This application claims priority to Japanese Patent Application Nos. 2005-356972, filed on Dec. 9, 2005, 2005-356978, filed on Dec. 9, 2005, and 2006-219741, filed on Aug. 11, 2006. The entire disclosures of Japanese Patent Application No. 2005-356972, 2005-356978 and 2006-219741 are hereby incorporated herein by reference.
1. Field of the Invention
The present invention generally relates to a flanged housing member in which a flange is disposed at one end of a trunk portion. More specifically, the present invention relates to ironing process, which is a kind of cold workings, that is being used to form a flange portion on a tubular trunk portion in which the flange portion and the trunk portion are formed as a one-piece, unitary member.
2. Background Information
A vehicle power train includes a rotation torque transmitting device that often has a constant-velocity joint. The constant-velocity joint sometimes has an outer ring that is a flanged housing member having a trunk portion with a blind bore and a flange protruding outward from the closed end of the trunk portion portion. The blind bore of the trunk portion can be provided with a plurality of tracks or grooves formed in its internal surface such that a gauge guide surface is formed between the tracks or grooves.
One conventional method for forming such a flanged housing member involves first forming the internal and external surfaces of the trunk portion and then thereafter welding a flange to one end of the trunk portion to close the end of the trunk portion. However, this is disadvantageous from the aspect of cost in that two components, i.e., a flange and a trunk portion, are required to be welded together.
Also, another conventional method involves a hot-forging process in which a flanged forged material is first formed with a through-hole. Thereafter, the external surface of the flanged forged material is machined to achieve a prescribed outside diameter and to obtain a prescribed flange and other components. In this method, the tracks or grooves and the gauge guide surfaces in the internal surface are formed by broaching and performing induction hardening. Then, in this method, a cover is attached to one end of the trunk portion. In this method, however, machining and broaching require processing time, with broaching itself being costly. Thus, this manufacturing process is inferior in terms of manufacturing costs.
Another conventional method of manufacturing a flanged cylindrical member that has a through-hole is disclosed in Japanese Laid-Open Patent Application No. 02-025223 (Japanese Patent No. 2661669). In this publication, a method is disclosed in which the flanged cylindrical member is formed using a cold forming process. This cold forming process includes using a punch to finishing the internal surface of the trunk portion. In this cold forming process, the punch is inserted into the trunk portion from the opposite side of the flange, and a die is then thereafter inserted from the same direction as the punch to shape the external surface of the trunk portion.
A conventional method of manufacturing a flanged cylindrical member that has a blind bore is disclosed in Japanese Laid-Open Patent Application No. 63-273523. In this publication, a method is disclosed in which the flanged cylindrical member is formed using a cold forming process. Here, a forged workpiece is supported with its flange side facing downward. Then, a punch for finishing the interior surface is inserted inside the trunk portion, and an ironing die divided into a plurality of parts along the axial center is disposed on the external surface to shape the external surface of the workpiece by moving the punch or the ironing die in the axial direction and passing the workpiece through the interior of the die. Thus, the internal surface of the workpiece is brought into close contact with the external surface of the punch, and the internal and external surfaces of the workpiece are finished.
In view of the above, it will be apparent to those skilled in the art from this disclosure that there exists a need for an improved flanged housing member. This invention addresses this need in the art as well as other needs, which will become apparent to those skilled in the art from this disclosure.
It has been discovered that the above mentioned processes, have certain drawbacks. In the process disclosed in Japanese Laid-Open Patent Application No. 02-025223 (Japanese Patent No. 2661669), it has been discovered that when the external surface is formed using a die on the flanged housing member, the flange will naturally become an obstruction and ironing cannot be applied across the entire external surface. For this reason, sufficient precision tends not to be achieved overall. Also, when the product is removed from the die, the precision may be further reduced because the ironing die re-irons the external periphery.
In the process disclosed in Japanese Laid-Open Patent Application No. 63-273523 (see Claims and
The present invention was contrived to in view of these problems of the above mentioned methods. One object of the present invention is to provide a flanged housing member, and a forming method and device thereof, in which an entire external surface of the flanged housing member can be formed such that the number of components can be reduced, the lead time can be shortened, and the manufacturing process can be improved at least from the aspect of cost.
In accordance with one aspect of the present invention, a flanged component forming method is provided to form a flanged housing member. The flanged component forming method basically comprises holding a forming material having a pre-flanged forming portion that is disposed at one end of a trunk portion; sizing at least an internal surface of the trunk portion using a first die having an external forming surface and a second die having an internal forming surface; and sandwiching and pressing the pre-flanged forming portion between the first die and a flange-forming die to form a flange portion on the end of the trunk portion.
