ML20078C403
| ML20078C403 | |
| Person / Time | |
|---|---|
| Site: | Byron  |
| Issue date: | 04/20/1983 |
| From: | Jarosz G TRANSCO, INC. |
| To: | |
| Shared Package | |
| ML20078C379 | List: |
| References | |
| TR-111, NUDOCS 8309270575 | |
| Download: ML20078C403 (26) | |
Text
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- TRANSCO
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'TRANSCO TEST REPORT TR ill FIRE AND HOSE STREAM TESTS OF TCO CO2 MEDIUM DENSITY SIL! CONE ELASTOMER O
By: G.J.Jarosz Date: 4-20-83 O
8309270575 030920 PDR ADOCK 05000 F
Test Report l'TR-l l !
'( ) . Page 1 of 25 A) Synopsis:
This report describes a three ho,ur fir,e and subsequent hose stream floor test of Transco #TCO-002 Mediun Density Silicone Elastomer insta'. led 12" deep in three electrical openings. The test was perforced in accordance with the ASTM E-119 time /te=perature curve for three hours along with provisions set forth in the IEEE 634-78, ANI, NML, and ASTM E-814 (for a "F" rating) test standards. These penetration seals were tested along with twenty-four other penetration seals in, a 17'-9" x 13'-10-1/2" x 12" thick concrete slab on March 9, 1983 at Portland Cement Association's Fire Research Laboratory (Skokie, Illinois).
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The test specimens consisted of three simulated electrical openings which ceasured 52-1/2" x 32" (penetrated by two 30" x 4" and one 24" x 6" cable trays and two conduits) and 1-1/2" and 6" diameter e= bedded conduits. All trays and conduits were filled in excess of 100% loadings sith PVC jacketed cables (with the exception of the 24" x 6" tray which was filled with Hypalon jacketed cables).
s The symmetrical penetration seals consisted of 12" of #TCO-002 Medium Density Silicone Elastoner (no per=anent damsing mate-rial was used). The elastomer weighs 90 lbs./ cubic foot (min.)
and is normally used for scaling penetrations in flood bound-g aries and radiation shield walls or floors.
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Test T.cpo r t #TR-111
. . Page 2 of 25 The purpose of this test was not only to demonstrate the 0 elastomer's fire endurance qualities as a penetration seal when used in electrical openings but also to qualify the use of a cast-in place core which was filled with a renovable plug made of ceramic blanket * (see attached drawings). In field use, this plug can easily be removed for the addition of cables through .
the penetration. This was demonstrated in the test when two of three plugs were recoved for the addition of cables (in order to simulate a repair to the scal). The remaining space around these cables was' sealed with additional elasto=er.
Besides qualifying the seals to the test standards =entioned,
. several other objectives were established in this test. These are:
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- 1) The material's ability to seal both narrow and wide areas without support;
- 2) The use of the material when installed next to either steel or concrete substrates;
- 3) The use of the material to seal both solid and ladder back cable trays;
- 4) The ability of the sealing material to be removed for additional cable installation (use of temporary plugs);
and, s
.5) That a symmetrical 12" thick seal can withstand the 3 hour3.472222e-5 days <br />8.333333e-4 hours <br />4.960317e-6 weeks <br />1.1415e-6 months <br /> fire and 2 hose stream tests.
- Patent applied for O
Test Report #TP.-I l l Page 3 of 25 B.) Test Slab:
O The test skabmeasured17'-9"x13'-10-1/2"x12" thick.
Twenty-seven openings which ranged from 1-1/2" diameter,to 109-1/2" x 32" in size penetrated the test slab. The penetrations were arranged in the slab so that 18" vide (min.)
concrete columns separated each row of pcnetrations. These columns were placed in the direction which would allow for the least amount of deflection from heat during the fire test.
The slab's steel reinforcement design and slab fabrication were completed by Portland Cement Association's personnel. After the slab was cast, the concrete was allcwed to dry for several days after which the slab was subjected to additional heat O cerins e furnece.
The slab's. superstructure, specimen fabrication and seal installations were performed by Transco employees. The slab's superstructure consisted of steel angle braces mounted to the slab which supported the pipes, cable trays, cables, etc., for the test.
C.) Specimen Configurations: s
.The large rectangular test penetration was 51-1/2" x 32" x 12" deep. Two sides of the penetration were lined with 1/4" thick steel plate (set at a right angle in the plan view of the pene-tration). The remaining two substrate surfaces were cast con-crete.
