RU200619U1 - MOBILE PHOTOELECTRIC STATION - Google Patents

Abstract

The utility model relates to the field of solar energy, in particular to photovoltaic power plants containing flexible solar modules, and can be used as portable power supply systems, as well as folding mobile energy sources, such as autonomous power supply systems of low power (up to 6 kW) Such systems include, as a rule, consumers who do not have a connection to the centralized power supply. The task of the proposed technical solution is to securely fix the module on the frame while providing the possibility of prompt dismantling of the module from the frame. The task of the proposed technical solution is to facilitate the installation and dismantling of mobile photovoltaic stations, consisting of flexible solar modules, with the preservation of the possibility of self-cleaning from snow and ice crust. This is achieved by the fact that in a mobile photovoltaic station, including a metal consisting of upper and lower horizontal hollow tubes and lateral vertical hollow tubes the frame and flexible solar modules suspended from the frame, characterized in that the horizontal tubes of the frame contain fasteners for fixing the modules, and the vertical tubes of the frame are pipes inserted into each other, separated by a spring, and having clamps to prevent spontaneous separation of the frame structure.

Description

The technical solution relates to the field of generating electrical energy using photovoltaic batteries by directly converting sunlight into electrical energy, and in particular - to photovoltaic stations containing flexible photovoltaic solar modules, and can be used as portable power supply systems, as well as folding mobile energy sources, such as autonomous power supply systems of low power (up to 6 kW).

Such systems include, as a rule, consumers who do not have a connection to a centralized power supply:

- Communication systems (repeaters, mobile radio systems, telephone networks, autonomous monitoring and control systems).

- Signaling devices (systems of signal navigation lights on rivers or in the sea, safety lights installed on high-rise buildings, on railway tracks, highways).

- Remote monitoring systems (mobile installations providing power to autonomous weather stations, autonomous temperature and water level control stations, air pollution control near industrial enterprises).

- Temporary power supply systems (provision of food for expeditions to remote places, provision of power supply in places of natural disasters or temporary economic activities).

At the same time, the operation of such systems should provide for ease of operation and prompt repair in the event of technical breakdowns in the system (in particular, the possibility of simple and prompt installation / dismantling.

The proposed technical solution is intended for use as a part of quickly mounted and dismantled mobile photovoltaic stations and makes it easier to assemble and install such stations, while maintaining their functionality.

Known mobile photovoltaic charger, including a collapsible frame of horizontal and vertical hollow racks, and a set of four folding photovoltaic panels (solar modules), each of which is a cloth bag with six pockets, which are inserted photovoltaic modules.

The pockets of the bag are equipped with sewn-in metal rods, which can move freely along the guide grooves in the vertical racks of the frame. The modules themselves are made on the basis of amorphous silicon photoconverters laminated into a polymer package, the design of which provides for a rigid substrate located on the reverse side of the package [1].

This design provides, first of all, the solution of such problems as convenience during transportation and storage of the charger.

However, this design has a significant drawback - low resistance to wind loads (air flows with a speed of more than 5 m / s in a direction perpendicular to the surface of the folding photovoltaic panels).

This disadvantage is especially noticeable when the device is located in open areas.

The known design of a photovoltaic station containing photovoltaic solar modules with a glass coating, fixed on a metal or carbon fiber frame. Such a frame is a rigid frame that is attached to a supporting structure, fixed in the ground or on other surfaces, which ensures the resistance of the entire station to wind loads and precipitation [2].

Basically, such designs are applied to stationary photovoltaic plants, the operation of which is designed for many years.

In the case of mobile systems, the use of which is periodic, and the systems themselves must be transferred to the transport position to move to another location, it is also possible to use the above structures, however, in this case, the power of the photovoltaic station is limited by the volumetric characteristics of the vehicle and the large weight of the solar modules.

The most suitable for mobile systems are flexible solar modules, which are significantly lighter and are not enclosed in a frame. For fastening, such modules contain either metal eyelets or metal strips with holes built into the laminate [3]. Fastening of such modules to the frame is carried out by any flexible elements (rope, cable) or rigid devices (staples, hooks, etc.).

The disadvantage of such solutions is the high labor intensity and time consuming installation and dismantling works, which in some cases is a critical factor.

The known design of a photovoltaic station, containing a vertical cylindrical frame with a rotation mechanism at its top, and photovoltaic solar modules in the form of a plurality of plate photovoltaic panels, which are mounted for rotation on a common axis of the frame and which can be in the open position in the form of a "petal" and in folded position in the form of a package in which the panels are located one above the other [4].

The specified design is equipped with a device for tracking the position of the sun, and can change the solarization area of the modules due to full or partial folding of the panels - "petals", and this can be effectively used to reduce increased wind loads on the plane of the deployed panels of the station.

The disadvantages of this design include the significant weight of the structure, as well as the excessive complexity of both the structure itself and the conditions of its operation.

The closest technical solution is a photovoltaic station with the function of self-cleaning solar modules [5].

The photovoltaic station according to this invention contains flexible solar modules with perforated inserts, which are suspended from a metal frame using springs, which provides self-cleaning of the modules during operation from snow and ice crust due to vibration under the influence of wind loads.

