DE102021134135A1 - Process for creating a solar system on a roof of a property - Google Patents

Abstract

The invention relates to a method for creating a solar system on a roof of a property. The roof on which the solar system is to be positioned and adjacent parts of the property are measured. A plan for the design, manufacture and installation of the solar system on the roof with a total area of the effective area of the solar system pointing away from the roof, which lies in one or more effective levels, is drawn up, with each of the effective levels being broken down into sub-areas. The complete solar system is prefabricated and pre-assembled at the factory and transported to the roof. The solar system is brought in the folded state from the transport device to a position above the roof using a crane. The solar system is unfolded above the roof while it is still hanging on the crane. The solar system is precisely aligned using the crane and additional cables fixed to the solar system. The unfolded solar system is placed on the roof. The solar system is then fixed to the outside wall of the property and/or to the front ends of the purlins. The electrical and/or hydraulic installation of the solar system is connected to the property's electrical and/or hydraulic system and the solar system is put into operation.

Description

The invention relates to a method for creating a solar system on a roof of a property.

In practice, solar systems are currently installed on the roof of a property in such a way that the roof is measured first. Then the roof of the building is covered with solar modules, their fastening to the roof using mounting profiles and fastening elements and their connection to the building is planned. Individual roof tiles are then lifted up on the construction site, notched if necessary and roof hooks are screwed to the exposed rafters. Mounting rails are then fixed to the roof hooks in a cross connection. Subsequently, solar modules are gradually attached to the mounting rails and continuously electrically wired and/or hydraulically connected. The individual cables and/or pipes and hoses of the solar modules are then brought together and connected to the electrical or hydraulic system of the property.

The invention is based on the object of providing a method for creating a solar system on the roof of a property that enables more efficient, gentler and more cost-effective assembly.

• Das Dach, auf dem die Solaranlage positioniert werden soll, und die angrenzenden Immobilienteile werden vermessen. Unter einer Solaranlage wird im Sinne der Erfindung eine Photovoltaikanlage, eine Solarthermieanlage oder auch eine Kombination hieraus verstanden. Das Dach kann hierbei eine bereits vollständig die Immobilie gegen Wind und Regen sowie gegebenenfalls gegen Kälte schützende Dachkonstruktion oder auch lediglich ein noch nicht weiter ausgebauter Dachstuhl sein. Unter dem Dach im Sinne der Erfindung kann auch ein Dachabschnitt verstanden werden, falls die Solaranlage lediglich auf einem Teil des Daches erstellt werden soll. Beim Vermessen werden etwaige Dacheinbauten und Dachaufbauten berücksichtigt. Das Dach kann zudem eine Neigung aufweisen, wie beispielsweise ein Satteldach, oder es kann auch ohne wesentliche Neigung als Flachdach ausgebildet sein.

The invention is solved by a method with the features of patent claim 1. The method according to the invention comprises the following steps:

• The roof on which the solar system is to be positioned and the adjoining parts of the property are measured. In the context of the invention, a solar system is understood to mean a photovoltaic system, a solar thermal system or a combination thereof. The roof can be a roof construction that already completely protects the property against wind and rain and, if necessary, against the cold, or simply a roof structure that has not yet been further developed. The roof within the meaning of the invention can also be understood to mean a roof section if the solar system is only to be installed on part of the roof. When measuring, any roof installations and roof structures are taken into account. The roof can also have a slope, such as a gable roof, or it can also be designed as a flat roof without a significant slope.

A plan for the design, manufacture and installation of the solar system on the roof with a total area of the effective area of the solar system pointing away from the roof, which lies in one or more effective levels, is drawn up, with each of the effective levels being broken down into sub-areas. If the solar system is to be installed, for example, on the two sides of a gabled roof, then the total area of the effective surface of the solar system pointing away from the roof is divided into two effective levels. An effective level is later arranged on each of the two sides of the roof. If, on the other hand, the solar system is only installed on one side of a gabled roof or on a flat roof, the solar system only has one effective level.

• Jeweils ein Trägerrahmen wird für jede der Teilflächen hergestellt. Die Breite und Länge des Trägerrahmens ist dabei an die vorgegebene Dimensionierung der zu belegenden Dachfläche angepasst.

