WO2007073850A1 - Tool for the chipless shaping of threads, in particular for the forming of internal threads - Google Patents

Abstract

The tool has a clamping shank (1) and a working part (3) which is designed in the form of a shaping region having thread grooves. So that the tool can be produced in a favourable and simple manner, the working part (3) is a component frictionally held on the clamping shank (1) in the axial direction. The thread grooves can be incorporated in the working part (3) without any problems using a grinding wheel. The working part (3) can be fastened to the clamping shank (1) in a simple manner. The tool is used for the chipless shaping of threads.

Description

 Tool for non-cutting shaping of threads, in particular for forming internal threads

The invention relates to a tool for non-cutting shaping of threads, in particular for molding internal threads, according to the preamble of claim 1.

There are known tools for chipless shaping of threads, in which the free end of the clamping shaft is designed as a working part in the form of a shaping area with thread grooves. The shaping area has a polygonal cross-section. In the area of the cross-section corners are cylindrical strips of hard and wear-resistant material, which are soldered into axially extending grooves of this shaping area. Such tools are difficult to manufacture. In particular, the common profile grinding for the production of thread grooves in the forming area and in the strips used leads to difficulties because the grinding wheels set for this purpose quickly.

The invention is based on the object, the generic tool in such a way that it can be made cheap and easy.

This object is achieved in the generic tool according to the invention with the characterizing features of claim 1. In the case of the tool according to the invention, the working part is a component which is fastened non-positively in the axial direction on the clamping shaft and which can be designed as a sleeve or as a solid head. In this working part, the thread grooves can be easily introduced with a grinding wheel. The working part can be easily attached to the clamping shaft, for example by gluing, by soldering or by shrinking.

Further features of the invention will become apparent from the other claims, the description and the drawings.

The invention will be explained in more detail with reference to some embodiments shown in the drawings. Show it

1 is a side view of an inventive tool for chipless shaping of threads,

2 is an end view of the tool of FIG. 1,

Fig. 3 to

Fig. 5 respectively in an enlarged view of a shaping area of further embodiments of tools according to the invention.

With the tools described below, threads, in particular internal threads, are produced by non-cutting shaping. The tool according to FIGS. 1 and 2 has a preferably cylindrical clamping shaft 1, with which the tool is received in a tool holder. The clamping shaft 1 is advantageously made of steel or a tough carbide. The left in Fig. 1 end 2 of the clamping shaft 1 is tapered in cross-section. On this shaft end 2, a sleeve 3 is fixed, which can be soldered, glued or shrunk on the shaft end 2. The sleeve 3 is advantageously made of hard metal and has at the free end a Anschnitteil 4, whose axial length is smaller than that half length of the sleeve 3. The Anschnitteil 4 tapers towards its free end. The adjoining the Anschnitteil 4 area 5 is formed as a polygon (Fig. 2) and has on the circumference lying in radial planes thread grooves. In the exemplary embodiment, the serving as a guide thread portion 5 of the sleeve 3 has four axially extending edges 6 to 9, each having an angular distance of 90 ° from each other. In the area between adjacent edges 6 to 9 of the shell portion of the region 5 is in each case convex. In these convex sheath sections are the (not shown) thread grooves, which are preferably ground into the shell sections.

The sleeve region 5 can also have a different polygon cross-section. A deviating from a polygon cross section of the sleeve portion 5 is possible.

The preparation of the tool is simple, since the annular sleeve 3 can be easily attached to the shaft end 2. The thread grooves can be easily grind into the sleeve 3. Since the grinding wheel only comes into contact with the material of the sleeve 3 during the grinding process, the risk of smearing of the grinding wheel is low. 2 shows a variant of the connection between the shaft end 2 and the sleeve 3. In the embodiment according to FIG. 1, the inner wall 10 of the sleeve 3 rests on a cylinder jacket. The shaft end 2 extends to the flat end face 1 1 of the sleeve. 3

