SE460009B - SAFETY BELT LOCKING DEVICE - Google Patents

Description

460 009 10 15 20 25 30 35 is moved to the free position for releasing the locking bar. This can happen if the vehicle ends up upside down in a traffic accident and a person gets stuck in the seat belt. In such a case, it may be necessary to lift the person before the actuator can be actuated to open the seat belt.

This work usually requires the participation of several people and can be time consuming, as working conditions are usually difficult in the event of a traffic accident. The alternative is to cut the seat belt, which, however, requires a suitable tool at hand, which is not always the case. The person in the seat belt must also be quickly released and taken out of the vehicle, as the risk of fire in a traffic accident of this kind is great. Thus, it is highly desirable that the seat belt can be opened in the normal manner, even if a person is hanging in the harness. This would also greatly facilitate the possibilities for a person hanging in the harness, who is conscious, to free himself from the harness and get out of the vehicle. The main object of the invention is therefore to provide a locking device with safety harnesses for the locking bar, which device with maintained reliability enables an opening of the safety harness even in cases where the safety harness is heavily loaded and the locking bar is thus exposed to a large force in the pull-out direction. This object is achieved by giving the locking device according to the invention the features specified in the claims.

Because the locking member has an abutment surface for the locking bar, the normal of which in the locking position of the locking member passes through a torque line parallel to the pivot axis of the locking member, which is offset from the pivot axis of the locking member, a force on the locking bracket neutral position. By suitable positioning of the torque line of the locking member in relation to the pivot axis of the locking member, a desired resulting torque on the locking member can be obtained at different loads in the seat belt. The locking means can then, after the locking means have been removed, be easily pivoted to the free position by means of the operating means for releasing the locking bar, even if this is very heavily loaded in the pull-out direction.

The torque can also be chosen so large that it overcomes the frictional forces which occur at the abutment of the locking bar against the locking member, and possibly also the forces which occur at the other abutment surfaces of the locking member when absorbing the force acting on the locking member from the locking bar. The locking means can thus, if desired, be made self-opening, ie opened without any force transfer from the operating means to the locking means, as soon as the locking means has been removed.

Thereby, the construction of the operating member and consequently the entire locking device can be simplified.

Three embodiments of the locking device according to the invention will now be described in more detail below with reference to the accompanying drawing figures.

Fig. 1 schematically shows a partially cut-away lock housing with a pivotally mounted locking member with a fixed pivot axis and a locking bar retained by the locking member. Fig. 2 schematically shows a slidably mounted locking member and a locking bracket retained by the locking member. Fig. 3 schematically shows in side view a locking member with displaceable pivot axis, a locking member and an operating member and a locking bracket retained by the locking member. Fig. 4 shows the device according to Fig. 3 in plan view. Pig. Fig. 5 shows in side view the device according to Fig. 3 with the pivot axis of the locking member displaced.

The locking member 10 shown in Fig. 1 is mounted in a U-shaped bracket, which forms the insertion path of the locking bracket and whose legs form storage means for the ends of the locking member.

Each leg is provided with an opening into which one end of the locking member projects. In the figure, only one leg 11 is shown on the U-shaped bracket with its storage opening 12, but the other leg is designed in a corresponding manner. The leg 11 is formed with a tongue 13, which projects into the opening 12 and is provided with a bearing edge 14 for the locking member 10, as will be explained in more detail below. In addition, three support members 9 for the locking bar are schematically indicated.

In the embodiment shown, the locking member 10 has a substantially U-shape with two leg parts 15, 16 on the upper side and a downwardly directed bearing part 17 on the lower side. The leg parts 15, 16 extend along the entire length of the locking member, but the bearing part 17 is only at the ends of the locking member.

