Belt retractor for a safety belt device

Abstract

The invention relates to a belt retractor (10) for a safety belt device, comprising a belt reel (20) for winding and unwinding the safety belt. According to the invention, it is provided that at least one reel end (21) of the belt reel (20) is mounted in a bearing which comprises at least two bearing sections (110, 120, 150) having different play.

Claims

1. A belt retractor (10) for a safety belt device, comprising a belt reel (20) for winding and unwinding the safety belt, characterized in that at least one reel end (21) of the belt reel (20) is mounted in a bearing which comprises at least two bearing sections (110, 120, 150) having different play; and one of the two bearing sections (110) is a bearing section which is exclusively in contact with the belt reel (20) and the other bearing section of the bearing (100) and is spatially separated from all of the remaining components (12) of the belt retractor.

2. The belt retractor (10) as claimed in claim 1, characterized in that the radial play of the two bearing sections (110, 120, 150) relative to the belt reel (20) is different than the radial play of the two bearing sections relative to the remaining components (12) of the belt retractor (10).

3. The belt retractor (10) as claimed in claim 1, characterized in that the bearing properties of the two bearing sections (110, 120) differ in their capacity for deflection in a direction transverse to the rotational axis of the belt reel (20).

4. The belt retractor (10) as claimed in claim 1, characterized in that the bearing is an integral plastics bearing, a component section forms a light-duty bearing section (110) which is in permanent contact with the section of the reel end (21) mounted therein, and permanently mounts the reel end (21), wherein the light-duty bearing section (110) is exclusively in contact with the belt reel (20) and a further component section and is spatially separated from all of the remaining components (12) of the belt retractor (10), and a further component section forms a heavy-duty bearing section (120) which has a larger internal diameter than the section of the reel end (21) located there and in normal operation is separated by an annular air gap (200) from the reel end (21).

5. The belt retractor (10) as claimed in claim 4, characterized in that the belt reel (20) is arranged such that in normal operation it is spaced apart from the heavy-duty bearing section (120) both in the radial and in the axial direction.

6. The belt retractor (10) as claimed in claim 1, characterized in that one of the bearing sections is configured to move radially outwardly in a resilient manner and another one of the bearing sections is a fixed bearing section; and the internal diameter of the bearing section which is configured to move radially outwardly in a resilient manner is smaller than that of the radially fixed bearing section.

7. The belt retractor (10) as claimed in claim 6, characterized in that the bearing section which is configured to move radially outwardly in a resilient manner includes a light-duty bearing section (110), and the radially fixed bearing section includes a heavy-duty bearing section (120), and wherein the two bearing sections are located directly one behind the other in the axial direction and are connected together and wherein the two bearing sections (110, 120) are coaxially arranged.

8. The belt retractor (10) as claimed in claim 6, characterized in that an intermediate section, hereinafter called the spring section (150), is arranged between the light-duty bearing section (110) and the heavy-duty bearing section (120), which has a larger internal diameter than the section of the reel end (21) located there and in normal operation is separated by an internal annular air gap (151) from the reel end (21), is separated radially outwardly by an external annular air gap (152) from the remaining components (12) of the belt retractor (10) and is configured to move radially outwardly in a resilient manner and is retained indirectly or directly by the radially fixed heavy-duty bearing section (120) and retains the light-duty bearing section (110) in a resilient manner.

9. The belt retractor (10) as claimed in claim 6, characterized in that the bearing section which is configured to move radially outwardly in a resilient manner is a light-duty bearing section (110), and the radially fixed bearing section is a heavy-duty bearing section (120).

10. A belt retractor (10) for a safety belt device, comprising a belt reel (20) for winding and unwinding the safety belt, characterized in that at least one reel end (21) of the belt reel (20) is mounted in a bearing which comprises at least two bearing sections (110, 120, 150) having different play, mone of the two bearing sections (120) is radially fixed and without radial deflection and the other a further of the two bearing sections (110, 150) has play radially outwardly and is configured to move in a resilient manner and is indirectly or directly retained by the radially fixed bearing section.

