EP1017518A1

EP1017518A1 - Flowturning device and method for producing internal geared wheels with two sets of inner toothing

Info

Publication number: EP1017518A1
Application number: EP98925614A
Authority: EP
Inventors: Karl Heinz PÜTZ; Bernd Stein; Heinz Steinhauer; Wilhelm Zimmermann
Original assignee: Dynamit Nobel AG; Dynamit Nobel GmbH Explosivstoff und Systemtechnik
Current assignee: Dynaform GmbH
Priority date: 1997-05-28
Filing date: 1998-05-14
Publication date: 2000-07-12
Anticipated expiration: 2018-05-14
Also published as: ATE214987T1; JP2002500564A; EP1017518B1; DE19722359A1; US6253589B1; WO1998053934A1; DE59803553D1

Abstract

The invention relates to a flowturning device (1; 101) for producing an internal geared wheel (17) with inner toothing, one set of which is slanted. The workpiece (9) is held by a retaining member (16; 116) during shaping of the first inner toothing. The workpiece (9) is held by the first toothing on the first shaping tool (2; 102) during shaping of the second inner toothing. Once the internal geared wheel (17) has been finished, the rotational coupling between both shaping tools (2, 4; 102, 104) is detached. The internal geared wheel (17) is detached from the slanted toothing(s) by means of a stripping member (18).

Description

Press-rolling device and method for producing ring gears with two internal gears

The invention relates to a pressure rolling device and a method for producing ring gears with two internal toothings arranged axially one behind the other, at least one of which is a helical toothing. A helical tooth is also to be understood as a thread.

Ring gears with internal gears made of steel alloys and other metallic materials are used in particular for power transmission in driven wheels of, for example, trucks or tractors. Ring gears of this type have internal gears that are accessible from the outside at their open ends at the front. The two internal gears can have a different diameter if the ring gear is used, for example, in a transmission. The ring gear can be a spur gear in which the teeth

ERSÄΓZBLAΠ (RULE 26) run parallel to the axis of rotation, or have a helical toothing or a thread.

WO 96/20050 describes a process for the production of internally toothed parts, in which ring gears with two internal toothings are produced by spinning rollers pressing the workpiece over molding tools. However, only ring gears with straight toothing on both sides can be produced.

The invention has for its object to improve the production of internally toothed parts in such a way that parts with two internal toothings, at least one of which is a helical toothing, are easy to manufacture.

This object is achieved with the features of claims 1 and 8, respectively.

The invention proposes a pressure rolling device which has a first and a second molding tool, each with external teeth, pressure rollers for pressing a workpiece seated on the interconnected molding tools, and a holding means which secures the workpiece against rotation during the pressure rolling of the first internal teeth on the first molding tool, having. At least one of the molding tools has helical teeth, in which the individual teeth run in the manner of a thread at an angle to the longitudinal axis of the molding tool. At least one scraper element is provided, which pushes the finished ring gear off the molding tool or tools with helical teeth with relative rotation between the molding tool and the ring gear. During the manufacture of the hollow

ERSÄΓZBLÄΪT (RULE 26) The two molds are non-rotatably coupled. After manufacture, this rotationally fixed coupling is released, so that the one molding tool rotates together with the ring gear, while the ring gear is released from the other molding tool with the aid of the stripping element. It is thereby achieved that one-piece ring gears with two internal gears, at least one of which is helical, can be produced in one operation, ie without having to reclamp the workpiece.

The holding means can be a displaceable sleeve surrounding the second molding tool. The sleeve presses the workpiece against the first mold while the first internal gear is being formed. The sleeve holds the workpiece on the molds and at the same time secures it against twisting. The sleeve is then withdrawn in order to be able to form the second internal toothing. The workpiece is then held on the mold by the first toothing.

The holding means can also be an embossing element of the first molding tool, e.g. a spur toothing. At the beginning of the forming process, the workpiece is pressed onto this spur toothing by the pressure of the pressure rollers, so that rotation of the workpiece is prevented without further holding means.

