DE3217082C1 - Lock for safety belts - Google Patents

Abstract

In a lock for safety belts of means of air and land transport, having an opening mechanism which can be released at any time as a result of the manual actuation of a push button (16), an automatic actuation by means of an electrical signal generated by a sensor is additionally possible. An electromechanical drive, preferably an electric motor (18), engages on the push button (16) with a pulling effect and moves the latter as an alternative to manual actuation. A reduction between the electric motor (18) and a threaded spindle (20) driven by this and pulling the push button (16) by means of a threaded sleeve (24) ensures the time delay during the automatic opening of the lock. The repeatability of the delay in the event of multiple impacts in the course of an accident cycle is guaranteed in that the threaded sleeve (24) engaging with only less than half the circumference into the threaded spindle (20) is lifted off by means of an electromagnet (36) excitable by the sensor signal, so that the push button (16) is each time brought into its initial position again by springs (28). <IMAGE>

Description

This well-known automatically opening lock is an independent one Assembly that does not come with a manual actuatable opening mechanism is united. The automatic deployment process is activated in the event of an accident by the first shock triggered, a reset of the delay time with several successive ones Impact is not possible. There is therefore a risk that the lock at a on the first joint subsequent later joint is already open.

Finally, after an automatic triggering z. B; for checking functionality of the pliers again by manually turning the threaded spindle are moved back into their closed position.

The invention is based on the object of a manual and automatic Openable lock of the type mentioned to improve so that it is after a Open inevitably back into its ready-to-use position for locking again returns and that automatic tripping in conjunction with a proven reliable manually operated opening mechanism can be used without this must be changed.

According to the invention, this object is achieved by the features of characterizing part of claim 1.

Advantageous further developments of the invention are set out in the subclaims specified.

In the lock according to the invention, the automatic opening takes effect effecting electric motor pulling on the threaded spindle and the threaded sleeve button and moves it in the same path as the manual one Actuation takes place pushing. The opening mechanism and its release by the pushbuttons therefore do not have to be changed. The triggering of the opening mechanism takes place in exactly the same way if the pushbutton is manually pushed through from one side Pressure shifted or from the opposite side by means of the electric motor is moved by train.

The pulling drive by means of the threaded sleeve gives the push button for the movement of manual actuation free, so that independent of the automatic Manual opening of the lock is also possible at any time.

Because the opening mechanism and the pushbutton that triggers it are not are changed, the automatic actuation can be used in any conventional Lock can be used. In particular, the automatic triggering can be used in conjunction can be used with manually operated conventional locks whose locking and opening mechanism is already proven and all safety regulations is equivalent to.

The electric motor is powered by the electrical signal from the inertia sensor put into operation. By the thread pitch of the threaded spindle and by a corresponding gear reduction between the electric motor and the threaded spindle causes the triggering of the opening mechanism at the end of the displacement path the push button takes place after the desired delay time. The gear reduction between the electric motor and the spindle also has the advantage that already a small electric motor with low torque which the overall dimensions of the castle not significantly affected, sufficient to exert a high tensile force on the pushbutton exercise. This high tensile force is necessary because the lock may also be automatic must be opened when it is under high tensile load, because z. B. an injured one or unconscious person is hanging in the belt.

This means that even in the case of several successive impacts, the entire Delay time expires after the last push is the one that pulls the pushbutton The threaded socket can be lifted off the threaded spindle. By lifting the threaded sleeve comes this out of engagement of the threaded spindle, so that the push button by their Return springs can be brought back into their original position. The opening the threaded sleeve is triggered by the electrical signal from the inertia sensor, so that with every shock impulse caused by an impact during the course of the accident, the threaded sleeve is opened and the pulling movement of the pushbutton by the electric motor is off again the initial position of the pushbutton over its full range of motion and thus over the full delay time begins. The threaded socket is secured by the rocker The threaded spindle is lifted when the electromagnet actuating the rocker is triggered by the electrical signal of the inertia sensor is excited.

A limit switch is preferably at the end of the movement path of the pushbutton provided, which is operated by the push button. This limit switch can on the one hand, the power supply to the electric motor can be switched off when the Lock is triggered automatically. This limit switch is advantageous also generates a signal exciting the electromagnet, so that after triggering of the lock is disengaged through the threaded sleeve and the push button inevitably returns to its starting position for a new locking.

In some cases it is desirable that the buckle of the seat belt does not open automatically after an accident if an unconscious person is in the seat belt depends to avoid further injuries to that person when opening the lock to cause. To meet this requirement, a strain gauge can be attached to the lock be provided that is responsive to the tensile load on the lock caused by the body weight of the person hanging in the belt. Exceeds this on the strain gauge the tensile load acting on the rocker of the threaded socket Acting electromagnet energized The threaded sleeve is therefore out of engagement for so long kept, as the tensile load acting on the strain gauge the specified Value exceeds. Only when the tensile load subsides does the threaded socket come into play engaged and the push button can be pulled by the electric motor so that it triggers the opening mechanism after the entire delay time has elapsed.

