| title = Seabrook Station, Revision 17 to Updated Final Safety Analysis Report, Chapter 2, Appendix 2G, Static Dynamic Rock Properties Through Appendix 2I, Geotechnical Report Additional Plant Site Borings

---------Tunnel127.5-127.9DioriteDiorite16,130x9.9 x 106 13,950Near ReactorsB728.2Schist17,94011 x 10610 x 106ContactB42123.5-123.9DiabaseSchistSchist27, 600x 10610 x 1069.1 x 1068.0 x 10610 x 1067.4 x 106 TABLEUNCONFINED COMPRESSION TESTS UnconfinedAxialInitialSecantPoisson's Ratio TestHoleRockCompressiveStrain@TangentModulusInitialSecantNo.LocationNo.DepthTypeStrengthFailureModulus50%LoadValue50%Reactor 1El-l31.8DioriteDioriteDioriteDioriteReactor 250.0DioriteDioriteDioriteDioriteDioriteDiorite12 x 10612 x 10619,5209.3 x9.3 x 10613 x 10611 x 10618,02012 x 10610 x 106Failed by splitting.Do not report.

15,53012 x 1069.9 x 106 5,97012 x 1069.7 x 10610 x 106xTunnelF2246.3-246.7Schist6,060Schist6,000Schist6,330NOTE:In tests for which values of axial strain at failure, modulus,and Poisson's ratio are omitted, the strain-gage readings appear to be unreliable,No stress-strain curves are plotted for these tests.

Test No.LocationHole No.Reactor 1 Reactor 2 Reactor 2 B 42 BContactB 42 GContactTunnelTunnelE l - lB 42B 42F 2TABLELABORATORY COMPRESSION WAVE VELOCITY MEASUREMENTS Depth(Feet)Rock Type 79.980.3Diorite51.251.6Diorite139.1139.4Diorite122.5123.0Diabase141.8142.3Schist128.7129.2Diorite259.0259.4SchistLaboratory Compression Wave Velocity 0 psi3000 psi2.8119,46019,8802.8318,86019,0902.7720,05020,3002.8418,60018,8002.7716,96017,3202.7920,05020,3402.8618,11018,370 TABLE016.19316.43716.47916.49616.63117.91116.77116.11116.62116.07117.61117.07,I.99.94.m,6.326.014.01mSERIESEl1ID6.UI71336947I26061Is466737Il.U2.616.11:6.363.616.133.337.:70'3.236.006.944.667Y 6.976' 12.19.116.44.664.7699 10.:36323.722.763.264.032.612.714.043.422.612.723.163.414.0119.3067.0266.91019.16324,79619,0360.240.941.460.910.391.440.311.431.361.07quartz,very*lcrr.med.tofeldspar.

*ical.med. tofine*lcu; rd.rd.withquartz-rich totord.sulfides;onlyschisttonllbutpn-*rlst,n# but STRENGTH, VELOCITY, AND HARDNESS DATA SAMPLES FROM TUNNEL ALIGNMENTS M-lM-IM-17f-617.40417.691IS.01417.33616.74717.62416.06616.627I67.0.267.1 266.6-267.6 267.0-267.7 73-6473-6673-w73-I)73-6216.99216.27116.37016.41014.99617.06316.34316.66217.60616.49216.31216.61616.01416,99617.00716.42316.64016.6272.932.m2.732.112.713.012.11 Amendment 45 June 1982 FSARAPPENDIX 2G STATIC AND DYNAMIC ROCK PROPERTIES FigureTitle Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve 2610Unconfined TestStress-Strain Curve 2611Unconfined TestStress-Strain Curve NOTE: The stress-strain curves shown in Figures throughare terminated at the last strain reading before sudden, brittle failure. The maximum compressive load at failure was recorded by the testing machine and was used to calculate the compressive strengths contained in Table 00.10.20.30.AXIAL STRAIN 000.10.20.3Diorite= Modulus of DeformationEl-l Depth 79.1 to 79.5 UNCONFINED TEST E 1 F STRESS -STRAIN CURVE FIGURE STRAINAXIAL STRAIN 00.10.20.3itfi 1n 0^ o1)0. iV .4v .VDioriteM = Modulus of DeformationDepth 49. to 50. Oft UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE 00.10.20.3AXIAL STRAIN STRAINC0.20.30Diorite=of Deformation Depth 50.4 to 50.8 ft UNCONFINEDTESTSTRESS-STRAIN CURVE FIGURE AXIAL STRAIN 0.10.20.3AXIAL STRAIN SchistDepth 139.4 to 139 M =of Deformation UNCONFINED TESTJ STRESS-STRAIN CURVE FIGURE FIGUREAXIAL STRAIN 00.20.3SchistUNCONFINED TESTSTRESS -STRAIN CURVE

=of DeformationDepth 141.9 to 142.3 STRAIN. %

c0.10.20 00.10.3AXIAL STRAIN UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE7SchistDepth 27.8 to 28.2 MDeformation AXIAL STRAIN DiabaseM =of DeformationB-12 Depth 123.5 to UNCONFINED TESTSTRESS-STRAIN CURVE FIGUREAXIAL STRAIN SchistM = Modulus of DeformationB42 Depth 141.3 to 141.

AXIAL STRAIN UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE AXIAL STRAIN 000.10.3AXIAL STRAIN 0.10.3II/ ax.SchistM =of DeformationDepth 142.7 to 143.1 ft UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE AXIAL STRAIN M I0 2.DioriteDepth 127.5 to 127.

M =of Deformation AXIAL STRAIN 00.10.3UNCONFINED TEST F IA STRESS-STRAIN CURVE FIGURE1 UPDATED FSAR APPENDIX 2H ROCK STRESS MEASUREMENTS IN BORING The information contained in this appendix was not revised, but has been extracted from the original FSAR and is provided for historical information.

STATIONROCK STRESS MEASUREMENTS IN BORING forYankee Atomic Electric Company andPublic Service Company of New Hampshire September 1973 Geotechnical Engineers, Inc.

934 Main Street Winchester, Massachusetts 01890 STATIONROCK STRESS MEASUREMENTS IN BORING CONTENTSPageSUMMARY1.INTRODUCTION 1.1 Background11.2 Purpose11.3 Scope12.METHOD OF MEASUREMENT

2.2 The Overcoring Technique 2.3 TheGage2.4 Measurement of Modulus of Rock 2.5 Computation of Stresses 3.TEST DATA AND RESULTS

3.2 In Situ Stresses and Directions84.DISCUSSION OF RESULTS9APPENDIX A MEASUREMENT OF STRESSES IN ROCK BY OVERCORING IN VERTICAL HOLE APPENDIX B MEASUREMENT OF MODULUS OF ANNULAR ROCK CORE GEOTECHNICAL ENGINEERS INC.

GEOTECHNICAL ENGINEERS LIST OF TABLES TABLE 1 CALIBRATIONS TABLE 2TEST CONDITIONS FOR STRESS MEASUREMENTS TABLE 3 DATA AND RESULTS OF STRESS MEASUREMENTS LIST OF FIGURESLog of Boring3Log of Boring El-lPhotograph ofGage SystemPhotograph ofGagePhotograph of Rock Modulus CellData from Stress Measurements, Test 8Data from Stress Measurements, Test9Data from Stress Measurements, Test10Data from Stress Measurements, Test OClA-7Data from Stress Measurements, Test12TestHole DimensionsTestHole DimensionsTest OClA-6 Hole DimensionsTest OC-7 Hole DimensionsTest OClA-9 Hole DimensionsPhotographs of Annular Cores, Hole18Summary of Stress Measurements SUMMARYRock stress measurements were made in June and July 19*73 at depths of 33 ft to 42 ft in vertical Boringis about 34 ft from the center of proposed Reactor No. 1 of The results of five measurements ofstresses in the horizontal plane were:

diameter core around the inner hole.The rock modulus was measured by testing the annular core in a cell constructed to apply stress to the exterior of thewhile making deformation measurements in the inner hole with thegage.GEOTECHNICAL ENGINEERS INC SEA BROOK STATION ROCK STRESS MEASUREMENTS IN BORING forYankee Atomic Electric Company andPublic Service Company of New Hampshire Geotechnical Engineers, Inc.September 10, 1973

: 1. INTRODUCTION 1.1 Background Measurements of seismic velocities in the bedrock at the plant site at Station were made in the spring of 1969 by Weston Geophysical Research. These measurements indicated that the velocity in the port granodiorite ranged from 16500 fps to 18500 fps, whereas in the Kittery Schist the velocity was about 13000 fps.The velocities in the granodiorite were slightly on the high side, although not unusual in the area, and could be taken as a possible indication of in-situ stresses in the bedrock. There-fore, a modest program of stress measurement was undertaken in the zone where high velocities were measured at the location of one of the two pro-posed reactors. The measurements were made during June and July 1973.

1.2 Purpose The purpose of this report is to present the results of measurements of in-situ stresses in the Newburyport granodiorite in vertical Boringata depth of 31 to 43 ft using the overcoring technique.The coordinates of this hole are N20413, E796*71.

1.3 Scope One hole was drilled near the center of proposed Reactor at Station for the purpose of measuring in-situ stresses. Eleven measurements GEOTECHNICAL ENGINEERS were made using the overcoring technique.Each measurement consisted of three deformation readings in the horizontal plane on axes oriented apart. Of the eleven attempts, the data from five ofmeasurements, at depths of 33 ft 9 in. to 41 ft 5 in. , were deemed suitable for analysis and are reported herein. The other measurements gave poor or marginal in-formation because of rock fracture and /or equipmentduringovercoring.

Moduli of elasticity of the rock were measured (a) on two annular cylinders of rock removed after overcoring, and intact specimens oriented such that the load was* in the direction of the axis that was horizontal in-situ. Thesewere used with the measured defor-mations and published formulae to compute the magnitude and direction of the largest and smallest normal stresses in the horizontal plane. The ver-tical stress was assumed to be equal to the overburden pressure.

The test procedures used are described in detail in Appendix A and B.

2.2 The Overcoring Technique Fig. 1 is a sketch of the appearance of the hole during overcoring.APX hole, 5. O-in. diameter, was first drilled with a single-tube core barrel to the desired depth. In this case, this depth was the shallowest at which the rock was continuous enough to be tested, which turned out to be 31 to 43 ft below ground surface. Logs of Boringand Boring El-l (NX-size),

which are about 14 ft apart, are shown in Figs. 2 and 3, respectively.

2.3 TheGageA photograph of the instrument, the hose, the readout, and the pres-sure application system is shown in Fig. 4. The instrument, without its vinyl sheath, is shown in Fig. 5. The deformation is measured by bending of the cantilevers that are seen at the left in Fig. 5. The readout. of strain gages on the cantilever arms is proportional to the movement of the tips of the cantilevers. In this instrument three pairs of cantilevers were installed apart. In principle only three cantilevers are needed, but a fourth is necessary to be able to compute body movement of the instrument within the hole. To eliminate this computation, the cantilevers were in-stalled in pairs such that body movements cause zero output on the readout device. The instrument was designed and constructed by Pierre The tips of the cantilevers are attached to the vinyl sheath, Fig. 4, such that when air pressure (or bottlednitrogen pressure) is applied in-side, the cantilevers are forced against the side ofhole. Hence the hose serves the dual purpose of protecting the strain gage leads and passing air to the instrument. The readout is made on a conventional strain gage in-dicator.2.4 Measurement of Modulus of Rock To obtain the best value of the modulus of elasticity of the rock in the zone tested, it is necessary to remove the overcored annular cylinder of rock from the hole and test it in a rock modulus cell. In Fig. 6 an annular core is shown in the cell with the gage in the central hole of the core. To determine the modulus one applies pressure to the outside of the core, up to about 3000 psi, and then removes it in increments, measuring the deformation of the central hole for each pressure decrement. In this way one reproduces reasonably well in the core the stresses that it under-went during overcoring. The details of the measurement procedure are given in Appendix B.

ENGINEERS EkPEkPIThe direction of stressis obtained from the formula: :

tan'To supplement the measurement of modulus onannular cores, intact specimens of rock from Boringfrom depths where stress measurementsmade, were tested in unconfined compression. The specimens were loaded in the direction ofaxisin-situ so that the loadinsame direction as in situ. The rebound modulus of these specimens was measured with the aid of strain gages glued on the sides of the specimens.

