SE467957B - TAPER STORES FOR SUN PROTECTION - Google Patents

Description

467 957 10 15 20 25 30 35 2 causes problems. In order for the shaft journal in the bearing cup not to have too much play, the bearing sleeve, which forms the bearing bowl, must abut tightly against the shaft journal. However, due to the relatively large enclosing angle, clamping of the bearing sleeve on the shaft journal can occur due to manufacturing tolerances. Consequently, the sun visor can only be rotated with difficulty around the shaft journal. In addition, manufacturing technical problems arise if the bearing sleeve with a large surface is to abut against the shaft journal. The problems described are exacerbated if the shaft journal diameter is to be reduced. With the known construction it is thus hardly possible to use thinner shaft pins and thus to provide thinner sun protection, since it is the diameter of the pin layer which determines the thickness of the sun protection. In addition to the described disadvantages in the manufacture of the known pin bearing construction, there is another disadvantage in the form of increased wear, for example when after prolonged use some form of contamination occurs between the shaft pin and the closely spaced bearing sleeve.

From DE-OS 3 235 997 and DE-PS 3 345 764 pin bearings are also known, which comprise a bearing sleeve, a support shaft and a leaf spring. The axle pin of the support shaft has two diametrically opposite planar chamfers, which likewise form barrier surfaces and allow adjustment of the sun visor in two preferred barrier positions. In these known pin bearings, however, the leaf springs from the outside via recesses in the bearing sleeves engage with the flat chamfers on the shaft pin. This pin bearing construction allows rotation of the sun visor body around the support shaft and also longitudinal displacement on the shaft pin. However, these pin bearing constructions are extremely complicated and, above all, do not allow the supply of a sufficiently large holding force for safe adjustment of the sun visor body in a desired position. The object of the present invention is thus to provide a pin bearing for sun protection, which is technically easier to manufacture and allows the use of a shaft pin with a smaller outer diameter. 10 15 20 25 30 35 -I-ë.

O \ \ J \ O U 'I \ ~ | This object is achieved in that the bearing sleeve in a section transverse to the axial direction is rectangularly designed with flat walls, and in that the leaf spring is located opposite a flat wall.

According to the invention, the bearing sleeve is no longer designed as a bearing bowl, which abuts against the shaft journal with a large surface. On the other hand, according to the invention, an advantageous linear abutment along the axial direction is provided between the shaft pin and the inner wall of the bearing sleeve. The linear abutment and the narrow abutment surface, respectively, in cooperation with the leaf spring, have the advantage that manufacturing tolerances of the bearing sleeve and the shaft journal are more easily compensable. In addition, the linear bearing facilitates the manufacture of the bearing sleeve. A bearing sleeve, which must be precisely adapted to the curvature of the shaft journal, is considerably more difficult - and thus more costly - to manufacture. If, after prolonged use of the pin bearing according to the invention, contaminants or dirt particles are present in the interior of the bearing sleeve, a abrasive effect arises due to the linear abutment between the shaft pin and the inner wall of the bearing sleeve. That is, the contaminants are no longer clamped to the bearing surfaces, but are transported corresponding to the direction of rotation of the shaft journal to one or the other side of the wall of the bearing sleeve. In addition, there are free spaces in the corner of the bearing sleeve for absorbing such contaminants or as a reservoir for lubricants. A further advantage is provided by the flat wall of the bearing sleeve, which according to the invention is located opposite the leaf spring, in that two locking positions of the shaft pin can be provided by means of a flat chamfer. A locking position is provided when the chamfer of the shaft pin engages the wall of the bearing sleeve and a second locking position when the chamfer engages with the leaf spring.

The holding or frictional force between the shaft journal and the bearing sleeve is provided by the compressive force which the leaf spring produces and with which the built-in leaf spring is biased. In the rest position of the sun visor, 467 957 10 15 20 25 30 35 4 abuts, for example, the flat chamfer of the shaft pin against the flat wall or the leaf spring. The compressive force is further increased when the shaft journal against the spring force of the leaf spring is turned out of the locking position. This additional compressive force is determined by the leaf path's spring path and spring constant. The spring path is determined by how long the tangential chamfer is retracted relative to the rounded surface of the shaft pin and its diameter, respectively, in the direction of the shaft center point. That is, outside the locking position, the total shaft diameter of the shaft pin determines the holding force, and when transitioning from the locking position to the position of use of the sun visor, one of the joint edges between the chamfer and the pin surface must be overcome. The holding force of the sun visor is not determined by the surface of the bearing sleeve or the shaft journal.

