Bingguo Zhu, Qing Zhang, Lingyu Ma, Houdong Shi. Analysis of heat transfer deterioration mechanism of supercritical fluid based on VOF two-phase method and pseudo-boiling theory [J]. International Journal of Heat and Mass Transfer, 2025, 240: 126643.
Bingguo Zhu, Lingyu Ma, Qing Zhang, Houdong Shi. An investigation of the thermos-hydraulic performance of a novel double tube heat exchanger with variable cross-section inner tube for trans-critical CO2 cycle [J]. Applied Thermal Engineering, 2024, 253: 123825.
Bingguo Zhu, Jinliang Xu*, Chenshuai Yan, Jian Xie. The general supercritical heat transfer correlation for vertical up-flow: K number correlation [J]. International Journal of Heat and Mass Transfer, 2020, 148: 119080.
Bingguo Zhu, Jinliang Xu*, Xinming Wu, Jian Xie, Mingjia Li. Supercritical “boiling” number, a new parameter to distinguish two regimes of carbon dioxide heat transfer in tubes [J]. International Journal of Thermal Science, 2019,136:254–266.
Bingguo Zhu, Jinliang Xu*, Haisong Zhang, Jian Xie, Mingjia Li. Effect of non-uniform heating on scCO2 heat transfer deterioration [J]. Applied Thermal Engineering, 2020, 181: 115967.
Bingguo Zhu, Xinjie Zhu, Jian Xie*, Jinliang Xu, Huan Liu. Heat transfer prediction of supercritical carbon dioxide in vertical tube based on artificial neural networks [J]. Journal of Thermal Science, 2021, 30(5): 1751–1767.
Chenshuai, Yan, Jinliang, Xu, Bingguo Zhu, XiaoTian, He, Guanglin Liu. Numerical study on convective heat transfer of supercritical CO2 in vertically upward and downward tubes [J]. SCIENCE CHINA-TECHNOLOGICAL SCIENCES, 2021, 64(5): 995-1006.
Kaigang Gong, Bingguo Zhu*, Bin Peng, Jixiang He. Numerical Investigation of Heat Transfer Characteristics of scCO2 Flowing in a Vertically-Upward Tube with High Mass Flux [J]. Entropy, 2022, 24(1): 79.
Mingtong Wei, Bingguo Zhu*, Jixiang He, Kaigang Gong. A new channel structure for strengthening heat transfer of SCO2 Printed Circuit Heat Exchanger (PCHE): variable sectional semicircular channel [J]. Front. Energy Res., 2023, 11: 1286376.
朱兵国,石厚栋,马凌宇,等.超临界CO2/Xe混合工质在PCHE内传热特性数值研究[J/OL].中国电机工程学报,1-10[2025-03-04].
朱兵国*, 何吉祥. 变截面耦合通道PCHE内超临界CO2热工水力性能研究[J]. 工程热物理学报, 2024,45(06):1749-1756.
朱兵国*, 巩楷刚, 彭斌. 垂直管内高质量流速超临界CO2换热特性[J].化工进展, 2024,43(02):937-947.
朱兵国*, 何吉祥, 徐进良等.冷却条件下渐扩/渐缩管内超临界压力二氧化碳的传热特性[J]. 化工学报, 2023,74(03):1062-1072.
何吉祥, 朱兵国*, 彭斌等. 太阳能热发电中超临界压力CO2在渐扩变截面圆管内冷却传热强化机理[J]. 太阳能学报, 2023,44(09):249-256.
朱兵国*,巩楷刚,杨小亮等.轴向非均匀热流条件下超临界二氧化碳垂直管内换热特性[J].热力发电, 2023, 52(06): 45-51.
彭斌, 孙振豪, 朱兵国*等. 变截面半圆通道内超临界二氧化碳热工水力性能研究[J].热力发电, 2024,53(04):43-52.
朱兵国*, 巩楷刚, 孙健等.竖直管中超高温压参数CO2的传热特性分析[J]. 流体机械, 2022, 50(07):29-36.
孙健, 彭斌, 朱兵国. 无油双涡圈空气涡旋压缩机的数值模拟及试验研究[J]. 上海交通大学学报, 2022,56(05):611-621.
朱兵国, 吴新明, 张良, 徐进良*, 刘欢. 压力瞬态下超临界压力CO2的传热特性[J].化工进展, 2019, 38(10): 4444–4451.
张海松, 朱鑫杰, 朱兵国等. 浮升力和流动加速对超临界CO2管内流动传热影响[J].物理学报, 2020,69(06):126-135.
朱兵国, 吴新明, 张良, 孙恩慧, 张海松, 徐进良*. 垂直上升管内超临界CO2流动传热特性研究[J]. 化工学报, 2019, 70(4): 1282-1290.
朱兵国, 张海松, 孙恩慧, 刘欢, 刘广林, 徐进良*. 超高参数CO2在垂直管中的传热分析[J].化工进展, 2019, 38(11): 4880–4889.
闫晨帅, 朱兵国, 张海松, 朱鑫杰, 徐进良*, 刘欢. 超临界压力CO2在倾斜光管内换热特性数值分析[J].中国电机工程学报, 2020, 40(02): 583–592.
张良, 朱兵国, 吴新明等.超临界二氧化碳在垂直光管内的传热特性[J].中国电机工程学报, 2019,39(15):4487-4497.
吴新明, 朱兵国, 张良等. 圆管内超临界CO2的阻力特性[J].化工学报, 2018,69(12):5024-5033.