Practical Implementation of an Embedded Controlled High Gain Interleaved Boost Converter for Solar Installation System
Abstract
In recent years, solar power generation has gathered
much attention in the field of generation and research. The aim of this
work is to develop a simulink model for closed loop controlled
interleaved boost converter and test it. This paper proposes a practical
implementation of two stage interleaved boost converter for solar
installation system. The topology study of open loop and closed loop
systems with step-up conversion and step increase in input voltage
are proposed. The modified two-stage interleaved DC to DC boost
converter is modeled and simulated using matlab/Simulink and it is
implemented using embedded controller. The simulation and
experimental results of this system are presented and compared. The
performance of the converter is compared with the conventional
boost converter. This comparison reveals that the present converter
system has the advantages of high efficiency and reduced switching
stress.
Keywords
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O. Abutbul, A. Gherlitz, Y. Berkovich, and A. Ioinovici, “Step-up
switching-mode converter with high voltage gain using a switched
capacitor circuit,” IEEE Trans. Circuits Syst. I, Fundam. Theory Appl.,
vol. 50, no. 8, pp. 1098–1102, 2003
I. Barbi and R. Gules, “Isolated DC–DC converters with high-output
voltage for TWTA telecommunication satellite applications,” IEEE
Trans.Power Electron., vol. 18, no. 4, pp. 975–984, 2003.
Wai Rong-Jong and Duan Rou-Yong, “High step-up coupledinductorbased
converter using bi-direction energy transmission,” IEEE
PESC'05, pp. 406-412, 2005.
Rong-Jong Wai, Wen-Hung Wang, and Chung-You Lin, “High-
Performance Stand-Alone Photovoltaic Generation System,” IEEE
Transactions on Industrial Electronics, VOL. 55, NO. 1, pp. 240-250,
Xu, J. 1991. An Analytical Technique for the Analysis of Switching DCDC
Converters,International Symposium on Circuits and Systems 2:
– 1215
Rashid M., Power Electronics: Circuits, Devices, And
Applications.Pearson Education International, 2004.
Veerachary, M., Senjyu, T. and Uezato, K.,. “Maximum power point
tracking control of IBD converter supplied PV System”, Proc. IEE
Electr. Power Appl. 2001. pp. 494-502
Gules, R., Lopes, L. and Claudio, L., 2003. “An Interleaved Boost DCDC
Converter with Large Conversion Ratio”, Proc.IEEE of the
International Symposium on Industrial Electronics 2003, pp. 411-416.
Sanchis-Kilders, E., Ferreres, A., Maset, E., Ejea, J., Esteve, V., Jordan,
J., Garcia, R. and Garrigbs, A. “High Power Passive Soft Switched
Interleaved Boost Converters”. Proc. IEEE Power Electronics Specialists
Conference, 2004, pp. 426-432.
Wang, J., Dunford, W. and Mauch, K., 1996. “Modified Boost
Converter with Continuous Inductor Current Mode and Ripple Free
Input Current”, Proc. IEEE Power Electronics Specialists Conference
, pp. 390-396.
Veerachary, M., Senjyu, T. and Uezato, K., “Maximum power point
tracking of coupled inductor interleaved boost converter supplied PV
system”, Proc. IEE Electr. Power Appl. 2003, pp. 71-80.
Eftichios Koutroulis and Kostas Kalaitzakis, "Development of a
Microcontroller- Based Photovoltaic Maximum Power Point Tracking
Control System," IEEE Transaction on Power Electronics, Vol. 16,
NO.1, pp.46-54, 2001.
Cheknane, T. Aemouts and M. O. A. Merad Boudia, "Modelling and
Simulation of organic bulk heterojunction solar cells," Revue des
Energies Renouvelables ICRESD-07 Tlemcen, pp83-90, 2007.
Eduardo Ivan Ortiz Rivera, „Modeling and Analysis of solar distributed
generation‟, Ph. D. dissertation, Michigan State University, 2006.
Ortiz-Rivera, Eduardo I; Peng, F.Z., "Analytical Model for a
Photovoltaic Module using the Electrical Characteristics provided by the
Manufacturer Data Sheet‟, Power Electronics Conference,
PESC‟05. IEEE 36th, vol. pp 2087-2091, 11-14, 2005.
Wai1 R.-Y. Duan, K.-H. Jheng, „High-efficiency bidirectional dc–dc
converter with high-voltage gain‟, IET Power Electron., 2012, Vol. 5,
Iss. 2, pp. 173–184
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