Hybrid Thermoelastic Stress Analysis

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• 作者：S. J. Lin (1)
  W. A. Samad (2)
  A. A. Khaja (3)
  R. E. Rowlands (4)
  
  1. National Kaohsiung University of Applied Sciences ; Kaohsiung ; Taiwan ; Republic of China
  2. Rochester Institute of Technology鈥揇ubai ; Dubai ; UAE
  3. Applied Materials ; Inc. ; Santa Clara ; CA ; 95054 ; USA
  4. University of Wisconsin ; Madison ; WI ; 53706 ; USA
  
• 关键词：Thermoelasticity ; Hybrid method ; Stress ; separation ; Stress intensity factors
• 刊名：Experimental Mechanics
• 出版年：2015
• 出版时间：April 2015
• 年：2015
• 卷：55
• 期：4
• 页码：653-665
• 全文大小：8,170 KB
• 参考文献：1. Greene, RJ, Patterson, EA, Rowlands, RE Thermoelastic stress analysis, Ch. 26. In: Sharpe, WM eds. (2008) Handbook of experimental solid mechanics. Springer, New York
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  10. Foust, BE, Rowlands, RE (2011) Thermoelastic determination of individual stresses in a diametrically-loaded disk. Strain 47: pp. 146-153 CrossRef
  11. Lin, SJ, Matthys, DR, Rowlands, RE (2009) Separating stresses thermoelastically in a central circularly perforated plate using an Airy stress function. Strain 45: pp. 516-526 CrossRef
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  14. Aziz AA (2010) Thermoelastically determined stresses around neighboring holes in finite structures whose stress fields interact, MS thesis, University of Wisconsin, Madison, WI
  15. Lin, SJ, Quinn, S, Matthys, DR, New, AM, Kincaid, IM, Boyce, BR, Khaja, AA, Rowlands, RE (2011) Thermoelastic determination of individual stresses in vicinity of a near-edge hole beneath a concentrated load. Exp Mech 51: pp. 797-814 CrossRef
  16. Lin, SJ, Matthys, DR, Quinn, S, Davidson, JP, Boyce, BR, Khaja, AA, Rowlands, RE (2012) Stresses at and in the neighborhood of a near-edge hole in a plate subjected to an offset load from measured temperatures. Eur J Mech A-Solid 39C: pp. 209-217
  17. Lin SJ, Matthys DR, Samad WA, Khaja AA, Boyce BR, Rowlands RE (2012) Infrared stress analysis of unsymmetrically-loaded perforated member, ISEM-ACEM-SEM-7th ISEM鈥?2-Taipei, Taiwan
  18. Samad WA, Khaja AA, Kaliyanda AR, Rowlands RE (2013) Hybrid thermoelastic stress analysis of a pinned joint. Exp Mech. doi:10.1007/s11340-013-9822-6
  19. Khaja AA, Rowlands RE (2013) Experimentally determined stresses associated with elliptical holes using polar coordinates. Strain 49(2):116鈥?24
  20. Samad WA, Rowlands RE (2013) Full-field thermoelastic stress analysis of a finite structure containing an irregularly-shaped hole. Exp Mech. doi:10.1007/s11340-013-9821-7
  21. Samad WA, Rowlands RE (2012) Hybrid full-field stress analysis of finite structures containing arbitrarily shaped cutouts, ISEM-ACEM-SEM-7th ISEM鈥?2-Taipei, Taiwan
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  34. Ni YY, Rowlands RE (2002) Thermoelastically-measured isopachics and BEM for inverse stress analysis on and adjacent to loaded and traction-free boundaries, Session Honoring Prof. J. W. Daly, 14th US Nat鈥檒 Cong. Theor. & Appl. Mechanics, Blacksburg
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  38. Tomlinson, RA, Nurse, AD, Patterson, EA (1997) On determining stress intensity factors for mixed mode cracks from thermoelastic data. Fatigue Fract Eng Mater Struct 20: pp. 217-226 CrossRef
  39. Lin, ST, Feng, Z, Rowlands, RE (1997) Thermoelastic determination of stress intensity factors in orthotropic composites using the J-integral. Eng Fract Mech 56: pp. 579-592 CrossRef
  40. Ju, SH, Rowlands, RE (2003) Mixed-mode thermoelastic fracture analysis of orthotropic composites. Int J Fract 120: pp. 601-621 CrossRef
  41. Ju, SH, Rowlands, RE (2003) Thermoelastic determination of KI and KII in an orthotropic graphite epoxy composite. J Compos Mater 37: pp. 2011-2025 CrossRef
  42. He, KY, Rowlands, RE (2004) Determining stress intensity factors in orthotropic composites from far-field measured temperatures. Exp Mech 44: pp. 555-561 CrossRef
  43. Ju, SH, Rowlands, RE (2007) Thermoelastic determination of crack-tip coordinates in composites. Int J Solids Struct 44: pp. 4845-4859 CrossRef
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  45. Murakami, Y, Yoshimura, Y (1997) Determination of all stress components from measurements of the stress invariant by the thermoelastic stress methods. Int J Solids Struct 34: pp. 4449-4461 CrossRef
  46. Gao, XL, Rowlands, RE (2000) Hybrid method for stress analysis of finite three- dimensional elastic solids. Int J Solids Struct 37: pp. 2727-2751 CrossRef
  47. Wong AK (11991) A non-adiabatic thermoelastic theory and use of SPATE on composite laminates, Proc. 9^th Int鈥檒. Conf. on Exper. Mech., ICEM9, Copenhagen, August, 20鈥?4; also Wang AK (1991) A non-adiabatic thermoelastic theory for composite laminates. J Phys Chem Solids 51:483鈥?94
  48. Sigimoto S, Rowlands RE, Ishikawa T (2001) A thermal conductivity analysis affecting thermoelastic stress measurement of laminated composites, Int鈥檒 Conf. on Composite Materials (ICCM-13), Beijing, China
  
• 刊物类别：Engineering
• 刊物主题：Mechanical Engineering
  Theoretical and Applied Mechanics
  Characterization and Evaluation Materials
  Structural Mechanics
  Engineering Fluid Dynamics
  Engineering Design
  
• 出版者：Springer Boston
• ISSN：1741-2765

文摘

Solids, like a confined gas, experience an increase in temperature when compressively loaded and a temperature decrease when stressed in tension. While such stress-induced temperature changes at a point in a solid are related to a linear combination of the local changes in the normal stresses, it is often necessary to know the individual stress components. An effective means to determine the individual stresses in engineering structures is to combine the measured thermal data with Airy stress function relevant mechanics information or analyses. Results demonstrate the ability of this general concept to provide reliable, full-field stresses in a range of engineering situations involving cracks or geometric discontinuities in isotropic or orthotropic composite materials.