• Introduction
  • Research
  • Teaching
  • Funding
  • Publications
  • Awards
  • Honor Reward
  • Admission
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Jiangfeng Guo

Professor PhD

Department: College of Mechanical and Electrical Engineering

Fields: Heat transfer enhancement, heat exchanger, supercritical fluids, eneryg storage

Email: gjf1200@126.com

Office:

ORCID: 0000-0002-9216-1295

DBLP:

10 Visits

Introduction

Jiangfeng Guo, currently a Professor at Beijing University of Chemical Technology, used to be a Fellow at Imperial College of Technology, a Post Professor at the University of the Chinese Academy of Sciences, and a Project Professor at the Institute of Engineering Thermophysics, Chinese Academy of Sciences. He obtained dual Bachelor's Degrees from North China Electric Power University in 2006 and a Doctoral Degree from Shandong University in 2011. Mainly engaged in research on heat transfer enhancement theory and energy-saving technology, heat transfer and flow characteristics of supercritical fluids, and research and development of high-efficiency heat exchangers, and has led more than ten projects including the National Key R&D Program, the EU Horizon 2020 Science and Technology Project, and the National Natural Science Foundation. Published over 100 academic papers, participated in the writing of two English academic books, applied for/authorized more than 10 national invention patents, and served as Deputy Editor and Editorial Board Member of multiple international academic journals. He has been selected into the World's Top 2% scientists annual and long-term scientific influence lists for many consecutive years, and has won the Chinese Academy of Sciences Lu Jiaxi Young Talent Award, the nomination of one hundred outstanding Doctoral dissertations in China, the EU Marie Curie scholar, and China's 100 most influential outstanding academic papers.

Education Work Experience

Social Position

Social Activities

Research

  1. For supercritical fluids and other working fluids with strongly variable physical properties, the mechanism of heat transfer enhancement and deterioration and the distribution law of irreversibility were revealed, and a new method of coupling the distribution of heat transfer parameters for synergistic enhancement was innovatively proposed, and a new type of heat transfer equipment was fabricated and successfully Applied to MW-level supercritical CO2 Brayton power generation system, etc.

  2.  Aiming at the heat exchange problems in typical high-energy-consuming industries, the irreversible analysis theory of heat exchange process was developed and improved, and a strong discrete multi-parameter collaborative design method for heat exchange equipment with constraints and a global optimization method for multi-objective heat exchange systems were constructed.

  3.  Focusing on solar energy and waste heat resources, etc., a new type of thermal energy grade improvement heat pump system, a deep utilization equipment for flue gas waste heat, and a thermodynamic model of a solar thermal storage system were constructed.

Teaching

  1. Pressure Vessel Design

  2. Heat Exchanger Design and Heat Transfer Enhancement Theory

Postgraduates

Funding

  1. Coupling heat transfer and thermodynamic optimization for supercritical CO2 heat exchanger, which is funded European Horizon 2020 Marie Skłodowska-Curie Action, May 2021-Jun 2023, Project leader.

  2. Research and development of heat exchanger for supercritical CO2 Power Cycle, which is funded by Power Equipment Co. Ltd. in Hebei Province, China, Jan. 2018-Dec. 2019, Project Leader.

  3. The studies on the coupled heat transfer characteristics and optimization design method of supercritical CO2 recuperator, which is funded by National Natural Science Foundation of China (No. 51676185), Jan. 2017-Dec. 2020, Project Leader.

  4. The efficient recovery and utilization technology for low grade thermal energy, which is funded by the National Key Research and Development Program of China (No. 2016YFB0601701), Jun. 2016-Dec, 2020, Project Leader.

  5. Talent Program of Youth Innovation Promotion Association, CAS (No. 2014128), which is funded by Chinese Academy of Sciences, Jan. 2014-Dec. 2017, Project Leader.

  6. The irreversibility analysis of heat transfer between LBE and helium gas and its thermodynamic optimization based on the ADS system, which is funded by National Natural Science Foundation of China (No. 51106158), Jan. 2011-Dec. 2016, Project Leader.

  7.  Basic research on deep utilization of waste heat from boiler low temperature flue gas, which is funded by National Key Basic Research Development Plan of China (973 Plan, No. 2011CB710700), Sep. 2010-Sep. 2015, Academic Backbone.

Vertical Project

Horizontal Project

Publications

(1)       J. Guo*, X. Huai, Maximizing Electric Power through Spectral-Splitting Photovoltaic-Thermoelectric Hybrid System Integrated with Radiative Cooling, Advanced Science (2023) 2206575.

