Determination of hydraulic resistance of the aerothermopressor for gas turbine cyclic air cooling

Dmytro Konovalov; Halina Kobalava; Mykola Radchenko; Ionut-Cristian Scurtu; Roman Radchenko

doi:10.1051/e3sconf/202018001012

All issues

Volume 180 (2020)

E3S Web Conf., 180 (2020) 01012

References

Open Access

Issue		E3S Web Conf. Volume 180, 2020 9^th International Conference on Thermal Equipments, Renewable Energy and Rural Development (TE-RE-RD 2020)


Article Number		01012
Number of page(s)		14
Section		Thermal Equipments and Processes
DOI		https://doi.org/10.1051/e3sconf/202018001012
Published online		24 July 2020

Radchenko, A., Radchenko, M., Konovalov, A., Zubarev, A.: Increasing electrical power out-put and fuel efficiency of gas engines in integrated energy system by absorption chiller scavenge air cooling on the base of monitoring data treatment. In: Proceedings of E3S Web of Conferences 70, 03011, p. 6. HTRSE-2018 (2018). [Google Scholar]
Kumar, T. A., Muzaffarul, H. M., Islam, M.: Effect of ambient temperature on the performance of a combined cycle power plant. Transactions of the Canadian Society for Mechanical Engineering 37(4), 1177–1188 (2013). [CrossRef] [Google Scholar]
Eidan, A. A., Alwan, K. J.: Enhancement of the Performance Characteristics for AirConditioning System by Using Direct Evaporative Cooling in Hot Climates. Energy Procedia 142, 3998–4003 (2017). [Google Scholar]
Günnur, S. G. et al.: The effect of ambient temperature on electric power generation in natural gas combined cycle power plant-A case study. Energy Reports 4, 682–690 (2018). [CrossRef] [Google Scholar]
Jonsson, M., Yan, J.: Humidified gas turbines – a review of proposed and implemented cycles. Energy 30, 1013–1078 (2005). [CrossRef] [Google Scholar]
Boyce, M. P.: Gas Turbine Engineering Hand-book. Gulf Publishing Company, Houston, Texas (2002). [Google Scholar]
Elbel, S., Lawrence, N.: Review of recent developments in advanced ejector technology. International Journal of Refrigeration 62, 1-18 (2016). [CrossRef] [Google Scholar]
Elbel, S.: Historical and present developments of ejector refrigeration systems with emphasis on transcritical carbon dioxide air-conditioning applications. International Journal of Refrigeration 34(7), 1545-1561 (2011). [CrossRef] [Google Scholar]
Elbel, S., Hrnjak, P.: Ejector refrigeration: an overview of historical and present developments with an emphasis on air-conditioning applications (2008). [Google Scholar]
Lawrence, N., Elbel, S.: Theoretical and practical comparison of two-phase ejector refrigeration cycles including First and Second Law analysis. International Journal of Refrigeration 36(4), 1220-1232 (2013). [CrossRef] [Google Scholar]
Konovalov, D., Kobalava, H.: Efficiency Analysis of Gas Turbine Plant Cycles with Water Injection by the Aerothermopressor. In: Ivanov V. et al. (eds.) Advances in Design, Simulation and Manufacturing II. DSMIE 2019. Lecture Notes in Mechanical Engineering, pp. 581-591. Springer, Cham (2020). [Google Scholar]
Fowle, A.: An experimental investigation of an aerothermopressor having a gas flow capacity of 25 pounds per second. Massachusetts Institute of Technology, USA (1972). [Google Scholar]
Stepanov, I. R., Chudinov, V. I.: Some Problems of Gas and Liquid Motion in the Channels and Pipelines of Power Plants. The Science Publ., Leningrad (1977). [Google Scholar]
Zhivitsa, V. I.: Intercoolers with thermopressor for two-stage ammonia refrigeration machines. Refrigeration Engineering 5, pp. 18-20 (2002). [Google Scholar]
Radchenko, М., Radchenko, R., Ostapenko, О., Zubarev, А., Hrych, А.: Enhancing the utilization of gas engine module exhaust heat by two-stage chillers for combined electricity, heat and refrigeration. In: Proceedings of 5th International Conference on Systems and Informatics, ICSAI 2018, pp. 240-244. Jiangsu, Nanjing, China (2019). [Google Scholar]
Shapiro, A. H., et al.: The Aerothermopressor – a Device for Improving the Performance of a Gas-Turbine Power Plant. In: Proceedings of the Trans. ASME, pp. 617-653. Cambridge, USA (1956). [Google Scholar]
Erickson, J.: A theoretical and experimental investigation of the aerothermopressor process. Massachusetts Institute of Technology, USA (1958). [Google Scholar]
Radchenko R., Radchenko A., Serbin S., Kantor S., Portnoi B. Gas turbine unite inlet air cooling by using an excessive refrigeration capacity of absorption-ejector chiller in booster air cooler. In: Proceedings of E3S Web of Conferences 70, 03012, 6 p. HTRSE2018 (2018). [Google Scholar]
Lockhart, R. W., Martinelli, R. C.: Proposed correlation of data for isothermal twophase, two-component flow in pipes. Chem. Eng. Progr. 45(1), 39–48 (1949). [Google Scholar]
Martinelli, R. C., Nelson, D. B.: Prediction of pressure drop during forced – circulation boiling of water. Trans. ASME 70, 695–702 (1948). [Google Scholar]
Dolinsky, A. A., Ivanitsky, G. K.: Heat and mass transfer and hydrodynamics in vaporliquid dispersed flow. Naukova Dumka, Kyiv (2008). [Google Scholar]
Kulinchenko, V. R.: Hydraulics, hydraulic machines and hydraulic drive. Tsentr navchalnoi literatury Publ., Kyiv (2006). [Google Scholar]
Konovalov D., Trushliakov, E., Radchenko, M., Kobalava, H., Maksymov, V.: Research of the Aerothermopressor Cooling System of Charge Air of a Marine Internal Combustion Engine Under Variable Climatic Conditions of Operation. In: Tonkonogyi V. et al. (eds.) Advanced Manufacturing Processes. InterPartner 2019. Lecture Notes in Mechanical Engineering, pp. 520-529. Springer, Cham (2020). [Google Scholar]
Lin, A., et al.: Evaluation of Mass Injection Cooling on Flow and Heat Transfer Characteristics for High-Temperature Inlet Air in a MIPCC Engine. International Journal of Heat and Mass Transfer 135, 620–630 (2019). [Google Scholar]
Radchenko, A., Bohdal, L., Zongming, Y., Portnoi, B., Tkachenko, V.: Rational designing of gas turbine inlet air cooling system. In: Tonkonogyi V. et al. (eds.) Advanced Manufacturing Processes. InterPartner 2019. Lecture Notes in Mechanical Engineering, pp. 591-599. Springer, Cham (2020). [Google Scholar]

