具有细线和任意结构的丝网印刷电极的预测

IF 3.6 4区工程技术 Q3 ENERGY & FUELS

Energy technology Pub Date : 2024-10-04 DOI:10.1002/ente.202401346

Marius Singler, Linda Ney, Simon Auerbach, Jonas Krause, Tom Hoger, Niloufar Rhabari, Andreas Lorenz, Sebastian Tepner, Florian Clement

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引用次数: 0

摘要

目前，光伏制造行业面临着即将到来的材料短缺，主要是由于TOPCon， SHJ和PERC太阳能电池的前端金属化持续依赖银。本研究采用Ney等人在2019年最初引入的数学模型，基于网格特性预测印刷接触结构的结果。为了验证，在印刷速度、丝网角度和压光强度的变化下进行了印刷实验。通常可以观察到，对于筛网的20°网角的预测比其他角度的预测更不准确。此外，还注意到随着通道宽度的增加，预测变得更加准确。虽然，在某些情况下，预测精度达到了77%到87%，但重要的是要承认，从模拟中获得的结果在一定程度上偏离了现实世界的观测结果。此外，观察到网孔厚度和印刷体积之间存在明显的相关性，从而可以预测银的使用和潜在的材料节省。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Prediction of Screen-Printed Electrodes with Fine-Line and Arbitrary Structures

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Prediction of Screen-Printed Electrodes with Fine-Line and Arbitrary Structures

Currently, the photovoltaic manufacturing industry is confronted with an upcoming material shortage, primarily driven by the continued dependence on silver for front-side metallization in TOPCon, SHJ, and PERC solar cells. This study employs a mathematical model originally introduced by Ney et al. in 2019 to predict the outcome of printed contact structures based on mesh characteristics. For validation, printing experiments are conducted with variations in printing speed, screen angle, and calendaring strength. It is generally observed that predictions for screens with a 20° mesh angle are less accurate than for other angles. In addition, it is noted that the prediction became more accurate with increasing channel width. Although, for some cases, a prediction accuracy between 77 and 87% is achieved, it is important to acknowledge that the results obtained from the simulation deviate from the real-world observations to some extent. Additionally, a clear correlation between mesh thickness and printed volume is observed, enabling the prediction of silver usage and potential material savings.

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来源期刊

Energy technology ENERGY & FUELS-

CiteScore

7.00

自引率

5.30%

发文量

审稿时长

1.3 months

期刊介绍： Energy Technology provides a forum for researchers and engineers from all relevant disciplines concerned with the generation, conversion, storage, and distribution of energy. This new journal shall publish articles covering all technical aspects of energy process engineering from different perspectives, e.g., new concepts of energy generation and conversion; design, operation, control, and optimization of processes for energy generation (e.g., carbon capture) and conversion of energy carriers; improvement of existing processes; combination of single components to systems for energy generation; design of systems for energy storage; production processes of fuels, e.g., hydrogen, electricity, petroleum, biobased fuels; concepts and design of devices for energy distribution.