Simulation investigation on heating characteristics of catalysts under microwave irradiation for decomposition of waste plastic

IF 5.6 2区 工程技术 Q2 ENERGY & FUELS
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Abstract

Microwave heating is a promising technique for heterogeneous catalytic reactions in plastic decomposition. The microwave-insensitive plastic material requires microwave-absorbing catalysts to facilitate catalytic-assisted decomposition and synergistic heating. However, the heating characteristics of catalyst particles within the microwave system is still unclear. In this study, the effects of particle size, particle arrangement direction, and particle shape on the microwave heating behavior of particles was investigated, and the model was experimentally validated and analyzed using infrared temperature data. The simulation results indicated that the heating rate increased as the particle size enlarged, with an average heating rate of 5.56 °C/s for the particle with a radius of 5 mm in comparison to 4.29 °C/s for that of 1 mm. Additionally, when particles were aligned parallel to the applied electric field, the electric field was intensely focused at the interparticle area, with a maximum electric field strength difference of 2.2 × 104 V/m in the samples. In contrast, the horizontal placement resulted in reduced electric field intensity (4.7 × 103 V/m) and lower temperatures (62 °C) near the areas adjacent to the particles compared to the maximum values in the particles. With respect to particle shape, cylindrical particles possessing larger aspect ratios exhibited superior heating performance due to the extended span of intraparticle microwave transmission aligned with the electric field direction but also resulted in increased thermal field distribution inhomogeneity. The research offers theoretical guidance to prevent catalyst sintering and promote microwave-assisted catalytic plastic decomposition.

微波辐照下催化剂分解废塑料的加热特性模拟研究
微波加热是塑料分解过程中一种前景广阔的异相催化反应技术。对微波不敏感的塑料材料需要微波吸收催化剂来促进催化辅助分解和协同加热。然而,催化剂颗粒在微波系统中的加热特性尚不清楚。本研究研究了颗粒尺寸、颗粒排列方向和颗粒形状对颗粒微波加热行为的影响,并利用红外温度数据对模型进行了实验验证和分析。模拟结果表明,加热速率随着颗粒尺寸的增大而增加,半径为 5 毫米的颗粒的平均加热速率为 5.56 ℃/秒,而半径为 1 毫米的颗粒的平均加热速率为 4.29 ℃/秒。此外,当粒子平行于外加电场排列时,电场强烈集中在粒子间区域,样品中的最大电场强度差为 2.2 × 104 V/m。相反,水平放置则导致电场强度降低(4.7 × 103 V/m),与颗粒内的最大值相比,颗粒邻近区域附近的温度较低(62 °C)。在颗粒形状方面,具有较大长宽比的圆柱形颗粒由于延长了与电场方向一致的颗粒内微波传输跨度而表现出更优越的加热性能,但同时也增加了热场分布的不均匀性。该研究为防止催化剂烧结和促进微波辅助催化塑料分解提供了理论指导。
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来源期刊
Journal of The Energy Institute
Journal of The Energy Institute 工程技术-能源与燃料
CiteScore
10.60
自引率
5.30%
发文量
166
审稿时长
16 days
期刊介绍: The Journal of the Energy Institute provides peer reviewed coverage of original high quality research on energy, engineering and technology.The coverage is broad and the main areas of interest include: Combustion engineering and associated technologies; process heating; power generation; engines and propulsion; emissions and environmental pollution control; clean coal technologies; carbon abatement technologies Emissions and environmental pollution control; safety and hazards; Clean coal technologies; carbon abatement technologies, including carbon capture and storage, CCS; Petroleum engineering and fuel quality, including storage and transport Alternative energy sources; biomass utilisation and biomass conversion technologies; energy from waste, incineration and recycling Energy conversion, energy recovery and energy efficiency; space heating, fuel cells, heat pumps and cooling systems Energy storage The journal''s coverage reflects changes in energy technology that result from the transition to more efficient energy production and end use together with reduced carbon emission.
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