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英文论文:
[1] Z.N. Sun, Mechanism of convection heat transfer on a heated crystal surface, Heat Transfer - Asian Research, 29(7) (2000) 573-580.
[2] L. Du, R. Tian, P. Zhang, Z. Sun, Numerical simulation and experiment investigating the performance of a capacitance sensor measuring the humidity of wet steam, Measurement Science and Technology, 22(12) (2011).
[3] X. Meng, Z. Sun, G. Xu, Single-phase convection heat transfer characteristics of pebble-bed channels with internal heat generation, Nuclear Engineering and Design, 252 (2012) 121-127.
[4] M. Ali, C. Yan, Z. Sun, H. Gu, K. Mehboob, Dust particle removal efficiency of a venturi scrubber, Annals of Nuclear Energy, 54 (2013) 178-183.
[5] M. Ali, C. Yan, Z. Sun, H. Gu, J. Wang, Study of iodine removal efficiency in self-priming venturi scrubber, Annals of Nuclear Energy, 57 (2013) 263-268.
[6] M. Ali, C. Yan, Z. Sun, H. Gu, J. Wang, K. Mehboob, Iodine removal efficiency in non-submerged and submerged self-priming venturi scrubber, Nuclear Engineering and Technology, 45(2) (2013) 203-210.
[7] M. Ali, C. Yan, Z. Sun, J. Wang, H. Gu, CFD simulation of dust particle removal efficiency of a venturi scrubber in CFX, Nuclear Engineering and Design, 256 (2013) 169-177.
[8] J. Su, Z. Sun, G. Fan, M. Ding, Experimental study of the effect of non-condensable gases on steam condensation over a vertical tube external surface, Nuclear Engineering and Design, 262 (2013) 201-208.
[9] J. Su, Z. Sun, M. Ding, G. Fan, Analysis of experiments for the effect of noncondensable gases on steam condensation over a vertical tube external surface under low wall subcooling, Nuclear Engineering and Design, 278 (2014) 644-650.
[10] J. Su, Z. Sun, D. Zhang, Numerical analysis of steam condensation over a vertical surface in presence of air, Annals of Nuclear Energy, 72 (2014) 268-276.
[11] J. Wang, X. Guo, S. Yu, B. Cai, Z. Sun, C. Yan, Study on the behaviors of a conceptual passive containment cooling system, Science and Technology of Nuclear Installations, 2014 (2014).
[12] G. Xu, Z. Sun, X. Meng, X. Zhang, Flow boiling heat transfer in volumetrically heated packed bed, Annals of Nuclear Energy, 73 (2014) 330-338.
[13] G. Xu, Z. Sun, X. Meng, X. Zhang, A study of bubble behaviors in the volumetrically heated packed bed, Progress in Nuclear Energy, 76 (2014) 100-105.
[14] X. Guo, Z. Sun, J. Wang, S. Yu, Simulating investigations on the start-up of the open natural circulation system, Nuclear Engineering and Design, 289 (2015) 35-48.
[15] X. Guo, Z. Sun, J. Wang, S. Yu, L. Gao, Numerical simulation of the transient behaviors in an open natural circulation system with a large scale, Annals of Nuclear Energy, 77 (2015) 83-93.
[16] P. Tong, G. Fan, Z. Sun, M. Ding, Experimental study of steam-air condensation over a vertically longitudinal finned tube, International Journal of Heat and Mass Transfer, 89 (2015) 1230-1238.
[17] P. Tong, G. Fan, Z. Sun, M. Ding, J. Su, An experimental investigation of pure steam and steam-air mixtures condensation outside a vertical pin-fin tube, Experimental Thermal and Fluid Science, 69 (2015) 141-148.
[18] Y. Zhou, Z. Sun, H. Gu, Z. Miao, Experimental research on aerosols collection performance of self-priming venturi scrubber in FCVS, Progress in Nuclear Energy, 85 (2015) 771-777.
[19] Y. Zhou, Z. Sun, H. Gu, Z. Miao, Structure design on improving injection performance for venturi scrubber working in self-priming mode, Progress in Nuclear Energy, 80 (2015) 7-16.
[20] X. Guo, Z. Sun, J. Wang, S. Yu, Steady-state performances and scaling analyses for an open flashing-driven natural circulation system, Progress in Nuclear Energy, 87 (2016) 1-14.
