| addressee name = Lising A J

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{{#Wiki_filter:UNIVERSITY OF TEXAS AT AUSTIN RESEARCH REACTOR LICENSE NO. R

-1 29 DOCKET NO. 50

-602 UNIVERSITY OF TEXAS AT AUSTIN LICENSE RENEWAL APPLICATION DECEMBER 12, 201 1        REDACTED VERSION*

      *REDACTED TEXT AND FIGURES BLACKED OUT OR DENOTED BY BRACKETS

TDepartment of Mechanical Engineering) THE UNIVERSITY OF TEXAS AT AUSTIN Nuclear Engineering Teaching Laboratory Austin, Texas 78758 512-232-5370" FAX 512-471-4589" http://www.

me. utexas.edul-netl/December 12, 2011 ATTN: Document Control Desk, U.S. Nuclear Regulatory Commission, Washington, DC 20555-0001 Allan Jason Lising Project Manager Division of Policy and Rulemaking Research and Test Reactors Licensing Branch  

Docket No. 50-602, Request for Renewal of Facility Operating License R-129 Sir: In accordance with direction provided by L. N. Tranh (ADAMS ML110040316), we respectfully request renewal of the University of Texas at Austin TRIGA II nuclear research reactor located at the Nuclear Engineering Teaching Laboratory at the University of Texas at Austin. Enclosed you will find: 1) A completed, updated Safety Analysis Report (SAR)2) Financial qualifications specified in 10CFR50.33 is incorporated in the SAR Chapter 15;a. None of the provision of 10CFR50.33(d) apply.b. Based on current budget and expenditures, estimated annual operating costs with the source of funding indicated for the first 5-year period after license renewal is incorporate in Chapter 15.3) Financial qualifications regarding decommissioning is provided in Chapter 15, a. An estimate of decommissioning based on NR guidance, b. A statement of intent regarding intent to seek support for decommissioning at the appropriate time, c. A description of cost adjustment of decommissioning costs is provided with the current estimate based on the methodology, d. Documentation that the University of Texas is a State agency and a State of Texas government licensee under 10CFR50.75*(2)(iv), and that University funding obligations are backed by the State.4) An Environmental Report 5) The Technical Specifications

: 6) The University of Texas facility has currently approved programs on file with the NRC for Operator Requalification Program, Emergency Plan, and Physical Security Plan, and does not propose changes in these plans and programs at this time.d(UL(

===1.2 Summary===

and conclusions on principle safety considerations The decision to build a new TRIGA was based on historical experience with a TRIGA II on main campus. Space considerations on main campus and a well-established infrastructure at the PRC campus led to facility siting.TRIGA II reactors routinely operate at power levels up to approximately 2 MW with natural convection.

At power levels less than 2 MW, fission product inventory is limited enough that emergency planning requirements are somewhat simplified.

Therefore, 1.1 MW was initially selected as the maximum steady state license limit providing a large margin to thermal limits and complex emergency planning.Heat generation in TRIGA fuel produces less than Y2 of critical heat flux with natural convection at power levels up to about 2 MW (see Chapter 5). The initial license power level of 1.1 MW provides an extremely large margin to thermal hydraulic limits in passive, natural circulation.

The TRIGA ZrH fuel inherently reduces the potential for thermal fission as fuel temperature increases so that temperature increases with operation at power intrinsically limit maximum steady state power level. The TRIGA fuel design retains a large fraction of fission products generated during operation, with stainless steel cladding acting as a passive barrier to release for the fission products that escape the fuel matrix.The NETL TRIGA shielding was designed to limit personnel exposure rates from radiation generated during reactor operation in accessible areas of the pool and shield structure at 1.5 MW to less than 1 mrem/hr. The maximum dose rate is shown to be at floor level.Current experimental programs at the beam ports limit routine access to the biological shielding surface near the core. Additional shielding information is provided in Chapters 3, 4 and 10.The principle off-site exposure source term during normal operations is 4'Ar, a noble gas with a 110 minute half life. Stack effluent is limited to maintain receptor doses to 109CFR20 limits, as discussed in Chapters 9 and 11. There are no routine liquid releases, and the production of radioactive waste during normal operations is extremely limited (with most radioactive waste held for decay). Accident analysis (Chapter 13) demonstrates potential consequences from postulated scenarios do not result in unacceptable consequences.

The reactor design has many safety features, including a large margin to thermal hydraulic limits, passive cooling, robust shielding, fuel matrix characteristics, and stainless steel Page 1-2 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 1 cladding.

Buildup of radioactive materials in the facility is controlled by a dynamic confinement and an argon purge system.1.2 General description of the facility A. Site Land development in the area of the current NETL installation began as an industrial site during the 1940's. Following the 1950's, lease agreements between the University and the Federal government led to the creation of the Balcones Research Center. The University became owner of the site and in 1994 the site name was changed to the J.J. Pickle Research Campus (PRC) in honor of retired U.S. Congressman James "Jake" Pickle.The PRC is a multidiscipline research campus on 1.87 square kilometers.

The site consists of two approximately equal areas, east and west. An area of about 9000 square meters on the east tract is the location of the NETL building.

Sixteen separate research units and at least five other academic research programs conduct research on the PRC. Adjacent to the NETL site are the Center for Research in Water Resources, the Bureau of Economic Geology, and the Research Office Complex, illustrating the diverse research activities on the campus. A Commons Building provides cafeteria service, recreation areas, meeting rooms, and conference facilities.

A more complete description of the environment surrounding the NETL is provided in Chapter 2.B. Building One of the primary laboratories contains the TRIGA reactor pool, biological shield structure, and neutron beam experiment area. A second primary laboratory has walls 1.3 meter (4.25 ft) thick for use as a general purpose radiation experiment facility.

Other areas of the building include shops, instrument

& measurement laboratories, and material handling facilities.

An Annex was installed adjacent to the NETL building in 2005, a 24 by 60 foot modular building.

The annex provides classroom space and offices for graduate students working at the NETL.C. Reactor The largest room in the NETL building is a vault type enclose that serves as a confinement volume for the UT TRIGA nuclear research reactor. The TRIGA Mark II reactor is a versatile and inherently safe research reactor conceived and developed by General Atomics to meet education and research requirements.

