Two-Phase Flow Pattern Map pada Pipa Horizontal dengan Permukaan Halus (Review Paper)

Ronald Akbar

Abstract


Untuk mengetahui pola (rejim) aliran dua fase yang mengalir pada suatu pipa, sampai sekarang terdapat dua metode yang dapat dilakukan yaitu dengan menggunakan high speed camera dan memprediksinya dengan menggunakan flow pattern map. Banyak penelitian terkait perancangan two-phase flow pattern map dilakukan dikarenakan mahalnya teknologi high speed camera ini yang membuat tidak semua peneliti dapat memiliknya. Pada penelitian ini, dilakukan sebuah review berbagai jurnal terkait penelitian two-phase flow pattern map aliran yang mengalir pada pipa horizontal dengan permukaan halus. Dari 18 jurnal dari berbagai peneliti dengan berbagai keadaan yang telah direview, didapat beberapa hasil yang didapatkan diantaranya : dengan berjalannya waktu diketahui bahwa penggunaan fluida kerja dalam penelitian berkembang dari air dan udara menjadi refrijeran, pipa yang digunakan semakin mengecil diameternya, dan dalam penelitiannya divalidasi dengan menggunakan high speed camera. Kemudian flow pattern map versi dahulu dikhawatirkan menimbulkan delay yang besar apabila dipaksa memprediksi data penelitian dengan fluida kerja refrijeran dan pipa skala mikro. Dari penelitian review ini dapat disimpulkan bahwa flow pattern map versi Wojtan et al. [11] dianggap reliable dan memungkinkan untuk digunakan pada penelitian-penelitian berikutnya.


Keywords


aliran dua fase; pipa horizontal; pola aliran; review jurnal; two-phase flow pattern map

Full Text:

PDF

References


Collier, J.G. and J.R. Thome, Convective boiling and condensation. 1994: Clarendon Press.

Ghiaasiaan, S.M., Two-Phase Flow, Boiling, and Condensation: In Conventional and Miniature Systems. 2017: Cambridge University Press.

Baker, O. Design of pipelines for the simultaneous flow of oil and gas. in Fall meeting of the petroleum branch of AIME. 1953. OnePetro.

Mandhane, J., G. Gregory, and K. Aziz, A flow pattern map for gas—liquid flow in horizontal pipes. International journal of multiphase flow, 1974. 1(4): p. 537-553.

Taitel, Y. and A.E. Dukler, A model for predicting flow regime transitions in horizontal and near horizontal gas‐liquid flow. AIChE journal, 1976. 22(1): p. 47-55.

Damianides, C. Two-phase flow patterns in a compact heat exchanger and in small tubes. in Proc. 2nd UK Natn Conf. Heat Transf., 1988.

Wang, C.-C., C.-S. Chiang, and D.-C. Lu, Visual observation of two-phase flow pattern of R-22, R-134a, and R-407C in a 6.5-mm smooth tube. Oceanographic Literature Review, 1998. 2(45): p. 418.

Kattan, N., J. Thome, and D. Favrat, Flow boiling in horizontal tubes: part 1—development of a diabatic two-phase flow pattern map. 1998.

Zurcher, O., J. Thome, and D. Favrat, Evaporation of ammonia in a smooth horizontal tube: heat transfer measurements and predictions. 1999.

Thome, J.R. and J.E. Hajal, Two-phase flow pattern map for evaporation in horizontal tubes: latest version. Heat Transfer Engineering, 2003. 24(6): p. 3-10.

Wojtan, L., T. Ursenbacher, and J.R. Thome, Investigation of flow boiling in horizontal tubes: Part I—A new diabatic two-phase flow pattern map. International journal of heat and mass transfer, 2005. 48(14): p. 2955-2969.

Cheng, L., et al., New prediction methods for CO2 evaporation inside tubes: Part I–A two-phase flow pattern map and a flow pattern based phenomenological model for two-phase flow frictional pressure drops. International Journal of Heat and Mass Transfer, 2008. 51(1-2): p. 111-124.

Barbieri, P., J. Jabardo, and E. Bandarra Filho. Flow patterns in convective boiling of refrigerant R-134a in smooth tubes of several diameters. in Proceedings of the 5th European Thermal-Sciences Conference, Eindhoven, The Netherlands. 2008. Citeseer.

