DE202014100961U1 - Solar Panel System - Google Patents

Abstract

Solar module system (2) with a support frame (6), comprising a lower, flat support base (8) and a vertical support (14), and with an inclined solar module (4) which at its lower end on the support frame (6) and on The upper end is fastened to the support (14), characterized in that a holder (16) fastened to the lower end of the solar module (4) is clamped in the supporting base (8) by tilting, and the solar module (4) is thereby clamped along the supporting base ( 8) fixed.

Description

The invention relates to a solar module system with a support frame, comprising a lower, planar support base and a particular vertical support, and with a tilted solar module, which is fixed at its lower end to the support frame and at its upper end to the support.

Flat roof solar module systems or outdoor solar module systems are equipped with a support frame, with which they are attached to the flat roof or to the ground. Usually, the support frame comprises a lower, flat support base which rests on a flat roof on bitumen, gravel or an underlying mat or in the field on a foundation. Since the solar modules are aligned obliquely according to the position of the sun, a support is usually present, which holds one or more solar modules at its upper end. When installing such a solar module system, the solar module must be attached to both the support base and the support. For this purpose, the individual solar module is placed on both units, adjusted and screwed.

It is an object of the present invention to provide a solar module system which is easily mountable on a flat surface such as a flat roof or a flat foundation.

This object is achieved by a solar module system of the aforementioned type, in which according to the invention a holder fastened to the lower end of the solar module is clamped in the support base by tilting and thereby fixes the solar module along the support base. By clamping a sufficient lower mounting of the solar module can be achieved on the support base, which can be dispensed with a screw, riveting or similar elaborate attachment methods. The solar modules can be fixed quickly and inexpensively in this way, with a long-term stable attachment is achieved.

The solar module system is expediently a flat roof system or outdoor system. The support base is used for support and / or mounting on a level surface. The support supports the solar module in its inclined position. In this respect, the support frame with its support base and the suitably vertical support reliably holds the solar module in its position relative to the support frame. The support base can rest on a bituminous substrate, on gravel or on a mat, wherein a foundation is also possible, in particular for outdoor installation. An attachment of the support frame or the solar module system to the ground is possible, but is not mandatory. It depends on the background and wind conditions as well as the geometry of the solar module system or several solar modules to each other.

The holder is expediently attached to the module frame of the solar module, in particular at the lower end of the module frame. He fixes the solar module along the support base and thus blocks movement of the lower end of the solar module along the support base.

In an advantageous embodiment of the invention, the lower support base on a C-profile rail, in the cavity of the holder is inserted. It can be achieved a simple assembly of holder and support base, through which the assembly is facilitated. The cavity refers to the C-profile shape and is thus encompassed by the C-shape. The arrangement of the C-profile is advantageously such that the "C" is on the back, so the profile ends are up and the opening facing upwards. The rail can be an anchor rail, in particular a Halfen rail, which can be dispensed with the usually existing anchor for floor mounting, depending on the design of the modular system.

A very stable fixation by the tilting can be achieved if the holder is tilted from above and below the two profile ends of the C-profile. As a result, jamming of the two profile ends can be achieved by tilting, so that the jamming is very strong and stable. The profile ends refer to the C-shape and not to the length of the profile along its axial direction. In this respect, the two profile ends can be towards each other or away from each other pointing legs of the C-profile, which extend over the entire length of the profile bar.

In an advantageous embodiment, the holder is a sheet projecting down over the module. This can be fixed flat on the lower end of the module frame, for example, be screwed. It advantageously has two recesses, in each of which a profile end of the C-profile can engage, and a thickening, which is inserted into the cavity of the C-profile.

In order to achieve a very simple assembly, it is further proposed that the holder is arranged on the solar module and shaped so that the tilting is effected by lifting the solar module at its upper end from an at least substantially horizontal position in the inclined position. The holder may expediently in the at least substantially horizontal position of the solar module, to which the holder is advantageously immovably already attached, in the profile of the lower support base be retracted without tilting. If the lower end of the solar module has reached its final position along the support base, the upper end can be raised, whereby the holder is tilted on the support base and thus the position of the lower end of the solar module is fixed to the support base. Advantageously, the tilting takes place by a rotation of the holder about a horizontal and perpendicular to the support base oriented axis of rotation.

