2nd German-West African Conference on Sustainable, Renewable Energy Systems SusRES – Kara 2021 

Photovoltaic  

https://doi.org/10.52825/thwildauensp.v1i.5 

© Authors. This work is licensed under a Creative Commons Attribution 4.0 International License 

Published: 15 June 2021 

Bi-facial Open-Space Photovoltaic Systems versus 
Conventional Systems using Mono-facial Modules 

A Technical and Economic Comparison 

Marcus Schmidt1,2, Martin Hinneburg2, Lutz B. Giese3 
1 Technische Hochschule Wildau (Graduate), Germany 

2 SUNfarming GmbH Erkner, Germany 

3 Technische Hochschule Wildau, Germany 

Abstract: As part of a scientific work within the solar company Sunfarming GmbH, the aim 
was to find out whether bi-facial modules on open spaces deliver better results economically 
than conventional mono-facial solar modules. In this context, an already installed 750 kWp 
PV system with mono-facial solar modules was compared directly with a structurally identical 
PV system with bi-facial modules, which, however, does not exist in practice but was only 
simulated with PV software. The second part of the investigation includes the comparison of 
four different assembly systems or elevation variants in order to determine the system with 
the best relationship between system yield and costs. 

The final result of the first investigation showed that the use of bi-facial modules reduced 
the specific costs per kWh by approximately 5 %. In order to improve this effect, the use of 
compact assembly systems is recommended, e.g. five rows of modules per table with 
horizontal alignment. 
Keywords: Bi-facial photovoltaics, open-space PV systems, Renewable Energy Sources 

Introduction 

For many years, photovoltaics have been one of the most important players in renewable 
power generation in Germany. The PV modules have been optimized in terms of production 
and quality, especially in the last 10 years, which at the same time increased customer 
demands, prices have fallen and the degree of efficiency depending on the design has 
already reached over 20 %. With the aim of placing as much power as possible in a small 
area, the trend of bi-facial modules developed on the market in 2018/2019. The technology is 
able to convert solar radiation into electrical energy on both the front and rear of the module. 
According to the suppliers and manufacturers, additional energy yields of 5-30 % compared 
to mono-facial modules are possible depending on the orientation, inclination and shading 
[1]. 

In this context, the question arises to what extent the bi-facial standard modules 
compare to mono-facial modules in terms of additional power and whether these can 
generally replace the conventional modules in open spaces. For this consideration, the 
actual costs and energy yields of a current open-space system were examined and 
compared with the costs and yields of a simulated system with bi-facial modules. 
 

37



Schmidt et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 

 

PV Open Space Systems 

A ground-mounted PV system basically 
consists of the following main components: 

 Mounting system / substructure 
 Solar modules 
 Generator connection boxes 
 Inverter 
 Transformer and transfer station 

The mounting system is used to hold and 
align modules (Figure 1). The modules are 

inclined to a certain angle (15°-30°) with the aid 
of the frames, while this is already guaranteed 
by the roof inclination in roof systems. The 
more module rows a table has, the lower the inclination must be selected in order to 
minimize the effect of wind loads. The mounting system is one of the most important factors 
influencing the effectiveness of the PV system [2].  

A conventional mono-facial solar module usually consists of several crystalline solar 
cells with silicon as the starting material. The solar cells form the heart of a PV system, as 
the actual photovoltaic effect takes place in these or convert the energy of the photons into 
electricity. In practice, mainly polycrystalline (light blue appearance) and monocrystalline 
(dark blue appearance) are used, which differ only in terms of the type of production and the 
degree of efficiency. While polycrystalline solar modules have an efficiency of 13-17 %, 
monocrystalline modules can have an efficiency of more than 20 %, but this is associated 
with higher costs. In a PV system, the solar modules are connected in series, creating so-
called strings that are then led to the generator junction box [3]. 

