BE1028429B1 - MOUNTING RAIL, KIT AND METHOD FOR INSTALLING SOLAR PANELS - Google Patents

Abstract

The present invention relates to a mounting rail for installation of solar panels comprising an elongate profile of rectangular cross section formed by four side walls, a first side wall comprising a longitudinal groove with two collars, the two collars extending towards each other and in-plane. from the first side wall; wherein a second opposing side wall includes a longitudinal groove; wherein a third sidewall is a closed sidewall; wherein a fourth sidewall comprises a longitudinal groove with two collars, the two collars extending towards each other and being in the plane of the fourth sidewall, and wherein the longitudinal groove in the second sidewall comprises longitudinal notches in upstanding walls of the groove, configured to interact with the threads of a bolt. The invention also relates to a kit and a method for installing solar panels.

Description

MOUNTING RAIL, KIT AND PROCEDURE FOR INSTALLING SOLAR PANELS

TECHNICAL DOMAIN The invention relates to a mounting rail for installation of solar panels. In a second aspect, the invention also relates to a kit for installing solar panels.

In a third aspect, the invention also relates to a method for installing solar panels.

In a fourth aspect, the invention relates to a method according to the third aspect, performed using a kit according to the second aspect.

BACKGROUND ART In recent years, solar panels have been increasingly installed in order to be able to use solar energy for generating electricity in a relatively simple and inexpensive manner. Such solar panels are installed on a surface by means of a mounting device or support device. A surface can be a ground surface as well as a flat or pitched roof. A fastening device according to the prior art comprises several profiles which are fixed or placed on the surface and a mounting rail which is fastened to the profiles by means of, often specifically designed, mechanical fastening elements, such as for instance bolts, nuts and the like. The actual solar panel can then be mounted on the mounting rail.

A prior art mounting rail comprises an extruded profile with thin side walls and a single internal rib. As a result, the mounting rail is not strong enough and is deformed or even damaged under heavy loads, such as the wind. The mounting rail comprises a longitudinal groove with two collars in two opposite side walls. A solar panel is secured to the mounting rail using a hammer head bolt in a longitudinal groove. The hammerhead bolt is slid into the groove through an open end of the mounting rail, making it necessary to determine in advance how many hammerhead bolts will be needed to secure the solar panels to the mounting rail. Fastening also requires a coordinated action where a nut and hammerhead bolt are manipulated simultaneously. The positioning of the longitudinal grooves only allows to fix the mounting rail with the side wall facing a surface on which the solar panel is placed, to profiles on the surface. It is not possible to use profiles that are attached laterally to the mounting rail. A mounting rail according to the state of the art is lacquered. The paint weathers over time and still offers insufficient protection against external elements. This is especially disadvantageous in saline environments, such as in coastal regions.

The present invention aims to find at least a solution to some of the above-mentioned problems or drawbacks.

SUMMARY OF THE INVENTION In a first aspect, the present invention relates to a mounting rail according to claim

1.

The great advantage of the mounting rail according to the present invention is that it comprises an elongate profile, a first side wall comprising a longitudinal groove configured to receive a hammerhead bolt, a second opposite side wall comprising a longitudinal groove, the longitudinal groove in upstanding walls of the groove includes longitudinal notches configured to interact with the threads of a bolt, wherein a third sidewall is a closed sidewall and wherein a fourth sidewall also includes a longitudinal groove configured to receive a hammerhead bolt. The longitudinal groove in the first sidewall and the fourth sidewall are suitable for securing the mounting rail to a support member using a hammerhead bolt and nut. The mounting rail can be attached to the support element with a side wall that faces a surface on which the solar panel is placed, as well as laterally. This provides more flexibility for optimally fixing a mounting rail to a support element. The longitudinal notches in the longitudinal groove in the second side wall allow to use a bolt instead of a hammer head bolt to fix a solar panel to the mounting rail. This is advantageous because it is not necessary to advance the correct number of hammerhead bolts from one end into the groove and because fixing a solar panel to the mounting rail only requires the manipulation of a bolt instead of the simultaneous manipulation of a hammerhead bolt and a nut as with a mounting rail according to the state of the art.

