Abstract
Objective: To determine the optimum size of a dc-link capacitor for a grid connected photovoltaic inverter. Methods: Dc-link capacitors are considered as one of the sensitive parts of the grid connected photovoltaic systems and needs effort to design a reliable and optimal size capacitor as its reliability is concerned with the overall system reliability. The double line frequency power flows between the input and outside of a Φ grid connected PV system which produces voltage ripples at the capacitor and dc link. This voltage ripple increases temperature of passive components and dc source which affects the MPP operation of the photovoltaic modules and the system life. Therefore, it is essential to limit the voltage ripples at the input side of the system. The easiest way to limit the double frequency ripple voltage is to connect a capacitor in parallel to the PV module and the inverter which buffers the double line frequency power and supply a constant power to the inverter. This study proposed a general method for sizing a dc-link capacitor for a Φ grid connected voltage source inverter. It is seen that the capacitance is inversely proportional to the nominal dc and ripple voltage. Thus an increase in the nominal system voltage decreases the size of the capacitor and at the same time increases the voltage ripple. Therefore to limit voltage ripple within permissible limits and to ensure better system performance the dc-link capacitor must be appropriately sized. The simulations based on 3kW grid connected PV system are carried out in DIgSILENT Power Factory software. Findings: A capacitor of 410µF is needed to be connected in parallel with a 3kVA inverter having an nominal input voltage of 370V and maintaining a voltage ripple under 8.5%. Novelty: After determining optimized dc-link capacitor size we will limit the voltage ripple under permissible limits and hence improves the system efficiency and life of the grid connected PV system. Keywords: Voltage source inverter; voltage ripple; Dc-link capacitor sizing; distributed generation; grid connected PV system
Highlights
A constant increase in the energy demand and environmental challenges favors for the distributed generation (DG) sources such as photovoltaic (PV), wind, geothermal, biomass etc. as quality electrical power[1,2]
In order to maintain the difference between input and output power, to decrease the double frequency voltage ripple from switching action to ensure effective dc-link and provide sufficient energy at the hold-up time, the capacitors are extensively used in pulse width modulation (PWM) inverters[18,19,20,21]
The size of dc-link capacitor based on input dc voltage and maximum allowable voltage ripple is derived in this study
Summary
A constant increase in the energy demand and environmental challenges favors for the distributed generation (DG) sources such as photovoltaic (PV), wind, geothermal, biomass etc. as quality electrical power[1,2]. In order to maintain the difference between input and output power, to decrease the double frequency voltage ripple from switching action to ensure effective dc-link and provide sufficient energy at the hold-up time, the capacitors are extensively used in pulse width modulation (PWM) inverters[18,19,20,21]. The aim of this capacitor connection is to increase the life of the inverter compared to the PV panel operating life time. Size of the dc-link capacitor must be calculated in terms of the maximum allowable voltage ripple for the considered system
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