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Warianty tytułu
Języki publikacji
Abstrakty
The paper describes applications of the vibration-assisted laser surface texturing and spark erosion process as methods of modifying properties and structures of metal surfaces. Practical aspects of the use of produced surfaces in the heat exchanger with a minichannel have been described. Compared with smooth surfaces, developed metal surfaces obtained by vibration-assisted laser surface texturing and electromachining show more effective heat transfer. The local heat transfer coefficient for the saturated boiling region obtained for developed surfaces had the values significantly higher than those obtained for the smooth plate at the same heat flux. The experimental results are presented as the heated plate temperature (obtained from infrared thermography) and relationships between the heat transfer coefficient and the distance along the length of the minichannel for the saturated boiling region.
Wydawca
Czasopismo
Rocznik
Tom
Strony
1983--1990
Opis fizyczny
Bibliogr. 37 poz., rys., tab., wykr., wzory
Twórcy
autor
- Kielce University of Technology, 7 1000-Lecia P.P. Av., 25-314 Kielce, Poland
autor
- Kielce University of Technology, 7 1000-Lecia P.P. Av., 25-314 Kielce, Poland
autor
- Kielce University of Technology, 7 1000-Lecia P.P. Av., 25-314 Kielce, Poland
Bibliografia
- [1] R. Pastuszko, M. Piasecka, Pool boiling on surfaces with mini-fins and micro-cavities, J. Phys. Conf. Ser. 395 (12137), 7 (2012).
- [2] R. Pastuszko, Pool boiling on rectangular fins with tunnel-pore structure, EPJ Web of Conferences 45 (01020), 5 (2013).
- [3] T. Orzechowski, K. Stokowiec, Quasi-stationary phase change heat transfer on a fin, EPJ Web Conf. 114 (02086), 5 (2016).
- [4] N. Radek, Ł. J. Orman, Preliminary data of boiling heat transfer of laser treated heat exchanger surfaces, in: J. I. Shalapko, L. A. Dobrzanski (Eds.), Scientific Basis of Modern Technologies: Experience and Prospects, Khmelnytskyi National University, Jaremche, Ukraine, 236-245 (2011).
- [5] L. Dąbek, A. Kapjor, Ł. J. Orman, Ethyl alcohol boiling heat transfer on multilayer meshed surfaces, AIP Conference Proceedings, 1745, 1-5 (2016).
- [6] M. Piasecka, Correlations for flow boiling heat transfer in mini-channels with various orientations, Int. J. Heat Mass Transf. 81, 114-121 (2015).
- [7] M. Piasecka, Impact of selected parameters on refrigerant flow boiling heat transfer and pressure drop in minichannels, Int. J. Refrig. 56, 198-212 (2015).
- [8] M. Piasecka, Heat transfer research on enhanced heating surfaces in flow boiling in a minichannel and pool boiling, Ann. Nucl. Energy, 73, 282-293 (2014).
- [9] T. Orzechowski, Boiling heat transfer on the fin with laser modified surface, Int. Symp. on Convective Heat and Mass Transfer in Sustainable Energy, April 26-May, Tunisia, 1-14 (2009).
- [10] M. Ameli, B. Agnew, P. S. Leung, B. Ng, C. J. Sutcliffe, J. Singh, R. McGlen, A novel method for manufacturing sintered aluminium heat pipes (SAHP), Appl. Therm. Eng. 52 (2), 498-504 (2013).
- [11] A. D. Sommers, K. L. Yerkes, Using micro-structural surface features to enhance the convective flow boiling heat transfer of R-134a on aluminum, Int. J. Heat Mass Transf. 64, 1053-1063 (2013).
- [12] B. Maciejewska, K. Strąk, M. Piasecka, The solution of a two-dimensional inverse heat transfer problem using the Trefftz method, Procedia Eng. 157, 82-88 (2016).
- [13] B. Grabas, Vibration-assisted laser surface texturing of metals as a passive method for heat transfer enhancement, Exp. Therm. Fluid Sci. 68, 499-508 (2015).
- [14] N. Radek, B. Antoszewski, The influence of laser treatment on the properties of electro-spark deposited coatings, Kovove Materialy-Metallic Materials 47 (1), 31-38 (2009).
- [15] W. Depczyński, Sintering of copper layers with a controlled porous structure, METAL 2014 23rd Int. Conf. Metallurgy and Materials, Ostrava, 1219-1224 (2014).
- [16] W. Depczyński, P. Młynarczyk, S. Spadło, E. Ziach, P. Hepner, The selected properties of porous layers formed by pulse micro-welding technique, 24th Int. Con. Metallurgy and Materials, Brno, 1087-1092 (2015).
