DE102021130323A1 - Holding device for fixing a component - Google Patents

Abstract

The invention relates to a holding device (2) for fixing a component, having a first component (3) which has a base body (4) and a bolt (5) adjoining the base body (4) and protruding from the base body (4). , which can be passed through a receiving opening of the component, whereby the component can be supported on the bolt (5) in the radial direction (6) of the bolt (5), and with a second component (8) arranged on the base body (4) , which comprises a bearing surface (10) and a through-opening (11) through which the bolt (5) is passed, whereby the component in the axial direction (12) of the bolt (5) via the bearing surface (10) on the base body (4) is supportable, wherein between the bolt (5) and the through-opening (11) in the radial direction (24) outwardly limiting wall (25) of the second component (8), a gap (26) is provided, through which a through the pin (5) generated abrasion of the component.

Description

The invention relates to a holding device for fixing a component according to the preamble of patent claim 1.

A holding device for fixing a component can be seen as known from the general state of the art. The component can be fixed or held in at least one spatial direction, in particular in two or three spatial directions, by means of the holding device. As a result, the component can be held in a desired position or aligned in the desired position by means of the holding device, for example. At least one manufacturing step of the component or for the component can be carried out on the component fixed by means of the holding device. For example, such a manufacturing step includes a joining process.

It is the object of the invention to create a holding device for fixing a component so that the component can be protected against damage to the component in a particularly reliable manner.

According to the invention, this object is achieved by a holding device for fixing a component with the features of patent claim 1 . Advantageous configurations of the invention are the subject matter of the dependent patent claims and the description.

The invention relates to a holding device for fixing or holding a component, in particular a metallic component. The holding device can be provided to fix or hold the component in at least one spatial direction, in particular in two or three spatial directions.

Preferably the component is an assembly. For example, the component is a shell for a motor vehicle or a shell component of the shell. The bodyshell can be understood in particular as a structure of the motor vehicle, which is designed, for example, as an in particular self-supporting body of the motor vehicle. The motor vehicle is preferably designed as a motor vehicle, in particular a passenger car, commercial vehicle or truck.

The component is preferably at least partially, in particular completely, made of aluminum.

The holding device comprises at least one first component, which has a base body and a bolt, in particular at least indirectly or directly, adjoining the base body and protruding from the base body. In other words, the base body and the bolt are connected to one another, in particular directly, with the bolt protruding at least partially, in particular completely, beyond the base body in its axial direction.

The bolt can be guided through a receiving opening of the component, as a result of which the component can be supported on the bolt, in particular directly, in the radial direction of the bolt. In other words, the component has the receiving opening through which the bolt can be passed or inserted to fix or hold the component, whereby the component can be attached to the bolt passed through the receiving opening in the radial direction of the bolt on the holding device or the first component supported by the bolt.

The fact that the bolt can be guided through the receiving opening of the component can in particular be understood to mean that the bolt can be arranged at least partially, in particular completely, inside the receiving opening. If the bolt is at least partially, in particular completely, arranged in the receiving opening, the component can be supported at least on a longitudinal area of the bolt in the radial direction.

Since the component can be supported or is supported on the bolt in the radial direction of the bolt, the component can be supported or can be supported on the bolt in two spatial directions, in particular spatially. A first of the spatial directions can in particular be referred to as the longitudinal direction. The second of the spatial directions can in particular be referred to as the transverse direction. The first spatial direction can be understood in particular as a longitudinal direction of the component. The second spatial direction can be understood in particular as a transverse direction of the component. The component can thus be fixed or held in the two spatial directions by means of the holding device over the bolt. As a result, the component can be aligned in a defined manner in the two spatial directions, for example. Thus, by means of the holding device, in particular by means of the bolt, the component can be secured in position, in particular in the two spatial directions.

Preferably, the component, in particular on a receiving wall of the component delimiting the receiving opening in the circumferential direction of the receiving opening, directly touches the bolt guided through the receiving opening. This means that a support surface can be provided between the bolt and the component, in particular the receiving wall.

The receiving opening can be designed as a through hole in the component. The bolt can in particular be referred to as a locating bolt.

The fact that the bolt is passed through the receiving opening of the component can in particular be understood to mean that the component, in particular the receiving wall, at least partially, in particular completely, surrounds the longitudinal region, in particular in the circumferential direction of the bolt.

The holding device has a second component which is arranged or can be arranged on the base body, in particular on a base area of the base body, which comprises a bearing surface and a through-opening. The bolt can be passed or passed through the through-opening, as a result of which the component can be supported in the axial direction of the bolt, in particular directly, via the bearing surface on the base body. In other words, the component is supported in the axial direction of the bolt on the bolt guided through the through opening and the receiving opening, in particular directly on the base body of the first component. This means that the second component can be or is arranged in the axial direction of the bolt, in particular directly, between the component and the first component, as a result of which the component can be supported on the base body of the first component in the axial direction of the bolt through the intermediary of the second component is supported.

