Analysis of the Performance of Various PV Module Technologies in Peru

A knowledge gap exists about the actual behavior of PV grid-connected systems (PVGCS) using various PV technologies in Peru. This paper presents the results of an over three-year-long performance evaluation of a 3.3-kWp monocrystalline silicon (sc-Si) PVGCS located in Arequipa, a 3.3-kWp sc-Si PVGCS located in Tacna, and a 3-kWp policrystalline (mc-Si) PVGCS located in Lima. An assessment of the performance of a 3.5-kWp amorphous silicon/crystalline silicon hetero-junction (a-Si/µc-Si) PVGCS during over one and a half years of being in Lima is also presented. The annual final yields obtained lie within 1770–1992 kWh/kW, 1505–1540 kWh/kW, and 736–833 kWh/kW for Arequipa, Tacna, and Lima, respectively, while the annual PV array energy yield achieved by a-Si/µc-Si is 1338 kWh/kW. The annual performance ratio stays in the vicinity of 0.83 for sc-Si in Arequipa and Tacna while this parameter ranges from 0.70 to 0.77 for mc-Si in Lima. An outstanding DC annual performance ratio of 0.97 is found for a-Si/µc-Si in the latter site. The use of sc-Si and presumably, mc-Si PV modules in desert climates, such as that of Arequipa and Tacna, is encouraged. However, sc-Si and presumably, mc-Si-technologies experience remarkable temperature and low irradiance losses in Lima. By contrast, a-Si/µc-Si PV modules perform much better in the latter site thanks to being less influenced by both temperature and low light levels.

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Photovoltaic modules evaluation and dry-season energy yield prediction model for NEM in Malaysia

PLoS ONE ◽

10.1371/journal.pone.0241927 ◽

2020 ◽

Vol 15 (11) ◽

pp. e0241927

Author(s):

Syed Zahurul Islam ◽

Mohammad Lutfi Othman ◽

Muhammad Saufi ◽

Rosli Omar ◽

Arash Toudeshki ◽

...

Keyword(s):

Temperature Coefficient ◽

Output Power ◽

Power Efficiency ◽

Crystalline Silicon ◽

Dry Season ◽

Performance Ratio ◽

Coefficient Of Determination ◽

Energy Yield ◽

Net Energy ◽

Pv Modules

This study analyzes the performance of two PV modules, amorphous silicon (a-Si) and crystalline silicon (c-Si) and predicts energy yield, which can be seen as facilitation to achieve the target of 35% reduction of greenhouse gases emission by 2030. Malaysia Energy Commission recommends crystalline PV modules for net energy metering (NEM), but the climate regime is a concern for output power and efficiency. Based on rainfall and irradiance data, this study aims to categorize the climate of peninsular Malaysia into rainy and dry seasons; and then the performance of the two modules are evaluated under the dry season. A new mathematical model is developed to predict energy yield and the results are validated through experimental and systematic error analysis. The parameters are collected using a self-developed ZigBeePRO-based wireless system with the rate of 3 samples/min over a period of five days. The results unveil that efficiency is inversely proportional to the irradiance due to negative temperature coefficient for crystalline modules. For this phenomenon, efficiency of c-Si (9.8%) is found always higher than a-Si (3.5%). However, a-Si shows better shadow tolerance compared to c-Si, observed from a lesser decrease rate in efficiency of the former with the increase in irradiance. Due to better spectrum response and temperature coefficient, a-Si shows greater performance on output power efficiency (OPE), performance ratio (PR), and yield factor. From the regression analysis, it is found that the coefficient of determination (R2) is between 0.7179 and 0.9611. The energy from the proposed model indicates that a-Si yields 15.07% higher kWh than c-Si when luminance for recorded days is 70% medium and 30% high. This study is important to determine the highest percentage of energy yield and to get faster NEM payback period, where as of now, there is no such model to indicate seasonal energy yield in Malaysia.

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Development of Amorphous/Microcrystalline Silicon Tandem Thin-Film Solar Modules with Low Output Voltage, High Energy Yield, Low Light-Induced Degradation, and High Damp-Heat Reliability

Journal of Nanomaterials ◽

10.1155/2014/861741 ◽

2014 ◽

Vol 2014 ◽

pp. 1-10 ◽

Cited By ~ 5

Author(s):

Chin-Yi Tsai ◽

Chin-Yao Tsai

Keyword(s):

Thin Film ◽

Output Voltage ◽

Low Voltage ◽

Crystalline Silicon ◽

High Energy ◽

Photovoltaic System ◽

Performance Ratio ◽

Energy Yield ◽

Microcrystalline Silicon ◽

Low Light

In this work, tandem amorphous/microcrystalline silicon thin-film solar modules with low output voltage, high energy yield, low light-induced degradation, and high damp-heat reliability were successfully designed and developed. Several key technologies of passivation, transparent-conducting-oxide films, and cell and segment laser scribing were researched, developed, and introduced into the production line to enhance the performance of these low-voltage modules. A 900 kWp photovoltaic system with these low-voltage panels was installed and its performance ratio has been simulated and projected to be 92.1%, which is 20% more than the crystalline silicon and CdTe counterparts.

