DE102005044524A1 - Adjustable solar power installation for use on building roof, has lower section with stand that has rollers at upper end, such that rollers move along rail fixed to upper section to ensure relative motion between upper and lower sections - Google Patents

Abstract

The installation (100) has a lower section and an upper section (103) set on a roof (101) and on which solar modules (107) are mounted. A wall is provided surrounding the lower section. An opening is formed for receiving articles for storage or vehicles. A drive device is included for rotating the upper and lower sections relative to each other. The lower section is provided with a stand (105) that has rollers at the top end. The rollers move along a circular track rail (115) fixed on the upper section to ensure the relative motion between the upper and lower sections with respect to the roof.

Description

The The present invention relates to a function of the relative position of the sun trackable during the day Solar system hall according to the generic term of claim 1.

In In recent years, solar panels have been increasingly used on buildings or buildings set up special racks. With them, the radiating to the surface Sunlight captured. Preferably, the solar modules of the generation of electricity, so-called photovoltaic modules. The inventive system However, it is also for storage of solar modules for production suitable for hot water. It was realized that the energy yield elevated can be tracked by keeping the solar modules tracked throughout the day, so that the sun is always in as optimal an angle as possible the surface the solar modules are irradiated.

Such a relative sun position trackable frame is from the DE 20 2005 002 411 U1 known. There, a frame for the storage of solar modules with a bottom-mounted mountable lower part and a rotatably mounted on the lower part upper part is described. The tracking of the solar modules is done during the day rotatory by means of a drive device with chain guide. However, this frame is comparatively large depending on the solar module area used and consequently takes up a relatively large amount of space. A function beyond that of a rack for storage of solar modules, the frame can not meet. The control device for the system is mounted in the center of the frame and thereby takes away comparatively much space. In addition, the frame is not rainproof, so it is useless as a storage area. Furthermore, the frame does not comply with the safety regulations, since the modules can fall down on persons or objects when they are destroyed. Even revision work is hardly possible with such racks. Moreover, by the appropriate design of the construction, the introduction of objects to be stored only under difficult conditions possible.

In the prior art, a trackable solar plant hall is also known. A solar system hall is understood here to mean a frame which consists of a base frame which can be mounted in a floor-mounted manner and of a hall upper part rotatably mounted thereon. Solar modules can be mounted on top of the upper part of the hall. The upper part of the hall also has walls that limit the solar system hall to the outside. In at least one of the walls, an opening is provided through which objects to be stored in the hall can be introduced. Unlike the frame from the DE 20 2005 002 411 U1 Consequently, the solar system hall of the invention on walls, so that can be spoken of a real building. Depending on the dimensions of the solar system hall and also from the opening, are placed on the items to be stored, the previously known solar system hall for the storage of smaller equipment, such as garden or garden furniture, to the storage and housing of vehicles or agricultural or other machinery and plants suitable.

The However, previously known racks and halls have various disadvantages on. On the one hand, the roofing of such facilities proved problematic. In the utility model cited above, the solar modules only on appropriate scaffolding slats mounted, so that a rain tightness is not given. By This assembly can be a storage heat not occur, but such a frame is suitable for storage not at the moment. In the previously known halls, an additional Roofing, however, proved the occurrence of heat accumulation due the sunlight as problematic. The remedy was therefore used in such systems fans, but the electrical Consume energy and thus lead to a less favorable balance sheet. Further would in case of a technical defect the solar modules are not cooled and therefore would it overheats come.

Besides have the previously known solar system halls and racks even more Disadvantages, in particular, that there is a risk that in the hall set items too close in the area of the rotating wall have been set so that things to hit the hall wall, what on the one hand to a damage of the stored objects and on the other hand also to a damage of the solar system hall can lead. Next were in the known solar system halls and stability problems in case of strong wind and storms. The well-known solar plant halls are

task The present invention is a solar plant hall available which is suitable for the storage of objects on the Top solar modules are attachable and without the use of fans for cooling the solar modules can be used. This task is solved by a solar system hall according to claim 1. Advantageous embodiments are the subject of the dependent claims.

In the inventive, depending on the relative position of the sun in the course of the trackable solar system hall is according to the invention provided on the upper hall a sealing roof skin. As such a sealing roof skin, for example, sheet metal or fiber cement are suitable, as it is known for the coverage of buildings such as halls. On this roof, the solar modules are attached with a certain distance. The distance is inventively dimensioned so that a ventilation of the solar modules takes place.