(2)       Z. Han, J. Guo*, X. Huai, Theoretical analysis of a novel PCHE with enhanced rib structures for high-power supercritical CO2 Brayton cycle system based on solar energy, Energy 270 (2023) 126928.

(3)       J. Guo*, J. Song, S. Narayan, K.S. Pervunin, C.N. Markides, Numerical investigation of the thermal-hydraulic performance of horizontal supercritical CO2 flows with half-wall heat-flux conditions, Energy 264 (2023) 125845.

(4)       J. Guo*, Maximizing uninterrupted solar electricity in spectral-splitting photovoltaic-thermal systems integrated with CO2 battery, Journal of Energy Storage 66 (2023) 107402.

(5)       Z. Han, J. Guo*, J. Chen, X. Huai, Experimental and numerical investigations on thermal-hydraulic characteristics of supercritical CO2 flows in printed circuit heat exchangers, International Journal of Thermal Sciences 194 (2023) 108573.

(6)       Z. Han, X. Cui, J. Guo*, H. Zhang, J. Zhou, K. Cheng, H. Zhang X. Huai, Experimental and numerical studies on the thermal-hydraulic performance of a novel airfoil fins printed circuit heat exchanger, International Journal of Heat and Mass Transfer 217 (2023) 124655. (JCR分区: Q1)

(7)       Guo, J.*, Song, J., et al. (2022): Investigation of the thermohydraulic characteristics of vertical supercritical CO2 flows at cooling conditions. Energy, Vol. 256, 124628.

(8)       Guo, J.*, Song, J., et al. (2022): Thermo-hydraulic performance of heated vertical flows of supercritical CO2. International Journal of Heat and Mass Transfer, Vol. 199, 123437.

(9)       Liu, X., Guo, J.*, et al. (2022): Studies on thermal-hydraulic characteristics of supercritical CO2 flows with non-uniform heat flux in a tubular solar receiver. Renewable Energy, Vol. 201, pp. 291-304

(10)    Han, Z., Guo, J.*, et al. (2022): Numerical investigation on the thermal-hydraulic performance of supercritical CO2 in a modified airfoil fins heat exchanger. The Journal of Supercritical Fluids, Vol. 187, 105643

(11)    Chen, J., Guo, J.*, et al. (2022): Thermal-hydraulic performance of mist/compressed humid air two-phase flow in an airfoil channel recuperator. Applied Thermal Engineering, Vol. 201, 117802.

(12)    Chen, J., Guo, J., et al. (2021): Thermal-hydraulic performance of compressed humid air flowing in a recuperator. Applied Thermal Engineering, Vo. 188, 116620.

(13)    Han, Z., Guo, J.*, et al. (2021): Experimental and numerical studies on novel airfoil fins heat exchanger in flue gas heat recovery system. Applied Thermal Engineering, Vo. 192, 116939.

(14)    Cheng, K., Zhou, J., Huai, X., Guo, J. (2021): Experimental exergy analysis of a printed circuit heat exchanger for supercritical carbon dioxide Brayton cycles. Applied Thermal Engineering, Vo. 192, 116882.

(15)    Zhang, H., Guo, J.*, et al. (2020): Heat transfer performance of supercritical pressure CO2 in a non-uniformly heated horizontal tube. International Journal of Heat and Mass Transfer, Vol. 155, 119748.

(16)    Cheng, K., Zhou, J., Zhang, H., Huai, X., Guo, J. (2020): Experimental investigation of thermal-hydraulic characteristics of a printed circuit heat exchanger used as a pre-cooler for the supercritical CO2 Brayton cycle. Applied Thermal Engineering, Vo. 171, 115116.

(17)    Zhou, J., Cheng, K., Zhang, H., Liu, B., Huai, X., Guo, J., et al. (2020): Test platform and experimental test on 100 kW class Printed Circuit Heat Exchanger for Supercritical CO2 Brayton Cycle. International Journal of Heat and Mass Transfer, Vol. 148, 118540.

(18)    Zhang, H., Guo, J.*, Huai X., Cui, X. (2019): Thermodynamic performance analysis of supercritical pressure CO2 in tubes. International Journal of Termal Sciences, Vol. 146, 106102.

(19)    Cui, X., Xiang, M., Guo, J.*, et al. (2019): Analysis of coupled heat transfer of supercritical CO2 from the viewpoint of distribution coordination. Journal of Supercritical Fluids, Vol. 152, 104560.

(20)    Cui, X., Zhang, H., Guo, J.*, et al. (2019): Analysis of two-stage waste heat recovery based on natural gas-fired boiler. International Journal of Energy Reserch, Vol. 43, pp. 8898-8912.

