Your search keyword '"Qualification standards"' showing total 3 results

1. Field Evaluation of the Potential for Creep in Thermoplastic Encapsulant Materials: Preprint

Author

Vanderpan, Crystal

Published

2012

2. Multi angle laser light scattering evaluation of field exposed thermoplastic photovoltaic encapsulant materials.

Author

Kempe, Michael D., Miller, David C., Wohlgemuth, John H., Kurtz, Sarah R., Moseley, John M., Nobles, Dylan L., Stika, Katherine M., Brun, Yefim, Samuels, Sam L., Shah, Qurat (Annie), Tamizhmani, Govindasamy, Sakurai, Keiichiro, Inoue, Masanao, Doi, Takuya, Masuda, Atsushi, and Vanderpan, Crystal E.

Subjects

*LIGHT scattering, *THERMOPLASTICS, *PHOTOVOLTAIC power systems, *POLYMERS, *CREEP (Materials)

Abstract

As creep of polymeric materials is potentially a safety concern for photovoltaic modules, the potential for module creep has become a significant topic of discussion in the development of IEC 61730 and IEC 61215. To investigate the possibility of creep, modules were constructed, using several thermoplastic encapsulant materials, into thin-film mock modules and deployed in Mesa, Arizona. The materials examined included poly(ethylene)-co-vinyl acetate (EVA, including formulations both cross-linked and with no curing agent), polyethylene/polyoctene copolymer (PO), poly(dimethylsiloxane) (PDMS), polyvinyl butyral (PVB), and thermoplastic polyurethane (TPU). The absence of creep in this experiment is attributable to several factors of which the most notable one was the unexpected cross-linking of an EVA formulation without a cross-linking agent. It was also found that some materials experienced both chain scission and cross-linking reactions, sometimes with a significant dependence on location within a module. The TPU and EVA samples were found to degrade with cross-linking reactions dominating over chain scission. In contrast, the PO materials degraded with chain scission dominating over cross-linking reactions. Although we found no significant indications that viscous creep is likely to occur in fielded modules capable of passing the qualification tests, we note that one should consider how a polymer degrades, chain scission or cross-linking, in assessing the suitability of a thermoplastic polymer in terrestrial photovoltaic applications. [ABSTRACT FROM AUTHOR]

Published

2016

3. Field testing of thermoplastic encapsulants in high-temperature installations.

Author

Kempe, Michael D., Miller, David C., Wohlgemuth, John H., Kurtz, Sarah R., Moseley, John M., Shah, Qurat A., Tamizhmani, Govindasamy, Sakurai, Keiichiro, Inoue, Masanao, Doi, Takuya, Masuda, Atsushi, Samuels, Sam L., and Vanderpan, Crystal E.

Subjects

*THERMOPLASTICS, *HIGH temperatures, *ENCAPSULATION (Catalysis), *PHOTOVOLTAIC power generation, *SILICON, *CRYSTALS, *THIN films, *THERMAL insulation

Abstract

Recently there has been increased interest in using thermoplastic encapsulant materials in photovoltaic modules, but concerns have been raised about whether these would be mechanically stable at high temperatures in the field. Recently, this has become a significant topic of discussion in the development of IEC 61730 and IEC 61215. We constructed eight pairs of crystalline-silicon modules and eight pairs of glass/encapsulation/glass thin-film mock modules using different encapsulant materials, of which only two were formulated to chemically crosslink. One module set was exposed outdoors with thermal insulation on the back side in Mesa, Arizona, in the summer (hot-dry), and an identical module set was exposed in environmental chambers. High-precision creep measurements (±20 µm) and electrical performance measurements indicate that despite many of these polymeric materials operating in the melt or rubbery state during outdoor deployment, no significant creep was seen because of their high viscosity, lower operating temperature at the edges, and/or the formation of chemical crosslinks in many of the encapsulants with age despite the absence of a crosslink-ing agent. Only an ethylene-vinyl acetate (EVA) encapsulant formulated without a peroxide crosslinking agent crept significantly. In the case of the crystalline-silicon modules, the physical restraint of the backsheet reduced creep further and was not detectable even for the EVA without peroxide. Because of the propensity of some polymeric materials to crosslink as they age, typical thermoplastic encapsulants would be unlikely to result in creep in the vast majority of installations. [ABSTRACT FROM AUTHOR]

Published

2015