The leg portion 15 is formed with a substantially cylindrical peripheral surface 18, which forms an abutment surface for the locking bar 19. The leg portion 16 is also formed with a substantially cylindrical peripheral surface 20. The cylindrical peripheral surfaces 18, 20 have substantially the same radii and the same center axis A, which is located on distance from the pivot axis B of the locking member and parallel thereto. The opening 12 has adjacent arcuate parts 15,16 substantially circular arcuate edges with slightly larger radii than the leg parts 15,16, so that there is a certain clearance between the peripheral surfaces 18,20 of the leg parts 15,16 and the adjacent edges of the opening 12.

The downwardly directed bearing part 17 of the locking member 10 forms a pocket 21, into which the bearing edge 14 of the tongue 13 can slide in, so that the locking member is pivotally mounted on the tongue 13.

The bearing part 17 has a curved abutment surface with a certain radius and a center of curvature B, which thus forms a pivot axis for the locking member. The bottom of the pocket 21 has a radius of curvature which corresponds to the curvature of the abutment surface of the bearing part, so that the locking member can pivot on the bearing edge 14 with the least possible friction. The locking means can be pivoted between a locking position, which is shown in the figure and in which the locking bar is held by the locking means, and a free position, in which the locking means abuts against the entire upper surface 22 of the tongue and in which the locking bar 19 is not held by the locking means. the opening 12 in the leg 11 is dimensioned so that the locking member can pivot on the bearing edge with a certain clearance to 10 20 h.) (II 30 35 460 009 the edges of the opening but cannot slide off the bearing edge. During the pivoting movement the locking member pivots about its bearing axis B.

As shown in Fig. 1, the center point A of the locking surface abutment surface 18 of the locking bar is offset from the center point B of the bearing surface provided on the tongue 13 and lies at a distance a from the center point B above it. The force exerted by the locking bar 19 on the locking member 10, when the seat belt is loaded, so that the locking bar is actuated by a force in the pull-out direction U, acts on the cylindrical abutment surface 18 of the locking member and can be divided into two force components, one directed radially along the abutment surface normal N through the center point A of the abutment surface and the other is directed tangentially along the abutment surface.

Due to the position of the point A above the point B, the radial force gives rise to a torque which strives to turn the locking means counterclockwise from the shown locking position towards the neutral position. If the locking bar abuts the locking member below point A, the tangential force is directed downwards, and if the locking bar abuts the locking member above point A, the tangential force is directed upwards. The tangential force can thus counteract or cooperate with the torque produced by the radial force, depending on the position of the locking tongue in height. Since it is desirable to provide a torque on the locking means in the direction from the locking position to the neutral position, i.e. in the direction indicated by the arrow M in the figure, the locking bar should abut against the locking means approximately at or above the point A, so that the tangential force appreciably counteracts the desired rotating moment on the locking member in the direction of the neutral position of the locking member. By suitably selecting the position of point A, a desired torque on the locking means can be obtained, since the torque is determined by the distance of point A from point B and the force component perpendicular to the connecting line between points A and B at point A. The line passing through point A parallel to the pivot axis B of the locking member, 460 009 10 15 20 25 30 35 can thus be regarded as a torque line of the locking member.

Point A is shown in Pig. 1 lying in a vertical plane slightly next to point B and in the locking means. Point A can, however, be placed in or next to the vertical plane through point B and in or outside the locking means.

By selecting the location of the points A and B, a suitable torque in the opening direction of the locking member can be obtained.

This torque can be varied within wide limits from a low value close to 0 to a very large value, especially if the tangential force on the locking member is caused to co-operate with the torque produced by the radial force. At a small distance between points A and B, a low value of the torque is obtained and only a certain aid of the load on the locking bar when swinging the locking member to the free position, so that most of the opening force still has to be transmitted from the operating member. By choosing a larger distance in the appropriate direction between points A and B, the frictional force when the locking bar abuts against the locking member can be completely or partially eliminated, and by even greater distance the locking member can be made self-opening, so that no action from the actuator is required to pivot the locking member to the idle position, after the locking organct has been removed.

