A DEM-based heat transfer model for the evaluation of effective thermal conductivity of packed beds filled with stagnant fluid: Thermal contact theory and numerical simulation

Abstract The heat conduction performance of the methanol synthesis reactor is significant for the development of large-scale methanol production. The present work has measured the temperature distribution in the fixed bed at air volumetric flow rate 2.4–7 m3 · h−1, inlet air temperature 160–200°C and heating tube temperature 210–270°C. The effective radial thermal conductivity and effective wall heat transfer coefficient were derived based on the steady-state measurements and the two-dimensional heat transfer model. A correlation was proposed based on the experimental data, which related well the Nusselt number and the effective radial thermal conductivity to the particle Reynolds number ranging from 59.2 to 175.8. The heat transfer model combined with the correlation was used to calculate the temperature profiles. A comparison with the predicated temperature and the measurements was illustrated and the results showed that the predication agreed very well with the experimental results. All the absolute values of the relative errors were less than 10%, and the model was veriﬁed by experiments. Comparing the correlations of both this work with previously published showed that there are considerable discrepancies among them due to different experimental conditions. The influence of the particle Reynolds number on the temperature distribution inside the bed was also discussed and it was shown that improving particle Reynolds number contributed to enhance heat transfer in the fixed bed.

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Research on Heat Transfer Characteristics of Nano-Porous Silica Aerogel Material and its Application on Mars Surface Mission

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.924.329 ◽

2014 ◽

Vol 924 ◽

pp. 329-335 ◽

Cited By ~ 5

Author(s):

Cong Hang Li ◽

Shi Chen Jiang ◽

Zheng Ping Yao ◽

Song Sheng ◽

Xin Jian Jiang ◽

...

Keyword(s):

Heat Transfer ◽

Thermal Conductivity ◽

Silica Aerogel ◽

Thermal Environment ◽

Porous Silica ◽

Heat Transfer Model ◽

Heat Radiation ◽

Transfer Model ◽

Ambient Conditions ◽

Coupled Heat Transfer

Based on the nanoporous network structure features of silica aerogel, the gas-solid coupled heat transfer model of silica aerogel is analyzed, and the calculation formulas of the gas-solid coupled, the gas thermal conductivity and the heat radiation within the aerogel are derived. The thermal conductivity of pure silica aerogel is calculated according to the derived heat transfer model and is also experimentally measured. Moreover, measurements on the thermal conductivities of silica aerogel composites with different densities at ambient conditions are performed. And finally, a novel design of silica aerogel based integrated structure and thermal insulation used for withstanding the harsh thermal environment on the Martin surface is presented.

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Effective Thermal Conductivity of Submicron Powders: A Numerical Study

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.846.500 ◽

2016 ◽

Vol 846 ◽

pp. 500-505

Author(s):

Wei Jing Dai ◽

Yi Xiang Gan ◽

Dorian Hanaor

Keyword(s):

Heat Transfer ◽

Thermal Conductivity ◽

Thermal Resistance ◽

Effective Thermal Conductivity ◽

Granular Materials ◽

Gas Phase ◽

Numerical Study ◽

Transfer Model ◽

Size Of Particles ◽

Contact Unit

Effective thermal conductivity is an important property of granular materials in engineering applications and industrial processes, including the blending and mixing of powders, sintering of ceramics and refractory metals, and electrochemical interactions in fuel cells and Li-ion batteries. The thermo-mechanical properties of granular materials with macroscopic particle sizes (above 1 mm) have been investigated experimentally and theoretically, but knowledge remains limited for materials consisting of micro/nanosized grains. In this work we study the effective thermal conductivity of micro/nanopowders under varying conditions of mechanical stress and gas pressure via the discrete thermal resistance method. In this proposed method, a unit cell of contact structure is regarded as one thermal resistor. Thermal transport between two contacting particles and through the gas phase (including conduction in the gas phase and heat transfer of solid-gas interfaces) are the main mechanisms. Due to the small size of particles, the gas phase is limited to a small volume and a simplified gas heat transfer model is applied considering the Knudsen number. During loading, changes in the gas volume and the contact area between particles are simulated by the finite element method. The thermal resistance of one contact unit is calculated through the combination of the heat transfer mechanisms. A simplified relationship between effective thermal conductivity and loading pressure can be obtained by integrating the contact units of the compacted powders.

