Impact of Solar Irradiation on the Performance Ratio of the Photovoltaic Module

The objective of this paper is to establish the performance of 8 kWp grid-connected photovoltaic (PV) power systems based on different PV module technologies in Nanjing, China. Nanjing has a hot summer and a cold winter which are considered based on monthly average solar irradiation and ambient temperature specifically for the deployment of grid-connected PV systems. The study focuses on performance assessment of grid-connected PV systems using typical PV modules made of monocrystalline silicon (m-Si), polycrystalline silicon (p-Si), edge-defined film-fed growth silicon (EFG-Si), cadmium telluride (CdTe) thin film, copper indium selenide (CIS) thin film, heterojunction with intrinsic thin layer (HIT), and hydrogenated amorphous silicon single-junction (a-Si:H single-PV) installed on location. The yearly average energy output, PV module and system efficiency, array yield, final yield, reference yield, performance ratio, monthly average array capture losses, and system losses of seven PV module technologies are all analyzed. The results show that grid-connected PV power system performance depends on geographical location, PV module types, and climate conditions such as solar radiation and ambient temperature. In addition, based on energy output and efficiency, the HIT PV power technology can be considered as the best option and CdTe and p-Si as the least suitable options for this area. The monthly average performance ratio of the CdTe technology was higher than those of other technologies over the monitoring period in Nanjing.

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Design and implementation of an I-V curvetracer dedicated to characterize PV panels

International Journal of Electrical and Computer Engineering (IJECE) ◽

10.11591/ijece.v11i3.pp2011-2018 ◽

2021 ◽

Vol 11 (3) ◽

pp. 2011

Author(s):

Mansour Zegrar ◽

M’hamed Houari Zerhouni ◽

Mohamed Tarik Benmessaoud ◽

Fatima Zohra Zerhouni

Keyword(s):

Photovoltaic Effect ◽

Experimental System ◽

Experimental Results ◽

Solar Irradiation ◽

Photovoltaic Module ◽

Solar Photovoltaic ◽

Efficient Manner ◽

Photovoltaic Modules ◽

Curve Tracer ◽

Current Voltage

In recent years, solar photovoltaic energy is becoming very important in the generation of green electricity. Solar photovoltaic effect directly converts solar radiation into electricity. The output of the photovoltaic module MPV depends on several factors as solar irradiation and cell temperature. A curve tracer is a system used to acquire the PV current-voltage characteristics, in real time, in an eﬃcient manner. The shape of the I-V curve gives useful information about the possible anomalies of a PV device. This paper describes an experimental system developed to measure the current–voltage curve of a MPV under real conditions. The measurement is performed in an automated way. This present paper presents the design, and the construction of I-V simple curve tracer for photovoltaic modules. This device is important for photovoltaic (PV) performance assessment for the measurement, extraction, elaboration and diagnose of entire current-voltage I-V curves for several photovoltaic modules. This system permits to sweep the entire I-V curve, in short time, with different climatic and loads conditions. An experimental test bench is described. This tracer is simple and the experimental results present good performance. Simulation and experimental tests have been carried out. Experimental results presented good performance.

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Automatic fault detection for Building Integrated Photovoltaic (BIPV) systems using time series methods

Built Environment Project and Asset Management ◽

10.1108/bepam-07-2017-0045 ◽

2018 ◽

Vol 8 (2) ◽

pp. 160-170 ◽

Cited By ~ 1

Author(s):

Mohsen Shahandashti ◽

Baabak Ashuri ◽

Kia Mostaan

Keyword(s):