In order to achieve a vibration-proof fixation of the solar module to the support base, it is further proposed that the holder is cut into the support base. For this purpose, it expediently comprises one or more edges, which are cut into the support base. The cutting takes place, for example, by tilting or jamming of the holder on the support base and / or by a force which presses the holder onto the support base in the longitudinal direction of the solar module.

The cutting can be accomplished during assembly in a very simple manner, when the holder is pressed by the solar module in the direction of the longitudinal orientation of the solar module in the support base and thereby and / or the jam is cut into the support base. The pressing can be done by a distortion of the solar module in the support frame.

Sufficiently deep cutting of the holder into the support base is favored if the holder is made of a material, in particular metal, which is harder than the metal of the support base. A suitable material combination is a soft metal, for example aluminum, and a hard metal, for example steel, brass or the like.

In solar modules over one meter long, it is advantageous if they are supported again between the holder and support, expediently at least approximately halfway between the holder and support. Such support can be achieved simply and inexpensively by a holder support, which supports the solar module from below and clamped in the support base by tilting and thereby fixed along the support base.

The mounting can be kept simple if the holder support is fastened to the lower support base in the same way as the holder.

Advantageously, an intermediate layer is arranged between an upper bearing surface of the holder support and the solar module, which counteracts slippage of the holder support and solar module to each other. Suitable is a rubber layer, e.g. a piece of a rubber mat, especially the rubber mat under the support base.

In a further advantageous embodiment of the invention, the holder is made of a continuous casting profile. As a result, a edge of the holder can be omitted at its upper end, whereby costs are saved. The same applies to the holder support, wherein holder and / or holder support can be made of a continuous casting profile.

The invention is also directed to a solar module system having a support frame having a lower, planar support base ( 8th ) and a vertical support. The solar module system also includes a tilted solar module, which is attached according to the invention at its lower end to the support frame and at its upper end to the support. This expression can be combined with all the details described above and below.

In an advantageous embodiment, it is proposed that the support of the support frame is fixed in the support base. The fixation is particularly advantageous by jamming the support in the support base. A stable combination of solar module and support frame can be achieved.

A particularly simple installation of the support can be achieved if the jamming is done by rotating the support about the axis of the support. For this purpose, the support expediently comprises on the jammed in the support base element two flat surfaces which rest in the clamped state flat to two inner surfaces of the support base. As a result, when locking and tilting a latching operation can be achieved so that the support is locked in the support base and thus reliably held in position.

Another way to attach the support to or in the support base is the jamming by tilting about a rotation axis perpendicular to the support base and the support. For example, the support may be inserted obliquely to the support base in a cavity of the support base and jammed by the upright in the support base. If the support base comprises, for example, a C-profile, the support can be introduced obliquely into this profile and raised upwards, whereby the clamping takes place in the cavity of the C-profile.

A stable attachment of the solar module in the support frame can be achieved if the solar module, the support and the support base form a triangular composite.

In a further advantageous embodiment of the invention, the solar module is pressed at its upper end by a clamping element on the support down and thereby the holder is cut into the support base. In particular, the formation of a triangular composite is at this Embodiment greatly facilitated. The solar module can be clamped in the support frame and thereby secured long-term stable.

A particularly simple and inexpensive embodiment of the support is realized by a tube which is flattened at the lower end. For example, the support may have a tube which is compressed at its lower end into a plate. Advantageously, the plate is cut on both sides and guided with each incision about a leg of a C-profile of the support base, which forms a profile end of the C-profile.

A stable module assembly can be achieved by two solar modules are arranged on both sides of the support and held symmetrically by this. The solar modules are expediently opposite to each other in their orientation, so that a gable roof shape is formed. As a result, the solar module system becomes less prone to wind, pushing the system down onto the flat floor or roof. The force of the support down is expediently derived on both sides symmetrically in the two modules. The two modules form with the support system expediently a double triangle network.

