ML11250A172
ML11250A172 | |
Person / Time | |
---|---|
Site: | U.S. Geological Survey |
Issue date: | 08/30/2011 |
From: | Timothy Debey US Dept of Interior, Geological Survey (USGS) |
To: | Document Control Desk, Office of Nuclear Reactor Regulation |
References | |
Download: ML11250A172 (17) | |
Text
-USGS science for a changingworld Department of the Interior US Geological Survey PO Box 25046 MS 974 Denver, CO 80225-0046 August 30, 2011 U.S. Nuclear Regulatory Commission Document Control Desk Washington, DC 20555
Reference:
U.S. Geological Survey TRIGA Reactor (GSTR), Docket 50-274, License R-1 13 Request for Additional Information (RAI) dated September 29, 2010
Subject:
Response to Question 1 of the Referenced RAI Mr. Wertz:
Question 1: The ISG requires the NRC staff to review significant changes to the facility, including those done in accordance with the provisions of Title 10 of the Code of Federal Regulations Section (10 CFR)
Section 50.59. In 1988, changes to the GSTR were made which involved the installation of a new reactor tank liner. The details of this change are not provided in the GSTR Safety Analysis Report (SAR). As such, please provide a description of the new tank liner, the applicable design and construction criteria, and any associated additional instrumentation or equipment added as a result of the new tank liner. In addition, please describe any analyses of accidents and malfunctions associated with the new tank liner.
Response: Twenty three years ago, in 1988, corrosion and the resultant water leakage in the original, aluminum reactor tank was resolved by installing a tank liner inside the leaking tank. The tank liner has a slightly (4") smaller diameter than the original tank so it could be easily slipped into place. The tank liner is constructed of 6061-T6 aluminum with an overall height of 25' 3" and with an outer diameter of 7' 7.25". The bottom of the tank liner is supported by twelve ribs that are welded to the outer surface of the liner. These twelve ribs are welded to the liner in a spoke pattern, at a 300 spacing. The ribs are 4" tall, 1" thick, and 32" long. The floor of the liner is one inch thick, and the wall thickness varies from 3/8" near the bottom to 1/4" at 90.375" up from the bottom.
The reactor core structure is supported by a triangular base. The base connects to the floor of the tank liner at three pads that are located 30.625" from the center and separated from each other by 1200. These pads are supported by the ribs on the underside of the tank, with each pad centered directly over a rib.
The pads are 4" wide, 8.5" long, and 1" thick. The triangular base is connected to the pads through adjusting screws that allow for the base to be leveled manually. The triangular shape is reinforced by crossing support beams. The reactor core structure sits on the crossing support beams of the triangular base and is connected via nuts and bolts.
Design and Construction Criteria The ASME pressure vessel code was used as the basis for the reasonable, safe and economical design of the tank. The design included seismic, strength and thermal calculations for the mechanical and structural integrity of the tank liner and lifting lugs.
Pressure: Int:10.83 PSI EXT: 1.184 PSI Temp: Max: 150 0 F Min: 50 0 F Liquid Level: Full of water Corrosion Allowance: None Joint Efficiency: 1.0 (100% X-Ray)
Specific Gravity of Contents : 1.0 (Water)
Seismic: PER API 650, APP'E' , Zone 1 A copy of the design specifications is provided as Attachment 1.
Added instrumentation or Equipment Because of Change The only equipment that was added because of the change was a "pump tube" located at the liner's edge in the SE quadrant of the tank liner. This tube is an aluminum tube, 6" diameter at the top and 3" diameter for the lower 5 feet. This tube penetrates the bottom of the tank liner so that access can be gained into the bottom annulus between the original tank and the tank liner. This access is needed to check the annulus for water accumulation and to allow removal of any accumulated water. An eductor pump system was purchased to fit in the pump tube for the removal of accumulated water. The pump is only located in the tube when water is being removed; otherwise the pump tube is empty. A radiation shield plug is located at the top of the pump tube to prevent radiation streaming into accessible locations.
The pump tube is checked regularly, when the reactor is shutdown, for water accumulation.
