Experimental Evaluation of Encapsulated Solar cells for Unmanned Aerial Vehicle Application

2019 IEEE International Conference on Aerospace Electronics and Remote Sensing Technology (ICARES) Pub Date : 2019-10-01 DOI:10.1109/ICARES.2019.8914549

Z. Sahwee, S. A. Hamid, N. Kamal, N. Norhashim

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引用次数: 3

Abstract

One of the recent area where renewable energy is used is in Unmanned Aerial Vehicle. It does offer many benefits but at the same time, create technical challenges both in the design and the manufacturing process. The photovoltaic (PV) cell in its raw form is very fragile and easily being damaged. Once cracked, the electrical output reduces, while a severe crack will cause the solar cell to be unusable. In this research, an encapsulation process to increase the durability and reliability were explored by performing a series of tests. Thus the objective of this study is to explore solar encapsulation process while aiming to maintain its conversion efficiency. Conversion efficiency and weight penalty of each technique were recorded and were measured under sun irradiance. The results show that epoxy resin encapsulation together with advance composite fabrication technique provide the best results in terms of reliability and conversion efficiency. This method helps to protect the PV cell against moisture and damage, thus prolong the life-span of the solar cells.

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无人机用封装太阳能电池的实验评价

最近使用可再生能源的一个领域是无人驾驶飞行器。它确实提供了许多好处，但与此同时，在设计和制造过程中都带来了技术挑战。光伏(PV)电池的原始形态非常脆弱，容易损坏。一旦破裂，电力输出减少，而严重的裂缝将导致太阳能电池无法使用。在本研究中，通过进行一系列试验，探索了一种提高耐久性和可靠性的封装工艺。因此，本研究的目的是探索太阳能封装工艺，同时保持其转换效率。记录每种技术的转换效率和重量损失，并在太阳辐照下进行测量。结果表明，环氧树脂封装与先进的复合材料制造技术在可靠性和转换效率方面取得了最好的效果。这种方法有助于保护光伏电池不受潮和损坏，从而延长太阳能电池的寿命。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2019 IEEE International Conference on Aerospace Electronics and Remote Sensing Technology (ICARES)

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