DEVICE AND METHOD FOR CLAMPING WORKPIECES

Abstract

An embossing device that serves for preparation of a combined form-fit and friction-fit clamping of a workpiece in a respective clamping chuck. The embossing device includes jaws having embossing teeth that are formed on insertion bodies. The insertion bodies include a penetration edge respectively with which they penetrate into the workpiece surface in order to create a depression with defined dimensions. For this a workpiece contact surface is formed on the insertion body, preferably in the proximity to the bar-like projection that stops the penetration process of the bar-like projection as soon as the workpiece contact surface gets in contact with the workpiece surface during the execution of the embossing process. Then the force required for movement of the jaw increases considerably from which a control device generates a switch-off signal for the operation device.

Claims

1. A method for clamping of workpieces, comprising: inserting and fastening at least one insertion body in at least one seat, wherein the at least one seat is provided in at least one jaw, positioning a workpiece between the at least one insertion body and a counter support, adjusting a distance between the at least one jaw and the counter support until the at least one insertion body contacts the workpiece at least one location, and further adjusting the distance between the at least one jaw and the counter support until the at least one insertion body has penetrated into the workpiece by a desired extent.

2. The method according to claim 1, wherein the at least one insertion body contacts the workpiece with an edge or with a corner.

3. The method according to claim 1, wherein the at least one jaw is moved in a force-limited or force-change-limited manner.

4. The method according to claim 1, wherein the workpiece is clamped in a clamping device by means of clamping jaws configured to match with depressions formed in the workpiece after the at least one insertion body has penetrated into the workpiece by a desired extent and has thus created the depressions in the workpiece via a local plastic deformation of the workpiece.

5. An embossing device for providing plastic deformations on a workpiece, comprising: a first jaw that comprises a seat for holding an insertion body; an insertion body that is arranged on the seat and fastened thereon; a second jaw that is a counter support opposed to the insertion body; and an operation device that is configured to move one of the first jaw and the second jaw toward and away from the other one of the first jaw and the second jaw.

6. The device according to claim 5, wherein the seat is formed by a polygonally surrounded pocket.

7. The device according to claim 5, wherein the seat is a plurality of seats and the insertion body is a plurality of insertion bodies, the plurality of seats holding the plurality of insertion bodies.

8. The device according to claim 5, wherein the counter support comprises one or more insertion bodies.

9. The device according to claim 5, wherein the insertion body comprises bar-like projections that are arranged as an embossing structure for engaging the workpiece.

10. The device according to claim 5, wherein the insertion body is a hard material body or a powder steel body.

11. The device according to claim 5, wherein the insertion body comprises a bar-like projection that extends along a lateral surface of the insertion body.

12. The device according to claim 11, wherein the first jaw or the second jaw comprises a workpiece support surface and the bar-like projection extends parallel to the workpiece support surface.

13. The device according to claim 11, wherein the bar-like projection has a triangular cross-section.

14. The device according to claim 11, wherein the bar-like projection is straight.

15. The device according to claim 11, wherein the bar-like projection adjoins a surface that is configured as a workpiece contact surface.

16. The device according to claim 6, wherein the seat is a plurality of seats and the insertion body is a plurality of insertion bodies, the plurality of seats holding the plurality of insertion bodies.

17. The device according to claim 16, wherein the counter support comprises one or more insertion bodies.

18. The device according to claim 17, wherein the plurality of insertion bodies and the one or more insertion bodies comprise bar-like projections that are arranged as an embossing structure for engaging the workpiece.

19. The device according to claim 18, wherein the plurality of insertion bodies and the one or more insertion bodies are a hard material body or a powder steel body.