Fig. 2 shows a slightly modified embodiment of the device shown in Fig. 1. The locking member 23 is in this embodiment mounted on an inclined, flat surface 24 and will therefore be displaced slightly on this surface, when the locking bar 19 is loaded in the pull-out direction U. The pivot axis of the locking member 23 will in this case be the upper edge B of the flat surface, and when the locking bar is loaded, the locking means will be brought into abutment with its cylinder surface 26 against the edge of the opening 12, which will thus function as a load-bearing surface. The edge of the opening 12 and the cylinder surface 26 should therefore be designed so that a large abutment surface 10 is obtained, as shown in Fig. 2. This can be easily achieved if the cylinder surface 26 is given a center axis C, which is different from cylinder axis 25 center axis A.

Figs. 3 and 4 also show a slightly modified embodiment in relation to the embodiment according to Fig. 1.

The tongue 27 projecting into the opening 12 is arranged and dimensioned so that the tongue yields at a very strong load on the locking member in the extension direction U of the locking bar, for example in the event of a collision. The cylindrical peripheral surface 20 of the locking member 10 on the leg part 16 then comes into contact with the edge of the opening 12. This edge suitably has a curvature which corresponds to the curvature of the leg part 16. It is particularly suitable that the edge of the opening has a radius of curvature which is substantially equal to the radius of curvature of the leg part 16, but another center D. The leg part 16 can then have its center in an axis through the point A. This thereby achieves locking means in normal cases, ie. if the locking means has not been subjected to any load of the order of magnitude which arises, for example, in a collision, it swings with very low friction around the bearing edge 28 on the tongue 27, but at very strong load is pressed into abutment against an edge 1 of the opening, so that this opening edge takes up the occurring load on the locking means. This case is shown in Pig. 5.

In Fig. 3, a locking member 29 for the locking member 10 and an operating member 30 for releasing the locking bar have also been schematically drawn. The locking member 29 is connected to the locking member 10 and consequently moves together with it and is also spring-actuated in the locking direction of the locking member, i.e. clockwise in the figure. The operating member 30 is provided with an abutment surface 31 for the locking member, so that it cannot be rotated in the opening direction of the locking member, as long as the operating member is in the closed position, as shown in the figure.

When the operating member is moved to the opening position (not shown), the abutment surface 31 of the locking member 29 is displaced, so that the locking member and consequently also the locking member can be rotated in the opening direction of the locking member. The rotation of the locking means and the locking means is effected by the operating means by means of a surface (not shown) thereon.

By suitable placement of the points A and B, a suitable torque can also be obtained in the embodiments according to Fig. 2 and Fig. 3. However, in order for the reading means to become self-opening or to be able to be rotated with a small force input by means of the operating means, it is required in these cases that the resulting torque produced by the locking bar on the locking means completely or almost completely eliminates the frictional forces at all friction surfaces.

In the embodiment according to Fig. 3 a special advantage can be achieved. If the resilient tongue is dimensioned in such a way that the tongue only yields to the forces and stresses which can occur momentarily in traffic accidents, such as collisions, and then springs back, when these forces and stresses have ceased, it can be achieved that the locking means becomes self-opening at normal or slightly higher stresses. It then becomes possible to easily open the seat belt by means of the actuator, even if the vehicle lies upside down after a collision and a person hangs in the seat belt. The load in the safety harness which arises due to a person hanging in the harness is not nearly as high as the load which arises in the event of a collision. The frictional force which arises in the displacement of the locking member for abutment against a force-absorbing surface, e.g. shown in Fig. 5, possibly in combination with a torque acting in the locking direction of the locking means can then be caused to cancel the torque produced by the locking bar, so that the locking means is certainly retained in the locking position, even if the locking means could not fulfill its locking function . Although only three embodiments of the locking device according to the invention have been shown and described, it is obvious that many different embodiments and variations are possible within the scope of the inventive concept. The locking means can, for example, be designed in many ways and the cylindrical surfaces can have the same or different radii and the same or different center points.

