论文著作

[1]     X Yang, JF Guo, HN Cheng, P Wei, YL He. Role of non-uniformly distributed annular fins on the thermal performance of a shell-and-tube thermal energy storage unit[J]. Applied Energy, accepted.

[2]     T Xiao, X Yang*, TJ Lu*. An analytical fractal model for permeability in isotropic metal foam with fully or semi open cells[J]. Journal of Physics D-Applied Physics, under review.

[3]     X Yang, ZX Guo, JF Guo, YL He. Effect of inclination on the melting phase change in a rectangle cavity with carious aspect ratios[J]. International Journal of Energy Research, under review.

[4]     Z Liu, ZH Liu, H Li, X Cao, X Yang*. Performance assessment of a self-condensing transcritical CO2 cogeneration system with extraction turbine and ejector refrigeration cycle[J]. Energy, accepted.

[5]     Z Liu, XR Wang, XQ Yang, SJ Yang, H Li, X Yang*. Energy and exergy analysis of a trigeneration system based on an underwater compressed air energy storage and an ejector refrigeration cycle[J]. Journal of Cleaner Production, accepted.

[6]     Z Liu, XQ Yang, WG Jia, H Li, X Yang*. Thermodynamic study on a combined heat and compressed air energy storage system with a dual-pressure organic Rankine cycle[J]. Energy Conversion and Management, accepted.

[7]     X Yang, ZY Niu, QS Bai, H Li, YL He. Optimization of solidification heat transfer in fin-foam composite structure for cold storage[J]. International Communications in Heat and Mass Transfer, accepted.

[8]     Z Liu, ZH Liu, X Yang*,X Xin. Proposal and assessment of a novel carbon dioxide energy storage system with electrical thermal storage and ejector condensing cycle: energy and exergy analysis[J]. Applied Energy, accepted.

[9]     X Yang, P Wei, Wang XY, YL He. Gradient design of pore parameters on the melting process in a thermal energy storage unit filled with open-cell metal foam[J]. Applied Energy, accepted.

[10]  X Yang, P Wei, Liu G, QS Bai, YL He. Performance evaluation on the gradient design of pore parameters for metal foam and pin fin-metal foam hybrid structure[J]. Applied Thermal Engineering, accepted.

[11]  QL Zhang, Y Niu, X Yang, DH Sun, X Xiao, Q Shen, G Wang. Experimental study on flue gas condensing heat recovery synergized with low nitrogen emission system[J]. Applied Energy, accepted.

[12]  Z Liu, XQ Yang, X Yang*, HY Zhai, ZY Duan. Performance evaluation on the in-cylinder heat transfer of a reciprocating compressor using CO2 as a working fluid[J]. Journal of Thermal Science, accept.

[13]  Z Liu, ZH Liu, X Cao, T Luo, X Yang*. Advanced exergoeconomic evaluation on supercritical CO2 recompression Brayton cycle[J]. Journal of Cleaner Production, accept. 

[14]  Z Liu, ZH Liu, XQ Yang, HY Zhai, X Yang. Advanced exergy and exergoeconomic analysis of a novel liquid carbon dioxide energy storage system[J]. Energy Conversion and Management, accept.

[15]  Z Liu, XQ Yang, WG Jia, H Li, X Yang*. Justification of CO2 as the working fluid for a compressed gas energy storage system: a thermodynamic and economic study[J]. Journal of Energy Storage, accept.

[16]  X Yang, JB Yu, ZH Hu, LW Jin, YL He. Design and operating evaluation of a finned shell-and-tube thermal energy storage unit filled with metal foam[J]. Applied Energy, accept.

[17]  X Cui, X Yang, QX Kong, XZ Meng, LW Jin. Performance evaluation and comparison of multi-stage indirect evaporative cooling systems in two operation modes[J]. International Journal of Energy Research, 2019: 1-11.

[18]  YL Liu, LW Jin, Li Y, X Yang, XZ Meng, LY Zhang*. Experimental and numerical study on heat and mass transfer of cross-flow liquid desiccant dehumidifier/regenerator[J]. Heat Transfer Engineering, 2019, in press.

