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Boiling of Liquids: Main Lines of Scientific Studies (Based of the Proceedings of the IHTC-16 and RNHTC-7)

  • HEAT AND MASS TRANSFER AND PROPERTIES OF WORKING FLUIDS AND MATERIALS
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Abstract—

The article is a review devoted to boiling heat transfer problems based on the reports discussed at the two largest conferences held in 2018. Boiling and evaporation issues were addressed in approximately 150 reports, and approximately half of them are considered in this review. The review contains four sections: vapor phase incipience and vapor bubble dynamics, pool boiling heat transfer and burnout, boiling in channels, and unsteady film boiling. This division is conditional in nature because some reports can be related to two sections according to their content. Although the author of the review tried to reflect the content of reports in a maximally unbiased manner, the review text also reflects his own assessments. The author’s 50 years of experience in the scientific research fields that are the subject of analysis enables him to do so.

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REFERENCES

  1. P. A. Pavlov, “Dynamics of a vapor bubble of near-critical radius,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 526–529.

  2. V. E. Vinogradov and P. A. Pavlov, “Pulse overheating of weak solutions of PES-4 and dodecane in freon-11 and n-hexane in the region of negative pressures,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 479–482.

  3. V. G. Baidakov and V. M. Bryukhanov, “Spontaneous cavitation in binary solutions: Molecular dynamics simulation,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 131–134.

  4. V. G. Baidakov and A. M. Kaverin, “Achievable overheating of gas-saturated cryogenic liquids,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 134–136.

  5. I. A. Kozulin and V. V. Kuznetsov, “Dynamics of explosive boiling of water on a flat and nanostructured microheater,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 513–517.

  6. I. A. Kozulin and V. V. Kuznetsov, “Explosive evaporation of water and propanol on flat and nanostructured microheaters,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id. IHTC16-22907.

  7. D. A. Labuntsov and V. V. Yagov, Mechanics of Two-Phase Systems (Mosk. Energ. Inst., Moscow, 2007).

    Google Scholar 

  8. J. Bhati, H. H. Desai, and S. Paruya, “Revisiting the Scriven theory of bubble growth in superheated water,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id. IHTC16-23509.

  9. H. S. Lee and H. Merte, Jr., “Spherical vapor bubble growth in uniformly superheated liquids,” Int. J. Heat Mass Transfer 39, 2427–2447 (1996).

    Article  Google Scholar 

  10. J. R. Thome and G. Davey, “Bubble growth rates in liquid nitrogen, argon and their mixtures,” Int. J. Heat Mass Transfer 24, 89–97 (1981).

    Article  Google Scholar 

  11. G. Giustini, K. H. Ardron, and S. P. Walker, “A semi-analytical model of bubble growth and detachment during nucleate boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23319.

  12. W. Ding, D. Sarker, and U. Hampel, “Impact of surface characteristics on microlayer, bubble dimensions and departure in nucleate boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23121.

  13. M. G. Cooper and T. T. Chandratilleke, “Growth of diffusion-controlled vapor bubbles at a wall on a known temperature gradient,” Int. J. Heat Mass Transfer 24, 1475–1492 (1981).

    Article  Google Scholar 

  14. K. Hu, Z. Chen, and Y. Utaka, “Study on characteristics of formation and evaporation of microlayer using laser interferometry during nucleate pool boiling for water and ethanol,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23120.

  15. M. Takeyama, T. Kunugi, T. Yokomine, and Z. Kawara, “Study on superheated liquid layer in pool boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23750.

  16. A. S. Surtaev, V. S. Serdyukov, A. N. Pavlenko, and V. V. Tumanov, “Investigation of the dynamics of vaporization during boiling of liquids on the surface of a transparent heater in the region of low and high heat fluxes,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 543–546.

  17. Z. Cao, D. Sun, J. Wei, and B. Yu, “Numerical simulation of bubble dynamics and heat transfer during nucleate boiling of FC-72 by using the 3d-VOSET method,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22743.

  18. N. V. Vasiliev, Yu. A. Zeigarnik, and K. A. Khodakov, “Characteristics of a solitary vapor bubble under subcooled water boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23598.

