B&W mPower

This page or section may contain link spam masquerading as content. Spam on Wikipedia consists of external links mainly intended to promote a website. If you are familiar with the content of the external links, please help by removing promotional links in accordance with Wikipedia:External links. (February 2012)

This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed. Find sources: "B&W mPower" – news · newspapers · books · scholar · JSTOR (February 2012) (Learn how and when to remove this message)

The B&W mPower is a proposed small modular reactor designed by Babcock & Wilcox, and to be built by Generation mPower LLC, a joint venture of Babcock & Wilcox and Bechtel. It is a Generation III++ integral pressurized water reactor (light water reactor).

The reactor was unveiled by Babcock & Wilcox in June 2009.^[1][2] In July 201, Generation mPower LLC, a joint venture of Babcock & Wilcox and Bechtel.^[3] At the same time, Babcock & Wilcox announced that it will build a test facility for the mPower reactor design at the Center for Advanced Engineering and Research in Bedford County, Virginia.^[4] In April 2011, Babcock & Wilcox has received a $5 million grant from the Virginia Tobacco Indemnification and Community Revitalisation Commission for this test facility.^[5][6]

In June 2011 Generation mPower signed a letter of intent with the Tennessee Valley Authority for constructing up to six reactors at Clinch River Breeder Reactor site in Tennessee.^[7][8] The company also plans to deploy the first unit by 2020.^[7]

Generation mPower is planning to apply to the Nuclear Regulatory Commission for design certification by 2013.^[7]

B&W mPower is a Generation III++ integral pressurized water reactor (light water reactor) with a modular design. The reactor and steam generator are located in a single integrated reactor vessel located in an underground containment facility that would store all of the spent fuel.^[2] The modular unit has diameter of 4.5 metres (15 ft) and it is 23 metres (75 ft) high. The reactor core is of 2 by 2 metres (6 ft 7 in by 6 ft 7 in). The steam generator, derived from naval designs, has 3.6 metres (12 ft) diameter and is 22 metres (72 ft) high. The unit has an air-cooled condenser giving 31% thermal efficiency, and passive safety systems.^[9]

The reactor will have a rated electrical output of 125–180 MWe.^[9] When originally announced, the reactor had planned capacity of 125 MWe.^[2][9] Later the power was increased to 160 MWe and then to 160 MWe.^[9] In its pre-application design certification interaction to the Nuclear Regulatory Commission, the reactor's rated capacity was described as 500 MWt of thermal power and 160 MWe of electrical power.^[10]

The reactor has an expected lifetime of 60 year.^{[2][10][11][12]}

B&W mPower uses standard fuel enriched to 5%, similar to the fuel loaded in the other PWRs.^[9] It is designed for a 4-year refueling cycle. In the process of refuelling, the entire core will be completely removed in a single evolution, and replaced in a second separate evolution, making the core nearly "plug and play", unlike traditional reactors, which require fuel handling and movement of individual fuel rods during a refueling outage.^[9] The entire used core, once removed, can be placed in storage in the spent fuel pool next to the IRV in the containment, which is designed to hold an entire 60 years worth of used fuel, and is accessible by the containment gantry crane located above the IRV within the containment.^[11]

The mPower incorporates several features of the boiling water reactor (BWR). Like a BWR, the mPower reactor's primary coolant/moderator is highly purified water (with no boric acid). The Reactor Water Cleanup System ensures that primary system water remains pure. Similar to the ABWR, the mPower reactor has integral coolant recirculation pumps inside the Integral Reactor Vessel (IRV). The mPower reactor control rods are inserted from the top of the core and insert upon scram under gravity. All of the primary coolant is in the liquid phase during normal operation.^{[citation needed]}

The integral once-through steam generator is an advanced derivative of the steam generators used in older B&W designs (Davis Besse). Control rod drives do not penetrate the IRV, as in the light water reactors of today, but are instead wholly enclosed within the IRV. Burnable neutron absorbers within the fuel and control rod inventory is used to suppress hot excess reactivity. Cold shut-down is accomplished with control rod insertion (as in BWRs).^{[citation needed]}

The mPower is designed to produce superheated steam and does not require steam separators and dryers prior to admitting steam into the high pressure turbine.^{[citation needed]}

The mPower is designed to eliminate the potential loss of coolant accidents as the integral reactor vessel does not have large cold or hot leg piping; it contains the entire primary coolant loop within the reactor pressure vessel. If secondary cooling is lost, creating an effective loss of standard heat removal, there are water supplies located above and within the containment that can be used to cool the IRV with gravity driven-cooling. Further advanced means of heat removal can be used in the event that these systems are exhausted, such as by flooding the containment and establishing natural circulation.^{[citation needed]}

• Hyperion Power Module
• NuScale MASLWR
• Toshiba 4S

• B&W mPower reactor (Babcock & Wilcox website)
• Pre-Application Documents for the B&W mPower Design (NRC website)