2.5 Computation of Stresses The major and minor stresses in the horizontal plane were computed from the measurements using the followingfrom Obert where:= Stress at center ofcircles of stress, psi q = Radius ofcircle of stress psi E= Modulus of elasticity measured for same stress changes as occurred in situ, psi d = Diameter of central hole in which instrument is placed, in.

= Horizontal expansion of the diameter of the overcoring. The subscripts refer to axes that are 120 apart in the plane perpendicular to the axis of thegageinthis case horizontal. R is the reading in microinches/inch and k is the instrument calibration in in.

Ifand2R 1, then 0and2R1, then Ifandthen2 R1thenbut(5) above are based on the assumption that a plane stress condition exists at the measuring point in situ, i.e. that the vertical stress is zero. Since the vertical stress is very close to the overburden stress of about.

The results of calibrations ofinstrument and measurements of rock modulus are shown in Table 1. Direct calibration of Instrument, No, 2 with a micrometer yielded k = 10 in..Sincecan beread, the instrument can be used to discern movements in theassmall as 5 xInstrument, No. 1 wasdirectly, but it is capable of discerning movements of 2 x 10 in. in the borehole.

Thegages were calibrated under conditionstoin-situ conditions by using an annular aluminum cylinder of known modulus (10 xpsi) as a standard. Table 1 shows that Instrument No. 2 yielded k =, as compared with 10for the direct calibration above. Since the calibration in the rock modulus cell models very closely the in-situ testing conditions and since the modulus of aluminum is well known, the value of k = 8.6 in.for Instrument No. 2 is the better value and was used herein.

* Similarly k = 4.4was usedInstrument No. 1.

*The direct calibration was made without the vinyl sheath in place.The canti-levers were therefore unstressed. When the gage is in the borehole, the canti-levers are stressed to half their elastic limit. Hence, the direct calibration is not as appropriate as the calibration which makes use of a standard annular cylinder.

GEOTECHNICAL ENGINEERS INC.

ReboundModulusFromTestSpecimens were cubes 1.2 in. on side.

The range of possible moduli of the granodiorite is from about 3 to xpsi. The larger values were measured on small intact specimens using strain gages, whereas the smaller values were measured on the an-nular cores using a loading sys tern and measuring device which were iden-tical for practical purposes to in situ conditions. Hence the moduli used in the computations were those measured on the annular cores.The factthat one intact specimen of granodiorite had a modulus of only 5 xpsigives some confidence in the use of a still lower modulus for the large an-nular cores, because they can be expected to contain more defects than the smaller specimens.

Fig. 18 shows to scale the computed stresses and directions for the best estimated values. Table 3 shows the numerical values for these best estimates as well as other possible values for Tests7, and9. These additional values arise from alternate selections of the changes in reading from Figs. 7, 10, and 11.

This average is 1240 psi (87 bars) for the major stress and 860 psibars)for the minor stressplane. The vertical stress is equal to the overburden pressure of about.psi,At the bottom of Fig. 18 is a tabulation of some known previous stress measurements in New Englandand Sykes, 1973). The general agreement.

TABLES TABLE 1 CALIBRATIONS Change in Reading per 10 Instrument No.for each Channel, Calibration Avg210010010310110B. CALIBRATIONS USING ANNULAR CORES IN ROCK MODULUS CELL No.Change in Reading per for each Channel, psikEMedium- -767876774.410Al4041398.610Al413939408.610Al2001731921884.44.1diorite1351401301353.0dioriteUnderlined values computed using equation for thick-walled cylinder under ex-ternal pressure for OD = 4.31 in, ID = 1.50 in.:=The quantity is equal to the diametral deformation.

33369383393415Granodiorite Granodiorite Granodiori te Granodiorite 21222Calib.kin.8.64.48.68.68.64.14.14.13.03.0285165285255240ModulusEpsiTrueAzimuthChanneldeg.TABLE 2 TESTFOR STRESS MEASUREMENTS in. = microinches

ENGINEERS TABLE 3 DATA AND RESULTS OF STRESS MEASUREMENTS ReadingChangeduringOvercoring inpsiCompressive StresstalPlaneBearingofpsi13351025N 38 E8095(1090)53692030015050N 553836011090119085039325015025021501570N 45 E250(1710)75 E)25015 0(1970)(1470)60 E)415901951001400800N 48 E195100(1470)36 E)1)Readings are shown for data from Channels 1, 2, and 3 on instrument. For all tests exceptthe numbering of the channels, eachapart, was counterclockwise. Forit was clockwise. In the equations for com-putation of the angle between theand the Channel 1 directions, the number-ing is assumed to be clockwise. Hence for all but Testandshould be exchanged when computing this angle.See text for equations used for computations.

GEOTECHNICAL. ENGINEERS FIGURES Bottom PX Hole PX Barrel-Start Measuring Point PX Barrel-Finish BottomHoleElectricGeotechnical Engineers, Inc AtomicSTATIONSKETCH OF HOLE DURING OVERCORING

: 10. 1973FIG. 1Hose andforGageNW Casing 0 (El. 28 Overcoring Barrel in. OD, 4.2 in. ID ENGINEERS Ton El.28.0Multipledrillingbreaks.,\\jointDrillingbreakDrillingbreakDrillingbreaksFeldspar-Multiple joints, with piecesnesiumBiotite 10%

Joint set intersecting at.6Tight joint Joint slightly rusty Rusty joint Rusty joint Two tight joints Joint rusty Tight joint broken by drillingjointRusted joint tight joints, rusty Quartz diorite. Dark gray, medium

Pegmatite dike,wide, at about Contact:dipdike, coarse N 20413; E 79671byI*.REMARKS Log isto a large scale, only for range of depth where stress mea-surements were attempted. Photographs of cores from tested depths are shown in Fig. 17. Log of Boring El-l, 14 away, shown in Fig. 3. Depth of stress measure-ments are shown above IFIG. 2303234404244 Top El.25.9Dec. 26,DIPOF CORE GRAPHIC Quartz diorite, medium finemediumMassive(not.foliated.

65 Dip Diplets as shown.

Quartz diorite, as above, hlassive, medium fine medium grey.

-on lowangle (3)Core- R u s t y allybyto moderate weathe

-jointsevening on joints as Most joints dip ab 10to in-jointsBreaks on angleing minor vuggi Chips, rustyock is fresh.

Slijointrustto minorslightcoatingsght weather-30-to 1.5* in-

- weathering 4on some joints.

40 Breaksto pieces Joints are nor-rustmally clean.

jointNot rusty.

.minor rust

\roughtodips. Joints slight weather- not ingas shown.

Rock is fresh.

FIG. 320STATIONLOG OFEl-lCoordinates:20400; E 79675 J. R. Rand GAGE SYSTEM BOREHOLEGAGE (vinyl sheath removed)

ROCK MODULUS CELL ENGINEERS Depth of Measuring Points 33 ftin.12345678Depth of Overcoring, in.

Massachusetts STATIONDATASTRESSMEASUREMENTS

'TEST8, 1973FIG. 7Project 7286 TEST0246812Depth ofin.Instrument230in. /in.0. 001 in.Hole I.D.in O.D. -4.31 in.

ProjectAug. s,FIG.10002004002003005004007006008000Depth of Measuring Points AtomicElectric Company Engineers, Inc.

DATA FROM STRESS MEASUREMENTS YankeeElectric Company STATIONProject 7256 Depth of Measuring Points 38 ft 3 in.

0134567Depth of Overcoring, in.

O.D.4.31 in.DATASTRESSMEASUREMENTS TESTAug. 8,FIG. 9 STATION200100020010003002001000124567Depth of Overcoring, in.

Instrument Calibration 116 in. /in.0. 001Hole I.D. = 1.495 in.

Yankee Atomic Electric Company GeotechnicalInc.Winchester, Massachusetts Aug.1973FIG. 10GEOTECHNICAL ENGINEERS DATA FROM STRESSMEASUREMENTS TEST Depth of Measuring 1345678Depth of Overcoring, in.

DATA FROM STRESS Yankee Atomic MEASUREMENTS STATIONElectric Company TESTGeotechnical Engineers, Inc.

,Aug. 8, 1973FIG. 11Massachusetts Project 7286 GEOTECHNICAL ENGINEERS NW Casing PX Overcoring Barrel 5.0 in. OD, 4.2 in. ID 4.54 in.33 ft, 5.5 in. BottomHole3 3 ft, 6 in.PX Barrel-Start 33 ft, 10 in.Measuring Point 34 ft, 3 in.PX Barrel-Finish EX Hole1.5 in. ID 35Bottom Hole andforGageISTATION,Project 7236June 20, 1973FIG. 12TESTHOLE DIMENSIONS GEO*TECHNICAL ENGINEERS Yankee Atomic Electric Company Gcotechnical Engineers, Inc.

Winchester, Massachusetts 028NW Casing Overcoring 5.0 in. OD, 4.2 35 ft, 9 in.

36 ft, 5.5 in.

I1EX Hole1.5 in. ID 37 ft, 7 in.

TESTHOLE DIMENSIONS Geotechnicsl Engineers, Inc. Winchester,7286Yankee AtomicSTATIONElectric CompanyHose and Wires forBottomHolePX Barrel-Start Measuring Point PX Barrel-Finish Bottom EX Hole June 27, 1973FIG. 13GEOTECHNICAL ENGINEERS INC.

NW Casing

-I-Hose andforGage37 ft, 10.8 in.

Bottom Px Hole37 ft, 11.3 in. PX Barrel-Start 38 ft, 3 in.Measuring Point III-- 3 8 ft, 6.5 in. PX Barrel-Finish 4.2 ln.iEX Hole1.5 in. ID 39 ft, 11.8 in. Bottom EX Yankee Atomic Electric Corn STATIONTEST OCIA-6 HOLE DIMENSIONS eotechnical Engineers, Inc.

HoseWires for GageNW Casing PX Overcoring Barrel 5.0 in. OD, 4.2 in. ID I38 ft, 8 in.Bottom PX Hole 38 ft, 11.5 in. PX Barrel-Start 393 in.Measuring Point

-- 39 ft, 6.6 in. PX Barrel-Finish in.EX Hole1.5 in. ID ft,in.EX HoleYankee Atomic STATIONTEST OCHOLE DIMENSIONS ProjectEngineers, Inc.

U-inches ter, Massachusetts June 28, 1973FIG. 15GEOTECHNICAL ENGINEERS INC.

H o s efor - -GageNW Casing PX Overcoring Barrel 5.0 in. OD, 4.2 in. ID iII--6 in.IIIEX Hole1. 5 in. ID 42 ft, 3 in.Bottom EX Hole 40 ft, 1 1 in.Bottom PX Hole 41 ft, 1.5 in. PX Barrel-Start 41 ft, 5 in.

,Project 7256 STATIONGEOTECHNICAL ENGINEERS INC.

HOLE DIMENSIONS TESTJune 29, 1973FIG. 16Yankee Atomic Electric Company Gcotechnical Engineers, Inc.

TRUENORTH2000 psiWBoringN 20413, E 79671, El. 28 Depth toMAXIMUM IN-SITU COMPRESSIVE STRESSES ON HORIZONTAL PLANE Nuclear Station, New Hampshire June July, 1973 PREVIOUS STRESS MEASUREMENTS NEW ENGLAND LocationMass.W. Chelmsford, Mass.bars54354576BearingRock Type N 14 EGraniteN 4WDolomiteN 2WParagneiss N 56 EGranite8559N 40 EGranodiorite145)(3 106)All stresses measured at depths less than 50 m (160 ft)

Stresses are compressive One bar is 14.5 psi L. and Sykes, L. R. (1973)Compressive Stress and Seismicity in Eastern North America: An Example of Intra-Plate Tectonics, Geological Society of America Bulletin, Volume 84, No. 6,1871.Yankee Atomic Electric Company STATIONProject 7286 SUMMARY OF STRESS MEASUREMENTS Sept. 7, 1973Fig. 18,Barre, Vt.

