WO2013037016A1

WO2013037016A1 - Set of components for the assembly of pipeless insulating solar panels

Info

Publication number: WO2013037016A1
Application number: PCT/BG2011/000017
Authority: WO
Inventors: Михаил Петров КОСТАДИНОВ
Original assignee: Kostadinov Mikhail Petrov
Priority date: 2011-09-16
Filing date: 2011-09-16
Publication date: 2013-03-21

Abstract

The set of components for the assembly of pipeless insulating and heating solar panels is intended, as the name suggests, for the assembly of such panels. The panels are designed for direct mounting onto walls or other surfaces. Using individual components from the set and other readily accessible materials, it is possible to make solar panels of any size and having any chosen shape, insulation thickness, pipe connection points and fastening points for attachment to surfaces. In other words, it is possible to produce solar panels and an insulating cover all-in-one to suit the criteria of each individual location. Such panels make it possible to cover the facades and/or roofs of various buildings irrespective of the location of windows, doors, pipes, etc. With the aid of such panels, surfaces can be completely covered with an insulating layer while the entire surface will be capable of absorbing energy from the sun.

Description

The complex of elements for the assembly of solar tubeless thermal insulation panels.

I. TECHNICAL FIELD

The complex of elements for the assembly of solar tubeless thermal insulation panels. Further, for convenience, instead of the full name, only the term “complex of elements” will sometimes be used. The full name of the subject matter of this patent application will be used under this term. The complex of elements refers to the area of solar heating panels in which some kind of coolant is heated by the action of sunlight (heat) .

P. BACKGROUND OF THE INVENTION

There are many different types of solar panels. Some of them have vacuum glass tubes in which the heating medium is heated. Another type of solar panels are those in which the coolant flows in the pipes under a double transparent coating. It is to this type of solar panels that the element complex is most relevant.

I am not aware of the fact that individual elements were proposed from which it would be possible to assemble a solar heating panel with any shape and size in length and width, designed for a specific installation site. Also, I do not know that solar panels are proposed that are structurally adapted for direct installation on walls and roofs and at the same time create a heat-insulating coating on the surface on which they are mounted.

III. TECHNICAL ESSENCE.

The complex of elements is a set of individual products, mainly profiles with different purposes and some details. Using profiles and parts from the complex of elements, as well as standard products, such as tin sheets, metal corners, insulation materials and other finished products, as a result of all this you can assemble a solar panel.

A solar panel assembled on the basis of elements from the complex will differ from other solar panels in its design, its functions, and may also vary in shape.

The structural difference from other solar panels is that in this panel, the coolant flows directly under a transparent coating. The functional difference is that this panel is designed to be mounted directly on walls and roofs and at the same time creates a heat-insulating coating on the surfaces on which it is mounted. The third difference from other solar panels is that from a set of complex elements you can assemble a solar panel of arbitrary shape and a garter to pipes with a coolant. For example, if you cover the facade of a house with such solar panels, the benefits would be as follows:

- the entire surface on which solar panels of this type are mounted will be heat-insulated.

sunlight will be actively absorbed from the entire surface.

panels can be not only rectangular, but arbitrary, made for a given place. For example, if during the installation of panels some of them come across so that a window comes up, for example, this panel can be made by preliminary design without the part that covers the window. In this case, the solar panel will work, that is, heat the coolant, just like the rest of the “whole” panels.

- the design of the solar panels is such that they can be made in such a way that places for connecting to pipes with a coolant can be installed almost anywhere in the solar panel. This feature of the solar panel allows you to bring pipes with a coolant to the solar panels in the most convenient and the functional way that conventional solar panels do not always allow such an opportunity.

You can use the analogy with aluminum and PVC windows and doors, which are made to order for each specific place from a set of ready-made profiles and parts. Custom windows and doors have very little restriction in terms of physical dimensions, shape, which way and how they open, where they have handles, hinges and so on.

IV. DESCRIPTION OF THE APPLIED FIGURES.

Figure 1. Profiles of a set of elements for assembling solar thermal insulation panels.

