The present invention relates to improvements to a wheel support rolling bearing unit which supports a wheel of a vehicle on a suspension unit, and to a manufacturing method therefor. In particular, the invention realizes a construction and a method whereby deformation of a flange accompanying fitting and supporting the base end portion of a stud in a mounting hole formed in a flange formed on an outer peripheral surface of a rotation ring, can be kept unrelated to the occurrence of an unpleasant vibration and noise at the time of braking.
By means of a construction for example as shown in
Double row outer ring raceways 11a and 11b are formed on the inner peripheral surface of the outer ring 6, and a coupling flange 12 is formed on the outer peripheral surface. Such an outer ring 6 is secured to the knuckle 3 by connecting the coupling flange 12 to the knuckle 3 with the bolts 7. On the other hand, on one part of the outer peripheral surface of the hub 8 on a portion protruding from the outside end opening of the outer ring 6 (“outside” in relation to the axial direction, is the outside in the widthwise direction of the vehicle in a condition when assembled on the vehicle, the right side in the figures. On the other hand, the left side in the figures which becomes the central side in the widthwise direction of the vehicle in a condition assembled on the vehicle is called the “inside”. The same applies throughout this specification), a mounting flange 13 is formed. The wheel 1 and the rotor 2 are fixedly connected by means of the studs 9 and the nuts 10 to a mounting surface 14 being the outside surface of the two axial side surfaces of the mounting flange 13.
Specifically, round shape mounting holes 15 at a plurality of locations around the circumferential direction near the outer peripheral portion of the mounting flange 13 are respectively formed in a condition axially passing through the mounting flange 13. By inserting the studs 9 into the mounting holes 15 from the inside surface side of mounting flange 13, the male serration portion 16 formed on the outer peripheral surface towards the end of the base end (the left end in
On the outer peripheral surface of the intermediate portion of the hub 8, on the portion which faces the outside outer ring raceway 11a of the aforementioned double row outer ring raceways 11a and 11b, is formed an inner ring raceway 19a. Furthermore, on a small diameter step portion 20 formed on the inside end portion of the hub 8, an inner ring 21 is externally fitted. An inner ring raceway 19b formed on the outer peripheral surface of this inner ring 21 is made to face the inside outer ring raceway 11b of the double row outer ring raceways 11a and 11b. Furthermore, a plurality of rolling elements 22 are provided so as to roll freely between these outer ring raceways 11a and 11b, and the inner ring raceways 19a and 19b.
As shown in the figure, since this is a wheel support rolling bearing unit 5 for the driven wheel (the front wheel of a front engine front wheel drive vehicle, the rear wheel of a front engine, middle engine or rear engine, rear wheel drive vehicle, and all wheels of a four wheel drive vehicle), a spline hole 23 is formed in the central portion of the hub 8. A spline shaft 25 of a constant velocity joint 24 is inserted into this spline hole 23. When using the wheel support unit constructed in this manner, the rotor 2, and a support and a caliper (not shown in the figure) which are fixed to the knuckle 3, are assembled together to constitute the disc brake for braking. At the time of braking, a pair of pads provided on both sides of the rotor 2 are pressed against the opposite side surfaces of the rotor 2.
