Volume 45 Issue 10
Oct.  2024
Turn off MathJax
Article Contents
CUI Youjiang, LIU Chao, CHEN Jiapeng, WANG Biao, WANG Baolin. Thermo-Electric-Mechanical Coupling Bending Property and Strength Analyses of Thermoelectric Devices With the Negative Poisson’s Ratio Architecture[J]. Applied Mathematics and Mechanics, 2024, 45(10): 1243-1255. doi: 10.21656/1000-0887.450113
Citation: CUI Youjiang, LIU Chao, CHEN Jiapeng, WANG Biao, WANG Baolin. Thermo-Electric-Mechanical Coupling Bending Property and Strength Analyses of Thermoelectric Devices With the Negative Poisson’s Ratio Architecture[J]. Applied Mathematics and Mechanics, 2024, 45(10): 1243-1255. doi: 10.21656/1000-0887.450113

Thermo-Electric-Mechanical Coupling Bending Property and Strength Analyses of Thermoelectric Devices With the Negative Poisson’s Ratio Architecture

doi: 10.21656/1000-0887.450113
Funds:

The National Science Foundation of China(12102104)

  • Received Date: 2024-04-24
  • Rev Recd Date: 2024-05-14
  • Available Online: 2024-10-31
  • Publish Date: 2024-10-01
  • The rapid development of smart wearable devices makes a higher requirement for the power supply components, including endurance, convenience and lightweight and so on. The thermoelectric devices can directly convert the thermal energy released by human metabolism into electricity, which can be further used to continuously power the wearable devices. With the global-local and micro-macro combined analysis method, the thermo-electro-mechanical coupling bending behavior and strength failure of a negative Poisson’s ratio thermoelectric device (NPR-TEG) were analyzed. Firstly, the macroscopic bending characteristics and the section with the largest stress were given through the establishment a homogeneous analysis model for the NPR-TEG. Then, the force analysis model for the thermoelectric honeycomb was built. The critical load for the strength failure of a mesoscopic cell wall was also derived with the thermodynamic strength theory. The results show that, the stress level of the thermoelectric honeycomb decreases first and then increases with the re-entrant angle. For the NPR-TEG, the strength failure occurred first in the middle part of the device. For the thermoelectric device with the traditional hexagonal honeycomb, the strength failure occurs at the end of the device rather than the middle part. With the fracture failure occurring in the thermoelectric device, the critical crack length of the middle fracture approximately equals that of the end fracture. The critical crack length could be fitted as an exponential function of the re-entrant angle.
  • loading
  • [2]崔有江, 王保林, 王开发. 多孔泡沫热电器件断裂及其对能量转化性能的影响规律研究[J]. 应用数学和力学, 2023,44(11): 1291-1298.(CUI Youjiang, WANG Baolin, WANG Kaifa. Evaluation of fracture and its effects on energy conversion performance of porous foam thermoelectric generators[J].Applied Mathematics and Mechanics,2023,44(11): 1291-1298.(in Chinese))
    JIANG F, ZHOU X, LV J, et al. Stretchable, breathable, and stable lead-free perovskite/polymer nanofiber composite for hybrid triboelectric and piezoelectric energy harvesting[J].Advanced Materials,2022,34(17): 2200042.
    [3]SHI X L, SUN S, WU T, et al. Weavable thermoelectrics: advances, controversies, and future developments[J].Materials Futures,2024,3(1): 012103.
    [4]YANG Y, DENG H, FU Q. Recent progress on PEDOT: PSS based polymer blends and composites for flexible electronics and thermoelectric devices[J].Materials Chemistry Frontiers,2020,4(11): 3130-3152.
    [5]SUN T T, ZHOU B Y, ZHENG Q, et al. Stretchable fabric generates electric power from woven thermoelectric fibers[J].Nature Communications,2020,11(1): 572.
    [6]NAN K W, KANG S D, LI K, et al. Compliant and stretchable thermoelectric coils for energy harvesting in miniature flexible devices[J].Science Advances,2018,4(11): eaau5849.
    [7]KONG D Y, ZHU W, GUO Z P, et al. High-performance flexible Bi2Te3 films based wearable thermoelectric generator for energy harvesting[J].Energy,2019,175: 292-299.
    [8]ZHAO X, ZHAO C S, JIANG Y F, et al. Flexible cellulose nanofiber/Bi2Te3 composite film for wearable thermoelectric devices[J].Journal of Power Sources,2020,479: 229044.
    [9]KARTHIKEYAN V, SURJADI J U, WONG J C K, et al. Wearable and flexible thin film thermoelectric module for multi-scale energy harvesting[J].Journal of Power Sources,2020,455: 227983.
