DE1088142B - Pulse-controlled relay - Google Patents

Description

In the case of remotely controllable relays whose switching part is controlled by a mechanical resonance system, e.g. B. resonance tongues, triggered, as it is often used for audio frequency overlay systems, makes a Defined, especially prolonged contact difficulties. With regard to high resonance sharpness the tongues must be dampened as little as possible, so they must not be used to. Work performance used will. Usually one has helped oneself in such a way that one protrudes a button into the vibration path of the tongue left, which is held by a stop at a certain distance from the rest position of the tongue. As soon as the tongue has rocked, this button is thrown up and repeated if necessary thrown up and then actuates a switch contact. As the amplitude and frequency of the stylus movement changes with each remote control act, such a button cannot be used to create a defined, i.e. none achieve secure contact; much less is there any guarantee that this. Always making contact has a very specific, once and for all fixed duration and then stops again.

.You can use the button on a switching shaft Let the seated wheel click away and only interlock it over 180 ° so that it is long enough Transmission pulse makes a half-turn, which closes a switch, for example. One achieves but hereby only a permanent contact. If this is to be lifted again, you need one another tongue, another button .with a ratchet and another ratchet wheel, the other half is interlocked, and it must then be sent a second frequency. the selector shaft back into the Bring the starting position and open the switch. But since, as mentioned, the buttons do not work regularly, also fluctuates here the ΖείίαΕμεΓ of the contact, Quite apart from the fact that to achieve this temporary contact closure an increased effort is required.

Is known, particularly for overlay remote. Control systems, a resonance relay that represents a significant advance in terms of defined contact represents. This resonance relay is also equipped with a mechanical oscillation system, and a voii equipped with this ejected button, which moves a switching element from an initial position into its operative position throws. The switching element is, for example, a pair of resiliently held contacts formed, which are open in the rest position. In addition, this relay has a holding device, z. B, a magnet, to hold the resonance system in place The rocked button is provided in its operative position, thus also the switching element holds in its operative position. In addition, at die-Imptile-controlled relay

Applicant:

Siemens-Schuckertwerke

Corporation,

Berlin and Erlangen,

Erlangen, Werner-von-Siemens-Str. 50

Friedrich Schmidt, Nuremberg,

and Hermann Ebert, Schwaig near Nuremberg,

have been named as inventors

sem relay a drive is provided which, when the contact closes the switching element in action, after a period of time the contact closure again • cancels. With this known relay it can be achieved with precise adjustment of the button distance from the switching element on the one hand and from the magnet on the other hand that the button is suddenly attracted by the magnet at a certain deflection distance and thus also jerks the switching element to contact closure. However, this setting is not easy and requires great care and trained personnel ; because the force of attraction of the magnet is counteracted by the vibration energy stored in the rocking button, and when setting it must be avoided that the magnet does not attract the button for a short time and thereby already makes contact, but then lets go of the button again, in order to finally hold it only with the next or a further oscillation. These adjustment difficulties also occur in the known relay when other holding devices are used instead of a magnet.

The invention relates to a pulse-controlled relay that, like the aforementioned known relay, with a determinable closing time of its normally open contact that is independent of the duration of the control pulse and provided with a drive controlled by the relay to open the closed normally open contact is. According to the invention, however, such a relay is characterized in that a movable first The contact piece of the normally open contact is held in the open position by a latch against a storage force will, after unlatching by the control pulse, hits its mating contact piece and thereby a

ch an I.

009 589/348 I.

Actuator triggers, which brings the first contact piece back into its latched position.

In contrast to the aforementioned known relay, a closing means is not used during the Receiving working drive, but an energy store. An equally important differentiator of the subject matter of the invention compared to the known relay mentioned is also that its the triggering, first. Contact piece against a storage force holding latch not the closed position of the Working contact ensures, but the open position; that it only triggers the contact, but not brings about, and that they can therefore not have an erroneous influence on the contact. Further Advantages of the relay according to the invention become apparent in the following detailed explanation of the invention and the description of some exemplary embodiments of the invention with reference to the drawing.

