CH718395A2 - Holding device for solar modules. - Google Patents

Abstract

The invention relates to a holding device for holding solar modules (15a, 15b) on a roof, a surface or a supporting structure, having a plurality of horizontal profiles arranged at a first spacing, a plurality of vertical profiles (13) arranged at a second spacing, the horizontal profiles and vertical profiles (13) are arranged at right angles to one another and form grid-like free spaces, with a solar module (15a, 15b) being able to be detachably held in a free space by the profiles, a first holding profile (51) which is attached to the vertical profile (13) in an assembly position can be latched and forms a receptacle for a solar module (15a) and a fixing element (69) which fixes the first retaining profile (51) on the vertical profile (13) in the assembly position. The first (51) and a second holding profile (53) are symmetrically latched to the vertical profile (13). The first retaining profile (51) has a first locking element and the second retaining profile (53) has a second locking element, which locking elements interact with a first and a second groove of the vertical profile (13). The widths of the grooves are greater than the widths of the locking elements.

Description

field of invention

The invention relates to a holding device for holding solar modules on a roof, a surface or a supporting structure.

State of the art

Holding devices for solar modules are known from the prior art, which make it possible that a roof is covered with solar modules. Such systems are referred to as "in-roof systems" in contrast to "on-roof systems". With the on-roof systems, the solar modules are attached to an existing roof and the solar modules only take over the function of electricity production. In addition to generating electricity, the in-roof systems also assume the function of covering the roof with an existing, tight roof membrane. In addition, they give the roof an aesthetic appearance.

[0003] In the field of in-roof systems, there are also holding devices which can hold frameless solar modules. The use of frameless solar modules has the advantage that material can be saved and the investment costs can be reduced compared to framed solar modules.

It is also envisaged that the solar modules are releasably held on the holding device. However, the solution and the re-attachment of the solar modules to the holding device is complex and only possible with additional tools and is therefore not very user-friendly.

In connection with this application, the term "solar module" should be understood to mean both framed and frameless modules (laminates).

object of the invention

From the disadvantages of the described prior art results in the task of creating a carrying device for solar modules that allows rapid tool-free attachment and detachment of the solar modules from the holding device.

Another object is that the holding device is suitable for solar modules with different strengths and can compensate for unevenness and tension.

description

The solution of the task is achieved with a holding device for holding solar modules on a roof, a surface or a structure by the features listed in the characterizing section of claim 1. Further developments and/or advantageous embodiment variants are the subject matter of the dependent patent claims.

The invention is preferably characterized by a second retaining profile, the first and the second retaining profile being latched symmetrically to the vertical profile, the first retaining profile having a first latching element and the second retaining profile having a second latching element, which are provided with a first or a second groove of the vertical profile and the widths of the grooves are greater than the widths of the locking elements. The two holding profiles hold solar modules symmetrically on the vertical profile. Together with the vertical profile, the retaining profiles form a receptacle for the edges of the solar modules. The receptacle has a flexible height, which is realized in that the widths of the grooves are greater than the widths of the locking elements. As a result, unevenness in the subsurface can be compensated for, tension and thermal expansion can be compensated for and solar modules with different thicknesses or heights can be mounted on the holding device. The special dimensioning of grooves and latching elements makes it possible for the retaining profiles to be held on the vertical profile not only in a form-fitting manner but also in a friction-locking manner over the entire length of the vertical profile. The retaining profiles are therefore held "floating" on the vertical profile.

In a particularly preferred embodiment of the invention, the first and the second holding profile have an L-shaped cross section and the cross sections of the holding profiles are symmetrical with respect to an imaginary vertical. The retaining profiles can be clamped symmetrically to the vertical profile with a fixing element and can be produced inexpensively due to their simple structure.

It proves to be advantageous if the holding profiles have a first vertical leg and a second horizontal leg, the first leg thickening in the direction of its open end. The shape of the first leg allows the holding profiles to be reliably clamped to the vertical profile.

The heights of the locking elements are expediently equal to the depths of the grooves. This enables the holding profiles to be reliably held on the vertical profile.

It has proven to be advantageous if a third groove is formed on the first limbs at the transition to the second limbs and the edge between the first and second limbs is rounded. The fixing element can be reliably latched in the third grooves, as a result of which an unintentional loosening of the fixing element is prevented. The rounded edges make it easier for the fixing element to latch in the third grooves.

