ПОРІВНЯННЯ ІМПЕДАНСНИХ ЛАНОК ДЛЯ ПЕРЕТВОРЮВАЧІВ З ДЖЕРЕЛОМ НАПРУГИ

O.O. Husev; A.I. Chub; D.V. Vinnikov

No. 3 (2015), Conversion of Electric Energy Parameters

No. 3 (2015)

Conversion of Electric Energy Parameters

COMPARISON OF THE IMPEDANCE- SOURCE NETWORKS FOR VOLTAGE-FED COVERTERS

Published 2015-04-28

O.O. Husev⁺⁻
A.I. Chub⁺⁻
D.V. Vinnikov⁺⁻

O.O. Husev

Chernigov National Technological University, Shevchenko str., 95, Chernigov, 14027, Ukraine

A.I. Chub

Tallinn University of Technology, str. Ehitayate, 5, Tallinn, 19086, Estonia

D.V. Vinnikov

Tallinn University of Technology, str. Ehitayate, 5, Tallinn, 19086, Estonia

ARTICLE_4_PDF (Українська)

Keywords

voltage-fed converter
impedance-source network
boost factor перетворювач
імпедансна ланка
коефіцієнт підсилення

How to Cite

[1]

Гусев, О., Чуб, А. and Вінніков, Д. 2015. COMPARISON OF THE IMPEDANCE- SOURCE NETWORKS FOR VOLTAGE-FED COVERTERS. Tekhnichna Elektrodynamika. 3 (Apr. 2015), 025.

Abstract

Impedance networks cover the entire realm of electric power conversion in a wide range of applications. Many converter topologies are presented in the literature in order to overcome the limitations of the traditional voltage source, current source, classical buck-boost, unidirectional and bidirectional converter topologies. This paper presents review of the main exist impedance-source networks for voltage-fed converter applications. The detailed analysis of their pros and cons is revealed. Boost factor of the different impedance networks is compared. The impedance networks that are based on the coupled inductors can have higher boost performance due to the adjustable turn’s ratio of the windings. The comparison in terms of input current behavior is presented as well. Modification examples of the impedancesourced converters are separately considered. Design principles of the isolated and cascaded converters based on the impedance-source networks are shown. The field of application is discussed. Doe to the wide voltage regulation range along with cross conduction immunity discussed solutions are promising for the renewable energy applications. References 18, table 1, fіgures 5.

ARTICLE_4_PDF (Українська)

References

Peng F.Z. Z-Source Inverter // IEEE Trans. Ind. Applicat. – 2003. – № 39(2). – Pр. 504-510.

Anderson J., Peng F.Z. A Class of Quasi-ZSource Inverters // Proc. of Industry Applications Society Annual Meeting, 2008. IAS '08. IEEE. – 2008. – Pр.1-7.

Anderson J., Peng F.Z. Four quasi-Z-Source inverters // Proc. of IEEE Power Electronics Specialists Conference, PESC’2008. – 2008. – Pр. 2743-2749.

Loh P.C., Gao F., Blaabjerg F. Embedded EZ-Source Inverter // IEEE Trans. Ind. App. – 2010. – № 46(1). – Pр. 256-267.

Strzelecki R., Adamowicz M., Strzelecka N., Bury W. New type T-source inverter // Proc. of Compatibility and Power Electronics (CPE), 2009 6th International Conference-Workshop. – 2009. – Pр. 191-195.

Adamowicz M., Guzinski J., Vinnikov D., Strzelecka N. Trans-Z-source-like Inverter with Built-in DC Current Blocking Capacitors // Proc. of Compatibility and Power Electronics (CPE), 2011 7th International Conference-Workshop. – 2011. – Pр. 137-143.

Adamowicz M., Strzelecki R., Peng F.Z., Guzinski J., Rub H.A. New Type LCCT-Z-Source Inverters // Proc. of EPE 2011. – 2011. – Pр. 1-10.

Loh P.C., Li D., Blaabjerg F. Γ-Z-Source Inverters // IEEE Trans. Power Electron. (letters). – 2013. – № 28(11). – Pр. 4880-4884.

Nguyen M.K., Lim Y.C., Kim Y.G. TZ-Source Inverters // IEEE Trans. Ind. Electron. – 2013. – № 60(12). – Pр. 5686-5695.

Siwakoti Y.P., Loh P.C., Blaabjerg F., Town G.E. Y-Source Impedance Network // IEEE Trans. Power Electron. (Letter). – 2014. – № 29(7). – Pр. 3250-3254.

Mo W., Loh P.C., Blaabjerg F. Voltage type Γ-source Inverters with Continuous Input Current and Enhanced Voltage Boost Capability // Proc. of 15th International Power Electronics and Motion Control Conference, EPE-PEMC 2012 ECCE Europe. – 2012. – Pр. 1-8.

Ahmed F., Cha H., Kim S.H., Kim H.G. A High Voltage Gain Switched-Coupled-Inductor Quasi-ZSource Inverter // Proc. of The 2014 International Power Electronics Conference IPEC-Hiroshima ECCE-ASIA. – 2014. – Pр. 480-484.

Vinnikov D., Roasto I., Jalakas T., Ott S. Extended Boost Quasi-Z-Source Inverters: Possibilities and Challenges // Electronics and Electrical Engineering. – 2011. – №.112(6). – Pр. 51-56.

Shuai J., Dong C., Peng F.Z. High frequency transformer isolated Z-source inverters // APEC. – 2011. – Pр. 442-449.

Dongsen S., Ge B., W. Wu, D. Bi, Peng F.Z., Haitham A.R. Quasi-Z source inverter based pole-phase modulation machine drive system // Proc. of Electrical Machines and Systems (ICEMS), 2011 International Conference on. – 2011. – № 112(6). – Pр. 1-6.

Rajaei A.H., Mohamadian M., Dehghan S.M., Yazdian A. Single-phase induction motor drive system using z-source inverter // Electric Power Applications, IET. – 2010. – № 4 (1). – Pр. 17-21.

Baby L.M., Salitha K. Speed control of maximum boost controlled Z source converter fed induction motor drive with peak DC link voltage control // Proc. of Control Communication and Computing (ICCC) 2013 International Conference on. – 2013. – Pр. 281-286.

Husev O. Determining of the controller parameters of the QZS DC/DC converter control system providing small signal stability // Tekhnichna Elektrodynamika. – 2013. – No 5. – Pp. 18-23. (Ukr)