Accident and/or Malfunction Analyses A copy of the design calculations for the tank liner is attached as Attachment 2. These accident/malfunction calculations include static and dynamic pressures that could result from water pressure, lifting and placement, and a design basis (0.2 G force) earthquake.
Additional Preliminary Responses Based on Information Received from the Colorado School of Mines:
Question 8. The technical parameters of the GSTR are being analyzed using the MCNP version 5 and RELAP version 5, mod 3.3. These analyses are being performed using the Oregon State University relicensing work as a starting point for the methodology. The code results will be benchmarked to the GSTR operating data. After the existing core model is finalized, the limiting core configuration will be modeled and analyzed. These models are being worked on and we expect to have final neutronic and thermal hydraulic results by October 31, 2011.
Question 9. We have a limiting core configuration determined, which will include a number of new 12 weight% fuel elements in the center of the core. However, since our neutronic and thermal hydraulic models are not completed, we do not have control rod worths or excess reactivities calculated for all configurations. Again, we expect to have these results by October 31, 2011.
Question 10. The fuel and moderator temperatures that are used are 293 K for low power operations and 600 K for full power operations. The void and power coefficients will be determined by October 31, 2011.
Question 12. The DNBR analysis will be done using RELAP version 5, mod 3.3. The model used for the GSTR was received from the Oregon State University relicensing effort and has been adapted for the GSTR conditions. These results will be available by October 31, 2011.
Question 15.1 The power density values given in our original license renewal submission are being recalculated with the MCNP version 5 model. Preliminary MCNP results are showing power peaks around 17 kW per element in the existing core. The limiting core will obviously have higher values. We expect that the peak power per element will stay below 22 kW for all core configurations. These results will be available by October 31, 2011.
Sincerely, C
Tim DeBey Qý07---
USGS Reactor Supervisor I declare under penalty of perjury that the foregoing is true and correct.
Executed on 8/30/11 : TRIGA Reactor Aluminum Tank Liner Specifications : Design Calculations for United States Geological Survey 1MW Mark I TRIGA Reactor -
Tank Liner Copy to:
Betty Adrian, Reactor Administrator, MS 975 USGS Reactor Operations Committee
- TRIGA Reactor Aluminum Tank Liner Specifications TRIGA REACTOR ALUMINUM TANK LINER SPECIFICATIONS FOR UNITED STATES GEOLOGICAL SURVEY FEDERAL CENTER 6TH & KIPLING LAKEWOOD, CO BY GILLAN'S ENGINEERING, INC.
5126 W 38TH AVE DENVER, CO 80212 (303) 480-0471 (revised original tank specification) 9-25-87
Part 1. General A. Definitions. Whenever used in any part Of this specification, the following shall have the respective meanings set forth below:
- 1. Purchaser shall mearn an authorized representative of the organization issuing the contfact for the work contained herein.
- 2. Fabricator shall mean the successful bidder for the work, material, and equipment included under this specification.
- 3. Ins2ector shall mean an authorized representative of the Purchaser.
B. Drawings arid Sg ecifications. The Purchaser- vill furnish to the Fabricator, free of charge, such numbers of drawings and specifications reasonably necessary for the execution of the work. The drawings accompany the specifications and they are by this reference incorporated into and shall become a part of the specifications.
C. Tests and Inspection. Where tests are required by the specifications, arrangements for- the conduction of such tests shall be made and all expenses in connection therewith shall be borne by the Fabricator. Such tests and inspections shall be made by an independently qualified inspection firm or agency approved by the Purchaser-. All tests shall be witnessed by the Purchaser. The Fabricator shall review, certify and submit to Purchaser for r eview all inspection reports, radiographs and material certifications. It shall be the responsibility of the fabricator to notify the Purchaser five (5) working days in advance so witnessing of tests can be arranged without delaying the work.
D. QualitY of Work and Materials. All materials, parts and equipment furnished by the Fabricator shall be new, high grade, and free from defects and imperfections. Workmanship shall be in accord with the highest standard practices. Both materials and workkmanship throuyhout shall be at all times subject to the approval of the Inspectors.
