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(Top) 1 Construction 2 Advantages 3 Legacy 3.1 Energy Multiplier Module (EM2) 4 See also 5 References 6 External links

Gas turbine modular helium reactor

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The Gas Turbine Modular Helium Reactor (GT-MHR) is a class of nuclear fission power reactor designed that was under development by a group of Russian enterprises (OKBM Afrikantov, Kurchatov Institute, VNIINM and others), an American group headed by General Atomics, French Framatome and Japanese Fuji Electric.^[1] It is a helium cooled, graphite moderated reactor and uses TRISO fuel compacts in a prismatic core design. The power is generated via a gas turbine rather than via the more common steam turbine.

A conceptual design was produced by 1997,^[1] and it was hoped to have a final design by 2005, and a prototype plant commissioning by 2010.^[1]

Construction[edit]

The core consists of a graphite cylinder with a radius of 4 metres (13 ft) and a height of 10 metres (33 ft) which includes 1 metre (3 ft 3 in) axial reflectors at top and bottom. The cylinder allocates three or four concentric rings, each of 36 hexagonal blocks with an interstitial gap of 0.2 centimetres (0.079 in). Each hexagonal block contains 108 helium coolant channels and 216 fuel pins. Each fuel pin contains a random lattice of TRISO particles dispersed into a graphite matrix. The reactor exhibits a thermal spectrum with a peak neutron energy located at about 0.2 eV. The TRISO fuel concept allows the reactor to be inherently safe. The reactor and containment structure is located below grade and in contact with the ground, which serves as a passive safety measure to conduct heat away from the reactor in the event of a coolant failure.^[2]

Advantages[edit]

The Gas Turbine Modular Helium Reactor utilizes the Brayton cycle turbine arrangement, which gives it an efficiency of up to 48% – higher than any other reactor, as of 1995.^[3] Commercial light water reactors (LWRs) generally use the Rankine cycle, which is what coal-fired power plants use. Commercial LWRs average 32% efficiency, again as of 1995.

Legacy[edit]

Energy Multiplier Module (EM2)[edit]

In 2010 General Atomics conceptualized a new reactor that utilizes the power conversion features of the GT-MHR, the Energy Multiplier Module (EM2). The EM2 uses fast neutrons and is a gas-cooled fast reactor, enabling it to reduce nuclear waste considerably by transmutation.^[4]

References[edit]

^ ^a ^b ^c "GT-MHR PROJECT" (PDF). IAEA. Retrieved 2018-02-16.

^ Labar, Malcomb P. "The Gas Turbine Modular Helium Reactor: A promising option for near term deployment" San Diego, CA; General Atomics Presentation; 2002

^ The Fifty Percent Efficiency Nuclear Power Plant Archived April 8, 2008, at the Wayback Machine

^ "Energy Multiplier Module (EM²)". Ga.com. Retrieved 2013-09-05.

External links[edit]

"General Atomics GT-MHR Page". Archived from the original on December 11, 2013. Retrieved December 11, 2013.{{cite web}}: CS1 maint: bot: original URL status unknown (link)

Types of nuclear fission reactor

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
bycoolant

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
bycoolant

Water

H₂O	AM-1 AMB-X EGP-6 RBMK

Gas

CO₂

GTMHR
- MHR-T
UHTREX
VHTR (HTGR)
- PBR (PBMR)
  - AVR
  - HTR-10
  - HTR-PM
  - THTR-300
- PMR

Molten-salt

Fluorides

None
(fast-neutron)

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

Nuclear power in Russia

Reactors

Active	Akademik Lomonosov Balakovo Beloyarsk Bilibino Dimitrovgrad Kalinin Kola Kursk Leningrad Leningrad II Novovoronezh Novovoronezh II Rostov Smolensk
Under construction	Kursk II Seversk
Closed	Obninsk Siberian Troitsk
Canceled	Bashkir Crimean Gorky Kaliningrad Krasnodar Primorsk South Ural Tatar (Kama) Tver Volgograd Voronezh
Planned	Central Kola II Nizhny Novgorod Smolensk II

Reactor types

Power plant reactors

Research, experimental
and prototype reactors

Research locations

Kurchatov Institute

Companies

Category

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