As the wheel support rolling bearing unit for rotatably supporting a wheel on a suspension system such as the knuckle 3, there is known a device such as shown in
Of these, in the case of a second example shown in
In the case of a third example shown in
In a fourth example as shown in
In the case of a fifth example shown in
In the case of a sixth example shown in
In the case of a seventh example shown in
In the case of an eighth example shown in
In the case of a ninth through fifteenth example shown in
Of the examples 9 through 15 shown in
Also in the case of the wheel support rolling bearing unit having any of the constructions shown above in
Therefore, conventionally, as described above, the studs 9 are inserted into the mounting holes 15 from the inside surface side of the mounting flange 13, and the male serration portions 16 provided on the outer peripheral surface of the portion towards the middle base end of the studs 9 is press fitted into the mounting holes 15. However, when the studs 9 are secured in the mounting holes 13 in this manner, the mounting holes 13 are slightly deformed. That is to say, when the male serration portion 16 of the stud 9 is press fitted into the mounting hole 15 formed in the mounting flange 13, the inner peripheral surface of the mounting hole 15 is strongly pressed in the radially outward direction of the mounting hole 15 as shown by the arrow in
Furthermore, at the portion into which the male serration portion 16 is inserted, as described above, not only is the inner peripheral surface of the mounting hole 15 pressed and expanded, but also the peripheral portion of the inner peripheral surface of the mounting hole 15 is pressed forward in the pressing direction. As a result, as shown exaggerated in
In this manner, the mounting flange 13 is deformed accompanying the press fit of the male serration portion 16 of the respective studs 9 into the respective mounting holes 15. Therefore the accuracy of the mounting surface 14 of the mounting flange 13 is poor. More specifically, the deviation of the mounting surface 14 from a virtual plane perpendicular to the rotation axis of the hubs 8a, 8b, 8c, 8d, 8e, and 8f is large. In the case where the rotor 2 is supported and secured on the mounting surface 14 with such poor accuracy, the rotational runout accuracy of the braking friction surface (both side surfaces of the outer diameter side portion) of the rotor 2 is poor, and with rotation of the hub 8a, 8b, 8c, 8d, 8e and 8f, the respective braking friction surfaces oscillate in the axial direction. As a result, partial wear of the pads and the braking friction surfaces occurs, and an abnormal noise referred to as judder occurs at the time of braking.
Heretofore as technology for preventing the occurrence of the aforementioned undesirable situation, there is known the technology disclosed in Patent Documents 1 through 3 (U.S. Pat. No. 6,415,508, Japanese Patent Application Publication No. 2002-46408 and Japanese Patent Application Publication No. 2003-326908). Of these, a first example of conventional technology disclosed in Patent Document 1 is related to a method where after press fitting the studs into the mounting holes, the swollen portion formed on the outside surface of the mounting flange accompanying this press fitting is removed by turning or grinding. A second example of the conventional technology disclosed in Patent Document 2 is related to a construction for preventing the formation of the swollen portion on the outside surface of the mounting flange accompanying the press fitting, by forming concavities around the periphery of the mounting holes in the outside surface of the mounting flange prior to press fitting the studs into the mounting holes. Furthermore, in a third example of the conventional technology disclosed in Patent Document 3, a dummy plug having a slightly smaller diameter than the male serration portion provided on the stud is press fitted into the mounting hole formed in the mounting flange, and machining of the mounting surface is performed in a condition with the mounting flange deformed. Then, the male serration portion of the stud is press fitted into the mounting hole instead of the dummy plug.
Of the abovementioned conventional technologies, in the case of the first example disclosed in Patent Document 1, the swollen portion formed on the outside surface of the mounting flange must be shaved off, so that chips and shavings which are produced at the time of turning or grinding are likely to become attached to the raceway surface. Then, if the adhered shavings or chips are left as is, it becomes difficult to maintain the durability of the wheel support rolling bearing unit. Therefore a cleaning operation is necessary to remove the shavings or chips after the turning or grinding, which causes an increase in manufacturing costs of the wheel support rolling bearing unit.
Moreover, since the turning or grinding is made in a condition with the wheel support rolling bearing unit assembled, a coolant cannot be used for performing the turning or grinding. Therefore, for example, the life of the cutting tool used in the turning is less compared to when a coolant is used, which causes an increase in manufacturing costs of the wheel support rolling bearing unit. Furthermore, the chips which are produced at the time of turning and which attach to the wheel support rolling bearing unit, come into contact with the outside surface of the mounting flange and cause damage such as scoring of the outside surface, so that there is the possibility of the flatness of the outside surface being furthermore worsened.
In the case of the second example disclosed in Patent Document 2, since the concavities are provided in the outside surface of the mounting flange, not only is the strength of the mounting flange reduced, but also it is not possible to take measures against the deformation of the mounting flange towards the warp direction.
