The present invention relates to a method and assembly for producing rings from a tube made of a metallic material, wherein the rings are provided with an axially continuous inner profile at their inner circumference and with a radial outer profile at their outer circumference.
Such a method is, for example, known from DE 102 19 441 C1. The method described in DE 102 19 441 C1 serves to produce rings that are profiled inside and outside (e.g., rolling bearing rings and transmission rings) from tubular or solid materials, and in a state completely ready for grinding. A radial outer profile can be formed by radial-axial-profile tube rolling. Therein, a tube section is processed from the outside by using a rolling tool. The flow of material generated therewith is influenced by a counterforce tool which acts on the processed tube section in an axial direction. The flow of material may be controlled in axial and radial directions, such that the evading material may be involved in formation of the profile.
For manufacturing such products as, for example, synchronizer rings, a radial inner profile may be formed simultaneously. For the production of shifting sleeves, it is proposed to machine the required inner teeth (i.e., axial profile) in a separate working step after the outer contour has been rolled completely ready for grinding.
In view of the above, it is an object of the invention to provide an enhanced method for producing rings from a metallic material, and starting from a raw material, wherein in particular axial profiles can be produced with greater ease.
This object is solved by a method for producing rings from a metallic material, wherein the rings are provided with an axially continuous inner profile at an inner circumference and with a radial outer profile at an outer circumference, and wherein the method comprises the steps of providing a tube having a tube section from which rings are to be produced; forming an inner profile of the tube section by swaging, wherein a first profile mandrel is arranged in the tube, the outer profile of the mandrel corresponds to the inner profile to be formed, and the tube section is processed from the outside by using a swaging tool; and forming a radial outer profile by rolling.
Similarly, the above object is solved by an assembly for producing rings from a metallic material (such as in performing the aforementioned method), wherein the assembly comprises: a swaging device for forming an inner profile, wherein the swaging device has a first profile mandrel arranged in the tube and having an outer profile corresponding to the inner profile of rings to be formed, and wherein the swaging device includes a swaging tool which processes the tube section from outside in order to form a tube section being profiled inside; and a rolling device for forming the outer profile.
With the inventive method and the inventive production assembly, the axial inner profile of the rings can be produced at considerably lower costs, i.e. by swaging. Since the metallic material used for producing the rings is capable of flowing to a certain extent due to the rolling method used for producing the radial outer profile, the swaging method for producing the axial inner profile is generally applicable.
As used herein, the term “swaging” has a broad meaning in this context, and includes all similar and alternative methods in which material is pressed into a profile of the profile mandrel by radial and/or axial pressure (e.g., intermittently, in some embodiments).
The axial inner profile produced in the manner described herein is surprisingly not influenced or is only slightly influenced in the subsequent rolling step for producing the radial outer profile, such that, in some cases, post-processing of the axial inner profile after the rolling step is not required.
The rings produced in the manners described and illustrated herein may in particular be shifting sleeves or clutch bodies, such as those used in transmissions.
In an alternative embodiment of the production method, the individual rings can be separated from the internally profiled tube section before the rolling step described above.
In this embodiment, it is preferred that, in the rolling step, the flow of material is controlled possibly from both axial sides near the rolling tool.
In an alternative embodiment, the rolling step described above is performed at the internally profiled tube section, wherein the finished rings are subsequently cut off.
Handling of the worked product is advantageous in this context, since a large number of single parts is not generated until the rings are finished.
Furthermore, it is advantageous if the tube is moved in an axial direction with respect to the swaging tool in the swaging step described above.
In this embodiment, the axial inner profile may be formed in a continuous working step upon the tube section. As an alternative, it is possible to move the swaging tool with respect to the tube.
It is also advantageous in some embodiments if the outer profile of the first profile mandrel is shorter than the length of the tube section, wherein the first profile mandrel is supported in a floating fashion, and wherein the tube section is moved in the axial direction with respect to the first profile mandrel in the swaging step.
With such embodiments, the length of the tube section at which the axial inner profile is formed in one piece can be configured comparatively long, such as 50 to 70 cm (20 to 28 in). However, it is also possible to form the tube section even longer, such as 2 m (6.6 ft) or more.
Compared to other methods, the utilizable portion of the basic tube can be considerably enlarged, since the length of the profiled tube section in relation to the length of the normally required clamping of the tube becomes larger.
Furthermore, it is advantageous in some embodiments that the first profile mandrel is supported in an axial direction in the swaging step, and remains substantially stationary with respect to the swaging tool.
In some embodiments, the profile mandrel is supported in a floating manner. However, in order to avoid deadlocks, a support in the axial direction may be provided, such as in the direction of movement of the tube section with respect to the first profile mandrel.
