DE462728C - Device for controlling switching devices in self-connecting telephone systems - Google Patents

Description

The subject of the present invention is a relay device for automatic Telephone systems and the like, in which, under the action of one or more groups of electrical surges, certain Effects are caused. The primary purpose of the invention is to make such devices effective actuated by compressed air or a similar means.

So far, compressed air has only been used to operate certain types of switchgear, namely so-called searchers, used, the z. B. the connection of a subscriber line with a specific point in the telephone exchange. In contrast, the present invention, in particular to operate switching devices by compressed air below Surveillance by power surges, which in the case of self-connecting systems from the transmitter equipment of the participants go out.

In one embodiment of the invention, an apparatus is used in which compressed air or the like, ζ. B. negative pressure or oil, acts on a number of engines in such a way that that after one of the motors responded to the individual bumps of a group has, a second motor is operated, which switches off the first-mentioned motor and then turns on a third motor so that it responds to the following group of shocks and can perform any desired function. The arrangement is such that the third engine is not started before the first engine ceases to operate can be.

Facilities are also provided that will be activated when the calling subscriber hangs up his receiver to release the switched on device. This triggering is monitored by a valve, which during the existence of a Connection is always open to keep the facility in the effective position while ·. rend the valve is closed after termination of a connection and the power means switches off, so that after the end of a call, the device returns to its returned to normal. Such a valve has such a design that it when Picking up the handset at the calling subscriber station responds immediately and through short successive power interruptions in the subscriber line unaffected remains, on the other hand in the event of a longer interruption of the current in the partial ■ subscriber line, as happens when hanging the listener, returned to its initial position.

The invention is explained in more detail with reference to the accompanying drawing. It means:

Fig. Ι a relay in an example of

type of guide with the associated line connections,

Fig. 2 is a top view of Fig. I, Fig. 3 is a vertical section through the Valve housing on an enlarged scale,

Fig. 4 is a section along line 4-4 of Fig. 3,

Fig. 5 is a section through a coming to use, pneumatically driven Driving device that works slowly in "one direction".

Figs. 6 and 7 are vertical sections through

a fast operating drive device with a short stroke, which is designed like a bellows, once in an expanded state, the other time in a compressed state.

Figure 8 is a schematic representation of the members associated with the relay device with their connections,

Fig. 9 is a similar schematic representation with a different arrangement of the valves and drive devices,

First of all, the valve used according to the invention, as shown in FIGS. 3 and 4, will be explained. The same consists of a housing 19 with a; Inlet pipe 20 and an outlet pipe 21 and valve openings 22 is provided. Two valve members 23 and 24 are provided within the housing 19, the rods 25 and 26 of which can abut against one another in a narrow channel 27. This channel connects the valve chambers with the outlet 21. The compressed air present in the pipe 20 usually keeps the valve members in the position shown in FIG. The member 23 has a pin 28 protruding from the housing wall, which is usually in contact with an armature 14 (FIG. 1) and acts on the valve 19. The entire apparatus, as shown in Fig. 3, will be referred to briefly as valve 19 in the following description.

Coil 13 (Fig. 1) has a single winding which is connected to lines 1 and 2, which z. B. belong to a telephone, self-access system. Around the pin 11 of a pole piece 12 of the coil 13, the relatively heavy armature 14 is mounted so that it can swing out; it has an upwardly curved side arm 15 which has a nose 16 made of insulating material. In the immediate vicinity of this nose 16, contact springs 17 and 18 are provided, which come into conductive contact with one another as soon as current flows through the coil 13 and the armature 14 is attracted.

At a suitable point on the valve 19 the pin 28 rests against the armature 14 and holds it against the action of a spring 29, which seeks to move the anchor into the tightened position in which Rest position. The tension of the spring 29 is such that its exerted on the armature Tensile force is less than the pressure exerted by the pin 28, so that accordingly . the anchor usually occupies an exactly vertical position.

However, if current flows through the coil 13, then that exerted on the armature 14 is applied The magnetic force is amplified sufficiently by the spring 29 to reduce the force acting on the member 24 exerted force of the compressed air to overcome, with the result that the members 23 and 24 are adjusted and thus establish the connection between the pipe 20 and the pipe 21, while the connection to the outlet valve 22 is interrupted. The compressed air now finds its way to the pipe 21 and arrives into the apparatus described later.