E. Reference Standa ds and Specificaticns. The following listed standards and i-ipecifications, as applicable to the work involved, forrm a part of this specification.
American Society of Mechanical Engineers (ASME)
TRIGA REACTOR TAN1{ T'.NER £'P'ECTFICATIONS il C-1 I
Par-to of Section 1IfMaterials Specifications, Part B-
-Nonferrous Materials, of the 1986 edition of the ASME Boiler and Pressure Vessel Code as follows:
ASME SB-209 Specification for. Aluminum--Alloy Sheet and Plates ASME SB-211 Specification for Aluminum--Alloy Bars, Rods and Wire ASME SB-221 Specification for Aluminum- -Alloy Extruded Bars, Rods and Shapes ASME SB-241 Specification for Aluminum--Alloy Seamless Pipe and Seamless Extruded Pipe AMSE SB-211 Specification for Aluminum -- Alloy Bolts Parts of Section II Materials Specifications:
Part C Welding Rods, Electrodes, and Filler Metals, of the 1986 edition of the ASnE Boiler and Pressure Vessel Code ASME SFA-5.10 Specification for Aluminum and Aluminum Alloy Welding Rods, Class ER 4043 Part of Section V, Nondestructive Examination, Subsection A of the 1986 edition of the ASNE Boiler- and Pressure Vessel Code as follows:
Article 6 Liquid Penetrant Examination Parts of Section V, Nondestructive Examination, Subsection B, for the 1986 edition of the ASME Boiler. and Pressure Vessel Code as follows:
Article 24 Liquid Penetrant Standards Parts of Section III, Division 1, of the 1986 edition of the ASME Boiler and Pressure Vessel Code as follows:
Subsection NB Acceptance Standards Para. NB-5300 Subpara NB-5320 Radiographic Acceptance Standards Subpara NB-5350 Liquid Penetrant Parts of Section IX, Welding & Br.azing Qualifications, of the 1986 edition of the ASME Boiler. and TRIGA REACTOR TANK LINER SPECIFICATIONS PAGE 2
Pressure Vessel Code as followoi Part QW Welding Aerospace Material Specifications (AMS) as follows:
AMS 2568A Hard Coating Treatment--Aluminum Alloys F. Packaging aýnd Shi- 2 rent.
- 1. All items shall be thoroughly cleaned of all grease, water, and other foreign matter.
- 2. All fabricated items shall be packed for shipment and shall conform to standards of packaging requirements for the carriers. No stacking of items will be permitted where metal surfaces can come in contact with other metal surfaces.
- 3. Seal off the open end of the tank with a wood frame, dust tight cover. A minimum of 3/4 inch plywood shall be used over opening.
- 4. The tank shall be loaded in a secure and safe manner. Extra bracing and special handling shall be supplied by the Fabricator' as necessary to prevent deformation of the tank in shipment.. All aluminum surfaces shall be protected from direct contact with bracing or crating and the elements during shipping cr storagce.
- 5. Fabricator will prepare all items for shipment and load aboard truck carrier selected by Purchaser.
Pert 2. SaOLe.
The work covered by this specification consists of furnishing all labor, materials, appliances, and equipment, and performing all coperations in connection with the fabrication, assembly, testing, bracing, shoring and loading for shipment of one aluminum reactor tank, complete, including special test fittings and cover plates, in strict accordance with this specification and the applicable drawings and subject to the terms and conditions of the contract.
Pert 3. Aluminum Tank.
TRIGA REACTOR TANK LINER SPECIFICATIONS PAGE 3
A. Codes. The fabrication, inspection, testing, handling, and installation shall be in strict accordance with this specification and with Section VIII and IX of the latest edition of the ASME Boiler and Pressure Vessel Code; however, a Code Stamp is not required. In the event of conflict between this specification and the codes, the Fabr.icator' shall notify the Purchaser and secure a written clarification before proceeding with the work.
