期刊
PHYSICA SCRIPTA
卷 97, 期 12, 页码 -出版社
IOP Publishing Ltd
DOI: 10.1088/1402-4896/ac9e7d
关键词
SMHH; susceptor material; COMSOL; skin depth; time-temperature; charcoal powder; graphite powder
This study investigates the performance of Graphite and Charcoal susceptors in a conical vertical cavity for Selective Microwave Hybrid Heating (SMHH) using Finite Element Method (FEM) simulation. It was found that Charcoal susceptor achieved a significantly higher maximum temperature compared to Graphite, and different cavity shapes also affected temperature rise.
The microwave processing of materials is gaining popularity over the past decade due to its unique heating abilities. The microwave hybrid heating (MHH) technique has effectively processed bulk metallic materials. MHH is assisted by susceptor material which forces metals to absorb microwave radiations. Further, MHH is modified to selective microwave hybrid heating (SMHH) to increase the efficiency of the process. This work examines the performance of Graphite and Charcoal susceptors with a conical vertical cavity for SMHH using FEM simulation. It is observed that the maximum temperature achieved by Graphite was 215 degrees C at an exposure time of 300 s, whereas, for Charcoal susceptor, it is 655 degrees C. Further, the effect of different vertical cavity shapes (cylindrical and conical) on the SMHH technique is presented for Charcoal susceptor. For an exposure time of 300 s, the temperature rise in the conical and cylindrical cavity is 655 degrees C and 319 degrees C, respectively. From resistive heat flow, time-temperature profile and temperature distribution, it is clear how SMHH is significantly effective for a conical vertical cavity having Charcoal susceptor. In addition, the performance of the conical vertical cavity having Charcoal susceptor was validated through experimental study. The real-time temperature profile was determined through testo 885/testo 890 thermal imaging camera. The observed maximum temperature of the susceptor after heating for 300 s was 639.9 degrees C.
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