Selection of optimum device parameters for permanent magnetic field generation

THE PURPUSE. To consider the fields of application of electromagnetic treatment of water systems. To analyze the modern literature on the use of constant magnetic fields for dehydration of oil-water emulsions. To develop the design of a device for generating constant magnetic fields and select its parameters. To select the electrical circuit for powering the device. To determine how the energy efficiency of the device changes with an increase in its overall dimensions. METHODS. When solving the problem, the KOMPAS-3D three-dimensional modeling system was used, the magnetic field induction was calculated using the PascalABC programming system, the optimal device parameters were selected using the Microsoft Excel program. RESULTS. The article describes the relevance of the topic, considers the distribution of the magnetic field in the device under development, determines the optimal design parameters for this device and selects the electrical power circuit. CONCLUSION. Calculations have shown that the coefficient taking into account the inhomogeneous distribution of the magnetic field in the device is 0.883. Using the KOMPAS-3D three-dimensional modeling system, a model of the device under development was builttaking into account the obtained relationships.When using a circuit with an uncontrolled rectifier and autotransformer, the power consumed by the device is 2.67 times lower than the power consumed by the device when using a circuit with a controlled rectifier and a transformer. Energy efficiency increases significantly with the increase in device performance.

1. Runov DM, Laptev AG. Electromagnetic water treatment in the circulating water supply system. Scientific and practical peer-reviewed journal Izvestiya vysshikh uchebnykh zavadenii. PROBLEMY ENERGETIKI. 2015;1-2:18-25.

2. Kashaev RS. Preparation of water-fuel emulsions in rotating magnetic and non-uniform electric fields with process control by NMR-relaxometry. Scientific and practical peer-reviewed journal Izvestiya vysshikh uchebnykh zavadenii PROBLEMY ENERGETIKI " 2016;1-2:20-26.

3. Voltsov AA. Intensification of the process of stratification of oil -water emulsions by means of their magnetic vibration treatment. Candidate dissertation. Ufa: USPTU. 2006. 122 p.

4. . Ermeev AM, Elpidinsky AA. On the use of a magnetic field in the processes of destruction of water-oil emulsions. Bulletin of Kazan Technological University. 2013;16(2):170-174.

5. Ibragimov NG, Sudykin AN, Sakhabutdinov RZ, et al.Technologies and methods of intensification of the process of preparation of high-viscosity oil. Oil industry. 2016;7:61-63.

6. Zolfagari R, Fakhru'l-Razi A, Abdulla LS. et al. Methods for demulsifying water-in-oil and oil-inwater emulsions in the petroleum industry. Sep. Purif. Technol. 2016;170:377–407.

7. Ivanov M.D, Konesev SG. Generator of pulsed electromagnetic field for dehydration of oil-water emulsion. An article in the collection Materials of the 71st Scientific and Technical Conference of Students, Postgraduates and Young Scientists of USPTU. 2 tons / hole ed. RU. Rabaev. Ufa: USPTU Publishing House, 2020. 572 p.

8. Veles PR, Pivovarova NA, Shchugorev VD, Berdnikov VM, Shelamkova OS, Kulneva IN. and Pivovarov AT. Method of dehydration of water-oil emulsion .Patent 2 152 817 (RF) dated 20.07.2000, IPC B01D 17/06.

9. Veles PR, Pivovarova NA. Magnetic tunnel. Patent 2 167 824 (RF) dated 27.05.2001, IPC C02F 1/48. Magnetic tunnel.

10. Shvetsov VN, Yunusov AA. New energy-efficient technology and technique of oil electrodeemulsification based on the use of composite electrodes // Izvestiya vysshikh uchebnykh zavadenii. PROBLEMY ENERGETIKI. 2018;20,3-4:54-61.

11. Sheikh-Ali A.D. Combined effect of magnetic field and demulsifiers on the process of oil dehydration. Oil and Gas Preparation. 2018;1:76-80.

12. Tavakoli MH, Ojagi A, Mohammadi-Manesh E, et al. The influence of coil geometry on the process of induction heating in crystal growing systems. Journal of growing crystals. 2009,311:6.

13. Keith Sum. K. Enhanced cavity filling passive power factor correction current driver, close to IEC. PCIM Magazine specification limits, February 1998

14. Konesev SG, Khazieva RT, Kirillov RV. Inductive-capacitive converters for secondary high-voltage power supplies. International Multiconference on Industrial Engineering and Modern Technologies, 2019. Institute of Electrical and Electronic Engineers, FarEastCon, pp. 1-5. doi: 10.1109/FarEastCon.2019.8934018.

15. Konesev SG., Khazieva RT., Kirillov RV, et al. Investigation of the stabilizing properties of inductive-capacitive converters based on hybrid electromagnetic elements. Journal of Physics: Conference Series (JPCS). 2017. V. 803. doi: 10.1088/1742-6596/803/1/012076.