EP0725693A1

EP0725693A1 - Method for the non-cutting production of a transmission component hub

Info

Publication number: EP0725693A1
Application number: EP94909865A
Authority: EP
Inventors: Udo Friese
Original assignee: WF Maschinenbau und Blechformtecknik GmbH and Co KG
Current assignee: WF Maschinenbau und Blechformtecknik GmbH and Co KG
Priority date: 1993-12-09
Filing date: 1994-02-23
Publication date: 1996-08-14
Anticipated expiration: 2014-02-23
Also published as: CA2161020C; ES2107817T3; CA2161020A1; JP3053219B2; EP0725693B1; JPH09506295A; US5619879A

Abstract

The invention concerns a method and device for the non-cutting production of a hub (27) for a transmission component. A sheet blank (21) which is carried by a tool (3) on a main spindle (4) and rotated relative to one or more presser rollers (9, 10) is formed to produce a cylindrical prominence (7), projecting from the sheet by pressing it with a presser roller round a pin (5) mounted on the tool or a mobile stop (8) and passing through said sheet.

Description

"Method for non-cutting production of a hub of a gear part having the hub"

The invention relates to a method for the non-cutting production of a hub of a gear part comprising the hub from a sheet metal plate.

5 Gear parts designed as sprockets or as pulleys, in particular poly-V belt pulleys, are used extensively in motor vehicle construction and are nowadays often produced from a round blank by pressing processes.

10 places. The formation of the toothing and / or the grooves is also possible in the pressing process, while the installation of the required hub is difficult. The actual hub is a sleeve-shaped in the area of the axis of rotation

15 part of the rotating disc, which connects to the shaft, shaft or a pin 1. Such a component is shown and described, for example, in US Pat. No. 2,696,740.

In the prior art, the hub of a gear part is produced by connecting a prefabricated cylindrical sleeve part to the gear part, four methods being used as the connection, namely one soldering of the two components , welding the two components, the connection of the two components by friction welding and finally it is possible to manufacture the gear part by a forging process.

15 The three first-mentioned procedures have the disadvantage that the absolutely necessary heat treatment adversely affects the actual gear part, whereby - if welding takes place - a subsequent treatment

20 work the weld is required. The

The cost of producing the hub as a turned part is relatively high.

The distortion of the gear part caused by the heat treatment must then be removed again by certain processing methods.

The proportion of rejects in gear components of such a production line that are not running flat is very high.

30

The use of forged gear parts is expensive and, in addition, undesired metal hardening occurs, ie. H. the structure is changed so that the subsequent application of the profiling

35 stanchions of the gear part, be it as a ring gear it becomes extremely difficult as pulley grooves. Finally, the surface of this gear part scales, which makes additional processing steps necessary.

In summary, it should be noted that the effort to date to fix a hub to a relatively small gear part is very complex, that the reject rate is high during manufacture and that undesirable material effects occur which affect the service life of the gear part can impair.

From the literature "Sheet metal, pipes, profiles 1980" page 660 it is known, outside! a el 1 bearer than

Manufacture sheet metal parts, these outer lamellar beams are manufactured in two press passes. A total of 27 processing stages are required to produce such an outer arm. They comprise 10 drawing, 7 calibration, 2 ironing and drawing processes, 7 cutting processes and 1 upsetting process. The structure is torn apart by the drawing work, i. H. the material structure is tired. In addition, pulling operations are usually associated with inaccuracies which can have a disadvantageous effect on a transmission part.

The object of the invention is to simplify the generic method and to carry it out in one work step without the material structure of the transmission part being influenced undesirably.

This object on which the invention is based is achieved by the teaching of the main claim. A device for performing this method is explained in the subclaim.

This object on which the invention is based is also achieved by the teaching of patent claim 3. A device for performing the method is explained in subclaims 5 and 6.

In other words, in contrast to the prior art - apart from those already mentioned

Forging and drawing processes for the production of the gear part - a one-part gear part is achieved, in which the gear part is achieved by corresponding pushing measures from the round disk running around an axial shaft while the hub is being produced.

It is not only achievable that the hub of the gear part is produced in one work step, but it is also possible that the wall thickness of the hub is greater or greater than the wall thickness of the sheet metal plate of the gear part, so that the required strength is achieved here to transmit the torque is reached.