[19]  X Yang, ZY Niu, QS Bai, H Li, X Cui, YL He. Experimental study on the solidification process of fluid saturated in fin-foam composites for cold storage[J]. Applied Thermal Engineering, 2019, 161: 114163.

[20]  Z Liu, Liu B, Guo JZ, Xin X, X Yang*. Conventional and advanced exergy analysis of a novel transcritical compressed carbon dioxide energy storage system[J]. Energy Conversion and Management, 2019, 198: 111807.

[21]  X Yang, P Wei, X Cui, LW Jin, YL He. Thermal response of annuli filled with metal foam for thermal energy storage: an experimental study[J]. Applied Energy, 2019 250:1457-1467.

[22]  X Yang, JB Yu, ZX Guo, LW Jin, YL He. Role of porous metal foam on the heat transfer enhancement for a thermal energy storage tube[J]. Applied Energy, 2019, 239:142-156.

[23]  X Yang, ZX Guo, YH Liu, LW Jin, YL He. Effect of inclination on the thermal response of composite phase changematerials for thermal energy storage[J]. Applied Energy, 2019, 238:22-33.

[24]  X Yang, QS Bai, ZX Guo, ZY Niu, C Yang, LW Jin, TJ Lu, J Yan. Comparison of direct numerical simulation with volume-averaged method on composite phase change materials for thermal energy storage[J]. Applied Energy, 2018, 229:700-714.

[25]  X Yang, QS Bai, QL Zhang, WJ Hu, LW Jin, J Yan. Thermal and economic analysis of charging and discharging characteristics of composite phase change materials for cold storage [J]. Applied Energy, 2018, 225:585-599.

[26]  X Yang, Li Y, LY Zhang, LW Jin, WJ Hu, TJ Lu. Thermal and fluid transport in micro open-cell metal foams: effect of node size[J]. Journal of Heat Transfer, 2018, 140: 014502-1.

[27]  SY Song, X Yang, FX Xin, TJ Lu. Analytical modeling of surface roughness effects on Stokes flow in circular pipes[J]. Physics of Fluids, 2018, 30: 023604.

[28]  HB Yan, X Yang, TJ Lu, GN Xie. Convective heat transfer in a lightweight multifunctional sandwich panel with X-type metallic lattice core[J]. Applied Thermal Engineering, 2017, 127:1293-1304.

[29]  SY Song, X Yang*, FX Xin, SW Ren, TJ Lu*. Modeling of roughness effects on acoustic properties of micro-slits [J]. Journal of Physics D: Applied Physics, 2017, 50:235303.

[30]  X Yang, Z Lu, QS Bai, QL Zhang, LW Jin, J Yan. Thermal performance of a shell-and-tube latent heat thermal energy storage unit: role of annular fins[J]. Applied Energy, 2017, 202:558-570.

[31]  X Yang, SY Song, C Yang, WJ Hu, FS Han, LW Jin, TJ Lu. Permeability model of micro-metal foam with surface micro-roughness[J]. Microfluidics and Nanofluidics, 2017, 21:32.

[32]  Y Chai, X Yang, XZ Meng, M Zhao, ZY Chen, LW Jin. Study of micro-structure based effective thermal conductivity of graphite foam[J]. Journal of Heat Transfer, 2017, 139: 052004-1.

[33]  X Yang, SS Feng, QL Zhang, C Yang, LW Jin, TJ Lu. The role of porous metal foam on the unidirectional solidification of saturating fluid for cold storage[J]. Applied Energy, 2017, 194: 508–521.

[34]  X Yang, WB Wang, LL Yan, QC Zhang, TJ Lu. Effect of pore morphology on cross-property link for close-celled metallic foams[J]. Journal of Physics D: Applied Physics, 2016, 49: 505301.

[35]  WB Wang, X Yang, B Han, QC Zhang, TJ Lu. Analytical design of effective thermal conductivity for fluid-saturated prismatic cellular metal honeycombs[J]. Theoretical and Applied Mechanics Letters, 2016, 6: 69-75.

