Floating nuclear power plant

Nuclear power station on a floating vessel

A floating nuclear power plant is a floating power station that derives its energy from a nuclear reactor. Instead of a stationary complex on land, they consist of a floating structure such as an offshore platform, barge or conventional ship.

Since the reactors employed are smaller in size and power than most commercial land-based reactors, mostly derived from nuclear ship and submarine power plants, the power output is generally a fraction of a conventional nuclear power plant, usually around 100MWe, although some are planned to have as much as 800MWe.

The advantage of such power plants is their relative mobility and their ability to deliver in-situ electric power "on demand" even to remote regions, since they can be moved or towed to position with relative ease within large water bodies, and then docked with coastal facilities to transfer the produced power and heat to a land power grid. However, environmental groups are concerned that floating nuclear power plants are more exposed to accidents than onshore power stations and also pose a threat to marine habitats.^[1]

History

20th century

The first floating nuclear power station was the MH-1A, using pressurized water reactor built in a converted Liberty ship, which achieved criticality in 1967. Proposals to build a floating nuclear power plants off the coast of New Jersey and off Jacksonville, Florida were considered in the 1970's but ultimately scrapped.

21st century

In the 21st century, Russia has led in the practical development of floating nuclear power stations. On 14 September 2019, Russia’s first-floating nuclear power plant, Akademik Lomonosov, arrived to its permanent location in the Chukotka region.^[2] It started operation on 19 December 2019.^[3]

In 2022, the United States Department of Energy funded a three-year research study of offshore floating nuclear power generation.^[4] In October 2022, NuScale Power and Canadian company Prodigy announced a joint project to bring a North American small modular reactor based floating plant to market.^[5]

Samsung and UK-based Core Power^[6] are also looking into using compact molten salt reactor technology in floating platforms, with the former aiming at a modular power barge of up to 800MWe.^[7]^[8]

Advantages

Virtually no land or concrete is used.
Earthquake resistant.
Easily transported for relocation, refueling, refurbishment and decommissioning.
Surrounded by water that can be used for active or passive cooling.
Available to remote locations where a conventional power plant would be unfeasible.^[9]

Footnotes

^ "Akademik Lomonosov Floating Nuclear Co-generation Plant". Power Technology. 2020. Retrieved 18 January 2023.
^ "Russia's first sea-borne nuclear power plant arrives to its base". Reuters. 14 September 2019. Retrieved 15 September 2019.
^ "Russia connects floating plant to grid". World Nuclear News. 19 December 2019. Retrieved 20 December 2019.
^ "US begins study of floating nuclear plants". Nuclear Engineering International. 1 September 2022. Retrieved 2 September 2022.
^ "NuScale and Prodigy conceptual design for marine-based SMR plant". World Nuclear News. 27 October 2022. Retrieved 31 October 2022.
^ "Japanese firms invest in maritime nuclear developer Core Power : New Nuclear". World Nuclear News. 24 May 2023. Retrieved 25 May 2023.
^ Prevljak, Naida Hakirevic (12 April 2022). "Samsung Heavy, Seaborg join forces to develop floating nuclear power plants". Offshore Energy. Retrieved 5 January 2023.
^ Mandra, Jasmina Ovcina (4 January 2023). "Samsung forges ahead with CMSR power barge development". Offshore Energy. Retrieved 5 January 2023.
^ Economist, The (25 April 2014). "Here Are The Advantages Of Floating Nuclear Power Stations". Business Insider. Retrieved 17 January 2023.

External links

Media related to Floating nuclear power plant at Wikimedia Commons
Sevmash, a leading Russian manufacturer of floating nuclear power plants
Floating nuclear power stations raise spectre of Chernobyl at sea

Science

Imaging	Autoradiograph RadBall Scintigraphy Single-photon emission (SPECT) Positron-emission tomography (PET)
Therapy	Fast-neutron Neutron capture therapy of cancer Targeted alpha-particle Proton-beam Tomotherapy Brachytherapy Radiosurgery Radiopharmacology

Processing

Weapons

Topics	Arms race Delivery Design Disarmament Ethics Explosion effects History Proliferation Testing high-altitude underground Warfare Yield TNTe
Lists	States with nuclear weapons Historical stockpiles and tests Tests Tests in the United States WMD treaties Weapon-free zones Weapons

Waste

Products	Actinide Reprocessed uranium Reactor-grade plutonium Minor actinide Activation Fission LLFP Actinide chemistry
Disposal	Fuel cycle High-level (HLW) Low-level (LLW) Nuclear decommissioning Repository Reprocessing Spent fuel pool cask Transmutation

Debate

Nuclear reactors

Fission

Moderator

Light water

Aqueous homogeneous
Boiling
- BWR
- ABWR
- ESBWR
- Kerena
Natural fission
Pressurized
- AP1000
- APR-1400
- APR+
- APWR
- ATMEA1
- CAP1400
- CPR-1000
- EPR
- HPR-1000
  - ACPR1000
  - ACP1000
- VVER
- IPWR-900
- many others
Supercritical (SCWR)

Heavy water
by coolant

D₂O	Pressurized CANDU CANDU 6 CANDU 9 EC6 AFCR ACR-1000 CVTR IPHWR IPHWR-220 IPHWR-540 IPHWR-700 PHWR KWU MZFR R3 R4 Marviken
H₂O	HWLWR ATR HW BLWR 250 Steam-generating (SGHWR) AHWR
Organic	WR-1
CO₂	HWGCR EL-4 KKN KS 150 Lucens

Graphite
by coolant

Water

H₂O	AM-1 AMB-X EGP-6 RBMK

Gas

CO₂	Uranium Naturel Graphite Gaz (UNGG) Magnox Advanced gas-cooled (AGR)
He	GTMHR MHR-T UHTREX VHTR (HTGR) PBR (PBMR) AVR HTR-10 HTR-PM THTR-300 PMR

Molten-salt

Fluorides	Fuji MSR Liquid-fluoride thorium reactor (LFTR) Molten-Salt Reactor Experiment (MSRE) Integral Molten Salt Reactor (IMSR) TMSR-500 TMSR-LF1

None
(fast-neutron)

Breeder (FBR) Integral (IFR) Liquid-metal-cooled (LMFR) Small sealed transportable autonomous (SSTAR) Traveling-wave (TWR) Energy Multiplier Module (EM2) Reduced-moderation (RMWR) Fast Breeder Test Reactor (FBTR) Dual fluid reactor (DFR)
Generation IV	Sodium (SFR) BN-350 BN-600 BN-800 BN-1200 CFR-600 Phénix Superphénix PFBR FBR-600 CEFR PFR PRISM Lead Helium gas (GFR) Stable Salt Reactor (SSR)

Others

Organic nuclear reactor
- Arbus
- Piqua
Aircraft Reactor Experiment

Fusion
by confinement
Magnetic	Field-reversed configuration Levitated dipole Reversed field pinch Spheromak Stellarator Tokamak
Inertial	Bubble (acoustic) Fusor electrostatic Laser-driven Magnetized-target Z-pinch
Other	Dense plasma focus Migma Muon-catalyzed Polywell Pyroelectric

Nuclear technology portal
Category
Commons

Electricity delivery

Concepts

Portal pylons of Kriftel substation near Frankfurt

Sources

Non-renewable	Fossil fuel power station Coal Natural gas Oil shale Petroleum Nuclear
Renewable	Biofuel Biogas Biomass Geothermal Hydro Marine Current Osmotic Thermal Tidal Wave Solar Sustainable biofuel Wind