CHAMFERING TOOL, CHAMFERING SYSTEM, GEAR-CUTTING MACHINE AND METHOD FOR CHAMFERING TOOTHINGS

Abstract

The invention relates to a chamfering tool (4) for chamfering workpiece toothings (22), comprising a helical toothing having, for each flight, a plurality of teeth (5) with a geometrically defined cutting edge and having a tooth profile (8, 9; 8, 9) which is designed for single-flank machining in rolling machining engagement with the workpiece toothing and asymmetrical as viewed in the axial section of the tool. The invention further relates to a chamfering system (100), to a gear-cutting machine, and to a method for producing a chamfer on the tooth edges of a tooth flank side of a workpiece toothing.

Claims

1. Chamfering tool (4) for chamfering workpiece toothings (22), comprising a helical toothing having, for each flight, a plurality of teeth (5) with a geometrically defined cutting edge and having a tooth profile (8, 9; 8, 9) which is designed for single-flank machining in rolling machining engagement with the workpiece toothing (22) and is asymmetrical as viewed in the axial section of the tool.

2. Chamfering tool according to claim 1, wherein the ratio of the axial length (a.sub.p/1) of the non-machining tooth flank side of the tooth profile to the axial length (a.sub.p/2) of the machining side is smaller than 1, and/or is greater than 0.05.

3. Chamfering tool according to either claim 1, wherein a predominant part of the tooth profile is concave on the machining tooth flank side and transitions into a convex shape toward the tooth tip.

4. Chamfering tool according to claim 3, wherein the angle of pressure of the tooth profile on the machining tooth flank side between the tooth root and transition decreases into the convex region, with a relative change factor of greater than 0.1 and/or smaller than 10.

5. Chamfering tool according to claim 1, the axial length (L) of which extends beyond a contact length of the machining operation having at least two tool teeth, such that in the event of a respositioning of the relative position of the tool and workpiece that matches a displacement of the tool along its axis, other tool teeth can come into machining engagement with the tool at least in part.

6. Chamfering tool according to claim 5, wherein the axial length (L) of the chamfering tool extends at least 50% beyond the contact length.

7. Chamfering system (100) consisting of two or more chamfering tools according to claim 1 wherein a first chamfering tool (4a) is designed for single-flank chamfering of the tooth edges on the left flanks of the tool toothing and a second, in particular differently formed chamfering tool (4b) is designed for single-flank chamfering of the tooth edges on the right flanks of the workpiece toothing.

8. Chamfering system according to claim 7, in which a tool head (80; 80) carrying one or more chamfering tools (4a, 4b; 4c, 4d) and designed for driving same in rotation can be moved with respect to the workpiece axis of rotation (C) in at least one linearly independent spatial axes (X, Y, Z) and can be pivoted for an angle of inclination () of the tool axis with respect to the workpiece axis, wherein a pivot device causing this pivotability (A) is directly carried by a slide setting the axial spacing between the axes, and this slide is carried by a slide arrangement (70, 72) causing the remaining spatial axis movements.

9. Chamfering system according to claim 8, wherein the pivot device allows pivoting by +/160.

10. Chamfering system according to claim 7 in which one or more fly cutters (14) are provided as a further chamfering tool, which fly cutters are also still arranged in the same tool head (80), and wherein the chamfering system is controlled to chamfer in a first operating mode and using at least one fly cutter chamfering tool in a second operating mode.

11. Gear-cutting machine comprising a main machining station for producing a workpiece toothing by machining, and comprising a chamfering system (100) equipped with a chamfering tool according to claim 1.

12. Method for producing a chamfer on the tooth edges of a tooth flank side of a workpiece toothing using a chamfering tool according to claim 1 by carrying out a single-flank machining process.

13. Method for producing a chamfer on the tooth edges on both tooth flank sides of an end face of the workpiece toothing wherein the tooth edges are chamfered using a chamfering system (100) according to claim 7 by carrying out two single-flank machining processes.

14. Method according to claim 12 wherein a workpiece toothing is chamfered by a first tool region as viewed with respect to the axial length (L) of the chamfering tool, and another workpiece toothing of the same type is chamfered by a second tool region having at least partially different tool teeth.

