Optimization of Kerosene-like Fuels Produced via Catalytic Pyrolysis of Packaging Plastic Waste via Central Composite Design and Response Surface Methodology: Performance of Iron-Doped Dolomite and Activated Carbon.

IF 4.2 2区化学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecules Pub Date : 2025-07-07 DOI:10.3390/molecules30132884

Oratepin Arjharnwong, Tharapong Vitidsant, Aminta Permpoonwiwat, Naphat Phowan, Witchakorn Charusiri

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Abstract

Rapid economic growth has led to an increase in the use of multilayer plastic packaging, which involves complex polymer compositions and hinders recycling. This study investigated the catalytic pyrolysis of plastic packaging waste in a 3000 cm³ semibatch reactor, aiming to optimize kerosene-like hydrocarbon production. The temperature (420-500 °C), N₂ flow rate (25-125 mL/min), and catalyst loading (5-20 wt.%) were examined individually and in combination with activated carbon and an Fe-doped dolomite (Fe/DM) catalyst. Central composite design (CCD) and response surface methodology (RSM) were used to identify the optimal conditions and synergistic effects. Pyrolysis product analysis involved simulation distillation gas chromatography (Sim-DGC), gas chromatography/mass spectrometry (GC/MS), and Fourier transform infrared (FT-IR) spectroscopy. The optimal conditions (440 °C, 50 mL/min N₂ flow, catalyst loading of 10 wt.% using a 5 wt.% Fe-doped dolomite-activated carbon 0.6:0.4 mass/molar ratio) yielded the highest pyrolysis oil (79.6 ± 0.35 wt.%) and kerosene-like fraction (22.3 ± 0.22 wt.%). The positive synergistic effect of Fe/DM and activated carbon (0.6:0.4) enhanced the catalytic activity, promoting long-chain polymer degradation into mid-range hydrocarbons, with secondary cracking yielding smaller hydrocarbons. The pore structure and acid sites of the catalyst improved the conversion of intermediate hydrocarbons into aliphatic compounds (C₅-C₁₅), increasing kerosene-like hydrocarbon production.

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基于中心复合设计和响应面法优化包装塑料废弃物催化热解制备类煤油燃料：掺铁白云石和活性炭的性能。

快速的经济增长导致多层塑料包装的使用增加，这涉及复杂的聚合物成分并阻碍回收。本研究在3000 cm3半间歇反应器中对塑料包装废弃物进行了催化热解，以优化类煤油烃的生产。分别考察了温度（420-500°C）、N2流速（25-125 mL/min）和催化剂负载（5-20 wt.%），以及活性炭和掺铁白云石（Fe/DM）催化剂的组合。采用中心复合设计（CCD）和响应面法（RSM）确定了最佳条件和协同效应。热解产物分析包括模拟蒸馏气相色谱（Sim-DGC）、气相色谱/质谱（GC/MS）和傅里叶变换红外（FT-IR）光谱。在最佳条件下（440°C， 50 mL/min N2流量，10 wt.%催化剂负载，5 wt.%掺铁白云石-活性炭0.6:0.4质量/摩尔比），热解油（79.6±0.35 wt.%）和类煤油分数（22.3±0.22 wt.%）最高。Fe/DM与活性炭的正协同效应（0.6:0.4）增强了催化活性，促进长链聚合物降解为中程烃，二次裂解生成较小的烃。催化剂的孔结构和酸位促进了中间烃向脂肪族化合物（C5-C15）的转化，提高了类煤油烃的产量。

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来源期刊

Molecules 化学-有机化学

CiteScore

7.40

自引率

8.70%

发文量

7524

审稿时长

1.4 months

期刊介绍： Molecules (ISSN 1420-3049, CODEN: MOLEFW) is an open access journal of synthetic organic chemistry and natural product chemistry. All articles are peer-reviewed and published continously upon acceptance. Molecules is published by MDPI, Basel, Switzerland. Our aim is to encourage chemists to publish as much as possible their experimental detail, particularly synthetic procedures and characterization information. There is no restriction on the length of the experimental section. In addition, availability of compound samples is published and considered as important information. Authors are encouraged to register or deposit their chemical samples through the non-profit international organization Molecular Diversity Preservation International (MDPI). Molecules has been launched in 1996 to preserve and exploit molecular diversity of both, chemical information and chemical substances.