DE202007012020U1 - Carrier system for photovoltaic elements - Google Patents

Abstract

Carrier system, which is suitable to carry photovoltaic elements on a building roof (1) with an inclination of 0 to 20 °, comprising
At least a first level consisting of a plurality of elevation elements,
At least one second level consisting of a plurality of substructure elements,
- At least a third level, consisting of securing elements with holding elements (7) which are adapted to be coupled to photovoltaic elements, wherein
- The Aufständerungselementen the first plane are slidably mounted on a support surface (2) of the building roof (1),
- The second level releasably connected to the first level, wherein a longitudinal axis (AA) of the substructure elements with a longitudinal axis (BB) of the Aufständerungselemente forms an angle (α), and
- Form the third level fuse elements with the substructure elements of the second level a grid pattern.

Description

The The following invention relates to a support system for photovoltaic elements, in particular for the Application on flat roofs.

STATE OF THE ART

Numerous photovoltaic systems are known from the prior art. Basically, photovoltaic modules are used to generate electrical energy from sunlight. In this case, the photovoltaic modules (PV modules) are arranged with the largest possible surface on a support such that the solar radiation on the PV modules is optimally possible. In order to arrange the PV modules, therefore, a support structure is required to ensure optimum light incidence on the elements. Such a support structure is approximately in the DE 20 2006 009 100 U1 described. Here, a support structure for solar modules for use on the site or the water surface is disclosed, with the focus being that depending on the number of supported by the support structure solar modules, the entire element should be portable. The disclosed subject matter is substantially directed to providing a portable solar module support member that provides maximum transportation comfort.

In many cases, however, the constructions that carry solar modules need not be portable, but should, in contrast, rest firmly on a substrate. Such ground may exist in the earth's surface, but especially in a roof area. The DE 20 2006 009 884 U1 describes therefore a substructure for a photovoltaic system, in particular a device for arranging photovoltaic modules on a support surface. The disclosed subject matter is intended to provide a safe and cost effective arrangement of PV modules on mounting surfaces, even on roofs. In this case, the object is designed such that the mounting surface is not destroyed or impaired by the arrangement of the PV modules; Therefore, fastening by means of screwing, which makes drilling required, is dispensed with. The disclosed device is therefore supported on a support surface such that in a region in which a photovoltaic module is arranged, the support surface is covered without support. By appropriate arrangement, the number of points at which the device is supported on the support surface or mounting surface is minimized; When measuring the number of interpolation points, the statics must be taken into account. The device comprises a cross member and a support member, wherein the PV module is disposed on the cross member and the support member, the cross member spaced from the support surface. Thus, a frame construction is provided on which the PV modules are arranged.

EPIPHANY

outgoing from this prior art, the present invention is the Task based, an improved photovoltaic system for arrangement on building roofs with to create a roof slope of up to 0 to 20 °. This task is powered by a photovoltaic system for placement on a flat roof the characteristics of the independent Claim 1 solved.

One first embodiment The invention relates to a support system that is suitable photovoltaic elements to be carried on a roof with a slope of 0 to 20 °. It is basically off built three levels of different construction elements, the in a level uprights, slidably mounted on a roof support surface. This allows the building roof advantageously continue to be repaired or subjected to revision, by desired Place the lowest level without loosing the superstructure, partially reversible becomes. It is particularly advantageous that this lower level is not is attached to the roof and this is not damaged and thus suffers no leakage. A second level includes substructure elements that are lightweight and static sent on the uprising elements can be stored. The third level advantageously comprises securing elements with holding elements, on which the photovoltaic elements can be arranged. The security elements are heavy and paint over the lower levels; they are already advantageous their own weight and form with the levels below a heavy and secure grid that was statically sent to come to rest and wind forces derives.

A another embodiment refers to the carrier system, that in its orientation advantageous to one of building roof support elements how about laminated beams spanned roof can be adapted, wherein the uprising elements forming the first plane are a longitudinal direction which is oriented so that each uprising element at least one of the roof rack sweeps over.

A yet another embodiment after all comprises the carrier system according to the invention, wherein the first level forming Aufständerungselemente on the Roof construction spanning elements such as glulam roof construction beams rest. Of course lies between these two elements levels the roof covering, which is beneficial unharmed obese, if the uprising elements arranged thereon become. The uprising elements in this case do not run parallel to a roof edge, what statically particularly favorable can be.

Further embodiments refer to the lattice patterns created by the arrangements of individual levels, and the associated alignment of the carrier system and the possibilities associated with it, the photovoltaic elements ideally to the south direction to align to benefit maximally from the solar energy.

