Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint

David Miller; Michael Kempe; Peter Hacke; Eleonora Annigoni; Amal Ballion; Jayesh Bokria; Laura Bruckman; David Burns; Lamont Elliott; Roger French; Sean Fowler; Christian Honeker; Hussameldin Khonkar; Michael Köhl; Peter Krommenhoek; Xiaohong Gu; Laure-Emmanuelle Perret-Aebi; Nancy Phillips; Kurt Scott; Fanny Sculati-Meillaud; Tsuyoshi Shioda; Shigeo Suga; Shin Watanabe; Xinxin Chen; Jiangtao Feng

Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint

David Miller, Michael Kempe, Peter Hacke, Eleonora Annigoni, Amal Ballion, Jayesh Bokria, Laura Bruckman, David Burns, Lamont Elliott, Roger French, Sean Fowler, Christian Honeker, Hussameldin Khonkar, Michael Köhl, Peter Krommenhoek, Xiaohong Gu, Laure-Emmanuelle Perret-Aebi, Nancy Phillips, Kurt Scott, Fanny Sculati-MeillaudTsuyoshi Shioda, Shigeo Suga, Shin Watanabe, Xinxin Chen, Jiangtao Feng

Materials Science

Research output: Contribution to conference › Paper

Abstract

Reduced optical transmittance of encapsulants resulting from ultraviolet (UV) degradation has frequently been identified as a cause of decreased PV module performance through the life of service in the field. The present module safety and qualification standards, however, apply short UV doses only capable of examining design robustness or 'infant mortality' failures. Essential information that might be used to screen encapsulation through product lifetime remains unknown. For example, the relative efficacy of xenon-arc and UVA-340 fluorescent sources or the typical range of activation energy for degradation is not quantified. We have conducted an interlaboratory experiment to provide the understanding that will be used towards developing a climate- and configuration-specific (UV) weathering test. Five representative, known formulations of EVA were studied in addition to one TPU material. Replicate laminated silica/polymer/silica specimens are being examined at 14 institutions using a variety of indoor chambers (including Xenon, UVA-340, and metal-halide light sources) or field aging. The solar-weighted transmittance, yellowness index, and the UV cut-off wavelength, determined from the measured hemispherical transmittance, are examined to provide understanding and guidance for the UV light source (lamp type) and temperature used in accelerated UV aging tests.

Original language	American English
Number of pages	8
State	Published - 2015
Event	42nd IEEE Photovoltaic Specialists Conference - New Orleans, Louisiana Duration: 14 Jun 2015 → 19 Jun 2015

Conference

Conference	42nd IEEE Photovoltaic Specialists Conference
City	New Orleans, Louisiana
Period	14/06/15 → 19/06/15

NREL Publication Number

NREL/CP-5J00-63508

Keywords

durability
reliability
thermal activation

Access to Document

https://www.nrel.gov/docs/fy15osti/63508.pdf

Cite this

Miller, D., Kempe, M., Hacke, P., Annigoni, E., Ballion, A., Bokria, J., Bruckman, L., Burns, D., Elliott, L., French, R., Fowler, S., Honeker, C., Khonkar, H., Köhl, M., Krommenhoek, P., Gu, X., Perret-Aebi, L.-E., Phillips, N., Scott, K., ... Feng, J. (2015). Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint. Paper presented at 42nd IEEE Photovoltaic Specialists Conference, New Orleans, Louisiana. https://www.nrel.gov/docs/fy15osti/63508.pdf

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title = "Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint",

abstract = "Reduced optical transmittance of encapsulants resulting from ultraviolet (UV) degradation has frequently been identified as a cause of decreased PV module performance through the life of service in the field. The present module safety and qualification standards, however, apply short UV doses only capable of examining design robustness or 'infant mortality' failures. Essential information that might be used to screen encapsulation through product lifetime remains unknown. For example, the relative efficacy of xenon-arc and UVA-340 fluorescent sources or the typical range of activation energy for degradation is not quantified. We have conducted an interlaboratory experiment to provide the understanding that will be used towards developing a climate- and configuration-specific (UV) weathering test. Five representative, known formulations of EVA were studied in addition to one TPU material. Replicate laminated silica/polymer/silica specimens are being examined at 14 institutions using a variety of indoor chambers (including Xenon, UVA-340, and metal-halide light sources) or field aging. The solar-weighted transmittance, yellowness index, and the UV cut-off wavelength, determined from the measured hemispherical transmittance, are examined to provide understanding and guidance for the UV light source (lamp type) and temperature used in accelerated UV aging tests.",

keywords = "durability, reliability, thermal activation",

author = "David Miller and Michael Kempe and Peter Hacke and Eleonora Annigoni and Amal Ballion and Jayesh Bokria and Laura Bruckman and David Burns and Lamont Elliott and Roger French and Sean Fowler and Christian Honeker and Hussameldin Khonkar and Michael K{\"o}hl and Peter Krommenhoek and Xiaohong Gu and Laure-Emmanuelle Perret-Aebi and Nancy Phillips and Kurt Scott and Fanny Sculati-Meillaud and Tsuyoshi Shioda and Shigeo Suga and Shin Watanabe and Xinxin Chen and Jiangtao Feng",

year = "2015",

language = "American English",

note = "42nd IEEE Photovoltaic Specialists Conference ; Conference date: 14-06-2015 Through 19-06-2015",

