Three-Dimensional Inverse Heat Transfer in a Composite Target Subject to High-Energy Laser Irradiation

Jianhua Zhou; Yuwen Zhang; J. K. Chen; Z. C. Feng

Source: Journal of Heat Transfer:;2012:;volume( 134 ):;issue: 011::page 111201

Author:

DOI: 10.1115/1.4006107

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: A new numerical model is developed to simulate the 3D inverse heat transfer in a composite target with pyrolysis and outgassing effects. The gas flow channel size and gas addition velocity are determined by the rate equation of decomposition chemical reaction. The thermophysical properties of the composite considered are temperature-dependent. A nonlinear conjugate gradient method (CGM) is applied to solve the inverse heat conduction problem for high-energy laser-irradiated composite targets. It is shown that the front-surface temperature can be recovered with satisfactory accuracy based on the temperature/heat flux measurements on the back surface and the temperature measurement at an interior plane.

keyword(s): Temperature , Heat transfer , Channels (Hydraulic engineering) , Lasers , Composite materials , Heat conduction , Gas flow , Pyrolysis , Heat flux , Equations , Irradiation (Radiation exposure) AND Simulation ,

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Three-Dimensional Inverse Heat Transfer in a Composite Target Subject to High-Energy Laser Irradiation

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contributor author	Jianhua Zhou
contributor author	Yuwen Zhang
contributor author	J. K. Chen
contributor author	Z. C. Feng
date accessioned	2017-05-09T00:51:53Z
date available	2017-05-09T00:51:53Z
date copyright	November, 2012
date issued	2012
identifier issn	0022-1481
identifier other	JHTRAO-926057#111201_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/149309
description abstract	A new numerical model is developed to simulate the 3D inverse heat transfer in a composite target with pyrolysis and outgassing effects. The gas flow channel size and gas addition velocity are determined by the rate equation of decomposition chemical reaction. The thermophysical properties of the composite considered are temperature-dependent. A nonlinear conjugate gradient method (CGM) is applied to solve the inverse heat conduction problem for high-energy laser-irradiated composite targets. It is shown that the front-surface temperature can be recovered with satisfactory accuracy based on the temperature/heat flux measurements on the back surface and the temperature measurement at an interior plane.
publisher	The American Society of Mechanical Engineers (ASME)
title	Three-Dimensional Inverse Heat Transfer in a Composite Target Subject to High-Energy Laser Irradiation
type	Journal Paper
journal volume	134
journal issue	11
journal title	Journal of Heat Transfer
identifier doi	10.1115/1.4006107
journal fristpage	111201
identifier eissn	1528-8943
keywords	Temperature
keywords	Heat transfer
keywords	Channels (Hydraulic engineering)
keywords	Lasers
keywords	Composite materials
keywords	Heat conduction
keywords	Gas flow
keywords	Pyrolysis
keywords	Heat flux
keywords	Equations
keywords	Irradiation (Radiation exposure) AND Simulation
tree	Journal of Heat Transfer:;2012:;volume( 134 ):;issue: 011
contenttype	Fulltext

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