Review and Design Overview of Plastic Waste-to-Pyrolysis Oil Conversion with Implications on the Energy Transition

M. J. B. Kabeyi, O. Olanrewaju
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引用次数: 1

Abstract

Plastics are cheap, lightweight, and durable and can be easily molded into many different products, shapes, and sizes, hence their wide applications globally, leading to increased production and use. Plastic consumption and production have been growing since its first production in the 1950s. About 4% of global oil and gas production is being used as feedstock for plastics, and 3–4% is used to provide energy for their manufacture. Plastics have a wide range of applications because they are versatile and relatively cheap. This study presents an in-depth analysis of plastic solid waste (PSW). Plastic wastes can be technically used for oil production because the calorific value of the plastics is quite comparable to that of oil, making this option an attractive alternative. Oil can be produced from plastic wastes via thermal degradation and catalytic degradation, while gasification can be used to produce syngas. Plastic pyrolysis can be used to address the twin problem of plastic waste disposal and depletion of fossil fuel reserves. The demand for plastics has continued to rise since their first production in the 1950s due to their multipurpose, lightness, inexpensiveness, and durable nature. There are four main avenues available for plastic solid waste treatment, namely, reextrusion as a primary treatment, mechanical treatment as secondary measures, chemical treatment as a tertiary measure, and energy recovery as a quaternary measure. The pyrolysis oil has properties that are close to clean fuel and is, therefore, a substitute to fresh fossil fuel for power generation, transport, and other applications. The study showed that plastic wastes pyrolysis offers an alternative avenue for plastic waste disposal and an alternative source of fossil fuel to reduce the total demand of virgin oil. Through plastic pyrolysis, plastic wastes are thermally converted to fuel by degrading long-chain polymers into small complex molecules in the absence of oxygen, making it a technically and economically feasible process for waste plastic recycling. The process is advantageous because presorting is not required, and the plastic waste can be directly fed without pretreatment prior to the process. Products of plastic pyrolysis are pyrolysis oil, a hydrocarbon-rich gas, with a heating value of 25–45 MJ/kg, which makes it ideal for process energy recovery. Hence, the pyrolysis gas can be fed back to the process to extract the energy for the process-heating purpose, which substantially reduces the reliance on external heating sources.
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塑料废弃物热解油转化技术综述与设计综述及其对能源转型的启示
塑料价格便宜,重量轻,耐用,可以很容易地塑造成许多不同的产品,形状和尺寸,因此它们在全球范围内广泛应用,导致生产和使用增加。自20世纪50年代首次生产以来,塑料的消费和生产一直在增长。全球约4%的石油和天然气产量被用作塑料的原料,3-4%用于为塑料制造提供能源。塑料用途广泛,因为它们用途广泛,而且相对便宜。本研究对塑料固体废物(PSW)进行了深入分析。从技术上讲,塑料废物可以用于石油生产,因为塑料的热值与石油相当,使这一选择成为一个有吸引力的替代方案。塑料垃圾可以通过热降解和催化降解生产石油,而气化可以用来生产合成气。塑料热解可用于解决塑料废物处理和化石燃料储量枯竭的双重问题。自20世纪50年代首次生产塑料以来,由于其多用途、轻便、便宜和耐用的性质,对塑料的需求不断上升。塑料固体废物的处理主要有四种途径,即:再挤出法为一级处理,机械法为二级处理,化学法为三级处理,能源回收法为四级处理。热解油具有接近清洁燃料的特性,因此是发电、运输和其他应用中新鲜化石燃料的替代品。研究表明,塑料垃圾热解为塑料垃圾处理提供了另一种途径,也为化石燃料的替代来源提供了减少初榨油总需求的途径。通过塑料热解,塑料废弃物在无氧条件下将长链聚合物降解为复杂小分子,热转化为燃料,是废塑料回收利用技术和经济上可行的工艺。该工艺是有利的,因为不需要预分类,塑料废物可以直接进料,而无需预处理之前的过程。塑料热解的产物是热解油,这是一种富含碳氢化合物的气体,热值为25-45 MJ/kg,是过程能量回收的理想选择。因此,热解气可以反馈到工艺中提取能量用于工艺加热,大大减少了对外部热源的依赖。
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审稿时长
28 weeks
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