As used herein, the term “sizing” refers to applying pressure to a workpiece by using a die in order to improve dimensional precision. Also as used herein, the term “flange” commonly refers to a portion that protrudes outwardly in a radial direction from an external surface of a trunk portion. The term “closure” refers solely to a portion that closes an end portion of a trunk portion. Unless otherwise described in the present specification, the term “flange” will refer to the portion that is integrally formed with the closure for closing the end portion of the trunk portion.
These and other objects, features, aspects and advantages of the present invention will become apparent to those skilled in the art from the following detailed description, which, taken in conjunction with the annexed drawings, discloses preferred embodiments of the present invention.
Referring now to the attached drawings which form a part of this original disclosure:
Selected embodiments of the present invention will now be explained with reference to the drawings. It will be apparent to those skilled in the art from this disclosure that the following descriptions of the embodiments of the present invention are provided for illustration only and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
Referring initially to
The forming material W basically includes a cylindrical (i.e., tubular) trunk portion 1 with a blind internal bore and a pre-flanged forming portion 2 that is deformed to form a flange portion F. The trunk portion 1 and the flange portion F are formed as a one-piece, unitary member in the flanged housing member (formed article) Wa. By way of example, the formed article Wa can be used for an outer ring of a constant-velocity joint that is used into a rotating torque transmitting mechanism of a vehicle engine. Therefore, the pre-flanged forming portion 2 is disposed so as to close the opening at one end of the trunk portion 1. The trunk portions 1 of this embodiment and the following embodiments are used for the outer ring of a constant-velocity joint, and thus, the cross section of the trunk portion 1 is circular. However, the present invention can also be applied to other components, and the cross-section of the trunk portion 1 is therefore not necessarily required to be circular. A rectangular cross section or another irregular shape can be used.
As seen in
The method for forming a flanged housing member is described first. The forming material W is held on the punch 10 (“first die”), as shown in diagram (A) of
Following is a more detailed description. The flanged component forming device used in this case uses the punch 10 to hold the forming material W. The punch 10 has an external surface (also referred to as “external forming surface” for simplification of description) that constitutes a forming surface of the forming material W. The sizing die 15 is used to iron the forming material W held by the punch 10 for sizing the internal and external surfaces of the trunk portion 1 of the forming material W. Thus, the sizing die 15 has an internal surface (also referred to as “internal forming surface” for simplification of description) that constitutes a forming surface of the external surface of the trunk portion 1 of the forming material W. The flange-forming die 19 is configured and arranged for sandwiching and pressing the pre-flanged forming portion 2 against the punch 10, as shown in
The punch 10 is a pillar-shaped body disposed upright in a fixed position on the base 11, as shown in diagram (A) of
The sizing die 15 is mounted by way of the support member 17 on the press ram 16 so as to be lifted and lowered relative to the punch 10. The sizing die 15 is a ring-shaped member having a center-positioned opening 18 for ironing the trunk portion 1 of the forming material W whereby the forming material W is pressed against the external surface of the punch 10, as shown in
Alternatively, as shown in
In the present embodiment, the flange-forming die 19 is disposed on the press ram 16, and the lower surface thereof is a plate-shaped member which forms a flat pressing surface 20. However, it will be apparent to those skilled in the art from this disclosure that other configurations are possible.
Preferably, a removal member 21, such as that shown by the dotted line in
The pre-flanged forming portion 2 is preferably configured so that the outside diameter D1 of the pre-flanged forming portion 2 is equal to or less than the outside diameter D2 of the trunk portion 1, as shown in
In the present embodiment, the flange-forming die 19 that forms the pre-flanged forming portion 2 preferably performs the process of sandwiching and pressing the pre-flanged forming portion 2 immediately after the sizing die 15 has sized the entire length of the trunk portion 1, or while the sizing die 15 is moving with respect to the forming material W. The process of sandwiching and pressing by the flange-forming die 19 can also be performed midway during the sizing process performed by the sizing die 15.
Therefore, the flange-forming die 19 can be disposed directly below the press ram 16, as shown in
In other words, the sandwiching and pressing position at which the flange-forming die 19 sandwiches and presses the forming material W can be a passage position in which the punch 10 has completed sizing across the entire axial length of the trunk portion 1 of the forming material W, or can be a midway position in the axial direction of the of the trunk portion 1. As used herein, the term “passage position” refers a position that immediately follows sizing, or can be a position that occurs during the relative movement of the punch 10 and the sizing die 15.