[21] X. Hou, Z. Sun, J. Su, G. Fan, An investigation on flashing instability induced water hammer in an open natural circulation system, Progress in Nuclear Energy, 93 (2016) 418-430.
[22] H. Xu, Z. Sun, H. Gu, H. Li, Forced convection condensation in the presence of noncondensable gas in a horizontal tube; Experimental and theoretical study, Progress in Nuclear Energy, 88 (2016) 340-351.
[23] H. Xu, Z. Sun, H. Gu, H. Li, Experimental study on the effect of wall-subcooling on condensation heat transfer in the presence of noncondensable gases in a horizontal tube, Annals of Nuclear Energy, 90 (2016) 9-21.
[24] Y. Zhou, Z. Sun, H. Gu, Z. Miao, Performance of iodide vapour absorption in the venturi scrubber working in self-priming mode, Annals of Nuclear Energy, 87 (2016) 426-434.
[25] H. Bian, Z. Sun, M. Ding, N. Zhang, Local phenomena analysis of steam condensation in the presence of air, Progress in Nuclear Energy, 101 (2017) 188-198.
[26] X. Guo, Z. Sun, J. Wang, S. Yu, Scaling analyses for the open flashing-driven natural circulation system, Nuclear Engineering and Design, 324 (2017) 111-121.
[27] Z. Guo, Z. Sun, N. Zhang, M. Ding, X. Cao, Radial porosity peak at the centerline of packed beds with small tube to particle diameter ratios, Powder Technology, 319 (2017) 445-451.
[28] Z. Guo, Z. Sun, N. Zhang, M. Ding, J. Liu, Pressure drop in slender packed beds with novel packing arrangement, Powder Technology, 321 (2017) 286-292.
[29] Z. Guo, Z. Sun, N. Zhang, M. Ding, J. Wen, Experimental characterization of pressure drop in slender packed bed (1 < D/d < 3), Chemical Engineering Science, 173 (2017) 578-587.
[30] X. Hou, Z. Sun, G. Fan, L. Wang, Experimental and analytical investigation on the flow characteristics in an open natural circulation system, Applied Thermal Engineering, 124 (2017) 673-687.
[31] X. Hou, Z. Sun, W. Lei, Capability of RELAP5 code to simulate the thermal-hydraulic characteristics of open natural circulation, Annals of Nuclear Energy, 109 (2017) 612-625.
[32] Z. Meng, L. Ding, Z. Qiu, Z. Sun, C. Yan, S. Qiu, G. Su, W. Tian, Model application research for liquid entrainment through ADS-4 pipe in AP1000, Annals of Nuclear Energy, 110 (2017) 1043-1051.
[33] J. Wen, H. Gu, Z. Sun, Y. Zhou, A theoretical model and experiment validation on filtration characteristics of methyl iodide in bubble column, International Journal of Heat and Mass Transfer, 114 (2017) 1263-1273.
[34] H. Xu, H. Gu, Z. Sun, Forced convection condensation of steam in the presence of multicomponent noncondensable gases inside a horizontal tube, International Journal of Heat and Mass Transfer, 104 (2017) 1110-1119.
[35] X. Yan, G. Fan, Z. Sun, Study on flow characteristics in an open two-phase natural circulation loop, Annals of Nuclear Energy, 104 (2017) 291-300.
[36] J. Zhou, Z. Sun, M. Ding, H. Bian, N. Zhang, Z. Meng, CFD simulation for flow distribution in manifolds of central-type compact parallel flow heat exchangers, Applied Thermal Engineering, 126 (2017) 670-677.
[37] H. Bian, C. Kurwitz, Z. Sun, K. Cheng, K. Chen, Enhanced nucleate boiling on 3D-printed micro-porous structured surface, Applied Thermal Engineering, 141 (2018) 422-434.
[38] H. Bian, Z. Sun, X. Cheng, N. Zhang, Z. Meng, M. Ding, CFD evaluations on bundle effects for steam condensation in the presence of air under natural convection conditions, International Communications in Heat and Mass Transfer, 98 (2018) 200-208.