(21)    Zhang, H., Guo, J.*, Huai, X., Cui, C., Cheng, K. (2019): Buoyancy effects on coupled heat transfer of supercritical pressure CO2 in horizontal semicircular channels. In: International Journal of Heat and Mass Transfer, Vol. 134, pp. 437-449.

(22)    Zhang, H., Guo, J.*, Huai, X., Cui, C., Cheng, K. (2019): Studies on the thermal-hydraulic performance of zigzag channel with supercritical pressure CO2. In: The Journal of Supercritical Fluids, Vol. 148, pp. 104-115.

(23)    Cui, X., Guo, J.*, Huai, X., Zhang, H., Cheng, K., Zhou, J. (2019): Numerical investigations on serpentine channel for supercritical CO2 recuperator. In: Energy, Vol. 172, pp. 517-530.

(24)    Guo, J.*, Cui, X., Huai, X., Cheng, K., Zhang, H. (2019): The coordination distribution analysis on the series schemes of heat exchanger system. In: International Journal of Heat and Mass Transfer, Vol. 129, pp. 37-46.

(25)    Guo, J.*, Xiang, M., Zhang, H., Huai, X., Cheng, K., Cui, X. (2019): Thermal-hydraulic characteristics of supercritical pressure CO2 in vertical tubes under cooling and heating conditions. In: Energy, Vol. 170, pp. 1067-1081.

(26)    Guo, J.*, Huai, X., Cheng, K., Cui, X., Zhang, H. (2018): The effects of nonuniform inlet fluid conditions on crossflow heat exchanger. In: International Journal of Heat and Mass Transfer, Vol. 120, pp. 807-817.

(27)    Guo, J.*, Huai, X., Cheng, K. (2018): The comparative analysis on thermal storage systems for solar power with direct steam generation. In: Renewable Energy, Vol. 115, pp. 217-225.

(28)    Cui, X., Guo, J.*, Huai, X., Cheng, K., Zhang, H., Xiang, M. (2018): Numerical study on novel airfoil fins for printed circuit heat exchanger using supercritical CO2. In: International Journal of Heat and Mass Transfer, Vol. 121, pp. 354-366.

(29)    Xiang, M., Guo, J.*, Huai, X., Cui, X. (2017): Thermal analysis of supercritical pressure CO2 in horizontal tubes under cooling condition. In: The Journal of Supercritical Fluids, Vol. 130, pp. 389-398.

(30)    Guo, J.*, Huai, X. (2017): Coordination analysis of cross-flow heat exchanger under high variations in thermodynamic properties. In: International Journal of Heat and Mass Transfer, Vol. 113, pp. 935-942.

(31)    Guo, J.*, Huai, X. (2017): Performance analysis of printed circuit heat exchanger for supercritical carbon dioxide. In: ASME Journal of Heat Transfer, Vol. 139, 061801.

(32)    Guo, J.*, Huai, X. (2016): The heat transfer mechanism study of three-tank latent heat storage system based on entransy theory. In: International Journal of Heat and Mass Transfer, Vol. 97, pp. 191-200.

(33)    Xu, M., Cai, J., Guo, J., Huai, X.*, Liu, Z., Zhang, H. (2017): Technical and economic feasibility of the Isopropanol-Acetone-Hydrogen chemical heat pump based on a lab-scale prototype. In: Energy, Vol. 139, pp. 1030-1039

(34)    Guo, J.* (2016): Design Analysis of supercritical carbon dioxide recuperator. In: Applied Energy, Vol. 164, pp. 21-27.

(35)    Guo, J.*, Huai, X. (2016): Numerical investigation of helically coiled tube from the viewpoint of field synergy principle. In: Applied Thermal Engineering, Vol. 98, pp. 137-143.

(36)    Guo, J.*, Huai, X., Liu, Z. (2016): Performance investigation of parabolic trough solar receiver. In: Applied Thermal Engineering, Vol. 95, pp. 357-364.

(37)    Guo, J.*, Huai, X. (2016): Multi-parameter optimization design of parabolic trough solar receiver. In: Applied Thermal Engineering, Vol. 98, pp. 73-79.

(38)    Guo, J., Huai, X.*, Xu, M. (2015): Thermodynamic analysis of an Isopropanol-Acetone-Hydrogen chemical heat pump. In: International Journal of Energy Research, Vol. 39, pp. 140-146.

(39)    Guo, J., Huai, X.*, Xu, M. (2014): Study on Isopropanol Acetone Hydrogen chemical heat pump of storage type. In: Solar Energy, Vol. 2014, pp. 684-690.

