =             1 92      MRXDEP    =     2. 32 EVRLURT ION-RXIS           R            L     Rr'L    R/TR                     LQM              I GH.
                                           '3'5      RE.LQW
               =                                                          - =-

H (X>-.20 = 1 f4 "0 17 ""'3. 08 (0 ~ 15r-2 91) (0.-20r3 25) HO'FURTHER EVAN URTIGN .NECESSRRY (Y)'.20 1. 8'1 0. 1'1 3. 05 2~ 67'0. 10r2-.61) (0. 15r 2.91)

 +~INDICATION REQUIRES                     FURTHEP. EVALUATION~~

COMMENTS: V. 28

PAGE 0015 80 DEC 17 22=52 -06 SUSQUEHRNNR- I WELD BRI OF i6 IHDI CRT ION REPOPT- CURPEHT BR -0006 UT CHRNNEL 2 0 W IHDICRTIOH:-'= 6 CLRSSIFICRTIOH- LAMINAR CHRPRCTEP.- LRMIHRR LGCRT I GH-.

             'MINX.   ='33   92'     . MRXX. =* 737. 98
     -=:: '-"MIHY = 197.50
                    ~

MRXY = 201.5'1 HIHDEP. = 1 96 MRXDEP. = 2..35+ EVRLUFlT ION = LX LY RECT RREA FILLOW

4. 06 4. 01 16. 28 16. 28 12. 60

   +++IHDICRTIOH REQUIRES FUPTHER EVALUATION+++.

INDICRT ION: REPORT- HISTORIC BR. -0006 UT CHRNNEL 2 0 Ii! IHDICRTION -:= 6 CLFISS IF I CRT ION: LRM I NAP. CHRPRCTER: LRMINRR LGCRTIGN-MIHX = 733 ~ 92 I'1RXX = 737.98 M INY = 197. 50 MRXY = 201.51 MINDEP = 1. 96 I'1FIXDEP = 2. 35+. EVRLUATI GH-LX LY RECT RRER FILLOW 4; 06- +. 01 16.28 16.28 12.60

   +VINDICATION REQUIRES               FURTHER     EVALUATION~

'I COMMENTS= V. 29

0 e

MI ~ t PRGE'01'6 80 DEC 17 22-'52=06 SUSQUEHRNNR I WELD. BRt QF )6 BEGIN UT INSPECTION RND CRRMLER tlOTIGN SEQUENCE EVRLURTIGN LEVEL = 50/ DRC MELD BR CH:: BET BER IR RELY RYiRZ DEP SCNR 10 588 1O 190 21 -0. 41 32 08

                                                          ~     2. 24    1770 10     587      10      190      24 -0. 47           32. 09    2. 24   1776 10     581      10      190            -0. 51        32. 09    2. 24. 1780 10     577      12      194      17 -0. 58           32. 10   i2e 28   1787 10    582      21      296      35 -4. 06           32. 79   3. 47    2135 10- -583       23'3    301   =. 38 -4" 02.          32.78    3.-53 '2131 10    583              301            -3. 94        32; 78   3. 53. 2422 io 583                 301               3% 87      32 77
                                                          ~     3.53 2115 10    582      26      301      48 -3.       80'r

32. 77 3. 53 2108 10 582 28 306 49 73 32. 76 3. 59 2101 10 582 30 306 49 -3. 66 32. 76 3. 59.

10 582 30 306 48 3e 58 32. 75 3. 59 2086 lo 581 30 306 44 -3. 50 32. 75 3. 59. 2078 10 582 33 307 45 3% 43 32. 74 3. 60 2071 10 582 37 307 41 3e 37 32. 74 3. 60 2065 10 586 10 307 17 -3. 77 33. 20 3. 60 21 06 10 586 11 304 20 -3. 81 33. 20 3e 2'1 1 0

                                         -3 88 56'.

10 586 10 299 33. 21 50 21 17 10 587 299. 18 -3. 95 33. 2-1 3. 50 2124-10 591 7 308 17 -4. 02 33 ~ 22 3. 61 2131 10 591 7 308 17 -4 0< 33 22

                                                          ~     3. 61    2138 10    596        7 332          15    -4. 17        33. 23   3. 89    2146 10    601        7 332          16    -4. 26        33 23
                                                          ~     3 ~ 89   2155 10    598        7- 338               -4. 18        33. 66   3. 96 10    601        7 337          24.   -4. 11        33. 66   3. 95    2.1 40 10    601        7 333          22    -4. 03        33. 65   3. 90    2132 10    601        7 342          18    -3. 97        33. 65   4. 00    2125 10    595        8 328          14    -3. 85        33. 64. 3. 84    2113 10    595      12 328           17    -3. 78        33. 64   3. 84. 2106 io    595      10 339           19.   -3. 60        34. 63   3. 97    2088 10    595        9 338                -3. 56        34. 62   3. 96    2 084-10    595      10 338           21    -3. 48        34 62
                                                          ~     3. 96-   2076 10    595      12 338           20    -3. 41        34. 61   3. 96    2069 10    595      19 338           19    -3. 34        34. 61   3. 96    2062 10     583      13 338           15       2 ~ 8i2    35. 04   3. 96    2010 10     583      10 342           15       2 ~ 83     35. 04   4. 00    2011 10     583                       16    -2. 91        35. 05   4. 00    2019.

10 583 341 17 M. 99 35. 05 3. 99. CH-'= BET'ER. IR. -P.ELK

                                          .          =

RYiRZ DEP SCNR" 10 581'- " 12 =233 " 26'4 -0,88 85. 13 2 7+ 1816-. 10 580'- 12 " 233 -0. 62 85. 11 2. 74. 1-790 1O Ser - 13 240 -0; 57 85. 11 i2 82 1785 10 586 14 239 24. -0. 51 85. 11 2. 81 1779" 1 0 586- 398 17 -2. 81 85. 73 4 ~ 66 2009" END OF PRSS

 +NOTE- BR-3           (PRGE   19      80 DEC 17         23-56-15)

v. 30

SUSQUEHANNA I lJELD BA

   ~e
   .e NC<     B.1BB XNi 731 7 NXi 738.1 VIOL 157.6 Y'Ixi 219+e Zei     i.'7 znx-    <.e

l SUSQUEHANNA I UELD BA

                           ~ ~

1 %90

 + ~90 IIAe-   0.1ee NII~  731 7 XIIX>> 73&.1 VPS~ 167,6 YtlX~ 219+0 ZNHi    1 7 zIIxi   4 e

0

CATEGORY 8-A (Continued)

           * 'ee note          BD-3
          ** Indication           8     required further evaluation: A manual examination was performed in the area of concern.                        The one indication recorded automatically was found to be two indications when examined manually.

The reason for this is the stepping motion of the automatic scan-ning devi'ce. The calculations per ASME Code Section XI paragraph IWB-3510 including Winter 1975 Addenda are as follows: Indication 8: Allowed 81 2a = .2 a 0 1 a

                                                             ='
                                                                 .1 1.00
                                                                        = 0.10           2. 61K a

a2

                  =    .85                           g           .85     0.12 2                                 2.73$

t. = 6.52 apt = 1.53% = value 82 2a = 0 a=o

                                                                 .1
                                                                .65
                                                                     = 012 1
                     .65                                   =

0 1.1

                                                                       = 0 Allowed
                 =   1.1 a             .0                     2.32K 0

6.52 V. 33

                           ~ V  4h \ .8 0 I I  ~

• f

I i

     ~

E '

Indications 1 8 2 Combined Allowed 2a = .3 a = .15 a = .15 = .08 z 1 .19

          =   1.9 1

a2 1'3 a .15 = .12 ) 2.73K a2 1'3 t = 6.52 a .15 2 3'5 Value 2 2.3X The data and calibration sheets used for this examination are

                                                                                      'ttached.

• • Indication II6 as evaluated by the computer requires further. evaluation.

However, the computer does not include paragraph IWB-3360 in its calcu-lations. When paragraph IWB-3360 is used, the area is reduced to 12.21 square inches in area rather than the 16.28 square inches shown. This

  . is less than the maximum acceptable limit 'allowed by code. None of the laminar indications were evaluated in accordance with paragraph IWB-3360.

Since none of the laminar indications require further evaluation (with the exception of indication 86 as discussed above) and all are still within acceptable limits of section XI, no further calculations are deemed necessary.

• • The evaluation of laminar indication 811 joining planar indication 812 is as follows:

Allowed a = .1 a .1 .059 2.425

                                     ~l   1.8
            =    1.8 gl a      .1
                                                         .056                  2.42/o 1.8                   2  1.8 2

a .1 1.53K t 6.52 V. 34

** The evaluation of laminar indication     811  joinin'g planar indication >15 is  as  follows:

Allowed a = .1 a

                                        .059                    2.42K gl    17 1.7 1
                                .1 a2   = 1.8                        =   .056                   2.42/o 1.8
                              .1   =   1.53K 6.52

• • • See note BJ-3 V. 35

I 1 l 1

6 EHEIIAL iQr,-'.ELECTIIIC 21A3BOOA8 NUC1.EAR ENERGY DIVISION REV.NO. 1 MffT cf0 'le UT CALIGRATlOMOATA Sl 'EKT Cd. Shoat No. uS OC l Frees we a)o C ~ l/V'L e. o atone ~~ ~ Praoyerationd Cd, Std. Tcrnt). C31.5.1..

