Inscrição na biblioteca: Guest
Heat Transfer Research
Regional Editor (China/Asia): Ya-Ling He (open in a new tab)
Regional Editor (Europe): Bengt Sunden (open in a new tab)
Regional Editor (USA): Xinwei Wang (open in a new tab)

Publicou 18 edições por ano

ISSN Imprimir: 1064-2285

ISSN On-line: 2162-6561

The Impact Factor measures the average number of citations received in a particular year by papers published in the journal during the two preceding years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) IF: 1.7 To calculate the five year Impact Factor, citations are counted in 2017 to the previous five years and divided by the source items published in the previous five years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) 5-Year IF: 1.4 The Immediacy Index is the average number of times an article is cited in the year it is published. The journal Immediacy Index indicates how quickly articles in a journal are cited. Immediacy Index: 0.6 The Eigenfactor score, developed by Jevin West and Carl Bergstrom at the University of Washington, is a rating of the total importance of a scientific journal. Journals are rated according to the number of incoming citations, with citations from highly ranked journals weighted to make a larger contribution to the eigenfactor than those from poorly ranked journals. Eigenfactor: 0.00072 The Journal Citation Indicator (JCI) is a single measurement of the field-normalized citation impact of journals in the Web of Science Core Collection across disciplines. The key words here are that the metric is normalized and cross-disciplinary. JCI: 0.43 SJR: 0.318 SNIP: 0.568 CiteScore™:: 3.5 H-Index: 28

Indexed in

Ganhar acesso(open in a new tab)
Mais
Compra $40.00(open in a new tab) Verifique a assinatura Download do registro MARC(open in a new tab) Obter permissões(open in a new tab)

A CONJUGATE MODEL FOR BUBBLE GROWTH IN LOW-VELOCITY SUBCOOLED FLOWS

Volume 51, Edição 14, 2020, pp. 1337-1350
DOI: 10.1615/HeatTransRes.2020034568
Get accessGet access
Maryam Medghalchi
Department of Mechanical and Industrial Engineering, University of Toronto, Toronto, Canada, M5S3G8
Nasser Ashgriz
Department of Mechanical and Industrial Engineering, University of Toronto, Toronto, Ontario M5S 3G8, Canada

RESUMO

A model for the growth of a bubble on a horizontal heated surface with a constant temperature and in a subcooled condition is presented. The model considers microlayer evaporation, transient thermal boundary layer conduction, and surface condensation or evaporation. The bubble growth time is divided into several stages, and the equation describing the bubble growth is simplified for different stages using a new characteristic time, and a new characteristic size. Several analytical solutions for the bubble growth are obtained at the early stages of the bubble growth and before the bubble lifts off. It is shown that before a critical time, the bubble growth is mainly governed by microlayer evaporation, however after the critical time the bubble growth is controlled by surface evaporation.

Palavras-chave: heat exchanger, single bubble growth, flow boiling, multiphase flows
Referências

  1. Chen, Z. and Utaka, Y., On Heat Transfer and Evaporation Characteristics in the Growth Process of a Bubble with Microlayer Structure during Nucleate Boiling, Int. J. Heat Mass Transf., vol. 81, pp. 750-759, 2015.

  2. Cheung, S.C.P., Vahaji, S., Yeoh, G.H., and Tu, J.Y., Modeling Subcooled Flow Boiling in Vertical Channels at Low Pressures-Part 1: Assessment of Empirical Correlations, Int. J. Heat Mass Transf., vol. 75, pp. 736-753, 2014.

  3. Colombo, M. and Fairweather, M., Prediction of Bubble Departure in Forced Convection Boiling: A Mechanistic Mode, Int. J. Heat Mass Transf, vol. 85, pp. 135-146, 2015.

  4. Cooper, M.G., The Microlayer and Bubble Growth in Nucleate Pool Boiling, Int. J. Heat Mass Transf., vol. 12, pp. 915-933, 1969.

  5. Cooper, M.G. and Lloyd, A.J.P., The Microlayer in Nucleate Pool Boiling, Int. J. Heat Mass Transf., vol. 12, pp. 895-913, 1969.

  6. Das, S.K. and Roetzel, W., A Composite Heat Transfer Model for Pool Boiling on a Horizontal Tube at Moderate Pressure, Can. J. Chem. Eng., vol. 82, pp. 316-322, 2004.

  7. Dhir, V.K., Abarajith, H.S., and Li, D., Bubble Dynamics and Heat Transfer during Pool and Flow Boiling, Heat Transf. Eng., vol. 28, no. 7, pp. 608-624, 2007.

  8. Foster, H.K. and Grief, R., Heat Transfer to Boiling Liquid, Mechanism and Correlations, Trans. ASME J. Heat Transf., vol. 81, pp. 43-53, 1958.

  9. Han, C.Y. and Griffith, P., The Mechanism of Heat Transfer in Nucleate Pool Boiling-Part I, Int. J. Heat Mass Transf., vol. 8, pp. 887-904, 1965.

