EP0212507A2 - Seat belt safety buckle - Google Patents

Abstract

1. Belt buckle (10) for a safety belt, for receiving and locking an insertable tongue (12) having a housing (11) and, arranged therein, an insertion path (14) for the insertable tongue (12), said path containing a spring-loaded ejector and having a bolt (16) guided in the buckle (10) and cooperating with the tongue recess in the event of locking, said bolt holding the insertable tongue (12) in an associated recess in the buckle (10), and a sliding knob (23) guided in the housing (11) transversely with respect to the plane of movement of the bolt (16) in order to release the lock, characterized in that, to protect the buckle (10) from shock, in the direction of actuation of the sliding knob (23), a counterweight (30) is provided which is offset relative to the line of action of the sliding knob (23) by means of a lever arm (29, 58) and which, in the event of locking, secures the sliding knob (23) against any forces of acceleration (44) which occur.

Description

The invention relates to a seat belt buckle for receiving and locking a tongue with a housing and an insertion path arranged therein containing a spring-loaded ejector for the tongue, with a led in the lock and cooperating with the tongue recess in the event of locking, which has a tongue in an associated recess the lock holds, and a sliding button in the housing transverse to the plane of movement of the bolt to release the lock.

Safety belt buckles generally have the problem that the bolt opens automatically under extreme conditions, in particular under the action of acceleration forces acting on the buckle in individual cases, if the operating or securing parts actuating the bolt or the bolt itself are due to move their inertia from their intended position for the locking case and ultimately the bolt is released from its locking position.

A generic sliding key lock is known from DE-OS 28 28 049, in which the bolt is movable perpendicular to the tongue and secured by a projection arranged on the sliding key over the bolt in the locking case against locking forces acting in the plane of movement of the bolt. Now, however, acceleration forces can also act on the buckle in the plane of action of the slide button actuating the bolt, for example if the buckle is moved in its longitudinal direction as part of a tightening of the seat belt in the event of an accident. If, in such a case, high acceleration forces occur in the plane of action of the slide button, this can lead to the slide button remaining due to its inertia while the closure body is moving, so that the two parts experience relative mobility with respect to one another. This means that the sliding button would then perform an opening movement and release the bolt for unlocking.

In another type of slide key lock, as described in EP-A-0 052 160, the latch locking the latch in the locking position is secured by a pivot lever perpendicular to the path for the latch, so that in the pivot plane of the latch on the Shocks or accelerating forces acting on the closure cannot bring about unlocking even with this type of closure. However, since the pivoting plane of the pivoting lever securing the bolt is also arranged in the direction of the sliding key plane of the acceleration forces, the inertia of the swivel lever, which acts in the same way, together with that of the sliding button, can also release the bolt from its locking position with this closure. A shock protection of this lock in the direction of action of the slide button is therefore not given.

Although EP-A-0 052 160 refers to impacts acting in the plane of action of the sliding key and it is proposed to achieve a certain mass compensation by supporting the pivot lever in its mounting in the housing, but this solution leaves the inertia of the Slightly pushing the latch-operated slide button. In addition, the mass balance on the bearing of the swivel lever itself cannot counteract the expected acceleration forces with sufficient certainty.

The invention is therefore based on the object of setting up a slide key lock of the type mentioned in such a way that the lock is also shock-proof against acceleration forces acting in the direction of the plane of action of the slide key. The achievement of this object, including advantageous refinements and developments, results from the content of the claims, which precede this description.

Although it is described in DE-OS 28 12 712 a shockproof closure in which the shock protection consists of an additional mass, it is a so-called push-button lock in which the levels of action of the bolt and the key actuating it are aligned or . to match. With a closure designed in this way, an acceleration supply of the closure in its longitudinal direction, that is, in the direction of the insertion movement for the lock tongue, does not bring about an unlocking of the bolt, which is why the problem underlying the invention does not arise. The mass balance assumed for the pushbutton lock corresponds in its effect only to the securing swivel lever in the generic lock.