The solar system is completely prefabricated and pre-assembled at the factory and transported to the roof. The prefabrication and pre-assembly of the complete solar system is therefore carried out in a workshop away from the construction site and includes the following sub-steps:

• A support frame is produced for each of the sub-areas. The width and length of the support frame is adapted to the specified dimensions of the roof area to be covered.

Supporting elements arranged on an underside of the support frame are fixed to the support frame for support relative to the roof. The support elements are preferably formed by blocks of elastic polymer or alternatively by support feet, the latter being fixed at one end to the support frame and at the other end advantageously having a protective element against the roof being scratched.

Solar modules arranged on an upper side of the carrier frame opposite the underside are fixed to the carrier frame.

All of the carrier frames assigned to one effective level are connected to one another via swivel joints to form a solar roof part in each case. It is particularly preferred that all rotary joints of a solar roof part each have axes of rotation that are parallel to one another.

The necessary electronics and/or pipes for operating the solar modules are installed and a functional test is carried out. The carrier frames, which are connected to one another to form a solar roof part, are each positioned parallel to one another to form a package and are transported to the roof. The solar system with the at least one solar roof part is brought in the folded state by means of a crane from the transport device to a position above the roof. The solar system is unfolded above the roof while it is still hanging on the crane. The solar system is attached by means of the crane and by means of of the solar system fixed additional ropes, with the help of which a fine adjustment of the desired positioning in horizontal alignment is made. The unfolded solar system is placed on the roof. The solar system is fixed to the building's exterior wall and/or to the front ends of the roof purlins. The fixation serves in particular to counteract a lifting of the solar system at high wind speeds acting on it. The electrical installation of the photovoltaic components of the solar system is connected to the real estate electrics and/or the hydraulic installation of the solar thermal components of the solar system are connected to the real estate hydraulics. The solar system is put into operation.

The method according to the invention significantly shortens the assembly time on site due to the high degree of prefabrication. However, the total time required to set up the solar system is also reduced, since prefabrication in a factory is made easier by the fact that it is independent of the weather and that all the necessary tools and materials are available. This makes assembly more effective. In the case of an existing roof covering, this is not changed by the method according to the invention. In particular, there is no roof penetration. The process is therefore gentler on the existing roof than when the solar system is installed on site. If necessary, the solar system created using the method according to the invention can be clearly determined statically. This offers the possibility of official approval or type approval. Furthermore, a solar system created using the method according to the invention can also be installed on old or dilapidated roofs. A dismantling of the solar system created with the method according to the invention is easier and quicker to implement. This has an advantageous effect on an overall cost analysis and the solar system can be more easily dismantled and taken with you when you move.

In an advantageous embodiment of the invention, during the complete prefabrication and preassembly of the solar system at the factory, the partial step is also carried out that insulation is introduced inside the support frame. The solar system itself thus supports the insulation of the roof or even forms the insulating part of the roof itself.

In a preferred embodiment of the invention, during the complete prefabrication and pre-assembly of the solar system at the factory, the sub-step is also carried out that a water-impermeable layer is fixed between the solar modules and the support frame and after the unfolded solar system has been placed on the roof, roof installations and roof structures are waterproof to the water-impermeable layer Layer to be connected. As a result of this configuration, the solar system forms either in addition to an already existing water-draining layer of the roof or exclusively a water-draining layer of the roof.

Advantageously, the support elements are made of permanently elastic, weather-resistant and non-flammable foam. This configuration is particularly suitable for roofs with a pitch. On the one hand, the foam serves to support the solar system against the roof and, on the other hand, unevenness in the roof, which can be caused by the shape of existing roof tiles, for example, can be compensated for by the permanently elastic material of the support elements.

In an alternative advantageous embodiment of the invention, the supporting elements are supports, on the ends of which facing the roof roof protectors are attached. This configuration is particularly suitable for flat roofs. The supports are arranged on the support frame and support it with respect to the roof. Particularly preferably, the supports are only placed on the roof and are designed without being fixed to the roof. The roof skin remains undamaged.

In a particularly preferred embodiment of the invention, the solar installation has ballast weights in order to increase the weight of the solar installation and thereby prevent the solar installation from lifting off or slipping due to wind forces.

