碱或酸辅助聚苯乙烯塑料在超临界CO2中的降解

Yanbing Liu, Jinwen Shi, Liuhao Mao, Bingru Lu, Xing Kang, Hui Jin
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引用次数: 2

摘要

塑料对环境造成了严重的“白色污染”,塑料的高度惰性特性给降解带来了重大挑战。超临界流体具有独特的物理性质,在各个领域得到了广泛的应用。本文选择条件温和的超临界CO2 (Sc-CO2),在NaOH/HCl溶液的辅助下降解聚苯乙烯(PS)塑料,并采用响应面法(RSM)设计反应模型。研究发现,无论何种助溶剂,影响PS降解效率的因素均为反应温度、反应时间和NaOH/HCl浓度。在温度400℃,时间120 min,碱/酸浓度5%(重量)的条件下,0.15 g PS产生126.88/116.99±5 mL气体,H2为74.18/62.78±5 mL, CO2为81.2/71.5±5 mL。Sc-CO2为PS创造了一个均匀的环境,使PS高度分散,受热均匀,从而促进了PS的降解,并且Sc-CO2还与降解产物发生反应,生成新的CO和更多的CH4和C2Hx (x= 4,6)。添加NaOH/HCl溶液不仅提高了PS在Sc-CO2中的溶解度,还提供了一个碱/酸环境,降低了反应的活化能,有效地提高了PS的降解效率。在Sc-CO2中降解PS是可行的,在碱/酸溶液的辅助下取得了较好的效果,可为今后废塑料的处理提供参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Base- or acid-assisted polystyrene plastic degradation in supercritical CO2

Base- or acid-assisted polystyrene plastic degradation in supercritical CO2

Plastic has caused serious "white pollution" to the environment, and the highly inert characteristics of plastic bring a major challenge for degradation. Supercritical fluids have unique physical properties and have been widely used in various fields. In this work, supercritical CO2 (Sc-CO2) with mild conditions was selected and assisted by NaOH/HCl solution to degrade polystyrene (PS) plastic, and the reaction model was designed using response surface methodology (RSM). It was found that, regardless of the types of assistance solutions, the factors affecting PS degradation efficiencies were reaction temperature, reaction time, and NaOH/HCl concentration. At the temperature of 400 °C, time of 120 min, and base/acid concentration of 5% (in weight), 0.15 g PS produced 126.88/116.99±5 mL of gases with 74.18/62.78±5 mL of H2, and consumed 81.2/71.5±5 mL of CO2. Sc-CO2 created a homogeneous environment, which made PS highly dispersed and uniformly heated, thus promoting the degradation of PS. Moreover, Sc-CO2 also reacted with the degradation products to produce new CO and more CH4 and C2Hx (x=4, 6). Adding NaOH/HCl solution not only improved the solubility of PS in Sc-CO2, but also provided a base/acid environment that reduced the activation energy of the reaction, and effectively improved the degradation efficiencies of PS. In short, degrading PS in Sc-CO2 is feasible, and better results are obtained with the assistance of base/acid solution, which can provide a reference for the disposal of waste plastics in the future.

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