DE6809101U - TOOTHED TOOL FOR CHIPLESS FORMING OF GEARS OR THE LIKE. - Google Patents

Description

Carl Hurth Munich, Nov 22nd I968 '''■

Machine and gear factory 2503 Lich / Wo

8 Munich 5, Holzstr. 17-27 PL

Toothed tool for non-cutting shaping of gears or the like.

The innovation relates to a toothed tool in the form of a Gear or a rack or the like. For the non-cutting shaping of gears or the like, wherein the workpiece and the tool roll off one another with essentially parallel axes.

It is known to use toothed tools for the non-cutting Forme ti of gears, i.e., gears, racks, or the like. These tools have uninterrupted tooth flanks.

The required contact pressure can be reduced for a given contact pressure if the tooth flanks are provided with a number of I. grooves, enclose the webs between them, which form the tooth flanks. So the contact pressure is concentrated on these webs, whereby the contact pressure, which is decisive for the deformation of the material is increased.

The innovation is based on the task of improving the surface quality of the Workpieces that are machined with the tools listed above, to increase.

It was found that the shape of the grooves influences the surface quality of the workpiece.

The problem underlying the innovation is achieved in that the Tooth flanks are provided with a number of webs forming grooves, and that the groove walls, without using the new three-dimensional shape with the Sotation planes (planes that are perpendicular to the axis of rotation of the tool) represent an angle that is not filled with tool material

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Form (undercut angle), so arranged inclined to the tool tooth flank are that the material-free undercut angle is reduced compared to the groove wall at right angles to the tool tooth flank.

The new three-dimensional shape affects both gear-like and rack-like Tools. It is only necessary to ensure that in the case of a toothed rack, not the plane of rotation but the plane in which the Rolling motion is considered. It has been found that in the grooves due to the contact position of one groove wall to the rotational or rolling plane forms a pocket-like cavity in which material settles during the deformation of the workpiece, which during the rolling movement is torn out of the workpiece surface, creating a rough surface. The new shape of the room softens or eliminates this process.

The effect of the innovation is increased by the fact that at least one of the two groove walls of the grooves lie in the sotation plane or parallel to the rolling movement. This makes the bags whole and with it completely avoided their harmful effects.

Another advantageous embodiment of the new spatial shape is as follows: that the two groove walls of the grooves lie in the plane of rotation or parallel to the rolling movement.

From the standpoint of the strength of the webs, such a design is the Invention favorable that the two walls of the grooves converge towards the groove base. Furthermore, an embodiment can also be advantageous * the goes to that. the two groove walls of the grooves with the plane running through the middle of the groove from the tooth tip to the tooth base (e.g. plane of rotation) each form the same angle, the groove walls converging towards the groove base.

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The innovation is shown on the basis of FIGS. 1 to 8

Embodiments explained.

Fig. 1 shows a machine on which the innovation can be applied ι.

Fig. 2 shows a tooth of a tool from the side.

Fig. 3 shows a section along the line 3-3 in Fig. 2 and a Shape of the grooves without using the new spatial shape.

FIG. K shows a detail of FIG. 3 and schematically the harmful effect of a groove according to the old form.

Fig. 5 shows as a detail a groove according to the new design.

Fig. 6 shows a section along the line 3-3 in Fig.2 and at the same time an embodiment of the innovation.

FIG. 7 shows a detail from FIG. 6 on an enlarged scale. Fig. 8 shows a groove according to an embodiment of the innovation.

Fig. 1 shows a gear rolling machine on which the innovation can be applied. On a machine frame 10 of the two Reitstö'cke, by means of a workpiece table 11, 12 and 13 transmits in a known manner, the workpiece 1 + ^2, o a gear. Like. Rotatably mounted. A gear-like tool 16 is mounted in a tool slide 15i which can execute one or more feed movements in a known manner. In the example, the tool slide only performs a feed at right angles to the workpiece axis in the direction of the double arrow 15a. The tool is set in rotation by a motor 17 and rolls on the workpiece without play, the axes of the workpiece and the tool being essentially parallel.

