A comparative study of calorimetric methods to determine the crosslinking degree of the ethylene-Co-vinyl acetate polymer used as a photovoltaic encapsulant

Ogier, Stéphane; Vidal, Chloé; Chapron, D.; Bourson, P.; Royaud, Isabelle; Ponçot, Marc; Vite, Marion; Hidalgo, Manuel

doi:10.1002/polb.24335

Cited by 8 publications

(3 citation statements)

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“…where z 1−α/2 is the 100(1−α/2)th percentile of the standard normal distribution. At a specific lamination temperature s, the sample size allocation (n 11 , n 12 , • • • , n 32 , n 33 ) affects the variance of the estimate of the optimal lamination time given in (11). So, it would be of interest to obtain the optimal sample size allocation in such an experiment.…”

Section: B Estimation and Inferencementioning

confidence: 99%

“…Suppose the pre-fixed specifications for the curing degree are LSL = 65 and USL = 80. When the lamination process is set at temperature s = 147 • C, the estimated optimal lamination time and the corresponding estimated asymptotic variance are obtained as 12.7908 and 0.0815, respectively, upon substitutingθ into (8) and (11). These readily yield a 95% normal-approximate confidence interval (CI) as 12.7908 ± 1.96 √ 0.0815 = [12.2312, 13.3505].…”

Section: B Optimal Lamination Designmentioning

confidence: 99%

“…where ∆H 1 and ∆H 2 are the reaction enthalpy of the uncured EVA reference and cured sample, respectively, can be used as an indicator to determine the degree of crosslinking on EVA. Much literature exists on methods for determining the degree of crosslinking by DSC and its applications (e.g., Bruckman et al [2]; Jaunich et al [7]; Ogier et al [11]); but, previous work has not dealt with optimal lamination time at different temperatures for the curing degree on EVA in a natural way, and this provides the main motivation for the present article. Optimal designs have many diverse applications in experimental designs (Cheng [3]; Jones & Majumdar [8]), in accelerated life and degradation tests (Tsai et al [14]; Hu et al [6]), and in clinical trials (Cheung et al [4]; Atkinson & Biswas [1]; Zang & Lee [17]).…”

Section: Introductionmentioning

confidence: 99%

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Lamination Scheme of Curing Degree at Multiple Levels of Temperature With Location-Scale Regression

Tsai

Lin

2021

IEEE Access

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Solar power has become a key green source of energy. An important factor that affects the reliability and lifetime of solar modules is the quality of encapsulation through the lamination process, which melts the ethylene vinyl acetate (EVA) to make the solar cells combine with the front glass side and the rear side units. The degree of crosslinking or curing degree for EVA sheets, when the EVA sheet gets heated, can affect the efficiency of the performance and power conversion of solar modules. For this reason, motivated by a lamination data, we construct here a statistical model for describing the relationship between the curing degree and the lamination factors (temperature and time). Then, based on some specification limits on the curing degree, the optimal lamination time for solar modules can be determined at different temperatures. Moreover, the optimal sample size allocation in a test for measuring EVA sheets can also be determined. A simulation study is finally carried out to show the closeness of simulation results to the asymptotic results.INDEX TERMS Confidence bands, curing degree, degree of crosslinking, sample size allocation, specification limits.

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Section: B Estimation and Inferencementioning

confidence: 99%

Section: B Optimal Lamination Designmentioning

confidence: 99%