Three Bypass Diodes Architecture at the Limit

Robert Witteck; Michael Siebert; Susanne Blankemeyer; Henning Schulte-Huxel; Marc Kontges

doi:10.1109/JPHOTOV.2020.3021348

Details

Original language	English
Article number	9205207
Pages (from-to)	1828-1838
Number of pages	11
Journal	IEEE journal of photovoltaics
Volume	10
Issue number	6
Publication status	Published - Nov 2020
Externally published	Yes

Abstract

In this work, we demonstrate that partial shading of one solar cell in a state-of-the-art monocrystalline photovoltaic module with three bypass diodes results in hot cells with critical peak temperatures of 164 $^\circ$C. We examine two solar modules in the IEC 61215-2 MQT 09 hot-spot endurance test, one with 367.3 W$_\text{P}$ featuring 72 full-cells and the other with 388.6 W$_\text{P}$ featuring 144 half-cells. For the solar module with 72 solar cells, we measure a maximum temperature of 164 $^\circ$C, which results in a degradation of the encapsulation material and increases the risk of solar module failure. The high temperature results from the hot cell effect due to the power dissipation in the reverse-biased solar cell caused by partial shading. Our experiments show that the half-cell solar module is advantageous in terms of solar cell shading compared to the full-cell solar module. Although the half-cell solar module has a higher power output than the full-cell solar module, we measure a cooler peak temperature of 150 $^\circ$C. However, under certain shading conditions, the half-cell solar module can exhibit similar temperatures as the full-cell solar module. Based on our experimental results, we develop an electrical and a thermal model to predict the temperature of novel high-power solar modules with solar cells from larger silicon wafer formats in case of partial cell shading. Our predictions consider the trends of further increasing solar cell and module efficiencies, larger silicon wafer formats, and larger solar modules. We simulate a maximum peak temperature of 176 $^\circ$C at the solar module's surface, which significantly increases the risk of solar module failure. Our results show that new high-power solar modules employing solar cells that are made from larger silicon wafer formats need a new protection against overheating. Three bypass diodes per solar module are no longer sufficient.

Keywords

Breakdown characteristics, hot cells, solar module reliability

ASJC Scopus subject areas

Materials Science(all)
Electronic, Optical and Magnetic Materials
Physics and Astronomy(all)
Condensed Matter Physics
Engineering(all)
Electrical and Electronic Engineering

Sustainable Development Goals

SDG 7 - Affordable and Clean Energy

Cite this

Three Bypass Diodes Architecture at the Limit. / Witteck, Robert; Siebert, Michael; Blankemeyer, Susanne et al.
In: IEEE journal of photovoltaics, Vol. 10, No. 6, 9205207, 11.2020, p. 1828-1838.

Research output: Contribution to journal › Article › Research › peer review

Witteck, R, Siebert, M, Blankemeyer, S, Schulte-Huxel, H & Kontges, M 2020, 'Three Bypass Diodes Architecture at the Limit', IEEE journal of photovoltaics, vol. 10, no. 6, 9205207, pp. 1828-1838. https://doi.org/10.1109/JPHOTOV.2020.3021348

Witteck, R., Siebert, M., Blankemeyer, S., Schulte-Huxel, H., & Kontges, M. (2020). Three Bypass Diodes Architecture at the Limit. IEEE journal of photovoltaics, 10(6), 1828-1838. Article 9205207. https://doi.org/10.1109/JPHOTOV.2020.3021348

Witteck R, Siebert M, Blankemeyer S, Schulte-Huxel H, Kontges M. Three Bypass Diodes Architecture at the Limit. IEEE journal of photovoltaics. 2020 Nov;10(6):1828-1838. 9205207. doi: 10.1109/JPHOTOV.2020.3021348

Witteck, Robert ; Siebert, Michael ; Blankemeyer, Susanne et al. / Three Bypass Diodes Architecture at the Limit. In: IEEE journal of photovoltaics. 2020 ; Vol. 10, No. 6. pp. 1828-1838.

Download

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abstract = "In this work, we demonstrate that partial shading of one solar cell in a state-of-the-art monocrystalline photovoltaic module with three bypass diodes results in hot cells with critical peak temperatures of 164 $^\circ$C. We examine two solar modules in the IEC 61215-2 MQT 09 hot-spot endurance test, one with 367.3 W$_\text{P}$ featuring 72 full-cells and the other with 388.6 W$_\text{P}$ featuring 144 half-cells. For the solar module with 72 solar cells, we measure a maximum temperature of 164 $^\circ$C, which results in a degradation of the encapsulation material and increases the risk of solar module failure. The high temperature results from the hot cell effect due to the power dissipation in the reverse-biased solar cell caused by partial shading. Our experiments show that the half-cell solar module is advantageous in terms of solar cell shading compared to the full-cell solar module. Although the half-cell solar module has a higher power output than the full-cell solar module, we measure a cooler peak temperature of 150 $^\circ$C. However, under certain shading conditions, the half-cell solar module can exhibit similar temperatures as the full-cell solar module. Based on our experimental results, we develop an electrical and a thermal model to predict the temperature of novel high-power solar modules with solar cells from larger silicon wafer formats in case of partial cell shading. Our predictions consider the trends of further increasing solar cell and module efficiencies, larger silicon wafer formats, and larger solar modules. We simulate a maximum peak temperature of 176 $^\circ$C at the solar module's surface, which significantly increases the risk of solar module failure. Our results show that new high-power solar modules employing solar cells that are made from larger silicon wafer formats need a new protection against overheating. Three bypass diodes per solar module are no longer sufficient.",

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author = "Robert Witteck and Michael Siebert and Susanne Blankemeyer and Henning Schulte-Huxel and Marc Kontges",

note = "Funding information: Manuscript received July 20, 2020; accepted August 15, 2020. Date of publication September 24, 2020; date of current version October 21, 2020. This work was supported in part by the European Union{\textquoteright}s Horizon 2020 Research and Innovation Program through SUPERPV Project under Grant 792245 and in part by the German Federal Ministry for Economic Affairs and Energy through NEXTSTEP Project under Grant FKZ 0324171 C. (Corresponding author: Robert Witteck.) The authors are with the Institute for Solar Energy Research in Hamelin, 31860 Emmerthal, Germany (e-mail: witteck@isfh.de; siebert@isfh.de; blankemeyer@isfh.de; schulte@isfh.de; koentges@isfh.de). This work was supported in part by the European Union?s Horizon 2020 Research and Innovation Program through SUPERPV Project under Grant 792245 and in part by the German Federal Ministry for Economic Affairs and Energy through NEXTSTEP Project under Grant FKZ 0324171 C.",

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N1 - Funding information: Manuscript received July 20, 2020; accepted August 15, 2020. Date of publication September 24, 2020; date of current version October 21, 2020. This work was supported in part by the European Union’s Horizon 2020 Research and Innovation Program through SUPERPV Project under Grant 792245 and in part by the German Federal Ministry for Economic Affairs and Energy through NEXTSTEP Project under Grant FKZ 0324171 C. (Corresponding author: Robert Witteck.) The authors are with the Institute for Solar Energy Research in Hamelin, 31860 Emmerthal, Germany (e-mail: witteck@isfh.de; siebert@isfh.de; blankemeyer@isfh.de; schulte@isfh.de; koentges@isfh.de). This work was supported in part by the European Union?s Horizon 2020 Research and Innovation Program through SUPERPV Project under Grant 792245 and in part by the German Federal Ministry for Economic Affairs and Energy through NEXTSTEP Project under Grant FKZ 0324171 C.

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Research@Leibniz University