Vortex Intensification of Heat Transfer in Channels and Pipes with Periodic Elements of Discrete Roughness

被引:1
|
作者
Isaev, S. A. [1 ]
Chornyi, A. D. [2 ]
Zhukova, Yu, V [2 ]
Vysotskaya, A. A. [1 ]
Kharchenko, V. B. [1 ]
机构
[1] St Petersburg State Univ Civil Aviat, 38 Pilotov Str, St Petersburg 196210, Russia
[2] Natl Acad Sci Belarus, AV Luikov Heat & Mass Transfer Inst, 15 P Brovka Str, Minsk 220072, BELARUS
来源
JOURNAL OF ENGINEERING PHYSICS AND THERMOPHYSICS | 2019年 / 92卷 / 06期
基金
俄罗斯基础研究基金会;
关键词
vortex intensification; turbulent flow; channels; pipes; discrete roughness;
D O I
10.1007/s10891-019-02070-x
中图分类号
O414.1 [热力学];
学科分类号
摘要
A complex numerical investigation of vortex intensification of heat transfer in turbulent inhomogeneous medium flow in channels and pipes with periodic elements of discrete roughness has been carried out with the use of multiblock computational technologies, realized in a specialized package VP2/3, and of a modified model of transfer of shear stresses. As roughness elements use was made of asperities and grooves of different geometries, with air and transformer oil used as a working medium. The influence of the geometrical parameters of the indicated channels and pipes as well as of the regime parameters of the flow in them on their thermal and hydraulic efficiency has been analyzed in detail.
引用
收藏
页码:1509 / 1516
页数:8
相关论文
共 50 条
  • [21] ROUGHNESS EFFECTS ON FLOW AND HEAT TRANSFER FOR ADDITIVELY MANUFACTURED CHANNELS
    Stimpson, Curtis K.
    Snyder, Jacob C.
    Thole, Karen A.
    Mongillo, Dominic
    ASME TURBO EXPO: TURBINE TECHNICAL CONFERENCE AND EXPOSITION, 2015, VOL 5A, 2015,
  • [22] Roughness Effects on Flow and Heat Transfer for Additively Manufactured Channels
    Stimpson, Curtis K.
    Snyder, Jacob C.
    Thole, Karen A.
    Mongillo, Dominic
    JOURNAL OF TURBOMACHINERY-TRANSACTIONS OF THE ASME, 2016, 138 (05):
  • [23] The influence of a porous, compliant layer with overlying discrete roughness elements as exhaust pipe wall on friction and heat transfer
    Reurings, C.
    Koussios, S.
    Bergsma, O. K.
    Breugem, W. -P.
    Vergote, K.
    Paeshuyse, L.
    Benedictus, R.
    HEAT AND MASS TRANSFER, 2020, 56 (08) : 2367 - 2387
  • [24] Simulation of Limiting Heat Transfer under Combined Intensification of Heat Transfer by Circular Vortex Generators and Tape Swirlers
    Dreitser, G. A.
    Lobanov, I. E.
    HEAT TRANSFER RESEARCH, 2006, 37 (08) : 651 - 662
  • [25] The influence of a porous, compliant layer with overlying discrete roughness elements as exhaust pipe wall on friction and heat transfer
    C. Reurings
    S. Koussios
    O. K. Bergsma
    W.-P. Breugem
    K. Vergote
    L. Paeshuyse
    R. Benedictus
    Heat and Mass Transfer, 2020, 56 : 2367 - 2387
  • [26] Effects of roughness elements on laminar flow and heat transfer in microchannels
    Zhang, Chengbin
    Chen, Yongping
    Shi, Mingheng
    CHEMICAL ENGINEERING AND PROCESSING-PROCESS INTENSIFICATION, 2010, 49 (11) : 1188 - 1192
  • [27] Turbulent heat transfer in pipes with increased roughness through shavings of helical ribs
    Kuegele, Simon
    Mathlouthi, Gino Omar
    Renze, Peter
    Dietl, Jochen
    Gruetzner, Thomas
    INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 2023, 210
  • [28] The roughness effects on friction and heat transfer in the fully developed turbulent flow in pipes
    Ceylan, K
    Kelbaliyev, G
    APPLIED THERMAL ENGINEERING, 2003, 23 (05) : 557 - 570
  • [29] Intensification of heat transfer and friction in the vortex matrices with semicylindrical protrusions on the surface of ribs
    Gorelov, YG
    IZVESTIYA VYSSHIKH UCHEBNYKH ZAVEDENII AVIATSIONAYA TEKHNIKA, 2002, (02): : 33 - 37
  • [30] Effect of longitudinal vortex generator on heat transfer in rectangular channels
    Wu, J. M.
    Tao, W. Q.
    APPLIED THERMAL ENGINEERING, 2012, 37 : 67 - 72
12345