1. closed profile

2. open profile

3. double closed profile

4. double open profile

5. closed profile with a visor

6. open profile with a visor

7. partition profile

Figure 2. connecting parts of a set of elements for assembling solar thermal insulation panels.

8. double corner connector

9 unit angular connecting element

10. double straight coupler

11. triple connecting element

12. straight unit coupler

Figure 3. Decorative profiles and parts of a set of elements for assembling solar thermal insulation panels.

13. cover for covering pipes with coolant

14. heat-insulated cover for covering spaces between solar panels

15. side cover

16. basis for elements N ^Q 13 and IM914

17. cover for covering the connection between the panels 18. distance profile between two transparent coatings

19. mounting element

20. distance mounting element between two transparent coatings

Figure 4. Triple connector closed profiles.

Figure 5. Triple connector of open profiles.

Figure 6. Internal corner connector of closed profiles Figure 7. External corner connector of closed profiles Figure 8. Internal corner connector of open profiles.

Figure 9. External corner connector of open profiles. Figure 10. General view of a tubeless heat-insulating solar panel on open profiles.

Figure 11. General view of a tubeless heat-insulating solar panel on closed profiles.

Figure 12. Fixing tubeless heat-insulating solar panel on closed profiles.

Figure 13. Fixing tubeless heat-insulating solar panel on open profiles.

Figure 14. dual solar panel on closed profiles Figure 15 two solar panels mounted side by side

Figure 16 is a detailed image of the connection of two panels

The individual elements depicted in various figures:

27. transparent coating

28. solar panel thermal insulation

29. mounting screw

30. surface on which the solar panel is mounted

31. mounting holes

32. bottom of the solar panel housing

33. pipe with coolant

34. thermal insulation of the pipe with a coolant 35. connecting part between the solar panel and a pipe with a heat carrier

V. EXAMPLE PERFORMANCE.

The complex of elements for assembling tubeless heat-insulating solar panels includes several types of linear profiles, connecting elements for profiles and several types of connectors of the solar panel with pipes through which heat carrier is supplied or removed. There are also several decorative profiles and parts for them. In addition to the elements included in this patent application, for the assembly of a tubeless heat-insulating solar panel, it is necessary to have other materials.

Additional materials are: metal sheet material (iron, aluminum, copper or some other tin), plastic, wood or some other sheet material suitable for this type of product. Suitable material for a transparent coating: glass, polycarbonate ply planes, plexiglass and the like.

A suitable material for thermal insulation is, for example, polystyrene foam or other similar insulating material.

Also, when assembling solar panels, it is necessary to use glue, solder (for metal parts), seals, fasteners and others.

An example of assembly of a tubeless heat-insulating solar panel made of galvanized sheet, open profiles of galvanized sheet and a polycarbonate layer transparent coating will be given below. The assembly of the solar panel is as follows. A sheet of tin is cut with the desired size and shape of the future solar panel. Profiles 2 are cut with the required length and soldered along the edges of the sheet of metal, connected by corner connectors 25 or 26, depending on the shape of the solar panel. With a rectangular shape, only corner connectors 25 will be used. Soldering should provide a watertight connection between profiles 2, corner connectors 25 and 26 and a sheet of tin that forms the bottom 32 of the solar panel. According to a pre-selected flow diagram of the coolant inside the solar panel, the profiles of the partitions 7 and the mounting elements 19 are soldered to the bottom 32. The mounting elements 19 can be located anywhere. One embodiment is shown in FIG. 10 when the mounting elements 19 are located on the line of the partitions 7. Another embodiment is shown in FIG. 11, where the mounting elements 19 are located between the partitions 7. So in the formed bath of tin sheet (bottom 32), profiles 2, mounting elements 19 and corner joints 25, partitions 7 form a channel through which the coolant will flow. At the beginning and end of the formed channel, holes are made in the bottom 32, preferably as close as possible to the angular connection 25 between the profiles 2. On the back of the bottom 32, connecting elements are soldered - for example 9. The holes in the bottom 32 and in the connecting elements must match. During sealing, the other end of the joint 9 is directed to the desired side, for subsequent connection with the pipe with a coolant 33. All sealed parts and seams should be watertight. Thus, the assembled sheet of tin (bottom 32), profiles 2, partitions 7, connecting elements 9, mounting elements 19 and corner joints 25 represent the body of the solar panel.