The UT-TRIGA reactor provides sufficient power and Page 1-3 CHAPTER 1, THE FACILITY 12/2011 neutron flux for comprehensive and productive work in many fields including physics, chemistry, engineering, medicine, and metallurgy C31ETHOL RO1D DRIVrE REACTOR RIOCDEi CENRA /AL.UlqIRINU TANK[E" XPEiIR IEN T* .., .~EE HLABL E* ., *u .o--:*S ~TRANIIF[R" 4* -t " iCOB[C I ..ROTAPIl.-.5 SPaCs aon, , a r o le RAC;K * '1 ,.,REFLECTOR.

CON O LT0 RO0 [D PRr FLOOR L]INE core is surrounded by a reflector, a 1 foot thick graphite cylinder.C.l Reactor Core.The reactor core is an assembly of cylindrical fuel elements surrounded by an annular graphite neutron reflector.

Fuel elements are positioned by an upper and lower grid plate, with penetrations of various sizes in the upper grid plate to allow insertion of experiments.

Each fuel element consists of a fueled region with graphite sections at top and bottom, contained in a thin-walled stainless steel tube. The fuel region is a metallic alloy of low-enriched uranium in a zirconium hydride (UZrH) matrix. Physical properties of the TRIGA fuel provide an inherently safe operation.

Rapid power transients to high powers are automatically suppressed without using mechanical control; the reactor quickly and automatically returns to normal power levels.Pulse operation, a normal mode, is a practical demonstration of this inherent safety feature.Page 1-4 THE UNIVERSITY OF TEXAS TRIGA 11 RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 1-' .Figure 1.2, C:ore and Support Structure Details C:.2 Reactor Reflector.

The reflector is a graphite cylinder in an aluminum-canister.

A 10" well in the upper surface of the reflector accommodates an irradiation facility, the rotary specimen rack (RSR), and horizontal penetrations through the side of the reflector allow extraction of neutron beams. In 2000 the canister was flooded to limit deformation stemming from material failure in welding joints. In 2004, the reflector was replaced with some modification, including a modification to the upper grid plate for more flexible experiment facilities.

D. Reactor Control.The UT-TRIGA research reactor can operate continuously at nominal powers up to 1.1 MW, or in the pulsing mode with maximum power levels up to about 1500 MW (with a trip setpoint of 1750 MW) for durations of about 10 msec. The pulsing mode is particularly useful in the study of reactor kinetics and control. The power level of the UT-TRIGA is controlled by a regulating rod, two shim rods, and a transient rod. The control rods are fabricated with integral extensions containing fuel (regulating and shim rods) or air (transient rod) that extend through the lower grid plate for full span of rod motion. The regulating and shim rods are fabricated from 134C contained in stainless steel tubes; the transient rod is a solid cylinder of borated graphite clad in aluminum.

Removal of the rods from the core allows the rate of neutron induced fission (power) in the UZrH fuel to increase.

The regulating rod can be operated by an automatic control rod that adjusts the rod position to maintain an operator-selected reactor Page 1-5 CHAPTER 1, THE FACILITY1201 12/2011 power level. The shim rods provide a coarse control of reactor power. The transient rod can be operated by pneumatic pressure to permit rapid changes in control rod position.

The transient rod moves within a perforated aluminum guide tube. Details of the control rods are provide in Chapter 4.The UT-TRIGA research reactor rod control system uses a compact microprocessor-driven control system. The digital control system provides a unique facility for performing reactor physics experiments as well as reactor operator training.

This advanced system provides for flexible and efficient operation with precise power level and flux control, and permanent retention of operating data. A more complete description of the rod control system is provided in Chapter 7.E. Experiment Facilities.

Facilities for positioning samples or apparatus in the core region include cut-outs fabricated in the upper grid plate, a central thimble in the peak flux region of the core, a rotary specimen rack in the reactor graphite reflector, and a pneumatically operated transfer system accessing the core in an in-core section. Beam ports, horizontal cylindrical voids in the concrete shield structure, allow neutrons to stream out away from the core. Experiments may be performed inside the beam ports or outside the concrete shield in the neutron beams. Areas outside the core and reflector are available for large equipment or experiment facilities.

A brief description of the facilities follows; a more complete description is provided in Chapter 10.E.1 Upper Grid Plate 7L and 31 Facilities The upper grid plate of the reactor contains four removable sections configured to provide space for experiments otherwise occupied by fuel elements (two three-element and two seven-element spaces). Containers can be fabricated with appropriate shielding or neutron absorbers to tailor the gamma and neutron spectrum to meet specific needs. Special cadmium-lined facilities have been constructed that utilize three element spaces.E.2 Central Thimble The reactor is equipped with a central thimble for access to the point of maximum neutron flux.The central thimble is an aluminum tube extending through the central penetration of the top and bottom grid plates. Typical experiments using the central thimble include irradiation of small samples and the exposure of materials to a collimated beam of neutrons or gamma rays.E.3 Rotary Specimen Rack (RSR)A rotating (motor-driven) multiple-position specimen rack located in a well in the top of the graphite reflector provides for irradiation and activation of multiple samples and/or batch Page 1-6 THE UNIVERSITY OF TEXAS TRIGA 11 RESEARCH REACTOR a12/2011 SAF ETY ANALYSIS REPORT, CHAPTER 1 production of radioisotopes.

Rotation of the RSR minimizes variations in exposure related to sample position in the rack. Samples are loaded from the top of the reactor through a tube into the RSR using a specimen lifting device. A design feature provides the option of using pneumatic pressure for inserting and removing samples.E.4 Pneumatic Tubes A pneumatic transfer system supports applications using short-lived radioisotopes.

The in-core terminus of the system is normally located in the outer ring of fuel element positions, with specific in-core sections designed to support thermal and epithermal irradiations.

The sample capsule is conveyed to a sender-receiver station via pressure differences in the tubing system.An optional transfer box permits the sample to be sent and received to three different sender-receiver stations.

One station is in the reactor confinement, one is in a fume hood in a laboratory room, and the third operates in conjunction with an automatic sample changer and counting system.E.5 Beam Port Facilities Five neutron beam ports penetrate the concrete biological shield and reactor water tank at core level, as shown in Fig.1.3. The beam ports were designed with different characteristics to accommodate a wide variety of experiments.