Preferred forms of the device are presented in claims 2 to 4. In a second aspect, the present invention relates to a kit according to claim 5. This kit has the advantage, inter alia, that it comprises a mounting rail according to the first aspect, whereby a solar panel with can be mounted quickly and easily on a mounting rail using a mounting bracket and a bolt. Hereby, the mounting rail in the kit provides the necessary flexibility to fix the mounting rail with a side wall facing a surface on which the solar panel is placed, or laterally to a support element, depending on the surface on which the support element is placed or mounted. Preferred forms of the kit are described in dependent claims 5 to 9. In a third aspect, the present invention relates to a method according to claim

10. The method is advantageous because of the use of a mounting rail according to the first aspect. The advantages are similar as stated under the kit of the second aspect. In a fourth aspect, the invention relates to a method according to the third aspect, performed using a kit according to the first aspect.

SUMMARY OF THE INVENTION Figure 1 shows a cross-sectional view of a mounting rail according to the prior art. Figure 2 shows a sectional view of a mounting rail according to an embodiment of the present invention. Figure 3 shows a perspective view of a mounting rail according to an embodiment of the present invention attached to a support element.

DETAILED DESCRIPTION Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meaning as generally understood by those skilled in the art of the invention. For a better assessment of the description of the invention, the following terms are explicitly explained. “A”, “the” and “the” in this document refer to both the singular and the plural unless the context clearly dictates otherwise. For example, “a segment” means one or more than one segment. The terms “comprise”, “comprising”, “consist of”, “consisting of”, “includes”, “contain”, “containing”, “contents”, “includes” are synonyms and are inclusive or open terms that indicate the presence of the following, and which do not exclude or preclude the presence of other components, features, elements, members, steps known from or described in the art. Citing numerical intervals through the endpoints includes all integers, fractions and/or real numbers between the endpoints, including these endpoints. In the context of this document, a gable roof is a roof comprising at least two pitched roof panels placed against each other and intersecting in a ridge. A gable roof is covered with tiles, slates or another suitable means. A gable roof comprises rafters with transverse purlins for supporting the roof construction, optional insulation between or on the rafters, a sub-roof on top of the rafters and the optional insulation, battens on the sub-roof, positioned in the same direction as the rafters and on top of the rafters, battens transverse to the battens and an upper roof comprising said tiles, slates or other suitable means.

In the context of this document, a support member is an element configured to attach to a mounting rail and support a mounting rail on a surface. A support element is placed or fixed on the surface. Non-limiting examples of support elements are legs and hooks.

In a first aspect, the invention relates to a mounting rail for installing solar panels.

According to a preferred embodiment, the mounting rail comprises an elongate profile of rectangular cross-section, formed by four side walls and internal ribs. The profile is preferably extruded.

A first sidewall includes a longitudinal groove with two collars. The longitudinal groove and the two collars preferably run the full length of the mounting rail. The two collars extend toward each other and are in the plane of the first sidewall. The longitudinal groove is configured to receive a hammerhead bolt. The hammerhead bolt is a hammerhead bolt M5, M6, M7, M8, M9 or M10. The longitudinal groove is configured for securing the mounting rail to a support member using a hammerhead bolt and nut. A second sidewall, opposing the first sidewall, includes a longitudinal groove. The longitudinal groove does not include collars. The longitudinal groove preferably runs the full length of the mounting rail. The longitudinal groove includes longitudinal notches in upstanding walls of the groove. The longitudinal notches preferably run the full length of the mounting rail. The longitudinal notches are configured to interact with the threads of a bolt. The bolt is a bolt M5, M6, M7, M8, M9 or M10. The bolt is preferably a bolt M8. The longitudinal groove is configured for mounting a solar panel. A third sidewall, transverse to the first and second sidewalls, is a closed sidewall.

