DE2335575B2 - - Google Patents

Description

In a known copy grinding machine of the type mentioned in the preamble of the main claim (US-PS 36 63 188), the template and the workpiece rotate around the copier roller and the tool, its axis only is displaceable for delivery. Here, the copier roller engages an inner surface of the stencil. at In this known copy grinding machine, the feed force of the grinding wheel is greater than that of the copy roller opposite, resiliently supported guide rollers added, so that a total undesirably a system that is susceptible to vibrations results in which the on the workpiece can affect the achievable dimensional and shape accuracy.

The invention is therefore based on the object of reducing the susceptibility of the generic copy grinding machine to vibrations to eliminate, so that an even more precise * o grinding of inner surfaces, especially the chamber surfaces a rotary engine, is made possible.

To solve this problem it is provided according to the invention that the scanned by the copying roller Area is the outer surface of the stencil.

In the invention, the template and the workpiece are arranged in a stationary manner. Because the The copier roll runs off the outer surface of the stencil, while the grinding wheel runs off the inner surface of the Attacks the workpiece, the feed force of the grinding so disk is supported on the stationary stencil via the copier roller, without the guide rollers or to apply their resilient support. This makes the desired immunity to vibrations achieved.

It is indeed already a copy grinder for processing those deviating from the circular shape Areas with straight and parallel surface lines known (FR-PS 12 27 965), in which the over the Grinding wheel applied feed force according to the invention from the template via the copier roller is picked up, but in this case it is one to be machined on its outer surface Workpiece, so that this prior art can therefore not be used without additional constructive rethinking of the h "> the present invention was to be assigned.

The invention is explained in more detail below with reference to schematic drawings of an exemplary embodiment

explained. It shows

F i g. 1 shows a simplified longitudinal section through a copy grinding machine according to the invention and

F i g. 2 the assignment of the workpiece, the template, the grinding wheel and the copier in the Copy grinding machine according to FIG. 1 in plan.

The copy grinding machine according to FIG. 1 essentially has a base plate 1 and a height-adjustable one Workpiece table 2 for receiving the workpiece 3 to be ground. Above the workpiece 3 a bearing housing 4 is attached, in which a bearing plate 5 is rotatably guided and laterally adjustable. For the grinding of the workpiece 3 is on the underside of the bearing plate 5 in its entirety with 6 designated grinding headstock attached. A template 7 is fixed to the top of the bearing housing 4 arranged. At the top of the bearing plate 5 is a copier designated in its entirety by 8 appropriate. This has a driven copying roller 9 on the outer surface to be scanned

10 engages the template 7 and thereby moves around the template 7. By the fact that the copier 8 on the bearing plate 5 is arranged, its movement around the template 7 generates a corresponding one Movement of the grinding headstock 6 relative to the workpiece!

The outer surface 10 of the template 7 corresponds to the inner surface 11 to be machined on the workpiece 3 formed, which here is the trochoid-shaped inner surface of a rotary engine housing. The shape of the Template 7 is shown most clearly from FIG. 2 emerges. In this figure is also the relationship between the outer surface 10 to be scanned and the inner surface 11 of the workpiece 3 shown. The template 7 is immediately above the workpiece, so that their Outer surface 10 seen from above with the inner surface

11 coincides.

The copying roller 9 rests on the outer surface 10 at a point of contact 12. Its axis of rotation lies in a plane PI which, at the point of contact 12, runs perpendicular to the outer surface 10. The copying roller 9 is arranged at the end of a spindle 13, which in turn is rotatably received in a slide 14. The other end of the spindle 13 penetrates the slide 14 and carries a pulley 15 around which a drive belt 16 wraps. The drive belt 16 loops around a belt pulley 17 fastened to the output shaft of a drive motor 18. The drive motor 18 is fastened with a bracket 19 to the slide 14, which is itself slidably received in a slide housing 20 in a direction parallel to plane P1.

A guide device 21 with two guide rollers 22 and 23, which rest on guide surfaces 24 and 25 of the inner surface of the stencil 7, belongs to the copier device 8. The axes of rotation of the guide rollers 22, 23 lie in a plane P- 2 normal to the plane PX . The guide rollers 22, 23 are urged in the direction against the copying roller 9, in order to produce a resultant effective in the plane P-i and directed through the point of contact 12 To generate power.

On the slide 14 is linearly displaceable in the same direction, however, independently of it second slide 26 performed. A holder 27 is attached to the underside of the second slide 26, in which the guide rollers 22 and 23 are rotatably mounted. The guide rollers 22 and 23 are

They are arranged offset in height relative to one another and act individually on the upper and lower guide surfaces 24 and 25 of the inner surface of the template 7. As in Fig. 2, the guide rollers 22, 23 are also offset from one another in the lateral direction and are arranged at the same distance from the plane P1 .

The second slide 26 is of a plate spring assembly 33, which is supported against a plate 28 to the right loaded to the guide rollers 22, 23 against the guide surfaces 24, 23 on the inner surface of the Stencil / urge.

