2.1. The Use of Photovoltaic Cells
Obtaining electricity from sunlight is an attractive way of powering electronic devices in areas without energy infrastructure and with limitations in securing the logistic of troops [
1,
2,
3]. Photovoltaic cells would usually act as a backup power source or support the operation of diesel-electric generators. At command posts, they can support the work of a field energy system. The amount of energy obtained from photovoltaic panels depends on the area, the efficiency of panels and the amount of sunlight [
4,
5]. Such power systems can only be operated during the daytime, which requires the accumulation of electricity.
Batteries with different parameters are used to power devices that soldiers are equipped with (e.g., radio stations, night vision devices, GPS devices). Their working time is limited by the capacity of the batteries and the temperature at which the battery operates [
6,
7,
8]. The easiest way to extend the run-time of your devices while completing tasks is to use additional power sources. However, it increases the weight of the soldier’s equipment. An alternative solution to the problem is to equip troops with portable charging devices powered by photovoltaic panels. Their use in various militaries, however, requires meeting additional expectations in terms of masking, resistance to mechanical damage, resistance to weather conditions, low weight, and small geometric dimensions [
1,
2,
6].
Photovoltaic panels consist of single cells connected in various configurations [
3,
9,
10] and currently manufactured panels can be grouped according to the material they are made of and their crystal structure. Most often they are manufactured on silicon basis with a crystal and amorphous structure, less often they are made of semiconductor compounds such as halides, GaAs, InP, as well as dye and organic materials [
11].
Currently conducted research is aimed at obtaining the highest possible ratio of the power recovered in a PV cell to the power of solar radiation falling on the surface of a PV cell [
10,
11,
12,
13,
14]. The manufacturing technology of PV cells can be divided into three generations. The first generation consists of PV cells based on crystalline or polycrystalline silicon. The second-generation PV cells are made of thin-film PV cells based on amorphous silicon, polycrystalline CIS (CuInSe2), CIGS (CuInGaSe2) layers. The third generation of PV cells is manufactured in a multi-layer technique from materials with different energy potentials [
11,
13,
14].
Due to their surface shape, thermal properties, and color, PV panels may have features that reveal the positions of troops. Dye-sensitized solar cells (DSSC) belonging to the third generation of PV cells can eliminate that disadvantage. The efficiency of PV DSSC cells is 15% [
12], and they cannot compete with silicon cells in terms of efficiency. PV DSSC cells, due to the possibility of producing them in any colors and shapes, as well as the high durability of the cells and operation at low light intensity, can be used in military applications. When considering the use of PV DSSC cells, their sensitivity to both too low and too high temperatures should be taken into account [
12].
The conducted research on flexible PV cells technology is focused on thin-film cells with increased efficiency and greater structure flexibility. This allows them to be integrated with soldier’s personal equipment (such as a uniform, backpack, bulletproof vest, helmet, etc.). The following solution enables maintenance-free powering of soldier’s life monitoring systems and charging batteries used in low-power radio stations, GPS receivers and light sources. Flexible PV panels are mostly produced with the use of PV cells made in the amorphous silicon technology as multi-junction structures or with organic technology [
3,
9,
13,
15]. The largest producers of flexible PV cells are American companies such as Global Solar, Uni-Solar, and Power Film, which also specialize in military production [
15,
16,
17,
18,
19,
20].
The exposition of a PV panel to solar radiation causes its temperature to rise significantly above the ambient temperature.
Figure 1 shows a PV panel exposed to solar radiation at the ambient temperature of about 15 °C with variable cloud cover. The thermographic image taken after 2 h of exposure to solar radiation indicates that the temperature of the PV panel differed from the ambient temperature by 12 °C, leaving a clear thermal trace.
Intelligent power supply systems in military applications are becoming a feasible reality [
21]. The supply of fuels intended for feeding diesel-electric units in subunits’ operation areas may be difficult or even impossible. Therefore, the use of energy-saving power receivers and a hybrid power supply reduces the demand for diesel and gasoline, which translates into lower operating costs and reduction in the number of possible convoy losses [
2,
21]. As part of the NATO Smart Energy program, in countries such as Greece, Germany, United Kingdom, the United States and the Netherlands, intensive research is being carried out and projects for field energy systems are being developed [
21,
22,
23,
24,
25,
26,
27,
28]. Poland also wants to join the group of users of similar energy systems on a daily basis. This has resulted in an urge to present selected solutions based on solar panels, which are currently used in other NATO countries. For several years, the German Bundeswer has been equipped with Multicontanier MC66 mobile solar containers [
2,
29,
30].
