70% Decrease of Hot-Spotted Photovoltaic Modules Output Power Loss Using Novel MPPT Algorithm

Dhimish, Mahmoud

doi:10.1109/tcsii.2019.2893533

Cited by 24 publications

(12 citation statements)

References 22 publications

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“…In this arrangement, the fuel cell must comprise a control system (with stability mode controller) to connect quickly and control the fuel cell's current flow into the DC-DC converter, followed by a DC-AC inverter linked with the wheel drive machinery. Here, the DC-DC converter must act unidirectional, where no feedback/reversed current passes into the fuel cell [8,9]. It is also worth noting that current fuel cell EV models follow the configuration as in Fig.…”

Section: Literature Reviewmentioning

confidence: 99%

Investigating the stability and degradation of hydrogen PEM fuel cell

Dhimish

Vieira

Badran

2021

International Journal of Hydrogen Energy

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Section: Literature Reviewmentioning

confidence: 99%

Investigating the stability and degradation of hydrogen PEM fuel cell

Dhimish

Vieira

Badran

2021

International Journal of Hydrogen Energy

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“…In addition, M. Dhimish. [19], proposed suitable method improves the output power of hot-spotted PV module at least by 70%. The method uses a modified maximum power point tracking (MPPT) algorithm which is skilled of determining the amount of current and voltage loss for hot-spotted PV modules, subsequently, increasing the output power production.…”

Section: Existing Hot-spots Mitigating Techniquesmentioning

confidence: 99%

Current limiter circuit to avoid photovoltaic mismatch conditions including hot-spots and shading

Dhimish

Badran

2020

Renewable Energy

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Photovoltaic (PV) hot-spots are considered as one of the main reliability issues for PV modules.Although PV modules are capable to tolerate over-temperature, the hot-spots can lead to accelerated aging and, sometimes, to sudden failure with possible risk to fire. The commonpractise for mitigating this phenomenon is the adoption of the conventional bypass diode circuit, yet, this method does not guarantee a decrease in the temperature of hot-spotted solar cell. Therefore, in this paper, we present the development of a new current limiter circuit that is capable of mitigating the current flow of PV modules affected by mismatch conditions including partial shading and hot-spotting phenomenon. The foundation of the proposed circuit is fundamentally based on an input buffer which allows high impedance input voltages, and an operational amplifier circuit which controls the current flow of an integrated MOSFETs.Hence, to allow the control of the amount of current passing though mismatched PV substrings, and therefore, increase the output power generation. Detailed circuit simulations and multiple experiments are presented to evidence the capability of the circuit. In contrast, the average dissipated power of the circuit is limited to 0.53 W.

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“…For serially connected PV system, shading, such a s birds, tree shadows, is a problem since the shaded PV module reduces the output whole string of PV modules [17][18][19]. The excess power from the unshaded PV module is dissipated in the shaded PV module and it is shown that temperature of the shaded PV module or cell rises as hot spot [20][21][22]. Until now, research on the shaded PV modules or 1030 cells has been mainly on the performance of the whole PV system, and there has been little analysis on the circuit and power dissipation of each PV module [23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Power dissipation analysis of PV module under partial shading

2021

IJECE

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Photovoltaic (PV) generation has been growing dramatically over the last years and it ranges from small, rooftop-mounted or building integrated systems, to large utility scale power stations. Especially for rooftop-mounted PV system, PV modules are serially connected to match with PV inverter input voltage specification. For serially connected PV system, shading is a problem since the shaded PV module reduces the output whole string of PV modules. The excess power from the unshaded PV module is dissipated in the shaded PV module. In this paper, power dissipation of PV module under partial shading is analyzed with circuit analysis for series connected PV modules. The specific current and voltage operating point of the shaded PV module are analyzed under shading. PSIM simulation tool is used to verify the power dissipation analysis. When there is no bypass diode and three solar modules are connected in series, upto 39.1% of the total maximum PV power is dissipated in the shaded PV module. On the other hand, when the bypass is attached, 0.3% of the total maximum power is generated as a loss in the shaded PV module. The proposed analysis technique of shaded PV module could be used in PV system performance analysis, especially for maximum power point tracking (MPPT) performance.

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70% Decrease of Hot-Spotted Photovoltaic Modules Output Power Loss Using Novel MPPT Algorithm

Cited by 24 publications

References 22 publications

Investigating the stability and degradation of hydrogen PEM fuel cell

Investigating the stability and degradation of hydrogen PEM fuel cell

Current limiter circuit to avoid photovoltaic mismatch conditions including hot-spots and shading

Power dissipation analysis of PV module under partial shading

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