The invention has the advantage that the opening or insertion forces in the closure according to the invention are hardly higher than a non-shock-proof closure, since the additional balancing mass to be moved is of little importance here. Only when the acceleration occurs does the mass develop its effect due to the inertia, which is reinforced by the bearing of the mass offset from the line of action of the sliding key.

In general, the solution according to the invention can be applied to all types of sliding key locks, in that the balancing mass is selected in accordance with the mass of the sliding key and is arranged on the sliding key itself via the lever. The same applies to the connection of the sliding button with a shock absorber. The size of the mass can also be influenced by the selection of the position of the mass storage in relation to the sliding key level, the mass being able to be smaller with a bearing point of the lever arm which is closer to the sliding key level, but with the acceptance of a larger pivoting path of the compensating mass.

According to a further exemplary embodiment of the invention, it is advantageous for the balancing mass to be closed by a shock absorber which interacts with the sliding button replace, which ensures the equalization of the acceleration forces acting on the slide button.

In a special, advantageous embodiment of a sliding key lock explained in the drawing, in which the latch in the housing of the lock is pivotally mounted and is secured in the locking position by a pivot lever mounted in the housing, the balancing mass acts via the lever on a plunger which is in the lock housing Direction of action of the sliding button is guided in a longitudinally displaceable manner and the movements of the sliding button on the one hand and of the pivotable bolt on the other hand are coupled.

Another embodiment of the invention has the particular advantage that the shock protection in the form of the lever-guided balancing mass is arranged in the lock independently of the locking mechanism, in that the lever carrying the balancing mass is mounted on a part fixed to the housing in such a way that the lever is located between the two in the event of a release its storage and the sliding button or a part connected to the sliding button in terms of movement. This results in the possibility of providing any design of a sliding key lock with the shock protection according to the invention without a structural change in its locking mechanism.

The invention also extends to the fact that the balancing mass can be arranged laterally offset to the sliding button and prevents the movement of the sliding button in the event of a release via a lever which acts correspondingly parallel to the closure plane.

In the drawing, exemplary embodiments of the invention are shown, which are described below.

• Fig. 1 einen Verschluß im Längsschnitt in Bereitschaftsstellung,
• Fig. 2 den Verschluß im Längsschnitt in verriegelter Stellung,
• Fig. 3 den Verschluß im Längsschnitt im Augenblick der Entriegelung,
• Fig. 4 ein anderes Ausführungsbeispiel des Verschlusses mit Stoßdämpfer,
• Fig. 6 ein weiteres Ausführungsbeispiel der Schocksicherung in entriegelter Stellung,
• Fig. 7 das Ausführungsbeispiel gemäß Figur 6 bei wirksamer Schocksicherung,
• Fig. 8 ein zusätzliches Ausführungsbeispiel der Schocksicherung in entriegelter Stellung,
• Fig. 9 das Ausführungsbeispiel gemäß Figur 8 bei wirksamer Schocksicherung.

Show it:

• 1 is a closure in longitudinal section in the standby position,
• 2 shows the closure in longitudinal section in the locked position,
• 3 shows the closure in longitudinal section at the moment of unlocking,
• 4 shows another embodiment of the closure with a shock absorber,
• 6 shows another embodiment of the shock protection in the unlocked position,
• 7 the embodiment according to FIG. 6 with effective shock protection,
• 8 shows an additional exemplary embodiment of the shock protection in the unlocked position,
• Fig. 9 shows the embodiment of Figure 8 with effective shock protection.

A seat belt buckle 10 has a U-shaped housing 11, in which a lock plate 13, spaced from the bottom of the housing 11, is arranged to fix the insertion path 14 for the insertion tongue 12 (FIG. 2). In the second lock plate 13, a bolt 16 is pivotally mounted in a recess 15 perpendicular to the lock plate plane, in that the bolt 16 extends through the recess 15 with a bearing extension 17 and projects into the track 14. As not shown, is A spring-loaded ejector is arranged in front of the bearing extension 17 in the web 14 towards the open end thereof.