  19. S. P. Aktershev, A. A. Levin, I. V. Mezentsev, and N. N. Mezentseva, “Numerical simulation of self-oscillations during boiling up of underheated liquid in the annular channel,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 7–10.

  20. A. A. Levin and P. V. Khan, “Experimental study of the non-stationary heat flux effect on the onset of nucleate boiling and maximum bubble diameters in the subcooled boiling flow,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23898.

  21. K. Wu, P. Liu, W.-F. Du, J.-F. Zhao, H.-X., and K. Li, “Heat transfer and bubble dynamical behavior during single bubble pool boiling in microgravity,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22294.

  22. P. Pontes, E. Teodori, A. S. Moita, and A. L. N. Moreira, “On the process of bubble growing and departure on hydrophilic, superhydrophobic and biphilic surfaces,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22252.

  23. L. Lei, K. Ling, and W.-Q. Tao, “Numerical simulation of bubble growth in a rectangular microchannel,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22172.

  24. A. Stroh, B. Frohnapfel, and R. Dittmeyer, “Numerical investigation of vapor bubble growth in a rectangular microchannel,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id. IHTC16-22961.

  25. S. C. Wu, X. D. Liu, C. B. Zhang, and Y. P. Chen, “Investigation on bubble dynamic behaviors under pulse heating,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23676.

  26. T. Tanaka, Yabuki1 T., and K. Miyazaki, “Contribution of latent heat transfer in pool boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23962.

  27. D. A. Labuntsov, Physical Fundamentals of Power Engineering (Mosk. Energ. Inst., Moscow, 2000) [in Russian].

    Google Scholar 

  28. M. Zamoum, H. Combeau, and L. Tadrist, “Heat transfer investigation on a single artificial nucleate site: influence of the wall orientation on the bubble behavior,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24595.

  29. D. M. Iceri, G. Ribatski, G. Ruso, F. M. Forino, L. Saraceno, and G. Zummo, “Experimental investigation of flow boiling in a 4.0 mm tube at different gravity conditions: 0g, 1g, and 2g,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24247.

  30. V. V. Yagov, Heat Transfer in Single-Phase Media and During Phase Transformations (Mosk. Energ. Inst., Moscow, 2014) [in Russian].

    Google Scholar 

  31. V. I. Zhukov, D. A. Shvetsov, and A. N. Pavlenko, “Features of heat transfer in evaporation and boiling modes in thin horizontal layers of liquid at low pressures,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 498–501.

  32. A. N. Pavlenko, “Current trends in the study and development of methods for the intensification of heat and mass transfer during boiling, evaporation and distillation,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 36–39.

  33. T. P. Allred, J. A. Weibell, and S. V. Garimella, “Control of pool boiling hydrodynamics through surface wettability patterning,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22684.

  34. R. F. Gaertner, “Photographic study of nucleate pool boiling on a horizontal surface,” Trans. ASME J. Heat Transfer. 87, 17–29 (1965).

    Article  Google Scholar 

  35. T. G. Theofanous, T. N. Dinh, J. P. Tu, and A. T. Dinh, “The boiling crisis phenomenon. Part II: Dryout dynamics and burnout,” Exp. Therm. Fluid Sci. 26, 793–810 (2002).

    Article  Google Scholar 

  36. B. Shen, M. Yamada, T. Mine, S. Hidaka, J. Shiomi, G. Amberg, M. Kohno, K. Takahashi, and Y. Takata, “Enhanced boiling heat transfer on surfaces patterned with mixed wettability,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018, id IHTC16-23482.

  37. D. I. Shim, G. Choi, D. Lee, N. Lee, and H. H. Cho, “Bubble dynamics and pool boiling performance on biphilic patterned surfaces,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23399.

  38. A. S. Surtaev, V. S. Serdyukov, A. N. Pavlenko, M. Liu, V. V. Tumanov, D. S. Selishchev, and D. V. Kozlov, “Influence of wetting properties on microcharacteristics and heat transfer during boiling of a liquid,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 410 –413.

  39. R. Wen, S. Xu, Y.-C. Lee, and R. Yang, “Capillary evaporation and boiling heat transfer on hybrid wicking structures,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23634.