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Test Repart #TE-111 Page 4 of 25 This opening was penetrated by three cable trcys cr.d c 6" and 2" diameter conduit. Each cable tray was r;ounted so that it extended 36" above the slab's unexposed surf ace and 12" below its exposed surface.
The conduity were 12" long and was mounted flush inside of the pene-
. tration.
One 6'" and one 1-1/2" diameter (x 12" long) rigid steci conduits were also cast into the concrete slab outside of the large rectangular opening. These were used to simulate embedded conduits (or sleeves) which pass through walls or floors.
.The cable trays and conduits were filled with cables based on loadings which exceeded 100% fills. The loadings were calculated so that a
- ( h 100% fill was equivalent to 40% of the actual sectional area of the cable trays or conduits. Some of the loadings were increased so that 100% visual loadings were also achieved. Cable lodings were as fol-lows:
A.) 32" x 52-1/2" RECTANGULAR OPENING: ,
1.) 30" x 4" ladder back tray filled with PVC jacketed cable:
134 2/c #14...................... 0.1372 ....... 18.3848 l 35 12/c #14...................... 0.5329........ 18.6190 26 1/e, 500McM.................. 0.7013........ 18.2359
! Total Loading = 55.2397 sq. in.
j (115% fill of tray) l I
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Test Report FTR-111 Page 5 of 25 O 2.)
30" x 4" solid back tray filled PVC jacketed cable:
134 2/c #14 .................... 0.1372 ....... 18.3848, 35 li / c # 14. . . . . . . . . . . . . . . . . . . ! . 0. 532 9 . . . . . . . 18.6190 26 1/c , 500MCM. . . . . . . . . . . . . . . . . . 0. 7 013 . . . . . . . 18. 2 3 5 9 Total Loading = 55.2397 sq. in.
(115% fill of tray)
- Two 2/c #14 and one 12/C #14 cables were added to this tray as part of the repair to this seal. ..
t-3.) 24" x 6" solid back cable tray filled with !!ypalon jacketed cable:
12 4 pr. # 20 . . . . . . . . . . . . . . . . . . 0. 418 5. . . . . . . . . 5. 0 2 2 0 2 8 pr. #16.................. 0.6792......... 1.35S4 1 12 pr. # 16 . . . . . . . . . . . . . . . . . . 0. 916 0. . . . . . . . . 0 . 916 0 2 2/C #14.................. 0.1839......... 0.3678 1 3/C # 14 . . . . . . . . . . . . . . . . . . 0 . 2 0 5 8 . . . . . . . . . 0 . 2 0 5 8 4 4/C # 14 . . . . . . . . . . . . . . . . . . 0. 2 715 . . . . . . . . . 1. 0 86 0 3 7/C #14.................. 0.3717......... 1.1151 10 9/C # 14 . . . . . . . . . . . . . . . . . . 0 . 4 9 3 8 . . . . . . . . . 4 . 9 3 8 0 (3) 9 12/C # 14 . . . . . . . . . . . . . . . . . . 0 . 7 013 . . . . . . . . . 6 . 3117 6 ~ /C, 3 4 / 0. . . . . . . . . . . . . . . . . . 1. 8 4 8 0, . . . . . . . 11.08 8 0 2 9/C # 10. . . . . . . . . . . . . . . . . . 0. 7 69 7 . . . . . . . . . 1. 5 394 6 3/C, 500McM............... 5.2563........ 31.5378 1/0 ................. 1.6695......... 8.3475 5 3/C,
- Total loading = 73.8335 sq. in.
(128% fill of tray)
- 0ne 12/C #14 cable was added to this tray as part of the repair to this seal.
4.) 6" diameter conduit filled with PVC jacketed cable:
30 2/ c # 14 . . . . .' . . . . . . . . . . . . . . . 0.13 7 2 . . . . . . . 4 .1160 i
l 8 12 / c # 14 . . . . . . . . . . . . . . . . . . . . 0 . 5 3 29 . . . . . . . 4 . 2 6 3 2 7 1/ c , 500MCM. . . . . . . . . . . . . . . . 0. 7013 . . . . . . . 4. 9 091 Total Loading = 13.2863 sq.in.
(117.4% fill of conduit)
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Test Twport (TR-111 Page 6 of 25 5.) 2" diameter conduit filled with Hypalon jacketed cable:
1 2/C 514.................... 0.1839......... 0 1839 1 12/C #14.................... 0.7013......... 0.7013, 1 3/C #6/0................... 0.7133......... 0.7133 Total Loading = 1.5985 sq. in.