    [10]CUI Y J, WANG B L, WANG P. Analysis of thermally induced delamination and buckling of thin-film thermoelectric generators made up of pn-junctions[J].International Journal of Mechanical Sciences,2018,149: 393-401.
    [11]KOGO G, XIAO B, DANQUAH S, et al. A thin film efficient pn-junction thermoelectric device fabricated by self-align shadow mask[J].Scientific Reports,2020,10(1): 1067.
    [12]ROJAS J P, SINGH D, CONCHOUSO D, et al. Stretchable helical architecture inorganic-organic hetero thermoelectric generator[J].Nano Energy,2016,30: 691-699.
    [13]XU X J, ZUO Y, CAI S, et al. Three-dimensional helical inorganic thermoelectric generators and photodetectors for stretchable and wearable electronic devices[J].Journal of Materials Chemistry C,2018,6(18): 4866-4872.
    [14]FENG R, TANG F, ZHANG N, et al. Flexible, high-power density, wearable thermoelectric nanogenerator and self-powered temperature sensor[J].ACS Applied Materials & Interfaces,2019,11(42): 38616-38624.
    [15]LEE G, KIM C S, KIM S, et al. Flexible heatsink based on a phase-change material for a wearable thermoelectric generator[J].Energy,2019,179: 12-18.
    [16]FUKUIE K, IWATA Y, IWASE E. Design of substrate stretchability using origami-like folding deformation for flexible thermoelectric generator[J].Micromachines,2018,9(7): 315.
    [17]PARK H, LEE D, KIM D, et al. High power output from body heat harvesting based on flexible thermoelectric system with low thermal contact resistance[J].Journal of Physics D:Applied Physics,2018,51(36): 365501.
    [18]周世奇, 侯秀慧, 邓子辰. 一般宏观应力状态下凹角蜂窝结构的屈曲性能分析[J]. 应用数学和力学, 2023,44(1): 12-24.(ZHOU Shiqi, HOU Xiuhui, DENG Zichen. Buckling analysis of re-entrant honeycomb structures under general macroscopic stress states[J].Applied Mathematics and Mechanics,2023,44(1): 12-24.(in Chinese))
    [19]CUI Y J, LIU C, WANG K F, et al. Effect of negative Poisson’s ratio architecture on fatigue life and output power of flexible wearable thermoelectric generators[J].Engineering Fracture Mechanics,2023,281: 109142.
    [20]CUI Y J, LI W J, WANG K F, et al. Thermal shock fracture of honeycomb-based porous thermoelectric materials with non-Fourier heat conduction[J].Ceramics International,2024,50(1): 2151-2161.
    [21]CUI Y J, WANG B L, WANG K F, et al. An analytical model to evaluate influence of negative Poisson’s ratio architecture on fatigue life and energy conversion performance of wearable thermoelectric generator[J].International Journal of Solids and Structures,2022,258: 112000.
    [22]WE J H, KIM S J, CHO B J. Hybrid composite of screen-printed inorganic thermoelectric film and organic conducting polymer for flexible thermoelectric power generator[J].Energy,2014,73: 506-512.
    [23]HU J S, WANG B L, HIRAKATA H, et al. Interfacial thermal damage and fatigue between auxetic honeycomb sandwich and underneath substrate[J].International Journal of Solids and Structures,2023,279: 112364.
    [24]PENG J, LI D K, HUANG Z X, et al. Interfacial behavior of a thermoelectric film bonded to a graded substrate[J].Applied Mathematics and Mechanics(English Edition),2023,44(11): 1853-1870.
    [25]MIAO X Y, LI C F, PAN Y C. Research on the dynamic characteristics of rotating metal-ceramic matrix DFG-CNTRC thin laminated shell with arbitrary boundary conditions[J].Thin-Walled Structures,2022,179: 109475.
    [26]王彪. 热力学强度理论[J]. 力学进展, 2023,53(3): 693-712.(WANG Biao. Thermodynamic strength theory (TST)[J].Advances in Mechanics,2023,53(3): 693-712.(in Chinese))
    [27]WANG B. The principle of virtual energy for predicting the strength of material structures[J].Engineering Fracture Mechanics,2024,300: 109997.
    [28]JANSSEN M, ZUIDEMA J, WANHILL R J H.Fracture Mechanics[M]. 2nd ed. London: Spon Press, 2004: 83-106.
    [29]蒋玉川, 蒲淳清. 用Westergaard应力函数求解Ⅰ-Ⅱ复合型平面裂纹问题的研讨[J]. 力学与实践, 2020,42(4): 504-507.(JIANG Yuchuan, PU Chunqing. The problem of Ⅰ-Ⅱ combined plane crack solved with Westergaard stress function[J].Mechanics in Engineering,2020,42(4): 504-507.(in Chinese))
  • 加载中

Catalog

    通讯作者: 陈斌, bchen63@163.com
    • 1. 

      沈阳化工大学材料科学与工程学院 沈阳 110142

    1. 本站搜索
    2. 百度学术搜索
    3. 万方数据库搜索
    4. CNKI搜索

    Article Metrics

    Article views (134) PDF downloads(48) Cited by()
    Proportional views
    Related

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return