The bolt 16 extends forward from its mounting and has a locking projection 18, with which it engages through the lock plate 13 in a further recess in the locking position and interlockingly engages in the associated recess of the inserted tongue 12 (FIG. 2). The bolt 16 has an encapsulation 19, which also ensures a low-friction rotary bearing 20 of the bolt 16 in the recess 15 and, at the same time, forms a support 21 in the upper part of the closure 10 for the further closure parts to be described, which interact with the bolt 16.

A sliding button 23 is arranged above the insertion funnel 22 for the tongue 12 and can be moved parallel to the track 14. A plunger 24 is inserted into the sliding key 23 and is arranged so as to be longitudinally displaceable in the housing 11, and couples the movements of the sliding key 23 and the bolt 16 to one another. In a recess 25 receiving the plunger 24 in the sliding button 23 there is arranged a spring 26 which surrounds the plunger 24 and which is supported on the one hand on the sliding button 23 and on the other hand on a flange 27 of the plunger 24. At the rear end of the plunger 24 there is a further spring 28, which is supported between the supporting encapsulation 19, 21 of the bolt 16 and a lever arm 29 for holding the balancing mass 30.

The lever 29 is rotatably mounted on an axle 31 mounted laterally inwards on the housing 11 of the closure 10 and engages with its upper end on a cam 32 projecting laterally from the tappet 24 in such a way that that lever 29 and tappet 24 are rotatable relative to each other. The upper end of the lever 29 has the possible end positions of the lever 29 each assigned stop surfaces 33, 34, which each assume a vertical position in the end positions of the lever 29 (FIG. 1 and FIG. 2), and on which the spring 28 of the Ram 24 supports each.

As not shown further, an arm 29 is held on both sides of the tappet 24 on cams 32 which protrude on both sides and, owing to the symmetrical division, only has to carry half of the overall balancing mass 30.

To secure the bolt 16 in the locking position (FIG. 2), a pivot lever 35 is provided, which is supported via plastic-molded bearing projections 36 in slots 37 recessed in the lateral legs of the U-housing 11. The bearing projections 36 have a hanging crescent-shaped shape, which encompass the associated links 37 with play, the link shape being essentially adapted to the shape of the mounting projections 36. The scenes 37 have extensions 38 drawn upwards over the crescent shape, into which the edges of the bearing projections 36 of the pivot lever 35 can engage in their respective end positions (FIG. 2 and FIG. 3). On the extension 38 which remains free in the locking position of the pivot lever 35, a projection 39 is arranged which prevents the pivot lever 35 clamped in the locking position from pivoting into the open extension 38 (FIG. 2).

The pivot lever 35 pivots in the locking position of the closure (Figure 2) on a nose 40 on the bolt 16 and holds the latter in the locked position. The upper end of the pivot lever 35 interacts with both the slide button 23 and the tappet 24, in that the slide button 23 has a shoulder 41 with a bevel 42 and in that on the other side of the pivot lever 35 on the tappet 24, the pivot lever 35 with longitudinal displacements of the tappet 24 actuating further cams 43 is arranged.

Starting from the ready position in Figure 1, the closure works as follows:

The plunger 24 is in a central position and holds the slide button 23 in its foremost position on the one hand via the relaxed springs 26, 28 and on the other hand the latch 16 in the swiveled-up position in which the web 14 is released.

If the tongue 12 is now inserted into the web 14 between the housing 11 and the lock plate 13, it first actuates the spring-loaded ejector, not shown, which in turn presses on the bearing extension 17 of the bolt 16. If the tongue 12 is inserted sufficiently far, the bolt 16 pivots under pressure on its bearing extension 17 about its bearing point 20 and falls with the locking projection 18 through the recess into the tongue recess of the tongue 12 and locks it.