The MC66 PV system includes 66 PV panels, each with a capacity of 300 Wp, which allows for a maximum power of 19.8 kWp. Electricity is stored in a 30 kWh LiFePo4 battery. The PV MC66 system can work independently as well in cooperation with the generator. Everything is stored in a standard container. The set is intended for supplying command posts and military bases [
2,
29,
30].
British troops were equipped with a compact photovoltaic power plant by Renovagen Roll-Array of the RAPID Roll system, which is produced in three power options (3.6 kWp, 7.2 kWp and 11 kWp) [
22]. The manufacturer has used the flexible PV cells technology. The RAPID Roll 11/120 system consists of a foldable PV panel with a power of 11 kWp, occupying an area of approximately 100 m
2, and an energy storage with 124 kWh, using lithium-ion batteries [
22]. Everything is located in the RAPID ROLL “T” trailer-towed by a 4 × 4 vehicle. The system can cooperate with field power systems powered from mobile sources of energy [
2,
22] and is intended to power small military bases [
22]. The authors of this study had two basic questions:
- 1.
If the lithium-ion battery is used, and the battery capacity is particularly large, how to solve the irreversible problem of overcharge and over-discharge?
(There is still no clear answer since testing is still going on).
- 2.
How to solve the possible fire and even explosion risk of battery overheating?
(Fire protection measures are used at command posts).
The described systems are intended for supplying command posts and military bases. For small sub-divisions carrying out missions and long duration, Thales Defense & Security Inc. has designed the Expeditionary Modular Universal Battery Charger (EMUBC). This device combines the functions and capabilities of many battery chargers used by the US Army in one product [
18,
19]. The EMUBC charges electricity from the grid, from batteries, and from flexible PV panels. The charger weighs less than 3 kg and can be carried or installed in military vehicles.
In the United States, research is being conducted on the Soldier Worn Integrated Power Equipment System (S.W.I.P.E.S.). As part of this program, the US Army is using over 7500 sets [
18,
19]. All elements of the SWIPES system are mounted into a tactical vest.
The system includes the following: a power distribution unit (Hub), two battery charging stations for Motorola and Harris radios, a GPS DAGR charging cable, power sources in the form of Zinc-Air batteries with a voltage of 12 V and a capacity of 24 Ah (whose main advantage is the ability to work in a temperature range between −20 °C and +60 °C, as well as providing resistance to mechanical damage including bullet holes) [
19]. Instead of Zinc-Air batteries, it is possible to use lithium batteries or a flexible PV panel [
19].
In Poland, research on the use of PV panels in military applications has been initiated at the Military Institute of Engineer Technology (WITI—Military Institute of Engineer Technology, Obornicka 136 Str., 50-961, Wroclaw, Poland) [
1,
8]. As a part of this research, PV panels prototypes were designed and manufactured. There were portable for a single soldier and transportable for powering devices (e.g., communications, electronics) that are equipped with combat vehicles [
31].
Greece has also been involved in the development of power systems, and its troops are equipped with a photovoltaic power plant by the Intracom Defense Electornic-IDE company. It is an autonomous, hybrid power system consisting of six PV panels with a total power of 3 kWp placed in transport boxes and a generator with a power of 20 kW. The set was designed to power Greek military units located in places with no access to power grids [
27,
28].
2.2. Application of Solar-Wind Power Plants
Mobile solutions are an interesting and dynamically developing sort of renewable energy system. In this group, there are some promising hybrid solutions enabling the simultaneous electricity generation using both solar and wind energy, which significantly increases their reliability in various weather conditions. The mobility of such devices additionally extends the scope of their applications, dominated by power supply, including military communication systems [
32] or small residential installations located in places without power grid access. Mobile solar-wind power plants are generally solar-wind electricity generators of a design and characteristics enabling them to be easily moved by available transportation means. The components of such sets are featured with a high integration degree of the functional system elements (
Figure 2), which means that they consist of a small number of parts that can be easily connected by a person with little experience.
