Presently, there is a strong competition to European manufacturers from China's solar panel industry that exports panels at really low prices. To fend down competition, there features been a change to non-silicon-based and thin-film PV technologies. Nevertheless, these technologies have only marginal benefits and set up requirements are similar to traditional solar panels. In addition, modules are mostly rigid panels and cannot be integrated into big structures without modifying the architecture design. The task decreased module and installation expenses by combining versatile OPV materials with tensile materials utilizing roll-to-roll manufacturing techniques. The ability to create the panels on fabric surfaces means that complex shapes can be created to increase solar collection. Addressing big areas with versatile polymer structures costs less than glass, with programs spanning from walkway shades, coach stops and carport covers to arcades and stadiums. The organic solar cells also do maybe not include the customary indium-tin-oxide that's scarce, expensive and brittle. Rather, project partners used aluminium that is cheaper and can be scaled up to create aluminium foils. The modules comply with European and intercontinental criteria and laws for implementation in off-grid since well as grid-connected or feed-in-tariff (FIT) power schemes. In the short term, FIT plans provide operators with motivation for investment by having to pay them for power created in their installed systems such as tones. In the long term, researchers envision a final system in which FIT schemes will be unnecessary given the low price of the PV technology contrasted to grid prices. Taken together, the materials and technology promise to bring the expense of solar energy on par with that of traditional power. Reduced production, transport and operating expenses should encourage investment in PV solar power. The technology is truly pioneering as there's nothing comparable available on the market these days.