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14. Arco 25775So'Patterson Pass Rd Tracy Ca.' <br />Name of Supplier, Owner or Dealer Address No. and Street (s) City State Data of Test <br />15. TANK TO TEST <br />Identify by position <br />/Are <br />Brand and Grade <br />15a. BRIEF DIAGRAM OF TANK FIELD <br />See Attached <br />17. FILL -UP FOR TEST <br />Stick Water Bottom D <br />before Fill -up in. <br />.. to 'n' Gallons <br />9.:? in. <br />Tank Diameter <br />16. CAPACITY <br />Nominal Capacity zo i 000 <br />Gallons <br />By most accurate <br />capacity chart available / 7 <br />Gallons <br />18. SPECIAL CONDITIONS AND PROCEDURES TO TEST THIS TANK Nater in tank X Lines) being tested with LVLLT <br />See manual sections applicable. Check below and record procedure in log (27). High water table in tank excavation <br />Lies maximum allowable teat pressure for all tests. 19. TANK MEASUREMENTS FOR <br />Four pound rule does not apply to doublewalled tanks. <br />TSTT ASSEMBLY <br />Complete section below <br />Inventory <br />Bottom of tank to grade' ............................ 1 �� in. <br />Add 30" for 'T'• probe asst' ........................... 30 in. <br />1. Is four pound rule required? Yes ❑ No X C� <br />,2. Height to 12' mark from bottom of tank <br />3. Pressure at bottom of tank <br />4. Pressure at top of tank <br />h of burial <br />die. <br />r table <br />NOTES: <br />• The above calculations are to be used for dry soil conditions to <br />establish a positive pressure advantage. or when using the four pound <br />rule to compensate for the presence of subsurface water in the tank <br />ares- <br />Belot <br />reaRefer to N.F.P.A. 30. Sections 2-3.2.4 and 2-7.2 and the tank <br />manufacturer regarding allowable system test pressures. <br />102 <br />From <br />II ..❑11 station chart <br />Tank Manufacturer's Chart <br />Company Engineering Data <br />❑ Charts supplied with <br />❑ Other <br />Total Gallons <br />Gallons ea. Reading <br />r�/'')��—_�_/_�_ <br />:;52 1/�, <br />!F6 9!F4 <br />Transfer total to bne 25a <br />21. VAPOR RECOVERY SYSTEM ❑ Stage I stage II _ <br />24b. COEFFICIENT OF EXPANSION <br />Total tubing to assemble — approximate ............. <br />! :!0- In, <br />20. EXTENSION HOSE SETTING <br />Type of Product ...................... <br />/ in <br />Hydrometer Employed................................... <br />Tank lop to grade' .................................. <br />/ <br />G G in. <br />Extend hose on suction tube 6" or more <br />a <br />below tank top ...................................... <br />6 in. <br />[� <br />Z 7-94 P.S.I <br />'If Fill pipe extends above grade. use top of fill. <br />CrQ <br />22. Ther al -Sensor reading after circulation <br />O -,-2 <br />Reciprocal / Page a 4_ <br />see C B D <br />lOg�► <br />ragas <br />6 6 in. <br />Volume change in <br />G <br />� — 1-17 <br />this tank per IF <br />7 <br />_'F <br />Corrected A.P.I. Gravity <br />o <br />23. <br />Between <br />Digits per OF in range of expected change <br />in. <br />digits <br />COEFFICIENT OF EXPANSION (Complete after circulation) <br />24a. Corrected A P.I. Gravity <br />—_ in. <br />Observetl A.P.I. Gravely ................................... <br />• The above calculations are to be used for dry soil conditions to <br />establish a positive pressure advantage. or when using the four pound <br />rule to compensate for the presence of subsurface water in the tank <br />ares- <br />Belot <br />reaRefer to N.F.P.A. 30. Sections 2-3.2.4 and 2-7.2 and the tank <br />manufacturer regarding allowable system test pressures. <br />102 <br />From <br />II ..❑11 station chart <br />Tank Manufacturer's Chart <br />Company Engineering Data <br />❑ Charts supplied with <br />❑ Other <br />Total Gallons <br />Gallons ea. Reading <br />r�/'')��—_�_/_�_ <br />:;52 1/�, <br />!F6 9!F4 <br />Transfer total to bne 25a <br />21. VAPOR RECOVERY SYSTEM ❑ Stage I stage II _ <br />24b. COEFFICIENT OF EXPANSION <br />H <br />RECIPROCAL METHOD <br />Type of Product ...................... <br />Hydrometer Employed................................... <br />Temperature in Tank <br />After Circulation <br />a <br />O <br />Temperature of Sample ....... <br />.F <br />Difference ('/-) ............................... ... <br />__�s _ °F <br />Observed A.P.I. Gravity ................................. <br />.......... °F <br />Reciprocal / Page a 4_ <br />see C B D <br />o <br />, <br />Taal quantity in Reciprocal <br />Volume change in <br />full tank (16 or 17) <br />this tank per IF <br />7 <br />Transfer to Line 26a. <br />Hydrometer employed ................................... <br />H <br />CD N <br />24c. FOR TESTING WITH WATER <br />Table <br />m <br />0 <br />Observed Sample Temperature ............... <br />.......... °F <br />see C B D <br />o <br />, <br />7 <br />Z <br />Corrected A.P.I. Gravity <br />Water Temperature after CirculationTable <br />Z <br />@ 60°F. From Table A .................................... <br />C <br />.................................... <br />Coefficient of Expansion <br />Coefficient of Water - <br />(3) <br />I-+ <br />0) <br />O <br />for Involved Product <br />Table D .......................................... <br />N <br />FromTable 6 ............................................ <br />...... <br />N <br />Transfer COE to Line 25b, <br />Added Surfactant? ❑ Yea ❑ No Transfer <br />COE to Line 25b. <br />O <br />25. (a) 41G % cX (b) _ (c) <br />`flr <br />Total quantity in in <br />Coafficienl of expansion for <br />Volume change in this tank <br />full tank (16 or 17) <br />Involved product <br />paM •F <br />C, <br />26. (a�. �/`/7�`! { <br />Q <br />lc�G. <br />,,/ <br />- _ .020 6 Zo-2 <br />Volume change per IF (25 or 24b) <br />Digits per •F In test <br />Range <br />Volume change per digit <br />This Is , \ <br />tact Q /) <br />(23) <br />Compute to 4 decimal places. <br />factor (e <br />