  40. Y.-Q. Wang, J.-L. Luo, Y. Heng, Y.-X. Fu, X.-Z. Huang, D.-C. Mo, and S.-S. Lyu, “The two-layers composite structure of biomimetic copper forest and honeycomb-like porous structure to enhance pool boiling performance,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23974.

  41. S. Mancin, L. Doretti, T. P. Allred, J. A. Weibel, G. Righetti, C. Zilio, and G. A. Longo, “Nanoparticle deposition on roughened copper surfaces via nanofluid pool boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22820.

  42. Z. Cao, Z. Wu, A. D. Pham, C. Preger, T. Ruzgas, C. Alber, S. Abbood, and B. Sunden, “Enhancement of HFE-7200 pool boiling heat transfer on copper surfaces with nanoparticle coatings,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23071.

  43. S. Fan, W. Tong, J. Luo, and F. Duan, “Nucleate pool boiling heat transfer on a titania nanotube-coated surface,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23586.

  44. Z. H. Zhang, S. Mou, Z. G. Xu, and C. Y. Zhao, “Experimental investigation on pool boiling mechanism of the gradient metal foam,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22409.

  45. T. Tran, D. Liu, and B.-T. Nguyen, “Critical heat flux enhancement on nanopillar array surfaces,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24033.

  46. W. Zhang, Y. Sun, Z. Wu, J. Yu, and J. Xu, “Characteristics of pool boiling heat transfer on a heterogeneous wetting microchannel surface,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-21910.

  47. A. N. Pavlenko, A. S. Surtaev, D. V. Kuznetsov, V. S. Serdyukov, V. I. Kalita, and D. I. Komlev, “Heat transfer enhancement and crisis phenomena at pool boiling on the surfaces with structured capillary-porous coatings,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22936.

  48. Y. Song, Y. Zhu, D. J. Preston, H. J. Cho, Z. Lu, and E. N. Wang, “Investigating the relationship between surface wickability and critical heat flux during pool boiling,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23315.

  49. H. Sakashita, “Estimation of local concentrations and visualization of boiling behaviors at high heat fluxes in saturated pool boiling of 2-propanol/water mixtures,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22954.

  50. Z. Huang, J. Ding, and J. Lu, “Periodical heat transfer performance of coiled tube type molten salt steam generator,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22170.

  51. X. Niu, H. Yuan, C. Quan, and L. Zhao, “Critical heat flux of R134a boiling flow in the circumferentially nonuniformly heated helically coiled tubes,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24352.

  52. A. V. Shishkin and S. E. Tarasevich, “Heat transfer, flow structure and critical heat fluxes at boiling of refrigerant R134a in channels with inserts in the form of finned twisted tapes,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 557–560.

  53. H. Asano and T. Nakamura, “Effect of surface structure on void fraction of subcooled forced boiling in rectangular narrow channel,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23156.

  54. G. Righetti, L. Doretti, S. Mancin, C. Zilio, and G. A. Longo, “R245fa flow boiling heat transfer on an electrically heated carbon/carbon surface,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22844.

  55. A. V. Belyaev and A. V. Dedov, “Features of the influence of changes in the properties of the coolant on the heat transfer during boiling of refrigerants in the channels,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 137 –140.

  56. J. Ma, W. Li, C. Ren, J. A. Khan, and C. Li, “Realize highly coordinated, rapid and sustainable nucleate boiling in microchannels on HFE7100,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22198.

  57. A. H. Al-Zaidi, M. M. Mahmoud, and T. G. Karayiannis, “Flow boiling in microchannels with HFE-7100: experimental results and comparison with correlations,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-20879.

  58. T. A. Moreira, F. D. Nascimento, and G. Ribatski, “Experimental evaluation of the flow boiling heat transfer coefficient of di-water inside minichannels under conditions close to the critical heat flux,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-21908.

  59. H. Wang and H. Qiu, “Bubble dynamics and heat transfer in a wettability patterned flow boiling microchannel,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16- 24287.

  60. V. V. Kuznetsov and A. S. Shamirzaev, “High heat flux flow boiling of water and dielectric coolant in parallel microchannels,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16- 22906.

  61. A. S. Shamirzaev, A. S. Mordovskoi, and V. V. Kuznetsov, “The mechanisms of the crisis of boiling and heat transfer during boiling of water in the slot microchannels,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 552–556.

