DE102012011750A1 - Fastening arrangement for fixing vehicle bodywork component to attachment component, has fixing element with rotatably mounted eccentric pin, and another fixing element with receiving opening for eccentric pin positioned in vertical plane - Google Patents

Abstract

The fastening arrangement (1) has a fixing element (4) with a rotatably mounted eccentric pin (7). Another fixing element (5) is provided with a receiving opening (8) for the eccentric pin. The eccentric pin is positioned in a vertical plane oriented perpendicular to a mounting axis by a rotary movement during the feed movement of a secondary component (3), such that the eccentric pin is introduced into the receiving opening and is fixed by an automatic engaging detent connection between the eccentric pin and the receiving opening. The secondary component is arranged in a predetermined position relative to the primary component (2).

Description

The invention relates to a fastening arrangement with automatic three-dimensional tolerance compensation, with a first component, a second component, which is fixed to the first component by an assembly process under automatic three-dimensional compensation of tolerances in the position of the second component relative to the first component, wherein the second component is movable relative to the first component during the assembly process by a feed movement in the direction of a mounting axis in a predetermined position, and with a fastening device having a first fastening element and a second fastening element.

Fastening devices for fastening a first component to a second component with an automatic tolerance compensation in the distance between the two components are known in great variety. In the DE 10 2010 048 239 A1 Such a spacer tolerance compensating mounting arrangement for two components will be described. This includes a first component fixedly assigned mounting recess, a longitudinally displaceable for overcoming the distance tolerance in the mounting recess insertable sleeve and a widening of the insertion sleeve in this insertable screw, by means of which the second component can be fastened to the insertion sleeve.

From the WO 2004/067975 A2 For example, a connection element for connecting a first component to a second component with a tolerance compensation in two planes or directions is known. The connecting element has a retaining clip fixedly connected to the first component and a sliding element arranged in the retaining clip and displaceable relative to the retaining element in a first spatial direction. In addition to the displacement body arranged in the retaining clip, the displacement element has an insertion body which can be inserted or latched into a receiving opening of a receiving element. As a result, the displacement element in relation to the receiving element in a second spatial direction is displaceable.

Another mounting arrangement of the type mentioned is already out of the WO 2009/106261 A1 known. This fastening arrangement has a fastening device for fastening an attachment to a fixed support part, which allows an automatic three-dimensional compensation of tolerances in the position of the attachment relative to the support member and requires no screwing of the components involved. The fastening device comprises a carrier part detent member and an attachment detent member. The carrier part locking member is arranged with the interposition of a centering frame in such an opening of the support member that it is mounted floating before the assembly process in a radial plane. The attachment detent member consists of a locking pin, a mounting portion, a screw and a nut and is arranged in a correspondingly shaped receiving opening of a receiving element, which is associated with the attachment. In this case, the attachment detent member is designed such that it relative to the carrier part, the carrier part detent member centered by displacement in the radial plane to the central axis and by an automatically latching detent connection between the carrier part locking member and the attachment locking member in at a feed movement of the attachment the predetermined position is determined. Thus, in addition to the two components to be connected, the fastening arrangement consists of a total of six individual parts, which partially have to be connected to one another before and partly during the assembly process or arranged on the carrier part and the attachment part.

Against this background, the object of the invention is to provide a simple alternative fastening arrangement with an automatic three-dimensional tolerance compensation.

This object is achieved with a fastening arrangement according to the features of patent claim 1. The subclaims relate to particularly expedient developments of the invention.

According to the invention, therefore, a fastening arrangement with automatic three-dimensional tolerance compensation is provided, in which the first fastening element has a rotatably mounted eccentric pin, wherein a rotational axis of the eccentric pin is arranged eccentrically to a central longitudinal axis of the eccentric pin and parallel to the mounting axis and the second fastening element has a receiving opening for the eccentric pin wherein the eccentric pin is positionable during the feed movement of the second component by a rotational movement in a direction perpendicular to the mounting axis vertical plane that the eccentric can be inserted into the receiving opening and fixed by an automatically latching latching connection between the eccentric and the receiving opening such that the second Component is arranged in the predetermined position relative to the first component. The compensation of tolerances in the direction of the mounting axis is effected by the latching connection, while the tolerance compensation in the aligned perpendicular to the mounting axis vertical plane not as in the prior art by a translational displacement movement, but by a rotational rotational movement of the Eccentric pin is done. In addition, the fastening arrangement according to the invention, in particular in comparison to that of the WO 2009/106261 known mounting arrangement fewer items. This reduction in the number of individual parts and a simplification of the structural design of these items results in particular over the prior art, considerable advantages. For example, the manufacturing costs of the individual parts and the duration of the assembly process can be reduced overall. At the same time there is an increase in the cycle times and the tolerance chain can be reduced. By the automatic assembly and fixation of the second component to the first component unfavorable mounting positions for the person performing the assembly can be prevented.