(127.2*.' fill of conduit)
B.) 1-1/2" diameter embedded conduit filled with P\'C jacketed cable (separate penetration):
3 2 / C # 14 . . . . . . . . . . . . . . . . . . . . . 0 .13 7 2 . . . . . . . . 0 . 41 16
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1 12 / C # 14 . . . . . . . . . . . . . . . . . . . . . 0. 5 3 2 9 . . . . . . . . 0. 5 3 2 9 Total Loading = 0.9445 sq. in.
(113.6% fill of conduit) -
C.) 6" diameter embedded conduit filled with PVC jacketed cable (separate penetration):
-[
30 2/ C # 14. . . . . . . . . . . . . . . . . . . . . 0.137 2 . . . . . . . . 4 .116 0 8 12 / C # 1,4 . . . . . . . . . . . . . . . . . . . . . 0 . 5 3 2 9 . . . . . . . . 4 . 2 6 3 2
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'7- ~ ~ 1/C 560scs. . : . : . . : .~ :: .~ ::::" :. 6.'7013........ 4.9091 Total Loading = 13.2883 sq.1'n!
(117.4% fill of conduit) .
All cables used in the test extended 36" above the slab's unex-posed surface and 12" below its exposed surface. Cables were held to the trays with both compression clamps and metal plates ,
located approximately 12" from the top of each tray. In ad-dition, a threaded rod was used across the bottom of each tray to prevent the cables from being pulled forward during the seal O
I Test Report ITR-lli Page 7 of 25 installation. This was done to simulate field conditions where
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continuous cable make it impossible in some cases to move the cables apart for seal installation. .
The top ends of all cables used inside of the cable trays were covered with silicone adhesive while conduit cable ends were covered wit,h electrical tape. This was done in accordance with .
IEEE 634-78 requirements.
Finally, the cables used in the conduits were grouped and mounted by type (i.e. , power, control and instrucent cables ) .
The grouping of power cables in each conduit sleeve created a
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more severe condition because of the high concentation of heat
"( h that would be produced during the fire test. .
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D Seal Installation The openings were first dammed by packing mineral wool between the cables to prevent leakage of the liquid silicone elastomer -
asterial. The rest of the opening was formed with plywood.
Once the elastomer was installed and set, all for=ing materials were removed.
s As part of the damming operation, round 2" diameter (approxi-mately) foam rubber tubes were placed in front of the 24" x 6" Hypalon cable tray and 30" x 4" PVC cable solid back cable trays. These were used so that once the elastomer was installed O and had hardened, the tubes could be easily re=oved to produce clean, empty cores through the clastomer seal.
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Test Report #TR-ll!
Page 8 of 25 The empty core in front of the' llypalon tray was used to add
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cabic to the tray to siculate field addition of cabic once the penetration seal is in place. The same was completed for one of two*eepty cores for the tray with PVC, cables. Additional elas-tomer was used to seal these two cores around the new cable.
The thir,d core (in front'of the PVC cable tray) was filled with ,
ceramic blanket. This was held in place by using a threaded rod through the center of the core and securing it with washers and nuts on each side of the penetration seal. This was done to simulate a removable plug (in place) which could later be
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removed (in the field) for the addition of cables through an ex-isting seal.
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The two-component silicone elastomer was installed in a one to one ratio (+/- 5%) 12" deep inside of the large penetration and conduits. A portion of the seal was installed using dispensing
- equipment while the remainder of the seal was ccepleted with large (30 gallon drum) hand mixed batches. Where the elasto=er was used in cable bundles, the bundles were spread apart by hand. A trowel was used to push the elastomer into the cable bundles to facilitate its flow.
Once the elastomer installation was completed, the dacming material was recoved. It was noted at this time that a small layer of material at the elastomer /PVC jacketed cable interf ace p n . - - ,-- -
Test Report FTR-111 Page 9 of 25 did not completely cure. This inhibition of' cure at the PVC O '
surf aces was attributed to the f ree sulphur in the PVC material. Sulphur is a caterial which af fects the curing mechanism of the platinum cataly'st silicone product. .Although the amount of . inhibition varied from PVC j acketed cable to cable, none was immediately observed at the silicone ,
elastomer /hypalon jacketed- cable interf aces. No' attempt was . ..
made to repair the seal where inhibition occurred in order to show both conditions. -
E.) Thermocouples:
Thermocouples were mounted to the test specimens to gather tem-perature data throughout the test at five minute intervals for
- (]) the first two hours and at ten minute intervals for the remain-ing hour (in accordance with the IEEE 634-78 standard). Temper-atures were recorded for the seal surfaces, seal / substrate
. interfaces (unexposed surface only), and penetrating members.
