THERMAL SCIENCE
International Scientific Journal
EFFECT OF VIBRATION IN COOLING CHANNEL ON HEAT TRANSFER OF AVIATION KEROSENE FLOWING UNDER DIFFERENT PRESSURES
ABSTRACT
In this study, experimental methods are used to investigate the effects of different vibration and pressure parameters on heat transfer performance are analyzed. The results show that at a subcritical pressure (0.1 MPa), the external vibration begins to affect the heat transfer when the fuel passes the phase-change point and becomes gaseous. At a near-critical pressure (3 MPa), the external vibration deteriorates the heat transfer of fuel across the critical-temperature zone. At the supercritical pressure (5 MPa), the external vibration intensifies the heat transfer in the hot end of the channel only when the fuel is below the critical temperature and the internal wall is above the critical pressure. Combined with data analysis, it can be seen that the external vibration mainly acts on the temperature boundary layer of the fuel oil to affect the wall temperature and heat transfer coefficient.
KEYWORDS
PAPER SUBMITTED: 2022-05-23
PAPER REVISED: 2022-06-06
PAPER ACCEPTED: 2022-07-03
PUBLISHED ONLINE: 2022-08-13
THERMAL SCIENCE YEAR
2023, VOLUME
27, ISSUE
Issue 1, PAGES [151 - 166]
- Zhang, J. L., et al., Investigations on Flame Liftoff Characteristics in Liquid-kerosene Fueled Supersonic Combustor Equipped with Thin Strut, Aerospace Science and Technology, 84 (2019), pp. 686-697
- Srinivasan, K., et al., Supersonic Combustion of A Scramjet Engine Using Hydrogen Fuel in Shock Tunnel, AIAA,56 (2018), 9, pp. 3600-3609
- Ma, J. C., et al., Control-oriented Unsteady One-dimensional Model for A Hydrocarbon Regeneratively-cooled Scramjet Engine, Aerospace Science and Technology, 85 (2019), pp. 158-170
- Gascoin, N., et al., Validation of Transient Cooling Modeling for Hypersonic Application, Journal of Thermophysics and Heat Transfer, 21 (2007), 1, pp. 86-94
- QIN, A., et al., Multi-Objective Optimization on Regenerative Cooling Structure of Scramjet, Journal of Propulsion Technology, 39 (2018), 6, pp. 136-144
- Zhang, S. L., et al., Review on Regenerative Cooling Technology of Hypersonic Propulsion, Journal of Propulsion Technology, 39 (2018), 10, pp. 23-36
- Han, Y., et al., Assessment of a hybrid RANS/LES Simulation Method and URANS Method in Depicting the Unsteady Motions of Flow Structures in a Scramjet Combustor, Aerospace Science and Technology, 72 (2018), pp. 114-122
- Ma, F., et al. Thermoacoustic Flow Instability in a Scramjet Combustor, 41st AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. 2005: 3824
- Lemlich, Robert., Effect of Vibration on Natural Convective Heat Transfer, Industrial & Engineering Chemistry, 47 (1955), 6, pp. 61-73
- Lemlich, R., Rao, M. A., The Effect of Transverse Vibration on Free Convection from a Horizontal Cylinder, International Journal of Heat & Mass Transfer, 8 (1965), 1, pp. 27-33
- Deaver, F. K., et al., Heat Transfer From an Oscillating Horizontal Wire to Water, Journal of Heat Transfer, 84 (1966), 3, p. 251
- Penney, W. R., Jefferson, T. B., Heat Transfer From an Oscillating Horizontal Wire to Water and Ethylene Glycol, Journal of Heat Transfer, 88 (1966), 4, pp. 359
- Hsieh, R., Marsters, G. F., Heat Transfer from a Vibrating Vertical Array of Horizontal Cylinders, The Canadian Journal of Chemical Engineering, 51 (1973), 3, pp. 302-306
- Dawood, A. S., et al., The effect of vertical vibrations on natural convection heat transfer from a horizontal cylinder, International Journal of Heat & Mass Transfer, 24 (1981), 3, pp. 491-496.
- Scanlan, J. A., Effects of Normal Surface Vibration on Laminar Forced Convective Heat Transfer, Industrial & Engineering Chemistry, 50 (1958), 10, pp. 1565-1568
- Saxena, U. C., et al., Heat Transfer from a Cylinder Oscillating in a Cross-Flow, Journal of Heat Transfer, 100 (1978), 4, pp. 684
- C.T. Leung., et al., Heat Transfer From a Vibrating Cylinder, Journal of Sound & Vibration, 1981, 75 (4):581-582
- Katinas, V. I., et al., Heat Transfer Behavior of Vibrating Tubes Operating in Crossflow. 1. Temperature and Velocity Fluctuations, Heat Transfer-Soviet Research, 18 (1986), 2, pp. 1-9
- Cheng, C. H., et al., Experimental Study of the Effect of Transverse Oscillation on Convection Heat Transfer From a Circular Cylinder, Journal of Heat Transfer, 119 (1997), 3, pp. 474-482
- Gau, C., et al., Heat Transfer Enhancement and Vortex Flow Structure over a Heated Cylinder Oscillating in the Crossflow Direction, Journal of Heat Transfer, 121 (1999), 4, pp. 789-795
- Bronfenbrener, L., et al., Experimental Study of Heat Transfer Intensification under Vibration Condition, Chemical Engineering & Technology, 24 (2015), 4, pp. 367-371
- Fu, W. S., Tong, B. H., Numerical Investigation of Heat Transfer from a Heated Oscillating Cylinder in a Cross Flow, International Journal of Heat & Mass Transfer, 45 (2002), 14, pp. 3033-3043
- Lee, Y. H., et al., An Experimental Investigation on the Critical Heat Flux Enhancement by Mechanical Vibration in Vertical Round Tube, Nuclear Engineering & Design, 229 (2004), 1, pp. 47-58
- Leng, X. L., et al., Hear Transfer Properties of the Vibrational Pipe When Fluid Passes by It Slowly, Journal of Engineering Thermophysics, 024 (2003), 002, pp. 328-330
- Klaczak A., Report from Experiments on Heat Transfer by Forced Vibrations of Exchangers, Heat & Mass Transfer, 32 (1997), 6, pp. 477-480
- Sarhan, A. R, Karima., et al., Experimental Investigation on the Effect of Vertical Vibration on Thermal Performances of Rectangular Flat Plate, Experimental Thermal and Fluid Science, 101(2019), PP. 231-240
- Jiang B., Analysis on Mechanism of Heat Transfer Enhancement by Vibration and Experimental Research on a New Type of Vibrational Heat Transfer Component, Ph. D. thesis, Shandong University, China, 2010
