WO2018024417A1

WO2018024417A1 - Flow forming machine and forming method for producing a wheel

Info

Publication number: WO2018024417A1
Application number: PCT/EP2017/066433
Authority: WO
Inventors: Benedikt Nillies
Original assignee: Leifeld Metal Spinning Ag
Priority date: 2016-08-02
Filing date: 2017-07-03
Publication date: 2018-02-08
Also published as: ES2686946T3; EP3278894A1; CN109689242B; JP2019528179A; CN109689242A; EP3278894B1; US20200023419A1

Abstract

The invention relates to a flow forming machine and a forming method for producing a wheel (50) with a rim (60) from a workpiece (5), comprising a pressure mandrel (20), the exterior of which is designed to form the rim (60); a mating mandrel (12), wherein the workpiece (5) is clamped against the pressure mandrel (20) or the mating mandrel (12); a rotational drive; and at least one pressure roller (40) which can be advanced towards the workpiece (5) in order to form the rim (60). According to the invention, the pressure mandrel (20) has a sleeve-shaped circumferential element (30) which can be moved axially during the forming process, and the pressure mandrel (20) has a main support (22) on which the circumferential element (30) is mounted in an axially movable manner. A front element (24) is arranged on a free front face of the main support (22), and a radial hub (52) or a drop center (64) can be axially clamped between the front element (24) of the pressure mandrel (20) and the mating mandrel (12). A controller is provided by means of which the at least one pressure roller (40) and the circumferential element (30) of the pressure mandrel (20) can be moved axially in a matching manner relative to the workpiece (5) while forming the rim (60).

Description

DRILLING MACHINE AND FORMING METHOD FOR MANUFACTURING A WHEEL

The invention relates to a flow-forming machine for producing a wheel, in particular a vehicle wheel, with a rim of a workpiece, with a spinning chuck whose outer side is designed for molding the rim, a counter-feed which is axially movable relative to the spinning chuck, wherein the workpiece on the Driven chuck and / or the counter-chuck is axially clamped, a rotary drive for rotationally driving Drückfutter and counter-chuck with the clamped workpiece and at least one spinning roller, which is deliverable axially and radially to the workpiece for forming the rim, according to the preamble of claim 1.

The invention further relates to a forming method for producing a wheel, in particular a vehicle wheel, with a rim of a workpiece, wherein the workpiece is clamped on a spinning chuck whose outer side is designed for molding the rim, and / or a counter-chuck, with a rotary drive the clamped workpiece is set in rotation and at least one spinning roller is delivered axially and radially to the rotating workpiece, wherein the rim is formed, according to the preamble of claim 8.

Such flow-forming machines and forming methods for producing a wheel, in particular of vehicle wheels, have long been known. For example, DE 196 15 675 A1 discloses a generic method for producing a vehicle wheel from a disc-shaped blank. The workpiece is clamped in a flow-forming machine to a spinning chuck whose outer circumference an inner contour of the rim to be formed corresponds. By means of at least one spinning roller a workpiece area is formed without cutting to the spinning chuck, wherein the rim base and the side rim flanges are formed.

In the vehicle wheel industry, it is often necessary to offer a model of a vehicle wheel with different rim widths. For example, numerous vehicles on the driven rear axle require a larger wheel width than on the front axle. Furthermore, it is common for vehicles of a model to be equipped by a manufacturer with vehicle wheels of different wheel widths depending on the engine.

To produce vehicle wheels with different rim widths, it is necessary to provide different spinning chucks. This means that either several flow-forming machines are required with different spinning chucks, which is very expensive consuming. Alternatively, a flow-forming machine can be converted by replacing the spinning chuck. However, this process is time-consuming and thus costly.

From WO 2005/065049 A2 a method for producing a vehicle wheel with drop center rim is known. A drop center rim has a radial indentation in a central region. For spin forming such a deep bed rim, a multi-part spinning chuck is taught, which must be disassembled after the shaping step.

JP S60-158933 A discloses a device for spin forming with an outer forming roller and a two-part inner forming roller. Here, the inner forming roller on a static to the inner contour of the workpiece matching outer contour.