B. Alternate Quotations and Deviations. The Fabricator may quote prices based on alternate construction methods when deviations from this constyruction will improve design, delivery, or decrease cost. List all such deviations and submit to the Purchaser in writing. Written approval will be required prior to putting changes into effect. If no exceptions are taken, it will be assumed that the pr-oposal is in stryict compliance with this specification.
C. DrawingE Ly Fabricator. The Fabricator shall submit to the Purchaser one reproducible tracing of his final fabrication drawings and any applicable standard. These drawings and standards shall locate plate Joints in plan and elevations, show construction details, such as all weld joint design, welding procedures and processes to be used, lifting lugs, slings, bracing jigs, fixtures, gussets, other reinforcements, and fabrication tolerances. One copy will be returned to the Fabricator stamped for fabrication as noted.
Fabricator shall not proceed until this stamped drawing is received unless written instr-uctions are given to the contrary. Shop drawings stamped by Purchaser. does not relieve the Fabricator of the responsibility for, fabrication and testing of the tank in accordance with the specification.
D. Functional Re uirernents and Basi.s for Design.
- 1. The Tank is to be a leak-tight container, for.
demineralized water, filled to 3 inches below the top channel. The tank plate thiulki-esses specified on the Purchaser.'s drawings are minirmum allowable. The Fabr-icator.
shall be responsible foy- desicnu of tank bracing required to suppor-t the tank during fabrication, shipping and handling, all in accordance with the basis lfor design.
- 2. The Following Re uire ments are the basis for-design of the aluminum tank using Part UNF of Section VIII of the ASME Unfired Pressure Vessel Code, latest edition.
- a. Oterjatinq PreEsure: 24.5 foot static head of water.
- b. ~Pec-ic Tign r.:-atures. 150 degrees F (maximum).
TRIGA REACTOR TANK LINER SPECIFICATIONS
- c. No Bracing, IntLe.L-al oi- External.
- d. Shell Thickness shall bie at least 1/4 inch.
E. Materiale.
- 1. Tank material shall be one of the following aluminum alloys: 5052-H32, 6061-T4 or 5154-H32, and shall conform to Specification SB-209 from the ASME Pressure Vessel Code, Section VIII, latest edition. Other- materials may be considered, but may be used only if approved in writing *by.
Purchaser. The first choice shall be 5052-H32 alloy.
Welding filler- wire shall be as follows (or equivalent approved by Purchaser): on the 5052 alloy use AWS-ASTI E 5154; on the 6061 alloy use AWS-ASTM E 4043; on the 5154 alloy, use AWS-ASTM E 5554; on combinations of 5000 series to 6061 alloy use AWS-ASTM E 4043.
- 2. Bolts that weld to tank bottom shall be 6061-T6 aluminum alloy and hayrdcoat anodized per. AMS-2468, except anodize shall be clear..
- 3. Aluminum Angle (Alcoa die 4892) shall be of alloy 6061-T6, or. equivalent as a.approved by the Purchaser.
F. Shop Fabrication.
- 1. Handling nd ForminQg. With the following exceptions, the aluminum used in the work is to be handled and formed in a normal manner.
- a. Aluminum to be used for the tank shall be stored in a clean place, free from dir.t, grease, etc.
- b. Care shall be taken not to nick, scratch, or, otherwise mar aluminum surfaces.
- c. All rolls and machine tools used in for-ming. the aluminum parts shall lie clean arnd free from grease, dirt, shavings, turnings, etc.
- d. Tolerances as specified on drawings shall bie maintained. Deviations shall tie subject to written approval by the Purchaser..
- e. Suitable lifting lugs, slings and handling equipment shall be provided by the Fabricator, either- as shown on the Purtchaser's drawings or in other locations where lifting of the tank can be accomplished during fabrication and shipping.
- 2. Special Creat.rutic, Features shall be complied with in fabrication, testing,. and preparation for shipping and field installation.
TRIGA REACTOR TANK LINER SPECIFICATIONS PAGE 5
- a. Round-off all sharp corners to 1/16" r-adius minimum.
