Modeling of Heat Conduction in Thermoplastic Honeycomb Core/Face Sheet Fusion Bonding 被引量：3

Modeling of Heat Conduction in Thermoplastic Honeycomb Core/Face Sheet Fusion Bonding

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摘要 Honeycomb sandwich materials have been widely used in aerospace industry as secondary structural materials or interior panels. Recently the research of full thermoplastic honeycomb sandwich materials has been of interest due to their recyclability. In their production, they usually demand an adhesive-free process, namely fusion bonding, to connect thermoplastic honeycomb core and face sheets. It is a heat induced process where a parameter of temperature should be well controlled to guarantee the product quality. This article presents a mathematical model of heat conduction to analyze the transient temperature distribution from heating tools towards inner part of the core under fusion bonding conditions. In order to simplify the complexity of 3D honeycomb geometry, a homogenization method is used to obtain average thermal properties of the honeycomb along the major heat flux direction. The model is validated by comparing with the results of in-situ temperature measurement during fusion bonding. The presented model can also be applied to analyzing general out-of-plane heat conduction through honeycomb sandwich structures made from other materials. Honeycomb sandwich materials have been widely used in aerospace industry as secondary structural materials or interior panels. Recently the research of full thermoplastic honeycomb sandwich materials has been of interest due to their recyclability. In their production, they usually demand an adhesive-free process, namely fusion bonding, to connect thermoplastic honeycomb core and face sheets. It is a heat induced process where a parameter of temperature should be well controlled to guarantee the product quality. This article presents a mathematical model of heat conduction to analyze the transient temperature distribution from heating tools towards inner part of the core under fusion bonding conditions. In order to simplify the complexity of 3D honeycomb geometry, a homogenization method is used to obtain average thermal properties of the honeycomb along the major heat flux direction. The model is validated by comparing with the results of in-situ temperature measurement during fusion bonding. The presented model can also be applied to analyzing general out-of-plane heat conduction through honeycomb sandwich structures made from other materials.

作者 Fan Xinyu Li Yubin Li Juan Yan Chun Li Ke

机构地区 Key Lab of Polymer Materials School of Materials Science and Engineering Xi'an Long Technology & Development Co.

出处《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2009年第6期685-690,共6页 中国航空学报（英文版）

关键词 honeycomb structures heat conduction homogenization method WELDING honeycomb structures heat conduction homogenization method welding

分类号 TK124 [动力工程及工程热物理—工程热物理] V414.6 [动力工程及工程热物理—热能工程]

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Chinese Journal of Aeronautics

2009年第6期

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Modeling of Heat Conduction in Thermoplastic Honeycomb Core/Face Sheet Fusion Bonding 被引量：3

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