EP3803272A1

EP3803272A1 - Holding apparatus for a laser device

Info

Publication number: EP3803272A1
Application number: EP19728678.4A
Authority: EP
Inventors: Josef Weber
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-06-07
Filing date: 2019-06-04
Publication date: 2021-04-14
Also published as: WO2019234058A1; DE102018113622B4; DE102018113622A1

Abstract

A holding apparatus (1) for fastening a laser device (10) to a preexisting ceiling or wall structure on site, more particularly to a roof slope, is described, said holding apparatus comprising at least one fastening unit (2), by means of which the holding apparatus (1) is securable to the ceiling or wall structure, at least one mounting rail unit (3) that is securely connected to the fastening unit (2), and a receiver unit (4), disposed on the mounting rail unit (3), for receiving the laser device in retentive fashion. In particular, the holding apparatus (1) is distinguished in that the fastening unit (2) has a rail-like embodiment and extends lengthwise along a first transverse axis (QA1) and in that the mounting rail unit (3) extends along a principal axis (HA) oriented substantially perpendicular to the first transverse axis (QA). The adjustably embodied receiver unit (4) comprises a receiver area (4.1) and is configured to allow the at least one receiver area (4.1) of the receiver unit (4) to be tilted relative to the mounting rail unit (3).

Description

Holding device for a laser device

Technical area

The invention relates to a holding device for fastening a

Laser device on a ceiling or wall, in particular on a roof slope.

State of the art

In the construction industry and in the field of interior design, laser devices are used to perform leveling or marking work, surveying and surveying

Perform flatness measurements. The laser beams of such laser devices serve to transmit reference lines to the ground or to walls or ceilings. As laser devices, which are also referred to as construction lasers or construction site lasers, rotation lasers, e.g. Self-leveling rotating laser or line laser, for example, cross-line laser used.

Occasionally, such laser devices are also referred to as construction projectors. In particular, such laser devices are used for appropriate alignment work, for example, in the assembly of plate-shaped ceiling or wall elements to align these elements so exactly to each other that they form a flat, flat surface. It is necessary to align the laser devices in a suitable position and position and hold precisely in this position. to

Attachment of the laser devices are therefore tripods or equivalent

Holding devices for mounting on a wall or struts or pipes of wall or ceiling structures known.

For example, DE 20 2016 101 184 U1 describes such a device

Holding device, which is designed by specially provided holding means for fixing a laser device to a pipe or a strut. DE 20 2017 001 7241 U1 discloses a universal adapter which is equipped with clamping and bolting devices in order to be able to fasten a laser device for mounting and alignment work on walls, ceilings, supports and the like. Furthermore, DE 10 2009 002 756 B3, for example, discloses a holding device for fastening a laser device with which a laser device can be fastened to a magnetic construction, to a pipe or to a rail or to a wall. The holding device has several

Fastening devices, which allow a suspension of the laser device to said different substrates. The several

Fasteners include tube adapters for suspension of the

Laser device on pipes or rails, magnetic holding elements for attachment to magnetic structures and a wall mounting device for

Attachment to a wall. Depending on the particular mode of use, in particular the correspondingly required fastening devices can be used, for example by those fastening devices can be moved with the tube adapters between a first non-use position in a second active use position.

A disadvantage, however, can not be fixed in a simple manner with the known holding devices laser devices on sloping walls, especially in sloping roofs, that even in the inclined ground for

Attachment nevertheless a precise alignment of the laser device and the laser line generated thereby is possible. Therefore, despite the solutions known from the prior art, there is a need for improved fixtures for mounting laser devices.

Presentation of the invention

Object of the present invention is therefore a holding device for

To provide laser devices available, which overcomes the disadvantages of the prior art and with a laser device can be easily attached to sloping walls or ceilings and aligned accordingly. This object is achieved by the device according to independent claim 1. Further advantageous aspects, details and embodiments of the invention will become apparent from the dependent claims, the description and the drawings. The present invention provides a holding device for fastening a laser device to a ceiling or wall structure specified by the customer, in particular on a roof slope, wherein the holding device at least one fastening unit, at least one fixed to the mounting unit support rail unit and arranged on the support rail unit receiving unit for holding holder of the laser device. About the attachment unit, the holding device on the ceiling or wall structure can be fixed. The fastening unit is designed like a rail and extends along its length along a first transverse axis. The likewise rail-like carrier rail unit extends along a main axis oriented substantially perpendicular to the first transverse axis. The adjustably formed receiving unit comprises a receiving surface and is configured such that at least the receiving surface of the receiving unit can be tilted relative to the support rail unit.

