Arizona Public Service touts the benefits of Solana solar project

Unlike other solar-powered electrical plants, the new Solana Generating Station keeps the sun’s energy working after dark to produce electricity for Arizona Public Service (APS) customers across the state, the utility said Oct. 3.

Solana, owned by Abengoa Solar, represents a major advance in solar production compared to photovoltaic technology, which needs direct sunlight to produce electricity. The three-square-mile Solana facility near Gila Bend, Ariz., uses concentrated solar power (CSP) and thermal energy storage to capture the sun’s heat. This technology enables Solana to produce electricity at full capacity for up to six hours after sunset, including the early evening hours when customer demand for power typically peaks in Arizona.

“Solana is a monumental step forward in solar energy production,” said Don Brandt, APS President and CEO. “Solana delivers important value to APS customers by generating power when the sun isn’t shining. It also increases our solar energy portfolio by nearly 50 percent. This provides a huge boost toward our goal to make Arizona the solar capital of America.”

Solana is one of the largest power plants of its kind in the world with a capacity of 280 MW. APS is purchasing 100% of the output from Solana, which was constructed and is owned by Abengoa Solar.

The plant’s CSP technology produces electricity by collecting the sun’s heat to create steam that turns conventional turbines. The process begins with 2,700 parabolic trough mirrors, which follow the sun to focus its heat on a pipe containing a heat transfer fluid. This fluid, a synthetic oil, can reach a temperature of 735 degrees. The heat transfer fluid then flows to steam boilers, where it heats water to create steam. The steam drives two 140-MW turbines.

What separates Solana from other solar plants is the ability to store the heat from the sun up to six hours for electrical production at night. In addition to creating steam, the heat transfer fluid is used to heat molten salt in tanks next to the steam boilers. The thermal energy storage system includes six pairs of hot and cold tanks with a capacity of 125,000 metric tons of salt, and the molten salt is kept at a minimum temperature of 530 degrees. When the sun goes down, the heat transfer fluid can be heated by the molten salt to create steam by running it through the tanks instead of the field of parabolic mirrors.

“With Solana’s substantial thermal heat storage capacity, we can manage electrical output from the plant much more effectively than from other solar power sources,” said Pat Dinkel, APS Vice President of Resource Management. “With photovoltaic technology, generated electricity needs to be used immediately or it’s lost. Solana’s technology extends the use of solar energy to produce power whenever our customers need it most, including evenings.”

With the addition of Solana, APS will have 750 MW of solar power on its system by the end of 2013. APS, Arizona’s largest and longest-serving electricity utility, serves more than 1.1 million customers in 11 of the state’s 15 counties. With headquarters in Phoenix, APS is the principal subsidiary of Pinnacle West Capital Corp. (NYSE: PNW).

The Abengoa website noted that besides the Solana project, which is coming on-line this year, it is building the Mojave Solar Project, a 280 MW (gross) parabolic trough plant. The plant is located 100 miles northeast of Los Angeles, near Barstow, Calif. Construction has begun and the Mojave Solar Project will come online in 2014, the website said.

About Barry Cassell 20414 Articles
Barry Cassell is Chief Analyst for GenerationHub covering coal and emission controls issues, projects and policy. He has covered the coal and power generation industry for more than 24 years, beginning in November 2011 at GenerationHub and prior to that as editor of SNL Energy’s Coal Report. He was formerly with Coal Outlook for 15 years as the publication’s editor and contributing writer, and prior to that he was editor of Coal & Synfuels Technology and associate editor of The Energy Report. He has a bachelor’s degree from Central Michigan University.