Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study

Zsiborács, Henrik; Hegedűsné Baranyai, Nóra; Vincze, András; Háber, István; Weihs, Philipp; Oswald, Sandro; Gützer, Christian; Pintér, Gábor

doi:10.3390/app9163392

Open AccessArticle

Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study

by

Henrik Zsiborács

¹,

Nóra Hegedűsné Baranyai

^1,*,

András Vincze

²,

István Háber

³,

Philipp Weihs

⁴,

Sandro Oswald

⁴

,

Christian Gützer

⁴ and

Gábor Pintér

¹

Department of Economic Methodology, University of Pannonia, Georgikon Faculty, 8360 Keszthely, Hungary

²

Department of Foreign Languages, Georgikon Faculty, University of Pannonia, 8360 Keszthely, Hungary

³

Department of Mechanical Engineering, University of Pécs, Faculty of Engineering and Information Technology, 7624 Pécs, Hungary

⁴

Department of Water, Atmosphere and Environment, Institute of Meteorology, University of Natural Resources and Life Sciences Vienna, 1180 Vienna, Austria

^*

Author to whom correspondence should be addressed.

Appl. Sci. 2019, 9(16), 3392; https://doi.org/10.3390/app9163392

Submission received: 15 July 2019 / Revised: 4 August 2019 / Accepted: 14 August 2019 / Published: 17 August 2019

(This article belongs to the Special Issue Renewable Energy Systems 2019)

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Abstract

:

This article examines the positioning features of polycrystalline, monocrystalline, and amorphous silicon modules relative to the focus points of concentrator photovoltaic modules under real meteorological conditions using a dual tracking system. The performance of the photovoltaic modules mounted on a dual-axis tracking system was regarded as a function of module orientation where the modules were moved step by step up to a point where their inclination differed by 30° compared to the ideal focus point position of the reference concentrator photovoltaic module. The inclination difference relative to the ideal focus point position was determined by the perfect perpendicularity to the rays of the sun. Technology-specific results show the accuracy of a sun tracking photovoltaic system that is required to keep the loss in power yield below a defined level. The loss in power yield, determined as a function of the measurement results, also showed that the performance insensitivity thresholds of the monocrystalline, polycrystalline, and amorphous silicon modules depended on the direction of the alignment changes. The performance deviations showed clear azimuth dependence. Changing the tilt of the modules towards north and south showed little changes in results, but inclination changes towards northwest, southwest, southeast, and northeast produced results diverging more markedly from each other. These results may make the planning of solar tracking sensor investments easier and help with the estimate calculations of the total investment and operational costs and their return concerning monocrystalline, polycrystalline, and amorphous silicon photovoltaic systems. The results also provide guidance for the tracking error values of the solar tracking sensor.

Keywords:

solar energy; solar module; sun-tracking; sun-tracking sensor; azimuth angle; tilt angle

1. Introduction

1.1. Changes in the Spread of Photovoltaic Technologies in the World

Nowadays, more and more countries understand the harmful consequences of climate change worldwide. Their common goal should be to keep the global temperature rise below 2 °C compared to the pre-industrial level and aiming for a maximum increase of only 1.5 °C [1]. In the transformation needed to achieve these targets and to reduce the greenhouse effect, the use of renewable energy plays a key role. Advances in renewable energy technologies have provided several sustainable alternatives, and more and more attention is also paid to solar energy. Many cities around the world have started to develop their solar energy programs in their urban planning to promote sustainable development and environmental protection. Energy from the Sun, which is available for all mankind, is the basis of most natural processes and it is a sustainable, plentiful, and clean resource [2,3,4,5,6,7,8,9,10,11]. The annual solar energy potential arriving on the Earth’s surface is approximately 8000 times greater than the current energy demand of the world. Photovoltaic (PV) technologies use PV cells and modules which transform the incoming solar energy into DC energy [12,13,14].

In the PV sector a significant market increase has been observed in the last 10 years mainly due to the state subsidies introduced in many countries, the falling investment costs and the accelerated technological development [6,15,16]. In 2018 the share of renewable electricity production was 26.2% of all the electricity produced worldwide, of which PV technology represented 2.4%. In 2018 the global built-in photovoltaic capacity was 505 GW, with the largest proportions being China’s 177.5 GW, the European Union’s 115 GW, the USA’s 62.4 GW and Japan’s 56 GW (Figure 1) [6,17,18].

