DE102010023237A1 - Solar module unit for application on a flat roof and method for fixing a solar module unit on a flat roof - Google Patents

Abstract

There is a solar module unit (1) for application on a flat roof (2) of a building, with a solar module (4) received in a frame (3) and a fastening unit (5) which has an anchor fastened to the outer wall (6) of the building (7), wherein, according to the invention, the solar module unit (1) placed loosely on the surface of the flat roof (2) without penetrating the flat roof (2) has at least one retaining profile (8), in the recess (9) of which a hold-down device ( 10) of the fastening unit (5) is inserted with a compressive force acting on the holding profile (8). In addition, a method for fixing a solar module unit on a flat roof of a building is specified, which is characterized by the following method steps: loose, aligned placement of the preassembled solar module unit (1) equipped with at least one retaining profile (8) on the flat roof (2), - Assembly of the anchor (7) on the outer wall (6) of the building with simultaneous or subsequent insertion of the hold-down device (10) in the retaining profile (8) of the solar module unit (1).

Description

The invention relates to a solar module unit according to the preamble of claim 1 and a method for fixing such a solar module unit on a flat roof according to the preamble of claim 16.

Flat roof solar units of the type concerned here are installed on flat roofs or on roofs with a very low slope, which often have a closed, circumferentially running and raised to the roof surface edge portion, the so-called parapet. In order to ensure optimal alignment of such flat roof solar units in the sun direction, it is necessary to provide a frame for receiving a solar module, which receives the solar module, for example, in an inclined position to the horizontal. However, this orientation also brings with it problems. It is namely to be noted that due to the inclined arrangement of the solar module in a frame an increased susceptibility to wind and storm is given. According to the building regulations, flat roofs must not be drilled through or are very expensive and thus time and cost-intensive seal, so that an anchoring of the frame directly in the flat roof is almost impossible. For this reason, flat roof solar units have hitherto usually been placed loosely on the roof and fastened with in part costly measures on the side walls or on the attic. However, these fixings do not change the fact that due to the mounting of the solar module in a frame, a relatively large windage surface is given and thus in strong wind tends to take off or there is the problem of dynamic deformation of the entire system, which is especially for the sensitive solar modules can be harmful.

From the EP 0 568 950 B1 a solar module unit and implicitly a method for fixing such a solar module unit on a flat roof of a building is known. To fix the solar module unit while an anchor is first attached to a house wall of the building. This anchor establishes a connection to a holding profile via suitable hooks or eyes and a tether. The complex structure holding profile has hooks or eyes through which the tether is passed and held clamped after its positioning. For clamping according to the disclosure of the Scripture with clamping screws against each other strained jaws are required to fix the tether. In addition, the holding profile is intended to receive the solar modules. For this purpose, the holding profile has a plurality of suitable legs, in each of which a solar module is inserted or inserted.

A disadvantage of this embodiment is on the one hand the complex structure of the individual elements and on the other hand, the complicated assembly process. So it is necessary to first fix the anchors to the building, then to mount the tethers and to tighten them. If the tethers are sufficiently tensioned, the solar module can be clamped or pushed into the legs of the retaining profile and must then be fixed to the tethers together with the retaining profile, that is to be held in a clamping manner. The time and assembly effort required for this is significant.

Similar variants are from the writings JP 8-288532 A and JP 3-199565 A1 known. From this, solutions for fixing a solar module unit on a roof with a roof slope are respectively described. According to the JP 8-288532 A For example, a larger number of anchor bolts are first mounted on the roof, with each anchor bolt to be fixed. Subsequently, a system of tethers between these anchor bolts is braced. After tensioning these tethers, the installation of the individual solar modules, whereby these solar modules are fixed directly to the tethers takes place. It should be noted that the assembly process is complicated and time-consuming designed and also no stable, torsion-free support and fixation of the solar modules is given.

Similar is the situation with the JP 3-199565 A1 , Here an anchor is attached to the outside of the roof, which serves to attach a tether. Overall, a system of tethers is arranged distributed over the roof slope in this solution, in which case the tethers are connected together and form a kind of network. The solar modules can be attached to this net-like system of tethers by means of separate clamping elements in a subsequent operation. The disadvantage of this solution also consists in the fact that the solar modules do not rest on the roof, but are mounted in the tethers and consequently the solar modules can not be attached torsion-resistant. The specified method of this document is that first the net of tethers is mounted on the roof, which require a subsequent tension. After tensioning the tethers, the solar modules are fastened to the net with numerous clamping elements. The individual fastenings are done via screw, so that here is a significant installation effort is recorded.

