WO2016000794A1 - Base frame - Google Patents

Abstract

The invention relates to a base frame for arranging a module (11a, 11a'; 11g, 11g'), in particular a wind power module, on a construction (12a; 12b; 12d; 12e; 12f; 12g), comprising at least one base support (13a, 13a'; 13b; 13c, 13c'; 13d; 13e; 13f; 13g), which is designed to be arranged in a near region of a construction edge (14a; 14d; 14e; 14f; 14g), at least one module support (15a, 15a'; 15b; 15c, 15c'; 15d; 15e; 15f; 15g), and at least one bearing unit (16a, 16a'; 16b; 16c, 16c'; 16d; 16e; 16f; 16g), which is designed to support the module support (15a, 15a'; 15b; 15c, 15c'; 15d; 15e; 15f; 15g) in such a way that the module support can be moved in relation to the base support (13a, 13a'; 13b; 13c, 13c'; 13d; 13e; 13f; 13g). According to the invention, the bearing unit (16a, 16a'; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) is designed to support the module carrier (15a, 15a'; 15b; 15c, 15c'; 15d; 15e; 15f; 15g) in such a way that the module carrier can be moved at least away from the construction edge (14a; 14d; 14e; 14f; 14g).

Description

 base frame

State of the art

The invention relates to a base frame for the arrangement of a module. It is already a basic framework for the arrangement of a module, in particular one

Wind power module, on a building, with at least one base beam, the

Arrangement in a vicinity of a building edge is provided, with at least one module carrier, and with at least one storage unit, which is intended to mount the module carrier movable relative to the base support is known. The object of the invention is in particular to provide a base frame for a particularly safe operation, installation and / or maintenance of a module. The object is achieved by the features of claim 1, while advantageous embodiments and refinements of the invention

Subclaims can be removed. Advantages of the invention

The invention is based on a base frame for arranging a module, in particular a wind power module, on a building, with at least one

Base support, which is provided for arrangement in a vicinity of a building edge, with at least one module carrier, and with at least one storage unit, which is intended to mount the module carrier movable relative to the base support.

It is proposed that the bearing unit is provided to mount the module carrier movable at least away from the building edge. This makes it particularly easy to move a module to a ready position. It can be effectively protected against overloading and it can provide a basic framework for a particularly safe operation of a module, in particular a wind turbine module become. Furthermore, the module can be mounted particularly safely and / or easily and / or maintained. The module can be brought from a maintenance and / or assembly position to an operation in an advantageous manner to an operation in a basic position. In this context, the term "on a building" is to be understood in particular as meaning an outer surface arranged at least substantially horizontally, in particular on a roof surface of the structure than 5 degrees, and more preferably an inclination of less than 2 degrees with respect to a horizontal

Connection in particular be understood an edge of the building, which is aligned at least substantially horizontally. Preferably, the

Building edge formed as a common boundary of the at least substantially horizontally oriented outer surface and an at least substantially vertically aligned facade surface. In this context, a "near zone" of the building edge is to be understood as meaning, in particular, an edge of the at least substantially horizontally arranged outer surface adjacent to the building edge.The near area extends, starting from the building edge, preferably 10 m, preferably 5 m and particularly preferably 3 m in a direction perpendicular to the edge of the building

In particular, it should be understood that the bearing unit is intended to support the module carrier for movement away from the building edge, i. to a movement along a movement path, which has a basic position for the module carrier and a standby position, in which the module carrier has a greater distance from the building edge than in the basic position. Preferably, the storage unit has a movement path for the module carrier, at the edge of the

Basic position and the ready position are arranged. Preferably, the movement from the home position to the standby position corresponds to a movement along a line that is aligned perpendicular to the building edge. The term "provided" is to be understood to mean in particular specially designed and / or equipped.Assuming that an object is intended for a specific function should in particular mean that the object fulfills this specific function in at least one application and / or operating state and / Preferably, the base frame is provided for an arrangement of a wind power module It is conceivable that the base frame may additionally or alternatively be arranged as another Module, for example, a solar module, a lighting module or a speaker module is provided.

In an advantageous embodiment, the storage unit is provided to a

Orientation of the module carrier in a movement relative to the building edge with respect to a horizontal at least substantially maintain. This allows the

 Module carrier can be moved very safely and it can be achieved a long life of the module. By "maintaining" an orientation, it should be understood in this context in particular that the bearing unit is intended for a movement of the model carrier which corresponds to a parallel displacement

Be understood in particular that the orientation in the

Movement, in particular in the ready position by less than 10 degrees, preferably by less than 5 degrees and more preferably by less than 2 degrees from the original orientation, in particular from the orientation in the

Basic position, deviates.

It is also proposed that the base frame has a basic position, which the module carrier occupies independently at least in an unloaded state. As a result, the module carrier can be brought into the basic position particularly efficiently and a particularly efficient operation of the module arranged by the base frame can be achieved. Under a basic position, in this context, a position, i. In particular, an arrangement relative to the base frame, to be understood that for an operation of the module, for example to a

Energy conversion is provided. Preferably, the module carrier in the

Basic position based on the trajectory on a minimum distance from the building edge. In this context, an "unloaded" state is to be understood as meaning, in particular, a state free of a load, for example a wind load Preferably, the base carrier has a threshold value for the load, below which the module carrier autonomously assumes the basic position in this context, in particular spontaneously, preferably without external energy supply, but at least the movement supportive understood. Preferably, the basic position is a stable position relative to the

Trajectory. Advantageously, the bearing unit comprises a linear guide, which the

Module carrier movably supports on the base support. As a result, a particularly simple and cost-effective base frame can be provided. It is also conceivable that the bearing unit is designed as a pivoting unit and / or at least one

partially curved path having a curvature in

has horizontal and / or vertical direction. Preferably, the

Trajectory of the storage unit at least substantially perpendicular to the

Aligned building edge.

It is also proposed that the storage unit has at least partially an inclination as a restoring unit for moving the module carrier into the basic position. As a result, it is particularly advantageous to use a weight force of the module carrier for a movement into the basic position. In this context, an "inclination" of the bearing unit is to be understood in particular to mean that the movement path is at least piecemeal, in particular in an area of the standby position

Inclination angle greater than zero degrees with a horizontal includes. Preferably, the storage unit has an angle of inclination greater than 2 degrees. Preferably, the

Storage unit an inclination angle less than 10 degrees, and more preferably less than 4 degrees.

In an advantageous embodiment, the storage unit has a rail guide. As a result, a particularly cost-effective, stable and secure storage unit can be provided. Alternatively, the bearing unit may be a waveguide, a

Telescopic guide, have a guide in the form of a Nuremberg scissors or a roller conveyor.

In an advantageous embodiment, the base support at least one

Ground foundation on. As a result, passages for mounting holes can be avoided by the footprint to a mounting of the base frame. In particular, the base frame for not to be damaged sealing surfaces, for example

Roofs, be provided. As a result, a particularly flexible base frame can be provided, which can be inexpensively mounted and / or installed. Under a "ground foundation" should in this context

In particular, a static element to be understood, which is intended to fix the base support in particular by means of a gravitational force on the footprint. Advantageously, the base frame comprises at least one running body, which is intended to transmit at least substantially a guiding force to the module carrier. As a result, the module carrier can be stored particularly securely with respect to the basic carrier. A movement of the module carrier can be performed very safe. In this context, a "guiding force" is to be understood as meaning, in particular, a force which is oriented at least substantially perpendicular to the movement path and is different from the weight force of the module carrier Preferably, the guiding force and the movement path in the region of the running body enclose an angle between 80 degrees and 100 degrees Preferably, the guiding force and the weight force in the region of the running body enclose an angle between 80 degrees and 100 degrees.

Advantageously, the base frame comprises an energy storage unit, which is provided to the module carrier in response to a deflection of the

Basic position with a restoring force to apply. As a result, the module carrier can be moved particularly reliably into the basic position. It can be provided a particularly compact base frame. In this context, an "energy storage unit" should be understood as meaning, in particular, a unit which is intended to absorb energy during a movement of the module carrier, starting from the basic position into the standby position, and to emit a movement starting from the standby position into the basic position. The energy storage unit is preferably provided to store the energy in the form of a potential energy, a spring tension or a gas pressure.

