Nuclear Science and Technology No1-2014

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Contents Results of Operation and Utilization of the Dalat Nuclear Research Reactor Nguyen Nhi Dien, Luong Ba Vien, Le Vinh Vinh, Duong Van Dong, Nguyen Xuan Hai, Pham Ngoc Son, Cao Dong Vu..............................................................................................1 Design Analyses for Full Core Conversion of The Dalat Nuclear Research Reactor Luong Ba Vien, Le Vinh Vinh, Huynh Ton Nghiem, Nguyen Kien Cuong........................10 Conceptual Nuclear Designof a 20 MW Multipurpose Research Reactor Nguyen Nhi Dien, Huynh Ton Nghiem, Le Vinh Vinh, Vo Doan Hai Dang, Seo Chulgyo, Park Cheol, Kim Hak Sung..................................................................................................26 Some Main Results of Commissioning of The Dalat Research Reactor with Low Enriched Fuel Nguyen Nhi Dien, Luong Ba Vien, Pham Van Lam, Le Vinh Vinh, Huynh Ton Nghiem, Nguyen Kien Cuong, Nguyen Minh Tuan, Nguyen Manh Hung, Pham Quang Huy, Tran Quoc Duong, Vo Doan Hai Dang, Trang Cao Su, Tran Tri Vien...............................36 Production of Radioisotopes and Radiopharmaceuticals at the Dalat Nuclear Research Reactor Duong Van Dong, Pham Ngoc Dien, Bui Van Cuong, Mai Phuoc Tho, Nguyen Thi Thu, Vo Thi Cam Hoa..................................................................................................................46 The gamma two-step cascade method at Dalat Nuclear Research Reactor Vuong Huu Tan, Pham Dinh Khang, Nguyen Nhi Dien, Nguyen Xuan Hai, Tran Tuan Anh, Ho Huu Thang, Pham Ngoc Son, Mangengo Lumengano..........................................57 Progress of Filtered Neutron Beams Development and Applications at the Horizontal Channels No.2 and No.4 of Dalat Nuclear Research Reactor Vuong Huu Tan, Pham Ngoc Son, Nguyen Nhi Dien, Tran Tuan Anh, Nguyen Xuan Hai….62 Characterization of neutron spectrum parameters at irradiation channels for neutron activation analysis after full conversion of the Dalat nuclear research reactor to low enriched uranium fuel C.D. Vu, T.Q. Thien, H.V. Doanh, P.D. Quyet, T.T.T. Anh, N.N. Dien.............................70 Some results of NAA collaborative study in white rice performed at Dalat Nuclear Research Institute T.Q. Thien*, C.D. Vu, H.V. Doanh, N.T. Sy........................................................................76 A new rapid neutron activation analysis system at Dalat nuclear research reactor H.V. Doanh, C.D. Vu, T.Q. Thien, P.N. Son, N.T. Sy, N. Giang, N.N. Dien.....................84 Nuclear Science and Technology, Vol. 4, No. 1 (2014), pp. 01-09 Results of Operation and Utilization of the Dalat Nuclear Research Reactor Nguyen Nhi Dien, Luong Ba Vien, Le Vinh Vinh, Duong Van Dong, Nguyen Xuan Hai, Pham Ngoc Son, Cao Dong Vu Nuclear Research Institute (NRI), Vietnam Atomic Energy Institute (VINATOM) 01 Nguyen Tu Luc, Dalat, Vietnam (Received 5 March 2014, accepted 26 March 2014) Abstract: The Dalat Nuclear Research Reactor (DNRR) with the nominal power of 500 kW was reconstructed and upgraded from the USA 250-kW TRIGA Mark-II reactor built in early 1960s. The renovated reactor was put into operation on 20th March 1984. It was designed for the purposes of radioisotope production (RI), neutron activation analysis (NAA), basic and applied researches, and nuclear education and training. During the last 30 years of operation, the DNRR was efficiently utilized for producing many kinds of radioisotopes and radiopharmaceuticals used in nuclear medicine centers and other users in industry, agriculture, hydrology and scientific research; developing a combination of nuclear analysis techniques (INAA, RNAA, PGNAA) and physic-chemical methods for quantitative analysis of about 70 elements and constituents in various samples; carrying out experiments on the reactor horizontal beam tubes for nuclear data measurement, neutron radiography and nuclear structure study; and establishing nuclear training and education programs for human resource development. This paper presents the results of operation and utilization of the DNRR. In addition, some main reactor renovation projects carried out during the last 10 years are also mentioned in the paper. Keywords: DNRR, HEU, LEU, RRRFR, RERTR, WWR-M2, NAA, INAA, RNAA, PGNAA. I. INTRODUCTION The DNRR is a 500-kW pool-type reactor loaded with the Soviet WWR-M2 fuel assemblies. It was reconstructed and upgraded from the USA 250-kW TRIGA Mark-II