By supporting the component in the axial direction on the bearing surface or the base body, the component can be fixed or held in a third spatial direction by means of the holding device, which corresponds to the axial direction of the bolt. The third spatial direction preferably corresponds to a vertical direction of the component. The component supported on the bearing surface in the axial direction of the bolt is preferably supported downwards in the third spatial direction, in particular vertically, or downwards in the vertical direction of the component. The component can thus be fixed or held in the three spatial directions by means of the holding device. A defined alignment or positional securing of the component in the three spatial directions can thereby be brought about.

For example, a manufacturing process can be carried out on the component fixed or held by means of the holding device. The manufacturing process can be understood in particular as a machining process of the component. For example, a joining process is carried out on the component fixed or held by means of the holding device. During the joining process, a second component that is formed separately from the component can be connected to the component, in particular in a non-positive and/or positive and/or frictional manner. For example, the joining process includes welding and/or screwing and/or riveting and/or gluing. Thus, the second component can be welded to the component and/or screwed to the component and/or riveted to the component and/or glued or glued to the component.

The fact that the bolt can be passed or is guided through the through-opening can be understood in particular to mean that a second longitudinal region of the bolt adjoining the longitudinal region of the bolt, in particular at least indirectly or directly, can be or is arranged in the through-opening. Thus, at least the second longitudinal region of the bolt guided through the through-opening, in particular in the circumferential direction of the bolt, is at least partially, in particular completely, surrounded by a wall of the second component which outwardly delimits the through-opening in the radial direction of the through-opening.

In particular because the second component can be arranged between the component and the first component, the second component can be referred to in particular as a bridge element.

In order to protect the component, which is fixed or held in particular by means of the holding device, particularly reliably from damage to the component, it is provided that between the bolt, which is guided in particular through the through-opening, and the through-opening in the radial direction of the through-opening outside delimiting wall of the second component, a gap is provided through which a generated by the bolt abrasion of the component passes. In other words, the wall of the second component is spaced apart from the bolt arranged in the through-opening or guided through the through-opening, in particular in the radial direction of the through-opening, with the abrasion getting between the wall and the bolt.

The gap can be understood in particular as a gap between the bolt and the wall. Under the gap can be understood in particular a cavity which is formed at least partially, in particular completely, by the distance between the wall and the bolt. The gap is arranged in the through hole. This means that the abrasion of the component caused by the bolt passes through the through opening.

The abrasion of the component can be understood in particular as chips of the component. The fact that the abrasion is generated by the bolt can in particular be understood to mean that the abrasion is generated or caused as a result of mechanical friction or mechanical contact between the bolt and the component, in particular on the support surface. This means that as a result of the mechanical friction or the mechanical contact, for example, particles of the component or of a material of the component can be detached from the component, with the detached particles forming the abrasion.

The fact that the abrasion passes through the gap can in particular be understood to mean that the abrasion can be removed through the gap or via the gap, in particular passively, for example from the bolt and/or from the component and/or from the bearing surface. The gap is thus provided for, in particular passive, removal of the abrasion.

The invention is based in particular on the following findings and considerations: The abrasion can be generated or caused, in particular due to tolerances, when the bolt is guided through or as a result of it being guided through the receiving opening. This can be promoted in particular if the surface hardness of the bolt is greater than the surface hardness of the component, in particular the mounting wall. The generation of abrasion can be particularly pronounced, for example, if the component is made of aluminum. In a conventional holding device, the abrasion can be applied to the component, in particular to the receiving wall. As a result, the abrasion can be pressed with the component, in particular the receiving wall. As a result, the component, in particular a surface of the component or the receiving wall, can be damaged. Damage to the receiving wall can in particular be understood to mean damage to the receiving opening. In other words, the abrasion can cause a deterioration, in particular geometrical, in quality of the component, in particular of the component surface. In addition, the abrasion can build up on the holding device, in particular on the bearing surface and/or on the bolt. As a result, an oversize, referred to in particular as a superstructure, can be produced on the holding device, in particular on the bearing surface and/or on the bolt. The application of the abrasion or the allowance can cause a particularly imprecise recording or fixing of the component by means of the holding device. As a result, the repeatability of fixing or holding the component in the desired position or the desired orientation cannot be guaranteed, which means that the component can be damaged. In addition, repeatability or error-free execution of the manufacturing process, in particular the joining process, cannot be guaranteed. This can damage the component.