In the case of the third example disclosed in Patent Document 3, since the male serration portion of the stud is press fitted into the mounting hole, the mounting flange is still nevertheless slightly deformed accompanying the press fit (interference). Recently, it has become necessary to make the runout of the rotor even less, and it has become necessary to make the deformation of the mounting flange even less. Therefore the case of the third example also has room for improvement.
The wheel support rolling bearing unit and manufacturing method therefor of the present invention takes into consideration the above mentioned situation, and has been invented in order to keep to a minimum the degradation in accuracy of the mounting surface of the mounting flange accompanying supporting the studs in the mounting holes.
The wheel support rolling bearing unit, which is the object of the present invention, and the wheel support rolling bearing unit to be manufactured by the manufacturing method therefore, being the object of the present invention, both comprise; a stationary ring and a rotating ring which are combined together concentric with each other and are rotatably supported relative to each other via a plurality of rolling elements; a flange provided on an outer peripheral surface of the rotating ring for fixedly supporting a wheel and a brake rotation member on a mounting surface being an axial side face thereof; and mounting holes provided at a plurality of locations around the circumferential direction of the flange in a condition axially piercing the flange.
Furthermore, in the case of the wheel support rolling bearing unit which is the object of the wheel support rolling bearing unit and manufacturing method therefor of the present invention, a base end portion of each of the plurality of studs is supported in each mounting hole by internally fitting a male serration portion provided on the base end portion of the studs into a female serration formed on the inner peripheral surface of the mounting hole.
In particular, in the wheel support rolling bearing unit according to the present invention, the mounting surface is made a flat surface perpendicular to the rotation axis of the rotating ring, by burnishing which is applied in a condition with the stationary ring, the rotating ring and the rolling elements assembled together.
Furthermore, in the case of the manufacturing method for a wheel support rolling bearing unit according to the present invention, the mounting flange is made a flat surface by subjecting the mounting surface to burnishing in a condition with the stationary ring, the rotating ring and the rolling elements assembled together.
Here burnishing is a processing method as prescribed in JIS B 0106, being a method which finishes the machined surface to a desired condition by rubbing a hard cutting tool against the machined surface (mounting surface) to thereby generate plastic flow of the machined surface, without chips being produced from the machined surface.
In the wheel support rolling bearing unit according to the present invention, the female serrations on the inner peripheral surface of the mounting holes are formed. Then, the mounting surface is made into a flat surface perpendicular to the rotation axis of the rotating ring by finishing which is applied after forming the female serrations by means of the processing jig, in the inner peripheral surface of the mounting holes.
Furthermore, in the case of the manufacturing method for a wheel support rolling bearing unit according to the present invention, the female serrations are formed in the inner peripheral surface of the mounting holes. Then, by subjecting the mounting surface to finishing, the mounting surface is made a flat surface perpendicular to the rotational axis of the rotating ring. Then the base end portions of the studs are fitted into the mounting holes.
In the wheel support rolling bearing unit according to the present invention, the female serrations on the inner peripheral surface of the mounting holes are formed in a larger diameter than that of the male serration portion, by broaching the plurality of unfinished holes formed in the flange. Then, the mounting surface is made a flat surface perpendicular to the rotational axis of the rotating ring, by finishing processing which is applied after forming the female serrations by the broaching on the inner peripheral surface of the mounting holes.
In the case of the manufacturing method for a wheel support rolling bearing unit according to the present invention, the female serrations with a larger diameter than that of the male serration portion are formed by broaching the plurality of unfinished holes formed in the flange. Then, by subjecting the mounting surface to finishing, the mounting surface is made into a flat surface perpendicular to the rotation axis of the rotating ring, after which the base end portions of the studs are fitted into the mounting holes.
In the wheel support rolling bearing unit and manufacturing method therefor according to the present invention, the female serrations and the male serration portion are of course serration engaged so as to prevent relative rotation.
According to the wheel support rolling bearing unit and manufacturing method therefor of the present invention constructed as described above, the deterioration in accuracy of the mounting surface of the flange accompanying supporting the respective studs in the flange is kept to a minimum. Moreover, the accuracy of the mounting surface can be increased as required without producing shavings. Therefore manufacturing cost increase can also be suppressed.