It is also proposed that the base support has at least one fastening point with the building. As a result, the base support particularly safe with the

Building are connected. An undesirable movement of the base carrier relative to the structure can be particularly effectively avoided. Under one

In this context, "attachment point" is to be understood in particular to be a point where the base support is connected to the building in a form-fitting and / or materially bonded manner

Fastener, for example by means of an anchor, a screw or a

Bolzens or by means of an adhesive connection, connected to the attachment point with the building. By "form-fitting" should be understood in particular that abutting surfaces of mutually positively connected components exert a force acting in the normal direction of the surfaces holding force on each other. In particular, the components are in geometric engagement with each other. Under

"Cohesively connected" should be understood in particular that two connected elements are held together by atomic or molecular forces, such as soldering, welding, gluing and / or vulcanization.

Advantageously, the attachment point is arranged on a facade surface of the structure. As a result, the base frame can be connected to the building in a particularly secure manner without passages for fastening openings through the installation surface to a fastening of the base frame. In particular, the base frame can be provided for not to be damaged sealing surfaces, such as roof surfaces.

It is also proposed that the module carrier has at least two support elements which are movable relative to one another. This can be a on the module carrier

arranged module tilted and placed in a particularly safe and / or accessible standby position. Preferably, the two support elements are arranged pivotable relative to each other.

Furthermore, a method for mounting a module designed as a wind power module by means of a base frame is proposed on a building in which the base frame arranged in a vicinity of a building edge, the module mounted on a module carrier and the module carrier by means of a bearing unit relative to the base support in the direction of Building edge is moved. This can be a

Wind power module can be mounted particularly efficiently and safely on a building.

Preferably, the module carrier is locked to a mounting of the wind power module. After mounting the wind power module on the module carrier, the lock is released and the module carrier moves independently relative to the base support in the direction of the building edge.

Furthermore, a building with a base frame according to the invention is proposed. As a result, a building can be provided, which can be advantageously used for the installation of a module, preferably for use of wind energy. drawings

Further advantages emerge from the following description of the drawing. In the drawings, an embodiment of the invention is shown. The drawings, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it:

1 is a perspective side view of two base frames,

 2 is a side view of one of the base frames,

 3 shows a section through a base support and a part of a

 Module carrier of the base frame in the direction perpendicular to a

Direction of movement of the module carrier,

 4 shows a section through a further embodiment of the

 5 shows a plan view of a further exemplary embodiment of two base frames each having an energy storage unit, FIG.

 6 is a side view of another embodiment of the

 Base frame with an attachment point,

 7 is a side view of another embodiment of the

 Base frame with a facade side arranged

Attachment site,

 Fig. 8 is a side view of a further embodiment of the

 Base frame with two attachment points,

 9 is a side view of another embodiment of the

 Base frame with mutually movably arranged support elements

Description of the embodiments

Figures 1 to 3 show a first base frame 10a for arranging a module 1 1 a on a building 12a, and another base frame 10a 'for arranging a further module 1 1 a'. The base frames 10a, 10a 'are arranged laterally adjacent to each other. The structure 12a has a building edge 14a. The Base frames 10a, 10a 'each comprise a base support 13a, 13a' which is intended for

Arrangement in a vicinity of a building edge 14a is provided, and in each case a module carrier 15a, 15a ', and in each case a bearing unit 16a, 16a', the

is provided, the module carrier 15a, 15a 'movable relative to the base support 13a, 13a' to store. The base frames 10a, 10a 'are formed analogously to each other, for which reason only the first of the base frame 10a will be described in more detail below.

The base frame 10a is provided for arranging a module 11a on an at least substantially horizontal mounting surface 30a. In the present

Embodiment, the structure 12 a on a roof surface 31 a, in which the

Set-up surface 30a is arranged. The structure 12a has an elevation 32a on the building edge 14a. The elevation 32a is in the form of a threshold.

The module carrier 15a has a plurality of support elements 24a, 25a, 33a, 34a, 35a, 36a, of which only two arranged laterally for the sake of clarity

Support elements 24a, 25a and arranged on a bottom support members 33a, 34a, 35a, 36a are provided with reference numerals (see Figure 1 and Figure 2). The module carrier 15a is formed in the present embodiment as a metal tube frame. The support elements 24a, 25a, 33a, 34a, 35a, 36a of the module carrier 15a are formed as spars. In principle, it is also conceivable that the module carrier 15a is made of a different material, for example of a plastic or a composite material. A first part of the support elements 24a, 25a is designed as vertically oriented stanchions, which are arranged laterally on the module carrier 15a. Another part of the support elements 33a, 34a, 35a, 36a is formed as transverse bars which connect the supporting elements 24a, 25a designed as stanchions. The module carrier 15a comprises a plurality of struts 40a, 41a, 42a, 43a, which connect stanchions with transverse bars for stabilization. Alternatively, it is also conceivable that the module carrier 15a has a different basic construction, which comprises, for example, net-like and / or planar elements.

The base support 13a is located about 0.5 meters away from the building edge 14a. The building edge 14 a extends horizontally and is formed by a facade surface 29 a and the roof surface 31 a of the structure 12 a. The base support 13a has two

Ground foundations 20a, 21a, which are formed as beam elements. The

Ground foundations 20a, 21a are analogous to each other. The ground foundations 20a, 21a have in particular an equal length, a same height and a same width. The ground foundations 20a, 21a are arranged perpendicular to the building edge 14a, ie a main extension direction of the ground foundations 20a, 21a is in each case arranged perpendicular to the building edge 14a. The ground foundations 20a, 21a are arranged parallel to each other. A first of the ground foundations 20a is arranged in the direction 44a on the building edge 14a on a left side of the footprint 30a. Another of the ground foundations 21a is in the direction of 44a on the

Building edge 14a seen arranged on a right side of the footprint 30a. The further of the ground foundations 21 a is integrally formed with a ground foundation 20 a 'of the further base frame 10 a'. The further base frame 10a 'has, analogously to the base frame 10a, a further ground foundation 21a'. It is conceivable that the ground foundations 20a, 21a, 20a ', 21a' of the base frames 10a, 10a 'are each formed separately from each other, i. the base frames 10a, 10a 'have no common ground foundation 21a, 20a'. It is conceivable that one of the ground foundations 20a, 21a of the base frame 10a or both ground foundations 20a, 21a are formed in several parts, i. in particular in a direction perpendicular to the

Building edge 14a are divided. The base support 13a is in the present

Embodiment by means of the ground foundations 20a, 21a by a frictional force caused by a frictional force frictionally connected to the horizontal footprint 30a and thus to the building 12a. The bearing unit 16a is provided to mount the module carrier 15a movable at least away from the building edge 14a.

In the present embodiment, the base frame 10a is provided for arranging a module 1 1 a formed as a wind power module. The module 1 1 a is provided for the conversion of wind energy into electrical energy and has a

Turbine element 45a, which is rotatably mounted in the module carrier 15a. The

Turbine element 45a has a horizontal and parallel to the building edge 14a aligned rotation axis.

The turbine element 45a is operated under the action of an air flow. The

Turbine element 45a is designed as an Ossberger turbine. The axis of rotation of the turbine element 45a is parallel to the footprint 30a and parallel to the

Building edge 14a arranged. The air flow becomes transverse with respect to the axis of rotation passed through the turbine element 45a. The turbine element 45a includes a shaft for transmitting torques and a plurality of airfoils 46a symmetrically disposed about the shaft. To fix the blades 46a, the turbine element 45a comprises two blade receiving disks 47a. The shaft, the blades 46a and the blade receiving discs 47a rotate around the shaft in operation

Axis of rotation. The turbine element 45a has a blade depth with a factor of 0.4-0.6 with respect to a turbine radius. The airfoils 46a are disposed on an outer circumference of the turbine element 45a and have a curvature. The blades 46a are concave relative to a direction of rotation of the

Turbine element 45a formed.