15. Method according to claim 12 in which the workpiece toothings are helically toothed, and the chamfering tools for chamfering the pointed edge and the blunt edge of the helical toothing take place in different pivot positions of the tool axis of rotation with respect to the workpiece axis of rotation, wherein, in relation to the orthogonal position of the axes of rotation (B, C) as viewed in the direction of the axial spacing, the pointed side is machined at a pivot angle (n) of less than 10 and/or the blunt side is machined at a pivot angle () of preferably more than 5 and less than 35.

16. Method according to claim 15 wherein when chamfering the blunt side, work is carried out further off-center, as viewed tangentially, than when chamfering the pointed side by at least 5 mm.

17. Chamfering system according to claim 7 comprising a mounting unit that is formed of at least two of the chamfering tools and has a common axis of rotation for the tools, by means of which mounting unit a relative axial position and/or a relative rotational position with respect to the common axis of rotation is defined between a predetermined reference tooth of the chamfering tools.

18. Gear-cutting machine comprising a main machining station for producing a workpiece toothing by machining, and comprising a chamfering system (100) according to claim 7.

19. Method according to claim 13 wherein a workpiece toothing is chamfered by a first tool region as viewed with respect to the axial length (L) of the chamfering tool, and another workpiece toothing of the same type is chamfered by a second tool region having at least partially different tool teeth.

20. Method according to claim 13 in which the workpiece toothings are helically toothed, and the chamfering tools for chamfering the pointed edge and the blunt edge of the helical toothing take place in different pivot positions of the tool axis of rotation with respect to the workpiece axis of rotation, wherein, in relation to the orthogonal position of the axes of rotation (B, C) as viewed in the direction of the axial spacing, the pointed side is machined at a pivot angle () of less than 10 and/or the blunt side is machined at a pivot angle () of preferably more than 5 and less than 35.

Description

[0038] Further details, features and advantages of the invention can be found in the following description with reference to the accompanying drawings, in which

[0039] FIG. 1 is an axial section of a tool tooth profile

[0040] FIG. 2 is an axial section of a tool tooth profile

[0041] FIG. 3 is a schematic axial section of a chamfering hob in engagement with a gear

[0042] FIG. 4 shows a position of a chamfering hob when cutting the pointed chamfer flank of a helical gear

[0043] FIG. 5 shows a position of a chamfering hob when cutting the blunt chamfer flank of a helical gear

[0044] FIG. 6 shows a chamfering hob with an asymmetrical tooth profile

[0045] FIG. 7 shows a machining head with two chamfering hobs

[0046] FIG. 8 shows a machining head with four chamfering hobs

[0047] FIG. 9 shows an axial arrangement of a chamfering unit

[0048] FIG. 10 shows a fly cutter, and

[0049] FIG. 11 is an explanatory sketch of a mounting unit with four chamfering tools.

[0050] In the drawings, the following symbols are used:

A pivot axis A
B tool spindle axis B
C tool axis C
X radial axis X
Y tangential axis Y
Z axial axis Z
HOA hobbing offset angle
TCP tool center point
PCP part center point
b.sub.f chamfer width
d.sub.a2 gear tip circle diameter
d.sub.f2 gear root circle diameter
r.sub.0 tool tip circle radius
pivot angle
x radial distance between TCP and PCP
y tangential distance between TCP and PCP
z axial distance between TCP and PCP
.sub.fP0/1 tool profile tip radius of the non-cutting tooth flank
.sub.fP0/1 tool profile root radius of the non-cutting tooth flank
.sub.aP0/2 tool profile tip radius of the cutting tooth flank
.sub.aP0/2 tool profile root radius of the cutting tooth flank
.sub.P0/1 tool profile angle of the non-cutting tooth flank
p axial pitch of the tool reference profile
a.sub.p/1 part of the axial pitch of the tool reference profile of the non-cutting tooth flank
a.sub.p/2 part of the axial pitch of the tool reference profile of the cutting tooth flank
h.sub.aP0 tip height of the tool reference profile
h.sub.fP0 root height of the tool reference profile
L tool length

[0051] First, with reference to FIG. 9, a chamfering unit 100 is shown together with associated movement axes, which is a possible and preferred embodiment. A workpiece spindle 50 that is rotatably mounted on a machine bed 40 of the chamfering unit 100 for receiving a workpiece (not shown) can be seen on the workpiece side, the axis of rotation of the workpiece spindle (workpiece axis) being denoted by C.

