[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.1016/j.net.2016.06.002

Technology Selection for Offshore Underwater Small Modular Reactors

Shirvan, Koroush (Department of Nuclear Science and Engineering, Massachusetts Institute of Technology)
Ballinger, Ronald (Department of Nuclear Science and Engineering, Massachusetts Institute of Technology)
Buongiorno, Jacopo (Department of Nuclear Science and Engineering, Massachusetts Institute of Technology)
Forsberg, Charles (Department of Nuclear Science and Engineering, Massachusetts Institute of Technology)
Kazimi, Mujid (Department of Nuclear Science and Engineering, Massachusetts Institute of Technology)
Todreas, Neil (Department of Nuclear Science and Engineering, Massachusetts Institute of Technology)

Publication Information

Nuclear Engineering and Technology / v.48, no.6, 2016 , pp. 1303-1314 More about this Journal

Abstract

This work examines the most viable nuclear technology options for future underwater designs that would meet high safety standards as well as good economic potential, for construction in the 2030-2040 timeframe. The top five concepts selected from a survey of 13 nuclear technologies were compared to a small modular pressurized water reactor (PWR) designed with a conventional layout. In order of smallest to largest primary system size where the reactor and all safety systems are contained, the top five designs were: (1) a lead-bismuth fast reactor based on the Russian SVBR-100; (2) a novel organic cooled reactor; (3) an innovative superheated water reactor; (4) a boiling water reactor based on Toshiba's LSBWR; and (5) an integral PWR featuring compact steam generators. A similar study on potential attractive power cycles was also performed. A condensing and recompression supercritical $CO_2$ cycle and a compact steam Rankine cycle were designed. It was found that the hull size required by the reactor, safety systems and power cycle can be significantly reduced (50-80%) with the top five designs compared to the conventional PWR. Based on the qualitative economic consideration, the organic cooled reactor and boiling water reactor designs are expected to be the most cost effective options.

