The Design Procedure of the Magnetoelectric Generator for Power Supply Consumers Own Power Plant
Keywords:
auxiliary generator, magnetoelectric excitation, design procedure, process modeling
Abstract
This article explores the possibility of using synchronous generators with excitation from permanent magnets as a source of electric energy in power plants of the gas pipeline assembly’s own needs. The scheme of constructing a power supply system for gas air-cooling apparatus is given. A design procedure for the generator of auxiliary needs is proposed, described in the form of an algorithm, the important components of which are the analysis of electromagnetic processes and an accurate calculation of magnetic losses in the steel cores and permanent magnets. The implementation of these steps makes it possible to requirements for the elemental base of power static converters (rectifier and inverter) and their control systems on the one hand and determine volumetric heat emissions in the active parts of the generator for subsequent calculation of the temperature field on the other. As a result of the execution of the described design procedure, it was possible to reduce the material and time costs for creating a prototype that meets the requirements of the technical task as much as possible.
References
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#
1. Kontseptsiya razyitiya energetiki OAO «Gazprom» na osnove primeneniya sobstvennykh elektrostantsiy i energoustanovok (The concept of energy development of JSC Gazprom based on the use of its own power plants and power plants), No. 52 dated 28.02.2000.
2. Arnold Magnetic Technologies [Electron. Resourse] https://www.vacuumschmelze.com/Assets-Web/VACODYM-VACO MAX-dt_12112014.pdf [Data of apple 17.04.2019]
3. Xiaohe M., Rong Su, Je T. K., Shuai W. Review of High Speed Electrical Machines in Gas Turbine Electrical Power Generation — Proc. TENCON IEEE Region 10 Conf., Nov. 2015, pp. 1-9.
4. Huang Z., Le Y. Rotordynamics Modelling and Analysis of High-Speed Permanent Magnet Electrical Machine Rotors. — IET Elec. Power Appl., 2018, vol. 12, iss. 8, pp. 1104—1109.
5. Pathmanathan M., Soong W. L. and Ertugrul N. V-и Control of Inverters Used in SPM Wind Turbine Generators. — 15th European Conf. on Power Electronics and Applications (EPE), pp. 1 — 10, 2013.
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7. Gieras J. F., Wing M. Permanent Magnet Motor Technology. Design and Application. Marcel Dekker Inc., New York, Basel, 2002, 590 p.
8. Zhou L., Wu Y., Geng W. Comparative Study on Concentrated-Windings Permanent Magnet Synchronous Machines with Different Rotor Structures for Aircraft Generator Application. — 18st Intern. Conf. on Electrical Machines and Systems (ICEMS) October 25—28, 2015, pp. 1246—1251.
9. Ledovskiy A.N. Elektricheskiye mashiny s vysokokoertsitivnymi postoyannymi magnitami (Calculation of electrical mashines). M.: Energiya, 1985, 168 p.
10. Makarichev Yu.A., Zubkov Yu.V., Ivannikov Yu.N., Gulyayev I.V. Elektrotekhnika — in Russ. (Electrical Engineering), 2019, No. 7, pp. 24—32.
11. Zubkov Yu.V., Chebotkov E.G. Trudy Mezhdunarod. Nauchno-tekhn. konf. (XVIII Benardosovskiye chteniya_ — in Russ. (Proc. of Intern. Scientific, and Technical Conf. (XVIII Benardos Lectures), 2015, pp. 128—131.
12. Shuyskiy V.P. Raschet elektricheskikh mashin (Calculation of electrical machines). M.: Energiya, 1968, 732 p.
13. Athanasopoulos K., Kastros V.I., Kappatou J.C. Electromagnetic Analysis of a PMSM with Different Rotor Topologies. — IEEE Int. Conf. of Elec. Mach., 2016, pp. 306—312.
2. Arnold Magnetic Technologies [Electron. Resourse] https://www.vacuumschmelze.com/Assets-Web/VACODYM-VACO MAX-dt_12112014.pdf [Data of apple 17.04.2019]
3. Xiaohe M., Rong Su, Je T. K., Shuai W. Review of High Speed Electrical Machines in Gas Turbine Electrical Power Generation — Proc. TENCON IEEE Region 10 Conf., Nov. 2015, pp. 1-9.
4. Huang Z., Le Y. Rotordynamics Modelling and Analysis of High-Speed Permanent Magnet Electrical Machine Rotors. — IET Elec. Power Appl., 2018, vol. 12, iss. 8, pp. 1104—1109.
5. Pathmanathan M., Soong W. L. and Ertugrul N. V-и Control of Inverters Used in SPM Wind Turbine Generators. — 15th European Conf. on Power Electronics and Applications (EPE), pp. 1 — 10, 2013.
