Sustainable valorization of agricultural waste into bioplastic and its end-of-life recyclability for biochar production: Economic profitability and life cycle assessment
Robert Senga , Mahmoud Nasr , Manabu Fujii , Amal Abdelhaleem
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引用次数: 0
Abstract
While the industrial sectors have recently focused on producing bioplastic materials, the utilization of edible feedstocks and the generation of wastes and byproducts during the bioplastic synthesis process might delay achieving the environmental sustainability strategy. To overcome these limitations related to bioplastic industrialization, this study focuses on synthesizing bioplastics from waste sources, followed by recycling its end-of-life (e.g., spent and exhausted) material into biochar. Sweet potato peel waste, banana pseudo-stems, and cooking oil waste were used to extract starch, cellulose, and glycerol (a plasticizer) involved in bioplastic manufacturing, respectively. It was found that the cellulose content of 30% w w−1 in bioplastic maintained the best physicochemical, mechanical, and biodegradability properties, recommending a high applicability for food packaging. The exhausted bioplastic was then pyrolyzed to maintain a biochar yield of 32.60 ± 0.89%, avoiding the risk of secondary pollution from waste material disposal. This biochar was utilized to treat wastewater generated from the bioplastic synthesis process, showing the optimum adsorption factors of biochar dosage = 3.81 g L−1, time = 102 min, and solution pH = 7.81. The combined bioplastic production, waste pyrolysis, and wastewater treatment scheme could earn profits from biomaterial sales, carbon credit, and pollution reduction shadow price, maintaining a 6.78-year payback period and a 12.09% internal rate of return. This integrated framework depicted better contributions to the mid-point/end-point life cycle assessment impact categories than the only bioplastic production scenario. This study contributed towards achieving several sustainable development goals (SDGs), including SDG#3: human health protection, SDG#6: wastewater treatment, and SDG#12: waste recycling.
虽然工业部门最近集中于生产生物塑料材料,但在生物塑料合成过程中使用可食用原料和产生废物和副产品可能会推迟实现环境可持续性战略。为了克服与生物塑料工业化相关的这些限制,本研究侧重于从废物来源合成生物塑料,然后将其寿命结束(例如,废和耗尽)的材料回收为生物炭。甘薯皮废物、香蕉假茎和食用油废物分别用于提取生物塑料制造中涉及的淀粉、纤维素和甘油(一种增塑剂)。研究发现,当纤维素含量为30% w w−1时,生物塑料的理化、力学和生物降解性能保持最佳,在食品包装中具有较高的适用性。将废弃的生物塑料进行热解处理,保持生物炭产率为32.60±0.89%,避免了废弃物处理的二次污染风险。利用该生物炭处理生物塑料合成过程中产生的废水,最佳吸附条件为生物炭投加量= 3.81 g L−1,时间= 102 min,溶液pH = 7.81。生物塑料生产-废弃物热解-废水处理组合方案可从生物材料销售、碳信用和污染减排影子价格中获得利润,投资回收期为6.78年,内部收益率为12.09%。与唯一的生物塑料生产情景相比,这一综合框架描述了对中点/终点生命周期评估影响类别的更好贡献。这项研究有助于实现若干可持续发展目标(SDG),包括可持续发展目标#3:人类健康保护、可持续发展目标#6:废水处理和可持续发展目标#12:废物回收。
期刊介绍:
Chemosphere, being an international multidisciplinary journal, is dedicated to publishing original communications and review articles on chemicals in the environment. The scope covers a wide range of topics, including the identification, quantification, behavior, fate, toxicology, treatment, and remediation of chemicals in the bio-, hydro-, litho-, and atmosphere, ensuring the broad dissemination of research in this field.
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