In a preferred embodiment of the invention, one of the molding tools protrudes from a tool holder, which is displaceably guided in the other molding tool and can act on the latter for rotational driving. The two molds are therefore freely accessible from one side, so that the workpiece is simple

SPARE BLADE (RULE 26) can be pushed onto the two molds and the finished ring gear can simply be pushed off the two molds. In this way, ring gears can also be produced that have a shoulder behind a toothing that has a smaller diameter than the toothing, because the ring gear is stripped off by the molding tools. The mold does not have to be pulled out through the smaller diameter heel.

In a further embodiment, the end of the second mold facing the first mold has a smaller diameter than the external toothing of the second mold. This enables a simple constructive design of the pressure rolling device, since the second molding tool is simply enclosed in an end bore of the first molding tool and, after completion of the ring gear, can also be easily pulled out of both the first molding tool and the ring gear, since the end of the molding tool is due to its smaller diameter can be moved through the internal toothing.

Exemplary embodiments of the invention are explained on the basis of the drawings.

Show it:

1 shows a first embodiment during the formation of the first toothing,

2 shows the first embodiment during the formation of the second toothing,

SPARE BLADE RULE 26 3 the stripping of the ring gear and,

Fig. 4 shows a second embodiment.

In the exemplary embodiment in FIGS. 1 to 3, the pressure-rolling device 1 has a first molding tool 2 in the form of a hollow mandrel. This is rotatably attached to the shaft of a machine. The machine is not shown in the figures; it is located on the left next to the pressure rolling device 1. The molding tool 2 has helical teeth 3 at its end facing away from the machine.

A second mold 4 runs in the central cavity of the first mold 2 and protrudes from an end opening of the first mold 2. It is attached to a shaft-side tool holder 5, which is located in the central cavity and can be rotated and axially moved by the machine. The displaceable tool holder 5 engages with a conical surface 7 in a corresponding inner cone of the first molding tool 2 for rotary driving. To produce a conical clamping between the tool holder 5 and the first molding tool 2, a hollow mandrel 8 operated by the machine is pressed against the first molding tool 2. The second molding tool 4 has parallel teeth 6 at its projecting end, which has a smaller diameter than the helical teeth 3. The two molding tools 2, 4 consist of materials containing chromium or molybdenum, which are tempered and surface-hardened.

According to Figure 1, the workpiece 9 to be formed into a ring gear is already pre-shaped such that each

ERSATZBLAπ RULE 26) a short tubular circumferential region 9a or 9b is located above the start of the toothing 3 or 6. These tubular areas 9a, 9b have a greater wall thickness than the ring gear to be produced, since the tubular areas 9a, 9b are pressed to a greater length and a smaller wall thickness. By contrast, the radial region 9c of the workpiece 9 connecting the two tube regions 9a, 9b already has the desired wall thickness, since it is not subject to any deformation.

Pressure rollers 10 made of hard metal or HSS steel form the workpiece 9 on the shaping tools 2, 4. The pressure rollers 10 are arranged in a radial plane and rotate about their central axis 11 with simultaneous feed. The pressure rollers 10 are pressed against the workpiece 9 with a radial force. The pressure applied in this way can be, for example,> 35 t. So that the pressure rollers 10 process the entire circumference of the workpiece 9 uniformly, a rotary relative movement between the workpiece 9 and the pressure rollers 10 must take place. For this purpose, either the shaping tools 2, 4 with the workpiece 9 held thereon can be rotated, or the pressure rollers 10 can be moved around the workpiece 9.

A tailstock-side mandrel 12 of the machine has a spring assembly 13 which is arranged around a centering pin 12a of the tailstock-side mandrel 12. The centering pin 12 engages in an end centering opening 14 of the second mold 4. The mandrel 12 is axially movable. This structure forms an ejection device 15 which can release the tool holder 5 from the conical pressing with the first mold 2. The tailstock mandrel 12 and the toothing

ERSÄΓZBLÄΓT (RULE 26) tion 6 of the second mold 4 are surrounded by a displaceable holding sleeve 16 which holds the workpiece 9 on the molds 2.4 rotatably.