11. A belt retractor (10) for a safety belt device, comprising a belt reel (20) for winding and unwinding the safety belt, characterized in that at least one reel end (21) of the belt reel (20) is mounted in a bearing which comprises at least two bearing sections (110, 120, 150) having different play, one of the bearing sections includes a light-duty bearing section and is in permanent contact with the section of the reel end (21) mounted therein and permanently mounts the reel end (21), one of the bearing sections includes a heavy-duty bearing section and has a larger internal diameter (D) than the section of the reel end (21) located there, and in normal operation is separated by an annular air gap (200) from the reel end (21), wherein if a belt strap pull-out force acting transversely to the rotational axis of the belt reel (20) exceeds a predetermined threshold, the reel end (21) is pulled counter to the spring force of the light-duty bearing section (110) against the heavy-duty bearing section (120) and the mounting of the reel end (21) is additionally carried out by the heavy-duty bearing section (120).

12. The belt retractor (10) as claimed in claim 11, characterized in that the light-duty bearing section (110) has play in both a radial direction and in an axial direction.

13. The belt retractor (10) as claimed in claim 11, characterized in that the heavy-duty bearing section (120) is fixed without play both radially and axially and retains the light-duty bearing section (110).

14. The belt retractor (10) as claimed in claim 11, characterized in that an intermediate section, hereinafter called the spring section (150), is arranged between the light-duty bearing section (110) and the heavy-duty bearing section (120), which has a larger internal diameter than the section of the reel end (21) located there and in normal operation is separated by an internal annular air gap (151) from the reel end (21), is separated radially outwardly by an external annular air gap (152) from the remaining components (12) of the belt retractor (10) and is configured to move radially outwardly in a resilient manner and is retained indirectly or directly by the radially fixed heavy-duty bearing section (120) and in turn retains the light-duty bearing section (110) in a resilient manner.

Description

(1) The invention is described in more detail hereinafter with reference to exemplary embodiments; in this case by way of example:

(2) FIG. 1 shows components of an exemplary embodiment of a belt retractor according to the invention with a belt reel in a three-dimensional exploded view,

(3) FIG. 2 shows an exemplary embodiment of a bearing which is suitable for mounting a reel end of the belt reel according to FIGS. 1, and

(4) FIG. 3 shows a further exemplary embodiment of a bearing suitable for mounting a reel end.

(5) In the figures, for the sake of clarity, the same reference numerals are always used for identical or comparable components.

(6) FIG. 1 shows in a schematic exploded view a belt retractor 10 which, amongst other things, has a belt reel 20, a tensioning drive 30 and an inertia coupling 35 connecting the tensioning drive 30 and the belt reel 20.

(7) FIG. 2 shows in a cross section an exemplary embodiment of a bearing 100, a reel end 21 of the belt reel 20 according to FIG. 1 being able to be mounted thereby. The other reel end of the belt reel 20, not shown in FIG. 2, may be correspondingly mounted in the same manner as the reel end 21.

(8) The bearing 100 is preferably an integral component, preferably a deep-drawn component made of metal or an integral plastics part.

(9) The bearing 100 has a light-duty bearing section 110 which is permanently in contact with the reel end 21 of the belt reel 20 and mounts this reel end 21. The light-duty bearing section 110 has play in the radial direction as is identified in FIG. 2 by an arrow with the reference numeral Y. In order to permit this radial play, a radial free space 111 is provided in the region of the light-duty bearing section 110, said radial free space separating the light-duty bearing section 110 from the remaining components 12 of the belt retractor 10.

(10) Moreover, the light-duty bearing section 110 has play in the axial direction, which in FIG. 2 is identified by an arrow X. The axial play is ensured by an axial free space 112 which in the axial direction separates the light-duty bearing section 110 from the remaining components 12 of the belt retractor 10.

(11) The function of the light-duty bearing section 110 is to mount the reel end 21 of the belt reel 20 in normal operation of the belt retractor; due to the play in the radial direction and in the axial direction the noise development produced by the bearing is low, since sound is not able to be coupled directly to the remaining components 12 of the belt retractor 10 but only indirectly via other bearing sections.

(12) The light-duty bearing section 110 is retained in a radially resilient manner by a heavy-duty bearing section 120 of the bearing 100; the heavy-duty bearing section 120 is connected via a radially outwardly extending connecting section 130 to the light-duty bearing section 110.

(13) In contrast to the light-duty bearing section 110, the heavy-duty bearing section 120 is radially fixed and is retained directly by one or more components 12 of the belt retractor 10. In other words, the heavy-duty bearing section 120 is free of radial deflection.