Specimens and/or equipment supporting experiment programs may be placed inside a beam port or outside the beam port in a neutron beam from the beam port.Shielding reduces radiation levels outside the concrete biological shield to safe values when beam ports are not in use. Beam port shielding is configured with an inner shield plug, outer shield plug, lead-filled shutter, and circular steel cover plate. A neutron beam coming from a beam port may be modified by using collimators, moderators and/or neutron filters.Collimators are used to limit beam size and beam divergence.

Moderators and filters are used to change the energy distribution of neutrons in beams (e.g., cold moderator).

E.5 (1) Beam Port 1 (BP1)BP1 is connected to BP5, forming a through port. The through port penetrates the graphite reflector tangential to the reactor core, as seen in Figure 5-2. This configuration allows introduction of specimens adjacent to the reactor core to gain access from either side of the biological shield, and can provide beams of thermal neutrons with relatively low fast-neutron and gamma-ray contamination.

Page 1-7 CHAPTER 1, THE FACILITY I 12/2011 A reactor-based slow positron beam facility is being fabricated at BP1. The facility (Texas Intense Positron Source) will be one of a few reactor-based slow positron beams in the world.The Texas Intense Positron Source concept includes a copper source, a source transport system, a combined positron moderator/remoderator assembly, a positron beam line and a sample chamber.E.5 (2) Beam Port 2 (BP2)BP2 is a tangential beam port, terminating at the outer edge of the reflector.

A void in the graphite reflector extends the effective source of neutrons into the reflector for a thermal neutron beam with minimum fast-neutron and gamma-ray backgrounds.

Tangential beams result in a "softer" (or lower average-)

BP2 is configured to support neutron depth profiling applications, with a prompt-gamma neutron activation analysis sharing the beam port.Neutron Depth Profiling (NDP) Some elements produce charged particles with characteristic energy in neutron interactions.

When these elements are distributed near a surface, the particle energy spectrum is modulated by the distance the particle traveled through the surface. NDP uses this information to determine the distribution of the elements as a function of distance to the surface.Page 1-8 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 1 Prompt-Gamma Neutron Activation Analysis (PGNAA) Characteristic gamma radiation is produced when a neutron is absorbed in a material.

PGNAA analyzes gamma radiation to identify the material and concentration in a sample. PGNAA applications include: i)determination of B and Gd concentration in biological samples which are used for Neutron Capture Therapy studies, ii) determination of H and B impurity levels in metals, alloys, and semiconductor, iii) multi-element analysis of geological, archeological, and environmental samples for determination of major components such as Al, S, K, Ca, Ti, and Fe, and minor or trace elements such as H, B, V, Mn, Co, Cd, Nd, Sm, and Gd, and iv) multi-element analysis of biological samples for the major and minor elements H, C, N, Na, P, S, Cl, and K, and trace elements like B and Cd.E.5 (3) Beam Port 3 (BP3)BP3 is a radial beam port. BP3 pierces the graphite reflector and terminates at the inner edge of the reflector.

This beam port permits access to a position adjacent to the reactor core, and can provide a neutron beam with relatively high fast-neutron and gamma-ray fluxes. BP3 contains the Texas Cold Neutron Source Facility, a cold source and neutron guide system.Texas Cold Neutron Source. The TCNS provides a low background subthermal neutron beam for neutron reaction and scattering research.

The TCNS consists of a cooled moderator, a heat pipe, a cryogenic refrigerator, a vacuum jacket, and connecting lines. The TCNS uses eighty milliliters of mesitylene moderator, maintained by the cold source system at "36 K in a chamber within the reactor graphite reflector.

A three-meter aluminum neon heat pipe, or thermosyphon, is used to cool the moderator chamber. The heat pipe working fluid evaporates at the moderator chamber and condenses at the cold head.Cold neutrons from the moderator chamber are transported by a 2-m-long neutron guide inside the beam port to a 4-m-long neutron guide (two 2-m sections) outside the beam port. Both neutron guides have a radius of curvature equal to 300 m. All reflecting surfaces are coated with Ni-58. The guide cross-sectional areas are separated into three channels by 1-mm-thick vertical walls that block line-of-sight radiation streaming.

Page 1-9 CHAPTER 1, THE FACILITY 12/2011 E.5 (4) Beam Port 4 (BP4)BP4 is a radial beam port that terminates at the outer edge of the reflector.

A void in the graphite reflector extends the effective source of neutrons to the reactor core. This configuration is useful for neutron-beam experiments which require neutron energies higher than thermal energies.

BP4 was configured in 2005 to support student laboratories.

E.5 (5) Beam Port 5 (BP5)A Neutron Radiography Facility is installed at BP5. Neutrons from BP5 illuminate a sample. The intensity of the exiting neutron field varies according to absorption and scattering characteristics of the sample. A conversion material generates light proportional to the intensity of the neutron field as modified by the sample.F Other Experiment and Research Facilities The NETL facility makes available several types of radiation facilities and an array of radiation detection equipment.

In addition to the reactor, facilities include a subcritical assembly, various radioisotope sources, machine produced radiation fields, and a series of laboratories for spectroscopy and radiochemistry.

The result is that reactor power excursions are terminated quickly and safely.The prompt shutdown mechanism has been demonstrated extensively in many thousands of transient tests performed on two prototype TRIGA reactors at the GA Technologies Page 1-10 THE UNIVERSITY OF TEXAS TRIGA 1I RESEARCH REACTOR SAFETY ANALYSIS REPORT, CHAPTER 1 I 12/2011 laboratory in San Diego, California, as well as other pulsing TRIGA reactors in operation.

