Co-pyrolysis of low-value wood sawdust and non-recyclable plastics into char: effect of plastic loading on char yield and its properties

RSC sustainability Pub Date : 2025-02-18 DOI:10.1039/D4SU00739E

Ranjeet Kumar Mishra

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Abstract

Co-pyrolysis of biomass and plastics is essential to improve the quality and yield of pyrolytic products, optimise energy recovery, and mitigate plastic waste, providing a sustainable approach to waste valorisation. This study examined char production from the co-pyrolysis of biomass and plastic in a semi-batch reactor at 500 °C with a heating rate of 10 °C min⁻¹ and a nitrogen gas flow rate of 100 mL min⁻¹. JCT and NRPET were physically mixed at 30, 50%, and 80% wt%, respectively. The physicochemical properties of biomass and plastics confirmed their suitability as pyrolysis feedstocks. TGA-FTIR results confirmed that the addition of NRPET at 30, 50 and 80 wt% with JCT significantly increased the hydrocarbons and reduced the formation of CO₂, CO and oxygenated compounds. Results showed that blending of non-recyclable PET (NRPET) with Jungle Cork Tree (JCT) at 30%, 50%, and 80% reduced char yield by 5.27%, 9.07%, and 12.47%, respectively. Additionally, the blending of JCT and NRPET improved the properties of the char, such as carbon content (22.59%), heating value (6.17 MJ kg⁻¹), bulk density (200.11 kg m⁻³), and electrical conductivity. The blending process also led to a significant reduction in the oxygen content (18.05%) and surface area (30.78 m² g⁻¹) of the char. FTIR analysis showed a loss of undesirable functional groups, while Raman spectroscopy revealed an increased I_D/I_G ratio. Finally, SEM analysis indicated that the incorporation of plastics increased the hardness and reduced the roughness of the char, enhancing its suitability for energy storage or carbon-based material applications.

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低价值木屑与不可回收塑料共热解成炭：塑料负荷对炭产率及其性质的影响

生物质和塑料的共热解对于提高热解产物的质量和产量、优化能源回收和减少塑料废物至关重要，为废物增值提供了一种可持续的方法。本研究考察了生物质和塑料在500°C的半间歇反应器中共热解制炭，加热速率为10°C min - 1，氮气流量为100 mL min - 1。JCT和NRPET分别以30%、50%和80% wt%进行物理混合。生物质和塑料的理化性质证实了它们作为热解原料的适宜性。TGA-FTIR结果证实，在JCT中加入30、50和80 wt%的NRPET显著增加了碳氢化合物，减少了CO2、CO和含氧化合物的形成。结果表明，当不可回收PET （NRPET）与JCT （Jungle Cork Tree， JCT）配比为30%、50%和80%时，炭产率分别降低5.27%、9.07%和12.47%。此外，JCT和NRPET的共混提高了炭的碳含量（22.59%）、热值（6.17 MJ kg−1）、堆积密度（200.11 kg m−3）和导电性。混合过程还导致炭的氧含量（18.05%）和表面积（30.78 m2 g−1）显著降低。FTIR分析显示不需要的官能团损失，而拉曼光谱显示ID/IG比增加。最后，SEM分析表明，塑料的掺入提高了炭的硬度，降低了炭的粗糙度，增强了其储能或碳基材料应用的适用性。

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来源期刊

RSC sustainability

CiteScore

0.60

自引率

0.00%

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