- b. Fabr-icato- shall Ic-cate all shell girth and longitudinal seams on shop drawificqS and identify by number-each plate or shell course.
- c. The tank E-hall be cormpletely fabricated and tested in the shop prior to Ehipment.
- 3. Welding. All welds shall be full penetration welds unless otherwise specified, and shall be in conformance with this specification, Part 4.
.4. Testing Sequence shall be as follows:
- a. Penetrant inspection of all welde shall be in conformance with Part 5B of this specification.
- b. Welds shall hbe radiographed in conformance with Part 5A of this specification.
- c. Air. pressure test of the completed tank shall be in conformance with Part 5C of this specification.
- d. As an alternate to the air pressure test, a hydr-ostatic test may be performed in confo-mance with Part 5D of this specification.
- e. A leak test of all welds shall be performed in conformance with Part 5E of this specification.
- 5. Defects found at any stage of testing shall be.
repaired at that stage, and all tests shall be repeated for-the defective area.
- 6. Responsibil1ty. The Fabricator. shall conduct and be fully responsible for. the inspection and tests called for in these specifications, and shall maintain cC-Toplete .- eccr-ds of all tests. Certified copies of all test and inspection reports shall be supplied to the Purchaser..
- 7. Finish.
- a. All wire brushes, welders' hammers or- scrapers used on tank must be of AISI 300 series stainless steel.
When welds are to be ground, aluminum oxide disks shall be used. The disks shall be new or dressed to remove any trace of non-aluminum grindings, and of a type that does not leave abrasive particles embedded in welds.
- b. nsi of t:: nk shall :e 1:ept clean, free of gr-ease, di-ft., etc.
TRIGA REACTOR TAN]" LINER SPECIFICATIONS PACE t
c . Care r-s)ll b~e cx.-rcdEt d during fIb icatioCn not to mar the inside surfaces of the tank.
- d. At the conclusion of all work and testing, the..
tank shall be thoroughly cleaned inside and out with a suitable solvent (Toluene, acetone, or others) to remove all grease, dirt, grime, etc.,, before packing for shipment.
8.- epcrts.
- a. Welding Documents: Prior to fabrication of the tank, the Contractor shall submit to the Purchaser for review one copy of each of the following: welding procedure specification; qualification test reaults of welding procedures; welder percformance qualification test results.
The welding procedure specifications and welding personnel shall be qualified in accordance with the requirements of ASbE Section IX.
- b. Prior- to any production fabrications; procedures for welding, liquid penetrant inspection, x-ray inspection, leak testing and cleaning shall be submitted to the Purchaser for approval.
- c. Within 10 days after tank is released for" shipment, the Fabricator shall submit copies of each of the following to the Purchaser.
(I) Dimensions of finished tank (5 copies).
(2) Two copies of certified test reports of all material used in the fabrication of this equipment.
(These are to be available to the Inspector upon request during fabrication. )
(3) Two certified copies of all test and inspection reports.
Part 4. Aluminum Welding.
A. Code. All welds shall be full penetration welds unless otherwise specified, and in accordance with Sections VIII and IX of the ASME Boiler and Pressure Vessel Code, latest edition.
B. Preiaratior, of Joints.
- 1. Welding JointS shall be prepared so as to permit complete fusion with complete Joint penetr-ation. Multipass welding from both sides is recommended to minimize distortion.
TRIGA REACTOR TANK LINER SPECIFICATIONS FTM71 7
- 2. All weld Joint edges shall be prepared either. by machining, sawing, or- grinding with tools which leave.. no r-esidue on the joint faces.
- 3. Surfaces to be welded shall be clean and free fr-om foreign material for a distance of at least 2 inches fr-om the joint edges.
- 4. Prior to welding, all Joints shall be thoroughly wire brushed Ior- a distance of at least one inch on each side of the joint to remove aluminurm oxide in the weld region.
Only Type AISI 300 stainless steel wi-re br-ushes shall be used on this wor-k.
- 5. Pr-ior to welding, but after wire brzushlng, all.
Joints shall be wiped with methyl alcohol and air-dried' to remove any dirt of foreign material in the weld region.