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[1] Radchenko, A., Radchenko, M., Konovalov, A., Zubarev, A.: Increasing electrical power out-put and fuel efficiency of gas engines in integrated energy system by absorption chiller scavenge air cooling on the base of monitoring data treatment. In: Proceedings of E3S Web of Conferences 70, 03011, p. 6. HTRSE-2018 (2018). [Google Scholar]

[2] Kumar, T. A., Muzaffarul, H. M., Islam, M.: Effect of ambient temperature on the performance of a combined cycle power plant. Transactions of the Canadian Society for Mechanical Engineering 37(4), 1177–1188 (2013). [CrossRef] [Google Scholar]

[3] Eidan, A. A., Alwan, K. J.: Enhancement of the Performance Characteristics for AirConditioning System by Using Direct Evaporative Cooling in Hot Climates. Energy Procedia 142, 3998–4003 (2017). [Google Scholar]

[4] Günnur, S. G. et al.: The effect of ambient temperature on electric power generation in natural gas combined cycle power plant-A case study. Energy Reports 4, 682–690 (2018). [CrossRef] [Google Scholar]

[5] Jonsson, M., Yan, J.: Humidified gas turbines – a review of proposed and implemented cycles. Energy 30, 1013–1078 (2005). [CrossRef] [Google Scholar]

[6] Boyce, M. P.: Gas Turbine Engineering Hand-book. Gulf Publishing Company, Houston, Texas (2002). [Google Scholar]

[7] Elbel, S., Lawrence, N.: Review of recent developments in advanced ejector technology. International Journal of Refrigeration 62, 1-18 (2016). [CrossRef] [Google Scholar]

[8] Elbel, S.: Historical and present developments of ejector refrigeration systems with emphasis on transcritical carbon dioxide air-conditioning applications. International Journal of Refrigeration 34(7), 1545-1561 (2011). [CrossRef] [Google Scholar]