The invention has for its object to provide a solar module unit for application to a flat roof, the one possible Has a simple structure and without damaging the flat roof to install in a short time.

In addition, a method for fixing such a solar module unit is to be specified on a flat roof, which allows a simple and without substantial expenditure of time to be implemented mounting the solar module unit.

The invention solves this problem with the features of the independent claims.

Further embodiments of the invention are the subject of each subsequent sub-claims.

A solar module unit for application to a flat roof of a building with a solar module accommodated in a frame and a fastening unit having an anchor attached to the outer wall of the building, according to the invention further developed such that the loose, so without penetration of the flat roof patched on the surface of the solar module unit has at least one retaining profile, in the trough a hold-down of the fastening unit is inserted with a pressure force acting on the retaining profile.

The solution according to the invention is characterized by several advantages. Thus, it should first be noted that the retaining profile for inserting the hold-down device is preferably a component of the solar module unit and in this case does not have to be additionally mounted. Moreover, it is of particular advantage that the solar module unit can be applied loosely, that is to say without penetration of the flat roof, onto the surface thereof. The solar module unit is simple and thus inexpensive to manufacture. The solar module unit also has optimum protection against unwanted lifting, unwanted proper movements or against the complete release of the flat roof, as could be done for example by wind influences in strong winds or storms. This ensures a high degree of safety and protection against destruction of the solar module unit. The effort to establish the solar module unit according to the invention on a flat roof can also be significantly reduced compared to known solutions.

A first embodiment of the invention is that the holding profile is a part of the frame of the solar module unit. This feature has the significant advantage that the retaining profile is already pre-assembled, so it can be attached to the entire solar module unit in this production. At the construction site, that is, during the attachment of the solar module unit on the flat roof, therefore, no additional installation effort for the attachment of the holding profile is required more. This shortens the time that is necessary to secure a solar module unit according to the invention on the flat roof.

In order to enable optimal introduction of the hold-down in the retaining profile, it is further proposed that the trough of the retaining profile is formed in cross-section V-shaped or U-shaped. Due to these special design features of the retaining profile no threading of the hold-down must be done. Rather, the retaining profile thus has a kind of self-adjustment for the hold-down by sliding into the retaining profile. Filigree work is therefore avoidable. This measure represents a considerable simplification of the assembly of a solar module unit according to the invention.

In addition, it is particularly advantageous if the frame of the solar module unit has a front plate with a wind-repellent effect and an aerodynamic design, which at the same time assumes the function of the holding profile. Thus, a plurality of existing on the solar module unit components can be combined into one unit, so that thereby material costs can be saved and also a simple assembly of the solar module unit is given. In other words, according to this further proposal, the holding profile is a front plate of the frame.

An embodiment of the invention is to be seen in that the anchor has a mounting plate on a connectable to the outer wall of the building side. This allows, for example, the attachment of the anchor to a building exterior wall. Thus, the flat roof does not need to be pierced and damage can be effectively avoided. The mounting plate can be fixed after completion of the building on the outer wall or already integrated in the creation of the masonry in this. The latter variant facilitates the installation of the solar module unit again, since a further step can be saved.

A special embodiment of the anchor is also to be seen in that it is approximately U-shaped and thereby surrounds the attic of the flat roof. The anchor thus has a considerable stability. In addition, with this measure, the holddown can be applied very flat on the flat roof, so that an optimal system of solar module unit is given.

As a hold-down a tensioning cable, a push rod or other similar elements can be used. However, a tensioning cable is preferred because it is quick and easy to install and has a low weight.

While a tensioning cable remains flexible to a small extent and thus continues to be a slight mobility of the solar module unit is possible, a push rod has the advantage that the solar module unit can be fixed with this relatively stable and secure in their position on the flat roof.