- 6. After- the weld Joints have been cleaned, the joints shall be handled only with clean cloth gloves.
- 7. The joint edges must not. be placed in contact with any material which could contaminate the surfaces after cleaning.
- 8. The use of welding flux of any kind is not per-mitted on this work.
C. Methods and Mechanics of Welding.
I. Welds shall be made by the inert-gas shielded consumable electrode welding method (nIG) or- the tungsten inert-gas shielded arc welding pr-ocess (AC-TIG or- DC-TIG).
- 2. The inert gas used with the MIG pr-ocess shall be helium, argon, or- a mixture of these gases. The iner-t gas used with the AC-TIG process shall be argon. The inert gas used with the DC-TIG process shall be helium.
- 3. Any inert gas used shall have a minimum pur-ity of 99.95 percent. The flow of Inert gas shall he sufficient to*
pr-operly protect the weld region during welding and coollng.
- 4. £electicro., of the welding process ahall he based on production of the bec:t quality welds with a minimum of distor-tion and residual stx--:-ss. in the finished work.
Processes other than specified may be used only with the wr-itten consent of the Purchaser.
- 5. When a Joint requires more than one pass, the preceding pass shall bie cleaned with a stainless steel wi-re br-ush prior to deposition of the nrexct pass.
TRIGA REACTORl TANI{ LINER, SPECIFICATIONS PMA C.3
- 6. When a weld joint if welded frome both sides; i.e., full penetration weldc, the ,side welded second (opposite aide) shall be gound out to sound metal and liquid penetrant inspected in accordance with Part 5 prior- to depositing metal on that side.
- 7. When using the TIG welding process, stopping of the arc shall occur in the Joint using a gr-adual reduction of welding current to permit the molten weld puddle to 'solidify slowly. After most of the puddle has solidified, the arc will be carried back over the completed weld Joint during the final reduction of the welding current to a point where no molten metal is observed beneath the arc. At this point the arc will be broken.
- 8. No peening of welds will be permitted.
D. Filler' Wire.
- 1. Only filler wire from a special marked container reserved for this work only shall hie used for- any welding, including tacks or temporaary welds.
- 2. All filler. metal shall be clean and dry.
- 3. All filler wires used for this work shall be stored in a separate area from other filler materials. The area shall be free of dirt, gcrease, or other for-eign material. Access to filler. wire shall be permitted only by responsible personnel supervisiong the fabrication of the work. Care must be used to assure that no unapproved wire is used on any aluminum work. The type of wire to be used is specified in Part 3, paragr-aph E.1 of this specification.
The wire shall be smooth, clean and free of surface defects.
E. Visual Inspection shall be made during and after each weld pass. Any defects detected shall be removed and repairs made before deposition of the next weld pass.
F. Qualification of Welding P:r-ocedures and Welders.
- 1. The welding proceduxre(s) and welders shall be qualified in accor.'a-nce with the requIrements of the ASIIE Boiler and Pres-sure VeEsel Code,Section IX latest edition, with the following addltional r-equirements:
- a. Aluminum alloy uoed for. the qualification test plates shall be of the same thickness, alloy and temper as used in the item to be fabricated.
- b. The test plates shall receive 100 percent radiographic inspection of the welds and shall meet the I-equir-ements of UW-5! fo £'ecticn VII of the AS)IE Boiler-and Pressure Vessel Code, Fepair welding is not permitted.
TRIGA R.7.ACTO=R TAN, L1-EI-Z _P'EC.IPICATIONS q 17.";:]
- c. The test plates shall be given a liquid penetrant inspection of the welds and shall meet the requirements of Part 5, paragraph B. Any evidence of cracking or. excessive pofosity shall be cause for. re-testing.
- d. In addit-ion to the groove weld qualification test plate(s) for p(erDfIrnoricne iual.ification required by Section IX of th ASME Code, weldero shall qualify on a fillet weld test plate in accordance with the requirements of Section IX.
- e. At least one weld stop and start per pass shall be made near the center. of procedure and welder qualification test plates.
