Performance of a crystalline silicon photovoltaic power plant during sandstorms

TL;DR

This paper examines how sandstorms affect the performance of crystalline silicon photovoltaic power plants, highlighting the impact on power output and the importance of dust storm monitoring for accurate yield prediction.

Contribution

It provides an analysis of sandstorm effects on PV plant yield and emphasizes integrating dust storm monitoring into power output forecasting models.

Findings

Power output decreases significantly during sandstorms.

Inverter performance remains satisfactory during sandstorms.

Dust storm monitoring improves PV yield prediction accuracy.

Abstract

Solar photovoltaic power generation has achieved grid parity in a number of countries during the last decade. This revolution has begun in countries where the solar radiation intensity is not very high. Solar resource maps created by a number of agencies worldwide indicate that areas of high intensity of solar radiation suitable solar for power generation are in deserts and semi-arid zones. These regions are dusty and are subjected to both anthropogenic pollution and natural sand storms. The impact of these events on the solar photovoltaic (PV) plant yield is significant. An increase in diffuse component of solar radiation is accompanied by a naturally occurring sand storm. Often the solar panels are tilted at an optimal angle and the global tilted radiation value falling on the panels changes significantly during and after the sand storms. It is noted that the decrease in the power output of a solar photovoltaic plant during such events is high enough to warrant further consideration while forecasting the plant output. Inverter performance during such sand storms is found to be satisfactory. Integrating dust storm monitoring with PV power plant yield prediction algorithms is necessary for an improved operation of PV plants.