A fourth sidewall, transverse to the first and second sidewalls and substantially parallel to the third sidewall, includes a longitudinal groove with two collars. The longitudinal groove and the two collars preferably run the full length of the mounting rail. The two collars extend toward each other and are located in the plane of the fourth sidewall. The longitudinal groove is configured to receive a hammerhead bolt. The hammerhead bolt is a hammerhead bolt M5, M6, M7, M8, M9 or M10. The longitudinal groove is configured for securing the mounting rail to a support member using a hammerhead bolt and nut. The longitudinal groove is similar to the longitudinal groove in the first sidewall.

A mounting rail according to the present invention is advantageous because a support element can be attached to a side wall, facing a surface on which the solar panel is placed, or laterally to a side wall. The longitudinal groove in the first sidewall is the groove that faces the surface on which the solar panel is placed. The longitudinal groove in the fourth side wall is the groove that is used when the mounting rail is attached laterally to the support element.

The mounting rail is fixed or placed on the surface with the aid of the support element. The surface can be either a ground surface or a flat or pitched roof. The longitudinal groove in the first and fourth sidewalls provide the necessary flexibility for optimally fixing a mounting rail to a support element, depending on the surface on which a solar panel is placed or mounted.

A mounting rail according to the present invention is also advantageous in that the longitudinal notches in the longitudinal groove in the second side wall allow to use a bolt instead of a hammerhead bolt to secure a solar panel to the mounting rail. When using a hammerhead bolt, the correct number of hammerhead bolts must be pre-slide from one end of the mounting rail into a longitudinal groove. Attaching a solar panel to the mounting rail requires the simultaneous manipulation of a hammerhead bolt and a nut. This is difficult because the solar panel obscures the view and manipulation of the hammerhead bolt during mounting. When using a bolt, it is not necessary to determine the correct number of bolts in advance. Additional bolts can easily be screwed into the longitudinal groove afterwards. While attaching the solar panel to the mounting rail, there is a full view of the bolt and the bolt can be easily manipulated. Only the bolt needs to be manipulated.

According to one embodiment, the profile of the mounting rail comprises a chamber in each corner of the rectangular cross-section and in the center. The profile includes at least five chambers. The chambers are formed by contiguous ribs. A chamber extends longitudinally. The chambers preferably extend over the full length of the mounting profile. The chambers in each corner of the rectangular cross-section provide sturdy side walls that are rigidly connected to each other in the corners. The chambers in each corner also reinforce the side walls. The central chamber stiffens the entire mounting rail against deformation in a direction transverse to the longitudinal direction of the mounting rail as well as against torsional deformation. Preferably, a chamber is connected at an angle to the central chamber by means of a rib. The chambers are advantageous for increasing the strength of the mounting rail, so that a mounting rail is not deformed or damaged under a high load, such as for instance by the weight of an installation of solar panels or by the wind.

According to one embodiment, each side wall and rib of the profile of the mounting rail has a thickness of at least 1.8 mm. A thickness of at least 1.8 mm is advantageous for increasing the intrinsic strength of the profile against deformation and damage under the influence of high loads, such as for example by the weight of a solar panel installation or by the wind. A thickness of at least 1.8 mm also prevents a side wall of the profile from being accidentally pierced by a tool during installation, which is possible with thin walls. This makes it possible for water to seep into the profile of the mounting rail, which can lead to damage to the mounting rail over time.

According to one embodiment, a collar of the longitudinal groove in the first and fourth sidewalls has a thickness of at least 2 mm. The collars are additionally loaded because the collars are not part of a chamber and because a mounting rail is attached to a support element by means of a hammerhead bolt. The load by, for instance, the weight of an installation of solar panels or, for instance, by the wind is transferred to the support element via the collars. A collar with a thickness of at least 2 mm is advantageous to prevent a collar from bending under the influence of high loads, such as the weight of a solar panel installation or the wind.

