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Surry Nuclear Generating Station, Virginia |
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Update: October 8, 2008
Next Update: October 2009 Surry Nuclear Generating Station Net Generation and Capacity, 2007
Description: The Surry plant, named for the county in which it is located, is on an 840-acre site near historic Williamsburg, Virginia. Surry, Unit 1 Nuclear Steam System Supplier (NSSS Vendor) = Westinghouse Electric Surry, Unit 2 Nuclear Steam System Supplier (NSSS Vendor) = Westinghouse Electric Pressurized-Water Reactor (PWR) In a typical commercial pressurized light-water reactor (1) the reactor core generates heat, (2) pressurized-water in the primary coolant loop carries the heat to the steam generator, (3) inside the steam generator heat from the primary coolant loop vaporizes the water in a secondary loop producing steam, (4) the steam line directs the steam to the main turbine causing it to turn the turbine generator, which produces electricity. The unused steam is exhausted to the condenser where it is condensed into water. The resulting water is pumped out of the condenser with a series of pumps, reheated, and pumped back to the steam generator. The reactors core contains fuel assemblies which are cooled by water, which is force-circulated by electrically powered pumps. Emergency cooling water is supplied by other pumps, which can be powered by onsite diesel generators. Other safety systems, such as the containment cooling system, also need power.
Containment: According to the U.S. Nuclear Regulatory Commission, both PWR units have dry, subatmospheric1 containment. _________________________________________ 1Dry, Subatmospheric: a reactor containment design which is held a negative (sub-atmospheric) pressure (i.e., a vacuum) during normal operations. When a pipe breaks or a steam release occurs in this design, much of the initial internal pressure rise is countered by the negative pressure that is already present. As a result, the final pressure reached is lower than that which would have occurred if the containment had started out at zero psig (atmospheric pressure). NOTE: If the expected containment pressure buildup from steam in an accident is say, +10 psig; and the containment walls will burst at 8 psig; - you can eliminate the possibly of a containment failure by simply starting out at negative 5 psig instead of 0 psig. So when the accident occurs, the pressure will rise from -5 psig to just +5 psig and still be safe. |
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