The electric motor is usually used to power the electric motor Electrical system. Since in the event of an accident, the on-board network z. B. by destruction the battery can fail completely or due to a short circuit, for safety reasons a storage accumulator or a capacitor in the power supply of the electric motor and the sensor must be switched on.

For the small DC motor, it is sufficient in terms of cost and in particular For reasons of space, a storage battery cell with low voltage. This low one Even in the event of a total failure of the on-board network, voltage is sufficient to operate the DC motor. The DC motor runs at this low voltage slower, but this only increases the delay time when opening of the castle.

The automatic actuation of the push button is required only low construction effort and takes up little space. The dimensions of the lock are therefore not significantly larger than a conventional lock.

In the following, the invention is illustrated by means of one in the drawing Embodiment explained in more detail. It shows F i g. 1 is a vertical longitudinal section by a lock according to the invention, and FIG. 2 is a plan view of this lock.

In the drawing, only those essential to explain the invention are essential Parts shown. In particular, the sensor generating the electrical signal is not shown As stated above, this sensor can be designed in any way The only thing that matters is its ability to generate an electrical signal respectively.

to take over a circuit function to close electrical circuits. The sensors that can be used belong to the known prior art.

Next is the design of the lock tongue, its locking in the lock, the opening mechanism and its release by the push button not shown. As stated above, these parts can be in any be designed conventionally.

The lock tongue 10 firmly connected to the belt engages in the only schematically indicated by its base plate 12 and its housing 14 lock in in a manner not shown. The engagement of the lock tongue 10 is through a opening mechanism, not shown, unlocked so that the lock tongue is ejected can be.

A push button 16 is slidably mounted on the plate 12 Push button 16 is out of its right end position shown in the drawing slidable to the left in an end position in which they open the mechanism for the locking of the lock tongue 10 triggers. For manual opening of the lock is the push button 16 by depressing a release button, not shown shifted in a manner known per se. The release button works directly or via a Lever sliding onto the end of the pushbutton 16 on the lock tongue side.

On the end of the plate 12 opposite the lock tongue 10 a small direct current electric motor 18 is mounted. The electric motor 18 is overdriving a reduction gear to a threaded spindle 20 as soon as its power supply turned on in the manner described above by the electrical signal of the sensor will. The threaded spindle 20 freely penetrates a vertical edge 22 of the push button 16 at the end facing the electric motor 18.

Inside the push button 16, a threaded sleeve 24 is seated on the threaded spindle 20. The threaded sleeve 24 extends only over less than half the circumference of the Threaded spindle 20 so that it can be lifted from this upwards and except The threaded sleeve 24 is engaged between two in the direction of displacement Push-button extending guides 26 of the push-button 16 are slidably guided. Return springs 28, which are arranged between the push button 16 and the lock housing, hold the push button 16 with its edge 22 resting against the threaded sleeve 24. With manual Actuation is the push button 16 against the force of the return springs 28 in the Drawing shifted to the left. The vertical edge 22 becomes the pushbutton 16 is lifted from the threaded sleeve 24 which slides in the guides 26. The manual actuation of the push button 16 and thus the manual triggering of the opening mechanism is therefore not handicapped. In slots 30 of the guides 26 is slidable The pivot axis of a two-armed rocker 32 is mounted. The seesaw is on one arm the threaded sleeve 24 attached, while the other arm of the rocker 32 as an anchor plate 34 is formed, which is a seated in the push button 16 electromagnet 36 is located opposite. By a spring 38, the rocker is preloaded so that the Threaded sleeve 24 is held in engagement with the threaded spindle 20.

When the electromagnet 36 is energized, it pulls the armature plate 34 on and the threaded sleeve 24 is against the force of the spring 38 of the threaded spindle 20 lifted off. Due to the mounting of the pivot axis of the rocker 32 in the elongated holes 30, the rocker 32 does not prevent the pushbutton 16 from being manually displaceable.

The automatic actuation of the push button works in the following way Way: The electrical signal that is generated in the event of an accident-related impact or fire generated by a sensor or manually by a button, switches on the one hand the power supply of the electric motor 18 and on the other hand energized briefly the electromagnet 36. The electromagnet 36 attracts the anchor plate 34 and brings it the threaded sleeve 24 disengaged from the threaded spindle 20. After this momentary When the threaded sleeve 24 is lifted off, it comes into engagement again with the threaded spindle 20. The electric motor 18 drives the threaded spindle 20, which pulls the threaded sleeve 24 in the direction of the electric motor 18, the threaded sleeve 24 on the vertical Edge 22 of the push button 16 rests and pulls it along. In this way, the push button 16 so far in the drawing to the left that it opens the opening mechanism of the lock triggers. After the opening mechanism has been triggered, the pushbutton is actuated 16 a limit switch 40 at the end of its movement path.

By actuating the limit switch 40, on the one hand, the power supply of the electric motor 18 is switched off and, on the other hand, the electromagnet 36 for a short time energized The threaded spindle 20 is therefore stopped and the electromagnet 36 lifts briefly the threaded sleeve 24 from the threaded spindle 20.

The return springs 28 can now push the button 16 back to the right Push back into the end position shown in the drawing. The castle is now ready again for receiving and locking the lock tongue 10.