At the other end of the pole piece 12, an armature 30 is attached so that it can swing out at its tail end carries an insulation piece 31 which rests against a spring 32. This spring 32 usually holds the armature 30 in its retracted position. But flows Current through the coil 13, then the armature 30 is also attracted and moves the spring 32 away from the spring 33, thereby interrupting the electrical connection.

If the subscriber sets up a connection between lines 1 and 2 by lifting his handset off the hook, current flows from battery B through coil 13 via lines 1 and 2 and via resistor R back to battery B. As soon as the coil is energized , both anchors 14 and 30 are tightened. If the connection between 1 and 2 is interrupted and immediately closed again quickly, as occurs when the power surges are transmitted in self-connecting telephone systems, then the armature 30 responds to all these power surges like a fast-acting relay, but the armature 14 acts like that Armature of a slow acting relay and does not respond to all of these surges. In other words: the relay works like a fast-acting relay insofar as the armature 30 comes into consideration, but like a slow-acting relay insofar as the armature 14 comes into question. The armature 14 responds only slowly because the force acting on the pin due to the air pressure is only slightly greater than the opposing force exerted by the spring 29, and because the weight to be moved is also quite heavy. In the short time intervals in the intermittent excitation of the coil 13, this small force is not strong enough to move the armature enough to thereby the

Connection between springs 17 and 18 to interrupt. The armature 14 remains in these short consecutive current surges, as far as its practical effect is concerned, stand still while the anchor 30 corresponds in its effect to all power surges in quick succession.

The springs 17 and 18 as well as 32 and 33 are indicated by dotted lines in Fig. 1 Lines connected to apparatuses that can consist of relays, switches and the like, such as they are common when a connection is established in self-access telephone systems are.

The relay shown in Fig. 1 and 2 closes the circuit when it works and keeps it closed by springs 17 and 18, while at the same time over the springs 32 and 33 individual current surges are transmitted.

Fig. 5 shows an engine with a pipe 34 into which compressed air is passed, which from a valve comes, which is of the type of valve 19 shown in Figs is. A head 35 is provided at the end of the tube 34 and has a head above this the drive device has a cap 36. If compressed air is introduced into the tube 34, then the cap 36 rises, and if the air is released from the tube again, then falls the cap.

In the embodiment of FIG. 5 there is a shut-off valve 37 which does not close completely provided, which allows the air to pass freely to press against the cap 36 and to lift them quickly while preventing the air from escaping quickly, so that the cap can only slowly return to its initial position, namely to the extent that the air passes through the wall gaps inside the cap or through the valve 37 finds its way through. The whole apparatus is a propulsion device, which works quickly and slowly returns to its resting position. Drive devices of this type are referred to as slow drive devices in the description below are designated and are indicated on the drawing by a conical cap, although of course the particular shape of the cap has nothing to do with the action of the drive device. The lower part of the Head 35 is conical, and in the closed lower end of cap 36 a correspondingly conical seat 38 is provided. The cap 36 rises to its highest point Position, then the head 35 rests on the seat 38. If the air is let out above the head, then air must be passed under the head; before the cap can fall. Through this, that the head rests on the seat 38, the motor is caused to move downwards experiences a delay. This delay stops as soon as the movement is initiated; she finds in addition the delay caused by the valve 37 takes place and serves as a further means to to allow the drive device to slowly return to its rest position.

Another drive device that can be used consists of a cap 40, which is attached to a stationary part 39 with a connected compressed air line (Fig. 8 and 9). With this type of drive device, the compressed air finds its way into or outward movement no inhibition so that the canopy moves in both directions with equal ease. For this reason, this drive device is referred to in the further description as fast drive device in contrast to the slow drive device described are designated. The fast drive device is indicated in the drawing by its straight cap. Another embodiment of the drive device is that shown in Figs Bellows drive device. It resembles a metallic harmonica and consists of Discs 7 and 8 articulated to one another. By supplying compressed air it is inflated and by evacuating the air it gets into the compressed one Location. It is used for short movements instead of the fast drive device and is of a simpler design and cheap to make.