Starting from a circular blank, the hub is molded onto the intermediate pulley product in one setting on a spinning machine. When the method is used, there is the possibility of producing intermediate pulley products for all known production methods for pulleys, since the thicknesses in the contour area and in the professional area of the intermediate pulley products are determined by the pressing method used. Exemplary embodiments of the methods according to the invention are explained below with reference to the drawings. The drawings show in

5. Fig. 1 a clamped hood in one

Pressing device, in FIG. 2 the deformation of the hood by pressing rolls, in FIG. 3 the shaping of the extra cylindrical

10 hub part by form rollers, in

4 shows the final stage of formation by using thickening rollers to achieve the cylindrical hub part

FIG. 5 shows a sheet metal plate inserted into a pressing device, in FIG. 6 the deformation of the sheet metal plate to

Fixing the same on the tool, in

7 shows a stage of the pressing process, in which the wall thickness of the gear part is reduced and, at the same time, the shaping of the hub is achieved

25 Fig. 8 the final stage of the pressing process with molded hub and possible in Fig. 9 in a schematic diagram

Variants of intermediate pulley products with different thicknesses

30 and hub positions.

1 to 4, a hood 2 is shown, which is fixed to a tool 3 of a main spindle 4 by a chuck 15 belonging to the tool 3. 35 The tool 3 has a zen in the axial direction trisch projecting tool pin 5, which rests on the inside of the clamped hood 2 or comes to rest, with a front 8 is applied to the outside of the hood 2.

The orientation of the flanges 16 and 17 adjoining the hood 2, which in the illustration in FIG. 1 run parallel to the tool pin 5 and to the axis of the main spindle 4, is immaterial.

The double arrow F shown in FIG. 1 clarifies the direction of movement of the main spindle 4 and the step-up 8 for fixing the hood 2.

FIG. 2 shows that the cover 2 is deformed in the direction of the cylindrical tool pin 5 by the action of pressure rollers 9 and 10, the deformation then being continued as far as possible by using a form roller 11 shown in FIG. 3 until the hood has wrapped around the tool pin 5. In this case, the hood 2 has partially applied as a round 6 to the top of the tool 3, while the remaining part of the hood 2 has waved around the tool pin 5 according to FIG. 3.

If, as shown in FIG. 4, this undulating region around the tool pin 5 is pressed together by thickening rollers 1 and 12 and 14, the part of the hood 2 then serving as a hub is cylindrical, the wall thickness of this cylindrical part Projection 7 can be greater than the wall thickness of the blank.

Of course it is possible in this process area lent, by withdrawing the front end 8, to achieve an outflow of the material towards the free end of the tool pin 5, so that it is also possible to make the wall thickness of the cylindrical projection 7 5 less than the wall thickness of the round blank 6.

The delivery 1 direction of the compression rollers 12 and 14 is illustrated by the arrows F in FIG. 4.

10 To summarize, it can be stated that the proposal according to the invention creates an inexpensive manufacturing process for gear parts equipped with a hub, with no structural changes within the gear part

15 due to its manufacture, at the same time the possibility is given to design the wall thickness of the hub as desired.

Starting from FIG. 4 of the above explanations 20, it is now necessary to open the cylindrical projection 7 so that it can receive a shaft or a pin. The opening of the cylindrical projection 7 can either be done by cutting off the bead of the cylindrical projection 7 shown in FIG. 4, but it is also possible to cover the end wall of the cylindrical projection 7 with holes or the like. to open so that the hub finally achieved has the bulge which contributes to the strength. Following this manufacturing process, the flanges 16 and 17 can then be machined to design the gear part.

5 to 8, 21 denotes a sheet metal plate 35 which is connected to a main spindle 22 arranged tool is arranged in that in the illustrated embodiment, the tool 23 carries a tool pin 24 onto which the sheet metal plate 21 can be placed by means of a hole provided centrally in the sheet metal plate. 25 is a front attachment which is movable back and forth and comes into contact with the tool pin 24 in its working position. The presetter 25 has in the area of the sheet metal plate 21 an outer diameter that is larger than the outer diameter of the tool pin 24, so that thereby a stop designated in the drawing with 34 is created, to which the inner part of the sheet metal plate deforms Can create sheet metal.