The amount of electric energy produced by PV systems depends primarily on the solar radiation, the temperature, the technology, the current natural factors, the composition of the particular module and the combined effects of the installation and the efficiency rates. PV systems are primarily mounted on fixed mounting systems for economic reasons. However, an advanced mounting technique is to use a solar tracking system to increase the energy production [19,20,21,22].

1.2. Energy Production and Accuracy Features of Dual Tracking PV Systems

With the help of a solar tracking system, the orbit of the Sun can be monitored with sensors. An ideal solar tracker allows PV panels or complete systems to precisely follow the sun within an accuracy of less than 0.1 degree. This makes it possible to maximize the current energy production since sun tracking systems keep the PV modules perpendicular to the incoming solar radiation. [19,22,23]. In order to obtain maximum efficiency, three main factors are crucial:

an optimal configuration of the tracking axes [24,25],
an optimal configuration of the control systems [26],
the optimization of the moving fixtures [27].

Currently, there are two different classes of solar tracking systems, whose characteristics have been examined by many manuscripts (Figure 2):

solar tracking systems with one axis (rotating around one axis) [28,29,30,31,32],
solar tracking systems with two axes (rotating around two axes) [22,33,34,35].

The efficiency of a solar tracking solution will be higher than that of a fixed PV system. Single- and dual-axis solar tracking PV systems can easily increase their energy produced by 12–42%, depending on the installation site and mounting type [22,25,37,38,39]. Focusing on Europe, Vokas et al. (2015) collected many (>100 pieces) real, detailed energy production measurement data from single- and dual-axis PV plants all over Greece. They investigated the real (measured) data comparison between dual-axis and fix-mounted PV systems in 8 towns in Greece (Kilkis, Ilia, Serres, Trikala, Evros, Karditsa, Magnisisa, and Rodope). It can be stated that the percentage of the average difference between the average performances of dual-axis and fix-mounted PV systems was 34.8%. Results delivered by other similar researches in other geographic locations (Canada, Turkey, Spain) were close to the average of the figures obtained in Greece (Table 1) [19].

Several sources suggest that dual-axis tracking solutions are more efficient and can also be cost-effective if bigger systems are implemented. Nevertheless, the implementation of solar tracking devices is only justified if the amount of electrical energy produced compensates for the costs of the equipment, the maintenance and the energy consumed by the moving parts [23,38,40,41,42].

Regarding solar tracking technologies, the implementation of good tracking and control algorithms is also crucial. These systems are generally classified into open- and closed loop systems depending on the type of control strategy involved and the mode of signal operation. [23,43,44]. An important aspect is the performance and the error of solar tracking systems. Lee et al. (2009) present the performance and error relationship of many precise solar tracking systems and algorithms. It is apparent from the research that there is typically a 0.0003°–1° tracking error tolerance, but nowadays the investment costs of such systems are high [45]. Nevertheless, there are solar tracking systems and sensors which are easily and cheaply available to the public but their tracking error tolerance is at least 1.5° [46]. According to Nsengiyumva et al. (2018) solar tracking system devices are exceptionally attractive and always yield more than 98.5% of their full tracking efficiency even when the aim is off by 10°. Notwithstanding, it is necessary to minimize small tracking errors to ensure the maximum energy gain on a long term basis [23,47]. An alternative option to control a two-axis PV tracking system without sensors is based on a mathematical sun tracking model for the specified geolocation (Zenith angle calculation). This model was presented in the study by Haber et al., 2013, which could give the perfect position but did not consider the diffuse radiation [48].

Due to various technical and economic aspects it is necessary to examine the technology-specific performance losses in the case of inaccurate sun tracking compared to the ideal position. This article tries to find an answer to the question when it is necessary to reposition a sun tracking PV system.

Furthermore, current scientific literature does not give an answer regarding the performance insensitivity thresholds of the most widely used PV technologies (m-Si or p-Si) [51] in the case of inaccurate sun tracking or sensor failures. Another important issue is whether the yield loss resulting from the solar tracking uncertainty shows an azimuthal dependence. These uncertain issues motivated this scientific work.

2. Material and Methods

2.1. Study Location

The experiment was conducted at the measuring station of the University of Pannonia Georgikon Faculty, Department of Economic Methodology, in Hungary in Keszthely (longitude: 17.26609°, latitude: 46.76750°, altitude 108 m) in the summers of 2017, 2018 and 2019 on fourteen different days.