The solar module can be a PV module for photovoltaic power generation or a thermosol module for generating heat by solar radiation. Both modular types have lines, either electrical or liquid lines, which are connected to the interior of the solar module. An externally protected secure arrangement of the lines can be achieved if the support carries an upwardly open shell profile, in the shell of which is connected to the solar module line. The upwardly facing opening is expediently covered at least predominantly by a plate or one or two solar modules, whereby the lines are particularly well protected. Under a shell profile can be understood a profile bar with a cup-shaped profile, in which an electrical or fluid line can be inserted.

Advantageously, the support carries a profile with a support leg on which the solar module rests. The profile may be a shell profile and have a different profile shape and expediently comprises a support leg for surface placement of the solar module. In a shell profile, the support leg can form the upper edge of the shell.

Advantageously, an identical profile is arranged above the profile, which rests with the underside of the support leg on the solar module and pulls it down. Due to the identical profiles, a variety of accessories and thus assembly costs can be kept low. The identity is to be seen in relation to the profile shape and not necessarily to the length of the profiles.

The support can be kept simple and costs can be saved if the support has a tube in the upper end of which a threaded element, such as a screw, a threaded rod or the like, is screwed. A nut on the screw or on the threaded rod conveniently pulls the solar module down, with another thread-fixable or fixed element, such as the head of the screw, being equivalent to the nut.

The invention also includes a method for setting up a solar module system. According to the invention, a holder fastened to a solar module is inserted into a rail of a flat support base, the solar module is pulled upwards at its upper end and the holder is thereby jammed in the support base by tilting. The solar module is advantageously attached at its upper end to a support. In this way, the solar module can be stably fixed, in particular in the support frame, whose part is the support base and in particular the support, and are braced.

The previously given description of advantageous embodiments of the invention contains numerous features, which are given in the individual subclaims partially summarized in several. However, those skilled in the art will conveniently consider these features individually and summarize them to meaningful further combinations. In particular, these features can be combined individually and in any suitable combination with the solar module system according to the invention and the method according to the invention.

The above-described characteristics, features and advantages of the invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of several embodiments, which will be explained in more detail in conjunction with the drawings. The embodiments serve to illustrate the invention and do not limit the invention to the combination of features specified therein. In addition, suitable features of the embodiments may also be considered explicitly isolated and combined with any of the claims.

Show it:

1 a solar module system for flat roof installation with several slanted, each other like a pitched roof opposite solar modules in a schematic side view,

2 a section of the lower part of the right solar module 1 in its edition on a lower support base,

3 an enlarged section 2 showing an upper leg of the support base to which the solar module is attached with a holder,

4 a front view of the made of an aluminum profile support base 3 with the holder and the solar module fastened therein,

5 the solar module, the holder and the support base are shown in a section from above,

6 the two upper ends of the solar modules, which are supported by a vertical support,

7 the lower part of the support in its fixation in the lower support base,

8th a section through the support base and the lowest part of the support 7 and

9 the left solar module off 1 centrally supported by a holder support.

1 shows a solar module system 2 with a number of solar modules 4 , which are each arranged in pairs in a gable roof formation and by a support frame 6 are held in a double triangle combination. You can see it in 1 only one pair of solar modules arranged opposite 4 However, there are several other pairs present in 1 lie behind the first and shown pair and therefore are not visible.

The supporting frame 6 comprises a number of lower support bases 8th on a flat roof 10 rest. The flat roof 10 is up with a rubber mat 12 provided, on which the carrying bases 8th immediately rests. As an alternative to the rubber mat, a bitumen layer or a gravel layer or both may be present. The support base is an anchor rail in the form of a Halfen rail, but without anchor, as they only on the flat roof 10 or his rubber mat 12 rests. An attachment of the support bases 8th on the flat roof 10 or the rubber mat 12 is possible, for example with anchors to the support base, which are fixed in the flat roof. In the embodiment 1 However, was omitted on a fixture, so that the positioning of the solar module system 2 on the flat roof 10 done by a mere resting. Due to the gable roof geometry, this positioning is also very stable in wind position, as the wind is the solar module system 2 down to the flat roof 10 suppressed.