These tests included step reactivity insertions as large as 3.5% Ok/k with resulting peak reactor powers up to 8400 MW(t) on TRIGA cores containing similar fuel elements as are used in this TRIGA reactor.Because the reactor fuel is similar, the experience and tests form other TRIGA installations apply to this TRIGA system. As a result it has been possible to use accepted safety analysis techniques applied to other TRIGA facilities to update evaluations with regard to the characteristics of this facility.Table 1.1, SHUTDOWN OR DECOMMISSIONED U.S. TRIGA REACTORS GA-TRIGA III TRIGA MK F, NORTHRUP UT TRIGA UNIV TEXAS BRR UC BERKELEY TRIGA MK I MICH ST UNIV TRIGA COLUMBIA UNIV TRIGA PUERTO RICO NUC CTR UI-TRIGA UNIV. ILLINOIS NRF NEUTRON RAD FACILITY TRIGA CORNELL DORF TRIGA MARK F ATUTR GA-TRIGA F GA-TRIGA I UI-TRIGA MK I TRIGA, VET. ADMIN.thermal power 1,500.00 1,000.00 1,000 1,000 250 250 2,000 1,500 1,000 500 250 250 250 250 100 20 type TRIGA MARK III TRIGA MARK F TRIGA MARK I TRIGA MARK III TRIGA MARK I TRIGA MARK II TRIGA CONV TRIGA MARK 11 TRIGA MARK I TRIGA MARK 11 TRIGA MARK F TRIGA MARK I TRIGA MARK I TRIGA MARK I TRIGA MARK I TRIGA MARK I initial crit 1/1/1966 1/1/1963 1/1/1963 8/10/1966 3/21/1969 1/1/1977 8/1/1960 7/23/1969 3/1/1977 1/1/1962 1/1/1961 1/1/1989 7/1/1960 5/3/1958 8/1/1960 6/26/1959 Table 1.2, U.S. OPERATING RESEARCH REACTORS USING TRIGA FUEL thermal initial crit power ANN. CORE RES. REACTOR (ACRR)UC DAVIS/MCCLELLAN N. RAD. CENTER OSTR, OREGON STATE UNIV.TRIGA II UNIV. TEXAS NSCR TEXAS A&M UNIV.UWNR UNIV. WISCONSIN WSUR WASHINGTON ST. UNIV.PSBR PENN ST. UNIV.AFRRI TRIGA 4,000 2,000 1,100 1,100 1,000 1,000 1,000 1,000 1,000 TRIGA ACPR TRIGA MARK II TRIGA MARK II TRIGA MARK II TRIGA CONV TRIGA CONV TRIGA CONV TRIGA MARK CONV TRIGA MARK F 6/1/1967 1/20/1990 3/8/1967 3/12/1992 1/1/1962 3/26/1961 3/13/1961 8/15/1955 1/1/1962 Page 1-11 CHAPTER 1, THE FACILITY I 12/2011 Table 1.2, U.S. OPERATING RESEARCH REACTORS USING TRIGA FUEL thermal initial crit power ANN. CORE RES. REACTOR (ACRR) 4,000 TRIGA ACPR 6/1/1967 GSTR GEOLOGICAL SURVEY 1,000 TRIGA MARK I 2/26/1969 DOW TRIGA 300 TRIGA MARK I 7/6/1967 ARRR 250 TRIGA CONV 7/9/1964 RRF REED COLLEGE 250 TRIGA MARK I 7/2/1968 UCI, IRVINE 250 TRIGA MARK I 11/25/1969 KSU TRIGA MK II 1,250 TRIGA MARK II 10/16/1962 NRAD 250 TRIGA MARK II 10/12/1977 MUTR UNIV. MARYLAND 250 TRIGA MODIFIED 12/1/1960 TRIGA UNIV. UTAH 100 TRIGA MARK I 10/25/1975 UNIV. ARIZONA TRIGA 100 TRIGA MARK I 12/6/1958 1.4 Summary of operations The UT TRIGA reactor has operated routinely since 1991 except for time required implementing a digital control system as a planned upgrade, and time to replace a failed reflector.

0250 1 0-z 200&150.0..-100 50-z 1992 1995 1998 2001 2004 2007 2010 Year of Operation Figure 1.4A, Days of Operation per Year 35 30 025 i, .20 " ... .... .E.jý20 15 l101992 1995 1998 2001 2004 2007 2010 Year of Operation Figure 1.4B, Burnup per Year 1.5 Compliance with NWPA of 1982 Compliance with NWPA of 1982 is assured by the Department of Energy. A copy of the fuels assistance contract is provided in Chapter 15.Page 1-12 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 1 1.6 Facility history & modifications The Department of Mechanical Engineering of the Cockerel College of Engineering at the University of Texas supports a Nuclear and Radiological Engineering program. Development of the nuclear engineering program was an effort of both physics and engineering faculty during the late 1950's and early 1960's. The program subsequently became part of the Mechanical Engineering Department where it currently resides. The program installed and operated the first UT TRIGA nuclear reactor in Taylor Hall on the main campus with initial criticality in August 1963, rated for 10 kilowatts; the license was upgraded for 250 kilowatts operations in 1968.The Taylor Hall reactor operated for 25 years.In October 1983, planning was initiated for the NETL to replace the original UT TRIGA installation.

The reflector was subsequently replaced.Page 1-13 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 2 2.0 SITE DESCRIPTION The site for the TRIGA reactor facility is located in the east tract of the AJ Pickle Research Campus, an area owned and operated by The University of Texas. The Research Center is located in northern Travis County and the City of Austin about 11.6 kilometers north-northwest of The University of Texas at Austin campus. Fig. 2.1 thru 2.4 display the facility locations in relation to surrounding areas. Located near the transition line between hill country and rolling plains, the site is situated about 7.4 kilometers from where the flood controlled Colorado river crosses the transition region and Balcones fault zone. The JA Pickle Research Campus east and west tracts span part of the inactive fault zone. The east tract is within the transition region to rolling plains.Site location of the TRIGA reactor is in the northeast region of the research center east tract.Adjacent to the north boundary of the research center and near to the eastern boundary, the site location is near the intersection of Braker Lane and Burnet Road. Fig. 2.4 shows the site location within the Ai Pickle Research Campus.2.1 GENERAL LOCATION AND AREA Major activities of The University of Texas at Austin, State of Texas government, and City of Austin business district are centered at respective distances of 11.6, 12.6, and 12.9 kilometers to the south-southwest.

Areas for parking, landscape and access roads are within the general site area. A buffer zone exists between the site area and activities or structures to the east and west. To the west the buffer zone is about 55 meters by 75 meters with parking also about 60 meters by 75 meters. The east buffer region is primarily open space that will provide the access to other development projects north of the general site area.Page 2-1 CHAPTER 2, SITE DESCRIPTION 12/2011...... ...:...*.......