Following is a description of the flanged component forming method will be presented in more detail.
First, the forming material W is set on the upper portion of the punch 10, and the press ram 16 is lowered as shown in diagram (A) of
Furthermore, when the press ram 16 is lowered, the pressing surface 20, which is the lower surface of the flange-forming die 19, fashions the pre-flanged forming portion 2 of the forming material W on the punch 10 to a prescribed thickness. This results in the pre-flanged forming portion 2 of the forming material W on the punch 10 to produce the formed article Wa having the flange portion F, as shown in diagram (C) of
In the present embodiment, the forming material W can thus be sized, the tracks or grooves and the gauge guide surface can be formed, and the flange portion F can all be produced in a single pressing process. Therefore, the formed article Wa can be obtained in a very simple manner. If the forming material W is temporarily detached from the punch 10 when the flange portion F is formed in another step, then the shape of the internal surface of the trunk portion 1 tends to deform after forming, and precision tends to be compromised. However, in the present embodiment, since the flange is formed without detaching the forming material W from the punch 10, a very high degree of precision is achieved across the entire length of trunk portion 1.
Since the trunk portion 1 and the flange portion F can be integrated into the formed article Wa by carrying out the formation in a single press process that includes the flange portion as well, the flange portion does not need to be welded on afterward. Also since the heat of welding is not applied, the formed article Wa with excellent strength can be formed that is thinner and more lightweight then with other types of processes that use welding. Also, not only can costs be thereby reduced, but because heat deformation does not occur, precision is improved, acoustic vibration characteristics are improved, the occurrence of joint knockings is prevented, and joint characteristics are improved in comparison to other types of processes that use welding. The number of components and steps can also be reduced.
More specifically, when a formed article is obtained by hot forging in a conventional manner, the so-called draft angle must be increased and internal burrs generated within the trunk portion 1 must be removed. Therefore, the precision of the formed article is reduced and the inner surface of the trunk portion tends to be damaged. However, since hot forging is not required to be used in the present embodiment, the draft angle does not need to be increased, the inside of the trunk portion 1 can be easily sized, high sizing precision is obtained, and a decarburized layer is not formed.
When the press ram 16 is moved upward, the distal end of the removal member 21 can engage the formed article Wa and be removed from the upper portion of the punch 10. The formed article Wa is removed from the die by an ejection mechanism (not shown).
In the present embodiment, the flange portion F is integrally formed with the closure Fa, as shown in diagram (C) of
Referring now to
In this forming method, the forming material W is first set on the upper portion of the punch 10, as shown in diagram (A) of
Next, when the press ram 16 is lowered, as shown in diagram (B) of
In the present embodiment, the flange-forming die 19 is lowered to the vicinity of the sizing die 15, and pressure is applied by the lifting mechanism. The forming material W ironed by the sizing die 15 that is held on the punch 10. Therefore, the pre-flanged forming portion 2 deformed by the pressing surface 20, which is the lower surface of the flange-forming die 19, such that the pre-flanged forming portion 2 is pressed, and the flange portion F is formed to a prescribed thickness. Specifically, the position in which the pre-flanged forming portion 2 is sandwiched and pressed in the present embodiment is different from that of the first embodiment. The pre-flanged forming portion 2 is sandwiched and pressed by the flange-forming die 19 when a distal end of the punch 10 and a back surface of the sizing die 15 are aligned at substantially the same time as sizing. In the present specification, the term “align” refers to a situation in which the distal end (upper free end surface) of the punch 10 and the back surface (upper surface facing the flange-forming die 19) of the sizing die 15 are in a matching arrangement in the movement directions of these two components.
After the flange portion F is formed, the flange-forming die 19 is raised by the lifting mechanism at the same time the press ram 16 is raised or after formation is completed. The forming material W is removed by engaging the formed article Wa with the aid of the removal member 21 disposed in a position that does not interfere with the flange-forming die 19, and detaching the article from the punch 10. The article is removed from the die by an ejection mechanism (not shown).
In the present embodiment as well, the forming material W can be sized, tracks or grooves and the gauge guide surface can be formed, and various other effects can be achieved in a single press operation in the same manner as in the first embodiment described above.