In contrast, with the holding device according to the invention, the abrasion produced by the bolt can get into the gap or be dissipated via the gap, in particular passively. As a result, the contact or pressing of the abrasion material on the component or with the component can be avoided or particularly reduced. In addition, the application of abrasion to the holding device, in particular to the bearing surface and/or to the bolt, can be avoided or particularly reduced. As a result, the quality of the component, in particular the quality of the surface of the component, can be particularly increased. In addition, the repeatability of fixing or holding the component in the desired position or alignment can be guaranteed or particularly increased. As a result, in particular the repeatability of the manufacturing process, in particular of the joining process, can be guaranteed or particularly increased. In this way, the component, which is in particular fixed or held on the holding device, can be protected particularly securely against damage to the component. Damage to the component can thus be avoided or particularly reduced by means of the holding device.

The bearing surface is preferably spaced apart from the bolt guided through the through-opening, in particular in the radial direction of the bolt or the through-opening. The gap is preferably arranged, in particular in the radial direction of the bolt or the through-opening, between the bolt arranged in the through-opening or guided through the through-opening and the bearing surface. This means that the receiving surface, in particular in the radial direction of the bolt or the through-opening, is at a distance from the point of origin of the abrasion, as a result of which the abrasion can get into the gap. With other words In other words, the contact surface is set back relative to the bolt or, in particular in the radial direction of the bolt, set back, as a result of which the abrasion can get into the gap or, in particular, be carried away passively via the gap.

The component preferably touches the second component, in particular the bearing surface, directly. In other words, the component rests on the second component, in particular the bearing surface, for example directly.

In a further embodiment, it is provided that the bolt is at least predominantly, in particular completely, surrounded by the bearing surface in its radial direction. In other words, the bearing surface encloses the bolt at least predominantly, in particular completely, in its circumferential direction. As a result, the component can be supported particularly advantageously, in particular particularly securely, on the bearing surface in the axial direction of the bolt.

Provision is preferably made for a side of the gap facing a free end of the bolt to be delimited outwards in its radial direction by the bearing surface, in particular directly. In other words, an input opening of the through-opening that delimits the through-opening in its axial direction is outwardly delimited in its radial direction, in particular directly, by the bearing surface. As a result, the through-opening and thus the gap can, for example, be particularly large and/or be positioned particularly advantageously on the second component, as a result of which the debris can get into the gap particularly well.

When the bolt has passed through the receiving opening, the free end of the bolt faces the component. For example, the inlet opening is formed at least partially, in particular completely, by the bearing surface.

In a further embodiment, it is provided that the components are formed separately from one another and are connected to one another. This means that the components are components which are different from one another and which can be produced separately, in particular independently, from one another or have been produced and are connected to one another. That is, the components are preferably not integrally formed together. As a result, the holding device can be produced particularly advantageously, in particular particularly cost-effectively. As a result, the costs of the holding device can be kept particularly low.

Alternatively, the components can be formed together in one piece. This means that, as an alternative, the components cannot be two components which are formed separately from one another and are connected to one another.

In a further embodiment, it is provided that the second component has at least one partial region which is spaced apart from the bearing surface in a direction running obliquely or perpendicularly to the axial direction of the bolt, via which the second component can be supported or is supported on the first component, in particular the base body , In particular fastened or fastened. In other words, the partial area is arranged laterally next to the bearing surface in relation to the axial direction of the bolt or the through-opening. This means that the partial area and the bearing surface are not arranged one above the other in the axial direction of the bolt or the through-opening. As a result, both the second component can be particularly advantageously supported on the base body or the base area and the through-opening and thus the gap can be made particularly large. As a result, the component can be fixed particularly securely by means of the holding device and the abrasion can get into the gap particularly well.

In a further embodiment, it is provided that the second component has at least one opening arranged on an outside of the second component or the holding device, into or through which the abraded material that has passed through the gap passes. In other words, the abrasion removed from the component, in particular passively, through the gap can be removed via the opening from the gap, in particular the second component or the holding device, for example to an area surrounding the holding device and the component. As a result, the abrasion can be particularly advantageously removed from the gap or the holding device via the opening. As a result, an accumulation, in particular an excessive accumulation, of the abraded material in the gap can be avoided.

Preferably, the outside in which the opening is arranged is a side of the second component that runs obliquely or perpendicularly to the axial direction of the bolt or the through-opening.

In a further embodiment, it is provided that the second component is at least partially, in particular completely, cylindrical. This means that at least a partial area of the second component is a cylinder or is ring-shaped. As a result, the second component can be produced in a particularly cost-effective manner.

