US start-up mPower Technology is scaling up its flexible crystalline silicon solar module technology for spatial and terrestrial applications. The back-contact solar panels consist of micro-singulated silicon dies that are “hyper-interconnected” in series or in parallel. The devices have efficiency ranging from 22 to 23% depending on the size or applications.
US-based start-up mPower Technology, a spin-off of the Department of Energy’s Sandia National Laboratories, has developed a flexible monocrystalline silicon solar module technology, called DragonScales, which it claims can be used for both space and terrestrial applications.
“Our main business is expected to be in the space solar cell segment,” the company’s president and CEO, Kevin Hell , told pv magazine. “But we are also planning to enter the building-integrated photovoltaics (BIPV) business, as our products could be easily used for residential and commercial projects, and to produce solar modules for soldier portable and shelter power applications.”
The fully encapsulated modules are fabricated with conventional back contact silicon solar cells with a thickness of 150 um or less and are assembled using existing high-volume fabrication processes from the microelectronics industry. “Our pilot line is a conventional machine for the production of semiconductors that has been adapted to the manufacturing of our flexible solar modules,” mPower CTO Murat Okandan stated. “The panels can be customized according to the customers’ needs and adapted to different applications.”
According to the manufacturer, its production equipment can produce very high volumes of modules and allow rapid scaling as needed by the customers and applications for space.
The back-contact solar panels consist of micro-singulated silicon dies that are “hyper-interconnected” in series or in parallel. According to the company, the design allows customization of its “super modules” to any shape, thickness, voltage, size, material stack, and other design considerations to meet application-specific requirements at the lowest cost.
The modules feature efficiencies ranging from 22 to 23% and temperature coefficients spanning from 0.4 to 0.27 percent per degree Celsius, depending on the size or applications. Since the interconnect design is very customizable, it is possible to provide high voltage/low current or other desired array configuration details to fit the desired physical footprint and achieve the highest possible power delivery, the company stated. This is also claimed to bring in a very high level of innate electrical and mechanical resilience at the system level.
This approach, according to the manufacturer, leverages the massive scale and high power of the terrestrial silicon PV market to minimize cost, while eliminating the challenging, hard-to-scale models of custom cell manufacturing.
“Our products are more expensive than conventional PV panels, but they are three to five times less expensive than III-V modules based on gallium arsenide for applications in space,” Hell further explained. “They are also significantly lighter since they are flexible and thus require less structural materials.”
At the beginning of February, mPower raised $10 million in a Series B financing round. The funds will be used to scale up the company’s manufacturing facility and integration and test facility in Albuquerque, New Mexico, and to further develop the cell technology.
The production line currently has a capacity of 100 kW and the company plans to expand it to 1.5 MW. The yearly volume is projected to reach around 50 MW by 2025.
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