                                                                                                               ~O Root)rt)ar r

f~c Ceca: Cnacnuncnt CAodef )fc). tccscrtyscn c feraca acre. LlHc o9/Z.8 It W 1 Caarn AOC)e OACC~) ~0-5 0 't0 j.lncwÃnenc ~ct)nCS:

                                                                                                        $ att    Fin sa At)moat)on Srotet)

Oc)ac nanny G+n fw)vatin)I Gan Frltor Poc) )ion Aeg Rcte Carnthny RC)KC 0 1 4 4 tc

                                                                                          ~am~  (                <l           X Can        ceca.      "W          Oor MP      SOH Ihthcc

1) )x Arne. I ha',s )Ore) F o)f Pcf lode C. Kaa Lect 1X 0 3W,p5 5 Octa 5hcct 3,z 1X g5 Q Q g 1X 1X rCIA CcCEaet)on ~l Ceotn IOI Q or Llctsl petn tarp) Q Fkgu:w 6a. SAVILE CALIBRATI(N OATA SHEET V. 36

Q,gL ~HI + 5/tg oo( GEi/ER/ILQsa ELEcTRIc PJV C LEAR ENERGY ON(SlOM OOCVMEXT NO. 2]A3BOOAB REV. NO. ] HEE'O. 21 EO~ I~ Ange Caarn Sorted once ~ Trartinc Ray cshbrattd

                                                      <  IX tylltrrl 45            or Cahbr at<on llandard corno>net>onl I.irene   Ray IC% OAC         25'4 OAC         SOta OAC          t~    OAC        50'0 OAC            25>>. OAC         10% OAC 0 or       y/     0 or                                 0 or                   0 or I/IF               Mir                                  MF                     ~

dr 1/4T

               ~erSt       I necnty Qtecb                                                         Control Lrneanty ILtsde Oarlyl                                                                 IEhde Oartyl 1~SR            0    % Frk .A%r5H         7>         %t  M HWFSrt                         4b      132-tSI V(I lra       /g     06 24l
                                                                                                        ~ 8>              <>>-se
                                                                                                       >>1  ~         Q

32. ISC-961'aw

p. Octa For Qneonty An~ Oeam

                                ~tra
                                                                                                 ~        cn II y/.2 Cfoctt on I/8- SOH tor Fserd Caleb Owckt. te Mac Amo. tor Born Near h Far Cocle Olocit T Fotiticna in % Screen rteignt Traducer Octa C

cr lz~ I /e S Ore Near Far Rowrreeed by Sre T.TC I.~ Fig" o 6b. SRMPLE CALIBRATIOH OATA SHEET V. 37

EE((ERAtELECTRIC ENERGY DIVlSlON 'UCLEAR ('~MENTNO. 21A3800AB REV. NO 1 SHEET NO. P3 1P~EL EXAtst (NATION OATA SHEET Cet. Stseec No. I Properecionel Oece

\".e(d Seetn (O No.
~re         Nrh Rloor der Oesm An(F ~ 0 RM  stoic
                                                                                            ~         45 60's Ran Scnsiovicy               d4         =      m    X                   E    ~conS~.,                                        /x Cost plane Con c wst rars    CWor CCW OAC   Wt               Wm    WF2      W2              Ot    OFI         Om    OF2      02         or'oot

( I /2 (50se (MIa (1/2 (II2 (50% (Mex (5QW (1 I 2 Transverse ~ oo or OACI OACI ACI IP< a I Mexl Meal OACI OACI hex x) Or Pcreoet SOOOns Meal E 3, Dd 3 5

                                     /,3 REFLECTOR PARALLEL (PI                                    Reterence System                  REFLECTOR TRANSVERSE TOIVELO                                                                                     (Tl TO WELD Looxine down on          ee.ses CW is co ngnc ot seesd end CCW rs co (etc ot       md Too is coo need er4 ot vessel MAX W2
                            *X     1    WO LO 5'4T-TC Leer(

Figure 8. SAMPLE EX$1IIIATI0l) CATA SHEET V. 38

I

  ~

I

  ~

I

GENERRL ELECTRIC POST PROCESSOR- VERSION 3 REV ~ 2 SUSQUEHANNA. I MELD BC EVRLURTIGN LEVEL = 50'RC TRBLE 1MB-351 0 RLLGWRBLE PLRNRR INDICRTIGNS RSPECT SURFRCE SUBSURFACE RRTIO INDICRTIONS INDICRTIONS RrL Rr'Tr t R/T~ 8

0. 00 1. 88 2. ~ -32

0. 05 2 00 -

2,. 42.

0. 10

0. 15

0. 20

0. 25

0. 30 2.7f'.

2 i8 2 42 3.. 08 3.48

2. 61.

2. 91 3.68

4. 13 25 0~ 35 3. 48 4. 63

0. 40 3. 48 5. 24

0. 45 3. 48 5 ~ 86

0. 50 3.48 6. 51 TRBLE IMB-351 0 2~

RLLOWRBLE LRMINRR IHDICRTIONS COMPONENT THICKNESS LRMINRR RRER. T~ IN. R~- SQ IN 0 10 6 10 8 20 10 30 12 40 EVAN URTION PFIRRMETERS-VESSEL MODE SCRNNER DIMENSIONS= CALIBRATION LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE= 3000 OD ~ UHITS PEP. INCH= 100. 00 SCRNNER STEPSIZE = 0. 050 STEP TOLERANCE = 0. 020 MINSEP = 0.250 100/ DRC = 100 EVRI URTIGN LEVEL = 50 MELD,REFERENCE POINT- R= 458.96 Y= 126.50 THICKNESS = 6.520 SHELL COURSE 1 CIRCUMFERENCE = 836.58 EVRLURTIGH FINGER ES = LRMIHRR= 1 0. 0 NON-PLRHRR= 1 0. 0 SURFRCE TOLERANCE DISTRHCE= 0 0000 PEPGRT'.E DRTR RT FULL B.E. RMP MAXIMUM'.E. RDFIC FGR EVRLURTION = 5 UT CHRHNEL DRTR- SCRNNER. SEP; FRCTOR = 13 CH RNGLE OFFSET Y OFFSET BEGIN STOP MN BE TSEP- T5/4R

2. 0.0 \J -2.55 0. 00 1200 2150 0 11 0. 00 4 45.0 T -2.25 2. 65 450 2150 0 28 0. 00~

5 60.0 T -1 05

                               ~                2.65       150     2150     0   40  -7.00l
         -45. 0 P          -5. 45              0. 60      850     1950     0   20   0.
                            -5. 45                                                  -6. 00 00'0 7   -60 ~ 0 P                              1. 75      850     1950     0 0.0 B            2 ~ 55             0. 00              2150     7        0-00
                                                                                             '1 10                                                        10                                 I, V. 39

PAGE 0002 SO DEC 17'9:40-19 SUSQUEHRNNR I WELD BC GF'8 BEGIN UT INSPECTION RND CRAWLER MOTION SEQUENCE EVRLURTIGN LEVEL = 50'RC 'ELD BC CH:- BET BEF} IT IR RELY RYrRZ DEP SCNR 10 593 16 364 18 -2. 01 80. 59 4.24 1932 10 602 10 457 17 -2. 06 81. 44 5r 32 1937 10 600 S 453 15 -1. 99 81. 45 5. 27 1930 10 584 14 448 15 -2. 39 =82. 85 5. 22 1970 MRX AMPLITUDE -50'RC +50/'RC OF T ID.= iDRC DEP REL X RY/RZ DEP REL X RY/RZ DEP REL X RYiRZ DEP- SDEP 2 1 5? 5'. 1 -2. 0 81.4- 5'.2 -P 0

                                                             -2. 1 82.9.

81.4 5. 1 -2.1 81.,4 l. 0 20. 9-

52. 5 1 -2.2. 81 9 5. 2 5. 0 -2.3 82.8 0 5 22. 4.

CH:- BET BER IT IR RELX RY/RZ DEP SCNR 10 580 7 413 17 -1.56 84. 05 4. 81 1887 10 580 8 414 16 -1.58 84. 05 4.. SP 1889 10 581 7 414 18 -1.71 84. 03 4. 82 1902 10 581 7 413 23 -1.78 84. 02, 4. 81 1909 10 SSO 7 409 24 -1. 84 84. 02 4. 76 1915 10 591 7 408 -1.90 84. 02 4. 75 1921 10 586 10 402 28 96 84. 00 4. 68 19PS 10 5S6 11 41i 24 -2. 03 83.99 4,79 1935 1 0 582 14 42P 21 -2. 21 83 98 4. 80 1943 1 0 582 12 415 17 -2. 18 83.97 4. 83 1950 MRX RMPLITUDE -50'. DRC +50'RC OF T I3:- >DRC DEP REE X RY/RZ, DEP. REL X RYiRZ DEP PEL X RYiRZ DEP SDEP i

2. 2 79 4.? -1. 9 84. 0 4.7 -1.8 84 0 4-. 7 -2. 1 84. 0 0. 0 27 6 2 . 3 76 4.4 -1.1 91.1, 4.4 -1. 0 91.P 4.4 -1.4 91. 1 1.0 31. 9 CH:: BET BER IT IR RELX RYiRZ DEP SCNR 10 575 17 186 20 -0. 51 1 05. 53 2. 19 1781 10 579 10 186 20 -0. 58 1 05. 53 2. 29 1788 10 579 7 28> 16 -0 65 10553 2 PO 1795 MRX RMPLITUDE -50'. DRC +50'. DRC OF T ID:- RDRC DEP REL X RY/AZ DER REL X RY/RZ DEP REL X RY/RZ DEP SDEP 2 4 51 2.1 -0 5 105 5 P. l. -0 5 105.5 2. -0.5 105.5 1.9 30. 2 2,5 51

                                   ~

5.0 -0 7 106 2. 5. 0 -0.7" 106.2. 5. 0 0 -0.7 206.2 0. 0 23. 8 CH-= 1 0 1 0 BET 573'.5 574 BER-15 IT 252. 25P IA-25'1RELX 25 67

                                            -1.. ?P, 106 1

67'. 95 RYiRZ.