The nominal output of a solar module is 
specified in kilowatt-peak (kWp) and indicates the 
maximum output of the module, which is also 
optimized with half-cell technology (Figure 2). If the 
cells are halved after production, the peak 
performance can be improved by 2-3 % according 
to the Fraunhofer Institute for Solar Energy 
Systems, since the electrical resistance and thus the 
energy losses are reduced within the cell connectors [4]. 

The generator junction boxes have the task of bringing the individual solar cables or 
strings together and, if necessary, of separating the load from the rest of the system by 
means of a switch disconnector (e.g. for maintenance work). By merging the strings, cable 
runs and costs can be saved [2]. 

The solar generator generates direct current and can therefore not feed into the power 
grid with alternating current. Therefore, all PV modules must be connected to one or more 
inverters depending on the generator power. This converts the direct current (DC) into 
alternating current (AC). In addition to the conversion, the inverters also perform the following 
tasks [3]: 

 Performance optimization 
 Plant monitoring 
 Power feed-in 

  

Figure 1. PV system with bi-facial modules. 

Figure 2. Half-cell technology [4]. 

38



Schmidt et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 

 

Performance optimization: The inverter detects the point of maximum power 
(MPP = Maximum Power Point) per module string. This point is different at any time 
depending on the irradiance, shading and module temperature, which is why the MPP is 
constantly searched for and tracked (MPP tracking) [5]. 

Plant monitoring: Thanks to the independent operation, inverters can switch to stand-
by mode when the voltage is too low in order to save energy and switch on again when there 
is sufficient incidence of light. They can also automatically disconnect themselves from the 
network in the event of network faults or failures using a disconnection device. With the help 
of a communication interface, the inverters and thus the yields of the PV system can be 
remotely monitored at any time, e.g. to quickly identify any loss of yield [6]. 

Power feed-in: After a successful conversion, the electricity is fed into the 
corresponding electricity network. While this process takes place in small PV systems (e.g. 
5 kWp) via the house connection with 230 V, larger systems (e.g. 750 kWp open-space 
systems) feed into the medium-voltage network between 1 kV and 35 kV via the transformer 
or the transfer station [2]. 

The transformer is connected to the PV generator via the inverter and transforms the 
output voltage of the inverter to the required medium-voltage level. In addition, with the help 
of a switchgear within the station, it is possible to disconnect the transformer from the power 
grid [2]. 

However, the energy from the PV system is fed into the public grid with the help of the 
transfer station. This also takes over the counting of the energy generated by the generator 
and at the same time forms the property boundary of the PV operator and the responsible 
network operator [7]. 

Bi-facial Modules PV Open Space System 

In contrast to the mono-facial cell, the bi-facial solar cell can convert the solar radiation on 
the front as well as on the back into electricity. However, these are not two separate areas, 
but simply the same item. The bi-facial PERC cell (PERC = Passivated Emitter Rear Cell) is 
characterized by its dielectric layer (dielectric = non-conductive). The illustration in Figure 3 
shows both a conventional solar cell and a PERC cell. The standard cell (left) has a full-
surface aluminum metallization on the back, which serves as a conductive contact for the 
cell. The PERC technology, on the other hand, involves the creation of a dielectric layer that 
has several small holes with the help of a laser. This means that the silicon wafers only have 
contact with the aluminum metallization through the tiny holes [1]. 
 

 

 
 
 
 
 
 

Figure 3. PERC cell technology [8] (in German). 
By modifying the back of the cell, the radiation can also be received from the back. In order 
to fulfill this function, there must also be a transparent back [8]. 

39



Schmidt et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 

 

The back is not symmetrical with the front and for this reason can only partially absorb 
the radiation as efficiently. The ratio between back and front performance is called the bi-
facial factor and is approximately 70 % under standard test conditions [1]. 

In addition, there are the following influencing factors that influence the rear side yield of 
bi-facial modules: 

The reflection factor (albedo) is a percentage of the reflection radiation that hits the 
back of the module and depends on the color and nature of the surface. While light colors 
have an albedo value of approximately 60-90 % (e.g. snow), grass, for example, guarantees 
a value of approximately 23 % [1]. 

