DE19811532A1 - Fixing unit for vehicle bodywork components - Google Patents

Abstract

The fixing unit (1) has a positioning element (6) with a positioning head (7) at least partly projecting from its welding collar (5). The positioning element is detachably connected to the fixing unit, and has a holding sector (14) projecting into a through boring (2) in the fixing unit. The positioning unit should be made of a material which becomes pasty during the welding-on process.

Description

The object of the invention relates to a method for training of a welding connection between a fastening unit and a component and a fastening unit.

The utility model 296 10 640.2 is a fastening unit for Formation of a welding connection between a fastening unit and a component known. The fastening unit is a welding nut, for example. The fastening unit points a through hole on a first and a second end face of the Fastening unit penetrates. The through hole can be for example, a threaded hole. The fastening unit has at least one welding collar that extends from one of the foreheads surfaces in the axial direction of the through hole from the fastening stretched away. Such a fastening unit can, for example by means of the drawn arc process or after the resistance welding process drive to be connected to the component. The fastening unit becomes Welding to the component which has a hole positioned so that the through hole of the assembly is substantially coaxial with Bore of the component is. After positioning, the actual one takes place Welding process.  

It is known that such structural units, for example by means of handling devices, such as robots, are welded to a component. The component can be, for example, a body of a Act motor vehicle. The use of an electronically controlled, in particular a programmable, handling device is in particular useful when a large variety of units on one or several components must be welded on. This is particularly so appropriate for series production.

For small series, the use of programmable handling devices is under Possibly uneconomical because the effort for programming the Coordinates and the sequences of the handling device is relatively large.

It is also known that so-called stencils are used for small series be a positioning of the assembly by a mouthpiece a manually operated welding device is simplified. Before the provision for this is the provision of templates. To be used individually manufacturing components, however, the production of templates is too open agile, so that the operating personnel of a manual welding device the assembly is positioned on the component without any additional aids. This may lead to the coaxiality of the through hole of the Unit and the drilling of the component may no longer be given is.

Proceeding from this, the present invention has the objective Basically a process for forming a welding connection to specify between a fastening unit and a component by which facilitates the positioning of the fastening unit on the component can be made without the need to make templates. A Another object of the invention is to provide a unit whose position  nation on the component is easy to achieve. This objective is fiction according to a method having the features of claim 1 approximately solved a unit with the features of claim 7. Advantageous further developments and refinements of the invention The method and the structural unit according to the invention are the subject of respective dependent claims.

To simplify the formation of a welding connection between a fastening unit, in particular a weld nut, and a component with a hole is proposed that the attachment unit a mouthpiece of a welding device, in particular one manually operated welding device. The fastening unit has a through hole, which has a first and a second end face the fastening unit penetrates. The fastening unit has at least one protruding from an end face, the through hole at least partially surrounding welding collar.

A positioning element is detachably connected to the fastening unit. The Positioning element has a positioning head. The sweat collar surrounds at least partially the positioning element. The positioning head is little at least partially over the welding collar. The positioning head is respected Lich adapted to the shape of the hole in the component that the head is at least partially insertable into the bore. The positioning head will in contact with a surface of the component, preferably in the environment brought the hole. By moving the welding device with the Fastening unit in the direction of the hole is the welding device move until the positioning head at least partially into the Boh got into it. The positioning head is preferably so far in front of the Weld collar before that when the positioning head into the hole comes, the welding collar comes into contact with the component. This has  the fastening unit reaches a substantially correct position, so that a welding process can be carried out.

The fact that the positioning element is detachable with the fastening unit is connected, this can be removed after the welding process. A Removing the positioning element can be done in that already rend the welding process on the positioning element in the direction of Bore directed force is exerted so that the positioning element the bore is driven through. Driving the positioning element through the hole of the component can also after welding course.

At least the positioning head of the positioning element is preferably formed by a material that little during the welding process is at least brought into a pasty state. The positioning head can For example, consist of a plastic that is generated by the heat tion melts during the welding process, so that only one relative little force is required to move the positioning element through the hole or remove through the through hole.

A procedure is preferred in which at least the positioning head melts during the welding process. Then only the Removal of the remaining part of the positioning element.

According to a further advantageous embodiment of the method, before struck that at least the positioning head of the positioning element gasified during the welding process. In particular, at least the Positioning head made of a material that during the on welding process due to the development of heat essentially without residues  gassed. This has the advantage that the method according to the invention also with Overhead work can be done.