06. 6?

DEP 2-.95 SCNR 1896-1902 I'1RX FIMPLITUDE -508 DRC +50'. DRC r. GFT ID--- rDRC DEP .REL X RYzRZ DEP REL X RYiRZ DEP- REL X RYiRZ DEP SDEP 2 6 84 2.7 -0.6 106.7 1.7 -0 ~ 5 106.7 -0.9 206.7 0. 5 25. 4. CH:: BET BER IT IR RELX RYiRZ DEP SCNR 10 582 12 310 18 -1.34 108.68 3. 62 1863 10 581 12 313 18 -2.39 208.68 3. 65 1868 10 585 12 309 21 -1.46 108.67 3. 61. 1875 10 586 10 309 29 -1.55 108.67 3. 61 1884-10 586  ?' 09. 41 -1.62. 2.0S 67 3 61 1892 V. 40

Z. tV t PRGE 0003 80 DEC 17 10-02-50 SUSQUEHRNNR- I MELD BC OP pe k CH:: BET BER IT IR PELX RYrRZ DEP SCl'lR 10 586 7 305 53 -1. 68 108 67 3..56 1897 10 586 9 305 61 -1. 73 108. 67" 3. 56 1902 10 582 1S 305 63 -1. 80 1 08. 6.7 3. 56 1909 10 581 27 309 59 -1 . 87 108. 67 3. 61 1916 10 581 33 309 50 -2. 95 208. 66 3. 61 1924 10 581 36 310 39 -2. 02 108.66 3.62 1931 NRX RNPLITUDE -508 DRC +50'RC OF T ID:- iDFIC DEP REL X RYiRZ DEP REL X RYiRZ DEP REL X RYiRZ DEP SDEP 2 7 128 3.5. -1.8 1.08.? 3.5 -1.5 108.7 3. 6 -2. 2 108. 7 2.0 44, 9 CH-= BET BE& 'T- IR" 'ELX. RYiRZ DEP SCAR" 1 0 585 36 250 3?" -3 3'i 209; 98 2 92 2060 10 588 24 250 - 29- 2i 209..99 2,. 92. 2.050 10 588 22 251 P3 -3..06 109. 99- 2 94 2035 NRX RNPLITUDE -50'. DRC +50'FIC OF T Js I DJL r.DRC DEP REL X RYiRZ DEP REL X RYiRZ DEP REL X'Y/RZ DEP SDEP P 8 55 2~ 7 -3.9 110. 0 2.7 -3.9 110. 0 2 7 -4. 2 110. 0 0. 0 41.7 84 2.7 -3.3 120. 2.7 -3. 0 110. 0 2.7 -3 5 210. 0 0. 0 41.7-2 2 10 11 65 83 2. 2.8 7'4. -2..8 0 11 Q. 7 113. i. 0 2.7 2.8

                                                                            -3.9 110.7
                                                                            -2 7 113.1
                                                                                                         ~

2.7 -4. 1 110. 7 2.8 -3. 0 113. 1

0. 0

0. 0 40 7 43..1

                                                                                                                                      ~

I CH:- BET BER IT IR- RELX RYiRZ'4. DEP SCAR 10 591 10 244 78 24 113. 91 2.8& 2148 10 592 20 473 18 -4. 24- 113.91 5. 50 2248 10 594 S 243 SS -4. 07 113. 91 2. 84. 2242 10 594 8 473 2P -4. 07 113..92 5. 50 2141 10 600 7 244. 93 -4. 00 113..91 2. 86 2134. 10 600 464 23 -4. 00 113.,91 5'0 2134. 10 7 7'05

                                  '244         93    -3.92; 113.91                2.86      2126 10      605        7       469          24-   -3. 92 113. 91               5. 46     2126 10      601               244           94. 3.85'13.91                  2. 86     2119
     -10                  7 7'01 470          24-   -3.85 113.91                 5. 47     21!9 10      606        7      244-        1 04-   -3.77 123.91                 2.86      2111 10      606        7      470           26    -3.77 213..91                5. 47     2111 10      681        7      2.43   ~

11 0 -3.69 113.91 2. 84. 21 03 10 6'81 7 469 P& -3.69 123.91 5. 46 2103 10 682 244- 1 06 -3..6P= 113.91 2.86 209& 10 7'82 7 474- 22 3.62 223.91 5. 51 2.096 10 592 7 243 9P -3 54-'23 91 2. 84. 2088 10 592 7 469 17 -3.54- ii3 91 5..46 208S 10 589- 7 244- 62 -3.47'13 91 P 86- 2081 10 588 S 244 38. -3 40 113.91. P.. 86. 2074-10 588 P48 1'. -3 34- 113 9.1 2 90 2-068 2 22 82 5' NRX FIMPLITUDE ID-" RDRC DEP. REL. X

                                      -3.-8 1.23.

RYiRZ 9'50'. DEP REL X 5;3 -3.5'23 DRC'. RYiRZ

                                                                                         .9    5 3
                                                                                                    +508 DEP REL X
                                                                                                      -4   1 DRC RYiRZ 123 9 DEP

0. 0 OF T v'DEP::

18.5H:- BET BER- IT IR RELX RYrRZ DEP- SCAR 10 579 23 164 26 -1. 08 114 34- 1. 93 2842 1'0 579 25 164 26 -1. 15 114. 34 1. 93 1849 10 579 34 248 3 ~ 87 114.34 2. 90 2121 20 579 29 248 54 -3 ~ 93 214.34 2. 90 2127 10 583 PS 248 58 . 01 114 34 2 90 2135

l

17'0- 1&-53 t PF}GE 0004 80 DEC SUSQUEHF}NNR I WELD BC OF O8

 'CH-'. BET'ER.               IT       IR       RELX       RYiRZ      DEP. SCNR 1  0    584       28        248        61     -4. 08 114.34           2a 90   2142 1  0    580      30         2.48       63     -4. 26 114. 34          2. 90   2150 MRX       RMPLITUDE                              -50'. DF}C                   +50'. DRC           OF T ID:- iDRC DEP REL              X   RYrRZ          DEP'EL X RY/RZ              DEP PEL X RY>RZ         DEP     SDEP 13    68         1.8     -2.1     114 3          2.8 -1. 0 114.3            1  ~ 9    -1 2 114.3
                                                                                                     ~           1.4   27a3 2       14    58        5 6      -4 1     114 3         5. 6 -4. 1 114. 3           5.6       -4; 1 114.3    0.0    14. 2 CH:-

10 BET 594 BER-15 IT'R 250 1 i8 PELX

                                                   -4. 14.

RYrRZ ii4. 79 DEP

2. 92.

SCNR 2148-1 0 594 497 25 -4. 14. 114. 79 5a fS 22 48 lb -4 08 224 79 15'0 591 259- 123 3. 03 2242 10 592 16 497 22 -4.. 08 114.79 5. 78 2142 10 59i 18 259 106 -4. 00 214 79 3. 03 2234 10 591 18 492 20 -4. 00 114 79. 5a 72. 2134 10 590 20 254 98 -3. 92 224. 74 3. 03 222& 10 590 22 259 S7 -3 85 114. 79

                                                        ~                 3. 03   21 19.

10 589 26 259 70 -3. 7S 114. 79 3. 03 2112 10 590 30 259 57 -3. 70 114.79 3. 03 2104 10 10 589 573 32. 32 259 263 42 31

                                                   -3. 63 114
                                                   -3. 56 114. 79
                                                                   '9     3. 03 3., 08 2097 2090 MRX        RMPLITUDE                             -50'. DRC                    +50<. DRC             OF T ID:-  RDF}C DEP          REL X RYrRZ              DEP REL X RYiRZ            DEP PEL X         RYiRZ  DEP    SDEP 2      15 159           2a8     -4. 0    113. 5         2.7     -3.8 113.5         2.8       -4. 2 113. 5 0~ 5   41. 7 211         2.6     -3.7     113. 9         2. 7    -3. 3 113. 9       2.6       -4. 1 113. 9 1.0 40. 3 140         2.8     -4.2     114. 3         2. 9    -3. 7 124. 3       2.8       -4. 1 114.3    2. 4. 42. 2 214-        2. 8    -4. 1    1 1.4=8.       2.8 -3.5 1,24.8            2 8       -4. 1, 114.,8  0.5 43..1 CH::       BET     BER-          IT      IR       P.ELX       RYrRZ     DEP     SCNR.