Due to the pivoting movement, the locking bar 16, with its encapsulation 19 or the support 21, presses on the plunger 24 on the one hand and on the stop surfaces 33, 34 of the lever arm 29 on the other hand via the spring 28. This leads to a displacement of the plunger 24 in the direction of the sliding key 23, whereby on the one hand the cam 32 paves the way for a pivoting of the lever 29 with the mass 30 releases the bearing 31, namely under the action of the spring 28. At the same time, on the other hand, the longitudinal displacement of the plunger 24 via the cam 43 also causes the pivoting lever 35 to pivot counterclockwise, as a result of which the lower end of the pivot lever 35 comes to lie on the nose 40 of the bolt 16 and holds it. Furthermore, the sliding key spring 26 is slightly biased.

The shock protection acting when the lock is in the locked position will now be described with reference to FIG. 2: If there is an acceleration force acting in the direction of arrow 44, for example as a result of a tightening movement in the belt system, the inertia of sliding button 23 and pivot lever 35 would lead to the fact that an actuation of the plunger 24 to the support 21 of the bolt 16 to take place in that the slide button 23 remains against the movement of the closure body 10, 11 and thus moves relative to the closure body 10, 11. Since at the same time the inertia of the pivot lever 35 would bring about a clockwise rotation, there would be nothing standing in the way of pivoting the bolt 16 as a result of the opening movement of the sliding button 23 from the locking position. This expected release behavior of the closure is prevented by the balancing mass 30, the mass of which is selected to be as large as the mass of the slide button 23, the pivot bolt 35 and the plunger 24, and which, due to its mounting on the lever arm 29, now exerts a counter-force on the plunger 24 exercises by the lever arm 29 remains stationary and holds the plunger 24 immovably over the cam 32. An opening of the bolt 16 is thus excluded, since this could only be effected by a longitudinal displacement of the plunger 24, which is excluded.

A further shock protection of the closure also results from the fact that, in the locked position, the projection 39 in the link 37 prevents pivoting of the bearing projections 36 and thus pivoting of the pivot lever 35.

If the lock is now to be opened (FIG. 3), the sliding button 23 is pushed into the lock housing 11 and presses with the extension 41 onto the pivot lever 35 in order to pivot it clockwise into the release position for the bolt 16. At the same time, the spring 26, which is supported between the slide button 23 and the flange 27 of the plunger 24, moves the plunger 24 to the right. As a result, the cam 43 first clears the way for the pivoting of the pivot lever 35 via the sliding key attachment 41, with the support projections 36 being pushed to the right in the slots 37 formed with play due to this initially still acting support on the attachment 41, so that the respective support projection 36 past the protrusion 39 securing it in the locking position into the extension 38 in the sense of a pivoting movement.

The displacement of the plunger 24 further leads to the fact that the further cam 32 also rotates the lever arm 29 in a clockwise direction, as a result of which the spring 28 is tensioned until a pivoting of the bolt 16 out of the locking recess by the stop of the plunger 24 on the support 21, 19 the tongue 12 out with their release. The parts then return to the starting position shown in FIG. 1 by relaxing the springs 26, 28.

According to a further embodiment of the invention (Figure 4) it is provided to replace the balancing mass with a shock absorber 45, which can attack the cam 32 of the plunger 24, for example with an otherwise unchanged design of the closure, and thus in the same way as the balancing mass 30 a displacement of the Tappet 24 prevents forces acting in the direction of arrow 44 and thus ensures shock protection for such load cases. The shock absorber can work with a liquid or gaseous medium. FIG. 4 also shows the fastening of the closure via a rivet 46 to an anchoring part 47, which is usually connected to a part fixed to the vehicle or a pretensioning device therefor.

According to the embodiment shown in Figure 5, the housing 11 of the closure 10 consists of a one-piece lock plate 50, which is bent in the area of its attachment to an anchoring part 53 to two legs 51, 52 of equal length, between which the lock tongue 12 against the action of an ejector 54 is insertable. In two in the rear area of the lock plate 50 bent tabs 55, a locking member 56 is rotatably mounted perpendicular to the insertion plane for the lock tongue 12 in a joint 57, the design of the locking mechanism is not the subject of the invention.