The higher the angle of installation, the more diffuse radiation can reach the rear, and 
the same applies to the installation height of the module tables [1]. 

The row spacing between the module tables also has an influence on the radiation 
behind the modules. At short distances, the horizon is narrowed down, so that the diffuse 
radiation decreases. Self-shading can also occur at low positions in the sun if a module table 
is too close to the rear one [1]. 

The last influencing factor is the shading from the solar cables and the mounting system. 
The profiles of the mounting system should therefore not cover the rear of the bi-facial 
modules [1]. 

Economics of Bi-facial PV Systems 

Economic Comparison of Two 750 kWp PV Systems 

A 750 kWp PV system that had already been built by SUNfarming GmbH was used as the 
basis for the investigation, and its investment costs were compared with the annual energy 
yields in order to calculate the specific costs in €/ kWh. In the study, these specific costs 
should represent a measure of the profitability of a PV system. 

With the help of the simulation software PV-Sol, it was then possible to simulate the 
same PV system with the same technical configurations that instead contains bi-facial solar 
modules. For the simulation system, the theoretical investment costs and yield data were 
also put in relation and the specific costs were calculated. According to the comparison, the 
specific costs when using bi-facial modules decreased by 3.17 %. However, it should be 
noted here that it is not certain whether the simulation software can calculate the actually 
possible energy yield through the rear. An additional energy yield of approximately 5 % was 
output in the simulation, which can therefore differ slightly from reality. 

Economic Comparison of Different System Concepts 

In the second part of the investigation, the standard assembly system used was compared 
economically with four other elevation concepts. An area of approximately 4 hectares was 
used as the basis, which was covered by the concepts below in full simulation.  

The fundamental data set of the installation concepts and their technical configuration is 
shown in Table 1.  

Table 1. Comparison of the system concepts [own illustration]. 

Concepts/ Reference Concept 1 Concept 2 Reference Concept 3 Concept 4 
Orientation of modules Vertical Horizontal horizontal horizontal horizontal 
Module rows per table 2 3 4 5 6 
Installation angle 30° 30° 25° 20° 15° 
Elevation (in m) 0.6 0.6 0.6 0.6 0.6 
Row spacing (in m) 3 3 3 3 3 

40



Schmidt et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 

 

In Figure 4 sketches of the configurations can be seen. 

Figure 4. System concepts 1 to 4 and reference [own illustration; in German]. 

During the simulations of the individual concepts, it turns out that the space utilization 
increases with the size of the module tables and that, despite the lower elevation angle, a 
higher energy yield is possible with concepts 3 and 4. At the same time, however, the 
possible reverse side yield decreases by up to 4 % compared to concept 1. 

Following the same procedure as mentioned above, where the investment costs and 
energy yields are used to calculate the specific costs, the end result shows that the specific 
costs of the first two variants are slightly more than for the comparison system. 
Variants 3 and 4, on the other hand, have lower specific costs. Of the four different concepts, 
variant 4, with an optimization of 0.84 % compared to the reference system, at least in 
theory, represents the most economical PV system. 

In the investigations, the bi-facial modules turned out to be the more economical variant 
for elevated PV ground-mounted systems. The additional yield of the bi-facial modules is 
high enough in the simulations to compensate for the additional costs and to achieve a 
positive benefit. Since it was not possible to determine whether the simulation software can 
realistically calculate the additional yield from bi-facial modules, it is nevertheless advisable 
to carry out a precise yield report in order to achieve a final result.  

Conclusions 

The bi-facial modules have not yet fully achieved the market breakthrough, but due to the 
ever increasing demands on solar modules, the trend is likely to continue to rise until the bi-
facial modules may have replaced the mono-facial modules for the most part on the market. 
Here, however, one can only assume speculation. 

The increase in yield can be of great advantage, especially in regions such as in the 
African area, as the solar radiation is about twice as high as in the European area, whereby 
the profitability could probably be optimized again. 