For the purposes of the present invention, a holding device for fastening a laser device is to be understood as meaning a suspension device or fastening device with which any conventional, used in the construction sector

Laser devices, such as Rotary laser or cross-line laser, in particular

Self-leveling rotating laser can be positioned and fixed or suspended on a wall or ceiling of a building, in particular on a sloping roof. For attachment, the rail-like fastening unit comes into contact with the intended for mounting surface of the wall or ceiling, in particular with an inclined surface of the roof slope, wherein the mounting rail unit so protrudes relative to the mounting unit from the inclined surface of the roof slope due to their vertical arrangement relative to the mounting unit that the main axis of the mounting rail unit a sloping oblique plane receiving the inclined surface of the roof slope perpendicularly intersects. For example, a simple attachment of the laser device to a rafter is possible with the present holding device in particular.

For the suspension of the laser device this is doing on the receiving unit, in particular on the receiving plane forming a receiving surface of the

Shutdown unit turned off and preferably by means of usually in such

Laser devices used screw fixed, for example, an advantageously provided on the receiving unit screw is screwed into an existing threaded hole of the laser device. Particularly advantageously, with the holding device according to the invention due to the possible adjustment or the possible tilting of the receiving surface relative to the support rail unit mounted on the receiving surface laser device its use according to precise and aligned with high accuracy and be set. In particular, the laser lines produced with the desired accuracy and precision can be projected onto the inclined surfaces of a sloping roof to a flatness measurement or at these inclined surfaces

Flatness adjustment or flatness compensation.

The tilting of the receiving surface relative to the mounting rail unit is to be understood in the present case as tilting or tilting of the receiving surface. In this case, one of the main axis of the support rail unit and the receiving plane

included angle changed. For example, the tilting plane can be brought into a tilted position by tilting from a vertical position in which the main axis of the support rail unit perpendicularly intersects the receiving plane, in which the main axis of the support rail unit intersects the receiving plane at an angle other than 90 °, and vice versa. Particularly advantageously, the receiving unit is adapted to the

Recording surface in at least a first direction of inclination and more preferably also in a second direction of tilt can be tilted. This is a very accurate and precise alignment and adjustment of the

Laser device possible, so that with the projected laser lines, for example, for the insulation and / or planking or cladding of roof slopes with appropriate cladding panels used in drywall, especially plasterboard, an exactly flat surface for planar alignment of

Cladding panels can be specified. In particular, it can thus be a plane and flat, "spaced", spaced from the roof sloping plane, "suspended"

Bevel surface plane to be marked.

In order to be able to precisely and precisely align a laser device which is mounted or fastened on the receiving surface in all spatial directions required for the alignment, particular advantages arise because at least the

Receiving surface of the receiving unit is further designed to be rotatable or pivotable about an axis of rotation oriented perpendicular to the receiving plane.

The mounting rail unit is preferably connected to the mounting unit via a first end such that the mounting unit and the

Carrier rail unit are arranged substantially T-shaped, whereby a particularly simple but at the same time safe and stable attachment to the roof slope is made possible. Alternatively, however, a substantially L-shaped arrangement of the mounting and mounting rail unit is possible. According to a preferred embodiment of the invention, the receiving unit has a connection device for attachment to the support rail unit, wherein the connection device in this preferred embodiment preferably has at least one retaining sleeve element and a connection element attached thereto and wherein the support rail unit sections in the

Holding sleeve element is added. The connection element is web or rail-like and extends along a parallel to the first

Transverse axis and perpendicular to the main axis extending second transverse axis. The receiving unit attached to the mounting rail unit via the connecting element thus stands away from the mounting rail unit, in principle in a direction oriented perpendicular to the main axis, which at the same time runs essentially parallel to the first transverse axis of the fastening unit. A parked in this way recording unit laser device can characterized in

Best possible position to be mounted relative to the roof pitch.

Most preferably, the receiving unit is displaceable on the

Fixed mounting rail unit, in such a way that the receiving unit can be moved by means of the connection device at least in sections along the support rail unit in the direction of the main axis. The distance of the mounted

Laser device to the inclined surface of the sloping roof can be changed over advantageous. Benefits also arise when the terminal device is designed to be detectable, for example, by a provided on the retaining sleeve element locking screw, which cooperates with the DIN rail unit, whereby the connection device in the desired position on the

Rail unit can be locked. Alternatively, a locking mechanism is conceivable for the detection.