The supporting frame 6 further comprises a number of supports 14 , each in a lower support base 8th and are secured at the upper end of each one solar module pair. In 1 is only a prop 14 to see, with several pairs of solar modules 4 in 1 are arranged one behind the other and each of two support bases 8th and two supports 14 be worn. Between two in 1 one behind the other arranged solar modules 4 So each is a support base 8th and a prop 14 arranged so that the supports 14 are each arranged on the abutting surfaces of the solar modules. The following is just a couple of solar modules 4 with both sides a support and a support base 8th without limiting it to only two solar modules 4 would be associated.

The solar modules 4 are at their upper end on the prop 14 attached and at its lower end to the support base 8th , The lower attachment is made by a holder 16 who in 2 and 3 is shown in more detail.

While in 1 the carrying bases 8th with the reference number 8th are designated, they are in 2 With 8a , in 4 With 8b and in 7 With 8c Mistake. The following is indeed between the support bases 8a . 8b and 8c However, large parts of the description of the figures can be read in all embodiments, so that in all embodiments equally applicable descriptions for the sake of simplicity only the reference number is given, eg " 8th ", In which case all embodiments are meant equally.

In 2 and 3 is shown that the holder 16 An upwardly folded sheet of stainless steel is flat on the bottom of a module frame 18 screwed on, which is the active element of the solar module 4 surrounds. At the top, the holder surrounds 16 the module frame 18 so that a tight fit is achieved. At the bottom is the holder 16 over the module frame 18 out and reach into the support base 8th one. Alternatively, the holder 16 consist of a continuous casting profile, for example made of aluminum. As a result, the edge can be omitted and it can already from the profile shape out a clean support on the frame 18 be achieved.

The support base 8th is a profile bar, for example, aluminum in the form of a continuous casting profile, for example, has the shape of a C-profile, as the support base 8a out 2 , or at least contains, as the support bases 8b out 4 and 8c out 7 in which the back of the C-profile is after points down, for example, on the floor or the rubber mat 12 rests, and the two legs or profile ends 28 project upwards so that the C-profile is open at the top. In the embodiments of 4 and 7 the C-profile is supplemented on the sides and down by other profile elements, the essential C-profile shape for embracing the holder 16 also preserved here.

The shape of the holder 16 can also out 4 and 5 be seen. 4 shows the holder 16 in the direction of the support base 8b and 5 shows a plan view of the lower end of the solar module 4 and the holder 16 , You can see the module frame 18 that the solar module 4 from the bottom, the holder 16 and the support base 8b from above into the cavity 24 , The holder 16 surrounds two solar modules 4a . 4b at the point of their abutment surface, where they are adjacent to each other. The at the ends of the solar module system 2 arranged holder 16 however, only encompass the outermost solar module 4 ,

The holder 16 has an upper part 20 laying flat on the module frame 18 rests and is attached to this, and a lower part 22 in the cavity 24 the C-profile of the support base 8th intervenes. The two parts 20 . 22 are separated on both sides by recesses, in which the upper end legs or profile ends 28 the C-profile of the support base 8th intervention. The two parts 20 . 22 thus embrace the two upper profile ends 28 the C-profile of the support base 8th on both sides, in this embodiment, above and below.

To create a stable triangular composite of solar module 4 , Support 14 and support base 8th to reach is the holder 16 by tilting at the support base 8th it jams and fixes the solar module 4 along the axial direction 26 the support base 8th , In addition, the holder 16 in the opposite to the holder 16 softer metal of the support base 8th cut and thus against slippage in the axial direction 26 secured, as in 3 indicated and explained below.

