Grinding-Disk Shield

Abstract

The invention relates to an internally cooled grinding disc shielding (16), wherein a cooling liquid (14) outwardly flows thorough a recess embodied in the peripheral surface of a grinding disk, the shielding is provided with a collecting groove (17) for the cooling liquid (14) which surrounds the grinding disc (1) under a sector comprises at least one discharge nozzle (20) which is arranged on the output side and by means of which a jet is directed to a work piece (13) or to a grinding point (16).

Description

The invention relates to grinding disk shield for internally cooled grinding disks, where a cooling liquid is outwardly discharged through openings in the outer grinding surface.

For internally cooled grinding disks, the cooling liquid is supplied to internal cavities in the grinding disk, from which point the cooling liquid passes at high pressure through passages to openings in the peripheral grinding surface and is outwardly discharged. The quantities of cooling liquid may be very large for large grinding disks having a diameter of 400 mm, for example.

Thus, for example, such a grinding disk operating at 3000 RPM and a cooling liquid pressure of 40 to 60 bar requires approximately 200 liters of liquid per minute. However, the cooling effect of the cooling liquid is needed primarily at the grinding location at which the grinding disk contacts the workpiece to be machined. Thus, a significant quantity of cooling liquid and the associated pumping capacity are wasted. The aim is to increase the cooling power at a lower cost.

A grinding-disk shield is known and also required by regulatory requirements, so that a sector of the grinding disk is covered by a sheet-steel cover in order to prevent injuries when parts of the grinding disk or the workpiece are projected outward. These protective plates capture a portion of the emitted cooling liquid, but do not improve the cooling effect.

The present invention is characterized in that the shield has a collecting groove for the cooling liquid which surrounds the grinding disk over a sector and which has at least one discharge nozzle on the output side, by means of which a jet may be directed onto the workpiece to be ground, or onto the grinding location. Further advantageous features are contained in the following description, the drawings, and the claims.

The invention is explained in greater detail below, with reference to several illustrated embodiments.

FIG. 1 shows a side view of a grinding-disk system having grinding-disk shield according to the invention.

FIG. 2 shows a sectional view of this system.

FIG. 3 shows an oblique view of the output-side end of the grinding-disk shield.

FIGS. 4 through 6 show details in various embodiments, and

FIG. 7 shows an oblique view of a further embodiment of the invention.

According to FIG. 1, the system comprises a grinding disk 1 having a grinding surface 2 and discharge openings 3 for the cooling liquid 4. The cooling liquid under is fed under high pressure through a conduit 5 into the interior of the grinding disk 1, and from there, in a manner known per se, passes through a chamber system and passages to the discharge openings 3.

The grinding-disk shield 6 has an inlet 7 and an outlet 8 and extends over a sector of the grinding disk. The grinding disk 1 pivots about the axis 10 in a rotational direction 9.

Visible on the output side is the handle 11 of a rotary element 12 that fits in a seat in the grinding-disk shield 6, and that passes through same and is rotatable by means of the handle. FIG. 1 also shows the workpiece 13 and two substreams 14 and 15 of the cooling liquid 4. One substream 15 flows along the grinding surface 2 of the grinding disk 1, and the substream 14 is projected in a targeted manner from the grinding-disk shield onto the grinding location 16.

The sectional illustration according to FIG. 2 shows the internal design of the system. The grinding disk 1 is only schematically illustrated, and the chambers and passages for the distribution and supply of cooling liquid are not shown. In this case it is only important that the cooling liquid conducted inside the grinding disk be supplied to the outlet openings 3 via these chambers and passages, from which point the liquid is discharged in an approximately radial direction.

In the vicinity of the grinding-disk shield 6 the grinding disk 1 for a collecting groove 17 having a relatively small clearance around the grinding disk 1. The collecting groove 17 extends over a portion of the periphery of the grinding disk, parallel to the grinding surface 2, and widens in the direction of the outlet 8. An end 18 widens in a continuous progression from the collecting groove 6. In the vicinity of the widening 18 is located the rotary element 12 together with a collection chamber 19 from which a discharge nozzle [20] extends in the direction of the outlet of the grinding-disk shield. FIG. 2 also shows that at the outlet 8 the collecting groove on the rotary body passes along the grinding disk, thereby forming an outlet slot 21.

