DE1166034B - Device for the simultaneous locking or unlocking of several locks, in particular door locks of motor vehicles - Google Patents

Description

Device for locking or unlocking several locks at the same time, in particular door locks for motor vehicles. The invention relates to a device for locking or unlocking several locks at the same time, especially door locks of motor vehicles, in which each lock is provided with an unlockable locking member which can be actuated by electromagnets temporarily operated by a common changeover switches for all locks.

Such a device makes it possible with a single handle To lock several locks, bolts or the like at the same time. This is particular advantageous in motor vehicles with several doors.

In previous devices of this type, the manual control worked the changeover switch directly to the contact elements of the electromagnetic circuit, so that the duration of the current supply depends on the more or less high speed, with which the switch was operated by hand, could vary. If it is too quick Actuation, it could therefore happen that the switching time was not sufficient for the To operate locks so that the switch operated again or even several times had to become. The operator was forced to switch the switch with the appropriate Attention to or the same for a sufficient amount of time in his To hold the switch-on position. The invention aims to address this deficiency remove.

The invention consists essentially in the fact that between the manual control element and the contact elements of the switch, a movable contact member is arranged which is independent of the respective speed of manual actuation of the manual actuator of the switch during a certain, constant period of time is held in its on position.

In a device designed according to the invention, the changeover switch can be operated for any longer or shorter period of time, and it does not need to held in its on position by hand for a certain period of time to become. In any case, the special, movable contact element causes one very specific, constant and predeterminable switching time is automatically adhered to so that the operator does not pay special attention to it got to. In order for the device to work properly, the current remains for a period of time switched on. However, this time no longer depends on arbitrariness or attention the operator, but it is automatically observed whether the operator is now move the switch by hand only briefly or hold it there for a long time.

In the event that the electrical actuation should fail, it is expediently ensured that the locking element also mechanically if necessary an arbitrary hand-operated organ can be unlocked. This will In any case, an opening option for all locks is guaranteed.

The invention is described in the following description with reference to the drawing which exemplifies various embodiments of the invention.

A b b. Fig. 1 shows, in side view, a changeover switch or commutator according to the invention; A b b. 2 shows an end view of the switch according to A b b. 1; A b b. 3 and 4 show schematically the changeover switch according to A b b. 1 in different operating positions; A b b. Fig. 5 schematically shows the mechanism for operating the changeover switch; A b b. 6 shows a variant of a detail of the mechanism according to A b b. 5; A b b. 7 schematically shows, in a partially sectioned side view, the locking member and the electromagnets actuating the same; A b b. 8 shows a variant of a detail of the locking device according to A b b. 7; A b b. 9 shows a locking device in a section along the line AA of A b b. 7; A b b. 10 finally shows a circuit diagram for a locking device according to the invention. The practical implementation of an electromagnetic locking and unlocking device for locks or the like according to the invention proceeds, for example, as follows: The electromechanical part of a changeover switch or commutator for actuating the locking electromagnets contains an insulating body 1 of essentially triangular shape (A b b. 1 and 2). The insulating body 1 is provided with conductive contact elements 2 and 3 on which contact pieces 4 and 5, respectively, can slide, which are carried by a tiltable carrier 6 which is articulated at point 7 to a movable arm 8. The arm 8 can rotate about an axis 9 with respect to the insulating body 1. The rotary movement of the arm 8, which takes place during the locking or unlocking operations, is effected by means of a mechanism described below.

The axis 9, the arm 8 and the carrier 6 are electrical conductors, so that the contact pieces 4 and 5, during their contact with the contact elements 2 and 3, place these elements under the voltage of the axis 9, which is connected to a power source.

A spring 10, which elastically connects the arm 8 and the carrier 6 with one another, provides the required contact pressure of the contact piece 4 on the contact element 2 and of the contact piece 5 on the contact element 3. The spring 10 is designed, dimensioned and arranged in such a way that it ensures the stability or durability of one or the other electrical contact. The triangular shape of the insulating body 1 generates an oscillating or tilting movement of the contact carrier 6 about the axis 7 at the end of the movement of the arm 8. As shown in A b b. 3 and 4, this tilting movement has the following effect: When the arm 8 rotates around the axis 9 in the direction of the arrow 11, the contact piece 5 comes into conductive contact with the contact element 3; if, on the other hand, the arm 8 rotates in the direction of arrow 12, the contact piece 4 comes into conductive contact with the contact element 2.

In this way one has the possibility of; Contact element 2 or to put the contact element 3 under tension for a while, depending on the direction of rotation of the arm 8 from its one or its other end position. In these extreme positions where the arm 8 is located in the zones 13 or 14 the contact pieces 4 and 5 are no longer in conductive contact with the contact elements 2 or 3, which are then no longer under tension in this way. if when the arm 8 is at the end of its movement on the side 13, the movable one represents Contact piece 5 makes electrical contact with a stationary contact piece 15, which is carried by the insulating body 1. The function of this contact piece 15 is explained in more detail below.

As you can see, the electrically conductive contact takes place between the Contact elements 2, 3 and their corresponding feed contact pieces 4 and 5, respectively a significant fraction of the displacement or rotation of the arm 8 takes place. This ensures that the contact elements 2 or 3 are each relatively stay under tension for a long time.

The rotation of the arm 8 about the axis 9 is carried out by one in A b b. 5 causes the mechanism illustrated, which contains two identical toggle levers 16, 17 which are rotatably mounted about axes 18 and 19, respectively, which are seated on the insulating body 1. Each toggle lever 16, 17 has an end 20 or 21 in the form of a fork with fork prongs of unequal length. A chest-shaped pin 22 arranged on the arm 8 can engage in this fork, wherein the inner profile of the fork can have a polygonal tip. A movable part 23 can move one or the other lever 16 or 17 symmetrically by acting on the end 24 or 25 of the lever in question. In addition, the two toggle levers 16 and 17 are elastically connected to one another by a spring 26.