The abutment surface of the locking bar does not have to be cylindrical but may have any shape, eg flat, provided that the surface or normals of the surface pass along the axis of rotation of the locking member in such a way that a rotating moment in the locking member's free position occurs when the locking bar is exposed. for load. The locking means may further be mounted on a bearing edge, which is designed or placed in a manner other than shown and possibly be mounted on a shaft, which may be resilient or strong enough to accommodate occurring loads. The locking member can furthermore be arranged in such a way that it must be pivoted in the opposite direction, ie clockwise, in order to reach its free position, whereby the torque line will be below the pivot axis of the locking member.

Claims (10)

460 009 10 e Patent claim Locking device for seat belts for a locking bar, which is arranged to be fastened to a strap included in the seat belt, comprising a locking member (10; 23), which is arranged to be pivotable about an axis (B) between a free position, in which the locking means cannot engage with the locking bar (19), and a locking position in which the locking means can engage and hold the locking bar; a locking means (29), which is arranged to lock the locking means in the locking position; and a slidable actuator (30), which is arranged to release the locking bar in the event of an actuation, so that the locking harness can be opened, characterized in that the locking means (10; 23) has an abutment surface (18; 25) for the locking bar (19), the normal (N) in the locking position of the locking member passes through a torque line (A) parallel to the axis of rotation of the locking member] (B), which is positioned relative to the locking axis of the locking member (B) so that a force on the locking bar (19) a resulting torque (M) on the locking means in the direction of the freewheeling position of the locking means, so that the release of the locking bar is facilitated when the seat belt is loaded, and that the pivot axis (B) of the locking means 20 in the locking bar pulling direction (U) is located outside the locking surface (18); Locking device according to Claim 1, characterized in that the resulting torque (M) at least partially cancels the frictional force at the abutment of the locking bar (19) against the locking member (10; 23). Locking device according to claim 2, characterized in that the resulting moment L (M) substantially completely cancels the frictional force at the abutment of the locking bar (19) against the locking member (10; 23), when the locking bar is to be released. Locking device according to Claim 2 or 3, characterized in that the abutment surface (18; 25) of the locking member (10; 23) consists of a part of a cylinder surface, the radius of which has its center at an axis of rotation of the locking member (B). ) parallel line (A), which lies above the axis of rotation of the locking member. Locking device according to claim 4, characterized in that the abutment surface (18; 25) constituting the center line (A) of the cylinder surface 10 15 20 25 30 35 460 009 11 lies in the locking means (10; 23). Locking device according to one of the preceding claims, characterized in that the locking member (10) is formed at each end with a pocket (21) and in this pocket is arranged on a bearing edge (14; 28) on a projecting tongue (13). ; 27) in an opening (12) in a force-absorbing wall (II) and that the bearing edge has a radius of curvature with a center line (B), so that the locking means pivots about a bearing axis through the point (B) when moving between the locking position and the free position. Locking device according to one of Claims 1 to 6, in which the locking means is arranged such that, as great as that of the frictional force when the locking means pivots about a fixed axis, the resulting torque (M) is essential (10). against the locking bar (19) maximally achieved the opposite torque when the locking bar is to be opened. Locking device according to any one of claims 1-6, wherein the locking means (10; 23) are slidably mounted and arranged to come into contact with a load-bearing during the displacement that the resulting torque (M) is substantially equal to the abutment surface, characterized by the of the frictional forces at the abutment of the locking member (10; 23) against the locking bar and the abutment surface. Locking device according to claims 6 and 8, characterized in that the tongue (27) supporting the bearing edge (28) is arranged to yield in the event of a very heavy load on the safety harness, for example in the event of a collision, so that the locking means (10) comes into contact with the edge of the opening (12) of the force-receiving wall (11) forming the abutment surface, and then springing back when the very heavy load of the seat belt has ceased. Locking device according to one of Claims 1 to 5 and 8, characterized in that the locking member (23) is arranged to slide on a surface (24) and to pivot about a pivot axis (B), which is constituted by a load on the locking bar. an edge on this surface, so that the locking means comes into abutment against the abutment surface.