(40)    Guo, J., Huai, X.* (2013): Thermodynamic analysis of lead-bismuth eutectic turbulent flow in a straight tube. In: Energy, Vol. 57, pp. 600-606.

(41)    Guo, J., Huai, X.* (2013): Optimization design of heat exchanger in an irreversible regenerative Brayton cycle system. In: Applied Thermal Engineering, Vol. 58, pp. 77-84.

(42)    Guo, J., Huai, X.*, Li, X., Cai, J., Wang, Y. (2013): Multi-objective optimization of heat exchanger based on entransy dissipation theory in an irreversible Brayton cycle system. In: Energy, Vol. 63, pp. 95-102.

(43)    Guo, J.*, Cai, J., Wang, H. (2012): Performance analysis of an irreversible regenerative intercooled Brayton cycle. In: International Journal of Exergy, Vol. 11, pp. 271-285.

(44)    Guo, J., Xu, M.* (2012): The application of entransy dissipation theory in optimization design of heat exchanger. In: Applied Thermal Engineering, Vol. 36, pp. 227-235.

(45)    Guo, J., Huai, X.* (2012): The application of entransy theory in optimization design of isopropanol acetone hydrogen chemical heat pump. In: Energy, Vol. 43, pp. 355-360.

(46)    Guo, J., Huai, X.*, Li, X., Xu, M. (2012): Performance analysis of Isopropanol-Acetone-Hydrogen chemical heat pump. In: Applied Energy, Vol. 93, pp. 261-267.

(47)    Guo, J., Xu, M., Tao, Y., Huai, X.* (2012): The effect of temperature dependent viscosity on entropy generation in curved square microchannel. In: Chemical Engineering Processing, Vol. 52, pp. 85-91.

(48)    Guo, J., Huai, X.* (2012): Optimization design of recuperator in a chemical heat pump system based on entransy dissipation theory. In: Energy, Vol. 41, pp. 335-343.

(49)    Guo, J., Xu, M.*, Cheng, L. (2011): The entransy dissipation minimization principle under given heat duty and heat transfer area conditions. In: Chinese Science Bulletin, Vol. 56, pp. 2071-2076.

(50)    Guo, J.*, Xu, M., Cheng, L. (2011): The influence of viscous heating on the entransy in two-fluid heat exchangers. In: SCIENCE CHINA Technological Sciences, Vol. 54, pp. 1267-1274.

(51)    Guo, J., Xu, M., Cai, J., HuaiX.* (2011): Viscous dissipation effect on entropy generation in curved square microchannels. In: Energy, Vol. 36, pp. 5416-5423.

(52)    Guo, J., Xu, M.*, Cheng, L. (2011): Numerical investigations of curved square channel from the viewpoint of field synergy principle. In: International Journal of Heat and Mass Transfer, Vol. 54, pp. 4148-4151.

(53)    Guo, J., Xu, M.*, Cheng, L. (2011): Second law analysis of curved rectangular channels. In: International Journal of Thermal Science, Vol. 50, pp. 760-768.

(54)    Xu, M.*, Guo, J., Wang, L., Cheng, L. (2011): Thermal wave interference as the origin of the overshooting phenomenon in dual-phase-lagging heat conduction. In: International Journal of  Thermal Science, Vol. 50, pp. 825-830.

(55)    Li, X., Guo, J., Xu, M.*, Cheng, L. (2011): Entransy dissipation minimization for optimization of heat exchanger design. In: Chinese Science Bulletin, Vol. 56, pp. 2174-2178.

(56)    Guo, J., Cheng, L., Xu, M.* (2010): Multi-objective optimization of heat exchanger design by entropy generation minimization. In: ASME J. Heat Transfer, Vol. 132, 081801.

(57)    Guo, J., Cheng, L., Xu, M.* (2010): The entropy generation minimization based on the revised entropy generation number. In: International Journal of Exergy, Vol. 7, pp. 607-626.

(58)    Guo, J., Xu, M.*, Cheng, L. (2010): Principle of equipartition of entransy dissipation for heat exchanger design. In: SCIENCE CHINA Technological Sciences, Vol. 53, pp. 1309-1314.

(59)    Guo, J., Xu, M.*, Cheng, L. (2010): Numerical investigation of circular tube fitted with helical screw-tape inserts from the viewpoint of field synergy principle. In: Chemical Engineering and Processing, Vo. 49, pp. 410-417.

(60)    Guo, J., Xu, M.*, Cheng, L. (2010): Thermodynamic analysis of waste heat power generation system. In: Energy, Vol. 35, pp. 2824-2836.

(61)    Guo, J., Cheng, L., Xu, M.* (2009): Entransy dissipation number and its application to heat exchanger performance evaluation. In: Chinese Science Bulletin, Vol. 54, pp. 2708-2713.

