Grid-Connected Photovoltaic Systems with Single-Axis Sun Tracker: Case Study for Central Vietnam

Cuong, Ngo Xuan; Nguyen, Thi Hong Duc; Y, Nhu; Nguyen, Duc Minh; Vo, Dai‐Viet N.; Lam, Su Shiung; Heo, Doyeon; Shokouhimehr, Mohammadreza; Nguyen, Van‐Huy; Varma, Rajender S.; Kim, Soo Young; Le, Quyet Van

doi:10.3390/en13061457

Cited by 22 publications

(11 citation statements)

References 38 publications

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“…For the highest possible utilisation of the energy potential of PV panels, it is suggested to optimise their tilt angle, or additionally to commission a tracking system (Ngo et al 2020;Whang et al 2019); the 18-year average optimal angle of the position of photovoltaic panels for Poland amounts to approx. 36 o , with 32 o for Malta and even 45 o for Finland (see Fig.…”

Section: Solar Irradiation Density In Europementioning

confidence: 99%

Thermal building upgrade with off-grid PV system: a Polish case

Wciślik

Kotrys-Działak

2021

Energy Efficiency

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Nowadays, one of the basic requirements for thermally upgraded buildings involves limitation in CO2 emission even by over 90%. To fulfil these criteria, it is necessary to use alternative energy sources and photovoltaics constitutes a reasonable option for this. This paper addresses an analysis of the efficiency and profitability of a photovoltaic system located in the geometric center of Europe-Poland, where the intensity of solar irradiation is not very high compared to other European countries. The difference of total solar radiation density between Poland and Malta is 49.2%, from analysis based on SolarGIS base. The PV Lighthouse calculator was used for global power density and photon current examination for a Polish city and locations of the highest and the lowest solar radiation values, Malta and Finland, respectively. This case study concerns a thermally upgraded building; a gas boiler was replaced by a heat pump supported by an off-grid PV system. To achieve a reduction in CO2 emission of 90%, it is necessary to install 182 PV cells, which generates high investment costs. An investment is entirely profitable with 70% of funding with Simple Pay Back Time, SPBT~7 years although Net Present Value, NPV>0; Internal Rate of Return, IRR=10.6%.

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Section: Solar Irradiation Density In Europementioning

confidence: 99%

Thermal building upgrade with off-grid PV system: a Polish case

Wciślik

Kotrys-Działak

2021

Energy Efficiency

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“…In Ref. [43], using the single-axis PV tracking system, it was determined that the total energy production increased up to 30.3% for a sunny day and 15.2% in average weather conditions. In Ref.…”

Section: Literature Overviewmentioning

confidence: 99%

“…In a study where the system was installed at a latitude angle of 36.25°N, it was determined that a dualaxis solar tracking system was able to generate approximately 30% more energy than a fixed-angle system, but the area covered was approximately 100% more than a single-axis tracker and approximately 160% more than a fixed-angle system [42]. The results of another experimental study show that the total energy consumption of the single-axis tracking system is approximately 2-8% of the energy produced by the grid-connected PV system and approximately 5-12% in the dual-axis solar tracking system [43]. In this respect, when compared to building-mounted solar energy generation systems ground projects, it can be stated that project logistics, installation cost, operating cost, overall efficiency, and service life are the factors that should be paid more attention to.…”

Section: Introductionmentioning

confidence: 97%

Technoeconomic Performance Analysis of Solar Tracking Methods for Roof-Type Solar Power Plants and Electric Vehicle Charging Stations

Boyekin

Kıyak

2021

International Journal of Photoenergy

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In building integrated photovoltaic (BIPV) solar energy projects, cost effectiveness, durability, and long-term reliability are among the criteria that should be taken into consideration as well as the gain in electricity generation efficiency. Also, in a study, it is stated that a dual-axis solar tracking system occupies approximately 100% more space than a single-axis system and 160% more than a fixed-angle system. It has been observed that most of the studies that are mounted on the building and include a tracking system are small-scale experimental studies. The aim of this article is to present a systematic analysis with a low investment cost, a low operating cost, and high reliability, in a real application especially for roof applications in buildings. Three buildings in the same location and with the same roof area were selected. Photovoltaic power plants with 23.68 kW power were installed; these panels had three types: fixed-angle, manually controlled, and single-axis solar tracking systems. The energy generation system is connected to the network with a double-sided meter, and there is a double-sided energy flow. The energy produced is used to meet the energy needs of the vehicle charging station and common areas of the buildings. Although the single-axis tracking system is 27.85% more efficient than other energy generation methods, the manually adjusted method has proven to have the shortest amortization time. The study also presents shading, which is a serious problem in large-scale roof projects, and the area covered by the module per unit watt produced.

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“…Graph 5 in turn presents average ITH values recorded by the Photovoltaic Geographical Information System (PVGIS) for European Communities in the years 2001 -2019, which indicate that Poland is rated twentieth in terms of the conditions of insolation, and the ITH in here is lower by 16% and 43% than European average and the maximum average for Malta, respectively, and higher by 17% than the minimum average recorded for Finland. For the highest possible utilisation of the energy potential of PV panels, it is suggested to optimise their tilt angle, or additionally to commission a tracking installation [30,31]; the 18-year average optimal angle of the position of photovoltaic panels for Poland amounts to approx. 36 o , with 32 o for Malta and even 45 o for Finland (see Figure 6).…”

Section: Solar Irradiation Density In Europementioning

confidence: 99%

The Energy, Economic and Environmental Efficiency of a PV Installation Cooperating with a Heat Pumpin the Central Part of Europe. Case study

Wciślik¹,

Kotrys-Działak²

2020

Preprint

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The paper addresses an analysis of the efficiency and profitability of the operation of a photovoltaic installation located in the geometric centre of Europe (near Białystok, Poland), where the intensity of solar irradiation is not too high compared to other European countries. It is calculated that in that place average solar irradiation being lower even by approx. 26 kWh than that for the whole Europe, which results in a 26% drop in the economic potential of the utilisation of solar energy for its conversion. A case study and an economic analysis show that without minimum funding amounting to 50% of the investment costs paid for the modernisation of a central heating system assisted by PV cells, the time of return of pecuniary expenditures exceeds 7 years. Apart from the Simple Pay-Back Time SPBT, discount indicators determined in the paper also include the net present value NPV and the internal rate of return IRR. Moreover, a direct ecological effect has been determined for such an investment.

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Grid-Connected Photovoltaic Systems with Single-Axis Sun Tracker: Case Study for Central Vietnam

Cited by 22 publications

References 38 publications

Thermal building upgrade with off-grid PV system: a Polish case

Thermal building upgrade with off-grid PV system: a Polish case

Technoeconomic Performance Analysis of Solar Tracking Methods for Roof-Type Solar Power Plants and Electric Vehicle Charging Stations

The Energy, Economic and Environmental Efficiency of a PV Installation Cooperating with a Heat Pumpin the Central Part of Europe. Case study

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