EP3969689A1 - Modular photovoltaic system - Google Patents

Abstract

The present invention relates to a modular photovoltaic system. In particular, the invention relates to a modular photovoltaic system which is suitable for use in the roofing of garage roofs and carports. In addition, the present invention relates to the use of the modular photovoltaic system for the purpose of producing a carport or a garage roof with an energy-generating function, and also to a carport or a garage roof comprising the modular photovoltaic system.

Description

MODULAR PHOTOVOLTAIC SYSTEM

The present invention relates to a modular photovoltaic system. In particular, the invention relates to a modular photovoltaic system which is suitable for use in the roofing of garage roofs and carports.

The present invention also relates to the use of the modular

Photovoltaic system for the production of a carport or a garage roof with an energy generation function and a carport or a garage roof, comprising the modular photovoltaic system.

State of the art

The state of the art is already modular photovoltaic systems for

Garage roofs and carports are known in which photovoltaic modules are arranged in a form-fitting manner next to one another and the space between them is sealed by elastic sealing compound, for example silicone compound.

The German patent specification No. DE 2020 130 115 B3 relates to a

Support structure for elevated photovoltaic modules, which can be mounted on a flat roof or a gable roof, for example.

These modular photovoltaic systems have disadvantages in that the watertight sealing of the intermediate spaces is usually only possible with one

Specialists can be done. In addition, the problem arises that the density compound cannot be used at low temperatures or when it is wet, which makes assembly more difficult. In addition, the problem also arises that the influence of weather conditions, especially the

Solar radiation, temperature changes and chemical processes age over time so that tightness cannot be guaranteed over a longer period of time. As a rule, the density mass has to be changed regularly, which in turn requires the use of specialists. Representation of the invention. Task. Solution. benefits

Based on the above considerations, the present invention is therefore based on the object of providing a modular photovoltaic system which can be easily installed and which is a good derivative of

Allows rainwater down. Another task was to provide a modular photovoltaic system that has a longer shelf life and can also be installed quickly and inexpensively

In a first aspect, the present invention therefore relates to a modular photovoltaic system. The modular photovoltaic system can comprise at least a first row of at least two prefabricated photovoltaic modules. A gap can be arranged on the longitudinal side between the prefabricated photovoltaic modules and a drainage channel can be arranged below the at least one gap.

According to the invention, a photovoltaic module is any commercially available

Photovoltaic module (PV) or photovoltaic element understood with which solar energy is converted into electrical energy. According to the invention, a drainage channel is understood to mean any channel with which rainwater can be drained off. In a preferred implementation, the gutter is made of metal or a plastic material. In particular, the drainage channel can be made of precious metal or stainless light metal, e.g. Aluminum.

Advantageously, the rainwater or meltwater hitting the photovoltaic modules when it rains can pass through the gap and be drained off in the direction of the ground via the drainage channel.

According to the invention, the drainage channel is attached below the at least one gap. This means that the drainage channel in the intended mode of operation is only attached to one side of the photovoltaic modules and closes the gap on the longitudinal side. In the intended mode of operation, the rainwater or meltwater hitting the photovoltaic modules can flow downwards, ie in the direction of gravity in the intended mode of operation Pass through the gap and flow downwards along the drainage channel, ie in the direction of gravity in the intended mode of operation.

In a preferred implementation, the at least one drainage channel can close off the gap between the prefabricated photovoltaic modules in a form-fitting and / or watertight manner. A form-fitting and / or watertight closure has the advantage that power lines, circuits or components placed below the photovoltaic modules are protected from water. In a preferred implementation, the gutter is with a

water-repellent material waterproof and form-fitting with the

Fixed photovoltaic module. The water-repellent material can ideally be a silicone compound. Silicone compound has the advantage that it ensures the watertight seal particularly well and has a long shelf life.

In a preferred implementation, an edge drainage channel can be arranged on each of the sides of the prefabricated photovoltaic modules that do not form a gap. In this advantageous embodiment, the rainwater can also be collected on all drainage sides of the photovoltaic modules on the side and drained off in the direction of the ground through drainage channels. Such a design is particularly suitable for installation on a garage or storage space for vehicles, since the water can also be effectively drained off to the side.