The disadvantage of this technical solution is the complexity of installation and dismantling, since each module has to be fastened using separate springs, which are also subject to constant weathering. If this design is applied to mobile systems, then the probability of breakage or loss of springs becomes very high, and the installation of the mobile photovoltaic station in bad weather becomes very difficult.

The problem to be solved by the claimed technical solution is to facilitate the installation and dismantling of mobile photovoltaic stations, consisting of flexible solar modules, while maintaining the possibility of self-cleaning from snow and ice crust.

This goal is achieved by the fact that in a photovoltaic plant, which includes a metal frame composed of upper and lower horizontal hollow tubes and lateral vertical hollow tubes and flexible solar modules suspended from the frame, characterized in that the horizontal tubes of the frame contain fasteners for fixing the modules, and the vertical frame tubes are tubes inserted into each other, separated by a spring, and having clamps to prevent spontaneous separation of the frame structure.

The utility model is illustrated by a drawing (Fig. 1), which shows a general view and individual elements of the claimed design, where:

1- upper horizontal tube of the frame;

2- lower horizontal tube of the frame;

3- lateral vertical tube of the frame;

3a - the upper part of the side vertical tube of the frame;

3b - the lower part of the side vertical tube of the frame;

4- fixing elements of the frame;

5- solar module;

6- perforated metal plates of the solar module;

7- spring;

8- perforated holes in the metal plate.

The rectangular metal frame of the photovoltaic station is an upper horizontal tube (1), a lower horizontal tube (2), and side vertical tubes (3), which consist of an upper (3a) and lower (3b) parts. The upper horizontal tube (1) and the lower horizontal tube (2) are equipped with fixing elements (4) in the form of mushroom or other type of hooks, on which solar modules (5) are hung, which have embedded perforated metal plates (6).

The vertical pipes of the frame (3) are made of the upper (3a) and lower (3b) parts of the lateral vertical pipes inserted one into the other, separated by a spring (7), which is fixed to the flat base of the upper part (3a) of the lateral vertical pipes (3). The distance between the hooks (4) on the upper and lower tubes of the frame is chosen so that it is equal to the distance between the perforated holes (8) in the solar module with the spring (7) straightened out.

The assembly of the photovoltaic station is carried out as follows: the upper part of the frame, including the upper horizontal pipe (1) and the upper parts (3a) of the lateral vertical pipes attached to it, are inserted into the lower part of the frame, including the lower horizontal pipe (2) and the lower parts ( 3b) lateral vertical pipes. Then, the solar modules (5) are hung on the upper horizontal tube (1) of the frame. The frame is compressed, which allows the second (lower) perforated strip (6) of the solar modules (5) to be fastened to the hooks on the opposite side of the frame located on the lower horizontal tube (2). The spring (7) is released and pulls the solar modules (5) between the top and bottom of the frame.

When the wind blows on the surface of the modules, they bend due to the compression of the spring inside the frame, which allows the structure to work to remove snow and ice crust in the same way as if the solar modules were suspended directly through springs to the upper and lower tubes of the frame.

This design of the frame allows you to move the photovoltaic station without disassembling the frame by placing several solar modules on the frame at once. When disassembling the PV plant, there is no need to detach the springs and store them separately. It also prevents loss of springs during assembly and disassembly.

The tests of the photovoltaic station according to the present technical solution were carried out in comparison with the photovoltaic station according to the prototype [4], which uses spring suspensions to suspend solar modules on the frame.

The test results showed that the time spent on the installation / dismantling of one photovoltaic solar module with the spring version of the suspension of the module on the frame is more than 10 times the time spent on the installation / dismantling of the module having fixation elements according to the claimed technical solution.

During the tests, the resistance of the modules of photovoltaic stations to wind loads was also assessed. The photovoltaic station according to the claimed technical solution withstood a wind load of more than 5 m / s (with local gusts of wind up to 20 m / s) for 5 hours, while in a photovoltaic station according to the prototype, already with local gusts of wind reaching 10 m / s, it was observed partial detachment of modules from the spring suspension.

In the known science and technology, solutions to a similar problem have not been found to use for fixing flexible solar modules on a metal frame of springy fasteners, which are pipes inserted into each other, separated by a spring, and having clamps to prevent spontaneous separation of the frame structure.

Sources of information

1. RF patent No. 2548154 dated June 10, 2013

2. Solar photovoltaic plants (review from 03.02.2020);

- URL: https://metallurgist.pro/solnechnye-fotoelektricheskie-stantsii/.

3. RF patent No. 178429 dated 08.21.2017

4. RF patent No. 2652095 dated 20.01.2014

5. RF patent No. 2558398 dated 02.12.2013 - prototype.

Claims (1)

Mobile photovoltaic station, including a metal frame composed of upper and lower horizontal hollow tubes and lateral vertical hollow tubes and flexible solar modules suspended from the frame, characterized in that the horizontal tubes of the frame contain fasteners for fixing the modules, and the vertical tubes of the frame are inserted into each other into the other pipes, separated by a spring and having clamps to prevent spontaneous separation of the frame structure.

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