In Fig. 2, a variant is shown, in which the inner wall 10 of the sleeve 3 is polygonal. In this way, a positive engagement is achieved between the shaft end 2 and the sleeve 3 in the direction of rotation of the tool. In the embodiment, the inner wall 10 of the sleeve 3 and, accordingly, the outer wall of the shaft end 2 has three axially extending edges 12 to 14, which is an angular distance of 120 ° from- have each other. In the area between the edges 12 to 14, the wall sections are convex. The edges 12 and 13 are angularly offset from the edges 6, 7, 9 of the sleeve 3, while the edge 14 of the inner wall 10 is in the same plane as the edges 6 and 8 of the sleeve 3. The inner wall 10 of the sleeve 3 can to achieve a Form fit with the shaft end 2 also have any other, deviating from a circular cross-section. Moreover, the tool of FIG. 2 is the same design as the embodiment of FIG. 1st

Fig. 3 shows an embodiment in which the shaft end 2 has a remote outer contour. The adjoining the clamping shaft 1 shaft portion 15 has a smaller cross-sectional area than the outside of the sleeve 3 lying part of the cylindrical clamping shank 1. The adjoining the shank portion 15 shank portion 16 is longer in the embodiment than the shank portion 15 and in turn has a smaller cross-section than the shank portion 15th Over the axial length, the shaft portions 15 and 16 each have a constant cross section. The shaft portions 15, 16 may be cylindrical as in the embodiment of FIG. 1, but may also be designed polygonal according to the embodiment of FIG. It is also possible to form the two shaft sections 15 and 16 differently in their cross-sectional shape. The stepped contour of the shaft end 2 increases the stability of the sleeve 3 in the Anschnitteil. 4

As in the previous embodiments, the sleeve 3 rests on the radial annular shoulder 17 which is formed at the transition from the clamping shaft 1 to the shaft portion 15. The inner wall 10 of the sleeve 3 is adapted to the outline shape of the shaft portions 15, 16. As in the previous embodiments, the sleeve 3 may be secured to the shaft sections 15, 16 by soldering, gluing or shrinking. The shank portion 16 extends to the end face 1 1 of the Anschnitteiles 4, so that the sleeve 3 sits securely on the shank portions 15, 16. According to the previous ones Embodiments is the sleeve 3 with its shaping region 5, which contains the thread grooves over the clamping shaft 1 radially over, so that a perfect chipless production of the thread is ensured.

In the embodiment of FIG. 4, the shaft end 2 is continuously tapered towards its free end. The shaft end 2 may be tapered conically. However, the tapering of the shank end 2 can also be provided, for example, in the case of a polygonal design or another shape deviating from a circular shape in cross section. Also by this design of the shaft end 2, the stability of the sleeve 3 is increased in the region of the Anschnitteiles 4. The inner wall 10 of the sleeve 3 is adapted to the contour shape of the shaft end 2, so that a secure connection between the shaft end 2 and the sleeve 3 is ensured.

The sleeve 3 projects radially beyond the clamping shaft 1. It is also the same design as in the previous embodiments.

Fig. 5 shows the possibility, instead of a sleeve to use a solid head 18 having the Anschnitteil 4 and the thread grooves containing area 5. In the outer shape of the solid head 18 is thus the same design as the sleeve 3. The solid head 18 has at its one end face 19, a blind hole 20 into which the shaft end 2 protrudes. By way of example, the blind hole 20 only extends over half the axial length of the region 5 of the solid head 18 which has the thread grooves. The shank end 2 can have a cylindrical, a polygonal or any other suitable outer contour. Accordingly, the inner wall 10 of the blind hole 20 is formed. The solid head 18 is advantageously made of hard metal and is attached to the shaft end 2 by soldering, gluing or shrinking. The blind hole 20 has in the illustrated embodiment over its axial length constant cross-section. It is also possible, the blind hole 20 so too design that its cross-section decreases axially inward, preferably steadily.

The solid head 18 protrudes radially beyond the clamping shaft 1 and rests with its end face 19 on the annular shoulder 17 of the clamping shaft 1.

FIG. 2 shows by way of example the possibility of providing the tool with an internal coolant supply 21. It is formed by at least one coolant hole, which extends axially through the clamping shaft 1 and the shaft end 2 and the shaft portions 15, 16 and opens into the end face 1 1 of the Anschnitteiles 4.