A particularly practical embodiment of the present invention provides that the eccentric pin has a particular conical insertion section. As a result, the insertion of the eccentric pin is ensured and facilitated during the feed movement of the second component relative to the first component. By the first contact of the insertion of the eccentric pin with the receiving opening bounding wall surfaces of the receiving opening of the eccentric pin is rotated in the vertical position or the vertical plane that it can be inserted so far into the receiving opening in the further course of the feed movement that the second component in the predetermined position is arranged relative to the first component.

Furthermore, it proves to be particularly useful that the eccentric pin has at least one locking element for producing the latching connection with the receiving opening. In this case, the at least one latching element is arranged circumferentially in an advantageous manner. In a particularly simple embodiment it is provided that the latching element has circumferential grooves, in particular a plurality of parallel and in the longitudinal direction of the eccentric pin behind or next to each other arranged grooves.

As a particularly practical it has been found that the rotatably mounted eccentric pin is attached to the first component, which is for example designed as a fixed body part of a motor vehicle, and the receiving opening is associated with the second component, which is designed as a delivery movement exporting attachment. However, it is also possible that the receiving opening is assigned to the first component and the eccentric pin is assigned to the second component.

A further feature of the invention is that the rotatably mounted eccentric pin has a recess for receiving a bolt arranged on the component side. As a result, the eccentric pin is freely rotatably mounted on the component-fixed bolt. The bolt can be cohesively fixed, for example by welding, to the component or be an integral part of the component.

Advantageously, the rotatably mounted eccentric pin is positively connected to the bolt in order to ensure the reliable fixing of the eccentric pin on the respective component or the second component to the first component.

A structural embodiment of the present invention provides that the receiving opening is arranged in a sleeve-shaped receiving element. The wall surfaces of the sleeve-shaped receiving element form a guide for the eccentric pin during the assembly process and prevent tilting of the eccentric pin during the feed movement of the second component. Furthermore, the sleeve-shaped receiving element offers the possibility of integration of further functional components of the fastening arrangement.

In this case, the sleeve-shaped receiving element can be integrally connected to the first component or the second component or be fixed as a separate component to the first component or the second component.

A further optimization of the present invention is also provided by the fact that a decoupling element is arranged between the sleeve-shaped receiving element and the first component or the second component. As a result, an acoustic and mechanical decoupling of the two components is achieved. At the same time, the decoupling element, which consists for example of an elastomer, dampens or dampens vibrations arising during operation of the motor vehicle and noise generated by the vibrations. The decoupling element may be formed as a separate part and fixed by form, force or material connection to the first component, the second component or the receiving element.

Furthermore, it proves to be particularly useful that the receiving element has at least one inwardly directed locking element for producing the latching connection with the eccentric pin.

A particularly advantageous development of the present fastening arrangement according to the invention provides that a cross-sectional area extending in the vertical plane Receiving opening in a first spatial axis has larger dimensions than in a second spatial axis arranged orthogonal to the first spatial axis, wherein the dimensions are configured such that the eccentric pin arranged in the receiving opening is mounted floating during the assembly process in the direction of the first spatial axis. By this floating movable mounting the tolerance compensation in the first spatial axis can be optimized and at the same time the insertion of the eccentric pin is simplified in the receiving opening.

It proves to be expedient that the latching element is designed as at least one rib, which extends in the direction of the first spatial axis. The rib engages during or after the assembly process in one of the grooves in the eccentric and forms the positive locking connection in the direction of the mounting axis. The positive connection between the eccentric pin and the receiving opening or the receiving element is optimized in that the locking element has at least two mutually opposite parallel ribs.