The module carriers 15a, 15a 'each comprise a cover 37a, 37a' which is provided in each case for protection of the modules 11a, 11a 'and / or for an air flow guide. The covers 37a, 37a 'each have a metal sheet and a

Regensammeivorrichtung 38a, 38a ', which is arranged on one of the building edge 14a facing edge. The module carriers 15a, 15a 'furthermore each include one

Front panel 39a, which has a lamellar structure.

The bearing unit 16a is intended to maintain an orientation of the module carrier 15a in a movement relative to the building edge 14a with respect to a horizontal. During a movement of the module carrier 15a, an alignment of the support elements 24a, 25a, 33a, 34a, 35a, 36a with respect to the set-up surface 30a is maintained. In particular, the supporting elements 24a, 25a, which are in the form of stanchions, remain vertically aligned and the supporting elements 33a, 34a, 35a, 36a designed as crossbars are aligned horizontally. The bearing unit 16a defines a trajectory of the

Base frame 10a for the module carrier 15a fixed. The base frame 10a has a basic position 17a, which the module carrier 15a automatically assumes, at least in an unloaded state. In the basic position 17a of the module carrier 15a at one of the building edge 14a facing the end of

Movement path arranged. The basic position 17a is provided for operation of the module 11a. In the present embodiment, the module 1 1 a in the

Basic position 17a provided for a conversion of wind energy into electrical energy. The module carrier 15a moves from one of the

Building edge 14a remote position in the direction of the basic position 17a on the Building edge 14a too. In a highly loaded state, a wind force acts on the module 1 1 a due to an air flow. The wind power has a component which is aligned parallel to the movement path of the module carrier 15a in the basic position 17a. The wind force moves the module carrier 15a along the path of movement predetermined by the bearing unit 16a and removes the module carrier 15a from the building edge 14a. The movement path has an end facing away from the building edge 14a. The module carrier 15a reaches a middle position depending on a wind force or a ready position 48a at an end of the movement path facing away from the building edge 14a. The ready position 48a is for a shielding of the module 1 1 a from the air flow to a reduction in the on the module 1 1 a

acting wind power and / or for a break in operation of the module 1 1 a provided. The ready position 48a corresponds to a maintenance and / or assembly position.

In an unloaded state or in a lightly loaded state, the module carrier 15a moves from the middle position or from the standby position 48a in the direction 44a of the building edge 14a, i. the module carrier 15a increases starting from the middle position or starting from the

Ready position 48a, the basic position 17a.

The bearing unit 16a has a linear guide 18a which movably supports the module carrier 15a on the base carrier 13a. The bearing unit 16a is provided to move the module carrier 15a in a rectilinear movement from the building edge 14a

move away. The defined by the bearing unit 16a trajectory for the module carrier 15a is rectilinear.

The storage unit 16a has as a restoring unit for moving the module carrier 15a in the basic position 17a on a slope. The bearing unit 16a in the present embodiment has a uniform, i. constant along the trajectory,

Tilt on. The bearing unit 16a has an inclination relative to a horizontal. The bearing unit 16a has an inclination relative to the horizontal footprint 30a. The bearing unit 16a has an inclination angle of about 3.5 degrees. The

Bearing unit 16a is inclined to the building edge 14a out. The angle of inclination opens in a direction away from the building edge 14a. The bearing unit 16a has a rail guide 19a. The rail guide 19a has two rails 49a, 50a, which are formed analogously to each other. The rails 49a, 50a have in particular a same length and a same width. The rails 49a, 50a are arranged perpendicular to the building edge 14a, ie a

Main extension direction of the rails 49a, 50a is perpendicular to the respective

Building edge 14a arranged. The rails 49a, 50a are arranged parallel to each other. Depending on one of the rails 49a, 50a is each associated with one of the ground foundations 20a, 21a of the base support 13a. The rails 49a, 50a are each firmly connected to the associated ground foundation 21a, 20a of the base support 13a. The rails 49a, 50a are each bolted to the associated grounding foundation 21a, 20a.

A first of the rails 49a is arranged in the direction 44a on the building edge 14a on a left side of the footprint 30a a further of the rails 50a is seen in the direction 44a on the building edge 14a on a right side of the

Set-up surface 30a arranged. The rails 50a have a cross-section, which is formed in the form of a three-sided closed rectangle. The cross section is open on one longitudinal side of the rectangle. The rails 49a, 50a are in an assembled state upright on the ground foundations 20a, 21a of the base support 13a

arranged. The rails 49a, 50a are each open laterally on a side facing the module carrier 15a. The cross sections of the rails 49a, 50a are arranged in mirror image relative to one another in relation to a vertical plane between the rails 49a, 50a. The rails 49a, 50a are intended to transmit at least one weight force of the module carrier 15a to the ground foundations 20a, 21a of the base carrier 13a. The bearing unit 16a has four stop elements 51a, 52a, of which two at one of the building edge 14a facing the end of the rails 49a, 50a and two each at one of the building edge 14a facing away from the end

Rails 49a, 50a are arranged on the rails 49a, 50a. The stop elements 51 a, 52 a are intended to limit the movement of the module carrier 15 a and a position of the module carrier 15 a in the basic position 17 a and in the

Set ready position 48a. The stop elements 51 a, 52 a are formed in the present embodiment as a bolt. It is conceivable that the

Stop elements 51 a, 52 a damping elements which are intended to at least damp a movement of the module carrier 15 a. The base frame 10a has a plurality of running bodies 53a, 54a, which are provided to transmit at least the weight of the module carrier 15a to the rails 49a, 50a (see FIG. In the present embodiment, the base frame 10a four running bodies 53a, 54a, which are each arranged on an underside of the module carrier 15a. The module carrier 15a forms a carriage for movement along the rails 49a, 50a. The running bodies 53a, 54a are each firmly connected to the module carrier 15a. The rails 49a, 50a each have one

Running surface, which is arranged in cross section in the interior of the rails 49a (see Figure 3). The treads are provided for contact with the running bodies 53a, 54a. The running bodies 53a, 54a in the present exemplary embodiment each have a roller which is intended to roll to a movement of the module carrier 15a on in each case one of the rails 49a, 50a. Each two of the running bodies 53a, 54a are each associated with one of the rails 49a, 50a. The running bodies 53a, 54a are intended to roll to a movement of the module carrier 15a on each one of the running surfaces. FIGS. 4 to 9 show six further exemplary embodiments of the invention. The following descriptions are essentially limited to the differences between the exemplary embodiments, reference being made to the description of the other exemplary embodiments, in particular FIGS. 1 to 3, with regard to components, features and functions that remain the same. To distinguish the embodiments, the letter a in the reference numerals of

 Embodiment in Figures 1 to 3 by the letters b to g in the

Reference number of the embodiments of Figures 4 to 9 replaced. With regard to identically named components, in particular with regard to components with the same reference numerals, reference may in principle also be made to the drawings and / or the description of the other exemplary embodiments, in particular FIGS. 1 to 3.

FIG. 4 shows a base frame for arranging a module on a structure 12b. The base frame comprises analogous to the preceding embodiment, a base support 13b, which is intended to be arranged in a vicinity of a building edge, and a module carrier 15b and a bearing unit 16b, which is intended to support the module carrier 15b, movable relative to the base support 13b. The base frame is provided for arranging a module on an at least substantially horizontal footprint 30b. The module carrier 15b has a plurality of support elements 24b, 34b, 36b. The module carrier 15b is analogous to the preceding embodiment as a

Metal tube frame formed. A first part of the support elements 24b is designed as vertically oriented stanchions, which are arranged laterally on the module carrier 15b. Another part of the support members 34b, 36b is formed as a cross-beams, which connect the support members formed as a stanchion.

The base support 13b has two ground foundations 20b, 21b, which are formed as beam elements. The ground foundations 20b, 21b are formed analogous to each other. A first of the ground foundations 20b is arranged in a direction towards the building edge on a left side. Another of the ground foundations 21 b is arranged in the direction of the building edge on a right side. The bearing unit 16b is provided to mount the module carrier 15b movable at least away from the building edge.