According to one embodiment, a mounting rail is made of a metal. Preferably, the mounting rail is made of aluminum. Aluminum has good corrosion resistance and is a light material. This is particularly advantageous when installing solar panels on a roof-like surface. More preferably, the aluminum is EN AW-6060 T66.

According to one embodiment, the mounting rail is coated with a powder coating. A powder coating forms a solid coating on a mounting rail and is well resistant to external elements such as weather elements or, for example, salt in coastal regions. In addition, powder coating is less susceptible to damage from impact than a coating. The powder coating provides permanent protection for the mounting rail.

According to one embodiment, the mounting rail has a square cross section of 40 mm x 40 mm.

In a second aspect, the invention relates to a kit for installing solar panels.

According to a preferred embodiment, the kit comprises a mounting rail according to the first aspect of the present invention, at least four mounting brackets for mounting a solar panel on the mounting rail, and at least four support elements for mounting or positioning the mounting rail on a surface.

Installing a solar panel requires at least two mounting rails, a first mounting rail to support a first half of the solar panel and a second mounting rail to support a second half of the solar panel. Two mounting rails for installing a solar panel can be obtained from one mounting rail of a kit by sawing one mounting rail to length.

A support member is configured for placing or mounting a solar panel on a surface. Installing a solar panel requires at least two support elements to fix or place one mounting rail on a surface. A first support element is placed near a first end of a mounting rail and a second support element is placed near a second end of a mounting rail. Depending on the load on the mounting rail, additional intermediate support elements can be placed.

Installing a solar panel requires at least four mounting brackets per solar panel. A solar panel is attached to a mounting rail at least near two opposite sides of a solar panel. A solar panel is attached to a mounting rail with at least two mounting brackets near ends of one side of a solar panel. Depending on the load caused by, for example, the wind or the weight of a solar panel installation, additional mounting brackets can be placed.

Preferably, the kit includes hammer head bolts and nuts for securing the mounting rails to the support members and bolts for securing the mounting brackets to the mounting rails.

This kit is advantageous for the installation of solar panels in that it comprises a mounting rail according to the first aspect, whereby a solar panel can be mounted quickly and easily on a mounting rail by means of a mounting bracket and a bolt.

Hereby, the mounting rail in the kit provides the necessary flexibility to fix a support element with the first side wall facing a surface on which the solar panel is placed, or laterally to the fourth side wall, depending on the surface on which the support element is placed or mounted.

It is obvious to a person skilled in the technical field that the kit may include additional mounting rails, support elements and mounting brackets, depending on the number of solar panels in an installation.

According to one embodiment, the kit comprises identical support elements configured for fastening by means of nails and/or screws on a part of a pitched roof.

A support element is, for example, a screwed roof hook or a hook attachment.

According to one embodiment, the kit comprises support elements and connecting elements configured for assembly into a wedge-shaped frame, the wedge-shaped frame comprising an acute angle of at least 20° and at most 45°.

Such a wedge-shaped frame is advantageous for placing solar panels at an angle on a ground surface or a flat roof.

The wedge-shaped frame is fixed to the ground surface or flat roof using screws.

Alternatively, the kit includes ballast for anchoring a wedge-shaped frame placed on a ground surface or a flat roof.

According to one embodiment, the mounting bracket comprises an L-shape.

The L-shape includes a circular bore through a first leg of the L-shape for securing the mounting bracket to the mounting rail by means of a bolt through the circular bore.

The L-shape is suitable for attaching a solar panel to a mounting rail, wherein a solar panel is clamped between a second leg of the L-shape and the mounting rail.

According to one embodiment, the mounting bracket comprises an S-shape.

The S-shape includes a standing leg and two lying legs.

A first lying leg includes a circular opening for securing the mounting bracket to the mounting rail by means of a bolt through the circular opening.

