Evaluation and Validation of Equivalent Circuit Photovoltaic Solar Cell Performance Models

Boyd, Matthew; Klein, S.A.; Reindl, Douglas T.; Dougherty, Brian P.

doi:10.1115/1.4003584

Cited by 105 publications

(59 citation statements)

References 16 publications

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“…First, the I-V characteristics of the glass-glass PV module have been measured, then the five parameters have been calculated starting from STC values using relations proposed in [22] and using the three different methods here proposed; in all cases, the I-V characteristics have been estimated. Figure 45.6a and b shows the I-V curves measured, the I-V curves estimated using the parameters calculated from STC values, the I-V curves estimated using the parameters calculated through the AB-DE algorithm, the I-V curves estimated using the parameters calculated through the analytical algorithm, and the I-V curves estimated using the parameters calculated through the analytical algorithm starting from the partial I-V characteristic.…”

Section: Resultsmentioning

confidence: 99%

“…Anyhow, the reference value of each parameter can be calculated starting from its value in the operating conditions and vice versa [22]. Once the parameters have been obtained, the I-V characteristic can be estimated by model (45.1):…”

Section: Architecture Of the Monitoring And Diagnostic Systemmentioning

confidence: 99%

“…• Calculation of the five parameters starting from data provided by manufacturers, which are referred to as STC • Measurement of solar radiation and cell temperature (in the real working conditions) • Calculation of the five parameters in the real working conditions through relations proposed in [22] • Estimation of the I-V characteristic in real working conditions using the calculated parameters • Measurement of the partial I-V curve • Calculation of the error ( mse) between the measured and the estimated I-V curve:…”

Section: Architecture Of the Monitoring And Diagnostic Systemmentioning

confidence: 99%

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Monitoring and Diagnostics of Photovoltaic Power Plants

Tina

Cosentino

Ventura

2015

Renewable Energy in the Service of Mankind Vol II

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Photovoltaic (PV) systems should be monitored in order to control their production and detect any possible faults. Different possibilities exist for data analysis. Some perform it yearly, analyzing the performance of the PV system over a significant time period of operation and comparing it with similar systems. This shows that a system is performing poorly, but it has the disadvantage that it cannot be used to explain the causes of this underperformance. Others use high-resolution monitoring (minutely to hourly intervals) to analyze the performance of the system; with this higher resolution, a fault diagnosis procedure can be executed. These systems can detect general faults like constant energy losses, total blackout, and short-time energy losses, and the best can also detect shading; however, they cannot identify the exact cause. With the introduction of distributed maximum power point tracking (DMPPT) systems-power optimizers and micro-inverters-a new level of PV system monitoring is possible. Since these systems require the monitoring of the modules' operating voltage and current (for the maximum power point tracking (MPPT) algorithm), the use of voltage and current sensors for each module is at no extra cost. It is only necessary to add a communication module since it is not directly incorporated in the DMPPT board.Based on the use of such appliances, a wireless sensor network (WSN) that allows monitoring, at panel level, the efficiency of PV panels has been proposed; nodes of the WSN, which are installed on each PV module, are equipped with voltage, current, irradiance, and temperature. Acquired data are then transferred to a management center which is in charge of estimating efficiency losses and correlated causes at the level of the single module.This research has been further developed in this chapter. The authors propose the possibility of using the DC/DC converter inside the system for MPPT. It allows

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Section: Resultsmentioning

confidence: 99%

Section: Architecture Of the Monitoring And Diagnostic Systemmentioning

confidence: 99%

Section: Architecture Of the Monitoring And Diagnostic Systemmentioning

confidence: 99%

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Monitoring and Diagnostics of Photovoltaic Power Plants

Tina

Cosentino

Ventura

2015

Renewable Energy in the Service of Mankind Vol II

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“…: T a " 20˝C; incident solar radiation of G T " 800 W/m 2 ; wind speed of 1 m/s, in absence of any external loads (η c " 0) [2]. All three models selected for this study have been extensively quoted in the literature but, to the authors' best knowledge, no one was validated as much as the model of King et al Boyd [11] reports that, depending on the conditions of the experiments, the model of King et al reproduces experimental data within 2.4% to 5.4%.…”

Section: Cell Temperature From Masters' Model [10]mentioning

confidence: 99%

“…The reason for the choice is twofold: King et al's model was validated against experimental data (2.4% to 5.4%, according to [11]) and it proved to reproduce Duffie et al's prediction within the accuracy of the method. Hence King's model was preferred to be used in the second part of the study; i.e.…”

Section: Monthly Average Solar Resource Datamentioning

confidence: 99%

Use of monthly average solar radiation data for assessing the efficiency of a photovoltaic array

Ortega

Orlando

Frota

2014

Int. J. Metrol. Qual. Eng.

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Abstract. Efficient solar energy installations depend largely on the availability of meteorological and geographical data (geographical coordinates, solar radiation, ambient temperature, wind speed) and the technical characteristics of the photovoltaic arrays. Usually, both, radiation and meteorological measurements are based on hourly surface observational data, not always easily accessible therefore requiring enormous memory capacity to be processed. From a practical point of view, this work investigated whether or not monthly average resource data can be used to assess the efficiency of the photovoltaic conversion (and thus the electrical energy obtained from this conversion) whenever hourly-based meteorological data are scarce or unreliable. Photovoltaic efficiency was calculated from predicted temperature of the cell by making use of classical analytical models of photovoltaic conversion. Calculations performed based on monthly average solar resource data reproduced within 0.5 K the temperature of the photovoltaic array and within 6% the total amount of energy converted as compared to hourly average solar resource data made available by official solar radiation and meteorological data bases.

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