[9] Elbel, S., Hrnjak, P.: Ejector refrigeration: an overview of historical and present developments with an emphasis on air-conditioning applications (2008). [Google Scholar]

[10] Lawrence, N., Elbel, S.: Theoretical and practical comparison of two-phase ejector refrigeration cycles including First and Second Law analysis. International Journal of Refrigeration 36(4), 1220-1232 (2013). [CrossRef] [Google Scholar]

[11] Konovalov, D., Kobalava, H.: Efficiency Analysis of Gas Turbine Plant Cycles with Water Injection by the Aerothermopressor. In: Ivanov V. et al. (eds.) Advances in Design, Simulation and Manufacturing II. DSMIE 2019. Lecture Notes in Mechanical Engineering, pp. 581-591. Springer, Cham (2020). [Google Scholar]

[12] Fowle, A.: An experimental investigation of an aerothermopressor having a gas flow capacity of 25 pounds per second. Massachusetts Institute of Technology, USA (1972). [Google Scholar]

[13] Stepanov, I. R., Chudinov, V. I.: Some Problems of Gas and Liquid Motion in the Channels and Pipelines of Power Plants. The Science Publ., Leningrad (1977). [Google Scholar]

[14] Zhivitsa, V. I.: Intercoolers with thermopressor for two-stage ammonia refrigeration machines. Refrigeration Engineering 5, pp. 18-20 (2002). [Google Scholar]

[15] Radchenko, М., Radchenko, R., Ostapenko, О., Zubarev, А., Hrych, А.: Enhancing the utilization of gas engine module exhaust heat by two-stage chillers for combined electricity, heat and refrigeration. In: Proceedings of 5th International Conference on Systems and Informatics, ICSAI 2018, pp. 240-244. Jiangsu, Nanjing, China (2019). [Google Scholar]

[16] Shapiro, A. H., et al.: The Aerothermopressor – a Device for Improving the Performance of a Gas-Turbine Power Plant. In: Proceedings of the Trans. ASME, pp. 617-653. Cambridge, USA (1956). [Google Scholar]

[17] Erickson, J.: A theoretical and experimental investigation of the aerothermopressor process. Massachusetts Institute of Technology, USA (1958). [Google Scholar]

[18] Radchenko R., Radchenko A., Serbin S., Kantor S., Portnoi B. Gas turbine unite inlet air cooling by using an excessive refrigeration capacity of absorption-ejector chiller in booster air cooler. In: Proceedings of E3S Web of Conferences 70, 03012, 6 p. HTRSE2018 (2018). [Google Scholar]

[19] Lockhart, R. W., Martinelli, R. C.: Proposed correlation of data for isothermal twophase, two-component flow in pipes. Chem. Eng. Progr. 45(1), 39–48 (1949). [Google Scholar]

[20] Martinelli, R. C., Nelson, D. B.: Prediction of pressure drop during forced – circulation boiling of water. Trans. ASME 70, 695–702 (1948). [Google Scholar]

[21] Dolinsky, A. A., Ivanitsky, G. K.: Heat and mass transfer and hydrodynamics in vaporliquid dispersed flow. Naukova Dumka, Kyiv (2008). [Google Scholar]

[22] Kulinchenko, V. R.: Hydraulics, hydraulic machines and hydraulic drive. Tsentr navchalnoi literatury Publ., Kyiv (2006). [Google Scholar]

[23] Konovalov D., Trushliakov, E., Radchenko, M., Kobalava, H., Maksymov, V.: Research of the Aerothermopressor Cooling System of Charge Air of a Marine Internal Combustion Engine Under Variable Climatic Conditions of Operation. In: Tonkonogyi V. et al. (eds.) Advanced Manufacturing Processes. InterPartner 2019. Lecture Notes in Mechanical Engineering, pp. 520-529. Springer, Cham (2020). [Google Scholar]

[24] Lin, A., et al.: Evaluation of Mass Injection Cooling on Flow and Heat Transfer Characteristics for High-Temperature Inlet Air in a MIPCC Engine. International Journal of Heat and Mass Transfer 135, 620–630 (2019). [Google Scholar]

[25] Radchenko, A., Bohdal, L., Zongming, Y., Portnoi, B., Tkachenko, V.: Rational designing of gas turbine inlet air cooling system. In: Tonkonogyi V. et al. (eds.) Advanced Manufacturing Processes. InterPartner 2019. Lecture Notes in Mechanical Engineering, pp. 591-599. Springer, Cham (2020). [Google Scholar]