To generate the required clamping force, which is necessary to keep the solar module unit according to the invention on the flat roof, it is proposed that the armature a clamping device for generating a tensile force on the tensioning cable or a clamping device for generating a force acting in the direction of flat roof pressure force on the Has push rod. When choosing a clamping device, care should be taken to ensure that it is as easy to operate as possible, so as not to unnecessarily complicated assembly.

For an optimal length compensation has been found that it is advantageous if the tensioning cable is guided over at least one deflection roller present at the anchor. Preferably, the tensioning cable can even be guided over a plurality of deflection rollers, so that in extreme cases even a kind of pulley can be reached. This embodiment allows an optimal clamping possibility of the tensioning cable, which improves the overall fixation of the solar module unit on the flat roof.

A further embodiment of the invention provides that the hold-down is inserted into the holding profile and passed under at least one rail of the solar module unit. This variant allows a very flat design of the retaining profile, because the existing above the hold-down rail effectively prevents the hold-down from the retaining profile. Thus, this solution of the invention provides a material saving.

The solar module of the solar module unit according to the invention may be a photovoltaic element or a solar thermal element. In any case, it is considered advantageous to place a Bautenschutz- or anti-slip mat on the flat roof under the solar module unit. This prevents over a longer period of time damage to the surface of the flat roof, which could possibly be caused by low proper movements of the solar module unit on the flat roof. Thus, the lifetime of the flat roof can be increased as a whole.

Overall, the invention provides the possibility of fixing a solar module unit without penetrating the flat roof on this. The goal here is to avoid lift-off and thus possible damage to the solar module unit in the event of wind or storm. As supportive of this measure, it can be regarded as having the solar module unit according to an embodiment of the invention wind-repellent, aerodynamically designed trim parts, or a wind-repellent, aerodynamically designed rear wall on their respective free outer sides. With this possibility, the inflowing air is offered a small attack surface, so that the entire solar module unit by itself does not tend to lift off. The teaching of this embodiment according to the invention is therefore to equip the solar module unit on its free outer sides with aerodynamically shaped trim parts as a wind deflector. In this case, the aerodynamically shaped trim parts can be shaped based on the design of wings of aircraft such that by sweeping an air flow, as the wind represents, even a pressure of the entire solar module unit to the flat roof takes place, as achieved by the rear wall becomes. Consequently, these aerodynamically shaped trim parts consequently have a wing-like contour, that is to say a correspondingly rounded contour.

To facilitate the assembly and transport of the individual parts of the solar module unit according to the invention, it is also advantageous if the entire solar module unit is designed in lightweight construction. For example, it is possible to use as materials aluminum or plastics, or composite materials, which bring a low weight of the entire solar module unit with it.

For optimum use of the existing solar energy, several solar module units according to the invention are preferably combined with one another to form a composite system applied to the flat roof. The solar module units can be provided in rows one behind the other and / or next to each other. It should be noted in such a composite system only that the individual solar module units do not overlap each other and thus reduce the influence of solar energy.

• – loses, ausgerichtetes Auflegen der vormontierten, mit mindestens einem Halteprofil ausgestatteten Solarmoduleinheit auf das Flachdach und
• – Montage des Ankers an der Außenwand des Gebäudes unter gleichzeitiger oder nachfolgender Einfügung des Niederhalters in das Halteprofil der Solarmoduleinheit.

The method according to the invention for fixing a solar module unit on a flat roof of a building has the following method steps:

• - Loose, aligned laying the pre-assembled, equipped with at least one holding profile solar module unit on the flat roof and
• - Mounting of the anchor on the outer wall of the building with simultaneous or subsequent insertion of the blank holder in the holding profile of the solar module unit.

The process according to the invention is characterized by only two process steps. This substantial reduction in assembly and production costs compared to the solutions known from the prior art is time-consuming and thus cost-saving. In addition, it is very easy to carry out and can be carried out practically even by a layman without considerable effort.

A first embodiment of this method according to the invention consists in that the insertion of the hold-down in the holding profile by means of the clamping unit present on the armature for generating a compressive force on the holding profile.

It is of advantage, of course, if the flat roof is first cleaned and / or measured to prepare the application of the solar module unit. By cleaning it can be prevented that sharp-edged parts lead to damage of the flat roof during assembly of the solar module unit. The measurement in the run-up to the assembly may save a subsequent alignment of the solar module unit later. This is ready for use by the previous measurement of the flat roof after their placement immediately and without further delay.

