Evolution of centrifugal distillation system with a thermoelectric heat pump for space missions
Part 3. Analysis of local and integral characteristics of centrifugal distillation system with a thermoelectric heat pump
Keywords:
thermoelectricity, heat pump, distillerAbstract
The paper describes a method for calculating the heat transfer coefficient and the efficiency of a centrifugal distiller, as well as determining the efficiency of a thermoelectric heat pump. For this, the results of theoretical and experimental studies of condensation and evaporation processes on a rotating surface and the study of processes in a liquid-liquid thermoelectric heat pump (THP) were used. A comparison was made of the calculated values of the average temperature difference ΔТav in ТНР and the temperature difference at the inlet to ТНР ΔТin with the experimental data obtained when testing the centrifugal distiller on water and urine. Bibl. 33, Fig. 3, Tabl. 2.
References
Rifert V., Barabash P., Goliad N. (1990). Methods and processes of thermal distillation of water solutions for closed water supply systems. SAE Paper 901249, 20th Intersociety Conference on Environmental Systems (Williamsburg, July 1990).
Samsonov N, Bobe L., Novikov V., Rifert V., et al. (1994). Systems for water reclamation from humidity condensate and urine for space station. SAE Paper 941536, 24th International society Conference on Environmental Systems (June, 1994).
Samsonov N.M., Bobe L.S., Novikov V., Rifert V.G., Barabash P.A, et al.. (1995). Development of urine processor distillation hardware for space stations. (1995). SAE Paper 951605, 25th International Conference on Environmental Systems (San Diego, July 1995).
Samsonov N.M., Bobe L.S, Novikov V., Rifert V.G., et al.(1997). Updated systems for water recovery from humidity condensate and urine for the International space station. SAE Paper 972559, 27th International Conference on Environmental Systems (Nevada, July 1997).
Samsonov N.M., Bobe L.S, Novikov V., Rifert V.G., et al. (1999). Development and testing of a vacuum distillation subsystem for water reclamation from urine. SAE Paper 1999-01-1993, 29th International Conference on Environmental Systems, 1999.
Rifert V., Usenko V., Zolotukhin I., MacKnight A., Lubman A. (1999). Comparison of secondary water processors using distillation for space applications. SAE Paper 99-70466, 29th International Conference on Environmental Systems (Denver, July 1999).
Rifert V., Strikun A., Usenko V. (2000). Study of dynamic and extreme performances of multistage centrifugal distiller with the thermoelectric heat pump. SAE Technical Papers 2000. 30th International Conference on Environmental Systems (Toulouse; France; 10-13 July 2000).
Rifert V., Usenko V., Zolotukhin I., MacKnight A. and Lubman A. (2001). Design optimisation of cascade rotary distiller with the heat pump for water reclamation from urine. SAE Paper 2001-01-2248, 31st International Conference on Environmental Systems (Orlando, July 2001).
Rifert V. G., Usenko V.I., Zolotukhin I.V., MacKnight A.and Lubman A. (2003).Cascaded distillation technology for water processing in space. SAE Paper 2003-01-2625. 34st International Conference on Environmental Systems (Orlando, July 2003).
Lubman A., MacKnight A., Rifert V., Zolotukhin I. and Pickering K. (2006). Wastewater processing cascade distillation subsystem. design and evaluation. SAE International, 2006-01-2273. July 2006.
Lubman A., MacKnight A., Rifert V., and Barabash P. (2007). Cascade distillation subsystem hardware development for verification testing. SAE International, 2007-01-3177, July 2007.
Rifert V.G., Anatychuk L.I., Barabash P.A., Usenko V.I., Strikun A.P., Prybyla A.V. (2017). Improvement of the distillation methods by using centrifugal forces for water recovery in space flight applications. J. Thermoelectricity, 1, 71-83.
Rifert Vladimir G., Barabash Petr A., Usenko Vladimir, Solomakha Andrii S., Anatychuk Lukyan I., Prybyla.A.V. (2017). Improvement the cascade distillation system for long-term space flights. 68th International Astronautical Congress (IAC) (Adelaide, Australia, 25-29 September 2017). IAC-17-A1.IP.25.
