Flow distribution of supercritical hydrocarbon fuel in parallel regenerative cooling channels under non-uniform heat flux

Renshuo Zhu , Xinyan Pei , Sihan Zou , Lingyun Hou

Propulsion and Energy ›› 2025, Vol. 1 ›› Issue (1)

PDF
Propulsion and Energy ›› 2025, Vol. 1 ›› Issue (1) DOI: 10.1007/s44270-024-00001-7
Research

Flow distribution of supercritical hydrocarbon fuel in parallel regenerative cooling channels under non-uniform heat flux

Author information +
History +
PDF

Abstract

Regenerative cooling technology is an important approach for thermal protection in scramjet engines. Non-uniform axial and circumferential heat flow distribution on the combustor leads to improper flow distribution, resulting in reduced cooling efficiency and localized overheating, potentially causing thermal protection failure. To effectively utilize the fuel heat sink and enhance cooling efficiency, it is necessary to investigate the mechanism of flow distribution in the channels under different heat flow conditions. This study investigates the flow and heat transfer characteristics in single cooling and parallel channels under various heat flux. The heat transfer characteristics, flow resistance changes, and the influence of heat flux on heat transfer deterioration are analyzed. There are two types of heat transfer deterioration in channels, caused by the inlet effect and the mutation of fuel supercritical properties. Furthermore, the mechanism behind flow deviation induced by non-uniform heat flux in parallel channels is investigated. When a supercritical process occurs, non-uniform heat flux induces temperature deviations, resulting in density distribution variations. This, in turn, influences velocity distribution and leads to disparities in flow resistance distribution. Consequently, flow deviation occurs, and the cracking reaction amplifies flow deviation while reducing temperature deviation.

Cite this article

Download citation ▾
Renshuo Zhu, Xinyan Pei, Sihan Zou, Lingyun Hou. Flow distribution of supercritical hydrocarbon fuel in parallel regenerative cooling channels under non-uniform heat flux. Propulsion and Energy, 2025, 1(1): DOI:10.1007/s44270-024-00001-7

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Li T, Yang Z, Zhang B. Experimental study on flow instability onset coupling with heat transfer of supercritical fluid in mini-tubes. Exp Therm Fluid Sci, 2019, 109: 109921.

[2]

Zhu J, Tao K, Tao Z, Qiu L. Heat transfer degradation of buoyancy involved convective RP-3 hydrocarbon fuel in vertical tubes with various diameters under supercritical pressure. Appl Therm Eng, 2019, 163: 114392.

[3]

Faulkner R, Weber J. “Hydrocarbon scramjet propulsion system development, demonstration and application”, in 9th International Space Planes and Hypersonic Systems and Technologies Conference, in International Space Planes and Hypersonic Systems and Technologies Conferences. American Institute of Aeronautics and Astronautics, 1999.

[4]

Ning W, Yu P, Jin Z. Research status of active cooling of endothermic hydrocarbon fueled scramjet engine. Proc Inst Mech Eng Part G J Aerosp Eng, 2013, 227(11): 1780-1794.

[5]

Negoescu CC, Li Y, Al-Duri B, Ding Y. Heat transfer behaviour of supercritical nitrogen in the large specific heat region flowing in a vertical tube. Energy, 2017, 134: 1096-1106.

[6]

Lei X, Li H, Zhang W, Dinh NT, Guo Y, Yu S. Experimental study on the difference of heat transfer characteristics between vertical and horizontal flows of supercritical pressure water. Appl Therm Eng, 2017, 113: 609-620.

[7]

Schatte GA, Kohlhepp A, Wieland C, Spliethoff H. Development of a new empirical correlation for the prediction of the onset of the deterioration of heat transfer to supercritical water in vertical tubes. Int J Heat Mass Transf, 2016, 102: 133-141.

[8]

Zhang J, Lin J, Huang D, Li W. Numerical study of heat transfer characteristics of downward supercritical kerosene flow inside circular tubes. J Zhejiang Univ-Sci A, 2018, 19(2): 158-170.

[9]

Yan J, Liu S, Guo P, Bi Q. Experiments on Heat Transfer of Supercritical Pressure Kerosene in Mini Tube under Ultra-High Heat Fluxes. Energies, 2020, 13(5): 5.

[10]

Zhong F, Fan X, Yu G, Li J, Sung C-J. Heat Transfer of Aviation Kerosene at Supercritical Conditions. J Thermophys Heat Transf, 2009, 23(3): 543-550.

[11]

Li Y, Xie G, Sunden B. Flow and thermal performance of supercritical n-decane in double-layer channels for regenerative cooling of a scramjet combustor. Appl Therm Eng, 2020, 180: 115695.

[12]

Tian K, Yang P, Tang Z, Wang J, Zeng M, Wang Q. Effect of pyrolytic reaction of supercritical aviation kerosene RP-3 on heat and mass transfer in the near-wall region. Appl Therm Eng, 2021, 197: 117401.

[13]

Hua Y-X, Wang Y-Z, Meng H. A numerical study of supercritical forced convective heat transfer of n-heptane inside a horizontal miniature tube. J Supercrit Fluids, 2010, 52(1): 36-46.

[14]

Qin J, Zhang S, Bao W, Zhou W, Yu D. Thermal management method of fuel in advanced aeroengines. Energy, 2013, 49: 459-468.

