Numerical analysis of thermodynamic behaviour of through-thickness stitched sandwich laminate

Ai Shigang; Mao Yiqi; Pei Yongmao; Fang Daining; Tang Liqun

doi:10.1007/s10443-013-9327-6

Numerical analysis of thermodynamic behaviour of through-thickness stitched sandwich laminate

Ai Shigang^*, Mao Yiqi, Pei Yongmao, Fang Daining, Tang Liqun

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Effects of stitching angle on mechanical properties, thermal protection capability and induced thermal stress of stitched sandwich laminate (SSL) are numerically analyzed by ABAQUS codes. Interest centers on the potential for microcracking in the vicinity of the through-thickness stitches and the skins/foam interfaces. Two numerical models, in-depth heat transfer and thermoelastic deformation, are coupled to yield the transient response of the SSL. Six different stitching angles are considered and the simulation results showed that: the heat conductivity ability of the SSL is improved as the stitching angle increasing, which alters the mechanical behaviour and the thermal stress state of the SSL.

Original language	English
Pages (from-to)	1161-1171
Number of pages	11
Journal	Applied Composite Materials
Volume	20
Issue number	6
DOIs	https://doi.org/10.1007/s10443-013-9327-6
Publication status	Published - Dec 2013
Externally published	Yes

Keywords

Heat transfer
Periodic boundary condition
Stitched sandwich laminate
Stitching angle
Thermal stress

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10.1007/s10443-013-9327-6

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title = "Numerical analysis of thermodynamic behaviour of through-thickness stitched sandwich laminate",

abstract = "Effects of stitching angle on mechanical properties, thermal protection capability and induced thermal stress of stitched sandwich laminate (SSL) are numerically analyzed by ABAQUS codes. Interest centers on the potential for microcracking in the vicinity of the through-thickness stitches and the skins/foam interfaces. Two numerical models, in-depth heat transfer and thermoelastic deformation, are coupled to yield the transient response of the SSL. Six different stitching angles are considered and the simulation results showed that: the heat conductivity ability of the SSL is improved as the stitching angle increasing, which alters the mechanical behaviour and the thermal stress state of the SSL.",

keywords = "Heat transfer, Periodic boundary condition, Stitched sandwich laminate, Stitching angle, Thermal stress",

author = "Ai Shigang and Mao Yiqi and Pei Yongmao and Fang Daining and Tang Liqun",

year = "2013",

month = dec,

doi = "10.1007/s10443-013-9327-6",

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T1 - Numerical analysis of thermodynamic behaviour of through-thickness stitched sandwich laminate

AU - Shigang, Ai

AU - Yiqi, Mao

AU - Yongmao, Pei

AU - Daining, Fang

AU - Liqun, Tang

PY - 2013/12

Y1 - 2013/12

N2 - Effects of stitching angle on mechanical properties, thermal protection capability and induced thermal stress of stitched sandwich laminate (SSL) are numerically analyzed by ABAQUS codes. Interest centers on the potential for microcracking in the vicinity of the through-thickness stitches and the skins/foam interfaces. Two numerical models, in-depth heat transfer and thermoelastic deformation, are coupled to yield the transient response of the SSL. Six different stitching angles are considered and the simulation results showed that: the heat conductivity ability of the SSL is improved as the stitching angle increasing, which alters the mechanical behaviour and the thermal stress state of the SSL.

AB - Effects of stitching angle on mechanical properties, thermal protection capability and induced thermal stress of stitched sandwich laminate (SSL) are numerically analyzed by ABAQUS codes. Interest centers on the potential for microcracking in the vicinity of the through-thickness stitches and the skins/foam interfaces. Two numerical models, in-depth heat transfer and thermoelastic deformation, are coupled to yield the transient response of the SSL. Six different stitching angles are considered and the simulation results showed that: the heat conductivity ability of the SSL is improved as the stitching angle increasing, which alters the mechanical behaviour and the thermal stress state of the SSL.

KW - Heat transfer

KW - Periodic boundary condition

KW - Stitched sandwich laminate

KW - Stitching angle

KW - Thermal stress

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DO - 10.1007/s10443-013-9327-6

M3 - Article

AN - SCOPUS:84890859932

SN - 0929-189X

VL - 20

SP - 1161

EP - 1171

JO - Applied Composite Materials

JF - Applied Composite Materials

IS - 6

ER -

Numerical analysis of thermodynamic behaviour of through-thickness stitched sandwich laminate

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Keywords

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