The S-shape is suitable for attaching a solar panel to a mounting rail, wherein a solar panel is clamped between a second lying leg of the S-shape and the mounting rail.

In one embodiment, the mounting bracket comprises a base wall and two side walls, the base wall and the two side walls forming a U, each side wall including a collar at a free end, substantially parallel to the base wall, the collar extending in a direction away from the You stretch. The mounting bracket is suitable for attaching two solar panels to a mounting rail, wherein a first solar panel is clamped between a first collar and the mounting rail and wherein a second solar panel is clamped between a second collar and the mounting rail. The base wall includes a circular opening for securing the mounting bracket to the mounting rail by means of a bolt through the circular opening. Such a mounting bracket is advantageous for reducing the number of mounting brackets required in installations with several adjacent solar panels.

It will be apparent to one skilled in the art that a kit may comprise a mixture of L-shaped, S-shaped and U-shaped mounting brackets, as in embodiments described above.

According to one embodiment, the kit comprises a water-resistant crossbar for fastening the support element to a gable roof. A water-resistant crossbar is, for example, a plastic crossbar. A water-resistant crossbar is, for example, an impregnated wooden crossbar. The water-resistant crossbar preferably has a rectangular cross-section with a height of at least 24 mm and a width of at least 95 mm. The water-resistant cross batten is suitable for transverse attachment to counter battens in the saddle roof. A water-resistant cross lath is advantageous for fixing a support element according to an above-described embodiment on a gable roof, wherein the support element is attached to the water-resistant cross lath by means of screws and/or nails and wherein the support element can be positioned freely in the width of the gable roof. turn into. According to one embodiment, the kit comprises a support element which is adjustable in height. A height-adjustable support element makes it possible to regulate the distance between the mounting rail and a surface on which the solar panel is placed. This is advantageous in order to be able to fix a mounting rail parallel to the surface and to be able to fix adjacent mounting rails at the same distance from the surface. Solar panels can therefore be guaranteed to be placed in a plane.

According to one embodiment, the kit includes coupling elements configured for coupling adjacent mounting rails. This is advantageous to obtain a longer mounting rail or to connect mounting rails at right angles to each other in order to obtain a frame.

According to one embodiment, a coupling element is an elongate plate with a height of at least 30 mm, preferably 35 mm and a length of at least 200 mm, preferably at least 250 mm. The coupling element comprises at least two circular openings, suitable for the passage of a bolt or hammerhead bolt. Preferably, the coupling element comprises at least four holes. The holes are preferably located on a longitudinal axis of symmetry. The coupling element is attached to a first and a second mounting rail by means of bolts and nuts or hammer head bolts and nuts. The bolt, nut or hammerhead bolt is preferably placed in a longitudinal groove in the first or fourth side wall of the mounting rail. This coupling element is advantageous for obtaining a longer mounting rail.

According to one embodiment, a coupling element is an L-shaped plate with a width of at least 30 mm, preferably 35 mm. One leg of the L-shaped plate has a length of at least 30 mm, preferably at least 40 mm. One leg includes a circular opening suitable for the passage of a bolt or hammerhead bolt.

The L-shaped plate preferably comprises equal legs. The coupling element is attached to mounting rails in a similar manner as in an embodiment of a coupling element described above. This coupling element is advantageous for connecting mounting rails at right angles to each other in order to obtain a frame.

According to an embodiment, the kit comprises at least two cover caps. The cover caps are configured to fit the open end of a mounting rail. The cover caps are advantageous for closing off the open end, so that, for example, no moisture can penetrate into the mounting rail.

In a third aspect, the invention relates to a method for installing solar panels.

According to a preferred embodiment, the method comprises the steps of attaching or placing a support element on a surface; mounting a mounting rail according to the first aspect to the support element and mounting a solar panel to the mounting rail.