20. The device according to claim 19, wherein the bar-like projections extend along a lateral surface of the plurality of insertion bodies and the one or more insertion bodies insertion body.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0017] FIG. 1 an embossing station for preparation of a workpiece for clamping in a suitable clamping chuck in a perspective schematic illustration,

[0018] FIG. 2 the embossing station of FIG. 1 in top view,

[0019] FIG. 3 the embossing station in a sectional perspective illustration,

[0020] FIG. 4 an insertion body in top view,

[0021] FIG. 5 the insertion body according to FIG. 4 in lateral view,

[0022] FIG. 6 a modified embodiment of an insertion body and a corresponding workpiece in schematic vertically sectioned illustration,

[0023] FIG. 7 a further modified embodiment of an embossing station in simplified vertically sectioned illustration.

DETAILED DESCRIPTION

[0024] FIG. 1 illustrates an embossing device 10 that serves to prepare a workpiece 11 for clamping in a clamping chuck that is configured for this purpose. The workpiece 11 is symbolized by a ring. However, workpieces 11 can also have different shapes, wherein they only correspond at least in sections to a cylinder in a lower zone 12 of their circumferential surface adjoining the base surface. The workpiece 11 can be subsequently held in a rotating chuck, e.g. in order to carry out lathe machining processes, rotational milling processes or the like.

[0025] Two jaws 13, 14 are part of the embossing device 10, wherein the distance of the jaws 13, 14 from each other can be adjusted in a controlled manner by means of an operation device 15.

[0026] As apparent from FIGS. 2 and 3, the two jaws comprise at their top side a workpiece support surface 16, 17 respectively that are preferably arranged in a common plane. The jaw 14 comprises at least one, preferably multiple seats 18 to 22 that can be configured, for example, as polygonally surrounded pockets. Also the jaw 13 comprises multiple seats 23 to 27 that are preferably configured as polygonally surrounded pockets that preferably correspond in shape and dimension with the seats 18 to 22. In at least one and preferably multiple of the seats 18 to 22; 23 to 27 of the two jaws 13, 14 insertion bodies 28, 29, 30, 31 are mounted and secured with a suitable fastening means, e.g. a screw, respectively. Thereby the insertion bodies 28 to 31 serve as embossing teeth or also as counter support for the respective opposed embossing tooth.

[0027] The insertion bodies 28 to 31 are also identically configured, just like the seats 18 to 27. The insertion body 28 illustrated in FIGS. 4 and 5 and its following description are thus representative for all of the used insertion for all of the insertion bodies 28 to 31 used in the embossing device 10.

[0028] The insertion body 28 comprises with view from the top a, for example, hexagonal scalene, however three times rotationally symmetric circumference. Bar-like projections 32 to 34 are formed on the three shorter edges of this hexagonal circumference that extend radially outward and form embossing teeth.

[0029] According to FIG. 5, below its hexagonal head the insertion body 28 comprises a polygonal, e.g. hexagonal, pole 35 that can also have a hexagonal circumference and fits with minor clearance in the seats 18 to 27. Preferably the hexagonal pole 35 comprises a scalene circumference having a triple rotational symmetry. In other words the pole 35 can be inserted in the respective pocket 19 in three positions that are respectively rotated about 120° relative to each other.

[0030] The bar-like projection 32 is identical with the bar-like projections 33, 34 and preferably comprises a wedge-shaped cross-section, as shown in FIG. 5, according to which two wedge surfaces 37, 38 adjoin the penetration edge 36. The penetration edge 36 is orientated in circumferential direction relative to the workpiece 11 and also relative to the insertion body 28 respectively. The rounding radius of the penetration edge 36 is preferably larger than zero, however in turn preferably smaller than one tenths of the length of the wedge surface 37 measured from the penetration edge 36 up to the adjoining workpiece contact surface 39. The wedge angle defined by the wedge surfaces 37, 38 comprises an angle bisector arranged in a plane 40 that comprises all penetration edges 36 of all bar-like projections 32 to 34 and is preferably orientated parallel to the workpiece support surface 17.

[0031] The wedge surface 38 transitions in a lateral surface of the insertion body 28 that is offset backward relative to the workpiece contact surface 39.

[0032] The insertion body 28 can consist of powder steel, a hard metal, ceramic or another hard material.