Time Series ◽

Automatic Detection ◽

Cost Effective ◽

Performance Ratio ◽

Solar Irradiation ◽

Short Term ◽

Content Type ◽

Structure Changes ◽

Cost Effective Approach ◽

Building Integrated Photovoltaic

PurposeFaults in the actual outdoor performance of Building Integrated Photovoltaic (BIPV) systems can go unnoticed for several months since the energy productions are subject to significant variations that could mask faulty behaviors. Even large BIPV energy deficits could be hard to detect. The purpose of this paper is to develop a cost-effective approach to automatically detect faults in the energy productions of BIPV systems using historical BIPV energy productions as the only source of information that is typically collected in all BIPV systems.Design/methodology/approachEnergy productions of BIPV systems are time series in nature. Therefore, time series methods are used to automatically detect two categories of faults (outliers and structure changes) in the monthly energy productions of BIPV systems. The research methodology consists of the automatic detection of outliers in energy productions, and automatic detection of structure changes in energy productions.FindingsThe proposed approach is applied to detect faults in the monthly energy productions of 89 BIPV systems. The results confirm that outliers and structure changes can be automatically detected in the monthly energy productions of BIPV systems using time series methods in presence of short-term variations, monthly seasonality, and long-term degradation in performance.Originality/valueUnlike existing methods, the proposed approach does not require performance ratio calculation, operating condition data, such as solar irradiation, or the output of neighboring BIPV systems. It only uses the historical information about the BIPV energy productions to distinguish between faults and other time series properties including seasonality, short-term variations, and degradation trends.

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Temperature impact on dusty and cleaned photovoltaic module exposed in sub-Saharan outdoor conditions

EPJ Photovoltaics ◽

10.1051/epjpv/2018007 ◽

2018 ◽

Vol 9 ◽

pp. 8 ◽

Cited By ~ 1

Author(s):

N'detigma Kata ◽

Y. Moussa Soro ◽

Djicknoum Diouf ◽

Arouna Darga ◽

A. Seidou Maiga

Keyword(s):

Standard Test ◽

Operating Conditions ◽

Solar Irradiation ◽

Test Facility ◽

Photovoltaic Module ◽

Significant Drop ◽

Single Junction ◽

Irradiation Level ◽

Sub Saharan ◽

Module Performance

In this work, impacts of temperature and dust cleaning on photovoltaic module performance operating in sub-Saharan's climate are investigated. Two single junction technologies, monocrystalline and polycrystalline silicon, and one micromorph (amorphous/micrystalline) thin film silicon tandem technology are considered. We have recorded at the same time under real operating conditions, the module temperature and the current versus voltage characteristics of each module, and the local solar irradiation. All the measurements were performed with the outdoor monitoring and test facility located at Ouagadougou in Burkina Faso. The results show the drop of generated power of dusty modules for the same irradiation level. Between April and June (where temperatures are higher) a significant drop of output power is observed, despite a daily cleaning. Furthermore, performance losses are observed for all technologies compared to that under standard test conditions. However, the micromorph silicon tandem technology with low temperature sensitivity present the less losses in performance compared to the monocrystalline and the polycrystalline single junction modules, even if the modules are not cleaned.

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Design of a low-cost measuring and plotting device for photovoltaic modules

Measurement and Control ◽

10.1177/0020294019865752 ◽

2019 ◽

Vol 52 (9-10) ◽

pp. 1308-1318

Author(s):

Sudipta Basu Pal ◽

Abhijit Das ◽

Konika Das (Bhattacharya) ◽

Dipankar Mukherjee

Keyword(s):

Heat Dissipation ◽

Low Cost ◽

Climatic Conditions ◽

Performance Ratio ◽

Photovoltaic Module ◽

Eastern Region ◽

Testing Apparatus ◽

Photovoltaic Modules ◽

Test Kit ◽

Capacitive Loading

The photovoltaic module testing apparatus being used presently for photovoltaic measurements acts principally on the method of photovoltaic module loading with resistive, capacitive, and electronic elements. In this work, a new method is described using a supercapacitor as the load to the photovoltaic module. This technique of characterization has proved to generate reliable V–I characteristics as validated by statistical and mathematical analyses in this article. Heat dissipation affecting the functioning of the photovoltaic modules is a common occurrence with resistive and capacitive loading techniques. It is reduced significantly in this method using supercapacitors, and curve tracing time is extremely modest and easily controllable. In effect, a low-cost, portable, and reliable I–V plotter is developed, which is operational from an embedded systems platform integrated with smart sensors. This I–V tracer has been used for the performance assessment of solar modules ranging from 10 to 100 Wp under varying climatic conditions in the eastern region of India. This test kit so developed in the photovoltaic engineering laboratory at Indian Institute of Engineering Science and Technology, Shibpur, is estimated to be useful for practicing engineers and photovoltaic scientists and in particular for photovoltaic module manufacturers. The performance parameters such as fill factor and performance ratio of photovoltaic modules measured by the device have been found to have almost identical values as the measurements from a reference commercial testing apparatus. The data pertaining to peak wattage as measured by the designed plotter have been found to be closely converging with an industry-friendly YOKOGAWA Power Meter (WT 330). Such peak values of power as measured and claimed by the datasheets will help reduce the uncertainties in measurement, leading to increased confidence of photovoltaic module manufacturers and investors. With this backdrop, the necessary work for scaling up of the low-cost I–V plotter has been taken up for assessing the performance of higher wattage photovoltaic modules.