In a particularly preferred embodiment of the invention, the ends of the holding profiles arranged on the vertical profile cooperate with a first and second fixing element, which fixing elements can be inserted between the first legs and the holding profiles are thereby pressed against the vertical profile. As a result, a holding connection for holding the solar modules can be produced quickly and without tools by simply pushing in the fixing elements at the ends of the holding profiles. The fixing elements can be pulled out of the holding profiles just as quickly, in order to enable the solar modules to be dismantled, for example for maintenance purposes.

It has proven to be expedient if the fixing element is T-shaped with a longitudinal leg and a transverse leg and a plurality of wedge-shaped lamellae is formed on the underside of the longitudinal leg. This allows a reliable clamping effect to be produced between the fixing element and the holding profiles. The transverse leg forms a clean and flush finish with the second leg of the retaining profile.

In a further preferred embodiment of the invention, a latching lug is formed on the fixing element on the transverse leg opposite the longitudinal leg. This latching lug can be pushed in at an angle from above onto a horizontal profile adjoining the vertical profile, and the fixing element can then be folded between the retaining profiles. A flush transition between the second legs and the upper side of the horizontal profile is formed by the fixing element.

The first and second retaining profile are expediently longer than the vertical profile. As a result, the holding profiles can protrude over the horizontal profiles and cover the edges of the horizontal profile.

As stated above, it is preferred if the second leg of the retaining profiles are planar in the assembled position with the top of the horizontal profiles. As a result, an aesthetic and, with the exception of the space between the holding profiles, a gap-free surface is formed on the upper side of the holding device together with the held solar modules.

In a particularly preferred embodiment of the invention, the horizontal profile has a first lower and second upper receptacle for adjacent solar modules, the first receptacle being delimited by a first retaining bar, the second receptacle being delimited by a second retaining bar and the first retaining bar having a has a greater width than the second web, whereby the first recording has a greater depth than the second recording. This dimensioning of the first and second holding receptacle enables a solar module to be quickly installed between two adjacent horizontal profiles. To do this, the upper edge of the solar module is inserted diagonally from above into the upper mount, then folded down and then pushed into the lower mount. In this assembly position, both holding webs protrude beyond the edges of the solar module.

It has proven to be useful if a trapezoidal profile is arranged below each vertical profile, which has a trough-shaped cross-section and is used to drain rainwater. This reliably protects the substructure of a roof against water ingress.

Because the sum of the height of the trapezoidal profile and the height of the horizontal profile preferably corresponds to the height of the vertical profile together with the holding profiles in the assembled position, a planar surface can be designed. The horizontal profiles can be placed on the trapezoidal profiles at right angles to them, which allows a stable grid construction to be built up.

The invention is also preferably characterized in that a retaining pin is used for hanging adjacent horizontal profiles at the ends of the vertical profile. As a result, the grid-shaped holding device can be set up quickly.

It has proven to be expedient if an upper or lower end plate is latched to the uppermost and lowermost horizontal profile. In this way, a transition or connection to the existing roof or to the existing substructure can be formed quickly.

[0024] The fact that the two outermost vertical profiles are preferably latched on to outer boundary plates means that a transition or a connection to the existing roof or to the existing substructure can also be quickly formed in the transverse direction to the horizontal profiles.

Snow stoppers are expediently attached to the horizontal profiles. This allows the mandatory snow stoppers to be installed at required points along the vertical profiles.

In one embodiment of the invention, the snow stopper has a triangular cross-section and its open ends are locked to the horizontal profile. This snow stopper can be installed quickly by hanging it in place. The angles of the triangle allow more or less snow retention.

In a further embodiment of the invention, the snow stopper is a horizontal tube which is held on the horizontal profile with a plurality of spacers. A passage has been created between the tube and the vertical and horizontal profiles, through which water and snow can move in a controlled manner.

Another aspect of the invention relates to a method for mounting a holding device according to the preceding claims and for mounting solar modules on the holding device with the following method steps: a) Fastening of trapezoidal profiles with a recess in a vertical orientation on a roof, a surface or a structure, b) attaching a plurality of bottom horizontal profiles to the trapezoidal profiles transversely to the trapezoidal beams and next to each other in a line, c) inserting vertical profiles into the trapezoidal profiles and locking the lower ends of the vertical profiles with the bottom horizontal profiles, d) setting a second Row of horizontal profiles on the trapezoidal profiles and latching of the upper ends of the vertical profiles with the second row of horizontal profiles and e) Continuing steps c) and d) until a grid of vertical and horizontal profiles is produced, solar modules being inserted into the free spaces formed n.

These method steps make it possible for the holding device to be built up quickly and stably.

