RU198969U1 - PHOTOELECTRIC STATION - Google Patents

Abstract

The utility model relates to the field of solar energy, in particular to photovoltaic plants containing flexible photovoltaic 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. This is achieved by the fact that in a photovoltaic station that includes a photovoltaic flexible module containing reinforcement elements in the form of a perforated metal strip with holes, a frame in the form of vertical and horizontal metal pipes fastened to each other and containing elements for fixing the module, characterized in that it is placed as fixing elements metal cylindrical posts mounted on vertical pipes, equipped with caps in the form of a spherical segment, and the module on the frame is positioned in such a way that the cylindrical posts are threaded through the holes of the module's reinforcement elements so that the caps of the posts are located above the module surface, and the fixation of the module is ensured by longitudinal displacement of the locking element located on the posts, which is a metal strip with perforations in the form of holes with an oblong oval cut.

Description

The technical solution relates to the field of solar energy, in particular to photovoltaic plants containing flexible photovoltaic modules, and can be used as portable power supply systems, as well as folding mobile energy sources, such as autonomous low-power power supply systems (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 units providing power to autonomous weather stations, autonomous temperature and water level control stations, air pollution control near industrial enterprises).

- Water pumping installations (autonomous systems used to lift drinking water from wells and wells for irrigation purposes in agriculture).

Since such systems are subject to increased influence of climatic factors (especially wind loads), they, as a rule, are additionally equipped with fasteners that ensure reliable fixation of the modules on the supporting frame (frame).

At the same time, the operation of such systems should provide for the convenience of operation and prompt repair in the event of technical breakdowns of the system (in particular, the possibility of simple and prompt dismantling of photovoltaic modules).

The known design of a solar photovoltaic station containing photovoltaic modules and a support structure, characterized in that the support structure is made in the form of a portable collapsible dwelling, approaching a hemispherical shape and representing a frame with an awning canvas stretched over it, while the photovoltaic modules are located on the outer the surface of the awning and attached to it with Velcro, while the photovoltaic modules are attached in such a way that their axes are aligned with the ribs of the frame [1].

The disadvantage of this design is the low reliability of fastening the modules when using fixing elements based on "Velcro", especially with wind loads acting on the separation of the module from the plane of fixation.

Known photovoltaic station containing photovoltaic modules and a supporting structure (frame), characterized in that the photoreceiving surface of the modules is corrugated or has the form of ribbons stretched between the frame elements, in which all the elements working in tension are made in the form of longitudinal and transverse strings, and the elements working in compression are made of rods abutting with one end against the expanding unit, and with the other against the cross of longitudinal and transverse strings, forming a spatial truss, and the photovoltaic modules are attached to the longitudinal or transverse strings using wedge locks, and the modules are of the tape type laced to the strings [2].

The disadvantages of this design include:

- congestion with auxiliary structural elements (in particular, elements that regulate the tension of the strings), which significantly slow down the assembly and installation of the system itself;

- complicated process of replacing the module (in the case of using the fastening method by lacing).

A photovoltaic station for marine use is also known, including a frame (frame), a photovoltaic reinforced module containing, as a reinforcing element, a thin metal sheet ~ 3.0 mm thick with holes, located on the back of the module, and the holes are reinforced with metal hollow rivets pressed into them (eyelets), the number of which, as a rule, does not exceed 6 pieces, and the fixation of the module on the frame is carried out by threaded elements (nuts) on metal studs threaded through the eyelets [3].

In recent models of such photovoltaic modules, lighter aluminum sandwich panels are used as a reinforcement element.

The disadvantages of this design include the increased weight of the module, due to the presence of a metal sheet as a reinforcement element, and the impossibility of prompt assembly / disassembly of the module due to the increased rigidity of fastening the modules with screw pairs.

Also known is a mobile photovoltaic station, including a collapsible frame of horizontal and vertical hollow posts, and a set of four folding photovoltaic panels, each of which is a fabric bag with six pockets, which are inserted photovoltaic modules. The pockets of the bag are equipped with sewn-in metal rods that 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 [4].

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

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

The closest to this technical solution is a photovoltaic station, which includes a photovoltaic flexible module containing reinforcement elements in the form of a perforated metal strip with holes, a frame in the form of vertical and horizontal metal pipes fastened together and containing elements for fixing the module in the form of springs for suspending the module on frame [5].