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2 shows a tooth 18 of the gear-like tool from the side. It is provided on both sides with grooves 19 »20 extending from the tooth head to the foot. Fig. 3 shows a section along the line 3-3 in Fig. 2. A row of grooves 19 ', 19 ", 19'" etc. and 20 ', 20 "etc. are incorporated on each tooth flank. In between there are webs 21. The groove walls 22, 23 form a right angle with the tooth spine 2h, one of these two groove walls forms an angle not filled with tool material with the plane of rotation 25, ie with the plane in which the direction of the rolling movement lies Undercut angle? G called (Fig. Ό. The undercut angle forms a pocket 27- When the tool rolls on the workpiece 1 * t, workpiece material P settles in the pocket and is torn out during the rolling movement, which results in an unclean workpiece surface.

Fig. 5 shows a groove in which this deficiency is avoided. The groove wall 29, which would form the pocket described above without the invention, is placed according to the invention in the plane of rotation. The bag is this avoids the fact that no material can be torn out, the workpiece surface is of higher quality. In this embodiment, the groove walls converge because the groove wall 22 is the one described above Has retained location.

Figures .6 and 7 show another advantageous embodiment the innovation, in which both groove walls 30, 31 are placed in one of the planes of rotation. The webs 32 formed in this way penetrate more easily under certain circumstances the workpiece material as, for example, the edge formed by the groove wall 22 (FIG. 5), but from the standpoint of strength can be more beneficial.

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Di ι. Innovation also applies to: i; hn; "t ^ ng-jnar ti --e '.Vorkz'juge a nv, ¹ endable. The picture in FIG. 2 would only change to the effect that the tooth flanks are straight instead of curved. Figures £ to 8 remain unchanged. The plane of rotation becomes the V.'älz plane (which is also the plane of rotation). The Wälzebenc usually lies
parallel to the end face 35 of the toothed rod shaped tool.

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Claims (1)

Carl Hurth Munich, July 3rd, 1969 Machine and gear factory 25OJ5 Lich / Wo Munich 5, Holzstr. I9 PL 23I Protection claims 1) Toothed tool in the form of a gear or the like. for the non-cutting shaping of the teeth of gears or the like. by rolling, characterized in that the tooth flanks are provided with a number of grooves (19i 20) forming webs (21), and that the groove walls (29), which without application of the new spatial shape with the planes of rotation (25) (planes that are perpendicular stand on the axis of rotation of the tool) an angle not filled with tool material (Undercut angle 26) would be so inclined to the tool tooth flank (2 * f) that the material-free undercut angle (26) is reduced in comparison to the groove wall at right angles to the tool tooth flank. 2) Toothed tool in the form of a rack or the like. for the non-cutting shaping of the teeth of gears or the like. by rolling, characterized in that the tooth flanks are provided with a number of grooves (19i 20) forming webs (21), and that the groove walls (29), which correspond to the direction of the rolling movement (without using the new three-dimensional shape), do not contain tool material Filled angle (undercut angle 26) were formed, so inclined to the tool tooth flank (2 * f) that the material-free undercut angle (26) is reduced compared to the groove wall perpendicular to the tool tooth flank. 3) Tool according to claim 1 or 2, characterized in that at least one of the two groove walls of the grooves lies in the plane of rotation or parallel to the rolling movement. -ά- * f) Tool according to claim 3i, characterized in that the two groove walls of the grooves lie in the plane of rotation or parallel to the rolling movement. 5) Tool according to claim 1, 2 or 3, characterized in that the two walls of the grooves converge towards the groove base. 6) Tool according to Claim 5, characterized in that the two groove walls (33, 3 * 0 of the grooves) each have the same angle (35 »36) with the plane (eg plane of rotation) (25) running through the center of the groove from the tooth head to the tooth foot. form, the groove walls converging towards the groove base (36).