It has proven to be expedient if the solar modules are inserted diagonally upwards into lower receptacles of the horizontal profiles, are pushed down into upper receptacles of the lower adjacent horizontal profiles and this step is continued until solar modules are inserted into all free spaces. As a result, the solar modules can be fastened particularly quickly and without tools by hanging them onto the horizontal profiles.

The invention is also preferably characterized in that a first and second retaining profile is used in each vertical profile and the retaining profiles are fixed at their ends by inserting fixing elements in the vertical profile. The final fixing of the solar modules to the vertical profiles is also quick and tool-free. The retaining profiles are held "floating" on the vertical profiles, which means that solar modules or laminates of different thicknesses can be used and temperature expansion and unevenness in the substructure can be compensated for. The retaining profiles are held on the vertical profiles over the entire length, creating a particularly even and reliable mount for the solar modules.

An outer boundary plate or an upper and lower end plate are expediently latched to the edge vertical and horizontal profiles. This allows a quick and uncomplicated transition or termination to the existing roof.

Further advantages and features emerge from the following description of exemplary embodiments of the invention with reference to the schematic representations. In a representation that is not true to scale: FIG. 1 shows a side view of a vertical profile which is part of a holding device for holding solar modules and in which a first and second holding profile are inserted; FIG. 2: the side view from FIG. 1, with a fixing element being pressed in between the holding profiles; FIG. 3: the vertical profile together with the installed solar modules and fixing element in an axonometric view at an angle from above; FIG. 4: an axonometric view of the vertical profile from FIG. 3 obliquely from below; FIG. 5: another axonometric view of the vertical profile placed on a trapezoidal profile; FIG. 6: an axonometric view of the holding device with a vertical profile and a horizontal profile; FIG. 7: a side view of the transition from the vertical profile to the horizontal profile; FIG. 8 shows an axonometric view of an outermost vertical profile with a boundary plate; FIG. 9: a side view of the uppermost horizontal profile with an upper end plate; FIG. 10: a side view of the lowest horizontal profile with a lower closing plate; FIG. 11: a side view of a horizontal profile with a snow stopper in a first embodiment; FIG. 12: a side view of a horizontal profile with a snow stopper in a second embodiment; FIG. 13: a side view of a horizontal profile with a snow stopper in a third embodiment; FIG. 14: a detailed view of the vertical profile from FIG. 1; and FIG. 15: an axonometric view of the holding device with two vertical profiles and one horizontal profile, the path of the water flowing off being shown.

In the figures 1 to 8 and 11 to 15, a vertical profile 13 is shown, which is part of a holding device 11 for holding solar modules 15 on a roof, a surface or a structure. The holding device is preferably attached to the battens of a roof and is designed as an “in-roof system”—the roof tiles are therefore replaced by solar modules with which the roof is covered.

The holding device 11 is designed so that solar modules 15 can be fastened quickly and without tools to the holding device by inserting or latching the required components and can be released again just as quickly. A plurality of grid-like free spaces 19 are formed by a plurality of vertical profiles 13 and horizontal profiles 17 , which are covered by solar modules 15 . It is understood that the vertical profiles 13 and the horizontal profiles 17 are inclined according to the roof pitch and that the vertical profiles lose their vertical orientation when the profiles 13, 17 are mounted on a horizontal surface.

First trapezoidal profiles 21 (Figures 5, 6 and 8) are attached in a vertical orientation and at certain intervals on a horizontally oriented battens. The number of trapezoidal profiles 21 is determined by the width of the roof area to be covered. The trapezoidal profiles have a trough-shaped cross-section, which reliably drains rain and melted water off the roof in lanes. On the trapezoidal profiles 21, a bottom row of horizontal profiles 17 are set or attached transversely thereto, which extend over the entire width of the top surface. Then a plurality of vertical profiles 13 are inserted into the trapezoidal profiles and latched to the bottom horizontal profiles 17 at their lower end faces. For latching purposes, a retaining pin 23 is inserted into the end faces of the vertical profiles, which engages in retaining grooves 25 in the horizontal profiles (FIG. 7). The vertical profile 13 has a height element 26 on the underside of which two flanges 28 are formed. The height elements 26 allow the vertical profiles 13 to correspond to the sum of the heights of the horizontal profiles 17 and the trapezoidal profiles 21 . With the flanges 28, the vertical profiles can preferably be latched to the trapezoidal profiles 21 or to the (roof) substructure or fastened by screw connections. The length of the vertical profiles 13 corresponds approximately to the length of the solar modules 15. This structure is continued until the area to be covered is covered with the grid of profiles. The roof area to be covered is framed by vertical and horizontal profiles 13, 17 at the edge.