In a particularly preferred embodiment of the invention, the solar system below the partial areas is designed without connecting anchors between the carrier frame and the supporting structure supporting the roof, in particular the rafters. With this design, the skin of the roof is not damaged. In addition, the solar system can be assembled and disassembled more quickly and easily. A fixation of the solar system on the building exterior wall of the property and/or on the front ends of the roof purlins is independently excluded from this.

Advantageously, at least one stabilizing plate is arranged between the support frame and the support elements to support the support frame relative to the support elements and/or to stiffen the support frame.

In an advantageous embodiment of the invention, the support elements are arranged circumferentially below and along the edge of the solar system. Rain and wind can be prevented, at least for the most part, from getting under the solar system. In a particularly preferred embodiment of the invention, the solar system is not supported over the entire surface by the support elements, but rather only in partial areas. This can significantly save material and assembly time.

The support frames of a solar roof part are advantageously fixed relative to one another by means of stop elements in the unfolded state, in which the partial surfaces of the solar system of this solar roof part lie in one effective plane. A pivoting movement of the support frames beyond the stop of the respective stop element is prevented by the stop elements. The weight of the support frames and the parts mounted thereon in turn prevent movement of the support frames relative to one another away from the stop element after the solar system has been placed on the roof.

• 1 bis 8 Teilschritte des erfindungsgemäßen Verfahrens zur Erstellung einer Solaranlage auf einem Satteldach einer Immobilie und
• 8 bis 11 Detailansichten des Gegenstands aus 8.

Further details and advantages of the invention can be found in the subclaims and the exemplary embodiments explained below and shown schematically; show it:

• 1 until 8th Sub-steps of the method according to the invention for creating a solar system on a gable roof of a property and
• 8th until 11 detailed views of the item 8th .

The features of the process sequences presented below can also be the subject matter of the invention in other combinations. Elements of the exemplary embodiments that have the same effect are provided with a uniform reference number in the following, insofar as this makes sense.

1 until 8th show various partial steps of the method according to the invention for creating a solar system 2 on a roof 4 of a property 6. In the exemplary embodiment, the roof 4 to be covered with the solar system 2 is a gabled roof. The roof 4 and adjoining parts of the property are measured. A plan for the design, manufacture and installation of the solar system 2 on the roof 4 with a total area of the effective area of the solar system 2 pointing away from the roof 4 is drawn up. The solar system 2 is in the embodiment in two effective levels 8, wherein the pitched roof has two sides of the roof and a plane of action 8 is arranged on one side of the roof and the second plane of action 8 on the second roof side of the pitched roof, as shown in FIG 5 until 7 is evident. The two effective planes 8 in the exemplary embodiment are in turn broken down into two partial areas 10 .

The complete solar system 2 is prefabricated and preassembled at the factory. For this purpose, a support frame 12 is produced for each of the sub-areas 10, which 1 are shown. The support frames 12 each comprise a peripheral base frame 14 and ribs 16 which are arranged within the base frame 14 and are fixed thereto. Free areas 18 for installations or structures 20 on the roof 4 are present within the solar system 2 . These free areas 18 are already created in the support frame 12, as in 1 you can see.

Supporting elements 24 arranged on an underside 22 of the support frame 12 are fixed to the support frame 12 for support relative to the roof 4 . Solar modules 28 arranged on the upper side 26 of the carrier frame 12 opposite the underside 22 are fixed to the carrier frame 12 . The solar modules 28 can be modules for photovoltaics 30 and/or modules for solar thermal energy 32 . In the exemplary embodiment, cover elements 34 are also fixed to the top of the support frame 26, between at least one of the solar modules 28 and a free area 18 within the solar system 2 for installations or superstructures 20 on the roof 4. The combination of modules for photovoltaics 30, modules for Solar thermal system 32 and cover elements 34 can be completely covered over the entire surface of the support frame 12 , which is dimensioned to match the roof 4 , except for the free areas 18 .

Two carrier frames 12 each are connected to one another via swivel joints 36 to form a solar roof part 38 in each case. The electrical system and/or pipes or hoses required to operate the solar modules 28 are installed and a functional test is carried out. The carrier frames 12, which are connected to one another to form a solar roof part 38, are each placed in a parallel position to form a package, as shown in FIG 4 is shown, and transported to the roof 4.