Yet further embodiments refer to the shape of the substructure elements, which are advantageous Cheap available, easy-to-manufacture trapezoidal carrier plates could be.

The The above and other advantages will become apparent from the following description and the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES

Of the Reference to the figures in the description is for the support of Description. objects or parts of objects, which are essentially the same or similar are, can be provided with the same reference numerals. The figures are merely a schematic representation of an embodiment of the invention.

1 shows an exploded view of the carrier system according to the invention,

2 shows a perspective top view of the arranged on a flat roof carrier system according to the invention,

3 shows a perspective section of the arranged on a flat roof carrier system,

3a shows an exploded view of a cross section of a Aufständerungsblockes.

DESCRIPTION

The inventive carrier system, which is suitable for photovoltaic systems on roofs with a slope of at the most 20 ° to wear, is particularly advantageous for the application on flat roofs, because the system of the invention no roof penetration of the water-bearing roof skin is required.

Basically on the roof skin only Aufständerungselemente laid, which is virtually a first level of the carrier system according to the invention form. Because of the uprising elements are merely applied, they are displaceable on their support level, so after lifting the levels described below through Move the support level at any time the revision and repair the bearing surface possible is. It is particularly advantageous that the on the first Level arranged further elements including the photovoltaic (PV) elements not from the carrier system must be dismantled. The uprising elements can advantageously created from Aufständerungsblöcken be placed on the support surface in such a way that they essentially transversely to the support surface itself forming support elements of bituminous Building roofs with Roof support columns, as they are made for example of laminated beams to be laid. Of course you can the carrier system according to the invention also on concrete or other roofs be attached. Advantageously, the uprising blocks are arranged parallel to one another, the distance from each other may be in the range of 1.0 m to 7.0 m, preferably from 2.5 m to 3.0 m, so that by an optimal number of Uprising blocks none high weight load is applied by this on the support surface.

Corresponding to the length of the substructure elements placed on the uprising blocks, long distances, in particular on flat roofs with roof carrier constructions, can be overcome without adversely affecting the roofing capacity. The weight introduction of the PV systems into the roof of the building is achieved with the help of the up to 10 m span bridging trapezoidal sheets - their length becomes Usually be located in the range of 3.0 m to 7.5 m because of the handling - determinable, since the uprising blocks are placed only in the range of outer walls or glued laminated timber or other beams of the building construction.

1 shows the arrangement of the invention as Aufständerungsblöcke 4 trained Aufständerungselemente which are arranged parallel to each other. The uprising blocks 4 have a length that corresponds to the width of a substructure element. The uprising blocks 4 , which are slidable on the support surface 2 of the building roof 1 are arranged have a longitudinal axis BB, which forms an angle with a longitudinal axis of an element, in particular a laminated beam roof carrier, which spans the building roof - not shown figuratively - the between 0 ° and 90 °, preferably between 30 ° and 90 °, most preferably between 45 ° and 90 °.

In this first level, a second level of support elements or substructure elements is placed, in the present case of trapezoidal sheet metal elements 5 be made available, so of elements that are easy and inexpensive to manufacture and available in different lengths and allow large static spans, up to 10 m. The longitudinal axis BB of the elevation blocks 4 forms with the longitudinal axis AA of the substructure elements, respectively the trapezoidal sheet metal elements 5 , an angle α. This is presently at 90 °, but can basically be between 0 ° and 90 °.

How out 1 becomes clear, can on a first level of trapezoidal sheet metal elements, a second level of trapezoidal sheet metal elements 5 be placed, in which the support is made so that the trapezoidal sheet metal elements 5 adhere to each other by positive locking. In one plane, to span about the entire length of a roof with a first level of substructure elements, trapezoidal sheet metal elements may be used 5 different lengths are arranged to each other such that a plurality of mutually parallel trapezoidal sheet metal elements 5 forms the total length of the first layer of substructure elements in the second plane. This second level spans a total area equal to the area spanned by the first level of elevation elements; both surfaces are congruent.

This second level of trapezoidal sheet metal elements 5 can so on the first level of trapezoidal sheet metal elements 5 be applied that the bumps of the underlying level of trapezoidal sheet metal elements 5 are each overlapped, which advantageously the stability of the substructure level is enhanced. Depending on the desired ge stability of the substructure level can have multiple levels of trapezoidal sheet metal elements 5 one above the other, as indicated by arrows a in FIG 1 is indicated. This can be done to generate a higher weight against suction and crosswinds.