It has been found that with appropriate spacing of sealing roof skin and the solar modules a kind of chimney effect between the solar modules and the roof skin takes place, so that the forming warm air is constantly dissipated in this area and is replaced by cooler ambient air. The distance to be maintained between the solar modules and the roof skin to achieve this effect is dependent on the solar modules used, the type of sealing roof skin, the roof pitch of the solar system hall and the size of the entire system. In an exemplary plant with a base of the hall of about 10 m × 10 m results in a solar area of about 260 m ² . The roof pitch is about 25 ° to 35 °. In such a system, a distance of 5 cm to 40 cm was found to be advantageous.

By the provision of a sealing roof skin is not only for the benefit achieved the impermeability of the solar system hall required for storage, but the safety of the system is significantly improved. destroyed Modules can not in the building interior fall. Inspection works are much easier and without additional Fuses possible.

A preferred embodiment a trackable Solar system hall has a separate floor, with the upper hall is firmly connected. This means that the floor with the hall shell is rotatable. Objects set in the solar system hall and Vehicles can as possible be used space-consuming and also touch the walls of the solar system hall, without that this is damaging of the objects or vehicles leads. Because of the advantageous embodiment that the ground with the upper part is rotatable, no relative movement between the objects or Vehicles and the hall walls, may be a damage no longer occur due to the rotation of the upper part of the hall. Advantageous is thus that the entire storage space can be utilized to the maximum can. Even attaching shelves and feeding others shelves are possible without any problems. The walls can also to attach the for the generation of electrical energy necessary controls and Transformers are used and these installations can then also be installed in areas that are unfavorable or difficult for storage can be reached, for example, with a certain distance from the hall floor.

It is expressly pointed out that the solar system hall according to the invention also without ground 9 is fully functional and solves the problem underlying the invention.

A preferred embodiment has an anchoring, with the help of the upper part of the solar system hall can be anchored on the subframe. Such an anchoring can For example, be a device in a hook shape attached to the hall top is and at least partially surrounds a rail of the subframe. Preferably, such a hook-shaped Device attached in the range of a drive roller.

Yet another version provides that a stripping device is provided on the upper part of the hall is which surfaces over which the rotary drive of the upper part of the hall compared to the lower frame done by foreign bodies keeping clear. Such a stripping device can also be used as a scraper or as a shearing slide be designated. Can with her both larger items like for example, branches as well as snow, stones, etc. removed from the drive surface so that, on the one hand, pollution of the drive units avoided and on the other hand a trouble-free operation of the system preferably without manual control over one preferably long period allows becomes. Preferably, the stripper is on each side of each Drive unit, d. H. both on the front and on the back, intended. As a result, the drive unit is covered, whereby the underreaching is prevented. Thus, the security of the plant even further increased.

following The invention will be explained and described in more detail with reference to the drawings. Show it:

1 a front view of a solar system hall according to the invention;

2 a side view of the solar plant hall the 1 ;

3 a section along the line III-III in 1 ;

4 a section of the section of the 3 in detail;

5 a section of the 2 in detail;

6 a further detail of a solar system hall according to the invention in front view;

7 another detail in front view; and

8th yet another detail in front view.

The solar system hall according to the invention 1 has a bottom-mounted mountable base 2 and an upper shell rotatably mounted thereon 3 on. The hall top 3 has walls 4 on, wherein on at least one wall an opening 5 is provided for introducing objects to be stored in the hall, which accordingly can also be referred to as the insertion opening. The solar system hall 1 is shown herein as a roughly cuboid building based on a square base. However, it can also take any other form, for. B. a round shape or on a multiple corner, z. Hexagon. It is also a drive device 20 provided in more detail on the basis of 6 to 8th will be described.

The hall top 3 has a roof, this roof of a sealing roof skin 6 and solar modules mounted thereon 7 consists. The inventive distance between the solar modules 7 and the sealing roof skin 6 is in an embodiment by a corresponding substructure 8th achieved. It can be in such, for example, in the longitudinal direction, ie, extending from the lower edge of the roof to the upper roof edge plates, squared timbers or metal profiles, so that a corresponding spacing of the solar modules 7 from the sealing roof skin 8th can be achieved. Alternatively, it is provided that the required distance already by the appropriate selection of the sealing roof skin 8th itself is achieved. For example, trapezoidal sheet can be used, the z. B. has a height of 150 mm. The shape of the roof skin 8th conditioned here the ventilation effect.