Is during the delay period of z. B. approx.

eight seconds it takes the electric motor to pull back the pushbutton 16 requires a second electrical signal over the entire displacement distance generated by the sensor, e.g. B. as a result of a second impact in the course of the accident, so the electromagnet 36 is again briefly energized by this electrical signal. He lifts the threaded sleeve 24 from the threaded spindle 20 so that the return springs 28 can press the pushbutton 16 back into its starting position. Once the Electromagnet 36 releases the armature plate again, the threaded sleeve 24 comes back with the threaded spindle 20 in engagement and the electric motor 18 starts again, the Pull the pushbutton over its entire distance. With every impact The delay time of approx. eight seconds therefore begins within the course of an accident to run again until the lock is automatically opened.

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Claims (3)

Claims: 1. Lock for seat belts of air, water and Land transport with an opening mechanism that is manually operated on the one hand pushing movement of a pushbutton and on the other hand automatically by pulling Movement of the pushbutton can be triggered by means of an electromechanical drive, wherein the automatic triggering is based on an electrical generated by an inertial sensor Signal takes place after a specified delay time and this delay time if there are several electrical signals following one another within the delay time begins to run anew on each signal, marked by the fact that the electromechanical drive an electric motor (18) with a threaded spindle (20) is, on which one the pushbutton (16) entrained and for the sliding movement releasing threaded sleeve (24) is seated so that the pushbutton (16) is under spring tension on the threaded sleeve (24) rests that the threaded sleeve (24) only over less than half the circumference comes into engagement with the threaded spindle (20) and can be lifted off from it and that the threaded sleeve (24) is attached to an arm of a rocker (32), on the other arm, an excitable by the electrical signal of the inertia sensor Electromagnet (36) attacks. 2. Lock according to claim 1, characterized in that the electromagnet (36) can also be excited by an electrical signal that is transmitted by means of a the pushbutton (16) at the end of its path of movement actuatable limit switch (40) is produced. 3. Lock according to claim 1 or 2, characterized in that the Electromagnet (36) controlled by a responsive to a tensile load on the lock Strain gauges can be excited when a predetermined tensile load is exceeded. The invention relates to a lock for seat belts from air, Water and land transport according to the preamble of claim 1. A lock of this type is known from CH-PS 6 18 094. at This known lock is the locked tongue by the pivoted Locked pushbutton The pushbutton can be manually removed from the locked position be pressed. On the other hand, the push button can be tensioned by a spring standing release lever can be swiveled out of the locked position. The release lever is normally locked and can be used to automatically open the lock using of a solenoid are released when this is triggered by an electrical Signal is energized. The electrical signal is in the event of an accident-related impact generated by an inertial sensor. The electrical generated by the inertial sensor Signal is electronic for a predetermined time of, for example, about 8 seconds delayed so that in the event of an accident the lock only opens when the accident occurs has expired Since several impacts often follow one another in an accident, It must be ensured that the person is still wearing the seat belt the subsequent impacts. For this purpose, several successive impacts by the respective electrical within the delay time Signal of the inertia sensor restarted the delay time, so that after The full delay time expires after the last push before the lock automatically opens is opened. In this known lock must after each automatic release the release lever can be manually returned to its locked position. If the lock is used, for example, to check its functionality triggered automatically and the manual one when the lock is subsequently closed If you forget to engage the release lever, the lock will automatically release not possible. The functional reliability of the lock is therefore not inevitable guaranteed. The automatic release by means of the plunger magnet and the The release lever is structurally complex and makes a special construction of the Locking and the opening mechanism of the lock necessary. One use the automatic release in connection with a proven and reliable Construction of a manually releasable lock is not possible. From US-PS 33 11188 a lock is known in which to lock the lock tongue a wedge-shaped sliding part two levers pivotable against one another holds in engagement with the lock tongue. The sliding part is on the one hand for manual opening of the lock Movable by pushing a push button and on the other hand for automatic opening of the lock by means of a plunger magnet acting on the opposite side pulling movable. By moving the sliding part, it releases the two levers, so that they are pivoted out of the locking position by means of a tension spring. In this known lock, too, is the construction of the opening mechanism specially adapted to the automatic release. The automatic release can therefore not with a reliable proven design of a manually triggered opening mechanism be combined. The tension spring that pulls the locking lever out of the lock tongue swings out, must be very strong in order to be able to open the lock even when the lock e.g. by the weight of the person wearing a seat belt under high tension stands. The strong tension spring in turn causes strong friction between the sliding part and the locking levers, which are overcome by the plunger magnet got to. The plunger magnet must therefore be very large and therefore expensive and space-consuming be designed to ensure reliable automatic triggering. From DE-OS 23 63 973 is an automatically triggering lock for Seat belts known. This lock is connected to the seat belt Bracket held by a pair of pliers. The pliers sit on a nut, which by means of a is displaceable by an electric motor driven threaded spindle. By moving the nut the pliers is pushed against a stop and opened by this. The lock is opened with a time delay compared to the Accidental shock causing the electric motor to start, with the delay time is determined by the duration of the displacement of the nut on the threaded spindle.