References
- Bataineh, K. M. 2016. “Multi-Effect desalination plant combined with thermal compressor driven by steam generated by solar energy.” Desalination 385. Elsevier: 39–52. 10.1016/j.desal.2016.02.011
- Beran, T., J. Hübel, R. Maertens, S. Reuter, J. Gärtner, J. Köhler, and T. Koch. 2021. Study of a polymer ejector design and manufacturing approach for a mobile air conditioning. International Journal of Refrigeration 126 (June):35–44. doi:10.1016/J.IJREFRIG.2021.01.023.
- Berni, F., and S. Fontanesi. 2020. “A 3D-CFD methodology to investigate boundary layers and assess the applicability of wall functions in actual industrial problems: a focus on in-cylinder simulations.” Applied Thermal Engineering 174. Elsevier: 115320. 10.1016/j.applthermaleng.2020.115320
- Besagni, G., N. Cristiani, L. Croci, G. Raymond Guédon, and F. Inzoli. 2021. “Computational fluid-dynamics modelling of supersonic ejectors: screening of modelling approaches, comprehensive validation and assessment of ejector component efficiencies.” Applied Thermal Engineering 186. Elsevier: 116431. 10.1016/j.applthermaleng.2020.116431
- Besagni, G., and F. Inzoli. 2017. “Computational fluid-dynamics modeling of supersonic ejectors: screening of turbulence modeling approaches.” Applied Thermal Engineering 117. Elsevier: 122–44. 10.1016/j.applthermaleng.2017.02.011
- Carrillo, J. A. E., F. J. S. de La Flor, and J. Manuel Salmerón Lissén. 2018. “Single-Phase ejector geometry optimisation by means of a multi-objective evolutionary algorithm and a surrogate CFD model.” Energy 164. Elsevier: 46–64. 10.1016/j.energy.2018.08.176
- Hai-Tao, X., Z.-F. Sang, B. Gu, N. Chai, and X. Wei-Dong. 2005. Numerical simulation of the performance of steam-jet vacuum pump. Journal of Chemical Engineering of Chinese Universities 1.
- Hibš, M. 1981. Proudové Přístroje. SNTL.
- Houghton, E. L., and P. William Carpenter. 2003. Aerodynamics for Engineering Students. Elsevier.
- Jiyuan, T., G. Heng Yeoh, and C. Liu. 2018. Computational Fluid Dynamics: A Practical Approach. Butterworth-Heinemann.
- Lamberts, O., P. Chatelain, and Y. Bartosiewicz. 2017. New methods for analyzing transport phenomena in supersonic ejectors. International Journal of Heat and Fluid Flow 64:23–40. doi:10.1016/j.ijheatfluidflow.2017.01.009.
- Lee, J. S., M. Se Kim, and M. Soo Kim. 2014. “Studies on the performance of a co2 air conditioning system using an ejector as an expansion device.” International Journal of Refrigeration 38. Elsevier: 140–52. 10.1016/j.ijrefrig.2013.08.019
- Ozen, M., and A.S.M.E. Fellow. 2014. “Meshing Workshop.” In MESHING WORKSHOP, 25.
- Pronobis, M. 2020. Environmentally oriented modernization of power boilers. Elsevier.
- Qiaorui, S., R. Lu, C. Shen, S. Xia, G. Sheng, and J. Yuan. 2020. “An intelligent cfd-based optimization system for fluid machinery: automotive electronic pump case application.” Applied Sciences Vol. 10. Multidisciplinary Digital Publishing Institute:
- Ramesh, A. S., and S. Joseph Sekhar. 2018. “Experimental and numerical investigations on the effect of suction chamber angle and nozzle exit position of a steam-jet ejector.” Energy 164. Elsevier: 1097–1113.
- Rapp, B. E. 2016. Microfluidics: Modeling, Mechanics and Mathematics. William Andrew.
- Refaey, H. A., M. A. Alharthi, M. R. Salem, A. A. Abdel-Aziz, H. E. Abdelrahman, and M. A. Karali. 2021. Numerical Investigations of Convective Heat Transfer for Lattice Settings in Brick Tunnel Kiln: CFD Simulation with Experimental Validation. Thermal Science and Engineering Progress 100934.
- Rogie, B., M. Ryhl Kaern, C. Wen, and E. Rothuizen. 2020. “Numerical Optimization of a Novel Gas-Gas Ejector for Fuelling of Hydrogen Vehicles.” International Journal of Hydrogen Energy 45 (41). Elsevier: 21905–19. 10.1016/j.ijhydene.2020.05.169
- Shaheed, R., A. Mohammadian, and H. Kheirkhah Gildeh. 2019. A Comparison of Standard k–ε and Realizable k–ε Turbulence Models in Curved and Confluent Channels. Environmental Fluid Mechanics 19 (2):543–68. doi:10.1007/s10652-018-9637-1.
- Škorpík, J. 2021. “Flow of Gases and Steam through Nozzles.” Accessed May 1. https://www.transformacni-technologie.cz/en_40.html.
- Sokolov. Inkjet Devices [Electronic Resource]/E.Ya. In Sok, <. I. I. A. I. M. S. <. 3rd Ed.; Rev. - Electron. Text Data. - M.: Energoatomizdat.
- Tashtoush, B., A. Alshare, and S. Al-Rifai. 2015. “Hourly Dynamic Simulation of Solar Ejector Cooling System Using TRNSYS for Jordanian Climate.” Energy Conversion and Management 100. Elsevier: 288–99. 10.1016/j.enconman.2015.05.010
- Varga, S., J. Soares, R. Lima, and A. C. Oliveira. 2017. “On the Selection of a Turbulence Model for the Simulation of Steam Ejectors Using CFD.” International Journal of Low-Carbon Technologies Vol. 12. Oxford University Press.
- Weina, F., Z. Liu, Y. Li, H. Wu, and Y. Tang. 2018. “Numerical study for the influences of primary steam nozzle distance and mixing chamber throat diameter on steam ejector performance.” International Journal of Thermal Sciences 132. Elsevier: 509–16. 10.1016/j.ijthermalsci.2018.06.033
- White, F. M., and I. Corfield. 2006. Viscous Fluid Flow, Vol. 3. McGraw-Hill New York.
- Yang, Y. Q., Z. Q. An, and S. D. Jing. 2006. Study on numerical simulation of ejector flow field. Journal of Southwest University for Nationalities (Natural Science Edition) 32 (2):316–23.
- Zhang, X., S. Jin, S. Huang, and G. Tian. 2009. Experimental and CFD analysis of nozzle position of subsonic ejector. Frontiers of Energy and Power Engineering in China 3 (2):167–74. doi:10.1007/s11708-009-0001-5.
- Zhang, S., J. Luo, Q. Wang, and G. Chen. 2018. “Step utilization of energy with ejector in a heat driven freeze drying system.” Energy 164 (December). Elsevier Ltd: 734–44. doi:10.1016/j.energy.2018.08.195.
- Zhang, J., X. Zhai, and S. Li. 2020. “Numerical studies on the performance of ammonia ejectors used in ocean thermal energy conversion system.” Renewable Energy 161. Elsevier: 766–76. 10.1016/j.renene.2020.07.025