IPHWR-220

IPHWR-220 Reactor Class
Kaiga Atomic Power Plant, showing four IPHWR-220 reactors
Generation	Generation II reactor
Reactor concept	pressurized heavy-water reactor
Reactor line	IPHWR (Indian Pressurized Heavy-water Reactor)
Designed by	Bhabha Atomic Research Centre
Manufactured by	PPED, DAE (now part of NPCIL)
Status	14 Operational
Main parameters of the reactor core
Fuel (fissile material)	²³⁵U (NU/SEU/LEU)
Fuel state	Solid
Neutron energy spectrum	Thermal
Primary control method	control rods
Primary moderator	Heavy water
Primary coolant	Heavy water
Reactor usage
Primary use	Generation of electricity
Power (thermal)	754.5 MWth
Power (electric)	220 MWe

The IPHWR-220 (Indian Pressurized Heavy Water Reactor-220) is an Indian pressurized heavy-water reactor designed by the Bhabha Atomic Research Centre.^[1] It is a Generation II reactor developed from earlier CANDU based RAPS-1 and RAPS-2 reactors built at Rawatbhata, Rajasthan. It can generate 220 MW of electricity. Currently, there are 14 units operational at various locations in India. It is sometimes referred to as an small modular reactor due to its modularization.^[2]

The IPHWR design was later expanded into 540 MW and 700 MW designs, as well as the AHWR-300 design.

Reactor fleet

IPHWR-220 Reactor fleet
Power station	Location	Operation start	Status
MAPS-1	Kalpakkam, Tamil Nadu	27 January 1984	Operational
MAPS-2	Kalpakkam, Tamil Nadu	21 March 1986
NAPS-1	Narora, Uttar Pradesh	1 January 1991
NAPS-2	Narora, Uttar Pradesh	1 July 1992
KAPS-1	Kakrapar, Gujarat	6 May 1993
KAPS-2	Kakrapar, Gujarat	1 September 1995
RAPS-3	Rawatbhata, Rajasthan	1 June 2000
RAPS-4		23 December 2000
RAPS-5		4 February 2010
RAPS-6		31 March 2010
KGS-1	Kaiga, Karnataka	6 November 2000
KGS-2		6 May 2000
KGS-3		6 May 2007
KGS-4		27 November 2010


Specifications	IPHWR-220^[3]	IPHWR-540^[4]^[5]^[6]^[7]	IPHWR-700^[8]
Thermal output, MWth	754.5	1730	2166
Active power, MWe	220	540	700
Efficiency, net %	27.8	28.08	29.08
Coolant temperature, °C:	?
core coolant inlet	249	266
core coolant outlet	293.4	310
Primary coolant material	Heavy Water
Secondary coolant material	Light Water
Moderator material	Heavy Water
Reactor operating pressure, kg/cm² (g)	87	100
Active core height, cm	508.5	594	594
Equivalent core diameter, cm	451	-	638.4
Average fuel power density	9.24 KW/KgU		235 MW/m³
Average core power density, MW/m³	10.13		12.1
Fuel	Sintered Natural UO₂ pellets
Cladding tube material	Zircaloy-2	Zircaloy-4
Fuel assemblies	3672	5096	4704 fuel bundles in 392 channels
Number of fuel rods in assembly	19 elements in 3 rings	37	37 elements in 4 rings
Enrichment of reload fuel	0.7% U-235
Fuel cycle length, Months	24	12
Average fuel burnup, MW · day / ton	6700	7500	7050
Control rods	SS/Co	Cadmium/SS
Neutron absorber	Boric Anhydride	Boron
Residual heat removal system	Active: Shutdown cooling system Passive: Natural circulation through steam generators	Active: Shutdown cooling system Passive: Natural circulation through steam generators and Passive Decay heat removal system
Safety injection system	Emergency core cooling system

^ "ANU SHAKTI: Atomic Energy In India". BARC. Archived from the original on 2020-06-26. Retrieved 2021-03-20.
^ "ARIS - Technical Data". IAEA.
^ "Status report 74 - Indian 220 MWe PHWR (IPHWR-220)" (PDF). International Automic Energy Agency. 2011-04-04. Retrieved 2021-03-21.
^ Soni, Rakesh; Prasad, PN. "Fuel technology evolution for Indian PHWRs" (PDF). International Atomic Energy Agency. S. Vijayakumar, A.G. Chhatre, K.P.Dwivedi.
^ Muktibodh, U.C (2011). "Design, Safety and Operability performances of 220 MWe, 540 MWe and 700 MWe PHWRs in India". Inter-Regional Workshop on Advanced Nuclear Reactor Technology for Near-term Deployment.
^ Bajaj, S.S; Gore, A.R (2006). "The Indian PHWR". Nuclear Engineering and Design. 236 (7–8): 701–722. doi:10.1016/j.nucengdes.2005.09.028.
^ Singh, Baitej (July 2006). "Physics design and Safety assessment of 540 MWe PHWR" (PDF). BARC Newsletter. 270. Archived from the original (PDF) on 2013-05-22. Retrieved 2021-03-21.
^ "Status report 105 - Indian 700 MWe PHWR (IPHWR-700)" (PDF). International Atomic Energy Agency. 2011-08-01. Retrieved 2021-03-20.

Uranium resources

Nuclear reactor technologies

Electricity generation	IPWR-900
Nuclear marine propulsion	CLWR CLWR-B1 CLWR-B2

BARC	APSARA CIRUS ZERLINA Dhruva PURNIMA-I PURNIMA-II PURNIMA-III
IGCAR	KAMINI Fast Breeder Test Reactor
Proposed	Compact High Temperature Reactor High-flux Research Reactor

Nuclear Power Plants

Research and testing

Organisations

Other topics

Moderator

Light water

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

Water

H₂O	AM-1 AMB-X EGP-6 RBMK

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

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

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)