Solar modules 15 are inserted or suspended in the free spaces 19 formed, the solar modules 15 being initially held only by the horizontal profiles 17 . Each free space 19 is delimited by a first and second support surface 27 , 29 formed on adjacent vertical profiles 13 and by a third and fourth support surface 31 , 33 formed on adjacent horizontal profiles 17 . Each solar module 15 rests on these bearing surfaces 27, 29, 31, 33 after it has been inserted into the free space 19.

The horizontal profile 17 has a first lower and second upper receptacle 35,37 for adjacent solar modules 15a, 15b. The first receptacle 35 is delimited by a first holding web 39 . The second receptacle 37 is delimited by a second holding web 41 . The first retaining web 39 has a greater width than the second web 41, as a result of which the first receptacle 35 has a greater depth than the second receptacle 37. A solar module 15 is first inserted with its upper edge into the first receptacle 35 as far as it will go and then downwards pushed into the second receptacle 37. As a result, the solar module 15 is held on adjacent horizontal profiles 17 .

A solar module 15 is attached to adjacent vertical profiles 13 as follows: Each vertical profile 13 has a recess 43 on the flanks 45 of which a first and second groove 47,49 are provided. A first and a second retaining profile 51, 53, which have symmetrical cross-sections, are inserted into the recess 43. The retaining profiles 51,53 have an L-shaped cross section with a first vertical leg 55 and a second horizontal leg 57. On the vertical leg 55, a first locking element 59 and a second locking element 61 is formed on the side facing the groove 47,49 . In the assembled position, the latching elements 59,61 engage in the grooves 47,49. The heights of the latching elements 59,61 are preferably equal to the depths of the grooves 47,49. The edge 62, which is formed at the transition from the first to the second leg 55,57, is rounded.

The invention is characterized in that the widths of the grooves 47.49 are greater than the widths of the locking elements 59.61. As a result, the holding profiles 51 , 53 together with the mounted solar module 15 can be displaced relative to the vertical profile 13 along the first arrow 63 in the installed position. In addition, an expansion joint 65 is provided between the edge of the solar module 15 and the vertical profile 13 in the assembled position, as a result of which the solar module 15 can be displaced along the second arrow 67 . These degrees of freedom in the vertical and horizontal directions make it possible to compensate for unevenness in the roof construction and for thermal expansion. In addition, the holding device 11 makes it possible for solar modules 15 with different thicknesses of 4.0 to 6.5 mm as well as frameless solar modules and solar modules with a frame to be held. Different frame heights are also possible due to the different designs of the profiles.

The first leg 55 thickens towards its open end. As a result, it can interact with a fixing element 69 in a clamping manner. The fixing element 69 is T-shaped and has a longitudinal leg 71 and a transverse leg 73 . A plurality of wedge-shaped lamellae 75 is formed on the underside of the longitudinal leg 71 . A locking lug 77 is formed on the fixing element 69 on the transverse leg 73 opposite the longitudinal leg 71 .

On the end faces of the retaining profiles 51,53, the locking lug 77 is inserted into the first and second receptacle 35,37 of a horizontal profile 17 at an angle downwards. Then the fixing element 69 is folded down and the slats 75 are clamped between the first legs 55 . As a result, the retaining profiles 51, 53 are pressed against the vertical profile 13 over the entire length and are held on it both in a form-fitting and friction-locking manner. So that the fixing element 69 cannot be pressed out of the space between the two vertical legs 55 unintentionally, the longitudinal leg 71 latches in third grooves 78 on the vertical legs. The third grooves 78 are formed at the transition to the horizontal legs 57 . Because the edges 62 are rounded, the longitudinal leg 71 can be pressed into the third grooves 78 with little force.

For a clean transition between the vertical and horizontal profiles 13,17, the retaining profiles 51,53 must be longer than the vertical profile 13. As a result, the holding profiles 51, 53 protrude into adjacent horizontal profiles 17 (FIG. 7). The width of the transverse leg 73 is dimensioned in such a way that it closes the gap between the second legs 57 and the first holding webs 39 or the second holding webs 41 . This results in a flat surface between the second legs 57, the holding webs 39,41 and the transverse leg 73 (Figure 6).