Select desired orientation of measuring points on instrument.Ifpossible, orient one axis in direction of anticipated major stress.

APPENDIX A CEOTECHNICAL ENGINEERS INC 16.Inflate the instrument to a pressure of about 4greaterthan the water pressure at that depth, but not greater than about 6above the water pressure.

32.Carefully and in detail describe the core, particularly within 3 in.,

on each side of the measurement point.Photograph the core wet and dry, making sure that the crayon mark shows up.

APPENDIX A GEOTECHNICAL ENGINEERS CHECK THE DATA SHEET, SKETCHES AND DESCRIPTIONS TO EN-SURE THAT ALL DATA NEEDED FOR UNDERSTANDING THE TEST HAVE BEEN RECORDED. LIST THE NAMES OF ALL PERSONNEL AT THE SITE.

APPARATUS 1.gage for EX hole (1.5-m. dia. ) including hose containing lead wires and air tube.

5.Datasheets,formattached.

6.Orientation rods for setting the gage elevation and formaintaining orientation of gage.7.Compassfordeterminingorientationofgage.APPENDIX A GEOTECHNICAL ENGINEERS OVERCORING READINGSII, NEW HAMPSHIRE DepthsProject No. Date TestBot. 5-in. HoleDrillerRot. EX Hole  EngineerPins on Gage  WeatherDimensions in  Page 7Strain Gage Readings 45IiIIIGeotechnical Engineers, ElapsedTime123457810111213141516III123DepthNo.Hole Location El. Top of Hole El. Datum Orientation of Gage APPENDIX APPENDIX B MEASUREMENT OF MODULUS OFROCK CORE Geotechnical Engineers Inc.

8.Apply pressure to exterior of rockin increments of 500 psiuntilthe compression of the diameters is equal to theirextension during coring but do not exceed 3000 psi unless an axial load is put on the core.

B2Pwhe re :=deformation instrument calibration R = instrument reading d = I.D. of core b = 0. D. of core P = external pressure E = rock modulus GEOTECHNICAL ENGINEERS INC UPDATED FSAR APPENDIX 21 GEOTECHNICAL REPORT ADDITIONAL PLANT SITE BORINGS The information contained in this appendix was not revised, but has been extracted from the original FSAR and is provided for historical information.

1.2 Scope 2.0 BORING AND TEST PIT DATA 2.1 Table and Figures 2.2 Boring and Test Pit Logs Summary of Boring Data FIGURESG-Series Borings; Plan of Boring Locations, Fig. 1 Grain Size Curve, TestTP Sample, Fig. 2 111333APPENDIX I Boring Logs and Description of Exploratory Test Pit APPENDIX IIDriller's Logs  

1.1 Purpose The purposethe geotechnical investigation was to provide soil and bedrock descriptions pertinent to the design and construction of several proposed structures which will be located at the plant site, in-cluding water and oil storage tanks, settling basin, retaining wall, and rip-rap structures.

b.Settling BasinA series of three borings was made in the area of a proposed settling basin using standard split-spoon sampling techniques to refusal for the purpose of invest-igating soil conditions at the proposed inlet and outlet structures for the basin, and also to examine the in-situ soil for possible use as construction materials forInaddition, a test pit bag sample was taken near the center of the settling basin, tested for grain size distribution, and examined as a possible dike material.

posed retaining wall for the purpose of locating and sampling the dense glacial till.These borings were advanced by first "washing" to establish the top of the till layer, then sampl-ing this layer by split-spoon techniques, and finally ad-vancing theto refusal using a roller bit.Based onthe results of geophysical surveys andborings drilled into bedrock in the vicinity, it is believed that refusal does correspond to the bedrock surface in these holes. 2.0 BORING AND TEST PIT DATA 2.1 Table and Figures Table I is a summary of the boring data including boring location, "as-bored" coordinates, ground elevation, depth to glacial till, and depth to top of bedrock.

TABLES TABLE ISURIRIARY OF BORING Boring No.

Boring Location As-boredGround Elev Depth toDepth toTop of Tillof Bedrock G-lG-2G-3G-4G-5G-6G-7G-8G-9G-10G-11G-12Oil Storage Tank Settling Basin (Inlet)Settling Basin (Outlet)Settling Basin (additional)

--s.L______,TP=10'100'200'300WO_..Pr MOM.,--_____.

*-.' '0....._1111111117111,11.:"

.11. -ILI21,000-1 /11111111.000 P'xiii' IREElltirillilltilligatitalblEEMEIVilliallik tratillittE_

MIIMERADIONEw 1;C3`ill(.111111111111111111PLi-Zs.'

: G-, -'=.---th---) r---1111-::- - k:: 20,00C10, ,-,-17timmrdww

--T--soo.wim-.V,4---.4'VIIMI-.R /tAPUBLIC SERVICE COMPANY OF NEW HAMPSHIRE SEABROOK STATION SEABROOK STATION SITE TOPOGRAPHY AND PLOT PLAN PLAN OF BORING LOCATIONS UNITED ENGINEERS G CONSTRUCTORS GEOTECHNICAL ENGINEERS, INC.

OCT. 17,1974FIG.I0- SERIES BORINGS Lab. 4-3, rev. 0 28 May 74 U.S. STANDARD SIEVE OPENING IN INCHESU.S. STANDARD SIEVE NUMBERSHYDROMETER 70 100 140 200 1020000IIII I1005050.10.050.010.005GRAINGRAVELOR CLAYICOARSECOARSEMEDIUMIYankee Atomic Electric Co.

StationGeotechnical Engineers, Inc.

Winchester, Massachusetts GRAIN SIZE CURVE TEST PITTP SAMPLE Project 7286 1974Fig. 2 APPENDIX I ofNo. : 7286 NO.Ground Elevation Depth toLevel:at ground elcv. 0700; Date: Sent. 30. 1974 Described by:PittSampleNO.DepthofperDescription S-l0. O-1.0l-2Black, soft PEAT and organic SILT; highly decomposed

: 1. O-2.06-14Gray-brown, gravelly, sandy, slightly organic SILT, contains subangular gravel up to 35 mm in size.

s-23.0-5.0Rust brown and brown slightlygravelly,sandy32-23SILT, trace clay. Contains gravel up to13 mm in size.

s-35.0-6.527-39SimilartoS-2.57Contains gravel up to 35 mm in size.

colorchanges-410.0-11.5 hammer gray, very dense,sandy,gravellySILTtrace clay.

hammer contains broken pieces of gravel up to 28-2235 mms - 554hammerSimilar to S-4 12hammer40Casingrefusalat16.5Bottom of End of Exploration SampleNo.DepthNuofperDescription S-l0.O-1.02-5Light brown, silty fine SAND. Contains root fibers and decomposed organic matter.

1.0-2.03-2Dark brown/rust brown/gray mottled; fine sandy SILT, trace fine gravel s-23. o-4.5hammerLight brown, gravelly, sandy SILT.22-42hammerContains gravel from various logies up to 35 mm in size.

s-35.0-7.015Light brown silty, gravelly, fine to coarse SAND 23widely graded,* resembles glacial till 2333s-4LO. O-11.5 57-100hammerGray brownbrown slightly 33hammerdense, silty, gravelly SAND (similar to S-3) Contains broken pieces of gravel up to 35 mm in size.Casing refusal met at 13.8*

G - 2 1 of 1 No. : 72861, 1974 Described by: Ground Elevation Depth toLevel: -5.1* measured at 0715,  1, 1974*S-ls-20.0-2.03.O-5.05*10-2021-20Brown grading to buff, soft, homogeneous SILT, trace clay. Uppercontains grass andzone.Similar to S-l, buff/rust brown mottled, contains black spots decomposed organic matter? ?; trace roots and mica particles s-36.0-7.014-16Light brown, loose, silty fine SAND, trace clay S-3A7.0-8.022-32Rust brown/buff medium dense, mottled SILT, little to trace clay.Low plasticity.

s-4s-510.0-12.15.0-17.C 2-44-5C 2-33-4Gray,mediumstiff homogeneousCLAY;highplasticity SimilartoS-4S-619.5-20.C 32Gray-brown silty, sandy, GRAVEL; trace clay. Con-tains angular pieces of gravel up to 25 mm.

graded.S-6A20. o-21.5 20-12Light brown, gravelly, sandy CLAY. Contains gravel pieces up to 25 mm in size 25-25.5hammer Similar to S-6, very dense hammer (Resembles glacial till) continued)

NO.S-83 0.0 - 31. 5 25Gray, very dense, silty fine SAND, some gravel up to 2530 mm in size 58s-9hammerNo recovery hammerCasing refusal at Bottom of Endof Exploration SampleN o.DepthNumberofBlowsDescription perS-l0. o-o. 5 1Dark brown, fibrous PEAT and organic SILT S-lA0.5-2.l-l-2Light brown, fine sandy SILTsilty fine SAND s-23. o-5.6-10Light brown/dark brown/rusty brown slightly mottled, 22-42medium dense, silty, gravelly fine SAND. Contains gravel up to 35 mm in size.

s-36-7.5hammerSimilar to S-Z, medium dense to dense 35-60hammer8.0Largecobbles-410.0-11.5 25-50Similar to S-3, coarse to fine SAND 57Widelygradeds-515.0 -16.2 100'0"hammerSimilar to S-4 4260hammer75S-620-21Gray,verydense,gravelly,siltycoarsetofineSAND;littletotraceclay.(Till)Rollerbitrefusalat22.5Bottom of End of Exploration Ground Elevation Depth to Water Level: Not taken BORING NO. G-4

- 1 of 1 -

No. :72862, 1974 Described by:Pitt19 Ground ElevationftDepthNot takenDescribed by: SampleNo.DepthofBlowsperDescription Drove casing to 9.0* , where encountered strata changecasing refusal Split-spoon at 9.09.7S -l9.0-9.7hammergray/brown slightly mottled, very hammerdense silty, gravelly, SAND; little to to trace clay, (Till)

Bedrock ?

Bottom of Endof Exploration BORING NO. G-5 Proj. No. :

7286 3, 1974 Oct. 3, 1974 No.: 7286 Ground ElevationftDepth to WaterNot takenDescribed by: No.DepthNumberofBlowsperDescription Drove casing to refusal9.0'Roller bitted to10.8'strata change Split-spoon attempt at 10. 8' S-l57830hammer gray, very dense, sandy, gravelly SILT, trace to little clay.(Till)hammerRollerbitrefusalat19.5'ofEnd of Exploration NO. G-G1 of 1 No.DepthNumberofBlowsperDescription Drove casing to Roller bitted to 11.5*strata change S-l11.5- 13.0 249222hammergray, very dense gravelly, silty SAND trace to little clay. (Till)

RolflereLitted to refusal at 23.2 Bottom of Endof Exploration NC). G-7 Ground ElevationftDepth loLevel: Not taken

- 1 of 1 -

Proj. No. :  7286 Date: Oct. 3. 1974 Described by:  Pitt 23.2 NO. G-8pg. -of-Proj. No. : OctoberGround Elevation Depth to WaterNot TakenDescribed by: No.DepthitNumberofBlowsperDescription 10.1Cobble. Drove casing to refusal at 10.5. Strata change.S-l12.018-16-24Gray, medium dense clayey silty, SAND, little to trace.Gravel containsgravel up to 15 mm in size.Medium plasticity, well graded. Moderate reactiontoshakingtest.Bottom of borehole, roller bit refusal at 19.0*.

10.519.0 Run No.Depth ft.

%NX-1*NX-2NX-3NoSamples --Washedthroughoverburden TOP OF ROCK 15.520.525.5REC =100%RQD =96%REC =100%RQD =76%REC =100%RQD =80%IGray/white mixed fine and mediumDIORITE.Minorjointing.Freshandhardthroughout.Minoron joint surfaces.

SimilartoNX-1;minortomoderately jointed.Jointsrusty; vuggy. Moderate weathering on joint surfaces.

Described by: W. Pitt Ground ElevationftDepth toNot Taken BORING NO. G-10 Ground ElevationftDepth to Water Level: Not Taken 1 of 1Proj. No. :

7286 October 8, 1974 Described by: Pitt Run NoDepth ft.

Recoveryand%Description NoSamples --Washedthroughoverburden TOP OF ROCK Roller bitted to 7.0 ftIREC =Gray, mixed fine and medium g-rained DIORITE.