The hall top 3 has a floor 9 up, between the walls 4 has been confiscated. In the sectional view of 3 became the ground 9 partially omitted, leaving the frame 10 it is apparent on the ground 9 is stored. The frame 10 is preferably additionally centered with the help of a bearing 16 stored. Because the floor 9 firmly with the upper part of the hall 3 is connected, the soil becomes 9 during a rotation of the hall upper part relative to the base frame 2 represented by the arrow 11 , also moved. Objects set in the hall 12 that in the representation of the 3 are indicated only schematically by a rectangle, can be adjusted by taking advantage of the full storage area. As for a specialist from the 3 is apparent, would be the setting of the object 12 to the corners 13 of the hall shell 3 without a rotating floor 9 not possible, because on the one hand the round rail 15 of the undercarriage 2 this would make it impossible and on the other a comparatively large distance to this rail 15 necessary, due to the rotational movement of the upper hall part. In the solar system halls of the prior art, objects to be stored can only be stored at a maximum in the area corresponding to the circle on which the walls are located 4 around the center of the solar system hall 1 rotate, shown as a dashed line 17 in the presentation of the 3 , In the hall upper part according to the invention 3 However, the entire storage room can be down to the corners 13 into, be fully exploited.

The drive of the hall upper part via a roller drive, wherein in the illustrated preferred embodiment, four pairs of rollers are provided, each consisting of a driven roller 21 and a passive role 22 , In 7 is a drive device 20 shown in detail. The round rail 15 of the undercarriage 2 is firmly mounted on the ground. On it are rolling over friction 21 with the help of a motor 23 driven.

The roles 21 are at the side in appropriate camps 24 stored. On it again is the upper hall part 3 assembled. In the illustrated embodiment, this is a scaffold made of metal profiles 25 of the hall shell. The hall top 3 however, it may be made of other materials and construction, such as wood, as will be readily apparent to one skilled in the art.

In 6 again a front view is shown on a drive device. 6 explains the structure and arrangement of both the anchoring device 30 as well as the stripping device 40 , where the 6A this device in its functional arrangement represents and the 6B and 6C the anchoring device 30 or the stripping device 40 represent as separate elements.

In the anchoring device 30 In the preferred embodiment, this is a planar element 31 at least one hook-shaped extension on at least one side 32 that has the round rail 15 at least partially encompasses. The hook-shaped extension 32 is preferred on the outside of the hall shell 3 provided so that when impinging from the outside wind pressure, indicated by the arrow 37 , the hook-shaped extension 32 a tilting of the hall shell 3 prevented. As wind and other disturbances experience shows, mainly from the outside of the solar system hall 1 acting, is usually the provision of a hook-shaped extension 32 before zugt on the outside of the solar system hall sufficient. However, it may also be provided on the inside of another hook-shaped extension, so that the round rail 15 is encompassed both from the inside and from the outside. The anchoring device 30 may also be designed differently, for example, it may be constructed of round rods, be designed as a casting or as a running storage.

At the stripping device 40 it is a sheet-like element that may be made of flat steel, for example. It points in the direction of the round rail 15 towards a cutting edge 41 on top of the top of the round rail 15 roams. This will dirt, snow and larger items from the round rail 15 removed, so that no disturbance of the rotational movement occurs. Because over time, a wear of the cutting edge 41 by the stripping movement over the round rail 15 will be done and also a height adjustment of the stripping 40 should be possible, this is correspondingly height adjustable. For example, as in 6 provided, oblong holes 42 be formed over the one height adjustment by means of a corresponding screw 43 can be done. From the representation of 6A will be apparent that the scraper 40 in front of a drive roller 21 respectively. 22 (see. 4 . 5 and 7 ) is attached. It is preferably provided that behind the drive roller, a further stripping device 40 is mounted. The scraper shields the drive roller 21 respectively. 22 from unauthorized access. Taking under the rollers is not possible, whereby the safety of the entire system is further improved.

In 8th is finally a device for position determination 50 shown. The solar system hall 1 has a control, with the help of the solar system hall 1 can be brought into a position which is referred to as Einbringposition in which objects can be introduced into the hall and removed from it. The change in position preferably takes place from outside, ie from outside the hall. For this purpose, a corresponding switchgear on the outside of the hall or separately outside the solar system hall is provided. The change in position can, however, for example, also be done by radio. The hall according to the invention rotates as a function of the relative position of the sun during the course of the day, wherein preferably an angle of approximately 270 ° is passed through. If the user of such a system would like to remove or insert devices, objects or vehicles from the solar system hall, the system is brought into the insertion position, to which the controller controls the relative position of the upper part of the hall 3 in relation to the base frame 2 must be known. For such a position determination is an incremental encoder 51 intended. A preferably rubber-tired wheel 52 is about a spring 53 on the round rail 15 of the undercarriage 2 pressed. The rubber-tired wheel 52 is about a wave 54 with the incremental encoder 51 connected. The incremental encoder 51 measures the actuating movement of the drive motor 23 and can thus pass the relative position to the controller.

