FR2665934A1 - BEARING AND ITS MANUFACTURING METHOD - Google Patents

Abstract

A ring-shaped bearing is formed in which a mounting base portion and a bearing portion supporting a shaft define an L-shaped cross section. The center of the bearing portion in the axial direction of the The shaft is disposed in a position superimposed on the base portion in the axial direction, or in the near vicinity of the position of the base portion in the axial direction. The bearing is manufactured first by subjecting a flat plate to a trimming operation to form a ring-shaped bearing blank in which the mounting base portion and the bearing portion define an L-shaped configuration and thereafter by compression molding the bearing portion of the bearing blank to the prescribed dimensions in the axial direction.

Description

PATENT DESCRIPTION

TITLE OF THE INVENTION

  BEARING AND METHOD OF MANUFACTURING

BACKGROUND OF THE INVENTION

  This invention relates to a bearing of a shaft

  carrying a lever or the like and a method of manufacturing

  More particularly, the invention

  comprises a ring-shaped bearing in which a mounting base portion and a bearing portion for supporting a shaft are formed into a shaped configuration

  of L and a method of manufacturing such a bearing.

  The safety belt device of a motor vehicle is generally provided with a retractor to take up a belt. The retractor is designed so that a reel shaft which takes up the belt is released in order to

  to be able to operate under normal conditions,

  so as to pull the belt freely from the spool shaft so that the belt does not hinder the passenger who

  In the case of an emergency such as a collapse

  however, the reel shaft is prevented from rotating by a locking means, so that the belt can not be pulled from the reel shaft.

  the belt to restrain and protect the passenger.

  Although the locking means of the reel shaft which resumes the belt itself can reliably stop the rotation of the reel shaft, there are circumstances where an excess of belt resumed

  by the spool shaft is released as a result of a trac-

  Despite the fact that the rotation of the spool shaft has been blocked. To prevent such a release of the belt as a result of traction, it has been proposed a seat belt retractor of the type shown on

Fig 4.

  As shown in FIG. 4, a seat belt retractor 1 comprises a rocker fixed to a frame 2 for tilting when it is subjected to an impact force greater than a predetermined value, a locking wheel 5 fixed coaxially to a spool shaft (not shown) which takes up a belt 4, a connecting element 6 actuated by the rocking of the rocker 3, so that a detent finger 6a thereof engages with a tooth of the wheel 5 and moves upwards by the effect of a rotational force produced by the ratchet wheel 5 and a stop element 8 rotatably mounted on the frame 2 to be rotated by the movement towards the top of the connecting element 6, so as to block the belt 4 between this element and a

wall element 7.

  With a safety belt winder 1 of this type, the stop element 8 itself blocks the belt 4

  between this element and the wall element 7 in case of emergency.

  The result is that the release of the belt 4 can be prevented in case of sudden pulling.

  In the conventional safety belt winder

  3 - rite 1 preventing the release of the belt 4 in case of sudden tension on the belt, the stop element 8

  is rotatably supported on the frame 2 by a shaft 9.

  In this case, the shaft 9 has its two ends supported on the frame 2 by a pair of bearings 10, as

shown in Fig 5.

  As shown in greater detail in Fig. 6, each bearing 10, usually formed as a ring by a jogging operation, has a ring-shaped configuration made to have a bearing portion Oa and a lob mounting base portion. , which are folded together to have an L-shaped cross section. In the folding work performed by sinking, the bending radius is comparatively large. Under these conditions, the bearing 10 is such that a central point c along the axial direction of a bearing surface a of the bearing portion l Oa is remote from the mounting base portion

lob, in terms of axial direction.