In a further embodiment, it is provided that the first component, in particular the base body and/or the bolt, has a through channel which comprises at least one channel area extending in the axial direction of the bolt. In other words, the through-channel runs within the first component, in particular the base body, with a direction of longitudinal extension of the through-channel running at least in the channel region in the axial direction of the bolt or the through-opening. This means that a channel wall that at least predominantly, in particular completely, delimits the through-channel in its circumferential direction is formed by the first component.

Alternatively or additionally, the through channel, in particular the channel area, can run at least partially, in particular completely, inside the bolt. This means that the channel wall can be formed at least partially, in particular completely, by the bolt.

Provision is preferably made for at least one clamping element of a clamping device to be able to be guided through the through-channel, as a result of which the component can be clamped, in particular directly, between the bearing surface and the clamping element guided through the through-channel. In other words, the component through whose receiving opening the bolt is guided can be arranged, in particular directly, between the tensioning element guided through the through-channel and the bearing surface, as a result of which the component is held or fixed in the axial direction of the bolt, in particular by means of the tensioning element is. As a result, the component can be fixed particularly securely by means of the holding device and, in particular, can be supported upwards on the clamping element in the third spatial direction or the vertical direction or can be fixed by the clamping element. A particularly secure positional securing of the component in the axial direction of the bolt, in particular upwards, can thus be made possible. The fact that the tensioning element can be passed or guided through the through-channel can be understood in particular to mean that at least one longitudinal region of the tensioning element can be or is arranged in the through-channel. Thus, at least the longitudinal area of the tensioning element is surrounded by the channel wall.

For example, the clamping device has the clamping element and a base body that is formed separately from the clamping element. The clamping element is connected to the base body.

The clamping element can preferably be moved relative to the base body, in particular in a translatory manner. A movement direction of the movement preferably runs in the longitudinal direction of the tensioning element. When the tensioning element is guided through the through-channel, the direction of longitudinal extension of the tensioning element preferably corresponds to the axial direction of the bolt or the passage opening. By moving the clamping element relative to the base body, the component can be clamped. For example, the tensioning element can be moved relative to the base body by an adjustment path which is between 0 and 6 millimeters, for example.

In a further embodiment, it is provided that the base body has a contact surface, via which the clamped component can be supported on the base body of the clamping device via the contact surface in the axial direction of the bolt or the through-opening. In other words, the first component can be arranged or attached to the base body, with the first component arranged or attached to the base body being supported in the axial direction of the bolt via the contact surface, in particular directly, on the base body, as a result of which the clamped component rests, in particular on the bearing surface overlying component is supported on the second component and the first component in the axial direction via the contact surface, in particular directly on the base body. As a result, the holding device and thus the component can be supported particularly securely on the clamping device or fixed or fastened by means of the clamping device.

The first component, in particular the contact surface, preferably touches the base body directly.

It is preferably provided that the clamping element guided through the through-channel is guided through the through-opening of the second component. In other words, the tensioning element arranged in the through-channel is partly arranged in the through-opening. This means that the tensioning element is at least partially, in particular completely, surrounded by the wall in the circumferential direction of the bolt or the through-opening. This allows the construction part can be clamped in a particularly space-saving manner.

The bolt preferably has a groove in which the clamping element guided through the through-channel is arranged. As a result, the component can be clamped in a particularly space-saving manner.

The clamping element preferably has a hook element, by means of which the component can be clamped. The hook element is preferably arranged on a side of the tensioning element that faces away from the base body. Preferably, the hook element contacts the clamped component directly. When the component is clamped, the hook element is preferably arranged at least partially, in particular completely, outside of the through-channel or the groove.

A further aspect relates to a clamping device which has a holding device according to the invention. In addition, the clamping device includes a clamping device. The clamping device preferably has a base body and a clamping element. The tensioning device can in particular be referred to as a hook tensioner or be designed as a hook tensioner. Advantages and advantageous configurations of the invention are to be regarded as advantages and advantageous configurations of the further aspect and vice versa.

Further features of the invention result from the claims, the figures and the description of the figures. The features and combinations of features mentioned above in the description and the features and combinations of features mentioned below in the description of the figures and/or shown alone in the figures can be used not only in the combination specified in each case, but also in other combinations or on their own.

• 1 eine schematische und perspektivische Teilansicht einer Spannvorrichtung mit einer erfindungsgemäßen Haltevorrichtung; und
• 2 eine schematische seitliche Teilansicht einer Spannvorrichtung mit einer erfindungsgemäßen Haltevorrichtung; und
• 3 eine schematische Draufsicht einer erfindungsgemäßen Haltevorrichtung; und
• 4 eine schematische Perspektivansicht eines ersten Bauelements einer erfindungsgemäßen Haltevorrichtung; und
• 5 eine schematische Perspektivansicht einer erfindungsgemäßen Haltevorrichtung gemäß einer weiteren Ausführungsform; und
• 6 eine schematische Perspektivansicht einer erfindungsgemäßen Haltevorrichtung gemäß einer weiteren Ausführungsform; und
• 7 eine schematische Seitenansicht einer erfindungsgemäßen Haltevorrichtung gemäß einer weiteren Ausführungsform; und
• 8 eine schematische Draufsicht einer erfindungsgemäßen Haltevorrichtung gemäß einer weiteren Ausführungsform; und
• 9 eine schematische Perspektivansicht einer erfindungsgemäßen Haltevorrichtung gemäß einer weiteren Ausführungsform.

