“双碳”目标下我国新能源行业关键金属供应分析
梁扬扬 , 刘丽丽 , 贺克斌 , 黄斐 , Gómez Moisés , 李金惠
中国工程科学 ›› 2024, Vol. 26 ›› Issue (3) : 131 -141.
“双碳”目标下我国新能源行业关键金属供应分析
梁扬扬 , 刘丽丽 , 贺克斌 , 黄斐 , Gómez Moisés , 李金惠
中国工程科学 ›› 2024, Vol. 26 ›› Issue (3) : 131 -141.
“双碳”目标下我国新能源行业关键金属供应分析
Supply of Key Metals for China's New Energy Industries under the Carbon Peaking and Carbon Neutrality Goals
风电、光伏发电等新能源行业是支撑实现“双碳”目标的关键领域,我国风电、光伏发电的装机规模居世界首位,保障关键金属材料供应、进行更精准的新兴固废管理具有重要意义。本文基于我国风电、光伏发电行业的历史数据和规划目标,设定了不同的发展情景;应用风电、光伏发电设备的寿命分布模型,评估了我国新能源行业关键金属的需求、废弃和供应情况;重点识别了银、铜、镓、银、钢铁、钕等金属的供应压力,为2060年前构建绿色低碳能源发展格局提供了基础支撑。在基准情景下,2035年的风电、光伏发电行业退役量分别为4.6 GW、28.3 GW;2035年、2060年的风电、光伏发电设备退役量(按质量计)分别为2.54×106 t、1.048×107 t。从我国新能源行业的关键金属供应压力来看,2030—2060年,钢铁为低风险(≤5%),钕为中高风险(25%~50%),铜、银为高风险(50%~100%),镓、铟因需求峰值过高而被列为极度危险等级。改善新能源产业供应链的安全性和多样性,既需要确保金属矿产资源的可持续供应,也需要开展回收循环和高效利用;为此建议将风电、光伏发电退役设备按照废弃电器电子产品进行管理,将风电、光伏发电企业纳入《固定污染源排污许可分类管理名录》,加快完善分布式新能源固废回收体系,切实提高新兴固废回收技术水平。
New energy industries, such as wind and photovoltaic (PV) power generation, are key to supporting the carbon peaking and carbon neutrality goals of China. The installed capacity of wind and PV power in China is the largest worldwide; therefore, it is necessary to secure the supply of key metal materials and conduct a more accurate management of emerging solid wastes. This study sets different development scenarios based on the historical data and planning objectives of wind and PV power industries of China. It assesses the demand, waste, and supply of key metals in China's new energy industry using a life distribution model of wind and PV power generation equipment, and focuses on identifying the supply pressure of silver, copper, gallium, silver, steel, and neodymium, thereby providing a basic support for realizing the green and low-carbon development of the energy industry by 2060. In the baseline scenario, the decommissioned volume of the wind and PV power generation industries will reach 4.6 GW and 28.3 GW in 2035, respectively; and the total decommissioned volume (by mass) of both wind and PV power generation equipment will reach 2.54 ×106 t and 1.048 ×107 t in 2035 and 2060, respectively. In terms of the supply of key metals for the new energy industry during 2030‒2060, iron and steel have a low supply risk (≤5%), neodymium has a medium-high supply risk (25%‒50%), copper and silver have a high supply risk (50%‒100%), and the supply of gallium and indium are at an extremely high risk owing to their excessive peak demand. To improve the security and diversity of the supply chain of the new energy industry, it is necessary to ensure the sustainable supply of metal mineral resources and promote material recycling and efficient use. Furthermore, we propose the following recommendations: (1) treating decommissioned equipment for wind and PV power generation as waste electrical and electronic products, (2) incorporating wind and PV power generation enterprises into the Catalogue of Classified Management of Pollutant Discharge Permits for Stationary Pollution Sources, (3) improving the distributed new-energy solid-waste recycling system, and (4) developing recycling technologies for emerging solid wastes.
新兴固废 / 风电设备 / 光伏组件 / 关键金属 / 供应风险
emerging solid waste / wind turbines / photovoltaic modules / key metal / supply risk
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