2.2. System Description

In the present experiment, a dual-axis tracking system equipped with modules using concentrator photovoltaic (CPV), amorphous silicon (a-Si), polycrystalline (p-Si) and monocrystalline (m-Si) PV technologies was examined under real meteorological conditions at the same measuring point. The CPV module on the monitoring system assisted only with the accurate sun adjustment in this research (Table 2, Figure 3 and Figure 4).

A professional multimeter (Voltcraft VC607) (Conrad Electronic SE, Wernberg-Köblitz, Germany), verified on a LT1021 (Linear Technology Corporation, Milpitas, USA) precision reference, was used for the calibration of the current and the voltage. During the measurements oscillation true maximum point seeking (TMPS) devices were used to optimize the current (A) and the voltage (V) of the PV modules. With these devices it was possible to manually check the maximum power point of the PV modules, thus allowing a correct measurement precision (Figure 5). Moreover, it was also possible to measure the V and A values directly without any loss in the TMPS devices.

Within the scope of the present study for the collection of environmental and technical data a GB HOBO (Onset Computer Corporation, Bourne, USA) four-channel analogue data logger, a CR1000 measurement (Campbell Scientific, Inc., Logan, USA) and control datalogger, a PicoLog 1012 (Pico Technology, St Neots, United Kingdom) data acquisition system and a PicoLog 1216 (Pico Technology, St Neots, United Kingdom) acquisition system were used (Figure 5 and Figure 6). The radiation intensity was measured by using an Eppley Black and White Model 4–48 Pyranometer (The Eppley Laboratory, Inc., Newport, USA), Hukseflux LP02 pyranometers (Hukseflux Thermal Sensors B.V., Delft, The Netherlands) and the global horizontal irradiation was taken by an EMS 11 Silicon PV detector (Energy XPRT, Brno, Czech Republic) (Figure 5 and Figure 6).

The angle information of the photovoltaic modules and pyranometers was measured using a digital angle gauge, while the humidity of the air was measured by a HYTE-ANA-1735 (B+B Thermo-Technik GmbH, Donaueschingen, Germany) meter and by an OTT TRH relative humidity sensor (OTT Hydromet GmbH, Kempten, Germany) (Figure 5).

Pt 100 sensors (Conrad Electronic SE, Wernberg-Köblitz, Germany) were used to detect the PV module and air temperatures with the help of the PicoLog devices. A digital LM 35-based precision thermometer (B+B Thermo-Technik GmbH, Donaueschingen, Germany) was used to calibrate the entire measuring circuit. In this research, the temperature values were for informational purposes only, because the temperature values of the PV modules remained stable throughout the experiments (see chapter “2.3. Data Processing and Analysis”). In 2017, 2018 and 2019 measuring stations ‘A’ and ‘B’ were used at the same places and times (Figure 5 and Figure 6).

For positioning the photovoltaic modules two linear actuators were used. By a handheld remote control, it was possible to carry out a set of attempts, which were suitable for both horizontal and/or vertical control. The accurate adjustment to the sun was checked by the visible focus point (FP) of the CPV solar module (Figure 7) because at this position the rays of the sun are ideally positioned, perpendicularly to the photovoltaic modules. The measurements at the FP position were used as a reference in order to obtain the power loss as a function of the solar tracking uncertainty angle. Thus, it was possible to measure the technology-specific performance losses in the case of inaccurate sun tracking compared to the ideal position. With inadequate dual tracking devices, it is difficult to provide appropriate measurement conditions, which may lead to erroneous evaluation of the data.

2.3. Data Processing and Analysis

The data collection for the research was carried out in the summers of 2017, 2018 and 2019 on fourteen different days between 11:00 am and 1:30 pm. In each case, measurements were taken continuously (every second, station ‘A’) and at an interval of an average of 10 s (station ‘B’). The measurements of the PV performance and irradiance were made altering the inclination of the PV module towards the north, north-west, west, south-west, south, south-east, east and north-east as follows:

Module performance and irradiance measurements between the FP and a solar tracking uncertainty of 5° at 0.5-degree intervals in all directions to find the performance insensitivity threshold of the m-Si, p-Si and a-Si technologies. It was possible to measure the performance values directly without any loss in the TMPS devices.
Module performance and irradiance measurements between the FP and a solar tracking uncertainty of 30° by moving in 10-degree steps in all directions to see the technology-specific performance properties of m-Si, p-Si and a-Si technologies. It was possible to measure the performance values directly without any loss in the TMPS devices.