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A Simple Mismatch Mitigating Partial Power Processing Converter for Solar PV Modules

Energies ◽

10.3390/en14082308 ◽

2021 ◽

Vol 14 (8) ◽

pp. 2308

Author(s):

Kamran Ali Khan Niazi ◽

Yongheng Yang ◽

Tamas Kerekes ◽

Dezso Sera

Keyword(s):

Experimental Tests ◽

Energy Yield ◽

Power Electronic ◽

Solar Pv ◽

Partial Shading ◽

Loss Analysis ◽

Pv Systems ◽

Pv Module ◽

Pv Modules ◽

In Series

Partial shading affects the energy harvested from photovoltaic (PV) modules, leading to a mismatch in PV systems and causing energy losses. For this purpose, differential power processing (DPP) converters are the emerging power electronic-based topologies used to address the mismatch issues. Normally, PV modules are connected in series and DPP converters are used to extract the power from these PV modules by only processing the fraction of power called mismatched power. In this work, a switched-capacitor-inductor (SCL)-based DPP converter is presented, which mitigates the non-ideal conditions in solar PV systems. A proposed SCL-based DPP technique utilizes a simple control strategy to extract the maximum power from the partially shaded PV modules by only processing a fraction of the power. Furthermore, an operational principle and loss analysis for the proposed converter is presented. The proposed topology is examined and compared with the traditional bypass diode technique through simulations and experimental tests. The efficiency of the proposed DPP is validated by the experiment and simulation. The results demonstrate the performance in terms of higher energy yield without bypassing the low-producing PV module by using a simple control. The results indicate that achieved efficiency is higher than 98% under severe mismatch (higher than 50%).

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Feasibility Study of the Technical and Economic Performance of Grid-Connected PV System for Selected Rooftops in UTHM

Journal of Electronic Voltage and Application ◽

10.30880/jeva.2021.02.02.005 ◽

2021 ◽

Vol 2 (2) ◽

Author(s):

Mohamad Fakrie Mohamad Ali ◽

◽

Mohd Noor Abdullah ◽

Keyword(s):

Feasibility Study ◽

Crystalline Silicon ◽

Electricity Consumption ◽

Payback Period ◽

Net Energy ◽

Pv System ◽

Pv Module ◽

Electricity Bill ◽

Pv Modules ◽

Energy Metering

This paper presents the feasibility study of the technical and economic performances of grid-connected photovoltaic (PV) system for selected rooftops in Universiti Tun Hussein Onn Malaysia (UTHM). The analysis of the electricity consumption and electricity bill data of UTHM campus show that the monthly electricity usage in UTHM campus is very high and expensive. The main purpose of this project is to reduce the annual electricity consumption and electricity bill of UTHM with Net Energy Metering (NEM) scheme. Therefore, the grid-connected PV system has been proposed at Dewan Sultan Ibrahim (DSI), Tunku Tun Aminah Library (TTAL), Fakulti Kejuruteraan Awam dan Alam Bina (FKAAS) and F2 buildings UTHM by using three types of PV modules which are mono-crystalline silicon (Mono-Si), poly-crystalline silicon (Poly-Si) and Thin-film. These three PV modules were modeled, simulated and calculated using Helioscope software with the capacity of 2,166.40kWp, 2,046.20kWp and 1,845kWp respectively for the total rooftop area of 190,302.9 ft². The economic analysis was conducted on the chosen three installed PV modules using RETScreen software. As a result, the Mono-Si showed the best PV module that can produce 2,332,327.40 kWh of PV energy, 4.4% of CO₂ reduction, 9.3 years of payback period considering 21 years of the contractual period and profit of RM4,932,274.58 for 11.7 years after payback period. Moreover, the proposed installation of 2,166.40kWp (Mono-SI PV module) can reduce the annual electricity bill and CO2 emission of 3.6% (RM421,561.93) and 4.4% (1,851.40 tCO₂) compared to the system without PV system.

