Evaluating environmental impacts of photovoltaic technologies using Data Envelopment Analysis

Q3 Engineering

Advances in Systems Science and Applications Pub Date : 2019-04-15 DOI:10.25728/ASSA.2019.19.1.651

S. Ratner, A. Lychev

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引用次数: 8

Abstract

This study contributes to the literature by proposing a new method of complex evaluation of multiple life cycle environmental impacts of different PV technologies based on the Data Envelopment Analysis (DEA). The main advantage of DEA as a non-parametric technique is that it does not require prior knowledge of underlying production functions. An empirical production technology frontier is estimated based on best-practice boundary of the input-output relationship. DEA evaluates comparative or relative efficiency, which means the measurement with reference to some set of units we are comparing with each other. The proposed approach allows to aggregate disparate quantitative estimates of individual negative environmental effects from the literature and special databases in a transparent and easily understandable index or coefficient of ecology efficiency. The evaluation of environmental effects is performed on data from the EcoInvent Database. The results of this study clearly show that from an environmental point of view it is more practical to prefer technologies, which are less resource and energy intensive in manufacturing and upstream activities. As of right now, this requirement is met by thin-film technologies (amorphous silicon, cadmium telluride, and copper-indium-diselenide); however, their ecologic efficiency evaluation may change as we obtain more data on the final stages of the lifecycle for PV modules of various types. Based on results of this study a number of opportunities for improving existing government incentives and rationalizing the design of state programs under elaboration can be identified.

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利用数据包络分析评估光伏技术的环境影响

本研究提出了一种基于数据包络分析（DEA）对不同光伏技术的多个生命周期环境影响进行复杂评估的新方法，为文献做出了贡献。DEA作为一种非参数技术的主要优点是，它不需要对底层生产函数的先验知识。基于投入产出关系的最佳实践边界来估计经验生产技术前沿。DEA评估比较效率或相对效率，这意味着参照我们相互比较的某组单位进行测量。所提出的方法允许将文献和特殊数据库中对个体负面环境影响的不同定量估计汇总到一个透明且易于理解的生态效率指数或系数中。环境影响评估是根据EcoInvent数据库中的数据进行的。这项研究的结果清楚地表明，从环境的角度来看，更实际的做法是选择制造业和上游活动中资源和能源密集度较低的技术。截至目前，薄膜技术（非晶硅、碲化镉和二硒化铜铟）满足了这一要求；然而，随着我们获得更多关于各种类型光伏组件生命周期最后阶段的数据，它们的生态效率评估可能会发生变化。根据这项研究的结果，可以确定一些改善现有政府激励措施和使正在制定的国家计划设计合理化的机会。

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

Advances in Systems Science and Applications Engineering-Engineering (all)

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： Advances in Systems Science and Applications (ASSA) is an international peer-reviewed open-source online academic journal. Its scope covers all major aspects of systems (and processes) analysis, modeling, simulation, and control, ranging from theoretical and methodological developments to a large variety of application areas. Survey articles and innovative results are also welcome. ASSA is aimed at the audience of scientists, engineers and researchers working in the framework of these problems. ASSA should be a platform on which researchers will be able to communicate and discuss both their specialized issues and interdisciplinary problems of systems analysis and its applications in science and industry, including data science, artificial intelligence, material science, manufacturing, transportation, power and energy, ecology, corporate management, public governance, finance, and many others.