=out.Moderatelyweathered;rustyonjointsurfaces.

65%NX-2REC =Similar to NX-1; intact rock generally fresh and hard.

17.0100%Moderate to severe weathering on joint surfaces.

=62%NX-3REC =Similar to NX-2;generally fresh and hard throughout.

22.0100%Moderatewe*atheringonjointsurfaces.

=75%Bottom of boringEl. -29.9 ft.

6.5,22.0' Run No.Depth ft.

Recoveryand%Description NoSamples -- Washed through overburden TOP OF ROCK IIIIIRoller bitted to 16.0 ftIIINX-116.REC =Gray, mixed fine and mediumDIORITE;-21.092%RQD =55%semi-schistose in texture.Moderatelyjointedwithseveralhighanglejoints.Generally hardand fresh throughout withminor clay infilling onslicked joint surfaces.

NX-221.REC =Similar to NX-1,moderately hard; vuggy in places with 26.0100%severalweathered,highanglejoints.RQD =67%NX- 326.REC =Similar toNX-2;moderatetosevereweathering on 31.0joint surfaces.

RQD =68%ofBottomboringEl.15.9*31.0*GroundftDepth to WalerNot Taken BORING NO. G-11

-of 1 -Proj. No. :

1Proj. No. :

7286Date:Described by: Pitt SampleNo.DepthNumberofBlowsperDescription S-l1.0l-4Brown-black soft PEATand organicSILT, highly decomposed, root mass throughout.

6-6Gray-dark brown mottled,loose fine tomediumSAND,little to trace silt.

------ COLORCHANGE --- Gray, slightly micaceous, similar to s-25.0-6.5-12-21-28s-310.10.9hammer. Gray, homogeneous CLAYHammer. High plasticity BottomholeofRoller bittedrefusal.Bedrock or large boulder.

Depth to Water Level: Not Taken OFLocationadjacent toWater:encountered Coord. 21, October 3, 19747 2 8 6DatePitGround Elev. :

SoilO-1.0Black-brown fibrous PEAT and organic SILT 1.0TPSamplelight brown-yellow brown, loose, silty fine SAND, cobbles found. throughout.

Test pit was hand dug to a depth of approximately2ft1.0' APPENDIX DrillingCo., Inc.

WATER STREETPROVIDENCE, R.

OFFSET ILOCATION OF BORING:

SHEETSAMPLEChongeIDENTIFICATIONType ofetc.seams ond No-S i l tverydenseBrown fine trace coarse sandfineto coarse9*moisthardclayeyto medium sandtocoarse gravel (TILL) 5 1*16.5*Bottom of Boring16.5*.IGROUND SURFACE TO *HEN Usedon0.SUMMARY:trace0O-IOLooseIO.30 Med. Dense Dense+ Veryo.4 Soft4.8some201035%Sompte Type O-Dry W-washed UP:V=Vone Test Undisturbed O F 1TOtoiISTARTHours,*.American DrillingBoring Co., Inc.

WATER STREET ADDRESS LOCATIONENGR.U  HoursGROUND WATER OBSERVATIONS SENT TOCOMPLETETOTAL HRS.

DATENO.LINESTA.I OFFSET SURF.CASINGSAMPLERSue I.D.l-3--Hammer Wt.BIT--LOCATION OF BORING:

GROUND SURFACE TO USED452IFrom - To onBlows per IIISamplerTOIMoistureDensityorhonge- -14.54*1*THEN I3rown fine silty sandfine-coarse IBouldersifinetrace fine gravel, trace of

,(Refusal cas.-12*6-drilled w/roller bit to 14*6)

- ---SOILIDENTIFICATIONType ofhord-Bottom of Boring14.5*SILT (Tonsoil) and etc.SAMPLENo. Pen Re:

2124Sample Type UsedWt.onSampler0IODenseo n d,+ Very Dense UP:PattonTestUT= Undisturbed Thinwoll some 201035%

IO-30 Med. Dense u-44-B WATERWATER STREETHoursDrillingCo., Inc.

tiommer0.ADDRESSCASING SAMPLERCORE BAR.

3NOBITCOMPLETEINSPECTOR TOTAL HRS.

STARTSOILSSHEETDATE HOLE NO.LINESTA. OFFSET SURF. ELEV. LOCATION OF BORING

--per 6MoistureSampleonSampler DepthsChongeFrom- TOSwetsoftIBrown SILT 24II612*7siBrown silty Gray CLAY wet3stiff4,tii6*18*12sandy175045.3028*fineIS442558ium gravel IIUsedon 20.D.

Consistency 0o-4 SoftO-IOLooseUP:littleIOIO-30 Med. Dense 4-8some30-50Densefond351050%Very Dense

.GROUND SURFACE TO .TestA-Auger V-Vone Test UT= Undisturbed stiffwetverydenseGray silty f ine-med Bottom of Boring34*10Refusalsilty sandy GRAVEL  

--I D.HommerHoursSHEETDATELINE 8 STA. OFFSET SURF.WATER OBSERVATIONS I--P COMPLETETOTALSTART3.H o m m e r  SOILS LOCATION OF BORING:

AtomicCo.TOADDRESS -I LOCATION SAMPLES SENT TOCASINGSAMPLERCORE1*6 after-23 Hours

--SampleSAMPLE.4*j19*22.5*GROUND SURFACE TO Proportions Used onSomplcrSample Type DensityW-WashedV-StiffUP= Undisturbed TestTestBlows per 6 tmce0littlesome,+ Very Dense Brown fine sandy SILT Brown finecoarsesandfine-coarse gravel trace of silt SOIL IDENTIFICATIONType ofhard-ondGray siltyfineto coarse gravel Bottom of22.5*RefusalRoller Bit (ionsoi.lSILTCohesiveConsistency o-4 Soft4-8 M/Stiff Stiff

_ __ Hours A t - I D.AmericanGo., Inc.

100 WATER STREET CoTOI-CASINGSAMPLERCOREBARamSTARTsCOMPLETETOTAL HRS.

INSPECTOR . .BIT___SOILS ENGR.-I,GROUND WATER OBSERVATIONS AlMoistureper 6BlowsDepthsFrom- Toorloot1dense1bitUsedD -DryUP:some351050%V-StiffTestUT-Undisturbed Thinwoll

. . . . ,

LOCATION OF BORING-O-IOLooseIO- 30 Med. Dense 30-50DenseVery Dense Casing Refusal9*Top of TILL 9*sampled SHEETDATE HOLE NO. LINEOFFSET SURF. ELEV. WATER STREET Yankee  Electric Co.

ADDRESSICo., Inc.

iOUR JOB NO. .I!.GROUND WATER OBSERVATIONS Al  o f t e r- Hours ofterHoursHammer Wt.BITISH o m m e r

_ _ _Sue I.D.STARTCOMPLETE.TOTAL HRS.

BORING FOREMAN,INSPECTOR SOILS ENGR. LOCATION OF BORING:

GROUND SURFACE TO  USED Blowsfoot30From- ToDepthsBlows per 6 6MoistureDensityor--LZIITHEN Gray finefineto coarse Bottom of19*6Refusal w/roller bit RemorksType ofness,seoms ond etc Casing Refusal9*Strata change (TILL)siltonSompler CohesionlessCohesive ConsistencyO-IOLooseIO-30 Med.

DenseDense+ Very DenseUsedlittlesomeond350o-4 Soft4-8 M/Stiff T y p eDry CUP:Test A t - ofler _ _ _

after - -

Al DrillingBoring Co., Inc.

WATEREASTRDATE HOLE NO.LINESTA. OFFSET LOCATION OF----RemorksType ofelcSAMPLEond etc--RefusalStrata(TILL)11'6Gray fine coarsesilt23'2Bottom of Boring23'2"Roller Bit Refusal GROUND SURFACE TOIon 20.D.

D-DryTypeCohesiveO-IOLooseUP:IO 1020%o-4 Soft4-aA-Augers o m eI..STARTTOTALFOREMAN ENGR.CASINGCORE BAR.

I.D.Wt.GROUND WATER OBSERVATIONS ADDRESSCircrll.7t.i--LOCATION7SHEETAmerican DrillingBoring Co., Inc.

WATER STREETEASTR.SAMPLES SENT TO I i O U-- RI SURF. ELEV. TOcHOLE NO.LINE STA. OFFSET TOTALGROUND WATER OBSERVATIONS CASINGSAMPLERCORE BARs/s----START-COMPLETEHoursINSPECTOR I,Al  wt.....LOCATION OF BORING etcPen- - -Refusal24317wetdenseIIbit refusal Proportions Used Somplc Type littleIO 1020%UP-PistonTestDenseI.Dry C-CoredI0O-IOMed. Dense finefine tocoarsesilt:SOIL IDENTIFICATIONSAMPLERemorks includeofBottom of Boring13'Roller Bit Refusal onCohesive consistency o-4 Soft4-8 M/Stiffseoms ond etcNo SHEET American Drilling Boring Co., Inc.

100 WATER STREET TO ADDRESSILOCATIONiSAMPLES SENT TOt oGROUND WATER OBSERVATIONSCASINGSAMPLERCORE BAR.

HoursSTARTCOMPLETETOTAL HRS.

BORING FOREMAN SOILSIof DWt.BITH o m n e r- -DATE HOLE NO.LINESTA. OFFSET SURF. ELEV. 4UP-LOCATION OF BORING:

GROUND SURFACE TO USEDCASING:Type1015A-AugerTestIs o m e3II0IO. .IO-30 Med. Dense Used25 6-1*HEN CoredIBottom of Boring25*6coredGray QUARTZ onSamplerCohesiveoSot4-8OVERBURDEN OFFSETISURF.of Hours--3__TOElectricLOCATION STREET DATEHOLE NO. LINE STA. INSPECTOR ENGR.STARTCOMPLETETOTAL HRS.

SHEETAmerican DrillingBoring Co., Inc.

O F 1E l e vSAMPLEetcseoms ond etc SOILRemorks IncludeType ofOVERBURDEN Cl 60*IIII IBottan ofboring- 22*

Gray DIORITE CASING:THENoUseds o me4-B*StiffI..4GROUND SURFACE TO SomplcIon 20.D.

CohesiveConsistency FLOCATION OF BORING-SUMMARY:7-22-O-IOLooseo-4 SoftHordtrace0littleGROUND WATER OBSERVATIONS CASINGSAMPLERCORE BAR.

Hommer Wt.

HommerTestTestD -DryUP:  

--Sue I D.--_______I6"onMoistureSAMPLEofBlowsFrom- ToNo Pen- - -IIIOVERBURDEN II 21' -26' C4II IGROUND SURFACE TO  USEDIIIIBottom of Boring31'Gray DIORITE Include color,Type oftype,hord-seoms ond SampleProportions Used someWt.on 20. D.

CohesiveIO-30 Med. Dense4-8 M/Stiff Dense..O-IOLooseo-4 SoftC=CoredUP-TestV-Vane Test American Drilling & Boring Co., Inc.

WATER STREET SHEET DATENO.LINESTA- - -- -.__SAMPLES SENT TOYankee

----A D D R E S S LOCATION OF BORING-At  HoursCASINGSAMPLERCORE BAR.

COMPLETETOTALSTART.,SOILS ENGR. GROUND WATER OBSERVATIONS SHEETAmerican Drilling Boring Co., Inc.

SAMPLENo PenSOILRemorksType ofetchord-ness,seoms and

---710I21wet.denseBottom of Boring- 11*

GROUND SURFACE TO  USEDIITHEN Proportions Used351050%littleIOsomeWt.on0. Sampler CohesiveO-IOLoose4- 8M/ S t i f f vo - 4....Sample Type UP: Undisturbed Piston TestUT-IO-30 Med.

DenseDenseVery Dense OF BORING:COMPLETE---I.D.HoursHommer,.H o m m e r WATER STREETR ITOccLOCATIONTop of Ground GROUND WATER OBSERVATIONS CASINGSAMPLERCURE BAR.1 SOILS ENGR. DATE HOLE NO. LINE STA. OFFSET UPDATED FSAR APPENDIX 2G STATIC DYNAMIC ROCK PROPERTIES The information contained in this appendix was not revised, but has been extracted from the originaland is provided for historical information.

