A space solar-powered satellite (SSPS) is a tremendous energy system that collects and converts solar power to electric power in space, and then transmits the electric power to Earth, spacecraft, or moving targets via microwave. It is regarded as one of the most potential ways to solve the problem of energy crisis.
In 2022, a team of researchers from Xidian University in China completed a full-link and full-system ground demonstration and verification system for an SSPS, named the Sun-Chasing Project. Their study, recently published in Engineering, introduces the design concept of OMEGA 2.0 SSPS, the related key technologies, and the development of ground demonstration and verification system for OMEGA 2.0.
In this research, several key technologies of SSPS were tackled, tested, and verified, including high-efficiency solar power collection and photoelectric conversion, microwave conversion, microwave wireless power transmission, beam-forming optimization, accurate microwave beam pointing measurement and control, microwave reception and rectification, and smart mechanical structure design, and more.
In the Sun-Chasing Project, solar power collected by spherical crown concentrators is converted and wirelessly transmitted via microwaves over a distance of 55 m. Over 2 kW of microwave power is transmitted from a circular active phased array with a diameter of 1.2 m, and 87.3% of which is captured by a rectenna with diameter of 5.2 m.
The team said, “The SSPS ground verification system can mimic the key links of a real SSPS in outer space, such as sun tracking, photoelectric conversion, high voltage and large power transmission and management, and smart mechanical structures.”
This breakthrough in the design of SSPS ground verification system holds significant potential for advancing the development of a future SSPS. It has the capacity to track the sun, concentrate the collected solar power, convert solar power to direct current (DC) power, beam the power to a rectenna via microwaves, and convert the microwave power back to DC power, which means that it can simulate the full working process of an actual SSPS in outer space.
Thus, this research could pave the way for the development of SSPS in the future. Also one of the key technologies of the work, microwave wireless power transmission technology, may have a wide variety of applications. For example, in the near future, satellites are expected to be equipped with foldable rectenna arrays in place of those bulky solar panels. A transmitting antenna could serve as a power pile to charge satellites equipped with rectenna arrays.