According to a preferred embodiment of the invention, the

Receiving unit, an upper and a lower plate member, wherein the upper plate member forms the receiving surface and wherein the plate elements are connected to each other via at least one adjustable connecting means.

Four adjustable connecting means are particularly preferably provided, wherein the four connecting means are arranged to each other such that they define the vertices of an imaginary rectangle. Particularly preferably, the adjustable connecting means are designed in the form of clamping screws, spring sleeves, adjustable spacers or adjustable spacers. In a preferred embodiment variant in which the receiving unit comprises an upper and a lower plate element, the upper plate element, which ultimately forms the upper receiving surface, can advantageously be rotatably mounted about the axis of rotation. In this embodiment, for example, the upper

Plate element are rotated against the lower plate member. For example, the at least one connecting means provided for connecting the plate elements may comprise a sliding bearing section. Alternatively, however, may be provided on at least one of the plate elements, a guide portion or a guide over which the one or more connecting means

Connecting means are slidably mounted such that the rotation of the upper plate member can be realized about the axis of rotation. By type

Slotted guide can be provided for example in the upper plate member arcuate grooves or recesses in which the connecting means are partially received and thereby guided sliding.

According to an alternative preferred embodiment, the receiving unit may also comprise a hinge plate with a hinge portion, wherein the

Joint section preferably by a three-way pointer or by a

Ball joint head is formed. In these embodiments, the hinge plate is preferably detectable via the joint portion, so that the receiving surface formed by the hinge plate is adjustable and fixable in any inclined or tilted position. Also in these preferred alternative embodiments, the hinge portion of the receiving unit may be formed such that a rotation of the receiving surface forming the hinge plate about the axis of rotation is possible.

The fastening unit of the holding device is preferably designed for a screw connection to a rafter. In particular, the fastening unit can be designed for this purpose, for example in the form of a profile, in particular in the form of an open profile and be provided at a first top of the support rail unit remote profile top with openings, in particular with slots, are guided by the correspondingly suitable fastening screws and screwed into the rafters can. According to alternative embodiments, however, the fastening unit can also be designed in the form of a clamping shoe or in the form of a clamping clamp. A fastening unit embodied as a clamping shoe can be set up, for example, such that legs of the clamping shoe have a rafter, in particular rafters or embrace an iron carrier, wherein provided suitable locking elements can be adjusted so that the clamping shoe is clamped to the rafter. A fastening unit embodied as a clamping clamp can be used particularly preferably in conjunction with a profile element provided on a wall, for example a UD profile customary in dry construction or an L profile. The clamp clamp takes, for example, engagement in the profile element and is clamped to a leg of the

Profile element set. The holding device is preferably made at least partially of aluminum.

Brief description of the drawings

The invention will be explained in more detail with reference to embodiments in conjunction with the drawings. Show it

Fig. La shown schematically in side view an embodiment of a holding device according to the present invention; Fig. Lb schematically illustrates the embodiment of Figure la in a mounted on a rafter state.

Fig. 2 in isolated view a view of the receiving surface of the receiving unit;

3 shows an isolated view of a view of the interconnected means interconnected plate elements of the embodiment of Figure la;

4a is a side view of another embodiment of a holding device according to the present invention with tilted receiving surface,

4b, the embodiment of Figure 4a in a front view,

Fig. 5a shows schematically a further embodiment of the holding device in a mounted on a rafter state; Fig. 5b in section in isolation representation of the attachment unit of the embodiment of Figure 5a and

Fig. 6 shows schematically a further embodiment of the filling device in a wall-mounted state.

Ways to carry out the invention

Figures la and lb show roughly schematically illustrated in a respective side view of an embodiment of a device for fixing a laser device 10 to a ceiling or wall structure predetermined by the customer, in particular on a roof slope, wherein the holding device 1 is shown isolated in Figure la and in FIG 1b is shown in a state mounted on a rafter S and with the laser device 10 attached.

The holding device 1 comprises an elongate, rail-like fastening unit 2, which extends along its length along a first transverse axis QA1 and over which the entire holding device 1 with a laser device 10 mounted thereon on the ceiling or wall structure, in the example shown on the rafter S, can be hung. The attachment to the rafter S takes place in the embodiment shown in Figures la, lb, for example, a simple screw, the rail-like fastening unit 2 is preferably designed in the form of an open profile, which on a

Profile top 2.1 with openings, preferably in the form of slots is equipped. Through these openings, especially slots, suitable fastening screws are performed, which can eventually be screwed into the rafters S and ensure a secure attachment.

