Heat mass transfer on the surface of a barrier with gas-thermal coat applying

Abstract

The calculated and experimental research results have been presented to show how the concentration and the composition of a dispersed phase, the physical-chemical transformations on the medium boundary influence the radiation-convective heat transfer between high-temperature two-phase flows and the surface of a solid media. The computation of the heat flow was made according to the following physical model of the process: the mass flow rate of transporting a gas and solid particles is constant; the distribution density of solid particles on the surface of the base follows the normal law. In this case the process of heat propagation by the depth of a material may be simulated by a one-dimensional non-linear energy equation.

Original language	English
Pages (from-to)	1229-1232
Number of pages	4
Journal	Teplofizika Vysokikh Temperatur
Volume	30
Issue number	6
Publication status	Published - Nov 1992
Externally published	Yes

ASJC Scopus subject areas

Fluid Flow and Transfer Processes

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@article{29be9007c5d44d63846ee653bb667c1b,

title = "Heat mass transfer on the surface of a barrier with gas-thermal coat applying",

abstract = "The calculated and experimental research results have been presented to show how the concentration and the composition of a dispersed phase, the physical-chemical transformations on the medium boundary influence the radiation-convective heat transfer between high-temperature two-phase flows and the surface of a solid media. The computation of the heat flow was made according to the following physical model of the process: the mass flow rate of transporting a gas and solid particles is constant; the distribution density of solid particles on the surface of the base follows the normal law. In this case the process of heat propagation by the depth of a material may be simulated by a one-dimensional non-linear energy equation.",

author = "Abaltusov, {V. E.} and Dement'ev, {V. F.} and Zharova, {I. K.} and Nemova, {T. N.} and Mamontov, {G. Ya} and Pinkin, {V. F.}",

year = "1992",

month = nov,

language = "English",

volume = "30",

pages = "1229--1232",

journal = "Teplofizika Vysokikh Temperatur",

issn = "0040-3644",

publisher = "Izdatel'stvo Nauka",

number = "6",

}

TY - JOUR

T1 - Heat mass transfer on the surface of a barrier with gas-thermal coat applying

AU - Abaltusov, V. E.

AU - Dement'ev, V. F.

AU - Zharova, I. K.

AU - Nemova, T. N.

AU - Mamontov, G. Ya

AU - Pinkin, V. F.

PY - 1992/11

Y1 - 1992/11

N2 - The calculated and experimental research results have been presented to show how the concentration and the composition of a dispersed phase, the physical-chemical transformations on the medium boundary influence the radiation-convective heat transfer between high-temperature two-phase flows and the surface of a solid media. The computation of the heat flow was made according to the following physical model of the process: the mass flow rate of transporting a gas and solid particles is constant; the distribution density of solid particles on the surface of the base follows the normal law. In this case the process of heat propagation by the depth of a material may be simulated by a one-dimensional non-linear energy equation.

AB - The calculated and experimental research results have been presented to show how the concentration and the composition of a dispersed phase, the physical-chemical transformations on the medium boundary influence the radiation-convective heat transfer between high-temperature two-phase flows and the surface of a solid media. The computation of the heat flow was made according to the following physical model of the process: the mass flow rate of transporting a gas and solid particles is constant; the distribution density of solid particles on the surface of the base follows the normal law. In this case the process of heat propagation by the depth of a material may be simulated by a one-dimensional non-linear energy equation.

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M3 - Article

AN - SCOPUS:0026944016

VL - 30

SP - 1229

EP - 1232

JO - Teplofizika Vysokikh Temperatur

JF - Teplofizika Vysokikh Temperatur

SN - 0040-3644

IS - 6

ER -