It would thus in principle be possible to arrange a shaft with a smaller outer diameter at the known bearing pin of the said type. However, this is hindered, as mentioned above, on the one hand due to manufacturing technical problems in the manufacture of the bearing bowl rounding.

In addition, the holding force can not be dimensioned exactly, since the angle of inclination of the bearing cup results in a clamping action reminiscent of that of a drum brake. Even small manufacturing tolerances of the bearing cup or shaft pin cause varying holding force. On the other hand, the pin bearing according to the invention with the linear abutment surface lacks this disadvantage, and consequently shaft pins with a smaller diameter can be used with precisely predictable holding forces, whereby additional, undefinable clamping forces due to the enclosing angle do not occur.

Thus, the pin bearing according to the invention with the linear abutment surface between the shaft pin and the bearing sleeve allows construction of thinner sun protection.

In addition, the individual walls of the bearing cup do not have to be exactly perpendicular to each other either, since only the linear abutment of the shaft journal against one or more walls and the leaf spring, respectively, is decisive. When cooperating with the flat wall of the bearing sleeve, the holding force can be increased by arranging a second chamfer, which is located diametrically opposite the first chamfer of the shaft journal, as well as at a smaller outer diameter of the shaft journal. In this case, the spring wall of the leaf spring is increased by the distance by which the second chamfer is retracted relative to the surface of the shaft pin. Thanks to the linear abutment of the shaft journal against the bearing sleeve, the shaft journal need not have a round cross section and may, for example, be polygonal. In addition, thanks to the linear abutment surface, the advantage is provided that there can be a play fit between the bearing sleeve and the shaft journal, which considerably facilitates the manufacture of the two parts. According to the invention, the play fit is smoothed by the leaf spring in cooperation with the flat wall.

Preferred embodiments of the invention appear from the dependent claims 2-8.

An embodiment of the invention is described in more detail in the following with reference to the drawing, in which Fig. 1 shows a perspective view of a pin bearing according to the invention; Fig. 2 shows a section through the pin bearing according to the invention along the section line A-A in Fig. 1; and Fig. 3 shows a section along the pin bearing according to the invention with exemplary embodiments of pull-out catches.

Fig. 1 shows in perspective a pin bearing according to the invention, comprising a support shaft 1, a bearing sleeve 2 and a leaf spring 14. The support shaft 1 has at its free end a shaft pin 18, which is inserted into the bearing sleeve 2. The shaft pin 18 has at the front end a tip 7 (shown in broken lines), which in the inserted state abuts against a closure 12 of the bearing sleeve 2. In the embodiment shown in fig. 1, the bearing sleeve 2 in section across the axial direction has the shape of a rectangle . Consequently, the 2 walls of the bearing sleeve have flat surfaces. In addition, the shaft pin 18 has two chamfers 8, 9, wherein in the figure the upper chamfer 8 abuts against the upper wall 19 of the bearing sleeve 2 and the lower chamfer 9 engages with the curved leaf spring 14. The leaf spring 14 abuts with its free ends against 467 957 10 15 20 25 30 35 6 the lower wall of the sleeve 2 and, due to its curved shape, presses the shaft journal 18 against the inside of the flat wall 19. For the sake of clarity, the attachment of the leaf spring 14 is not shown. In addition, depressions 10 are arranged in the upper wall 19 of the bearing sleeve 2, which form sliding surfaces for the shaft pin 18, which thus do not completely abut against the inner wall of the upper wall 19 of the bearing sleeve 2. When mounting, the shaft pin 18 with the tip 7 in front is inserted into the bearing opening 11 and consequently comes into abutment against the leaf spring 14 and the depressions 10.