The sliding button 23 arranged above the insertion funnel for the tongue 12 is guided via projections between the legs 51, 52 of the lock plate 50. On the top of the upper leg 51 facing the sliding button 23, a leaf spring 58 is clamped in a bracket 59, which in the rest position extends with its free end to the sliding button 23. The spring 58 is opposed the actuation direction of the sliding button 23 is slightly bent back and carries the balancing mass 30 on the upper side thereby formed.

The sliding button 23 has on its underside in the area of the spring end 60 a recess 61 with a stop 62, into which the spring end 60 can be pivoted in the event of tripping. The functioning of this embodiment of the shock protection results as follows:

If, as already described, the closure body is accelerated in the direction of arrow 44, the spring 58 with mass 30 remains, as it were, due to its inertia compared to the other closure parts. As a result of the relative movement thereby formed, the end 60 of the spring 58 pivots into the recess 61 of the sliding key 23 and holds it firmly via the stop 62, so that an opening movement of the sliding key is excluded. It goes without saying that the mass of the spring and the balancing mass must be greater than that of the sliding key.

The shown direct connection of the sliding button and lever can also be replaced by an indirect connection, in that the spring designed as a lever engages, for example, an actuating element for the locking mechanism, which is generally designed on the sliding button, and in this way prevents a sliding movement of the sliding button.

It is also easy to see that instead of the spring 58, a rigid lever can also be provided as a carrier of the mass, which is arranged rotatably fixed to the housing and is otherwise spring-loaded. In such a case, the design of the lever as an angle lever, one arm of which with a pendulum-like balancing mass interacts and its other arm engages directly or indirectly on the sliding button in the sense of blocking its opening movement.

Such a mode of operation also results in particular from the exemplary embodiments according to FIGS. 6-9 of the drawing.

Here, an angle lever 65 is rotatably supported on the lock housing 11 by means of journals 66, so that in the rest position one arm of the angle lever 65 extends into the plane of movement of the sliding key 23 and the other arm runs perpendicularly thereto in the lock body 11. At the lower end of the latter arm of the angle lever 65, the latter is operatively connected via an elongated hole guide 67 with a pin 68 of an inertial mass 69 engaging therein, which in turn is movably guided in a frame 70 firmly connected to the lock housing 11. In this exemplary embodiment, the inertial mass 69 is provided with metallic inserts 71, but can also be made entirely of metal.

The inertial mass 69 is held in its rest position by means of a compression spring 72 such that the angle lever 65 connected to the inertial mass 69 via the pin-slot connection 67, 68 is not pivoted, and it lies against the front stop 73 of the frame 70 . The spring 72 is held on a pin 74 of the frame 70, the front end of which simultaneously forms a stop 75 for the displacement of the inertial mass 69.

The sliding button 23 has on its lower side facing the angle lever 65 an extension 76 with a locking edge 77 which interacts with the angle lever 65.

The shock protection according to the above-described embodiment works in broad accordance with the previously described embodiments as follows: In the rest position of the inertial mass 69, this is pressed by the spring 72 against the stop 73 of the frame 70; due to the positive connection 67, 68 with the angle lever 65, its free leg is also located outside the shoulder 76 of the sliding button 23, so that a free movement of the sliding button 23 is possible in the sense of a normal actuation of the lock mechanism. When a strong acceleration is initiated in the plane of movement of the sliding button 23 on the belt buckle (arrow 44), the inertial mass 69 compresses the compression spring 72 due to its relative movement to the lock housing 11 until the inertial mass 69 abuts the stop 75 of the frame 70. With this movement, the inertial mass 69 pivots the angle lever 65 around the bearing journal 66, so that the free arm of the angle lever 65 comes to rest in front of the locking projection 76, 77 of the sliding key 23. A further movement of the sliding button 23 in the sense of opening the lock is thus restricted to dimension 78, a complete sequence of movements until the release can no longer take place.

