The invention relates to a method and a device for producing a ring-shaped formed part in accordance with the preamble of patent claim 1 and the preamble of patent claim 9, respectively.
A known method for producing rolling bearing rings lies in first producing a pair of rings by means of hot-forming in a forming device, one of which rings forms the internal ring and the other of which forms the external ring of a rolling bearing. One or both of the rings is/are expanded by a certain amount, for example in order to create space for the balls or rollers to be arranged between the rings.
The expansion of the rings is generally effected outside the forming device in separate devices, for example in a ring rolling device or by means of cold calibration. In addition to requiring additional devices, that kind of ring expansion also requires interfaces between the devices involved and entails a relatively large amount of handling work.
U.S. Pat. No. 6,065,322 A discloses in that regard methods and devices in which, in an expansion stage of the forming device, a ring formed in the forming device is expanded to the cross-sectional dimensions of the formed part being produced by means of a die and by means of at least one expansion punch, wherein the ring is arranged in the die and in one step the expansion punch is pressed into the ring in the axial direction and thereby expands the ring. During that procedure the material can be subjected to high stresses, which can result in material damage.
Against that background, the problem underlying the invention is to improve a method and a corresponding device for producing a ring-shaped formed part so that the expansion process takes place inside the forming device, while excessive material stresses are avoided.
That problem is solved by the method according to the invention and the device according to the invention, as defined in independent patent claim 1 and in independent patent claim 9, respectively. Especially advantageous developments and embodiments of the invention will be apparent from the respective dependent patent claims.
In respect of the method, the core of the invention lies in the following: in a method for producing a ring-shaped formed part, by means of a forming device a ring of smaller cross-sectional dimensions than the formed part being produced is formed from a blank and then, in an expansion stage of the forming device, the resulting ring is expanded to the cross-sectional dimensions of the formed part being produced by means of at least one die and by means of at least one expansion punch, wherein the ring is arranged in the die and the expansion punch is pressed into the ring in the axial direction and thereby expands the ring. According to the invention, the expansion of the ring is effected in two or more steps.
Because the expansion is carried out in an appropriately configured forming stage or expansion stage inside the forming device it is possible to produce virtually finished formed parts (expanded rings) inside the forming device. The processing steps for the expansion that are otherwise customarily carried out outside the device are entirely unnecessary. Because the expansion of the ring is effected in two or more steps, excessive material stresses and any resulting material damage can be avoided.
It is advantageous that the length of the formed part is altered at most insignificantly by the expansion.
Expediently an expansion punch is used which has at least two portions of different cross-sectional dimensions and a transition portion between each two such portions. Such an expansion punch enables the expansion process to be carried out relatively easily. Advantageously the expansion punch can have clearance gaps or angles, especially in order to reduce friction.
Expediently a die having a die chamber for receiving the ring is used, wherein the cross-sectional dimensions of the die chamber correspond to the external cross-sectional dimensions of the formed part being produced. This guarantees the dimensional accuracy of the formed part being produced.
Advantageously the expansion of the ring is effected by means of two or more dies of different dimensions and accordingly by means of two or more expansion punches of different dimensions. This allows optimum adaptation to the particular materials used.
Alternatively the expansion of the ring can also be effected by means of an expansion punch which is doubly or multiply stepped in its cross-sectional dimensions.
Advantageously the expansion is followed by a coining step, wherein the expanded ring is acted upon in the die by pressure in the axial direction by means of a portion of the expansion punch or by means of a separate coining punch, possibly in a further forming stage. The coining step ensures that the die chamber is filled without gaps, thus further improving the dimensional accuracy of the finished expanded ring or the formed part being produced. Moreover, the end faces of the ring or of the formed part being produced are smoothed, so that flawless straight end faces are obtained.
Advantageously the formed part being produced is a rolling bearing ring. The forming of the blank into the ring is advantageously effected by hot-forming at temperatures of 700° C. and above.
In respect of the device, the core of the invention lies in the following: a device for producing a ring-shaped formed part comprises a forming device having forming stages which are configured to form a ring from a blank. The forming device comprises an expansion stage which has at least one die for receiving the ring and at least one expansion punch which is arranged to be pressed axially into the ring located in the die, the ring being expandable in the die by the expansion punch. According to the invention, the expansion stage is configured to carry out the expansion of the ring in two or more steps.