}

Miller, D , Kempe, M , Hacke, P, Annigoni, E, Ballion, A, Bokria, J, Bruckman, L, Burns, D, Elliott, L, French, R, Fowler, S, Honeker, C, Khonkar, H, Köhl, M, Krommenhoek, P, Gu, X, Perret-Aebi, L-E, Phillips, N, Scott, K, Sculati-Meillaud, F, Shioda, T, Suga, S, Watanabe, S, Chen, X & Feng, J 2015, 'Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint', Paper presented at 42nd IEEE Photovoltaic Specialists Conference, New Orleans, Louisiana, 14/06/15 - 19/06/15. <https://www.nrel.gov/docs/fy15osti/63508.pdf>

TY - CONF

T1 - Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint

AU - Miller, David

AU - Kempe, Michael

AU - Hacke, Peter

AU - Annigoni, Eleonora

AU - Ballion, Amal

AU - Bokria, Jayesh

AU - Bruckman, Laura

AU - Burns, David

AU - Elliott, Lamont

AU - French, Roger

AU - Fowler, Sean

AU - Honeker, Christian

AU - Khonkar, Hussameldin

AU - Köhl, Michael

AU - Krommenhoek, Peter

AU - Gu, Xiaohong

AU - Perret-Aebi, Laure-Emmanuelle

AU - Phillips, Nancy

AU - Scott, Kurt

AU - Sculati-Meillaud, Fanny

AU - Shioda, Tsuyoshi

AU - Suga, Shigeo

AU - Watanabe, Shin

AU - Chen, Xinxin

AU - Feng, Jiangtao

PY - 2015

Y1 - 2015

N2 - Reduced optical transmittance of encapsulants resulting from ultraviolet (UV) degradation has frequently been identified as a cause of decreased PV module performance through the life of service in the field. The present module safety and qualification standards, however, apply short UV doses only capable of examining design robustness or 'infant mortality' failures. Essential information that might be used to screen encapsulation through product lifetime remains unknown. For example, the relative efficacy of xenon-arc and UVA-340 fluorescent sources or the typical range of activation energy for degradation is not quantified. We have conducted an interlaboratory experiment to provide the understanding that will be used towards developing a climate- and configuration-specific (UV) weathering test. Five representative, known formulations of EVA were studied in addition to one TPU material. Replicate laminated silica/polymer/silica specimens are being examined at 14 institutions using a variety of indoor chambers (including Xenon, UVA-340, and metal-halide light sources) or field aging. The solar-weighted transmittance, yellowness index, and the UV cut-off wavelength, determined from the measured hemispherical transmittance, are examined to provide understanding and guidance for the UV light source (lamp type) and temperature used in accelerated UV aging tests.

AB - Reduced optical transmittance of encapsulants resulting from ultraviolet (UV) degradation has frequently been identified as a cause of decreased PV module performance through the life of service in the field. The present module safety and qualification standards, however, apply short UV doses only capable of examining design robustness or 'infant mortality' failures. Essential information that might be used to screen encapsulation through product lifetime remains unknown. For example, the relative efficacy of xenon-arc and UVA-340 fluorescent sources or the typical range of activation energy for degradation is not quantified. We have conducted an interlaboratory experiment to provide the understanding that will be used towards developing a climate- and configuration-specific (UV) weathering test. Five representative, known formulations of EVA were studied in addition to one TPU material. Replicate laminated silica/polymer/silica specimens are being examined at 14 institutions using a variety of indoor chambers (including Xenon, UVA-340, and metal-halide light sources) or field aging. The solar-weighted transmittance, yellowness index, and the UV cut-off wavelength, determined from the measured hemispherical transmittance, are examined to provide understanding and guidance for the UV light source (lamp type) and temperature used in accelerated UV aging tests.

KW - durability

KW - reliability

KW - thermal activation

M3 - Paper

T2 - 42nd IEEE Photovoltaic Specialists Conference

Y2 - 14 June 2015 through 19 June 2015

ER -

Degradation in PV Encapsulation Transmittance: An Interlaboratory Study Towards a Climate-Specific Test: Preprint

Abstract

Conference

NREL Publication Number

Keywords

Access to Document

Fingerprint

Cite this