[36]  H Meng, X Yang, SW Ren, FX Xin, TJ Lu. Sound propagation in composite micro-tubes with surface-mounted fibrous roughness elements[J]. Composites Science and Technology, 2016, 127: 158–168.

[37]  X Yang, WB Wang, C Yang, LW Jin, TJ Lu. Solidification of fluid saturated in open-cell metallic foams with graded morphologies[J]. Internatinal Journal of Heat and Mass Transfer, 2016, 98:60-69.

[38]  HB Yan, SS Feng, X Yang, TJ Lu. Role of cross-drilled holes in enhanced cooling of ventilated brake disc[J]. Applied Thermal Engineering, 2015, 91: 318-333.

[39]  QC Zhang, X Yang, P Li, GY Huang, SS Feng, C Shen, B Han, XH Zhang, F Jin, F Xu, TJ Lu. Bioinspired Engineering of Honeycomb Structure - Using Nature to Inspire Human Innovation[J]. Progress in Materials Science, 2015, 74: 332-400 (IF: 31.14).

[40]  X Yang, SW Ren, WB Wang, X Liu, Xin XF, TJ Lu. A simplistic unit cell model for sound absorption of cellular foams with fully/semi-open cells [J]. Composites Science and Technology, 2015, 118: 276-283.

[41]  X Yang, HB Yan, WB Wang, LW Jin, TJ Lu, K Ichimiya. Thermo-fluidic characteristics of natural convection in honeycombs: The role of chimney enhancement[J]. Science in China: Technological Series, 2015, 58(8): 1318-1327.

[42]  X Yang, JX Bai, KJ Kang, TJ Lu, T Kim. Effective thermal conductivity of wire-woven bulk Kagome sandwich panels[J]. Theoretical and Applied Mechanics Letters, 2014, 4(5): 051010-1-6.

[43]  X Yang, TJ Lu, T Kim. An analytical model for permeability of isotropic porous media[J]. Physics Letters A, 2014, 378(30-31): 2308-2311.

[44]  X Yang, JX Bai, TJ Lu, T Kim. Experimental investigation of chimney-enhanced natural convection in hexagonal honeycombs[J]. Theoretical and Applied Mechanics Letters, 2014, 4(3): 032005-1-6

[45]  X Yang, JX Bai, KJ Kang, TJ Lu, T Kim. Experimental investigations of natural convection in Wire-woven bulk Kagome[J]. Transport in Porous Media, 2014, 105(1): 1-22.

[46]  X Yang, JX Bai, HB Yan, JJ Kuang, TJ Lu, T Kim. An analytical unit cell model for the effective thermal conductivity of high porosity open-cell metal foams[J]. Transport in Porous Media, 2014, 102(3): 403-426.

[47]  X Yang, TJ Lu, T Kim. Effective thermal conductivity modeling for closed-cell porous media with analytical shape factors[J]. Transport in Porous Media, 2013, 100(2): 211-224.

[48]  X Yang, JJ Kuang, FS Han, TJ Lu, T Kim. A simplistic analytical unit cell based model for the effective thermal conductivity of high porosity metal foams with open cells[J]. Journal of Physics D: Applied Physics, 2013, 46(25): 255302-1-6.

[49]  X Yang, TJ Lu, T Kim. Thermal stretching in two-phase porous media: physical basis of Maxwell model[J]. Theoretical and Applied Mechanics Letters, 2013, 3(2): 021011-1-5.

[50]  X Yang, TJ Lu, T Kim. A simplistic model for the tortuosity in two-phase close-celled porous media[J]. Journal of Physics D: Applied Physics, 2013, 46(12): 125305-1-4.

[51]  X Yang, TJ Lu, T Kim. Influence of non-conducting pore inclusions on phase change behavior of porous media with constant heat flux boundary[J]. International Journal of Thermal Sciences, 2013, 64: 137-144.

[52]  X Yang, TJ Lu, T Kim. Temperature effects on the effective thermal conductivity of phase change materials with two distinctive phases[J]. International Communications in Heat and Mass Transfer, 2011, 38(10): 1344-1348.