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Heat Transfer Model and Analysis of Oil-Immersed Electrical Transformers with Heat Pipe Radiator

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.516-517.312 ◽

2012 ◽

Vol 516-517 ◽

pp. 312-315

Author(s):

Guang Hua Li ◽

Hong Lei Liu ◽

De Jian Wang

Keyword(s):

Heat Transfer ◽

Numerical Simulation ◽

Temperature Field ◽

Heat Pipe ◽

Heat Transfer Model ◽

Transfer Model ◽

Cooling Device ◽

Transformer Design ◽

Electrical Transformers ◽

Good Agreement

This paper has formulated a heat transfer model for analyzing the cooling properties of a heat pipe cooling device of oil-immersed electrical transformer. Based on the model, the oil temperature field of a 30 KVA oil-immersed transformer has been numerical simulated, and experiments also had been conducted. Results showed that the numerical simulation has good agreement with experiment results. Results also showed that heat pipe radiator is feasible for oil-immersed electrical transformer cooling. The model can be used to analyze the oil temperature distribution properties in an oil-immersed electrical transformer with heat pipe cooling device, and provide theoretical guide for transformer design and improvement.

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Influence of Contact Mechanics in the Prediction of the Effective Thermal Conductivity of Spheroid Packed Beds

Heat Transfer: Volume 1 ◽

10.1115/ht2003-47351 ◽

2003 ◽

Cited By ~ 1

Author(s):

G. Buonanno ◽

A. Carotenuto ◽

G. Giovinco ◽

L. Vanoli

Keyword(s):

Thermal Conductivity ◽

Effective Thermal Conductivity ◽

Statistical Approach ◽

Thermal Contact ◽

Peak Height ◽

Thermal Contact Conductance ◽

Curvature Radius ◽

Packed Beds ◽

Wide Range ◽

Thermal Phenomena

Thermal contact conductance is an important parameter in a wide range of thermal phenomena, and consequently a large number of experimental, numerical and statistical investigations have been carried out in literature. In the present paper an analysis of thermal contact resistance is carried out to predict heat transfer between spherical rough surfaces in contact, by means of a statistical approach. The micro-geometry of the surface is described through a probabilistic model based on the peak height variability and invariant asperity curvature radius. The numerical model has been applied to evaluate the effective thermal conductivity of packed beds of steel spheroids and validated through the comparison with the experimental data obtained by means of an apparatus designed and build up for this purpose.

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Convective Heat Transfer Analysis of Open Cell Metal Foam for Solar Air Heaters

Solar Energy ◽

10.1115/isec2003-44030 ◽

2003 ◽

Cited By ~ 2

Author(s):

Nihad Dukhan ◽

Pablo D. Quinones

Keyword(s):

Heat Transfer ◽

Thermal Conductivity ◽

Effective Thermal Conductivity ◽

Metal Foam ◽

Heat Transfer Analysis ◽

Transfer Model ◽

Aluminum Foams ◽

Maximum Heat ◽

Open Cell ◽

Maximum Heat Transfer

A one-dimensional heat transfer model for open-cell metal foam is presented. Three aluminum foams having different areas, relative densities, ligament diameters, and number of pores per inch were analyzed. The effective thermal conductivity and the heat transfer increased with the number of pores per inch. The effective thermal conductivity of the foams can be up to four times higher than that of solid aluminum. The resulting improvement in heat transfer can be as high as 50 percent. The maximum heat transfer for the aluminum foams occurs at a pore Reynolds number of 52. The heat transfer, in addition, becomes insensitive to the flow regime for pore Reynolds numbers beyond 200.

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Numerical simulation of time fractional bio-heat transfer model during cryosurgical treatment of skin cancer

Computational Thermal Sciences An International Journal ◽

10.1615/computthermalscien.2021034414 ◽

2021 ◽

Author(s):

MUKESH KUMAR ◽

K. N. Rai

Keyword(s):

Heat Transfer ◽

Numerical Simulation ◽

Skin Cancer ◽

Heat Transfer Model ◽

Transfer Model

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