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.... = = N I ~ -K.,......." ... ..., ., ,.. ... _ __L _ _. ., !.. ...., .F, " "O " 8 "  K ~ K.I --Figure 2.1, STATE OF TEXAS COUNTIES Page 2-2 THE UNIVERSITY OF TEXAS TRIGA Ii RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 2 Figure 2.2, TRAVIS COUNTY Page 2-3 CHAPTER 2, SITE DESCRIPTION I 12/2011 Figure 2.3, CITY OF AUSTIN Page 2-4 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR SAFETY ANALYSIS REPORT, CHAPTER 2 I 12/2011 O/14/4//r b I/r~it Ii,/5 1 i/if<I'Pu I ~4< 7 <1 I,~ 451 ii/ Ii;i~ /*1 Pig 2 Figure 2.4, JJ PICKLE RESEARCH CAMPUS Page 2-5 CHAPTER 2, SITE DESCRIPTION I 12/2011 Figure 2.5, LAND USAGE AROUND JJ PICKLE RESEARCH CAMPUS, 2007 Page 2-6 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 2 Most areas adjacent to the Research Center are developed for mixed commercial and industrial activities including warehouses, manufacturing facilities, and small business parks (see Figure 2-5).Mixed commercial and industrial areas south and east of the Research Center are bounded by highway US 183, highway FM 1325 (Burnet Road), and the Texas New Orleans Railroad to the east. Approximately

&#xa9; 0 200 000 FEET NORT 00 G I- -NORTH 100 800 I ACR Figure 2.16, PICLKE RESEARCH CAMPUS 1960 Page 2-29 CHAPTER 2, SITE DESCRIPTION I 12/2011 W, CMM.1C ftaL-u CSUO MG 0 I~ES C2*0 MA&#xfd;-s 80.10 281* hOW 0*WIHA CLLRSITTO CENTER THE UNIVERSITY OF TEXAS AT AUSTIN Figure 2.17, BALCONES RESEARCH CENTER 1990 Page 2-30 UT TRIGA II RESEARCH REACTOR SAFETY ANALYSIS REPORT CHAPTER 2 APPENDIX 1, SUBSURFACE EXPLORATION LOGS I 12/2011 SUBSURFACE EXPLORATION LOG P4oJ0ET NETL Building SORI,. No. B-2 Balcones Research Center OATE 8/13/85 Austin, Texas Jo01 NO. 5408 TYPE oF BORNG Auger/Samole/Core SURFACE ELEY. 791 .0 ft.Z ttssn~waltod tube 91 00fltetwatk) twot of no ea .cey'L ~~~double tube c,, barre 0 dsstuwbed 1 s gl I I O E S C R I P T I O N O f S T R A T A .... ...(7870)-_ (787.0)B 1 0 1l 5 20 25-(765.5)-30 35 1 2 3 Light olive gray, clayey GRAVEL w/sand, medium dense to dense, calcareous.

====3.1.9 Sumps====

and Drains Control of liquid releases that contain radioactive material is provided in room 1.108, which contains storage tanks for collection, processing, storage, or release of liquid effluents.

The reactor pool will not release liquid effluents as a part of normal operation.

Drainage provisions for the building roof, site landscape, access roadways and subsurface control local runoff. Local flood control includes gravity flow drainage and collection sumps with dual operation pumps. Roof drainage and site runoff are by gravity flow. Separate sumps with pumps control subsurface drainage at the building perimeter and beneath the reactor shield foundation.

Page 3-8 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 3 3.2 Meteorological Damage Normal wind and storm conditions are within the design factors established in Uniform Building Code for 70 mph (31.3 m/sec). Hurricanes are not likely to be a direct threat because of the natural dissipation of energy on land. However, tornados are a concern with their extreme wind velocities.

Tornado type activity is roughly one event per year per 1000 square miles (2590 sq. kilometers) in the general site area. This activity represents a frequency of one per 2.5 x 10 5 years for an area of a square with sides of 333 feet (31 meters) representative of the building.3.3 Water Damage Gentle slope characteristics in the immediate site vicinity provide an ample gradient of about 3 feet (1 meter) for surface water runoff. A concrete spillway has been constructed to assure drainoff does not concentrate.

Mean elevation at the local site is 791 feet (241 meters). Data from the National Flood Insurance Program indicates that no portion of the research campus site is within the 100 or 500 year flood zone. Thus, the only flooding likely will be as a result of local runoff conditions.

One sump collects water from the truck access ramp and French drains around the building foundations.

Equipment providing services to reactor systems is located in two rooms on the lower level of the reactor building.

Makeup water, compressed air, and HVAC chill water are provided from a reactor building lower level room adjacent to the reactor bay. Pool cooling and cleanup are located in a room within the reactor bay structure.

Makeup water is provided by potable water pressure.

Service would still be available if the makeup water system were flooded, although water quality could not be monitored.

The loss of chill water to fan coil units affect habitability only. The ventilation system damper controls, pool cooling controls, and pulse rod operate using compressed air system. The compressors and air dryer would likely fail if the air compressor room were flooded. The pulse rod would be inoperable with the control rod fully inserted in a safe condition.

Pool cooling would be inoperable.

Reactor bay air dampers would fail closed. These systems are not required to maintain safe shutdown conditions, but the ventilation is required for reactor operation.

Pool cooling and cleanup pumps could be damaged or rendered inoperable by water intrusion; however, the pool cleanup pump is not required for operation unless chemistry Page 3-9 CHAPTER 3, DESIGN OF STRUCTURES, SYSTEMS AND COMPONENTS 1 011 control is required to maintain pH at acceptable levels, and the pool cooling pump is not required for operations as long as temperatures are acceptable (or operating at less than about 100 kW) or while shutdown.

===3.4 Seismic===

Damage The potential for seismic damage is evaluated in three areas, (A) core and structural support, (B) pool and pool cooling, and (3) the building.A. Core and structural Support Given (1) the height of the reflector surrounded by a pool of water, (2) the distributed weight of the radial reflector around the core, and (3) the potential motion of fuel elements, hypothetical seismic event is not likely to create any significant acceleration that would not be absorbed by the pool water and/or mitigated by movement of the fuel elements followed by automatic re-centering of the elements in the lower gird plate. NUREG/CR-2387 (PNL-4028) analysis indicates that any disruption of the lattice by mechanical rearrangement would result in negative reactivity, increasing shutdown margin for a seismic event that dislocates, shifts, or otherwise moves fuel elements within the core B. Pool and pool cooling An aluminum liner is installed to provide integrity for the reactor pool. Beam ports penetrate the pool wall. However incredible, an earthquake has the potential to cause a loss of pool integrity and therefore is postulated for analysis as a loss of cooling accident.