6. Иванов-Смоленский А.В. Электрические машины: Учебник для вузов. М.: Энергия, 1980, 928 с.
7. Gieras J. F., Wing M. Permanent Magnet Motor Technology. Design and Application. Marcel Dekker Inc., New York, Basel, 2002, 590 p.
8. Zhou L., Wu Y., Geng W. Comparative Study on Concentrated-Windings Permanent Magnet Synchronous Machines with Different Rotor Structures for Aircraft Generator Application. — 8st Intern. Conf. on Electrical Machines and Systems (ICEMS) October 25—28, 2015, pp. 1246—1251.
9. Ледовский А.Н. Электрические машины с высококоэрцитивными постоянными магнитами. М.: Энергоатомиздат, 1985, 168 с.
10. Макаричев Ю.А., Зубков Ю.В., Иванников Ю.Н., Гуляев И.В. Анализ характеристик электромеханического стартера газотурбинной установки. — Электротехника, 2019, № 7, с. 24—32.
11. Зубков Ю.В., Чеботков Э.Г. Идентификация параметров синхронного генератора с возбуждением от постоянных магнитов методом численного моделирования магнитного поля. — Труды международ. научно-техн. конф. (XVIII Бенардосовские чтения), 2015, c. 128—131.
12. Шуйский В.П. Расчет электрических машин. М.: Энергия, 1968, 732 с.
13. Athanasopoulos K., Kastros V.I., Kappatou J.C. Electromagnetic Analysis of a PMSM with Different Rotor Topologies. — IEEE Int. Conf. of Elec. Mach., 2016, pp. 306—312.
#
1. Kontseptsiya razyitiya energetiki OAO «Gazprom» na osnove primeneniya sobstvennykh elektrostantsiy i energoustanovok (The concept of energy development of JSC Gazprom based on the use of its own power plants and power plants), No. 52 dated 28.02.2000.
2. Arnold Magnetic Technologies [Electron. Resourse] https://www.vacuumschmelze.com/Assets-Web/VACODYM-VACO MAX-dt_12112014.pdf [Data of apple 17.04.2019]
3. Xiaohe M., Rong Su, Je T. K., Shuai W. Review of High Speed Electrical Machines in Gas Turbine Electrical Power Generation — Proc. TENCON IEEE Region 10 Conf., Nov. 2015, pp. 1-9.
4. Huang Z., Le Y. Rotordynamics Modelling and Analysis of High-Speed Permanent Magnet Electrical Machine Rotors. — IET Elec. Power Appl., 2018, vol. 12, iss. 8, pp. 1104—1109.
5. Pathmanathan M., Soong W. L. and Ertugrul N. V-и Control of Inverters Used in SPM Wind Turbine Generators. — 15th European Conf. on Power Electronics and Applications (EPE), pp. 1 — 10, 2013.
6. Ivanov-Smolenskiy A.V. Elektricheskiye mashiny: Uchebnik dlya vuzov (Electric cars: Textbook for high schools). M.: Enerdiya, 1980, 928 p.
7. Gieras J. F., Wing M. Permanent Magnet Motor Technology. Design and Application. Marcel Dekker Inc., New York, Basel, 2002, 590 p.
8. Zhou L., Wu Y., Geng W. Comparative Study on Concentrated-Windings Permanent Magnet Synchronous Machines with Different Rotor Structures for Aircraft Generator Application. — 18st Intern. Conf. on Electrical Machines and Systems (ICEMS) October 25—28, 2015, pp. 1246—1251.
9. Ledovskiy A.N. Elektricheskiye mashiny s vysokokoertsitivnymi postoyannymi magnitami (Calculation of electrical mashines). M.: Energiya, 1985, 168 p.
10. Makarichev Yu.A., Zubkov Yu.V., Ivannikov Yu.N., Gulyayev I.V. Elektrotekhnika — in Russ. (Electrical Engineering), 2019, No. 7, pp. 24—32.
11. Zubkov Yu.V., Chebotkov E.G. Trudy Mezhdunarod. Nauchno-tekhn. konf. (XVIII Benardosovskiye chteniya_ — in Russ. (Proc. of Intern. Scientific, and Technical Conf. (XVIII Benardos Lectures), 2015, pp. 128—131.
12. Shuyskiy V.P. Raschet elektricheskikh mashin (Calculation of electrical machines). M.: Energiya, 1968, 732 p.
13. Athanasopoulos K., Kastros V.I., Kappatou J.C. Electromagnetic Analysis of a PMSM with Different Rotor Topologies. — IEEE Int. Conf. of Elec. Mach., 2016, pp. 306—312.