  Under these conditions, when the two ends of the shaft 9 are supported by the pair of bearings 10 as shown in FIG. 5, the centers c 1, c 2 of the support surfaces at the two bearings 10 become widely separated. to minimize the stress produced when a load is received from the shaft 9, the area of

  the bearing portion 1 Oa supporting the shaft 9 is enlarged

  Under these conditions, there is a distance of 1

  between the centers of the charges acting on the

  support surfaces at level portions i Qa

  the load of the shaft 9, in this case the distance between the centers c 1, c 2 of the parts in step l Oa. When there is such a large distance at 1 between the centers c 1, c 2 of the charges f in the two bearings 10, this inevitably leads to a torque M

  produced by the tree 9 which is important.

  4 - tions, the bending stress developed by the shaft 9 is also increased This means that the shaft 9 must be provided strong enough to withstand this bending stress To ensure the strength of the shaft 9, however, it is necessary to In particular, when the locking element 8 itself blocks the belt 4 between this element and the wall element 7 in the winder 1, a large load F is applied to the shaft 9. to achieve the shaft 9 with a particularly large diameter In these conditions, the shaft 9 not only requires to use a large

  quantity of material because of its larger size.

  you, but still the weight and the cost of the tree increase

Consequently.

  In addition, the fact of minimizing the size and the weight of the bearing 10 is desirable in view of overall reduction of the weight of the vehicle. For this purpose, it has been envisaged to make the thickness of the plate of the bearing 10 as low as However, when the thickness of the bearing plate 10 is decreased, the support surface a becomes too far from the mounting base part 1 Ob when the bearing is made by shredding as described above. the folded part A as it is shown in Fig. 6 becomes too weak because of this large distance. The consequence is that when a load acts on the shaft 9 in the z direction, the folded part A is deformed and therefore, the level portion loa and the shaft 9 move in the z direction, which

decreases the blocking force.

SUMMARY OF THE INVENTION

  An object of the present invention is to provide a bearing and a method for manufacturing it, where the stress produced by a load acting on a shaft can be minimized, with the result that the size of the shaft can be considerably reduced and that he could

to be trained at low prices.

  Another object of the present invention is to provide a bearing and a method for manufacturing it, where the weight can be decreased and sufficient strength provided. According to the present invention, the above objects are achieved by providing a ring-shaped bearing in which a mounting base portion and a shaft bearing bearing portion are formed with an L-shaped configuration, characterized in that that a center of the bearing portion in an axial direction is disposed at a position superimposed on the base portion in the axial direction, or in the near vicinity of the position of the base portion in the axial direction. Furthermore, according to the present invention, there is provided a method of manufacturing a bearing, characterized by a step of converting a flat plate into a ring-shaped bearing blank, in which a part at the base of assembly and a bearing portion carrying a shaft are formed with an L-shaped configuration and a subsequent pressing step in compression molding of the bearing portion of the bearing blank to the dimensions prescribed in a

axial direction.

  In the bearing of the present invention constructed as described above, the center of the bearing surface of the bearing in the axial direction is disposed in a position superimposed on the axial mounting base portion, or in a position very close to the mounting base part in the axial direction. Under these conditions, when the shaft is supported by the support surfaces of a pair of bearings, the distance between the centers of the support surfaces of these bearing portions is decreased by comparison with the

  As a result, the couple of

  xion produced by the load acting on the shaft is decreased, as well as the bending stress developed by the shaft. In these conditions, the diameter of the shaft can be considerably decreased In addition, even when the shaft is supported by the tier of this

  invention and another bearing such as the conventional bearing

  the distance between the centers of the parts of

  support of these bearings is decreased.

  Since the center of the support surface in the axial direction is superimposed on the axially-mounted mounting base portion or is in close proximity to the axial-mounting base portion, there is a substantial increase in the resistance of the folded part between the part in

  bearing and the part in the mounting base

  even when the thickness of the bearing plate is reduced, the folded part does not undergo warping deformation and under these conditions the bearing portion and the shaft will not move in the direction

  perpendicular to the axial direction.

  In the method of manufacturing the bearing according to the

  In the present invention, the bearing is press-molded.

