DESCRIPTION OF THE PREFERRED EMBODIMENT

[0025] The device revealed in the drawings takes the form of a CNC-controlled grinding machine in particular for surface and edge-grinding of optical lenses L. The device has a frame 1 moulded from polymer concrete with two horizontally spaced side walls 2 , on the upper surfaces of which there are attached guide rails 3 extending horizontally and parallel to one another. A gantry 4 displaceable horizontally in both directions of a Y-axis is mounted slidably on the two guide rails 3 . As is clear from FIG. 4 , sliding of the gantry 4 is effected by means of a roller ball spindle 5 attached stationarily to the frame 1 and a hollow shaft servo motor 6 engaging non-interlockingly therewith and fitted in the gantry 4 . The space between the side walls 2 forms a machining area 7 , in which tools act on the lenses L in a manner still to be described. Two tool spindles 8 displaceable vertically in both directions of a Z-axis are provided on the gantry 4 likewise in a manner still to be described.

[0026] In the machining area 7 there is located a U-shaped yoke 9 , which carries on its web portion 10 a workpiece holding means 11 , which will be described in greater detail. Journals 13 pointing outwards and arranged in mutual coaxial alignment are attached to each of the branches 12 of the yoke 9 , as is shown best by FIG. 6 . These journals 13 serve to mount the yoke 9 on the side walls 2 rotatably about a swivel axis A. To swivel the yoke 9 about the swivel axis A, a torque motor 14 is provided which is attached to a side wall 2 of the frame 1 concentrically to the swivel axis A and is connected actively with the associated journal 13 of the yoke 9 , i.e. may move this journal 13 and thus the entire yoke 9 with the workpiece holding means 11 in both directions of rotation non-interlockingly and rotationally in accordance with control signals. To this end, the torque motor 14 has, according to FIG. 6, a stator S mounted non-rotatably in the right-hand side wall 2 and a rotor R fitted non-rotatably on the journal 13 of the yoke 9 . It is clear that the torque motor 14 is actively connected directly, i.e. without gearing, with the associated journal 13 of the yoke 9 . Like the Y-axis and the Z-axis, the swivel axis A is also CNC-controlled.

[0027] Counterweights 15 are attached, non-rotatably relative to the yoke 9 , to both journals 13 of the yoke 9 on the sides remote from the machining area, i.e. outside the side walls 2 of the frame 1 . These generate a torque at the journals 13 , which counteracts the torque generated by the yoke 9 and the holding means 11 , substantially compensating the latter.

[0028] For certain machining processes, the yoke 9 may preferably be locked in its particular swivel position by means of a frictional or interlocking brake 16 , which may be spring pre-tensioned. In the exemplary embodiment illustrated, the brake 16 is attached to the opposite side wall 2 from the torque motor 14 , as revealed by FIG. 6 . To unlock the brake, a suitable pneumatically or hydraulically actuated device (not shown) is provided.

[0029] As FIG. 6 also shows, the journal 13 of the yoke 9 connected actively with the torque motor 14 is mounted rotatably in the corresponding side wall 2 of the frame 1 with a swivel bearing on each side of the torque motor 14 . On the motor side, the swivel bearing 17 nearest the machining area 7 takes the form of a fixed bearing and the outer swivel bearing 18 takes the form of a movable bearing. The other journal 13 of the yoke 9 is mounted rotatably in the other side wall 2 with a swivel bearing 18 in the form of a movable bearing on each side of the brake 16 .

[0030] The swivel movements of the yoke 9 may be controlled on the basis of signals, which may be detected by means of a high-resolution rotary transducer 19 , which is arranged on the swivel axis A of the yoke 9 , in the example illustrated externally on the motor-side journal 13 of the yoke 9 ( FIG. 6 ).

[0031] It is clear from FIGS. 1, 4 and 5 that a horizontal slide 20 may be displaced on the gantry 4 on mutually parallel guide rails 21 attached horizontally on the gantry 4 . The gantry 4 and the horizontal slide 20 form a cross-slide arrangement, in which the horizontal slide 20 may be displaced in both directions of an X-axis, which extends perpendicularly to the Y-axis of the gantry 4 . The movements on the X-axis are also CNC-controlled.

[0032] Two tool spindles 8 are provided on the horizontal slide 20 , which spindles 8 may be displaced vertically along the Z-axis independently of one another in particular for optional rough or fine machining of the workpiece.

