Finite element (GFEM) simulations on the effect of microwave heating for lossy dielectric samples with various shapes (circle, square and triangle)

Basak, Tanmay

doi:10.1108/hff-07-2019-0601

Cited by 8 publications

(2 citation statements)

References 54 publications

(92 reference statements)

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“…In order to solve this problem, it is necessary to optimize the electromagnetic field in the cavity by rationally designing the microwave equipment. The use of numerical computations for visualizing the electromagnetic waves is feasible to aid in designing the optimized cavity geometry [ 92 , 93 ]. Another concern in microwave device design is the leakage of microwave during operation, which must be avoidable in batch mode or continuous systems.…”

Section: Summary and Prospectmentioning

confidence: 99%

A Review and Perspective of Environmental Disinfection Technology Based on Microwave Irradiation

Wang

Laghari

et al. 2023

Curr Pollution Rep

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Purpose of Review In the context of COVID-19 sweeping the world, the development of microbial disinfection methods in gas, liquid, and solid media has received widespread attention from researchers. As a disinfection technology that can adapt to different environmental media, microwave-assisted disinfection has the advantages of strong permeability, no secondary pollution, etc. The purpose of this review is to put forward new development requirements for future microwave disinfection strategies by summarizing current microwave disinfection methods and effects. From the perspective of the interaction mechanism of microwave and microorganisms, this review provides a development direction for more accurate and microscopic disinfection mechanism research. Recent Findings Compared to other traditional environmental disinfection techniques, microwave-assisted disinfection means have the advantages of being more destructive, free of secondary contamination, and thorough. Currently, researchers generally agree that the efficiency of microwave disinfection is the result of a combination of thermal and non-thermal effects. However, the performance of microwave disinfection shows the differences in the face of different environmental media as well as different types of microorganisms. Summary This review highlights the inactivation mechanism of microwave-assisted disinfection techniques used in different scenarios. Suggestions for promoting the efficiency and overcoming the limitations of low energy utilization, complex reactor design, and inaccurate monitoring methods are proposed.

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Section: Summary and Prospectmentioning

confidence: 99%

A Review and Perspective of Environmental Disinfection Technology Based on Microwave Irradiation

Wang

Laghari

et al. 2023

Curr Pollution Rep

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“…The technique is also applied to a variety of practical problems, for instance, flow control in microchannels, groundwater and soil analysis, micro-pumping, oil exploration, chemical remediation and biomedical engineering (Di Fraia et al, 2018). However, there is evidence that the use of microwave radiation may offer multiple advantages such as high speed, uniform heating, deep penetration and volumetric heat release (Sun et al, 2016;Basak, 2020). The possibility of optimal control and automation of the process is also promising (Sysoev and Kislitsyn, 2011).…”

Section: Introductionmentioning

confidence: 99%

Implementation of a multi-layer radiation propagation model for simulation of microwave heating in hydrate reservoirs

Gupta

Yadav

Das

et al. 2021

HFF

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Purpose This paper aims to present the implementation of a multi-layer radiation propagation model in simulations of multi-phase flow and heat transfer, for a dissociating methane hydrate reservoir subjected to microwave heating. Design/methodology/approach To model the induced heterogeneity due to dissociation of hydrates in the reservoir, a multiple homogeneous layer approach, used in food processes modelling, is suggested. The multi-layer model is incorporated in an in-house, multi-phase, multi-component hydrate dissociation simulator based on the finite volume method. The modified simulator is validated with standard experimental results in the literature and subsequently applied to a hydrate reservoir to study the effect of water content and sand dielectric nature on radiation propagation and hydrate dissociation. Findings The comparison of the multi-layer model with experimental results show a maximum difference in temperature estimation to be less than 2.5 K. For reservoir scale simulations, three homogeneous layers are observed to be sufficient to model the induced heterogeneity. There is a significant contribution of dielectric properties of sediments and water content of the reservoir in microwave radiation attenuation and overall hydrate dissociation. A high saturation reservoir may not always provide high gas recovery by dissociation of hydrates in the case of microwave heating. Originality/value The multi-layer approach to model microwave radiation propagation is introduced and tested for the first time in dissociating hydrate reservoirs. The multi-layer model provides better control over reservoir heterogeneity and interface conditions compared to existing homogeneous models.

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Batch and Continuous Flow Microwave Processing

Yang,

Fan

2024

Food Engineering Series

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Finite element (GFEM) simulations on the effect of microwave heating for lossy dielectric samples with various shapes (circle, square and triangle)

Cited by 8 publications

References 54 publications

A Review and Perspective of Environmental Disinfection Technology Based on Microwave Irradiation

A Review and Perspective of Environmental Disinfection Technology Based on Microwave Irradiation

Implementation of a multi-layer radiation propagation model for simulation of microwave heating in hydrate reservoirs

Batch and Continuous Flow Microwave Processing

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