[0052] A column 60 is provided on the tool side, which column carries a slide arrangement for implementing linear relative movements between the tool and the workpiece, in this embodiment in the form of mutually perpendicular movement axes X, Y, Z. An axial slide 70 is thus provided, the direction of movement Z of which extends in parallel with the workpiece axis of rotation and therefore vertically in this embodiment. The slide 70 in turn carries a tangential slide 72 with the movement of direction Y. A radial slide 74 is guided in an opening of the tangential slide 72. The radial slide 74 carries a tool head 80 in a pivotable manner (with pivot axis A). In this embodiment, the tool head 80 has an indirectly (CNC) driven tool spindle 82, with spindle axis B. In addition to such indirect drives with a belt drive between the motor and the spindle, a directly CNC driven spindle is also conceivable. In the embodiment shown in FIG. 9, the workpiece spindle 82 carries two chamfering tools, which are explained in more detail below with reference to further drawings.

[0053] Due to the arrangement of the radial slide X, the movement of which changes the axial spacing between the tool axis of rotation B and the workpiece axis C, as only the pivot device with pivot axis A, but none of the other linear movement axis slides, the machine axis is exposed only to low loads and moments for the pivot movement and radial movement.

[0054] The tool head 80 is shown enlarged again in FIG. 7. One-sided attachment of the tool spindle 82 can be seen. However, in another embodiment, shown in FIG. 8, a tool spindle 82 could also be mounted on both sides and optionally also carry a higher number of tools, for example four chamfering tools 4a, 4b, 4c, 4d.

[0055] All these chamfering tools 4a, 4b, 4c and 4d could be chamfering hobs according to the invention, but it is also conceivable that, for example, two of the tools are chamfering hobs according to the invention, while two others are fly cutters as shown in FIG. 10.

[0056] In the first case, an asymmetrical chamfering hob could be provided for chamfering the left and right flanks on the upper and lower end faces of a workpiece. In this case, a pivotability of +/80 or less from the horizontal for the pivot axis A may be sufficient for chamfering purposes. However, it is preferable for a pivotability of more than 160, in particular more than 180, to be provided, such that for the design of the tool head 80 of FIG. 7, for example, the two chamfering tools 4a, 4b, which are provided for the blunt and pointed edges in the case of a helically toothed workpiece, for example, work on one end face and, if required, on the other end face after appropriate pivoting.

[0057] Each of the chamfering tools 4a, 4b, 4c, 4d may be a tool, as shown in FIG. 6, having helical teeth 5. FIG. 6 shows a single-flight chamfering hob 4, although multiple-flight variants are conceivable. In general, it is preferable for fewer than 8, in particular fewer than 6, flights to be provided.

[0058] The tooth profile that is asymmetrical in the axial section of the tool 4 is clearly visible. The teeth 5 are thus provided with a significantly asymmetrical profile, and have a machining tooth flank 6 and a non-machining tooth flank 7. The chamfering hob 4 is therefore intended for only single-flank machining. In FIG. 7, the second chamfering hob on the workpiece spindle 82 would therefore be designed for machining the other flank of the workpiece.

[0059] The asymmetrical tooth profile of the chamfering hob 4 for an embodiment is shown in more detail in FIG. 1. The profile 8 of the machining tooth flank 6 is shown in FIG. 1 in part a.sub.p/2 of the axial pitch of the tool. Starting from the curve in the root region, the profile 8 extends in a concave manner until it passes an inflection point near the transition of the axial pitch of the non-cutting tooth flank a.sub.p/1 before transition into the tooth tip rounding. It is clear that the profile curve 9 in the region of the non-cutting tooth flank 7 between the tip rounding and the root rounding extends significantly more steeply than the profile 8 on the cutting tooth flank 6.

[0060] For this embodiment, the tool profile of the chamfering tool which machines the pointed edge of the workpiece (for example, helically toothed with helix angle between 10 and 35) is shown in FIG. 2. Here, too, a clear asymmetry can be seen; the profile curve 8 on the cutting tooth flank extends significantly less steeply than the profile curve 9 on the non-cutting tooth flank of the tool. However, the difference is less pronounced than in the profile curve 8, 9 shown in FIG. 1 for machining the blunt edge of the workpiece.

