EP4356513A1 - Method for mounting a photovoltaic system, and mounting system for a photovoltaic system - Google Patents

Abstract

The invention relates to a method for mounting a photovoltaic system, comprising the steps of: adapting overlapping regions (30) of roofing tiles (3) which are disposed so as to overlap each other; arranging roof hooks (4) in the adapted overlapping regions (30); fastening the roof hooks (4) to rafters (1) which are located below the overlapping regions (30); arranging bearing profiles (6) on the existing roofing tiles (3) such that these bearing profiles rest on the roofing tiles (3) at least in the overlapping regions (30); fastening the bearing profiles (6) to the roof hooks (4); and arranging and fastening photovoltaic modules (8) on the bearing profiles (6).

Description

PHOTOVOLTAIC SYSTEM INSTALLATION METHOD AND PHOTOVOLTAIC SYSTEM INSTALLATION SYSTEM

TECHNICAL AREA

The present invention relates to a method for mounting a photovoltaic system and a mounting system for a photovoltaic system, in particular for mounting on pitched roofs.

STATE OF THE ART

Mounting systems for photovoltaic systems are known from the prior art, which have to be mounted on pitched roofs by means of extremely laborious roof hook mounting. With the roof hooks, the load (module weight, wind and snow) is transferred past the tiles directly onto the rafters. To do this, the bricks must be raised and finished. In addition, today's assembly systems are statically overdetermined. The static structure of the roofs is usually a wooden beam construction. Wood has a thermal expansion of about 8xlCü ⁶ /K and its dimensions change depending on the moisture content. Today's assembly systems are mostly based on aluminum profiles with a thermal expansion of about 23xlCü ⁶ /K, which is about three times greater than that of the underlying wooden beam construction. The mounting systems are exposed to temperature fluctuations from -10°C to 60°C, for example, with the mounting systems being exposed to more extreme temperatures than those below wooden beam constructions. In addition, the static support structure of the roof deforms under load, such as wind or snow. The circumstances mentioned above mean that considerable and almost uncontrollable stress conditions occur in the substructures, which can lead to damage to the roof (brick breaks, breaks in corrugated fiber cement panels, etc.). The damage patterns in practice are varied. These superimposed stress conditions weaken the resilience of the systems to any additional stresses such as wind or snow.

DESCRIPTION OF THE INVENTION

An object of the present invention is a method for mounting photovoltaic systems on roofs, especially pitched roofs and a mounting system for

Provide photovoltaic systems for pitched roofs, in which the assembly effort and assembly errors are reduced and with which less damage is caused to the roof. This object is achieved by a method having the features of claim 1. Further embodiments of the method and an assembly system with which the method can be carried out are defined by the features of further claims. A method according to the invention for installing a photovoltaic system comprises the steps:

adjusting overlapping areas of roof tiles arranged overlapped with each other; arranging roof hooks in the adjusted overlap areas;

attaching the roof hooks to rafters located below the overlap areas; - Arranging support profiles on the existing ones

Roof tiles, such that they rest on the roof tiles at least in the overlapping areas;

Attaching the support profiles to the roof hooks; and

Arranging and fastening of photovoltaic modules on the support profiles.

This method has the advantage that the support profiles rest on the roof tiles in a stable area and forces that act on the roof in a vertical direction can be transferred through the tiles to the roof battens and rafters. It can be exploited with that

roof tiles made of coarse ceramics, cement or fiber cement a load-bearing structure is available. Since roof tiles are arranged next to one another and overlapping one another, overlapping areas arise in the lateral edge areas of the respective roof tiles and in the upper and lower edge areas with respect to the line of fall. When adjusting an overlapping area, the upper edge area of the upper surface of the lower roof tile and/or the lower edge area of the lower surface of the upper roof tile relative to the fall line can be adjusted, i.e. material can be removed in such a way that a roof hook can pass through the recess formed essentially without touching it is feasible. For a better distribution of the load, the support profiles can be opened rest on the underlying roof tiles along their entire length. With a photovoltaic on-roof mounting system mounted in this way, significantly fewer roof hooks are required, which means that a reduction in the material costs and a reduction in the mounting costs of up to 50% can be achieved.