A further development of the method is also that the hold-down is fixed to the frame of the solar module unit and not the solar module. This has the significant advantage that the solar module is not subject to the risk of damage, because no distortion of the solar module unit takes place by the hold-down and possibly occurring forces on the solar module. A transfer of movements, which may be initiated via the hold-down on the frame is harmless for the entire solar module unit, or the solar modules.

The invention will be explained in more detail with reference to the accompanying drawings. By the illustrations, no limitation is given to the variants shown, but the figures are only illustrative of the principle of the invention. The same or similar components have always been designated by the same reference numerals. In order to be able to illustrate the mode of operation according to the invention, only greatly simplified schematic representations are shown in the figures, in which the components which are not essential to the invention have been dispensed with. However, this does not mean that such components are not present in a solution according to the invention.

It shows:

1 partial view of a flat roof with a solar module unit and an attic surrounding the flat roof,

2 partial section of a flat roof with a part of the attic to which a fastening device is attached,

3 FIG. 2: a partially enlarged section of the insert area of a hold-down in the holding profile below a profile rail, FIG.

4 a flat roof with a composite system of several solar module units and

5 : a solar module unit as an isolated item on a hinted flat roof.

The 1 shows a detail and in greatly simplified form a solar module unit according to the invention 1 on a flat roof 2 is arranged. The solar module unit 1 consists of a frame 3 in which a solar module 4 accommodated in an inclined arrangement. The inclination serves the optimal orientation of the solar module 4 in the direction of the maximum solar action to be achieved in order to achieve the highest possible efficiency of the system. The special feature according to the invention in the present case is that the solar module unit 1 as a total prefabricated unit can be produced or, depending on requirements, can be assembled on site in a simple modular design. An embodiment in lightweight design, so for example, the predominant production of the solar module unit made of aluminum materials allows their prefabrication and a simplified transport, so that the assembly and set-up times can be reduced to a minimum on the flat roof, which is why this embodiment is preferred. The solar module unit 1 also has in its front, facing the sun, a holding profile 8th on, which is designed in cross-section U-shaped and at the same time the front plate of the solar module unit 1 forms, which has a wind-repellent effect by its aerodynamic design. The cross-sectionally U-shaped retaining profile 8th therefore has a trough 9 into which a hold-down 10 is loosely inserted. The hold down 10 is part of a fastening unit 5 next to the hold down 10 an anchor 7 has, which is also U-shaped and the attic 11 of the flat roof 2 completely encompassing. This arrangement of the anchor 7 at the Attica 11 allows the attachment of the anchor to the outer wall 6 of the building, which is advantageous because a piercing of the flat roof 2 is not required. This can damage the flat roof 2 prevented and its life can be extended altogether.

The hold-down is at the in 1 shown embodiment designed as a cable or Bowden cable, which is set by means of a tensioning unit, not shown, under tension and thus a vertical compressive force on the holding profile 8th the solar module unit 1 transfers. He fixes the solar module unit with it 1 against the flat roof 2 , The hold down 10 is used to implement the clamping force over two pulleys 13 and 14 led, who also at the anchor 7 are arranged. As the entire solar module unit 1 according to the invention loose on the flat roof 2 is attached and only against a lift in strong wind or storm through the mounting unit 5 is secured according to the embodiment in the representation of 1 provided an additional security, which consists in that the downholder 10 within the holding profile 8th and under a rail 15 passed through. The one part of the frame 3 forming retaining profile 8th moreover has several retaining shoes 18 on, which serve the solar modules 4 in the frame 3 the solar module unit 1 use.

