Geodesic
Mathematical model development of automated pumping station electromechanical complex
Matematičeskoe modelirovanie, Tome 27 (2015) no. 4, pp. 3-15

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The aim of this work is to develop a mathematical model of a electro-mechanical pumping station complex, including low-voltage frequency converter, step-up and step-down transformers, sine-wave filter and choke at the frequency converter (FC) output to control a high-voltage induction motor (IM), and the hydraulic system including electric centrifugal pump and pipe fittings. The simulation was performed in the programmable software based on electro-hydraulics analogy, which adequacy is confirmed by the transient processes graphs, as well as characteristics of the pump and pipe-hydraulic resistance.
Keywords: mathematical model, automation system, pumping station, electric drive, frequency converter, AC motor. 
A. M. Sagdatullin. Mathematical model development of automated pumping station electromechanical complex. Matematičeskoe modelirovanie, Tome 27 (2015) no. 4, pp. 3-15. http://geodesic.mathdoc.fr/item/MM_2015_27_4_a0/
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[1] D. A. Zavarihin, Razrabotka chastotnogo metoda obespecheniya bezopasnoy ekspluatatsii elektroprivodov mashinnyih agregatov neftegazovyih proizvodstv, avtoref. dis. ... kand. tehn. nauk, Ufa, 2009

[2] A. I. Kayashev, A. A. Emekeev, A. M. Sagdatullin, “Analiz energoeffektivnosti sistem avtomatizatsii vyisokovoltnogo elektroprivoda nasosnoy stantsii”, Gazovaya promyishlennost, 699 (2013), 47–50 | MR

[3] G. Lazarev, “Vyisokovoltnyie preobrazovateli dlya chastotno-reguliruemogo elektroprivoda. Postroenie razlichnyih sistem”, Novosti elektrotehniki, 2005, no. 2(32)

[4] B. S. Leznov, Energosberezhenie i reguliruemyiy privod v nasosnyih ustanovkah, Energoatomizdat, M., 2006, 360 pp.

[5] A. E. Kozyaruk, V. V. Rudakov, “Matematicheskaya model sistemyi pryamogo upravleniya momentom asinhronnogo elektroprivoda”, Elektrotehnika, 2005, no. 9, 8–14

[6] I. Ya. Braslavskiy, Yu. V. Plotnikov, “Matematicheskie modeli dlya opredeleniya energopotrebleniya razlichnyimi tipami asinhronnyih elektroprivodov i primeryi ih ispolzovaniya”, Elektrotehnika, 2005, no. 9, 14–18

[7] R. T. Shreyner, Matematicheskoe modelirovanie elektroprivodov peremennogo toka s poluprovodnikovyimi preobrazovatelyami chastotyi, URO RAN, Ekaterinburg, 2000, 654 pp.

[8] M. P. Kostenko, L. M. Piotrovskiy, Elektricheskie mashinyi, v. 2, Mashinyi peremennogo toka, ed. M. P. Kostenko, Energiya, L., 1973, 648 pp.

[9] V. M. Terehov, O. I. Osipov, Sistemy upravleniya elektroprivodov, Izdatelskiy tsentr «Akademiya», M., 2006, 304 pp.

[10] A. M. Sagdatullin, A. I. Kayashev, A. A. Emekeev, Ustroystvo plavnogo puska i regulirovaniya rezhimov rabotyi gruppyi vyisokovoltnyih asinhronnyih elektrodvigateley, Patent RF No 140350, zayavka No 2013151910/07(080943); opublikovano: 10.05.2014, byul. No 13

[11] A. M. Sagdatullin, A. A. Emekeev, Shema kompleksnoy avtomatizatsii elektroprivoda nasosnoy stantsii, Patent Rossii No 136504, zayavka No 2013131974/07 (047770); data prioriteta: 09.07.2013

[12] R. I. Borisov, V. S. Kostyishin, “Moschnost i moment tsentrobezhnyih nasosov magistralnyih nefteprovodov v razlichnyih rezhimah nagruzki”, Izv. vuzov SSSR. Energetika, 1986, no. 4, 106–109

[13] A. M. Sagdatullin, “Analiticheskoe issledovanie sistem avtomatizirovannogo elektroprivoda nasosnoy stantsii”, Izvestiya vyisshih uchebnyih zavedeniy. Povolzhskiy region. Tehnicheskie nauki, 2014, no. 2(30), 89–99

[14] A. M. Sagdatullin, A. I. Kayashev, A. A. Emekeev, Sistema upravleniya nizkovoltnyim asinhronnyim elektrodvigatelem, Svidetelstvo No 2014617590 ot 28.07.2014, Rospatent, M., 2014

[15] A. M. Sagdatullin, A. I. Kayashev, A. A. Emekeev, Sistema vektornogo upravleniya vyisokovoltnyim asinhronnyim elektrodvigatelem, Svidetelstvo No 2014618025 ot 07.08.2014, Rospatent, M., 2014