According to a further inventive idea, a fastening unit to form a welding connection with a component, which has a bore, proposed, the fastening unit has a positioning element that has a positioning head that at least partially protrudes over a welding collar of the fastening unit. Of the Welding collar at least partially surrounds a through hole. By Use of such a fastening unit according to the invention can be based on the production of templates for welding the fastening unit to be dispensed with. An exact positioning of the fastening unit will thereby achieved that the positioning head at least partially in a Boh tion of the component can be introduced.

The design of the fastening unit according to the invention is also for Handling devices, in particular programmable robots, are suitable if the positioning element consists of an electrically insulating material. When positioning a conventional fastening unit can also then a welding current will flow if the fastener is misplaced is. This is prevented in the fastening unit according to the invention, if the positioning element is made of an electrically insulating material exists because the positioning head at least partially over the Welding collar protrudes, an electrical circuit is not lockable. The positioning of the fastening unit can therefore be canceled or be made again. A signal can also be generated by which the actual welding process is not triggered.

According to an advantageous embodiment of the fastening according to the invention unit is proposed that the positioning head ver with a shaft  is bound, the one extending into the through hole Has holding section. The holding section is used to determine the position nierelementes on the fastening unit, so that the positioning element is captively connected to the fastening unit.

According to a further advantageous embodiment of the invention Fastening unit is proposed that the collar with a radial Distance to the through hole is formed and the shaft an has impact that abuts an end face. The attack will prevents that during the positioning of the fastening unit Positioning element is pressed into the through hole when on the positioning head exerts a substantially axially directed force becomes. The stop is preferably formed all around, so that the Force can be absorbed substantially evenly. The um running stop also ensures that tilting of the positioning element is prevented, so that coaxiality between the positioning head and the through hole remains ensured. The stop is preferably in the form of a bead.

According to yet another advantageous embodiment of the fastening unit it is proposed that the shaft at least one between the position kidney head and the holding portion lying, the cross cutting area is larger than the cross-sectional area of the holding portion, wherein the holding portion and the portion substantially coaxial with each other are formed and the transition surface between the holding portion and the section forms the stop. Such an arrangement of the position kidney element is advantageous because the stop much higher forces can record than is the case with a stop in the form of a bead is. In particular with large axially directed forces on the position Kidney head prevents the stop from shearing off. Such  Formation of the positioning element is also advantageous if that Positioning element is made of a plastic, because the Her Position such a positioning element necessary forms a relative have simple geometry.

The configuration of the fastening unit in which the positioning head tapers away from the shaft. In particular, should taper the positioning head away from the shaft. This configuration has the advantage that a self-centering of the positioning head in the The component is drilled. An embodiment of the positioning is preferred head, in which this conical, in particular frustoconical, trained det.

According to a further advantageous embodiment of the fastening unit this one chamber, partly by a collar with radial Distance to the through hole and circumferentially in the circumferential direction is limited to. The positioning element preferably has little Mostly a channel that connects the chamber with an ambient atmosphere connects. Gas development can occur during a welding process occur so that there is a higher gas pressure in the chamber than in the Ambient atmosphere. This gas pressure can cause sweat melt is blown radially away from the weld by the gas. This can lead to an unsatisfactory formation of a welded joint between the fastening unit and the component. To do this avoid the positioning element has the at least one channel connects the chamber to an ambient atmosphere. Through the channel can the gas that is generated during the welding process from the Chamber can be derived into the ambient atmosphere, so that the gas pressure inside the chamber always the pressure of the surrounding atmosphere corresponds.  

According to an advantageous embodiment of the fastening unit, struck that the channel through at least one groove in a lateral surface of the positioning head is formed. The positioning head preferably has a plurality of grooves on the circumferentially equidistant to each other are trained. In particular, the positioning head can have the shape of a Have bevel gear. In addition to the advantage that a through the grooves fluidic connection between the chamber and the environment atmosphere is created, has a design of the positioning head a variety of grooves the advantage that when the positioning head a fusible material, less heat is necessary to melt away the material defining the grooves, than this would be the case with a positioning head without such grooves.

Instead of the positioning head with at least one groove in a lateral surface of the Forming positioning head, the channel can also by a Axial direction extending central channel and at least one in Axial direction extending secondary channel be formed, the secondary channel opens into the chamber. The central channel preferably has one polygonal cross-section, so that the central channel is also a tool handle can form, through which the positioning element from the passage hole can be unscrewed if the through hole as a threaded hole is formed.