- 2. All other te&t.s of weldE as required by the qualification code shall be piex for.med. and a comiplete report of the qualification resLlts shall be made.
Part 5. Testing and ngpegt!ion.
A. RadioqE!a2hiS Inspection.
I.. One hundred percent of every full penetration weld Joint not specifically exempted by Purchaser in writing shall be radiographed in conformance with Subsection UW-51 of Section VIII of the ASME Boiler and Pressure Vessel Code to demonstrate that proper weld quality is attained.
- 2. When any of the weld as repzresented by radiography contains rejectable defects as specified by UW-51, the weld shall be removed, rewelded and 100 percent radiographed.
- 3. Each radiograph shall bie made as soon as practicable after the completion of the increment of weld that is to be examined.
- 4. X-ray shall be used, gamma ray is not acceptable.
- 5. Final acceptance of all radiographs shall be
.obtained from the inspector.
- 6. Originals of the developed film of radiographs shall be properly identified and made available to the Purchaser-, and after' acceptance of the tank shall become the property of the Purchaser.
B. Penetrant Inspection. All finihed welds and the second side of a full penetration weld shall be checked for defects using a liquid penetrant test in conformance with TRIGA REACTOR TANK LINER SPECIFICATIONS PAGE 10
Appendix 8 of the ASME Doiler and Pressure Vessel Code and the following.
- 1. The Fabr-icato.x shall Submit a detailed wr-itten liquid penetrant inspection procedure for approval by the Purchaser.
- 2. Liquid Penetrant Acceptance Standards.
- a. All linear indication_- are unacceptable and shall be r-emoved comupletely and xepair welded.
- b. All non-linear (rounded) indications with any dimension which exceed2 I/,1," wice unacceptable and shall he completely removed and repair welded.
- 3. Rejectable defe.cts shall be xepaired and retested.
C. Air-Pressure Test. The alr-pressure test shall be conducted .to demonstrate adequate strength of the tank.
- 1. The tank shall be internally pressur-ized to a pressure of 10 pounds per square inch gage using suitable cover, plates and fittings.
- 2. After- completion of the test, the pressure can be decreased to that specified for performance of the leak test (soap bubble).
- 3. It is the responsibility of the Fabricator for the safe per-formance of this test.
D. HydgriostatIc Test (Alternate to Air-Pressure Test).
- 1. Hydrostatic testing shall be performed on the completed tank.
- 2. The hydrostatic test shall consist of placing the tank in a vertical position, andfilling the tank with clean water with a pH between 6. 0 and 7. 0. After 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />, all outside surfaces shall be visually inspected for leaks. Any trace of moisture on the outside surfaces must be traced to the sour-ce of the leaks. The leaks must bie repaix-ed and the test repeated. Water shall not remain in the tank longer, than. 36 hour-s; after the water is removed, all surfaces of the tank shall be wiped dry with clean, lint-free rags.
E. Leak Test.
- 1. The leak testing . shall be per-formed on the completed tank assembly.
TRIGA REACTOR TANK LINER SPECIFICATIONS
!"ACE, 11
- 2. The tanh shall Lbe I.illed wiLh ai. at a pressure of 4 pounds per square inch gaqe. The tank shall he br-aced and supported as requi:ed to TaDItain the dimensional tolerances specified.
- 3. After- the tank has been pressurized, a soap bubble test shall be applied to all weld regions and regions where a large amount of cold work has been applied to the tank (such as at. the knuckle between the side plates and the bottom).
- 4. The liquid used for testing shall be "Leak-Tec" No. 277-C, a product of American Gas and Chemicals, Inc.,
P.O. Box 101, Gracie Station, New York, NY 10021, or. an equal product.
- 5. The "Leak-Teo" shall be s.prayed or brushed over all surfaces to be checked and the surfaces shall be carefully examined visually for white foam or live bubbles.
- 6. Any leaks detected by this test shall be repaired, and the test shall be repeated until no leaks ar-e detected.
TRIGA REACTOR TANI!,'1 LINEi" SPECFICATI CtS F..... 12