A finite element model for simulating temperature distributions in rotating food during microwave heating

Liu, Shixiong; Fukuoka, Mika; Sakai, Noboru

doi:10.1016/j.jfoodeng.2012.09.019

Cited by 107 publications

(68 citation statements)

References 20 publications

(26 reference statements)

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“…Because ICCG is used to solve edge-based finite-element equations for quasi-static electromagnetic fields and heat transfer, other parameters, including the converge test tolerance levels, divergence tolerance and maximum iterations, were also necessary (Liu et al, 2013). The convergence test tolerance demonstrated the tolerated calculation error, while iterations showed the maximum number of repetitions of the analysis process until the desired convergence test tolerance (calculation error) was approached (Liu et al, 2014).…”

Section: Solution Proceduresmentioning

confidence: 99%

Computer simulation of radiofrequency defrosting of frozen foods

Llave

Liu

Fukuoka

et al. 2015

Journal of Food Engineering

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Section: Solution Proceduresmentioning

confidence: 99%

Computer simulation of radiofrequency defrosting of frozen foods

Llave

Liu

Fukuoka

et al. 2015

Journal of Food Engineering

Self Cite

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“…The volumetric heating rate or the power deposition of microwaves (Q) can be calculated as: Q = 2πf·ε 0 ·ε″·(E rms ) 2 , where f is the frequency of the microwaves, ε 0 is the permittivity of free space, ε″ is the dielectric loss factor of the material, and E rms is the root mean square value of electric field intensity at a location (Liu et al, 2013). Therefore, the nonuniformity of the microwave heating rate is related not only to the electromagnetic field pattern but also to the spatial and temporal variation in food properties.…”

Section: Dielectric Loss Factors Of Whey Protein Gel and Mashed Potatomentioning

confidence: 99%

Temperature-Dependent Dielectric and Thermal Properties of Whey Protein Gel and Mashed Potato

Chen¹,

Pitchai²,

Birla³

et al. 2013

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“…In most cases, FDTD method‐based solvers are limited in simulation application because of their inability to handle irregular geometries and longer computational time. Alternatively, FEM‐based solvers have been used extensively in simulating microwave heating that includes complex geometries (Lin and others ; Geedipalli and others ; Liu and others ; Pitchai and others ). Solving coupled electromagnetic and heat and mass transfer equations in 3‐D space and time requires a great amount of computational resources.…”

Section: Introductionmentioning

confidence: 99%

Multiphysics Modeling of Microwave Heating of a Frozen Heterogeneous Meal Rotating on a Turntable

Pitchai

Chen

Birla

et al. 2015

Journal of Food Science

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A 3-dimensional (3-D) multiphysics model was developed to understand the microwave heating process of a real heterogeneous food, multilayered frozen lasagna. Near-perfect 3-D geometries of food package and microwave oven were used. A multiphase porous media model combining the electromagnetic heat source with heat and mass transfer, and incorporating phase change of melting and evaporation was included in finite element model. Discrete rotation of food on the turntable was incorporated. The model simulated for 6 min of microwave cooking of a 450 g frozen lasagna kept at the center of the rotating turntable in a 1200 W domestic oven. Temperature-dependent dielectric and thermal properties of lasagna ingredients were measured and provided as inputs to the model. Simulated temperature profiles were compared with experimental temperature profiles obtained using a thermal imaging camera and fiber-optic sensors. The total moisture loss in lasagna was predicted and compared with the experimental moisture loss during cooking. The simulated spatial temperature patterns predicted at the top layer was in good agreement with the corresponding patterns observed in thermal images. Predicted point temperature profiles at 6 different locations within the meal were compared with experimental temperature profiles and root mean square error (RMSE) values ranged from 6.6 to 20.0 °C. The predicted total moisture loss matched well with an RMSE value of 0.54 g. Different layers of food components showed considerably different heating performance. Food product developers can use this model for designing food products by understanding the effect of thickness and order of each layer, and material properties of each layer, and packaging shape on cooking performance.

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A finite element model for simulating temperature distributions in rotating food during microwave heating

Cited by 107 publications

References 20 publications

Computer simulation of radiofrequency defrosting of frozen foods

Computer simulation of radiofrequency defrosting of frozen foods

Temperature-Dependent Dielectric and Thermal Properties of Whey Protein Gel and Mashed Potato

Multiphysics Modeling of Microwave Heating of a Frozen Heterogeneous Meal Rotating on a Turntable

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