In an alternative preferred implementation, the modular

Photovoltaic system comprise at least a second row of at least two prefabricated photovoltaic modules. A gap can be arranged on the longitudinal side between the prefabricated photovoltaic modules and a drainage channel can be arranged below the at least one gap. The first row of

prefabricated photovoltaic modules can be arranged in an overlapping manner opposite the second row of prefabricated photovoltaic modules. This means that in the intended mode of operation, the water from the first row of prefabricated photovoltaic modules which are arranged above the second row of prefabricated photovoltaic modules and these on the top overlap, can be diverted downwards via the second row of prefabricated photovoltaic modules, as an alternative to diverting through the gap and the drainage channel. Preferably, the series of ^;

Photovoltaic modules connected to one another in a form-fitting and watertight manner. In this case water can not be used on the possibly below ^' the

Photovoltaic modules arranged electronic components meet.

Such an overlapping design has the further advantage that the photovoltaic system can be built and installed more easily and more cost-effectively.

In a preferred implementation, the drainage channel can be an essentially U-shaped drainage channel. Alternatively, the drainage channel can also be an im

Be essentially V-shaped gutter. These forms of drainage channels are in terms of the material used in the manufacture of the drainage channel in

Combination with the water drainage in the assembled state is optimal.

In a preferred implementation, the pre-built

Photovoltaic modules each have at least one mounting element.

Preferably, two of the mounting elements can each have one

Connecting element are connected to each other. The mounting elements can with the connecting element by conventional

Connectivity options are connected. Preferably the

Assembly elements are screwed or glued, in particular screwed, to the connecting elements. In this case the modular

Photovoltaic system has excellent stability.

The gap between the photovoltaic modules can preferably have a width in the range between 0.5 and 3 cm, more preferably in the range between 1 and 2 cm and in particular 1.5 cm. Ideally, the gap is so large that the drainage channel can be cleaned with suitable means through the gap, and on the other hand small enough that an optimal

Land use is made possible by the photovoltaic modules. In a second aspect, the invention relates to the use of the modular photovoltaic system for producing a carport or a garage roof with an energy generation function. The use of the modular

Photovoltaic system for producing a carport or a garage roof has the advantage that the energy is generated by solar elements in spatial proximity to the possible storage location of the electrical energy in the accumulators of the electric vehicles or hybrid vehicles in the carport or in the garage. In this way the roof area becomes the

Storage options optimally used and a long and lossy one

Energy transfer can be avoided.

In a third aspect, the invention relates to a carport or a garage roof, comprising the modular photovoltaic system. According to the invention, a carport is understood to mean any parking facility for vehicles, mostly cars, which is attached to a building or integrated into a building or is free-standing.

According to the invention, a garage is understood to mean any covered parking space for vehicles, mostly cars, enclosed by solid walls.

Advantages of the modular photovoltaic system according to the invention are above all the easy transport of the photovoltaic modules, the quick assembly of the

Systems even in bad weather and by a non-specialist and the longer durability compared to conventional systems.

Brief description of the figures

Some special embodiments of the invention are described below by way of example and not in an exhaustive manner with reference to the accompanying figures.

The particular embodiments serve only to explain the general inventive concept, but do not limit the invention.

In the special embodiments show: 1 shows a bottom view of the modular photovoltaic system (1) with mounting elements (5) attached to the underside of the photovoltaic modules (2).

2 shows different views of the modular photovoltaic system (1) with overlapping rows of photovoltaic modules (2) when used on a carport or a garage roof.

3 shows a cross-sectional view of the modular photovoltaic system (1) with overlapping rows of photovoltaic modules (2).

4 shows a plan view of the modular photovoltaic system (1) with

Photovoltaic modules (2), gap (3) and drainage channel (4).

Preferred embodiment of the invention

1 shows a bottom view of the modular photovoltaic system (1) with mounting elements (5) attached to the underside of the photovoltaic modules (2). The modular photovoltaic system (1) consists of several rows of at least two prefabricated photovoltaic modules (2). The photovoltaic modules (2) each have at least one mounting element (5) and can be fixed to one another by means of the connecting elements (6). In this

The photovoltaic modules are commercially available

Photovoltaic modules. The mounting elements and connecting elements can be made, for example, of noble metal or non-rusting light metal, in particular aluminum. The elements are off-the-shelf elements.