It is apparent to one skilled in the art that a support element may be placed or mounted on a ground surface or flat roof or mounted on a pitched roof, as in the embodiments described above.

This method is advantageous in that a mounting rail according to the first aspect is used. This allows a solar panel to be mounted quickly and easily on a mounting rail using a mounting bracket and a bolt. The bolt remains visible and accessible during mounting of the solar panel and only the bolt needs to be manipulated. No simultaneous manipulation of, for example, a hammerhead bolt and a nut is required. It is also advantageous that the mounting rail allows the necessary flexibility to fix a support element to the first side wall, oriented towards the surface on which the solar panel is placed, or laterally to the fourth side wall. This depends on the surface on which the support element is placed or attached. When placed on a ground surface, a flat roof or a pitched roof covered with flat roof tiles or slates, a support element is preferably attached to the first side wall. A ground surface, flat roof or pitched roof covered with flat roof tiles or slates makes it possible to fix a mounting rail to a support element using, for example, a socket wrench, whereby the movement of the socket wrench in the case of installation on a sloping roof does not pass through the flat roof tiles or slates are obstructed. When placed on a ground surface or a flat roof, there is sufficient free space in any case. The attachment of the support element to the first side wall is also advantageous because in that case the mounting rail is positioned above the support element, so that the weight of a solar panel in this arrangement exerts a moment where the support element rests against the ground surface, the flat roof or the pitched roof. is printed. As a result, there is a lower load on screws or nails with which the support element is possibly attached to a surface.

When placed on a pitched roof covered with undulating roof tiles, a support element is preferably attached to the fourth side wall. With undulating roof tiles, the movement of a socket wrench when attaching a support element to the first side wall is hindered by the undulating roof tiles, unless the mounting rail is mounted excessively high above the pitched roof, which is not desirable. When the support element is attached to the fourth side wall, a socket wrench can move unhindered in a plane transverse to the gable roof. According to one embodiment, the method comprises the additional step of adjusting the height of the mounting rail above the surface. This is advantageous in order to be able to fix a mounting rail parallel to the surface and to be able to fix adjacent mounting rails at the same distance from the surface. Solar panels can therefore be guaranteed to be placed in a plane.

According to one embodiment, the method includes the additional step of orienting a mounting rail on an outer periphery of a solar panel installation, wherein the third closed sidewall faces the outer perimeter of the installation.

The mounting rails on the outer perimeter of a solar panel installation are the mounting rails that are most exposed to external conditions, such as weather conditions. By orienting the third side wall of a mounting rail on the outer circumference in the direction of the outer circumference, the mounting rail is protected as well as possible against, for example, precipitation. Rain cannot penetrate directly into one of the mounting rail's longitudinal grooves, so no water remains in these grooves. The longitudinal groove in the first side wall faces the surface on which the solar panels are placed. The longitudinal groove in the second side wall is covered by the solar panels. The longitudinal groove in the fourth side wall is also shielded by the solar panels.

According to one embodiment, the method comprises the additional step of coupling adjacent mounting rails by means of coupling elements. The coupling elements are advantageous for obtaining longer mounting rails from two or more mounting rails. L-shaped coupling elements are advantageous for connecting mounting rails at right angles to each other in order to obtain a frame.

According to one embodiment, the method comprises the additional steps of removing a row of roof tiles or slates from a gable roof between at least two adjacent battens and/or rafters, attaching a water-resistant cross batten transversely to the at least two adjacent battens and/or rafters, attaching a support element to the water-resistant crossbar and replacing the roof tiles and/or slates.

In known methods according to the state of the art, a support element is clamped around a tile batten and a roof tile or slate, whereby a roof tile or slate can break or crack under heavy load, for instance due to wind, resulting in water seepage.

In another known method, a support element is attached to a batten batten and/or twill.

This has the drawback that a support element can only be placed at a limited number of positions in the width of the saddle roof, so that a support element cannot necessarily be optimally placed in a cavity of a roof tile, so that it is sometimes necessary to grind into a roof tile. .