Of course it will the expert know that except the cheap, easily available and easy to transport trapezoidal sheet metal elements and others Elements can be used which can be made of aluminum or plastic or about show in cross section no trapezoidal shapes, but about triangular shapes as shown for example by triangular plates, or semi-circular or semi-oval forms, as they are present in corrugated iron elements. Of course they are other suitable cross-sectional geometries conceivable, the expert are known.

How out 1 can be seen, the elements that form the substructure level, so on the Aufständerungsblöcken 4 are arranged so that a parallel running, spaced-apart, strip-like basic pattern is formed on the trapezoidal sheet.

As 1 shows, and in particular 2 holding the arrangement on a flat roof 1 with an attic 10 demonstrated, a third level consisting of securing elements is arranged on the substructure level. In the present case, the securing elements are rails 6 , where the rails 6 basically have different shapes. It may also be profiles or rods with a round, oval or square, in particular rectangular cross section, further cross-sectional shapes are of course conceivable. From 1 to be seen uprising blocks 4 be on the in 2 shown bearing surface 2 of the building roof 1 , which here is a flat roof, arranged.

In the 1 and 2 shown rails 6 have at their pointing away from the substructure level top holding elements 7 suitable for the photovoltaic elements can be mounted on them. At the rails 6 these are preferably such rails 6 , which are made of heavy materials, so that by the circulation of heavy rails 6 on the substructure level already by weight is a backup. The third level is therefore due to the large number of rails 6 formed with the underlying substructure elements, re prospective trapezoidal sheet metal elements 5 form a grid pattern.

The grid pattern created between the second and third levels is a grid with grid areas of squares, rectangles or parallelograms 9 , as in 2 shown, formed, since the securing elements are advantageously also arranged parallel to each other. Together with the substructure level, the third level securing elements form a "safety grate", which is advantageously made of metal, which compensates for the static effects required by wind but through the trapezoidal sheet metal elements 5 alone unattainable total dead weight of the entire plant with the photovoltaic elements. By the arrangement of the three levels and the attachment of the photovoltaic elements on the holding elements 7 , Which are arranged on the securing elements, is achieved by the entire system a total weight in conjunction with the over the entire roof surface extending security elements, which is sufficient to control wind forces statically.

In addition, the securing plane can be formed by an at least partially arranged securing profile circulating around the end faces of the securing elements 15 be assured, this by claw-shaped angle iron 16 is secured. Here is the longer leg of the pratzenförmigen angle iron 16 - It may be about an aluminum flat profile - led down to the outer wall in a way, so this angle iron 16 can be screwed to the attic, or a concrete ring anchor or to the steel structure of the building. The shorter leg of the pratzen-shaped angle iron 16 or even a "hat profile" lies pratzenartig on the circumferential frame of the metal profile safety grating 15 on. The security profile 15 may be a metal U-profile, which encloses and stabilizes the metal profiles of the grate. It can also be clamped over the Attika corners also bow-shaped security elements

As in particular from 1 becomes clear, are the uprising blocks 4 slidable under the substructure elements, as they are with the support surface 2 (please refer 2 ) are not screwed. In order to ensure easy displacement, the Aufständerungsblöcke 4 on its upper side with two parallel plastic spacers 8th be equipped. The arrows b show those of the uprising blocks 4 lifted trapezoidal sheet metal elements 5 , Of course, more or less than two strips on the uprising blocks 4 be arranged. The shape of the cross sections of the strips can be triangular or round, or have other suitable geometry, the elements reduces the contact surface between the Aufständerungselementen and the substructure to be arranged above.

The plastic spacers 8th may in principle have different heights, so that in the case of the plurality of Aufständerungsblöcken 4 , which are arranged on a support surface, respectively a roof, with the selection of different height plastic handle strips 8th also a slope compensation of the roof can be created. Of course, more than the two bars shown 8th on the uprising blocks 4 be arranged, the corresponding alternative strips must also not necessarily be made of plastic, but they can also be made of a suitable metal or wood.

An uprising block 4 may consist of one or more elements, depending on the total height of the uprising blocks to be achieved. For example, as in 3 shown a flat roof 1 with a comparatively high attic 10 and bearing surface 2 is present, it is necessary that the support system for the photovoltaic elements forms a relatively high construction, so that the substructure elements possible only with a distance 12 from about 1-2 cm below the top of the parapet 10 to lock. This shading of the solar modules, respectively PV elements, through the building attic 10 counteracted.