reactor built in early 1960s. The first criticality of the renovated reactor was on the 1st November 1983 and its regular operation at nominal power of 500 kW has been since March 1984. The first fresh core was loaded with 88 fuel assemblies enriched to 36% (HEU- Highly Enriched Uranium). In the framework of the program on Russian Research Reactor Fuel Return (RRRFR) and the program on Reduced Enrichment for Research and Test Reactor (RERTR), the DNRR core was partly converted from HEU to Low Enriched Uranium (LEU) with 19.75% enrichment in September 2007. Then, the full core conversion of the reactor to LEU fuel was also performed from 24th November 2011 to 13th January 2012. Recently, the DNRR has been operated with a core configuration loaded with 92 WWR-M2 LEU fuel assemblies and 12 beryllium rods around the neutron trap. The reactor is used as a neutron source for the purposes of radioisotopes production, neutron activation analysis, basic and applied researches and training. As a unique research reactor in Vietnam, the DNRR has been playing an important role in the research and development of nuclear technique applications as well as in nuclear power programme development of the country. Safe operation and ©2014 Vietnam Atomic Energy Society and Vietnam Atomic Energy Institute RESULTS OF OPERATION AND UTILIZATION OF THE DALAT NUCLEAR RESEARCH REACTOR effective utilization of the reactor expected at least to the year 2030 are a long-term objective of the DNRR. For this reason, so far the Government has strongly supported for many specific projects in order to upgrade the facility and improve its operation and utilization. some main reactor renovation projects carried out during the last 10 years are also mentioned, too. The results of operation and utilization of the DNRR are presented in this paper and Main specifications of the DNRR are shown in Table I. II. BRIEF REACTOR DESCRIPTION AND IT’S OPERATION Table I. Specifications of the DNRR. Reactor type Swimming pool TRIGA Mark II, modified to Russian type of IVV-9 Nominal thermal power 500 kW, steady state Coolant and moderator Light water Core cooling mechanism Natural convection Reflector Beryllium and graphite Fuel types WWR-M2, dispersed UO2-Al with 19.75% enrichment, aluminium cladding Number of control rods 7 (2 safety rods, 4 shim rods, 1 regulating rod) Materials of control rods B4C for safety and shim rods, stainless steel for automatic regulating rod Neutron measuring channels 6 combined in 3 housings with 1 CFC and 1 CIC each Vertical irradiation channels 4 (neutron trap, 1 wet channel, 2 dry channels) and 40 holes at the rotary rack Horizontal beam-ports 4 (1 tangential - No #3 and 3 radial - No #1, #2, #4) Thermal column 1 Maximum thermal neutron flux 2.1x1013 n.cm-2.s-1 (in the neutron trap at core center) Main utilizations RI, NAA, PGNAA, NR, basic and applied researches, nuclear training The reactor consists of a cylindrical aluminum tank 6.26 m high and 1.98 m in diameter of the original TRIGA Mark II reactor. The reactor core, positioned inside the graphite reflector, is suspended from above by an inner cylindrical extracting well so as to increase the cooling efficiency for copping with higher thermal power of the reactor. The vertical section view of the reactor is shown in Fig. 1 and the cross-section view of the reactor core is shown in Fig. 2. 2 NGUYEN NHI DIEN et al. ~ 2000 mm Rotating top lid SR Pool tank Sh Upper cylindrical shell R Sh ~ 6840 mm Extracting well RgR Concrete shielding Spent fuel storage tank Thermal column door A Core Graphite Sh Sh Door plug SR (ex bulk-shielding experimental tank) Fig. 1. Vertical section view of the DNRR reactor. The reactor core has a cylindrical shape with a height of 60 cm and a diameter of 44.2 cm, that is constituted of 92 LEU fuel assemblies, 7 control rods, a neutron trap at the core center and 3 in-core irradiation facilities. Fig. 2. Cross-section view of the core with 92 fuel assemblies. At present, the DNRR is operated mainly in continuous runs of 100 or 130 hrs, once every 3-4 weeks, for radioisotope production, neutron activation analyses, basic and applied researches and training. The remaining time between two consecutive runs is devoted to maintenance activities and also to physics experiments. From the first start-up to the end of 2013, it totaled about 37,800 hrs of operation, namely a yearly average of 1300 hrs, and the total energy released was about 760 MWd. Detailed yearly operation time of the