In one embodiment, the overlapping areas are adjusted in an area spaced apart from the lateral roof tile edges. I.e. the adjustment is made in a central area of the upper or lower edge areas of the roof tiles.

In one embodiment, the method further comprises the steps of:

Arranging and attaching insert profiles on the support profiles; and

Arranging and fastening the photovoltaic modules between two mutually adjacent insertion profiles.

This procedure has the advantage that the photovoltaic modules are arranged between a stable frame construction.

In one embodiment, the support profiles are arranged at regular intervals from one another and the insertion profiles are arranged at regular intervals from one another. Such an arrangement is necessary if several photovoltaic modules of the same dimensions are to be arranged next to one another and one above the other. Since the lateral distances between the rafters cannot be changed, the lateral distances are from two to each other adjacent support profiles essentially predetermined by the rafter spacing. Accordingly, the roof hooks are designed in such a way that a laterally offset arrangement with respect to the rafters is possible, for example by means of a fastening plate with a plurality of through-holes.

In one embodiment, some or all support profiles are attached to an upper roof hook or to an upper roof hook and to at least one lower roof hook. In this way, a distributed introduction of forces, primarily of the forces acting in the fall line, can be achieved from the photovoltaic system into the rafters of the roof construction.

In one embodiment, each upper roof hook is designed in such a way that it allows the respective support profile to be displaced along its longitudinal axis during assembly and, after installation, firmly connects the respective support profile to the corresponding rafter, and each lower roof hook is designed in such a way that it can be moved during and after assembly a shift of the respective

Support profile allowed along its longitudinal axes. This has the advantage that the photovoltaic system is firmly connected to the roof in its upper area and changes in length of the support profiles are not blocked by the lower roof hooks, which means that mechanical stresses in the construction can be avoided. Less mechanical stress on the structure extends its service life. Changes in length of the support profiles can be caused by lateral forces acting on them or by Temperature changes are caused. For example, the support profiles can be bent by wind or snow, or they experience thermal expansion, for example in midsummer when the roof gets particularly hot. In one embodiment, upper roof hooks, which are opposite one another with respect to a roof ridge, are connected to one another with a reinforcing band. In this way, a load distribution of the forces acting in the line of fall can be achieved. In one embodiment, the support profiles comprise a metal profile and an elastic support layer connected thereto, which extends along the entire length of the metal profile, the support profiles resting with the support layer on the roof tiles. Due to its deformation, the elastic support layer causes the support forces to be distributed over a larger area, which reduces the pressure acting on the roof tiles. This applies above all to forces acting vertically on the roof. Since the deformation results in a larger contact surface, the elastic increases

Support layer also reduces the resulting static friction between the support profiles and the roof tiles, which means that the forces acting in the line of fall are better distributed in the roof tiles or roof construction. In one embodiment, the metal profile comprises

Fastening ribs which protrude into the overlay layer. This increases the contact surface between the metal profile and the overlay layer and thus also their adhesive surfaces. The overlay layer can be connected to the metal profile be glued or the metal profile can be cast with the overlay layer. For example, the metal profile is a stainless steel or aluminum profile. For example, the support layer is a layer of silicone. The support layer can also be compressible and can comprise a foam, for example. For example, the support layer can comprise a rubber made from EPDM, EVA or EPR, or preferably a foam made from PUR. These materials have excellent weather and aging resistance and exhibit thermo-mechanical properties that enable them to withstand the loads that are applied.

The embodiments of the method mentioned can be used in any combination, provided they do not contradict one another.