1 0 586 36 261 38 -3. 87 227.20 3. 05 21? 1. 1 0 582 33 267 39 -3. 93 117.20 3. 12, 21?7 1 0 583 28 2&c 34. -4. 01 i17.20 3. 12. 2235 1 0 583 23 270 ?6 -4. 10 117.20 3.16 2144-1 0 586 20 262. 2i -4. 19. 117.20 3. 05 2153 10 602 8 271 4.2 -4. 15 117.68 3. 17 2149 10 592 7 27? 42 -4. 04 117.68 3. 18 2143 10 591 9 272. 38 -4. 01 117'.68 3. 18 2235 10 591 13 267 33 -3 ..94 117'.68 3. 12 21?8 1 0 591 17'7& 28 -3. 86 217.68 3. 23 2120 1 0 596 15 278 17 -2. 98 117. 69. 3a 25 203? 2 0 593 16 279. 19 . ~ 91 117.69 3. 2& 2.025 MRX RMPLITUDE -508 DF}C +50'RC OF T ID-- RDF}C DEP REL X RY/RZ'EP REL X RY/RZ DEP REL X RY/RZ DEP SDEP. 16 84 3. 1 -3.9" i27 2. 3. 1 -3.7 117.2 3. 1- -4. 1 117.2 0 5 47., 0 9& 3. 0 -4. 1 117.7 3. 0 -3.8 117.7 3. 0 -4' 117. 7 0.0 46. 0 CH:: BET BER IT IF} RELX RYiRZ DEP SCNR 10 575 17 183 17 -0.61 122.29 2.15 1795'802 10 575 15 182 20 -0.68 122.29 2 ~ 14 10 10 575 575 11 10 178 178 28 33

                                                  -0   '5     122.29.
                                                  -0. 81 122a 29

2. 09

2. 09 1804 1815 10 576 10 179 31 -0.89 122.29 2. 10 1823 10 575 14 181 15 -1. 03 122 ?9 13 2837 V. 42

PRGE 0005 80 DEC 17 10-21-44 SUSQUEHRHNR. I WELD BC OF P8 NRX RNPLITUDE -50'. DRC +50'RC r. OF T" ID-"- RDRC DEP REL X RYiRZ DEP REL X RYiRZ DEP REL X RYiRZ DEP SDEP. I 2 17 86 1.9 -0 8 122 3 2. 1 -0. 7 12P. 3 2. 0 -0. 8 122. 3 0.5 31.2 18 63 2.2 -3.5 124.1 2. 1 -3. 4 124. 1 2. 2 -3. 6 124. 1 1.9 31.6 2 19 69 1.7 -0.6 130. 0 1. 6 -0. 4 130. 0 1. 7 -0 8

                                                                                      ~    130. 0     O. 5    24.9 FINRL EVRLURTIGN TRBLE CH    TYPE      I ND-     T     l'I I NX    NRXX     N IHY      NRXY      DNIN      DNRX VFILUE      RLLGM     EVRL 2      OW        1S S H     454.75 455.62 239.96 241.29                 2a 63     2.91    2. 16     2.99 2 ~ 16     2a65 2       OW       14 S   Y   454.80 454.80 240.84 240.84.                5 59      5. 59   0. Oi      6. 51 2       OIJ;     16- S  N   454 81. 455 P4 243 70 244 18                3 00      3 09     0. 72. 2 67

0. 72 2. 60 2 OM 18 S X 455.32 455.53 2S0.63 250.63 2. 07 2. 19 0. 90 3. 94 2 OW 1 S H 456.64 456.97 207.94. 208.37 5. 04 5. 15 0. 81 2. 98

0. 81 P. 74 2 OM 2SX 456. 85 457. 18 210.48 210.52, 4;62 4a 73 O'81 2 ~ 96 2 OIAI 7SX 456. 85 457. 41 235.16 235.17 3 ~ 46 3. 58 0. 90 2. 64 2 OM 3 S X 457. 51 457. 94 217.61 217.65 4. 33 4. 45 0. 90 P ~ 83 2 OM 13 S X 457.74. 457. 94 240. 84- 240. 84 1. 79 1. 88 0. 64 3 ~ 31 2 OM 17SX 458. 07 458.28 248.79 248.79 qo 2. 05 0. 90 3 ~ 96 2 OM 19 S 458.18 458.49 256.5P 256.52 1. 62 1. 72 0. 81 3. 05 2 OW 5 S Y 458.22 458.22 232.73 232.73 4.96- 4. 96 0. Oi 6. 51 2 OIAI 4-S X 458.38 458. 45 232.03 232.03 1. 98 2. 09 0. 81 6. 51 2 8 L 454.77 455.90 236.47 237.18 2. 64- 2. 73 0. 80 12. 60 2

Old OIJ OM 11 6 L 454 '2 L 458.02 458.43 456.23 239. 55 233.19 240. 41 233.21 2 76

1. 66 5 '1

1. 68 1.21

0. 01

12. 60

12. 60 EHD OF PRSS BEGIN UT INSPECTION FIND CPRMLER MOTION SEQUENCE.

EVRLURTIGN LEVEL = 508 DRC WELD BC CH- BET BER IT IR RELX RY~RZ DEP SCNP. 10 563 16 241 23 -4.30 115.82 2. 82 1296. 10 562 14 240 23 -4a25 115.8P 2. 81 1301 10 592. 7 293 P4 -3.30 115.33 3.42 1395 10 591 8 293 21 -3.35 115.34 3. 42. 1390 10 591 8 292 25 3.40 115.34 3.41 1385 10 591 8 292. 28 -3.47 115 34 3.41 1378 10 591 7'92 28 -3.54 115.35 3.41 1371 10 591 7 292 23 -3 61 115.35 3. 41. 1364 10 595 8 P93. 19 -3.68 115'a35 3 42. 1357 10 595 1 1 287 15 -3.74 115.36 3.35 1351 10 581 42. 249. 69- -3.76 113.66 2. 91 1.35 0 10 581 44 245 99 -3.69 113.66 2a 87 1.357 10 584 37 245 106 -3.62 113.66 2 87 1364 10 584 28 245 106 -3.55 113.65 2. 87 1371 10 584 28 487 28 -3.55 113.65 S. 66 1371 10 584 16 246 105 -3.49 113.6S 2 ~ 88 1377 ~ ll 10 584 578 578 16 10 10 487 P45 486 101 27 -3.49

                                           -3.42 25 -3.42 113.65 113.65 113.65

5. 66

2. 87

5. 65 1377 1384 1384 10 569 11 24S 94 -3.35 113.65 2.87 1391 10 S69- ii. 487 22 -3.35 113 65 5. 66 1391 V. 43

S PRGE- 0006 80 DEC 17 11=40-25 SUSQUEHRNHR I WELD' aF 08 CH- BET BER IT IR RELX RYrR2 DEP SCAR 10 570 18 241 Si -3. 2.9 113.65 2.82 2.397 10 570 18 491 18 3 29 213.65 5. 71 1397 f0 578 25 249 62 3>> 22 113.64 2. 91 1404 10 579 30 250 50 -3 15

                                  ~    113.64          2. 92  1411 10    578   32   250      43-  -3 ~ 08 113.64          2. 92  1418 10    578   33   250      34 -3. 02    223.63          2. 92  1425 10    588   30   250      40 -3. 13    113.14          2. 92  1423 10    592   30   241      42 -3. 19    113.14          2.>> S2 1407 10    59P   28   246      50 -3. 26    113.14          2. SS  1.40 0 10    588   24. 246      55    3 32
                                  ~    113.14          2. 88  1394 10    592   20   245      67    3>> 38  113. 1.4.       2. 87  1388 1;0 --59&   i5   2.46'93 77>>  3. 45 123 15           ? 88   1382, 10 592      15            1? -3 4S 113. 15             5. 73  1381 10 592      1.4- 245      87    3 ~ 52 113.            2-. 87 1374-10          14   497      f4 3>> 52            15'13.15 5>> 78  1374 20    592   13   245      93    3. 59 223.25           2>> 87  1367'36T 10    592   13   496      2.0   3 59 213.15            5. 7?

10 588 14 249 94 -3 65 113.15 2. 91 1361 10 5SS 14 501 18 -3. 65 113.15 5. 83 1361 10 589 18 250 84 3 ~ 73 123.16 2. 92 1353 10 589 18 501 20 3>> 73 113.16 5. 83 1353 10 588 24 254 81 3.80 113.16 2. 97 1346 10 588 34 258 62 -3. 88 113.16 3. 02 1338 10 588 40 258 45 -3. 95 113.16 3. 02 1331 10 581 27 239 5'4- -3. 74. 112.71 2. 80 1351 10 580 37 234 46 3 72

                                  ~    112.72          2. 74. 1353 10    580   32   238      52   -3. 65  112.71          2. 79  1360 10    580   30   238      68   -3 54   112.?l          2. 79  1366 10    580   28   238      Si   -3. 53  112>>71          2 ~ 79 1372 10    584   23   239      98   -3. 46  112>>71          2. 80  1379 10    584   18   P.38    109   -3 39
                                  ~    122. 72         2. 79  2386 10    584   12   235     114   -3. 34  112.72          2. 75  2391 10    584   12   468      16   -3. 34  112.71          5. 45  1391 10    588     8  235     114    3 ~ 27 112.70          2. 75  1398 10    588     8  459      17    3 ~ 27 112.70          5. 34  139S 10    588     7  ?35     112   -3. 20  112.70          2. 75  1405 10    588     7  460      18 -3. 20    112.70          5. 35  1405 10    587     7  238     103 -3. 13    112. 70         2. 79  1412 10    587    7   468      16 -3. 13    122. 70         5. 45  1422 20    582    9   238      84 -3. 06    112.?      0        79 1419 10    582   13   238      6?           112. 70         ? ..79 2426.