For all angles the starting position of the PV modules was the FP of the CPV solar cells, after which the aforementioned orientations, radiation and performance data were measured. The performance output for each position was measured over 10 s, and switching to the next measurement lasted for 2–20 s. Due to the switching of the measuring instruments, it was necessary to wait about 6 s. During the measurements this method made it possible to eliminate the effect of the changing environmental conditions (for example, temperature changes of PV modules), since the starting point for each measurement was the FP.

Appropriate measurements of yield loss for a solar tracking position from the FP to a solar tracking uncertainty of 5° were achieved during 2018 and 2019. In the summers of both years, measurements were performed 20 times for each direction. These data were averaged and checked using relative standard deviation (CV%). A relative standard deviation between 0 and 10% shows homogeneous conditions, between 10.1 and 20% it shows a medium variability, between 20.1 and 30% it shows strong variability, while above 30.1% it is related to strongly heterogeneous conditions [52]. For all measurements, the relative standard deviation of the averaged data was below 1%, which was an excellent result. To manage, evaluate and analyse the data Microsoft Excel (version: 2016, Redmond, DC, USA), PicoScope (version: R5.23.0, St Neots, UK), Matlab (version: R2017a, Natick, MA, USA) and SPSS Statistics (version: 24, Armonk, NY, USA) software were used. It is difficult to detect systematic mistakes but these phenomena do not increase the deviation of the measurements. The given measuring accuracy and calibration (which should be independent of the measuring system) of the measuring devices can help solve this problem.

3. Results

3.1. The Performance Insensitivity Threshold of Selected PV Technologies, as a Function of Direction

The measurement results showed the performance insensitivity thresholds of the m-Si, p-Si and a-Si modules depending on alignment changes. In the case of same-direction changes around the FP the performance deviations were not the same. Figure 8, Figure 9 and Figure 10 provide information for the easier interpretation of the solar tracking sensors’ inaccuracy. Figure 8, Figure 9 and Figure 10 show no variation as a function of the gap relative to the focus point (FP) for any of the modules if the angle of deviation is below 3°. Indeed, in every direction and for every technology, there is still 100% of performance (pink color) below 3° of “offset” compared to the FP and less than 2% of loss below 5°. The most indifferent orientation was north-south up to 5°. The east and west measurements showed a 1% power reduction in the case of 4.5°–5° compared to the FP. The north-west orientation was the most sensitive setting with a 2% performance change in the case of a change in alignment of between 4.5°and 5°. The average values were the same for all three technologies up to 5° (Figure 8, Figure 9 and Figure 10). Up to a deviation of 10° the m-Si, p-Si and a-Si module data showed a 1–4% change in power. That was the limit where the performance features of the measured technologies were almost the same. Only the p-Si technology differs by 1% in the case of the south-west orientation. In the case of a 20° change it becomes more visible which orientation causes greater deviation. The least sensitive orientation is south-north, where the crystalline technologies showed 4%, while the a-Si one showed 5% power reduction compared to the FP. In the case of the east-west orientation the values were reduced by 5–8% (Figure 8, Figure 9 and Figure 10). The measurements performed for inclination changes towards north-west, south-west, south-east, and north-east showed about an 8–12% performance loss for the crystalline modules, while the a-Si module seemed more sensitive with 11–16%. It can be seen that when the solar tracking uncertainty was increased to 20°, the orientation sensitivity of the technologies used became measurable. These features were also observable for a 30° uncertainty, but the performance change showed a greater difference. In this case, the biggest difference was again seen for the north-west, south-west, south-east, and north-east directions (Figure 8, Figure 9 and Figure 10). In the cases of solar tracking deviations of 20° and 30°, it is not only the technology-specific differences that can be seen, but also the fact that the western deviation is 1–5% more sensitive compared to the eastern direction (Figure 8, Figure 9 and Figure 10). The explanation is not only that the direct and diffuse radiation from the sun changes with the orientation of the module, but there is also an influence by reflected radiation from the surroundings.

Our aim was to publish our experimental and theoretical results in as much detail as possible. This method ensures the reproducibility of experimental results for other researchers. These results may make the planning of solar tracking sensor investments easier and help with the estimate calculations of total investment and operational costs and their return concerning monocrystalline, polycrystalline and amorphous silicon photovoltaic systems. The results also provide guidance for the tracking error values of solar tracking sensors.

3.2. Polynomial Regression Models of Dual-Axis Solar Tracking m-Si, p-Si and a-Si Systems between 0–30° of Deviation Compared to the FP

Polynomial regression models (Table 3, Table 4, Table 5, Table 6, Table 7 and Table 8) have been created from the results of Figure 8, Figure 9 and Figure 10 by Matlab software. This method ensures the reproducibility of experimental results for other researchers. Other regression methods have been also tested (logarithmic, quadratic, exponential, multivariable) for the data analysis, nevertheless, the most accurate fit came from the polynomial regression model at the highest R-squared value.

