Getting the Most Out of Solar Panels

Solar is cheaper than ever, thanks to the falling cost and rising efficiency of photovoltaic (PV) solar panels. But here’s something to consider: figuring out the real cost of solar energy is about more than just the price tag on the panels and their rated power output. For example, there’s the lifespan of the panels to take into account. And then there’s the system’s “solar energy yield” — or how much electricity it will actually generate over the course of the year.

Solar panels are rated on efficiency and the power output under standard laboratory conditions. Of course, your solar energy system isn’t being installed in a lab. It’s going outside, where all kinds of things can change its actual solar energy yield. That’s why the U.S. Department of Energy’s SunShot Initiative is funding research into better, tougher modules that can last longer and generate more electricity in less-than-ideal conditions. Read on to learn about three ways the outside world can conspire to cut into your solar energy yield — and how SunShot-funded projects are working on solutions.

Man, It’s a Hot One

High temperatures reduce the voltage of a solar cell — which, as you might guess, is a bad thing. Conventional rooftop solar modules can lose as much as 30 percent of their electricity output on hot summer days. Researchers at Arizona State University are trying to address this problem by improving the backsheet — or bottom layer — of a solar PV module, which serves as an electrical insulator and protects the module from moisture and other environmental damage. By studying backsheets with different heat-conducting properties, the team hopes to keep solar panels cooler and improve performance in hot weather.

Dirt Does Hurt

Another way panels lose power is simply that they get dirty. The effects of “soiling” (as it’s known in the solar industry) vary widely by location, but energy yield losses of 10 percent are not uncommon. Enki Technology researchers are scouring everything from panel maintenance procedures to environmental conditions to better understand how and why panels lose power to dirt. The company hopes to use the information it gathers to better predict soiling from one solar energy system to another, and to design more effective dirt-resistant treatments for PV module glass.

Shady Situations

While heat and dirt reduce solar panels’ energy yield in a pretty straightforward way, shadows are a bit more complicated. In instances when a faint cloud goes over the solar module, the power levels are simply reduced. However, sometimes the light is completely or regularly blocked by a permanent structure — like a utility pole that shades just one part of the module — which can actually cause “hot spots” that can damage the module over time. The University of Michigan, Ann Arbor has a clever solution in the works: its “super-cell” design can actually balance power across the module at the cell level. This lets the unshaded cells keep working normally, increasing the energy yield of the module and even improving its durability.                                         

Increasing energy yield continues to be a fruitful subject of research by SunShot awardees. SunShot has already made huge advances in solar cell efficiency — including a recent announcement that a new Ohio State University design achieved 40 percent efficiency. Increasing energy yield is what will help drive down the cost of solar power in the real world. That is why, in addition to the new projects announced this week, SunShot plans to release a funding opportunity in the coming weeks that focuses on improving module and system design. Stay tuned for more innovation in this area.

This article was originally published by the U.S. Department of Energy in the public domain.

Lead image credit: U.S. Department of Energy

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Dr. Lenny Tinker is Acting Photovoltaics Program Manager for the U.S. Department of Energy. He has been at the DOE Solar Energy Technologies Office (SETO) since September 2011 and started as an AAAS Science and Technology Policy Fellow on the Photovoltaics team working on Incubator Round 6. As a Federal employee, he now manages early-stage applied research and development programs at national labs, universities, and companies to develop advanced photovoltaic systems.

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