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马来西亚 NEM 光伏组件评估和旱季能源产量预测模型。

Photovoltaic modules evaluation and dry-season energy yield prediction model for NEM in Malaysia.

机构信息

Faculty of Electrical & Electronic Engineering, Universiti Tun Hussein Onn Malaysia(UTHM), Parit Raja, Johor, Malaysia.

Department of Electrical and Electronics Engineering, Advanced Lightning, Power and Energy Research (ALPER), Faculty of Engineering, Universiti Putra Malaysia, Serdang, Selangor, Malaysia.

出版信息

PLoS One. 2020 Nov 12;15(11):e0241927. doi: 10.1371/journal.pone.0241927. eCollection 2020.

DOI:10.1371/journal.pone.0241927
PMID:33180779
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7660538/
Abstract

This study analyzes the performance of two PV modules, amorphous silicon (a-Si) and crystalline silicon (c-Si) and predicts energy yield, which can be seen as facilitation to achieve the target of 35% reduction of greenhouse gases emission by 2030. Malaysia Energy Commission recommends crystalline PV modules for net energy metering (NEM), but the climate regime is a concern for output power and efficiency. Based on rainfall and irradiance data, this study aims to categorize the climate of peninsular Malaysia into rainy and dry seasons; and then the performance of the two modules are evaluated under the dry season. A new mathematical model is developed to predict energy yield and the results are validated through experimental and systematic error analysis. The parameters are collected using a self-developed ZigBeePRO-based wireless system with the rate of 3 samples/min over a period of five days. The results unveil that efficiency is inversely proportional to the irradiance due to negative temperature coefficient for crystalline modules. For this phenomenon, efficiency of c-Si (9.8%) is found always higher than a-Si (3.5%). However, a-Si shows better shadow tolerance compared to c-Si, observed from a lesser decrease rate in efficiency of the former with the increase in irradiance. Due to better spectrum response and temperature coefficient, a-Si shows greater performance on output power efficiency (OPE), performance ratio (PR), and yield factor. From the regression analysis, it is found that the coefficient of determination (R2) is between 0.7179 and 0.9611. The energy from the proposed model indicates that a-Si yields 15.07% higher kWh than c-Si when luminance for recorded days is 70% medium and 30% high. This study is important to determine the highest percentage of energy yield and to get faster NEM payback period, where as of now, there is no such model to indicate seasonal energy yield in Malaysia.

摘要

本研究分析了两种光伏模块,非晶硅(a-Si)和晶体硅(c-Si)的性能,并预测了能源产量,这可以视为实现 2030 年温室气体减排 35%目标的一种促进手段。马来西亚能源委员会建议使用晶体光伏模块进行净计量(NEM),但气候制度对输出功率和效率存在担忧。本研究基于降雨和辐照数据,旨在将马来西亚半岛的气候分为雨季和旱季;然后在旱季评估这两种模块的性能。开发了一种新的数学模型来预测能源产量,并通过实验和系统误差分析对结果进行验证。使用自行开发的基于 ZigBeePRO 的无线系统收集参数,在五天的时间内以 3 个样本/分钟的速率进行采集。结果表明,由于晶体模块的负温度系数,效率与辐照度成反比。对于这种现象,c-Si(9.8%)的效率始终高于 a-Si(3.5%)。然而,与 c-Si 相比,a-Si 具有更好的阴影容忍度,从前者的效率随着辐照度的增加而降低的速率较小可以看出。由于具有更好的光谱响应和温度系数,a-Si 在输出功率效率(OPE)、性能比(PR)和产量因子方面表现出更好的性能。从回归分析中可以发现,决定系数(R2)在 0.7179 到 0.9611 之间。从所提出的模型中获得的能量表明,当记录天数的亮度为 70%中等和 30%高时,a-Si 的千瓦时产量比 c-Si 高 15.07%。本研究对于确定最高的能源产量百分比并获得更快的 NEM 投资回报期非常重要,因为目前还没有这样的模型可以指示马来西亚的季节性能源产量。

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