If at a high parapet 10 the substructure elements are too deep, the photovoltaic elements are through the parapet 10 shaded and the energy input to the photovoltaic elements is reduced. The uprising blocks 4 may therefore consist of several individual blocks, each of which may have a square or rectangular cross-section; it is also conceivable that, as in 3a shown, the cross-sectional area of the blocks forms a trapezoid, respectively, a rectangular trapezoid, so that two complementary block modules 11 . 11 ' the uprising block 4 form. For block modules 11 . 11 which are bevelled at their top or bottom, and in the present case according to arrow c are arranged on top of each other, there is the particular advantage that the block modules 11 . 11 ' are mutually displaceable, which is particularly advantageous when Aufständerungsblock 4 should be released from its position on the support surface and moved. By shifting the elements against each other 11 . 11 ' in the corresponding direction (arrows d) then the Aufständerungsblock 4 separated into its two components, which then at another Correspondingly, they can be pushed together again. In this case, the two block parts are by a profile iron, such as the flat profile 13 , secured. The flat profile is with screws 14 screwed to the block parts. Of course, a claw or other securing element, which is suitable to secure the two or more block elements against slipping, are attached to the end faces.

As in 2 shown, the securing elements of the third level are advantageously arranged on the second level, that when fixing fixed photovoltaic elements they are ideally aligned in the south direction, to ensure optimum energy input.

Of course, it is also conceivable that the photovoltaic elements pivotally mounted on the holding elements 7 , in the 1 merely exemplified are arranged. With pivotally mounted photovoltaic elements on corresponding holding devices which are arranged on the fuse elements, there is the advantage that regardless of the arrangement of the underlying, the carrier system forming three levels an ideal light absorption can be ensured by the photovoltaic elements, since the photovoltaic elements already from the state are known in the art, trackable photovoltaic elements that follow according to the light.

Advantageous substructure elements are the known trapezoidal sheets, which can be correspondingly galvanized and can have spans of up to 7.50 m. If elements of greater length or shorter elements are available on the market, they can be arranged at any time in the arrangement according to the invention on the Aufständerungsebene; if necessary, can trapezoidal sheet metal elements 5 can be shortened and the "piece of rubbish" can be placed elsewhere or used in a second plane to overlap two joints under it 5 , which often have a plate thickness of 0.75 mm and which are available on the market in lengths of 750 cm and widths of 92 cm, bolted together, riveted or glued. This allows several layers of trapezoidal sheet metal elements form a substructure level. Basically, the following dimensions are preferred for the substructure elements:
A length in the range of 3.0 m to 10.0 m, most preferably a length of 7.0 m, a width in the range of 0.5 m to 2.0 m, more preferably a width of 0.7 m to 1.40 m, most preferably a width of 1.0 m, and a thickness in the range of 0.5 mm to 2.0 mm, most preferably a thickness of 0.75 mm.

The available on the market Trapezoidal sheet metal substructures are often galvanized. Of course, the Trapezoidal sheet metal elements, like all others, form a substructure Elements coated, painted or otherwise related to their surface be modified.

At the edge of the roof, the trapezoidal sheet metal elements as well as triangle plate or corrugated sheet metal elements and all other open to the roof end geometries with corresponding end caps 3 , please refer 1 be provided to prevent ingress of wind or water. Furthermore, each element constituting the carrier system can additionally be secured to the edge of the roof without penetrating the roof skin. It may be possible to do this on the outside of the roof, as shown in 1 , an edge attachment by appropriate longitudinal profiles 9 make, which are screwed at one end to the corresponding trapezoidal sheet, Aufständerungsblock or fuse element, riveted or otherwise secured and screwed at its opposite end to the reinforced concrete ceiling on the outer wall of the building or riveted or otherwise secured. For this purpose, ring anchors can be introduced into the reinforced concrete ceiling.

The uprising blocks 4 can be placed variably on the support surface, their number and orientation depends on the static requirements, which are determined in particular by a support structure of the roof. An advantageous size of an uprising block may be in the length of 80 cm, the height of 25 cm and the width of 20 cm. Of course, other dimensions are chosen depending on the requirements given by the statics and roof geometry.

