DEVICE FOR SETTING A SETTING ELEMENT IN A COMPONENT

Abstract

The invention relates to a device for setting a setting element having a first plastic material in a component having a second plastic material, comprising a rotational advancing unit, by means of which the setting element can be rotated about an axis of rotation and simultaneously an axial force acting in the direction of the axis of rotation can be applied to the setting element in order to drive the setting element into the component, a friction welding joint thereby being produced between the setting element and the component, a differential-distance measuring apparatus for measuring the differential distance between a surface of the component and a surface of the driven setting element, and a control unit for controlling the rotational advancing unit in dependence on the measured differential distance.

Claims

1-16. (canceled)

17. An apparatus for setting a setting element comprising a first plastic material in a component comprising a second plastic material, the apparatus comprising a rotary feed unit by which the setting element can be set into rotation about an axis of rotation and simultaneously an axial force acting in the direction of the axis of rotation can be exerted onto the setting element to drive the setting element into the component while producing a friction welding connection between the setting element and the component; a differential distance measuring device for measuring the differential distance between a surface of the component and a surface of the driven setting element; and a control unit for controlling the rotary feed unit in dependence on the measured differential distance.

18. The apparatus in accordance with claim 17, wherein the differential distance measuring device is arranged adjacent to the axis of rotation.

19. The apparatus in accordance with claim 17, wherein the control unit is adapted so that it controls the rotary feed unit such that, on reaching a maximum predefined differential distance, the setting element is rotated before the end of the setting procedure over a predetermined period of time with an axial force and/or feed speed reduced to at least approximately zero.

20. The apparatus in accordance with claim 17, further comprising a force measuring device for measuring the axial force exerted onto the setting element.

21. The apparatus in accordance with claim 20, wherein the rotary feed unit can be regulated by the control unit, with an axial force exerted onto the setting element; a torque exerted on the setting element; a number of revolutions of the setting element per time; and/or an absolute number of revolutions of the setting element as a control variable.

22. The apparatus in accordance with claim 17, wherein the control unit is adapted such that it divides a setting procedure into a plurality of stages and regulates the rotary feed unit in at least two stages with different control variables.

23. The apparatus in accordance with claim 17, wherein the rotary feed unit has an electric motor feed drive.

24. The apparatus in accordance with claim 17, wherein the rotary feed unit has an electric motor rotary drive.

25. The apparatus in accordance with claim 17, further comprising supply means for the automatic supply of setting elements from a setting element store.

26. The apparatus in accordance with claim 25, wherein the supply means comprises one of a pneumatic supply device, a pick & place system and a magazine containing a number of setting elements.

27. The apparatus in accordance with claim 26, wherein, if the supply means comprises the magazine, then the magazine is an exchangeable magazine containing a number of setting elements.

28. A method of setting a setting element comprising a first plastic material in a component comprising a second plastic material, in which method the setting element is set into rotation by means of a rotary feed unit and is acted on by an axial force to drive the setting element into the component while producing a friction welding connection between the setting element and the component; a differential distance between a surface of the component and a surface of the driven setting element is measured by means of a differential distance measuring device; and the rotary feed unit is controlled by means of a control unit in dependence on the measured differential distance.

29. The method in accordance with claim 28, wherein the axial force and/or a feed speed is/are reduced to at least approximately zero on reaching a predefined maximum differential distance, while the rotation of the setting element is maintained for a predetermined time period.

30. The method in accordance with claim 28, wherein the component is provided with a top layer having a prepunched hole and the setting element is set into the prepunched hole such that it melts behind the top layer and forms an undercut.

31. The method in accordance with claim 30, wherein the top layer is formed from one of a plastic material and a non-plastic material.

32. The method in accordance with claim 31, wherein, if the top layer is formed from a non-plastic material, then this is one of wood, glass and metal.

33. The method in accordance with claim 28, wherein the plastic material of the component is fiber-reinforced and/or forms a honeycomb structure and/or has a foam material.

34. The method in accordance with claim 28, wherein the plastic material of the setting element has a higher melting point than the plastic material of the component.

Description

[0028] A friction welding apparatus 10 is shown in FIG. 1 which serves for the setting of a setting element 12 comprising a first plastic material in a component 14 comprising a second plastic material, as will be explained in more detail with reference to FIGS. 2 to 4.