The detail enlarged view of the area of the fastening unit 5 as they are from the 2 shows once again more clearly than this in connection with the 1 was possible, the arrangement of the anchor 7 on the outside wall 6 of the building. The anchor 7 For this purpose has a mounting plate 12 , which by means of fastening screws on the outer wall 6 of the building can be fixed. The anchor 7 is designed approximately U-shaped and surrounds the Attica 11 of the building completely. The arm of the anchor on the inside of the flat roof 7 goes almost to the surface of the flat roof 2 down. In its front area, this arm has two pulleys 13 and 14 on, about the downholder 10 is guided, which in this case is a cable or a Bowden cable. This hold down 10 represents the connection between the mounting unit 5 and the solar module unit 1 He lies loosely in the holding profile 8th the solar module unit 1 , where the retaining profile 8th this a trough 9 in which the hold-down 10 is self-centering inserted. Every solar module 4 a solar module unit 1 is in the manner previously described in a holding shoe 18 or in several shoes 18 directly as part of the framework 3 on the holding profile 8th are attached, recorded. The advantage of the holding shoes 18 is that the solar modules 4 only in the shoes 18 are used. Consequently, if necessary, individual solar modules 4 if this is necessary due to destruction or defects. From the 2 is also apparent that the solar module units 1 have on their free outsides on trim parts, of which only a single trim part 17 is shown. The trim parts 17 have a wind-repellent effect and are therefore aerodynamically optimized. Through the trim parts 17 can be ensured that the lowest possible windage surface on the solar module units 1 given is.

The detail enlarged representation in 3 illustrates the arrangement of the blank holder 10 on a solar module unit 1 , The hold-down designed as a cable or Bowden cable 10 lies in the hollow 9 of the holding profile 8th , The solar module unit 1 has several profile rails 15 which serve to connect the frame parts and / or several solar module units to one another. The special feature is that the rail 15 above the hold-down 10 is guided along. This can be an additional safeguard against an automatic lifting of the solar module unit 1 from the flat roof 2 be enabled. The solar module 4 the solar module unit 1 is by means of a holding shoe 18 on the frame 3 fixed, with the solar module 4 loose in this shoe 18 used and thus interchangeable. The lateral exterior of the solar module unit 1 is here by an aerodynamically designed, wind-repellent trim part 16 closed, so that too on this side of the solar module unit 1 a small wind attack surface is given.

From the 4 Finally, a view goes on a flat roof 2 out. This flat roof 2 is encircling with a parapet 11 fitted. On the flat roof 2 Furthermore, a plurality of mutually parallel and successively arranged rows of solar module units 1 applied. The individual rows of solar module units 1 are doing each other by rails 15 connected with each other. this type of connection allows only in the front and in the back of the flat roof 2 at the Attica 11 one attachment unit each 5 provided. The fastening unit 5 is in each case in the manner already described by an anchor 7 formed, which is designed approximately U-shaped and on the outside 6 of the building a mounting plate 12 by means of which he with the outer wall 6 the building is bolted. The anchor 7 each has a means of a clamping unit set under tension clamping device 10 in the form of a cable or Bowden cable on the pulleys 13 and 14 is guided and thus immediately above the surface of the flat roof 2 through the retaining profiles 8th the foremost and the rearmost row of solar module units 1 is guided. This fixes each hold-down 10 in connection with the connection of the individual rows of the solar module units 1 and this coupling profile rails 15 the whole in 4 illustrated composite system of several rows of solar module units 1 , Each row of solar module units 1 also has on its free outsides on aerodynamic and wind-repellent designed trim parts 16 respectively 17 ,

The 5 finally shows an insulated solar module unit 1 as a single part representation, in which the solar module unit 1 a solar module designed as a photovoltaic element 4 having, in an inclined arrangement having frame 3 is used. In the front, the Hauptsonneneinstrahlungsrichtung facing area, the solar module unit 1 a holding profile 8th in, in which the hold down 10 is inserted in the form of a cable or Bowden cable. Above the hold-down 10 are profile rails 15 transverse to the holding profile 8th guided, which serve in the manner already described, several solar module units 1 to couple with each other. In the 5 shown special feature is that the rear, free outside of the solar module unit 1 an aerodynamically designed and wind-repellent rear panel 19 having. Such a back wall 19 is of course used on every solar module unit used 1 intended.