[15]

Zhang S, Feng Y, Zhang D, Jiang Y, Qin J, Bao W. Parametric numerical analysis of regenerative cooling in hydrogen fueled scramjet engines. Int J Hydrog Energy, 2016, 41(25): 10942-10960.

[16]

Zhang S, Qin J, Xie K, Feng Y, Bao W. Thermal Behavior Inside Scramjet Cooling Channels at Different Channel Aspect Ratios. J Propuls Power, 2016, 32(1): 57-70.

[17]

Zhang S, et al.. Thermal behavior in the cracking reaction zone of scramjet cooling channels at different channel aspect ratios. Acta Astronaut, 2016, 127: 41-56.

[18]

Li X, Qin J, Zhang S, Cui N, Bao W. Effects of Microribs on the Thermal Behavior of Transcritical n-Decane in Asymmetric Heated Rectangular Mini-Channels Under Near Critical Pressure. J Heat Transf, 2018, 140(12): 122402.

[19]

Li X, Zhang Y, Zhang S, Qin J, Bao W. Effects of pyrolysis on heat transfer enhancement for hydrocarbon fuel flow in unilateral heated channels with dimples. Appl Therm Eng, 2023, 218: 119301.

[20]

Feng Y, Cao J, Li X, Zhang S, Qin J, Rao Y. Flow and Heat Transfer Characteristics of Supercritical Hydrocarbon Fuel in Mini Channels With Dimples. J Heat Transf, 2017, 139(12): 122401.

[21]

Tong JCK, Sparrow EM, Abraham JP. Geometric strategies for attainment of identical outflows through all of the exit ports of a distribution manifold in a manifold system. Appl Therm Eng, 2009, 29(17): 3552-3560.

[22]

Wang C-C, Yang K-S, Tsai J-S, Chen IY. Characteristics of flow distribution in compact parallel flow heat exchangers, part I: Typical inlet header. Appl Therm Eng, 2011, 31(16): 3226-3234.

[23]

Vist S, Pettersen J. Two-phase flow distribution in compact heat exchanger manifolds. Exp Therm Fluid Sci, 2004, 28(2): 209-215.

[24]

Jiang Y, et al.. The flow rate distribution of hydrocarbon fuel in parallel channels with different cross section shapes. Appl Therm Eng, 2018, 137: 173-183.

[25]

Qin J, et al.. Flow rate distribution of cracked hydrocarbon fuel in parallel pipes. Fuel, 2015, 161: 105-112.

[26]

Jiang Y, et al.. The influences of variable sectional area design on improving the hydrocarbon fuel flow distribution in parallel channels under supercritical pressure. Fuel, 2018, 233: 442-453.

[27]

Jiang Y, Qin J, Chetehouna K, Gascoin N, Bao W. Effect of geometry parameters on the hydrocarbon fuel flow rate distribution in pyrolysis zone of SCRamjet cooling channels. Int J Heat Mass Transf, 2019, 141: 1114-1130.

[28]

Jiang Y, Qin J, Chetehouna K, Gascoin N, Bao W. Parametric study on the hydrocarbon fuel flow rate distribution and cooling effect in non-uniformly heated parallel cooling channels. Int J Heat Mass Transf, 2018, 126: 267-276.

[29]

Gao M, Guo J, Pei X, Hou L. Aspect Ratio Effects on the Noncracking and Cracking Heat Transfer in Microchannels. J Thermophys Heat Transf, 2022, 36(1): 51-60.

[30]

Jiang Y, Zhang S, Feng Y, Cao J, Qin J, Bao W. A control method for flow rate distribution of cracked hydrocarbon fuel in parallel channels. Appl Therm Eng, 2016, 105: 531-536.

[31]

Jing T, He G, Qin F, Li W, Zhang D, Wang M. “Flow Distribution Characteristics of Supercritical Hydrocarbon Fuel in Parallel Channels with Pyrolysis”, Xibei Gongye Daxue XuebaoJournal Northwest. Polytech Univ, 2019, 37(1): 1.

[32]

Jackson JM, Hupert ML, Soper SA. Discrete geometry optimization for reducing flow non-uniformity, asymmetry, and parasitic minor loss pressure drops in Z-type configurations of fuel cells. J Power Sources, 2014, 269: 274-283.

[33]

Pistoresi C, Fan Y, Luo L. Numerical study on the improvement of flow distribution uniformity among parallel mini-channels. Chem Eng Process Process Intensif, 2015, 95: 63-71.

[34]

Chen Y, et al.. Flow distribution of hydrocarbon fuel in parallel minichannels heat exchanger. AIChE J, 2018, 64(7): 2781-2791.

[35]

Zheng S, Guo P, Yan J, Ren S, Wang H. Experimental investigation of the flow distribution of high-pressure CO2 flowing in heated parallel channels. J Supercrit Fluids, 2022, 184: 105569.

[36]

Kim J-J, Baik J-J. A numerical study of the effects of ambient wind direction on flow and dispersion in urban street canyons using the RNG k–ε turbulence model. Atmos Environ, 2004, 38(19): 3039-3048.

[37]

Pei X, Hou L, Roberts WL. Experimental and Numerical Study on Oxidation Deposition Properties of Aviation Kerosene. Energy Fuels, 2018, 32(7): 7444-7450.

[38]

Hou L, Dong N, Sun D. Heat transfer and thermal cracking behavior of hydrocarbon fuel. Fuel, 2013, 103: 1132-1137.

RIGHTS & PERMISSIONS

The Author(s)

AI Summary AI Mindmap
PDF

412

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/