[0029] The apparatus 10 comprises a carrier plate 16 which is installed as stationary in the present embodiment and has a guide rail 18 which extends in an axial direction and at which a rotary feed unit 20 is supported displaceably in the axial direction. An electric motor feed drive 22 is provided for displacing the rotary feed carrier plate 16 and drives the rotary feed unit 20 via a feed spindle 24. The axial force with which the feed drive 22 moves the rotary feed unit 20 forward is measured with the aid of a force measuring device, not shown, which is integrated in the rotary feed unit 20. The measured axial force is evaluated in a control unit, not shown, of the apparatus 10.

[0030] The rotary feed unit 20 furthermore has an electric motor rotary drive 26 by means of which a tool mount 28, and thereby a tool 29 for the setting element 12 received therein (FIGS. 2 to 4), can be rotatingly driven about an axis of rotation 31 extending in the axial direction. The torque applied during a setting process can be derived from the current pick-up of the rotary drive 26. This can likewise be evaluated in the control unit.

[0031] A differential distance measuring device 30 is furthermore laterally attached to the rotary feed unit 20 and comprises a sensing hoop 32 which projects over the tool mount 28 viewed in the axial direction in a position of rest shown in FIG. 1. The sensing hoop 32 is curved in the direction of the axis of rotation 31 such that a front end 34 of the sensing hoop has a spacing of approximately 2 cm from the axis of rotation 31. A rear end 36 of the sensing hoop 32 is connected to a guide rod 38 supported displaceably in the axial direction at the rotary feed unit 20. The guide rod 38 is coupled in a section remote from the sensing hoop 32 to a return spring, here in the form of a helical spring 40 surrounding the guide rod 38, against whose return force the sensing hoop 32 is supported at the component 14 can deflect when setting the setting element 12 into the component 14.

[0032] A contactlessly readable scale, which is not shown in any more detail, is provided at the guide rod 38, e.g. in the form of a marked magnetic strip which, on the deflection of the sensing hoop 32, moves past a distance sensor 41 installed in a stationary manner relative to the guide rod 38 and suitable for reading the scale to feed unit 20 and the sensing hoop 32, i.e. that is ultimately to display the penetration depth of the setting element 12 in the component 14.

[0033] The tool 29 received in the tool mount 28 is stocked with a setting element 12 for a setting procedure. This can generally take place manually. However, a supply device, e.g. a pneumatic supply device, (not shown) is preferably provided for this purpose which shoots the setting element 12 fully automatically into a supply head, likewise not shown, of the apparatus 10 in which the setting element 12 is brought into engagement with the tool 29. Instead of a pneumatic supply device, a pick & place system or a magazine solution is also conceivable for the supply of setting elements 12.

[0034] As FIG. 2 shows, the setting element 12 has a rotationally symmetrical design about a longitudinal center axis 42. It comprises a conical base body 44 at whose head end a collar 46 radially projects in whose lower side a peripheral recess 48 is sunk. An engagement feature 50 for the tool 29, for example a hexagonal hole, is provided at the upper side of the setting element 12.

[0035] The setting element 12 is produced, e.g. by means of an injection molding process, in one piece from a plastic material which has a higher melting point than the plastic material of the component 14 into which the setting element 12 is to be set. The component 14 shown in FIG. 2 comprises a honeycomb structure 52 from plastic or from a paper-like material which is provided with a top layer 54 of plastic, e.g. of fiber-reinforced plastic.

[0036] To set the setting element 12 into the component 14, the setting element 12 in engagement with the tool 29 is pushed forward by the feed drive 22 until it contacts the component 14. The sensing hoop 32, which is likewise supported at the component 14, has already been deflected by a certain distance in this situation and in this position defines a zero point for the differential distance measurement.

[0037] The setting element 12 is set into rotation by the rotary drive 26 of the rotary feed unit 20 and is brought to a rotational speed required for the friction welding process. As soon as this has been reached, the setting element 12 is driven by the feed drive 22 into the component 14 while applying a desired axial force, with the jacket surface 55 of the base body 44 of the setting element 12 and the adjacent material of the component 14 melting and entering into a connection with material continuity.