10 17 P38 43 -2. 92 212. 70 2. 79 1433 10 581 20 233 32. -2>> 86 112.69 2>> 73 1439 10 582. 21, P43 24- -2. 79 112 64 2. 84 1446. 10 590 10 262. ?2 -3 10 1 12.. 12 3'. 06 1416 10 589 10 P62. 14. -3 28 112: 23 3..0& 1408 589 258 3>> 25 112.13 3. 02. 1401 10 '10 10 589 589 ii 10 15 261 258 18 P6-31 3>> 33

                               -3. 38 112.23 122 13

3. 05

3. 02 1393 1388 10 589- 23 258 36- -3 ~ 4S 122.13 3. 02 1381 10 589 30 P57 3S 3 ~ 52 112.13 3. 01 1374 10 578 22 252 24 2 ~ 47 111.63 2.95 2479 10 580 7 23S 20 2>> 76 108. 75 2. 79 1450 10 245 25 -2. 82 1 08 75

                                            ~          2. 87  1445 10    592    7   24S      30   -2. 87 108. 74          2. 87  1439 10    592    7   244-     32    2 95 108. 74           P. 86  1431 V. 44

 ~ '

i

1~ PRGE 0007 80 DEC 17 11.=42= 06 SUSQUEHRNNR. I lJEt D BC1 QF 08 CH-'- BET BER IT IR RELY RYrRZ DEP 10 10 58S 588 7 8 244. 244-30 26

                                                  -3. 04-
                                                  -3. 11 108 108.
                                                                 '4      74-2.86 2.86 SCNR 1422 1415 10      584        10           248     20      -3. 18    108 ~ 74         2. 90        1408 10      585        12           248      16     -3. 25    1 08.        74. 2. 90        1401 10      585        15           243      15     -3. 31    108.         74. 2. 84        1395 10      575       31            307     46      -1. 71    107.         04  3. 58        1555 10      574-      31            307     50      -1 66
                                                     ~      107.         04  3.58         1560 10      575       23            307     46      -1 . 59   107.         04  3.58         1567 10      575        17           307     34      -1 ..51   107.         04. 3.58         1575 10      579       13            302. 23     -l.. 44. 107.         04  3. 53        1582 10      579                     311.           -i. 38   1.07. 04         3..63        1588 10 10 5?1 570 ii 357 10 12347 16",

15'5 -5'. 71

                                                 -5. 7?"

96. 09

96. 09

4. 1&

4. 05 1 1155 149.

10 570 10 347 15 -5. 84. 96. 09 4. 05 1142, 10 593 14= 447 2.0 -0. 43 79. r6 5. 20 1683 10 593 18 446 21., -0. 47 79. 76 5. 19 1679 10 593 18 44r 20 -0. 54. 79. 76 5. 20 1672 10 593 15 451 21 -0. 60 79 76

                                                                 ~           5. 25       1666 10      5a2       14            451     21     -0. 67      79. 76          5. 25       1659 10     592        14           450      21     -0. 75      79. 77          5. 24       1651 10     59 l.      12           453      1.9    -0. 83      79 77           5. 27      1643 10     591        10   =-

453 17 -0. 89. ?a. ?r 5e 27 1637 10 594 io 448 14 -0. 96. 79. 77 5. 21 1630 10 582 24. 276 43 3 a8 74. 21 3. 23 1328 10 588 24 283 43 -+. 03 74. 22 3. 31 1323 10 588 26 274. 55 -4. 10 74. 22 3. 20 1316 10 588 23 279 66 -4. 17 74. 22 3. 26 1309 10 588 20 273 62 -4. 2.3 74. 22 3. 19 1303 10 592 20 274. 57 -4. 31 74. 22 3. 20 1295 10 593 21 283 48 -4. 38 74. 23 3. 31 1288 10 593 21 283 41 -4. 44. 74. 23 3. 31 1282.

 ]. 0    593        ia        283        31      -4. 51      74. 23          3. 31 1275 10      593        20        284.       20      -4. 5a      74. 23          3. 32 1267 10      582        12        278        23      -4. 50      73. 76          3. 25 1276 10      584.         8       279        26      -4. 47      73.76           3.26 12.79 10      583          8       278        30            3a    73.             3.25 128r 10      583        14       274         36-     -4. 34.           75'3.

75 3. 20 1292 10 583 23 2,74 41 -4. 28 73m 75 3. 20 1298 10 57a 3+ 273 42. 22 73 ~ 75 3. 19. 1304 10 579 42 274. 43 -4.16 73. 75 3. 2.0 1310 10 579'86 28 278 34- -3 ..49 73. 29 3. 25 1377 10 30 282. 41 -3.-55 73. 29- 3. 29 1371 10 586. 31 43 3~ 62. 73 29 3. 24. 1364 37'- -3 69-277'1 587'C 286 73..30 3. 34-10'NOTE (PRGE 30 80 DEC, 17 11 58) +NOTE e 3 (PAGE 30 80 DEC i7 11 58) 1357'VRLURTIQN PRRRMETERS-VESSEL MODE SCRNNER. D I MENS I QNS = CRLIBRRTIQN LENGTH= 36 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE= 3000 QD. UNITS PER INCH= 100. 00 SCRNNER STEPSIZE = 0.050 STEP TQLERRNCE = 0.020 MINSEP = 0. 250 100/ DRC = 100 EVRLURTIQN LEVEL = 50 V. 45

j PRGE 0008 80 DEC 18 13=56'-'38 SUSQUEHRNNR I MELD OF p8 BC'ELD PEFEREHCE POINT 8= 458 96 Y= 126 50 THICKNESS ='.520 SHELL COURSE 1 CIRCUNFEREHCE = 83&-58 EVRLURT ION RNGLES- LRNIHRR= 1 0. 0 NGH-PLRNRR= 1 0. 0 SURFRCE TOLERRNCE DISTRHCE= 0.0000 REPORT B.E. DRTR RT FULL B E Rl'IP NRRIMUM B ~ E. RDRC FGR EVRLURTIGH = 5 UT CHRNHEL DRTR-'CRNHER SEP FRCTGR = 13 CH RHGLE OFFSET Y OFFSET BEGIN0 STOP'.i50 NH- BE TSEP T5/4R. t~ 1200

     '4-0 0 M 45.0 T 2 ~55
                         -2. 25
                         -1 ..05 2.. 65 65'50           450     2150 0

0 28'.

11. 0 00, 00 j

5. 60.0 T 2 2150 0 40

                         -5. 45
                                                                                                     -7.00'0
          -45 0 P                        0. 60               850     1950                0                   0. 00: ~

t7 -60. 0 P -5. 45 1.,75 850 1950 0 20 -6. 00 i0 0 0 B -2.55 0..00 10 2-1 50 7 1 i. 0.00 END GF PRSS

 +NOTE- BC-4       (PRGE 81    80 DEC 18        1.4-        07-46>

V. 46

0

SUSQUEHANNA E MELD BC

   ~Q ss IQG     1 160 XNi 45li8 XMX~  45&.5 VS'B8,0 YNi 256 5 2'~

ZQ~ i6 S.6 Nfl

SUSQUEHANNA I IJELD BC

                   ~   ~ ~

NAG' e 181 XNN~ 454,8 XNX>> 45$ ,5 VNN 28B 8 VNX~ 256+5 2llN~ 1.6 ZNX0 5 6

GENERRL ELECTRIC POST PROCESSOR- VERSION 3 REV. 2. SUSQUEHRNNR I WELD BD EVRLURTIGN LEVEL = 508 DRC VELOCITY GF SOUND = 0. 1164 LRG TINE = 1. 000 DISTRNCE C.F. = 0. 0000 RCQUSTIC LOCRTIQN TGLERRNCE = 0. 250 CYLINDRICRL GEONETRYr CIRCUMFERENCE = 837. 72 SHELL COURSE =- 2 THRESHOLD = 922 CRRWLER- PULSER- I QCRTION X = 0..00 V == 0. 00 REGION 4-SENSOR GLOBRL X Y 1 ~ 1 =

8. 7 00 1.98.2.76

2. 154. 314 205. 416 3 3- 295'. 086 2 04. 396 4 439.522 190.236 5 5 574. 586 207. 036 6 713. 735 205. 356 7 15 81.555 373.116 8 16 103.545 377.676 9 17 499. 243 356. 796

          =-

10 18 520.392 380.676 13 13 717.340 466.356 14- -9 2.19.743 478.836 15 12 611.356 479.976 TRBLE IWB-3510 RLLOMRBLE PLRNRR INDICRTIQNS RSPECT'URFRCE SUBSURFRCE RRTIQ INDZCRTIONS INDICRTIONS RrL

0. 00 -

RiT~ 1.88 i RIT r/ 2 ~ 32.

0. 05 2 00 2. 42

0. 10 2. 18 2. 61

0. 15 2. 42 2 ~ 91

0. 20 2. 7I. 3. 25

0. 25

0. 30-

3. 08 3.48 3 '8

4. 13 0.35 3. 48 4. 63

0. 40 3. 4S 5'. 24 045 3 48- 5. 86

0. 50 3. 48 6. 51 TRBLE IMB-3510.2 RLLQMRBLE LRHINRR INDICRTIONS COMPONENT'HICKNESS LRHINRR RRER-

         ~   -

T~ IN. R~. SQ IN.. 0 10

6. 10 8 20 10 30 12 40

 'EVRLURTION PRRRNETERS=

VESSEL MODE V. 49

i

 ~

1 f I I i

 ~

0

PAGE 0002, 80 DEC 15'4-'46=16 SUSQUEHRNHR I WELD BD OF pp SCRNHER DIMENSIGHS-CRLIBRRTIGH LENGTH=- 36. 00 FULL SCALE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE='000

- GD. UNITS PER INCH= 100. 00 SCRHHER STEPSIZE = 0. 050 STEP" TOLERRNCE = 0. 020 MINSET = 0. 250 100'. DRC = 100 EVRLURTIGH LEVEL = 50 WELD REFERENCE POINT- X= 8 02. 82 Y= 263. 5 0 THICKNESS = 6. 520 SHELL COURSE 2 CIRCUMFERENCE = 837.72 EVRLURTIGH RHGLES= LRMINFIR= 10' NON-PLRNRR= 10. 0 SURFACE TGl ERRNCE DISTRNCE=' 0000.