The invention will now be explained in more detail using a preferred exemplary embodiment and with reference to the drawings. Show it:

• 1 a schematic and perspective partial view of a clamping device with a holding device according to the invention; and
• 2 a schematic lateral partial view of a clamping device with a holding device according to the invention; and
• 3 a schematic plan view of a holding device according to the invention; and
• 4 a schematic perspective view of a first component of a holding device according to the invention; and
• 5 a schematic perspective view of a holding device according to the invention according to a further embodiment; and
• 6 a schematic perspective view of a holding device according to the invention according to a further embodiment; and
• 7 a schematic side view of a holding device according to the invention according to a further embodiment; and
• 8th a schematic plan view of a holding device according to the invention according to a further embodiment; and
• 9 a schematic perspective view of a holding device according to the invention according to a further embodiment.

Elements that are the same or have the same function are provided with the same reference symbols in the figures.

1 shows a clamping device 1, which has a holding device 2, in a schematic and perspective partial view. The holding device 2 is provided for fixing or for holding a component, in particular a metallic component, for example made of aluminum. The component is, for example, a bodyshell of a motor vehicle or a bodyshell component of the bodyshell, in particular a body of the motor vehicle or a body part of the body. 2 shows the clamping device 1 in a schematic lateral partial view. 3 shows the holding device 2 in a schematic plan view.

4 shows a first component 3 of the holding device 2 in a schematic perspective view. The holding device 2 thus comprises the first component 3. The first component 3 has a base body 4 and a base body 4, in particular directly, adjoining it and protruding from the base body 4 Bolt 5. The bolt 5 can in particular be referred to as a bolt part. The base body 4 and the bolt 5 can be formed separately from each other and connected to each other, or the base body 4 and the bolt 5 can be formed together in one piece. The component has a receiving opening. The bolt 5 can be passed through the receiving opening, as a result of which the component can be supported on the bolt 5 in the radial direction 6 of the bolt 5 . This means that the bolt 5 guided through the receiving opening of the component is at least in a longitudinal area of the bolt 5 in the receiving opening of the component is arranged, wherein the component, in particular a receiving wall of the component delimiting the receiving opening in its circumferential direction, is supported on at least one support surface 7 of the bolt 5, in particular directly, in the radial direction 6 on the bolt 5 or the first component 3. The support surface 7 is preferably arranged in the longitudinal area of the bolt 5 .

The holding device 2 has a second component 8 which is arranged or held on or on the base body 4 of the first component 3 . In the exemplary embodiment, the second component 8 is arranged or held directly on a base area 9 of the base body 4 . The second component 8 comprises at least one bearing surface 10 and a through-opening 11. The bolt 5 is guided through the through-opening 11. FIG. This means that the bolt 5 is arranged in the through-opening 11 in a second length region of the bolt 5 which is different from the length region, in particular spaced apart from the length region. As a result, the component can be supported in the axial direction 12 of the bolt 5, in particular directly, via the bearing surface 10 on the base body 4 of the first component 3. This means that the component, in whose receiving opening the bolt 5, in particular the longitudinal area, is arranged, via the second component 8, in particular via the bearing surface 10, in the axial direction 12 of the bolt 5 on the first component 3, in particular the base body 4 , is supported.

The component can be held or fixed in three spatial directions 13 , 14 , 15 by means of the holding device 2 . By supporting the component in the radial direction 6 of the bolt 5, the component can be held or fixed in a first and a second of the spatial directions 13, 14. The component fixed or held by means of the holding device 2 is preferably not spatially movable in the first and the second spatial direction 13 , 14 . By supporting the component on the bearing surface 10 in the axial direction 12 of the bolt 5, the component can be fixed or held in the third of the spatial directions 15. The component preferably rests on the support surface 10, in particular directly. The component held or fixed by means of the holding device 2 is preferably supported in a first direction 16 running in the third spatial direction 15 and is thereby fixed or held. The component held or fixed by means of the holding device 2 can be moved in space in a second direction 17 running in the third spatial direction 15 and opposite to the first direction 16 . This means that the component fixed or held by means of the holding device 2 cannot be fixed or held in the second direction 17 .