The consequences of a loss of cooling accident are addressed in Chapter 13.C. Building A building of good construction should withstand an earthquake acceleration of about 0.75 g. Ground accelerations that exceed this would be rare events in a region in which earthquakes are already infrequent.

Page 3-10 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 4 4.0 Reactor This chapter will discuss the reactor core (fuel, control rods, reflector and core support, neutron source, core structure), reactor pool, biological shielding, nuclear design (normal operating conditions, and operating limits), and thermal hydraulic design.4.1 Summary description The University of Texas Nuclear Engineering Teaching Laboratory (NETL) is home to a General Atomics' TRIGA Mark II research reactor. This installation follows 25 years (1963-1988) of successful operation of a TRIGA reactor at Taylor Hall on the main campus.The basic TRIGA design uses U-ZrH 1.6 fuel clad with stainless steel in natural water convection cooling mode during operation, with a maximum decay heat that can be removed by natural convection of either water or air. The reactor is located in an open pool of purified, light water that serves as a heat sink during operations at power. Nuclear properties and characteristics control heat generation; thermodynamic characteristics of the fuel and the coolant control heat removal and temperature response.

Maximum fuel temperature is the principle design constraint.

Solubility of hydrogen in the fuel matrix varies with temperature.

Consequently, operation at high power levels (i.e., elevated fuel temperature) can cause hydrogen to evolve into space around the fuel matrix; the hydrogen at elevated temperature can generate pressure inside the cladding.

Temperature that produces stress greater than the yield strength for the stainless steel cladding is lower than temperature which leads to phase change or melts U-ZrH 1.6.TRIGA fuel has a very strong prompt negative fuel temperature coefficient.

Fuel mass exceeding critical loading (i.e., excess reactivity) is required to compensate for the negative fuel temperature coefficient, as well as potential experiments, fission product poisons, and fuel burnup. There are several major experiment facilities that could affect core reactivity, as described in Chapter 10. Experiment program requirements vary widely; limits are imposed on the reactivity effects of experiments.

The amount of excess reactivity determines the maximum possible power, and therefore the maximum possible fuel temperature.

22 Elements of Nuclear Reactor Design, 2 nd Edition (1983), J. Weisman, Section 6.3 2' GA-4361, Calculated Fluxes and Cross Sections for TRIGA Reactors (8/14/1963), G. B. West Page 4-38 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR SAFETY ANALYSIS REPORT, CHAPTER 4 12/2011 P q ' NI .DL B. Power distribution within a Fuel Element The radial and axial distribution of the power within a fuel element is given by q .'(r,z) = q1f(r)g(_)

===5.2 Reactor===

Pool The reactor pool is a tall tank formed by the union of two half-cylinders with a radius of 6 separating the half-cylinders as Page 5-1 CHAPTER 5, REACTOR COOLING SYSTEMS 1 12/2011 shown in Fig. 5.1A. The bottom of the pool is at the reactor bay floor level. The reactor core is centered on one of the half-cylinders.

Normal pool level is 8.01 meters above the bottom of the pool, with a minimum level of 6.5 m required for operations.

The volume of water in the pool (excluding the reflector, beam tubes and core-metal) is 40.57 m 3 and 32.50 m 3 for the nominal and minimum-required levels. Basic reactor coolant system data is provided in Table 5.1.Table 5.1, Reactor Coolant System design Summary Material Aluminum plate (6061)Reactor Tank Thickness 1/4 in. (0.635 cm)Volume (maximum) 11000 gal (41.64 M 3)Pipes Aluminum 6061 Iron-Plastic Liner, 316 SS Coolant Lines ValvesBalndSe Ball and Stem Fittings Aluminum (Victaulic)

Type Centrifugal Coolant Pump Material Stainless Steel Capacity 250 gpm (15.8 Ips)Type Shell & Tube Materials (shell) Carbon steel Materials (tubes) 304 stainless steel Heat Exchanger Heat Duty Flow Rate (shell) Flow Rate (tubes) Tube Inlet F Tube Outlet69'Typical Heat Exchanger Operating Parameters Shell Inlet S h e ll O u t le t 5.2.1 Heat Load The reactor pool is open at the top (with an argon purge system normally drawing air across the surface) surrounded by concrete.

Conduction of heat through the concrete combined with forced convection and evaporation provide ambient cooling adequate to control pool water temperature at low power operations and decay heat removal. At 1 MW operation the reactor is capable of heating up the pool under nominal level of 8.1 m at 20.7&deg;C per hour, and at 2 MW approximately 41&deg;C per hour.Page 5-2 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 5 5.2.2 Pool Fabrication The pool is fabricated from sheets of 0.25 in. (0.635 cm) 6061 aluminum in 4 vertical sections welded to a Y2 in. thick aluminum plate. Full penetration inspection was performed on tank components during fabrication, including 20% of the vertical seam welds, 100% on the bottom welds (internal and external to the pool volume), and 100% on the beam port weld external to the pool volume. A single floor centerline seam weld was used; a sealed channel was welded under the seam and instrumented through a /4 in. NPT threaded connection to perform a leak test during fabrication.

A 2 in. X 2 in. X /4 in. (square) aluminum channel was rolled and welded to the upper edge of the tank.5.2.3 Beam Ports Beam port penetrations are fabricated around the core to allow extraction of radiation beams to support experiments.

The beam ports are centered 90.2 cm (35 in.) above the pool floor, 7.2 cm (2.83 in.) below the core centerline.

The section of the beam ports that are an integral part of the pool include an in-pool section, interface with the pool wall, and a section extending outside of the pool.In pool sections are 0.1524 m (6 in.) in diameter, with a 0.00635 cm (0.25 in.) wall thickness.