The bearing unit 16b is intended to maintain an orientation of the module carrier 15b in a movement relative to the building edge with respect to a horizontal. During a movement of the module carrier 15b, an alignment of the support elements 24b, 34b, 36b with respect to the installation surface is maintained. In particular, the support members 24b formed as stanchions remain vertically aligned and the transverse bars

trained support elements 34b, 36b aligned horizontally. The bearing unit 16b defines a movement path of the base frame for the module carrier 15b. The base frame has a basic position, which the module carrier 15b at least in one

unloaded state independently occupies.

The bearing unit 16b has a linear guide 18b which movably supports the module carrier 15b on the base carrier 13b. The bearing unit 16b is intended to move the module carrier 15b in a rectilinear movement away from the building edge. The defined by the bearing unit 16b trajectory for the module carrier 15b is rectilinear.

The storage unit 16b has as a restoring unit for moving the module carrier 15b in the basic position on an inclination. The angle of inclination opens in one of the

Building edge facing away direction. The bearing unit 16b has a rail guide 19b. The rail guide 19b has two rails 49b, 50b, which are formed analogously to each other. The rails 49b, 50b have in particular a same length and a same width. The rails 49b, 50b are arranged perpendicular to the building edge, ie a

Main extension direction of the rails 49b, 50b is perpendicular to the respective

 Building edge arranged. The rails 49b, 50b are arranged parallel to each other.

One of the rails 49b, 50b is each one of the ground foundations 20b, 21b of the

Basic carrier 13b assigned. The rails 49b, 50b are each fixed to the

associated mass foundation 20b, 21 b of the base support 13b connected. The rails 49b, 50b are each bolted to the associated ground foundation 20b, 21b. The rail guide 19b has a plurality of disc-shaped fastening elements for connecting the rails 49b, 50b to the ground foundations 20b, 21a.

A first of the rails 49b is arranged in the direction of the building edge on a left side of the installation surface 30b. A further one of the rails 50b is arranged in the direction of the building edge on a right side of the installation surface 30b. The rails 49b, 50b have a cross-section, which is formed in the form of a three-sided closed rectangle. The cross section is at one

Long side of the rectangle open. The rails 49b, 50b are arranged in a mounted state upright on the ground foundations 20b, 21a of the base support 13b. The rails 49b, 50b are each open laterally on a side facing the module carrier 15b. The cross sections of the rails 49b, 50b are arranged in mirror image relative to one another with respect to a vertical plane between the rails 49b, 50b. The rails 49b, 50b are intended to transmit at least one weight force of the module carrier 15b to the ground foundations 20b, 21b of the base carrier 13b. The base frame has a plurality of running bodies 22b, 23b, 53b, 54b. A first part of the running bodies 53b, 54b is designed as a load-bearing body and is provided to transmit at least the weight of the module carrier 15b to the rails 49b, 50b. In contrast to the preceding embodiment, the base frame has eight running bodies 22b, 23b, 53b, 54b, which are each arranged on an underside of the module carrier 15b. The running bodies 22b, 23b, 53b, 54b each have a roller which is intended to unroll to a movement of the module carrier 15b respectively along one of the rails. Four of the running bodies 22b, 23b, 53b, 54b are each associated with one of the rails 49b, 50b. The module carrier 15b forms a carriage for movement along the rails 49b, 50b. The running bodies 22b, 23b, 53b, 54b are each firmly connected to the module carrier 15b. The rails 49b, 50b each have a running surface, which is arranged in cross section in the interior of the rails 49b, 50b. The running surfaces are provided for contact with the running bodies 53a, 54a designed as load-bearing bodies.

Another part of the running bodies 22b, 23b is designed as a guide bearing body and is intended to transmit at least substantially a guiding force to the module carrier 15b, which is perpendicular to the weight of the module carrier 15b and perpendicular to the movement path of the module carrier 15b during a movement of the module carrier 15b

 Bearing unit 16b acts. The running bodies 22b, 23b designed as guide bearing bodies are arranged on a supporting element 33b of the module carrier 15b, which is arranged horizontally in a direction perpendicular to the rails 49b, 50b and perpendicular to the movement path of the bearing unit 16b. The running bodies 22b, 23b have a vertical

arranged axis of rotation. The rails 49b, 50b each have another

Tread on. The treads are intended to each with one of

Guide body trained running body 22b, 23b to be in contact. The

Running surfaces are based on the footprint 30b and relative to the module carrier 15b each on an Au ßenseite the rails 49b, 50b arranged. FIG. 5 shows a further exemplary embodiment of a base frame 10c for

 Arrangement of a module on a building as well as a further base frame 10c 'for the arrangement of a further module. The base frames 10c, 10c 'are arranged laterally adjacent to each other. The base frames 10c, 10c 'each comprise a base support 13c, 13c', which is provided for placement in a vicinity of a building edge, and in each case a module carrier 15c, 15c 'and in each case a bearing unit 16c, 16c', which is provided to the module carrier 15c, 15c 'movable relative to the base support 13c, 13c' to store. The base frames 10c, 10c 'are formed analogously to each other, for which reason only the first of the base frame 10c will be described in more detail below.

The base frame 10c is for arranging a module on at least one of

Essentially horizontal footprint 30c provided. The module carrier 15c has a plurality of support elements 33c, 34c, 35c, 36c. The module carrier 15c is formed in the present embodiment as a metal tube frame. The support elements 33c, 34c, 35c, 35c of the module carrier 15c are formed as spars. The base support 13c is located about 0.5 meters away from the building edge. The building edge runs horizontally and is formed by a façade surface and the roof surface of the building. The base support 13c has two ground foundations 20c, 21c, which are formed as beam elements. The ground foundations 20 c, 21 c are formed analogous to each other. The ground foundations 20 c, 21 c have in particular a same length, a same height and a same width. The ground foundations 20 c, 21 c are arranged perpendicular to the edge of the building, ie a

Main extension direction of the ground foundations 20 c, 21 c is arranged in each case perpendicular to the building edge. The ground foundations 20 c, 21 c are arranged parallel to each other. A first of the ground foundations 20c is in the direction 44c on the

Building edge seen arranged on a left side of the footprint 30c. Another of the ground foundations 21 c is seen in the direction 44 c on the building edge on a right side of the footprint 30 c arranged. The further of the

Ground foundations 21 c is integrally formed with a ground foundation 20 c 'of the further base frame 10 c'. The further base frame 10c 'has, analogously to the base frame 10c, a further ground foundation 21c'. It is conceivable that the ground foundations 20c, 20c ', 21c, 21c' of the base frame 10c, 10c 'are each formed separately from each other, ie that the base frame 10c, 10c' have no common ground foundation 21c, 20c '. The bearing unit 16c is provided to mount the module carrier 15c movable at least away from the building edge. The bearing unit 16c is intended to maintain an orientation of the module carrier 15c in a movement relative to the building edge with respect to a horizontal. During a movement of the module carrier 15c, an alignment of the support elements 33c, 34c, 35c, 36c with respect to the mounting surface 30c is maintained. In particular, the supporting elements designed as stanchions remain vertically aligned and the supporting elements 33c, 34c, 35c, 36c designed as transverse bars are aligned horizontally. The bearing unit 16c defines a movement path of the base frame 10c for the module carrier 15c. The base frame 10c has a basic position 17c, which the module carrier 15c automatically assumes, at least in an unloaded state. In the basic position 17c of the module carrier 15c at one of the building edge facing the end of

Movement path arranged. In the present embodiment, the

Base frame 10c provided for arranging a module designed as a wind power module. The basic position 17c is intended for operation of the module. The module carrier 15c, starting from a position remote from the building edge, moves toward the building edge in the direction of the basic position 17c. In one

Highly loaded state acts due to an air flow, a wind force on the module. The wind power has a component which is aligned parallel to the path of movement of the module carrier 15c in the basic position 17c. The wind force moves the module carrier 15c along the path of movement predetermined by the bearing unit 16c and removes the module carrier 15c from the edge of the building. The trajectory has an end facing away from the building edge. The module carrier reaches depending on a wind force a middle position or at one of the building edge

remote end of the trajectory a standby position 48c. The

Standby position 48c is provided for shielding the module from the airflow to reduce the wind force applied to the module and / or for a break in operation of the module. The ready position 48c corresponds to a maintenance and / or assembly position.

