DE3233868A1 - Clamping device for hollow workpieces - Google Patents

Abstract

In a clamping device for hollow workpieces with an outer collet, it is proposed that an inner collet be provided inside the outer collet, which inner collet is intended for acting on an inner surface of the workpiece, and that a common actuating element be allocated to the two collets, which actuating element is movable in the axial direction and acts on a constriction sleeve for the outer collet as well as an expanding arbor for the inner collet, flexible transmission means being provided between the actuating element and one of the parts, constriction sleeve - expanding arbor.

Description

Clamping device for hollow workpieces

The invention relates to a clamping device for hollow workpieces according to the preamble of claim 1.

Such clamping devices are in the most varied of designs well-known, for example in lathes and milling machines.

The known clamping devices are also suitable for hollow workpieces can be used as long as the wall thickness of these workpieces is sufficiently large to accommodate the occurring when clamping the clamping fingers to fix the respective workpiece to endure necessary forces without significant deformation.

It becomes more difficult when the hollow workpieces to be machined are in their Wall thickness will be so small that the clamping finger is subject to the necessary clamping forces a deformation occurs which hinders proper machining.

This can be the case in particular when machining workpieces made of plastic and other sensitive or elastically deformable workpieces appear. Particularly critical table, the clamping problem also becomes such workpieces that are slotted one or more times and therefore due to their macroscopic structure are elastically deformable.

In the case of machining such workpieces, one has hitherto frequently so that one has inserted a filler piece into the respective workpiece and then clamped the workpiece from the outside with the collet. This method has two disadvantages. First of all, that you need a filler piece, which is difficult can be inserted automatically and therefore manually inserted into the workpiece and must be removed again after processing. This leads to Most of the processing cannot be automated. Another disadvantage is to see that the filler pieces are normally always the same size while the workpieces differ slightly due to the tolerance. It follows that the filler piece once too loose and once too tight. A filler piece that is too loose can to move; In addition, the workpiece can be damaged when the outer pliers are tightened deformed in diameter despite the filler piece, which is due to the machining Can have repercussions. If the filler piece is too large, there is a risk that when inserting the filler piece, the hollow workpiece is already deformed and possibly the removal of the filler piece from the hollow workpiece makes difficulties.

The invention is based on the object of a clamping device of the type described with regard to hollow workpieces so that Adequate clamping force on the workpiece while avoiding filler pieces without the risk of deformation of the same can be exercised when the workpiece very thin-walled or easily deformable or prone to breakage for other reasons is.

Tolerance-related diameter variations of the Workpiece To be taken into account. Furthermore, the clamping process should be simplified and, if necessary, automated be.

Finally, the jig should be simple and simple in structure the manufacturing costs must be economically viable.

To solve this problem, the features a) to d) proposed according to the characterizing part of claim 1.

In the clamping device according to the invention, the inner ones fit and the outer collets inevitably to the respective inner or outer diameter The use of a special filler piece within the expected tolerances is avoided. The handling during installation and removal of the workpiece from the Jig is simple. A single mechanical, hydraulic or electric actuatable actuator is sufficient to the outer and the inner collet to bring into effect, so that thereby the structure of the clamping device as a whole becomes relatively simple and the opening and closing of the collets is carried out easily can be.

The measure of claim 2 prevents the clamping device according to claim 1, the first gripping clamping fingers against the action of the resilient transmission means are pushed back again when the clamping f ## er take effect, and via the deformable workpiece to the S% # i # inrinqer that will grip first act.

For reasons of a simple structure, the measure is recommended claim 3.

In principle, it is possible to attach the outer collet to any Position within the clamping device. place. For reasons However, the measure of claim 4 is recommended for stability. The same stability consideration also applies to the inner collet, which is why the measure of claim 5 is proposed will. The support of the inner collet in the area of axial proximity to the workpiece engagement surfaces but now creates difficulties because the inner collet is separated from the outer collet is surrounded, and therefore the support means for the inner collet the outer Have to enforce the collet.

In order to remedy this problem, the measure of claim 6 is proposed.

In principle, it is conceivable that the inner clamping fingers and the the outer clamping fingers are in a gap in the circumferential direction. In such an embodiment but there is still the risk of undesired deformation of the workpiece. It is therefore preferred to proceed according to claim 7. When proceeding according to claim 7 is, the arrangement of the radial support arms according to claim 6 can approximately after Proposal contained in claim 8 are carried out.

The measure of claim 9 is recommended with regard to a simple one Adjustment of the clamping device to match the respective workpiece or the respective workpiece series.