According to yet another advantageous embodiment of the fastening unit it is proposed that at least the positioning head of the positioning element tes, in particular the entire positioning element, consists of one material, at least in a pasty state during a welding process transforms. In particular, the positioning element can be made of a plastic exist, the melting temperature is relatively low, so that when The heat generated is sufficient to ensure that  Melt the positioning element out of the fastening unit. Preferential as the positioning element consists of a material which during of the welding process is gasified essentially without residues.

Further advantages and details of the method according to the invention and the Fastening unit according to the invention are based on the in the drawing illustrated embodiments explained. Show it:

Fig. 1 shows schematically and in section a first embodiment of a fastening unit,

Fig. 2 shows schematically and in full section of a second embodiment of a fastening unit,

Fig. 3 shows the positioning member of the fixing unit of FIG. 2 in a top view,

Fig. 4 shows a third embodiment of a fixing unit in section,

Fig. 5 schematically and in a perspective view an example of a Ausfüh approximately a positioning element, and

Fig. 6 shows another embodiment of a positioning element in partial section.

Fig. 1 shows a first embodiment of a fixing unit 1 for welding connection with a component 16. The fastening unit 1 is preferably designed in the form of a weld nut. The fastening supply unit 1 has a through hole 2 , which is in particular in the form of a threaded hole. The through hole 2 penetrates a first 3 and a second 4 end face of the Befestigungsein unit. The through hole 2 extends along the axis 12 .

A welding collar 5 is formed on the end face 4 . The welding collar 5 is formed circumferentially when viewed in the circumferential direction. It surrounds the through hole at a radial distance.

The fastening unit 1 has a releasably connected to this positioning element 6 . The positioning element 6 has a positioning head 7 . The positioning head 7 tapers in the axial direction. It is frustoconical. The positioning head 7 has a lateral surface 11 which can be brought into contact with an edge 13 of a bore 10 in the component 16 .

The positioning element 6 has a shaft 8 which carries the positioning head 7 at its free end section. The shaft 8 has a holding section 14 . The holding portion 14 extends into the through hole 2 . The positioning element 6 is detachably connected to the fastening unit 1 via the holding section 14 . The connection is however formed so that the positioning element 6 captive with its mountings supply unit 1 is connected. In particular, the holding section 14 is screwed into the through hole 2 which is designed as a threaded hole. The shaft 8 has a stop 9 . The stop 9 lies on the end face 4 . The stop 9 is formed by a circumferential bead 18 .

The shape and shape of the frustoconical positioning head 7 is designed such that it can be partially inserted into the bore 10 . During a positioning of the fastening unit 1 , the positioning head 7 is introduced into the bore 10 of the component 16 . The head 7 reaches the bore 10 to the extent that one end face 15 of the collar 5 comes to rest against a surface 17 of the component 16 . Due to the conical design of the positioning head 7 , the assembly 1 is self-centered. If the bore 10 is essentially circular in cross section, the through bore 2 of the structural unit 1 is aligned coaxially to the bore 10 after positioning. A welding process can then be carried out.

In Fig. 2, a second embodiment example of a structural unit 1 is shown schematically and in full section. The assembly 1 has a through hole 2 which penetrates a first and a second end face 3 , 4 . A collar 5 surrounds the through hole 2 with radial Ab stood. The collar 5 extends in the axial direction away from the end face. The collar 5 partially delimits a chamber 21 .

In the through opening 2 , a holding portion 14 of a positioning element 22 projects into it. The shaft 8 of the positioning element 22 has a section 23 lying between the positioning head 7 and the holding section 14 . The holding section 14 and the section 24 each have a substantially circular cross-sectional area. The holding section 14 and the section 23 are formed coaxially to one another, as can be seen from FIG. 3. Fig. 3, also shows that the cross-sectional area of section 23 is greater than the cross-sectional surface of the holding portion 14. The annular surface 24 forms a stop 9 . The stop 9 bears against the end face 4 of the fastening unit 1 .

The collar 5 partially delimits a chamber 21 . The positioning element 22 has a channel which connects the chamber 21 to the ambient atmosphere. The channel is formed by a central channel 19 which extends from an end face of the head 7 and which is connected to secondary channels 20 . The central channel 19 extends over part of the axial length of the positioning element 22 . The channels 20 are formed substantially perpendicular to the central channel twentieth As can be seen from the illustration in FIG. 3, four channels 20 are provided, which are essentially offset by 90 ° to one another.

During a welding process, gases and vapors can arise which are discharged from the chamber 21 into the surrounding atmosphere via the secondary channels 20 and the central channel 19 .