At the transition from the cylindrical clamping shaft 2 to the reduced in cross-sectional area shank end 2 and the shaft portions 15, 16 is advantageously a transitional bevel, a transition radius or a similar contour provided to reduce the notch effect in these areas. Also between the shank portions 15, 16 is advantageously provided such a transitional bevel, transition radius and the like.

The tools described can be very easily and inexpensively. With the tools, heavy-duty threads can be produced without a cutting process. With the provided in the region 5 of the sleeve 3 and the solid head 18 thread grooves, the thread is produced by a stamping process in the workpiece. As a result of the described design of the tools, the high loads which occur in the workpiece due to the material displacement in the non-cutting thread production are reliably absorbed. The radially directed pressure forces occurring during manufacture are derived from the sleeve 3 or from the solid head 18 into the shaft end 2 or the shaft sections 15, 16 and from there into the clamping shaft 1.

Claims

claims

1. A tool for chipless shaping of threads, in particular for molding internal threads, with a clamping shaft and a working part which is provided on its outside with thread grooves, characterized in that the working part (3, 18) on the clamping shaft (1) in Axial direction frictionally held component is.

2. Tool according to claim 1, characterized in that the working part (3, 18) on a reduced cross-sectional area (2, 15, 16) of the clamping shank (1) is fixed.

3. Tool according to claim 2, characterized in that the reduced cross-sectional area (2, 15, 16) of the clamping shank (1) to the free end of the working part (3, 18).

4. Tool according to one of claims 1 to 3, characterized in that the working part (3) is a sleeve which is non-positively and / or positively secured in the circumferential direction on the clamping shaft (1).

5. Tool according to one of claims 1 to 3, characterized in that the working part (18) is a solid head having a blind hole (20) for receiving the end (2) of the clamping shank (1).

6. Tool according to one of claims 1 to 5, characterized in that the clamping shaft (1) in the fastening region (2; 15, 16) of the working part (3, 8) has a round cross-section.

7. Tool according to one of claims 1 to 5, characterized in that the clamping shaft (1) in the fastening region (2; 15, 16) of the working part (3, 18) has non-circular cross-section.

8. Tool according to claim 7, characterized in that the clamping shaft (1) in the mounting region (2, 15, 16) of the working part (3, 18) has polygonal shape.

9. Tool according to one of claims 1 to 8, characterized in that the working part (3, 18) has at least in the region of its thread grooves larger cross-section than the clamping shaft (1).

10. Tool according to one of claims 2 to 9, characterized in that at the transition from the clamping shaft (1) to the fastening region (2; 15, 16) for the working part (3, 18) a chamfer, a rounding or the like is provided.

11. Tool according to one of claims 2 to 10, characterized in that the fastening region (15, 16) of the clamping shank (1) is stepped.

12. Tool according to one of claims 1 to 10, characterized in that the fastening region (2) of the clamping shank (1) has increasingly tapered cross-section.

13. Tool according to one of claims 1 to 12, characterized in that the thread grooves having region (5) of the working part (3, 18) has polygonal shape.

14. Tool according to one of claims 1 to 13, characterized in that the working part (3, 18) is provided with a Anschnitteil (4).

15. Tool according to one of claims 1 to 14, characterized in that the working part (3, 18) is soldered to the clamping shaft (1).

16. Tool according to one of claims 1 to 14, characterized in that the working part (3, 18) is glued to the clamping shaft (1).

17. Tool according to one of claims 1 to 14, characterized in that the working part (3, 18) is shrunk onto the clamping shaft (1).

18. Tool according to one of claims 1 to 17, characterized in that the working part (3, 18) consists of hard metal.

19. Tool according to one of claims 1 to 18, characterized in that the clamping shaft (1) is provided with at least one inner coolant supply (21).

20. Tool according to claim 19, characterized in that the coolant supply (21) opens into the end face of the clamping shank (1).

21. Tool according to one of claims 1 to 20, characterized in that the working part (3, 18) rests against an annular shoulder (17) of the clamping shank (1).