A solar-wind electricity generation system (hybrid generator) that generates electricity consists of mechanical-electrical components with their control systems and electronic circuits connected to them. They convert the generated current to a form that allows charging of batteries using an inverter to convert direct current into alternating current with characteristics matching the devices powered from it. Each system also includes cables for connecting the components, a set of electricity accumulators, and systems for distributing the generated direct and alternating current. The key parts of each set are mechanical and electrical devices that enable the conversion of energy obtained from external factors into electricity [
31]. Due to the specifics of each set, these generator components determine the basic features of the entire hybrid system (i.e., the dimensions, efficiency, characteristics of the generated current, operational stability, the possibility of mobile use etc.). Each solar-wind power generation system (
Figure 3) consists of four key functional blocks: wind electricity (BEW), light electricity (BES), generated energy accumulation (BAE), and distribution of generated electricity (BDE).
2.3. Operational Rules
The main, shared medium of electricity transmission in a standard generator is the DC magistrate shown in the
Figure 3 (hereafter referred to as the DC magistrate).
Electricity generated in BEW and BES via the DC magistrate is accumulated in BAE and supplies the receiving devices via the BDE. In case of insufficient or a lack of energy generated by BEW and BES units, the current flows from the BAE to the DBE. In case it is necessary to ensure the continuity of electricity supply to receivers connected to BDE, and in the absence of energy generated continuously and stored in the BAE, electricity must be generated by a generator using non-renewable sources [
32].
Electronic circuit modules used in the described system are used to convert electricity and optimize the operation of solar panels and wind turbines. In order to obtain a common power source for external receivers in a hybrid system combining wind and photovoltaic model, it is necessary to include a power converter that converts alternating current (AC) into direct current (DC) or vice versa. DC systems are also essential for adjusting the current-voltage parameters to a level set for a given system implementation [
33,
34].
The main part of BEW is a wind turbine that converts the kinetic energy of the wind into mechanical energy and then into electricity. It is worth noting that it produces alternating current. Wind turbines can be classified into two types based on the axis around which the turbine rotates. Turbines rotating around a horizontal axis are more common in real life systems. In modern solutions, there is a large variety of forms of such mechanisms. The use of a specific shape and the choice of the rotor operation axis is related to the specific environment in which the generator is supposed to operate.
The most important parameter influencing the power generated by the wind energy conversion system is its speed, the size of which is proportional to both the effective rotor surface and the cube of the wind speed. Most manufacturers claim that their devices generate electricity at low wind speeds. However, the theoretical basis and mathematical calculations show that for most solutions, acceptable power is only generated at speeds between 20–27 km/h. It is assumed that turbines with such wind generate only 1/8 of their maximum power, which means that, for example, an 800-watt turbine in such conditions produces only 100 W of power [
35]. In BEW, the Maximum Power Point Tracking (MPPT) system, also referred to as the advanced maximum power point tracking system, is responsible for reducing the negative impact of wind speed fluctuations on the stability of the generated electricity parameters, which can increase the amount of energy obtained by up to 20% (in relation to the inverter without MPPT). The main task of such system is to “track” this point and adjust to its new value as quickly as possible by reducing or increasing the rotational speed of the turbine. The operation of such systems is often improved with the use of the latest solutions in the field of computer technology (e.g., neural networks) [
36,
37].
The rectifier in the BEW converts the alternating current generated by the turbine into a direct current source using power diodes or by controlling the ignition angles of controllable switches. The BEW produced this way should have the characteristics required to be fed to the DC Magistrate.
2.4. Solar Electricity Generator
In case of the BES block, it is worth noting that the photovoltaic panels already generate the direct current. However, in some implementations this requires the use of a DC/DC converter system in order to obtain the current with the desired parameters. Here as well, in the BES block, the MPPT module is implemented. It uses the latest technology when it comes to the control of electromechanical systems [
36]. The DC/DC converter in this block has the functionality extended by:
- 1.
CC charging control (i.e., preventing loopback from batteries to photovoltaic panels modules).
- 2.
Automatic shutdown of the block if the voltage level from the panels is too high or too low.
- 3.
