CHANGING DEVICE FOR ROTARY INDEXING TABLES

Abstract

1. Changing device for rotary indexing tables.

2. A changing device for rotary indexing tables, having a stand component (12), which is used as a base component and through which a shaft (18) passes, which defines the axis of rotation of tables (2) rotatable by an electric motor and which has an interface (20) for coupling concerned tables (2), which can be fixed in predeterminable rotational positions relative to an respective assigned table unit (8) by means of a clamping device (60), wherein at least two table units (8), differing from each other at least with respect to their clamping devices (60), together with their assigned table (2) as exchange components can be fixed in an interchangeable manner on the base component for their operation.

Claims

1. A changing device for rotary indexing tables, having a stand component (12), which is used as a base component and through which a shaft (18) passes, which defines the axis of rotation of tables (2) rotatable by an electric motor and which has an interface (20) for coupling concerned tables (2), which can be fixed in predeterminable rotational positions relative to an respective assigned table unit (8) by means of a clamping device (60, 84), wherein at least two table units (8), differing from each other at least with respect to their clamping devices (60, 84), together with their assigned table (2) as exchange components can be fixed in an interchangeable manner on the base component for their operation.

2. The changing device according to claim 1, characterized in that at one free end of the shaft (18), and at least partially enclosed by the stand component (12), a rotary encoder (24) is arranged, and at the other free end the interface (20) for the respective table (2) of a table unit (8) is arranged.

3. The changing device according to claim 1 or 2, characterized in that the coil winding (56) of an electric motor (54) for driving the respective table (2) is accommodated in the table unit (8), wherein said electric motor (54) is formed as an external or internal rotor.

4. The changing device according to claim 1, characterized in that the cylindrical outer circumference of the stand component (12) forms a guide surface (34), along which the differently formed table units (8) can be placed as respective exchange units.

5. The changing device according to claim 1, characterized in that the respective clamping device (60, 84) can be at least partially hydraulically operated, in that the one type (84) of clamping device (60, 84) between the table (2) and the assigned table unit (8) establishes the frictional engagement between the rotating table (2) and the table unit (8) arranged stationarily on the stand component (12) by hydraulic spreading, and in that the other type (60) of clamping device (60, 84) is provided with a lamellar frictional engagement device (72).

6. The changing device according to claim 1, characterized in that the stand component (12) is divided into two parts, having a rotary guide (14) for the shaft (18) and a foot part (16), which is flange-like and widens radially outwards in relation to the rotary guide (14), wherein on said foot part (16) the table unit (8) together with the respective type of clamping device (60, 84) is placed stationary.

7. The changing device according to claim 1, characterized in that a coaxial hollow cylinder (14) adjoins to the food part (16) of the stand component (12) and encompasses the rotary encoder (24).

8. The changing device according to claim 1, characterized in that the stand component (12) always has the same predeterminable size for all sizes of tables (2) and table units (8) and irrespective of the type of clamping device (60, 84) used in the individual case.

9. The changing device according to claim 1, characterized in that the respective rotatable table (2) is flush with the outer circumference (78) of the assigned table unit (8) or, in contrast, is offset radially inwards.

10. The changing device according to claim 1, characterized in that on part of the stand component (12) at least one rotary seal (30) extends between the rotary guide (14) of the stand component (12) and the shaft (18), wherein said rotary seal (30) is interrupted by lubrication grooves or distribution grooves.

Description

[0015] Below, the invention is explained in detail with reference to exemplary embodiments shown in the drawing. In the Figures:

[0016] FIG. 1 shows a schematically simplified oblique perspective view, cut-away along a central vertical plane, of an exemplary embodiment of the changing device according to the invention, and

[0017] FIG. 2 shows a correspondingly cut-away, schematically simplified oblique perspective view of a second exemplary embodiment of the changing device according to the invention.

[0018] In the figures, a table, which has a circular, planar table surface 4, as is common for rotary indexing tables, is designated by the numeral 2. In the exemplary embodiment of FIG. 1, the table surface 4 is shown without any parts, such as workpieces or the like, mounted thereon, but in the exemplary embodiment of FIG. 2, exemplary pieces of equipment 6 are shown on the table surface 4. In both exemplary embodiments of FIG. 1 and FIG. 2, the table 2 forms a structural unit with an assigned stationary table unit 8, on which the table 2 is rotatably mounted by means of a bearing 10 formed by a roller bearing unit of the standard type. In both exemplary embodiments, the table unit 8 forms a type of outer housing having mainly circular cylindrical outer wall parts. The structural unit, comprising the table 2 and the table unit 8, forms an exchange component which, although it may be of different construction, can be fixed to one and the same base component in the form of a stand component 12.

[0019] In this respect, FIGS. 1 and 2 show different construction for the table 2 together with the table unit 8, which differ mainly in the type of clamping between the table 2 and the table unit 8. The stand component 12 has a circular cylindrical hollow body 14, at the end, at the bottom in the figures, of which there is a foot part 16, which has the form of a flange that widens radially outwards. The hollow body 14 forms the rotary guide for a shaft 18, which defines the axis of rotation for the table 2 and the upper end of which forms an interface 20, with which the exchange component can be coupled. In this example, as FIG. 1 shows, for this purpose bolts 20 are provided for a bolted connection to the table 2 at the bottom of the table surface 4.