The base frames 10c, 10c 'comprise, unlike the preceding ones

Embodiments in each case an energy storage unit 26c, 26c ', the purpose

is provided, the module carrier 15c, 15c in each case in response to a deflection from the basic position 17c to apply a restoring force. The

Energy storage units 26c, 26c 'are formed analogously to each other, which is why in

Only a first of the energy storage units 26c will be described in more detail below. The energy storage unit 26c is arranged between the building and the module support 15c and provided to provide the restoring force between the building and the module support 15c. The base frame 10c has an engagement point 55c, where the energy storage unit 26c is fixedly connected to the building, and another point of attack 56c, where the energy storage unit 26c is fixedly connected to the module carrier 15c. The energy storage unit 26 c has in the present

Embodiment, an energy storage element 57c acting as a coil spring is trained. It is conceivable that the energy storage element 57c is alternatively embodied as another element which appears suitable to a person skilled in the art, for example as a gas spring or as a helical spring which is intended to actuate a cable pull. Further, it is conceivable that the energy storage unit 26 c has a connected to a cable mass element, which is intended to a

To provide positional energy to a movement of the module carrier 15c.

In a deflection of the module carrier 15c starting from the basic position 17c in the direction of the standby position 48c, for example due to wind power, the module carrier 15c biases the energy storage element 57c and the energy storage unit 26c acts on the module carrier 15c with a restoring force. In the ready position 48c, the restoring force has a maximum. In an unloaded condition or in a lightly loaded condition, the restoring force moves the module carrier 15c from an intermediate position or from the standby position 48c towards the edge of the building, i. the module carrier 15c assumes the basic position 17c starting from the middle position or starting from the ready position 48c.

The bearing unit 16c has a linear guide 18c, which supports the module carrier 15c movably on the base carrier 13c. The bearing unit 16c is intended to move the module carrier 15c in a rectilinear movement away from the building edge. The defined by the bearing unit 16c trajectory for the module carrier 15c is rectilinear. It is conceivable that the storage unit 16c as a restoring unit analogous to the preceding embodiments at least to support a movement of the module carrier 15c in the basic position 17c has a slope and is inclined to the building edge. The bearing unit 16c has a rail guide 19c. The rail guide 19c has two rails 49c, 50c, which are formed analogously to each other. The rails 49c, 50c have in particular a same length and a same width. The rails 49c, 50c are arranged perpendicular to the building edge, i. a

Main extension direction of the rails 49c, 50c is perpendicular to the respective

Building edge arranged. The rails 49c, 50c are arranged parallel to each other. One of the rails 49c, 50c is each one of the ground foundations 20c, 21 c of the

Basic carrier 13c assigned. The rails 49c, 50c are each fixed to the

associated mass foundation 20c, 21 c of the base support 13c connected. The rails 49c, 50c are respectively screwed to the associated ground foundation 20c, 21c. A first of the rails 49c is arranged in the direction of the building edge on a left side of the footprint 30c arranged another of the rails 50c is seen in the direction of the building edge on a right side of the footprint.

Analogous to the preceding embodiments, the base frame 10c has a plurality of running bodies which are provided to transmit at least the weight of the module carrier 15c to the rails 49c, 50c.

FIG. 6 shows a further exemplary embodiment of a base frame for arranging a module on a structure 12d. Analogously to the preceding exemplary embodiments, the base frame comprises a base support 13d, which is intended to be arranged in a vicinity of a building edge 14d, and a module support 15d and a bearing unit 16d, which is intended to support the module support 15d movably relative to the base support 13d. The base frame is provided for arranging a module on an at least substantially horizontal footprint 30d. The building 12d has an elevation 32d at the building edge 14d. The elevation 32d is in the form of a threshold. The module carrier 15d has a plurality of support elements 24d, 25d, 33d, 35d. The module carrier 15d is formed in the present embodiment as a metal tube frame. The support elements 24d, 25d, 33d, 35d of the module carrier 15d are formed as spars.

The base support 13d is disposed about 0.5 meters away from the building edge 14d. The building edge 14d extends horizontally and is formed by a facade surface 29d and a roof surface of the structure 12d. In contrast to the preceding exemplary embodiments, the base carrier 13d has two attachment points 27d with the structure 12d, one of which is shown in FIG. The attachment points 27d are arranged in the region of the elevation 32d of the structure 12d on a horizontal surface of the elevation 32d. The base support 13d comprises two fixing units 60d which are designed analogously to each other and which are intended to support the base support 13d positively to connect in each case at one of the attachment points 27d with the building 12d. The base support 13d is in an assembled state to the

Attachment points 27d connected by means of fastening units 60d fixed to the building 12d. The fastening units 60d are formed in the present embodiment as screw. The base carrier 13d has two storage elements 58d designed analogously to one another, which are provided to support and support the storage unit 16d in the region of the attachment points 27d. The bearing unit 16d is partially formed in one piece with the base support 13d in the present embodiment. The base support 13d has two ground foundations 20d which, in contrast to the preceding embodiments, are designed as plate elements. The

Ground foundations 20d are analogous to each other. The ground foundations 20d are arranged at an end of the base support 13d facing away from the building edge 14d. The base support 13d is frictionally engaged with the horizontal by means of the ground foundations 20d by a frictional force caused by gravity

 Installation surface 30d and thus connected to the building 12d. The base carrier 13d has two further bearing elements 59d, which are provided to support and support the bearing unit 16d in the area of the ground foundations 20d. Each of the two further bearing elements 59d is assigned to one of the ground foundations 20d. The further bearing elements 59d are arranged in the vertical direction in each case between the bearing unit 16d and the ground foundation 20d assigned to the further bearing element 59d.

The bearing unit 16d is provided for the purpose of movably supporting the module carrier 15d at least away from the building edge 14d. The bearing unit 16d is intended to maintain an orientation of the module carrier 15d with a movement relative to the building edge 14d with respect to a horizontal. During a movement of the module carrier 15d an alignment of the support elements 24d, 25d, 33d, 35d remains with respect to

Set-up surface 30d obtained. The bearing unit 16d defines a trajectory of the

Base frame for the module carrier 15d fixed. The base frame has a basic position, which independently assumes the module carrier 15d at least in an unloaded state. The base frame also has a standby position, which is intended for assembly, for protection of the module and / or for maintenance. The bearing unit 16d has, analogously to the preceding embodiments, a linear guide 18d, which supports the module carrier 15d movably on the base support 13d. The bearing unit 16d is intended to move the module carrier 15d in a rectilinear movement away from the building edge 14d. The of the

Bearing unit 16d fixed path of movement for the module carrier 15d is formed in a straight line. The storage unit 16d has as a reset unit for moving the

Module carrier 15d in the basic position an inclination. The bearing unit 16d in the present embodiment has a uniform, i. along the

Trajectory constant, inclination on. The bearing unit 16d has an inclination relative to a horizontal. The bearing unit 16d has an inclination relative to the horizontal footprint 30d. The bearing unit 16d has an inclination angle of about 3.5 degrees. The bearing unit 16d is inclined towards the building edge 14d. The angle of inclination opens in a direction away from the building edge 14d.

The bearing unit 16d has a rail guide 19d. The rail guide 19d is partially formed integrally with the base support 13d in the present embodiment. The rail guide 19d has two rails 49d, which are analogous to each other. The rails 49d have in particular a same length and a same width. The rails 49d are provided to transfer at least one weight of the module carrier 15d to the structure 12d. The

Bearing unit has four stop elements 51 d, 52 d, of which two at one of the building edge 14 d facing the end of the rails 49 d and two more at one of the building edge 14 d opposite end of the rails 49 d are arranged on the rails 49 d. The stop elements 51 d, 52 d are provided to limit the movement of the module carrier 15 d and to fix a position of the module carrier 15 d in the basic position and in the ready position.