(14) In order to ensure fixing in the axial direction in the direction of the arrow X, the heavy-duty bearing section 120 is axially retained by a fixing section 140 on the end side, which also in turn bears directly against a component 12 of the belt retractor 10. With regard to minimal noise development, it is advantageous if the belt reel 20 and the fixing section 140 on the end side are separated from one another by a free space 141.

(15) In FIG. 2 it may also be identified that the internal diameter D of the heavy-duty bearing section 120 is larger than the external diameter d of the belt reel 20 in the region of the heavy-duty bearing section 120 so that an annular gap 200 is formed between the heavy-duty bearing section 120 and the belt reel 20. In other words, therefore, the heavy-duty bearing section 120 has radial play relative to the belt reel 20; in normal operation of the belt retractor 10, therefore, the reel end 21 and/or the belt reel 20 has no mechanical contact with the heavy-duty bearing section 120.

(16) In normal operation, the function of the heavy-duty bearing section 120 is thus limited to retaining the light-duty bearing section 110 in a resilient manner via the connecting section 130 and to permit the mounting of the belt reel 20 by the light-duty bearing section 110. The function of the light-duty bearing section 110 is to mount the reel end 21, wherein mechanical vibrations or noises due to the radial spacing from the remaining components 12 of the belt retractor 10 are able to be coupled only via the connecting section 130 and the heavy-duty bearing section 120 to the remaining components 12, so that noise damping which is as effective as possible is achieved.

(17) In other words, the function of the heavy-duty bearing section 120 in normal operation is limited, therefore, to a retaining function for the actively operating and/or actively bearing light-duty bearing section 110.

(18) If a tensile force is produced on the belt reel 20 in the direction of the arrow F in FIG. 2, for example in the case of a locking of the rotation of the belt reel 20 and a forward displacement of the vehicle occupant who is fastened by the safety belt, in a dangerous or accident situation, in the view according to FIG. 2 the belt reel 20 is pulled upwardly counter to the heavy-duty bearing section 120, which is now able to undertake the bearing of the belt reel 20 for this heavy-duty operation; this is possible since the heavy-duty bearing section 120 is in turn radially fixed and thus is not able to avoid the upward movement of the belt reel 20—in contrast to the light-duty bearing section 110. In heavy-duty operation, therefore, the bearing of the reel end 21 is carried out both by the resiliently flexible light-duty bearing section 110 and by the radially fixed, force-bearing heavy-duty bearing section 120.

(19) FIG. 3 shows a further exemplary embodiment of a bearing 100 which is suitable for mounting the reel end 21 of the belt reel 20. The bearing 100 according to FIG. 3 has a resilient intermediate section between the light-duty bearing section 110 and the connecting section 130, hereinafter called the spring section 150, which facilitates the capacity for radial deflection of the light-duty bearing section 110 relative to the radially fixed heavy-duty bearing section 120.

(20) The spring section 150 has a larger internal diameter than the section of the reel end 21 located there, so that in normal operation the spring section is separated by an internal annular air gap 151 from the reel end 21; the spring section 150 is separated by an external annular air gap 152 from the remaining components 12 of the belt retractor 10. Due to the annular air gaps 151 and 152, the spring section 150 is in turn pivotable radially outwardly and inwardly in a resilient manner, whereby—as mentioned—the capacity for radial deflection of the light-duty bearing section 110 is improved. The function of the spring section 150 is thus substantially to retain the light-duty bearing section 110 and to this end in turn to be retained by the radially fixed bearing section 130 and to dampen the sound transmission even further.

(21) Moreover, the above embodiments apply accordingly in connection with FIG. 2.

(22) Whilst the invention has been illustrated further and described in detail by preferred exemplary embodiments, the invention is not limited by the disclosed examples and other variants may be derived therefrom by the person skilled in the art without departing from the protected scope of the invention.

LIST OF REFERENCE NUMERALS

(23) 10 Belt retractor

(24) 12 Component

(25) 20 Belt reel

(26) 21 Reel end

(27) 30 Tensioning drive

(28) 35 Inertia coupling

(29) 100 Bearing

(30) 110 Light-duty bearing section

(31) 111 Free space

(32) 112 Free space

(33) 120 Heavy-duty bearing section

(34) 130 Connecting section

(35) 140 Fixing section on end side

(36) 141 Free space

(37) 150 Spring section

(38) 151 Internal annular air gap

(39) 152 External annular air gap

(40) 200 Annular air gap

(41) d External diameter

(42) D Internal diameter

(43) F Direction of arrow

(44) X Arrow

(45) Y Arrow