  Under these conditions, the simple fact of guaranteeing the accuracy of the dimensions of the pressing mold makes it possible to improve the accuracy of the bearing hole and also to produce in series in a simple manner a bearing of

high accuracy.

  Other objects and advantages of the invention will be

  part of the description and in part

  The invention therefore comprises characteristics of

  construction, combinations of elements and an agency

  parts which will be illustrated by the embodiment 7 - described hereinafter, and the scope of the invention.

  will be indicated in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

  Fig 1 is a sectional view illustrating an embodiment of a bearing according to the present invention;

  FIG. 2 is a diagrammatic sectional view

  the way a tree is supported by the bearing of this embodiment; Fig 3 serves to describe a method of manufacturing a bearing according to the embodiment of the invention, (a) being a diagram illustrating the manufacturing step

  of a bearing blank and (b) being an illus-

  the step of pressing the bearing; Fig. 4 is a perspective view showing a seat belt retractor according to the prior art;

  FIG. 5 is a diagrammatic sectional view

  trant the manner in which a shaft is supported by a bearing according to the prior art; and Fig. 6 is a sectional view showing the bearing

according to the prior art.

  DESCRIPTION OF THE PREFERRED EXECUTION FORM

  Fig. 1 is a sectional view similar to that of Fig. 6, showing an embodiment of the present invention and Fig. 2 is a partial sectional view similar to that of Fig. 5, showing the manner in which a tree is supported using the bearing according to this

  Moreover, the components identi-

  those of the prior art shown in Figs. 4 to 6 are denoted by the same reference characters and need not be described again. An apostrophe (') is appended to the reference numbers of the parts which correspond to those of FIGS. 4 to 6, but

by being different.

  As shown in FIG. 1, a bearing 10 'according to this embodiment comprises a bearing portion 8 - 1 Oa' having a support surface a whose center c is disposed in a position superimposed on a base portion of lob 'mounting in the axial direction In these conditions, the bearing 10' has a high resistance to bending in the folded portion A between the step portion

  Oa 'and the part in mounting base lob'.

  It should be noted that the center c of the support surface a does not necessarily need to be in a position superimposed on the mounting base part lob in the axial direction. Depending on the thickness of the plate, it is sufficient to that the center c of the support surface a is located in a position very close to the base part lob ', compared with the prior art. Under these conditions, when the shaft 9 is supported

  by the steps 10 'of the embodiment as shown

  2, the centers C1, c 2 of the support surfaces in the axial direction of the two bearings 10 'at the two ends of the shaft 9 are much closer in comparison with the bearing of the prior art. conditions, the distance between the centers of the two support surfaces a, that is to say a distance a 2 between the centers c 1, c 2 of the loads f acting on the bearing 10 ', is less than the distance a 1 between the centers c 1, c 2 of the loads f acting on the level 10 of

  the prior art (i.e., a 2 <a 1).

  As regards the support of the shaft 9 by the bearings 10 'of this embodiment in which the distance a 2 between the centers c 1, c 2 of the loads f is thus reduced, the bending moment M produced by the tree 9 is also decreased by (a 2 / a 1) 2, compared with the prior art. Under these conditions, the stress of

  bending developed by the shaft 9 is also decreased.

  As the resistance of the bearing 10 'to bending is increased, the bent portion A of the bearing 10' does not undergo deformation when the load f is received from the shaft 9, even when the thickness of the bearing plate In these conditions, the bearing loa 'and the shaft 9 will not move in the z direction and consequently a sufficient locking force of the element.

  stopping 8 against the belt 4 can be ensured.

  A method for forming the bearing 10 ', according to

  this form of execution is described now.