  10. Hsieh, Y.Y., Chiang, L.J., and Lin, T.F., Subcooled Flow Boiling Heat Transfer of R-134a and the Associated Bubble Characteristics in a Vertical Plate Heat Exchanger, Int. J. Heat Mass Transf., vol. 45, pp. 1791-1806, 2002.

  11. Hsu, Y. Y. and Graham, R.W., An Analytical and Experimental Study of the Thermal Boundary Layer and Ebullition Cycle in Nucleate Boiling, NASA Tech. Rep. TND-594, Cleveland, OH, 1961.

  12. Huang, Y.L and Shi, S.S., Numerical Simulation of Vapor-Liquid Phase Flow and Vapor-Liquid Phase Change, Int. Conf. on Computer Systems and Industrial Applications (CISIA), Bangkok, Thailand, 2015.

  13. Jia, H.W., Zheng, P., Fu, X., and Jiang, S.C., A Numerical Investigation of Nucleate Boiling at a Constant Surface Temperature, App/. Therm. Eng., vol. 83, pp. 248-257, 2015.

  14. Jung, S. and Kim, H., An Experimental Method to Simultaneously Measure the Dynamics and Heat Transfer Associated with a Single Bubble during Nucleate Boiling on a Horizontal Surface, Int. J. Heat Mass Transf., vol. 73, pp. 365-375, 2014.

  15. Kunkelmann, C. and Stephan, P., Numerical Simulation of the Transient Heat Transfer during Nucleate Boiling of Refrigerant HTF-7100, Int. J. Refrig., vol. 33, pp. 1221-1228, 2010.

  16. Lal, S., Sato, Y., and Niceno, B., Direct Numerical Simulation of Bubble Dynamics in Subcooled and Near-Saturated Convective Boiling, Int. J. HeatF/uid F/ows, vol. 51, pp. 16-28, 2015.

  17. Marek, R. and Straub, J., Analysis of the Evaporation Coefficient and the Condensation Coefficient of Water, Int. J. Heat Mass Transf, vol. 44, pp. 39-53, 2001.

  18. Medghalchi, M., Heat and Mass Transfer around a Bubble on a Horizontal Surface in a Subcooled Flow, PhD, University of Toronto, Toronto, 2016.

  19. Ose, Y. and Kunugi, T., Development of a Boiling and Condensation Model on Subcooled Boiling Phenomena, Energy Procedia, vol. 9, pp. 605-618, 2011.

  20. Ose, Y. and Kunugi, T., Numerical Simulation of Bubble Departure in Subcooled Pool Boiling Based on Non-Empirical Boiling and Condensation Model, 7th Int. Symp. on Mu/tiphase F/ow, Heat Mass Transfer and Energy Conversion. Conf. Proc, vol. 1547, pp. 733-740, 2013.

  21. Plesset, M.S. and Zwick, S.A., The Growth of Vapor Bubbles in Superheated Liquids, J. App/. Phys., vol. 25, pp. 493-500, 1954.

  22. Prodanovic, V., Fraser, D., and Salcudean, M., Bubble Behavior in Subcooled Flow Boiling of Water at Low Pressure and Low Flow Rates, Int. J. Mu/tiphase F/ow, vol. 28, pp. 1-19, 2002.

  23. Ranz, W.E. and Marshal, W.R., Evaporation from Drops, Chem. Eng. Prog., vol. 48, pp. 141-146, 1952.

  24. Son, G., Numerical Study on a Sliding Bubble during Nucleate Boiling, KSME Int. J., vol. 15, no. 7, pp. 931-940, 2001.

  25. Stephan, P.C. and Busse, C.A., Analysis of the Heat Transfer Coefficient of Grooved Heat Pipe Evaporator Walls, Int. J. Heat Mass Transf., vol. 35, pp. 383-391, 1992.

  26. Sun, D., Xu, J., and Chen, Q., Modeling of the Evaporation and Condensation Phase-Change Problems with Fluent, Numer. Heat Transf., Part B, vol. 66, pp. 326-342, 2014.

  27. Surgue, R.M., The Effect of Orientation Angle, Subcooling, Heat Flux, Mass Flux, and Pressure on Bubble Growth and Detachment in Subcooled Flow Boiling, Masters, Massachusetts Institute of Technology, Cambridge, MA, 2012.

  28. Synder, N.R. and Edwards, D.K., Summary of Conference on Bubble Dynamics and Boiling Heat Transfer, Memo (20-37) Jet Prop. Lab., 1956.

  29. Tong, L.S. and Tang, Y.S., Boi/ing Heat Transfer and Two Phase F/ow, Milton Park, UK: Taylor and Francis Press, 1997.

  30. Unal, H.C., Maximum Bubble Diameter, Maximum Bubble Growth Time and Bubble Growth Rate during the Subcooled Nucleate Flow Boiling, Int. J. Heat Mass Transf., vol. 19, pp. 643-649, 1976.