Also, in some embodiments, it is particularly advantageous if a second profile mandrel is arranged in the tube section or ring in the rolling step described above.
By arranging the second profile mandrel (as just described), the outer profile of which corresponds to the already finished axial inner profile of the tube section or ring, the rolling step may be performed such that a flow of material does not affect the integrity of the already finished inner profile.
Although it may possibly be necessary to perform post-processing of the axial inner profile after the rolling step, in some embodiments, no further post-processing is required at all, or at least no post-processing by machining is required.
In some embodiments of the production method, an axial counterforce acting on the tube section or the ring is generated in the rolling step (e.g., opposite to the direction of flow of the material caused by the rolling tools) in order to be able to control the flow of material in axial and/or radial directions.
In such embodiments, it radial elevations can be produced during the rolling of the radial outer profile, wherein the elevations exceed the outer diameter of the non-rolled tube. In other words, a radially outward flow of material can be generated in order to form a radial outer profile having comparatively large differences between maximum and minimum outer diameters while affecting the already finished axial inner profiles as little as possible.
Even if the aforementioned production method in which the first profile mandrel is shorter than the tube section to be axially profiled is preferred, it is also possible, according to some embodiments of the present invention, that the outer profile of the first profile mandrel is approximately or at least as long as the tube section, wherein the first profile mandrel moves in an axial direction together with the tube or with respect to the swaging tool in the swaging step.
With such embodiments, the axial inner profile is formed from outside by swaging tools by generating a flow of material into the radial outer profile of the profile mandrel. In these embodiments, however, no relative speed between the profile mandrel and the tube section exists, such that production accuracy can be very high.
In the embodiments described herein in which the profile mandrel is supported in a floating manner, it is possible that the shape of the radial inner profile changes slightly after the swaging at the profile mandrel, in particular if the infeed speed is not optimally adjusted.
In some embodiments of the production assembly, the outer profile of the first profile mandrel is shorter than the length of the tube section, wherein the first profile mandrel is supported in a floating manner with respect to the tube.
In the rolling device, a counterforce tool can be used, wherein the counterforce tool includes an abutting section with which an axial counterforce acting on the tube section or the ring can be generated opposite to the direction of the flow of material caused by the rolling tools, in order to control the flow of material in axial and/or radial directions.
The counterforce tool can be formed integrally with the second profile mandrel, in some embodiments.
In some embodiments of the inventive production assembly, a separating device for separating individual rings from the tube section can be utilized.
For this purpose, a separate device can be used, such as a turning tool, a milling tool, a grinding tool, a saw, and the like, for radially cutting off individual tubes.
The separating device can be arranged in front of the rolling device in order to supply individual rings profiled only at their inner circumference to the rolling device.
As an alternative, the separating device can be arranged at or behind the rolling device in order to cut off individual rings from the tube section, wherein each ring is already profiled at its inner circumference as well as at its outer circumference.
The aforementioned features and the features explained below can be used in any combination or alone without leaving the scope of the present invention.
Embodiments of the invention are shown in the drawings and explained in detail in the following description.
In
According to the production method according to some embodiments of the present invention, the tube 10 will be reshaped into a plurality of rings each having an axial inner profile at an inner circumference and a radial outer profile at an outer circumference, such as for shifting sleeves for transmissions.
The swaging device 12 comprises a swaging tool 14 with swaging jaws 16 acting from radially outside of the tube 10 in a manner generally known to those skilled in the art.
The swaging device 12 is used to generate an axial inner profile of the basic tube 10, such as a toothed inner profile.
For this purpose, a first profile mandrel 20 is supported in the swaging device 12.
The profile mandrel 20 comprises a section being comparably short in an axial direction, wherein the section includes an outer profile 22 of the mandrel 20. The outer profile 22 has a shape corresponding to the inner profile which is to be generated in the tube 10.
Further, the profile mandrel 20 shown in
During the swaging process, a certain reduction of the diameter of the basic tube 10 occurs, and the axial front end of the conical section 24 is conformed to the inner circumference of the basic tube 10, whereas the rear end of the conical section is conformed to the reduced diameter of the outer profile 22 of the mandrel 20.
The profile mandrel 20 illustrated in
In the swaging device 12, a tube section 28 of the tube 10 is provided with the axial inner profile, wherein the tube section 28 is considerably longer than the outer profile 22 of the mandrel 20. For example, the tube section 28 may have a length of 50 or 60 cm (20 to 25 in), and can even have a length of 2 m (6.6 ft) or more. In some embodiments, the tube section 28 can be indefinitely long.
Using the process described above, a major part (i.e., tube section 28) of the basic tube 10 can be profiled. In some embodiments, generally no profiling or a non-usable profiling is generated at either or both ends of the tube 10, due to a bearing point.
