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    Journals >Acta Physica Sinica >Volume 69 >Issue 5 >Page 056501-1 > Article
    • Acta Physica Sinica
    • Vol. 69, Issue 5, 056501-1 (2020)
    Thermal rectification mechanism of one-dimensional composite structure with interface thermal contact resistance
    Jian-Ning Zhao1, Dong-Huan Liu1、*, Dong Wei2, and Xin-Chun Shang1
    Author Affiliations
  • 1Beijing Key Laboratory for Magneto-Photoelectrical Composite and Interface Science, School of Mathematics and Physics, University of Science and Technology Beijing, Beijing 100083, China
  • 2Computational Aerodynamics Institute, China Aerodynamics Research and Development Center, Mianyang 621000, China
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    DOI: 10.7498/aps.69.20191409 Cite this Article
    Jian-Ning Zhao, Dong-Huan Liu, Dong Wei, Xin-Chun Shang. Thermal rectification mechanism of one-dimensional composite structure with interface thermal contact resistance[J]. Acta Physica Sinica, 2020, 69(5): 056501-1 Copy Citation Text show less
    Schematic of the one-dimensional composite thermal rectifier model with variable cross section area and thermal conductivity: (a) Forward heat flows from left to right; (b) reverse heat flows from right to left.
    Fig. 1. Schematic of the one-dimensional composite thermal rectifier model with variable cross section area and thermal conductivity: (a) Forward heat flows from left to right; (b) reverse heat flows from right to left.
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    Finite element model of the thermal rectifier.
    Fig. 2. Finite element model of the thermal rectifier.
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    Comparisons of temperature distribution of the thermal rectifier (Reverse and Forward denote the case of that LaCoO3 and La0.7Sr0.3CoO3 materials locate in high-temperature side respectively).
    Fig. 3. Comparisons of temperature distribution of the thermal rectifier (Reverse and Forward denote the case of that LaCoO3 and La0.7Sr0.3CoO3 materials locate in high-temperature side respectively).
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    Response of the thermal rectifier with different temperature differences: (a) Heat flux; (b) thermal rectification ratio.
    Fig. 4. Response of the thermal rectifier with different temperature differences: (a) Heat flux; (b) thermal rectification ratio.
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    Relationship between cross-section area and cross-section radius change rate.
    Fig. 5. Relationship between cross-section area and cross-section radius change rate.
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    Temperature distribution of the thermal rectifier with different length ratios: (a) Length ratio is 0.5; (b) length ratio is 0.2.
    Fig. 6. Temperature distribution of the thermal rectifier with different length ratios: (a) Length ratio is 0.5; (b) length ratio is 0.2.
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    Variations of thermal rectification coefficient with length ratio under different contact thermal resistance: (a) ; (b) –0.03
    Fig. 7. Variations of thermal rectification coefficient with length ratio under different contact thermal resistance: (a) ; (b) –0.03
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    Variations of thermal rectification coefficient with length ratio at different boundary temperature differences: (a) ; (b)
    Fig. 8. Variations of thermal rectification coefficient with length ratio at different boundary temperature differences: (a) ; (b)
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    Variations of thermal rectification coefficient with length ratio at different length variation ratio.
    Fig. 9. Variations of thermal rectification coefficient with length ratio at different length variation ratio.
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    Abstract
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    Jian-Ning Zhao, Dong-Huan Liu, Dong Wei, Xin-Chun Shang. Thermal rectification mechanism of one-dimensional composite structure with interface thermal contact resistance[J]. Acta Physica Sinica, 2020, 69(5): 056501-1
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