The clamping device 1 has a clamping device 18 which is designed separately from the holding device 2 . The clamping device 18 has a base body 19 and a clamping element 20 held on the base body 19 so as to be movable, in particular translationally, in relation to the base body 19 . In this case, the clamping element 20 can be moved along a direction of movement 21, in particular translationally, relative to the base body 19. The direction of movement 21 preferably corresponds to the axial direction 12 of the bolt 5. The component can be arranged, in particular directly, between the bearing surface 10 and the clamping element 20. By moving the clamping element 20 in the direction of movement 21 relative to the base body 19 , the component arranged between the bearing surface 10 and the clamping element 20 can be clamped between the bearing surface 10 and the clamping element 20 by means of the clamping element 20 . For this purpose, the clamping element 20 has a hook element 22, for example. By means of the hook element 22, by moving the clamping element 20 or the hook element 22 in the direction of movement 21, in particular in the first direction 16, a force can be brought about that acts on the component, as a result of which the component can be clamped. The clamped component is located in a position referred to in particular as clamping position 23 between the support surface 10 and the clamping element 20, in particular the hook element 22. The component clamped by means of the clamping element 20 can thus be fixed or held particularly securely. The clamping position 23 can be understood in particular as a clamping area.

The component clamped by means of the clamping device 1 can thus be fixed or held in the third spatial direction 15, in particular in the first and the second direction 16, 17. This means that the component fixed or clamped by means of the clamping device 1 cannot be moved in space along the third spatial direction 15, in particular in the first and the second direction 16, 17.

The clamping device 1 is thus provided for fixing or holding the component, in particular in all spatial directions 13 to 15, for example for securing the position. For example, a joining process can be carried out on the component fixed by means of the clamping device 1 or the holding device 2 .

In order to protect the component particularly reliably from damage to the component, it is provided that a gap 26 is provided between the bolt 5 and a wall 25 of the second component 8 which bounds the through-opening 11 outwards in the radial direction 24 of the through-opening 11, through which an abrasion of the component generated by the bolt 5 passes. The abrasion can be generated or caused when the bolt 5 is guided through the receiving opening of the component, in particular due to mechanical friction between the receiving wall and the bolt 5 , for example the support surface 7 . The abrasion, in particular passively, can be removed from the bolt 5 and/or the bearing surface 10 or the component through the gap 26 . As a result, the component or the holding device 2, in particular the bolt 5 and/or the bearing surface 10, can be kept free from abrasion. This can prevent the abraded material from being pressed with the component, in particular the receiving opening or the receiving wall, which can damage the component, in particular the receiving opening. In addition, the abrasion can be prevented from accumulating on the bolt 5 or the bearing surface 10 . As a result, precise fixing or holding of the component by means of the clamping device 1 or the holding device 2 can be guaranteed. As a result, repeatability of the joining process can be guaranteed or particularly increased. Damage to the component during the joining process can thus be prevented.

The gap 26 is arranged in the through opening 11 . Thus, the gap 26 is a partial area of the through opening 11, the partial area being free of the bolt 5 in particular.

Provision is preferably made for the bolt 5 to be at least predominantly, in particular completely, surrounded by the bearing surface 10 in its radial direction 6 . As a result, the component can be supported particularly advantageously on the bearing surface 10 and the abrasion can reach the gap 26 particularly well.

In a further embodiment, a side 28 of the gap 26 facing a free end 27 of the bolt 5 is delimited outwards in its radial direction 29 by the bearing surface 10, in particular directly. As a result, the abrasion can get into the gap 26 particularly well. The radial direction 29 of the gap 26 preferably corresponds to the radial direction 24 of the through opening 11 and/or the radial direction 6 of the bolt 5.

The components 3, 8 are preferably formed separately from one another and connected to one another. As a result, the holding device 2 or the clamping device 1 can be produced in a particularly cost-effective manner. For example, the components 3, 8 are screwed together. For this purpose, holes 30 can be provided on the components 3, 8, via which the components 3, 8 can be screwed together or are screwed together.

in the in 1 , 2 and 3 In the embodiment shown, it is provided that the second component 8 has at least one partial region 32, which is spaced apart from the bearing surface 10 in a direction 31 running obliquely or perpendicularly to the axial direction 12 of the bolt 5, via which the second component is attached to the first component 3, in particular the base body 4 or the base 9, preferably directly, supported or attached. The bores 30 are preferably arranged in the partial area 32 . in the in 1 until 3 shown embodiment, the second component is stepped or stepped.

in the in 1 until 3 The embodiment shown provides that the second component 8 has at least one opening 33a which is arranged on an outer side 33 of the second component 8 or the holding device 2 and through which the abrasion material that has passed through the gap 26 passes. Thus, the gap 26 is connected via the opening 33a to an environment of the holding device 2 or the clamping device 1, in particular fluidly, whereby the abrasion located in the gap 26 via the opening 33a from the gap 26 or the clamping device 1, in particular the holding device 2, preferably passively, can be dissipated. As a result, the abrasion can be removed in a particularly advantageous manner, in particular because excessive accumulation of the abrasion in the gap 26 can be avoided. The opening 33a preferably has a particularly large cross section.