JP S58-202927 A teaches a device for forming a cylindrical workpiece by means of feeding an outer forming roll, wherein a cylindrical preform is fixed to an inner tool having a first and a second mold half.

The CN 101 934 326 B discloses a device for forming a cylindrical hollow body by means of an outer forming roller and a two-part inner Forming tool. The producible inner contour of the cylindrical workpiece in this case corresponds to the outer contour of the inner tool. The inner tool is formed in two parts from two opposite sides of the cylinder extractable parts.

US 2003/145466 A1 discloses a method for producing wheel rims, wherein a cylindrical hollow body is provided between two axially deliverable inner forming tools, a first mold is introduced by means of a first outer forming tool into the cylindrical preform and a second contour by means a second outer forming roll is introduced into the workpiece. The inner contour of the workpiece corresponds to the outer contour of the inner tool.

The invention is based on the invention to provide a flow-forming machine and a forming method for producing a wheel, with which wheels with different dimensions and shapes can be produced particularly efficiently.

The object we achieved on the one hand by a flow-forming machine with the features of claim 1 and on the other hand by a forming process with the features of claim 8. Preferred embodiments of the invention are specified in the respective dependent claims.

The flow-forming machine according to the invention is characterized in that the spinning chuck has a sleeve-shaped peripheral element, which is axially movable during forming, and that a control is provided, by means of which the at least one spinning roller and the peripheral element of the spinning chuck matched to each other during forming of the rim axially relative to Workpiece are movable.

A basic idea of the invention is to provide a variable spinning chuck during forming or pressure-rolling of the rim of a wheel, which is adjusted or moved during the re-forming. With such a variable, adjustable spinning chuck, various shapes and dimensions of a drum-shaped rim can be formed during wheel production. The spinning lining preferably has a disk-shaped front element and a sleeve-shaped peripheral element, which can be adjusted axially during forming. So the circumferential ment be moved together with the externally applied pressure roller in the same axial direction, so that almost any length of the rim can be formed. When dimensional changes of the rim thus no time and costly conversion of the flow-forming machine is more necessary. The adjustment of the sleeve-shaped peripheral element and the at least one spinning roller via an electronic control. The workpiece may be disc-shaped, with a radial hub already being preformed. Alternatively, the workpiece may be annular, with a hub attached after molding the rim.

A preferred embodiment of the invention is that the sleeve-shaped peripheral element is at least partially conical, wherein the peripheral element tapers towards the free end. In a conical design of the peripheral element so so different inner diameter for internal support of the externally acting pressure roller are available. This can be created with a very high variety of shapes, an inner contour of the rim of the rim, even undercut areas, such as those provided for a drop-center rim, can be readily formed. In this case, the conical peripheral element is moved during the forming along the axis of rotation in both directions. An outer contour of the peripheral element is largely independent of the inner contour of the rim to be formed. The cone must extend only over the largest and smallest diameter, which occur on the inner contour of the rim.

According to a development of the invention, it is advantageous that a molding area is arranged on a region of the peripheral element, which is designed to form a rim flange on the rim. The molding region has an arcuate contour, so that in this way an inner region of the rim flange to be formed is predetermined. For wheels with different lengths of the rim base, the shape of the rim flange at the edge region of the rim often remains unchanged.

In particular, for producing a deep-bed rim, it is preferred according to an embodiment of the invention that for forming an axial undercut area on the rim, the control for the relative axial movement of the at least one spinning roller and the forming element is formed, so that the at least one Pressure roller initially acts on a first diameter portion of the conical peripheral element, then acts on a second diameter range of the peripheral element, which is smaller than the first diameter portion, and then acts on a third diameter range of the peripheral element, which is greater than the second diameter range. By means of a corresponding axial adjustment of the conical circumferential element, a smaller diameter region corresponding to the spinning roller can be provided for forming a center region of the deep-bed rim. For the configuration of the two side regions, the conical peripheral element is adjusted such that larger diameter regions in the radial direction are opposite the engaged pressure roller, so that overall an axial undercut region for a drop center rim can be produced in a middle region of the rim.