All seal surface thermocouples were embedded 1/4"-1/2" into seal surfaces,to prevent the effect of contact with umbient air tem-peratures. Thermocouples used for monitoring cable temperaturas were tied with wire to the cables so that their tips were also embedded into the seal surface. .
"The thermocouples used in this test along with final temperature ,
readings are as follows (temperature data for the entire test can be found in section "H" of this report):
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Test Paport RIP.- 111 1
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- Page 10 of 25 T/C# Print # Description Final Te=perature (*F) 118 57a Seal surface . 82.6 119 78a Seal surface 89.1 120 78a Seal surface . . 94.4
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121 72a Instrument cable 126.5 -- Solid back cable
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122 73a* Control cable 200.6 tray with Hypalen 123 74a Power cable 202.7 jacketed cable 124 75a cable tray 243.2_
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125 62a Seal surface 71.3 126 63a Interface 295.8 --- Hypalon j acketed 127 64a Instrument cable 225.8 cable conduit c
128 65a Control cable 264.1 129 70a Power cable 277.5_
130 58a Instrument cable 296.3 --- Solid back cable 131 60a control cable 246.1 tray with PVC 132 59a Power cable 549.8 jacketed cable 133 61a cable tray' 154.5 134 95b Instrument cable 242.9 135 96b Control cable None --- Ladder back cable 136 80a Power cable 461.0 tray with PVC 137 50b Cable tray 195.3 ,
jacketed cable 138 76a Concrete substrate /
seal interface None 139 77a Steel substrate /
seal interface 175.4
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- Test Report #TR-111 Page 11 of 25
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T/C# Print 4 Description Final Temperature (*F)
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140 67a Seal surface ,
448.2- .
141 66a Interface ~. 339.6 --- PVC jacketed 142 68a instru=ent cable 337.5 cable conduit 168 69a control cable 444.1 169 71a. Power cable 410.9,_ -
217 91b Repair surface 114.6 --- Hypalon tray 218 92b . Repair cable None__ repair 219 93b Repair surface 107.2 --- PVC tray 220 94b Repair cable 133.3,_ repair 83 33a Seal surface 94.8 -- l-1/2" dia:e ter 84 34a Interface 111.3 conduit
~ (:) 85 35a control cable 184.6 __
86 61b Seal surface ,
311.4_
87 62b Instrument cable 335.3 -- 6" dia=eter embed-88 64b Power cable 509.4 ded conduit 90 65b Interface -337.6 _
9 h
-_.-y,.7.1 m. 3 - _ __y. -,. - ,--,y
- ,_. ~, - - . - . ,- _
r Test Report fTP.-111
() . Page 12 of 25 F.) Furnace:
The furnace used for this test,tessures approxiestely 14' x 18' at its support points. It is approximately 7' t'all making it possible to ucck on the specf =en's exposed surface and view it prior to the fire test. The furnace atmosphere is controlled by six self-igniting burners which burn natural gas and operate in' unison. The burners are autocatically controlled by a computer located inside of .the control room. As the furnace atmosphere tempe'ratures are monitored in the control room, manual adjust-ments can be made to the burners to account for varying a=ounts of fuel contribution throughout the test.
The furnace atmosphere temperatures are monitored by 16 thermo-
,. couples located 12" below the test slab. These temperatures are individually printed on a continuous chart and also averaged on a computer printout.
The furnace draft is manually operated and averages to approxi-mately .08" of water pressure throughout the test. Since canual adjustments are made to the burners in order to follow the ASTM E-119 time / temperature curve, brief periods of positive pressure are introduced inside of the furnace. This is evidenced by visible puffs of smoke generated through openings in the test ,
specimen (i.e., through a fire danper, unsealed pipe insulation,
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(g etc.).
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Test Report OTR-111
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Page 13 of 25 C.) Test Record:
The fire test was conducted for three, hours in accordance with the ASTM E-119 time /te perature curve. Throughout the test, an even blanket of flame covered .the plan area of the furnace. All -
combustible materials located on the exposed surface of the slab (i.e., cable jacketing material, etc.) quickly ignited and con-tinued to char for the duration of the test. Little smoke was noted during the test and all seal surface te=peratures re=ained relatively cool.