The photovoltaic modules are suspended from spring-loaded reinforcements on the frame. Reinforcement elements of the modules are a metal strip with holes. The fastening of the reinforcement elements in the plane of the module is carried out by the lamination method during the manufacture of the module.

Due to the suspension of the modules on springs, constant vibrations and the possibility of bending the modules simultaneously in several directions are provided due to elastic deformations, which, first of all, increases the likelihood of self-cleaning of the module surface.

The main disadvantage inherent in the specified technical solution is the low reliability of fixing the modules on the frames and low efficiency when mounting / dismounting modules.

The problem to be solved by the claimed technical solution is the reliability of fixing the module on the frame while providing the possibility of prompt dismantling of the module from the frame.

This is achieved due to the fact that in a photovoltaic station, including a photovoltaic flexible module containing reinforcement elements in the form of a perforated metal strip with holes, a frame in the form of vertical and horizontal metal pipes fastened together and containing elements for fixing the module, characterized by the fact that fixation elements use metal cylindrical posts placed on vertical pipes, equipped with hats in the form of a spherical segment, and the module on the frame is positioned in such a way that the cylindrical posts are threaded through the holes of the module reinforcement elements so that the posts of the posts are located above the module surface, and the module is fixed provided due to the longitudinal displacement of the locking element located on the posts, which is a metal strip with perforation in the form of holes with an oblong oval cut.

The design of the flexible photovoltaic module with reinforcement elements in the form of a perforated metal strip with holes laminated into the module structure used in the claimed utility model is illustrated in FIG. 1, where:

1 - upper carrier film;

2 - upper fastening film;

3 - reinforcing layer;

4 - intermediate fastening film;

5 - chains of solar cells;

6 - lower fastening film;

7 - lower carrier film;

8 - elements of the module reinforcement (perforated metal strips);

9 - tape holes for fixing elements;

10 - technological holes of the tape.

The manufacturing technology of such a module and the substantiation of the dimensional parameters of its structural elements are presented in detail in [6].

The lower carrier film 7 - polyethylene terephthalate film “PYE. A lower bonding film 6 of polyethylene methacrylate is placed on top of it.

A soldered chain of solar cells 5 is laid on top of this package, and the switching buses of the soldered chain of elements are brought out to the reverse surface of the film 7 through holes with a diameter of 4 ÷ 5 mm cut through in the formed package.

Along the long edges of the chain of elements 5, reinforcement elements 8 are laid, which are pieces of metal perforated tape.

On top of the soldered chain of solar cells 5 with two perforated metal strips (reinforcing elements) 8 laid sequentially, an intermediate fastening film 4 is laid, on top - a reinforcing layer 3, which is a mesh of fiberglass with a cell of 5 × 5 mm formed by threads 0.2 ÷ 0 , 3 mm, then - the upper fastening film 2, and the formation of the package is completed by laying the upper layer of the carrier film 1.

The bag (laminated blank) prepared in this way is placed in a laminator, where the blank of the film packet is sintered (laminate formation).

At the final stage of the process of forming the module, the laminate is cut at the locations of the holes 9, as a result of which chains of through holes 9 are obtained along the vertical sides of the module.

The thickness of the laminate (photovoltaic reinforced flexible module) made in this way is about 4.0 mm, which is determined by the sum of the thicknesses of the layers (films) constituting the laminate:

- the thickness of the upper 1 and lower 7 carrier films is ~ 0.6 mm in total;

- the thickness of the upper bonding film 2 is ~ 0.4 mm. The intermediate bonding film 4 has a similar thickness (~ 0.4 mm);

- perforated tapes 8 with a thickness of 0.7 mm located on the lower bonding film 6 and the film 6 itself (thickness 0.4 mm) give a total thickness of ~ 1.1 mm;

- the thickness of the reinforcing mesh 3 is ~ 1.0 mm, which is determined by its thickness at the nodes of intersection of the mesh threads.

Perforated tape 8 is formed along the vertical sides of the module. Holes 9 of the tape have a diameter of 8.5 mm, holes 10 have a diameter of 4 mm.

The holes 10 are technological, and their presence is determined only by the provision of a higher reliability of fixing the tape of the lower 6 and intermediate 4 fastening films.

The diameter of the holes 9 of the tape 8.5 mm was chosen for reasons of securing on the fasteners (cylindrical metal posts with a head, the diameter of which is slightly less than the diameter of the holes in the perforated tape). Pillars with a cap diameter of less than 8.5 mm are technologically unacceptable, because do not provide the required reliability of fixing the module.

