Flywheel energy storage control system with the system operating status control via the Internet

• Autorzy: Baszyński M. , Siostrzonek T.

Identyfikatory

DOI

10.2478/aee-2014-0033

• Języki publikacji: EN

Abstrakty

EN

Modern electronics systems consist of not only with the power electronics converters, but also with the friendly user interface which allow you to read the operating parameters and change them. The simplest solution of the user interface is to use alphanumeric display which displays information about the state of the converter. With a few additional buttons you can change the settings. This solution is simple, inexpensive but allows only local control (within walking distance from the system) and the number of displayed information is low. You can create extensive menu, but it causes problems with access to information. This paper presents the example of a rotating energy storage universal solution which is lack of the above mentioned disadvantages.

Słowa kluczowe

EN

BLDCPM; high speed drive; flywheel energy storage system; FPGA

• Wydawca: Polish Academy of Sciences, Committee on Electrical Engineering
• Czasopismo: Archives of Electrical Engineering
• Rocznik: 2014
• Tom: Vol. 63, nr 3
• Strony: 457--467
• Opis fizyczny: Bibliogr. 10 poz., rys., tab.

Twórcy

autor

Baszyński M.

• Department of Power Electronics and Energy Control Systems AGH, University of Science and Technology

autor

Siostrzonek T.

• Department of Power Electronics and Energy Control Systems AGH, University of Science and Technology

Bibliografia

• [1] Piróg S., Baszyński M., Siostrzonek T., Energy Storage- The High- Speer Flywheel Energy Storage System. SCIYO, pp. 37-67 (2009).
• [2] Sziebig G., Takarics B., Korondi P., Control of an Embedded System via Internet. Industrial Electronics, IEEE Transactions on 57(10): 3324-3333 (2010).
• [3] Bernat J., Stępień S., Application of optimal current driver for the torque control of BLDC motor. Archives of Electrical Engineering 60(2): 149-158 (2011).
• [4] Ciurys M., Dudzikowski I., Transients of electrical and mechanical quantities of a brushless DC motor - computations, measurements. Archives of Electrical Engineering 60(1): 23-34 (2011).
• [5] Kaliappan E., Chellamuthu C., Modeling, simulation and experimental analysis of permanent magnet brushless DC motors for sensorless operations. Archives of Electrical Engineering 61(4): 499-515 (2012).
• [6] Biskup T., Recovery braking of variable-structure electronic commutator for BLDC motor. Archives of Electrical Engineering 61(4): 579-596 (2012).
• [7] Joice C.S., Paranjothi S.R., Kumar V.J.S, Digital Control Strategy for Four Quadrant Operation of Three Phase BLDC Motor With Load Variations. IEEE Trans. on Industrial Informatics 9(2): 974-982 (2013).
• [8] Das P., Pahlevaninezhad M., Drobnik J. et al., A Nonlinear Controller Based on a Discrete Energy Function for an AC/DC Boost PFC Converter. IEEE Trans. on Industrial Application 28(12): 5458-5476 (2013).
• [9] Kulikowski K., Modified algorithms of direct power control of AC/DC converter co-operating with the grid. Archives of Electrical Engineering 61(3): 373-388 (2012).
• [10] Stupar A., Friedli T., Minibock J., Kolar J.W., Towards a 99% Efficient Three-Phase Buck-Type PFC Rectifier for 400-V DC Distribution Systems. IEEE Trans. on Power Electronics 27(4): 1732-1744 (2012).