-(:) Two separate hose stram tests were conducted on the three speci-mens. Water did not penetrate any of the seals during either of the 6 minute and 18 second long exposures. The hose stream tests conducted are as follows:
a.) IEEE-634-78: 75 p.s.i. hose stream delivered through an 1-1/2" hose equipped with a fog nozzle set at a discharge of 30* from a distance of 10'.
s b.) ANI: Same as above except that the nozzle was set at a dis-charge angle of 15*. ,
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-p , - - , + , , - - ,, ,,,,,n.- - - - - - - , - - - - - - - - - ,- - -
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Test Repor: "T P.- 1 1 1 r=ce t' or 2s
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H.) Tc=perature Data: ,
The following chects identify both co:plete furnace atmosphere and unexposd surf ace temperatures throughout the three hour fire test. .
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. Page 15 of 25 1 F. All5CO .C P5056 / -
0 3 0 9."B .-
. FUPil AC E ATliG5FHERE T E r.T E R A T U E E (DEC. F)
TEST T illE , FURtlRCE ASTil E119 YARI6T]Ori F R0!:
Hr :11i n T Ei!P. T EllP. ft0Til T EllP. '
F F
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0:00 196 68' 128 0:05 995 1000 -5 ,
0:10 1271 1300 -29 0:15 ,
1503 1399 104 0:20 1527 1462 65 0:25 1547 1510 37 0:30 1657 1550 7 0:35 1600 1504 24
'0 : 40 1626 1613 13 0: 45 1633 1630 0 0:53 ; 1655 1661 -6 1704 1681 0:55 ,
23 1:00 1714 1700 14 1:05 1724 1718 6
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- l f 1:10 1729 1735 ,
-6 1:15 1748 1750 -2 1:20 1771 . 1765 6 1:25 1776 -
1779 -3 f 1:30 1779 1792 -13 f*
1:35 1818 1804 14 1140 1823 1815
- 8 1:45 1830 1826 4 1:50 1036 1835 1 1:55 1844 ,
1843 1 2:00 1854 1850 4
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2:10 -
1873 1862 11
. 2:20 1880 1875 5 2:30 .
1880 1888 -8 2140 - 1895 1900 !-5 2:50 1916 1912 4 5
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3:00 1930 1925 e
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TRANSOU n oe u a 25 TEST Tif**.E THERI.iOCCUFLES HR: MIN (temperatures in digrecs F) 118 119 120 121 122 123 0:00 71.9 72.3 71.8 71.9 72.2 71.8 0:05 71.9 72.3 7-1.9 71.9 72.3 71.8 0:10 72.0 72.3 71.8 71.9 72.8 71.9 0:15 72.0 72.3 71.9' 72.0 74.2 72.2 0 20 72.0 72.3 71.8 .72.0 76.2 72.6 0:25 72.4 72.4 72.1 -
72.2 78.7 73.5 0: 30 72.8 72.5 72.1 72.3 81.2 74.5 0:-35 73 2 72.7 72.3 72.8 83.9 76.0 0:40 73.6 72.9 72.5 73.2 86.9 77.7 ~
0:45 74.h 73 1 ~72.8 73.9 90.3 79.7
- 0. : 50 75.0 73 3 73 1 74.5 93.9 82.0 0: 55 75.8 73.6 73.4 75.4 97.8 84.5 1:00 76.4 73 9 73 9 76.4 102.1 87.5 1:05 76.8 74.2 74.3 77.4 106'.3 90.5 1:10 77.6 74.6 74.8 78.8 110.6 93.9
. 1:15 78.6 75.1 ~ 75.4 8c.2 115.9 97.7 1:20 78.8 75.6 76.0 81.8 120.5 101.7 1:25 .79 9 76.1 76.6 83.5 126.2 105.8 1: 30 79.8 76.6 77.2 85.2 132.5 110.0 1: 35 81.5 77.2 78.0 87.1 137.1 114.6 1:40 79.8 77.7 78.7 89.0 lu2.3 119.2 1:45 '78.8 78.1 79.4 90.9 149.0 124.0
- (]) 1: 50 79.3 78.7 80.2 92.9 154.8 129 0 1: 55 80.2 79.4 81.1 95.2 5.59 3 134.0 2:00 81.2 80.0 81.9 97.5 165.2 139.1 2:10 80.6 81.2 83.6 101.9 173.8 147.7 2:20 82.4 82.7 85.5 106.8 181.5 159.5 2: 30 81.4 84.2 87.5 111.5 187.3 170.1 2:40 80.9 85.8 89.8 116.4 191.9 181.1 2: 50 82.2 87.5 92.2 121.6 196.5 191.8 3:00 82.6 89:1 94.4 .. . 126.5 200.6 202.7 -
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TRANSCO eS Ea 2s TEST TIME THERT/.OCOi)PLES 1 HR: MIN (temperatares in degrees F) 0 125 125 126 127 12E 229 0:00 71.5 72.1 71.6 71.6 71.6- ;
0:c5 71.9 72.0 71.6 71.7 71.7 715 71.