In the exemplary embodiment, a first solar roof part 38 is connected to a further solar roof part 38 via pivotable connecting elements 40 . One of these connecting elements 40 is shown in a detailed view in 9 represented by dotted lines. This configuration is particularly advantageous for pitched roofs, in which case a solar roof part 38 is arranged on each of the two sides of the roof.

In the exemplary embodiment, a ridge cover 42 is fitted between a first solar roof part 38 and a further solar roof part 38 . As a result, no water gets under the solar system 2 in the ridge area.

The solar system 2 is moved in the folded state by means of a crane 44 from the transport device 46 to a position above the roof 4, as shown in FIG 5 is shown. The back of the solar system 2 and the solar modules 28 and cover 34 are in the 4 until 8th not shown separately for better clarity. In order to move the solar system 2 to the position above the roof 4, a traverse 48 is suspended from the crane 44, on which a plurality of cable winches with cables are arranged, on the cable ends 50 of which the support frames 12 are in turn fixed.

The solar system 2 is unfolded above the roof 4 while it is still hanging on the crane 44 . The solar system 2 is precisely aligned by means of the crane 44 and by means of additional cables 52 fixed to the solar system 2, with the aid of which a fine adjustment of the desired positioning in the horizontal orientation is carried out.

In the 7 and 8th is shown how the unfolded solar system 2 is placed on the roof 4. The solar system 2 is fixed to the building exterior wall of the property 54, as shown in the detailed view of FIG 11 is shown, and/or fixed to the front ends of the purlins 56, as in 10 to see. The fixation is used in particular to counteract a lifting of the solar system 2 at high wind speeds acting on it.

In the 10 and 11 the fixing of the solar system 2 to the property 6 is shown. In a top view of the solar system 2 , laterally protruding locking elements 58 are arranged on the carrier frame 12 , which protrude beyond the sides of the roof when the solar system 2 is placed on the roof 4 .

In each case one fastening device 60 is arranged at one end on the locking elements 58 and at the other end is fixed to the outer wall 54 of the building and/or to a front end of a purlin 56 of the roof 4 of the property 6 .

At least one of the fastening devices 60 has a spring element 62 and an adjustment element 64 for adjusting the length of the fastening device 60 . The spring element 62 can be prestressed in a defined manner via the setting element 64 .

The electrical installation of the photovoltaic components of the solar system 2 is connected to the property's electrical system and/or the hydraulic installation of the solar thermal components of the solar system 2 are connected to the property's hydraulic system. Solar system 2 is put into operation.

Reference List

2

solar system

4

Roof

6

property

8th

impact level

10

partial areas

12

carrier frame

14

base frame

16

ribs

18

Free area within the solar system for installations or structures on the roof

20

Roof installations / roof structures

22

underside of the support frame

24

support elements

26

top of the support frame

28

solar panels

30

Modules for photovoltaics

32

Solar thermal modules

34

cover element

36

swivel joint

38

solar roof part

40

pivoting connectors

42

ridge cover

44

crane

46

transport device

48

traverse

50

rope ends

52

additional ropes

54

Building exterior wall of the property

56

front ends of the purlins

58

locking elements

60

fastening device

62

spring element

64

adjustment element

Claims (17)