According to a development of the flow-forming machine according to the invention, it is advantageous that the spinning chuck has a base support on which the peripheral element is mounted axially displaceable, and that on a free front of the base support a front element is arranged, wherein a radial hub between the spinning chuck with the front element and the counter-chuck is axially clamped. This also allows a simple change of the sleeve-shaped peripheral element, if it should be necessary for maintenance or diameter or design changes to the wheel to be manufactured.

In principle, an axial displacement of the peripheral element can take place in any desired manner. According to one embodiment variant of the invention, it is particularly preferred that at least one adjusting element, in particular a setting cylinder or a spindle drive, is provided for the axial displacement of the peripheral element on the base carrier.

Actuating cylinders, which may be actuated hydraulically or pneumatically, constitute a conventional actuator on conventional flow-forming machines. It is also possible to convert an optionally existing ejector with an axial adjusting movement for displacing the peripheral element. Alternatively, a spindle drive, so a rotary drive can be used in which by a corresponding spindle assembly, the rotational movement is converted into an axial movement. To increase the variety of forms, it is provided according to a development of the invention that the front element is exchangeably fixed to the base support. The front element can be provided corresponding to the counter-chuck for axial clamping of the workpiece on the radially extending disk or hub region. Depending on the design of the hub portion, which is preformed by casting or forging, for example, the front element and the counter-lining are suitably formed. With appropriate changes in shape, the front element but also a corresponding front panel on the counter-chuck, for example by loosening screw, easily solved and replaced by a new element. The counter-chuck can be a chuck for radial clamping when clamping an annular and / or disc-shaped workpiece.

The method according to the invention is characterized in that the spinning chuck has a sleeve-shaped circumferential element which is moved axially during the shaping of the rim, and in that, during the shaping of the rim, the at least one spinning roller and the circumferential element of the spinning chuck are moved axially relative to the workpiece. The method according to the invention can preferably be carried out on the above-described flow-forming machine according to the invention. In particular, the advantages described above with regard to flexibility and variety of shapes can be achieved.

A particularly accurate pressure-rolling is achieved according to an embodiment of the invention in that a plurality of spinning rollers evenly distributed over the circumference of the workpiece and axially offset from each other are delivered to the workpiece. Preferably, three or four spinning rollers are arranged above the circumference of the workpiece. The forming forces can thus be distributed to several spinning rollers, which allows a particularly workpiece and machine gentle forming.

In the method according to the invention, the spinning roller and the peripheral element of the spinning chuck are moved in a coordinated manner axially relative to the front element or the clamped workpiece. The method of spinning roller and peripheral element preferably takes place differently, in particular if more complex inner contours of the rim base region are produced by means of a conically formed circumferential element. In particular, for producing a wheel with drop-center rim, it is advantageous according to a variant of the invention that, for forming an axial undercut area on the rim, the at least one spinning roller first acts on a first diameter area of a conical peripheral element, then the at least one spinning roller on a second diameter area of the peripheral element which is smaller than the first diameter portion, and then engages the at least one spinning roller at a third diameter portion of the peripheral member, which is larger than the second diameter portion. The third diameter region may have a diameter size as the first diameter region.

A deep bed area on the rim can be arranged and shaped as desired over the axial length of the rim. The deep bed area can be formed not only in a central region, but also on a side region of the rim, which lies opposite the radial hub region of the disk-shaped workpiece. It is thus achieved a vehicle wheel with a rim with a relatively far outlying Tiefbettbereich, resulting in a particularly voluminous-looking vehicle. Such vehicle wheels with external deep bed area may be desirable for different wheel designs. With larger diameter portions of the conical peripheral member, the side surfaces of the deep bed portion are formed, and with a smaller diameter portion, the bottom of the deep bed portion is shaped under the action of the spinning roller.

According to a further advantageous variant of the method of the invention, it is provided that a peripheral element is used, whose axial length is smaller than the rim to be formed, and that are formed with the peripheral element wheels with different axial length of the rim. Thus, for example, with a substantially same design of the disc-shaped hub region with the inventive method without much effort different rim widths can be made from an initial workpiece.