When installing the solar module system 2 becomes their holder 16 on the lower end of the module frame 18 screwed. Subsequently, the solar module 4 flat on the lower support base 8th hung up so that the support base 8th and the solar module 4 are level. Now the holder can 16 with its lower part 22 in the cavity 24 the profile shape of the support base 8th be introduced from the side. In the same way with the opposite solar module 4 so that both solar modules are flat on the support base 8th rest, and then one of the solar modules 4 one piece over the other is pulled over, so that the two solar modules overlap a piece. The length of the overlap is determined by the angle α, the solar modules 4 with the flat roof 10 or the support base 8th should form. The larger the angle α, the larger the overlap.

Now the two solar modules 4 each pulled at its upper end in the height, so that the holder 16 skewed in profile, as in 2 and 3 is shown. Then the upper ends of the solar modules can 4 at the in the support base 8th used support 14 be attached.

By tilting the holder 16 at the support base 8th tilted the holder 16 around the two upper profile legs 28 the support base 8th , as in 3 you can see. Here, the width of the two-sided recesses between the upper part 20 and the lower part 22 so dimensioned that the upper part 20 from above and the lower part 22 from below into the profile legs 28 be pressed. The holder 16 notches so far up and down a bit in the two profile legs 28 one. Now become the two solar modules 4 pressed apart and thereby clamped, as will be explained later, a force acts from the solar modules 4 on the support base 8th , In 2 and 3 is that a force along the solar module 4 from diagonally above to diagonally below and into the support base 8th into it. This will be the holder 16 from the perspective of 2 and 3 pressed a little way to the right and cuts in addition to the dimension-related notch from above into the support base 8th a, like in 3 is indicated. This creates a very strong bond between the solar module 4 and support base 8th , which is long-term stable and later also nachspannbar.

The support 14 is in the 6 and 7 shown in more detail. The support 14 includes a tube 30 such as stainless steel, at its lower end 32 is flattened. At its upper end is a clamping unit 33 arranged, which are the two upper ends of the solar modules 4 pulls down.

The clamping unit 33 includes several elements: In the pipe inside a female thread cut into which a threaded element 34 , For example, a threaded rod is screwed. The threaded element 34 is through two shell profiles 36 led by nuts 38 on the threaded element 34 are fixed. The lower shell profile 36 lies down on the top of the support 14 up and down through the lower mother 38 fixed on this.

In the embodiment 6 are both shell profiles 36 formed exclusively of a profile bar with the profile of a shell, the upwardly two outwardly aligned support legs 40 contains. But there are others too Profile forms conceivable in which in addition to the shells further profile elements are present without the principle of the shell profile would be displaced by this. The support legs 40 may be directed outwards and / or inwards.

On the two support legs 40 of the lower shell profile 36 lies in each case the upper end of one of the solar modules 4 on and thus through the corresponding support leg 40 carried. The upper shell profile 36 is with its support legs 40 from the top to the top of the two solar panels 4 hung up and by the mother 38 down on the threaded element 34 pulled and thus clamps the two upper ends of the two solar modules 4 between itself and the lower shell profile 36 one. In this way, the two upper ends of the solar modules 4 pulled down and pressed with their lower ends apart or kept at a distance, so that the solar modules 4 down into the support base 8th inculcate force. The two solar modules 4 are firm with the prop in this way 14 and the support base 8th clamped and immovably fixed.

For better positive retention of the module frame 18 on the shell profiles 36 can the thighs 40 each be provided with one or more formations in the module frame 18 intervene inside, as in 6 is shown. A slipping down of the solar module 4 from the thigh 40 of the lower shell profile 36 can be counteracted this way. At the in 6 embodiment shown is the module frame 18 from above and below from the formations on the thighs 40 embraced so that the resulting positive fit the module frame 18 grasps us on both sides.

Along the axial direction of the lower shell profile 36 and / or the upper shell profile 36 are lines 42 led the corresponding solar module 4 connect to a utility. The wires 42 In the case of a PV module, these can be electrical lines or, in the case of a thermosol module, liquid lines. The wires 42 are protected against external influences and safely guided. For further protection, the cavity 44 of the upper shell profile 36 through a cover plate 46 be closed, as in 6 is shown.