One of the rails 49d, one of the attachment points 27d one of

Mounting units 60d and a bearing member 58d are associated with each other. In Figure 6, only one of the rails 49d is shown. The rail 49d is connected by means of the bearing member 58d and the fixing unit 60d at the attachment point 27d fixed to the building 12d. The bearing element 58d is arranged at the attachment point 27d in the vertical direction between the rail 49d and the structure 12d. Further, each one of the rails 49d, one of the ground foundations 20d and one of the others Bearing elements 59d associated with each other. The rail 49d is fixedly connected to the ground foundation 20d by means of the further bearing element 59d. The further

Bearing member 59d is in the vertical direction between the rail 49d and the

Ground foundation 20d arranged. The rail 49d is associated with the

Ground foundation 20d bolted.

The base frame has a plurality of running bodies 53d, 54d, which are provided to transmit at least the weight of the module carrier 15d to the rails 49d. The base frame has four running bodies 53d, 54d, which are each arranged on an underside of the module carrier 15d. Two of the running bodies 53d, 54d are each associated with one of the rails 49d. The module carrier 15d forms a carriage for movement along the rails 49d.

FIG. 7 shows a further exemplary embodiment of a base frame for arranging a module on a structure 12e. Analogous to the preceding exemplary embodiments, the base frame comprises a base support 13e, which is intended to be arranged in a vicinity of a building edge 14e, and a module support 15e, and a bearing unit 16e, which is intended to support the module support 15e movably relative to the base support 13e. The base frame is provided for arranging a module on an at least substantially horizontal footprint 30e. The building 12e has an elevation 32e on the building edge 14e. The elevation 32e is in the form of a threshold. The module carrier 15e has a plurality of support elements 24e, 25e, 33e, 35e. The module carrier 15e is formed in the present embodiment as a metal tube frame. The support elements 24e, 25e, 33e, 35e of the module carrier 15e are formed as spars.

The base support 13e is located about 0.5 meters away from the building edge 14e. The building edge 14e extends horizontally and is formed by a facade surface 29e and a roof surface of the structure 12e. Analogous to the previous one

Embodiment, the base support 13e two attachment points 27e with the structure 12e, one of which is shown in Figure 7. The attachment points 27e are arranged on the vertically aligned facade surface 29e of the structure 12e. The base support 13e comprises two attachment units 60e designed analogously to one another, which are provided to connect the base support 13e in a form-fitting manner in each case to the structure 12e at one of the attachment locations 27e. The base support 13e is in a mounted state at the attachment points 27e by means of the fastening units 60e firmly connected to the building 12e. The

Mounting units 60e are in the present embodiment as

Formed screw. In contrast to the preceding exemplary embodiment, the bearing unit 16e protrudes beyond the building edge 14e and over the footprint 30e in the horizontal direction and has an end extending beyond the building edge 14e. The base support 13e has two bearing elements 58e designed analogously to one another, which are provided to support and support the bearing unit 16e in each case at the end projecting beyond the building edge 14e in the region of the fastening points 27e. The bearing unit 16e is partially formed in one piece with the base support 13e in the present embodiment.

The base support 13e has two ground foundations 20e, which are formed as plate elements. The ground foundations 20e are analogous to each other. The ground foundations 20e are at one of the building edge 14e facing away from the

Basic carrier 13e arranged. The base support 13e is frictionally connected by means of the ground foundations 20e by a frictional force caused by gravity with the horizontal footprint 30e and thus with the structure 12e. Of the

Base support 13e has two further bearing elements 59e which are provided to support and support the bearing unit 16e in the area of the ground foundations 20e. Each of the two further bearing elements 59e is assigned to one of the ground foundations 20e. The further bearing elements 59e are each assigned in the vertical direction between the bearing unit 16e and the further bearing element 59e

Ground foundation 20e arranged. The bearing unit 16e is provided to at least the module carrier 15e of the

Baugekante 14e movable away to store. The bearing unit 16e is intended to maintain an orientation of the module carrier 15e with a movement relative to the building edge 14e with respect to a horizontal. During a movement of the module carrier 15e remains an alignment of the support elements 24e, 25e, 33e, 35e with respect to

Floor space 30e obtained. The bearing unit 16e defines a trajectory of the

Base frame for the module carrier 15e fixed. The base frame has a basic position, which the module carrier 15e independently at least in an unloaded state occupies. The base frame also has a standby position, which is intended for assembly, for protection of the module and / or for maintenance.

Analogously to the preceding exemplary embodiments, the bearing unit 16e has a linear guide 18e which movably supports the module carrier 15e on the base support 13e. The bearing unit 16e is intended to move the module carrier 15e in a rectilinear movement away from the building edge 14e. The of the

Bearing unit 16e fixed path of movement for the module carrier 15e is rectilinear. The storage unit 16e has as a return unit for moving the

Module carrier 15e in the basic position an inclination. The bearing unit 16e in the present embodiment has a uniform, i. along the

 Trajectory constant, inclination on. The bearing unit 16e has an inclination relative to a horizontal. The bearing unit 16e has an inclination relative to the horizontal footprint 30e. The bearing unit 16e has an inclination angle of about 3.5 degrees. The bearing unit 16e is inclined towards the building edge 14e. The angle of inclination opens in a direction away from the edge of the building 14e.

The bearing unit 16e has a rail guide 19e. The rail guide 19e is partially formed integrally with the base support 13e in the present embodiment. The rail guide 19e has two rails 49e, which are analogous to each other. The rails 49e have in particular a same length and a same width. The rails 49e are provided to transfer at least one weight force of the module carrier 15e to the structure 12e. The

Bearing unit has four stop elements 51 e, 52e, of which two at one of the building edge 14e facing the end of the rails 49e and two further at one of the building edge 14e opposite end of the rails 49e are arranged on the rails 49e. The stop elements 51 e, 52 e are provided to limit the movement of the module carrier 15 e and to fix a position of the module carrier 15 e in the basic position and in the ready position.

In contrast to the preceding embodiment, the rails 49e protrude beyond the building edge 14e and beyond the footprint 30e in the horizontal direction. One of the rails 49e, one of the attachment points 27e, one of the attachment units 60e and a bearing element 58e are associated with each other. In Figure 7, only one of the rails 49e is shown. The rail 49e is by means of the bearing element 58e and the fixing unit 60e at the attachment point 27e by means of

Mounting unit 60e firmly connected to the structure 12e. The bearing element 58e is arranged at the fastening point 27e in the vertical direction between the rail 49e and the structure 12e and connects the end of the rail 49e protruding beyond the building edge 14e with the building 12e. Further, each one of the rails 49e, one of the ground foundations 20e and one of the other bearing elements 59e associated with each other. The rail 49e is fixedly connected to the ground foundation 20e by means of the further bearing element 59e. The further bearing element 59e is arranged in the vertical direction between the rail 49e and the ground foundation 20e. The rail 49e is bolted to the associated ground foundation 20e.

The base frame has a plurality of running bodies 53e, 54e, which

are provided to transmit at least the weight of the module carrier 15e on the rails 49e. The base frame has four running bodies 53e, 54e, which are each arranged on an underside of the module carrier 15e. Two of the running bodies 53e, 54e are each associated with one of the rails 49e. The module carrier 15e forms a carriage for movement along the rails 49e.

FIG. 8 shows a further exemplary embodiment of a base frame for arranging a module on a structure 12f. Analogous to the preceding embodiments, the base frame comprises a base support 13f, which is intended to be arranged in a vicinity of a building edge 14f, and a module support 15f, and a bearing unit 16f, which is intended to support the module support 15f movably relative to the base support 13f. The base frame is provided for arranging a module on an at least substantially horizontal footprint 30f. The structure 12f has an elevation 32f at the building edge 14f. The elevation 32f is in the form of a threshold. The module carrier 15f has a plurality of support elements 24f, 25f, 33f, 35f. The module carrier 15f is in the present

Embodiment designed as a metal tube frame. The support elements 24f, 25f, 33f, 35f of the module carrier 15f are formed as spars.

