Numerical Investigation on Characteristics of Supercritical CO2&nbsp;Heat Transfer in Vertical Circular Tubes with Circumferentially Half-Side Heating

ZHANG Yan; ZHANG Xinyi; YAN Chenshuai; WU Wenhua; GAO Erman

doi:10.1007/s11630-024-2007-z

2024 , Vol. 33 >Issue 5: 1744 - 1756

DOI: https://doi.org/10.1007/s11630-024-2007-z

Numerical Investigation on Characteristics of Supercritical CO₂ Heat Transfer in Vertical Circular Tubes with Circumferentially Half-Side Heating

ZHANG Yan ,
ZHANG Xinyi ,
YAN Chenshuai ,
WU Wenhua ,
GAO Erman

Expand

School of Energy and Power Engineering, Northeast Electric Power University, Jilin 132012, China

Online published: 2024-09-08

Supported by

This work is supported by Science and Technology Research Projects of the Education Department of Jilin Province (No. JJKH20230116KJ), Doctoral Scientific Research Funds for Northeast Electric Power University (No. BSJXM-2021214), Natural Science Foundation of Jilin Province of China (No. 20230101341JC).

Copyright

Science Press, Institute of Engineering Thermophysics, CAS and Springer-Verlag GmbH Germany, part of Springer Nature 2024

Fold

Abstract

The design of heat exchangers in the advanced supercritical power conversion system cannot be separated from the study of heat transfer issues. Half-side heating mode is often encountered for solar receiver and supercritical boiler. Here, the characteristics of supercritical CO₂ (sCO₂) convection heat transfer in vertical tubes with circumferentially half-side heating was numerically investigated through the SST k-ω turbulent model which matches well with the experimental data. Then, heat transfer between sCO₂ upflow and downflow was compared. Similar to film boiling heat transfer at subcritical pressure, numerical results were processed according to the supercritical pseudo-phase transition hypothesis, with liquid-like phase in the tube core region and vapor-like film in the region near the heated tube wall. The structure of two layers was demarcated by pseudo-critical temperature T_pc. Therefore, sCO₂ heat transfer was assessed according to double thermal resistances caused by vapor-like film near the wall and core liquid-like phase. The findings suggest that wall temperature for upflow is higher than that for downflow, which is attributed to larger thermal resistance in the fluid domain for upflow than that for downflow. The difference guarantees the excellent heat transfer performance for downflow than upflow. It is also further concluded that the formation of vapor-like film near the wall due to pseudo-phase transition plays a key role in dominating wall temperature and inducing heat transfer deterioration in half-side heating tubes. The present contribution is significant to the design of supercritical heat exchanger under half-side heating mode.

Key words： supercritical CO₂; pseudo-phase transition; half-side heating; thermal resistance; flow direction

Cite this article

ZHANG Yan , ZHANG Xinyi , YAN Chenshuai , WU Wenhua , GAO Erman . Numerical Investigation on Characteristics of Supercritical CO₂ Heat Transfer in Vertical Circular Tubes with Circumferentially Half-Side Heating[J]. Journal of Thermal Science, 2024 , 33(5) : 1744 -1756 . DOI: 10.1007/s11630-024-2007-z