With the help of these models, a context has been created for the effects of solar radiation changes caused by inaccurate dual-axis solar tracking systems on m-Si, p-Si and a-Si performance. Using a pyranometer and applying the contexts for deviations between the FP and 30° in all directions anyone can estimate the performance changes for these technologies. The R-square values in the case of the effect of solar radiation changes on m-Si performance showed an almost perfect fit (Table 3, Table 4 and Table 5).

Using the polynomial regression models, we developed equations which describe the performance of m-Si, p-Si or a-Si modules as a function of solar tracking uncertainties up to 30°. Using the values of directional changes and the equations anyone can estimate the performance changes for these technologies for dual-axis solar tracking systems. The R-square values obtained for the m-Si performance represented an almost perfect fit (Table 6, Table 7 and Table 8).

4. Conclusions

In our research, we studied the positioning features of polycrystalline (p-Si), monocrystalline (m-Si), and amorphous silicon (a-Si) modules relative to the FP of a reference CPV module under real meteorological conditions using a dual tracking system. The measurement results indicated that the performance insensitivity thresholds of m-Si, p-Si, and a-Si modules depend on the direction of the changes. According to the relevant literature, solar tracking system devices are very popular and always perform at more than 98.5% of their full tracking efficiency even when the aim of the device is off by 10°. Nevertheless, the deviations in performance showed a significant dependence on the azimuthal direction. The most indifferent orientation was the north-south, while the most sensitive settings were the north-west, south-west, south-east, and north-east orientations. According to the results, there is no variation as a function of the deviation relative to the focus point for any of the module technologies examined if the angle of variance is below 3°. This also provides guidance for the tracking error values of solar tracking sensors. Although nowadays there are many easily and cheaply available solar tracking systems and sensors, their tracking error tolerance is at least 1.5°. The 3° threshold of insensitivity indicates that it is not economically sensible to make solar tracking sensors more sensitive than that. This information may contribute to the achievement of economically optimal investments. With the help of the new evidence delivered by the study, it may become easier to plan solar tracking sensor equipment and to assess the total investment and operational costs and their return in the case of m-Si, p-Si, and a-Si PV systems.

In the future, CPV modules will be examined. According to preliminary measurements, this technology is much more sensitive to changes in orientation, and from the point of view of future investments, it would be important to determine its insensitivity.

Author Contributions

H.Z. was mainly responsible for the technical, experimental and modelling aspects, and conceived and designed the manuscript. All authors contributed equally in the analysis of the data and the writing and revision of the manuscript.

Acknowledgments

The publication is supported by the EFOP-3.6.3-VEKOP-16-2017-00008 project. The project is co-financed by the European Union and the European Social Fund. This research was supported by the Austrian Hungarian Action Foundation [AÖU Project 99ÖU3]. The work was carried out in the University of Pécs, János Szentágothai Research Centre, Energy Design research Group.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Estimated global solar photovoltaic capacity, by country and region in 2018, based on [18].

Figure 2. Types of sun tracker solutions based on [36].

Figure 3. The measuring station in Keszthely (1, HYTE-ANA-1735 humidity module [measuring air humidity]; 2, Pt 100 sensor; 3, manual/automatic tracking control unit; 4, m-Si module; 5, CPV module; 6, photosensors; 7, Eppley Black and White pyranometer; 8, a-Si module; 9, p-Si module; 10, Hukseflux LP02 pyranometers; 11, EMS 11 Silicon PV detector; 12, DS-2 Sonic anemometer; 13, OTT TRH relative humidity sensor; Orange dot: Pt 100 sensors).

Figure 4. Fisheye view of the measuring station surroundings in the summer afternoon.

Figure 5. Schematic illustration of PV module measuring station ‘A’.

Figure 6. Schematic illustration of PV module measuring station ‘B’.

Figure 7. The accuracy of the alignment to the sun can be illustrated with the help of the CPV cells (upper image: incorrect setting; lower image: precise setting).

Figure 8. The performance insensitivity thresholds, the performance changes, the solar radiation features and the performance characteristics of m-Si technology depending on directional changes compared to the focus point (FP).

Figure 9. The performance insensitivity thresholds, the performance changes, the solar radiation features and the performance characteristics of p-Si technology depending on directional changes compared to the FP.

