@misc{96ee4a3f16a74adc9d50ac040f15b87a,
title = "Simulating Wind-Driven Loading on PV Systems",
abstract = "As PV modules continue to trend toward larger, thinner, and more flexible forms they grow more susceptible to damage from dynamic wind loading. As a result, understanding the impact of wind on PV systems, particularly when mounted on compliant solar-tracking hardware, and identifying robust, stable array layouts and stow strategies is becoming increasingly important for the PV community. We are developing an open-source software package, PVade (PV aerodynamic design engineering), to simulate the cascading fluid-structure interaction that occurs within single-axis, solar-tracking arrays to enable researchers to test hardware, layout, and tracker control changes, leading to enhanced stability and a reduction in wind-driven damage. We will give an overview of the PVade software and present the latest outcomes from our ongoing validation campaign in which we compare time series and statistical structural responses with field data. From there, we will present simulated results from a larger, multi-row array and highlight the effect of varying tracker angles on stability and the differences between positive and negative tilt angles.",
keywords = "fluid, interaction, loading, PV, solar, stability, structure, tracking, wind",
author = "Ethan Young and Walid Arsalane and Brooke Stanislawski and Xin He and Melissa Rasmussen and Chris Ivanov and Scott Dana",
year = "2024",
language = "American English",
series = "Presented at the DuraMAT Simulating Wind-Driven Loading on PV Systems Webinar, 14 October 2024",
type = "Other",
}