At first, in the case of the wheel support rolling bearing unit and manufacturing method therefor according to a first embodiment of the present invention, by burnishing in a condition with the wheel support rolling bearing unit assembled, the mounting surface is made a desired flat surface. Therefore, there is no occurrence of shavings, giving an improvement in the accuracy of the mounting surface of the mounting flange.
Furthermore, in the case of the wheel support rolling bearing unit and manufacturing method therefor according to a second embodiment of the present invention, the finishing process is applied to the mounting surface after forming the female serrations on the inner peripheral surface of the mounting holes. Therefore any deterioration in accuracy of the mounting surface accompanying machining of the female serrations can be compensated for. Moreover, regarding the male serration portion of the stud, since this is loosely fitted into the mounting hole, there is no deformation of the mounting flange accompanying fitting of the male serration portion.
Preferably in the case of implementing the wheel support rolling bearing unit according to the present invention, a retaining means for preventing the base end portion of the studs from coming out from the mounting holes, is provided between the mounting holes and the studs.
This retaining means, for example, may be an adhesive which bonds the male serration portion to the female serrations.
Alternatively, this may be an O-ring externally fitted to a portion of the stud which protrudes from the mounting surface of the flange, at an intermediate portion of the stud. In this case a chamfer or countersink is formed in the peripheral portion of the opening of the mounting hole on the mounting surface side, in order to accommodate the O-ring in at least an elastically compressed condition.
If constructed in this manner, then even in the case where the male serration portion of the studs are loosely engaged in the mounting holes, the studs can be prevented from dropping out from the mounting holes in the stage of handling the wheel support rolling bearing unit, during the time from transporting the wheel support rolling bearing unit from the manufacturing site to the vehicle assembly site, and then assembling into the vehicle suspension system.
Preferably in the case of implementing the wheel support rolling bearing unit according to the present invention, the finishing process for the mounting surface is performed while rotating the rotating ring with respect to the stationary ring, with the stationary ring, the rotating ring, and the rolling elements assembled together.
If constructed in this manner, then irrespective of errors in the assembly of the respective members (stationary ring, rotating ring, rolling elements) constituting the wheel support rolling bearing unit, the mounting surface can be highly accurately matched on the virtual plane perpendicular to the central rotation axis of the rotating ring.
As shown in
By moving the processing male serration portion 33 of the processing jig 31 from the condition shown in
In any case, when the processing male serration portion 33 is pressed into the unfinished hole 29 (press fitted) to make the mounting hole 15 having the female serrations 32 on the inner peripheral surface, the peripheral portion of the unfinished hole 29 being a portion of the mounting flange 13 is nevertheless slightly distorted (deformed). If the wheel support rolling bearing unit is assembled with this distortion unremoved, then as above-mentioned, the axial runout of the rotor 2 (refer to
Therefore, in the case of this example, after extracting the processing jig 31 from the mounting hole 15, then as shown in
In the above manner, once the mounting surface 14 has been made into a highly accurate flat surface existing in the direction perpendicular to rotation axis, the male serration portion 16 provided in the portion towards the base end of the middle portion of the stud 9 is fitted into the mounting hole 15. At this time, the stud 9 is inserted from the tip end thereof into the mounting hole 15 from the opposite side (axial inside) to the mounting surface 14, and the male serration portion 16 and the female serrations 32 are engaged by the serrations. As described above, since the diameter of the male serration portion 16 is less than the diameter of the female serrations 32, the male serration portion 16 is engaged in the female serrations 32 with a loose fit (however in a condition where relative rotation is prevented). Consequently, there is no deformation of the mounting flange 13 accompanying engagement of the serrations of the male serration portion 16 and the female serrations 32, so that the mounting surface 14 maintains the high accuracy flat surface.