With 29 a chuck working together with the tool 23 is designated, which, after a pressure roller 26 has bent the outer edge region of the sheet metal plate, defines this edge area of the sheet metal plate 21, so that migration of the sheet metal plate is prevented.

The pressure roller 21 can be moved towards the tool pin 24 in the direction of the arrow shown in FIG. 6 and, as this is particularly clearly shown in FIG. 7, reduces the mean wall thickness of the sheet metal plate 21, this being due to the pressure roller 26 pressed material flows into the space which is present around the tool pin 24 and, as is clearly shown in FIG. 8, bears against the stop 34, so that a cylindrical projection 28 is thereby created which is in the intermediate pulley product the actual hub 27 according to FIG. 9 forms. From the drawing, in particular in comparison to FIGS. 6 and 8, it can be seen that the edge area of the sheet metal plate 21 defined by the chuck 29 is thicker than the central edge area of the sheet metal plate 21 and that again the cylindrical projection 28 is essential has a greater material thickness than the central edge region of the sheet metal plate 21. Depending on the size of the space between the stop 34 of the front 25

10 and the outside of the tool 23, this wall thickness of the cylindrical projection 28 can be determined.

The trailing roller 35 15 shown in FIGS. 7 and 8 prevents the material of the sheet metal plate 21 from bending up during the pressing process.

In Fig. 9, under the positions A, to _ are possible variants of intermediate pulley products

20 different thicknesses and hub positions are shown. If the pulley - as under ϊ. and shown - should have a contour area K. and possibly a perforation 11, this contour area can possibly be made with the perforation on a press from that of the

25 spinning machine intermediate pulley manufactured easily. It is also possible to create simple contour areas directly on the spinning machine using additional tool carriers.

30

In summary, it can thus be stated that, compared to the previously known production process, the spinning processes according to the invention have the following advantages:

35 1. Less machine use,

2. The material structure of the intermediate pulley product is not subject to any negative influences, such as. B. in welding and forging,

3. the inside diameter of the hub can be produced by the pressing process without subsequent rolling,

4. there are no disadvantages when profiling the pulley from previous operations,

5. There is the possibility of producing grooves or toothings on the inner diameter of the hub by means of the pressing process without post-processing, as can be seen, for example, from the illustration in FIG. 9, in which the pulling groove 32 can be produced in the pressing process.

Claims

Patent claims:

Method for the non-cutting production of a hub of a gear part having the hub from a sheet metal blank, the sheet metal blank being formed into a hood, characterized in that the hood

(2) is deformed by pressing around a central tool pin (5) into a cylindrical projection (7) protruding from a blank (6) and the cylindrical projection (7) is then opened to accommodate a coaxial shaft becomes .

Device for carrying out the method according to claim 1, characterized by a tool carried by a main spindle (4).

(3) with tool pin (5) and chuck (15), an attachment (8) arranged opposite the tool pin (5), which together with the tool pin (5) and the chuck (15) defines a hood (2) and these in sequence acting pressure rollers (9, 10), shaping rollers (11) and thickening rollers 12, 14).

Method for the non-cutting production of a hub of a gear part having the hub from a sheet metal blank, characterized in that the sheet metal blank (21) is carried by a tool (23) of a main spindle (22) and rotates relative to one or more pressure rollers (26). ) is reduced in thickness by pressing using the pressing roller (26) and becomes one of the sheet metal

CORRECTED SHEET (RULE 91) ISA/EP The cylindrical projection (28) protruding from the plate (21) is deformed around a tool pin (24) arranged on the attachment (25) or tool (23) and penetrating the sheet metal plate (21).

4. The method according to claim 3, characterized in that the edge region of the sheet metal plate (21) is fixed before carrying out the pressing process that reduces the thickness.

5. Device for carrying out the method according to claims 3 and 4, characterized by a main spindle (22).

Tool (23) with tool pin (24) and chuck (29), an attachment (25) arranged opposite the tool pin (24), the outer circumference of which is larger than the diameter of the tool pin (24) and thus a stop (34 ) and at least one pressure roller (26) which can be moved parallel to the plane of the sheet metal plate (21) onto the center of the sheet metal plate (21).

Device according to claim 5, characterized by a follower roller (35) which becomes effective at the same time as the pressure roller (26).

CORRECTED SHEET (RULE 91) ISA/EP