In FIG. 4, a further embodiment of a fixing unit 1 is shown. The basic structure of the fastening unit 1 corresponds to the design of the fastening unit 1 according to FIG. 1. The fastening unit shown in FIG. 4 differs from the positioning element 6 according to FIG. 1 with regard to the design of the positioning element 25 .

The positioning element 25 has a holding section 14 which projects into the through hole 2 of the fastening unit 1 . Below the holding section 14 , a bead 18 is formed, which forms a stop 9 , which abuts an end face 4 of the fastening unit 1 . Between the bead 18 and the positioning head 7 , the shaft has a tapering section 26 . By tapering in the area from section 26 , a predetermined breaking point is quasi formed.

If a force is exerted on the end face of the holding section 14 in the axial direction and for the bore 10 of the component 16 , then there is a deformation or a break of the section 26 , since the head 7 is pressed against the component 16 . The head 7 and the shaft 8 can then fall out through the bore 10 . If the positioning element 25 consists of a plastic, the tapering section 26 has the advantage that the heat development during a welding process can be sufficiently large to melt the positioning element in the area of the section 26 .

A positioning element 27 is shown in perspective in FIG. 5. The positioning element 27 has a shaft 8 . The shaft 8 has a holding section 14 , to which a section 23 adjoins. The cross-sectional area of the holding section 14 is smaller than the cross-sectional area of the section 23 . The holding section 14 and the section 23 have a substantially circular cross section. They are formed coaxially with one another. An annular surface 24 is formed , which forms a stop 9 .

A positioning head 7 adjoins section 23 . The head 7 has the basic shape of a truncated cone. The jacket 11 has a plurality of grooves 28 which extend in the longitudinal direction of the jacket. The grooves 28 form channels that connect a chamber 21 with an ambient atmosphere. In the example shown, the jacket 11 of the head is essentially wave-shaped. Such a positioning head 7 rests with a large number of points on the edge 13 of a bore 10 . If the positioning element 27 consists of a plastic, the walls lying between the grooves 28 melt, so that, with a relatively low heat input, an output of the positioning element 27 can be removed from the fastening unit 1 .

Fig. 6 shows a further variant, schematically shows a positioning 32nd The positioning element 32 has a positioning head 29 . The positioning head 29 is formed by a wall 30 which extends essentially perpendicular to the longitudinal extension of the shaft 8 and on which a wall 31 is formed in the form of a shell. The positioning head 29 has a truncated cone-shaped outer contour. A certain flexibility of the positioning head 29 is achieved by the shell-shaped wall 31 . The wall 31 may be provided zen with Schlit, so that the head portions 29 radially inward resilient wall having radially deflect during pressing of the positioning member 32 through a bore 10 inwardly and thus with a relatively small force, the positioning element 32 through the bore 10 therethrough can be performed.

The positioning elements shown in FIGS . 1-6 are preferably made of a material that changes little in a pasty state during a welding process. Preferably, at least the positioning head of the positioning element consists of a material that preferably gasifies completely during a welding process.

Reference list

1

Fastening unit

2nd

Through hole

3rd

,

4th

Face

5

collar

6

Positioning element

7

Positioning head

8th

shaft

9

attack

10th

drilling

11

coat

12th

axis

13

edge

14

Holding section

15

Face

16

Component

17th

surface

18th

bead

19th

Central channel

20th

Secondary channel

21

chamber

22

Positioning element

23

section

24th

surface

25th

Positioning element

26

section

27

Positioning element

28

Groove

29

Positioning head

30th

,

31

wall

32

Positioning element

Claims (20)