0:10 71.8 72.2 72.0 71.9 72.1 72.1 0:15 72.7 72.3 72.9
- 72.6 73 1 73.5 0:20 7b.3 72.2 74.S. 74.0 74.9 75 9 0:25 77.2 72.7 78.1 76.6 78.3 Sc.3 0: 30 80.9 72.9 82.8 80.4 82.5 25.8 0: 35 85.9 73 1 88.6 85.2 88.5 92.3 0:40 9.2 ;1 73 1 .95.3 90.7 95.0 99.7 -
0: 45 99.0 73.6 103.0 97.3 101.9 107.5 0: 50 106.2 73.8 110.5 102.9 109.1 115.7 0: 55 113.2 74.2 118.6 109.8 116.0 163.9 1:00 120.5 74.2 126.6 116.1 123.2 131.E 1:05 127.4 74.3 134.c 121.8 129 9 139.2 1:10 135.0 74.7~ 142.0 127.2 137.1 147.0 1:15 142.5 74.8 150.0 134.2 143.8 15t.7 1:20 150.2 75.6' 157.7 140.4 151.1 162.4 1:25 157.7 75.3 165.0 145.6 157.0 17c.0 1: 30 165.6 76.0 172.7 151.4 164.5 177.5 1: 35 174.0 76.2 180.1 157.0 170.5 134.7 1:40 187.2 74.2 187.7 161.3 178.1 191.8
.A 1: 45 196.4 72 9 195.0 166.0 183.7 198.3 V 1: 50 196.1 73 0 201.0 170.7 877.5 202.8 1: 55 197.6 73.5 207.1 175.1 190.3 206.7 2:00 207.5 73.1 214.1 179.6 196.2 212.5 .
2:10 219.6 72.9 233.7 190.3 208.3 224.6 2:20 227.6 73.9 2h7.8 199 6 215.4 236.4 2: 30 229.7 70.9 260.2 205 9 224.3 246.7 2:40~ 232.9 71.1 272.8 212.8 232.1 257.6 2: 50 236.3 71.2 284.3 217.6 240.2 267.7 243.2 71.3 295.8 225.8 246.1 277.5 3:00 --
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Page 18 of 25 EST lt. E THERMOCCUPLES HR: MIN (temperatur-s in ddgrees F)
~O 133 134 135 13C 131 132 0:00 72.3 72.0 73.0 72.2 72.2- no::E 0:05 72.5 72.1 -75.6 72.2 72.2 ' -
0:10 7 3 . #. 72.7 85.1 72.3 72~.3 " "
0:15 7G.7 74.0 99.5 72.4 72.7 " "
0:20 70.h 76.4 118.3 72.6 73.5 " "
0:25 84.9 79.9 139.6 73.4 74.7 " "
0: 30 91.8 84.4 162.0 74.4 76.4 " "
0: 35 99.7 89. 5 184.5 75.6 78.9 " "
0:40 10.8.2 95.2 206.9 77.2 82.0 " " ._
0: 45 117.1 101.4 227.5 79.1 85 5 " "
0: 50 126.5 107.8 247.6 81.3 89 7 " "
0: 55. 13c.9 114.2 266.3 84.4 94.3 " "
1:00 145.6 121.3 282.2 88.3 98.6 " "
1:05 154.0 127.9 295.0 92.1 103 9 " "
1:10 163.h 134.9 306.6 95.9 109.4 " "
1:15 172.4 141.7 317.4 99.8 115.2 " "
1:20 180.5 148.2 325.7 103 7 121.2 " "
1:25 188.4 154.6 334.3 107.1 127.6 " "
1: 30 195.8 160.6 343.0 110.6 133.8 " "
1: 35 203.1 166.5 352.3 113.8 140.2 " "
1: 40 210.4 172.4 362.3 116.6 146.5 " "
217.1 177.8 371.9 115.6 152.9 " "
-Q 1: 45 1: 50 223.4 183.1 383.9 120.9 159.4 "
1: 55 ~229.5 188.0 394.9 123.3 165.8 " " '
2:00 235.5 193.1 406.4 125.8 172.1 " "
2:10 247.1 202.8 432.2 131.2 184.6 " "
2:20 258.5 212.1 457.2 137.8 197.0 " "
2: 30 268.9 220.7 481.7 142.5 200.9 " "
2:40 278.7 228.6 505.9 146.1 220.3 " "
2: 50 287.7 236.0 527.9 150.0 231.8 3:00 _.296.3 243.4 549.8 154.5 242 9_
NONE
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TRANSCO Page 19 of 25 TEST Tif.'E THERMOCOUPLES HR: MIN ,
(temperatures .in degrees F) 134 137 13F 139 140 141 0:00 71 9 Mony, 71,7 71.6