The tape has a width L ₁ = 20.0 mm (the width was chosen to minimize the use of the useful area of the tape in order to increase the reliability of fixing its plane with bonding films).

A tape with a width of L ₁ = 20.0 mm corresponds to a thickness of 0.70 mm.

The alternation pitch L _{2 of the} holes 9 in these types of tapes is 28.0 mm, which ensures the optimal number of alternating fastening holes in the module when laminating the tape.

The selected ratios of the parameters of the perforated tape (width, thickness, diameters and hole locations) are standardized values for the steel tape used (model CLP1M-LP-20-1, manufacturer - IEK, and model LSP 20 × 0.7, manufacturer - firm "YUMA").

The thickness of the laminate (photovoltaic reinforced flexible module) produced in this way does not exceed 4.0 mm.

The elements of the fixing unit and the process of fixing such a flexible module on the frame itself are illustrated in Figs. 2, where:

11 - cylindrical posts;

12 - hat;

13 - vertical tube of the frame;

14 - laminate (photovoltaic module with amplification elements);

15 - locking element;

16 - opening of the locking element;

17 - oval cutout of the opening of the locking element;

18 - nut.

Metal cylindrical posts 11, equipped with caps 12 in the form of a spherical segment, placed on vertical metal pipes 13 of the frame are screws with a semicircular head (GOST 1473-80) with an M4 thread and up to 50 mm long, fixed to the frame 13 by screwing into threaded holes , the ends of which are fixed with nuts 18. The diameter of the screw head is 7.0 mm, respectively.

The photovoltaic module (laminate) 14, the design of which provides for reinforcement elements 8 located along the vertical sides of the module (Fig. 1), is placed on the posts 11 so that it is put on the posts 11, and their caps 12 are threaded through the holes 9 of the module.

The locking element 15, which is a metal strip with holes 16 with oval cutouts 17, is pushed onto the posts 11 so that the holes in the laminate 14 are located symmetrically to the holes 9 of the module. With a slight vertical shift of the locking element 15 relative to the plane of the module, the elements 11 enter the oval cut 17 of the hole 16 of the locking element, which ensures the fixation of the tape between the plane of the module and the caps 12.

A photovoltaic station was tested according to the present technical solution in comparison with a photovoltaic station using a spring suspension as the fixing elements of the module [5].

The test results showed that the time spent on mounting / dismounting one flexible photovoltaic module with the spring-loaded version of fixing the module on the frame is more than 10 times longer than the time spent on mounting / dismantling the module having fixation elements according to the claimed technical solution.

During the tests, the resistance of photovoltaic power plant modules 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.

Tests have shown that a photovoltaic station comprising flexible reinforced modules and a frame equipped with fixation elements based on metal cylindrical posts with hats in the form of a spherical segment and having locking elements in the form of a metal strip with perforation in the form of holes with an oblong oval cutout, provides reliable fixation of the module to the frame, while ensuring the possibility of quick dismantling of the module from the frame.

In the known science and technology solutions of a similar problem, the use of metal cylindrical posts with hats in the form of a ball segment for fixing photovoltaic flexible modules on the frame has not been found, and the modules are fixed on the frame due to the longitudinal displacement of the locking element located on the posts, which is a metal strip with perforation in the form of holes with an oblong oval cut.

Sources of information.

1. RF patent No. 2 371 641 dated 09.07.2008

2. RF patent No. 2 127 008 dated 02.27.1999

3. Solar Panels for Boats - https://www.greenmatch.co.uk/solar-energy/solar-panels/solar-panels-for-boats.

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

5. RF patent No. 2558398 dated 02.12.2013 (prototype).

6. RF patent No. 178429 dated 08.21.2017

Claims (1)

Photovoltaic station, including a photovoltaic flexible module, containing reinforcement elements in the form of a perforated metal strip with holes, a frame in the form of vertical and horizontal metal pipes fastened to each other and containing elements for fixing the module, characterized in that metal elements placed on vertical pipes are used as fixation elements cylindrical posts, equipped with caps in the form of a spherical segment, and the module on the frame is positioned in such a way that the cylindrical posts are threaded through the holes of the module's reinforcement elements so that the caps of the posts are located above the module surface, and the module is fixed due to the longitudinal displacement located on the posts the locking element, which is a metal strip with perforation in the form of holes with an oblong oval cut.

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