Comparison of the Brayton-Brayton cycle with the Brayton-Diesel cycle

• Autorzy: Mostowy M. , Szabłowski Ł.
• Języki publikacji: EN

Abstrakty

EN

This article is a comparative analysis of two systems: Brayton-Brayton and Brayton-Diesel. These two systems were both compared with a simple cycle of a gas turbine as a benchmark. The paper compares and contrasts the various advantages and disadvantages of the systems. The comparison with the simple cycle was made possible by having the same mass flow of air at the inlet of the gas turbine compressor for all analyzed cases (in the case of the Brayton-Brayton system - at the inlet of the compressor of the first gas turbine). Compared to the simple cycle, the Brayton-Brayton cycle has greater power and the Brayton-Diesel less. In terms of efficiency both systems outperformed the simple cycle, with the Brayton-Diesel system achieving slightly better results than the Brayton-Brayton.

Słowa kluczowe

EN

gas turbine; Brayton-Brayton; Brayton-Diesel

PL

turbina gazowa; Brayton-Brayton; Brayton-Diesel

• Wydawca: Institute of Heat Engineering, Warsaw University of Technology
• Czasopismo: Journal of Power Technologies
• Rocznik: 2018
• Tom: Vol. 98, nr 1
• Strony: 97--105
• Opis fizyczny: Bibliogr. 23 poz., rys., tab., wykr.

Twórcy

autor

Mostowy M.

• Institute of Heat Engineering, Warsaw University of Technology, 21/25 Nowowiejska Street, 00-665 Warsaw, Poland

autor

Szabłowski Ł.

• Institute of Heat Engineering, Warsaw University of Technology, 21/25 Nowowiejska Street, 00-665 Warsaw, Poland

Bibliografia

• [1] K. Badyda, Perspektywy rozwoju technologii turbin gazowych oraz bloków gazowo-parowych, Rynek Energii 4 (113) (2014) 74–82.
• [2] J. Milewski, A. Miller, Off-design analysis of MCFC hybrid system, Rynek Energii 1.
• [3] J. Milewski, A. Miller, J. Sałaciński, Off-design analysis of sofc hybrid system, International Journal of Hydrogen Energy 32 (6) (2007) 687–698.
• [4] J. Milewski, T. Świercz, K. Badyda, A. Miller, A. Dmowski, P. Biczel, The control strategy for a molten carbonate fuel cell hybrid system, international journal of hydrogen energy 35 (7) (2010) 2997–3000.
• [5] J. Milewski, M. Wołowicz, R. Bernat, L. Szablowski, J. Lewandowski, Variant analysis of the structure and parameters of sofc hybrid systems, in: Applied Mechanics and Materials, Vol. 437, Trans Tech Publ, 2013, pp. 306–312.
• [6] J. Kupecki, J. Milewski, A. Szczesniak, R. Bernat, K. Motylinski, Dynamic numerical analysis of cross-, co-, and counter-current flow configuration of a 1 kw-class solid oxide fuel cell stack, International Journal of Hydrogen Energy 40 (45) (2015) 15834–15844.
• [7] J. Milewski, M. Wołowicz, A. Miller, R. Bernat, A reduced order model of molten carbonate fuel cell: A proposal, International Journal of Hydrogen Energy 38 (26) (2013) 11565–11575.
• [8] J. Milewski, K. Futyma, A. Szczesniak, Molten carbonate fuel cell operation under high concentrations of SO2 on the cathode side, INTERNATIONAL JOURNAL OF HYDROGEN ENERGY 41 (41) (2016) 18769–18777, 3rd International Workshop on Molten Carbonates and Related Topics (IWMC), NE Univ, Shenyang, PEOPLES R CHINA, JUN 11-13, 2015. doi:10.1016/j.ijhydene.2016.03.121.
• [9] G. Cinti, U. Desideri, D. Penchini, G. Discepoli, Experimental analysis of sofc fuelled by ammonia, FUEL CELLS 14 (2) (2014) 221-230.doi:10.1002/fuce.201300276.
• [10] D. Thombare, S. Verma, Technological development in the stirling cycle engines, Renewable and Sustainable Energy Reviews 12 (1) (2008) 1–38.
• [11] A. Chmielewski, R. Gumiński, S. Radkowski, Chosen properties of a dynamic model of crankshaft assembly with three degrees of freedom, in: Methods and Models in Automation and Robotics (MMAR), 2015 20th International Conference on, IEEE, 2015, pp. 1038–1043.
• [12] A. Chmielewski, R. Gumiński, J. Mączak, S. Radkowski, P. Szulim, Aspects of balanced development of res and distributed microcogeneration use in poland: Case study of a _chp with stirling engine, Renewable and Sustainable Energy Reviews 60 (2016) 930–952.
• [13] A. Chmielewski, S. Gontarz, R. Gumiński, J. Mączak, P. Szulim, Research study of the micro cogeneration system with automatic loading unit, in: Challenges in Automation, Robotics and Measurement Techniques, Springer, 2016, pp. 375–386.
• [14] K. Wang, S. R. Sanders, S. Dubey, F. H. Choo, F. Duan, Stirling cycle engines for recovering low and moderate temperature heat: A review, Renewable and Sustainable Energy Reviews 62 (2016) 89–108.
• [15] A. Chmielewski, S. Gontarz, R. Gumiński, J. Mączak, P. Szulim, Research on a micro cogeneration system with an automatic loadapplying entity, in: Challenges in Automation, Robotics and Measurement Techniques, Springer, 2016, pp. 387–395.
• [16] K. Badyda, A. Miller, Energetyczne turbiny gazowe oraz układy z ich wykorzystaniem, Wydawnictwo Kaprint, 2014.
• [17] M. Korobitsyn, Industrial applications of the air bottoming cycle, Energy Conversion and Management 43 (9) (2002) 1311–1322. doi:10.1016/S0196-8904(02)00017-1.
• [18] Spilling Energie Systeme, Gas expansion. URL http://www.enesko.pl/images/ Spilling-expander_prospekt.pdf
• [19] Y. Cengel, M. Boles, Thermodynamics: An Engineering Approach with Student Resources DVD, McGraw-Hill Education, 2010.
• [20] R. Kiš, M. Malcho, M. Janovcová, A CFD Analysis of Flow through a High-Pressure Natural Gas Pipeline with an Undeformed and Deformed Orifice Plate, International Journal of Mechanical, Aerospace, Industrial, Mechatronic and Manufacturing Engineering (2014) 606–609.
• [21] F. Brooks, GE Gas Turbine Performance Characteristics. URL http://www.up.farsscript.ir/uploads/13316846411.pdf
• [22] R. Szewalski, Sposób podwyższania sprawności obiegu energetycznego turbiny gazowej [a method of increasing the efficiency of the gas turbine’s energy cycle] (1973).
• [23] P. Ziółkowski, M. Lemański, J. Badur, W. Zakrzewski, Wzrost sprawności turbiny gazowej przez zastosowanie idei Szewalskiego, Rynek Energii (3) (2012) 63–70.

Uwagi

PL

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).