光伏电池板的生命周期评估,包括运输和两种报废方案:塑造可再生能源的可持续未来

IF 4.2 Q2 ENERGY & FUELS Renewable Energy Focus Pub Date : 2024-10-01 DOI:10.1016/j.ref.2024.100649
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引用次数: 0

摘要

本研究探讨了与太阳能光伏(PV)系统相关的日益严重的环境问题,该系统是可再生能源转型的关键组成部分。研究的主要目的是加深对太阳能光伏技术的环境可持续性的理解,并特别关注墨西哥的情况。本研究采用生命周期评估(LCA)框架,采用最新的方法论(ReCiPe 2016)和数据库(Ecoinvent 3.8),对中点和终点指标进行评估。生命周期评估方法弥合了中点和终点指标之间的差距,为环境影响评估带来了透明度。这项研究需要对 1 千瓦晶体硅太阳能电池板的 25 年寿命进行 "从摇篮到坟墓 "的生命周期评估,同时适应 ISO 14044 生命周期评估标准,包括中点和终点指标,特别是包括寿命终结和运输情景。此外,考虑到生命周期数据,还进行了敏感性分析,以评估环境指标的变化。据报告,回收工艺可在多个类别上对环境影响产生实质性的缓解作用,使矿物资源稀缺程度降低高达 89%。值得注意的是,电池加工阶段是对环境影响最大的阶段,占总影响的 37%。这种高影响主要归因于银的使用和电力消耗的增加。敏感性分析表明,各种性能指标对设计变量的不确定性表现出不同程度的敏感性,这凸显了在硅太阳能电池板的生命周期中减少环境影响时仔细考虑的重要性,特别是在解决对生态系统的影响方面。我们的研究结果还表明,运输对资源保护的影响很大,占这一类别总影响的 15%,对生态系统和人类健康的影响较小,但也很显著。这项工作的影响表明,有必要制定严格的政策,在墨西哥制造完整的太阳能光伏组件,以减少运输造成的环境负担。此外,本研究的见解还为墨西哥政府改革当前的能源转型政策提供了一个途径,即纳入太阳能光伏系统的多种回收方案,最终实现该市场的可持续增长。
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Life cycle assessment of photovoltaic panels including transportation and two end-of-life scenarios: Shaping a sustainable future for renewable energy
This research study addresses the growing environmental concerns associated with solar photovoltaic (PV) systems which is a pivotal component of renewable energy transition. The primary objective is to advance the comprehension of the environmental sustainability of solar PV technology, with a specific focus on the context of Mexico. This study applies a life cycle assessment (LCA) framework, employing an up-to-date methodology (ReCiPe 2016) and database (Ecoinvent 3.8) for midpoint and endpoint indicators in this problem by considering a specific focus on end-of-life and transportation scenarios which have been absent in the current state-of-the-art research. An LCA approach bridges the gap between midpoint and end-point indicators, bringing transparency to the environmental impact assessment. This research entails a cradle-to-grave LCA of a 1 kW crystalline silicon solar panel over a 25-year lifespan while adapting to ISO 14044 standards for LCA and encompassing both midpoint and end-point indicators, specifically including end-of-life and transportation scenario. Furthermore, a sensitivity analysis is conducted to evaluate the variations in environmental indicators considering the life-cycle data. It is reported that recycling processes can cause a substantial mitigating effect on environmental impacts across multiple categories, leading to reductions of up to 89 % in mineral resource scarcity. Notably, the cell processing phase emerges as the most environmentally impactful stage, accounting for 37 % of the total impact. This high impact is predominantly attributed to silver usage and heightened electricity consumption. The sensitivity analysis revealed that various performance indicators exhibited differing degrees of sensitivity to uncertainty in the design variables, highlighting the importance of careful consideration, particularly in addressing the impact on the ecosystem, when aiming to reduce environmental impacts in the life cycle of silicon solar panels. Our results have also indicated that transportation significantly impacts resource protection, accounting for 15 % of the total impacts in this category, with lesser yet notable contributions to ecosystems and human health. The implications of this work suggest a need for stringent policies to fabricate complete solar photovoltaic modules in Mexico to reduce the environmental burden caused by transportation. Additionally, the insights from this study offer a gateway for the Mexican government to reform current energy transition policies by including multiple recycling scenarios for solar photovoltaic systems, ultimately leading to sustainable growth in this market.
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Renewable Energy Focus
Renewable Energy Focus Renewable Energy, Sustainability and the Environment
CiteScore
7.10
自引率
8.30%
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0
审稿时长
48 days
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