Programmable Device Circuits and Systems

Open Access Open Access  Restricted Access Subscription Access
Open Access Open Access Open Access  Restricted Access Restricted Access Subscription Access

Design and Implementation of a Photovoltaic Energy Management System with Battery Backup


Affiliations
1 Bharath University, Chennai, India
     

   Subscribe/Renew Journal


This paper presents the analysis, design, and experimentation results of a photovoltaic energy management system with battery backup. The proposed system is capable of both gridconnected and islanded operations. The main advantage of the proposed system is that, in grid-connected mode, the inverter works as a current source in phase with the grid voltage, injecting power to the grid and controlling the dc-link voltage. The dc/dc converter manages the battery charge. In islanded mode, the inverter control is reconfigured to work as a voltage source using droop schemes. The dc/dc converter controls the dc-link voltage to enable the maximum power point tracking reference to be followed. A battery bank is connected to the dc link as energy storage for islanded operation mode. The aim of this paper is to show that the proposed system performs correctly, without dangerous transients for the inverter or the loads. Simulation and experimental results on a prototype model show the feasibility of the proposed control strategy.
User
Subscription Login to verify subscription
Notifications
Font Size

Abstract Views: 177

PDF Views: 1




  • Design and Implementation of a Photovoltaic Energy Management System with Battery Backup

Abstract Views: 177  |  PDF Views: 1

Authors

S. P. Vijayaragavan
Bharath University, Chennai, India
Debasish Pati
Bharath University, Chennai, India
B. Karthik
Bharath University, Chennai, India

Abstract


This paper presents the analysis, design, and experimentation results of a photovoltaic energy management system with battery backup. The proposed system is capable of both gridconnected and islanded operations. The main advantage of the proposed system is that, in grid-connected mode, the inverter works as a current source in phase with the grid voltage, injecting power to the grid and controlling the dc-link voltage. The dc/dc converter manages the battery charge. In islanded mode, the inverter control is reconfigured to work as a voltage source using droop schemes. The dc/dc converter controls the dc-link voltage to enable the maximum power point tracking reference to be followed. A battery bank is connected to the dc link as energy storage for islanded operation mode. The aim of this paper is to show that the proposed system performs correctly, without dangerous transients for the inverter or the loads. Simulation and experimental results on a prototype model show the feasibility of the proposed control strategy.