Rifert V.G., Anatychuk L.I., Barabash P.O., Usenko V.I., Strikun A.P, Solomakha A.S., Petrenko V.G., Prybyla A.V. (2019). Evolution of centrifugal distillation system with a thermoelectric heat pump for space missions. Part 1. Review of publications on centrifugal distillation in the period of 1990 – 2017. J.Thermoelectricity, 1.
Rifert V.G., Anatychuk L.I., Barabash P.O., Usenko V.I., Strikun A.P, Solomakha A.S., Petrenko V.G., Prybyla A.V. (2019). Evolution of centrifugal distillation system with a thermoelectric heat pump for space missions. Part 2. . Study of the variable characteristics of a multi-stage distillation system with a thermoelectric heat pump. J.Thermoelectricity, 2.
Muzhilko A.A., Rifert V.G., Barabash P.A. (1985) Flow of liquid film over the surface of a rotating disk. Heat transfer. Soviet research.
Butuzov A.I., Rifert V.G. (1972). An experimental study of heat transfer during condensation of steam at a rotating disk. Heat Transfer-Soviet Research, 4(6).
Butuzov A.I. and Rifert V.G. (1973). Heat transfer in evaporation of liquid from a film on a rotating disk. Heat Transfer-Soviet Research, 5(1).
Rifert V.G., Barabash P.A., Solomakha A.S., Usenko V., Sereda V.V., Petrenko V.G.(2018). Hydrodynamics and heat transfer in centrifugal film evaporator. Bulgarian Chemical Communications, 50, Special Issue K, 49-57.
Rifert V.G., Barabash P.A., Goliyad N.N. Condensation of steam on a water film falling down a rotating surface. Heat transfer. Soviet research, 16 (3), 132-137.
Gimbutis G. (1988). Heat exchange with gravitational flow of liquid film. Monograph. Vilnus.
Bae S., Maulbetsch J.S., Rohsenow W.M. (1969). Refrigerant forced-convection condensation inside horizontal tubes. Report No. DSR-79760-64. Massachusetts Institute of Technology (Cambridge, MA).
Traviss D.P., Baron A.N., Rohsenow W.M..(1971). Forced-convection condensation inside tubes. Report No. DSR-72591-74. Massachusetts Institute of Technology.(Cambridge, MA)
Rifert V.G., Sereda V.V., Gorin V.V., Barabash P.A., Solomakha A.S. (2018). Restoration of correctness and improvement of a model for film condensation inside tubes. Bulgarian Chemical Communications, 50, Special Issue K, 58-69.
Rifert V., Sereda V., Solomakha A. (2019). Heat transfer during film condensation inside plain tubes. Review of theoretical research. Heat and Mass Transfer/Waerme- und Stoffuebertragung, 2019.
Usenko V.I., Fainzilberg S.N. (1974). Effect of acceleration on the critical heat load with the boiling of freons on elements having small transverse dimensions. High Temperature.
Usenko V.I., Podgoretskiy V.M., Kudelya P.P. (1985). Nucleate boiling heat transfer from freon-11 and 12 at very high «g». Heat transfer. Soviet research.
Anatychuk L.I.., Prybyla A.V. (2015). Optimization of thermal connections in thermoelectric liquid-liquid heat pumps for water purification systems of space application. J.Thermoelectricity, 4, 45 – 51.
Anatychuk L.I., Prybyla A.V. (2015). Optimization of power supply system of thermoelectric liquid-liquid heat pump. J.Thermoelectricity, 6, 53 – 58.
Anatychuk L.I., Rozver Yu.Yu., Prybyla A.V. (2017). Experimental study of thermoelectric liquid-liquid heat pump. J.Thermoelectricity, 3, C. 33 – 39.
Anatychuk L.I., Prybyla A.V. (2017). Limiting possibilities of thermoelectric liquid-liquid heat pump. J.Thermoelectricity, 4, 33 – 39.
Anatychuk L.I., Prybyla A.V. (2017). The influence of quality of heat exchangers on the properties of thermoelectric liquid-liquid heat pumps. J.Thermoelectricity, 5, 33 – 39.
Anatychuk L.I., Prybyla A.V. (2017). On the coefficient of performance of thermoelectric liquid-liquid heat pumps with regard to energy loss for heat carrier transfer. J.Thermoelectricity, 6, 33 – 39.