Furthermore, the invention is also characterized by the fact that the eccentric pin and the receiving element are positively connected in the predetermined position by the latching connection in the direction of the mounting axis and the second spatial axis and positively in the direction of the first spatial axis. In this case, the latching connection can be acted upon by a normal force counter to the feed movement, which frictionally connects the latching element of the eccentric pin and the latching element of the receiving element in the direction of the first spatial axis when the second component is arranged in the predetermined position relative to the first component. The normal force results from a restoring force of a seal arranged between the first component and the second component, which is initially compressed by the advancing movement of the second component and expands again after reaching the predetermined position of the second component. By this normal force, the locking elements of the eccentric pin and the locking elements of the receiving element frictionally or non-positively connected. By this non-positive connection, a relative movement between the eccentric pin and the receiving element in the vertical plane is prevented.

A further advantageous embodiment of the invention provides that the first component is a body component of a motor vehicle and / or the second component is a mounting or mounting part. As a result, the tolerances occurring in the manufacture of the shell and the body component can be compensated in a simple manner.

The invention allows numerous embodiments. To further clarify its basic principle, one of them is shown in the drawing and will be described below. This shows in

1 an exploded perspective view of a mounting arrangement with a first component and a second component;

2 a sectional side view of the 1 illustrated mounting arrangement;

3 a sectional side view of the mounting assembly immediately prior to assembly of the second component on the first component;

4 a sectional side view of the fastening assembly in a first installation situation;

5 a sectional side view of the fastening arrangement in a second installation situation;

6 a sectional side view of the fastening assembly in a third installation situation.

The 1 and 2 each show an exploded view of the fastening arrangement according to the invention 1 with a first component 2 , a second component 3 and one of a first fastener 4 and a second fastener 5 existing fastening device 6 , In the embodiment shown in the figures, the first component 2 as a body component of a motor vehicle and the second component 3 as a mounting or mounting part, such as an air conditioner, trained. The first fastening element 4 has a rotatably mounted eccentric pin 7 and the second fastening element 5 a receiving opening 8th having receiving element 9 on. Furthermore, an existing of an elastomer decoupling element 10 provided, which between the receiving element 9 and the second component 3 is arranged.

A rotation axis 11 of the eccentric pin 7 points to a central axis 12 of the eccentric pin 7 an eccentricity 13 on. The rotatable mounting of the eccentric pin 7 on the first component 2 is component side by one with the first component 2 firmly connected cylindrical bolts 14 and pin side by a for receiving the bolt 14 suitable recess 15 realized. In addition, the eccentric pin 7 a conically shaped insertion section 16 and a cylindrically shaped attachment portion 17 on, with the introduction section 16 the receiving element 9 or the receiving opening 8th is facing. The cylindrical one attachment section 17 has a latching element 18 on which is arranged circumferentially and from several in the longitudinal direction of the eccentric pin 7 one behind the other and parallel grooves 19 consists.

A cross-sectional area 20 in the receiving element 9 arranged receiving opening 8th is formed as a slot and points in the direction of a first, parallel to the z-axis aligned spatial axis 21 larger dimensions than in the direction of an orthogonal to the first spatial axis 21 and aligned parallel to the y-axis second spatial axis 22 , The dimensions of the receiving element 9 in the direction of its longitudinal extent (ie in the direction of the x-axis) are chosen such that the eccentric pin 7 at least partially or particularly preferably almost completely into the receiving opening 8th of the receiving element 9 is insertable. Furthermore, the receiving element 9 two in the receiving opening 8th protruding locking elements 23 on. In the illustrated embodiment, the locking elements 23 as two oppositely disposed and mutually parallel ribs 24 . 25 formed, which extend in the direction of the first spatial axis 21 or extend in the direction of the z-axis.

As already described, the receiving element 9 with the interposition of the decoupling element 10 on the second component 3 arranged. The decoupling element 10 So on the one hand on the receiving element 9 and on the other hand on the second component 3 fixed. For fixing the decoupling element 10 on the second component 3 are in the decoupling element 10 two in the direction of the z-axis grooves 26 . 27 provided, in which two on the second component 3 arranged webs 28 . 29 interlock positively.

Before the actual assembly of the second component 3 on the first component 2 First, the pre-assembly of the receiving element 9 on the second component 3 and the eccentric pin 7 on the first component 2 , 3 shows the mounting arrangement 1 after the pre-assembly. As part of the pre-assembly is first the decoupling element 10 , For example, by a positive or cohesive connection, on the receiving element 9 fixed. Subsequently, the receiving element 9 with the interposition of the decoupling element 10 such on the second component 3 attached that the receiving element 9 , the decoupling element 10 and the second component 3 a jointly manageable first unit 30 form. For fixing the with the receiving element 9 connected decoupling element 10 on the second component 3 becomes the decoupling element 10 such relative to the second component 3 positioned and moved that on the second component 3 arranged webs 28 . 29 positively in the correspondingly shaped grooves 26 . 27 of the decoupling element 10 intervention.