[39] H. Bian, Z. Sun, N. Zhang, Z. Meng, M. Ding, A preliminary assessment on a two-phase steam condensation model in nuclear containment applications, Annals of Nuclear Energy, 121 (2018) 615-625.
[40] G. Fan, P. Tong, Z. Sun, Y. Chen, Experimental study of pure steam and steam–air condensation over a vertical corrugated tube, Progress in Nuclear Energy, 109 (2018) 239-249.
[41] G. Fan, P. Tong, Z. Sun, Y. Chen, Development of a new empirical correlation for steam condensation rates in the presence of air outside vertical smooth tube, Annals of Nuclear Energy, 113 (2018) 139-146.
[42] W. Li, Z. Meng, Z. Sun, L. Sun, C. Wang, Investigations on the penetration length of steam-air mixture jets injected horizontally and vertically in quiescent water, International Journal of Heat and Mass Transfer, 122 (2018) 89-98.
[43] W. Li, Z. Meng, J. Wang, Z. Sun, Effect of non-condensable gas on pressure oscillation of submerged steam jet condensation in condensation oscillation regime, International Journal of Heat and Mass Transfer, 124 (2018) 141-149.
[44] J. Wen, K. Shi, Q. Sun, Z. Sun, H. Gu, Measurement for surface tension of aqueous inorganic salt, Frontiers in Energy Research, 6(MAR) (2018).
[45] J. Wen, Q. Sun, Z. Sun, H. Gu, An improved image processing technique for determination of volume and surface area of rising bubble, International Journal of Multiphase Flow, 104 (2018) 294-306.
[46] G. Xu, X. Zhang, Z. Sun, J. Ruan, B. He, Flow patterns and transition criteria in boiling water-cooled packed bed reactors, Progress in Nuclear Energy, 108 (2018) 214-221.
[47] J. Zhou, M. Ding, H. Bian, Y. Zhang, Z. Sun, CFD simulation for the effect of the header match on the flow distribution in a central-type parallel heat exchanger, Chemical Engineering Research and Design, 136 (2018) 144-153.
[48] J. Zhou, M. Ding, Z. Meng, Y. Zhang, Z. Sun, Reducing the flow distribution in central-type compact parallel flow heat exchangers having optimized tube structure, Frontiers in Energy Research, 6(JUN) (2018).
[49] H. Bian, Z. Sun, N. Zhang, Z. Meng, M. Ding, A new modified diffusion boundary layer steam condensation model in the presence of air under natural convection conditions, International Journal of Thermal Sciences, 145 (2019).
[50] H. Bian, Z. Sun, N. Zhang, Z. Meng, M. Ding, Numerical investigations on steam condensation in the presence of air on external surfaces of 3 × 3 tube bundles, Progress in Nuclear Energy, 111 (2019) 42-50.
[51] Z. Guo, Z. Sun, N. Zhang, X. Cao, M. Ding, Mean porosity variations in packed bed of monosized spheres with small tube-to-particle diameter ratios, Powder Technology, 354 (2019) 842-853.
[52] Z. Guo, Z. Sun, N. Zhang, M. Ding, Influence of confining wall on pressure drop and particle-to-fluid heat transfer in packed beds with small D/d ratios under high Reynolds number, Chemical Engineering Science, 209 (2019).
[53] Z. Guo, Z. Sun, N. Zhang, M. Ding, H. Bian, Z. Meng, Computational study on fluid flow and heat transfer characteristic of hollow structured packed bed, Powder Technology, 344 (2019) 463-474.
[54] Z. Guo, Z. Sun, N. Zhang, M. Ding, S. Shi, CFD analysis of fluid flow and particle-to-fluid heat transfer in packed bed with radial layered configuration, Chemical Engineering Science, 197 (2019) 357-370.
[55] Z. Guo, Z. Sun, N. Zhang, M. Ding, Y. Zhou, Influence of flow guiding conduit on pressure drop and convective heat transfer in packed beds, International Journal of Heat and Mass Transfer, 134 (2019) 489-502.
[56] W. Li, Z. Meng, J. Wang, J. Liu, Z. Sun, Experimental investigations on pressure oscillation induced by steam-air mixture gas sonic jets in subcooled water, International Journal of Heat and Mass Transfer, 128 (2019) 450-458.
