Modelling and implementation of Mppt (Inc) algorithm for Pv water pump applications using Matlab

 
 
 
  • Abstract
  • Keywords
  • References
  • PDF
  • Abstract


    The presentdissertationhaggle by means of the configuration and enforcement proceeding from a common despite of a capable solar DC water pumping technique with battery backup by means of MATLAB SIMULINK software. The overall system depends on sunlight during daytime. It consists of subsystems like solar or photovoltaic (PV) panel, MPPT, Cuk converter, battery and DC motor and pump. This PV panel subsystem is designed by MATLAB range is 60W module with various irradiation rank and medium temperature. During daytime the clash of source and load, PV panel efficiency gets summarized.In some measures, to draw the zenith power to theammunition from PV panel, MPPT lives toput into effectin the Cuk converter manipulating by PWM Generator in addition to MPPT hill climbing (HC) algorithm which is also known as incremental conductance (INC). The result validates for MPPT put upessentially increases the system efficiency. The attainment of an overall solar power from the Photovoltaic (PV) water pump proposed system preserveindefinitely codified by a Simulink Paradigm. The MATLAB simulations ratify the DC-DC converter design. This allows a lower cost system. The battery was used as a backup during night time.


  • Keywords


    PV Panel,MPPT,Hill Climbing,CUK converter,MATLAB SIMULINK

  • References


      [1] Harsh Kumar Jain, Monika Vardia, “A Novel Maximum Power Point Tracking Algorithm for Photovoltaic Application”, IJEDR, Volume 3, Issue 2, ISSN: 2321-9939, 2015.

      [2] Mei Shan Ngan, Chee Wei Tan, “A Study of Maximum Power Point Tracking Algorithms for Stand-alone Photovoltaic Systems”, IEEE Power Electronics Colloquium (IPEC), 2011.

      [3] Dr. N. Veerappan, V. Rattan Kumar, V. Archana, “Smart Self Regenerative Illumination-solar Energy Based Hybrid Power Generation System”, 2014 IEEE.

      [4] Johan H. R. Enslin, Mario S. Wolf, Daniel B. Snyman, WernherSwiegers, “Integrated Photovoltaic Maximum Power Point Tracking Converter”, IEEE Transactions On Industrial Electronics, Vol. 44, No. 6, December 1997.

      [5] Roberto Faranda, Sonia Leva, “Energy comparison of MPPT techniques for PV Systems”, Issue 6, Volume 3, June 2008.

      [6] Esram T and Chapman P.L, “Comparison of Photovoltaic Array Maximum Power Point Tracking Techniques”, IEEE Trans. Energy Conv., vol.22, no.2, June, 2007, pp.439-449.

      [7] Chihchiang Hand Chihming S, "Study of maximum power tracking techniques and control of DC/DC converters for photovoltaic power system," Annual IEEE Power Electronics Specialists Conference, vol.1, pp. 86-93 vol.1, May 1998.

      [8] Chan Y. K and Gu J. C, “Modeling and control of stand-alone photovoltaic generation system”, IEEE International Conference on Power System Technology (POWERCON), pp. 1-7, Oct. 2010.

      [9] Mohamed M. Algazar, Hamdy AL-monier and Hamdy Abd EL-halim, Mohamed Ezzat El Kotb Salem, “Maximum power point tracking using fuzzy logic control”, Electrical Power and Energy Systems 39,pp. 21–28, 2012.

      [10] Taufik, Akihiro Oi, Makbul Anwari, and Mohammad Taufik, “Modeling and Simulation of Photovoltaic Water Pumping System”, Third Asia International Conference on Modelling & Simulation, 2009.

      [11] N.Chandrasekaran, Ganeshprabu and K.Thyagarajah “Comparative study of photovoltaic pumping system using a DC motor and PMDC motor”, IEEE-International Conference on Advances in Engineering, Science and Management (ICAESM -2012).


 

View

Download

Article ID: 10643
 
DOI: 10.14419/ijet.v7i1.7.10643




Copyright © 2012-2015 Science Publishing Corporation Inc. All rights reserved.