However, since there is this engagement with the loose fit, there is a possibility of the stud 9 dropping out from the mounting hole 15. Therefore, in the case of this example, the male serration portion 16 and the female serrations 32 are bonded with an adhesive, so that the stud 9 cannot come out from the mounting hole 15. That is to say, in the case of this example, due to the serration engagement of the male serration portion 16 and the female serrations 32, when the stud 9 and the nut 10 (refer to
The hub 8b with the base end portion of the studs 9 secured to the mounting holes 15 in the above manner, is then assembled with the outer ring 6, the rolling elements 22, and the inner ring 21, to give the aforementioned wheel support rolling bearing unit as shown in
In the case where a rotor 2 is connected and secured to the mounting surface 14 of the mounting flange 13 fitted to the wheel support rolling bearing unit of this example, obtained as described above, axial direction oscillations of the braking friction surface of the rotor 2 can be kept to a minimum. Therefore, the aforementioned partial wear of the pads and the braking friction surfaces, and the abnormal noise referred to as judder which occurs at the time of braking, can be suppressed.
The above embodiment has been illustrated for the case where the present invention is applied to the construction shown in
That is to say, in the case of this example, after forming the female serrations 32 on the inner peripheral surface of the mounting hole 15, and before subjecting the mounting surface 14 to finishing processing, the finished product of the wheel support rolling bearing unit or the semi-finished product as shown in
The method of subjecting the mounting surface of the mounting flange to burnishing while rotating the hub after assembling in the finished product or semi-finished product of the wheel support rolling bearing unit, as with this example, is not limited to the construction as shown in
In either case, in the present example, after the hub 8 has been actually assembled in the wheel support rolling bearing unit, the mounting surface 14 is subjected to finish processing. Therefore, the mounting surface 14 can be matched highly accurately on the virtual plane perpendicular to the rotation axis of the hub 8b, even if there being erroneous assembly of the related respective members (the hub 8b, the outer ring 6, the rolling elements 22) which constitute the wheel support rolling bearing unit. Furthermore, in the case of this example, since the finishing processing for the mounting surface 14 is performed by burnishing, there is no occurrence of shavings accompanying the finishing process, and the mounting surface 14 can be made to conform with high accuracy to the virtual plane perpendicular to the rotation axis of the hub 8b. Moreover, the occurrence of the aforementioned undesirable condition accompanying adhesion of the chips to the mounting surface 14 does not arise. After subjecting the mounting surface 14 to the finishing process, then as shown in
Details other than this are the same as for the first example, and repeated description is omitted.
Next, as shown in
The details other than that the process of making the unfinished hole 29 into the mounting hole 15 is performed after assembly of the hub 8b with the other members, are the same as for the aforementioned second example including the effects due to burnishing, and hence repeated description is omitted.
In each of the above described examples, the female serrations 32 are formed on the inner peripheral surface of the unfinished hole 29 by pressing the processing jig 31 into the unfinished hole 29. However, the method of forming the female serrations 32 is not limited to this method. For example, by strongly pressing a processing jig having an appropriate shape, into a mounting flange which is not formed with the unfinished holes, so as to subject this to plastic working at the same time as a punching process, then mounting holes formed with the female serrations on the inner peripheral surface equivalent to those made by pressing the processing jig 31 into the unfinished hole 29 as mentioned above, can be formed. If the mounting holes are made by the abovementioned method, then the unfinished hole processing can be omitted, so that the mounting holes can be formed in a single step. Therefore this is advantageous from the point of production cost reduction. Furthermore, after performing punching or plastic working for processing the unfinished holes, then similarly to the case of the aforementioned respective examples, mounting holes provided with female serrations on the inner peripheral surface equivalent to the case of the respective examples, can be also formed with a processing jig having a processing male serration portion.
In the case of this example, by screwing and tightening the bolts which are inserted inwards from the outside of the wheel 1 and the rotor 2 into the threaded holes 36, the wheel 1 and the rotor 2 are connected and secured to the mounting flange 13.
Other construction and operation are the same as for the aforementioned second example including the effects due to burnishing, and hence repeated description is omitted.
Number | Date | Country | Kind |
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2004 124295 | Apr 2004 | JP | national |