---------Tunnel127.5-127.9DioriteDiorite16,130x9.9 x 106 13,950Near ReactorsB728.2Schist17,94011 x 10610 x 106ContactB42123.5-123.9DiabaseSchistSchist27, 600x 10610 x 1069.1 x 1068.0 x 10610 x 1067.4 x 106 TABLEUNCONFINED COMPRESSION TESTS UnconfinedAxialInitialSecantPoisson's Ratio TestHoleRockCompressiveStrain@TangentModulusInitialSecantNo.LocationNo.DepthTypeStrengthFailureModulus50%LoadValue50%Reactor 1El-l31.8DioriteDioriteDioriteDioriteReactor 250.0DioriteDioriteDioriteDioriteDioriteDiorite12 x 10612 x 10619,5209.3 x9.3 x 10613 x 10611 x 10618,02012 x 10610 x 106Failed by splitting.Do not report.

15,53012 x 1069.9 x 106 5,97012 x 1069.7 x 10610 x 106xTunnelF2246.3-246.7Schist6,060Schist6,000Schist6,330NOTE:In tests for which values of axial strain at failure, modulus,and Poisson's ratio are omitted, the strain-gage readings appear to be unreliable,No stress-strain curves are plotted for these tests.

Test No.LocationHole No.Reactor 1 Reactor 2 Reactor 2 B 42 BContactB 42 GContactTunnelTunnelE l - lB 42B 42F 2TABLELABORATORY COMPRESSION WAVE VELOCITY MEASUREMENTS Depth(Feet)Rock Type 79.980.3Diorite51.251.6Diorite139.1139.4Diorite122.5123.0Diabase141.8142.3Schist128.7129.2Diorite259.0259.4SchistLaboratory Compression Wave Velocity 0 psi3000 psi2.8119,46019,8802.8318,86019,0902.7720,05020,3002.8418,60018,8002.7716,96017,3202.7920,05020,3402.8618,11018,370 TABLE016.19316.43716.47916.49616.63117.91116.77116.11116.62116.07117.61117.07,I.99.94.m,6.326.014.01mSERIESEl1ID6.UI71336947I26061Is466737Il.U2.616.11:6.363.616.133.337.:70'3.236.006.944.667Y 6.976' 12.19.116.44.664.7699 10.:36323.722.763.264.032.612.714.043.422.612.723.163.414.0119.3067.0266.91019.16324,79619,0360.240.941.460.910.391.440.311.431.361.07quartz,very*lcrr.med.tofeldspar.

*ical.med. tofine*lcu; rd.rd.withquartz-rich totord.sulfides;onlyschisttonllbutpn-*rlst,n# but STRENGTH, VELOCITY, AND HARDNESS DATA SAMPLES FROM TUNNEL ALIGNMENTS M-lM-IM-17f-617.40417.691IS.01417.33616.74717.62416.06616.627I67.0.267.1 266.6-267.6 267.0-267.7 73-6473-6673-w73-I)73-6216.99216.27116.37016.41014.99617.06316.34316.66217.60616.49216.31216.61616.01416,99617.00716.42316.64016.6272.932.m2.732.112.713.012.11 Amendment 45 June 1982 FSARAPPENDIX 2G STATIC AND DYNAMIC ROCK PROPERTIES FigureTitle Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve Unconfined TestStress-Strain Curve 2610Unconfined TestStress-Strain Curve 2611Unconfined TestStress-Strain Curve NOTE: The stress-strain curves shown in Figures throughare terminated at the last strain reading before sudden, brittle failure. The maximum compressive load at failure was recorded by the testing machine and was used to calculate the compressive strengths contained in Table 00.10.20.30.AXIAL STRAIN 000.10.20.3Diorite= Modulus of DeformationEl-l Depth 79.1 to 79.5 UNCONFINED TEST E 1 F STRESS -STRAIN CURVE FIGURE STRAINAXIAL STRAIN 00.10.20.3itfi 1n 0^ o1)0. iV .4v .VDioriteM = Modulus of DeformationDepth 49. to 50. Oft UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE 00.10.20.3AXIAL STRAIN STRAINC0.20.30Diorite=of Deformation Depth 50.4 to 50.8 ft UNCONFINEDTESTSTRESS-STRAIN CURVE FIGURE AXIAL STRAIN 0.10.20.3AXIAL STRAIN SchistDepth 139.4 to 139 M =of Deformation UNCONFINED TESTJ STRESS-STRAIN CURVE FIGURE FIGUREAXIAL STRAIN 00.20.3SchistUNCONFINED TESTSTRESS -STRAIN CURVE

=of DeformationDepth 141.9 to 142.3 STRAIN. %

c0.10.20 00.10.3AXIAL STRAIN UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE7SchistDepth 27.8 to 28.2 MDeformation AXIAL STRAIN DiabaseM =of DeformationB-12 Depth 123.5 to UNCONFINED TESTSTRESS-STRAIN CURVE FIGUREAXIAL STRAIN SchistM = Modulus of DeformationB42 Depth 141.3 to 141.

AXIAL STRAIN UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE AXIAL STRAIN 000.10.3AXIAL STRAIN 0.10.3II/ ax.SchistM =of DeformationDepth 142.7 to 143.1 ft UNCONFINED TESTSTRESS-STRAIN CURVE FIGURE AXIAL STRAIN M I0 2.DioriteDepth 127.5 to 127.

M =of Deformation AXIAL STRAIN 00.10.3UNCONFINED TEST F IA STRESS-STRAIN CURVE FIGURE1 UPDATED FSAR APPENDIX 2H ROCK STRESS MEASUREMENTS IN BORING The information contained in this appendix was not revised, but has been extracted from the original FSAR and is provided for historical information.

STATIONROCK STRESS MEASUREMENTS IN BORING forYankee Atomic Electric Company andPublic Service Company of New Hampshire September 1973 Geotechnical Engineers, Inc.

934 Main Street Winchester, Massachusetts 01890 STATIONROCK STRESS MEASUREMENTS IN BORING CONTENTSPageSUMMARY1.INTRODUCTION 1.1 Background11.2 Purpose11.3 Scope12.METHOD OF MEASUREMENT

2.2 The Overcoring Technique 2.3 TheGage2.4 Measurement of Modulus of Rock 2.5 Computation of Stresses 3.TEST DATA AND RESULTS

3.2 In Situ Stresses and Directions84.DISCUSSION OF RESULTS9APPENDIX A MEASUREMENT OF STRESSES IN ROCK BY OVERCORING IN VERTICAL HOLE APPENDIX B MEASUREMENT OF MODULUS OF ANNULAR ROCK CORE GEOTECHNICAL ENGINEERS INC.

GEOTECHNICAL ENGINEERS LIST OF TABLES TABLE 1 CALIBRATIONS TABLE 2TEST CONDITIONS FOR STRESS MEASUREMENTS TABLE 3 DATA AND RESULTS OF STRESS MEASUREMENTS LIST OF FIGURESLog of Boring3Log of Boring El-lPhotograph ofGage SystemPhotograph ofGagePhotograph of Rock Modulus CellData from Stress Measurements, Test 8Data from Stress Measurements, Test9Data from Stress Measurements, Test10Data from Stress Measurements, Test OClA-7Data from Stress Measurements, Test12TestHole DimensionsTestHole DimensionsTest OClA-6 Hole DimensionsTest OC-7 Hole DimensionsTest OClA-9 Hole DimensionsPhotographs of Annular Cores, Hole18Summary of Stress Measurements SUMMARYRock stress measurements were made in June and July 19*73 at depths of 33 ft to 42 ft in vertical Boringis about 34 ft from the center of proposed Reactor No. 1 of The results of five measurements ofstresses in the horizontal plane were:

diameter core around the inner hole.The rock modulus was measured by testing the annular core in a cell constructed to apply stress to the exterior of thewhile making deformation measurements in the inner hole with thegage.GEOTECHNICAL ENGINEERS INC SEA BROOK STATION ROCK STRESS MEASUREMENTS IN BORING forYankee Atomic Electric Company andPublic Service Company of New Hampshire Geotechnical Engineers, Inc.September 10, 1973

: 1. INTRODUCTION 1.1 Background Measurements of seismic velocities in the bedrock at the plant site at Station were made in the spring of 1969 by Weston Geophysical Research. These measurements indicated that the velocity in the port granodiorite ranged from 16500 fps to 18500 fps, whereas in the Kittery Schist the velocity was about 13000 fps.The velocities in the granodiorite were slightly on the high side, although not unusual in the area, and could be taken as a possible indication of in-situ stresses in the bedrock. There-fore, a modest program of stress measurement was undertaken in the zone where high velocities were measured at the location of one of the two pro-posed reactors. The measurements were made during June and July 1973.

1.2 Purpose The purpose of this report is to present the results of measurements of in-situ stresses in the Newburyport granodiorite in vertical Boringata depth of 31 to 43 ft using the overcoring technique.The coordinates of this hole are N20413, E796*71.

1.3 Scope One hole was drilled near the center of proposed Reactor at Station for the purpose of measuring in-situ stresses. Eleven measurements GEOTECHNICAL ENGINEERS were made using the overcoring technique.Each measurement consisted of three deformation readings in the horizontal plane on axes oriented apart. Of the eleven attempts, the data from five ofmeasurements, at depths of 33 ft 9 in. to 41 ft 5 in. , were deemed suitable for analysis and are reported herein. The other measurements gave poor or marginal in-formation because of rock fracture and /or equipmentduringovercoring.

Moduli of elasticity of the rock were measured (a) on two annular cylinders of rock removed after overcoring, and intact specimens oriented such that the load was* in the direction of the axis that was horizontal in-situ. Thesewere used with the measured defor-mations and published formulae to compute the magnitude and direction of the largest and smallest normal stresses in the horizontal plane. The ver-tical stress was assumed to be equal to the overburden pressure.

The test procedures used are described in detail in Appendix A and B.

2.2 The Overcoring Technique Fig. 1 is a sketch of the appearance of the hole during overcoring.APX hole, 5. O-in. diameter, was first drilled with a single-tube core barrel to the desired depth. In this case, this depth was the shallowest at which the rock was continuous enough to be tested, which turned out to be 31 to 43 ft below ground surface. Logs of Boringand Boring El-l (NX-size),

which are about 14 ft apart, are shown in Figs. 2 and 3, respectively.

2.3 TheGageA photograph of the instrument, the hose, the readout, and the pres-sure application system is shown in Fig. 4. The instrument, without its vinyl sheath, is shown in Fig. 5. The deformation is measured by bending of the cantilevers that are seen at the left in Fig. 5. The readout. of strain gages on the cantilever arms is proportional to the movement of the tips of the cantilevers. In this instrument three pairs of cantilevers were installed apart. In principle only three cantilevers are needed, but a fourth is necessary to be able to compute body movement of the instrument within the hole. To eliminate this computation, the cantilevers were in-stalled in pairs such that body movements cause zero output on the readout device. The instrument was designed and constructed by Pierre The tips of the cantilevers are attached to the vinyl sheath, Fig. 4, such that when air pressure (or bottlednitrogen pressure) is applied in-side, the cantilevers are forced against the side ofhole. Hence the hose serves the dual purpose of protecting the strain gage leads and passing air to the instrument. The readout is made on a conventional strain gage in-dicator.2.4 Measurement of Modulus of Rock To obtain the best value of the modulus of elasticity of the rock in the zone tested, it is necessary to remove the overcored annular cylinder of rock from the hole and test it in a rock modulus cell. In Fig. 6 an annular core is shown in the cell with the gage in the central hole of the core. To determine the modulus one applies pressure to the outside of the core, up to about 3000 psi, and then removes it in increments, measuring the deformation of the central hole for each pressure decrement. In this way one reproduces reasonably well in the core the stresses that it under-went during overcoring. The details of the measurement procedure are given in Appendix B.

ENGINEERS EkPEkPIThe direction of stressis obtained from the formula: :

tan'To supplement the measurement of modulus onannular cores, intact specimens of rock from Boringfrom depths where stress measurementsmade, were tested in unconfined compression. The specimens were loaded in the direction ofaxisin-situ so that the loadinsame direction as in situ. The rebound modulus of these specimens was measured with the aid of strain gages glued on the sides of the specimens.