In some cases, the valve can be driven by an electromagnet instead of the armature other means are actuated, as described in an exemplary embodiment will.

In Fig. 8, an electromagnet 43 is shown, the two with the trunk lines 1 and has 2 connected windings. This electromagnet 43 differs from the Electromagnet 13 insofar as it has only one armature 44. Is this located in the attracted position, then he acts on a no valve 49, which every excitation of the Coil follows because the spring 29 of Fig. 1 is missing. If the circuit is closed via magnet 43 and the armature 44 is attracted, then this opens the valve 49. This allows compressed air from the supply pipe 20 to the Bellows valve 50 reach and via pipe 51 also to the slow motor 42 its way Find. The bellows valve 50 expands suddenly and brings the angle lever 53 to Swing out so that the normally open valve 48 can close. the

Drive device 42 gives when climbing the spring 45 free, which then opens the valve 47 through the lever 46 and compressed air from Tube 20 can reach valve 48 via tube 58. But since this valve 48 through the action of the bellows valve 50 is closed, air cannot pass through this valve keep flowing.

In the case of self-access systems, the closing of the circuit is through. Magnets 43 a preparatory step and independent of the effect of the sending device. at whose actuation the circuit is first interrupted and then closed again, and when this effect ends, the circuit remains closed. The apparatus described here is set up so that it acts under the influence of current surges sent in this way through the line. ao In the following description it is assumed that the current surges with a Speed of 10 or more per second can be transmitted.

If the circuit is interrupted by the magnet 43, the armature 44 falls back and enables the valve 49 to be closed. The bellows valve 50 is thereby emptied, consequently the spring 59 can pull the lever 53 into the position shown in FIG. That Valve 48 is thereby opened and causes the compressed air coming from pipe 58 through Pipe 52 to flow to motors 40 and 41, both of which rise instantaneously. Will hereafter the circuit is closed again, then the valve 48 also closes, and the drive device 40 immediately falls into its starting position return. The drive device rises at the next power interruption again, only to fall again the next time the power is cut off. In this way the drive device speaks 40 to all current surges that flow through the magnet 43 as long as this current flow continues. The - drive device 41 but remains during the alternating action of the drive device 40 in a raised position because they have a slow drive device according to the Execution of Fig. 5 is. The drive device 41 only falls back into its initial position after the end of a surge group. The drive device 42 receives air from the valve 49 and pipe 51 every time when the armature 44 is tightened and the drive device 41 receives air through valve 47 and 48 through tube 52 each time armature 47 is in its The rest position falls back, provided that the drive device 42 is operated properly will. If current surges flow through magnets 43 in the manner described, then both receive slow drive devices enough air to be held in its elevated position. Is a group of electrical surges terminated when the circuit of the magnet is closed, then the drive device falls 41 back while the drive device 42 still remains raised. Will the circuit is interrupted for a long time, then the drive device 42 drops back and 'cuts off the air supply to valve 47.

It can be seen that valve 47 and valve 19 (Fig. 3) have the same effect evoke under the same conditions but in different ways. ■

In self-access telephone systems, the various drive devices described have been described all to do a certain job, mostly by overcoming the force of a spring or weight; the details are irrelevant for the present invention. Rather, it just depends on the special effect.

Current surges flowing through the magnet 43 cause the attraction and fall of the Armature 44, which in turn causes air currents in the tubes 51 and 52, which the Magnetic excitations correspond. The propulsion device 40 speaks in all of these flows and executes as many strokes as the armature 44. The driving device 41 on the other hand, does not respond to the individual power surges, rather it is during the Sending a group of power surges held in their elevated position and power only one hub for each group '. The drive device 42 remains in its elevated position during the transition from a group from power surges to another and only falls back when the circuit continues interrupted by the magnet.

In the embodiment of Fig. 9, part of the prescribed effect is provided this is exerted by the drive device 42 on a further drive device 62, and the pipe 51 is connected to the drive device 62.

In this embodiment, the valve 47 is driven by the drive device 62 is controlled and tube 58 directs air to both valve 48 and the drive device 42. The drive device 40 is in the manner described above through the valve 48 and the tube 52 operated, but the drive device 41 is operated by a special Drive device 63, the valve 64 with the pipe 65 controlled.