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Performance Analyses of 15 kW Grid-Tied Photo Voltaic Solar System Type under Baghdad city climate

Journal of Engineering ◽

10.31026/j.eng.2020.04.02 ◽

2020 ◽

Vol 26 (4) ◽

pp. 21-32

Author(s):

Nibras Mahmood Obaid ◽

Emad T. Hashim ◽

Naseer K. Kasim

Keyword(s):

Solar System ◽

Average Power ◽

Performance Ratio ◽

Solar Irradiation ◽

Solar Array ◽

Energy Yield ◽

Solar Pv ◽

Pv System ◽

Current Output ◽

Performance Analyses

The performance analyses of 15 kWp (kW peak) Grid -Tied solar PV system (that considered first of its type) implemented at the Training and Energy Research Center Subsidiary of Iraqi Ministry of Electricity in Baghdad city has been achieved. The system consists of 72 modules arranged in 6 strings were each string contains 12 modules connected in series to increase the voltage output while these strings connected in parallel to increase the current output. According to the observed duration, the reference daily yields, array daily yields and final daily yields of this system were (5.9, 4.56, 4.4) kWh/kWp/day respectively. The energy yield was 1585 kWh/kWp/year while the annual total solar irradiation received by solar array system was 1986.4kWh/m2. The average power losses per day of array, system losses and overall losses were (1.38, 0.15, 1.53) kWh/kWp/day respectively. The average capacity factor and performance ratio per year were 18.4% and 75.5% respectively. These results highlighted the performance analyses of this PV solar system located in Baghdad city. The performance can be considered as good and significant comparing with other world PV solar stations.

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Performance of BIPV modules under different climatic conditions

WEENTECH Proceedings in Energy ◽

10.32438/wpe.6519 ◽

2019 ◽

pp. 107-115 ◽

Cited By ~ 1

Author(s):

Juliana Goncalves ◽

Twan Van Hooff ◽

Dirk Saelens

Keyword(s):

Cape Town ◽

Climatic Conditions ◽

Performance Ratio ◽

Solar Irradiation ◽

Energy Yield ◽

Average Cell ◽

Ambient Temperatures ◽

Building Geometry ◽

Low Energy Buildings ◽

Representative Office

Building integrated photovoltaic (BIPV) technology has gained attention as a solution to achieve low energy buildings. However, unlike conventional PV applications, BIPVs typically operate at non-optimal orientation, imposed by the building geometry. Moreover, the building integration reduces the heat exchange to the exterior, leading to higher temperatures. This paper investigates the performance of BIPV modules in different locations by simulating a representative office room in a high-rise building having a BIPV facade. The locations considered are Riyadh (Saudi Arabia), Seville (Spain), Naples (Florida, USA), Cape Town (South Africa), and Munich (Germany). The facade is vertical and faces the equator for all locations. Results show the highest annual BIPV energy yield occurs in Seville, followed by Cape Town, Riyadh, and Naples. In terms of monthly yields, the highest values are observed in Riyadh and Seville in wintertime. Monthly yield is more uniform over the year in Munich, while important differences between summer and winter have been obtained for Riyadh. These results confirm the influence of the latitude on the BIPV yield, with equator-facing facades in high latitudes receiving up to 40 % less irradiation compared to a horizontal surface, with important reductions especially in the summer. In these locations, the use of west and east facades may be necessary to achieve a balanced profile over the year. Moreover, the highest average cell temperatures occur in Riyadh, Naples and Seville, while lowest temperatures are verified in Cape Town and Munich, which is consistent with the corresponding ambient temperatures. Finally, with lower BIPV temperatures and relatively high solar irradiation, Cape Town achieves the highest performance ratio (PR) values. Conversely, the combination of high solar irradiation and high temperatures leads to lower PR values in Riyadh and Seville

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Performance Analysis of PV Systems: Case study of Palestine Technical University (PTUK) PV Plant

مجلة جامعة فلسطين التقنية للأبحاث ◽

10.53671/pturj.v9i1.147 ◽

2021 ◽

Vol 9 (1) ◽

pp. 10-21

Author(s):

Mahmoud Ismail

Keyword(s):