The internally profiled tube section 30 may now be supplied to a rolling device for producing a radial outer profile. As an alternative, it is also possible to separate individual internally profiled rings 36 from the internally profiled tube section 30, such as by a separating device 34, as shown schematically in
The rolling device 40 is arranged downstream of the swaging device 12. In the rolling device 40, an internally profiled tube section 30 is used as a basic workpiece. At the internally profiled tube 30, a radial outer profile of a ring to be produced is rolled, wherein the thus finished ring is subsequently separated from the internally profiled tube 30, such as by a separating device 34a, which is also schematically shown in
Subsequently, a further section of the internally profiled tube section 30 may be rolled in order to produce a further ring, which is then again separated.
The rolling device 40 can be structured and operated as described in document DE 102 19 441 C1, the entire contents of which are incorporated herein by reference.
The rolling device 40 shown in
Further, the rollers 42 respectively apply a radial pressure onto the tube section 30, as is schematically indicated at reference numeral 44.
One end of the tube section 30 is clamped by means of a chuck 46, and is rotated about its longitudinal axis via the chuck 46, as is schematically shown at reference numeral 48.
However, a difference vis-à-vis DE 102 19 441 C1 is that the tube section 30 has an axial inner profile 32 which shall be affected as little as possible, and in some cases to no extent or substantially no extent, during the rolling process.
For this purpose, a second profile mandrel 50 is provided in the rolling device 40. The second profile mandrel 40 has a first section with an outer profile 52 which corresponds to the axial inner profile of the tube section 30.
Further, the second profile mandrel 50 comprises an abutting section 54, the diameter of which is larger than that of the outer profile 52. The abutting section 54 abuts the free end of the tube section 30 in the axial direction. The profile mandrel 50 is also movable in the axial direction, as is schematically indicated at reference numeral 56. Therefore, the second profile mandrel 50 can simultaneously define a counterforce tool, and can be configured to apply an axial force onto the rolled section. The axial force is adapted to control the flow of material (namely in the axial direction as is shown at reference numeral 58, and in the radial direction as is shown at reference numeral 59).
Consequently, a radial outer profile 62 is produced in the rolling device 40 by the rolling processing of a section of the internally profiled tube section 30 (namely, the radial outer profile for one ring, or alternatively simultaneously for a plurality of rings). After the rolling process, the ring 60 thus finished is separated, such as by the schematically shown separating device 34a.
By applying an axial pressure onto the tube section 30 during the rolling process, the flow of material may be controlled in the axial and/or radial directions, wherein a radial outer profile 62 can finally be generated, the outer circumference of which can be in sections larger than the outer circumference of the internally profiled tube section 30.
In the embodiment shown in
The structure and function of the rolling device 40′ correspond to those of the rolling device 40 of
On the side of the ring opposing the abutting section 54′, a further counterforce tool 66 may be provided, and can be axially movable as is shown at reference numeral 68. In this manner, the ring may be influenced from both sides to control the flow of material.
The structure and function of the swaging device 12′ correspond to those of the swaging device 12 of
In the swaging device 12′ of
Herein, the first profile mandrel 20′ is clamped in a chuck 70 which is fed to the swaging device 14′ in an axial direction together with the tube 10.
Consequently, a tube section 30′ having an axial inner profile is swaged in the swaging device 12′, wherein the length of the tube section approximately corresponds to the length of the outer profile 22′ of the first profile mandrel 20′.
It is discernible that in this case, compared to the method including the floating first profile mandrel 20 (shown in
In
According to some embodiments of the present invention, the clutch body 80 is provided with an axial inner profile 32″ and a radial outer profile 62″. The axial inner profile 32″ serves to slide the body onto a respective toothed element or structure, such as a freewheel of a transmission. The radial outer profile 62″ is configured such that the clutch body 80 is readily attachable to a freewheel, such as by welding. Therefore, the radial outer profile 62″ comprises a radial flange section.
Furthermore, an outer toothed section 82 is provided on the clutch body 80, and comprises outer teeth into which the inner teeth of the shifting sleeve may be inserted in order to obtain a form fit between the clutch body 80 (and therefore the freewheel connected to the clutch body 80) and a transmission shaft, at which the shifting sleeve is supported to be axially movable, but stationary.
Number | Date | Country | Kind |
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10 2005 028 828.6 | Jun 2005 | DE | national |
This is a continuation of International Patent App. No. PCT/EP2006/005695 filed on Jun. 14, 2006, and also claims priority to German Patent App. No. 10 2005 028 828.6 filed on Jun. 15, 2005. The entire contents of both prior-filed patent applications are hereby incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/EP2006/005695 | Jun 2006 | US |
Child | 11958184 | US |