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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 698Energy-Saving Reversible Electric Drive Based on...

Energy-Saving Reversible Electric Drive Based on Active Front End Rectifier and Voltage Source Inverter

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Abstract:

This paper addresses the issue of functional possibilities of reversible electric drive based on active front end rectifier and voltage source inverter from the point of view of energy saving. This paper will review all theoretical capabilities of reactive power compensation in the supply mains by the active front end rectifiers. The reactive power consumption or generation can be created out by using of active front end converters which connect the electric drive with supply mains. Active front end rectifiers can be actively used in operation of supply mains of enterprise as they are able to provide controlled power factor and bidirectional power flow. The studies by mathematical modeling in the Matlab/Simulink program were carried out. It was established that the controlling of power factor of active front end rectifier can be used for reactive power compensation in supply mains. The huge prospects of energy-saving reversible electric drive integration to the Smart Grid have been determined as it is able to provide high power and capabilities of the controlling reactive power flow by means of active front end rectifier. It can reduce a share of the consumption reactive power from a substation and to improve the power quality.

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Electrical Engineering, Energy, Mechanical Engineering – EEM 2014

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Periodical:

Applied Mechanics and Materials (Volume 698)

Pages:

150-154

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.698.150

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Online since:

December 2014

Authors:

A.A. Radionov, A.S. Maklakov, E.A. Karyakina

Keywords:

Active Front End Rectifier, Back to Back Converter, Electric Drive, Reactive Power Compensation, Smart Grid (SG)

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© 2015 Trans Tech Publications Ltd. All Rights Reserved

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[1] Cook D., Das S. Smart Environments. Technologies, protocols and applications / – Hoboken NJ: Wiley-Interscience. 2005. p.329.

[2] Farhangi H. The path of the smart grid / IEEE Power and Energy Magazine. 2010. V. 8. No. 1. pp.18-28.

[3] Fang, X., Misra, S., Xue, G., Yang, D. Smart grid – The new and improved power grid / IEEE Communications Surveys and Tutorials. 2012. V. 14. No. 4. pp.944-980.

DOI: 10.1109/surv.2011.101911.00087

[4] Amin S. M., Wollenberg B. F. Toward a smart grid / IEEE Power and Energy Magazine. 2005. V. 3. No. 5. pp.34-41.

[5] Smart Grids portal. ABB Group. (referred 26. 06. 2014) http: /www05. abb. com.

[6] Smart Grids portal. ABB Group. (referred 12. 06. 2014) http: /new. abb. com/smartgrids/smart-grid-technologiesABB.

[7] Smart Grids portal. ABB Group. (referred 10. 07. 2014) http: /www. abb. com/cawp.

[8] Smart Grids portal. ABB Group. (referred 10. 07. 2014) http: /new. abb. com/smartgrids/why-smart-grids.

[9] Maklakov A.S., Gasiyarov V.R., Belyi А.V. Energy-saving electric drive on the basis of back to back converter / Russian Internet Journal of Electrical Engineering. 2014. Vol. 1. №1. pp.23-30.

DOI: 10.24892/rijee/20140104

[10] Maklakov A.S., Radionov A.A. Influence of AFE rectifier with different types of PWM on supply power / Russian Internet Journal of Industrial Engineering. 2013. №2. pp.40-47.

DOI: 10.24892/rijie/20130206

[11] Nikolaev A.A., Kornilov G.P., Ivekeev V.S., Lozhkin I.A., Kotyishev V.E., Tukhvatullin M.M. Using of the static var compensator of the ultra-high power electric arc furnace for supporting of electrical power system's stability and increasing reliability of factory power supply / Russian Internet Journal of Industrial Engineering. 2014. №. 1. pp.59-69.

DOI: 10.24892/rijie/20140108

[12] Maklakov A.S. Analysis of PWM Boost Rectifier in modes of reactive power compensation / Russian Internet Journal of Industrial Engineering. 2013. №1. pp.43-50.

DOI: 10.24892/rijie/20130107

[13] Maklakov A.S. Simulation of the Main Electric Drive of the Plate Mill Rolling Stand / Russian Internet Journal of Industrial Engineering. 2014. №3. pp.16-25.

DOI: 10.24892/rijie/20140303

[14] Remus Teodorescu, Marco Liserre, Pedro Rodrıguez. Grid converters for photovoltaic and wind power systems / – UK: John Wiley & Sons, Ltd. 2011, p.398.

[15] Hramshin T.R., Krubtsov D.S., Kornilov G.P. Evaluation of methods PWM voltage active rectifiers rolling mills / Russian Internet Journal of Industrial Engineering. 2013. №2. pp.48-52.

DOI: 10.24892/rijie/20130207

[16] Khramshin T.R., Krubtsov D.S., Kornilov G.P. A Mathematical Model of the Power Circuit of Main Electric Drives of Rolling Mills / Russian Internet Journal of Electrical Engineering. 2014. Vol. 1. №1. pp.3-7.

[17] Liserre M., Blaabjerg F., Hansen S. Design and control of an lcl-filter-based three-phase active rectifier / Industry Applications, IEEE Transactions on. 2005. V. 41. No. 5. pp.1281-1291.

DOI: 10.1109/tia.2005.853373