As a result of the disk spring assembly 33 arranged between the two slides 14 and 26, the copying rollers are

9 on the carriage 14 against the outer surface 10 and the guide rollers 22 and 23 in opposite directions Direction pushed against the guide surfaces 24 and 23 on the inner surface of the template 7 The contact pressure, with which the copying roller 9 and the guide rollers 22, 23 are urged against the template 7 is through Change of spring preload changeable.

As a result of the above-described structure of the copying device 8, the resulting force required to maintain the axis of rotation of the guide rollers 22, 23 in the plane P- 1 is generated as soon as the copying device 8 is moved around the stencil 7. Since the guide rollers 22 and 23 are equally spaced from the plane P-i , they effectively overcome inertial forces which tend to pivot the copier 8 and move the contact point 12 out of the plane P- 1. By driving the copying roller 9 at a constant speed by means of the motor! S, the copying device 8 is advanced around the outer surface

10 around at constant speed In this way it is achieved that the outer surface 10 moves relative to one another moved to the point of contact 12 and through this at a constant speed

As shown in FIG. 2, the upper 24 and lower guide surfaces 25 of the template 7 show different ones Course. The exact course of each guide surface 24, 25 is determined by the outer surface 10 It is It can be clearly seen that the guide surfaces 24, 25 along the side sections which form the concave sections the outer surface 10 opposite, differ from each other. The differences in shape between the guide surfaces 24, 25 as shown in FIG. 2 are shown, arise from the fact that two against each other offset guide rollers can be used. The guide rollers 22, 23 touch any one Time the guide surfaces 24, 25 at different points. Is it the surface to be sanded? around the trochoid-shaped inner surface of a Wankel engine housing, the surface is continuous changing radius of curvature. Because the leading roles 22 and 23 are offset from one another, the guide surfaces 24 and 25 are in different in shape. The differences in shape are slight and with the exception of the undercut Side sections in FIG. 2 not shown

As already mentioned, the copying device 8 is mounted on the upper side of the bearing plate 5. This arrangement is achieved with a support body 34 which is fastened to the upper side of the bearing plate 5 and which carries the slide valve housing 20. In order to enable the copier 8 to move around the stencil 7, the bearing plate 5 is rotatable about an axis which runs parallel to the plane P-i and is laterally displaceable in a direction normal to this axis. The peripheral part of the bearing plate 5 lies within the bearing housing 4. The bearing housing 4 can be supplied with hydraulic pressure to act on the upper and lower sides of the bearing plate 5 in order to keep the bearing plate 5 floating in the bearing housing 4, ie the bearing housing 4 and the bearing plate 5 form together hydrostatic bearing.

According to the invention, the grinding headstock 6 comprises a grinding wheel 36, the axis of rotation of which is arranged in the same plane P-i as the axis of rotation of the copying roller 9. This is clear from FIG. 2, in which it is also shown that the circumferential surface of the sliding slide 36 engages the inner surface 11 of the workpiece 3 at a point which coincides with the point of contact 12. The grinding wheel 36 is fastened to the end of a rotationally driven spindle 37, the motor and headstock 6 of which is fastened to a bracket 38 firmly attached to the underside of the bearing plate 5.

The adjustment of the grinding wheel 36 in the plane P-i and towards the surface of the workpiece 3 to be ground takes place with a stepping motor 41. This motor is attached to the slide housing 20 and has an output threaded spindle 42. The output threaded spindle 42 is screwed into a threaded hole in the plate 28, which in turn is fastened to the slide 14, which carries the copying device 8.

Upon actuation of the stepping motor 41 with a direction of rotation of the driven screw 42 in which the slide 14 according to FIG. 1 is pulled to the left, the grinding wheel 36 moves according to FIG. 1 to the right. The reason for this is that the slider 14 is firmly connected Because of its interaction with the stationary template 7, the copying roller 9 does not move to the left can. However, the stepper motor 41 is attached to the valve housing 20, and this is on the floating Bearing plate 5 supported. Because of this arrangement and because the bearing plate 5 is inside the bearing housing 4 is freely movable, the bearing plate 5 moves to the right. Since the grinding wheel 36 via the console 38 is firmly connected to the underside of the bearing plate 5, this movement in turn causes the Grinding wheel 36 is moved to the right in grinding engagement with the inner surface 11 to be ground on workpiece 3.

The force generated by the grinding wheel 36 acting on the workpiece 3 is that on the guide rollers 22 and 23 acting in the opposite direction. The copier is therefore prone to under the during the highest loads that occur during the grinding process do not cause them to detach from the cam.

1 sheet of drawings

Claims (1)

Claim: Copy grinding machine for processing inner surfaces deviating from the circular shape with straight and parallel surface lines with one workpiece table, one opposite the workpiece table adjustable wheelhead and with an annular template, which on its one Side a scanned by a copier roll stored in a holder and the one to be processed Contour corresponding to the inner surface and on its other side opposite one side, has two guide surfaces on which two are symmetrical to the copier roller and against each other Rolling guide rollers arranged offset in height, characterized in that the from The surface scanned by the copier roller (9) is the outer surface (10) of the stencil (7). 20th