According to this scheme, the housing can be assembled from profiles 1 and angular joints 23 and 24. Also, instead of galvanized sheet, you can use plastic, wood or any other planes and components, but then instead of soldering, they can be glued, thermally or some other in a manner depending on the material used.

According to the external dimensions of the case of the solar panel, a sheet of bilayer polycarbonate is cut, which performs the function of a transparent coating 27. This sheet attaches tightly to profiles 2, partitions 7 and mounting elements 19, as shown in Fig. 13. The attachment can be done by gluing and additionally screwed into the profiles 2. The connection of the transparent coating 27 with the housing must be impermeable to water. When mounting the solar panel, screws 29 passing through the mounting elements 19, FIG. 13 will provide additional reinforcement of the transparent coating 27 to the partitions 7. Having covered the case with a transparent coating 27 inside, the coolant will flow directly through the transparent coating 27 through the channels.

For the reverse side of the casing, the insulating material is cut out and glued so that it covers all the surfaces through which the coolant has thermal contact with the environment. It is desirable that the thermal insulation coating 28 be in a parallel plane with the bottom 32 of the solar panel body. With a flat surface of the heat-insulating coating, the installation of the solar panel will be simplified and it will perform to a greater extent the function of the heat insulator of the surface 30 on which it is mounted.

After mounting the solar panel on the surface 30, for example on the facade of the house, pipes are connected to the coolant 33 with the panel through the connecting elements 9 and the connecting parts 35. Depending on the particular case, the connection can be on a thread, on brackets, glued, thermally connected or connected by some some other way. It depends on how the connecting elements 9 are made and which pipes 33 and parts 35 are used in the case.

Next to the first solar panel, you can mount the next one and so on until the surface that is intended for the installation of such panels is covered. According to a pre-compiled scheme, solar panels can be made from individual elements of the complex, while it is possible to make panels in advance so so that they fit the size, shape, thickness, heat of insulation 28, the location and direction of the connecting elements from 8 to 12. You can also choose solar panels with a glass transparent coating 27, while using enclosed profiles 1; 3 and 5 for corner sides, corner connections for profiles 23 and 24, a triple connector for profiles 21, spacer profiles 18 and spacer mounting elements 20. Fig. 11 shows a solar panel assembled from a sheet for bottom 33 and prefabricated elements of a closed type - profiles 1 and corner connectors for profile 23.

In FIG. Figure 14 shows the case when two separate bathtubs are assembled on one common sheet, representing essentially two separate solar panels. The solar panel in FIG. 14 is assembled on the elements: profiles 1 and 3, corner connectors for profiles 23, 24 and triple connectors for profiles 21.

When mounting on the surface 30, the space between the individual solar panels that is left for laying the pipes and the pipes themselves with the coolant 33 can be covered in two ways, using certain profiles from a set of elements. Figure 10 shows a solar panel which includes a profile 6 in its construction with an elongated portion in the form of a visor. A pipe with a coolant 33 passes under this visor. Another pipe 33 passes in a base 16 mounted next to the solar panel, which, after mounting the pipe 33 with thermal insulation 34, is covered with a decorative element 13. On the surface section 30 on which the base 16 is mounted, thermal insulation of this section will be carried out by thermal insulation 34 pipes 33. On top of the pipe 33 and the base 16, a decorative profile 13 is mounted (fixed). If the pipe 33 passes only to somewhere along the base 16, then the rest of the section, where there is no longer a pipe, the space between lyami is covered by a decorative profile 14 which imee insulation property. When pipes are not laid between the panels, then the panels must be mount tight to each other. In FIG. 15 shows two panels standing side by side. The connecting pipes pass inside the insulation of the panels. Pipe binding is done between the panels themselves. The connection point is covered by a decorative element 17. in FIG. 16 shows in detail the place of communication between two adjacent solar panels.