The exemplary embodiment according to FIGS. 8 and 9 shows an alternative to the previously described embodiment insofar as the corresponding arm of the angle lever 65 is connected directly and in one piece to the inertial mass 69, this inertia arm 69 of the angle lever 65 also being loaded by the compression spring 72. Otherwise, the same movement sequence results as described for the exemplary embodiment according to FIGS. 6 and 7.

The features of the subject matter of these documents disclosed in the above description, the patent claims, the abstract and the drawing can be essential, individually as well as in any combination with one another, for realizing the invention in its various embodiments.

Claims (29)

1. Seat belt buckle for receiving and locking a tongue with a housing and an insertion path therein containing a spring-loaded ejector for the tongue, with a guided in the buckle and interacting with the tongue recess in the case of locking, which has a tongue in an associated recess of the closure holds, and a sliding button in the housing transverse to the plane of movement of the bolt to release the lock, characterized in that, in order to secure the lock (10) in the direction of actuation of the sliding button (23), a sliding button (23) against accruing acceleration forces (arrow 44 ) holding and is offset by a lever arm (29, 58) offset to the line of action of the sliding button (23) provided balancing mass (30) is provided. 2. Seat belt buckle according to claim 1, characterized in that the compensating mass (30) via the lever (29) is connected directly to the sliding button (23) and corresponds to the mass of the sliding button (23). 3. Seat belt buckle according to claim 1, wherein the bolt is pivotally mounted in the housing and is secured in the locking position by means of a pivot lever mounted in the housing, characterized in that a plunger (24) is guided longitudinally displaceably in the buckle housing (11) in the direction of action of the sliding button (23) which couples the movements of the slide button (23) on the one hand and the pivotable latch (16) on the other hand. 4. Seat belt buckle according to claim 3, characterized in that on the slide button side on the plunger (24) a in a slide button recess (25) inserted spring (26) is arranged, which is located between the slide button (23) and a on the plunger (24) arranged flange (27) supports. 5. Seat belt buckle according to claim 3, characterized in that for holding the balancing mass (30) on an on the housing (11) transverse axis (31) mounted arm (29) is provided, which has one end on the tappet (24) attacks and carries the balancing mass (30) at its other end. 6. Seat belt buckle according to claim 3, characterized in that the compensating mass (30) is selected to be as large as the total mass of the sliding button (23), pivot lever (35) and plunger (24). 7. Seat belt buckle according to claim 5, characterized in that for the connection of the tappet (24) and lever arm (29) on the tappet (24) a laterally projecting cam (32) is arranged, which the lever (29) partially includes with an associated recess . 8. Seat belt buckle after connection 5 and 7, characterized in that on both sides of the plunger (24) two balancing masses (30) each of half the required total mass are arranged, guided on the housing (11) and laterally projecting cams on both sides of the plunger (24) 32) can be actuated. 9. Seat belt buckle according to claim 5-8, characterized in that on the bolt-side end of the plunger (24) a spring (28) is arranged, which is supported on the one hand on the lever arm (29) and on the other hand on the bolt (16). 10. Seat belt buckle according to one of claims 1-9, characterized in that the pivoting lever (35) on the one hand via a laterally on the plunger (24) arranged further cams (43) by the longitudinal displacement of the plunger (24) and on the other hand via a Slide button (23) located approach (41) can be pivoted by the slide button movement. 11. Seat belt buckle according to claim 10, characterized in that the pivot lever (35) with lateral projections (36) in scenes (37) in the side walls of the U-housing (11) is mounted and guided such that an additional shock protection against locking there is a pivoting of the pivot lever (35). 12. Seat belt buckle according to claim 11, characterized in that the shape of the bearing projections (36) adapted in form of scenes (37), the bearing projections (36) of the pivot lever (35) with play and that in the respective backdrop (37) has a projection (37) 39) is provided which, in the locked position, fixes the associated bearing projection (36) against pivoting. 