LIST OF REFERENCE NUMBERS

1

Solar module unit

2

flat roof

3

frame

4

solar module

5

fixing unit

6

outer wall

7

anchor

8th

retaining profile

9

trough

10

Stripper plate

11

Attica

12

mounting plate

13

idler pulley

14

idler pulley

15

rail

16

cowling

17

cowling

18

retaining shoe

19

rear wall

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0568950 B1 [0003]
• JP 8-288532 A [0005, 0005]
• JP 3-199565 A1 [0005, 0006]

Claims (20)

Solar module unit ( 1 ) for application on a flat roof ( 2 ) of a building, with one in a frame ( 3 ) received solar module ( 4 ) and a fastening unit ( 5 ), one on the outer wall ( 6 ) anchored to the building ( 7 ), characterized in that the loose, so without penetration of the flat roof ( 2 ) on the surface of the flat roof ( 2 ) mounted solar module unit ( 1 ) at least one holding profile ( 8th ), in whose trough ( 9 ) a hold-down ( 10 ) of the fastening unit ( 5 ) with one on the holding profile ( 8th ) acting pressure force is inserted. Solar module unit according to claim 1, characterized in that the retaining profile ( 8th ) a part of the framework ( 3 ) of the solar module unit ( 1 ). Solar module unit according to one of the preceding claims, characterized in that the trough ( 9 ) of the holding profile ( 8th ) is formed in cross-section V-shaped or U-shaped. Solar module unit according to one of the preceding claims, characterized in that the retaining profile ( 8th ) a front plate of the frame ( 3 ). Solar module unit according to one of the preceding claims, characterized in that the armature ( 7 ) at one with the outer wall ( 6 ) of the building connectable side a mounting plate ( 12 ) having. Solar module unit according to one of the preceding claims, characterized in that the armature ( 7 ) U-shaped, the attic ( 11 ) of the flat roof ( 2 ) is formed encompassing. Solar module unit according to one of the preceding claims, characterized in that the hold-down ( 10 ) is a tensioning cable or a push rod. Solar module unit according to claim 7, characterized in that the armature ( 7 ) a tensioning device for generating a tensile force on the tensioning cable or a tensioning device for generating a in the direction of a flat roof ( 2 ) has acting pressure force on the push rod. Solar module unit according to one of claims 7 to 8, characterized in that the tensioning cable via at least one at anchor ( 7 ) existing pulley ( 13 . 14 ) is guided. Solar module unit according to one of the preceding claims, characterized in that the hold-down ( 10 ) in the holding profile ( 8th ) and under at least one rail ( 15 ) of the solar module unit ( 1 ) is passed. Solar module unit according to one of the preceding claims, characterized in that the solar module ( 4 ) is a photovoltaic element or a solar thermal element. Solar module unit according to one of the preceding claims, characterized in that below the solar module unit ( 1 ) a building protection or anti-slip mat on the flat roof ( 2 ) is launched. Solar module unit according to one of the preceding claims, characterized in that the solar module unit ( 1 ) wind-repellent, aerodynamically designed trim parts ( 16 . 17 ) or a wind-repellent, aerodynamically designed rear wall ( 19 ) has on its free outer sides. Solar module unit according to one of the preceding claims, characterized in that the entire solar module unit ( 1 ) is designed in lightweight construction. Solar module unit according to one of the preceding claims, characterized in that a plurality of solar module units ( 1 ) to one on the flat roof ( 2 ) applied composite system are combined. Method for fixing a solar module unit on a flat roof of a building according to one of the preceding claims, characterized by the following method steps: - loose, aligned laying of the pre-assembled, with at least one holding profile ( 8th ) equipped solar module unit ( 1 ) on the flat roof ( 2 ), - installation of the anchor ( 7 ) on the outside wall ( 6 ) of the building with simultaneous or subsequent insertion of the blank holder ( 10 ) in the holding profile ( 8th ) of the solar module unit ( 1 ). Method according to claim 11, characterized in that insertion of the hold-down device ( 10 ) in the holding profile ( 8th ) by means of the at the anchor ( 7 ) existing clamping unit for generating a compressive force on the holding profile ( 8th ). A method according to claim 11 to 12, characterized in that the flat roof ( 2 ) as preparation for the application of the solar module unit ( 1 ) is first cleaned and / or measured. Method according to one of the preceding claims 11 to 13, characterized in that the hold-down ( 10 ) on the frame ( 3 ) of the solar module unit ( 1 ) and not on the solar module ( 4 ). Solar module unit according to one of the preceding claims, characterized in that the attachment of the solar module unit ( 1 ) or the interconnected system as multipoint anchorage with multiple anchors ( 7 ) and hold-downs ( 10 ) he follows.

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