Furthermore, before the actual assembly of the second component 3 on the first component 2 the eccentric pin 7 with the first component 2 , as in 3 shown, to a jointly manageable second assembly 31 connected. For this purpose, the eccentric pin 7 positioned so that the recess 15 of the eccentric pin 7 coaxial with that with the first component 2 connected bolts 14 is arranged. By a relative movement between the eccentric pin 7 and the first component 2 becomes the bolt 14 then into the recess 15 introduced, and that until the bolt 14 in the in 3 shown position is arranged. Preferably, a connection between the eccentric pin occurs 7 and the bolt 14 by a positive axial locking, which is designed such that a movement of the eccentric pin 7 in the axial direction, ie in the direction of the x-axis, is prevented, the eccentric pin 7 but at the same time free around its axis of rotation 11 can turn.

When the receiving element 9 with the decoupling element 10 on the second component 3 and the eccentric pin 7 on the first component 2 , as in 3 shown, preassembled, the second component 3 on the first component 2 be mounted, which is described below.

In the actual assembly process, for example, designed as an air conditioner second component 3 on the formed as a body component of a motor vehicle first component 2 be fixed. To the second component 3 in the correct position relative to the first component 2 To fix, it is only necessary that the second component 3 For example, by a robot, by a feed movement 32 in the direction of a parallel to the x-axis aligned mounting axis 33 is guided until the second component 3 on a circumferential seal, not shown, of the first component 2 strikes. During the delivery movement 32 of the second component 3 in the direction of the mounting axis 33 the introductory section appears 16 of the eccentric pin 7 in the receiving opening 8th of the receiving element 9 one. As a result, the eccentric pin 7 around its axis of rotation 11 rotated and thus in the plane defined by the y-axis and the z-axis and perpendicular to the mounting axis 33 arranged vertical plane that positions the eccentric pin 7 almost completely into the receiving opening 8th of the receiving element 9 be introduced and thereby the second component 3 in a predetermined position relative to the first component 2 can be arranged. By the rotation of the eccentric pin 7 Tolerance compensation takes place in the vertical plane, ie in the direction of the plane spanned by the y-axis and the z-axis.

During the delivery movement 32 of the second component 3 relative to the first component 2 there is a latching of the locking elements 23 of the receiving element 9 with the locking elements 18 of the eccentric pin 7 , By this automatically latching locking connection 34 (please refer 4 to 6 ) between the locking elements 18 . 23 of the eccentric pin 7 and the receiving opening 8th or the receiving element 9 , Tolerance compensation takes place in the direction of the x-axis, wherein the feed movement 32 of the second component 3 relative to the first component 2 is complete when the second component 3 on the seal, not shown, of the first component 2 strikes and the second component 3 in the predetermined position relative to the first component 2 is arranged (see 4 ). Between the two components 2 . 3 then acts a restoring force generated by the seal 35 which the locking elements 18 of the eccentric pin 7 and the locking elements 23 of the receiving element 9 pressed against each other so that they are positively connected with each other.

The 4 . 5 and 6 show the in the 1 and 2 illustrated fastening arrangement 1 in different installation situations, the 5 and 6 the maximum tolerance positions of the mounting arrangement 1 in the direction of the y-axis.

LIST OF REFERENCE NUMBERS

1

mounting assembly

2

first component

3

second component

4

first fastening element

5

second fastening element

6

fastening device

7

eccentric

8th

receiving opening

9

receiving element

10

decoupling element

11

axis of rotation

12

central longitudinal axis

13

eccentricity

14

bolt

15

recess

16

insertion

17

attachment section

18

Locking element (eccentric pin)

19

groove

20

Cross sectional area

21

first space axis

22

second space axis

23

Locking element (receiving element)

24

rib

25

rib

26

groove

27

groove

28

web

29

web

30

first building unit

31

second unit

32

infeed

33

mounting axis

34

locking connection

35

Restoring force

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010048239 A1 [0002]
• WO 2004/067975 A2 [0003]
• WO 2009/106261 A1 [0004]
• WO 2009/106261 [0007]

Claims (14)