According to the invention, it is further provided that sensors, in particular mechanical limit switches, are provided for the final positioning and referencing. This is the relative position between the upper part of the hall 3 and undercarriage 2 detectable in at least one angular position, so that a referencing can always be done again. Such recalibration is preferably daily. This ensures that the solar system hall is always optimally aligned to the sun over a longer period of time, depending on the time. Preferably, three limit switches are provided, of which z. B. one each in the south, east and west can be mounted.

A further embodiment of the invention provides that an anemometer is provided, whose data is reported to a controller. From a specifiable wind strength, the solar system hall 1 then automatically placed in a position so that the wind can cause as little damage to the hall. The hall is turned as far as possible into the wind, so that the wind does not attack from the side, at which the entry opening 5 but in front of the side on which the solar panels 7 are fixed in 2 through the arrow 14 indicated.

1

Solar plant hall

2

undercarriage

3

Hall shell

4

wall

5

opening

6

roof

7

solar module

8th

substructure

9

ground

10

frame

11

arrow

12

object

13

corner

14

arrow

15

RoundTrack

16

camp

17

line

20

driving means

21

driven role

22

passive role

23

engine

24

camp

25

framework

30

anchoring device

31

flat element

32

hook-shaped extension

37

arrow

40

stripper

41

cutting edge

42

Long hole

43

screw

50

contraption for position determination

51

incremental encoder

52

wheel

53

feather

54

wave

Claims (15)

Depending on the relative position of the sun in the course of the day, trackable solar energy hall ( 1 ), which consist of a floor-mountable underframe ( 2 ) and an upper shell rotatably mounted thereon ( 3 ), whereby on the upper part of the hall solar modules ( 7 ), wherein the upper hall part walls ( 4 ), which form the hall, and at least one opening ( 5 ) for introducing objects to be stored in the hall ( 12 ) and / or vehicles, and wherein a drive device ( 20 ) is provided which rotatably drives the upper hall part, characterized in that on the upper part of the hall a sealing roof skin ( 6 ) is provided, on which the solar modules are fastened with a certain distance from the roof skin, wherein the distance between the roof skin and the solar modules is dimensioned so that a ventilation of the solar modules takes place. A trackable solar system hall according to claim 1, characterized in that the hall has a floor ( 9 ), which is fixedly connected to the upper hall and rotatable with this. Trackable solar system hall according to claim 2, characterized in that the hall floor is mounted in the region of its center, in particular via a bearing ( 16 ). Traceable solar system hall according to one of the preceding claims, characterized in that the drive via friction by means of rollers driven on the base ( 21 ), wherein in particular a plurality of driven rollers are provided. A trackable solar system hall according to claim 4, characterized in that in front of at least one of the rollers ( 21 . 22 ) in particular before each roller a stripping device ( 40 ), which keeps the underframe free of foreign bodies. Traceable solar system hall according to one of the preceding claims, characterized in that an anchoring device ( 30 ) is provided, with which an anchoring of the hall upper part is achieved on the base. Traceable solar system hall according to claim 6, characterized in that the anchoring device is a hook-shaped extension ( 32 ) or that the anchoring device is a hook, which in the region of at least one drive roller ( 21 . 22 ) is attached to the upper part of the hall and a rail ( 15 ) of the underframe partially surrounds. A trackable solar system hall according to one of the preceding claims, characterized in that a position determining device ( 50 ) is provided, with the aid of which the position of the hall upper part in relation to the base frame can be determined. A trackable solar plant hall according to claim 8, characterized in that the position determining device comprises an incremental encoder ( 51 ), which via a shaft ( 54 ) with a wheel running on the base ( 52 ), in particular a rubber-tired wheel, so that a change in the position of the wheel relative to the underframe is detected by the rotary encoder. Traceable solar system hall according to claim 9, characterized in that the wheel via a spring ( 53 ) is pressed against the base. trackable Solar system hall according to one of the preceding claims, characterized characterized in that the roof skin is made of sheet metal or fiber cement. trackable Solar system hall according to one of the preceding claims, characterized characterized in that the distance between the roof skin and the solar modules between 5 cm and 40 cm. trackable Solar system hall according to one of the preceding claims, characterized characterized in that the upper part of the hall and the lower frame at least each a limit switch is provided, with the aid of a referencing and determination of the absolute position of the upper hall part is possible. Traceable solar system hall according to one of the preceding claims, characterized in that the hall upper part can be brought into a position in which an introduction of the objects to be stored and / or vehicles can take place, wherein the control for the position change from the outside of the solar system hall. trackable Solar system hall according to one of the preceding claims, characterized in that an anemometer is provided whose data be reported to a controller, the solar system hall off a predetermined wind strength can be moved to a position so that the wind is as possible minor damage to the hall can cause.