2.5 Computation of Stresses The major and minor stresses in the horizontal plane were computed from the measurements using the followingfrom Obert where:= Stress at center ofcircles of stress, psi q = Radius ofcircle of stress psi E= Modulus of elasticity measured for same stress changes as occurred in situ, psi d = Diameter of central hole in which instrument is placed, in.

= Horizontal expansion of the diameter of the overcoring. The subscripts refer to axes that are 120 apart in the plane perpendicular to the axis of thegageinthis case horizontal. R is the reading in microinches/inch and k is the instrument calibration in in.

Ifand2R 1, then 0and2R1, then Ifandthen2 R1thenbut(5) above are based on the assumption that a plane stress condition exists at the measuring point in situ, i.e. that the vertical stress is zero. Since the vertical stress is very close to the overburden stress of about.

The results of calibrations ofinstrument and measurements of rock modulus are shown in Table 1. Direct calibration of Instrument, No, 2 with a micrometer yielded k = 10 in..Sincecan beread, the instrument can be used to discern movements in theassmall as 5 xInstrument, No. 1 wasdirectly, but it is capable of discerning movements of 2 x 10 in. in the borehole.

Thegages were calibrated under conditionstoin-situ conditions by using an annular aluminum cylinder of known modulus (10 xpsi) as a standard. Table 1 shows that Instrument No. 2 yielded k =, as compared with 10for the direct calibration above. Since the calibration in the rock modulus cell models very closely the in-situ testing conditions and since the modulus of aluminum is well known, the value of k = 8.6 in.for Instrument No. 2 is the better value and was used herein.

* Similarly k = 4.4was usedInstrument No. 1.

*The direct calibration was made without the vinyl sheath in place.The canti-levers were therefore unstressed. When the gage is in the borehole, the canti-levers are stressed to half their elastic limit. Hence, the direct calibration is not as appropriate as the calibration which makes use of a standard annular cylinder.

GEOTECHNICAL ENGINEERS INC.

ReboundModulusFromTestSpecimens were cubes 1.2 in. on side.

The range of possible moduli of the granodiorite is from about 3 to xpsi. The larger values were measured on small intact specimens using strain gages, whereas the smaller values were measured on the an-nular cores using a loading sys tern and measuring device which were iden-tical for practical purposes to in situ conditions. Hence the moduli used in the computations were those measured on the annular cores.The factthat one intact specimen of granodiorite had a modulus of only 5 xpsigives some confidence in the use of a still lower modulus for the large an-nular cores, because they can be expected to contain more defects than the smaller specimens.

Fig. 18 shows to scale the computed stresses and directions for the best estimated values. Table 3 shows the numerical values for these best estimates as well as other possible values for Tests7, and9. These additional values arise from alternate selections of the changes in reading from Figs. 7, 10, and 11.

This average is 1240 psi (87 bars) for the major stress and 860 psibars)for the minor stressplane. The vertical stress is equal to the overburden pressure of about.psi,At the bottom of Fig. 18 is a tabulation of some known previous stress measurements in New Englandand Sykes, 1973). The general agreement.

TABLES TABLE 1 CALIBRATIONS Change in Reading per 10 Instrument No.for each Channel, Calibration Avg210010010310110B. CALIBRATIONS USING ANNULAR CORES IN ROCK MODULUS CELL No.Change in Reading per for each Channel, psikEMedium- -767876774.410Al4041398.610Al413939408.610Al2001731921884.44.1diorite1351401301353.0dioriteUnderlined values computed using equation for thick-walled cylinder under ex-ternal pressure for OD = 4.31 in, ID = 1.50 in.:=The quantity is equal to the diametral deformation.

33369383393415Granodiorite Granodiorite Granodiori te Granodiorite 21222Calib.kin.8.64.48.68.68.64.14.14.13.03.0285165285255240ModulusEpsiTrueAzimuthChanneldeg.TABLE 2 TESTFOR STRESS MEASUREMENTS in. = microinches

ENGINEERS TABLE 3 DATA AND RESULTS OF STRESS MEASUREMENTS ReadingChangeduringOvercoring inpsiCompressive StresstalPlaneBearingofpsi13351025N 38 E8095(1090)53692030015050N 553836011090119085039325015025021501570N 45 E250(1710)75 E)25015 0(1970)(1470)60 E)415901951001400800N 48 E195100(1470)36 E)1)Readings are shown for data from Channels 1, 2, and 3 on instrument. For all tests exceptthe numbering of the channels, eachapart, was counterclockwise. Forit was clockwise. In the equations for com-putation of the angle between theand the Channel 1 directions, the number-ing is assumed to be clockwise. Hence for all but Testandshould be exchanged when computing this angle.See text for equations used for computations.

GEOTECHNICAL. ENGINEERS FIGURES Bottom PX Hole PX Barrel-Start Measuring Point PX Barrel-Finish BottomHoleElectricGeotechnical Engineers, Inc AtomicSTATIONSKETCH OF HOLE DURING OVERCORING

: 10. 1973FIG. 1Hose andforGageNW Casing 0 (El. 28 Overcoring Barrel in. OD, 4.2 in. ID ENGINEERS Ton El.28.0Multipledrillingbreaks.,\\jointDrillingbreakDrillingbreakDrillingbreaksFeldspar-Multiple joints, with piecesnesiumBiotite 10%

Joint set intersecting at.6Tight joint Joint slightly rusty Rusty joint Rusty joint Two tight joints Joint rusty Tight joint broken by drillingjointRusted joint tight joints, rusty Quartz diorite. Dark gray, medium

Pegmatite dike,wide, at about Contact:dipdike, coarse N 20413; E 79671byI*.REMARKS Log isto a large scale, only for range of depth where stress mea-surements were attempted. Photographs of cores from tested depths are shown in Fig. 17. Log of Boring El-l, 14 away, shown in Fig. 3. Depth of stress measure-ments are shown above IFIG. 2303234404244 Top El.25.9Dec. 26,DIPOF CORE GRAPHIC Quartz diorite, medium finemediumMassive(not.foliated.

65 Dip Diplets as shown.

Quartz diorite, as above, hlassive, medium fine medium grey.

-on lowangle (3)Core- R u s t y allybyto moderate weathe

-jointsevening on joints as Most joints dip ab 10to in-jointsBreaks on angleing minor vuggi Chips, rustyock is fresh.

Slijointrustto minorslightcoatingsght weather-30-to 1.5* in-

- weathering 4on some joints.

40 Breaksto pieces Joints are nor-rustmally clean.

jointNot rusty.

.minor rust

\roughtodips. Joints slight weather- not ingas shown.

Rock is fresh.

FIG. 320STATIONLOG OFEl-lCoordinates:20400; E 79675 J. R. Rand GAGE SYSTEM BOREHOLEGAGE (vinyl sheath removed)

ROCK MODULUS CELL ENGINEERS Depth of Measuring Points 33 ftin.12345678Depth of Overcoring, in.

Massachusetts STATIONDATASTRESSMEASUREMENTS

'TEST8, 1973FIG. 7Project 7286 TEST0246812Depth ofin.Instrument230in. /in.0. 001 in.Hole I.D.in O.D. -4.31 in.

ProjectAug. s,FIG.10002004002003005004007006008000Depth of Measuring Points AtomicElectric Company Engineers, Inc.

DATA FROM STRESS MEASUREMENTS YankeeElectric Company STATIONProject 7256 Depth of Measuring Points 38 ft 3 in.

0134567Depth of Overcoring, in.

O.D.4.31 in.DATASTRESSMEASUREMENTS TESTAug. 8,FIG. 9 STATION200100020010003002001000124567Depth of Overcoring, in.

Instrument Calibration 116 in. /in.0. 001Hole I.D. = 1.495 in.

Yankee Atomic Electric Company GeotechnicalInc.Winchester, Massachusetts Aug.1973FIG. 10GEOTECHNICAL ENGINEERS DATA FROM STRESSMEASUREMENTS TEST Depth of Measuring 1345678Depth of Overcoring, in.

DATA FROM STRESS Yankee Atomic MEASUREMENTS STATIONElectric Company TESTGeotechnical Engineers, Inc.

,Aug. 8, 1973FIG. 11Massachusetts Project 7286 GEOTECHNICAL ENGINEERS NW Casing PX Overcoring Barrel 5.0 in. OD, 4.2 in. ID 4.54 in.33 ft, 5.5 in. BottomHole3 3 ft, 6 in.PX Barrel-Start 33 ft, 10 in.Measuring Point 34 ft, 3 in.PX Barrel-Finish EX Hole1.5 in. ID 35Bottom Hole andforGageISTATION,Project 7236June 20, 1973FIG. 12TESTHOLE DIMENSIONS GEO*TECHNICAL ENGINEERS Yankee Atomic Electric Company Gcotechnical Engineers, Inc.

Winchester, Massachusetts 028NW Casing Overcoring 5.0 in. OD, 4.2 35 ft, 9 in.

36 ft, 5.5 in.

I1EX Hole1.5 in. ID 37 ft, 7 in.

TESTHOLE DIMENSIONS Geotechnicsl Engineers, Inc. Winchester,7286Yankee AtomicSTATIONElectric CompanyHose and Wires forBottomHolePX Barrel-Start Measuring Point PX Barrel-Finish Bottom EX Hole June 27, 1973FIG. 13GEOTECHNICAL ENGINEERS INC.

NW Casing

-I-Hose andforGage37 ft, 10.8 in.

Bottom Px Hole37 ft, 11.3 in. PX Barrel-Start 38 ft, 3 in.Measuring Point III-- 3 8 ft, 6.5 in. PX Barrel-Finish 4.2 ln.iEX Hole1.5 in. ID 39 ft, 11.8 in. Bottom EX Yankee Atomic Electric Corn STATIONTEST OCIA-6 HOLE DIMENSIONS eotechnical Engineers, Inc.

HoseWires for GageNW Casing PX Overcoring Barrel 5.0 in. OD, 4.2 in. ID I38 ft, 8 in.Bottom PX Hole 38 ft, 11.5 in. PX Barrel-Start 393 in.Measuring Point

-- 39 ft, 6.6 in. PX Barrel-Finish in.EX Hole1.5 in. ID ft,in.EX HoleYankee Atomic STATIONTEST OCHOLE DIMENSIONS ProjectEngineers, Inc.

U-inches ter, Massachusetts June 28, 1973FIG. 15GEOTECHNICAL ENGINEERS INC.

H o s efor - -GageNW Casing PX Overcoring Barrel 5.0 in. OD, 4.2 in. ID iII--6 in.IIIEX Hole1. 5 in. ID 42 ft, 3 in.Bottom EX Hole 40 ft, 1 1 in.Bottom PX Hole 41 ft, 1.5 in. PX Barrel-Start 41 ft, 5 in.

,Project 7256 STATIONGEOTECHNICAL ENGINEERS INC.

HOLE DIMENSIONS TESTJune 29, 1973FIG. 16Yankee Atomic Electric Company Gcotechnical Engineers, Inc.

TRUENORTH2000 psiWBoringN 20413, E 79671, El. 28 Depth toMAXIMUM IN-SITU COMPRESSIVE STRESSES ON HORIZONTAL PLANE Nuclear Station, New Hampshire June July, 1973 PREVIOUS STRESS MEASUREMENTS NEW ENGLAND LocationMass.W. Chelmsford, Mass.bars54354576BearingRock Type N 14 EGraniteN 4WDolomiteN 2WParagneiss N 56 EGranite8559N 40 EGranodiorite145)(3 106)All stresses measured at depths less than 50 m (160 ft)

Stresses are compressive One bar is 14.5 psi L. and Sykes, L. R. (1973)Compressive Stress and Seismicity in Eastern North America: An Example of Intra-Plate Tectonics, Geological Society of America Bulletin, Volume 84, No. 6,1871.Yankee Atomic Electric Company STATIONProject 7286 SUMMARY OF STRESS MEASUREMENTS Sept. 7, 1973Fig. 18,Barre, Vt.