- 71.6 0:05 73.1 . 71.7 72.1 71.9 0:10 78.0 n 71.8 74.8 73.1
. 0:15 87.6 n 72.1 80.9 76.7 0:20 in2.3 " 72.5 91.1 83.3 0:25 120.7 u '73.5 104.1 92.5 0:30 141.0 n 74.8 117.4 103.7 0: 35 162.2 n 76.5 131.9 115.3 0:40 1R3.5 n 78.6 146.7 125.9 '
0: 45 204.0 E " 81.1 160.2 140.4 0: 50 223.3 E "
83.9 173.4 151.9 0:55 2h1.2 ,8 a 87.1 188.3 163.9 1:00 254.4 " 90.5 206.2 176.1 1:05 266.9 o "
94.1 ~220.5 185.2 1:10 277.7 ,
98.2 231.1 193.9 1:15 285.h c " 102~.3 242.1 203.7 1:20 292.1 " 106.6 253.1 212.8 1:25 298.4 R " 110.1 264.7 220.7 1: 30 304.9 8 " 114.1 276.7 229 7 1: 35 311.1 " 118.1 287.8 237.4 3:40 317.6 " 121.9 297.1 247.4 on
%# 1: 45 3'23 9 123.2 307.2 254.7 1: 50 331.0 160.9 " 126.0 317.5 262.4 1: 55 338.9 166.8 "
128.9 328.7 270.0
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2:00 346.9 171.2 132.4 339 0 276.6 2:10 362.2 175.8 140.7 357.9 289.4 2:20 379.7 180.7 "
148.6 376.3 301.0 2: 30 398.2 184.5 "
155.4 395.7 314.0 2:46 418.1 186.3 "
162.4 414.3 .323.1 2: 50 438.0 190.6 169.0 431.3 329 2 195.3 NONE 175.4 448.2 339.6 3:00 _461.0 e
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Page 20 of 25 TEST Tif.iE TH E R t.*OCC'JPLE S
. HR :!.*lN (temperatures m cL y ses F) 1h2 168 169 217 21E 219
. Mcne 0:00 71.7 71.7 72 5 72.5 72.3 72.4 0:05
- 71.9 72.0 73.5 72.5 0:10 72.8 73.2 7. 8 .' 3 72.7 72.7 0:15 75.0 76.8 87.7 72.8 "
72.9 0:20 To.h 83.4 103.4 73.2 73.3 0:25 86.7 93.9 123.6 73.9 73.7 96.n . 107.3 144.3 74.6 74.0 0: 30 "
74.6 0: 35 107.0 122.5 164.7 75.6 118.5 138.5 183.8 76.8 "
7L.9 -
0:40 77.9 75.4 0:45 130.3 154.6 202.0 141.7 170.5 218.3 78.9 76.0 0: 50 232.8 80.4 "
76.6 0: 55 142.5 185.F 162.9 202.3 246.9 81.3 77.2 1:00 172.4 213.4 257.5 82.7 "
76.1 1:05 182.0 228.5 267.8 84.0 "
78.9 1:10 191.0 243.6 275.8 85.2 -
79.S 1:15 199 5 258.3 281.4 86.7 "
81.0 1:20 207.0 272.0 286.6 88.0 " 82.0 215.0 285.2 291.9 89.4 82.9 222.1 296.4 297.5 90.7
" 84.0 1: 35 229.7 311.5 302.1 92.3 85.2 1: 40 237.1 323.5 306.9 93.7
" 86.0 1:45 244.6 334.8 312.7 95.1
" 87.2 1: 50 252.2 344.0 318.8 96.8
" 88.6 1: 55 259.8 350.5 325.6 98.0 89.9 2:00 275.6 362.1 341.7 101.3 "
92.9 2:10 290.6 378.4 357.6 104.1 "
95.9 2:20 305.1 395.0 372.4 107.0 "
98.6 2: 30- 317.0 411.8 386.9 109.3
" 102.1 2:40 327.9 428.5 399 5 111.7 " 104.8 2: 50 337.5 444.1 410.9 114.6 NCME 107.2 -
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TEST Tif.',E THERT.10 COUPLES HR:f ilN ,
(temperaturcs in c6grees F) 6h 85 86 57 220 83 72.8 72.5 72.7
- 72.7 72.7 0:00 72.3 73.0 72.9 72.9 0:05 72.4 73.0 72.6 73.9 72.9 73.9 73 3 74.6 73.7 0:10 74.5 77.8 75.7 75.9 0:15 73.2 76.0 79.3 79.6 77.1 82.8 79 6 0:20 73 3 -