DNRR is given in Fig. 3. Type of fuel with a 235U enrichment of 19.75% of UO2+Al covered by aluminum cladding is used. Each LEU fuel assembly contains about 50.5 g of U-235, distributed on three coaxial fuel tubes, of which the outermost one is hexagonal shaped and the two inner ones are circular. Fig. 3. Yearly operation time of the DNRR. 3 RESULTS OF OPERATION AND UTILIZATION OF THE DALAT NUCLEAR RESEARCH REACTOR disease therapeutics and 32P in injectable solution, 99mTc generator of gel type by 98Mo(n, )99Mo reaction have regularly been produced and supplied once every 2 weeks. Other radioisotopes as 51Cr, 60Co, 65Zn, 64Cu, 24Na, etc. were also produced in a small amount when requested. 53Sm in solution form was ready for labelling. Totally, about 5,500 Ci of radioisotopes have been produced and supplied to medical uses so far with a yearly average in the last 5 years of about 400 Ci (Fig. 4) correspondingly. So far, the reactor has proved to be safe and reliable, as it has never suffered from any incident, which significantly affected the environment, and annual operation schedules have been rigorously respected. The unscheduled shutdowns were mainly due to unstable working of the city electric network. III. MAIN RESULTS OF REACTOR UTILIZATION A. Radioisotopes and radiopharmaceuticals production In order to support the application of Tc, 113mIn and 53Sm radioisotopes in clinical diagnosis and therapeutics, the preparation of radio-pharmaceuticals in Kit form for labelling was carried out in parallel with the development of 99mTc generator systems. About 17 labeled compounds kits have been regularly prepared and supplied including Phytate, Gluconate, Pyrophosphate, Citrate, DMSA, HIDA, DTPA, Macroaggregated HSA and EHDP, etc.. The annual production rate is about 1000 bottles for each Kit which is equivalent to 5000 diagnostic doses. Research on radioisotope and radiopharmaceutical production serving nuclear medicine and other users such as industry, agriculture, hydrology, scientific research, etc. is oriented towards efficient use of the reactor. Via such research a variety of products including 131I, 32P applicators and solutions, 99mTc generators, etc. were produced. 99m For medicine applications, radioisotopes and radiopharmaceuticals have been delivered to 25 hospitals throughout the country. The main radioisotopes, such as 131I in NaI solution and 131I capsule type, 32P applicators for skin Fig. 4. Total radioactivity of RI produced annually at Dalat Nuclear Research Institute for medicine. 4 NGUYEN NHI DIEN et al. Other applications of radioisotopes produced at the DNRR are radiotracer technique in sediment studies, oil exploitation, chemical industry, biology, agriculture and hydrology. Some main products are 46Sc, 192Ir, 198 Au, 131I, 140La, etc. In addition, some small sources of 192Ir and 60Co with low radioactivity have also been produced for industry applications. channel. An auto-pneumatic transfer system installed in 2012 at the DNRR can transfer a sample from irradiation position to measuring detector about 3 seconds. The k-zero method for INAA has been also developed to analyse airborne particulate samples for investigation of air pollution; crude oil samples and base rock samples for oil field study. Based on developed k-zero-INAA method, a multi-elements analysis procedures have been applied to simultaneously determine concentration for about 31 elements including Al, As, Ba, Br, Ca, Cl, Cr, Cu, Dy, Eu, Fe, Ga, Hf, Ho, K, La, Lu, Mg, Mn, Na, Sb, Sc, Sm, Sr, Th, Ti, V, Yb, Zn. B. Neutron activation analysis Research on analytical techniques based on neutron activation and other related processes consists of the elaboration of analytical processes and the design and construction of analytical instruments. C. Neutron beam utilization Requests of many branches of the national economy for various types of samples have quickly been responded. NAA at the DNRR has always been met the demand of analytical services for geology exploration, oil prospecting, agriculture, biology, environmental studies, etc. The reactor has four horizontal beam ports, which provide beams of neutron and gamma radiation for a variety of experiments. They also provide irradiation facilities for large specimens in a region close to the reactor core. Besides, the reactor also has a large thermal column with outside dimensions of 1.2m by 1.2m in cross section and 1.6m in length (Fig. 5). The relatively high neutron flux in irradiation channels of