The accompanying figures explain the invention on the basis of exemplary embodiments. The figures show: FIG. 1 a first exemplary embodiment of a clamping device according to the invention in longitudinal section; 2 shows the outer and inner collets of the clamping device of Fig. 1 in an exploded view; and 3 shows a further embodiment a clamping device according to the invention, wherein in the upper half of Fig. 3 shows a first embodiment of the clamping finger engaging jaws and in the lower half a second embodiment of the clamping finger engagement jaws is shown.

In Fig. 1, the clamping device according to the invention is part of a Rotary spindle 10. The rotary spindle 10 has a central channel 12. In this central channel 12 a constriction sleeve 14 is received adjacent to its inner circumferential surface, which are axially displaceable along the central channel but with respect to the rotating spindle 10 cannot be rotated. Within the constriction sleeve 14 there is an outer one Collet 16. This outer collet 16 is formed by an outer collet tube 16a (see also FIG. 2) on which outer clamping fingers are located to the right in the axial direction Connect 16b (see also Fig. 2).

The outer clamping fingers 16b are through axial slots in the outer Collet tube 16a is formed, as can be seen from FIG. On the outer collet fingers 16b are workpiece engagement surfaces directed radially inward at their right ends 16c arranged. In the area of these workpiece engagement surfaces 16c, the outer Clamping fingers 16b radially outwardly directed annular lugs 16d. These ring lugs 16d lie in the axial direction on the radially inwardly directed flange of a union nut 18 at.

The union nut 18 is screwed to a spindle attachment 20, which is fastened to the rotating spindle 10 by bolts 22. This is the collet 16 according to FIG. 1 set in the axial direction to the right. Furthermore, the outer ones Clamping fingers 16b within the union nut 18 in their radial mobility restricted.

Between the end of the collet chuck 16 on the left in the figure and a radial one inwardly facing collar 14a of the narrowing sleeve 14 is a Helical compression spring 24 is arranged, which engages the collet 16 to the right with the radially inwardly directed flange of the union nut 18 holds and the constriction sleeve 14 seeks to push back to the left opposite the collet 16.

Outer constriction cones 16e are arranged on the clamping fingers 16b, which an inner constriction cone 14b of the constriction sleeve 14 faces. At the collar 14a of the constriction sleeve 14 rests on a plate 26 on which in turn a in the channel 12 guided actuating element 28 of a mechanical hydraulic or electrical or pneumatic clamping device is applied. This actuator 28 can be displaced in the direction of double arrow 30 and is under mediation of the plate 26 constantly to the collar 14a, so that the helical compression spring 24 constantly is under a certain bias and the annular lugs 16d constantly on the flange the union nut 18 rest.

When the drive element 28 is advanced to the right in FIG. 1, so the constriction sleeve 14 looks over the inner constriction cone 14b and the outer ones Narrowing cones 16e to move the outer clamping fingers 16b radially inward, so that these rest against a hollow workpiece 32 and clamp it, as shown in Fig. 1 shown.

Radially inside the outer collet tube 16 is an expanding mandrel 34 added. This expanding mandrel 34 comprises an expanding mandrel guide pin 34a, which is guided axially displaceably within the outer collet tube 16a. An expanding mandrel extension is located in an inner threaded bore of the expanding mandrel guide pin 34a 34b, which can be screwed axially and is therefore adjustable, which at its in Fig. 1 right end carries an expanding head 34c. On the expanding mandrel guide pin 34a is an inner collet 36 with an inner collet tube 36a guided axially displaceably. The inner collet 36 is shown in detail in the lower one Half of Fig. 2 shown. Through slots in the inner collet tube 36a webs 36b and inner clamping fingers 36c are formed alternately in the circumferential direction.

On the webs 36b there are radially directed support arms projecting in a star shape 36d arranged, which the slots of the outer collet 16 between the outer Clamping fingers 16b penetrate and between the right-hand end of the spindle attachment in FIG. 1 20 and the radially inwardly directed flange of the union nut 18 clamped are.

As a result, the inner collet 36 is in the axial direction of the rotary spindle 10 set.

On the inner clamping fingers 36c, as can be seen from FIG. 1, Workpiece engagement surfaces 36e arranged, which on the radially inner circumferential surface of the hollow workpiece 32 come to rest. At the expansion head 34c is a radial The outer expansion cone 34d is molded on, the inner expansion cone 36f with the radially inner expansion cone Clamping finger 36c comes into engagement.

If the expanding mandrel 34 is advanced to the right in FIG. 1, so the clamping fingers 36c are spread radially outward so that the workpiece engagement surfaces Place 36e on the inside of workpiece 32.

Between a shoulder surface 34e of the expanding mandrel guide pin 34a and the plate 26 a plate spring assembly 38 is clamped through the mediation of a screwed to the expanding mandrel guide pin 34a, resting on the plate 26 Mother 40.