  62. H. Nalbandian, C.-Y. Yang, and K.-T. Chen, “An experimental investigation on flow boiling heat transfer of refrigerants HFO-1234yf and HFC-134a in microchannels,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16- 22298.

  63. L. Kong, Z. Liu, M. Lv, C. Ji, L. Jia, and Y. Jiang, “Micro-PIV analysis of laminar flow and boiling heat transfer characteristics in micro pin-fin heat sinks,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23840.

  64. T. An, Y. Wang, and W.-Q. Liu, “Experimental investigation of heat transfer characteristics of liquid nitrogen flow boiling in a mini-channel,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23486.

  65. B. Zhang, Q. Li, Y. Wang, J. Zhang, P. Zhang, and H. Jia, “Experimental investigation of flow boiling heat transfer boundary of nitrogen in 1.2 mm vertical mini-channel,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24048.

  66. J. Y. Park, E. J. Choi, and M. S. Kim, “Two-phase pressure drop characteristics of HFE-7100 in mini-channels,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24123.

  67. B. M. Gasanov and N. V. Bulanov, “Heat transfer characteristics and flow regimes of a two-phase flow at boiling water and emulsion in a mini-channel,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 487–490.

  68. S. S. Mehendale, “A new correlation for predicting the heat transfer coefficients of R407C undergoing flow boiling within horizontal microfin tubes,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22945.

  69. M. M. Shah, “Evaluation of some correlations for heat transfer during saturated boiling in mini/micro and conventional channels,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22823.

  70. N. B. Chien, P. Q. Vu, C.-K. Il, J.-T. Oh, and H. Cho, “Saturated flow boiling of R410a in various multiport-tubes with rectangular microchannels,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23549.

  71. H. Ohtake, “Film boiling collapse temperature and boiling heat transfer correlations through two-dimensional temperature field measurement and observation of liquid-solid contact,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-23658.

  72. Yu. A. Zeigarnik, Yu. P. Ivochkin, K. G. Kubrikov, O. A. Sinkevich, and I. O. Teplyakov, “Experimental study of the contact of water with a hot metal surface,” in Proc. 7th Russ. National Conf. on Heat Transfer (R-NKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 510–513.

  73. Y. Haramura and Y. Isikawa, “Analysis of temperature uniformity and measurement of boiling curve in transition boiling on a large surface consists of five parts,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22705.

  74. V. V. Yagov, A. R. Zabirov, P. K. Kanin, and M. A. Lexin, “An approximate model of incipience of highly intensive film boiling regime in subcooled liquids,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22322.

  75. V. V. Yagov, A. R. Zabirov, P. K. Kanin, and M. A. Leksin, “Approximate model of the appearance of intensive heat transfer mode during film boiling of subcooled liquid,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 560–565.

  76. A. R. Zabirov, P. K. Kanin, and V. V. Yagov, “Nonsteady film boiling of subcooled water-ethanol mixtures,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-22327.

  77. A. R. Zabirov, P. K. Kanin, V. V. Yagov, M. M. Vinogradov, M. Yu. Gorin, and V. A. Ryazantsev, “Film boiling of subcooled water-ethanol solutions,” in Proc. 7th Russ. National Conf. on Heat Transfer (RNKT-7), Moscow, Oct. 22–26, 2018 (Mosk. Energ. Inst., Moscow, 2018), Vol. 1, pp. 502–505.

  78. S. B. Seo and I. C. Bang, “Acoustic analysis on the dynamic motion of vaporliquid interface in boiling crisis during the quenching process,” in Proc. 16th Int. Heat Transfer Conf. (IHTC-16), Beijing, China, Aug. 10–15, 2018 (Begell House, Danbury, CT, 2018), id IHTC16-24127.

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Funding

This work was partially supported by the Russian Scientific Foundation (grant no. 17-79-20402) and the Russian Foundation for Basic Research (grant no. 19-08-01044).

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  1. National Research University Moscow Power Engineering Institute, 111250, Moscow, Russia

    V. V. Yagov

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Yagov, V.V. Boiling of Liquids: Main Lines of Scientific Studies (Based of the Proceedings of the IHTC-16 and RNHTC-7). Therm. Eng. 66, 779–797 (2019). https://doi.org/10.1134/S0040601519110090

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