Figure 10. The performance insensitivity thresholds, the performance changes, the solar radiation features and the performance characteristics of a-Si technology depending on directional changes compared to the FP.

Table 1. The gain in yearly real energy production compared to optimally positioned south-facing crystalline photovoltaic (PV) systems.

Country (City/Town)	Gain in Yearly Real Energy Production Achieved by Using a Double-Axis Tracker System (%)	Reference
Turkey (Muğla)	30.8	[22]
Canada (Vermilion)	31	[49]
Spain (Palencia)	30.5	[50]
Greece (average)	34.5	[19]
Greece (Ilia)	21
Greece (Serres)	27.4
Greece (Karditsa)	37.3
Greece (Evros)	42.2
Greece (Kilkis)	34.5
Greece (Trikala)	34.6
Greece (Magnisia)	39.1
Greece (Rodopi)	42.2

Table 2. Technical information of the PV modules. (standard test conditions: air mass 1.5; cell temperature 25 °C; irradiance = 1000 W/m²/m-Si, p-Si, a-Si modules; irradiance = 850 W/m²/concentrator photovoltaic (CPV) module).

Module Type	CPV	a-Si	m-Si	p-Si
Model	CX-75-III	G-EA050	SM636-50	SL50TU-18P
Nominal power (Pmax) (W)	75	50	50	50
Performance tolerance (%)	±5%	±10%	±3%	±3%
MPP voltage (Vmp) (V)	135	67	18.18	19.12
MPP current (Imp) (A)	0.55	0.75	2.8	2.62
Open circuit voltage (Voc) (V)	150	91.8	23.17	22.68
Short circuit current (Isc) (A)	0.64	1.19	3.08	2.80
Efficiency (%)	27.2	5.3	14.4	13.7
Temperature Coefficient (%/°C)	0.15	0.27	0.5	0.5

Table 3. The effect of solar radiation changes on m-Si performance. (x = change in solar radiation (%), FP = 100%, 80% = 20% change in solar radiation; f(x) = percentage value of the performance compared to the FP).

Description	Equation	Numerical Results for Modeling	R-Square
South	f(x) = p1 × x² + p2 × x + p3	p1 = −0.01395	0.9889
		p2 = 3.748
		p3 = −135.5
North		p1 = 0.04104	0.9996
		p2 = −6.601
		p3 = 349.7
East		p1 = −0.01577	0.9947
		p2 = 3.978
		p3 = −140.1
West		p1 = 0.05651	0.9939
		p2 = −9.401
		p3 = 475.1
South-east		p1 = 0.006652	0.9953
		p2 = −0.2319
		p3 = 56.61
South-west		p1 = 0.01358	0.9943
		p2 = −1.421
		p3 = 105.9
North-east		p1 = −0.01195	0.9987
		p2 = 3.244
		p3 = −105
North-west		p1 = −0.009231	0.9880
		p2 = 2.776
		p3 = −85.95
Example of calculation result, south-east, 80% change in solar radiation [%]	81% = p1 × 80² + p2 × 80 + p3

Table 4. The effect of solar radiation changes on p-Si performance (x = change in solar radiation (%), FP = 100%, 80% = 20% change in solar radiation; f(x) = percentage value of the performance compared to the FP).

Description	Equation	Numerical Results for Modeling	R-Square
South	f(x) = p1 × x² + p2 × x + p3	p1 = −0.01918	0.9910
		p2 = 4.745
		p3 = −182.8
North		p1 = 0.06783	0.9963
		p2 = −11.8
		p3 = 601.7
East		p1 = −0.02172	0.9926
		p2 = 5.032
		p3 = −185.9
West		p1 = 0.05355	0.9827
		p2 = −8.834
		p3 = 447.7
South-east		p1 = −0.009841	0.9985
		p2 = 2.717
		p3 = −73.46
South-west		p1 = 0.01107	0.9910
		p2 = −0.9367
		p3 = 82.5
North-east		p1 = −0.01228	0.9957
		p2 = 3.236
		p3 = −101.1
North-west		p1 = 0.002913	0.9898
		p2 = 0.6102
		p3 = 9.131
Example of calculation result, south-east, 20% change in solar radiation [%]	81% = p1 × 80² + p2 × 80 + p3

Table 5. The effect of solar radiation changes on a-Si performance (x = change in solar radiation (%), FP = 100%, 80% = 20% change in solar radiation; f(x) = percentage value of the performance compared to the FP).