Thus, it is possible to cover those parts of the facade and / or roof of the house that are provided for the installation of such panels. Suitable places for the installation of these panels will be those parts of the house or some other object that are heated by the sun in sufficient quantities.

VI. APPLICATION OF CIRCLE THERMAL INSULATING SOLAR PANELS.

These panels can be used for installation on a wide variety of objects - residential, commercial, administrative and all sorts of other buildings. When using such solar panels, the building will receive the necessary thermal insulation from the outside and at the same time, sunlight will be actively absorbed from all this area covered with such panels, turning into thermal energy.

Since these panels can be made with any size and in any shape, the facade and / or roof of the building can be fully lined with these solar panels. On the other hand, the building will receive an additional heat source, which can be used for heating and / or heating water for domestic purposes.

Only certain parts of facades and / or roofs can be covered with such panels. For example, you can clad the facade of one separate apartment in a multi-apartment building.

Claims

VI. CLAIM

1 a complex of elements, characterized in that of its elements and other common materials available can collect solar heating insulating beztrubnuyu ^'panel.

2. as a consequence of the claim 91, a complex of elements, characterized in that from its elements and other generally available materials, it is possible to assemble a solar panel with an arbitrary configuration and geometric shape based on right angles and straight lines.

3. as a result of claims N91 and N? 2, a set of elements, characterized in that from its elements and other generally available materials, it is possible to assemble a solar panel for a specific place for installation, depending on the desired shape, thickness of thermal insulation, places of fixation to the surface, place and the position of the pipes with a coolant and adjacent panels and decorative elements.

4. a complex of elements, characterized in that the individual elements in the complex are compatible with other elements in physical dimensions, chemical and physical properties, and are equally compatible with other commonly available materials that are necessary in the manufacture of a solar panel.

5. a complex of elements, characterized in that when assembling individual elements with other elements from the complex using other commonly available materials, a watertight compound is formed at the junction points.

6. a complex of elements, characterized in that during the assembly of the solar panel, in the places where individual elements are connected with other commonly available materials, a watertight compound is formed.

7. a closed profile of a complex of elements, characterized by the purpose of being an external side solar panel and hold and separate the transparent coating and the bottom of the solar panel housing.

8. a closed profile of a complex of elements, characterized in that it partially or fully covers the edge of the transparent coating that lies on it.

9. an open profile from a complex of elements, characterized by the purpose of being the outer side of the solar panel and to hold and separate the transparent coating and the bottom of the solar panel body.

10. a double closed profile from a set of elements, characterized by the purpose of being the inner side of the solar panel and to hold and separate the transparent coating and the bottom of the solar panel body.

11. double closed profile from a set of elements, characterized in that it partially or fully covers the edges of the transparent coatings that lie on it.

12. a double open profile from a complex of elements, characterized by the purpose of being the inner side of the solar panel and to hold and separate the transparent coating and the bottom of the solar panel housing.

13. as a consequence of claims N97 and N98, a closed profile with a visor, characterized in that it performs, in addition to all, the functions of a closed profile, additionally covers the place on the surface under the visor where the pipe with the coolant passes.

14. as a consequence of claim 9 9, an open profile with a visor, characterized in that it performs, in addition to all the functions of an open profile, additionally covers a place on the surface under the visor where the pipe with the coolant passes.

15. A partition from a complex of elements, characterized in that it separates the bottom and the transparent coating and forms a channel inside the solar panel body in which the coolant flows.

16. connecting elements from a complex of elements characterized in that each of them has one of the holes adapted and designed to connect and form a waterproof connection with the solar panel body.

17. connecting element position 8, FIG. 2, characterized in that in addition to the hole for connecting to the solar panel body, it has two holes for connecting to the pipes and these two holes are located at right angles to each other and to the hole connected to the body .

