Organic photovoltaics (OPV) is an innovative solar cell technology based on conductive plastic materials such as polymers
Such devices are fabricated by ultra low-cost, roll-to-roll printing techniques. They are formed by layering extremely thin, photo-active coatings on lightweight, flexible carrier substrates, which are organic in nature as well. OPV is one of the most dynamic, rapidly developing technology segments pertaining to renewable, or green, energy.
Despite the current upheaval in world financial markets, OPV continues to gain in economic importance and make steady technical progress. Various OPV technologies are being developed in industrial and academic research cooperatives and project-based partnerships. At this time, OPV is well on its way to broad commercialization, as first products are available on consumer markets. By heavily investing in manufacturing capacity, the OPV industry is gearing up for mass production of a new kind of lowcost, organic and printed micro-electronics. Current trends and the latest developments in this field will be on display at LOPE-C in Frankfurt, Germany from May 31 – June 2, 2010.
Consumer Goods and Utilities for Mass Markets
Organic photovoltaics (OPV) is a key segment of organic and printed electronics. OPV opens up a new and advantageous way of clean electricity generation using lightweight and low-cost solar cells. Their every-day utility will go far beyond today’s cell types made of crystalline silicon sealed in relatively heavy glass modules. OPV cells will be an integral part of a broad range of customary, as well as absolutely novel products operated by their own, grid independent local power – without constraining their originally intended functionalities.
First examples of such solar-enabled consumer products are handbags equipped with flexible organic solar cells. OPV-functionalized bags serve as charging stations for mobile phones and other portable devices carried inside to keep them operational at all times.
Other innovative OPV products, forerunners of mass-market consumer and utility goods, are sun shades and umbrellas covered with thin, flexible organic solar cells. While offering shadow, they also provide power for charging laptops and communications devices. Tents, for military purposes or recreational use, are further examples. Next in line are car roofs as solar generators. Then, all larger-size outdoor objects exposed to the sun’s radiation. They all may be suited as carriers of large-area organic photovoltaic devices. From there, it’s just a small step to another timely concept: realizing the Zero Energy House through “building integrated photovoltaics”, or BIPV.
Building Integrated Photovoltaics
Organic photovoltaics enables large-scale solar energy generation directly integrated in roofs and facades. This includes new housing as well as the energetically renovated building stock. Building-integrated photovoltaics, if based on organic and printed electronics, should become an integral part of house construction leading to novel architectural solutions for residential and industrial buildings. Due to its low weight and easy malleability, BIPV should be able to replace today’s add-on crystalline silicon roof modules. BIPV cells can be integrated already in the building’s design. Forming a second, outer skin, they conform to a building’s cubature. This is similar to “smart” fabrics, where organic solar cells excel by their robustness and flexibility without constraining the textiles’ original functionality.
“In all these applications, organic and printed photovoltaics can be realized much easier and more cost efficient,” says Dr. Klaus Hecker, Managing Director of the Organic Electronics Association (OE-A), a Working Group within VDMA. “Solar cells can now be directly integrated in their intended applications. They become a functional part as well as a design component of a product.”
Organic Photovoltaics: from Lab to Fab
Functionally integrated solar local energy generation increases the utility of consumer products and commercial objects. This is the decisive advance that organic photovoltaics will bring about. The most relevant observation in this context is that OPV technology is currently moving out of the R&D stage and is moving towards industrial manufacturing – lab to fab. At LOPE-C 2010 (Large Area Organic and Printed Electronics Convention), the annual conference and exhibition of the OE-A, taking place May 31 to June 2, 2010, organic photovoltaics is set to claim a major share of marketer and investor attention.
“2010 will be the year of OPV moving into initial production for a variety of consumer oriented applications”, says Andrew Hannah, CEO of Plextronics in Pittsburgh, Pennsylvania, a leading industry player. A Carnegie- Mellon University spin-off, Plextronics specializes in OPV and OLED (organic light emitting diode) lighting ink products. The market for printed electronic devices, components and systems, according to Andrew Hannah, could surpass $300bn worldwide within the next 20 years. As one of the leading vendors of conductive polymers and organic inks used in the coating processes of OPV modules, Plextronics is currently developing large-scale coating processes to help spur the introduction manufacturing of commercially viable OPV modules.
Heliathek GmbH, located in Ulm and Dresden, Germany, has concluded another round of venture capitalization led by Wellington Partners in the amount of $27m for establishing a production facility for organic solar cells for mobile applications and BIPV. With their OPV tandem cells, Heliathek currently achieves an efficiency of slightly above 6 percent and is planning to utilize a large-area continuous vacuum coating process.
First Consumer Products: Bags and Backpacks
“At LOPE-C 2010, we will see numerous attendees carrying the first available OPV products, such as bags and backpacks,” says Thomas Kolbusch, VP of Coatema Coating Machinery GmbH of Dormagen, Germany. This is an important indicator of OPV nearing marketability, Kolbusch says: “These products are now offered by several new vendors.” They serve as a market opener and attract the early adaptors of novel consumer goods based on organic and printed electronics.
Coatema offers a broad range of equipment for the automation of OPV cell manufacture and encapsulation between robust and flexible, yet transparent barrier layers protecting against degradation by oxygen and vapor penetration. Coatema also makes machinery for substrate bonding of organic cells. At LOPE-C 2010, the company will demonstrate a large OPV coating machine. According to Kolbusch, a cumulative installed basis of 2 gigawatts of flexible organic solar cells during 2010 is a realistic forecast. On the other hand, there is no doubt that OPV still has to overcome major challenges. Kolbusch: “Especially BIPV applications will require long-term stability – whereas efficiency, in the light of ultra low-cost manufacturing, is of second priority. We are seeing strong demand for the development of flexible OPV barrier materials at a reasonable cost.”
OPV Efficiency Jumps to almost 8 Percent
In terms of efficiency, OPV has recently encountered a major step upwards. Current record holder is Solarmer Energy Inc. of El Monte, California. Their flexible plastic solar panels have reached an independently (NREL) verified efficiency of 7.9 percent. This, of course, pertains to an R&D environment.
Commercially available OPV modules, at this moment, can muster just 3 to 5 percent. Compared to off-theshelf crystalline silicon solar modules this appears minuscule. But in practice, the OPV cells’ low efficiency is more than compensated for by the much larger usabl