At the beginning of the pressure rolling operation, the workpiece 9 is pushed onto the two molds 2, 4 from the tailstock side, the ejection device 15 and the holding sleeve 16 being retracted, that is to say separated from the second mold 4. The holding sleeve 16 is then moved forward to fix the workpiece 9. It presses the workpiece 9 against the end face of the first molding tool 2. The hollow mandrel 8 on the machine side is advanced until the spring assembly 13 bears against the mandrel 12 mandrel 12, which has been moved into position, in a compressed state. This has the effect that the tool holder 5 enters into a conical clamping with the first mold 2, which leads to a rotationally fixed coupling of the two molds 2 and 4. At the same time, the spring assembly 13 of the ejection device 15 is pressurized. The first molding tool 2, the tool holder 5 with the second molding tool 4, the hollow mandrel 8, the ejection device 15 and the holding sleeve 16 thus form a rotating unit together with the workpiece 9.

The pressure rollers 10 are now moved up to the tubular region 9a of the workpiece 9, which surrounds the beginning of the helical toothing 3 of the first molding tool. Each pressure roller 10 rotates about its axis 11. The pressure rollers 10 are moved together towards the machine, whereby they push the material of the workpiece 9 in front of them and at the same time press into the helical teeth 3 of the first molding tool 2, so that in the workpiece 9 a Ent toothing ent

SPARE BLADE (RULE 26) stands. A pressure roller 10a in the end position is shown at the bottom in FIG. 1, as well as the completed first internal toothing of the workpiece 9.

Figures 1 and 2 each show two processing steps. In the upper half of the figures, the pressure roller 10 and the workpiece 9 are shown at the beginning of the forming process and in the lower half of each figure at the end of the forming process.

2 shows how the second internal toothing is shaped. After the first toothing has been completed, the holding sleeve 16 is withdrawn since the workpiece 9 is now held by the first helical toothing. While the first toothing was produced in the synchronous pressing process, in which the feed direction of the pressure rollers 10 corresponds to the material flow direction, the second toothing is produced in the counter-rotating pressing process. In this case, the material flows in the opposite direction to the feed direction of the pressure rollers 10. Starting from an initial position 10b of the pressure rollers 10, these are moved towards the first molding tool 2. The material softening under the pressure roller 10 is pressed into the contour of the parallel toothing 6 and pressed in the direction of the tailstock so that the internal thread of the workpiece 9 is completely formed when the pressure rollers 10 have reached the end position 10c.

3 how the finished ring gear 17 is removed from the pressure rolling device 1 will now be explained. After the pressure rollers 10 have been moved away from the ring gear 17, the machine-side hollow mandrel 8 is moved back, so that the spring assembly 13 Tool holder 5 with the second molding tool 4, which has the parallel toothing 6, is pressed out of the conical clamping in the first molding tool 2. Due to the parallel toothing 6 of the second mold 4, this can be moved in the ring gear 17. If the second toothing 6 is a helical toothing, the releasable rotary coupling between the first mold 2 and the second mold 4 is realized in a different way, since the second mold 4 could then no longer be axially displaced in the ring gear 17. The rotary coupling can be realized, for example, with pawls which engage in the other molding tool and are withdrawn again after the ring gear 17 has been completed.

After the rotary coupling between the two shaping tools 2, 4 has been released, a stripping sleeve 18, which surrounds the first shaping tool 2, is pressed against the end face of the ring gear 17. The scraper sleeve 18 has an axial bearing 19 on its end face pressing against the ring gear 17, so that translatory, but no rotational, movements are transmitted. To detach the ring gear 17, the stripping sleeve 18 is pressed against the end face of the ring gear 17, so that it is pushed off the first mold 2 in a rotating manner. At the same time, the ring gear 17 slides in the direction of the tailstock and is thus rotated by the first molding tool 42. The loosened ring gear 17 ′, which is shown here in dashed lines, can be removed from the pressure rolling device 1 as soon as the ejection device 15 is moved to the tailstock side and is thus separated from the second molding tool 4. If the second toothing 6 is also a helical toothing, a second scraper sleeve is provided which runs on the ejection device 15 in order to detach the ring gear 17 from the second toothing in the same way.

4 shows a second exemplary embodiment of the pressure rolling device 101. The first molding tool 102 also has helical teeth 3. However, it is not designed as a hollow mandrel, but rather as a tube with an end-side central opening into which the second mold 104 engages. The second molding tool 104 has a parallel toothing 6 and is firmly connected to the tailstock-side tool mandrel 12.