The existing cross-sectional shapes of the vertical and horizontal profiles 13,17 are used to allow the edge profiles 13,17 to snap or clip end or boundary plates to the sealing transition to the roof or the surface. An upper or lower end plate 79, 81 can be latched onto the top and bottom horizontal profile 17. A connection plate 82 is shown in FIG. 9, which can be latched to the upper end plate 81 and nailed to the roof substructure. As a result, a functional transition to the remaining roof is formed at the upper end of the holding device 11 . Limiting plates 83 can be latched onto the outermost vertical profiles 17 .

Various embodiments of snow stoppers 85 can be attached to the horizontal profile 17, as shown in FIGS. The snow stopper 85 can be an L-shaped profile which is screwed to the horizontal profile 17 (Figure 13). The snow stopper 85 can also have a horizontal tube 87 which is fastened to the horizontal profile 17 with a plurality of spacers 89 (FIG. 12). The tube 87 is secured to the spacers 89 with grub screws 91 . FIG. 11 shows that the snow stopper 85 can be a metal sheet with a triangular cross section. Different snow stoppers 85 can be mounted on each row of horizontal profiles 17 . In this way, account can be taken of the fact that snow lying on the holding device can have different consistencies and, accordingly, different snow stoppers 85 are required.

In the figure 15, the path of the outflowing rainwater or meltwater is indicated by arrows 93. The water flows over the upper inclined vertical profile 13 into the adjoining horizontal profile 17. From the horizontal profile 17, the water can leave the holding device 11 in the trapezoidal profile 21. This water flow fulfills a reliable drainage.

The holding device 11 is suitable for holding solar modules 15 with different thicknesses with and without frames (laminates). The holding device is quickly mounted on a roof or another surface and the solar modules 15 can also be fastened to the holding device without tools and accordingly quickly. The holding device 11 compensates for unevenness in the underlying surface and compensates for thermal expansion of the solar modules 15. In addition, the solar modules 15 are held on the holding device 11 along their entire longitudinal and broad sides.

Legend:

11 Holding device for holding solar modules 13 Vertical profile 15a, 15b solar modules 17 Horizontal profiles 19 Free spaces 21 Trapezoidal profiles 23 Retaining pins 25 Retaining grooves 26 Height element 27 First bearing surface 28 Flange 29 Second bearing surface 31 Third bearing surface 33 Fourth bearing surface 35 First receptacle 37 Second receptacle 39 First retaining bar 41 Second holding web 43 Indentation 45 Flanks 47 First groove 49 Second groove 51 First holding profile 53 Second holding profile 55 First leg 57 Second leg 59 First latching element 61 Second latching element 62 Edges of the holding profile 63 First arrow 65 Expansion joint 67 Second arrow 69 Fixing element 71 Longitudinal leg 73 Transverse leg 75 Slats 77 Latch 78 Third grooves 79 Upper end plate 81 Lower end plate 82 Connection plate 83 Outer perimeter plate 85 Snow stopper 87 Horizontal tube 89 Spacers 91 Grub screws 93 Arrows showing water drainage

Claims (23)