REPORT'.E DRTR. RT'ULL B.E RMP. MRXIMUM B E. RDFIC FGR EYRLURTIGH = 5 UT CHANNEL DRTR- SCRNNER SEP. FRCTGR = 13 CH =- RHGLE X OFFSET Y OFFSET BEGIN STOP MH BE TSEP. T5r4R. 2 4. 0.0 W 45.0 T

                                      -2.5S
                                      -2.25

0. 00 1200 450 2150 2150 0

0 ii 0. 00 28 0. 00 5 60.0 T 2.65 2.65'1..05 150 2150 0 39 -7. 00 6 -45. 0 P -5. 45 0.60 850 1950 0 20 0..00 7 -60. 0 P -5.45 1 75 850 1950 0 20 -6.00 10 0.0 B -2. 55 0..00 l0 2150 7 1.1 0 00 BEGIN UT INSPECTION RND CRRWh ER- MOTION SEQUENCE EVALUATION LEYEL = SOB DRC IJJELD BD MRX RMPLITUDE -50'RC +50K DRC r.OF T

ID=- r.DRC DEP REL X RYrRZ DEP REL X RYiRZ DEP REL X RY/RZ DEP SDEP 6 59 6.6 2. i. -0.9 6.6 2.,3 -0..9 6.6 1.9 -0.9 0.0 -0 7 1

79- 6.8 1.5 -0.7'.8 2.. 3 -0. 6~ 8 1.,3 -0. 7 0.5 -4.. 0 6 2,86

    +NOTE- BD-3 79 6.5 6.8 (PAGE 25 1.3 1.5      -0. 7'.
                                              -0.9 6.6 80 DEC 15 8    2. 3
                                                                                -0.9
                                                                                -0.

53- 23) 7'.6 7'S-6.5 6.8 1.2 -0.9 1.3 -0.7 0.5 0.5

                                                                                                                               -0.7
                                                                                                                               -4. 0 F INRL. EYRLURTION TRBLE-CH TYPE        IHD=           T     MINX        MRXX              MINY      MRXY            DMIN      DMAX VRt UE     RLLOW     EYRL 6 -45P           1   I      N  804. 03 805. 14- 262.53 262.76                             6. 55     6. 79 0. 40     1.82
                                                                                                                -0. 40     1.61 END GF PRSS BEG:IH UT IHSPECTIGN. RND CRAWLER MOTION SEQUENCE EVAN   URTIGH LEVEt            =      50/... DRC WELD BD
.~ CH---   BET 'BEFI             IT      IR      RELX             RYiRZ       DEP           SCNR 10    582      39                   39     -0. 65 77; 26                 3. 36.        l6 05
                                                 -0. 71 77'. 26 289'0 583      21     281           42                                   3. 27         1599 10    583      20     286           42.    -0. 79 77'. 26                3. 33         1591 END OF PRSS
    +NOTE- BD-2.         (PAGE=       39     80 DEC 15                17   ii)

V. 50

GENERAL ELECTRIC POST PROCESSOR- VEPSIGN 3 REV. 2 I'ELD BJ SUSQUEHANNA-EVRLURTION LEVEL. ='0'RC VELOCITY OF. SOUND = 0. 1164. LAG TII'lE = 1. 000 DISTANCE C.F. =- 0. 0000 RCOUSTIC LOCRTION TQLERRNCE = 0.250 CYLINDRICRL GEOMETRY~ CIRCUMFERENCE =- 836 66 SHELL COURSE =-: 4-THRESHOLD = 20000 CRRMLER PULSER LOCATION. X, = . 0.00- Y 0..00 REGION' 2 SENSOR" GLOBAL =- X Y 30 269; 532 631. 000 380. 676 5'6 18: 51.9 734-3 - . 1.1. 501 ..012. 47?'16-27' 570. 234 632. 9-16 7'49'19; 4-

76. 267 604. 092 6 15 81.452 373.116 780. 759 478. 596,

  ~

8 9>> 10- . -" 7'8

                          .22.      784.659 465
                                                     ..209-478. 836 485. 376 514.,2.96.

13 12 610.582 479.976 14 20 523.934- 522.936 15 19 332.936 521.016 TRBLE IMB-3510 RLLQMRBLE PLRNRR- IND I CRT IGNS RSPECT SURFACE SUBSURFRCE'RTIG INDICRTIONS INDICATIONS RrL RiTti RrT~i 0.'0 1.88 2a 32

0. 05 2..00 2 ..42.

0. 10 2. 18 2. 61.

0. 15 2. 42 2. 91

0. 20 2. 71' 25'.

25 3. 08 3. 68

0. 30 3..48 4. 13.

0. 35 3 48 4. 63 3'. 48- 5'. 24 0.45,3

0. 40 5'6-

                         '~

48

0. 50 3 48 6. 51.

TABLE IMB-351 0. 2 . =

    'Lt   QMRBLE. LRMINRR INDICATIONS COMPONENT THICKNESS LAMINAR RRER-T~. IN;.                                   SQ      IN;

0. 10 6: 1,0' 20 10 30 12 40 EVRLURT ION PRRRMETERS =

VESSEL MODE V. 51

t

t PRGE 0002 OF SCRHHER DIMENSIQNS-80 DEC 08 14-54 25 SUSQUEHRNHR- I MELD BJ CRLIBRRT ION LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LEHGTH= 30.00 FULL SCRLE= 3000

- QD. UNITS PER INCH= 100. 00 SCRHNER STEPS IZE = 0. 050 STEP TOLERRHCE = 0. 020 MIHSEP. = 0.250 1008 DRC = 1,00 EVRt URTION LEVEL = 50 WELD REFEPEHCE POINT X='58 48. Y= 400 50 THICKHESS =

COURSE 4 CIRCUMFERENCE = 836.66

                       &.520'HELL EVRLURTION RHGLES                          LRMIHRR= 10. 0 NOH-PLRNRR= 10 0 SURFRCE TQLERRHCE DISTRHCE='. 0000 REPORT B. E DRTR RT FULL B E RMP MRXIMUM B E. RDRC FGR EVRLURTIGN =                                        5 UT CHRNNEL DRTR= SCRNNER SEP. FRCTGR. =                                        13 CH           RNGLE                X OFFSET        Y OFFSET         BEGIN         STOP          MH BE      TSEP  T5i4R

2. 0.0 W -2. 55 0. 00 1200 2150 0 11 0. 00 45.0 T -2. 25 2. 65 450 2150 0 28 0. 00 5 60.0 T -1 05 2 65 15'0 2150 0 38 7. 00 M5'. 0 P -5. 45 0. 60 850 20 0. 00 t

1950 0 7 -60. 0 P -5. 45 1. 75'2 850 1950 0 20 -6. 00 10 0.0 B 55 0. 00 10 2150 7 1 1 0. 00 BEGIN UT IHSPECTIQH RHD CPRMLER MQTIGH SEQUENCE EVRLURTIGN LEVEL = 50/ DRC MELD BJ MRX RMPLITUDE -50'. DRC +50'. DRC OF T ID'-= iDRC DEP REL X RYiRZ DEP PEL X RYrRZ DEP REL X RYiRZ DEP SDEP 5 1 64 6.2 7.7 123.9 6.3 7.7 123.9 6.2, 7.8 123.9 1.4 4. 1 CH:- BET BER IT IR P.ELX RYrRZ DEP SCHR. 10 578 7 305 15 -2. 24- 50. 45 3.54 1577 10 579 14 306 15 2% 22 50. 45 3.55 1579 10 578 7 305 -2. 15 50 45 3. 54. 158& 1 0'78 7 305'814. -2,. 09

                                                    -2 03.

