Analytical layer-element method for 3D thermoelastic problem of layered medium around a heat source
详细信息 查看全文
- 作者:Zhi-Yong Ai (1)
Lu-Jun Wang (1)
Kai Zeng (1) - 关键词:Analytical layer ; element ; Thermoelastic problems ; Layered medium ; Heat source
- 刊名:Meccanica
- 出版年:2015
- 出版时间:January 2015
- 年:2015
- 卷:50
- 期:1
- 页码:49-59
- 全文大小:590 KB
- 参考文献:1. Delage P, Sultan N, Cui YJ (2000) On the thermal consolidation of Boom clay. Can Geotech J 37:343-54 CrossRef
2. Tomasz H, Rita P (2002) Reactive plasticity for clays: application to a natural analog of long-term geomechanical effects of nuclear waste disposal. Eng Geol 64:195-15 CrossRef
3. Amatya BL, Soga K, Bourne-webb PJ et al (2012) Thermo-mechanical behavior of energy piles. Géotechnique 62:503-19 CrossRef
4. Malekzadeh P, Ghaedsharaf M (2014) Three-dimensional thermoelastic analysis of finite length laminated cylindrical panels with functionally graded layers. Meccanica 49:887-06 CrossRef
5. Dai HL, Dai T (2014) Analysis for the thermoelastic bending of a functionally grade material cylindrical shell. Meccanica 49:1069-081 CrossRef
6. Biot MA (1956) Thermoelasticity and Irreversible Thermodynamics. J Appl Phys 27:240-53 CrossRef
7. Keramidas GA, Ting EC (1976) A finite element formulation for thermal stress analysis. Part I: variational formulation. Nucl Eng Des 39:267-75 CrossRef
8. Keramidas GA, Ting EC (1976) A finite element formulation for thermal stress analysis. Part II: finite element formulation. Nucl Eng Des 39:277-87
9. Booker JR, Savvidou C (1985) Consolidation around a point heat source. Int J Numer Anal Methods Geomech 9:173-84 CrossRef
10. Savvidou C, Booker JR (1989) Consolidation around a heat source buried deep in a porous thermoelastic medium with anisotropic flow properties. Int J Numer Anal Methods Geomech 13:75-0 CrossRef
11. Carter JP, Booker JR (1989) Finite element analysis of coupled thermoelasticity. Comput Struct 31:73-0 CrossRef
12. Kumar R, Rani L (2004) Response of generalized thermoelastic half-space with voids due to mechanical and thermal sources. Meccanica 39:563-84 CrossRef
13. Yu L, Chen GJ (2009) Transient heat and moisture flow around heat source buried in an unsaturated half space. Transp Porous Media 78:233-57 CrossRef
14. Abbas IA, Abd-alla AN (2008) Effects of thermal relaxations on the thermoelastic interactions in an infinite orthotropic elastic medium with a cylindrical cavity. Arch Appl Mech 78:283-93 CrossRef
15. Abbas IA, Youssef HM (2013) Two-temperature generalized thermoelasticity under ramp-type heating by finite element method. Meccanica 48:331-39 CrossRef
16. Small JC, Booker JR (1986) The behavior of layered soil or rock containing a decaying heat source. Int J Numer Anal Methods Geomech 10:501-19 CrossRef
17. Yue ZQ (1988) Solution for the thermoelastic problem in vertically inhomogeneous media. Acta Mech Sin 4:182-89 CrossRef
18. Wu GC (1997) The analytic theory of the temperature fields of bituminous pavement over semi-rigid road base. Appl Math Mech 18:181-90 CrossRef
19. Lee SL, Yang JH (1998) Modelling of effective thermal conductivity for a nonhomogeneous anisotropic porous medium. Int J Heat Mass Transf 41:931-37 Zhi-Yong Ai (1)
Lu-Jun Wang (1)
Kai Zeng (1)
1. Department of Geotechnical Engineering, Key Laboratory of Geotechnical and Underground Engineering of Ministry of Education, Tongji University, 1239 Siping Road, Shanghai, 20092, China - ISSN:1572-9648
文摘
This paper presents a numerically efficient and stable method to study the thermoelastic problem of layered medium containing a heat source. Based on the governing equations of 3D thermoelasticity, the relationship between generalized displacements and stresses of a single layer is described by an analytical layer-element, which is obtained in the Laplace–Fourier transformed domain by using the eigenvalue approach. Considering the continuity conditions between adjacent layers, the global stiffness matrix of layered medium is gotten by assembling the interrelated layer-elements. Once the solution in the transformed domain is obtained, the actual solution can be recovered by an inverse transformation. Finally, numerical examples are given to study the influence of the layered medium’s properties on the behavior of thermoelastic problems.