In addition to the pure increase in yield, the transparency and the longer shelf life due to 
the glass-glass construction speak for the use of bi-facial solar modules, as this opens up 
completely new applications for photovoltaics, in which conventional mono-facial modules 
could not be used efficiently. At the moment, the modules are mainly used as roof-integrated 
in greenhouses, in order to serve as both a power generator and a roof at the same time. 
The modules are also suitable for multi-purpose use for facades, balconies, noise barriers 
and carports. In addition, they can also be erected on flat roofs with the lightest possible foil 
as a substrate in order to increase the albedo value. In this case, the high reflection factor 
could achieve an additional energy yield on the back that clearly exceeds 5 %. For this 
reason, it is advantageous to examine the economic viability of bi-facial modules in other 
areas of application and to test them in practice. 

41



Schmidt et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 

 

 

References 

[1] Frontini F, Caccivio M, Renken C. Anwendung von bifazialen Solarmodulen – 
Einsatzmöglichkeiten an Gebäuden, Dimensionierung der Anlagenkomponenten. 
EnergieSchweiz; 2019 August. 
[2] Sperling P. Masterarbeit - Ertrags- und Kostenoptimierung von PVFreiflächenanlagen. 
2016. 
[3] Antony F, Dürschner C, Remmers KH. Photovoltaik für Profis: Verkauf, Planung und 
Montage von Solarstromanlagen. 2. vollständ. überarb. Edition. Solarpraxis; 2009. 
[4] Alpha Solar & Heizungstechnik GmbH. Halbzellenmodule – Der neue Trend bei den 
Modulherstellern 2019. http://docplayer.org/129827504- Halbzellenmodule-der-neue-trend-
bei-den-modulherstellern-2019.html. Accessed 2020 December 17. 
[5] ET-SYSTEM. MPP-Tracking. 
https://www.etsystem.de/fileadmin/user_upload/Applikationen_Sondergeraete/MPP-
Tracking_HPSMP_de.pdf. Accessed 2020 December 17. 
[6] SMA Solar Technology AG. Wechselrichter: Leistungselektronik für eine saubere 
Energieversorgung. https://www.sma.de/partner/expertenwissen/wechselrichter-
leistungselektronikfuer-eine-saubere-energieversorgung.html 
[7] Solibra System Montage Gmbh. Baubeschreibung für den geplanten Bau einer 
Photovoltaik-Freiflächenanlage auf der ehemaligen Kasernenanlage in Zerbst. 
http://docplayer.org/62688876-Baubeschreibung-fuer-den-geplanten-bau-einer-photovoltaik-
freiflaechenanlage-auf-der-ehemaligen-kasernenanlage-in-zerbst.html. 2017; 
[8] Kutzer M, Fülle A, Jahnke A, Becker J, Hahn H, Wendt S, Neuhaus D, Witzig A, Kunath L, 
Stöckli U. Ertragssteigerung durch bi-faciale Modultechnologie. 
https://www.velasolaris.com/wpcontent/uploads/2018/12/solarworld_otti_beitrag_final_1.pdf. 

 

42

http://docplayer.org/129827504-%20Halbzellenmodule-der-neue-trend-bei-den-modulherstellern-2019.html
http://docplayer.org/129827504-%20Halbzellenmodule-der-neue-trend-bei-den-modulherstellern-2019.html
https://www.etsystem.de/fileadmin/user_upload/Applikationen_Sondergeraete/MPP-Tracking_HPSMP_de.pdf
https://www.etsystem.de/fileadmin/user_upload/Applikationen_Sondergeraete/MPP-Tracking_HPSMP_de.pdf
https://www.sma.de/partner/expertenwissen/wechselrichter-leistungselektronikfuer-eine-saubere-energieversorgung.html
https://www.sma.de/partner/expertenwissen/wechselrichter-leistungselektronikfuer-eine-saubere-energieversorgung.html

	5_5-Schmidt-etal_Conference paper-7-1-6-20210506