Performance Analysis ◽

Energy Production ◽

The Other ◽

Performance Ratio ◽

Solar Irradiation ◽

Pv System ◽

Pv Systems ◽

Science Building ◽

University Buildings

Performance ratio is one of the indicators used to describe the effectiveness of the PV systems. The sustainability of the PV system year after year as well as its reliability can be checked by measuring the performance ratio each year. This indicator will also enable us to carry out a comparison between the performances of different PV systems. In this paper, the performance ratios for five PV systems installed on the roof tops of some of PTUK university buildings have been calculated on monthly and yearly basis. The analysis has been carried out using the available data (energy production and solar irradiation) for the year 2019. It was found that the performance ratio has higher values for May and September in comparison with other months. On the other hand, its lowest values were obtained in winter months. This trend can be observed for all of the PV clusters on the five buildings. When taking into account the overall system, the highest value for the performance ratio was 0.89, which was for September, whereas its lowest value of 0.70 was obtained in January. The performance ratio, which was calculated on yearly basis for the overall system, was found to be 0.80. When considering each building separately, the lowest value was 0.44 for the “Services” building whereas the highest value was 0.94 for the Science building.

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Numerical Analysis of a Real Photovoltaic Module with Various Parameters

Modelling and Simulation in Engineering ◽

10.1155/2018/7329014 ◽

2018 ◽

Vol 2018 ◽

pp. 1-12 ◽

Cited By ~ 1

Author(s):

Costica Nituca ◽

Gabriel Chiriac ◽

Dumitru Cuciureanu ◽

Guoqiang Zhang ◽

Dong Han ◽

...

Keyword(s):

Thermal Model ◽

Power Estimation ◽

Solar Irradiation ◽

Photovoltaic Module ◽

Temperature Influence ◽

The Finite Element Method ◽

Modeling And Simulations ◽

Pv Module ◽

Pv Cell ◽

Optimal Values

This article presents a real photovoltaic module with modeling and simulations starting from the model of a photovoltaic (PV) cell. I-V, P-V, and P-I characteristics are simulated for different solar irradiation, temperatures, series resistances, and parallel resistances. For a real photovoltaic module (ALTIUS Module AFP-235W) there are estimated series and parallel resistances for which the energetical performances of the module have optimal values for a solar radiation of 1000 W/m2 and a temperature of the environment of 25°C. Temperature influence over the PV module performances is analyzed by using a thermal model of the ALTIUS Module AFP-235W using the finite element method. A temperature variation on the surface of the PV module is starting from a low value 40.15°C to a high value of 52.07°C. Current and power estimation are within the errors from 1.55% to about 4.3%. Experimental data are measured for the photovoltaic ALTIUS Module AFP-235W for an entire daylight.

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Experimental thermodynamic performance analysis of semi-transparent photovoltaic-thermal hybrid collectors using nanofluids

Proceedings of the Institution of Mechanical Engineers Part E Journal of Process Mechanical Engineering ◽

10.1177/09544089211013663 ◽

2021 ◽

pp. 095440892110136

Author(s):

P Jidhesh ◽

TV Arjunan ◽

N Gunasekar ◽

M Mohanraj

Keyword(s):

Performance Analysis ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Weather Conditions ◽

Solar Irradiation ◽

Experimental Result ◽

Photovoltaic Module ◽

Thermodynamic Performance ◽

Experimental Trials

In this article, the experimental thermodynamic performance analysis of a semi-transparent photovoltaic-thermal hybrid collector (SPV-THC) using CuO, Al2O3, TiO2 based nanofluids and water is investigated and compared with conventional opaque photovoltaic panels. The SPV-THC consists of a polycrystalline silicon cell photovoltaic module with a serpentine tube configuration heat sink. The influence of nanoparticle concentration, mass flow rate of nanofluids, ambient factors such as solar irradiation and ambient temperature on thermodynamic performance of SPV-THC have been experimentally studied under the weather conditions in Coimbatore, India. The concentration of nanoparticles and mass flow rate of nanofluids were optimized to 0.2% (by volume) and 0.016 kg/s, respectively based on experimental trials. The experimental result shows that the electrical efficiency of SPV-THC using CuO, TiO2, Al2O3 based nanofluids and water has been improved by 11.2%, 9.1%, 7.3% and 5.9% respectively than the conventional opaque photovoltaic modules. Also, the thermal efficiencies of SPV-THC using CuO, TiO2 and Al2O3 nanofluids improved by 42.6%, 34.8% and 19.7% respectively than water.

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