Mounting arrangement ( 1 ) with automatic three-dimensional tolerance compensation, with a first component ( 2 ), a second component ( 3 ) attached to the first component ( 2 ) by an assembly process under automatic three-dimensional compensation of tolerances in the position of the second component ( 3 ) relative to the first component ( 2 ) is fixable, wherein the second component ( 3 ) during the assembly process by a feed movement ( 32 ) in the direction of a mounting axis ( 33 ) in a predetermined position relative to the first component ( 2 ) is movable and with a first fastener ( 4 ) and a second fastening element ( 5 ) having fastening device ( 6 ), characterized in that the first fastening element ( 4 ) a rotatably mounted eccentric pin ( 7 ), wherein an axis of rotation ( 11 ) of the eccentric pin ( 7 ) eccentric to a central longitudinal axis ( 12 ) of the eccentric pin ( 7 ) and parallel to the mounting axis ( 33 ) is arranged, and that the second fastening element ( 5 ) a receiving opening ( 8th ) for the eccentric pin ( 7 ) and that the eccentric pin ( 7 ) during the delivery movement ( 32 ) of the second component ( 3 ) by a rotational movement in such a direction perpendicular to the mounting axis ( 33 ) aligned vertical plane is positioned that the eccentric pin ( 7 ) into the receiving opening ( 8th ) and by an automatically latching latching connection ( 34 ) between the eccentric pin ( 7 ) and the receiving opening ( 8th ) is determinable such that the second component ( 3 ) in the predetermined position relative to the first component ( 2 ) is arranged. Mounting arrangement ( 1 ) according to claim 1, characterized in that the eccentric pin ( 7 ) an in particular conically shaped insertion section ( 16 ) having. Mounting arrangement ( 1 ) according to claims 1 or 2, characterized in that the eccentric pin ( 7 ) at least one latching element ( 18 ) for producing the locking connection ( 34 ) with the receiving opening ( 8th ) having. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the at least one latching element ( 18 ) is arranged circumferentially and / or that the locking element ( 18 ) circumferential grooves ( 19 ) having. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the rotatably mounted eccentric pin ( 7 ) on the first component ( 2 ) and the receiving opening ( 8th ) the second component ( 3 ) is assigned or that the rotatably mounted eccentric pin ( 7 ) on the second component ( 3 ) and the receiving opening ( 8th ) the first component ( 2 ) assigned. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the rotatably mounted eccentric pin ( 7 ) a recess ( 15 ) for receiving a bolt arranged on the component side ( 14 ) and / or that the rotatably mounted eccentric pin ( 7 ) positively with the component side arranged bolt ( 14 ) connected is. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the receiving opening ( 8th ) in a sleeve-shaped receiving element ( 9 ) is arranged. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the sleeve-shaped receiving element ( 9 ) in one piece with the first component ( 2 ) or the second component ( 3 ) or that the sleeve-shaped receiving element ( 9 ) on the first component ( 2 ) or the second component ( 3 ) is fixed. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that between the sleeve-shaped receiving element ( 9 ) and the first component ( 2 ) or the second component ( 3 ) a decoupling element ( 10 ) is arranged. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the receiving element ( 9 ) at least one inwardly directed locking element ( 23 ) for producing the locking connection ( 34 ) with the eccentric pin ( 7 ) having. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that a cross-sectional area extending in the vertical plane ( 20 ) of the receiving opening ( 8th ) in a first spatial axis ( 21 ) has larger dimensions than in an orthogonal to the first spatial axis ( 21 ) arranged second spatial axis ( 22 ), wherein the dimensions are designed such that in the receiving opening ( 8th ) arranged eccentric ( 7 ) during the assembly process in the direction of the first spatial axis ( 21 ) is floatingly mounted. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the latching element ( 23 ) of the receiving element 9 as at least one rib ( 24 . 25 ) is formed, which in the direction of the first spatial axis ( 21 ), or that the locking element ( 23 ) at least two oppositely arranged parallel ribs ( 24 . 25 ) having. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the eccentric pin ( 7 ) and the receiving element ( 9 ) in the predetermined position by the latching connection ( 34 ) in the direction of the mounting axis ( 33 ) and the second spatial axis ( 22 ) positively and in the direction of the first spatial axis ( 21 ) are positively connected. Mounting arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the latching connection ( 34 ) by one of the delivery movement ( 32 ) opposing normal force can be acted upon, which the latching element ( 18 ) of the eccentric pin ( 7 ) and the locking element ( 23 ) of the receiving element ( 9 ) frictionally connects, when the second component ( 3 ) in the predetermined position relative to the first component ( 2 ) is arranged.

Images