88.3 85 2 60.9 74.4 83 1 80.5 0:25 87.0 83 3 93.6 92.8 92.0 0: 30 75.0 98.5 101.2 100.1 75.7 90.8 85 9 1c9 1 0: 35 94.8 89 7 103.2 110.3 76.5
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0:40 92.2 107.7 119.8 118.3 77.5 98.8 129 5 125.5 0:45 78.6 106.6 95 9 112.1 0: 50 110.8 97.9 116.2 138.8 137.5 7 146.7 146.0 120.7 0 55 81.1 115.2 101.2 1:00 104.8 124.8 156.7 155.9 82.6 119.6 165 1 150.0 1:05 8h.3 124.2 108.8 129.2 1:10 112.7 133.5 174.5 173.7 86.0 129 0 183.6 183 3 1:15 87.9 134.6 116.5 138.1 1:20 119.9 143.0 191.6 191.2 89.9 1 h o . 3.
148.3 199.2 199.1 1:25 91.9 146.9 123.9 203.2 1: 30 131.8 153.4 207.1 94.0 154.4 214.3 215.7 1: 35 96.0 159.8 129 9 156.8 224.2 2:4o 166.1 134.1 158.9 221.0
.O 1: 45 98.0 100.4 171.2 124.5 161.2 165.3 227.6 234.9 232.1 237.2 1: 50 102.7 175.3 114.9 243.S 1:55 108.8 166.9 241.2 105.0 178.9 -
253.5 256.7 2:00 87.2 115.2 170.0 109.7 17.5.6 266.6 272.2 2 30 114.5 194.9 134.8 28t.6 2:20 119,3 199 0 109.8 177.1 276.9
' 2: 30 115.5 178.4 287.3 300.4 2:40 123.9 205.2 301.6 317.1 128.6 208.3 111.7 179 0 2: 50 111.3 184.6 311.4 335.3 3:00 133.3 94.8 _
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I IMI ND U Pcge 22 of 25 TEST TIME THERMOCOUPLES HR: MIN (temperatures in dagrees F)
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88 89 90 0:00 72.6 73.3 72.5 0:0, 72.8 -
75.7 72.8 0:10 .
73.8 83.8 73.8 0:15 75.8 96.5 76.h 0:20 79.6 115.3 2 0:25 85.4 138.0 81.E 88.
0: 30 92.5 160.5 97.2 0: 35 100.4 161.7 107.1 0:40 . 109.2 202.0 117 5 ~
0: 45 118.1 221.6 128.1 0: 50 127.4 241.3 138.7 0: 55 137.0 254.5 149.3 1:00 145.8 261.6 158.6 1:05 155.9 273.6 169.9 1:10 165.6 283.0 180.4 1:15 175.4 290.7 190.3 1:20 185.6 299'.0 199.7 1:25 194.3 306.5 208.6 1: 30 202.8 314.2 217.4 1: 35 210.1 324.0 225.8 1: 40 217.7 333.8 234.0 224.9 366.2 241.9
- C 1: 45 1: 50 232.1 -
394.6 249.5 1: 55 239.6 404.4 257.1 2:00 246.8 413.9 264.0 2:10 261.0 434.6 277.5 2:20 275.7 485.6 291.0 289.7 484.0 303.0 2: 30 489.6 314.9 2-40 303.8 319.3 498.2 326.8 2: 50 509.4 337.6 3:00 334.8 h W 9
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' e T'st Report (:TR-l l!
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Page 23 of 25 Post Test Observations:
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After the fire and hose stream tests it was observed that the exposed surface cable jacket materials were co:pletely chared by the fire.. The unexposed cable jackets (PVC cables only) swelled ..
slightly near the seal surface.
The seal's exposed surface, although co.=pletely intact, formed a brittle char layer which varied 3 1/2" deep into the seal.
The seal's unexposed surface was not affected.
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