A kinetic study of thermal degradation of non-metallic part of printed circuit boards for the combined effect of particle size and catalyst

IF 0.9 Q4 ENGINEERING, CHEMICAL

Indian Chemical Engineer Pub Date : 2022-09-23 DOI:10.1080/00194506.2022.2126333

Vaibhav Pandere, A. Gautam, Shina Gautam

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Abstract

ABSTRACT After the successful removal of metals from printed circuit boards either through a physical or chemical process, epoxy resins are thermosetting plastics left over for landfilling. To overcome landfilling, thermal degradation of this resin was done under different particle sizes with varying catalyst concentrations. A series of thermogravimetric experiments were carried out using ZSM-5 as the catalyst. To study kinetics parameters’ mass loss with temperature was divided into 3 zones 120–240°C, 240–360°C and 360–650°C. To determine activation energy and the order of reaction, the Coats and Redfern method was used. Experimental data in all three zones were found in agreement with the Coats and Redfern method. ZSM-5 was found to be reducing activation energy and the order of reaction in zone 2. The average activation energy was in the range of 150–200 kJ/mol and the order of reaction was 1.5–2 in zone 2 for different experiments. Coarser particles were found to have less decomposition than finer particles due to heat transfer limitation within the particle. However, the effect of increasing catalyst concentration was found ineffective in the mass transfer of more volatiles from PCB. GRAPHICAL ABSTRACT

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粒径和催化剂共同作用下印刷电路板非金属部件热降解的动力学研究

摘要在通过物理或化学工艺成功去除印刷电路板上的金属后，环氧树脂就是剩下来填埋的热固性塑料。为了克服填埋，在不同催化剂浓度下，在不同颗粒尺寸下对该树脂进行热降解。以ZSM-5为催化剂进行了一系列热重实验。为了研究动力学参数随温度的质量损失，将其分为120–240°C、240–360°C和360–650°C三个区域。为了测定活化能和反应顺序，使用了Coats和Redfern方法。所有三个区域的实验数据均与Coats和Redfern方法一致。发现ZSM-5降低了区域2中的活化能和反应顺序。平均活化能在150–200之间 kJ/mol，不同实验的反应级数在2区为1.5–2。由于颗粒内的传热限制，发现较粗的颗粒比较细的颗粒分解更少。然而，增加催化剂浓度的效果对PCB中更多挥发物的传质无效。图形摘要

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来源期刊

Indian Chemical Engineer ENGINEERING, CHEMICAL-

CiteScore

3.00

自引率

6.70%

发文量