The security elements can advantageously be arranged at a distance of about 2.50 m parallel next to each other on the substructure level. Great stability is achieved when the angle subtended by a securing element with respect to the underlying substructure element is 90 °. Of course, other angles, also depending on the roof geometry or the static requirements can be selected. LIST OF REFERENCE NUMBERS 1 flat roof 2 bearing surface 3 endcaps 4 Elevation Blocks 5 Trapezoidal sheet elements 6 rails 7 retaining elements 8th Plastic trapeze bars 9 longitudinal profile 10 Attica 11 . 11 ' block modules 12 distance 13 low profile 14 screw 15 Circumferential profile 16 angle iron 17 screw AA longitudinal axis BB longitudinal axis ( α ) Angle between longitudinal axes AA and BB

Claims (23)

Carrier system that is suitable for photovoltaic elements on a building roof ( 1 ) with an inclination of 0 to 20 °, comprising - at least one first plane consisting of a plurality of elevation elements, - at least one second plane consisting of a plurality of substructure elements, - at least one third plane consisting of securing elements with retaining elements ( 7 ) which are adapted to be coupled with photovoltaic elements, wherein - the elevation elements of the first plane slidable on a support surface ( 2 ) of the building roof ( 1 the second plane is detachably connected to the first plane, wherein a longitudinal axis (AA) of the substructure elements forms an angle (α) with a longitudinal axis (BB) of the elevation elements, and - the securing elements of the third plane with the substructure elements form a grid pattern on the second level. carrier system according to claim 1, wherein the uprising elements are arranged parallel to each other. carrier system according to claim 1 or 2, wherein an elevation element has a length, which corresponds to a width of a substructure element. carrier system according to one of the claims 1 to 3, wherein the angle (α) between 0 ° and 90 °. carrier system according to one of the claims 1 to 4, wherein a longitudinal axis (B-B) of an uprising element with a longitudinal axis an element, in particular a laminated beam roof carrier, the the building roof spans, forms an angle between 0 ° and 90 °, preferably between 30 ° and 90 °, most preferably between 45 ° and 90 °. A carrier system according to any one of claims 1 to 5, wherein the second level and the third Ebe ne formed grid pattern shows grid areas with rectangular shape or with parallelogram. carrier system according to one of the claims 1 to 6, wherein the substructure elements structured, planar elements are whose length is larger as their width. A support system according to any one of claims 1 to 7, wherein the uprising elements comprise uprising blocks ( 4 ) are. A carrier system according to claim 7, wherein the elevation blocks ( 4 ) several parts, in particular at least two complementary block modules ( 11 . 11 ' ). Carrier system according to claim 9, wherein at the plurality of parts, in particular at the at least two complementary block modules ( 11 . 11 ' ) frontally a securing element, in particular a flat iron ( 13 ) or a claw is mounted. carrier system according to one of the claims 1 to 10, wherein the uprising elements at its side facing the second plane along its longitudinal direction at least one strip, preferably a strip with a trapezoidal cross section, exhibit. carrier system according to claim 11, wherein the elevation elements and / or the Substructure elements and / or the strips of a metal, a metal alloy, a plastic or wood or one Combination of the same exist. carrier system according to claim 7 to 12, wherein the structured, planar element a corrugated sheet metal element or a triangular sheet metal element or a sheet metal with another suitable cross-sectional geometry. Carrier system according to one of claims 1 to 10, wherein the substructure elements Trapezblechblechelemente ( 5 ), preferably with a length in the range of 3.0 m to 10.0 m, most preferably with a length of 7.5 m, preferably with a width in the range of 0.5 m to 2.0 m, more preferably with a width of 0.7 m to 1.40 m, most preferably with a width of 1.0 m, preferably with a thickness in the range of 0.5 mm to 2.0 mm, most preferably with a thickness of 0.75 mm, are. carrier system according to one of the claims 6 to 12, wherein a plurality of structured, sheet-like elements overlap or on top of each other form-fitting arranged a substructure element constituting the second level forms. carrier system according to claim 13, wherein the one above the other arranged structured, flat, form-fitting glued together interconnected elements, bolted or riveted. Support system according to one of the preceding claims, characterized in that the retaining elements ( 7 ) have a device for receiving fixedly mounted or the light trackable arranged photovoltaic elements, preferably nachführbar arranged solar panels. carrier system according to one of the preceding claims, characterized the second and third planes each span congruent surfaces. Support system according to one of the preceding claims, characterized in that the securing elements profiles or bars or rails ( 6 ), preferably profiles or bars or rails ( 6 ) made of metal, are. carrier system according to one of the preceding claims, characterized that the substructure elements and / or the securing elements galvanized, coated, painted or with another suitable, from the weather protected Layer are provided. Supporting system according to one of the preceding claims, characterized in that the substructure elements are provided at their ends with end caps ( 3 ) are provided. Support system according to one of the preceding claims, characterized in that the Siche tion level by an at least partially arranged, circulating around the front sides of the fuse elements fuse profile 15 is secured. Support system according to claim 22, characterized in that the securing profile 15 , with U-shaped profiles or angled, claw-shaped profiles ( 16 ), with screws ( 17 ) are screwed, is secured.