Referring now to
If the forming recess 23 for forming a flange is formed, for example, on the pressure application surface of the flange-forming die 19, as shown in diagram (A) of
Various modified examples such as those described below can be used with this embodiment. In these examples, the forming recess 23 is disposed in such a flange-forming die 19, and the forming recess 23 is used to form the pre-flanged forming portion 2.
Referring now to
The formed article Wa of the present exemplary modification has the flange portion F uniformly extending in the outward radial direction from the trunk portion 1, as shown in the views (A) and (B) of
When the pre-flanged forming portion 2 enters the forming recess 23 of the flange-forming die 19 after the forming material W has been or is being ironed by the sizing die 15, the outwardly protruding portion in the radial direction of the pre-flanged forming portion 2 is restricted by the forming recess 23, and the flange portion F is formed with a flat and circular, disc-like shape (discoid) as seen in
Referring now to
The formed article Wa of the present exemplary modification has the flange portion F with a plurality of radial protrusions 26, as shown in
Thus, the flange-forming die 19 is uses the forming recess 23 in which a plurality of concavities corresponding to the protrusions 26 are formed in the internal surface of the die. When the pre-flanged forming portion 2 is pressed inside the flange-forming die 19, the flange portion F is formed having the protrusions 26 corresponding to the shape of the forming recess 23.
Referring now to
The formed article Wa of the present exemplary modification is one in which the flange-forming die 19 is used that is substantially the same as the flange-forming die used in the second exemplary modification described above. Thus, the flange portion F is formed a shape in which three protrusions 27 protrude from the trunk portion 1. The forming material W is a material in which the pre-flanged forming portion 2 has excess material, as shown in diagrams (A) and (B) of
When the pre-flanged forming portion 2 is pressed inside the flange-forming die 19 in such a configuration, a relatively large flange portion F is formed from the excess material, and the machining allowance can therefore be reduced when the formed article is to be machined. The portion having excess material disposed in the pre-flanged forming portion 2 is not necessarily required to be disposed in uniform positions in the peripheral direction, and an irregularly shaped flange portion F can be formed by disposing the excess material in a non-uniform manner.
In the embodiment described above, an irregularly shaped flange portion F is formed by disposing excess material in the pre-flanged forming portion 2, but an irregularly shaped flange portion F can also be formed by ironing the pre-flanged forming portion 2, forming the flange portion F using the flange-forming die 19, and trimming the external periphery of the flange portion F. Machining, plastic working, and other methods can be used as the trimming method.
Such a configuration allows an irregularly shaped flange portion F to be rapidly formed in a simple manner.
Referring now to
In the prior embodiments described above, the forming material W is held by the punch 10, and the forming material W held on the punch 10 is ironed by the sizing die 15, but a reverse arrangement is also possible. In particular, the forming material W can be held by the die 15 and the forming material can be ironed by the cooperative work of the die 15 and punch 10. In other words, the first and second dies of the embodiment described above can be used in reverse to carry out the forming procedure.
The flanged component forming device of this present embodiment has the sizing die 15 holding the forming material W, as shown in diagram (A) of
The punch 10 is a columnar body that is mounted on the press ram 16, while the sizing die 15 is disposed in a fixed position. The forming material W is held in the central opening 18 of the sizing die 15. As in the first embodiment, the opening 18 has a configuration in which the substantially lower half has the tapered portion 18a, and the substantially upper half has the cylindrical portion 18b. The forming material W is held by the tapered portion 18a, which is the upper half of the opening 18.
Therefore, the forming material W is set in the lower portion of the sizing die 15, as shown in diagram (A) of
Furthermore, when the press ram 16 is lowered, the pressing surface 20, which is the upper surface of the flange-forming die 19, forms the pre-flanged forming portion 2 of the forming material W into a flange portion F having a prescribed thickness, as shown in diagram (C) of
In the present embodiment as well, the sizing of the forming material W, the forming of tracks or grooves and the gauge guide surface, and the forming of a flange can be performed in a single press operation in the same manner as in the prior embodiment described above.
Referring now to
Diagram (A) of
In the embodiments described above, since the entire forming material W is sized and the pre-flanged forming portion 2 is thereafter simply sandwiched and pressed against the punch 10 and compressed using the flange-forming die 19 to form the flange portion F, the pre-flanged forming portion 2 of the forming material W is sandwiched and pressed while supported only by the punch 10. For this reason, the corners that reach from the internal surface of the pre-flanged forming portion 2 to the internal surface of the trunk portion 1 bulge outward. Thus, cavities due to so-called shrink marks are produced, the entire forming material W moves in the forming direction from a midway point in the process in which the flange portion F is being formed, and the forming precision is reduced. Furthermore, the forming material W cannot be finished into a flat, well-formed flange portion F having a surface orthogonal to the axis, and the pre-flanged forming portion 2 having considerable volume may be required in order to obtain the desired outside diameter.
