Palo Verde Nuclear Generating Station, Arizona

Last Updated: Septemper 10, 2009

Palo Verde Nuclear Generating Station

Description: Palo Verde is one of the few power plants in the Nation that contain three reactors (no U.S. power plants have more than three, although some foreign plants have more than four). According to preliminary data, unit two was up rated in capacity and is now the Nation's largest. Palo Verde is located in Maricopa County, on a 4,050-acre site near Wintersburg, Arizona. On November 18, 2005, the U.S. Nuclear Regulatory Commission announced approval of uprates at two of Palo Verde's reactors. According to the NRC press release, "The power uprates at each unit, located near Phoenix, Arizona, increases the net generating capacity of the reactors from 1270 to 1313 and 1317 megawatts electric, respectively, for Units 1 and 3. The licensee intends to implement the uprate by the end of December for Unit 1, and by the end of 2007 for Unit 3."

Palo Verde, Unit 1

Nuclear Steam System Supplier (NSSS Vendor) = Combustion Engineering (CE80, CE Standard Design)
Architect Engineer = Bechtel
Owner = (See Table)
Operator (Licensee) = Arizona Nuclear Power Project

Palo Verde, Unit 2

Nuclear Steam System Supplier (NSSS Vendor) = Combustion Engineering (CE80, CE Standard Design)
Architect Engineer = Bechtel
Owner = (See Table)
Operator (Licensee) = Arizona Nuclear Power Project

Palo Verde, Unit 3

Nuclear Steam System Supplier (NSSS Vendor) = Combustion Engineering (CE80, CE Standard Design)
Architect Engineer = Bechtel
Owner = (See Table)
Operator (Licensee) = Arizona Nuclear Power Project

Plant Operator and Ownership,* 2004

© U.S. Nuclear Regulatory Commission

According to the U.S. Nuclear Regulatory Commission, all three reactors are dry, ambient pressure. [2]

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

[1] Capacity, for purposes of this report, is the net summer capability as reported in Energy Information Administration (EIA) Form EIA-860, "Annual Electric Generator Report." Capacity Factor is a percentage calculation in which the maximum possible generation (based on net summer capability) is divided into the actual generation then multiplied by 100. Generation is the net electricity output reported by plant owners on Form EIA-906, “Power Plant Report.” Type of Unit: All U.S. commercial reactors currently in operation are one of two types: BWR (boiling water reactor) or PWR (pressurized light water reactor). The type, on-line date, and the license expiration date are published annually in Information Digest by the U.S. Nuclear Regulatory Commission.

[2] Dry, Ambient Pressure: a reactor containment design whose safety has been evaluated on the basis of having a dry air atmosphere at ambient pressure (0 psig) prior to the onset of a loss of coolant accident or steam pipe break. The containment design (concrete and steel tendons) must be able to take the full thermal and pressure stresses associated with the rapid energy release (steam) from a major pipe break.