References

[1] Iverson B., Conboy T., Pasch J., et al., Supercritical CO₂ Brayton cycles for solar-thermal energy. Applied Energy, 2013, 111: 957–970.
[2] Linares J.I., Montes M.J., Cantizano A., et al., A novel supercritical CO₂ recompression Brayton power cycle for power tower concentrating solar plants. Applied Energy, 2020, 263: 114644.
[3] Khatoon S., Kim M.H., Preliminary design and assessment of concentrated solar power plant using supercritical carbon dioxide Brayton cycles. Energy Conversion and Management, 2022, 252: 115066.
[4] Li Z., Shi M., Shao Y., et al., Supercritical CO₂ cycles for nuclear-powered marine propulsion: preliminary conceptual design and off-design performance assessment. Journal of Thermal Science, 2024, 33(1): 328–347.
[5] Luo D., Huang D., Thermodynamic and exergoeconomic investigation of various SCO₂ Brayton cycles for next generation nuclear reactors. Energy Conversion and Management, 2020, 209: 112649.
[6] Li M., Wang G., Xu J., et al., Life cycle assessment analysis and comparison of 1000 MW S-CO₂ coal fired power plant and 1000 MW USC Water-Steam Coal-Fired Power Plant. Journal of Thermal Science, 2022, 31(2): 463–484.
[7] Chen D., Han Z., Guo D., et al., Exergoeconomic perspective to evaluate and optimize supercritical carbon dioxide coal-fired power generation system. Energy Conversion and Management, 2021, 244: 114482.
[8] Tong Y., Duan L., Yang M., et al., Design optimization of a new supercritical CO₂ single reheat coal-fired power generation system. Energy, 2021, 239: 122174.
[9] Zhang R., Su W., Lin X., et al., Thermodynamic analysis and parametric optimization of a novel S-CO₂ power cycle for the waste heat recovery of internal combustion engines. Energy, 2020, 209: 118484.
[10] Hao Y., He Q., Fu H., et al., Thermal parameter optimization design of an energy storage system with CO₂ as working fluid. Energy, 2021, 230: 120688.
[11] Liu Y., Wang Y., Zhang Y., et al., Design and performance analysis of compressed CO₂ energy storage of a solar power tower generation system based on the S-CO2 Brayton cycle. Energy Conversion and Management, 2021, 249: 114856.
[12] Xu M., Wang X., Wang Z., et al., Preliminary design and performance assessment of compressed supercritical carbon dioxide energy storage system. Applied Thermal Engineering, 2021, 183: 116153.
[13] Shitsman M.E., Impairment of the heat transmission at supercritical pressures. High Temperature, 1963, 1(2): 237–244.
[14] Ackerman J.W., Pseudo-boiling heat transfer to supercritical pressure water in smooth and ribbed tubes. Transactions of the ASME, Journal of Heat Transfer, 1970, 92: 490–498.
[15] Hall W.B., Heat transfer near the critical point. Advances Heat Transfer, 1971, 7: 1–86.
[16] Jackson J.D., Hall W.B., Influences of buoyancy on heat transfer to fluids flowing in vertical tubes under turbulent conditions. Kakac S., Splading D.B. (Eds.), Turbulent Forced Convection in Channels and Bundles, Hemisphere, Washington, 1979, pp. 613–640.
[17] Jackson J.D., Cotton M.A., Axcell B.P., Studies of mixed convection in vertical tubes. International Journal of Heat and Fluid Flow, 1989, 10(1): 2–15.
[18] Shiralkar B.S., Griffith P., The deterioration in heat transfer to fluids at supercritical pressure and high heat fluxes. Department of Mechanical Engineering, Massachusetts Institute of Technology, 1968, Report No. DSR-70332-70355.
[19] He S., Jiang P., Xu Y., et al., A computational study of convection heat transfer to CO₂ at supercritical pressures in a vertical mini tube. International Journal of Thermal Science, 2005, 44: 521–530.
[20] Kim D.E., Kim M.H., Experimental investigation of heat transfer in vertical upward and downward supercritical CO₂ flow in a circular tube. International Journal of Heat and Fluid Flow, 2011, 32: 176–191.
[21] Wang H., Bi Q., Yang Z., et al., Experimental and numerical investigation of heat transfer from a narrow annulus to supercritical pressure water. Annals Nuclear Energy, 2015, 80: 416–428.
[22] Fan Y., Tang G., Numerical investigation on heat transfer of supercritical carbon dioxide in a vertical tube under circumferentially non-uniform heating. Applied Thermal Engineering, 2018, 138: 354–364.
[23] Simeoni G.G., Bryk T., Gorelli F.A., et al., The Widom line as the crossover between liquid-like and gas-like behavior in supercritical fluids. Nature Physics, 2010, 6(7): 503–507.
[24] Banuti D.T., Crossing the Widom-line—Supercritical pseudo-boiling. Journal of Supercritical Fluids, 2015, 98: 12–16. DOI: 10.1016/j.supflu.2014.12.019
[25] Lemmon E.W., Huber M.L., Mclinden M.O., NIST standard reference database 23: reference fluid thermodynamic and transport properties-refprop, version 9.1, Standard Reference Data Program, NIST. NSRDS, 2010.
[26] Zhu B., Xu J., Wu X., et al., Supercritical “boiling” number, a new parameter to distinguish two regimes of carbon dioxide heat transfer in tubes. International Journal of Thermal Science, 2019, 136: 254–266.
[27] Zhu B., Xu J., Yan C., et al., The general supercritical heat transfer correlation for vertical up-flow tubes: K number correlation. International Journal of Heat and Mass Transfer, 2020, 148: 119080.
[28] Zhang H., Xu J., Zhu X., et al., The K number, a new analogy criterion number to connect pressure drop and heat transfer of SCO₂ in vertical tubes. Applied Thermal Engineering, 2021, 182: 116078.
[29] Longmire N., Banuti D.T., Onset of heat transfer deterioration caused by pseudo-boiling in CO₂ laminar boundary layers. International Journal of Heat and Mass Transfer, 2022, 193: 122957.
[30] Ha M., Yoon T., Tlusty T., et al., Widom delta of supercritical gas-liquid coexistence. Journal of Physical Chemistry Letters, 2018, 9: 1734–1738.
[31] Xu J., Wang Y., Ma X., Phase distribution including a bubblelike region in supercritical fluid. Physical Review E, 2021, 104: 014142.
[32] Wang W., Xu W., Chen T., et al., Numerical calculation of temperature fields on a non-uniformly heated tube wall. Journal of Engineering for Thermal Energy and Power, 2007, 22: 435–439. (in Chinese)
[33] Yan C., Zhu B., Zhang H., et al., Numerical analysis on heat transfer characteristics of supercritical pressure CO₂ in inclined smooth tube. Proceedings CSEE, 2020, 40(2): 583–592. (in Chinese)
[34] Yan C., Zhu B., Yin S., et al., Numerical analysis on flow and heat transfer characteristics of supercritical pressure CO₂ in inclined tube. Scientia Sinica Technologica, 2020, 50(5): 571–581. (in Chinese)
[35] Li Z., Wu Y., Tang G.L., et al., Comparison between heat transfer to supercritical water in a smooth tube and in an internally ribbed tube. International Journal of Heat and Mass Transfer, 2015, 84: 529–541.

Options

Outlines

模态框（Modal）标题

Journal of Thermal Science

Abstract

Cite this article

References