  As shown in Fig. 3 (a), a searing step is first formed as in the prior art bearing manufacturing method, a bearing blank 10 "having a comparatively high bending radius and having a step portion

  1a and a part in mounting base 10b defined

  Then, as shown in Fig. 3 (b), the bearing blank 10 "is disposed in a lower mold 11, so that a hole loc", of a portion of Bearing loa "of the bearing blank 10" corresponds to a cylindrical protrusion 11a projecting from the lower mold 11 Then, an upper mold 12 is disposed on the upper end of the bearing portion 10 "and the bearing 10a" is compressed from above by a press acting on the upper mold 12, whereby the level portion i Qa 'is compressed to a predetermined length.

  bearing 10 'of this embodiment.

  According to this method of manufacture, the internal diameter of the hole 1 Oc of the bearing portion loa 'can be formed with great precision, simply by ensuring that the dimensions of the mold 11 have a precision

  In these circumstances, not only are

  The accuracy of the position of the shaft 9 is improved, but the possibility of shifting the shaft 9 and the bearing portion 10a 'of the bearing 10' is eliminated almost completely. Moreover, the durability of the shaft 9 and - Of the bearing 10 'is improved In addition, the manufacturing method of the invention allows to manufacture the bearing

  High precision 10 'in series and simply.

  Although an embodiment has been described in which the present invention applies to the bearing of a retractor of a seat belt device, it goes without saying that the invention can also be applied to

bearings of other trees.

  On the other hand, in the embodiment described above,

  above, the two bearings supporting the shaft 9 both use the bearing according to this invention. However, it goes without saying that the same effects can be obtained even when a bearing is a bearing of the present invention.

  invention and the other bearing is a different bearing.

  In the case of the bearing of the present invention and

  as is clear from the description below.

  above, the support surface of the bearing is brought closer to the mounting base portion by comparison with the bearing of the prior art and therefore, the bending strength is greater than with the bearing of the prior art Under these conditions, the thickness of the bearing plate can be considerably reduced and it is possible to reduce the weight of the bearing In addition, the support portion of the bearing will not be deformed by a load of the shaft when the shaft is supported, which

  prevents the tree from moving in the direction

  perpendicular to the axial direction.

  When a tree is supported by a pair of trees

  In accordance with the invention, the distance between the centers of the loads acting on the bearing is

  diminished by comparison with the level of the prior art

  laughter and therefore the bending torque and the stress of

  bending developed by the tree are decreased, by comparison

  reason with those of the prior art In these conditions,

  the diameter of the tree can be considerably reduced

  This saves on the material constituting the shaft and reduces the costs. Moreover, as the diameter of the shaft can be decreased, it is possible to realize an additional reduction in an apparatus made using the bearing. of the invention. In addition, when the bearing is applied to a retractor of a seat belt device, the bending torque acting on the shaft is small and the retractor may therefore have a greater force for

block the belt.

  In the method of manufacturing the bearing according to the present invention, the internal diameter of the hole of the bearing portion can be formed with a very large diameter.

  precision, simply by ensuring that the dimensions

  Press molds have the prescribed precision.

  In these circumstances, not only the accuracy of posi-

  The shaft is improved, but also the possibility that the shaft and the support portion of the bearing are offset are eliminated. In addition, the durability of the shaft and the bearing is improved. In addition, in the method of manufacture of the invention, a high precision bearing can be produced in series

and simply.

  As one can realize many forms of execu-

  seemingly very different from the present invention.

  without departing from the spirit of the invention and leaving its domain, it is understood that the invention is not limited by specific embodiments,

  but by the appended claims.

12 -

Claims (2)

  A ring-shaped bearing in which a mounting base portion and a bearing portion supporting a shaft are formed with an L-shaped configuration, characterized in that a center of said bearing portion in an axial direction is disposed in a position superimposed on said base portion in the axial direction, or in the near vicinity of the position   from said base portion in the axial direction.   A method of manufacturing a bearing, comprising the steps of: trimming a flat plate into a ring-shaped bearing blank, wherein a mounting base portion and a bearing portion carrying a shaft are formed with an L-shaped configuration; and then compressively molding the bearing portion of said bearing blank to the prescribed dimensions in an axial direction.