Description	Equation	Numerical Results for Modeling	R-Square
South	f(x) = p1 × x² + p2 × x + p3	p1 = −0.01557	0.9933
		p2 = 4.28
		p3 = −172.4
North		p1 = 0.0601	1
		p2 = −10
		p3 = 499.2
East		p1 = −0.01756	0.9948
		p2 = 4.468
		p3 = −171.3
West		p1 = 0.06519	0.9929
		p2 = −10.82
		p3 = 530.1
South-east		p1 = 0.01088	0.9942
		p2 = −0.7589
		p3 = 67.21
South-west		p1 = 0.01088	0.9956
		p2 = −0.6964
		p3 = 60.43
North-east		p1 = −0.01392	0.9990
		p2 = 3.776
		p3 = −138.5
North-west		p1 = 0.004485	0.9957
		p2 = 0.5934
		p3 = −4.726
Example of calculation result, south-east, 20% change in solar radiation [%]	76% = p1 × 80² + p2 × 80 + p3	-

Table 6. The effect of directional changes on m-Si performance (x = change in orientation (°); f(x) = percentage value of the performance compared to the FP).

Description	Equation	Numerical Results for Modeling	R-Square
South	f(x) = p1 × x⁴ + p2 × x³ + p3 × x² + p4 × x + p5	p1 = −1.683 × 10⁻⁵	0.9998
		p2 = 0.0009611
		p3 = −0.02697
		p4 = 0.09686
		p5 = 99.95
North		p1 = −1.877 × 10⁻⁵
		p2 = 0.0009883
		p3 = −0.02603
		p4 = 0.09122
		p5 = 99.95
East		p1 = −4.017 × 10⁻⁵	0.9979
		p2 = 0.001883
		p3 = −0.03404
		p4 = −0.01403
		p5 = 100.1
West		p1 = −2.936 × 10⁻⁵	0.9987
		p2 = 0.001704
		p3 = −0.04316
		p4 = 0.08324
		p5 = 100
South-east		p1 = 2.095 × 10⁻⁵	0.9994
		p2 = −0.0007642
		p3 = −0.01447
		p4 = −0.06451
		p5 = 100.1
South-west		p1 = −3.515 × 10⁻⁶	0.9996
		p2 = 0.0004726
		p3 = −0.03775
		p4 = 0.01547
		p5 = 100.1
North-east		p1 = −8.536 × 10⁻⁶	0.9997
		p2 = 0.0006003
		p3 = −0.03319
		p4 = 0.03196
		p5 = 100
North-west		p1 = −6.333 × 10⁻⁵	0.9987
		p2 = 0.002912
		p3 = −0.05449
		p4 = −0.1513
		p5 = 100.3
Example of calculation result, south-east, 20% direction change [%]	90% = p1 × 20⁴ + p2 × 20³ + p3 × 20² + p4 × 20 + p5

Table 7. The effect of directional changes on p-Si performance (x = change in orientation (°); f(x) = percentage value of the performance compared to the FP).

Description	Equation	Numerical Results for Modeling	R-Square
South	f(x) = p1 × x⁴ + p2 × x³ + p3 × x² + p4 × x + p5	p1 = −1.17 × 10⁻⁵	0.9999
		p2 = 0.0006521
		p3 = −0.02167
		p4 = 0.07924
		p5 = 99.96
North	f(x) = p1 × x³ + p2 × x² + p3 × x + p4	p1 = −2.369 × 10⁻⁵	0.9956
		p2 = −0.008792
		p3 = −0.02042
		p4 = 100.1
East	f(x) = p1 × x⁴ + p2 × x³ + p3 × x² + p4 × x + p5	p1 = −1.88 × 10⁻⁵	0.9981
		p2 = 0.0007663
		p3 = −0.01851
		p4 = −0.0239
		p5 = 100.1
West	f(x) = p1 × x³ + p2 × x² + p3 × x + p4	p1 = −6.694 × 10⁻⁵	0.9935
		p2 = −0.01025
		p3 = −0.1163
		p4 = 100.1
South-east	f(x) = p1 × x⁴ + p2 × x³ + p3 × x² + p4 × x + p5	p1 = −3.306 × 10⁻⁵	0.9996
		p2 = 0.001555
		p3 = −0.03691
		p4 = −0.002006
		p5 = 100.1
South-west		p1 = −2.717 × 10⁻⁵	0.9985
		p2 = 0.001542
		p3 = −0.04935
		p4 = 0.001848
		p5 = 100.1
North-east		p1 = −2.624 × 10⁻⁵	0.9993
		p2 = 0.001321
		p3 = −0.0354
		p4 = −0.03995
		p5 = 100.1
North-west	f(x) = p1 × x³ + p2 × x² + p3 × x + p4	p1 = −2.968 × 10⁻⁵	0.9961
		p2 = −0.01921
		p3 = −0.2668
		p4 = 100.2
Example of calculation result, south-east, 20% direction change [%]	92% = p1 × 20⁴ + p2 × 20³ + p3 × 20² + p4 × 20 + p5

Table 8. The effect of directional changes on a-Si performance (x = change in orientation (°); f(x) = percentage value of the performance compared to the FP).