[0033] The embossing device 10 described so far operates as follows:

[0034] In preparation of the subsequent clamping of the workpiece 11 it is inserted in the embossing device 10. Therefore, the jaws 13, 14 are first moved away from one another by means of the operation device 15 so far that the workpiece 11 can be placed on the workpiece support surfaces 16, 17 without getting in contact with the insertion bodies 28 to 31, as illustrated in FIGS. 1 and 2. In the next step the operation device 15 is activated such that the jaws 13, 14 are moved toward each other, e.g. in that the movable jaw 14 is moved toward the immovable jaw 13. In doing so, the workpiece 11 gets into contact with the bar-like projections 32 (i.e. the embossing teeth) of the individual insertion bodies 28 to 31 and centers automatically therebetween such that all four insertion bodies 28 to 31 abut against the lower zone 12 of the circumferential surface of the workpiece 11 with their bar-like projections 32. Thereafter the bar-like projections 32 penetrate during continuous increase of the penetration force into the workpiece 11 until the penetration force increases abruptly, due to the contact between the workpiece contact surface 39 and the workpiece 11. With this process a uniform embossing depth is achieved independent from the material characteristic and the geometric characteristics of the workpiece 11, e.g. its spring characteristics. In this case the operation device 15 is configured such that the operating force is monitored during embossing and the operation device 15 is switched off and moves the jaws 13, 14 again away from each other in order to release the workpiece, if a threshold of the operating force or a threshold of the operating force change is exceeded.

[0035] The invention was explained above based on insertion bodies 28 to 31 specifically configured for the embossing process. It is, however, also possible to use other elements instead of the specifically formed insertion bodies 28, e.g. hard metal bodies as they are in use as indexable cutting inserts as insertion bodies 28′. An example for this is shown in FIG. 6 in which the cutting edge of the indexable cutting insert, that is used as embossing tooth, is used as penetration edge 36′.

[0036] It is also possible to support the insertion body 28′ on a surface or a seat 19 that is inclined relative to the workpiece support surface 16 in order to create a depression also with a standard component, such as for example an indexable insert, in use as insertion body 28′ that is symmetrically with reference to a horizontal plane (plane that is parallel to the workpiece support surface 16).

[0037] An inventive embossing device 10 is provided for preparation of a mixed form-fit and friction-fit clamping of workpieces 11 in a respective clamping chuck. The embossing device 10 comprises jaws 13, 14 with embossing teeth that are formed on insertion bodies 28 to 31. The insertion bodies 28 comprise a penetration edge 36 respectively with which they penetrate into the workpiece surface in order to create a depression with defined dimensions. For this a workpiece contact surface 39 is formed on the insertion body 28, preferably in proximity to the bar-like projection 32 that stops the penetration process of the bar-like projection as soon as the workpiece contact surface 39 gets in contact with the workpiece surface during the execution of the embossing process. If the workpiece contact surface 39 abuts against the workpiece 11, the force required for moving the jaw 14 increases considerably from which a control device generates a switch-off signal for the operation device 15.

[0038] Such a control or feedback control of the embossing process allows to prepare workpieces 11 having different geometries and consist of different materials in an embossing process for subsequent clamping without the requirement to readjust the embossing device 10 depending on the respective geometry or the respective material of the workpiece 11.

LIST OF REFERENCE SIGNS

[0039] 10 embossing device

[0040] 11 workpiece

[0041] 12 lower zone of circumferential surface

[0042] 13, 14 jaws

[0043] 15 operation device

[0044] 16, 17 workpiece support surface

[0045] 18-22 seat of jaw 14

[0046] 23-27 seat of jaw 13

[0047] 28-31 insertion body

[0048] 28′ insertion body

[0049] 32-34 bar-like projections

[0050] 35 pole

[0051] 36 penetration edge

[0052] 36′ penetration edge

[0053] 37, 38 wedge surfaces

[0054] 39 workpiece contact surface

[0055] 40 plane