Fig. 1 shows the mode of operation of a simple principle example in the movement phases α to / to explain the concept of the invention;

Fig. 2 shows an embodiment with a magnetic drive for canceling the contact;

Fig. 3 to 6 show another embodiment in different phases of movement that with a thermal drive, here with bimetal, works.

In Fig. 1, the switching element consists of the two switching elements 1 and 2 and the contacts 5 and 6 held by them. The first switching element 1, which carries the contact 5, is in the rest position of the relay (phase a) by a pawl 3 locked and is in this position under the action of an energy storage device indicated here by a spring 4. The pawl 3 holds itself in its locked position and can be brought into the disengaged position by remote control. The second switching element 2, which carries the contact 6, rests on a stop 7, which, however, can also be omitted if this rest position is fixed in another way. A stop 8 is attached in its way. The link 2 is connected to a reversible drive. The whole arrangement is coordinated so that the link 1 has a relatively greater inertia than the link 2, based on the ratio of mass to driving force.

If the pawl 3 is temporarily disengaged when a remote control pulse arrives, then the relaxing spring 4 moves the switching element 1 to the element 2 until it touches, i.e. contact closure, of the two contacts 5 and 6 Member 2 switches on a propulsion which acts in the direction of arrow P. The duty cycle of the propulsion is indicated by the hatched rectangle 9. The contacts 5 and 6, or contacts working in parallel with them, on the other hand, simultaneously provide a power supply for the device to be operated remotely. This short-circuit lasts exactly as long as the on-time of the propulsion and accordingly also corresponds to the rectangle 9. The start of the short-circuit is determined by phase b .

Now the link 2 pushes the link 1 in the direction of the arrow, while constantly maintaining the contact closure, until it finally (phase c) hits the stop 8. The stop 8 is arranged in such a way that the link 1 reaches behind the pawl 3 with certainty. While the link 2 remains at the stop 8, the link 1 (phase d) continues to move temporarily in the direction of the arrow due to its inertia, whereby the contacts 5 and 6 are separated and the link 2 is switched to reverse drive, the duration of which is determined by the dashed rectangle 10 is indicated. At the same time, the contact for the device to be remotely controlled is interrupted (end of rectangle 9). The link 2 now returns relatively quickly (phases e and f) to its starting position at the stop 7, while the link 1 first reverses its movement due to its greater inertia and then comes back to the pawl 3, where it is latched again (phases e and f ) . So there is no renewed contact after the reversal of movement of the link 1, because the less sluggish link 2 has moved away in the meantime. In phase /, which corresponds to phase α , the relay is in its starting position. After receiving a remote control pulse, there was a temporary contact of precisely defined duration, rectangle 9.

In the exemplary embodiment in FIG. 2, corresponding parts are provided with the same reference numerals As in FIG. 1. The force of gravity here serves as the storage force for the link 1; limb 1 is a pendulum executed. The greater inertia is indicated by a correspondingly larger mass 11. The advance supplies an electromagnet 12 with Z-Ankerl3, the return drive a spring 14, to wind the magnet 12, the remotely operated device 15 is connected in parallel. The device can e.g. B. be one winding of a toggle switch that activates a hot water tank causes a second winding of the toggle switch to turn it off.

The arrangement works as follows: The pawl 3 is disengaged again by a remote control pulse, the pendulum 1 lies against the link 2 with a contact closure, thereby the magnet 12 and the device 15 are switched on, the magnet moves the link 2 while maintaining the contact closure in the Direction of arrow P until it hits stop 8. However, under the action of inertia, the link 1 continues to oscillate in the direction of the arrow P and thereby opens the contact. As a result, the magnet 12 and the device 15 are de-energized again. The link 2 is brought back into the starting position by the spring 14, the link 1 is latched into the position shown by the pawl 3, which has now collapsed again.