The holding device 1 further comprises a support rail unit 3 fixedly connected to the fixing unit 2 and extending along a main axis HA oriented substantially perpendicular to the first transverse axis QA1. The

Support rail unit 3 is connected via a first end 3 'with the fixing unit 2 such that the fixing unit 2 and the support rail unit 3 in

Essentially T-shaped or form a T-shape. In the region of a first end 3 'opposite the second end 3 "of the support rail unit 3 is an adjustable receiving unit 4 for holding the holder Laser device 10 is arranged and movable or displaceable with the

Support rail unit 3 connected.

For the connection of the receiving unit 4 with the mounting rail unit 3, the receiving unit 4 comprises a connection device 8, the at least one

Holding sleeve element 8.1 and attached thereto a connection element 8.2. The elongate, web or rail-like connection element 8.2 extends along a second transverse axis QA2 extending parallel to the first transverse axis QA1 and perpendicular to the main axis HA. Via the connection device 8, in particular via the retaining sleeve element 8.1 provided in the example, the receiving unit 4 can be displaced at least in sections along the carrier rail unit 3 in the direction of the main axis HA.

The receiving unit 4 comprises a receiving surface 4.1 for the holding or receiving holder of the laser device 10, wherein the receiving surface 4.1 is received in a receiving plane E or runs, or wherein the receiving surface 4.1 forms a receiving plane E. In the illustrated example of Figures la and lb, the receiving unit 4 has an upper and lower plate member 5, 6, wherein the upper plate member 5, the receiving surface 4.1 for the laser device 10 provides. For fixing or holding mounting of the laser device 10 to the receiving unit 4 is on the receiving surface 4.1 forming upper

Plate member 5 a provided with an easily accessible by the user head screw (not shown in the figures), which extends from one of the receiving surface 4.1 opposite bottom of the plate member 5 forth through the plate member 5 therethrough and, for example, in a

correspondingly provided threaded bore can be screwed to the laser device 10.

The lower plate element 6 rests on the connecting element 8.2 and is attached to this or firmly connected to this, that the lower plate member 6 oriented in a direction parallel to the second transverse axis QA2

Connection level AE is included. The support rail unit 3 extending along the main axis HA therefore intersects the connection plane AE of the lower plate element 6 in the vertical.

The plate elements 5, 6 are arranged at a predetermined distance d (see Figure 3) spaced from each other and are adjustable or adjustable, in particular length-adjustable connecting means 7, for example by means of Clamping screws, spring sleeves, adjustable spacers or holders or the like connected to each other. Preferably, four adjustable or adjustable connecting means 7 are provided for the connection of the plate elements 5, 6 (of which only three are visible in the figures la, lb), which are arranged to each other so that they together describe a rectangle, or that they are positioned at the corners of an imaginary rectangle (see Figure 3).

The receiving unit 4 is in particular designed so that at least the receiving plane E forming the receiving surface 4.1 can be tilted relative to the support rail unit 3. The tilting of the receiving surface 4.1, which in the present case is also understood as tilting or pivoting or deflection, can take place in at least one first inclination direction NR1 and one second inclination direction NR2 in the exemplary embodiments shown. The first and second

Inclination direction NR1, NR2 are to be understood essentially as respective inclination or as respective deflection or tilting in the direction of the x and y axes, which span the receiving plane E, as illustrated more clearly in FIGS. 2 and 3. Here, Figure 2 shows the receiving surface 4.1 shown in isolation and Figure 3 shows the two interconnected via connecting means 7 plate elements 5, 6 - also isolated from the entire

Flattenvorrichtung 1 - again.

By tilting the receiving surface 4.1 this is brought from a zero position or initial position in which the plate members 5, 6 of the illustrated example according to figures la, lb and 3 are oriented parallel to each other, in an inclined position in which the upper plate member 5 is one of the Parallel position to the lower plate member 6 has a different arrangement. In the zero position or starting position thus extend the receiving plane E and the connection plane AE parallel to each other, that is, the main axis FIA of the support rail unit 3 is perpendicular to the receiving plane E. On the other hand takes the receiving plane E in the tilted position deviates from a parallel orientation to the connection plane AE orientation and extends obliquely to the connection plane AE. In this inclined position, the main axis FIA runs obliquely to the receiving plane E.

