In-situ fast thermal detection method for large-scale photovoltaic field under shading conditions

H. Shareef; Zahi M. Omer; Mohamed N. Zareer

doi:10.1109/CENCON.2017.8262488

In-situ fast thermal detection method for large-scale photovoltaic field under shading conditions

H. Shareef, Zahi M. Omer, Mohamed N. Zareer

Department of Electrical and Communication Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

PV power plants are subjected to faults and failures and typically requires fast and precise diagnosis. For large scale PV plant, fault diagnosis is expensive due to shutdown periods and maintenance cost. In this paper, a cost-effective method has been proposed for partial/permanent shading conditions detection using thermal signatures. The simulation was conducted using the COMSOL program. Results: show that there are distinctive temperature variation signature at different shading degrees. The thermal simulation results are further validated experimentally by utilizing an array of temperature sensors. In addition, PV module terminal voltage output vary proportionally to the imposed shading level. A variation of 2 to 3 °C degrees per 20% shading level increment has been recorded.

Original language	English
Title of host publication	2017 IEEE Conference on Energy Conversion, CENCON 2017
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	224-229
Number of pages	6
ISBN (Electronic)	9781538639344
DOIs	https://doi.org/10.1109/CENCON.2017.8262488
Publication status	Published - Jul 1 2017
Event	3rd IEEE Conference on Energy Conversion, CENCON 2017 - Kuala Lumpur, Malaysia Duration: Oct 30 2017 → Oct 31 2017

Publication series

Name	2017 IEEE Conference on Energy Conversion, CENCON 2017
Volume	2018-January

Conference

Conference	3rd IEEE Conference on Energy Conversion, CENCON 2017
Country/Territory	Malaysia
City	Kuala Lumpur
Period	10/30/17 → 10/31/17

Keywords

Photovoltaic faults
Shading
Thermal modeling

ASJC Scopus subject areas

Energy Engineering and Power Technology
Renewable Energy, Sustainability and the Environment
Electrical and Electronic Engineering
Control and Optimization

Access to Document

10.1109/CENCON.2017.8262488

Cite this

Shareef, H., Omer, Z. M., & Zareer, M. N. (2017). In-situ fast thermal detection method for large-scale photovoltaic field under shading conditions. In 2017 IEEE Conference on Energy Conversion, CENCON 2017 (pp. 224-229). (2017 IEEE Conference on Energy Conversion, CENCON 2017; Vol. 2018-January). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/CENCON.2017.8262488

In-situ fast thermal detection method for large-scale photovoltaic field under shading conditions. / Shareef, H.; Omer, Zahi M.; Zareer, Mohamed N.
2017 IEEE Conference on Energy Conversion, CENCON 2017. Institute of Electrical and Electronics Engineers Inc., 2017. p. 224-229 (2017 IEEE Conference on Energy Conversion, CENCON 2017; Vol. 2018-January).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Shareef, H, Omer, ZM & Zareer, MN 2017, In-situ fast thermal detection method for large-scale photovoltaic field under shading conditions. in 2017 IEEE Conference on Energy Conversion, CENCON 2017. 2017 IEEE Conference on Energy Conversion, CENCON 2017, vol. 2018-January, Institute of Electrical and Electronics Engineers Inc., pp. 224-229, 3rd IEEE Conference on Energy Conversion, CENCON 2017, Kuala Lumpur, Malaysia, 10/30/17. https://doi.org/10.1109/CENCON.2017.8262488

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abstract = "PV power plants are subjected to faults and failures and typically requires fast and precise diagnosis. For large scale PV plant, fault diagnosis is expensive due to shutdown periods and maintenance cost. In this paper, a cost-effective method has been proposed for partial/permanent shading conditions detection using thermal signatures. The simulation was conducted using the COMSOL program. Results: show that there are distinctive temperature variation signature at different shading degrees. The thermal simulation results are further validated experimentally by utilizing an array of temperature sensors. In addition, PV module terminal voltage output vary proportionally to the imposed shading level. A variation of 2 to 3 °C degrees per 20% shading level increment has been recorded.",

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N2 - PV power plants are subjected to faults and failures and typically requires fast and precise diagnosis. For large scale PV plant, fault diagnosis is expensive due to shutdown periods and maintenance cost. In this paper, a cost-effective method has been proposed for partial/permanent shading conditions detection using thermal signatures. The simulation was conducted using the COMSOL program. Results: show that there are distinctive temperature variation signature at different shading degrees. The thermal simulation results are further validated experimentally by utilizing an array of temperature sensors. In addition, PV module terminal voltage output vary proportionally to the imposed shading level. A variation of 2 to 3 °C degrees per 20% shading level increment has been recorded.

AB - PV power plants are subjected to faults and failures and typically requires fast and precise diagnosis. For large scale PV plant, fault diagnosis is expensive due to shutdown periods and maintenance cost. In this paper, a cost-effective method has been proposed for partial/permanent shading conditions detection using thermal signatures. The simulation was conducted using the COMSOL program. Results: show that there are distinctive temperature variation signature at different shading degrees. The thermal simulation results are further validated experimentally by utilizing an array of temperature sensors. In addition, PV module terminal voltage output vary proportionally to the imposed shading level. A variation of 2 to 3 °C degrees per 20% shading level increment has been recorded.

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In-situ fast thermal detection method for large-scale photovoltaic field under shading conditions

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

Access to Document

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