Development and investigation of existing opportunities of detander generator unit application for gas distribution station with thermal pump unit as gas heating system
DOI:
https://doi.org/10.14529/power170201Keywords:
expander-generator set, gas distribution station, heat pump installationAbstract
Development of resource saving technologies for existing energy sources is one of the priority tasks of
the Energy Strategy of Russia which envisages the reduction of losses and costs at all stages of the technological process in the extraction, preparation and transportation of natural gas. To date, it is very promising to utilize the excess pressure energy of natural gas at gas distribution stations (GDS) with the help of expander systems. The solution of the problem of gas heating absence in the DHA can be the installation layout with heating due to the use of the gas heating system of the heat pump station.
References
Kulakov A.S., Popovskiy S.N. [Industry Review “Heat and Power Engineering in Russia 2012–2016.
Years Since the Beginning of Energy Reform”], 2016, no. 1, pp. 11–15. (in Russ.)
Bulanova O.V., Igumenschev V.A., Malafeev A.V., Rotanova Yu.N. [Research of Convergence of Calculation Method for the Set Modes of Electrical Power Supply Systems at Separate Operation with Power Supply System]. Electrotechnical Systems and Complexes, 2005, no. 10, pp. 129–134. (in Russ.)
Malafeev A.V., Karandaeva O.I., Rotanova Yu.N., Bulanova O.V. [Influence of High-Voltage Engines of Own Needs on Reliability of Electrical Power Supply System of Own Needs at CHPP of MMK, JSC]. Electrotechnical Systems and Complexes, 2009, no. 17, pp. 96–104. (in Russ.)
Odintsov K., Rotanova Yu., Karandayeva O., Mostovoy S., Shilyaev P. [Technique to Predict Electrical Equipment Operation Remaining Life]. News of the Tula State University. Technical Science, 2010, no. 3-1,
pp. 192–198. (in Russ.)
Cinnella P., Hercus S.J. Efficient Implementation of Short Fundamentals. Equations of State for Numerical Simulation of Dense Gas Flows. Conference Paper of 42nd AIAA Thermophysics Conference, At Honolulu, Hawaii, vol. AIAA: 2011-3947, 2011. DOI 10.2514/6.2011-3947
Cinnella P., Congedo P., Parussini L., Pediroda L. Quantification of Thermodynamic Uncertainties in Real Gas Flows. Int J Eng Syst Modell Simul., 2010, pp. 12–24. DOI:10.1504/ijesms.2010.031867
Nannan N.R. Advancements in Non-Classical Gas Dynamics. Ph.D. thesis. Technische Universiteit Delft, 2009, 20 p.
Zamfirescu C., Dincer I. Performance Investigation of High-Temperature Heat Pumps with Various BZT Working Fluids. Thermochimica Acta, 2009, pp. 66–77. DOI: 10.1016/j.tca.2009.01.028
Cinnella P., Hercus S. Robust Optimization of Dense Gas Flows under Uncertain Operating Conditions. Computers & Fluids, 2010, pp. 1893–1908. DOI: 10.1016/j.compfluid.2010.06.020
Cinnella P., Congedo P. Computationally Efficient Models for Numerical Simulation of Thermodynamically Complex Flows. 5th European Congress on Computational Methods in Applied Sciences & Engineering, Venice, Italy, 2008, p. 145.
Congedo P., Cinnella P., Corre C. Shape Optimization for Dense Gas Flows in Turbine Cascades. Proceedings of ICCFD 4. Springer Berlin Heidelberg, Ghent, Belgium, 2006, pp. 555–560. DOI: 10.1007/978-3-540-92779-2_87
Span R., Eckermann T., Herrig S., Hielscher S., Thol, M. TREND. Thermodynamic Reference and Engineering Data 2.0., 2015, 125 p.
Venkatarathnam G., Oellrich L. Identification of Fluid Phase Using Partial Derivatives of Pressure, Vo¬lume, and Temperature without Reference to Saturation Properties: Applications in Phase Equilibria Calculations. Fluid Phase Equilibria, 2011, no. 301 (2), pp. 225–233. DOI: 10.1016/j.fluid.2010.12.001
Guevara-Carrion G., Nieto-Draghi C., Vrabec J., Hasse H. Prediction of Transport Properties by Molecular Simulation: Methanol and Ethanol and Their Mixture. J. Phys. Chem. B, 2008, vol. 112, рр. 16664–16674.
Arkharova A.Yu. Razrabotka i analiz sistem podogreva gaza v detander-generatornykh ustanovkakh: dis. … kand. tekhn. nauk [Development and Analysis of Gas Heating Systems in Expander-Generator Sets. Cand. sci. diss.]. Moscow, 2006. 187 p.
Baydakova Yu.O. Issledovanie effektivnosti skhem bestoplivnykh ustanovok generatsii elektroenergii na osnove detander-generatornykh agregatov i teplovykh nasosov: avtoref. dis. … kand. tekhn. nauk [Investigation of Efficiency of Fuel-Free Power Generation Facilities Schemes of Based on Expander-Generator Sets and Heat Pumps. Abstract of Cand. sci. diss.]. Moscow, 2013. 19 p.
Arkharov Yu.M., Arkharova A.Yu., Agababov V.S., Koryagin A.V. Expander-Generator Set. Patent RF, no. 39937, 2004.
Kozhichenkov V.S. Povyshenie nadezhnosti elektrosnabzheniya konechnykh potrebiteley za schet primeneniya detander – generatornykh ustanovok na stantsiyakh ponizheniya davleniya gaza v Moskve: avtoref. dis. … kand. tekhn. nauk [Improving the Reliability of Power Supply to End Consumers Through the Use of Expander-Generator Sets at Gas Pressure Reduction Stations in Moscow. Abstract of Cand. sci. diss.]. Moscow, 2012. 20 p.
Agababov V.S., Baidakova Yu.O., Zenkina UI. Expander-Generator. Patent RF, no. 88781, 2009.
Dzhuraeva E.V. Issledovanie skhem ispol'zovaniya detander-generatornykh agregatov v energetike i sistemakh gazosnabzheniya: dis. … kand. tekhn. nauk [Research of Schemes for Expander - Generator Aggregates Use in Power and Gas Supply Systems. Cand. sci. diss.]. Moscow, 2005. 155 p.