50. 45 3. 54 1592 1 0 577'0 7 304- 18. 50. 45 3 53 1598 578 30'4 17 -1 97 50 ..45 3. 53 16 04-10 578 8 300 13 -1. 9-1 50 45 3. 48 1610 FINRL EVRLUFITIGN TRBLE CH'YPE IHD:= T'INX MRXX MINY MRXY DMIN DMRX VRLUE RLLQM EVR4 5 &OT', 1 S X 566-13 56&-27 524 39. 524-39 6-17'HD 6..25 0.59 3.90 OF PRSS t +NOTE- BJ-3 (PRGE 26 BEGIN UT INSPECTION RHD CRRMLER MOTION SEQUENCE EVRLURTIGN LEVEL =

MELD BJ 80 50'RC DEC 08 16 04) V. 52

PAGE 00 03 8 0 DEC 08 18 41 SUSQUEHANNA I MELD B J OF CH:- BET BER- IT IR RELX RYiRZ DEP SCNR 10 0 0 301 19 7 ~ 99, 98.85 3.49 951 10 0 0 305 22 8. 06 98.85 3.54. 944 10 0 0 299 21 8. 13 98.85 3.47 937 10 0 0 300 18 8. 20 98. 85 3. 48 930 10 0 0 308 14 8. 27 98. 85 3a 57 923 EVALUATION TABLE CH TYPE IND- T NINX NRXX NINY NRXY 47'NRX DNIN VALUE RLLOW EVAN 10 OB.PASS'INAL L 566 47 566 75 499;35 499 35 3 3-57 0 00 tB 60 END OF V. 53

,0 SUSQUEHANNA I lJELD BJ NAE NOD

   ~P
   ~P NAc. e. iep XNN~  566+4 XNX~  566.V VNNi  199.3 YNX~  499.3 ZNN~    3o5 ZNXi    3.6

SUSQUEHANNA E tJELD BJ IQG~ 0. 100 xN~ 566il ax- see'.v Y%~ l99o3 Ytlx~ l99o3 2%~ 3.5 ZPIXi 3.6

~, IL ELECTRIC 'ENERRt POST PROCESSOR- VERSION 3 PEV. 2 SUSQUEHRNNR. I WELD BG EVRLURTIGN LEVEL = 50'FIC VELOCITY QF SOUND = 0-1164 LRG TINE = 1. 000 DISTRNCE C. F. = 0. 0000 RCGUSTIC LOCRTION TGLERRNCE = 0.250 CYLINDRICFIL GEONETRYv CIRCUNFERENCE = 837. 72 SHELL COURSE:: 3 THRESHOLD = 961 CRRWLER PULSEP. LGCRTION X = 0. 00 Y 0. 00 REGION 2 SENSOR GLOBRL. =-" ' " - " " Y 1 30 269.874- 631.000 18 520. 392- 380. 676 3 1 1. 501. 647 477. 516. 27 570. 957 632. 916

5. 26 76. 364 604. 092

6. 15 81.555 373.116 7 14 781. 748 478. 596 8 9 219.743 478.836 7 48.270 485.376 10 22 785. 653 514. 296 13 12 6 1-1. 35& 479. 976 14 20 524. 598 522. 936 15 19 333 '58 521. 016 TRBLE I MB-351 0 RLLQMRBLE PLRNRR INDICRTIQNS RSPECT SUPFRCE SUBSUPFRCE PRT IO IND I CRT I GNS IND I CRT IGNS RiL R/T vi R/T vR

0. 00 1.88 2e 32

0. 05 2. 00 2-. 42

0. 10 2. 18 2. 61

2. 42 2. 91 0 15

  ~

0. 20 2. 71 3. 25

0. 25 3. 08 3. 68

0. 30 3. 48 4. 13

0. 35 3. 48 4. 63 0 ~ 40 3. 48 5. 24

0. 45 3 ~ 48 5. 86

0. 50 48- 6. 51 TFIBLE- I MB-351 0. 2 FILL QMRBLE LRNINRP.- INDICRTIGNS CONPGNENT THICKNESS LRNINRR RRER

        '"   Tv" IN-                        .- Rv" SQ IN
              ~ .'.*vl..

0 .a . -.. ..- ~, 1 0 ~ 6 10-20 10 30 12 40 EVFILURT ION PRRRNETERS-VESSEL NODE V. 56

PRGE 0002 80 DEC 09 10: 10- 02 SUSQUEHFINHR. I WELD BG ~ GF p3 SCRHNER DINENSIONS: CFILIBRRTION LENGTH= 36. 00 FULL SCRLE= 3600 VESSEL LENGTH= 30.00 FULL SCRLE= 3000 OD. UNITS PEP. INCH= 100. 00 SCRNNER STEPSIZE = 0. 050 STEP TOLERRNCE = 0 020 NINSEP = 0.250 200/ DRC = 100 EVRLURTION LEVEL = 50 MELD REFERENCE POINT-" X= 0. 00 Y= 400.50 THICKNESS = 6.5P.O SHELL COURSE -3 C1RCUNFERENCE = 837. 7P EVFILURTION'NGLES: LRN1HFIR= 20. 0. NON-PLRNRR= 10. 0-.- SURFFICE TOLERANCE. DISTFIHCE= 0. 0000 PEPORT- B.E. DRTR. RT FULL B.E. RNP tlAXINUN B ~ E. /DRC FOR. EVRLURTION = 5 UT CHRNNEL DRTR- SCANNER SEP.-FRCTOR= = 13 -=>>" CH:: RHGLE OFFSET Y OFFSET BEGIN STOP NN BE TSEP T5>4A 2 0. 0 I!J -2. 55 0 ~ 00 1200 2150 0 11 0. 00 4 45.0 T -2. 25 2. 65 450 2150 0 28 0. 00 5 60.0 T 1. 05 2. 65 150 2150 0 -7. 00 6 -45. 0- P -5. 45 0.60 850 2950 0- 20 0. 00

7. -60. 0 P -5; 45 -

1 ~ 75 850 1950 ">> 0 20 -6. 00 0;0 B -2 55 .=2%50' t 10 0 00 10 7 11. 0. 00 BEGIN UT INSPECTION RND CRAWLER MOTION SEQUENCE EVALUATION LEVEL = 50'RC I!JELD BG

   -           NRX RNPL ITUDE-                                -5M DAC                             +50'. DRC             OF T ID-     rDRC DEP PEL X RYrRZ                     DEP PEL X RYiRZ                     DEP REL X PYrRZ           DEP   SDEP 2      1    6-7    Be 6       6~         11.3       2.7       6.4      11.3             2.6      6.3     11.3     1.0   39. 8 96                6.94'.4

11. 8 2.4 7. 0 11.8 2.5 6.4. 11.8 0.5 37. 4 ".

2 2 59. 2.6 6.8 11. 3 2.6 6.8 11 ~ 3 2.5 6.7 11.3 1.4 38. 8 ~ 96 2.4 6.9 11.8 2. 4. 7. 0 11.8 2.5 6.4 11.8 0.5 37.4 > 2 3 50 2.4 5.9 11. 8 2. 4. 5.9 11.S 2. 4 5.9 11.8 0. 0 36. 4 4 52 2.5 7.8 12. 3 2.5 7.9 123 = 2~ 5 Zes 12. 3 0. 0 38. 8 5 58 Be 9 7.0 14. 9 2 8 7.1 14;9 -

                                                                                          "2.8      6.9     14. 9    1. 0  42. T" 52     3. 0     7 3        15. 4. 3. 0      7. 4-    15. 4     -   =

3.=0 7.3 15. 4 0. 0 45 5 i

                                                                                                                              ~

6 64 2.6 6. 4. 16. 8 2. 6- 6.5 ib.8 -2; -- .6. 6.4 16.8 0;0 40 3< 90 Be 8 6. 1: 17. 8 6.3 17 8 = 24 5.9 17. 8 0. 0 44. 1 r 2 8 79-: 2-. 3 B;T 18.2 2. 4. 2.8. 18; 2 ~ '-2:. 3" " Be b. 18. B. 0. 5- 35.9'l 2 9.= 54-- B. 2 5. 0- 19;2 2.1 5. 0 19.2'- ":2 -0 4.9 19. 2 0.5 31'. 2 I 20'T

                                                               =

2 2.9 4i 9. 22. 6 2.9 5. 1 22;6 -.2.9. 22. 6 0. 0 45. 2-I 2 11 52; 5.1 3.0 26. 6 5.1 3. 0 26.6= = -5. 1" 3. 0 26. 6 0.5 21. 4" 70 5. 0 2~7 26. 9. 5.1 2e S 26. 9 "'5. 1 2.5 26. 9 0. 0 22.4 > t CH:- 10 BET 591 BER 21 IT 455 IR iS PELX 3.46 RYiRZ 31.77 DEP 5.30 SCNR 1621 V. 57

PFIGE 0003 80 DEC 09 10:44:56 SUSQUEHRNNR= I WELD BG I'1RX Fll'1PL I TUDE -5% DRC +50'. DRC iQFT ID:: iDRC DEP. PEL X RY/RZ DEP REL X RYiRZ DEP REL X RYrRZ DEP SDEP 2 12 76 5.2 3.3 31.8 5.2 3.5 31.8 5.1 3. 0 31.8 1.4 20. 0 FIHFIL EVRLURTIQH TRBLE CH TYPE IND=- T N IHX NRXX N INY I'1RXY DNIH DNRX VRLUE RLLQW EVRL 2 OM 11 S H 2.48 3. 04 427. 06 427.37 4. 95 5. 13 1.44 3. 03

1. 44 4. 12 2 1BS X 3. 02 3. 53 432 27 432. 28 5. 12 5. 23 0. 81 2%63 2

OM9SX OW OMS V 4- 95 5:. 89 e

5. Oi 419. 68 5'. 89 412.30 419.68- -"

2. 04 412.30 '*"2 36.

