Parabolic heat onduction specialized applications involving imperfect contact surfaces: Local discontinuous Galerkin finite element method - Part 2

A. Jain; K. K. Tamma

doi:10.1080/01495731003658788

Parabolic heat onduction specialized applications involving imperfect contact surfaces: Local discontinuous Galerkin finite element method - Part 2

A. Jain, K. K. Tamma

Mechanical Engineering

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5 Scopus citations

Abstract

Parabolic heat conduction specialized applications involving imperfect thermal contact surfaces are analyzed via the Local Discontinuous Galerkin (LDG) finite element method. In this paper, we describe the advantages of the LDG finite element formulation over the traditional continuous Galerkin (CG) finite element method for modeling imperfect thermal contact between surfaces. To-date, mostly interface/gap elements have been primarily used to model the imperfect contact between two surfaces to solve thermal contact resistance problems. The LDG method eliminates the use of such interface/gap elements and provides a higher degree of accuracy. Several illustrative 2-D applications highlight the effectiveness of the present LDG finite element formulations for this class of problems.

Original language	English (US)
Pages (from-to)	344-355
Number of pages	12
Journal	Journal of Thermal Stresses
Volume	33
Issue number	4
DOIs	https://doi.org/10.1080/01495731003658788
State	Published - Apr 2010

Bibliographical note

Funding Information:
Related support in form of computer grants from the Minnesota Supercomputer Institute (MSI), Minneapolis, Minnesota is gratefully acknowledged.

Keywords

Finite elements
Heat conduction
High gradients
Local discontinuous Galerkin method

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title = "Parabolic heat onduction specialized applications involving imperfect contact surfaces: Local discontinuous Galerkin finite element method - Part 2",

abstract = "Parabolic heat conduction specialized applications involving imperfect thermal contact surfaces are analyzed via the Local Discontinuous Galerkin (LDG) finite element method. In this paper, we describe the advantages of the LDG finite element formulation over the traditional continuous Galerkin (CG) finite element method for modeling imperfect thermal contact between surfaces. To-date, mostly interface/gap elements have been primarily used to model the imperfect contact between two surfaces to solve thermal contact resistance problems. The LDG method eliminates the use of such interface/gap elements and provides a higher degree of accuracy. Several illustrative 2-D applications highlight the effectiveness of the present LDG finite element formulations for this class of problems.",

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year = "2010",

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doi = "10.1080/01495731003658788",

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volume = "33",

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AU - Jain, A.

AU - Tamma, K. K.

N1 - Funding Information: Related support in form of computer grants from the Minnesota Supercomputer Institute (MSI), Minneapolis, Minnesota is gratefully acknowledged.

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AB - Parabolic heat conduction specialized applications involving imperfect thermal contact surfaces are analyzed via the Local Discontinuous Galerkin (LDG) finite element method. In this paper, we describe the advantages of the LDG finite element formulation over the traditional continuous Galerkin (CG) finite element method for modeling imperfect thermal contact between surfaces. To-date, mostly interface/gap elements have been primarily used to model the imperfect contact between two surfaces to solve thermal contact resistance problems. The LDG method eliminates the use of such interface/gap elements and provides a higher degree of accuracy. Several illustrative 2-D applications highlight the effectiveness of the present LDG finite element formulations for this class of problems.

KW - Finite elements

KW - Heat conduction

KW - High gradients

KW - Local discontinuous Galerkin method

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Parabolic heat onduction specialized applications involving imperfect contact surfaces: Local discontinuous Galerkin finite element method - Part 2

Abstract

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Keywords

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