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Outdoor Performance Test of Bifacial n-Type Silicon Photovoltaic Modules

Sustainability ◽

10.3390/su11226234 ◽

2019 ◽

Vol 11 (22) ◽

pp. 6234 ◽

Cited By ~ 1

Author(s):

Hyeonwook Park ◽

Sungho Chang ◽

Sanghwan Park ◽

Woo Kyoung Kim

Keyword(s):

Tilt Angle ◽

Performance Test ◽

Power Production ◽

Energy Yield ◽

Concrete Floor ◽

Photovoltaic Modules ◽

Pv Module ◽

Pv Modules ◽

Solar Tracker ◽

One Year

The outdoor performance of n-type bifacial Si photovoltaic (PV) modules and string systems was evaluated for two different albedo (ground reflection) conditions, i.e., 21% and 79%. Both monofacial and bifacial silicon PV modules were prepared using n-type bifacial Si passivated emitter rear totally diffused cells with multi-wire busbar incorporated with a white and transparent back-sheet, respectively. In the first set of tests, the power production of the bifacial PV string system was compared with the monofacial PV string system installed on a grey concrete floor with an albedo of ~21% for approximately one year (June 2016–May 2017). In the second test, the gain of the bifacial PV string system installed on the white membrane floor with an albedo of ~79% was evaluated for approximately ten months (November 2016–August 2017). During the second test, the power production by an equivalent monofacial module installed on a horizontal solar tracker was also monitored. The gain was estimated by comparing the energy yield of the bifacial PV module with that of the monofacial module. For the 1.5 kW PV string systems with a 30° tilt angle to the south and 21% ground albedo, the year-wide average bifacial gain was determined to be 10.5%. An increase of the ground albedo to 79% improved the bifacial gain to 33.3%. During the same period, the horizontal single-axis tracker yielded an energy gain of 15.8%.

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Sustainable End of Life Management of Crystalline Silicon and Thin Film Solar Photovoltaic Waste: The Impact of Transportation

Applied Sciences ◽

10.3390/app10165465 ◽

2020 ◽

Vol 10 (16) ◽

pp. 5465 ◽

Cited By ~ 1

Author(s):

Ilke Celik ◽

Marina Lunardi ◽

Austen Frederickson ◽

Richard Corkish

Keyword(s):

Thin Film ◽

United States ◽

End Of Life ◽

Crystalline Silicon ◽

The United States ◽

Hotspot Analysis ◽

Material Recovery ◽

Pv Module ◽

Pv Modules ◽

The Impact

This work provides economic and environmental analyses of transportation-related impacts of different photovoltaic (PV) module technologies at their end-of-life (EoL) phase. Our results show that crystalline silicon (c-Si) modules are the most economical PV technology (United States Dollars (USD) 2.3 per 1 m2 PV module (or 0.87 ¢/W) for transporting in the United States for 1000 km). Furthermore, we found that the financial costs of truck transportation for PV modules for 2000 km are only slightly more than for 1000 km. CO2-eq emissions associated with transport are a significant share of the EoL impacts, and those for copper indium gallium selenide (CIGS) PV modules are always higher than for c-Si and CdTe PV. Transportation associated CO2-eq emissions contribute 47%, 28%, and 40% of overall EoL impacts of c-Si, CdTe, and CIGS PV wastes, respectively. Overall, gasoline-fueled trucks have 65–95% more environmental impacts compared to alternative transportation options of the diesel and electric trains and ships. Finally, a hotspot analysis on the entire life cycle CO2-eq emissions of different PV technologies showed that the EoL phase-related emissions are more significant for thin-film PV modules compared to crystalline silicon PV technologies and, so, more environmentally friendly material recovery methods should be developed for thin film PV.

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Origin of Bypass Diode Fault in c-Si Photovoltaic Modules: Leakage Current under High Surrounding Temperature

Energies ◽

10.3390/en11092416 ◽

2018 ◽

Vol 11 (9) ◽

pp. 2416 ◽

Cited By ~ 7

Author(s):

Woo Shin ◽

Suk Ko ◽

Hyung Song ◽

Young Ju ◽

Hye Hwang ◽

...

Keyword(s):

High Temperature ◽

Leakage Current ◽

Schottky Diode ◽

Crystalline Silicon ◽

Operating Voltage ◽

Reverse Voltage ◽

Photovoltaic Modules ◽

Pv Module ◽

Bypass Diode ◽

Pv Modules

Bypass diodes have been widely utilized in crystalline silicon (c-Si) photovoltaic (PV) modules to maximize the output of a PV module array under partially shaded conditions. A Schottky diode is used as the bypass diode in c-Si PV modules due to its low operating voltage. In this work, we systematically investigated the origin of bypass diode faults in c-Si PV modules operated outdoors. The temperature of the inner junction box where the bypass diode is installed increases as the ambient temperature increases. Its temperature rises to over 70 °C on sunny days in summer. As the temperature of the junction box increases from 25 to 70 °C, the leakage current increases up to 35 times under a reverse voltage of 15 V. As a result of the high leakage current of the bypass diode at high temperature, melt down of the junction barrier between the metal and semiconductor has been observed in damaged diodes collected from abnormally functioning PV modules. Thus, it is believed that the constant leakage current applied to the junction caused the melting of the junction, thereby resulting in a failure of both the bypass diode and the c-Si PV module.