In the illustrated example of Figures la and lb the tilting of the

Receiving surface 4.1 in that the upper plate member 5 is tilted by corresponding adjustment or adjustment of the four, the corner points of an imaginary rectangle descriptive connecting means 7 relative to the lower plate member 6. In this case, the connecting means 7 by appropriate adjustment or Adjustment shortened or extended, so that consequently the distance d (see Figure 3) between the plate elements 5, 6 is reduced or enlarged. As can be illustrated with reference to FIG. 3, for example, the receiving surface 4.1 formed by the upper plate element 5 is replaced by corresponding ones

Adjustment of the two connecting means 7, which are arranged along lines i or ii, tilted or inclined in the first inclination direction NR1 about a tilting axis extending in the direction of the X-axis. In the other case, the receiving surface 4.1 is tilted or inclined by a corresponding adjustment of the two connecting means 7, which are arranged along lines iii or iv in the second direction of inclination NR2 and that about a tilt axis extending in the direction of the y-axis.

The respective deflection or tilting or tilting of the receiving surface 4.1 in the direction of the respective x and y axes preferably takes place starting from the zero position or starting position in a range of +/- 10 °.

Particularly advantageous can with the adjustment or the tilting of the

Recording surface 4.1 a laser device 10 mounted thereon its use according to precise and adjusted with high accuracy and aligned, so that the laser lines generated with the desired accuracy and precision for a flatness measurement or for a

Flatness compensation of inclined surfaces of a sloping roof projected on these bevels. As is apparent from Figures 2 and 3, the receiving surface is the 4.1

Recording unit 4 in addition to a perpendicular to the receiving plane E extending axis of rotation DA rotatable so that a particular precise alignment of a mounted on the receiving surface 4.1 laser device 10 in all of its

Alignment required spatial directions is possible. The rotation of the

Recording surface 4.1 about the axis of rotation DA takes place in the illustrated example by a rotation of the upper plate member 5 relative to the lower plate member 6. To enable such a twist are, for example, the

Connecting means 7 sections in (not shown in the figures) provided and correspondingly designed guides in the upper

Plate element 5 was added. Such guides may for example be formed in the form of arcuate recesses in which sections of the

Connecting means 7 are guided in a sliding manner. Figures 4a and 4b show another possible embodiment of a

Holding device 1 according to the present invention in a state with tilted receiving surface 4.1, wherein Figure 4a shows a side view and Figure 4b shows a front view.

The holding device 1 according to FIGS. 4a, 4b differs from that of FIGS. 1a, 1b essentially only by an alternative embodiment of the receiving unit 4, which has a hinge plate 9 forming the receiving surface 4.1 with a hinge section 9a, which here instead of the one another via connecting means 7 connected plate elements 5, 6 of the shown in the figures la, lb

Embodiment variant is provided. The hinge portion 9a of the hinge plate is, for example, a lockable or lockable

Three-way or ball joint head. In the holding device 1 according to FIGS. 5a and 5b, the fastening unit 2 is designed in the form of a clamping shoe. The clamping shoe 2 is adapted for attachment to a rafter S or an iron carrier and can engage around the rafters S with its legs, the clamping shoe 2 preferably being adaptable to different rafter strengths by means of a suitable adjusting mechanism. About intended locking elements 13, which preferably

Include Klemmschraubelemente or formed for example by locking screws or clamping screws, the clamping shoe 2 can be attached to the rafter S by clamping. The terminal shoe 2 of the illustrated example also has a connector 11 for the firm connection of the clamping shoe 2 with the mounting rail unit 3. The connector 11 is formed in the example shown as a sleeve-like connection sleeve, which is fixed by means of provided screws 12, for example starwheel screws on the support rail unit 3 can be.

In the holding device 1 according to FIG. 6, the fastening unit 2 is designed in the form of a clamping clamp. The clamping clamp 2 of the holding device 1 according to FIG. 6 engages in a profile element 14 fastened or provided on the wall W, which is, for example, an L-angle or a UD profile commonly used in dry construction. Applies to all variants that a Einsteilbarkeit or an adjustment of the receiving surface 4.1 and thus the receiving unit 4 in three axial directions is possible. For example, can be made by the tilting or tilting of the receiving surface 4.1 a setting in the x and y-axis direction and by the Movement by means of the connection unit 8 can be a necessary adjustment in the z-axis direction, for example, to set a distance a (see Figure lb) between the receiving plane E and the inclined surface of a sloping roof to a desired, appropriate value.

