CFD modeling of heat transfer and flow field in spin flash drying process

Spin flash drying equipment is widely used in chemical, food and other fields. Drying process consumes large amounts of energy and reduction in operating cost will be extremely beneficial for the industry. Therefore, in order to improve the efficiency of spin flash dryer. A three-dimensional CFD mod...

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Veröffentlicht in:	Heat and mass transfer 2020-11, Vol.56 (11), p.3011-3021
Hauptverfasser:	Yuan, Yuejin, Dong, Pengpeng, Xu, Yingying, Wang, Dong, Yuan, Yueding, Tan, Libin, Kong, Lingbo
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerodynamics Calcium carbonate Computational fluid dynamics Drying Engineering Engineering Thermodynamics Flow stability Heat and Mass Transfer Heat transfer Industrial Chemistry/Chemical Engineering Mathematical models Original Pressure drop Process parameters Radial velocity Structural stability Thermodynamics Three dimensional models
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creator	Yuan, Yuejin Dong, Pengpeng Xu, Yingying Wang, Dong Yuan, Yueding Tan, Libin Kong, Lingbo
description	Spin flash drying equipment is widely used in chemical, food and other fields. Drying process consumes large amounts of energy and reduction in operating cost will be extremely beneficial for the industry. Therefore, in order to improve the efficiency of spin flash dryer. A three-dimensional CFD model of the drying process was established by computational fluid dynamics, and the flow field characteristics and heat transfer mechanism of the drying process were obtained. We studied the specific effects of different parameters on the drying process, and verified the results with calcium carbonate as raw material. The experimental results are basically consistent with the simulation results. The velocity, temperature and pressure in the drying chamber near the wall are greater than those in the central region, which generally decrease with height. The speed of the cutter set has a large effect on the tangential and radial velocity, but the influence on the pressure drop is not significant. Meanwhile the temperature and velocity of inlet air have a greater impact on distribution of flow field and material drying, the variable structure improves the stability of the drying process.
doi_str_mv	10.1007/s00231-020-02918-6
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subjects	Aerodynamics Calcium carbonate Computational fluid dynamics Drying Engineering Engineering Thermodynamics Flow stability Heat and Mass Transfer Heat transfer Industrial Chemistry/Chemical Engineering Mathematical models Original Pressure drop Process parameters Radial velocity Structural stability Thermodynamics Three dimensional models
title	CFD modeling of heat transfer and flow field in spin flash drying process
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