To insert the workpiece into the pressure rolling device 101, the tailstock-side tool mandrel with the second molding tool 104 is first pulled out of the first molding tool 102 and the workpiece is positioned on the first molding tool 102 and then the second molding tool 104 through the workpiece into the opening of the first molding tool 102 inserted. The two molding tools 102, 104 can be coupled in a rotationally fixed manner by pressing the two molding tools 102, 104 together or, for example, by means of securing pawls (not shown). The first internal toothing is then shaped as described above. A holding sleeve is not absolutely necessary, since the first molding tool 102 has an end toothing 116 against which the workpiece is pressed by the pressure rollers at the beginning of the forming process, so that the workpiece and the first molding tool 102 enter into a rotationally fixed connection. In addition, however, can still a holding sleeve may be provided. The second internal toothing is also shaped as described above. After the ring gear 17 has been completed, the rotary coupling between the two molding tools 102, 104 is released, the stripping sleeve 18 is pressed against the ring gear 17 and the first molding tool 102 is unscrewed from the internal toothing of the ring gear 17. The tailstock-side tool mandrel 12 is pulled out of the ring gear 17 so that it can be removed from the pressure rolling device 101.

Claims

PATENT CLAIMS

1. Press-rolling device (1; 101) for producing a ring gear (17) with two internal teeth, each with an external toothing (3,6) having first (2; 102) and second (4, -104) molding tool, the two molding tools (2, 4; 102, 104) can be coupled to one another in a rotationally secure manner for pressure rolling, with pressure rollers (10) for the pressure rolling of a workpiece (9) seated on the interconnected forming tools (2, 4; 102, 104) and with a holding means (16; 116) which secures the workpiece (9) against rotation during the pressure rolling of the first internal toothing on the first molding tool (2; 102), characterized in that at least one molding tool (2; 102) has helical teeth (3) and that at least one in the longitudinal direction Movable scraper member (18) is provided which, after the mutual coupling of the two molding tools (2, 4; 102, 104) is canceled, the finished ring gear (17) from a molding tool (2; 102) with Sch helical gearing

(3) with relative rotation between the mold (2; 102) and the ring gear (17).

2. Press-rolling device according to claim 1, characterized in that the holding means is a sleeve (16) surrounding the second molding tool (4; 104).

3. Press-rolling device according to claim 1 or 2, characterized in that the holding means is an embossing member (116) of the first mold (102).

4. Press-rolling device according to one of claims 1 to 3, characterized in that the stripping member (18) is a sleeve which can be displaced on a molding tool (2, -102) and is pressed with an axial bearing (19) against the ring gear (17).

5. Press-rolling device according to one of claims 1 to 4, characterized in that the one mold (4) protrudes from a tool holder (5) which is guided displaceably in the other mold (2) and acts on the latter for rotational driving.

6. Press-rolling device according to claim 5, characterized in that an ejection device (15) acts on the free end of a molding tool (4) for releasing the rotary drive after the end of manufacture.

7. Press-rolling device according to claim 5, characterized in that with the first mold

(102) coupled end of the second mold (104) has a smaller diameter than the external toothing (6) of the second mold (104), so that the second mold (104) can be pulled out of the ring gear (17).

8. A method for producing ring gears (17) with two internal gears, at least one of which is a helical gear, with a device

(1; 101), which has a first (2, -102) and a second (4; 104) molding tool each having external toothing (3,6) and pressure rollers (10) for pressing a workpiece (9) onto the outside Gears (3,6) of the molding tools (2; 102, 4; 104) with the following steps:

Placing the workpiece (9) on the molding tools (2; 102, 4, -104), rotationally fixed coupling of the two molding tools (2, -102, 4, -104),

Activating at least one holding means (16, -116) for securing the workpiece (9) against rotation during the pressure rolling of the first internal toothing on the first molding tool (2; 102), pressure rolling on the first molding tool (2; 102),

Spinning rollers on the second mold (4; 104),

Releasing the anti-rotation lock between the two molds (2, 4; 102, 104),

Pushing off the ring gear (17) from a molding tool (2; 102) with a scraper element (18) and

Separating the ring gear (17) from the other mold (4; 104).