Select desired orientation of measuring points on instrument.Ifpossible, orient one axis in direction of anticipated major stress.

APPENDIX A CEOTECHNICAL ENGINEERS INC 16.Inflate the instrument to a pressure of about 4greaterthan the water pressure at that depth, but not greater than about 6above the water pressure.

32.Carefully and in detail describe the core, particularly within 3 in.,

on each side of the measurement point.Photograph the core wet and dry, making sure that the crayon mark shows up.

APPENDIX A GEOTECHNICAL ENGINEERS CHECK THE DATA SHEET, SKETCHES AND DESCRIPTIONS TO EN-SURE THAT ALL DATA NEEDED FOR UNDERSTANDING THE TEST HAVE BEEN RECORDED. LIST THE NAMES OF ALL PERSONNEL AT THE SITE.

APPARATUS 1.gage for EX hole (1.5-m. dia. ) including hose containing lead wires and air tube.

5.Datasheets,formattached.

6.Orientation rods for setting the gage elevation and formaintaining orientation of gage.7.Compassfordeterminingorientationofgage.APPENDIX A GEOTECHNICAL ENGINEERS OVERCORING READINGSII, NEW HAMPSHIRE DepthsProject No. Date TestBot. 5-in. HoleDrillerRot. EX Hole  EngineerPins on Gage  WeatherDimensions in  Page 7Strain Gage Readings 45IiIIIGeotechnical Engineers, ElapsedTime123457810111213141516III123DepthNo.Hole Location El. Top of Hole El. Datum Orientation of Gage APPENDIX APPENDIX B MEASUREMENT OF MODULUS OFROCK CORE Geotechnical Engineers Inc.

8.Apply pressure to exterior of rockin increments of 500 psiuntilthe compression of the diameters is equal to theirextension during coring but do not exceed 3000 psi unless an axial load is put on the core.

B2Pwhe re :=deformation instrument calibration R = instrument reading d = I.D. of core b = 0. D. of core P = external pressure E = rock modulus GEOTECHNICAL ENGINEERS INC UPDATED FSAR APPENDIX 21 GEOTECHNICAL REPORT ADDITIONAL PLANT SITE BORINGS The information contained in this appendix was not revised, but has been extracted from the original FSAR and is provided for historical information.

1.2 Scope 2.0 BORING AND TEST PIT DATA 2.1 Table and Figures 2.2 Boring and Test Pit Logs Summary of Boring Data FIGURESG-Series Borings; Plan of Boring Locations, Fig. 1 Grain Size Curve, TestTP Sample, Fig. 2 111333APPENDIX I Boring Logs and Description of Exploratory Test Pit APPENDIX IIDriller's Logs  

1.1 Purpose The purposethe geotechnical investigation was to provide soil and bedrock descriptions pertinent to the design and construction of several proposed structures which will be located at the plant site, in-cluding water and oil storage tanks, settling basin, retaining wall, and rip-rap structures.

b.Settling BasinA series of three borings was made in the area of a proposed settling basin using standard split-spoon sampling techniques to refusal for the purpose of invest-igating soil conditions at the proposed inlet and outlet structures for the basin, and also to examine the in-situ soil for possible use as construction materials forInaddition, a test pit bag sample was taken near the center of the settling basin, tested for grain size distribution, and examined as a possible dike material.

posed retaining wall for the purpose of locating and sampling the dense glacial till.These borings were advanced by first "washing" to establish the top of the till layer, then sampl-ing this layer by split-spoon techniques, and finally ad-vancing theto refusal using a roller bit.Based onthe results of geophysical surveys andborings drilled into bedrock in the vicinity, it is believed that refusal does correspond to the bedrock surface in these holes. 2.0 BORING AND TEST PIT DATA 2.1 Table and Figures Table I is a summary of the boring data including boring location, "as-bored" coordinates, ground elevation, depth to glacial till, and depth to top of bedrock.

TABLES TABLE ISURIRIARY OF BORING Boring No.

Boring Location As-boredGround Elev Depth toDepth toTop of Tillof Bedrock G-lG-2G-3G-4G-5G-6G-7G-8G-9G-10G-11G-12Oil Storage Tank Settling Basin (Inlet)Settling Basin (Outlet)Settling Basin (additional)

--s.L______,TP=10'100'200'300WO_..Pr MOM.,--_____.

*-.' '0....._1111111117111,11.:"

.11. -ILI21,000-1 /11111111.000 P'xiii' IREElltirillilltilligatitalblEEMEIVilliallik tratillittE_

MIIMERADIONEw 1;C3`ill(.111111111111111111PLi-Zs.'

: G-, -'=.---th---) r---1111-::- - k:: 20,00C10, ,-,-17timmrdww

--T--soo.wim-.V,4---.4'VIIMI-.R /tAPUBLIC SERVICE COMPANY OF NEW HAMPSHIRE SEABROOK STATION SEABROOK STATION SITE TOPOGRAPHY AND PLOT PLAN PLAN OF BORING LOCATIONS UNITED ENGINEERS G CONSTRUCTORS GEOTECHNICAL ENGINEERS, INC.

OCT. 17,1974FIG.I0- SERIES BORINGS Lab. 4-3, rev. 0 28 May 74 U.S. STANDARD SIEVE OPENING IN INCHESU.S. STANDARD SIEVE NUMBERSHYDROMETER 70 100 140 200 1020000IIII I1005050.10.050.010.005GRAINGRAVELOR CLAYICOARSECOARSEMEDIUMIYankee Atomic Electric Co.

StationGeotechnical Engineers, Inc.

Winchester, Massachusetts GRAIN SIZE CURVE TEST PITTP SAMPLE Project 7286 1974Fig. 2 APPENDIX I ofNo. : 7286 NO.Ground Elevation Depth toLevel:at ground elcv. 0700; Date: Sent. 30. 1974 Described by:PittSampleNO.DepthofperDescription S-l0. O-1.0l-2Black, soft PEAT and organic SILT; highly decomposed

: 1. O-2.06-14Gray-brown, gravelly, sandy, slightly organic SILT, contains subangular gravel up to 35 mm in size.

s-23.0-5.0Rust brown and brown slightlygravelly,sandy32-23SILT, trace clay. Contains gravel up to13 mm in size.

s-35.0-6.527-39SimilartoS-2.57Contains gravel up to 35 mm in size.

colorchanges-410.0-11.5 hammer gray, very dense,sandy,gravellySILTtrace clay.

hammer contains broken pieces of gravel up to 28-2235 mms - 554hammerSimilar to S-4 12hammer40Casingrefusalat16.5Bottom of End of Exploration SampleNo.DepthNuofperDescription S-l0.O-1.02-5Light brown, silty fine SAND. Contains root fibers and decomposed organic matter.

1.0-2.03-2Dark brown/rust brown/gray mottled; fine sandy SILT, trace fine gravel s-23. o-4.5hammerLight brown, gravelly, sandy SILT.22-42hammerContains gravel from various logies up to 35 mm in size.

s-35.0-7.015Light brown silty, gravelly, fine to coarse SAND 23widely graded,* resembles glacial till 2333s-4LO. O-11.5 57-100hammerGray brownbrown slightly 33hammerdense, silty, gravelly SAND (similar to S-3) Contains broken pieces of gravel up to 35 mm in size.Casing refusal met at 13.8*

G - 2 1 of 1 No. : 72861, 1974 Described by: Ground Elevation Depth toLevel: -5.1* measured at 0715,  1, 1974*S-ls-20.0-2.03.O-5.05*10-2021-20Brown grading to buff, soft, homogeneous SILT, trace clay. Uppercontains grass andzone.Similar to S-l, buff/rust brown mottled, contains black spots decomposed organic matter? ?; trace roots and mica particles s-36.0-7.014-16Light brown, loose, silty fine SAND, trace clay S-3A7.0-8.022-32Rust brown/buff medium dense, mottled SILT, little to trace clay.Low plasticity.

s-4s-510.0-12.15.0-17.C 2-44-5C 2-33-4Gray,mediumstiff homogeneousCLAY;highplasticity SimilartoS-4S-619.5-20.C 32Gray-brown silty, sandy, GRAVEL; trace clay. Con-tains angular pieces of gravel up to 25 mm.

graded.S-6A20. o-21.5 20-12Light brown, gravelly, sandy CLAY. Contains gravel pieces up to 25 mm in size 25-25.5hammer Similar to S-6, very dense hammer (Resembles glacial till) continued)

NO.S-83 0.0 - 31. 5 25Gray, very dense, silty fine SAND, some gravel up to 2530 mm in size 58s-9hammerNo recovery hammerCasing refusal at Bottom of Endof Exploration SampleN o.DepthNumberofBlowsDescription perS-l0. o-o. 5 1Dark brown, fibrous PEAT and organic SILT S-lA0.5-2.l-l-2Light brown, fine sandy SILTsilty fine SAND s-23. o-5.6-10Light brown/dark brown/rusty brown slightly mottled, 22-42medium dense, silty, gravelly fine SAND. Contains gravel up to 35 mm in size.

s-36-7.5hammerSimilar to S-Z, medium dense to dense 35-60hammer8.0Largecobbles-410.0-11.5 25-50Similar to S-3, coarse to fine SAND 57Widelygradeds-515.0 -16.2 100'0"hammerSimilar to S-4 4260hammer75S-620-21Gray,verydense,gravelly,siltycoarsetofineSAND;littletotraceclay.(Till)Rollerbitrefusalat22.5Bottom of End of Exploration Ground Elevation Depth to Water Level: Not taken BORING NO. G-4

- 1 of 1 -

No. :72862, 1974 Described by:Pitt19 Ground ElevationftDepthNot takenDescribed by: SampleNo.DepthofBlowsperDescription Drove casing to 9.0* , where encountered strata changecasing refusal Split-spoon at 9.09.7S -l9.0-9.7hammergray/brown slightly mottled, very hammerdense silty, gravelly, SAND; little to to trace clay, (Till)

Bedrock ?

Bottom of Endof Exploration BORING NO. G-5 Proj. No. :

7286 3, 1974 Oct. 3, 1974 No.: 7286 Ground ElevationftDepth to WaterNot takenDescribed by: No.DepthNumberofBlowsperDescription Drove casing to refusal9.0'Roller bitted to10.8'strata change Split-spoon attempt at 10. 8' S-l57830hammer gray, very dense, sandy, gravelly SILT, trace to little clay.(Till)hammerRollerbitrefusalat19.5'ofEnd of Exploration NO. G-G1 of 1 No.DepthNumberofBlowsperDescription Drove casing to Roller bitted to 11.5*strata change S-l11.5- 13.0 249222hammergray, very dense gravelly, silty SAND trace to little clay. (Till)

RolflereLitted to refusal at 23.2 Bottom of Endof Exploration NC). G-7 Ground ElevationftDepth loLevel: Not taken

- 1 of 1 -

Proj. No. :  7286 Date: Oct. 3. 1974 Described by:  Pitt 23.2 NO. G-8pg. -of-Proj. No. : OctoberGround Elevation Depth to WaterNot TakenDescribed by: No.DepthitNumberofBlowsperDescription 10.1Cobble. Drove casing to refusal at 10.5. Strata change.S-l12.018-16-24Gray, medium dense clayey silty, SAND, little to trace.Gravel containsgravel up to 15 mm in size.Medium plasticity, well graded. Moderate reactiontoshakingtest.Bottom of borehole, roller bit refusal at 19.0*.

10.519.0 Run No.Depth ft.

%NX-1*NX-2NX-3NoSamples --Washedthroughoverburden TOP OF ROCK 15.520.525.5REC =100%RQD =96%REC =100%RQD =76%REC =100%RQD =80%IGray/white mixed fine and mediumDIORITE.Minorjointing.Freshandhardthroughout.Minoron joint surfaces.

SimilartoNX-1;minortomoderately jointed.Jointsrusty; vuggy. Moderate weathering on joint surfaces.

Described by: W. Pitt Ground ElevationftDepth toNot Taken BORING NO. G-10 Ground ElevationftDepth to Water Level: Not Taken 1 of 1Proj. No. :

7286 October 8, 1974 Described by: Pitt Run NoDepth ft.

Recoveryand%Description NoSamples --Washedthroughoverburden TOP OF ROCK Roller bitted to 7.0 ftIREC =Gray, mixed fine and medium g-rained DIORITE.