- [17] S. Blasiak, J. E. Takosoglu, P. A. Laski, Heat transfer and thermal deformations in non-contacting face seals, J. Therm. Sci. Technol. 9 (2), 1-8 (2014).
- [18] S. Blasiak, An analytical approach to heat transfer and thermal distortions in non-contacting face seals, Int. J. Heat Mass Transf. 81, 90-102 (2015).
- [19] J. T. Cieśliński, K. Krygier, Influence of surface curvature on sessile droplet contact angle of nanofluids, Trans. Inst. Fluid-Flow Mach. 125, 3-12 (2013).
- [20] H. Boertz, A. Baars, J. T. Cieśliński, S. Smolen, Turbulence model evaluation for numerical modelling of turbulent flow and heat transfer of nanofluids, Appl. Mech. Mater. 831, 165-180, (2016).
- [21] J. T. Cieśliński, A. Fiuk, B. Siemieńczuk, Performance of a plate heat exchanger operated with water-Al2O3 nanofluid, Appl. Mech. Mater. 831, 188-197 (2016).
- [22] O. S. Prajapati, N. Rohatgi, Flow boiling heat transfer enhancement by using ZnO-water nanofluids, Hindawi Publ. Corp. 2014, 7 pages (2014).
- [23] L. Yu, A. Sur, D. Liu, Flow boiling heat transfer and two-phase flow instability of nanofluids in a minichannel, J. Heat Transfer, 137 (051502), 1-11 (2015).
- [24] A. Dominic, J. Sarangan, S. Suresh, V. S. Devah Dhanush, An experimental investigation of wavy and straight minichannel heat sinks using water and nanofluids, J. Therm. Sci. Eng. Appl. 7 (3), 9 pages (2015).
- [25] A. A. Chehade, H. L. Gualous, S. Le Masson, F. Fardoun, A. Besq, Boiling local heat transfer enhancement in minichannels using nanofluids, Nanoscale Res. Lett. 8, 20 p. (2013).
- [26] M. Piasecka, Laser texturing, spark erosion and sanding of the surfaces and their practical applications in heat exchange devices, Adv. Mater. Res. 874, 95-100 (2014).
- [27] B. Grabas, Impact of the parameters of laser-vibration treatment on the roughness of aluminium melts, Adv. Mater. Res. 874, 71-75 (2014).
- [28] Calibration certificate No. K1501035, Calibration laboratory No. 2372, accredited by Czech ccreditation Institute under ČSN EN ISO/IEC 17025:2005 for: Calibration of non-contact temperature measuring instruments.
- [29] www.haynesintl.com.
- [30] M. Piasecka, K. Strąk, B. Maciejewska, Calculations of flow boiling heat transfer in a minichannel based on Liquid Crystal and Infrared Thermography data, Heat Transf. Eng. 38 (3), 332-346 (2017).
- [31] M. Piasecka, Determination of the Temperature field using Liquid Crystal Thermography and analysis of two-phase flow structures in research on boiling heat transfer in a minichannel, Metrol. Meas. Syst. XX (2), 205-216 (2013).
- [32] M. Piasecka, B. Maciejewska, The study of boiling heat transfer in vertically and horizontally oriented rectangular minichannels and the solution to the inverse heat transfer problem with the use of the Beck method and Trefftz functions, Exp. Therm. Fluid Sci. 38, 19-32 (2012).
- [33] M. Piasecka, Theoretical and experimental investigations into flow boiling heat transfer in a narrow channel (in Polish), Ph. D. Thesis. Poland: Kielce University of Technology, 2002.
- [34] B. Maciejewska, M. Piasecka, Trefftz function-based thermal solution of inverse problem in unsteady-state flow boiling heat transfer in a minichannel, Int. J. Heat Mass Transf. 107, 925-933 (2017).
- [35] M. Piasecka, B. Maciejewska, Heat transfer coefficient during flow boiling in a minichannel at variable spatial orientation, Exp. Therm. Fluid Sci. 68, 459-467 (2015).
- [36] S. Hożejowska, M. Piasecka, Equalizing calculus in Trefftz method for solving two-dimensional temperature field of FC-72 flowing along the minichannel, Heat Mass Transf. 50 (8), 1053-1063 (2014).
- [37] M. Piasecka, D. Michalski, K. Strąk, Comparison of two methods for contactless surface temperature measurement, EPJ Web Conf. 114 (02094), 9 (2016).
Uwagi
EN
The research reported herein was supported by the grant from the Polish National Science Centre (No. DEC-2013/09/B/ST8/02825)
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b410161b-f8c6-4cf3-8f7e-951f5d3f7c5f