13. Seat belt buckle for receiving and locking a tongue with a housing and a spring-loaded ejector containing therein insertion path for the tongue, with a guided in the buckle and interacting with the tongue recess in the event of locking, which holds the tongue in an associated recess of the closure , and a sliding button in the housing, transverse to the plane of movement of the bolt, for releasing the locking, characterized in that, in order to secure the lock (10) in the direction of actuation of the sliding button (23), a sliding button (23) in the event of locking against acceleration (arrow 44) holding shock absorber (45) is arranged. 14. Seat belt buckle according to claim 13 and claim 3, characterized in that the shock absorber (45) is connected to the tappet (24). 15. Seat belt buckle according to one of claims 1-14, characterized in that the insertion path (14) for the insertion tongue (12) in the U-shaped housing (11) is formed by a lock plate (13) spaced from the bottom of the housing (11) . 16. Seat belt buckle according to claim 3, characterized in that the bolt (16) is mounted on a positioning extension (17) in a recess (15) of the second lock plate (13), wherein the positioning extension (17) of the bolt (16) in the Insertion path (14) protrudes between the lock plates (11, 13). 17. Seat belt buckle according to claim 16, characterized in that the bolt (16) with a front Locking projection (18) passes through the lock plate (13) in an associated recess and engages in the recess of the insertion tongue (12). 18. Seat belt buckle according to one of claims 1-17, characterized in that the storage and holding projections (17, 19, 20, 21, 36) of the bolt (16) and pivot lever (35) are formed by plastic extrusion. 19. Seat belt buckle for receiving and locking a tongue with a housing and an insertion path therein containing a spring-loaded ejector for the tongue, with a guided in the buckle and interacting with the tongue recess in the event of locking, which has a tongue in an associated recess of the closure holds, and a sliding button in the housing transverse to the plane of movement of the bolt to release the locking, characterized in that a lever (58,) loaded with an inertial mass (30, 69) is loaded in the actuating direction of the sliding button (23) in order to secure the shock (10). 65) is provided, which in the event of tripping is braced between its mounting (51, 59; 66) and the sliding button (23). 20. Seat belt buckle according to claim 19, characterized in that the lever (58, 65) in the event of tripping on a part connected to the sliding button (23) in terms of movement is braced. 21. Seat belt buckle according to claim 19 or 20, characterized in that a spring-loaded (72) angle lever (65) is provided, on the latter The inertial mass (69) engages in a pendulum-like manner and the other end, when triggered, is set up to engage in the path of movement of the sliding key (23). 22. The seat belt buckle according to claim 19 or 20, characterized in that the lever carrying the inertial mass (30) is designed as a spring (58) clamped on one side of the housing (51, 59), the free end (60) of which is triggered when the slide button ( 23) tense. 23. Seat belt buckle according to one of claims 19 - 22, characterized in that an inertial mass (69) guided in the direction of movement of the sliding key (23) on the lock housing (11) with the free end of the angle lever (65) via a pin-slot connection (67, 68) is coupled. 24. Seat belt buckle according to claim 23, characterized in that the inertial mass (69) is held in its rest position by a spring (72). 25. Seat belt buckle according to one of claims 19 - 22, characterized in that the inertial mass (69) is formed on the free end of the lever (65) and the lever end by a housing-side (70) supporting spring (72) in the rest position of the lever (65 ) is burdened. 26. Seat belt buckle according to one of claims 19 - 25, characterized in that the sliding button (23) has on its underside of the lever configuration (58, 65) a configuration (61, 62; 76, 77) for engaging the free lever end. 27. Seat belt buckle according to claim 22 and 26, characterized in that the design on the sliding button (23) consists of a recess (61) with a stop (62) for the spring end (58, 60). 28. Seat belt buckle according to one of claims 23 - 25 and 26, characterized in that in the plane of the lever arm (65) an extension (76) with a locking edge (77) on the slide button (23) is formed. 29. Seat belt buckle according to claim 26, characterized in that the design is designed as a toothed strip cooperating with the lever end in the event of a trigger.

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