Depending on the desired holding force, the leaf spring 14 attached to the bearing sleeve 2 can be differently strongly curved.

The bearing sleeve 2 is preferably bent by a piece of sheet metal, so that the bearing sleeve 2 forms a box-shaped tube with the bearing opening 11 and the closure 12. By manufacturing the bearing sleeve 2 as a bent detail of a plate piece, corresponding plates of the die piece with the bearing sleeve 2. The support plates 3 and the stops 4 serve to receive a wire frame 5, which is arranged inside the sun protection body (not shown). The sun visor body completely encloses the parts shown in Fig. 1, wherein in a known manner only an opening located on the side is arranged for insertion of the shaft pin 18, the extension of which is connected via the curved support shaft 1, for example to a pivot bearing. The support frame 5 is connected, for example, by means of a welded connection or bent parts (not shown) to the support plates 3 and the stops 4, respectively.

For better abutment of the wire frame 5, support 6 can be arranged at the support plates 3 - as can be seen from Fig. 1. In order that the box-shaped bearing sleeve 2 should not be bent apart due to the compressive force provided by the leaf spring 14, the ends of the bent part overlap each other in the area of the support plates 3 and are fixedly connected to each other, for example by collar 13. The bearing sleeve 2 thus forms together with the support plates 3 a stable unit, which is completed after insertion and snapping of the leaf spring 14.

Especially thanks to the box-shaped profile, a torsionally rigid bearing sleeve 2 is provided. Depending on the method of use, the bearing sleeve 2 can also be made of plastic.

Fig. 2 shows a cross section through the pin bearing in Fig. 1 along the section line A-A. The opening cross-section of the bearing opening 11 is limited on the side of the side walls 21, the mutual distance of which substantially corresponds to the diameter of the shaft journal 18. Thus, the side walls 21 form a side guide for the shaft journal 18 upon insertion and rotation thereof. In the positions shown in Figs. 1 and 2, the bearing sleeve 2 is in a locking position, whereby the bearing sleeve 2 can only be pivoted to another position by exceeding a certain limit force.

Thanks to the chamfers 8, 9, the leaf spring 14 and the upper wall 19 of the bearing sleeve 2, the shaft pin 18 can assume two locking positions. The shaft pin 18 can also assume two locking positions when only one bevel 8 or 9 is provided. The advantage of the diametrically opposite chamfers 8, 9 is that a considerably greater displacement distance and spring path, respectively, is achieved for the leaf spring 14, if the shaft pin 18 from the locking position by exceeding the joint edge 22 (Fig the inner wall of the wall 19. The spring path and the stroke of the leaf spring 14, respectively, are determined by the diameter minus the distance of the chamfer 8, 9. Consequently, the holding force in the locking positions is less than in the turning positions. The holding force in the locking positions is determined by the bias of the spring 14.

In addition to the limit force which must be applied to rotate the shaft pin 18 on the leaf spring 14 over the joint edges 22, the width and depth of the chamfers 8, 9, respectively, determine the setting angle over which the sun visor can be continuously adjusted. If the bearing sleeve 2 is in a locking position, the round surface of the shaft journal 18 abuts in addition to with a small clearance linearly against the inner sides of the inner walls 21. At the same time the chamfers 8, 9 also abut over a large surface against the leaf spring 14 of the bearing sleeve 2 beyond the joint edge 22, the wall 19 and the leaf spring 14 are brought into linear engagement with the shaft pin 18. If the bearing sleeve 2 in Fig. 2, for example, is rotated 90 °, arises due to the chamfers 8, 9 the largest possible game at the side walls. However, this is not a significant disadvantage, and it can also be remedied with a relatively long pin bearing. In addition, this corresponds to a mode of use of the sun visor that is only rarely used.

It will be appreciated that the holding force of the described pin bearing can be varied within a wide range of applications, whereby manufacturing tolerances due to the linear abutment in the curved position of use of the sun visor have little influence on the holding force. In addition, it is not necessary that the side walls be parallel to each other or perpendicular to the wall.