Description	Equation	Numerical Results for Modeling	R-Square
South	f(x) = p1 × x⁴ + p2 × x³ + p3 × x² + p4 × x + p5	p1 = 2.646 × 10⁻⁷	0.9999
		p2 = 5.382 × 10⁻⁵
		p3 = −0.01624
		p4 = 0.06834
		p5 = 99.96
North	f(x) = p1 × x³ + p2 × x² + p3 × x + p4	p1 = 3.102 × 10⁻⁵	0.9998
		p2 = −0.01546
		p3 = 0.06449
		p4 = 99.97
East	f(x) = p1 × x⁴ + p2 × x³ + p3 × x² + p4 × x + p5	p1 = −4.779 × 10⁻⁵	0.9984
		p2 = 0.002246
		p3 = −0.04004
		p4 = −0.02006
		p5 = 100.1
West		p1 = −3.919 × 10⁻⁵	0.9994
		p2 = 0.002307
		p3 = −0.05705
		p4 = 0.1432
		p5 = 99.97
South-east		p1 = 3.445 × 10⁻⁵	0.9999
		p2 = −0.001102
		p3 = −0.02458
		p4 = 0.03649
		p5 = 100
South-west		p1 = −1.174 × 10⁻⁶	0.9996
		p2 = 0.0002058
		p3 = −0.03832
		p4 = 0.01014
		p5 = 100.1
North-east		p1 = 7.699 × 10⁻⁶	0.9998
		p2 = −0.0002437
		p3 = −0.02453
		p4 = −0.01247
		p5 = 100.1
North-west		p1 = 7.456 × 10⁻⁵	0.9984
		p2 = −0.003751
		p3 = 0.02249
		p4 = −0.373
		p5 = 100.4
Example of calculation result, south-east, 20% direction change [%]	88% = p1 × 20⁴ + p2 × 20³ + p3 × 20² + p4 × 20 + p5

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Zsiborács, H.; Hegedűsné Baranyai, N.; Vincze, A.; Háber, I.; Weihs, P.; Oswald, S.; Gützer, C.; Pintér, G. Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study. Appl. Sci. 2019, 9, 3392. https://doi.org/10.3390/app9163392

AMA Style

Zsiborács H, Hegedűsné Baranyai N, Vincze A, Háber I, Weihs P, Oswald S, Gützer C, Pintér G. Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study. Applied Sciences. 2019; 9(16):3392. https://doi.org/10.3390/app9163392

Chicago/Turabian Style

Zsiborács, Henrik, Nóra Hegedűsné Baranyai, András Vincze, István Háber, Philipp Weihs, Sandro Oswald, Christian Gützer, and Gábor Pintér. 2019. "Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study" Applied Sciences 9, no. 16: 3392. https://doi.org/10.3390/app9163392

APA Style

Zsiborács, H., Hegedűsné Baranyai, N., Vincze, A., Háber, I., Weihs, P., Oswald, S., Gützer, C., & Pintér, G. (2019). Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study. Applied Sciences, 9(16), 3392. https://doi.org/10.3390/app9163392

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Changes of Photovoltaic Performance as a Function of Positioning Relative to the Focus Points of a Concentrator PV Module: Case Study

Abstract

1. Introduction

1.1. Changes in the Spread of Photovoltaic Technologies in the World

1.2. Energy Production and Accuracy Features of Dual Tracking PV Systems

2. Material and Methods

2.1. Study Location

2.2. System Description

2.3. Data Processing and Analysis

3. Results

3.1. The Performance Insensitivity Threshold of Selected PV Technologies, as a Function of Direction

3.2. Polynomial Regression Models of Dual-Axis Solar Tracking m-Si, p-Si and a-Si Systems between 0–30° of Deviation Compared to the FP

4. Conclusions

Author Contributions

Acknowledgments

Conflicts of Interest

References

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