The in pool section for BP 1 and 5 is 6 in. while the remaining in-pool beam port sections are longer. Supports (2 in. X 2 in. X Y4 in. aluminum angle bracket) are welded at one end to the bottom of the pool and at the other end directly to BP 2, 3, and 4 to support the weight of the extended lengths. BP 2 and 4 terminate at the outer surface of the reflector, while BP 3 extends into the reflector, terminating at the inner shroud.BP 2 terminates in an oblique cut, extending approximately 43 cm (16.94 in.) into the pool with the support 12.7 cm (5 in.) from the in-core end. BP 3 extends 73 cm (28.75 in.) into the pool with the support 37.62 cm (14.8125 in.) from the in-pool end. BP 4 extends 43 cm into the pool (16.94 in.) with the support 7.62 cm (3 in.) from the in pool end. Beam port 1 and 5 are aligned in a single beam line. A flight tube inserted into BP 1/5 extends through the reflector near the core shroud; BP 1 and 5 are equipped with a bellows to seal a neutron flight-tube.

Beam ports 2, 3, and 4 are sealed at the in-pool end. BP 2 is tangential to the core shroud, offset 34.29 cm (13 Y2 in.) from core center rotated 30' with respect to BP 3.Beam port 3 is oriented 90' with respect to BP 1/5, aligned to the center of the core.Alignment of BP 4 is through the core center, rotated 600 from BP 3.The beam port interface with the pool wall includes a reinforcing flange on the inner pool wall. The flange is 3/8 in. thick, 11 in. in diameter.

The flange is welded on the outer diameter to the pool wall. The inner diameter of the flange is welded to the beam port tube.Page 5-3 CHAPTER 5, REACTOR COOLING SYSTEMS I 12/2011 The beam ports extend approximately 15.4 cm (6 in.) outside of the area define by the pool walls. A stainless steel (304) ring is machined for a slip fit over the 6 in. (15.24 cm) aluminum tube extension.

The ring is welded to 6 5/8 in. diameter stainless steel pipe (SST 304W/ASTM 312) extending the flight tube for the beam port into the biological shielding.

Four pads are welded to the pool floor reinforcing the floor for the core and support structure.

As noted, the in-pool beam port supports are welded to the pool floor... ...... ... ...." Figure 5.1A, Pool Fabrication IC?!lrl, CIt"CWOI IC AIN tIIIS'U Figure 5.1B, Cross Section Figure 5.C, Beam Orientation 5.3 Pool Cooling System The pool cooling system is shown in Fig. 5.2.Figure 5.2, Pool Cooling System 5.3.1 Reactor Pool The reactor pool is open at the top (with an argon purge system normally drawing air across the surface) surrounded by concrete.

Conduction of heat through the concrete combined Page 5-4 THE UNIVERSITY OF TEXAS TRIGA 11 RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 5 with forced convection and evaporation provides ambient cooling adequate to control pool water temperature at low power operations.

At 1 MW operation the reactor is capable of heating up the pool 20.7TC per hour, at 2 MW approximately 41 0 C per hour. As noted above, fuel element cooling analysis assumed a maximum temperature of 48.9&deg;C, which could be achieved after operating at the maximum power level for short periods. Therefore a pool cooling system is installed to control pool temperature.

Historically the maximum pool temperature of 48.9&deg;C was established to protect the integrity of ion exchange resin. The reactor pool is normally controlled at about 20 0 C. In the absence of pool cooling, a temperature rise of 28&deg;C (from 20 0 C to the maximum permissible pool temperature of 48.9&deg;C) could occur in 1.35 hours at 1 MW, or about 40 minutes at 2 MW. Even without pool cooling, time-limited support for experimental program is possible while still maintaining pool temperature below the limiting value used in analyses.5.3.2 Pool Heat Exchanger A tube and shell heat exchanger is installed for heat removal from the reactor pool to the available chilled water system. Design and operating parameters for the heat exchanger are provided in Table 5.1. Heat exchanger capacity is designed to maintain reactor pool temperature at or below the maximum temperature used in heat transfer analysis, 120&deg;F (48.9 0 C). The stable temperature is maintained by a heat exchanger capacity equivalent to the reactor core thermal output capacity.

Other heat losses such as evaporation, or heat gains from the pump, are considered negligible.

Heat transfer is defined by: q =U.A.6T where U overall heat transfer coefficient (watt/m 2 -0 C)A -surface area for heat transfer (M 2)6 Tin = true mean temperature difference

(&deg;C)The overall heat transfer coefficient of a tube and shell heat exchanger is composed of three terms, the convective heat transfer from the fluid in the tubes to the tube walls, the conductive heat transfer thru the tube wall, and the convective heat transfer from the outside tube wall to the fluid in the shell of the heat exchanger.

Based on the outside tube area for heat transfer, the overall heat transfer coefficient is defined as': Heat Transfer, Holman, JH. P., McGraw-Hill, 4 th Edition (1976) pp386-391 Page 5-5 CHAPTER 5, REACTOR COOLING SYSTEMS I 12/2011 u= + +A-Rkh h Wherer: Ao is the total outside tube area (m 2)Ai is the total inside tube area (M 2)ri is the tube inside radius (m)ro is the tube outside radius (m)hi is the convective heat transfer coefficient between fluid in tubes (W/m 2-oC)ho is the convective heat transfer coefficient between fluid in shell (W/m 2-oC)k is the conductive heat transfer coefficient in the tube wall (W/m 2-oC)I is the total tube length in heat exchanger (m)and tube wall and tube wall A correction is applied for fouling of heat exchanger caused by buildup of various deposits.

The overall heat transfer coefficient for a fouled heat exchanger is determined by: 1 U- 1 where Rf is the fouling factor, (non-dimensional).

The convective heat transfer coefficient is defined as h Nu '-k he-d Where: Nu is the Nusselt Number k is the thermal conductivity of the fluid evaluated at the appropriate average temperature (W/m-&deg;C)d is the tube diameter or applicable hydraulic diameter (m)Page 5-6 THE UNIVERSITY OF TEXAS TRIGA 11 RESEARCH REACTOR 12/2011 SAFETY ANALYSIS REPORT, CHAPTER 5 The complicated nature of turbulent flow heat transfer is described by a Nusselt number determined by experimental correlation with the Reynolds and Prandtl Numbers. Dittus and Boelter 2 recommend the following relation for fully developed turbulent flow in tubes: Nut = 0.023. Re'

* Prn where parameters are measured inside the tubes Re is the Reynolds Number based on tube diameter, Pr is the Prandtl Number at average fluid temperature, n is 0.4 for heating, 0.3 for cooling.The relation for the shell side of a baffled cross flow heat exchanger is suggested by Colburn 3 as follows: Nut = 0.33 -Re 0.6 Pr 0.3 3 where parameters are measured outside the tubes and Re is the Reynolds Number based on tube outside diameter and velocity at minimum shell cross sectional area, Pr is the Prandtl Number at average fluid temperature.