In FIGS. 3 to 6, too, corresponding parts are provided with the same reference numerals as in FIGS 1 and 2. Instead of a magnetic drive force, a thermal force is used here. the Links 1 and 2 consist of bimetal springs that bend in the direction of the arrow when heated and in the cold state rest against the stop 7 or the pawl 3 with a certain bias. Both Bimetal springs have a common heating coil 120, which are switched on via contacts 5 and 6 can. The device 15 to be operated remotely lies parallel to the heating coil 120. The pawl 3 forms here the rear extension of a button 30. The stop 31 at a certain distance is held by the rest position of a resonance tongue 32. The tongue is made up of by a capacitor 33 Magnet 34 supplemented to form an electrical oscillating circuit is excited. The spring 1 has a larger one thermal inertia than the spring 2.

The arrangement works as follows: When a remote control pulse arrives, the resonance frequency the tongue 32 has - this frequency is in the resonance range of the oscillating circuit 33,34 - will the button 30 thrown up. As a result, the spring 1 is unlatched and lies down under the action their bias and under contact closure, here

Switching on the heating coil 120, against the spring 2 (Fig. 4). At the same time she holds the button 30 in the specified position.

Now the tongues are heated up and move in the while maintaining the contact closure Direction of the arrow until the spring 2 hits the stop 8. The spring 1, which has a greater thermal inertia has than the spring 2, but moves still further and thereby removes the contact closure (Fig. 5 and 6). In the meantime it has left the pawl 3 so that the button 30 can return to the stop 31 again. In the meantime, however, the remote control impulse has ceased. ^ As a result of the interruption of contact, the Wick- ' ment 120 is switched off, and the springs 1 and 2 move while cooling in an opposite direction to the arrow Direction, the spring 1 slower than the spring 2 because of its greater thermal inertia. Finally, the spring 1 is latched again and the spring 2 rests again on the stop 7 (FIG. 3).

Depending on the coordination of the inertia of the bimetal springs, the strength of the heating and the size of the covered Longer or shorter contact times can be obtained here.

Claims (13)

Claims: a5 1. Pulse-controlled relay with a determinable, independent of the duration of the control pulse Closing time of its working contact, with a drive controlled by the relay to open of the closed working contact, characterized in that a movable first contact piece (5) of the normally open contact of a pawl (3) against a storage force (4 in Fig. 1) in the open position is held, after unlatching by the control pulse on its mating contact piece (6, second Contact piece) and thereby triggers a drive that the first contact piece (5) in brings back its latched position. 2. Relay according to claim 1, characterized in that the drive when returning the first Contact piece (5) the second contact piece (6) part of Ses return path in the closed position moved with it, whereupon the second contact piece (6) returns to its open position. 3. Relay according to claim 2, characterized in that the drive is also the return of the second Causes contact piece (6) in its open position. 4. Relay according to claim 2 and 3, characterized in that to limit the tracking distance of the second contact piece, a fixed stop (8) is provided. 5. Relay according to claim 1 to 4, characterized in that the drive on the second contact piece engages and moves the first contact piece by means of the second. 6. Relay according to claim 1 to 5, characterized by a spring holder of the first contact piece (Fig. 1). 7. Relay according to claim 1 to 5, characterized by a pendulum holder of the first contact piece (Fig. 2). 8. Relay according to claim 1 to 5, characterized by a heat-storing holder of the first Contact piece (Fig. 3 to 6). 9. Relay according to claim 1 to 8, characterized by an electric motor drive (Fig. 2). 10. Relay according to claim 1 to 8, characterized by a thermal drive (Fig. 3 to 6). 11. Relay according to claim 10, characterized in that the holder of both contact pieces (5, 6) consists of bimetal springs (1 and 2 in Fig. 3 to 6) that the bimetal spring (1) of the first contact piece (5) has a greater thermal inertia than that of the second contact piece (6) and that a heating device (120) is provided for both springs, which, depending on the Relative movement of the two contacts, switches on when the contact closes and when the contact opens turns off. 12. Relay according to claim 1 to 11, characterized in that as a pawl for holding the first contact piece a button (30 in Fig. 3 to 6) is provided, which is known per se Way notched by a resonance organ (32) that vibrates due to remote excitation will. 13. Relay according to claim 12, characterized by such a design and arrangement of the Button that this from the unlocked first contact piece (5) or from its holder in the notch is held. Considered publications:
German patent specification No. 921 815. 1 sheet of drawings © 009 589/348 8.60