[0020] A rotary encoder 24, arranged at the bottom of the foot part 16, interacts with an extension 26 of the shaft 18 to determine its rotational position and thus the rotational position of the table 2. In the rotary guide, formed by the hollow body 14 and in which the shaft 18 is guidably supported with and without roller bearings 28, there is a rotary distributor for lubricating fluid and other media, which are beneficial to the seal. The rotary distributor has along the outside of the shaft 18 between the rolling bearings 28 a rotary seal 30, in this case a Zurcon seal, which is interrupted by supply grooves. Furthermore, a variant having gap seals and bearing instead of contact seals can be used. Starting from a feed point (not shown), to which the lubricant or other medium is routed via a supply line 32, the lubricant or other medium is distributed along the seal 30 via the lubrication grooves and/or supply grooves. The circular cylindrical outer circumference of the hollow body 14 of the stand component 12 forms a guide surface 34, along which the table unit 8 together with the assigned table 2 as an exchange component can be put on the base component formed by the stand component 12. As shown in FIG. 1, in the mounted position, an inner collar 38, projecting radially inwards, of an inner housing part 36 of the table unit 8 rests against the top surface of the flange-like base part 16 of the stand component 12. An end sided outer flange 40 of the inner housing part 36 forms the support for a bottom part 42 of the outer housing formed by the table unit 8. An inner circumferential surface of the table 2 is guided, sealed by means of a sealing ring 46, at the upper end area of the guide surface 34 of the hollow cylinder 14.

[0021] Bolts 48, 50 and 52 are used to connect the table 2 to a shell part 54, which as an outer rotor encompasses a coil winding 56, which is fixed to the housing bottom part 42 using bolts 58. Also feasible with an internal rotor. This arrangement forms the electric drive motor of the table 2. The main difference between the exchange component shown in FIG. 1 and the exchange component shown in FIG. 2 is the construction of the clamping device.

[0022] In the example of FIG. 1, a plurality of equally formed clamping units 60 are arranged at equal distances from each other on a circular line concentric to the shaft 18, wherein of said clamping units 60 two clamping units 60 are visible in FIG. 1. Every clamping unit 60 has a stationary device body 62 attached to the inner wall of the housing shell formed by the table unit 8. More specifically, the device body 62 is located in an area below the inner bearing part 64 of the bearing 10, which is fixed to the underside of the table surface 4 using bolts 66. In the area between the underside of the inner bearing part 64 and the device body 62 there are, from top to bottom, a stationary compression ring 68 connected to the table unit 8, an intermediate ring 70 and a lamellar pack 72. The intermediate ring 70, which is connected to the table 2 by the bolts 48, can be rotated relative to the stationary compression ring 68.

[0023] The lamellar pack 72 is formed by a stacked sequence of disks in the manner of clutch plates, wherein the pack 72 comprises a succession of stationary lamellas, connected to the stationary compression ring 68 by bolts 74, and movable lamellas, connected to the movable intermediate ring 70 by bolts not shown. Every device body 62 has a hydraulically actuated piston 76, the end face of which can be used to load and press the lamellar pack 72 against the compression ring 78 and the intermediate ring 70, establishing a frictional engagement between the lamellas, by means of which the compression ring 68 and the intermediate ring 70 are fixed non-rotatable to each other.

[0024] In FIG. 2, components that functionally match those of the example of FIG. 1 are designated by the same reference numerals as in FIG. 1. While in the example of FIG. 1 the circumferential surface 76 of the table 2 is set back radially inwards relative to the outer circumference 78 of the table unit 8, in the example of FIG. 2 the circumferential l surface 76 of the table 2 and the outer circumference 78 of the table unit 8 are flush with each other. Whereas in the example of FIG. 1, a coaxial hollow cylinder 80 is provided at the underside of the foot part 16, wherein said hollow cylinder 80 encompasses the rotary encoder 24 and to which hollow cylinder 80 the port 82 for the lubricant supply or media supply to the conduit 32 is provided, this hollow cylinder 80 is omitted as an optional component in the example of FIG. 2.

[0025] In all other respects, however, the stand component 12 fully matches that of the example of FIG. 1 as far as its function as a base component, on which exchange components comprising the table 2 together with the table unit 8 of different constructions can be placed, is concerned. The difference is mainly in the arrangement and construction of the clamping device, the position of the bearing 10 below the clamping device and the construction of the electric motor, for which the shell part 62, connected to the table 2, is not arranged as an outer rotor on the outside of the coil winding 56, but as an inner rotor on the inside of the coil winding 56.

[0026] The clamping units 84, which are hydraulically actuated like the clamping units 60 of FIG. 1, are arranged between a circumferential area 86 of the table 2, adjacent to the table surface 4, and a clamping surface 88, extending in a radial plane and formed by an end surface in a recess in the outer wall of the housing of the table unit 8. The clamping units 84 comprise a spreader body 90 having an internal pressure chamber 92. By supplying pressure to the pressure chamber 92, the spreader body 90 can be hydraulically spread and generates a clamping force acting between the circumferential area 86 of the table 2 and the stationary clamping surface 88 on the table unit 8 to form a frictional connection for fixing the relative rotational position. As shown in FIG. 2, the bearing 10 is arranged below the clamping units 84, wherein, as in FIG. 1, the inner bearing part 64 is fixed to the table 2 using bolts 66.