For this reason, in the present embodiment, the sizing die 15 is temporarily stopped in a state in which the upper portion of the trunk portion 1 of the forming material W has been sized, the upper portion of the trunk portion 1 of the forming material W is held by the sizing die 15 from the external periphery, the movement of the forming material W is restricted, and the pre-flanged forming portion 2 is sandwiched and pressed by the flange-forming die 19 in this state and compressed to form a flange portion F.
Following is a more detailed description. First, the forming material W is set on the upper portion of the punch 10, the press ram 16 is lowered, a first sizing is performed to a prescribed length in the axial direction, and the process is then stopped, as shown in diagram (A) of
The stop position of the sizing die 15 is preferably a position at which the distal end of the punch 10 and the back surface of the sizing die 15 are aligned. In this position, the flange portion F can be received by the punch 10, and also by the sizing die 15 during flange portion formation, and the flange portion F can be formed using the flat back surface 15a of the sizing die 15. Therefore, the occurrence of cavities produced by shrinkage can be prevented, the flange portion F can be made flatter, and the precision of the formed article Wa can be further improved.
The press ram 16 is then lowered further, as shown in diagram (D) of
In addition to the effects achieved in the embodiments described above, the present embodiment allows the shape of the internal surface of the formed trunk portion 1 to remain unchanged, the required precision to be preserved, and very high degree of precision to be achieved across the entire trunk portion 1. This is because the process is stopped after the first sizing, and the second sizing is performed to thereby size the forming material W, form the tracks or grooves and the gauge guide surface, and form the flange portion in a single press operation.
Lastly, when the flange-forming die 19 is raised and the flange-forming die 19 is separated from the formed article Wa on the punch 10, as shown in diagram (E) of
Referring now to
In the flanged component forming method described above, the forming material W is held only by the sizing die 15 from the external periphery during flange portion formation. Therefore, when pressing force is applied by the flange-forming die 19 to the forming material W, the sizing die 15 may occasionally cause positional displacement. Since this positional displacement tends to negatively affect the formation of the flange portion F, the position of the sizing die 15 is fixed in the present embodiment by using a fixing device K.
The fixing device K can be any type of fixing device as long as the sizing die 15 can be supported in a fixed position. The fixing device K preferably includes a die cushion 30.
The die cushion 30 comprises a cushion pad 31 that is coaxially disposed about the periphery of the punch 10, and a plurality of cushion pins 32 for supporting the cushion pad 31 while the cushion pad 31 can move up and down. When the sizing die 15 is at the stop position described above, the cushion pad 31 moves upward to support the sizing die 15 from below, as shown in diagram (C) of
The fixing device K can further include a hydraulic mechanism, a spring, a gas cushion, or other device used in closed die sets. Also, a stopper member (not shown) can be disposed laterally of the punch 10, assume a protruding position when the sizing die 15 is stopped, and support the sizing die 15 from below.
In this forming method as well, the forming material W is set on the upper portion of the punch 10, as shown in diagram (A) of
Next, the cushion pad 31 is raised by the cushion pins 32 toward the stopped sizing die 15 to support the sizing die 15 from below, as shown in diagram (C) of
After the flange portion F has been formed, the press ram 16 is lowered again and the trunk portion of the forming material W is subjected to a second sizing by ironing using the sizing die 15, as shown in diagram (D) of
Lastly, the flange-forming die 19 is raised and the formed article Wa is removed from the die by using an ejection mechanism (not shown), as shown in diagram (E) of
In the present embodiment as well, the forming material W can be sized, and tracks or grooves and a gauge guide surface can be formed in a single press operation in the same manner as in the first embodiment described above.
Referring now to
In this flanged component forming device, the sizing die 15 is provided with a concavity 33 for forming the flange portion F. In particular, the concavity 33 is formed in a back surface 15a of the sizing die 15 where the pressure is applied by the press ram 16 to the forming material W. Thus, the flange portion F is finished into a prescribed shape inside the concavity 33.