After exiting through the outlet openings 3, the cooling liquid supplied to the grinding disk is collected under high pressure in the sector of the grinding disk covered by the grinding-disk shield 6, and is transported toward the outlet 8. The cooling liquid passes into the widening 18 and into the collection chamber 19. From there, the substream of the cooling liquid represented by substream 14 in FIG. 1 is compressed by the discharge nozzle 20. Another substream may be entrained along the grinding surface 2 by means of the grinding disk and may be discharged through the outlet slot 21.

Rotation of the rotary element 12 can direct the stream from the discharge nozzle 20 in such a way that the substream 14 strikes the workpiece 13 precisely at the intended location.

FIG. 3 shows the outlet of the grinding-disk shield, with the grinding disk omitted. Its inner surface 22 has two parallel grooves 23 which receive the cooling liquid in the collecting groove 17. The discharge nozzle 20 is designed as a continuous slot.

At the outer surface of the grinding-disk shield 6 is located a peripheral undercut groove 24 that via appropriate fastening means is used to mount the grinding-disk shield 6 and adjustably position same.

FIG. 4 shows the rotary element 12 in the design of FIG. 3. View is into the collection chamber 19, from which the discharge nozzle 20 extends.

FIG. 5 shows a side view of another embodiment of the rotary element, with the discharge nozzle 20 forming three nozzle passages 25.

In a further embodiment according to FIG. 6, the rotary element has a branch conduit 27 which diverts the liquid stream, or at least a substream, from the collection chamber 19 and conveys same to a conduit or an external discharge nozzle, not illustrated. It is thus possible to distribute additional targeted coolant streams onto the workpiece or the grinding surface. FIG. 7 shows such a system on a grinding disk where the cooling liquid is streamed on both sides from the rotary element 12 into two external discharge nozzles 26, thus allowing the cooling liquid to be supplied from another angular position.

With regard to the collecting groove as illustrated in FIG. 3, for example, the cross-sectional shape thereof may be chosen at the discretion of one skilled in the art. The cross-sectional shape of the collecting groove may be adapted to the cross section of the grinding disk, for example, in particular when profiled parts are ground.

The apparatus according to the invention offers not only the advantage of improved supply of coolant to the grinding location, but also makes separate rinsing of the grinding surface of the grinding disk unnecessary.

The grinding-disk shield is illustrated in the figures as a cast element, but may also be made of plastic or metal. Production from sheet steel is also possible. The term “cooling liquid” as used herein encompasses all liquids, including lubricants, for example, that are supplied to the grinding surface and/or the workpiece in grinding-disk systems.

Claims

1. A grinding-disk shield for internally cooled grinding disks where the cooling liquid is outwardly discharged through openings in a peripheral grinding surface wherein the shield has a collecting groove for the cooling liquid which surrounds the grinding disk over a sector and which has at least one discharge nozzle on the output side by means of which a jet may be directed onto the workpiece to be ground, or onto the grinding location.

2. The grinding-disk shield according to claim 1 wherein the collecting groove has a widening by means of which the cooling liquid is conducted to the discharge nozzle.

3. The grinding-disk shield according to claim 2 wherein the discharge nozzle is situated in a rotary element that is rotatably supported in the shield, thereby allowing the stream direction to be adjusted.

4. The grinding-disk shield according to claim 3 wherein the rotary element has a collection chamber which is open toward the widening of the collecting groove and by means of which the discharge nozzle is supplied with the cooling liquid.

5. The grinding-disk shield according to claim 3 wherein on the output side the collecting groove runs past the rotary element to an exit slot so that a substream of the cooling liquid is entrained along the grinding surface, and the other substream is discharged through the discharge nozzle.

6. The grinding-disk shield according to claim 3 through wherein the rotary element has a turning handle.

7. The grinding-disk shield according to claim 3 wherein the discharge nozzle has multiple nozzle passages.

8. The grinding-disk shield according to claim 3 wherein the rotary element has at least one branch conduit for conducting the stream or a substream of the cooling liquid to a conduit or an external discharge nozzle.

9. The grinding-disk shield according to claim 2 wherein the widening extends in a continuous progression from the collecting groove.