In principle, the forming can take place with an approximately horizontal axis of rotation. A particularly accurate implementation of the forming process according to the invention is achieved according to a variant of the method, that during the forming of the workpiece about a vertical axis of rotation is set in rotation. The Position of the spinning rollers takes place substantially in the radial, horizontal direction.

The invention will be further elucidated on the basis of preferred exemplary embodiments, which are illustrated schematically in the attached drawings. In the drawings show:

Fig. 1 is a cross-sectional view of an essential part of a flow-forming machine according to the invention; and

Fig. 2 is a cross-sectional view of a vehicle wheel made according to the invention.

3a to 3c are cross-sectional views through a workpiece at different

Forming steps according to a variant of the invention;

4a to 4c cross-sectional views through a workpiece in different

Forming steps according to another variant of the invention;

Fig. 5a to 5d cross-sectional views through a workpiece in different

Forming steps according to another variant of the invention;

6a to 6e cross-sectional views through a workpiece in different

Forming steps according to another variant of the invention;

A flow-forming machine 10 according to the invention has a spinning chuck 20 and an opposite counter-chuck 12, between which a workpiece 5 with a disk-shaped hub region 6 with a central centering hole and a circumferential region 7 to be reshaped is clamped axially. The counter-chuck 12 and the spinning chuck 20 are each rotatably mounted via a drive flange 16 and 17 and connected to one, preferably one, not shown rotary drive, wherein the spinning chuck 20, the counter-chuck 12 and the clamped workpiece 5 to a vertical, central axis of rotation 2 during forming can be driven in rotation.

The spinning chuck 20 has a central base support 22, at the free end of an annular or disc-shaped front member 24 is releasably secured by screws. The front element 24, like the opposing counter-chuck 12, which is provided with a forming surface 14, is adapted to the shape of the workpiece 5 to be clamped. In a design change of the workpiece 5, in particular the hub portion 6, the counter-chuck 12 and the front member 24 can be easily solved via the screw and replaced by appropriately adapted new elements. On the molding surface 14, a first rim flange 56 of a vehicle wheel 50 to be produced can be formed.

Furthermore, the spinning chuck 20 has a sleeve-shaped peripheral element 30, which is mounted axially displaceable on the base carrier 22. For displacement, the peripheral element 30 is attached to a pusher element 28, which is displaceable axially by means of an actuating cylinder (not shown) along the axis of rotation 2 between an advanced initial position and a retracted end position, which is shown in FIG. The peripheral element 30 has an outer cone surface 32 in its front or upper region, which tapers towards the top. In a lower end or middle region, a molding region 34 is formed, which is designed to form a second rim flange 58 on the vehicle wheel 50.

To form the vehicle wheel 50 from the workpiece 5, a plurality of spinning rollers 40, only one of which is indicated schematically, are delivered radially to the peripheral region 7 of the workpiece 5. In this case, the peripheral element 30 of the spinning chuck 20 is in the overhead initial position, so that this serves as an abutment for the pressing roller 40 engaging the workpiece 5. The spinning roller 40 is axially displaced radially to some extent to form a rim portion, and a wall thickness of the peripheral portion 7 is thinned and rolled out to the rim portion. By means of a controller, depending on the movement of the spinning roller 40, the sleeve-shaped, conical peripheral element 30 moves axially, so that the desired inner diameter range is always provided as an abutment for the spinning roller 40 at the desired position. Depending on a given As seen in the length of the rim area, the peripheral element 30 remains axially stationary, so that in a further method of the spinning roller 40, the material of the workpiece 5 is formed on the molding area 34 and the second rim flange 58 is correspondingly pressed onto the hub area 6 corresponding to the first rim flange 56.

In Fig. 1, a total of three different lengths of the vehicle wheel 50 are schematically indicated to illustrate the flexibility of the flow-forming machine 10 according to the invention in wheel production. The spinning chuck 20 is thus largely independent of the vehicle wheel 50 to be formed and can be used for different axial lengths and inner contours. For the creation only the electronic control has to be adapted without the need for mechanical conversion work on the flow-forming machine 10.