[57] W. Li, Z. Sun, Z. Meng, G. Fan, J. Wang, Experimental investigations on the interfacial characteristics of steam-air mixture sonic jets in subcooled water, International Journal of Heat and Mass Transfer, 144 (2019).
[58] W. Li, J. Wang, Z. Sun, J. Liu, Z. Meng, Experimental investigation on thermal stratification induced by steam-air mixture vertical injection with shallow submergence depth, Progress in Nuclear Energy, 115 (2019) 52-61.
[59] W. Li, J. Wang, Z. Sun, Y. Zhou, J. Liu, Z. Meng, Experimental investigation on thermal stratification induced by steam direct contact condensation with non-condensable gas, Applied Thermal Engineering, 154 (2019) 628-636.
[60] W. Li, J. Wang, Y. Zhou, Z. Sun, Z. Meng, Investigation on steam contact condensation injected vertically at low mass flux: Part I pure steam experiment, International Journal of Heat and Mass Transfer, 131 (2019) 301-312.
[61] Y. Li, Q. Ma, Z. Sun, H. Gu, Y. Zhou, K. Shi, Study on calculation method of soluble aerosol removal efficiency under high humidity condition, Frontiers in Energy Research, 7(MAR) (2019).
[62] Y. Li, Z. Sun, H. Gu, Y. Zhou, Deposition characteristic of micro-nano soluble aerosol under bubble scrubbing condition, Annals of Nuclear Energy, 133 (2019) 881-888.
[63] J. Wen, Q. Sun, Z. Sun, H. Gu, Bubble coalescence efficiency near multi-orifice plate, Chinese Journal of Chemical Engineering, (2019).
[64] J. Wen, Q. Sun, Z. Sun, H. Gu, The effect of multi-orifice plate configuration on bubble detachment volume, Chinese Journal of Chemical Engineering, 27(1) (2019) 72-84.
[65] G. Xu, X. Zhang, Z. Sun, Bubble growth in a boiling water-cooled packed bed reactor, Nuclear Engineering and Design, 349 (2019) 144-149.
中文期刊论文:
[1] 孙福泰,孙中宁,阎昌琪,黄渭堂.管内覆丝网强化对流换热及阻力特性的实验研究[J].核动力工程,1995(02):149-153.
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[4] 孙中宁,黄渭堂,阎昌琪,孙福泰.管内插螺旋丝紊流对流换热性能研究[J].核动力工程,1996(04):50-56.
[5] 黄渭堂,欧贵宝,阎昌琪,孙中宁.螺纹槽管的疲劳强度试验及分析[J].发电设备,1997(03):25-28+38-39.
[6] 彭敏俊,王兆祥,杜泽,孙中宁.船舶核动力装置人机系统设计研究[J].核动力工程,1997(03):93-97.
[7] 孙中宁,彭敏俊,杜泽,黄渭堂.换热器热工计算中传热温差计算方法的一致性问题[J].核动力工程,1997(04):38-44.
[8] 阎昌琪,孙中宁,黄渭堂.复杂管路中的淹没问题研究[J].核科学与工程,1997(03):270-275.
[9] 黄渭堂,刘天才,孙中宁,阎昌琪.螺纹槽管传热与阻力特性的实验研究[J].哈尔滨工程大学学报,1998(01):32-37.
[10] 黄渭堂,阎昌琪,孙中宁,杜泽.螺纹槽管冷凝器若干应用问题的探讨[J].哈尔滨工程大学学报,1998(04):85-91.
[11] 孙中宁,杜泽,黄渭堂,阎昌琪,王明为.单头螺纹槽管管内紊流对流换热[J].核动力工程,1998(05):35-38+77.
[12] 孙中宁.竖直光管及环隙流道内沸腾换热启动时的壁温变化规律[J].哈尔滨工程大学学报,1999(02):89-93.
[13] 孙中宁.晶体加热表面对流换热机理[J].工程热物理学报,1999(03):356-359.
[14] 阎昌琪,孙中宁.流动欠热沸腾起始点计算模型的分析研究[J].哈尔滨工程大学学报,2000(01):15-19.
[15] 孙中宁,阎昌琪,杜泽,张志华.窄环隙流道内自然对流沸腾换热实验研究[J].核科学与工程,2000(01):57-63.
