Sensitivity analysis on the microwave heating of coal: A coupled electromagnetic and heat transfer model

•A coupled electromagnetic and heat transfer model was built for microwave heating.•An optimal frequency of 2.45GHz was found to achieve efficient heating.•Increase in the MW power contributes to the thermal heterogeneity.•Temperature increases while thermal heterogeneity decreases with loss factor....

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Bibliographic Details
Published inApplied thermal engineering Vol. 126; pp. 949 - 962
Main Authors Lin, Baiquan, Li, He, Chen, Zhongwei, Zheng, Chunshan, Hong, Yidu, Wang, Zheng
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 05.11.2017
Elsevier BV
Subjects
Coal
Coal permittivity
Electric field
Electromagnetism
Energy absorption
Energy conservation
Energy consumption
Frequency and power
Heat transfer
Heating
Heterogeneity
Microwave heating
Microwaves
Optimization
Power consumption
Power efficiency
Sensitivity analysis
Studies
Thermal field
Thermal field
Coal permittivity
Electric field
Frequency and power
Microwave heating
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Summary:•A coupled electromagnetic and heat transfer model was built for microwave heating.•An optimal frequency of 2.45GHz was found to achieve efficient heating.•Increase in the MW power contributes to the thermal heterogeneity.•Temperature increases while thermal heterogeneity decreases with loss factor. Microwave irradiation has gained widespread popularity in coal processing. However, the effects of microwave parameters and coal properties on the heating behavior remain much less explored. In this study, a coupled electromagnetic and heat transfer model was developed to investigate the microwave-coal interactions. Results show that microwave heating is sensitive to frequency: an optimal frequency of 2.45GHz was found whereby the maximum temperature and energy efficiency can be achieved. In addition, the increase in the microwave power contributes to the thermal heterogeneity and energy consumption, suggesting that low powers are suitable for uniform heating and energy saving, while high powers apply to differential and rapid heating. As the loss factor increases, the temperature and energy efficiency increase while the thermal heterogeneity decreases. Increasing the loss factor could not only achieve rapid and uniform heating but also save energy. Furthermore, the optimal coal size for enhancing microwave energy absorption could be obtained when the coal diameter is 50mm, with heights ranging from 60mm to 100mm. Outcomes of this study can be used to identify the electric and thermal fields of coal and thereby help to optimize the microwave applicators.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2017.08.012