In Fig. 2, a further form of a vehicle wheel 50 is shown in highly schematic form, which can be produced according to the invention. The vehicle wheel 50 has a disk-shaped hub 52 and a drum-shaped rim 60, which are arranged substantially rotationally symmetrical to a wheel axle 51. In the region of the hub 52 may be provided a center hole 54 and other holes, depending on the design.

The rim 60 is provided with a rim base 62 which extends from a first rim flange 56 to a second rim flange 58. On the rim bed 62, a deep bed area 64 is formed in a middle section. The deep bed area 64 represents a radial narrowing on the rim bed 62 and thus an undercut area 70, which is illustrated particularly schematically in FIG. 2. The deep bed area 64 can also have a different dimensioning and arrangement, in particular, it can be arranged closer to the free-standing second rim flange 58.

The deep bed region 64 has two slightly tapered side flanks 66, which extend in a radial direction and extend up to an approximately cylindrical base 68. The vehicle wheel 50 with the rim 60 and the deep bed area 64 can be manufactured with a method according to the invention with a correspondingly conical peripheral element 30 as an abutment for externally acting spinning rollers 40. The peripheral element 30 is thereby to provide the corresponding diameter range by means of a controller and corresponding actuator axially in response to the position of the spinning roller 40.

According to the process variant according to FIGS. 3 a to 3 c, a cup-shaped workpiece 5 with a radial hub region 6 and a drum-shaped peripheral region 7 is transformed by the method according to the invention into a press-rolled wheel blank according to FIG. 3 b or to the finished wheel according to FIG FIG. 3b shows an intermediate step, for example a wheel blank, before being turned on.

In the variant of the method according to FIGS. 4 a to 4 c, a half-sectionally Y-shaped workpiece 5 is used, which has a radial hub region 6 and a drum-shaped peripheral region 7 which extends on both sides of the radial hub region 6. In this process variant, a flow-forming machine can be used, in which the counter-feed is the same or substantially equal to the spinning chuck and has a movable peripheral element.

In the variant of the method according to FIGS. 5a to 5d, a disk-shaped workpiece 5, also called a blank, is provided as the starting workpiece. This is converted by folding and partial splitting to form an intermediate form shown in FIG. 5b. In this case, the radial hub portion 6 and a V-shaped peripheral portion 7 is formed. The workpiece 5 is then finally formed via the intermediate step according to FIG. 5c to the vehicle wheel 50 with a drop-bottom.

According to the further method variant according to FIGS. 6a to 6e, a tubular workpiece 5 which forms the peripheral region 7 can be used as the starting workpiece. The workpiece 5 can be clamped by a counter-chuck, which is designed as a radial chuck, such as a four-jaw chuck. The spinning chuck can thus be used for processing the entire radial inner side of the workpiece 5. According to Fig. 6e, a wheel 50 is reached, which consists solely of the drum-shaped rim 60. As far as a hub region is desired, this can be made separately and attached to the rim 60 by welding, in particular friction welding, or screwing. According to a further variant of the method, a tubular workpiece 5 according to FIG. 6a can be accommodated on both sides by means of a spinning lining according to the invention in a double-sided design and first the deep bed can be produced by pressing or profiling, so that this area of the axial holding or securing against axial displacement or for torque transmission for the subsequent flow-forming process with axial displacement of the sleeve-shaped peripheral elements is used.

Claims

1 . Flow-forming machine for producing a wheel, in particular a vehicle wheel (50), with a rim (60) of a workpiece (5), with

a spinning chuck (20), the outside of which is designed to form the rim (60),

a counter-feed (12) which is axially movable relative to the spinning chuck (20), wherein the workpiece (5) is clamped on the spinning chuck (20) and / or the counter-chuck (12),

a rotary drive for rotatably driving the spinning chuck (20) and counter - chuck (12) with the clamped workpiece (5) and

at least one spinning roller (40) which can be delivered axially and radially to the workpiece (5) for shaping the rim (60),

characterized ,

in that the spinning chuck (20) has a sleeve-shaped peripheral element (30) which can be moved axially relative to the workpiece (5) during forming, in that the spinning chuck (20) has a base carrier (22) on which the peripheral element (30) is mounted so as to be axially displaceable .

a front element (24) is arranged on a free front side of the base support (22), wherein a radial hub (52) or a deep bed (64) between the spinning lining (20) with the front element (24) and the counter-lining (12) axially is clamped, and

a control is provided by means of which, during the forming of the rim (60), the at least one spinning roller (40) and the peripheral element (30) of the spinning chuck (20) are movable relative to one another axially relative to the workpiece (5).