LIST OF REFERENCE NUMBERS

1 holding device

2 mounting unit

2.1 profile top

3 mounting rail unit

3 'first end of the DIN rail unit

3 "second end of the DIN rail unit

4 recording unit

4.1 Recording surface

5 upper plate element

6 lower plate element

7 fasteners

8 connection device

8.1 retaining sleeve element

8.2 Connection element

9 joint plate

9a joint section

10 laser device

11 connection piece

12 screws

13 locking element

14 profile element a distance length

AE connection level

d distance

DA axis of rotation

E recording level

HA main axis

QA1 first transverse axis

QA2 second transverse axis

NR1 first direction of inclination

NR2 second direction of inclination

S rafters

W wall

x, y, z axis directions

Claims

claims

1. holding device (1) for attaching a laser device (10) on a building provided ceiling or wall structure, in particular on a roof slope, comprising at least one fastening unit (2) via which the holding device

(1) can be fixed to the ceiling or wall structure, at least one support rail unit (3) fixedly connected to the fastening unit (2) and a receiving unit (4) arranged on the support rail unit (3) for retaining the laser device (10) , that the

Mounting unit (2) is formed like a rail and extends along its length along a first transverse axis (QA1) and that the

Carrier rail unit (3) along a substantially perpendicular to the first transverse axis (QA) oriented main axis (HA), wherein the adjustable receiving unit (4) comprises a receiving surface (4.1) and is adapted to at least the receiving surface (4.1) of the receiving unit

(4) can be tilted relative to the mounting rail unit (3).

2. Holding device (1) according to claim 1, characterized in that the

Recording unit (4) is adapted to that the receiving surface (4.1) can be tilted in at least a first direction of inclination (NR1).

3. Holding device (1) according to claim 2, characterized in that the

Receiving unit (4) is adapted to that the receiving surface (4.1) can also be tilted in at least a second direction of inclination (NR2)

4. Holding device (1) according to one of claims 1 to 3, characterized

characterized in that at least the one in a receiving plane (E)

recorded receiving surface (4.1) is rotatably mounted about a perpendicular to the receiving plane (E) oriented axis of rotation (DA).

5. Holding device (1) according to one of the preceding claims, characterized

in that the mounting rail unit (3) is connected to the fastening unit (2) via a first end (3 ') such that the

Mounting unit (2) and the support rail unit (3) are arranged substantially T-shaped.

6. Holding device (1) according to one of the preceding claims, characterized in that the receiving unit (4) has a connection device (8) for attachment to the mounting rail unit (3).

7. Holding device (1) according to claim 6, characterized in that the

Connecting device (8) has at least one retaining sleeve element (8.1) and a connection element (8.2) attached thereto, wherein the support rail unit (3) in sections in the retaining sleeve member (8.1) is received and wherein the connecting element (8.2) web or rail-like and is formed along a parallel to the first transverse axis (QA1) and perpendicular to the main axis

(HA) extending second transverse axis (QA2) extends.

8. Holding device (1) according to claim 6 or 7, characterized in that the receiving unit (4) is slidably mounted on the support rail unit (3), wherein the receiving unit (4) by means of the connection device (8) at least partially along the support rail unit (3 ) in the direction of the main axis (HA) can be moved.

9. Holding device (1) according to one of the preceding claims, characterized

in that the receiving unit (4) has an upper and a lower one

Plate element (5, 6), wherein the upper plate member (5) the

Receiving surface (4.1) forms and wherein the plate elements (5, 6) via at least one adjustable connecting means (7) are interconnected.

10. Holding device (1) according to claim 9, characterized in that four

adjustable connecting means (7) are provided, wherein the four

Connecting means (7) are arranged to each other such that they define the vertices of an imaginary rectangle.

11. Holding device (1) according to claim 9 or 10, characterized in that the adjustable connecting means (7) in the form of clamping screws,

Spring sleeves, adjustable spacers or adjustable spacers are formed.

12. Holding device (1) according to one of claims 1 to 8, characterized

in that the receiving unit (4) comprises a hinge plate (9) with a hinge section (9a).

13. Holding device (1) according to claim 12, characterized in that the hinge portion (9 a) by a three-way pointer or by a

Ball joint head is formed.

14. Holding device (1) according to one of the preceding claims, characterized in that the fastening unit (2) for a screw connection to a rafter (S) is formed.

15. Holding device (1) according to one of the preceding claims, characterized in that the fastening unit (2) is designed in the form of a profile, in particular in the form of an open profile.

16. Holding device (1) according to one of the preceding claims, characterized in that the holding device (1) is at least partially made of aluminum.