  31. Utaka, Y., Kashiwabara, Y., and Ozaki, M., Microlayer Structure in Nucleate Boiling of Water and Ethanol at Atmospheric Pressure, Int. J. Heat Mass Transf., vol. 57, pp. 222-230, 2013.

738 Visualizações do artigo 25 downloads de artigos Métricas
738 VISUALIZAÇÕES 25 TRANSFERÊNCIAS Google
Scholar CITAÇÕES

Artigos com conteúdo semelhante:

Comparison of Different Heat Transfer Mechanisms Governing the Growth of a Bubble on a Heated Surface and in a Subcooled Flow ICHMT DIGITAL LIBRARY ONLINE, Vol.0, 2018, issue
Maryam Medghalchi, Nasser Ashgriz
HEAT TRANSFER TO A SLIDING VAPOUR BUBBLE Multiphase Science and Technology, Vol.14, 2002, issue 1
D. B. R. Kenning, Y. Yan, O. E. Bustnes
BUBBLE BEHAVIOR AND BUBBLE GROWTH MODEL OF HIGHLY SUBCOOLED FLOW BOILING IN A VERTICAL RECTANGULAR CHANNEL Heat Transfer Research, Vol.49, 2018, issue 12
Dewen Yuan, Jianjun Xu, Yunke Zhong, Yanping Huang, Deqi Chen, Xiao Yan
BUBBLE DYNAMICS DURING POOL BOILING UNDER MICROGRAVITY CONDITIONS Computational Thermal Sciences: An International Journal, Vol.4, 2012, issue 6
Dean Vijay K. Dhir, Eduardo Aktinol, G. R. Warrier
Heat Transfer and Interaction of Suspended Droplets and Locally Heated Liquid Layer International Heat Transfer Conference 15, Vol.15, 2014, issue
Alexander A. Fedorets, Igor V. Marchuk, Oleg A. Kabov

Última edição

A TEMPERATURE PRE-RECTIFIER WITH CONTINUOUS HEAT STORAGE AND RELEASE FOR WASTE HEAT RECOVERY FROM PERIODIC FLUE GAS Hengyu Qu, Binfan Jiang, Xiangjun Liu, Dehong Xia INVESTIGATION OF THE EFFECT OF DEAD-STATE TEMPERATURE ON THE PERFORMANCE OF BORON-ADDED FUELS AND DIFFERENT FUELS USED IN AN INTERNAL COMBUSTION ENGINE İrfan Uçkan, Ahmet Yakın, Rasim Behçet PREDICTION OF PARAMETERS OF BOILER SUPERHEATER BASED ON TRANSFER LEARNING METHOD Shuiguang Tong, Qi Yang, Zheming Tong, Haidan Wang, Xin Chen TEMPERATURE CORRECTION METHOD OF RADIATION THERMOMETER BASED ON THE NONLINEAR MODEL FITTED FROM SPECTRAL EMISSIVITY MEASUREMENTS OF Ni-BASED ALLOY Yanfen Xu, Kaihua Zhang, Kun Yu, Yufang Liu

Próximos artigos

Effect of Metal Foam Filling Position and Porosity on Heat Transfer of PCM: A Visualized Experimental Study Xuesong Zhang, Jun Wang, Zhiwei Wu, Xiaolin Li, Wenxiang Cao Modeling the Influence of Nanoparticles and Gyrotactic Microorganisms on Natural Convection in a Heated Square Cavity: A New Machine-Learning Study Andaç Batur Çolak Optimization of Micro Heat Sink with Repetitive pattern of Obstacles for Electronic Cooling Applications Digvijay Ronge, Prashant Pawar Experimental Investigation on the Application Potential of Finless Heat Exchanger with Mini-Diameter Tubes Utilized as Air Heater or Air Cooler Binfei Zhan, Zhichao Wang, Shuangquan Shao, Zhaowei Xu, Jiandong Li, Jing Yan, Lichao Han Effective Efficiency Analysis of Artificially Roughed Solar Air Heater MAN AZAD Energy, Exergy-Emission Performance Investigation of Heat Exchanger with Turbulators Inserts and Ternary Hybrid Nanofluid Ranjeet Rai, Vikash Kumar, Rashmi Rekha Sahoo A temperature pre-rectifier with continuous heat storage and release for waste heat recovery from periodic flue gas Hengyu Qu, Binfan Jiang, Xiangjun Liu, Dehong Xia Examining the Synergistic Use of East-West Reflector and Coal Cinder in Trapezoidal Solar Pond through Energy Analysis VINOTH KUMAR J, AMARKARTHIK ARUNACHALAM
Portal Digital Begell Biblioteca digital da Begell eBooks Diários Referências e Anais Coleções de pesquisa Políticas de preços e assinaturas Begell House Contato Language English 中文 Русский Português German French Spain