Allen F. Zielnik scite author profile

Reduced optical transmittance of encapsulants resulting from ultraviolet (UV) degradation is frequently identified as a cause of decreased performance through the service life of photovoltaic modules. However, the present module safety and qualification standards apply short UV doses, only capable of examining design robustness and “infant mortality” failures. Furthermore, essential information remains unknown that might be used to screen encapsulants through product lifetime. We conducted an interlaboratory study to provide the understanding that will be used toward developing a higher‐fidelity, more‐rigorous UV weathering test. Five representative known formulations of poly (ethylene‐co‐vinyl acetate) were studied, in addition to one thermoplastic polyurethane material. Replicate laminated silica/polymer/silica specimens were examined at seven institutions using a variety of indoor chambers (including xenon, UVA‐340, and metal‐halide light sources). Specimens were artificially weathered for 180 cumulative days at steady‐state accelerated test conditions, predesignated relative to the default irradiance of 1.0 W·m−2·nm−1 at 340 nm, chamber temperature of 60°C, and chamber relative humidity of 30%. The solar‐weighted transmittance, yellowness index, and the UV cut‐off wavelength—each determined from the measured hemispherical transmittance—are examined to provide understanding and guidance for the UV light source (type lamp and filters), temperature, and humidity used in accelerated UV aging tests. The relative efficacy of xenon‐arc and UVA‐340 fluorescent sources and the typical range of activation energy for degradation is quantified from the experiments.

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An Arrhenius approach to estimating organic photovoltaic module weathering acceleration factors

Haillant¹,

Dumbleton²,

Zielnik³

2011

Solar Energy Materials and Solar Cells

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Survey of Mechanical Durability of PV Backsheets

Kempe

Miller

Zielnik

et al. 2017

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Degradation in photovoltaic encapsulation strength of attachment: Results of the first PVQAT TG5 artificial weathering study

Miller

Alharbi

Andreas

et al. 2020

Progress in Photovoltaics

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Delamination of the encapsulant in photovoltaic (PV) module technology results in immediate optical loss and may enable subsequent corrosion or mechanical damage. The effects of artificial weathering were not previously known; therefore, an empirical study was performed to survey the factors most affecting adhesion, including: the UV source (i.e., Xe or fluorescent lamp(s)); the optical filters for the lamp; the chamber temperature; and the relative humidity. Natural weathering was also performed at locations, including: Golden,

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Allen F. Zielnik

Degradation in photovoltaic encapsulant transmittance: Results of the first PVQAT TG5 artificial weathering study

An Arrhenius approach to estimating organic photovoltaic module weathering acceleration factors

Survey of Mechanical Durability of PV Backsheets

Degradation in photovoltaic encapsulation strength of attachment: Results of the first PVQAT TG5 artificial weathering study

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