When the part 23 is shifted to the right in the drawing, the subsequent movement of the fork 21 forces the arm 8 to rotate in the direction of the arrow 11 (from b. 3). In the course of this rotation, the pin 22 engages more and more in the fork 20 , and the spring 26 is tensioned. When it rotates about the axis 19, the fork 21 becomes the tangent with respect to the displacement of the pin 22 and releases this pin in this way. The movement of the fork 20 under the action of the spring 26 ensures the end phase of the movement of the arm 8, during which the contact piece 5 remains in conductive contact with the contact element 3 for a sufficiently long time.

It is clear that during this final phase of the movement, the duration of the contact of the contact piece 5 with the contact element 3 depends above all on the elastic properties or the characteristics of the spring 26 and not on the more or less high speed of the displacement movement, which the Part 23 was originally given.

If the arm 8 has reached the side 14 of the insulating body 1 in this way in the direction of the arrow 11 , a displacement of the part 23 in the drawing to the left in a similar way will result in a movement of the arm 8 in the direction of the arrow 12 (A b b . 4) cause.

The part 23 can be operated by hand, for example with the aid of a key. The operation of this key then causes the contact elements 2 and 3 to be energized for a certain time in the manner described above.

In the embodiment according to A b b. 5, the part 23 moves on an arc of a circle. Of course, the displacement movement can take place in any other, equivalent way. Such a variant is in A b b. 6, the ends 24, 25 of the toggle levers 16 and 17, respectively, being actuated by means of a cam 27.

All of these facilities can easily be attached to vehicles, in particular be attached to motor vehicles, especially the switch described arranged in the immediate vicinity of a door lock and this through the key Lock can be operated.

Each lock to be locked has an axially displaceable locking member 28 (A b b. 7), which consists of a rod whose one end forms the movable cores of electromagnets 29,30. The windings these electromagnets 29 and 30 are connected to the corresponding contact elements 2 or 3 of the switch described above. In the case of A b b. 7 it is assumed that that the locking is brought about by temporarily energizing the electromagnet 29 is, while the solenoid 30 causes the unlocking.

If necessary, the unlocking, i. H. solving the blocking of the Locks, also mechanically through the action of a finger that is steered at 32 31 can be made on the end of the locking member 28. When the finger 31 is in the direction of of the arrow 33 is lowered, it rests on an inclined part 34 of the locking member 28 and pushes this organ back, the end of which is in the unlocked position 35 arrives.

According to one in A b b. The variant illustrated in FIG. 8 can be the finger 31 can also be replaced by a lever 36 which acts on the end of the locking member 28 works.

The way in which the axial movement of the locking member 28 is used to lock the lock can be very different in practice be. A b b. 9 shows an example of such a lock, which specifically is suitable for the door locks of motor vehicles. Unlocking the lock is normally by a rotation of the articulated at 38 part 37 in the sense of the arrow 39 is achieved. To lock the lock, the locking member 28 is in a Brought locked position, in which there is a rotation of the part 37 in the direction of the Arrow 39 opposes, as from A b b. 9 can be seen.

In A b b. 7, a spring 40 is also indicated, which ensures the stability of the end positions of the locking member 28. An element 41, shown only schematically, makes contact with a ring 42 of the locking member when the latter is in its unlocked position.

A b b. 10 shows a circuit diagram for the electrical connections that exist between a power source 43, a commutation switch of the type described and two lock locking devices which are electrically connected in parallel. A fuse 44 is built into the power supply line. Furthermore, a test or control lamp 45 is provided, which is fed via the stationary contact piece 15 of the insulating body 1 and the contact parts 41, 42. The lamp 45 lights up when the changeover switch is in its locked position, but one of the locking devices happened to remain in its unlocked position.

An electromagnetic one embodied as above, for example Locking device for locks or the like, especially for automobile locks numerous advantages over the previously known devices of this type. before It all offers great functional reliability regardless of the type of actuation the locking device. In addition, the invention is in no way limited to embodiments described above and shown in the drawing, but it includes all variants within the scope of the essential inventive concept.

Claims (5)

Claims: 1. Device for simultaneous locking or unlocking several locks, in particular door locks of motor vehicles, in which each Lock is provided with an unlockable locking device, which is activated by electromagnets, temporarily from a common switch for all locks with electricity be supplied, can be operated, thereby g e k e n n -z e i c h n e t that a movable one between the manual control element and the contact elements of the switch Contact member is arranged, which is independent of the respective speed the manual operation of the manual actuator of the switch during a certain, constant period of time is held in its switch-on position. 2. Device according to claim 1, characterized in that the changeover switch has a substantially triangular insulating body (1) which carries two contact elements (2, 3) which are connected to the electromagnets (29, 30) and which are connected via contact pieces (4 , 5) which are attached to a tiltably mounted support (6) which is articulated to an arm (8) which is rotatable with respect to the insulating body (1). 3. Apparatus according to claim 1 and 2, characterized in that the rotatable Arm (8) of the switch is operated by a mechanism which consists of two coupled to one another by a spring (26). Levers (16, 17) consists of their movement partly from the effect of a key or the like and partly from the effect the spring (26) results. 4. Apparatus according to claim 1 and 2, characterized in that that the insulating body (1) of the switch carries a contact piece (15) over which a control lamp (45) is fed, which lights up when a locking element in its unlocked position remains while the switch is in the locked position is located. 5. Device according to one or more of claims 1 to 4, characterized characterized in that the locking member (28) optionally electromagnetically by actuation of the switch or mechanically by an arbitrary hand-operated organ (31) can be unlocked.