A boundary integral equation formulation for the thermal creep gas flow at finite Peclet numbers

César Nieto; Henry Power; Mauricio Giraldo

doi:10.1016/j.ijmecsci.2014.05.016

A boundary integral equation formulation for the thermal creep gas flow at finite Peclet numbers

César Nieto, Henry Power, Mauricio Giraldo

Research output: Contribution to journal › Article in an indexed scientific journal › peer-review

3 Scopus citations

Abstract

The integral equation formulation developed previously by the authors to study isothermal micro flows under shear slip boundary condition is extended in this work to consider the case of non-isothermal micro gas flows with thermal creep effects at finite Peclet numbers. The effect of thermal creep over the flow patterns with and without considering the effect of shear slip is investigated in detail using a boundary element method. In this work the boundary integral approaches for both fluid velocity and temperatures fields are used to solve the problem of shear-driven cavity flow at finite Peclet number. This is obtained by considering the diffusive-convective heat equation using the Dual Reciprocity Method to transform the corresponding volume integral of the convective terms into equivalent surface integrals.

Original language	English
Pages (from-to)	267-275
Number of pages	9
Journal	International Journal of Mechanical Sciences
Volume	88
DOIs	https://doi.org/10.1016/j.ijmecsci.2014.05.016
State	Published - Nov 2014

Bibliographical note

Publisher Copyright:
© 2014 Elsevier Ltd. All rights reserved.

Keywords

Boundary integral solution
Maxwell' slip condition
Micro flow
Rarefied gases
Stokes flow
Thermal creep

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10.1016/j.ijmecsci.2014.05.016

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title = "A boundary integral equation formulation for the thermal creep gas flow at finite Peclet numbers",

abstract = "The integral equation formulation developed previously by the authors to study isothermal micro flows under shear slip boundary condition is extended in this work to consider the case of non-isothermal micro gas flows with thermal creep effects at finite Peclet numbers. The effect of thermal creep over the flow patterns with and without considering the effect of shear slip is investigated in detail using a boundary element method. In this work the boundary integral approaches for both fluid velocity and temperatures fields are used to solve the problem of shear-driven cavity flow at finite Peclet number. This is obtained by considering the diffusive-convective heat equation using the Dual Reciprocity Method to transform the corresponding volume integral of the convective terms into equivalent surface integrals.",

keywords = "Boundary integral solution, Maxwell' slip condition, Micro flow, Rarefied gases, Stokes flow, Thermal creep",

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year = "2014",

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doi = "10.1016/j.ijmecsci.2014.05.016",

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T1 - A boundary integral equation formulation for the thermal creep gas flow at finite Peclet numbers

AU - Nieto, César

AU - Power, Henry

AU - Giraldo, Mauricio

PY - 2014/11

Y1 - 2014/11

N2 - The integral equation formulation developed previously by the authors to study isothermal micro flows under shear slip boundary condition is extended in this work to consider the case of non-isothermal micro gas flows with thermal creep effects at finite Peclet numbers. The effect of thermal creep over the flow patterns with and without considering the effect of shear slip is investigated in detail using a boundary element method. In this work the boundary integral approaches for both fluid velocity and temperatures fields are used to solve the problem of shear-driven cavity flow at finite Peclet number. This is obtained by considering the diffusive-convective heat equation using the Dual Reciprocity Method to transform the corresponding volume integral of the convective terms into equivalent surface integrals.

AB - The integral equation formulation developed previously by the authors to study isothermal micro flows under shear slip boundary condition is extended in this work to consider the case of non-isothermal micro gas flows with thermal creep effects at finite Peclet numbers. The effect of thermal creep over the flow patterns with and without considering the effect of shear slip is investigated in detail using a boundary element method. In this work the boundary integral approaches for both fluid velocity and temperatures fields are used to solve the problem of shear-driven cavity flow at finite Peclet number. This is obtained by considering the diffusive-convective heat equation using the Dual Reciprocity Method to transform the corresponding volume integral of the convective terms into equivalent surface integrals.

KW - Boundary integral solution

KW - Maxwell' slip condition

KW - Micro flow

KW - Rarefied gases

KW - Stokes flow

KW - Thermal creep

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DO - 10.1016/j.ijmecsci.2014.05.016

M3 - Artículo en revista científica indexada

AN - SCOPUS:84908501288

SN - 0020-7403

VL - 88

SP - 267

EP - 275

JO - International Journal of Mechanical Sciences

JF - International Journal of Mechanical Sciences

ER -

A boundary integral equation formulation for the thermal creep gas flow at finite Peclet numbers

Abstract

Bibliographical note

Keywords

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