A Sensitivity Study of the Impact of Installation Parameters and System Configuration on the Performance of Bifacial PV Arrays

Amir Asgharzadeh; Bill Marion; Chris Deline; Clifford Hansen; Joshua S Stein; Fatima Toor

doi:10.1109/JPHOTOV.2018.2819676

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Journal article

A Sensitivity Study of the Impact of Installation Parameters and System Configuration on the Performance of Bifacial PV Arrays

Amir Asgharzadeh, Bill Marion, Chris Deline, Clifford Hansen, Joshua S Stein and Fatima Toor

IEEE journal of photovoltaics, Vol.8(3), pp.798-805

05/2018

DOI: 10.1109/JPHOTOV.2018.2819676

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Abstract

In this paper, we present the effect of installation parameters (tilt angle, height above ground, and albedo) on the bifacial gain and energy yield of three south-facing photovoltaic (PV) system configurations: a single module, a row of five modules, and five rows of five modules utilizing RADIANCE-based ray tracing model. We show that height and albedo have a direct impact on the performance of bifacial systems. However, the impact of the tilt angle is more complicated. Seasonal optimum tilt angles are dependent on parameters such as height, albedo, size of the system, weather conditions, and time of the year. For a single bifacial module installed in Albuquerque, NM, USA (35 °N) with a reasonable clearance (∼1 m) from the ground, the seasonal optimum tilt angle is lowest (∼5°) for the summer solstice and highest (∼65°) for the winter solstice. For larger systems, seasonal optimum tilt angles are usually higher and can be up to 20° greater than that for a single module system. Annual simulations also indicate that for larger fixed-tilt systems installed on a highly reflective ground (such as snow or a white roofing material with an albedo of ∼81%), the optimum tilt angle is higher than the optimum angle of the smaller size systems. We also show that modules in larger scale systems generate lower energy due to horizon blocking and large shadowing area cast by the modules on the ground. For albedo of 21%, the center module in a large array generates up to 7% less energy than a single bifacial module. To validate our model, we utilize measured data from Sandia National Laboratories' fixed-tilt bifacial PV testbed and compare it with our simulations.

Clouds

Meteorology

Optimization

Bifacial PV

Computational modeling

Data models

Laboratories

Photovoltaic systems

ray tracing

solar power generation

Details

Title: Subtitle: A Sensitivity Study of the Impact of Installation Parameters and System Configuration on the Performance of Bifacial PV Arrays
Creators: Amir Asgharzadeh - University of Iowa
Bill Marion - National Laboratory of the Rockies
Chris Deline - National Laboratory of the Rockies
Clifford Hansen - Sandia National Laboratories
Joshua S Stein - Sandia National Laboratories
Fatima Toor - University of Iowa
Resource Type: Journal article
Publication Details: IEEE journal of photovoltaics, Vol.8(3), pp.798-805
DOI: 10.1109/JPHOTOV.2018.2819676
ISSN: 2156-3381
eISSN: 2156-3403
Publisher: IEEE
Grant note: 1625350 / U.S. Department of Energy SunShot National Laboratory Multiyear Partnership (SuNLaMP) — Photovoltaic Subprogram
Language: English
Date published: 05/2018
Academic Unit: Electrical and Computer Engineering; Iowa Technology Institute; Physics and Astronomy; Holden Comprehensive Cancer Center
Record Identifier: 9984197233702771

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