In Fig. 1, the actuating element 28 is in its right End position, so that the workpiece 32 of the outer collets 16b and of the inner collets 36c is beat and between these is clamped. The workpiece engagement surfaces 16c of the outer Clamping fingers 16b and the workpiece engaging surfaces 36e of the inner clamping fingers 36c in the radial direction # opposite.

When the actuating element 28 is retracted to the left in FIG. 1 the outer clamping fingers and the inner clamping fingers are released from the Workpiece 32.

The following is now the one for understanding the subject of the application essential process when re-clamping a workpiece 32 is described: If the actuator 28 moves forward to the right, so it takes over the plate 26 and the disk spring assembly 38 with the expanding mandrel 34. The clamping fingers 36c expanded by the interaction of the expansion cones 34d and 36f. The clamping fingers 36c come into engagement with the workpiece 32 with their workpiece engagement surfaces 36e before the outer clamping fingers 16b with their workpiece engagement surfaces 16c on the Workpiece 32 come to rest.

If, after the work piece engagement surfaces 36e have come into contact with Workpiece 32 the actuating element 28 is advanced further to the right, comes the radial outward movement of the inner clamping fingers 36 through the workpiece 32 to the Standstill and therefore the expanding mandrel 34 can no longer be moved further to the right will. The further movement of the actuating element 28 to the right therefore leads to a compression of the disk spring assembly 38. The force with which the work piece engagement surfaces 36e on the workpiece 32 depends on the spring stiffness and, if applicable, the preload of the disc spring assembly 38. This bias is adjusted so that the workpiece 32 not excessively deformed or by the spreading of the inner clamping fingers 36c can even be damaged. The forward stroke of the constriction sleeve 14 to the right begins also with the forward stroke of the actuating element ments 28. By However, appropriate dimensioning ensures that the inner constriction cone 14b only then in constricting interaction with the outer constriction cones 16e of the outer clamping finger 16b occurs after the workpiece engaging surfaces 36e of the clamping fingers 36c have already come into engagement with the workpiece 32.

After the expanding mandrel 34 has come to a standstill, it moves the constriction sleeve 14 with compression of the plate springs 38 and the helical compression spring 24 further to the right, so that now with the mediation of the narrowing cones 14b and 16e also the work piece engagement surfaces 16c of the outer tension spring 16b for engagement get with the workpiece 32 and this so between the inner and outer Clamping fingers is clamped centering.

The stroke of the actuating element 28 to the right is dimensioned in such a way that that the correct clamping force is exerted on the workpiece 32.

The expansion cones 34d and 36f are designed to be self-locking.

That is to say that when the outer clamping fingers take effect 16b on the workpiece 32, the inner clamping fingers 36c are not pushed back radially inward can be while yielding the expanding mandrel 34 to the left against the action of the Disk spring assembly 38. If there is self-locking between the Spreizkoni 34d and 36f is spoken, it is meant to say that taking into account the Spring tension in the disk spring assembly 38 occurs a self-locking. So it is not absolutely necessary that the inclination of the Spreizkoni 34d and 36f also with Failure to consider the disk spring assembly 38 leads to self-locking.

Around the early start of the expanding action of the expanding mandrel 34 to be able to adjust the advance of the actuating element 28 to the right and also To be able to set the correct extent of the expansion effect is the expansion mandrel extension 34d by screwing against the expanding mandrel guide pin 34a adjustable. For this purpose, the expanding mandrel extension is on the expanding head 34c and on the left end 34b each has a screwdriver engagement slot 34f or 34g.

When the actuator 28 goes back to the left, so the Constriction sleeve 14 pushed back by the helical compression spring 24 to the left and the plate 26 taken along, the plate spring assembly 38 also being relaxed.

After the plate 26 comes to rest on the nut 40 again is, the expanding mandrel 34 is also withdrawn to the left by the plate 26.

Regarding the stability of the internal structure, it should be pointed out that The one # unqshülse 14 is guided at its right end inside the spindle attachment 20 is and via the narrowing cones 14b, 16e the clamping fingers 16b in their radial mobility limited. It should also be noted that the inner collet tube 36a via the webs 36b and the support arms 36d both axially and radially Direction is fixed on the rotary spindle 10, so that the inner clamping fingers 36c are limited in their radial mobility.

In the embodiment of FIG. 3, analog parts are identical Reference numerals are provided, as in the embodiment according to FIG. 1, in each case increased at 100.