Advantageously the expansion punch has at least two portions of different cross-sectional dimensions and a transition portion between each two such portions.
Advantageously the expansion stage has two or more dies of different dimensions and accordingly two or more expansion punches of different dimensions.
In the case of two or more dies, the expansion stage is to be understood as comprising two or more sub-expansion stages each having a die and an associated expansion punch.
The invention is described in greater detail below with reference to exemplary embodiments shown in the drawing, wherein:
The following observations apply in respect of the description which follows: where, for the purpose of clarity of the drawings, reference signs are included in a Figure but are not mentioned in the directly associated part of the description, reference should be made to the explanation of those reference signs in the preceding or subsequent parts of the description. Conversely, to avoid overcomplication of the drawings, reference signs that are less relevant for immediate understanding are not included in all Figures. In that case, reference should be made to the other Figures.
The diagrammatic overview in
The production of the pair of rings 41 and 42 from a length of material A in various forming stages of a forming device corresponds to the prior art and therefore requires no further explanation. The invention relates primarily to the way in which the ring 41 is expanded to form the finished formed part R and to the configuration of the expansion stage 50 of the forming device required for that purpose. This is described in detail below with reference to various exemplary variants.
An important aspect of the invention lies in the fact that the expansion of the ring 41 takes place still inside the forming device 100 in the special expansion stage 50 provided for that purpose, more specifically by means of a die and an expansion punch, wherein the ring 41 being expanded is introduced into the die and the expansion punch is pressed axially through the ring and thereby expands the ring. Because that expansion is carried out in an appropriately configured forming stage or expansion stage inside the forming device it is possible to produce virtually finished formed parts (expanded rings) inside the forming device. The processing steps for the expansion that are otherwise usually carried out outside the device are entirely unnecessary.
Expansion in one step using such an expansion punch 52 alone can lead to high material stresses and is therefore not ideal in many cases. According to the invention the expansion is therefore carried out in two or more steps, as described below.
It should also be added that in the context of the description of the illustrated embodiments, it has been assumed for reasons of clarity that the rings being produced have circular cross-sections, which is the case that is most common in practice. Accordingly, the cross-sectional dimensions of the rings, of the die and of the expansion punch are given by internal and external diameters. Expansion accordingly means an enlargement of the internal and external diameters. However, the invention is not limited to the production of rings having circular cross-sections. In the case of other cross-sectional shapes (for example triangular or polygonal), internal and external cross-sectional dimensions analogously take the place of internal and external diameters. Expansion in that case means an enlargement of the internal and external cross-sectional dimensions. It will be understood that the die and the expansion punch then have appropriately adapted internal and external cross-sectional dimensions. The cross-sectional dimensions of the die relate only to the effective cross-section, but lead-in chamfers or clearance gaps may be present.
It will be understood that the expansion can also be effected in more than two steps, in which case an expansion punch having a correspondingly larger number of stepped cylindrical portions would be used. In all cases the expansion punches can have lead-in chamfers and clearance gaps.
In the described embodiment of
The variant of
The embodiment according to the invention of
In terms of the device, this variant is implemented so that the expansion stage comprises two sub-expansion stages each having a die 451 and 551 and an associated expansion punch 452 and 552, respectively.
The larger-diameter portion 241b of the ring 241 already has the dimensions of the finished expanded ring. Accordingly, only the smaller-diameter portion 241a of the ring 241 and the transition region to the larger portion 241b needs to be expanded.
The method according to the invention described above and the corresponding device according to the invention are suitable especially for producing rolling bearing rings from rolling bearing steel. The forming in the individual forming stages is effected in hot-forming processes in a temperature range of about 700° C. and above. The integration of the expansion operation directly into the forming device makes it possible for the thermal energy absorbed during the forming process to be utilised for the expansion. Depending upon the material, the forming and especially the expansion can also take place in the cold state.
Number | Date | Country | Kind |
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01486/15 | Oct 2015 | CH | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/074120 | 10/10/2016 | WO | 00 |