2. flow-forming machine according to claim 1,

characterized,

in that the sleeve-shaped peripheral element (30) is conical at least in regions, wherein the peripheral element (30) tapers towards a free end.

3. flow-forming machine according to one of claims 1 or 2,

characterized,

in that on a region of the peripheral element (30), a shaping region (34) is arranged, which is designed to form a rim flange (58) on the rim (60).

4. flow-forming machine according to one of claims 2 or 3,

characterized,

in that, for forming an axial undercut region (70) on the rim (60), the control for the relative axial movement is formed by the at least one spinning roller (40) and the peripheral element (30), so that the at least one spinning roller (40) is initially secured to one engaging the first diameter portion of the conical peripheral member (30), then engaging a second diameter portion of the peripheral member (30) which is smaller than the first diameter portion, and then engaging a third diameter portion of the peripheral member (30) larger than the second diameter portion ,

5. flow-forming machine according to one of claims 3 or 4,

characterized,

in that at least one adjusting element, in particular a setting cylinder or a spindle drive, is provided for the axial displacement of the peripheral element (30) on the base carrier (22).

6. Flow-forming machine according to one of claims 3 to 5,

characterized,

in that the front element (24) is exchangeably fixed to the base support (22).

7. forming method for producing a wheel, in particular a vehicle wheel (50), with a rim (60) of a workpiece (5), in which

the workpiece (5) is clamped on a spinning chuck (20) whose outer side is designed to shape the rim (60) and / or a counter-chuck (12),

with a rotary drive the clamped workpiece (5) is set in rotation and

at least one pusher roll (40) is delivered axially and radially to the rotating workpiece (5), wherein the rim (60) is formed,

characterized,

that the spinning chuck (20) has a sleeve-shaped circumferential element (30) which is moved axially during the shaping of the rim (60),

in that the spinning chuck (20) has a base carrier (22) on which the peripheral element (30) is displaced axially,

in that a front element (24) is arranged on a free front side of the basic carrier (22), wherein a radial hub (52) or a deep bed (64) of the workpiece (5) between the press lining (20) with the front element (24) and the Counter-chuck (12) is axially clamped, and

in that, during the shaping of the rim (60), the at least one spinning roller (40) and the peripheral element (30) of the spinning chuck (20) are moved in a coordinated manner axially relative to the workpiece (5).

8. forming method according to claim 7,

characterized,

that a plurality of pressure rollers (40) evenly distributed over the circumference of the workpiece (5) and axially offset from each other to the workpiece (5) are delivered.

9. forming method according to claim 7 or 8,

characterized,

that during molding of the rim (60), the at least one spinning roller (40) and the peripheral element (30) are moved axially differently.

10. Forming method according to one of claims 7 to 7,

characterized, in that, to form an axial undercut region (70) on the rim (60), the at least one spinning roll (40) first engages a first diameter region of the conical peripheral element (30), then the at least one spinning roll (40) engages a second diameter region of the peripheral element ( 30), which is smaller than the first diameter portion, and then engages the at least one spinning roller (40) at a third diameter portion of the peripheral member (30) which is larger than the second diameter portion.

11. Forming method according to one of claims 7 to 10,

characterized,

that a peripheral element (30) is used whose axial length is smaller than the rim (60) to be formed, and

that wheels of different axial length of the rim (60) are formed with the peripheral element (30).

12. Forming method according to one of claims 7 to 11,

characterized,

that during forming the workpiece (5) about a vertical axis of rotation (2) is set in rotation.