This again damages the roof tile, causing it to crack or break.

It also limits the choice of positioning a solar panel installation.

In addition, the support elements are fixed in the thin battens and/or rafters by means of screws, so that they can split.

The screws can rust and rot the wood.

The method according to the present invention is advantageous because use is made of a water-resistant cross lath, which is fastened transversely to at least two counter battens and/or rafters.

The water-resistant crossbar preferably has a rectangular cross-section with a height of at least 24 mm and a width of at least 95 mm.

By using a water-resistant crossbar, a support element can be positioned freely over the full width of the crossbar.

An installation of solar panels can be optimally positioned and support elements can be placed in a cavity of a roof tile, so that it is not necessary to grind in the roof tile to guide a support element from the batten or rafter through the gable roof.

A support element can be firmly attached to the water-resistant crossbar with several screws.

The water-resistant crossbar will not split due to its size and will not rot due to its water resistance.

The water-resistant crossbar is attached to the counter battens and/or rafters using several nails with glue.

The width of at least 95 mm allows the nails to be spread out sufficiently to minimize the risk of splitting a batten batten or twill.

By using nails with glue, the wood will be held together by the glue in case of splitting. The adhesive also limits possible water seepage, which prevents the wood of a batten or twill rot.

In a fourth aspect, the invention relates to a method according to the third aspect, performed with a kit according to the second aspect. One skilled in the art will appreciate that the kit is preferably configured for performing the method, and thus the method can be performed using the kit. Accordingly, each feature described in this document, above as well as below, may relate to any of the four aspects of the present invention. The present invention will now be described in more detail with reference to figures which are not limiting.

DESCRIPTION OF THE FIGURE Figure 1 shows a cross-sectional view of a mounting rail according to the prior art. A mounting rail (1) according to the prior art comprises four side walls. A first sidewall (2) includes a longitudinal groove (3) configured to receive a hammerhead bolt. The longitudinal groove (3) comprises two collars (4) extending towards each other and located in the plane of the first side wall (2). An opposing second side wall (5) includes a longitudinal groove (6) configured for mounting a solar panel. The longitudinal groove (6) comprises two collars (4) extending towards each other and located in the plane of the second side wall (5). The mounting rail comprises a third side wall (7) and a fourth side wall (8), which are placed transversely to the first side wall (2) and the second side wall (5). The third side wall (7) and the fourth side wall (8) are closed side walls. The mounting rail (1) has a rectangular cross-section, comprising two chambers (9), separated by a single rib (10). Figure 2 shows a sectional view of a mounting rail according to an embodiment of the present invention.

The mounting rail (1) according to the present invention comprises four side walls.

A first sidewall (2) includes a longitudinal groove (3) configured to receive a hammerhead bolt.

The longitudinal groove (3) comprises two collars (4) extending towards each other and located in the plane of the first side wall (2).

An opposing second side wall (5) includes a longitudinal groove (6) configured for mounting a solar panel.

The longitudinal groove (6) includes longitudinal notches (11) in upstanding walls configured to interact with the threads of a bolt (12). The third side wall (7) is placed transversely to the first side wall (2) and the second side wall (5).

The third side wall (7) is a closed side wall.

The fourth sidewall (8) is also placed transversely to the first sidewall (2) and the second sidewall (5) and substantially parallel to the third sidewall (7).

The fourth side wall (8) includes a longitudinal groove (13) configured to receive a hammerhead bolt.

The longitudinal groove (13) comprises two collars (4) extending towards each other and located in the plane of the fourth side wall (8).

The mounting rail (1) has a rectangular section, comprising four chambers (9) in each corner of the rectangular section and a chamber (14) centrally in the rectangular section.

The chambers (9) and (14) are formed by contiguous ribs (10).

Figure 3 shows a perspective view of a mounting rail according to an embodiment of the present invention attached to a support element.