[16] 阎昌琪,孙中宁.流动欠热沸腾通道内净蒸汽产生起始点的确定[J].核科学与工程,2000(02):130-134+168.
[17] 孙中宁,杜泽,阎昌琪,张志华.竖直及倾斜环隙流道内自然对流沸腾临界热负荷[J].核科学与工程,2000(02):123-129.
[18] 阎昌琪,孙中宁,李洪喜.深海潜器用小型核动力的研制与发展前景[J].核动力工程,2000(04):378-380+384.
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[22] 阎昌琪,王东旭,孙中宁.论高等教育与国际接轨[J].继续教育研究,2001(03):20-22.
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[26] 黄渭堂,阎昌琪,孙中宁,于文艳.钛螺纹槽管传热及流动阻力的实验研究[J].核动力工程,2001(05):456-459.
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[28] 孙中宁,谈和平,阎昌琪.外侧加热环隙流道自然循环流动沸腾临界热负荷分析研究[J].核动力工程,2001(05):451-455.
[29] 孙中宁,阎昌琪,谈和平,郭建强,孙立成.双侧加热窄环隙流道强迫对流换热[J].核动力工程,2002(04):33-36.
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[31] 孙中宁,阎昌琪,黄渭堂,谈和平.管外及窄环隙流道池沸腾换热对比实验分析[J].哈尔滨工程大学学报,2003(02):136-140.
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[37] 孙中宁,孙立成,阎昌琪,黄渭堂.窄缝环形流道单相摩擦阻力特性实验研究[J].核动力工程,2004(02):123-127.
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[39] 吴国辉,黄渭堂,孙中宁.断续螺旋折流板在管壳式换热器中的应用[J].应用科技,2005(04):45-47.
[40] 路广遥,孙中宁,王经,阎昌琪.窄缝环形流道内流动传热特性的实验研究[J].动力工程,2005(02):275-279.
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[42] 黄渭堂,孙中宁,阎昌琪.钛波槽管水平管外凝结换热的实验研究[J].哈尔滨工程大学学报,2006(01):61-65.
[43] 路广遥,孙中宁,王经,阎昌琪.窄缝环形通道内流动阻力特性的实验研究[J].核动力工程,2006(03):28-31.
[44] 李建华,孙中宁,吴国辉.螺旋折流板波槽管换热器换热与阻力实验研究[J].应用科技,2006(08):65-67.
[45] 曹夏昕,阎昌琪,孙立成,孙中宁.摇摆状态下竖直管内单相水摩擦压降特性分析[J].哈尔滨工程大学学报,2006(06):834-838.
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[47] 曹夏昕,阎昌琪,孙立成,孙中宁,黄渭堂.竖直管内弹状流向搅混流转变界限的判定[J].核动力工程,2006(S1):68-72.
[48] 曹夏昕,阎昌琪,孙中宁.气-液两相泡状流在摇摆状态下的摩擦压降计算[J].核动力工程,2007(01):72-77.
[49] 曹夏昕,阎昌琪,孙中宁.摇摆状态下竖直管内环状流摩擦压降计算[J].核动力工程,2007(02):24-27.
[50] 曹夏昕,阎昌琪,孙立成,孙中宁.摇摆状态下竖直管内单相水阻力特性实验研究[J].核动力工程,2007(03):51-55.
[51] 曹夏昕,阎昌琪,孙中宁.摇摆状态下竖直管内弹状流单元物理模型解析[J].核动力工程,2007(03):47-50.
[52] 胡岩,孙中宁.折流板结构对管壳式换热器壳程流动与传热的影响[J].应用科技,2007(09):14-18.
[53] 路广遥,王经,孙中宁.换热器热力学计算中平均温差计算方法[J].核动力工程,2008(01):76-80.
[54] 孙中宁,曹夏昕,吕襄波.窄隙自然循环过冷沸腾流道中的温度分布特性[J].哈尔滨工程大学学报,2008(06):563-567.
[55] 张金红,阎昌琪,曹夏昕,孙中宁.摇摆状态下水平管中单相水的摩擦阻力实验研究[J].核动力工程,2008(04):44-49.
[56] 张金红,阎昌琪,孙中宁.摇摆状态下水平管内气液两相流流型转换研究[J].哈尔滨工程大学学报,2008(10):1050-1053.
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