The following differences compared to the embodiment according to FIG. 3 are determine: The inner collet 136 and the outer collet 116 are in the range their left ends by a grooved pin 142 together against axial displacement and relative rotation connected. Since the outer collet 116 on the union nut 118 is set in the axial direction is so also the inner one Collet 136 set in the axial direction. On the support arms provided in FIG 36d, which penetrate the outer collet 16 there, is omitted here. These Embodiment is intended in particular for larger formats for which a sufficient Stability is also possible without the support arms 36d.

The expanding mandrel extension 134b is on in this embodiment provided with a square head at its left end.

The disk spring assembly 38 is replaced by a helical compression spring 138.

Engaging jaws are located on the right-hand ends of the outer clamping fingers 116b in FIG. 3 exchangeably attached, which have the workpiece engagement surfaces 116c. At the ends of the inner clamping fingers 136c on the right in the figure are interchangeable Workpiece engaging jaws attached, which the workpiece engaging surfaces 136e and the expansion cones 136f have.

In the lower half of Fig. 3 it is indicated that different Forms of workpiece engaging jaws attached for different workpiece dimensions can be.

Otherwise, the embodiment of FIG. 3 corresponds with respect to Structure and mode of operation of the embodiment of FIG. 1, so that on the description according to FIG. 1 can be referred to.

In the embodiment according to FIG. 3, there is a stroke limiting shoulder for the plate 126 112a provided.

Claims (9)

Clamping device for hollow workpieces Claims (\ c \: clamping device for hollow workpieces, especially for fixing the workpieces on a turning spindle a machine tool or the like, comprising an outer collet having a plurality of outer clamping fingers distributed in the circumferential direction for contact with an outer one Peripheral surface of the workpiece and a span in the direction for pressing the outer Clamping fingers on the outer peripheral surface of the workpiece, characterized by the Combination of the following features: a) inside the outer collet (16) is one inner collet chuck (36) with a plurality of inner ones distributed in the circumferential direction Clamping fingers (36c) arranged to bear against an inner peripheral surface of the workpiece (32); b) the clamping device for the outer collet (16) comprises the outer one The constriction sleeve (14) which surrounds the collet and is displaceable in the axial direction cooperates with the outer collets (16b) in the manner of a clamping cone (14b, 16e); c) inside the inner collet (36) is an axially displaceable expanding mandrel (34) arranged, which with the inner clamping fingers (36c) in the manner of an expanding cone (34d, 36f) cooperates; d) for the axial displacement of the constriction sleeve (14) and the expanding mandrel (34) is a common, axially displaceable actuating element (28) is provided, which on one (14) of the parts Einenaunashülse (14) and expanding mandrel (34) directly or through an essentially rigid chain of transmission media (26, 14a) acts, and on the other (34) of the parts constriction sleeve (14) and expanding mandrel (34) acts via resilient transmission means (38) so that this other part (34) after installation of the clamping fingers (36c) assigned to it, which first become effective the respective circumferential surface of the workpiece (32) with a predetermined force to a standstill comes, while the one part (14) against the action of the resilient transmission means (38) can still be moved further, for the purpose of pressing down on the one assigned to it later effective clamping finger (16d) to the associated peripheral surface of the workpiece (32). 2. Clamping device according to claim 1, characterized in that the clamping cone or expansion cone (34d, 36f) of the other part (34) is self-locking in this way is designed that he by the action of force on his associated clamping fingers (36c) cannot be reset against the action of the resilient transmission means (38) is, the tension in the resilient transmission means (38) if necessary to achieve contributes to this self-locking. 3. Clamping device according to one of claims 1 and 2, characterized in that that the resilient transmission means between the expanding mandrel (34) and the actuating element (28) are provided. 4. Clamping device according to one of claims 1 to 3, characterized in that that in axial proximity to the workpiece engagement surfaces (16c) of the outer clamping fingers (16b) the outer collet (16) is supported on at least one side in the axial direction is and / or is limited in its radial mobility. 5. Clamping device according to one of claims 1 to 4, characterized in that that in axial proximity to the workpiece engagement surfaces (36e) of the radially inner clamping fingers (36c) the inner collet (36) fixed at least on one side in the axial direction is and / or is limited in its radial mobility. 6. Clamping device according to claim 5, characterized in that the radially inner collet (36) is provided with radially directed support arms (36d) which reach through between successive outer clamping fingers (n6b). 7. Clamping device according to one of claims 1 to 6, characterized in that that in each case a radially inner clamping finger (36c) in radial alignment with a radial outer clamping finger (16b) lies. 8. Clamping device according to claim 7 in conjunction with claim 6, characterized in that the radial support arms (36d) on the inner collet (36) carried by intermediate webs (36b) between successive clamping fingers (36c) are. 9. Clamping device according to one of claims 1 to 8, characterized in that that the beginning and / or the extent of the narrowing or spreading effect is adjustable are.