Dave Savastano10.24.14
Flexible organic photovoltaic (OPV) cells more than 6m long and 50cm wide have been produced by FabriGen, a recent pan European collaborative R&D project. The project, which involved six partners from four different countries, manufactured the demonstrator that combines flexible OPV materials with tensile fabrics utilizing roll to roll production techniques; 16 square meters of active-area material was made for the final demonstrators.
The aim of FabriGen was to work towards Europe’s ambitious targets for renewable energy generation by bringing new innovative solar energy products to market. The development of organic photovoltaics (OPV) with flexible form factors opens up a host of opportunities for designers to embed energy harvesting and functionality into their products, creating the opportunity for new, innovative solar panels that are thinner, lightweight large area and potential lower cost.
The flexible nature of OPV provides a number of advantages to the solar power industry. The ability to produce the panels on fabric or plastic surfaces means that complex shapes and structures can be designed to maximize solar collection. In addition, the technology will enable the production of large area panels to be manufactured in a cost and resource efficient manner, promising to bring the cost of solar power on par with that of conventional energy.
FabriGen focused on developing the technology for applications such as, large scale tensile membrane structures for example, ‘The Millennium Dome and Stadia covers, and smaller scale permanent installations such as Solar Car Park covers, marquees, walkways and textile facades for buildings. A key aspect of the research was the development and integration of barrier encapsulation layers to provide the long-life performance that is needed for outdoor use.
“The FabriGen consortium has been able to successfully produce a large area working prototype, a significant achievement in the development of low cost, flexible organic photovoltaics,” Dr. David Bird, senior scientist at CPI, said. “The use of an ITO-free front contact facilitated the fabrication of the flexible device. The next steps are focused on upscaling the OPV fabric to a price point that enables volume production so that we can start to see the emergence of novel applications in the built environment.“
“Delivering the demonstrator from concept to prototype, was a real joint effort from all of the consortium,” Robert Carpenter, CEO of Inside2Outside (I20), who coordinated the project, added. “From vacuum processing the metal electrode at CPI, followed by coating the organic semiconductor at Fraunhofer ISE, through to printing the silver contacts and the lamination at Coatema, and lastly the high frequency welding of the solar foil on the fabric membrane at I2O, a range expertise was involved. The solar cell structure and the module design were developed at Fraunhofer ISE.
“The Freiburg researchers were also involved in the encapsulation development under the leadership of CPI,” Carpenter noted. “Coatema Coating Machinery GmbH was responsible for the process development of the large area lamination. The robust, weatherproof electrical design was provided by ELON Technologies, whilst The University of Chemical Technology and Metallurgy achieved the UV stabilization and down-conversion. DZP Technologies supported the development throughout with the delivery of testing devices and assessment of novel materials.“
The aim of FabriGen was to work towards Europe’s ambitious targets for renewable energy generation by bringing new innovative solar energy products to market. The development of organic photovoltaics (OPV) with flexible form factors opens up a host of opportunities for designers to embed energy harvesting and functionality into their products, creating the opportunity for new, innovative solar panels that are thinner, lightweight large area and potential lower cost.
The flexible nature of OPV provides a number of advantages to the solar power industry. The ability to produce the panels on fabric or plastic surfaces means that complex shapes and structures can be designed to maximize solar collection. In addition, the technology will enable the production of large area panels to be manufactured in a cost and resource efficient manner, promising to bring the cost of solar power on par with that of conventional energy.
FabriGen focused on developing the technology for applications such as, large scale tensile membrane structures for example, ‘The Millennium Dome and Stadia covers, and smaller scale permanent installations such as Solar Car Park covers, marquees, walkways and textile facades for buildings. A key aspect of the research was the development and integration of barrier encapsulation layers to provide the long-life performance that is needed for outdoor use.
“The FabriGen consortium has been able to successfully produce a large area working prototype, a significant achievement in the development of low cost, flexible organic photovoltaics,” Dr. David Bird, senior scientist at CPI, said. “The use of an ITO-free front contact facilitated the fabrication of the flexible device. The next steps are focused on upscaling the OPV fabric to a price point that enables volume production so that we can start to see the emergence of novel applications in the built environment.“
“Delivering the demonstrator from concept to prototype, was a real joint effort from all of the consortium,” Robert Carpenter, CEO of Inside2Outside (I20), who coordinated the project, added. “From vacuum processing the metal electrode at CPI, followed by coating the organic semiconductor at Fraunhofer ISE, through to printing the silver contacts and the lamination at Coatema, and lastly the high frequency welding of the solar foil on the fabric membrane at I2O, a range expertise was involved. The solar cell structure and the module design were developed at Fraunhofer ISE.
“The Freiburg researchers were also involved in the encapsulation development under the leadership of CPI,” Carpenter noted. “Coatema Coating Machinery GmbH was responsible for the process development of the large area lamination. The robust, weatherproof electrical design was provided by ELON Technologies, whilst The University of Chemical Technology and Metallurgy achieved the UV stabilization and down-conversion. DZP Technologies supported the development throughout with the delivery of testing devices and assessment of novel materials.“