区块链驱动的新能源汽车动力电池回收与溯源技术投入策略研究

doi:10.16381/j.cnki.issn1003-207x.2023.0319

Abstract

Abstract:

It is found that：（1） with introducing BT technology， both the supplier and third-party remanufacturer have improved their profits. However， whether the manufacturer benefit depends on BT technology’s impact on promoting demand and consumers’ trust in BT；（2） a higher traceability level can promote the circulation of the whole NEV closed-loop supply chain and the saving of social resources， so as to achieve the purpose of promoting circular economy； and （3） if the investment cost of BT technology is controllable and the effect of BT technology （consumption/recycling preference） is significant， the essential impact of BT technology on the closed-loop supply chain of NEVs is positive.Research Question Sources　The rapid growth in new energy vehicle （NEV） sales has been reflected in the expanding demand and scaling up of battery production， which reached 160 GWh in 2020. In reality， the average service life of the battery for electric cars is 5-8 years， and safety measures hold that the battery must be replaced before a 20-30% degradation occurs from its original capacity. The increased demand for battery power not only places increasing pressure on manufacturers to recycle retired batteries， it also poses a severe threat to the environment， owing to toxic electrolytes and chemicals. Firms are also seeking to recycle used batteries where possible. Most manufacturers choose to cooperate with third-party recyclers （3PRs） to recycle their used batteries so that they can focus on their core business. For example， NEV manufacturers such as Nissan and Volkswagen ask their consumers to return retired batteries to authorized third-party collection centers. Although cooperating with 3PRs can improve the efficiency of recycling electric vehicle batteries， there remains some technological limitations in the reverse supply chain of these batteries， such as the traceability of the energy consumption and the verification of the recyclability of the batteries. These limitations， however， may potentially be overcome by the use of Blockchain traceability （BT） technology. With China’s commitment to “carbon peak and carbon neutrality”， new problems of power battery upgrading or scrapping emerge. How to effectively track the energy consumption of power batteries and the performance of battery materials， verify the recyclability of batteries and ensure compliance？ It is not only a technical problem at present， but also an inevitable environmental problem in the future. Based on the above scenario， Stackelberg game models are employed to study the motivation and influence mechanism of key factors for NEV manufacturers or power battery suppliers to adopt BT technology to track the use of power batteries.

Key words: new energy vehicle, recycling of power battery, Blockchain traceability technology, closed-loop supply chain, game theory

CLC Number:

F274

Zhangwei Feng, Bisheng Du, Zhiyong Yu, Shandong Mou. Recycling and Traceability Technology Introducing Strategy of New Energy Vehicles’ Power Battery Driven by Blockchain[J]. Chinese Journal of Management Science, 2025, 33(4): 313-324.

Figures/Tables 8

符号	定义	符号	定义
参数		$k b$	区块链溯源技术研发成本的规模系数
$m$	动力电池的单位原材料成本	$k r$	回收努力成本的规模系数
$c m$	动力电池的单位制造成本	决策变量
$c n$	新能源汽车的单位生产成本及除电池以外的零部件成本	$w$	动力电池的批发价，且 $w > m + c m$
$c n$	新能源汽车的单位生产成本及除电池以外的零部件成本	$p$	新能源汽车的零售价，且 $p > w + c n$
$c s$	未投入区块链溯源技术的单位使用成本	$r$	产品追溯水平
$a$	3PR的废旧动力电池回收费用	$e$	回收努力水平
$b$	动力电池供应商的回购费用，且 $b > a$	函数
$α$	潜在的市场规模	$D$	需求函数
$β$	零售价格的敏感系数	$Q$	回收数量
$k$	消费者对产品信息的信任度	$C e$	回收努力成本
$Q 0$	无偿情形下的回收数量	$C s$	区块链溯源技术投入成本
$λ$	对产品追溯水平的影响系数	$π i j$	$i$ 企业在情形 $j$ 下的利润函数， $i ∈ {S, M, 3 P R}$ ， $j ∈ {N, S, M}$
$μ$	对回收努力水平的影响系数	$π i j$	$i$ 企业在情形 $j$ 下的利润函数， $i ∈ {S, M, 3 P R}$ ， $j ∈ {N, S, M}$

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文献	是否考虑闭环供应链	是否采用区块链溯源技术	主要研究内容
Li等^[5]	是	否	研究补贴和双信用政策对考虑电池回收的新能源、燃料汽车的生产决策的影响机理
谢家平等^[7]和马亮等^[8]	是	否	研究新能源汽车或电池生产企业主导的闭环供应链的协调机制
张梅梅^[15]	否	是	研究基于区块链技术的动力电池梯次利用方案
李剑等^[16]	是	是	研究区块链驱动的供应链协同减排信息共享机制
Centobelli等^[17]	否	是	构建循环区块链平台的基本框架
Gopalakrishnan等^[18]	否	是	研究基于区块链的固体废物管理模型
易余胤和陈健^[20]	是	否	研究“以旧换新燃油”和“以旧换新能源”定价策略
Yang等^[21]	否	否	研究存在绿色技术投资的环境责任供应链中的双渠道选择问题
本文	是	是	研究制造商或供应商采取区块链溯源技术的动机和关键因素的影响机理

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Recycling and Traceability Technology Introducing Strategy of New Energy Vehicles’ Power Battery Driven by Blockchain

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