If the pre-flanged forming portion 2 is sandwiched and pressed between the flange-forming die 19 and the punch 10 by using the sizing die 15 that has the concavity 33, as shown in
When the concavity 33 is disposed in the sizing die 15 and the pre-flanged forming portion 2 is formed, various modified examples such as those shown in
Referring now to
In the sixth to eighth embodiments described above, the forming material W is held on the punch 10, and first and second sizing processes are performed on the forming material W while being held on the punch 10 by the sizing die 15. However, a reverse arrangement is also possible; namely, the forming material W can be held by the sizing die 15, and the forming material W can be ironed by the cooperative work of the sizing die 15 and the punch 10.
When the forming material W is set on the lower portion of the sizing die 15 and the press ram 16 is lowered, as shown in diagram (A) of
After the first sizing is completed, the processing operation of the punch 10 is temporarily stopped; the flange-forming die 19 is raised by driving means (not shown) during the stoppage, as shown in diagram (C) of
When the formation of the flange portion F is completed, the flange-forming die 19 is lowered by the driving device (not shown), as shown in diagram (D) of
In the present embodiment as well, the forming material W can be sized, the tracks or grooves and the gauge guide surface can be formed, and the flange portion can be formed in a single press operation in the same manner as in the first embodiment described above.
As seen in
As used herein, the term “grain flow” is a continuous line that extends from one side surface of the flange portion F into the interior of the flange portion F toward the protruding direction of the flange portion F, curves and returns inside the flange portion F, and then arrives at the trunk portion 1, as shown in
Therefore, the formed article Wa has the continuous grain flow G that is not severed at a midway point and has excellent strength with respect to transmitting torque. Therefore, the formed article Wa can be made thinner and more lightweight, and costs can also be reduced. In particular, since the grain flow is continuous from the flange portion F to the trunk portion 1, the strength of the flange portion F in which stress is most likely concentrated can be increased.
In accordance with the above embodiments of the present invention, sufficient precision can be achieved overall without machining the formed article Wa (flanged housing member) because the trunk portion 1 of the forming material W is ironed by the first and second dies, at least the internal surface is sized, and the pre-flanged forming portion is sandwiched and pressed between the first die and the flange-forming die to form the flange portion. Also, since the formed article Wa (flanged housing member) can be formed by cold and warm forging without the use of hot forging, the formation of a decarburized layer can be reduced and a formed article can be obtained that has high degree of precision and does not tend to have reduced strength. Furthermore, since a flange or cover member does not need to be mounted after forming, the number of components can be reduced, lead time can be shortened, and manufacturability can be made advantageous from the aspect of costs.
Moreover, as described above, if the process is temporarily stopped in a state in which the trunk portion of the forming material has been sized to a prescribed length and the formation of the flange is started during this stoppage, a flange can be formed in a state in which the forming material is held in the second die, the back surface of the second die can be used to form the flange, and a flange can be formed in a simple manner with very good precision and no shrinkage in the forming material.
While only selected embodiments have been chosen to illustrate the present invention, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made herein without departing from the scope of the invention as defined in the appended claims. For example, the size, shape, location or orientation of the various components can be changed as needed and/or desired. Components that are shown directly connected or contacting each other can have intermediate structures disposed between them. In the embodiments described above, for example, a substantially flat flange portion F is formed at the end of the trunk portion 1, but other possible options include those in which a shaft protrudes from the flange portion F as an outer ring of a constant-velocity joint. This type of formed article Wa can be obtained even in the case of a so-called housing with a shaft. However, in such a case, the shaft must be prevented from being pressed by the flange-forming die. The forming material W of the embodiments is used to form the outer ring of a constant-velocity joint, but no limit is imposed thereby, and any material can be used as long as the forming material W is one having the trunk portion 1 and the pre-flanged forming portion 2 that is disposed so as to close one end of the trunk portion 1.
Thus, the foregoing descriptions of the embodiments according to the present invention are provided for illustration only, and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
---|---|---|---|
2005-356972 | Dec 2005 | JP | national |
2005-356978 | Dec 2005 | JP | national |
2006-219741 | Aug 2006 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5374219 | Kohara et al. | Dec 1994 | A |
5632682 | Krude et al. | May 1997 | A |
Number | Date | Country |
---|---|---|
4411515 | Aug 1995 | DE |
19858324 | Mar 2000 | DE |
57-056124 | Apr 1982 | JP |
63-273523 | Nov 1988 | JP |
02-025223 | Jan 1990 | JP |
03-081043 | Apr 1991 | JP |
Number | Date | Country | |
---|---|---|---|
20070131014 A1 | Jun 2007 | US |