At its lower end is the flattening 32 the prop 14 shaped like the holder 16 , Here, too, are an upper part 48 and a lower part 50 present, which are spaced apart by lateral recesses. The lower part 50 is in the cavity 24 the support base 8th introduced and the two parts 48 . 50 grip the two on both sides between the two parts 48 . 50 protruding profile ends 28 the support base 8th ,

For fixing the support 14 at the lower support base 8th There are two options that can be used individually or together. Especially easy is the lower part of the support 14 by 90 ° to the presentation 7 around the longitudinal axis of the column 14 twisted from the top into the cavity 24 the support base 8th be introduced. By twisting into a position as in 7 shown, now clamped the lower part 50 in the cavity 24 and thus fixes the lower part of the support 14 in the support base 8th , This is in 8th indicated.

Is now the width of the lower part 50 so measured that they are quite accurate in the width of the cavity 24 fits in and a twisting by a diagonal position of the part 50 a deadlock between the sidewalls of the cavity 24 effects, so bringing into the position, as in 8th shown a snap of the lower part 50 in the cavity 24 or effect between its side walls. Conveniently, in this case the width is exactly the distance between the side walls or a few hundredths of a millimeter wider, so that a firm locking and jamming takes place. As almost no longitudinal forces along the axial direction 26 on the prop 14 act, this attachment is in the support base 8th sufficient.

Another option is to lower the support 14 in the cavity 24 or the support base 8th insert analogous to the holder 16 , So this is the support 14 not vertically inserted, but folded a little way down, so that the lower part 50 in the cavity 24 is insertable and the two parts 48 . 50 the profile ends 28 embrace top and bottom. By erecting the support 14 Now the lower part expands 50 upwards or downwards and clamps up and down between the two profile ends upwards and the lower part of the C-profile, so that a stable attachment is achieved.

At the profile of the support base 8c out 7 are lower thighs 52 pulled over the remaining profile width, so that on a randbeschwerung 54 can be placed, eg concrete slabs. This makes sense in a roof edge area in which there may be turbulent air flows that affect the solar module system 2 can lift. The surcharge of the edge weight presses on the lower legs 52 the support base 8c and keeps them reliably on the ground, the flat roof 10 or the rubber mat 12 ,

9 shows the left part 1 supplemented by a support post 56 that the solar module 4 something in the middle between holder 16 and prop 14 supported from below. For long solar modules 4 above 1 m, the snow load can lead to an undesirably large deflection, so that a support between the holder 16 and prop 14 makes sense. At the in 9 embodiment shown are the solar modules 4 1.7 m long and angled at 15 ° to the horizontal, so flat that snow does not slide down easily.

The support post 56 is in the support base 8th in the same way as the holder 16 jammed by tilting and thereby along the support base 8th fixed. The lower part of the support post 56 So it's the same as the holder 16 shaped and identically in the support base 8th tilted and cut, leaving the descriptions too 2 and 3 analogous to the support post 56 can be read. In this way, all solar modules 4 all module pairs in the middle by support columns 56 supported from below, with the support posts 56 from below to the module frame 18 issue. Analogous to the holders 16 and the supports 14 also supports a support post 56 two solar modules 4 and is thus under the butt joint between the solar modules 4 arranged.

The support post 56 may be a sheet that is folded upwards, so that a holding surface is formed, which is the upward-facing orientation of the support post 56 bends. Particularly easy is the holding surface, if as a support post 56 a continuous casting profile is used, which is already drawn with the kinking holding surface. Conveniently, the sheet thickness or profile thickness of the support post 56 thicker than the holder 16 because a relatively long distance from the support base 8th to the solar module 4 must be overcome.

Between holding surface and solar module 4 is an intermediate layer 58 arranged in the form of a rubber pad, by the sliding of the holding surface on the solar module 4 counteracted. The rubber pad is made of the material of the rubber mat 12 also manufactures and cushions the solar module 4 against the possibly sharp-edged holding surface of the support post 56 from. Alternatively or additionally, the holding surface on the solar module 4 be glued directly or indirectly.