[0061] The asymmetry of the tooth profiles can be represented as quotients of the ratios (a.sub.p/2:a.sub.p/1) for the blunt and pointed sides, respectively. It is preferable for the quotient of the ratio (a.sub.p/2:a.sub.p/1).sub.blunt in the case of the tool profile chamfering the blunt edge and the ratio (a.sub.p/2:a.sub.p/1).sub.pointed in the case of the tool profile chamfering the pointed edge is greater than 1.1, preferably greater than 1.25, in particular greater than 1.4 and/or less than 3.0, preferably less than 2.5, in particular less than 2.0.

[0062] The relative position of the machining operation is shown schematically in FIG. 3, the drawing plane of FIG. 3 being the radial-axial plane and the viewing direction thus the tangential direction Y for the coordinate system shown in FIG. 9.

[0063] The machine axis settings for chamfering are selected so that the chamfering hob meets the tooth root of the workpiece 20 at its tip circle at the deepest radial advancement (X minimum) with a set hobbing offset angle HOA at a spacing of the chamfer width b.sub.F from the end face of the workpiece facing the tool. The axial axis Z and the radial axis X are preferably the advancement and feed axes. In a preferred design, the Z-axis position of the tool center TCP is set to the height shown in FIG. 3 (at a distance Z from the chamfering plane) and the relative movement between the tool 4 and the workpiece 20 can be limited to a purely radial movement X. However, combined XZ movements are also conceivable.

[0064] FIG. 4 shows a preferred relative position between the tool 4 and the workpiece (gear) 20 in the tangential/axial plane; here, the viewing direction is the radial direction X. In FIG. 4 it can be seen that the pivot angle A is set to zero, as a specific embodiment, as explained above, for chamfering the pointed tooth edge of the workpiece at a small pivot angle .

[0065] For chamfering the blunt tooth edge of the workpiece 20, on the other hand, a pivot angle n that is clearly different from zero is preferred as the setting for the pivot axis A. In addition, as can be clearly seen from a comparison of FIGS. 4 and 5, the tool 4 is arranged off-center; the planes containing the tool center TCP or the workpiece center PCP orthogonally to the tangential direction Y are spaced apart by Y.

[0066] In contrast to the fly cutter shown in FIG. 10, the chamfering hob 4 shown in FIG. 6 has a significantly larger region of cutting edges, due to the plurality of teeth for each flight. Even if not all tooth edges have a machining effect in one machining position, the machining region can be moved along the axial axis by axial displacement with respect to the tool axis and thus new, still-unused cutting edges can always be used for machining before the chamfering tool has to be reconditioned or replaced. This also results in advantages in the tool service life.

[0067] The chamfering hob shown in FIG. 6 and also the tool profiles shown in FIGS. 1 and 2 are matched to the workpiece to be chamfered at the intended machining relative positions and are therefore workpiece-specific. The fly cutter 14 shown in FIG. 10, on the other hand, with its symmetrical design of the cutting edges formed by indexable inserts 15, can be used independently of the workpiece; when it is used, the chamfer is formed on the workpiece by means of coupled machine axis movements, which are carried out individually depending on the workpiece to be chamfered.

[0068] In an embodiment of the tool head 80 shown in FIG. 8, a design with extremely flexible application possibilities is created by combining two chamfer hobs and two fly cutters. For example, a larger batch of identical workpieces, for which the chamfering hobs are designed, can be machined, but in the meantime workpieces not matching this batch of workpieces can also be chamfered by using the fly cutters.

[0069] In FIG. 11, the chamfering system explained above is briefly explained again in terms of the mounting unit. A mounting unit 200 having a common base body 202 that carries four chamfering hobs 204a, 204b, 204c and 204d is shown schematically. The spacings between the individual chamfering tools are defined and no longer change when using the mounting unit 200. The rectangular boxes with reference numbers 206a, 206b, 206c and 206d schematically indicate the defined spacing between a planar surface of the milling spindle 208 and the axial position of the first full tooth of each chamfering tool; the rotational position of this tooth is aligned in the same way in this embodiment. Both these axial positions and the rotational positions are stored and are available to an operator of a chamfering machine when using the mounting unit 200 in order to be able to make the position settings for chamfering each individual chamfering tool of the mounting unit 200 as explained above.

[0070] The invention is not limited to the features and details described in the embodiments provided above. Rather, the features of the following claims and the above description may be essential, individually and in combination, for implementing the invention in its different embodiments.