A University of Arkansas professor and his team will develop a device to link solar power arrays to the national power grid thanks to a $3.4 million award from the U.S. Department of Energy.
Yue Zhao, an assistant professor in the College of Engineering, has been working on the 300-watt silicon-carbide solar inverter; the funds, which include $713,853 in matching funds from the university and industry, will allow the research to continue.
In a press release from the university,
The converter converts the direct current (DC) produced by solar power into the voltage level of alternating current, or AC, for delivery to the grid. The silicon-carbide inverter will replace the less efficient transformers in use today.
The press release in full:
Zhao Receives $3.4 Million Award to Develop Solar Inverter
Research may lead to a cost-effective commercial device capable of integrating solar energy with the nation’s power grid.
FAYETTEVILLE, Ark. – Yue Zhao, assistant professor of electrical engineering at the University of Arkansas, has been awarded $3.4 million to advance power electronics research on the nation’s electric grid. The award includes $2,765,138 from the U.S. Department of Energy Solar Energy Technologies Office and $713,853 in matching funds from university and industry partners.
The funding will enable Zhao’s team to continue developing a high-density, 300-kilowatt, silicon-carbide solar inverter, a critical power electronic device to link solar power arrays to the national power grid. Zhao’s technology is intended to lower the cost of electricity produced by photovoltaic farms.
“Working with cutting-edge, silicon-carbide power electronics, our research team uses a holistic design approach to develop a solar inverter that will achieve higher efficiency and power density, an extended service life and lower long-term costs,” Zhao said.
Solar power arrays produce direct
The design of Zhao’s solar inverter proposes a new circuit capable of generating AC directly at medium voltage, eliminating the need for a transformer. This innovation significantly increases the volumetric power density of the device, while decreasing its size and reducing installation and maintenance costs.
The U.S. Department of Energy expects to cut the cost of solar electricity by an additional 50 percent by 2030 to enable greater adoption of solar energy. Aligned with this goal, Zhao’s research may lead to the development of a commercial-scale, silicon-carbide solar inverter system. If successful, the power density of the inverter will be 10 times greater than current technology, and the cost of the inverter system will be reduced by 50 percent.
Zhao was selected as a part of the Solar Energy Technologies Office’s Advanced Power Electronics Design for Solar Applications funding program, which aims to develop new technology to improve devices that serve as an interface between solar photovoltaic arrays and the electric power grid. These devices will enhance the reliability and resiliency of the nation’s electric grid.
Zhao’s team is developing the solar inverter at the U of
“We are very fortunate to have built a strong power electronics program with the support of U of A administration,” Zhao said. “This award reflects the competitiveness of our program and the great team we have been able to assemble.”
The U of A research team members