The base support 13f is located about 0.5 meters away from the building edge 14f. The building edge 14f is horizontal and is formed by a facade surface 29f and a roof surface of the structure 12f. Unlike the previous ones

Embodiments, the base support 13f four attachment points 27f, 28f with the structure 12f, two of which are shown in Figure 8. The attachment points 27f, 28f are arranged on the horizontally oriented footprint 30f

Base support 13f comprises two fastening units 60f, 61f designed analogously to one another, which are provided to connect the base support 13f to the building 12f in a form-fitting manner at one of the attachment locations 27f, 28f. The base support 13f is in an assembled state at the attachment points 27f, 28f by means of

Mounting units 60f, 61 f firmly connected to the building 12f. The

Mounting units 60f, 61f are in the present embodiment as

Formed screw. The base support 13f has four bearing elements 58f, 59f, which are formed in pairs analogous to each other. The bearing elements 58f, 59f are provided to support and support the bearing unit 16f in each case in the region of the fastening points 27f, 28f. The bearing unit 16f is partially formed integrally with the base support 13f in the present embodiment. The base support 13f has in

Unlike the previous embodiments, no ground foundations 20f.

The bearing unit 16f is provided for movably supporting the module carrier 15f at least away from the building edge 14f. The bearing unit 16f is intended to maintain an orientation of the module carrier 15f with a movement relative to the building edge 14f with respect to a horizontal. During a movement of the module carrier 15f an alignment of the support elements 24f, 25f, 33f, 35f remains with respect to

Floor space 30f obtained. The bearing unit 16f defines a trajectory of the

Base frame for the module carrier 15f fixed. The base frame has a basic position, which automatically assumes the module carrier 15f at least in an unloaded state. The base frame also has a standby position, which is intended for assembly, for protection of the module and / or for maintenance.

Analogously to the preceding exemplary embodiments, the bearing unit 16f has a linear guide 18f which movably supports the module carrier 15f on the base carrier 13f. The bearing unit 16 f is provided to the module carrier 15 f in a

move away from the building edge 14f rectilinear motion. The of the

Bearing unit 16f fixed trajectory for the module carrier 15f is formed in a straight line. The storage unit 16 f has as a reset unit for moving the Module carrier 15f in the basic position an inclination. In the present exemplary embodiment, the bearing unit 16f has a uniform inclination, ie constant inclination along the movement path. The bearing unit 16f has an inclination relative to a horizontal. The bearing unit 16f has an inclination relative to the horizontal footprint 30f. The bearing unit 16f has an inclination angle of about 3.5 degrees. The bearing unit 16f is inclined toward the building edge 14f. The angle of inclination opens in a direction away from the edge 14f of the building.

The bearing unit 16f has a rail guide 19f. The rail guide 19f is partially formed in one piece with the base support 13f in the present embodiment. The rail guide 19f has two rails 49f, which are formed analogously to each other. The rails 49f have in particular a same length and a same width. The rails 49f are provided to transfer at least one weight force of the module carrier 15f to the structure 12f. The bearing unit has four stop elements 51 f, 52 f, of which two at one of the building edge 14 f facing the end of the rails 49 f and two each at one of the

 Building edge 14f opposite end of the rails 49f are arranged on the rails 49f. The stop members 51 f, 52 f are provided to prevent the movement of the

To limit module carrier 15f and a position of the module carrier 15f in the

Basic position and in the ready position. One of the rails 49f, two of the attachment points 27f, 28f and two of the

 Bearing elements 58f, 59f are associated with each other. In Figure 8, only one of the rails 49f is shown. The rail 49f is by means of the bearing elements 58f, 59f and

Fixing units 60f, 61f each at one of the attachment points 27f, 28f fixedly connected to the building 12f. The bearing members 58f, 59f are respectively attached to the

Attachment 27f, 28f arranged in the vertical direction between the rail 49f and the structure 12f.

The base frame has a plurality of running bodies 53f, 54f which are intended to transmit at least the weight of the module carrier 15f to the rails 49f. The base frame has four running bodies 53f, 54f, which are each arranged on an underside of the module carrier 15f. Two of the running bodies 53f, 54f are each associated with one of the rails 49f. The module carrier 15f forms a carriage for movement along the rails 49f. FIG. 9 shows a further exemplary embodiment of a base frame 10g for arranging a module 11g on a structure 12g. The base frame 10g comprises analogous to the preceding embodiments, a base support 13g, which is intended to be arranged in a vicinity of a building edge 14g, and a module carrier 15g and a bearing unit 16g, which is intended to support the module carrier 15g movable relative to the base support 13g. The base frame 10g is provided to arrange a module 11g on an at least substantially horizontal footprint 30g. The building 12g has an elevation of 32g at the edge of the building 14g. The elevation 32g is in the form of a threshold. The module carrier 15g has a plurality of support elements 24g, 25g, of which only two laterally arranged support elements 24g, 25g are provided with reference numerals for the sake of clarity. Unlike the previous ones

Embodiments, the module carrier 15g at least two support elements 24g, 25g, which are movable relative to each other. The module carrier 15g is formed in the present embodiment as a metal tube frame. The support elements 24g, 25g of the module carrier 15g are formed as spars. In principle, it is also conceivable that the module carrier 15g made of a different material, for example a

Plastic or a composite material is formed.

The base support 13g is located about 0.5 meters away from the building edge 14g. The building edge 14g is horizontal and is formed by a facade surface 29g and the roof surface of the structure 12g. The bearing unit 16g is provided to mount the module carrier 15g movable at least away from the building edge 14g. The base support 13g has two attachment points 27g with the structure 12g, one of which is shown in FIG. The attachment points 27g are in the range of

Elevation 32g of the structure 12g arranged on a horizontal surface of the elevation 32g. The base support 13g comprises two fixing units 60g designed analogously to one another, which are provided to support the base support 13g

positively to connect in each case at one of the attachment points 27g with the building 12g. The base support 13g is in an assembled state to the

Attachment 27g by means of fastening units 60g firmly connected to the building 12g. The fastening units 60g are formed in the present embodiment as screw. The base support 13g has two analogous to each other formed bearing elements 58g, which are intended to store the bearing unit 16g respectively in the region of the attachment points 27g and support. The bearing unit 16g is partially formed in one piece with the base support 13g in the present embodiment. The base support 13g has two ground foundations 20g, which are formed as plate elements. The ground foundations 20g are analogous to each other. The ground foundations 20g are arranged at an end of the base support 13g facing away from the building edge 14g. The base support 13g is frictionally connected by means of the ground foundations 20g by a frictional force caused by gravity with the horizontal footprint 30g and thus with the building 12g. Of the

 Base support 13g has two further bearing elements 59g which are provided to support and support the bearing unit 16g in the area of the ground foundations 20g. Each of the two further bearing elements 59g is assigned to one of the ground foundations 20g. The further bearing elements 58g are each assigned in the vertical direction between the bearing unit 16g and the further bearing element 59g

Ground foundation 20g arranged.

In the present embodiment, the base frame 10g is provided for arranging a module 1 1 g formed as a wind power module. The module 1 1 g is provided for the conversion of wind energy into electrical energy and has in

Difference to the preceding embodiments one not closer

represented rotor with radially oriented rotor blades. The rotor has an rotor plane and a rotation axis arranged perpendicular to the rotor plane. The rotor is operated under the action of an air flow. Next, the module 1 1 g on a housing unit, which accommodates at least the rotor. The base frame 10g has a basic position 17g, which the module carrier 15g automatically assumes, at least in an unloaded state. In the basic position 17g of the module carrier 15g at one of the building edge 14g facing edge of

Movement path arranged. The basic position 17g is intended for operation of the module 1 1 g. In the basic position 17g, the axis of rotation is horizontal and perpendicular to the building edge 14g. In the basic position 17g, the rotor plane is vertically aligned. In the present embodiment, the module 1 is 1 g in the

Starting position 17g for a conversion of wind energy into electrical energy intended. The base frame 10g also has a ready position 48g, which is intended for mounting, for protection of the module 11 g and / or for maintenance.