Harirchian, T. and S.V. Garimella, A comprehensive flow regime map for microchannel flow boiling with quantitative transition criteria. International Journal of Heat and Mass Transfer, 2010. 53(13-14): p. 2694-2702.

Ong, C.L. and J. Thome, Macro-to-microchannel transition in two-phase flow: Part 1–Two-phase flow patterns and film thickness measurements. Experimental Thermal and Fluid Science, 2011. 35(1): p. 37-47.

Costa-Patry, E. and J.R. Thome, Flow pattern-based flow boiling heat transfer model for microchannels. International Journal of Refrigeration, 2013. 36(2): p. 414-420.

Zhuang, X., et al., Two-phase flow pattern map for R170 in a horizontal smooth tube. International Journal of Heat and Mass Transfer, 2016. 102: p. 1141-1149.

Yang, Z.-Q., et al., A new flow pattern map for flow boiling of R1234ze (E) in a horizontal tube. International Journal of Multiphase Flow, 2018. 98: p. 24-35.

Yang, Z.-Q., et al., A new diabatic two phase flow pattern transition model of R600a. International Journal of Refrigeration, 2019. 99: p. 138-144.

Pietrasanta, L., et al., Developing flow pattern maps for accelerated two-phase capillary flows. Experimental Thermal and Fluid Science, 2020. 112: p. 109981.

La Rocca, V. and G. Panno, Experimental performance evaluation of a vapour compression refrigerating plant when replacing R22 with alternative refrigerants. Applied energy, 2011. 88(8): p. 2809-2815.

Ausbildungszentrum, W.u., Töss, Zusammenstellung von Leistunsdaten von Wärmenpumpen. Töss, Schweiz, 2002.

Pamitran, A.S., K.-I. Choi, and J.-T. Oh, Evaporation heat transfer coefficient in single circular small tubes for flow natural refrigerants of C3H8, NH3, and CO2. International Journal of Multiphase Flow, 2011. 37(7): p. 794-801.

Da Silva Lima RJ, Quibén JM, Thome JR. Flow boiling in horizontal smooth tubes: New heat transfer results for R-134a at three saturation temperatures. Applied Thermal Engineering. 2009;29(7):1289-98.

Ducoulombier M, Colasson S, Bonjour J, Haberschill P. Carbon dioxide flow boiling in a single microchannel–Part II: Heat transfer. Experimental Thermal and Fluid Science. 2011;35(4):597-611.

Grauso S, Mastrullo R, Mauro A, Thome J, Vanoli GP. Flow pattern map, heat transfer and pressure drops during evaporation of R-1234ze (E) and R134a in a horizontal, circular smooth tube: Experiments and assessment of predictive methods. International journal of refrigeration. 2013;36(2):478-91.

Hamdar M, Zoughaib A, Clodic D. Flow boiling heat transfer and pressure drop of pure HFC-152a in a horizontal mini-channel. International Journal of Refrigeration. 2010;33(3):566-77.

Saisorn S, Kaew-On J, Wongwises S. Two-phase flow of R-134a refrigerant during flow boiling through a horizontal circular mini-channel. Experimental thermal and fluid science. 2011;35(6):887-95.

Anwar Z. Evaporative heat transfer with R134a in a vertical minichannel. Pakistan Journal of Engineering And Applied Sciences. 2016.

Shiferaw D, Huo X, Karayiannis T, Kenning D. Examination of heat transfer correlations and a model for flow boiling of R134a in small diameter tubes. International Journal of Heat and Mass Transfer. 2007;50(25-26):5177-93.




DOI: http://dx.doi.org/10.32497/jrm.v17i3.3692

Refbacks

  • There are currently no refbacks.


Copyright (c) 2022 Jurnal Rekayasa Mesin

_____________________________________________________________________

   

Publisher:

Mechanical Engineering Department, Politeknik Negeri Semarang (Semarang State Polytechnic)
Address: Jl. Prof. Sudarto, SH., Tembalang, Semarang
Email: jurnalrekayasamesin@polines.ac.id
WA: 085669661997

_____________________________________________________________________

Lisensi Creative Commons
This work is licensed under a License Creative Commons Attribution-NonCommercial-ShareAlike 4.0 Internasional.

View Statistics

slot gacor slot gacor hari ini slot gacor 2025 demo slot pg slot gacor slot gacor