柏超,女,1984年生,山东济南人,工学博士,副教授,硕士生导师。
联系方式:baichao@sdu.edu.cn
教育及工作经历:
2001年至2005年于古天乐代言太阳集团获得学士学位;
2005年至2008年于古天乐代言太阳集团获得硕士学位;
2008年至2012年于香港大学机械工程学院获得博士学位;
2012年来校工作至今。
主要研究领域:
主要从事小微尺度强化换热研究。研究领域主要涉及:
1. 微通道单相/两相流换热性能强化;
2. 纳米流体性能研究及结构优化设计;
3. 小微尺度通道内冷凝换热性能研究及强化。
主持项目:
山东省自然科学基金面上,基于进化拓扑算法的纳米流体直接结构优化及优化纳米流体的制备与性能表征,2024.1.1-2026.12.31.
工信部,数据采集系统及数据处理软件,2012.12.20-2014.12.20.
山东电力工程咨询院有限公司横向,数据采集系统及数据处理软件,2014.10.1-2016.12.31.
工信部,GF晃荡****研究,2015.1.1-2018.12.1.
论文论著:
至今以第一作者授权发明专利6项,以第一作者发表SCI 论文14篇。代表论著如下:
[1]C. Bai﹡, Y. Qiu, M. Wei, 2023, “Theoretical analysis for conduction heat transfer performance inside converging-shaped microchannel under varying-gravity conditions,” ASME Journal of Heat and Mass Transfer, 145, p.101003.
[2] C. Bai, Y. Qiu, M. Wei, M. C. Tian﹡, 2021, “Converging-shaped small channel for condensation heat transfer enhancement under varying-gravity conditions,” International communications in Heat and Mass Transfer, 123, p.105171.
[3] C. Bai, Y. Qiu, X. L. Leng, G. M. Zhang, M. C. Tian﹡, 2020, “Diverging/converging small channel for condensation heat transfer enhancement under different gravity conditions,” International communications in Heat and Mass Transfer, 116, p.104714.
[4] C. Bai, H. Z. Cao, G. M. Zhang, M. C. Tian﹡, 2019, “Diverging Small Channel for Condensation Heat Transfer Enhancement,” International Journal of Heat and Mass Transfer, 133, pp. 218-225. [3] S. H. Zhai, C. Bai﹡, J. Q. Liu, T. Luan, 2017, “Enhancement of Laminar Film Condensation with Diversion Panels for Large Space,” International Journal of Heat and Mass Transfer, 108, pp.1819-1824.
[5] C. Bai, G. M. Zhang, Y. Qiu, X. L. Leng, M. C. Tian﹡, 2019, “A new method for heat transfer and fluid flow performance simulation of plate heat exchangers,” Numerical Heat Transfer, Part B: Fundamentals, 75, pp.93-110.
[6] C. Bai, L. Q. Wang﹡, L. Cheng, 2009, “Remarks on Microfluidic Fabrication of Nano-/Subnano-Liter Droplets,” Current Nanoscience, 5, pp.353-357.
[7] C. Bai, G. M. Zhang, Y. Qiu, X. L. Leng, M. C. Tian﹡,2018, “Direct Nanofluids Configuration Optimization Based on the Evolutionary Topology Optimization Method,” International Journal of Heat and Mass Transfer, 117, pp. 201-210.
[8] C. Bai, L. Q. Wang﹡, 2009, “Constructal Design of Particle Volume Fraction in Nanofluids,” Journal of Heat Transfer, 131, p.112402.
[9] C. Bai, L. Q. Wang﹡, 2010, “Constructal Design of Nanofluids for One-Dimensional Steady Heat Conduction Systems,” NANO, 5, pp.39-51.
[10] C. Bai, L. Q. Wang﹡, 2010, “Constructal Allocation of Nanoparticles in Nanofluids,” Journal of Heat Transfer, 132, p.052404.
[11] C. Bai, L. Q. Wang﹡, 2010, “Constructal Structure of Nanofluids,” Journal of Applied Physics, 108, p.074317.
[12] C. Bai, L. Q. Wang﹡, 2011, “Constructal Blade Shape in Nanofluids,” Nanoscale Research Letters, 6, Nanofluids series 240.
[13] C. Bai, L. Q. Wang﹡, 2013, “Two Nanofluid Configurations for Heat Conduction Systems: Performance Comparison,” International Journal of Heat and Mass Transfer, 66, pp.632-641.