18. connecting element, position 9, FIG. 2, characterized in that it has one hole connected to the housing of the solar panel, and the other hole is designed to connect to the pipes, and these two holes are arranged at right angles to each other.

19 connecting element, position 10, FIG. 2, characterized in that in addition to the hole for connecting to the housing of the solar panel, there are two holes for connecting to the pipes and these two holes are located in one line and perpendicular to the hole connected to the housing.

20. connecting element, position 11, FIG. 2, characterized in that in addition to the hole for connecting to the housing of the solar panel, there are three holes for connecting to the pipes and these three holes are located at right angles to the hole connected to the housing, two of them located in one line and perpendicular to the third hole for connection to the pipes.

21. connecting element, position 12, FIG. 2, characterized in that it has two holes in one line, one hole is connected to the housing of the solar panel partially through the bottom and partially through the side, and the other hole is designed to connect to the pipes.

22. decorative element, position 13, Fig 3, characterized in that it is intended to cover pipes with a coolant passing near the solar panels.

23. decorative element, position 14, FIG. 3, characterized in that it is intended to cover the free space near the solar panel and create a heat-insulating coating of the surface on which it is located.

24. as a consequence of claim 23, the decorative element, position 14, FIG. 3, characterized in that it is filled with heat-insulating material and creates a heat-insulating coating on the surface area where it is mounted.

25. decorative element, position 15, figure 3, characterized in that it is intended to cover the ends of the decorative elements 13 and 14.

26. decorative element, position 16, Fig 3, characterized in that its function is to hold decorative elements 13 and 14 when it is mounted on the surface.

27. decorative element, position 17, FIG. 3, characterized in that it is intended to cover the areas between the solar panels, where pipes are connected between the two panels.

28. decorative element, position 17, FIG. 3, characterized in that it is intended to cover devices, sensors and other devices mounted on the connecting elements of the solar panels.

29. distance profile, position 18, FIG. 3, characterized in that it creates a watertight bond between it and transparent coatings on both sides of it.

30. mounting element, position 19, FIG. 3, characterized in that after assembly of the case with a transparent coating creates a watertight connection between it and the bottom and the transparent coating.

31. As a consequence of claim N9 29, the mounting element, position 19, FIG. 3, characterized in that the fastening element passes through it and the watertight connection between the mounting element with the bottom and the transparent coating does not break.

32. The spacing mounting element between two transparent coatings, position 20, FIG. 3, characterized in that it creates a watertight connection between it and the transparent coatings on both sides thereof.

33. distance mounting element between two transparent coatings, position 20, FIG. 3, characterized in that the fastening element passes through it and when water is not broken waterproof connection between the mounting element and transparent coatings.

34. as a consequence of the claim N ^Q 30; IM931; N ° 2 and N ° 3, the connection between elements 19 and 20, characterized in that when the fastening element passes through them, the connection between the bottom, transparent coatings and elements 19 and 20 remains waterproof.

35. connecting corner element for profiles, position 21, FIG. 4, characterized in that it connects two profiles 1 in one line and profile 3 at a right angle to profiles 1.

36. connecting corner element for profiles, position 22, FIG. 5, characterized in that it connects two profiles 2 in one line and profile 4 at right angles to the profiles 2.

37. connecting corner element for profiles, position 23, FIG. 6, characterized in that it connects two profiles 1 at an angle of 90 ° between their sides which are the sides of the solar panel housing.

38. connecting corner element for profiles, position 24, FIG. 7, characterized in that it connects two profiles 1 under 270 ° angle between their sides which are the sides of the solar panel enclosure.

39. connecting corner element for profiles, position 25, FIG. 8, characterized in that it connects two profiles 2 at an angle of 90 ° between their sides which are the sides of the solar panel housing.

40. connecting corner element for profiles, position 26, FIG. 9, characterized in that it connects two profiles 2 at an angle of 270 ° between their sides which are the sides of the solar panel housing.