探索从废物中回收材料的框架--实现清洁环境的革命性举措

IF 5.5 Q1 ENGINEERING, CHEMICAL Chemical Engineering Journal Advances Pub Date : 2024-01-29 DOI:10.1016/j.ceja.2024.100589
M. Arun , Debabrata Barik , Sreejesh S. R. Chandran
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引用次数: 0

摘要

通过实行可持续废物管理和化学品生产,减少对环境的影响并保证关键化学品的稳定供应。通过推进循环经济理念和减少对有限资源的依赖,这项研究有可能从根本上改变工业格局。本文探讨了废料回收和化学品生产的技术、经济、监管和社会障碍。解决这些问题的关键在于找到既经济可行又对环境无害的解决方案。本文介绍了可持续的化学品生产和废料回收框架(CP&WMRF),该框架融合了创新的回收和再循环方法、创新的化学品生产工艺,以及人工智能(AI)和机器学习(ML)等数字技术,以最大限度地提高资源利用效率。在 CP&WMRF 的帮助下,可以减少界面生产过程中的废物和能源消耗。可以使用可持续原料生产化学品,以替代化石燃料。该系统规范了电子废弃物的回收以及回收金属和材料的使用方式。要证明这些方法的可行性和效率,需要创新的模拟和建模工具。这些评估有助于决策者了解拟议技术在性能、环境影响和经济可行性方面的利弊。与 AI-ML 的 94.2% 相比,CP&WMRF 的 96.2% 显示出明显的优势。AI-ML 的效率较低,仅为 93.8%。在可持续性分析领域,CP&WMRF 的得分高达 95.2%,比 AI-ML 的 93.2% 低得多。在资源效率方面,CP&WMRF 的得分高达 97.5 %,大大超过了 AI-ML 的 92.8 %。在优化废物回收方面,CP&WMRF 取得了令人瞩目的成功,得分 98.7%,高于 AI-ML 的 91.5%。本研究通过整合创新方法、全方位应用和严谨的模拟分析,为实现循环和绿色化学的革命性发展建立了框架。
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Exploration of material recovery framework from waste – A revolutionary move towards clean environment

Reduce environmental impacts and guarantee a steady supply of critical chemicals by practising sustainable waste management and chemical production. By advancing circular economy ideas and decreasing dependency on finite resources, this research has the potential to alter the industrial landscape radically. The technological, economic, regulatory, and social barriers to waste material recovery and chemical production are explored in this paper. The key to resolving these issues is the identification of solutions that are both economically viable and environmentally benign. This paper introduces the sustainable Chemical Production and Waste Material Recovery Framework (CP&WMRF), which incorporates innovative recycling and upcycling methods, innovative chemical manufacturing processes, and the incorporation of digital technologies like artificial intelligence (AI) and machine learning (ML) to maximize the efficiency with which resources are employed. It is possible to reduce waste and energy use in the production of Interfaces with the help of CP&WMRF. Chemicals can be manufactured using sustainable feedstocks as an alternative to fossil fuels. The system standardizes how e-waste can be recycled and recovered metals and materials can be used. To prove the viability and efficiency of these methods, they require innovative simulation and modeling tools. The assessments help decision-makers understand the benefits and drawbacks of the proposed technologies in terms of their performance, environmental effect, and economic viability. When pitted against AI-ML, which achieved 94.2 %, CP&WMRF's 96.2 % result reveals a significant edge. AI-ML is less efficient, with a score of 93.8 %. The field of sustainability analysis, with a score of 95.2 %, is higher than AI-ML's decent lower score of 93.2 %. The impressive 97.5 % score of CP&WMRF in terms of resource efficiency substantially surpasses the 92.8 % score ascribed to AI-ML. The remarkable success of CP&WMRF in optimizing waste recovery, with a score of 98.7 %, higher than the 91.5 % associated with AI-ML. The present research establishes the framework for a revolutionary move toward circular and green chemistry by integrating innovative methods, all-encompassing applications, and rigorous simulation analysis.

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来源期刊
Chemical Engineering Journal Advances
Chemical Engineering Journal Advances Engineering-Industrial and Manufacturing Engineering
CiteScore
8.30
自引率
0.00%
发文量
213
审稿时长
26 days
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