(62)    Guo, J., Xu, M.*, Cheng, L. (2009): The application of field synergy number in shell-and-tube heat exchanger optimization design. In: Applied Energy, Vol. 86, pp. 2079-2087.

(63)    Guo, J., Cheng, L., Xu, M.* (2009): Optimization design of shell-and-tube heat exchanger by entropy generation minimization and genetic algorithm. In: Applied Thermal Engieering, Vol. 29, pp. 2954-2960.

(64)    Jiangfeng Guo*, Jian Song, Konstantin S. Pervunin, Christos N. Markides. Heat exchanger arrangements in supercritical CO2 Brayton cycle systems: an analysis based on the distribution coordination principle. HEFAT-ATE, Amsterdam, Netherland, 2022.

(65)    Jiangfeng Guo*; Xinying Cui; Haiyan Zhang; Xiulan Huai; The heat transfer analysis of low temperature recuperator in supercritical CO2 Brayton cycle, Applied Energy Symposium: MIT A+B, Boston, USA, 2019.5. 21-25.

(66)    Jiangfeng Guo*; Xinying Cui; Haiyan Zhang; Xiulan Huai; Thermal analysis of low grade flue gas heat recovery heat exchanger, International Conference on Applied Energy 2019, Västerås, Sweden, 2019.8.12-15.

(67)    Jiangfeng Guo*; Xinying Cui; Haiyang Zhang; Xiulan Huai; Keyong Cheng; Performance analysis of heat exchanger for fluids with variable properties, 10th International Conference on Applied Energy, ICAE 2018, Hongkong, China, 2018.8.22-25.

(68)    Xinying Cui; jiangfeng Guo*; Haiyan Zhang; Xiulan Huai; Keyong Cheng; Haiyan Zhang; Mengru Xiang; Numerical investigation on convective heat transfer of supercritical pressure CO2 in serpentine channel, 16th International Heat Transfer Conference, IHTC 2018, Beijing, China, 2018.8.10-15.

(69)    Haiyan Zhang; Jiangfeng Guo*; Mengru Xiang; Xiulan Huai; Keyong Cheng; Xinying Cui; Numerical studies on the coupled heat transfer characteristics of supercritical pressure CO2 under cooling condition, 16th International Heat Transfer Conference, IHTC 2018, Beijing, China, 2018.8.10-15.

(70)    Jiangfeng Guo*; Xinying Cui; Haiyan Zhang; Xiulan Huai; Keyong Cheng; Performance analysis of heat exchanger for fluids with variable prop, The 10th International Conference on Applied Energy – ICAE2018, China, 2018.08.20-25.

(71)    Jiangfeng Guo*; Xiulan Huai; Keyong Cheng; Xinying Cui; Haiyan Zhang; Thermal analysis of heat exchanger with supercritical pressure CO2, Proceedings of the 16th International Heat Transfer Conference, IHTC-16, China, 2018.08.10-15.

(72)    Guo, Jiangfeng*; Huai, Xiulan*; Entransy dissipation in a straight tube with leadbismuth turbulent flow, 26th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2013, Guilin, China, 2013.7.16-19.

(73)    Guo, J.*, Xu, M., Cheng, L. (2010): A new criterion for assessing heat exchanger performance. Proceedings of the 14th International Heat Transfer Conference at Washington, USA, August 2010.

(74)    Guo, J.*, Xu, M., Cheng, L. (2010): The application of entransy dissipation theory in optimization design of heat exchanger. Proceedings of the 14th International Heat Transfer Conference at Washington, USA, August 2010.

Awards

  1. World Ranking of Top 2% Scientists, career impact, 2021, 2022, 2023

  2. European Marie Skłodowska-Curie Fellowship, 2021

  3. Outstanding science and Technology Paper Award for Beijing youth, 2016

  4. The president's prize of Chinese Academy of Sciences, 2015

  5.  Chinese 100 most Excellent Doctor Degree Dissertation Nomination, 2014

  6. Member of Youth Innovation Promotion Association, Chinese Academy of Sciences, 2014

  7. Top 100 most cited Chinese papers published in domestic journals, 2013

  8. Forerunners 5000-Chinese Top academic papers, 2013

  9. Forerunners 5000-Chinese Top academic papers, 2012

  10. Outstanding doctoral dissertation of Shandong University, 2012

  11. Young scholar Prize of the Institute of Engineering Thermophysics, Chinese Academy of Sciences, 2012

  12. Postgraduate outstanding technological innovating achievement award of Shandong province, 2011

patent

Honor Reward

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