Fig. 2 shows different views of the modular photovoltaic system (1) with overlapping rows of photovoltaic modules (2) when used on a carport or a garage roof. Fig. 2a shows a plan view of the modular photovoltaic system (1) with several prefabricated

Photovoltaic modules (2), with the lengthways between the prefabricated

Photovoltaic modules (2) at least one gap (3) is formed. In this case, the modular photovoltaic system (1) is mounted on a carport. Figure 2b shows a view from below of a modular photovoltaic system (1) mounted on a carport. Fig. 2c shows the assembly of the individual photovoltaic modules (2) using the assembly elements on a carport. In this

Embodiment, the rows of photovoltaic modules (2) are arranged overlapping, so that the water very effectively over the rows of

Photovoltaic modules can be derived downwards. The ranks of

Photovoltaic modules (2) are connected to one another in a form-fitting and watertight manner. Silicone compound can also be embedded between the rows of photovoltaic modules. In addition, in this embodiment, too, the water can be drained off into the drainage channel via the gap.

3 shows a cross-sectional view of the modular photovoltaic system (1) with overlapping rows of photovoltaic modules (2).

Fig. 4 shows a plan view of the modular photovoltaic system (1) with

Photovoltaic modules (2), gap (3) and drainage channel (4). The drainage channel (4) closes the gap (3) between the prefabricated photovoltaic modules (2) in a form-fitting and watertight manner. In this example the drainage channel (3) is U-shaped, which results in a simple design. The drainage channel can preferably be glued to the photovoltaic modules (2) below the full length of the gap, so that the drainage channel (4) and the photovoltaic modules (2) are watertight at the bottom. That on the

Rainwater hitting photovoltaic modules (2) can in this way be drained down through the gap (3) and then along the drainage channel (4) to the earth. This has the advantage that electrical components are below the

Photovoltaic modules and other components of the carport or garage are well protected from moisture and the water can run off completely. In this exemplary embodiment, the photovoltaic modules are commercially available

Photovoltaic modules.

The drainage channel (4) can be made of precious metal or stainless light metal, e.g. Aluminum. Between the gutter and the

Photovoltaic modules can also use silicone compound for waterproof insulation be upset. The gap between the photovoltaic modules can have a width of approx. 1 cm.

The modular photovoltaic system is easy to assemble, even in bad weather, and can be assembled by non-specialists. Compared to conventional systems, the system is longer

Durability, especially because of the improved drainage of

Rainwater or melt water aging, corrosion or mossing of the individual components of the system is largely avoided. The design of the photovoltaic system also enables the individual components to be easily transported and inexpensive to manufacture from standard components.

Bezuqszeichenliste modular photovoltaic system prefabricated photovoltaic modules gap

Drainage channel

Mounting element

Connecting element

Edge drainage channel

Claims

Claims

1. Modular photovoltaic system (1), comprising at least a first row of at least two prefabricated photovoltaic modules (2), with the longitudinal side between the prefabricated photovoltaic modules (2)

at least one gap (3) is formed, a drainage channel (4) being arranged below the at least one gap (3).

2. Modular photovoltaic system (1) according to claim 1, wherein the

at least one drainage channel (4) between the prefabricated

Photovoltaic modules (2) lying gap (3) closes positively and / or watertight.

3. Modular photovoltaic system (1) according to one of claims 1 or 2, each comprising an edge drainage channel (7) on the side of the prefabricated photovoltaic modules (2) on which no gap (3) is formed.

4. Modular photovoltaic system (1) according to one of claims 1 to 3, comprising at least one second row of at least two

prefabricated photovoltaic modules (2), with at least one gap (3) being formed along the length between the prefabricated photovoltaic modules (2), with one below the at least one gap (3)

The drainage channel (4) is arranged, the first row of prefabricated photovoltaic modules (2) being arranged so as to overlap the second row of prefabricated photovoltaic modules (2).

5. Modular photovoltaic system (1) according to one of claims 1 to 4, wherein the drainage channel (4) is a substantially U-shaped drainage channel (4).

6. Modular photovoltaic system (1) according to one of claims 1 to 5, wherein the prefabricated photovoltaic modules (2) each have at least one mounting element (5).

7. Use of the modular photovoltaic system (1) according to one of claims 1 to 6 for the production of a carport or one

Garage roofs with energy generation function.

8. Carport or garage roof, comprising the modular photovoltaic system (1) according to one of claims 1 to 6.