A new Offshore Floating Nuclear Plant (OFNP) concept with high potential for attractive economics and an unprecedented level of safety is presented, along with an overview of work done in the area of security. The OFNP creatively combines state-of-the-art Light Water Reactors (LWRs) with floating platforms such as those used in offshore oil/gas operations, both of which are well-established technologies which can allow implementation on a time scale consistent with combating climate change in the near future. OFNP is a plant that can be entirely built within a floating platform in a shipyard, transferred to the site. OFNP eliminates earthquakes and tsunamis as accident precursors; its ocean-based passive safety systems eliminate the loss of ultimate heat sink accident by design. The defense of an OFNP poses new security opportunities and challenges compared to land-based plants. Such a plant can be more easily defended by virtue of the clear 360 degree lines of sight and the relative ease of identifying surface threats. Conversely the offshore plant is potentially vulnerable to underwater approaches by mini-submarines and divers. We investigate security considerations of the OFNP applicable to two potential plant options, an OFNP-300 with a 300 MWe reactor, and an OFNP-1100 with an 1100 MWe reactor. Three innovative security system approaches could be combined for the offshore plant. The first is a comprehensive detection system which integrates radar, sonar and unmanned vehicles for a long distance overview of the vicinity of the plant. The second approach is the use of passive physical barriers about 100 meters from the plant, which will force a fast-moving power boat to lose speed or stop at the barrier allowing the plant security force more time to respond. The third approach takes advantage of the offshore plant siting and the monthly or biweekly rotation of crew to reduce the total on-plant and onshore security force by using the off-duty security force on the plant as a reserve force. Through the use of these approaches, the OFNP-300 should be able to achieve a similar security cost (on a per Megawatt basis) as land-based plants of similar or somewhat larger power rating. Due to non-linear scaling of cost, the security cost of the OFNP-1100 has the potential to be reduced significantly compared to its land-based equivalents.
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2016 24th International Conference on Nuclear Engineering
June 26–30, 2016
Charlotte, North Carolina, USA
Conference Sponsors:
- Nuclear Engineering Division
ISBN:
978-0-7918-5005-3
PROCEEDINGS PAPER
Overview of Security Plan for Offshore Floating Nuclear Plant
Vincent Kindfuller,
Vincent Kindfuller
Massachusetts Institute of Technology, Cambridge, MA
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Neil Todreas,
Neil Todreas
Massachusetts Institute of Technology, Cambridge, MA
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Jacopo Buongiorno,
Jacopo Buongiorno
Massachusetts Institute of Technology, Cambridge, MA
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Michael Golay,
Michael Golay
Massachusetts Institute of Technology, Cambridge, MA
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Arthur Birch,
Arthur Birch
ECSI International, Inc., Clinton, NJ
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Thomas Isdanavich,
Thomas Isdanavich
ECSI International, Inc., Clinton, NJ
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Ron Thomas,
Ron Thomas
ECSI International, Inc., Clinton, NJ
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Harvey Stevens
Harvey Stevens
Stevens Associates, Inc., Red Bank, NJ
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Vincent Kindfuller
Massachusetts Institute of Technology, Cambridge, MA
Neil Todreas
Massachusetts Institute of Technology, Cambridge, MA
Jacopo Buongiorno
Massachusetts Institute of Technology, Cambridge, MA
Michael Golay
Massachusetts Institute of Technology, Cambridge, MA
Arthur Birch
ECSI International, Inc., Clinton, NJ
Thomas Isdanavich
ECSI International, Inc., Clinton, NJ
Ron Thomas
ECSI International, Inc., Clinton, NJ
Harvey Stevens
Stevens Associates, Inc., Red Bank, NJ
Paper No:
ICONE24-61029, V005T15A076; 16 pages
Published Online:
October 25, 2016
Citation
Kindfuller, V, Todreas, N, Buongiorno, J, Golay, M, Birch, A, Isdanavich, T, Thomas, R, & Stevens, H. "Overview of Security Plan for Offshore Floating Nuclear Plant." Proceedings of the 2016 24th International Conference on Nuclear Engineering. Volume 5: Student Paper Competition. Charlotte, North Carolina, USA. June 26–30, 2016. V005T15A076. ASME. https://doi.org/10.1115/ICONE24-61029
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