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Photovoltaic differential power converter trade-offs as a consequence of panel variation

Photovoltaic (PV) elements have inherent variation between cells and panels due to manufacturing tolerance, degradation, and situational differences. This variation increases over system lifetime and creates maximum power point current mismatch that reduces output power when PV elements are strung i...

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Main Authors:	Kim, K. A., Shenoy, P. S., Krein, P. T.
Format:	Conference Proceeding
Language:	English
Subjects:	Computer architecture Degradation Electric variables Monte Carlo methods Power generation Production Topology
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creator	Kim, K. A. Shenoy, P. S. Krein, P. T.
description	Photovoltaic (PV) elements have inherent variation between cells and panels due to manufacturing tolerance, degradation, and situational differences. This variation increases over system lifetime and creates maximum power point current mismatch that reduces output power when PV elements are strung in series. Traditionally, mismatch loss is addressed using cascaded converters. However, this research examines a differential converter architecture that achieves higher efficiency by processing a fraction of the total power. The effect of PV maximum power point (MPP) current variance on output power is modeled and examined using Monte Carlo simulation for the series string architecture with and without bypass diodes, and the PV-to-Bus and PV-to-PV differential power processing (DPP) architectures at various power ratings. Hot spotting can be a problem that significantly reduces output power. PV elements at fault can be bypassed, passively or actively, to reduce power loss. Simulation results show that both DPP architectures employing active bypass are able to compensate mismatch over the 25-year lifetime of a PV system with converters sized at approximately 10-20% of the panel ratings.
doi_str_mv	10.1109/COMPEL.2012.6251789
format	conference_proceeding
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The effect of PV maximum power point (MPP) current variance on output power is modeled and examined using Monte Carlo simulation for the series string architecture with and without bypass diodes, and the PV-to-Bus and PV-to-PV differential power processing (DPP) architectures at various power ratings. Hot spotting can be a problem that significantly reduces output power. PV elements at fault can be bypassed, passively or actively, to reduce power loss. 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issn	1093-5142
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Computer architecture Degradation Electric variables Monte Carlo methods Power generation Production Topology
title	Photovoltaic differential power converter trade-offs as a consequence of panel variation
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