[0038] The penetration depth of the setting element 12 in the component 14 is measured by means of the differential distance measuring device 30 during the feed of the rotary feed unit 20. As soon as the setting element 12 has penetrated so deeply into the component 14 that the lower side of the collar 46 comes into contact with the surface of the component 14, the axial force applied to the setting element 12 and/or the feed speed is reduced to zero by stopping the feed drive 22, whereas the rotation of the setting element 12 can still be maintained for a specific time period so that the recess 48 at the lower side of the collar 46 of the setting element 12 can be filled with melted plastic material, but no melted plastic material moves outwardly beyond the collar 46. To end the setting process, the rotary drive 26 is stopped and the tool 29 is released by moving the rotary feed unit 20 back from the setting element 12 and the melted material can cool down. Optionally, a waiting time has to be worked through after the stopping of the rotary drive 26.

[0039] An alternative application is shown in FIG. 3 in which a setting element 12 of the above-described type is set into a component 14 which comprises a honeycomb structure 52 of plastic or of a paper-like material and a top layer 54 thereon of a metal material. The top layer 54 is provided with a round prepunched hole 56 so that the setting element 12 can penetrate through it. Alternatively, the prepunched hole 56 can also be non-round, e.g. angled, whereby the set setting element 12 can later receive a higher rotating element, e.g. when a screw is screwed into the setting element 12.

[0040] For the setting procedure, the setting element 12 is aligned with the prepunched hole 56 and is driven as described with reference to FIG. 2 into the honeycomb structure 52 of the component 14. With a suitable control of the axial force exerted onto the setting element 12 and of the speed of the setting element 12, the setting procedure can be continued such that the setting element 12 widens below the top layer 54 and in this manner forms an undercut 58 which provides a shape-matched connection of the setting element 12 to the top layer 14 in addition to the connection of the setting element 12 with material continuity with the honeycomb structure 52.

[0041] An application example is shown in FIG. 4 in which a setting element 12 of the above-described kind is used for joining two components 14a, 14b. Each component 14a, 14b comprises a plastic material whose melting point is lower than that of the setting element 12. The components 14a, 14b are placed over one another for the joining procedure and the setting element 12 is driven through the upper component 14a in the already described manner into the lower component 14b so that it at least enters into a connection with material continuity with the lower component 14b. The upper component 14a can be provided with a prepunched hole to achieve only a clamping effect with respect to the lower component 14b.

[0042] The penetration depth of the setting element 12 is also monitored exactly by the differential distance measuring device 30 here and the axial force exerted onto the setting element 12 on the reaching of the desired penetration depth, namely when the lower side of the collar 46 of the setting element 12 comes into contact with the surface of the upper component 14a, is reduced to zero by stopping the feed drive 22, while the setting element 12 is still rotated further for a specific time period.

[0043] It must finally be noted that the apparatus 10, in contrast to what is shown in FIG. 1, does not necessarily have to be mounted in a stationary manner. It is by all means conceivable also to install the apparatus 10 in a movable manner, for example in a multiaxial machining station or at a robot arm. It is of advantage in this respect that much lower axial forces are sufficient for the setting of plastic setting elements 12 in plastic components 14 than in the friction welding of metal components so that the setting processes carried out with the apparatus 10 can generally be carried out without a counter-bearing of the component 14 with a sufficient stiffness of the component 14.

REFERENCE NUMERAL LIST

[0044] 10 apparatus [0045] 12 setting element [0046] 14 component [0047] 16 support plate [0048] 18 guide rail [0049] 20 rotary feed unit [0050] 22 feed unit [0051] 24 feed spindle [0052] 26 rotary drive [0053] 28 tool mount [0054] 29 tool [0055] 30 differential distance measuring device [0056] 31 axis of rotation [0057] 32 sensing hoop [0058] 34 front end [0059] 36 rear end [0060] 38 guide rod [0061] 40 helical compression spring [0062] 41 distance sensor [0063] 42 longitudinal central axis [0064] 44 base body [0065] 46 collar [0066] 48 recess [0067] 50 engagement feature [0068] 52 honeycomb structure [0069] 54 top layer [0070] 55 jacket surface [0071] 56 prepunched hole [0072] 58 undercut