Keywords

Advanced Reactors; Nuclear Design; Nuclear Safety; Offshore Power Cycle; Small Modular Reactor;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	G. Haratyk, C. Lecomte, F.X. Briffod, Flexblue(R): a subsea and transportable small modular power plant, in: Proceedings of ICAPP, 2014. Charlotte, USA.
2	J. Buongiorno, J. Jurewicz, M. Golay, N. Todreas, The offshore floating nuclear plant concept, Nucl. Technol. 194 (2016) 1-14. DOI
3	K. Shirvan, G. Haratyk, R. Ballinger, J. Buongiorno, C. Forsberg, M. Kazimi, N. Todreas, Advanced offshore seabed reactors, in: Proceedings of ICAPP, 2015. Nice, France.
4	M. Galvin, N. Todreas, L. Conway, Maintenance cycle extension in the IRIS advanced light water reactor, Nucl. Technol. 143 (2003) 270-280. DOI
5	N. Yoshida, M. Kawakami, K. Hiraiwa, H. Heki, Study on long life core with uranium fuel for LSBWR, in: Proceedings of PHYSOR, 2002. Seoul, Korea.
6	Y.C. Ko, M.S. Kazimi, Conceptual design of an annular-fueled superheat boiling water reactor, MIT-ANP-TR-130, MIT, Cambridge (MA), USA, 2010.
7	G. Toshinsky, V. Petrochenko, Modular lead-bismuth fast reactors in nuclear power, Sustainability 4 (2012) 2293-2316. DOI
8	K. Shirvan, R. Ballinger, J. Buongiorno, C. Forsberg, M. Kazimi, N. Todreas, Advanced offshore seabed reactors, MIT-ANPTR-155, MIT, Cambridge (MA), 2014.
9	J. Buongiorno, J.W. Sterbentz, P.E. MacDonald, Study of solid moderators for the thermal-spectrum supercritical watercooled reactor, Nucl. Technol. 153 (2006) 282-303. DOI
10	E.D. Greaves, K. Furukawa, L. Sajo-Bohus, H. Barros, The case for the thorium molten salt reactor, Proc. Latin Am. Symp. Nucl. Phys. Appl. 1423 (2012) 453-460.
11	C. Forsberg, D. Curtis, J. Stempien, R. MacDonald, P. Peterson, Fluoride-salt-cooled high-temperature reactor (FHR) commercial basis and commercialization strategy, MIT-ANPTR-153, MIT, Cambridge (MA), USA, 2014.
12	E.A. Hoffman, W.S. Yang, R.N. Hill, Preliminary core design studies for the advanced burner reactor over a wide range of conversion ratios, ANL-AFCI-177, ANL, Chicago, USA, 2006.
13	K. Kunitomi, S. Katanishi, S. Takada, T. Takizuka, X. Yan, Japan's future HTR-the GTHTR300, Nucl. Eng. Design 233 (2004) 309-327. DOI
14	P. Anzieu, R. Stainsby, K. Mikityuk, Gas-cooled fast reactor (GFR): overview and perspectives, in: Proceedings of the GIF Symposium, 2009. Paris, France.
15	P. Hejzlar, N.E. Todreas, E. Shwageraus, A. Nikiforova, R. Petroski, M.J. Driscoll, Cross-comparison of fast reactor concepts with various coolants, Nucl. Eng. Design 239 (2009) 2672-2691. DOI
16	M.A. Erighin, A 48 month extended fuel cycle for the B&W mPowerTM small modular nuclear reactor, in: Proceedings of PHYSOR, 2012. Knoxville, USA.
17	International Atomic Energy Agency (IAEA), Status of small and medium sized reactor designs, September 2011.
18	K. Shirvan, P. Hejzlar, M.S. Kazimi, The design of a compact integral medium size PWR, Nucl. Eng. Design 243 (2012) 393-403. DOI
19	J.M. Cronje, J.J. Van Wyk, M.J. Memmott, Overview of the Westinghouse small modular reactor building layout, in: Proceedings of ICAPP 2012, June 24-28, 2012. Chicago, USA.
20	M.J. Memmott, A. Manera, The use of a flashing drum to generate steamin the integral, inherently safe (I2S) light water reactor, in: Proceedings of ICAPP 2014, 2014. Charlotte, USA.
21	HEATRICTM [Internet]. [cited 2008 Dec]. Available from: http://www.heatric.com.
22	G. Haratyk, K. Shirvan, M. Kazimi, Compact steam generator for nuclear application, Proceedings of NURETH16, 2015. Chicago, USA.
23	Aspentech, ASPENONE V8 [Internet]. 2014. Available from: http://www.aspentech.com/products/.
24	S. Dewson, C. Grady, HEATRIC Workshop at MIT, Cambridge, MA, USA, 2003.
25	Measuring Worth [Internet]. 2010. Available from: http://www.measuringworth.com/uscompare/.
26	KAERI, Status report 77 d System-Integrated Modular Advanced Reactor (SMART) [Internet]. Available from:, 2011 https://aris.iaea.org/sites/..%5CPDF%5CSMART.pdf.
27	H. Bae, D.E. Kim, S.U. Ryu, J.-S. Suh, An SBLOCA test of safety injection line break with the SMART-ITL facility and its MARSKScode simulation, in: Proceedings of ICAPP, 2014 paper 14140.
28	F. Incropera, Fundamentals of Heat and Mass Transfer, fifth ed., John Wiley and Sons, New York, USA, 2002.
29	D. Feng, P. Hejzlar, M.S. Kazimi, Thermalehydraulic design of high-power-density annular fuel in PWRs, Nucl. Technol. 160 (2007) 16-44. DOI
30	Y.S. Yang, D.H. Kim, J.G. Bang, H.K. Kim, T.H. Chun, K.S. Kim, K.W. Song, C.G. Seo, H.T. Chae, Irradiation test of dual-cooled annular fuel pellets, in: Proceedings of WRFPM/Top Fuel, 2009. Paris, France.
31	B.A. Pint, K.A. Terrani, M.P. Brady, T. Cheng, J.R. Keiser, High temperature oxidation of fuel cladding candidate materials in steamehydrogen environments, J. Nucl. Mater. 440 (2013) 420-427. DOI
32	M. Short, R.G. Ballinger, H.E. H€anninen, Corrosion resistance of alloys F91 and Fee12Cre2Si in leadebismuth eutectic up to 715C, J. Nucl. Mater. 434 (2013) 259-281. DOI
33	P. Kasten, R. Adama, R. Carlsmith, R. Chapman, E. Epler, E. Gift, F. Harrington,M.Myers, R. Olson, J. Roberts, R. Solmon, J.Sanders,R. Stone, D.Vondy, C.Walker,T.Washburn, L.Yeatts, F. Zapp, An evaluation of heavy-water-moderated organiccooled reactors, ORNL-3921, ORNL, Knoxville, USA, 1967.
34	M.T. Simnad, The U-ZrHx alloy: its properties and use in TRIGA fuel, Nucl. Eng. Design 64 (1981) 403-422. DOI
35	P. Macdonald, J. Buongiorno, C. Davis, K. Weaver, R. Latanision, B. Mitton, G. Was, M. Carelli, D. Paramonov, L. Conway, Feasibility study of supercritical light water cooled fast reactors for actinide burning and electric power production, INEEL/EXT-02-00925, INL, Idaho Falls, USA, 2002.
36	K. Shirvan, E. Forrest, Design of an organic simplified nuclear reactor, J. Nucl. Eng. Technol. 48 (2016) 893-905. DOI
37	S.A. Wrights, R.F. Radel, T.M. Conboy, G.E. Rochau, Modeling and experimental results for condensing supercritical $CO_2$ power cycles, SAND2010-8840, Sandia National Lab, Albuquerque, USA, 2011.
38	Siemens, ''Industrial Steam Turbines: The comprehensive product range from 2 to 250 megawatts [Internet]. [cited 2013]. Available from: http://www.energy.siemens.com/us/pool/hq/power-generation/steam-turbines/Industrial_Steam_Turbines_en.pdf.
39	K. Shirvan, M. Kazimi, Superheated water small modular underwater reactor concept, J. Nucl. Eng. Technol. 48 (2016) 1338-1348. DOI

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