the reactor allows elemental analysis using various neutron activation approaches, such as Instrumental NAA (INAA), Radiochemical NAA (RNAA), Delayed NAA (DNAA) and Prompt gamma NAA (PGNAA). By the end of 2013, a total of about 60,000 samples have been irradiated at the reactor with a yearly average of 2000 samples. It can be estimated that those make up 60% of geological samples, 10% of biological samples, 20% of environmental samples, 5% of soil and agriculture materials, 3% of industrial materials. Up to now, only three beam ports (No.2, No.3 and No.4) and the thermal column have been used for reseaches and applications. At the beam port No.2, a BGO-HPGe gamma-rays Compton suppression spectrometer has been recently installed for PGNAA and experimental researches on neutron capture reactions. The filtered thermal neutron beams extracted from the tangential beam port No.3 are used for nuclear structure studies, especially for experimental determination of nuclear energy levels and level density in regions below neutron binding energy. The filtered neutron beams at the piercing beam port No.4 with quasi-monoenergies of 24keV, 54keV, 59keV, 133keV and 148keV are used In order to determine the elements having short-lived radionuclides, the method of cyclic INAA with the alternation of irradiation and measurement was implemented by using the thermal column and vertical irradiation 5 RESULTS OF OPERATION AND UTILIZATION OF THE DALAT NUCLEAR RESEARCH REACTOR for the mesurements of neutron total and capture cross sections. In addition, these neutron beams are also applied for practical study on radiation shielding design. Typical research activities using neutron beam of the DNRR are listed below. Thermal column No. 2: Gamma spectrometry system with BGO detector for PGNAA and neutron capture reactions study No. 3: Nuclear structure study Colum n door Be am port # 2 Be am port # 3 The rm al Colum n Stainle s s s te e l Alum inum Graphite re fle ctor Be llow s as s e m bly Be am port # 1 This port is closed Pool tank w all Core Be am port # 4 The rm alizing colum n (clos e d) Concre te s hie lding No. 4: Nuclear data measurement Spe nt fue l s torage tank Fig. 5. Horizontal section view of the DNRR. Neutron physics and nuclear data measurement - Measurement of isomeric ratio created in the reaction 81Br(n, )82Br on the 55 keV and 144 keV neutron beams; In the keV energy region, filtered neutron beams are the most intense sources, which can be used to obtain neutron data for reactors and other applications. The following experiments have been carried out at the DNRR including: - And other investigations, such as average resonance capture measurements, using the - coincidence spectrometer for study on the (n, 2) reaction, etc. Application of neutron capture gamma ray spectroscopy - Total neutron cross section measurement for 238U, Fe, Al, Pb on filtered neutron beams at 144 keV, 55 keV, 25 keV and evaluation of average neutron resonance parameters from experimental data; - Development of PGNAA technique using the filtered thermal neutron beam in combination with the Compton-suppressed spectrometer for analyzing Fe, Co, Ni, C in steel samples; Si, Ca, Fe, Al in cement samples; Gd, Sm, Nd in uranium ores, Sm, Gd in rare earth ores; etc.; - Gamma ray spectra measurement from neutron capture reaction of some reactor materials (Al, Fe, Be, etc.) on filtered neutron beam at 55 keV and 144 keV; - Utilization of the PGNAA method for investigating the correlation between boron and tin concentrations in geological samples as a geochemical indication in exploration and assessment of natural mineral resources; analyzing boron in sediment and sand samples - Measurement of average neutron radioactive capture cross section of 238U, 98Mo, 151 Eu, 153Eu on the 55 keV and 144 keV neutron beams; 6 NGUYEN NHI DIEN et al. to complement reference data for such samples from rivers; Besides, the DNRR has been used as a main tool for practical training, a set of equipment was supported under IAEA TC project, bilateral projects with the Japan Atomic Energy Agency and Bhabha Atomic Research Center of India. The measuring systems for practices at the Training Center can meet the fast increasing demand and is expected to move forward to the regional standard in the field of nuclear training. - Development of the spectrometer of summation of amplitudes of coinciding pulses for (n, 2) reaction research and for measuring activity of activated elements with high possibility of