The mounting rail (1) is similar to the embodiment shown in Figure 2.

The support element (14) is attached laterally to the mounting rail (1).

The support element (14) is fastened to the mounting rail (1) by means of a hammer head bolt (15) in the longitudinal groove (13) in the fourth side wall (8) and a nut (16).

The support element (14) is adjustable in height.

To this end, the support element (14) comprises a slot-shaped opening (17), a bolt (18) and a nut for slidably coupling a fastening element (19) of the support element (14) to a base element (20) of the support element (14).

The nut is not visible on the figure.

On top of the mounting rail (1), a mounting bracket (21) is fixed with the aid of a bolt (12) in the longitudinal groove (6) of the second side wall (5).

The mounting bracket (21) includes a base wall (22), two side walls (23), and at one end of each side wall (23), a collar (24) extending substantially parallel in a direction away from a U-shape, the U shape is formed by the base wall (22) and the two side walls (23).

Claims (14)

CONCLUSIONS A mounting rail for installation of solar panels consisting of an elongated profile of rectangular section formed by four side walls and internal ribs, a first side wall comprising a longitudinal groove with two collars configured to receive a hammerhead bolt, the two collars being located extending towards each other and being in the plane of the first side wall; wherein a second opposing sidewall includes a longitudinal groove configured for mounting a solar panel; and wherein a third sidewall is a closed sidewall; characterized in that a fourth sidewall includes a longitudinal groove with two collars configured to receive a hammerhead bolt, the two collars extending towards each other and being in the plane of the fourth sidewall, and in that the longitudinal groove in the second sidewall includes longitudinal notches in upstanding walls of the groove configured to interact with the threads of a bolt. Mounting rail according to claim 1, characterized in that the profile comprises in each corner of the rectangular cross-section and centrally in the profile a chamber formed by contiguous ribs, a chamber extending longitudinally. Mounting rail according to claim 1 or 2, characterized in that each side wall and rib of the profile has a thickness of at least 1.8 mm. Mounting rail according to one of the preceding claims 1-3, characterized in that the mounting rail is coated with a powder coating. A kit for installing solar panels, comprising a mounting rail according to any one of the preceding claims 1-4; at least four mounting brackets for mounting a solar panel on the mounting rail and at least four support elements for mounting or positioning the mounting rail on a surface. Kit according to claim 5, characterized in that the mounting bracket comprises a base wall and two side walls, the base wall and the two side walls forming a U, each side wall comprising a collar at a free end substantially parallel to the base wall, wherein the collar extends in a direction away from the U. Kit as claimed in any of the foregoing claims 5-6, characterized in that the kit comprises a water-resistant cross lath for fastening the support element to a gable roof. 8. Kit as claimed in any of the foregoing claims 5-7, characterized in that the support element is adjustable in height. Kit according to any one of the preceding claims 5-8, characterized in that the kit comprises coupling elements configured for coupling adjacent mounting rails. A method of installing solar panels comprising mounting or placing a support member on a surface; fixing a mounting rail according to any one of the preceding claims 1-4 on the support element and fixing a solar panel to the mounting rail, characterized in that the method comprises the additional step of orienting a mounting rail on an outer circumference of an installation of solar panels, with the third closed side wall facing the outer perimeter of the installation. Method according to claim 10, characterized in that the method comprises the additional step of adjusting the height of the mounting rail above the surface. A method according to claim 10 or 11, characterized in that the method comprises the additional step of coupling adjacent mounting rails by means of coupling elements. A method according to any one of claims 10-12, characterized in that the method comprises the additional steps of removing a row of roof tiles or slates from a gable roof between at least two adjacent battens and/or rafters, attaching a waterproof cross lath, transverse to the two adjacent counter battens and/or rafters, attaching a support element to the water-resistant cross lath and replacing the roof tiles or slates. A method according to any one of the preceding claims 10-13, performed using a kit according to any one of the preceding claims 5-9.