The gap 26 preferably runs exclusively through the second component 8 and in particular not through the first component 3. The abrasion can thus be removed through the gap 26 through the second component 8, in particular bypassing the first component 3, preferably passively.

5 until 8th show further respective embodiments of the holding device 2. 5 shows a schematic perspective view of the holding device 2 according to a further embodiment. 6 shows in a schematic perspective view in 5 shown embodiment of the Hal te device 2, where in 6 a different perspective is shown than in 5 . 7 shows the holding device 2 according to a further embodiment in a schematic side view. 8th shows the in 7 shown embodiment of the holding device 2 in a schematic plan view.

At the in 5 until 8th shown embodiments, it is provided that the second component 8 is cylindrical. Thus, the second component is designed as a hollow cylinder, which includes the through-opening 11 . As a result, the holding device 2, in particular the second component 8, can be produced particularly cost-effectively, for example.

At the in 5 until 8th The respective embodiment shown is thus the partial region 32, via which the second component 8 is supported or attached to the first component 3, not at a distance from the bearing surface 10, in particular in the direction 31. A support surface, via which the second component 8 is supported or attached to the first component 3, in particular the base body 4 or the base surface 9, therefore extends, in particular directly, in the axial direction 12 of the bolt 5 below the bearing surface 10.

In a further embodiment, it is in the in 1 until 8th shown respective embodiment of the holding device 2 provided that the first component 3 has a through channel 34 which comprises at least one in the axial direction 12 of the bolt 5 extending channel area 35. The through-channel 34, in particular the channel area 35, preferably runs through the base body 4 and/or the bolt 5. The clamping element 20 of the clamping device 18 can be passed through the through-channel 34, in particular the channel area 35, whereby the component is placed between the bearing surface 10 and the can be clamped through the through-channel 34 passed clamping element 20. The clamping element 20 of the clamping device 1 is thus passed through the first component 3 via the through-channel 34 . As a result, the clamping device 1 can be designed to be particularly space-saving.

When the component is clamped between the support surface 10 and the clamping element 20 , in particular the hook element 22 , the clamping element is partially arranged in the passage channel 34 . In this case, the hook element 22 is arranged at least partially, in particular completely, outside of the through-channel 34 or at a distance from the through-channel 34 .

In the exemplary embodiment, the bolt 5 has a groove 36 in which the clamping element 20 can be partially arranged, as a result of which the component can be clamped between the bearing surface 10 and the clamping element 20 partially arranged in the groove 36 . This means that the clamping element 20 is partially arranged in the through channel 34 and the groove 36 when the component is clamped. In this case, the hook element 22 is preferably arranged outside of the groove 36 or at a distance from the groove 36 . Due to the groove 36, the clamping device 1 or the holding device 2 can be designed to be particularly space-saving.

In a further embodiment, it is provided that the tensioning element 20 passed through the through-channel 34 , in particular through the groove 36 , is passed through the through-opening 11 of the second component 8 . Thus, when the component is clamped, the clamping element 20 is at least partially surrounded by the second component 8 , in particular the wall 25 . As a result, the clamping device 1 or the holding device 2 can be designed or manufactured in a particularly advantageous manner, in particular in a particularly space-saving manner and/or with particularly little effort. This is the case in particular because the through-opening 11 can be used for a number of functions, for example for forming the gap 26 and for guiding the clamping element 20 through.

in the in 1 until 8th In the respective embodiment of the holding device 2 or the clamping device 1 shown, it is provided that the base body 4 of the first component 3 has a contact surface 37, via which the clamped component, mediated by the bearing surface 10, in the axial direction 12 of the bolt 5 on the base body 19 of the clamping device 18 can be supported or is supported, in particular can be fastened or is fastened. As a result, the clamping device 1 can be designed to be particularly stable.