cascade transitions. D. Eduacation and training activities Training Center at Dalat Nuclear Research Institute which was established in 1999 is responsible for organizing training courses and training in reactor engineering, nuclear and radiation safety, application of nuclear techniques and radioisotopes in industry, agriculture, biology and environment, etc. Training courses on non-destructive evaluation (NDE) including radiographic testing, ultrasonic testing as well as on security of nuclear facilities and radiation sources have also been done. The center also is the training facility for expertise students from local universities and foreign postgraduate students. Thereby, the human resource development is conducted annually so that it can deal with scientific works of higher and higher quality and meet a huge demand in the field of nuclear science and technology in Vietnam in the future. Thanks to the bilateral co-operation with the Japan Atomic Energy Agency, US Department of Energy, Bhabha Atomic Research Center of India, and Korea Atomic Energy Research Institute, we have conducted a variety of training courses in the four following key areas: E. Other applications Research on sediment using radiotracer techniques was carried out to investigate bed load layers displacement at estuaries navigation channel region and to explain the sediment deposition phenomenon causing frequent dredging activities. Research on radio-biology consists of using gamma radiation associated with other factors for improving agricultural seeds and applying radioactive tracers for studying biological metabolism, especially nutrition problems. These studies are to investigate phosphorus absorption and other nutritional problems during the growing processes of rice and other plants. Irradiation effects on some plants to gain higher yield or environment adapted varieties were also studied. Gemstone colorizing experiments of topaz and sapphire in the reactor core, in the rotary rack as well as in horizontal channels has been done. As research purpose, silicon monocrystals have been irradiated at the central neutron trap of the reactor. Irradiated products of good quality, appropriate for fabrication of power diodes and thyristors have been created thanks to proper neutron distribution in this irradiation facility and suitable cadmium ratio. - Reactor engineering for nuclear power programme; - Research and development activities; - State management in the field; - And University lecturer training program. 7 RESULTS OF OPERATION AND UTILIZATION OF THE DALAT NUCLEAR RESEARCH REACTOR IV. SOME MAIN REACTOR RENOVATION PROJECTS PERFORMED B. Reactor control and instrumentation system modification A. Reactor conversion from HEU to LEU fuels The Control and Instrumentation System In the framework of the program on Russian Research Reactor Fuel Return (RRRFR) and the program on Reduced Enrichment for Research and Test Reactor (RERTR), the DNRR core was partly converted from HEU to LEU in September 2007. (C&I) of the DNRR was designed and manufactured by the former Soviet Union and put into operation in November 1983. Due to the spare part procurement problem was suspected and using technology of the 1970’s with discrete and low-level integrated electronic components, the system technology was somewhat obsolete and un-adapted to tropical climate. After this success, the full core conversion study from HEU to LEU of the DNRR was also carried out during years 2008 - 2010. The results of neutronics, thermal hydraulics and safety analysis showed that a LEU core loaded with 92 fuel assemblies and 12 beryllium rods around the neutron trap satisfies the safety requirements while maintaining the utilization possibility similar to that of the previous HEU and recent mixed fuel cores. The first renovation work was implemented during 1992-1993 period and the renovated C&I system was commissioned at the end of 1993. The most important renovation task was to redesign and construct a number of electronic systems/blocks, which play the key role in enhancing the reliability of the system. This renovation work was focused mainly on the process and instrumentation system, but not on the neutron measurement and data processing parts. Because of that, it was necessary to fulfill the second renovation and modernization during the years of 20052007 to replace neutron measurement and signal processing parts of the existing C&I system by the digital system named ASUZ14R. The main items