The product terms, 6 Tin, are defined consistent with the definition of U and heat exchanger design. The total cross sectional area of the tubes is represented by the heat transfer area, A, as specified by the heat transfer coefficient, U. The true mean temperature difference, 6Tm, is related to the heat exchanger type by a correction factor, F, and a log mean temperature difference, LMTD 4. The correlation relates a simple single pass heat exchanger with more complex multiple pass baffled units. A relation is defined by 6Tm = F -LMTD where F is the correction factor 5 , 6, 2 University of California (Berkeley)

Pub. Eng, Dittus, F. W and Boelter, L. M. K., Vol 2, pp 443 (1930)A method of Correlating Forced Convection Heat Transfer Data and Comparison with Fluid Friction, Colburn, A. P.,Trans. AlChE, Vol 29, pp 174-210 (1933)4 Heat Tansfer, White, op. cit.s Mean Temperature Difference in Design, Bowman, R. A., Mueller, A. C., and Nagle, W. M., Trans. ASME, Vol 62 (1940) pp283-294 6 Standards, TEMA 3rd Ed., Tubular Heat Exchanger Manufacturers Association New York (1952)Page 5-7 CHAPTER 5, REACTOR COOLING SYSTEMS 12/2011 T -Tb LMTD = b In Ta Tb For a counter flow heat exchanger Ta is (T hot fluid in -T cold fluid out)Tb is (T hot fluid out -T cold fluid in)Actual heat exchanger capacity is calculated using an energy balance on either the shell or tube fluid. The heat transfer is defined as: Tb = Thot-l~uia-out

-Tofttluid-out q = C (Tin -Tout)where C = m Cp m is the mass flow rate, cp is the fluid specific heat, Ti, is the temp of fluid entering heat exchanger, Tout is the temp of fluid exiting heat exchanger.

In the current case Tout of either fluid is not known. Only Tin (100*F pool water, 48 0 F coolant water) and the mass flow rate of both fluids are known. To determine Tout the effectiveness/NTU method 7'8 is used. The dimensionless parameter called the heat exchanger effectiveness E is defined as ActualHX Max_HX where the maximum possible heat transfer is MaXHX = Cmin " (r ot_,n -Told_in)Substituting (11) for each fluid and (13) into (12) results in Chot (Thot, in -Tcoldan)cmin (Thotin -Tcoa i)7Heat Transfer, White, F. M., Addison-Wesley (1984) pp 512-513 8 Compact Heat Exhcangers,2 nd Ed., Keys, W. and Landon, A. L., McGraw-Hill (1964)Page 5-8 THE UNIVERSITY OF TEXAS TRIGA II RESEARCH REACTOR SAFETY ANALYSIS REPORT, CHAPTER 5 I 12/2011 for the hot fluid and Ccold '(Tcold-in

-Tcold in)Cmin *( Thot- -clin for the cold fluid. The heat exchange effectiveness determined exchanger with one shell pan and any multiple of tube passes= z+ e-N[B -1 E~z- l~r+B.1e---N-.B]

Where R is Cmin/ Cmax U is the overall heat transfer defined in (2)A is the surface area for heat transfer B is( 1+r2)12 by 9 for a shell and tube heat Once the effectiveness is calculated and the above used to determine Thot out and TcoId out.These may then be used to determine the capacity of the heat exchanger.

Table 5.2, Heat Exchanger, Heat Transfer and Hydraulic Parameters Component/Parameter Specification Value Units Outside Diameter in. (cm)Tubes Wall Thickness in. (cm)Thermal Conductivity Btu/hr-ft-&deg;F Tube Side in 2 (cm 2)Flow Area Shell Side in 2 (cm 2)Heat transfer Surfaces Na ft 2 (M 2)Average Prandtl No. Tube na Shell na Tube ft 2/s (m2/S)Average Kinematic Viscosity Shell ft 2/s (m2/s)Reynolds No. Tube  na Shell  na Corrective Heat Transfer Tube  Btu/hr-ft 2--F (W/m 2-&deg;C)Coefficients Shell Btu/hr-ft 2-&deg;F (W/m 2-&deg;C)Overall Heat Transfer Tube Btu/hr-ft 2 -F (W/m 2-&deg;C)Coefficient Shell Btu/hr-ft 2 -F (W/m 2-&deg;C)Effectiveness Clean na Fouled na LMTD Na F ('C)Corrective Factor F Na na Capacity Clean kW 9 Compact Heat Exchangers op. cit.Page 5-9 CHAPTER 5, REACTOR COOLING SYSTEMS 12/2011 Fouled 1070 kW Heat removal capacity and thus pool heat rate is specified by analysis of a tube and shell heat exchanger.

Heat removal rate of 1140 kW is expected at a flow rate of 400 gal/min (25.2 liters/sec) of chilled water at 48&deg;F (8.89*C).

The presence of fouling in the heat exchanger is considered minimal based on the purity of the two heat exchanger fluids. Capacity is reduced to 1070 kW for a fouling factor of 0.0004.5.3.3 Secondary Cooling When the pool cooling system is operating, pool temperature is controlled by transferring heat from the pool water to a campus chill water system in a heat exchanger.

The chilled water system is operated by the University for cooling of Pickle Research Campus buildings and equipment through a campus supply loop. At the time of NETL construction, chilling capacity was provided by multiple 1200 ton (4220 kW) units, with 25% of the chilling system capacity of one unit allocated to pool cooling. Construction is currently underway to remove a major load/demand from the shared system; the Texas Advanced Computing Center is expanding, and installing a dedicated cooling system. The PRC chill water supply is also currently planning for system renovations which will expand capacity to meet campus growth and development.