[0033] A workpiece loading means visible in FIGS. 1, 4 and 5 , which allows automatic workpiece change-over, consists of a cylinder 22 attached to the spindle head of a tool spindle 8 and a loading arm 23 with suction cup 24 , which loading arm 23 may be moved up and down and swivelled by the cylinder 22 . The loading means may be displaced vertically along the Z-axis together with the relevant tool spindle 8 .

[0034] The loading means may, for example, transport lenses L from a pallet store 25 or the like to the respective workpiece spindle 26 , of which the holding means 11 on the web part 10 of the yoke 9 comprises two ( FIG. 6 ). It is additionally possible to insert the lens into a centring station 27 and also into a reversing station 28 by means of the loading means. The lens is removed in the reversed position from the reversing station 28 and inserted into a workpiece receptacle 29 attached to the workpiece spindle 26 for machining of its rear.

[0035] Of particular advantage in this design of the device is that no additional CNC-controlled axes are required for the movements of the loading arm 23 . The two horizontal X and Y CNC axes thus allow fully automated workpiece change-over with little additional effort with the aid of the additional pneumatic cylinder 22 .

[0036] Since the axes of rotation of the two workpiece spindles 26 lie in a plane with the swivel axis A of the yoke 9 , the centre of the workpiece remains substantially in the area of the swivel axis A.

[0037] A tool changer 30 is arranged between the side walls 2 of the frame, which tool changer 30 may be displaced parallel to the guide rails 3 of the gantry 4 . The tool changer 30 may also be displaced on guide rails 31 which are attached to the frame 1 parallel to the guide rails 3 of the gantry 4 , as is clearest from FIG. 2 and FIG. 4 together. Sliding drive of the tool changer 30 proceeds by means of a hydraulic or pneumatic cylinder/piston arrangement 32 acting thereon, which is arranged in a recess 33 in the frame 1 . A replacement tool may be moved into the machining area 7 very quickly by means of the tool changer 30 . A carrousel store 34 belonging to the tool changer 30 may be appropriately indexed for the purpose of tool change-over, wherein the horizontal slide 20 with the respective tool spindle 8 may be positioned above the replacement tool or the tool to be replaced in the carrousel store 34 . This arrangement allows very rapid tool change-over, because no long horizontal paths have to be travelled with the heavy cross-slide arrangement consisting of gantry 4 and horizontal slide 20 . The tool changer 30 allows even very complex workpieces with different geometries to be machined with relatively little effort.

[0038] The above description is of an exemplary embodiment having two tool spindles 8 , but it is also possible to use just one tool spindle 8 for example to machine very large workpieces. The same applies to the number of workpiece spindles 26 , i.e. the fitting of just one workpiece spindle 26 on the yoke 9 is possible, e.g. for machining large lenses with a diameter of 300 mm and more. To machine complex flat optical or hybrid optical components, it is possible, for example, for the workpiece to be highly precisely positioned using this one workpiece spindle 26 , while individual flat surfaces are produced by means of cup or disk grinding tools or other tools. The use of disk milling cutters or cutter heads in the “flycutting” process is also possible, in order for example to produce inserts for injection moulds of metal by means of the device. Apart from the machining of such casting moulds or glass lenses and moulds, the device may also be used to machine polishing compression moulds of silicon carbide or ceramic drop-plate-type moulding substrates.

[0039] Due to the kinematic conditions of the device according to the invention, it is possible, in addition to spherical and flat optics, to machine aspheres, toroidal surfaces and also aspheres which are not rotationally symmetrical (atoroidal or progressive surfaces) as well as freeform surfaces. The device may operate both with cup grinding tools and in single point mode (as described for example in DE 195 29 786 C1 in the name of the applicant). Disk grinding tools may operate according to the principle of rotary circumferential cross grinding or longitudinal grinding.

[0040] A very versatile device is proposed for high-precision machining of optical workpieces, in particular optical lenses, which comprises a horizontally displaceable (Y-axis) gantry with at least one vertically displaceable (Z-axis) tool spindle and a yoke with workpiece holding means mounted so as to be rotatable about a swivel axis A by means of journals fitted on both sides. For swivelling of the yoke without gearing and therefore without backlash, a torque motor is provided concentrically to the swivel axis A, which motor is directly connected actively with one of the journals.