1. Method for forming a welding connection between a fastening unit ( 1 ), in particular a welding nut, and a component ( 16 ) with a bore ( 10 ), in which the fastening unit ( 1 ),
the one through hole ( 2 ), which penetrates a first and a second end face ( 3 , 4 ) of the fastening unit ( 1 ), at least one of at least one end face ( 3 , 4 ) protruding, the through hole ( 2 ) at least partially surrounding, welding collar ( 5 ), and a positioning element ( 6 , 22 , 25 , 27 , 32 ) with a positioning head ( 7 , 29 ) which is detachably connected to the fastening unit ( 1 ), the welding collar ( 5 ) at least partially comprising the positioning element ( 6 , 22 , 25 , 27 , 32 ) and the positioning head ( 7 ) protrudes at least partially above the welding collar ( 5 ),
is fed to a mouthpiece of a welding device, the welding device with the fastening unit ( 1 ) is positioned on the component ( 16 ) and a welding process is carried out when the positioning head ( 7 ) projects partially into the bore ( 10 ). 2. The method according to claim 1, in which during the welding operation on the positioning element ( 6 , 22 , 25 , 27 , 32 ) a force directed in the direction of the drilling ( 10 ) is exerted, so that the positioning element ( 6 , 22 , 25 , 27 , 32 ) is driven through the bore ( 10 ). 3. The method according to claim 1, in which after the welding operation on the positioning element ( 6 , 22 , 25 , 27 , 32 ) a force directed in the direction of the drilling ( 10 ) is exerted, so that the positioning element ( 6 , 22 , 25 , 27 , 32 ) is driven through the bore ( 10 ). 4. The method according to claim 1, 2 or 3, in which during the welding process at least the positioning head ( 7 , 29 ) is at least transferred into a pasty state. 5. The method according to claim 4, wherein at least the positioning head ( 7 , 29 ) melts during the welding process. 6. The method according to claim 4, wherein at least the positioning head ( 7 , 29 ) gasifies during the welding process. 7. Fastening unit for welding connection with a component ( 16 ), in particular weld nut, with a through hole ( 2 ) which penetrates a first and a second end face ( 3 , 4 ), and with at least one of at least one end face ( 3 , 4 ) projecting welding collar ( 5 ) at least partially surrounding the through bore ( 2 ), characterized by a positioning element ( 6 , 22 , 25 , 27 , 32 ) detachably connected to the fastening unit ( 1 ) and having a positioning head ( 7 , 29 ) , wherein the welding collar ( 5 ) at least partially surrounds the positioning element ( 6 , 22 , 25 , 27 , 32 ) and the positioning head ( 7 , 29 ) at least partially protrudes beyond the welding collar ( 5 ). That the positioning head (7, 29) is connected to a shaft (8), which has 8. The fastening unit according to claim 7, characterized in a the through-bore (2) extending into the holding portion (14). 9. Fastening unit according to claim 7 or 8, characterized in that the collar ( 5 ) is formed at a radial distance from the through bore ( 2 ) and the shaft ( 8 ) has a stop ( 9 ) on an end face ( 4 ) of the fastening unit ( 1 ) is present. 10. Fastening unit according to claim 9, characterized in that the stop ( 9 ) is circumferential. 11. Fastening unit according to claim 9 or 10, characterized in that the stop ( 9 ) is formed by a bead ( 18 ). 12. Fixing unit according to claim 9 or 10, characterized in that the shaft (8) has at least one lying between the positioning head (7, 29) and the holding section (14) portion (23) whose cross-sectional area is greater than the cross-sectional area of the retaining section ( 14 ), the holding section ( 14 ) and the section ( 23 ) being essentially coaxial to one another and a surface ( 24 ) between the holding section ( 14 ) and the section ( 23 ) forming the stop ( 9 ). 13. Fastening unit according to one of claims 7 to 12, characterized in that the positioning head ( 7 , 29 ), preferably ko African, tapers away from the shaft ( 8 ). 14. Fastening unit according to claim 13, characterized in that the positioning head ( 7 , 29 ) is conical, in particular frustoconical. 15. Fastening unit according to one of claims 7 to 14, wherein the fastening unit ( 1 ) has a chamber ( 21 ) which is partially limited by a collar ( 5 ) which is formed with a radial distance from the through hole ( 2 ) and circumferentially in the circumferential direction , characterized in that the positioning element ( 6 , 22 , 25 , 27 , 32 ) has at least one channel ( 19 , 20 ) which connects the chamber ( 21 ) with an ambient atmosphere. 16. Fastening unit according to claim 15, characterized in that the channel is formed by a groove ( 28 ) in a lateral surface ( 11 ) of the positioning head ( 7 ). 17. Fastening unit according to claim 16, characterized in that the positioning head ( 7 ) has a plurality of grooves ( 28 ) which, viewed in the circumferential direction, are designed to be equidistant from one another. 18. Fastening unit according to claim 15, characterized in that the channel is formed by a central channel ( 19 ) extending in the axial direction and at least one secondary channel ( 20 ) extending in the radial direction, the secondary channel ( 20 ) in the chamber ( 21 ) flows out. 19. Fastening unit according to one of claims 7 to 18, characterized in that the shaft ( 8 ) tapers towards the positioning head ( 7 ), preferably the section ( 26 ) tapers towards the positioning head ( 7 ). 20. Fastening unit according to one of claims 7 to 19, characterized in that at least the positioning head ( 7 , 29 ) of the positioning element ( 6 ) consists of a material which passes during a welding process at least into a pasty state.