The bearing unit 16g has a linear guide 18g, which supports the module carrier 15g movably on the base carrier 13g. The bearing unit 16g is intended to move the module carrier 15g in a rectilinear movement from the building edge 14g

move away. The movement path defined by the bearing unit 16g for the module carrier 15g is rectilinear.

The storage unit 16g has as a restoring unit for moving the module carrier 15g in the basic position 17g on a slope. The bearing unit 16g in the present embodiment has a uniform, i. along the trajectory constant, tilt up. The bearing unit 16g has an inclination relative to a horizontal. The bearing unit 16g has an inclination relative to the horizontal footprint 30g. The bearing unit 16g has an inclination angle of about 3.5 degrees. The

Bearing unit 16g is inclined to the building edge 14g out. The angle of inclination opens in a direction away from the building edge 14g.

The bearing unit 16g has a rail guide 19g. The rail guide 19g is partially formed integrally with the base support 13g in the present embodiment. The rail guide 19g has two rails 49g, which are analogous to each other. The rails 49g have in particular a same length and a same width. The rails 49g are provided to transfer at least one weight of the module carrier 15g to the structure 12g. The

Bearing unit 16g has four stop elements 51g, 52g, of which two at one of the building edge 14g facing the end of the rails 49g and two other at one of the building edge 14g facing away from the end of the rails 49g are arranged on the rails 49g. The stop elements 51g, 52g are provided to limit the movement of the module carrier 15g and to fix a position of the module carrier 15g in the home position 17g and in the standby position 48g.

The base frame 10g has a plurality of rolling bodies 53g, 54g, which are provided to transmit at least the weight of the module carrier 15g to the rails 49g. In the present embodiment, the base frame 10g four running body 53g, 54g, which are each arranged on an underside of the module carrier 15g. The module carrier 15g has a first pair of support members 25g and another pair of support members 24g. The couples are movable to each other. The first pair is arranged on a side of the module carrier 15g facing the building edge 14g. The further pair is arranged on a side remote from the building edge 14g side of the module carrier 15g. The support members 24g, 25g enclose an angle with each other. The module carrier 15g has a pivot bearing, each one

Support member 25g of the first pair and a support member 24g of the other pair pivotally supports each other. The support members 24g, 25g are each connected at a lower end to one of the running bodies 53g, 54g.

In a first movement mode, the module carrier 15g moves in total away from the building edge 14g. The running bodies 53g, 54g keep a distance from each other. The included by the support members 24g, 25g angle remains unchanged. In a further movement mode, the running bodies 53g assigned to the first pair of support elements 24g, 25g are arranged in a stationary manner. The other couple of

Support members 24g associated running body 54g move away from the building edge 14g and increase the distance to the running bodies 53g of the first pair. The included by the support members 24g, 25g angle increases and the module 1 1 g tilts away from the building edge 14g. Likewise, the rotor plane tilts and leaves the vertical orientation in the direction of a horizontal orientation. It is conceivable that the two modes of motion are combined.

Claims

claims

1 . Basic frame for the arrangement of a module (1 1 a, 1 1 a '; 1 1 g, 1 1 g'), in particular a wind power module, on a building (12a; 12b; 12d; 12e; 12f; 12g), with at least one base support (13a, 13a '; 13b; 13c, 13c'; 13d; 13e; 13f; 13g) provided for placement in a vicinity of a building edge (14a; 14d; 14e; 14f; 14g) having at least one module support (15a , 15a ', 15b, 15c, 15c', 15d, 15e, 15f, 15g), and at least one bearing unit (16a, 16a '; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) provided for this purpose the module carrier (15a, 15a ', 15b; 15c, 15c'; 15d; 15e; 15f; 15g) is movable relative to the base carrier (13a, 13a '; 13b; 13c, 13c'; 13d; 13e; 13f; 13g). to store

 characterized in that

 the bearing unit (16a, 16a '; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) is provided for holding the module carrier (15a, 15a '; 15b; 15c, 15c'; 15d; 15e; 15f; 15g). At least from the building edge (14a, 14d, 14e, 14f, 14g) to store movable away.

2. Base frame according to claim 1,

 characterized in that

The bearing unit (16a, 16a ';16b; 16c, 16c';16d;16e; 16g) is intended to provide orientation of the module carrier (15a, 15a ', 15b; 15c, 15c';15d;15e; 15g) in one Movement relative to the building edge (14a, 14d, 14e, 14g) with respect to a horizontal at least substantially maintain.

3. Basic frame according to claim 1 or 2,

 marked by

 a basic position (17a, 17c, 17g) which the module carrier (15a, 15a '; 15b; 15c, 15c'; 15d; 15e; 15f; 15g) occupies independently, at least in an unloaded state.

4. Basic frame according to one of the preceding claims,

 characterized in that

 the bearing unit (16a, 16a '; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) a

 Linear guide (18a, 18a '; 18b; 18c, 18c'; 18d; 18e; 18f; 18g) comprising the module carrier (15a, 15a '; 15b; 15c, 15c'; 15d; 15e; 15f; 15g) on the

 Base support (13a, 13a ', 13b, 13c, 13c'; 13d; 13e; 13f; 13g) movably supports.

5. Basic frame according to one of the preceding claims,

 characterized in that

 the bearing unit (16a, 16a '; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) as

 Resetting unit for moving the module carrier (15a, 15a '; 15b; 15c, 15c'; 15d; 15e; 15f; 15g) into the basic position (17a; 17c; 17g) at least partially has an inclination.

6. Basic frame according to one of the preceding claims,

 characterized in that

 the bearing unit (16a, 16a '; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) a

 Rail guide (19a, 19a '; 19b; 19c, 19c'; 19d; 19e; 19f; 19g).

7. Basic frame according to one of the preceding claims,

 characterized in that

 the basic carrier (13a, 13a '; 13b; 13c, 13c'; 13d; 13e; 13g) at least one

Ground foundation (20a, 20a ';20b; 20c, 20c';20d;20e; 20g).

8. Basic frame according to one of the preceding claims,

 marked by

 at least one running body (22b, 23b) which is intended to transmit at least substantially one guiding force to the module carrier (15b).

9. Basic frame according to one of the preceding claims,

 marked by

 an energy storage unit (26c) which is provided to act on the module carrier (15c) in response to a deflection from the basic position (17c) with a restoring force.

10. Basic frame according to one of the preceding claims,

 characterized in that

 the base carrier (13d; 13e; 13f; 13g) has at least one attachment point (27d; 27e; 27f, 28f; 27g) to the structure (12d; 12e; 12f; 12g).

1 1. Base frame according to claim 10,

 characterized in that

 the fastening point (27e) is arranged on a façade surface (29e) of the building (12e).

12. Basic frame according to one of the preceding claims,

 characterized in that

the module carrier (15g) has at least two support elements (24g, 25g) which are movable relative to each other.

13. Method for mounting a module (1 1 a, 1 1 a '; 1 1 g, 1 1 g') designed as a wind power module by means of a base frame (10a, 10a ', 10g, 10g') on a structure (12a; 12b; 12d; 12e; 12f; 12g), wherein a base support (13a, 13a '; 13b; 13c, 13c'; 13d; 13e; 13f; 13g) is located in a vicinity of a building edge (14a; 14d; 14e; 14f; 14g), the module (11a, 11a ', 11g, 11g') is mounted on a module carrier (15a, 15a '; 15b; and the module carrier (15a, 15a '; 15b; 15c, 15c'; 15d; 15e; 15f; 15g) by means of a

 Bearing unit (16a, 16a '; 16b; 16c, 16c'; 16d; 16e; 16f; 16g) relative to the

 Base carrier (13a, 13a '; 13b; 13c, 13c'; 13d; 13e; 13f; 13g) is moved in the direction (44a; 44c) of the building edge (14a; 14d; 14e; 14f; 14g).

14. Building with a base frame according to one of claims 1 to 12.