Comparative Life Cycle Assessment of Suspension PVC Production: Case for Indonesian Industry, Chinese Industry, and European Database.

IF 8.4 4区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Integrated Environmental Assessment and Management Pub Date : 2025-10-21 DOI:10.1093/inteam/vjaf145

Ernie S A Soekotjo, Hismiaty Bahua, Soen Steven, Elsye Veradika Yemensia, Nugroho Adi Sasongko, Tjokorde Walmiki Samadhi, Akhmad Zainal Abidin

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Abstract

Polyvinyl chloride (PVC) is a global plastic commodity with the third-highest rank in production volume after polyethylene and polypropylene. Unfortunately, the chlorine element therein can be detrimental to the environment. Thus, a life cycle assessment (LCA) for the PVC industry becomes important. This study conducted a process-level LCA with a gate-to-gate system boundary of suspension PVC (S-PVC) production in the Indonesian industry using primary industrial data. The results were then compared with the Chinese PVC industry in Anhui Province, as well as the EU27 database from Ecoinvent 3.8. The assessment was carried out using OpenLCA 1.11 software, using the CML-IA baseline method. Following this study, the Indonesian and Chinese PVC industries have a lower impact on marine aquatic ecotoxicity, human toxicity, and freshwater aquatic ecotoxicity compared to the EU27 database. In contrast, the Chinese PVC industry has the highest impact on GWP. This study also demonstrates that chlorine from stripped VCM and PVC dust release is the cause of marine aquatic ecotoxicity, with respective portions of 30.82%, 59.02%, and 23.86% for the Indonesian PVC industry, the Chinese PVC industry, and the EU27 database. The organic additives also add to the impact of human toxicity and freshwater ecotoxicity. In addition, the utilization of refrigerant compounds, as well as CO2 and CH4 emissions during the process, causes GWP. Finally, a ± 5% change in the input amount causes an alteration in marine aquatic ecotoxicity by -7.02% to 12.97% for the Indonesian PVC industry, -26.43% to -18.99% for the Chinese PVC industry, and -11.55% to -9.77% for the EU27 database.

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暂停PVC生产的生命周期比较评估：以印尼工业、中国工业和欧洲数据库为例。

聚氯乙烯（PVC）是继聚乙烯和聚丙烯之后产量排名第三的全球性塑料商品。不幸的是，其中的氯元素可能对环境有害。因此，PVC行业的生命周期评估（LCA）变得非常重要。本研究使用原始工业数据，对印尼工业中悬浮PVC （S-PVC）生产的门到门系统边界进行了过程级LCA。然后将结果与安徽省的中国PVC工业以及Ecoinvent 3.8的欧盟27国数据库进行比较。采用OpenLCA 1.11软件，CML-IA基线法进行评估。根据这项研究，与欧盟27国数据库相比，印度尼西亚和中国PVC工业对海洋水生生态毒性、人体毒性和淡水水生生态毒性的影响较低。相比之下，中国PVC行业对GWP的影响最大。该研究还表明，剥离VCM和PVC粉尘释放的氯是海洋水生生态毒性的原因，印度尼西亚PVC行业、中国PVC行业和欧盟27国数据库的比例分别为30.82%、59.02%和23.86%。有机添加剂也增加了人体毒性和淡水生态毒性的影响。此外，制冷剂化合物的使用以及过程中CO2和CH4的排放也会导致全球变暖潜能值。最后，输入量的±5%的变化会导致海洋水生生态毒性的变化，印度尼西亚PVC工业的变化幅度为-7.02%至12.97%，中国PVC工业的变化幅度为-26.43%至-18.99%，欧盟27国数据库的变化幅度为-11.55%至-9.77%。

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来源期刊

Integrated Environmental Assessment and Management ENVIRONMENTAL SCIENCESTOXICOLOGY&nbs-TOXICOLOGY

CiteScore

5.90

自引率

6.50%

发文量

156

期刊介绍： Integrated Environmental Assessment and Management (IEAM) publishes the science underpinning environmental decision making and problem solving. Papers submitted to IEAM must link science and technical innovations to vexing regional or global environmental issues in one or more of the following core areas: Science-informed regulation, policy, and decision making Health and ecological risk and impact assessment Restoration and management of damaged ecosystems Sustaining ecosystems Managing large-scale environmental change Papers published in these broad fields of study are connected by an array of interdisciplinary engineering, management, and scientific themes, which collectively reflect the interconnectedness of the scientific, social, and environmental challenges facing our modern global society: Methods for environmental quality assessment; forecasting across a number of ecosystem uses and challenges (systems-based, cost-benefit, ecosystem services, etc.); measuring or predicting ecosystem change and adaptation Approaches that connect policy and management tools; harmonize national and international environmental regulation; merge human well-being with ecological management; develop and sustain the function of ecosystems; conceptualize, model and apply concepts of spatial and regional sustainability Assessment and management frameworks that incorporate conservation, life cycle, restoration, and sustainability; considerations for climate-induced adaptation, change and consequences, and vulnerability Environmental management applications using risk-based approaches; considerations for protecting and fostering biodiversity, as well as enhancement or protection of ecosystem services and resiliency.