replaced under the second modification are neutron detector channels; neutron flux control system (NFCS), reactor protection system, control console and control panels, reactor protocol and diagnostic system, etc. Physics and energy start-up of the DNRR for full core conversion to low enriched uranium (LEU) fuel were performed from November 24 th, 2011 until January 13 th, 2012 according to a planned program that was approved by Vietnam Atomic Energy Institute (VINATOM). At 15:35 on November, 30 th, 2011 the reactor reached criticality with core configuration including 72 LEU FAs and neutron trap in center. Then the fuel loading for working core and power ascension test were also carried out from December, 6th, 2011 to January, 13 th, 2012. Experimental results of physical and thermal hydraulics parameters of the reactor during start up stages and long operation cycles at nominal power showed very good agreement with calculated results and met the safety requirements. The commissioning of the new I&C system was finished in August 2007 and operating license was approved in October 2007. 8 NGUYEN NHI DIEN et al. V. CONCLUSIONS REFERENCES The DNRR has been safely operated and effectively utilized for 30 years. To achieve that, maintaining and upgrading the reactor technological facilities have been done with a high quality. The reactor physics and thermal hydraulics studies have also provided the important bases for safety evaluation and incore fuel management to ensure its safe operation and effective exploitation. The safety and security for the reactor are one of the main issues that national and local authorities are particularly interested in and strongly support up. [1] Nguyen Nhi Dien, Dalat Nuclear Research Reactor - Twenty five years of safe operation and efficient exploitation, Dalat, (March 2009). [2] Duong Van Dong, Status of Radioisotope Production and Application in Vietnam, Dalat Sym. RR-PI-09, Dalat, (2009). [3] V. V. Le, T. N. Huynh, B. V. Luong, V. L. Pham, J. R. Liaw, J. Matos, Comparative Analyses for Loading LEU Instead of HEU Fuel Assemblies in the DNRR, RERTR Int’l Meeting, Boston, (2005). [4] P.V. Lam, N.N. Dien, T.D. Hai, L.B. Vien, L.V. Vinh, H.T. Nghiem, N.M. Tuan and N.K. Cuong, Results of the reactor control system During 30 years of operation, the DNRR has been playing an important role in the use of atomic energy for peaceful purpose in Vietnam. The reactor has been used for radioisotope production for medicine and industry purposes, NAA of geological, crude oil and environment samples, performance of fundamental and applied researches on nuclear and reactor physics, as well as creation of a large amount of human resource with high skills and experiences on application of nuclear techniques in the country. A strategic plan and long-term working plan for the DNRR has been set up in order to continue its safe operation and effective utilization at least to 2025. replacement and reactor core conversion at the Dalat nuclear research reactor, The 12th Annual Topical Meeting on Research Reactor Fuel Management, Hamburg, Germany, (2008). [5] P.V. Lam, N.N. Dien, L.V. Vinh, H.T. Nghiem, L.B. Vien and N.K. Cuong, Neutronics and thermal hydraulics calculation for full core conversion from HEU to LEU fuel of the Dalat nuclear research reactor, RERTR Int’l Meeting, Lisbon, Portugal, (2010). [6] L.B. Vien, L.V. Vinh, H.T. Nghiem and N.K. Cuong, Transient/ accident analyses for full core conversion from HEU to LEU fuel of the Dalat nuclear research reactor, RERTR Int’l Meeting, Lisbon, Portugal, (2010). [7] C.D. Vu, Study on application of k0-IAEA at Dalat research reactor, Project report (code CS/09/01-01), (2010). It should be mentioned that a project for establishment of a new nuclear science and technology center with a high power research reactor expected to put into operation between 2020-2022 is now under preparation and consideration. Therefore, the DNRR will be necessary and keep playing an important role in scientific research, applications and human resource development for Vietnam in the coming time. [8] N.N. Dien, L.B. Vien, P.V. Lam, L.V. Vinh, H.T. Nghiem, N.K. Cuong, N.M. Tuan, N.M. Hung, P.Q. Huy, T. Q. Duong, V.D.H. Dang, T.C. Su, T.T. Vien, Some main results of commissioning of the Dalat Nuclear Research Reactor with low enriched fuel, Nuclear Research Institute, (2012). [9] Safety Analysis Report (SAR) for the Dalat Research Reactor, Dalat, (2012). 9
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