=out.Moderatelyweathered;rustyonjointsurfaces.

65%NX-2REC =Similar to NX-1; intact rock generally fresh and hard.

17.0100%Moderate to severe weathering on joint surfaces.

=62%NX-3REC =Similar to NX-2;generally fresh and hard throughout.

22.0100%Moderatewe*atheringonjointsurfaces.

=75%Bottom of boringEl. -29.9 ft.

6.5,22.0' Run No.Depth ft.

Recoveryand%Description NoSamples -- Washed through overburden TOP OF ROCK IIIIIRoller bitted to 16.0 ftIIINX-116.REC =Gray, mixed fine and mediumDIORITE;-21.092%RQD =55%semi-schistose in texture.Moderatelyjointedwithseveralhighanglejoints.Generally hardand fresh throughout withminor clay infilling onslicked joint surfaces.

NX-221.REC =Similar to NX-1,moderately hard; vuggy in places with 26.0100%severalweathered,highanglejoints.RQD =67%NX- 326.REC =Similar toNX-2;moderatetosevereweathering on 31.0joint surfaces.

RQD =68%ofBottomboringEl.15.9*31.0*GroundftDepth to WalerNot Taken BORING NO. G-11

-of 1 -Proj. No. :

1Proj. No. :

7286Date:Described by: Pitt SampleNo.DepthNumberofBlowsperDescription S-l1.0l-4Brown-black soft PEATand organicSILT, highly decomposed, root mass throughout.

6-6Gray-dark brown mottled,loose fine tomediumSAND,little to trace silt.

------ COLORCHANGE --- Gray, slightly micaceous, similar to s-25.0-6.5-12-21-28s-310.10.9hammer. Gray, homogeneous CLAYHammer. High plasticity BottomholeofRoller bittedrefusal.Bedrock or large boulder.

Depth to Water Level: Not Taken OFLocationadjacent toWater:encountered Coord. 21, October 3, 19747 2 8 6DatePitGround Elev. :

SoilO-1.0Black-brown fibrous PEAT and organic SILT 1.0TPSamplelight brown-yellow brown, loose, silty fine SAND, cobbles found. throughout.

Test pit was hand dug to a depth of approximately2ft1.0' APPENDIX DrillingCo., Inc.

WATER STREETPROVIDENCE, R.

OFFSET ILOCATION OF BORING:

SHEETSAMPLEChongeIDENTIFICATIONType ofetc.seams ond No-S i l tverydenseBrown fine trace coarse sandfineto coarse9*moisthardclayeyto medium sandtocoarse gravel (TILL) 5 1*16.5*Bottom of Boring16.5*.IGROUND SURFACE TO *HEN Usedon0.SUMMARY:trace0O-IOLooseIO.30 Med. Dense Dense+ Veryo.4 Soft4.8some201035%Sompte Type O-Dry W-washed UP:V=Vone Test Undisturbed O F 1TOtoiISTARTHours,*.American DrillingBoring Co., Inc.

WATER STREET ADDRESS LOCATIONENGR.U  HoursGROUND WATER OBSERVATIONS SENT TOCOMPLETETOTAL HRS.

DATENO.LINESTA.I OFFSET SURF.CASINGSAMPLERSue I.D.l-3--Hammer Wt.BIT--LOCATION OF BORING:

GROUND SURFACE TO USED452IFrom - To onBlows per IIISamplerTOIMoistureDensityorhonge- -14.54*1*THEN I3rown fine silty sandfine-coarse IBouldersifinetrace fine gravel, trace of

,(Refusal cas.-12*6-drilled w/roller bit to 14*6)

- ---SOILIDENTIFICATIONType ofhord-Bottom of Boring14.5*SILT (Tonsoil) and etc.SAMPLENo. Pen Re:

2124Sample Type UsedWt.onSampler0IODenseo n d,+ Very Dense UP:PattonTestUT= Undisturbed Thinwoll some 201035%

IO-30 Med. Dense u-44-B WATERWATER STREETHoursDrillingCo., Inc.

tiommer0.ADDRESSCASING SAMPLERCORE BAR.

3NOBITCOMPLETEINSPECTOR TOTAL HRS.

STARTSOILSSHEETDATE HOLE NO.LINESTA. OFFSET SURF. ELEV. LOCATION OF BORING

--per 6MoistureSampleonSampler DepthsChongeFrom- TOSwetsoftIBrown SILT 24II612*7siBrown silty Gray CLAY wet3stiff4,tii6*18*12sandy175045.3028*fineIS442558ium gravel IIUsedon 20.D.

Consistency 0o-4 SoftO-IOLooseUP:littleIOIO-30 Med. Dense 4-8some30-50Densefond351050%Very Dense

.GROUND SURFACE TO .TestA-Auger V-Vone Test UT= Undisturbed stiffwetverydenseGray silty f ine-med Bottom of Boring34*10Refusalsilty sandy GRAVEL  

--I D.HommerHoursSHEETDATELINE 8 STA. OFFSET SURF.WATER OBSERVATIONS I--P COMPLETETOTALSTART3.H o m m e r  SOILS LOCATION OF BORING:

AtomicCo.TOADDRESS -I LOCATION SAMPLES SENT TOCASINGSAMPLERCORE1*6 after-23 Hours

--SampleSAMPLE.4*j19*22.5*GROUND SURFACE TO Proportions Used onSomplcrSample Type DensityW-WashedV-StiffUP= Undisturbed TestTestBlows per 6 tmce0littlesome,+ Very Dense Brown fine sandy SILT Brown finecoarsesandfine-coarse gravel trace of silt SOIL IDENTIFICATIONType ofhard-ondGray siltyfineto coarse gravel Bottom of22.5*RefusalRoller Bit (ionsoi.lSILTCohesiveConsistency o-4 Soft4-8 M/Stiff Stiff

_ __ Hours A t - I D.AmericanGo., Inc.

100 WATER STREET CoTOI-CASINGSAMPLERCOREBARamSTARTsCOMPLETETOTAL HRS.

INSPECTOR . .BIT___SOILS ENGR.-I,GROUND WATER OBSERVATIONS AlMoistureper 6BlowsDepthsFrom- Toorloot1dense1bitUsedD -DryUP:some351050%V-StiffTestUT-Undisturbed Thinwoll

. . . . ,

LOCATION OF BORING-O-IOLooseIO- 30 Med. Dense 30-50DenseVery Dense Casing Refusal9*Top of TILL 9*sampled SHEETDATE HOLE NO. LINEOFFSET SURF. ELEV. WATER STREET Yankee  Electric Co.

ADDRESSICo., Inc.

iOUR JOB NO. .I!.GROUND WATER OBSERVATIONS Al  o f t e r- Hours ofterHoursHammer Wt.BITISH o m m e r

_ _ _Sue I.D.STARTCOMPLETE.TOTAL HRS.

BORING FOREMAN,INSPECTOR SOILS ENGR. LOCATION OF BORING:

GROUND SURFACE TO  USED Blowsfoot30From- ToDepthsBlows per 6 6MoistureDensityor--LZIITHEN Gray finefineto coarse Bottom of19*6Refusal w/roller bit RemorksType ofness,seoms ond etc Casing Refusal9*Strata change (TILL)siltonSompler CohesionlessCohesive ConsistencyO-IOLooseIO-30 Med.

DenseDense+ Very DenseUsedlittlesomeond350o-4 Soft4-8 M/Stiff T y p eDry CUP:Test A t - ofler _ _ _

after - -

Al DrillingBoring Co., Inc.

WATEREASTRDATE HOLE NO.LINESTA. OFFSET LOCATION OF----RemorksType ofelcSAMPLEond etc--RefusalStrata(TILL)11'6Gray fine coarsesilt23'2Bottom of Boring23'2"Roller Bit Refusal GROUND SURFACE TOIon 20.D.

D-DryTypeCohesiveO-IOLooseUP:IO 1020%o-4 Soft4-aA-Augers o m eI..STARTTOTALFOREMAN ENGR.CASINGCORE BAR.

I.D.Wt.GROUND WATER OBSERVATIONS ADDRESSCircrll.7t.i--LOCATION7SHEETAmerican DrillingBoring Co., Inc.

WATER STREETEASTR.SAMPLES SENT TO I i O U-- RI SURF. ELEV. TOcHOLE NO.LINE STA. OFFSET TOTALGROUND WATER OBSERVATIONS CASINGSAMPLERCORE BARs/s----START-COMPLETEHoursINSPECTOR I,Al  wt.....LOCATION OF BORING etcPen- - -Refusal24317wetdenseIIbit refusal Proportions Used Somplc Type littleIO 1020%UP-PistonTestDenseI.Dry C-CoredI0O-IOMed. Dense finefine tocoarsesilt:SOIL IDENTIFICATIONSAMPLERemorks includeofBottom of Boring13'Roller Bit Refusal onCohesive consistency o-4 Soft4-8 M/Stiffseoms ond etcNo SHEET American Drilling Boring Co., Inc.

100 WATER STREET TO ADDRESSILOCATIONiSAMPLES SENT TOt oGROUND WATER OBSERVATIONSCASINGSAMPLERCORE BAR.

HoursSTARTCOMPLETETOTAL HRS.

BORING FOREMAN SOILSIof DWt.BITH o m n e r- -DATE HOLE NO.LINESTA. OFFSET SURF. ELEV. 4UP-LOCATION OF BORING:

GROUND SURFACE TO USEDCASING:Type1015A-AugerTestIs o m e3II0IO. .IO-30 Med. Dense Used25 6-1*HEN CoredIBottom of Boring25*6coredGray QUARTZ onSamplerCohesiveoSot4-8OVERBURDEN OFFSETISURF.of Hours--3__TOElectricLOCATION STREET DATEHOLE NO. LINE STA. INSPECTOR ENGR.STARTCOMPLETETOTAL HRS.

SHEETAmerican DrillingBoring Co., Inc.

O F 1E l e vSAMPLEetcseoms ond etc SOILRemorks IncludeType ofOVERBURDEN Cl 60*IIII IBottan ofboring- 22*

Gray DIORITE CASING:THENoUseds o me4-B*StiffI..4GROUND SURFACE TO SomplcIon 20.D.

CohesiveConsistency FLOCATION OF BORING-SUMMARY:7-22-O-IOLooseo-4 SoftHordtrace0littleGROUND WATER OBSERVATIONS CASINGSAMPLERCORE BAR.

Hommer Wt.

HommerTestTestD -DryUP:  

--Sue I D.--_______I6"onMoistureSAMPLEofBlowsFrom- ToNo Pen- - -IIIOVERBURDEN II 21' -26' C4II IGROUND SURFACE TO  USEDIIIIBottom of Boring31'Gray DIORITE Include color,Type oftype,hord-seoms ond SampleProportions Used someWt.on 20. D.

CohesiveIO-30 Med. Dense4-8 M/Stiff Dense..O-IOLooseo-4 SoftC=CoredUP-TestV-Vane Test American Drilling & Boring Co., Inc.

WATER STREET SHEET DATENO.LINESTA- - -- -.__SAMPLES SENT TOYankee

----A D D R E S S LOCATION OF BORING-At  HoursCASINGSAMPLERCORE BAR.

COMPLETETOTALSTART.,SOILS ENGR. GROUND WATER OBSERVATIONS SHEETAmerican Drilling Boring Co., Inc.

SAMPLENo PenSOILRemorksType ofetchord-ness,seoms and

---710I21wet.denseBottom of Boring- 11*

GROUND SURFACE TO  USEDIITHEN Proportions Used351050%littleIOsomeWt.on0. Sampler CohesiveO-IOLoose4- 8M/ S t i f f vo - 4....Sample Type UP: Undisturbed Piston TestUT-IO-30 Med.

DenseDenseVery Dense OF BORING:COMPLETE---I.D.HoursHommer,.H o m m e r WATER STREETR ITOccLOCATIONTop of Ground GROUND WATER OBSERVATIONS CASINGSAMPLERCURE BAR.1 SOILS ENGR. DATE HOLE NO. LINE STA. OFFSET}}