Automatic restart after returning to the appropriate operating parameters, protection against short-circuit or overload, etc.
- 4.
Electricity accumulation block.
The level of reliability and efficiency of the hybrid electricity generator is largely defined by the operational reliability of BAE (i.e., the unit responsible for storing the generated BWE and BSE energy). Among the various electricity storage devices, batteries are the most widely used, so the correct selection of them is crucial. Therefore, it should be clearly pointed out which type of battery should be selected for military purposes, such as lithium-ion battery, lead-acid battery, solid-state battery, etc.
The batteries must be able to handle the peak power needed during the operation of the entire generator and provide sufficient power at a nominal load for the time assumed for the device [
24,
33]. At the same time, it is worth noting that they are probably the most important part that should be taken into account when considering the mobility of the entire system due to the fact that a specific feature of even the latest solutions in this field is their heavy weight and considerable dimensions. An interesting analysis of this problem has been presented in [
33].
In the BDE electricity distribution block, the key parts are:
- 1.
A DC/AC converter, also called the inverter, converting direct current into alternating current (230 V, 50 Hz in Europe), which is acceptable to receivers. Such a system should also include functionalities related to protection against a generator overload, unfavorable loopback during energy consumption and automation systems responding to improper current-voltage parameters of the supplied electricity.
- 2.
A set of AC and DC sockets for distribution of electricity generated by the system.
Electricity generators are installations called solar-wind mobile power plants, solar-wind power mobile generators, and solar-wind portable generators, available in versions that enable the production and storage of electricity from about 1 up to 100 kW power. When used in an area with adequate sunlight and proper air movement characteristics, they are able to provide electricity 24 h a day, 7 days a week. This is the result of the authors’ direct observations during land forces exercises at command posts. Often, these installations are equipped with various systems for remote control and component control via extensive computer networks. They do not require direct supervision, which significantly increases their functionality and applicability.
Among the devices of this type available on the market, you can find both sets of autonomous solutions offered with parts ensuring mobility, as well as modular installations consisting of ready-made components that enable the generation and storage of electricity from both wind and sunlight. These can be adapted to one’s own needs and for possibilities offered by the range of displacement of the entire hybrid system.
Among the large comprehensive solutions, one of the most interesting is the German offer [
35] presenting a product called Solarcontainer. It is a wind-solar container power plant equipped with an autonomous optimization system of power generation and a remote monitoring and control system for its operation. It consists of a set of six wind generators with a power of 1 kW each and photovoltaic panels generating up to 55 kWp. It also has a battery system that allows the store of up to 75 kWh of electricity. The following set weighs about 10 tons and can be set up in 30 min.
Presented below is the Canadian MOBISMART Hybrid Off-grid Wind and Solar Power Generator (
Figure 4) [
38]. This represents an example of smaller and cheaper solution that is also more interesting for the inhabitants of the northern hemisphere.
The kit is installed on an aluminum trailer that can be connected to any car. It allows one to generate up to 6 kWp of power and is equipped with an energy storage kit allowing up to 30 kWh (Lux model). An installed wind turbine generating up to 1 kWp (vertical axis) or 1.2 kWp (horizontal axis operation).
The mobile energy management system (MEMS) from the German company PFISTERER integrates a conventional source of electricity in the form of a power generator with various renewable energy sources. The MEMS consists of two ZSEs with a power of 10 kW each, a wind turbine with a maximum capacity of 5 kWp, PV panels with a maximum capacity of 5 kWp, and an energy storage 60 kWh. Additionally, the system can be supplemented with Austrian Smartflower sets with a maximum power of 2 kWp and the PV MC66 system [
2,
20,
39].
In the solutions related to the described systems, modular power supply systems play an important role, enabling the construction of their own structures dedicated to the specific needs of the user. They secure specific capacities in terms of electricity demand and offer solutions related to the mobility of structures (dimensions, shock resistance, etc.). The existing commercial offers of solutions in the field of small wind turbines, solar panels and is wide, but not every device is suitable for military applications.
All of the autonomous hybrid generators presented above can be combined into larger structures, thus obtaining energy systems with greater powers. The MOBISMART company offers a solution consisting of connected generators giving a total of approx 200 kWp of electricity and dedicated to power a small container estate in Canada.