2. 2 37 07 0. 28

0. Oi

4. 13

6. 51-B OM 1SH 6. 25 7. 00 411.84 412. 30 =-

2. 42 2. 64- 1.71 2. 90 1 ~ 1 1.71 3. 61 2 OM 5SH 6 ~ SS 7. 39 415. 43 415. 88 -

2. 79 2. 97 1. 43 3. 14

1. 43 3. 30 2 OW 8 L 2.58 Ba 78 418. 70 418. 70 2-. 35 P. 37 0. 00 12. 60 2 OM 10 L 4. 87 5. 06 423. 14. 423. 14 2. 94 2. 95 0~ 00 12. 60 2 OM L 5 93 6 26 418. 28 418. 28

                                              ~                              2. 84     2. 89     0,00   12 60
                                                                                                           ~

2 OM 6 L 6 37 6. 51 417. 28 417.28 Be 62 2 ~ 63 0. 00 12. 60 2 0M 4 L 7. 80 7 ~ 87 412.76 412.76 2 ~ 52 2. 52 0. 00 12. 60

           'HD QF PRSS t BEGIN UT INSPECTIQN RND CRRMLER NQTIQH SEQUENCE EVRLURTIQN LEVEL =

WELD BG EHD QF. PFISS 50'RC

 +HQTE= BG-2            (PRGE 13       80 DEC 09     14- 01-41)
 +NOTE- BG-3            (PRGE 13       80 DEC 09     14- 01-41)

V. 58

0 SUSQUEHANNA E VELD BG

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   ~ 91 NAG~     0. 100 NN~      2.5 XNi      7 9 YltN~ 411+0 YNX~   432o3 2IO~     2,0 ZNX<     5.2

                                                                                                                   'I Control             No.          I QZAV)CE                                                                                     E>:am Sheet               ~2
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+x+Pzeoperational . ~~x.s.x.

7?e3.d Seam XD No'. 8 Date lZ Examiner W. A 447 Level~0 Recorder Level / 7

                                   'l Procedure                1$ E"     A .3ZW                          'Revision                    2.
       -Scanning Sensitivity ]X. C3P n8 ou~)                                 Evaluation Sensitivity /X                            C ~R   oa.our)
   . Couplant                          cerine                             Component Temperature                                           3 op Lo=                                              Ro=       8   A                                 No=            88 EYELD   Q Ind.      B.R.

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I'rszr LLAtlcws AscAvccC CNGlhcEHINQ GIVISiOH VHS HL HMNl;l'1ATXON DATA SIII.':)"T Site SusquehannaX SQX-761 ~x'Prcoperational ++T--S-X- Date i2 l'.<<~ Examiner ' e'eel~. Recorder I . P1 ui Level 45o tTreweld Seam XX) J9o. 6Oo Procetsuro Ho. Revision 2. Scan Sensitivity 2. x + Evaluation Sensitivity Couplant Glycerine ~ Component Temperature gg o,. Wq Wi:I W<n Wi 2 tY2 DI DF1 Drn DF2 Continuous CVJ or CCV DAC {Qr~o/ o(50",:- (Vicx (5Q.'( PSo/o {50ie {Vlcx (60 Mcx DA(:) DAC DAC) DAC) {'$5%!( /go br sttot, Top or p:,{:) I pu,c) IAcx) DAC) DAC) DAC) Tor P 8ottc:n

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V. 62 GENERALjgg, ELECTRIC

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1 ~ IIVSIALEArirte4 ERvlCE ERGIREEHIRQ rtIVISNW UFSSSFSL FYAMXNATXOiN DATA SIKET Site Susquehannal SQi-761 ~x/Preopera tzonal ~~X. S.T... Da te l2 A'

     'Examiner                P1.                                 'LeVel~                 Reoot:Set..              /%c&rrtw                   Zevel t ttelQ Seam              XD No.            8                               3e~m       Angle        0        ~           45                    60 Procedure              %To.        a-            t9                      Revision            '

Scan- Sensitivi ty . 2X +Cd I 3 Evaluation Sensitivity I 'C f- 440 Couplant Glycerine Component Temperature EVl (IIrf l <<'m VVFP N2 Dl DF l Dm DFZ Dp CotltinttoUs C'tv or CC'tV DAO (50"j (iYiav. 0",4 Max pAC) DAC OAC) f)AC) (Z5of 'j (Z5c f ar) ( (Spre (Max (bC'.e (Z5% br sf)ot, Toft of Q4Q) p<c) DAC) DAC) pic) T or P f3ot totn le ~E 78 >@% 2.0 PV tocR C'f: M ,Og Reference System REFLECTOR TRANSVERSE

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VESSEl UT CALIBRATIONDATA SHEET ANYTWtteee AttYWatts IHl'IAllAHOHA sl>>VICs Cal. Sheet No.~~ lHOIHu>>IHO OIVIsION Sl te KPreoperatlonal C I I.s.l. Procedure No. Rev. Coup!ant Cal. Std. Temp Examiner" ASNT Level Recorder ASNT Level Equipment Data: Instrument Model No. Shoe No.

                                                                                                                 ~

Instrument Serial No. Cable No. Transducer Size ,O Frequency ~e~ MHz Transducer Serial No. IIW 2 Beam Angle DAC Curve: Range 0 5 CI 0 10 Ij Instrument Settings: 90 St'art Finish 80 Attenuation 70 Sweep 60 Delay '/ssc 50 Scanning Gain

                                                                                                    '%.rs'ort'FF Evaluating Gain                      o/zdlo 40                                                                                                              on>>T 30                                                                        Filter Position Rep Rate 20 Damping 10 Reject 0          2      3     4     5          6     7    8     9   10 0          1            2                3          4         5      ~dhohangefnr~                                X Hole Depth                            I Iwe e                SDH Gain     Max.      e 0 or          or
      ~e Ta ~

Inches 81X Amp. Inch Inch FBH Initgal Calibratgon Time~@ IX I 9 SOLI Periodic Checks: l.aat Time Value Data Sheet I/2 g,~ IX eor. "/>> Sx II 3/4 IX vo7. "/>> gDH 2'/ Notch

                                "/>>       <</>>          "/>>         N/A Calibration in Depth(D)     Rj     or Metal Poth (MP)        CI              Final Check OI            go1.          ~ c>;i )

GENERAL ELECTRIC V. 67

gc>+> Angle Beam Spread 9 1X 45 ~ or 60 (Mode once per colibroted syatent- Calibration standard combination) Trailing Ray Leading Ray Hole Depth 10% DAC 25% OAC 50% DAC 100% OAC 50% DAC 25% OAC 10% DAC Dor Oor Dor Oor Dor Dor Oor W W alas W a4Hs asts QR fStl'/4T l Z l2 (3 t.g l.( I 4 l.9 J7 2.0 1.8 2l l.$s 1/2T X.8 2.8 2.9 >v sz 3/4T tleOb be3 Amplitude Linearity Check Control Linearity (Made Daily) s (Made Daily)

            ~~                                ~%                                                             ~9 100%FSH 90%

80% re

             ~ 40
                       % FSH 4 ~

50%FSH 40% 30% FSH 80%FSH 80% 40%

                                                                                                       -6db
                                                                                                      -12db
                                                                                                      + 6db   ~+

(32-48)

                                                                                                                    + (16-24)

(64-96)

                                                                                         "                      8'E
             ~

70% " 20% " 20% +12db (64-96)

        ~~                ~4 f~ COtaI4    NoT'CCtaLVC 7fVggg PAarS PoC loam ~pli~c(C eF 47~a4 RLtpeaeC.

Equip. Data Angle Beam Me +II, For Linearity Checks Checks on llW-2 Code Block T Block on I/8 SOH for Field Colib. Transducer Data: Checks Q Mox Amp.for Both Near 8 Far Serial No. Positions in  % Screen Height Beam Angle l/8" SOH Near Far Size ~44~4 Freer >~SF Shoe No M~ Cable No~ Max. Amp. Metal Check Made By: Path Reviewed by v ~l SNT-TG Level V. 68

VESSEL UT CALIBRATIONDATA SHEET WINCER Atty Aliy~e.. Cal. Sheet No.~+ INSIAIBAIIONA 5IIVICS INOINIIBINO OIVISION Site Hpreope'rotionol GI.S I Procedure No. Rev. Date Couplant Cal. Std. Temp. Examiner ASNT Level Recorder ASNT Level EquiprtIent Data: Instrument Model No. Shoe No. Instrument Serial No. Transducer Size Transducer Serial No. nb Frequency ~~ ffW2 BeamAngle~ MHz OAC Curve: Range 0 5 Q 0 10 Kj Instrument Settings: 90 Start Finish 80 Attenuation 'I z/ 70 Sweep /o~a. /a.a; 60 Delay 'oa h~ 50 Scanning Gain Stdl J8 b 40 Evaluating Gain ur Filter Position ovT OQ I 30 Rep Rate A Tb AIIzo 20 Damping of p

                                                                                     ~ ~

10 Off'fF Reject off 0 2 3 4 5 6 7 8 9 10

0. 1 2 3 4 5 dn Cnenge for X Hole Depth Gain Max. ~ ewee 0 or le SDH or

                ~e Tee Inches   81X      Amp.      Inch         (nch     'BH            Initial Calibration Time~I 1/4              1X                                                     Periodic Checks:

Last Time Value Oata Sheet 1/2 1X 3/4 1X gggege @~ Ia x afx7 C g N/A Calibralionin Oeplh(O) QX or Metal Path (MP) Q Final Check: gC" a Pr GEII ERAL ELECTRIC V. 69

I 0

L age 2c

                                                                    ~
                                                                                                                  ~

Angle Beam Spread 9 1X 45 or 60 (Made once per calibrated system Calibration standard combination) Trailing Ray Leading Ray Hole Depth 10% DAC 25% OAC 50% DAC 100% CAC 50% DAC 25% DAC 10% DAC W Oor Oor Oor W Dor par por Oor MP MP MP MP MP MP MP 1/4T H(r T l4 1/2T s MA 'DE. KR, 3/4T Amplitude Linearity Check Control Linearity (Made Daily) i (Made Daily) 100%FSH 90% "

            ~~         % FSH         50%FSH 40%   "
                                                +~    % FSH                       80%FSH 80%   "
                                                                                                    -6db
                                                                                                   -12db
                                                                                                          ~ ~O (32-48)

(16-24)