KYOCERA Solar Modules Confirmed as PID Resistant by Fraunhofer CSP Testing

Outstanding quality and reliability make Kyocera one of only four manufacturers to pass Fraunhofer's high-voltage stress test with zero degradation

KYOTO, July 10, 2012 Kyocera Corporation (NYSE:KYO)(TOKYO:6971) announced that its solar modules have again passed independent quality testing with flying colors after the non-profit Fraunhofer Center for Silicon Photovoltaics CSP (Halle, Germany) disclosed the results of its potential induced degradation (PID) test which demonstrated that Kyocera's modules did not show any degradation after being subjected to high voltage stress testing. The results of this third-party test illustrate the high quality and high reliability of Kyocera's modules which are born of the company's more than 35 years of experience in the industry and its quality-focused manufacturing process.

Potential induced degradation (PID) is a phenomenon where the power output of a solar module is reduced when exposed to high negative voltage bias between the cells and ground. PID can potentially affect the performance of individual modules as well as the overall power output and efficiency of an entire solar power generating system. The resistance to, or intensity of, power output degradation in different companies' modules can vary greatly, as shown by Fraunhofer CSP's testing.

Earlier this year, Fraunhofer CSP anonymously acquired and independently tested modules from 13 well-known manufacturers; subjecting the modules to a high voltage stress test (50 deg. C, 50% relative humidity, -1000V, aluminum film at the front side, 48 hours). Kyocera was one of only four manufacturers whose modules passed the test without showing any degradation, while other companies' modules showed partial to significant degradation. These results highlight a stark divide between different companies' modules while distinguishing Kyocera among a select number to be proven as PID resistant.

"As a pioneer in the industry Kyocera has been involved in R&D and manufacturing of solar power generating systems for more than 35 years, and in that time we have developed numerous innovations and manufacturing technologies to ensure the high quality and long-term durability of our products," said Tatsumi Maeda, general manager of the Kyocera Corporate Solar Energy Group. "With Kyocera's solar modules having been the first in the world to be certified by TUV Rheinland's Long-Term Sequential Test, the Fraunhofer CSP test results further demonstrate the industry-leading technology and reliable performance of Kyocera modules."

Kyocera has decades of experience in every phase of the solar module manufacturing process, from raw materials (silicon casting), to cell production (wafer slicing), to the finished product (module assembly). The company draws upon this experience in all phases of its R&D, procurement and manufacturing activities to deliver solar modules of outstanding quality and reliability.

For more information about Kyocera Solar Reliability:


Kyocera Corporation (NYSE:KYO)(TOKYO:6971) (, the parent and global headquarters of the Kyocera Group, was founded in 1959 as a producer of fine ceramics (also known as "advanced ceramics"). By combining these engineered materials with metals and plastics, and integrating them with other technologies, Kyocera has become a leading supplier of solar power generating systems, telecommunications equipment, printers, copiers, electronic components, semiconductor packages, cutting tools and industrial ceramics. During the year ended March 31, 2012, the company's net sales totaled 1.19 trillion yen (approx. USD14.5 billion). The company is ranked #426 on Forbes magazine's 2012 "Global 2000" listing of the world's largest publicly traded companies.

Featured Product

Flex-Core - Flexible Split-Core Current Transformer

Flex-Core - Flexible Split-Core Current Transformer

The FCL model split-core current transformers have multiple benefits, including a flexible twisting motion for ease of application. Installing a split-core CT means there is no need to disconnect your primary conductor(s) which reduces downtime. Many customizations are available including extended secondary lead wire lengths, various outputs including 5A, 1A, 1VAC, and 0.333VAC, and custom rubber inserts to help center the CT and maintain accuracy. The FCL models can be used in applications up to 720VAC and have an operating frequency from 50Hz to 400Hz.