LIST OF REFERENCE NUMBERS

2

Solar Panel System

4a, b

 solar module

6

supporting frame

8a-c

 support base

10

flat roof

12

rubber mat

14

support

16

holder

18

module frame

20

part

22

part

24

cavity

26

axially

28

profile end

30

pipe

32

flattening

33

clamping unit

34

threaded element

36

shell profile

38

mother

40

supporting leg

42

management

44

cavity

46

cover

48

part

50

part

52

leg

54

Randbeschwerung

56

holding support

58

 interlayer

α

angle

Claims (21)

Solar module system ( 2 ) with a support frame ( 6 ), comprising a lower, planar support base ( 8th ) and a vertical support ( 14 ), and with a tilted solar module ( 4 ), which at its lower end on the support frame ( 6 ) and at its upper end to the support ( 14 ), characterized in that one at the lower end of the solar module ( 4 ) attached holder ( 16 ) in the support base ( 8th ) is jammed by tilting and thereby the solar module ( 4 ) along the support base ( 8th ) fixed. Solar module system ( 2 ) according to claim 1, characterized in that the lower support base ( 8th ) has a C-profile rail, in the cavity ( 24 ) the holder ( 16 ) is introduced. Solar module system ( 2 ) according to claim 2, characterized in that the holder ( 16 ) from above and below around the two profile ends ( 28 ) of the C-profile is tilted. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the holder ( 16 ) down over the solar module ( 4 ) is protruding sheet metal. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the holder ( 16 ) so on the solar module ( 4 ) is arranged and shaped, that the tilting by lifting the solar module ( 4 ) has taken place at its upper end from an at least substantially horizontal position in the inclined position. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the holder ( 16 ) in the support base ( 8th ) is cut. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the holder ( 16 ) through the solar module ( 4 ) in the direction of the longitudinal orientation of the solar module ( 4 ) in the support base ( 8th ) and by the tilting in the support base ( 8th ) is cut. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the solar module ( 4 ) between holders ( 16 ) and supported ( 14 ) is supported by a holder support from below, in the support base ( 8th ) jammed by tilting and thereby along the support base ( 8th ) is fixed. Solar module system ( 2 ) according to claim 8, characterized in that the holder support in the same way to the lower support base ( 8th ), like the holder ( 16 ). Solar module system ( 2 ) according to claim 8 or 9, characterized in that the holder ( 16 ) and the holder support are continuous casting profiles. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the support ( 14 ) in the support base ( 8th ) is jammed. Solar module system ( 2 ) according to claim 11, characterized in that the jamming by twisting about the axis of the support ( 14 ) is done. Solar module system ( 2 ) according to claim 11 or 12, characterized in that the jamming by tilting about an axis of rotation perpendicular to the support base ( 8th ) and to support ( 14 ) is done. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the solar module ( 4 ), the support ( 14 ) and the support base ( 8th ) form a triangular composite. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the solar module ( 4 ) at its upper end by a clamping unit ( 33 ) on the support ( 14 ) pressed down and thereby the holder ( 16 ) in the support base ( 8th ) is cut. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the support ( 14 ) has a tube which is flattened at the lower end, and the plate ( 32 ) incised on both sides and with the incision around the legs ( 28 ) of a C-profile of the support base ( 8th ) is guided. Solar module system ( 2 ) according to one of the preceding claims, characterized in that two solar modules ( 4 ) on both sides of the support ( 14 ) are arranged and held symmetrically by this. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the support ( 14 ) an upwardly open shell profile ( 36 ), in whose shell one with the solar module ( 4 ) connected line ( 42 ) lies. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the support ( 14 ) a profile with a support leg ( 40 ) on which the solar module ( 4 ) rests. Solar module system ( 2 ) according to claim 19, characterized in that above the profile an identical profile is arranged, which with the underside of the support leg ( 40 ) on the solar module ( 4 ) and pulls it down. Solar module system ( 2 ) according to one of the preceding claims, characterized in that the support ( 14 ) has a tube in whose upper end a threaded element ( 34 ), whose mother ( 38 ) the solar module ( 4 ) pulls down.

Images