Having first holding device (11) for holding solar modules (15) on a roof, a surface or a supporting structure - a plurality of horizontal profiles (17) arranged at a first spacing, - A plurality of vertical profiles (13) arranged at a second distance, wherein the horizontal profiles (17) and vertical profiles (13) are arranged at right angles to one another and form grid-like free spaces (19), wherein in a free space (19) of the profiles a solar module ( 15) can be held releasably, - A first retaining profile (51) which can be locked in an assembly position on the vertical profile (13) and forms a receptacle for a solar module (15) and - a fixing element (69), which fixes the first holding profile (51) on the vertical profile (13) in the assembly position, further characterized, by a second holding profile (53), wherein - the first and the second retaining profile (51,53) are symmetrically latched to the vertical profile (13), - The first retaining profile (51) has a first locking element (59) and the second retaining profile (53) has a second locking element (61), which interact with a first and a second groove (47, 49) of the vertical profile (13) and - The widths of the grooves (47.49) are greater than the widths of the locking elements (59.61). 2. Holding device according to claim 1, characterized in that the first and the second holding profile (51,53) have an L-shaped cross section and the cross sections of the holding profiles (51,53) are symmetrical with respect to an imaginary vertical. 3. Holding device according to claim 2, characterized in that the holding profiles (51,53) have a first vertical leg (55) and a second horizontal leg (57), the first legs (55) thickening in the direction of their open end. 4. Holding device according to one of the preceding claims, characterized in that the heights of the locking elements (59,61) are equal to the depths of the grooves (47,49). 5. Holding device according to one of claims 3 or 4, characterized in that a third groove (78) is formed on the first limbs (55) at the transition to the second limbs (57) and the edge (62) between the first and second leg (57) is rounded. 6. Holding device according to one of Claims 3 to 5, characterized in that the ends of the holding profiles (51, 53) arranged on the vertical profile (13) interact with a first and second fixing element (69), which fixing elements (69) are located between the allow the first leg (57) to be pushed in, thereby pressing the holding profiles (51, 53) against the vertical profile (13). 7. Holding device according to claim 6, characterized in that the fixing element (69) is T-shaped with a longitudinal leg (71) and a transverse leg (73) and a plurality of wedge-shaped lamellae (75) is formed on the underside of the longitudinal leg (71). is. 8. Holding device according to claim 7, characterized in that on the transverse leg (73) the longitudinal leg (71) opposite a locking lug (77) is formed on the fixing element (69). 9. Holding device according to one of the preceding claims, characterized in that the first and second holding profile (51,53) are longer than the vertical profile (13). 10. Holding device according to one of Claims 3 to 9, characterized in that the second legs (57) of the holding profiles (51,53) are flush with the upper side of the horizontal profiles (17) in the assembled position. 11. Holding device according to one of the preceding claims, characterized in that the horizontal profile (17) has a first lower and second upper receptacle (35, 37) for adjacent solar modules (15a, 15b), the first receptacle (35) being supported by a first Holding web (39) is limited, the second receptacle (37) is limited by a second holding web (41) and the first holding web (39) has a greater width than the second web (41), whereby the first receptacle (35) has a larger Possesses depth than the second shot (37). 12. Holding device according to one of the preceding claims, characterized in that below each vertical profile (13) a trapezoidal profile (21) is arranged, which has a trough-shaped cross section and is used to drain rainwater. 13. Holding device according to claim 12, characterized in that the sum of the height of the trapezoidal profile (21) and the height of the horizontal profile (17) corresponds to the height of the vertical profile (13) together with the holding profiles (51,53) in the assembled position. 14. Holding device according to one of the preceding claims, characterized in that at the ends of the vertical profile (13) in each case a retaining pin (23) for hanging adjacent horizontal profiles (17) is used. 15. Holding device according to one of the preceding claims, characterized in that an upper or a lower end plate (79, 81) latches onto the uppermost and lowermost horizontal profile (17). 16. Holding device according to one of the preceding claims, characterized in that on the two outermost vertical profiles (13) outer boundary plates (83) are locked. 17. Holding device according to one of the preceding claims, characterized in that snow stoppers (85) are attached to the horizontal profiles (17). 18. Holding device according to claim 17, characterized in that the snow stopper (85) has a triangular cross section and that its open ends are latched to the horizontal profile (17). 19. Holding device according to claim 17, characterized in that the snow stopper (85) comprises a horizontal tube (87) which is held on the horizontal profile (17) with a plurality of spacers (89). 20. Method for assembling a holding device according to the preceding claims and for assembling solar modules (15) on the holding device (11), characterized by the following method steps: a) Fastening trapezoidal profiles (21) with a recess in a vertical orientation on a roof, a surface or a supporting structure, b) Fastening of a plurality of bottom horizontal profiles (17) on the trapezoidal profiles (21) transversely to the trapezoidal beams and next to each other in a line, c) Insertion of vertical profiles (13) in the trapezoidal profiles (21) and locking of the lower ends of the vertical profiles (13) with the lowest horizontal profiles (17), d) setting a second row of horizontal profiles (17) on the trapezoidal profiles (21) and locking the upper ends of the vertical profiles (13) with the second row of horizontal profiles (17) and e) Continuing steps c) and d) until a grid of vertical and horizontal profiles (13,17) is produced, with solar modules (15) being inserted into the free spaces formed. 21. The method according to claim 20, characterized in that the solar modules (15) are inserted diagonally upwards into lower receptacles (37) of the horizontal profiles (17) and pushed downwards into upper receptacles (37) of the lower adjacent horizontal profiles (17). and this step is continued until solar modules (15) are inserted into all free spaces. 22. The method according to claim 21, characterized in that in each vertical profile (13) a first and second holding profile (51,53) is used and the holding profiles (51,53) at their ends by inserting fixing elements (69) in the Vertical profile (13) are fixed. 23. Method according to one of Claims 20 to 22, characterized in that outer boundary plates (83) or an upper and lower end plate (79, 81) are latched to the edge vertical and horizontal profiles (17).