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The Status and Trends of Crystalline Silicon PV Module Recycling Treatment Methods in Europe and China

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.724-725.200 ◽

2013 ◽

Vol 724-725 ◽

pp. 200-204 ◽

Cited By ~ 2

Author(s):

Jia Zhang ◽

Fang Lv ◽

Li Yun Ma ◽

Li Juan Yang

Keyword(s):

Mechanical Treatment ◽

Crystalline Silicon ◽

Advanced Technology ◽

Thermal Method ◽

Abrasive Machining ◽

Pv Systems ◽

Pv Module ◽

Pv Modules ◽

The Status ◽

Treatment Research

The disposal of PV systems will become a problem in view of the continually increasing production of PV modules. Development for waste PV modules recycling would be extremely effective in coping with this problem. In Europe, the thermal method and chemical method for PV recycling were deeply developed. The thermal treatment was to separate the module components under 600°C. The chemical treatment is to recover silicon wafers out of solar cells, which can be used again in modules. But automated separation of components and advanced chemical process needs to be studied on. In China, mechanical treatment research for PV recycling has just started. PV modules were separated and recycled by abrasive machining under the cryogenic condition and electrostatic separation. The mechanical treatment can't recycle silicon to reprocess new wafers for its low purity. Compared to the advanced technology in Europe, PV recycling in China is primary and badly in need of improving to face the huge PV module recycling demands in future.

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The Application of Novel Platinum-Reinforced Tin-Silver-Copper Solder to Bifacial Photovoltaic Module for Improvement of Yield and Reliability

Journal of Solar Energy Engineering ◽

10.1115/1.4027265 ◽

2014 ◽

Vol 136 (4) ◽

Cited By ~ 1

Author(s):

Chin Kim Lo ◽

Yun Seng Lim ◽

Mee Chu Wong ◽

Yee Kai Tian

Keyword(s):

Solar Cells ◽

Solder Joint ◽

Lead Free ◽

Energy Yield ◽

Substantial Impact ◽

Snagcu Solder ◽

Silver Copper ◽

Pv Module ◽

Pv Modules ◽

Tin Silver Copper

The characteristics of solder joints between the busbars of solar cells and copper ribbons can affect the performance of a photovoltaic (PV) module significantly. The resistivity of the joints and the intermetallic compound structures within the joints are the two main characteristics that impose a substantial impact on the yield and the reliability of the PV module. In this paper, we aim to present and analyze a novel platinum-reinforced tin-silver-copper (Sn-3.8Ag-0.7Cu-0.2Pt) as the lead-free solder material to connect copper ribbons to the metallization of bifacial solar cells. The performance of the PV module using platinum-reinforced solder is investigated by constructing two bifacial PV modules using the popular lead-free Sn-3.8Ag-0.7Cu solder and Sn-3.8Ag-0.7Cu-0.2Pt solder, respectively. Micrographs of the joints are obtained to show that the platinum-reinforced solder joint has fewer voids and a more evenly distributed and thinner intermetallic layer than that of a conventional SnAgCu solder joint. As a result, the physical attachment between the busbars and the ribbon using SnAgCuPt solder is stronger than that using SnAgCu solder. The power outputs of both PV modules are measured together with two commercial PV modules under the sun using an IV plotter. The results show that the total energy yield of the bifacial PV module with the new solder is about 6–10% higher than that with the conventional SnAgCu solder. The energy yield of the bifacial PV module using SnAgCuPt solder is 35.8% and 0.2% higher than that of the commercially available monofacial polycrystalline and monocrystalline PV modules, respectively.

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Fabrication and Characteristics of Recyclable PV Modules

Solar Energy ◽

10.1115/isec2003-44223 ◽

2003 ◽

Cited By ~ 1

Author(s):

Takuya Doi ◽

Izumi Tsuda ◽

Koichi Sakuta ◽

Goichi Matsui

Keyword(s):

Crystalline Silicon ◽

Cell Recovery ◽

Total Cost ◽

Transparent Films ◽

Pv Module ◽

Pv Modules ◽

Pv Cell ◽

Cell Modules ◽

Weather Resistance ◽

Resistance Tests

Since the life of crystalline silicon PV modules is mainly determined by that of the encapsulations and not of the cells, it is possible to reuse the cells, except when the cells are physically damaged. By reusing the cells, we can save the significant amount of energy consumed in the manufacture of PV cells, and reduce the total cost of PV modules as a consequence. PV cells are resources, and they should be recycled. However, it has not been easy to remove cells from modules without damaging them because of the very strong adhesiveness of EVA, the most common encapsulant resin. We propose a new PV module with a double encapsulation module (DEM) structure, in which both surfaces of the PV cells are wrapped with non-adhesive transparent films. Here, the concept of DEM is explained and detailed results from the fabrication of single-cell modules are presented. The results of PV cell recovery experiments and weather resistance tests are also shown.

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