The relationships among the effects of the driving devices 40, 42 and 41 and the current impulses flowing through magnets 43 are the same as those shown with reference to Fig. 8

portrays. The main difference between Figs. 8 and 9 is only the insertion of the drive devices 62 and 63. This addition has only meaning with regard to the special devices, which are still to be activated as a result, but which have no particular influence on the present one Practice invention.

Fig. 9 has only been chosen to show that, through the addition of special further drive devices 62 and 63 does not affect the essence of the invention will. Both versions of Figs. 8 and 9 use slow and fast drive devices, which are influenced by a single armature of a magnet 43 independently of one another.

In the case of automatic telephone systems, some links only work in one Direction, while other limbs first in one direction and then in the other Act direction. Fast and slow acting magnets and a considerable number of relays and other auxiliary links are required. Apart from that, a holding device is also required through which the apparatus held in a certain advanced position while switching from one switch to another will.

The fast drive devices 40 and slow drive devices 41 represent in their action the fast and slow acting magnets, and the drive device 42 serves to hold certain apparatus during two successive actions.
The device is of course not limited to automatic telephone systems, but includes a wide range of applications.

Claims (8)

Patent claims: i. Device for controlling switching devices in self-connecting telephone systems, their drive is effected by a pressure medium supplied via a pipe or a group of pipes and is controlled by electrical current surges, characterized in that a slow, pneumatic or electric (by an electromagnet) controlled valve (19,47,64) to allow the pressure medium Driving device of the switching device regulates by it when it arrives electrical Current surges is transferred to its working position and controlled in such a way It becomes that it will only slowly return to its rest position and consequently during the transmission of a group electrical surges remain effective. 2. Apparatus according to claim i, characterized characterized in that the inert valve (19,47) is so in a group of Tubes is arranged so that when an electromagnet (13, 43) is excited is actuated and controls the admission of the pressure medium to the tubes by it is operated as long as the excitation of the electromagnet lasts, regardless of whether this is intermittent due to a group of electrical surges or uninterrupted is energized before or after the cessation of the impulses, and that the valve is in its rest position only returns when the electromagnet is de-energized. 3. Apparatus according to claim 1, characterized in that the inert valve (64) is arranged in a group of tubes in such a way that it is not actuated, when the solenoid (43) regulating the pressure medium admission is energized, on the other hand it is actuated when the solenoid is de-energized, so that the valve is in intermittent excitation of the electromagnet is in the working position due to a group of power surges but returns to the rest position, when the electromagnet is continuously energized after the surge group has ceased. 4. Apparatus according to claim 1 and 2, characterized in that the movement of the inertial valve (19) in one direction under the combined action a magnet (13) and an auxiliary force (spring 29) quickly and in the other Direction under the pressure of the propellant takes place slowly, as this is the effect of the auxiliary power after the shutdown the magnet must overcome, 5. Arrangement according to claim 1 to 3, characterized in that the sluggish Valve (47, 64) is moved by a pneumatic drive device (62, 63, 42) which is actuated by the pressure medium is and is provided with internal control means (37, 38), which in one direction cause a quick movement so that the valve is operated quickly, but one in the opposite direction cause slow movement so that the valve slowly returns to the rest position. 6. Apparatus according to claim 2 and 3, characterized in that the electromagnet (13) by means of its delayed working armature (14) the effect of a Monitored valve (19) and at the same time also acts on contacts (17, 18), so that the valve and the contacts during brief power interruptions are held in their working position by the electromagnet (13) and only return to their original position after the end of the surge group. 7. Apparatus according to claim 1, 2 and 3, characterized in that one and the same electromagnet (43) that of is controlled from a remote point, acts on two valves (47, 49 or 48, 64), one of which (49,48) in the beat of the individual thrusts of a group is influenced, while the other (47, 64) remains in its working position during the transmission of a shock group. 8. The device according to claim 1, characterized in that a pressure medium drive device (40) is controlled under the influence of electrical surges so that the compressed air to the Drive device usually cannot be accessed when the armature (44) of the control solenoid is in the attracted state Position (through 48) or in its rest position (through 47), but intermittently the drive device (40 through 47 and 48) when the armature swings back and forth rapidly. 1 sheet of drawings