A mounting system according to the invention for a photovoltaic system comprises at least two roof hooks, which can be arranged in an overlapping area of overlapping roof tiles and which can be fastened to the rafters below, and at least two support profiles, which can be arranged lying on the overlapping area and which can be fastened to the roof hooks, wherein the support profiles comprise a metal profile and an elastic support layer connected thereto, which extends along the entire length of the metal profile. BRIEF DESCRIPTION OF THE FIGURES

Exemplary embodiments of the present invention are explained in more detail below with reference to figures. These are for explanation only and are not to be construed as limiting. Show it

1 shows a sectional view through a photovoltaic system mounted according to the invention on a pitched roof;

FIG. 2 shows a perspective view of a support profile of FIG. 1;

3 shows a schematic perspective view of a mounting system according to the invention for a photovoltaic system mounted on a roof;

figs 4A-B a first embodiment of a lower roof hook; and

figs 5A-B a second embodiment of a lower roof hook.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows a sectional view through a photovoltaic system mounted according to the invention on a pitched roof.

For this purpose, overlapping areas 30 of roof tiles 3 arranged overlapping with one another were adapted by removing projections and possibly parts of the tile surface in this area in order to form a passage for a roof hook 4 . Then roof hooks 4 were arranged in the adapted overlapping areas 30 . in the illustrated case, an upper roof hook 40 and a lower roof hook 41 were arranged. The roof hooks 4 were then attached to the rafters 1, which are located below the overlapping areas 30. Then support profiles 6 were arranged on the existing roof tiles 3 in such a way that they rest on the roof tiles 3 at least in the overlapping areas 30 . The support profiles 6 were then attached to the roof hooks 4. In a further step, insert profiles 7 were attached to the support profiles 6. In another

Step photovoltaic modules 8 were arranged on the support profiles 6 and between the insert profiles 7 and fastened. In the illustrated assembly, the top roof hook 40 has been connected with a reinforcing band 5 to another top roof hook (not shown) located on the opposite side of the roof ridge.

FIG. 2 shows a perspective view of a support profile 6 from FIG. The support profile 6 comprises a metal profile 60 and a support layer 61 firmly connected thereto. The support layer 61 is connected to the metal profile 60 essentially at a support surface 600 . For better attachment of the support layer 61 on the metal profile 60 are at the

Support surface 600 ribs 601 provided, which protrude into the support layer 61.

FIG. 3 shows a schematic perspective view of one according to the invention mounted on a roof Mounting system for a photovoltaic system. Shown are several support profiles 6, which are arranged parallel and at equal distances from each other, with respect to the line of fall next to each other. The two outer support profiles 6 and the middle support profile 6 are each fastened to the roof with an upper roof hook 40 and a lower roof hook 41 and lie on the roof tiles 3 . All support profiles 6 are connected to one another with several insert profiles 7 . The insert profiles 7 are distributed evenly along the support profiles 6 . The support profiles 6 together with the insert profiles 7 form a solid frame construction. In order to increase the rigidity of the construction, diagonally arranged profiles can be provided (not shown), which are firmly connected to support profiles and/or insert profiles.

FIG. 4A shows a first embodiment of a lower roof hook 4 and FIG. 4A shows an end area of a spacer 400 of the roof hook 4 of FIG. 4A. The spacer 400 is in the form of a lug and its end area is aligned parallel to the rafters in the intended position of use and has a slot 401 which extends along the fall line after assembly. The support layer 61 of the support profile 6 rests on the end area of the roof hook 4 . A through hole extends through the support layer 61 and the metal profile 60 of the support profile 6. A screw 402 is arranged in the through hole and extends through the slot 401 of the roof hook 4 in the assembled state. The screw 402 is fixed with a nut 404 . A sleeve 403 is clamped between the metal profile 60 and the nut 404 is held. The sleeve 403 is designed to be slidable along the slot 401 . Ie the diameter of the sleeve 403 is smaller than the width of the slot 401 and the length of the sleeve creates a gap between the clamping surface of the nut 404 and the corresponding surface of the roof hook 4 when the nut 4 is tightened. The sleeve 403 and the nut 404 can be separate elements from each other or they can be formed together in one piece as shown here. Spring elements (not shown) can be provided between the nut and the roof hook. Shorter sleeves can also be used or the sleeve can be omitted if a fixing clamp of the roof hook and the support profile is desired, for example if the roof hook is to be used as an upper fixed roof hook.

