Three-Dimensional Numerical Modeling of the Temperature Distribution in a High Dam Reservoir on the Mekong River

In order to inspect on wall condition inside the coke oven, an inspection device has been developed to protect a camera inside and sustains high temperature long enough so that it can be permanently-installed on the pusher ram beam. The temperature of the coking chamber during operation is about 1200 °C while the maximum tolerable temperature of a camera is less than 40 °C. The device has to function as a good thermal insulator with cooling element for the camera at the pusher head and for signal cables along the beam. In this paper, the necessary conditions of the inspective device were found out by building a three-dimensional numerical model of the device to simulate the temperature distribution inside the device with CFD commercial software.

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The Modeling of Chemical Technological Process in the Fire Chambers

Eurasian Chemico-Technological Journal ◽

10.18321/ectj527 ◽

2017 ◽

Vol 4 (3) ◽

pp. 147

Author(s):

A.S. Askarova ◽

S.A. Bolegenova ◽

E.I. Lavrishcheva ◽

I.V. Loktionova

Keyword(s):

Mass Transfer ◽

Numerical Modeling ◽

Temperature Distribution ◽

Numerical Experiment ◽

Chemical Reactions ◽

Three Dimensional ◽

Hydroelectric Station ◽

Heat Propagation ◽

Heat Radiation ◽

Radiation Chemical

<p>In this paper the results obtained by the method of numerical modeling of Ekibastuz coal burning in furnace on the example of fire chamber fixed on Aksy hydroelectric station are represented. Numerical experiment was carried out on the basis of three-dimensional equations of convective heat and mass transfer, taking into account the heat propagation, heat radiation, chemical reactions and multiphase structure of the medium. After the numerical experiment, the pictures of temperature distribution on the height of the chamber and concentration of CO, CO<sub>2</sub>, ash and coke distribution along the chamber were obtained. The results are represented graphically.</p>

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Three Dimensional Numerical Modeling of Current and Temperature Distribution in the Estuary of Palu River

Journal of Physics Conference Series ◽

10.1088/1742-6596/1354/1/012020 ◽

2019 ◽

Vol 1354 ◽

pp. 012020

Author(s):

Mohammad Lutfi

Keyword(s):

Numerical Modeling ◽

Temperature Distribution ◽

Three Dimensional

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NUMERICAL MODELING OF THREE-DIMENSIONAL FLOWS OF VISCOUS GAS IN NOZZLES

TsAGI Science Journal ◽

10.1615/tsagiscij.2011004142 ◽

2011 ◽

Vol 42 (4) ◽

pp. 445-465

Author(s):

Anatoliy Pavlovich Mazurov

Keyword(s):

Numerical Modeling ◽

Three Dimensional ◽

Viscous Gas

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Boundary Condition Design to Heat a Moving Object at Uniform Transient Temperature Using Inverse Formulation

Journal of Manufacturing Science and Engineering ◽

10.1115/1.1763179 ◽

2004 ◽

Vol 126 (3) ◽

pp. 619-626 ◽

Cited By ~ 8

Author(s):

Hakan Ertu¨rk ◽

Ofodike A. Ezekoye ◽

John R. Howell

Keyword(s):

Boundary Condition ◽

Temperature Distribution ◽

Design Problem ◽

Manufacturing Industry ◽

Three Dimensional ◽

Chemical Deposition ◽

Iterative Solution ◽

Conveyor Belt ◽

Temperature History ◽

Transient Temperature

The boundary condition design of a three-dimensional furnace that heats an object moving along a conveyor belt of an assembly line is considered. A furnace of this type can be used by the manufacturing industry for applications such as industrial baking, curing of paint, annealing or manufacturing through chemical deposition. The object that is to be heated moves along the furnace as it is heated following a specified temperature history. The spatial temperature distribution on the object is kept isothermal through the whole process. The temperature distribution of the heaters of the furnace should be changed as the object moves so that the specified temperature history can be satisfied. The design problem is transient where a series of inverse problems are solved. The process furnace considered is in the shape of a rectangular tunnel where the heaters are located on the top and the design object moves along the bottom. The inverse design approach is used for the solution, which is advantageous over a traditional trial-and-error solution where an iterative solution is required for every position as the object moves. The inverse formulation of the design problem is ill-posed and involves a set of Fredholm equations of the first kind. The use of advanced solvers that are able to regularize the resulting system is essential. These include the conjugate gradient method, the truncated singular value decomposition or Tikhonov regularization, rather than an ordinary solver, like Gauss-Seidel or Gauss elimination.

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Simulation of Thermal and Electric Field Distribution in Packaged Sausages Heated in a Stationary Versus a Rotating Microwave Oven

Foods ◽

10.3390/foods10071622 ◽

2021 ◽

Vol 10 (7) ◽

pp. 1622

Author(s):

Wipawee Tepnatim ◽

Witchuda Daud ◽

Pitiya Kamonpatana

Keyword(s):

Temperature Distribution ◽

Electric Field ◽

Three Dimensional ◽

Development Stage ◽

Microwave Oven ◽

Computational Time ◽

Plastic Package ◽

Heating Uniformity ◽

The Cost ◽

Good Agreement

The microwave oven has become a standard appliance to reheat or cook meals in households and convenience stores. However, the main problem of microwave heating is the non-uniform temperature distribution, which may affect food quality and health safety. A three-dimensional mathematical model was developed to simulate the temperature distribution of four ready-to-eat sausages in a plastic package in a stationary versus a rotating microwave oven, and the model was validated experimentally. COMSOL software was applied to predict sausage temperatures at different orientations for the stationary microwave model, whereas COMSOL and COMSOL in combination with MATLAB software were used for a rotating microwave model. A sausage orientation at 135° with the waveguide was similar to that using the rotating microwave model regarding uniform thermal and electric field distributions. Both rotating models provided good agreement between the predicted and actual values and had greater precision than the stationary model. In addition, the computational time using COMSOL in combination with MATLAB was reduced by 60% compared to COMSOL alone. Consequently, the models could assist food producers and associations in designing packaging materials to prevent leakage of the packaging compound, developing new products and applications to improve product heating uniformity, and reducing the cost and time of the research and development stage.

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