In addition, a shaft pin 18 with a smaller diameter can be used, since the box-shaped bearing sleeve 2 can easily be manufactured even with a smaller opening cross-section. This advantage arises by aligning the pin bearing on a linear abutment along the shaft pin 18, when the sun visor has been pivoted from the locking position. The linear abutment is achieved in that the leaf spring 14 is located opposite the flat path 19 and in that the shaft pin 18 is clamped between the wall 19 and the leaf spring 14. In addition, the corner portions of the bearing sleeve form free spaces 23 suitable for receiving lubricant or worn material occur after prolonged use of the sunscreen.

According to a further embodiment (not shown), two leaf springs 14 can also be arranged, so that a leaf spring is in engagement with each bevel 8, 9. This second leaf spring can easily be accommodated and fastened to the inside of the box-shaped basic construction of the bearing sleeve 2. the flat wall 19. Arrangement of two leaf springs is particularly suitable if the bearing sleeve 2 in the locking position is to be displaced axially on the shaft pin 18. The preload of the two leaf springs is chosen in that case so that an easy-running sliding fit is achieved. shown) on the support shaft 1 is pivotable towards the side window of a vehicle. Thanks to the large variation possibilities and 10 15 20 25 30 35 J; GN \: | V) 01 * <1 9 the possibility of accurately determining the holding force in the locking position as well as in the pivoting position of the sun visor, the axial displacement movement described above can also be achieved with a leaf spring 14.

Fig. 3 shows a partial view of a longitudinal section through the pin bearing in Fig. 1 with two embodiments of pull-out latches for the shaft pin 18 from the bearing sleeve 2. The first pull-out latch consists of the free end 16 of the leaf spring 14, which is brought into engagement with a groove 15. As mentioned above, the leaf spring 14 is fixed inside the bearing sleeve 2.

The free end of the leaf spring 14 can be designed so that it first engages with the groove 15 when the shaft pin 18 has been pivoted out of the locking position. On the other hand, the length of the free end of the leaf spring 14, which faces the groove 15, may be such that upon insertion of the shaft pin 18 due to bending of the leaf spring 14, the free end 16 is brought into engagement with the groove 15, which in that case extends around the entire shaft pin.

Another embodiment of a pull-out latch can be provided by, as can be seen from Fig. 3, the depressions 10 engaging an associated ring groove 17 in the shaft pin 18. It is also possible to provide an pull-out latch in the form of a thickening at the tip 7 of the shaft pin 18, if the pin bearing together with the rotational movement is to allow the above-mentioned axial longitudinal displacement of the sun visor. If the closure 12 (Fig. 1) is not provided, the pin bearing can be designed so that it can be used for sun protection on both the driver and passenger side.

Claims (8)

467 957 10 15 20 25 30 35 10 PATENT CLAIMS A pin bearing for sun protection comprising a bearing sleeve anchored in the sun protection body, a support shaft having in the area of the pin bearing an axle pin with a planar bevel extending in the axial direction, and a leaf spring extending in the axial direction and resilient is arranged between the inner wall of the bearing sleeve and the shaft pin, characterized in that the bearing sleeve (2) in a section transverse to the axial direction is rectangularly designed with flat walls, and that the leaf spring (14) is located opposite a flat wall (19). Drain bearing according to Claim 1, characterized in that the bearing sleeve (2) is bent by a piece of plate. Drain bearing according to claims 1 and 2, characterized in that the bearing sleeve (2) has a closure (12) at its free end. Drain bearing according to Claims 1 to 3, characterized in that the flat wall (19) has depressions (10). Pin bearing according to claim 1, characterized by two leaf springs (14) arranged opposite each other. Pin bearing according to Claim 1, characterized in that the shaft pin (18) has two flat chamfers (8, 9), which are preferably located opposite one another. Pin bearing according to claim 1, characterized in that a free end (16) of the leaf spring (14) together with a groove (15) in the shaft pin (18) forms a pull-out catch for the shaft pin (18) from the bearing sleeve (2). Pin bearing according to Claim 4, characterized in that the depressions (10) together with a ring lock (17) in the shaft pin (18) form a pull-out lock for the shaft pin (18) from the bearing sleeve (2).