For example, the components 3, 8 via the holes 30 in the 1 until 3 embodiment shown can be screwed to the base body 19 . In the respective in 5 until 8th The respective exemplary embodiment shown are provided, in particular bores 38 which are formed separately from the bores 30 and via which the first component, in particular the base body 4, can be screwed to the base body 19.

in the in 6 embodiment shown, the first component 3 is connected to the second component 8 via a pin 39 . As a result, the components 3, 8 can be centered, for example.

in the in 6 shown embodiment is at least one recess 40, for example three recesses 40 is provided. The respective recess 40 can bring about a respective form fit between the second component 3 and the component. For this purpose, the respective recess 40 comprises, for example, a second bearing surface 41 which is spaced apart from the bearing surface 10 in the axial direction of the bolt 5 and via which the component can be supported on the base body 4 in the axial direction 12 of the bolt 5 . In addition, the respective recess 40 comprises two, in particular opposite, obliquely or perpendicularly to the second bearing surface 41 side surfaces 42, via which the component can be supported in the obliquely or perpendicularly to the axial direction 12 of the bolt 5 direction. As a result, the component can be held or fixed particularly securely by means of the holding device 2 or the clamping device 1 . Preferably, the component has a respective component area designed to correspond to the respective recess 40, which can be arranged in the respective recess to form the form fit.

9 shows the holding device 2 according to a further embodiment in a schematic perspective view. In the 9 The embodiment shown of the holding device 2 is preferably not provided for arranging or attaching the holding device 2 or the first component 3 to the clamping device 18 , in particular the base body 19 . in the in 9 shown embodiment, the holding device 2 comprises a spaced from a central axis of the bolt 5 fastening area 43, via which the holding device 2 can be fastened to a separate from the holding device 2 and the clamping device 18 trained further component. Bores 44 are preferably arranged in the fastening area 43, via which the holding device 2 can be screwed to the further component.

Reference List

1

clamping device

2

holding device

3

first component

4

body

5

bolt

6

radial direction

7

support surface

8th

second component

9

Floor space

10

bearing surface

11

passage opening

12

axial direction

13

first spatial direction

14

second spatial direction

15

third spatial direction

16

first direction

17

second direction

18

clamping device

19

base body

20

clamping element

21

direction of movement

22

hook element

23

clamping position

24

radial direction

25

wall

26

gap

27

free end

28

Page

29

radial direction

30

drilling

31

Direction

32

subarea

33

outside

33a

opening

34

through channel

35

canal area

36

groove

37

contact surface

38

drilling

39

Pen

40

recess

41

second bearing surface

42

side face

43

mounting area

44

drilling

Claims (10)

Holding device (2) for fixing a component, with a first component (3) which adjoins a base body (4) and a base body (4) and from the base body per (4) protruding bolt (5), which can be passed through a receiving opening of the component, whereby the component can be supported on the bolt (5) in the radial direction (6) of the bolt (5), and with one on the base body (4) arranged, second component (8), which comprises a bearing surface (10) and a through opening (11), through which the bolt (5) is passed, whereby the component in the axial direction (12) of the bolt (5) over the bearing surface (10) can be supported on the base body (4), there being a gap between the bolt (5) and a wall (25) of the second component (8) delimiting the through-opening (11) outwards in the radial direction (24). (26) is provided, through which an abrasion of the component generated by the bolt (5) passes. Holding device (2) after claim 1 , characterized in that the bolt (5) in its radial direction (6) is at least predominantly surrounded by the bearing surface (10). Holding device (2) after claim 1 or 2 , characterized in that a side (28) of the gap (26) facing the free end (27) of the bolt (5) is delimited outwards in its radial direction (29) by the bearing surface (10). Holding device (2) according to one of the preceding claims, characterized in that the components (3, 8) are formed separately from one another and are connected to one another. Holding device (2) according to one of the preceding claims, characterized in that the second component (8) has at least one partial region spaced apart from the bearing surface (10) in a direction (31) running obliquely or perpendicularly to the axial direction (12) of the bolt (5). (32), via which the second component (8) is supported on the first component (3). Holding device (2) according to one of the preceding claims, characterized in that the second component (8) has at least one opening (33a) arranged on an outer side (33) of the second component (8), through which the reached abrasion reached. Holding device (2) according to one of the preceding claims, characterized in that the second component (8) is cylindrical. Holding device (2) according to one of the preceding claims, characterized in that the first component (3) has a through channel (34) which comprises at least one channel region (35) extending in the axial direction (11) of the bolt (5), wherein a Clamping element (22) of a clamping device (18) can be passed through the passage (34), whereby the component can be clamped between the bearing surface (10) and the clamping element (20) passed through the passage (34). Holding device (2) after claim 8 , characterized in that the base body (4) has a contact surface (37) via which the clamped component, mediated by the contact surface (10), in the axial direction (11) of the bolt (5) on a base body (19) of the clamping device (19 ) can be supported. Holding device (2) after claim 8 or 9 , characterized in that the clamping element (22) passed through the through-channel (34) is passed through the through-opening (11) of the second component (8).

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