FIG. 5A shows a second embodiment of a lower roof hook 4. In this embodiment, the spacer 440 is rod-shaped and its end area is aligned parallel to the rafters in the intended position of use. A connector 441 is arranged around the end region of the spacer 440 and is firmly connected to the metal profile 60 of the support profile 6 with screws 442 . A gap is formed between the outer diameter of the spacer 440 and the inner diameter of the recess of the connector 441, as a result of which a relative displacement of these two elements is possible. Optionally in the connector a locking screw (not shown) can be provided with which the spacer can be fixed in the connector. This roof hook could therefore be used both as an upper and as a lower roof hook.

REFERENCE LIST

1 rafter 441 connector

2 battens 442 screw

3 roof tiles 5 reinforcing tape

30 Overlap area 6 support profile

4 roof hooks 60 metal profile

40 upper roof hook 600 support surface

41 lower roof hook 601 fastening rib

400 spacer 61 overlay layer

401 slot 7 insertion profile

402 screw 8 PV module

403 sleeve

404 nut L longitudinal axis

440 spacers

Claims

PATENT CLAIMS

1. A method for installing a photovoltaic system comprising the steps:

Adaptation of overlapping areas (30) of roof tiles (3) arranged overlapping with one another;

Arranging roof hooks (4) in the adjusted overlapping areas (30);

Attaching the roof hooks (4) to rafters (1) located below the overlapping areas (30);

Arranging support profiles (6) on the existing roof tiles (3) in such a way that they rest on the roof tiles (3) at least in the overlapping areas (30);

Attaching the support profiles (6) to the roof hooks (4); and

Arranging and fastening photovoltaic modules (8) on the support profiles (6).

2. The method according to claim 1, wherein the overlapping areas (30) are adjusted in an area spaced from the lateral roof tile edges.

3. The method according to claim 1 or 2, comprising the steps:

arranging and fastening of insert profiles (7) on the support profiles (6); and Arranging and fastening the photovoltaic modules (8) between two mutually adjacent insertion profiles (7).

4. The method according to any one of the preceding claims, wherein the support profiles (6) are arranged at regular intervals from one another and the insertion profiles (7) are arranged at regular intervals from one another.

5. The method according to any one of the preceding claims, wherein some or all support profiles (6) are attached to an upper roof hook (40) or to an upper roof hook (40) and to at least one lower roof hook (41).

6. The method according to claim 5, wherein each upper roof hook (40) is designed in such a way that it allows displacement of the respective support profile (6) along its longitudinal axis (L) during assembly and fixes the respective support profile (6) after assembly connected to the corresponding rafter (1), and each lower roof hook (41) is designed in such a way that it allows a displacement of the respective support profile (6) along its longitudinal axis (L) during and after assembly.

7. The method according to claim 5 or 6, wherein upper roof hooks (40) which are relative to a roof ridge opposite, with a reinforcement band (5) are connected to each other.

8. The method according to any one of the preceding claims, wherein the support profiles (6) comprise a metal profile (60) and an elastic support layer (61) connected thereto, which extends along the entire length of the metal profile (60), the support profiles ( 6) rest with the overlay (61) on the roof tiles (3).

9. The method according to claim 7, wherein the metal profile (60) comprises fastening ribs (601) which protrude into the supporting layer (61).

10. Mounting system for a photovoltaic system, comprising at least two roof hooks (4) which can be arranged in an overlapping area (30) of roof tiles (3) arranged so that they overlap with one another and which can be fastened to the rafters (1) underneath and at least two support profiles (6) which can be arranged lying on the overlapping area (30) and which can be fastened to the roof hooks (4), characterized in that the support profiles (6) comprise a metal profile (60) and an elastic support layer (61) connected to it, which extends along the entire length of the metal profile (60).

11. The mounting system for a photovoltaic system according to claim 10, wherein the support layer (61) comprises a foam made of PUR or a rubber made of EPDM, EVA or EPR.