Method for creating a solar system (2) on a roof (4) of a property (6) comprising the following steps: a) Measurement of the roof (4) on which the solar system (2) is to be positioned and adjacent parts of the property, b) Elaboration of a plan for the construction, production and assembly for the installation of the solar system (2) on the roof (4) with a total area of the effective surface of the solar system (2) pointing away from the roof (4), which is divided into one or more effective levels (8 ) is located, whereby each of the effective levels (8) is in turn broken down into sub-areas (10), c) Factory prefabrication and pre-assembly of the complete solar system (2) and transport to the roof (4) with the sub-steps: i) producing a support frame (12) for each of the sub-areas (10), ii) fixing of support elements (24) arranged on an underside (22) of the support frame (10) on the support frame (12) for support relative to the roof (4), iii) fixing solar modules (28) arranged on a top side (26) of the support frame (12) opposite the underside (22) on the support frame (12), iv) connection of all support frames (12) assigned to an effective level (8) to one another via swivel joints (36) to form a solar roof part (38) in each case, v) Installation of the necessary electrics and/or pipes for operating the solar modules (28) and carrying out a functional test, vi) Moving the support frames (12) connected to one another to form a solar roof part (38) into a parallel positioning to form a package and transport to the roof (4), d) moving the solar system (2) with the at least one solar roof part (38) in the folded state from the transport device (46) to a position above the roof (4) by means of a crane (44), e) unfolding the solar system (2) above the roof (4) while it is still hanging on the crane (44), f) exact alignment of the solar system (2) by means of the crane (44) and by means of additional cables (52) fixed to the solar system (2), with the aid of which a fine adjustment of the desired positioning in horizontal alignment is carried out, g) placing the unfolded solar system (2) on the roof (4), h) fixing the solar system (2) to the building exterior wall (54) of the property (6) and/or to the front ends (56) of the roof purlins, i) Connection of the electrical and/or hydraulic installation of the solar system (2) to the property's electrical and/or hydraulic system and commissioning of the solar system (2). procedure after claim 1 , characterized in that in step c) the sub-step is additionally carried out: connection of a first solar roof part (38) to at least one further solar roof part (38) via pivotable connecting elements (40). procedure after claim 2 , characterized in that in step c) the sub-step is additionally carried out: attaching a ridge covering (42) between a first solar roof part (38) and a further solar roof part (38). Method according to one of the preceding claims, characterized in that in step c) the partial step is additionally carried out: introducing insulation inside the support frame (12). Method according to one of the preceding claims, characterized in that in step c) the sub-step of fixing a water-impermeable layer between the solar modules (28) and the support frame (12) is also carried out and after step g) roof components and structures (20 ) are watertightly connected to the water-impermeable layer. Method according to one of the preceding claims, characterized in that in step c) the partial step is carried out: Fixing at least one cover element (34) on the upper side (26) of the support frame (12), between at least one of the solar modules (28) and an open area (20) within the solar system (2) for roof installations and roof structures (20). Method according to one of the preceding claims, characterized in that the support frame (12) comprises a peripheral base frame (14) and ribs (16) which are arranged inside the base frame (14) fixed thereto. Method according to one of the preceding claims, characterized in that the support elements (24) consist of permanently elastic, weather-resistant and non-combustible foam. Procedure according to one of Claims 1 until 7 , characterized in that the support elements (24) are supports, at the ends facing the roof roof protectors are attached. Method according to one of the preceding claims, characterized in that the solar system (2) below the partial areas (10) is designed without connecting anchors between the carrier frame (12) and the supporting structure supporting the roof (4). Method according to one of the preceding claims, characterized in that at least one stabilizing plate is arranged between the support frame (12) and the support elements (24) to support the support frame (12) relative to the support elements (24) and/or to stiffen the support frame (12). is. Method according to one of the preceding claims, characterized in that the support elements (24) are arranged circumferentially below and along the edge of the solar installation (2). Method according to one of the preceding claims, characterized in that to move the solar system (2) in the folded state to a position above the roof (4) on the crane (44) hangs a traverse (48) on which a plurality of cable winches with cables are arranged are, at the cable ends (50) in turn support frames (12) are fixed. Method according to one of the preceding claims, characterized in that the carrier frame (12) of a solar roof part (2) in the unfolded state, in which the partial surfaces (10) of the solar system (2) of this solar roof part (38) lie in an effective plane (8), be fixed relative to each other via stop elements. Method according to one of the preceding claims, characterized in that laterally protruding locking elements (58) are arranged on the support frame (12) in a top view of the solar modules (28), which when the solar system (2) is placed on the roof (4) over protrude the roof sides. procedure after claim 15 , characterized in that in each case a fastening device is arranged at one end on the locking elements (58) and at the other end on the building outer wall (54) and/or on a front end (56) of a purlin of the roof (4) of the property (6). procedure after Claim 16 , characterized in that at least one of the fastening devices (60) has a spring element (62) and an adjusting element (64) for adjusting the length of the fastening device (60).

Images