DE1157295B - Ripple control receiver working according to the synchronous selector principle - Google Patents

Description

Ripple control receiver working according to the synchronous selector principle Ripple control systems are used from a central command post via the electrical power distribution network To be able to send switching commands to any point in the network, the switching processes there can trigger for a wide variety of purposes. There is only the tariff change here of counters, the operation of coupling switches and the switching on and off of certain consumers, e.g. B. Boilers, stoves, street lights, etc. mentioned.

Ripple control systems that are superimposed on the network are very common tone-frequency command pulses work according to the synchronous selector principle. Here exist the ripple control receiver essentially consists of one that only responds to the audio frequency Pulse relay and a synchronous selector, which, triggered by a start pulse, each makes a full cycle and, at the same time, in chronological order those for the individual Switching operations intended switching relay connects with the pulse relay. Meets a command pulse following the start pulse, it brings in each of the receivers, whose synchronous selector rotate synchronously, that switching relay to respond, the from the synchronous selector of the receiver in question to its pulse relay connected is. From the time grouping of the sent by the sender, the Start impulse following command impulse it depends on which correspond to each other Switching relays of the receiver are energized during the voter rotation. One denotes this remote control method is therefore also called a time interval method.

Fig. 1 of the drawing shows an example of a conventional pulse diagram. The start impulse brings the synchronous selectors of the various ripple control receivers in the network to start up. Due to the synchronous running of the synchronous selector, very specific time intervals are provided for the subsequent command pulses. In the example shown, the start impulse is followed by a few single commands a., B ", Co, d0, which are generally used for group selection; then so-called double commands 1, 2, 3 .... in which the intended impulses are combined in pairs The second impulse of the pair contains the opposite command as the first impulse.For example, impulse 1E can switch on a consumer, while a pulse given in time interval 1 A would switch off the relevant consumer again.

In ripple control systems of this type, there is now the risk that by unwanted impulses, i.e. caused by interference impulses, incorrect switching. Such glitches can, caused by rectifiers, crane motors, etc., as so-called continuous pulses of longer duration. However, short-term ones are much more common Interference pulses, so-called interference peaks, such as those caused by switching processes in the network can be.

The probability that a Glitch causes a faulty switching, is naturally the greater, the longer is the period of time during which the synchronous selector of the receiver takes the command path keeps the individual switching relays closed. However, this period of time can end cannot be made arbitrarily small for various reasons. One reason for this lies in the fact that one cannot count on the synchronous dialers of all receivers start immediately at the beginning of the start impulse, especially not when the start impulse Due to the network conditions, individual receivers only have a greatly weakened amplitude achieved.

To ensure that all synchronous selectors start up as simultaneously as possible To achieve this, you have already had a preparatory impulse before the start impulse let, which, in itself, of any duration, only serves to draw the recipient to a greater responsiveness toggle so that they are on the following, actual start impulse, even if it arrives strongly weakened, start immediately. The resulting improved synchronism of the synchronous selector allows then a shortening of the individual command pulses. The reduced likelihood that noise just in a time interval provided for a command pulse fall, however, is offset by the fact that within this time interval as a result of the increased sensitivity, speckles of lower amplitude are also undesirable Effect.

Another known measure to avoid brief glitches if possible To make it ineffective, is that the receiver is equipped with a timer that only allows an impulse to take effect if it has a certain minimum duration having. For this purpose, the impulse is allowed to charge a capacitor to which the Pulse relay is connected in parallel via a mica discharge path, the first ignites at a certain capacitor voltage. Here, however, sturgeon pimples can also Shortest duration cause incorrect switching, namely if their amplitude is very large is or if several speckles follow each other in quick succession, because their energy content can be summed up in the capacitor.

An effective protection against incorrect switching due to the normal command pulse duration short-term interference pulses, which is based on the fact that only Impulse of a certain minimum duration can take effect, therefore the following must be Fulfill the conditions: The insufficient duration of an interference pulse must not pass an oversized amplitude of the glitch can be replaced. Several in quick succession Short-term interfering impulses arriving may not be like a correspondingly longer one Interfering impulses act. The switching relay may only open regardless of the pulse height Respond to impulses that started at the latest at a specified point in time and those without interruption at least until a second, later, likewise given time, taking into account the different circumstances in different networks or at different points in one and the same network both times must be selectable within the command transmission period.

These requirements are met by the invention, which accordingly refers to a ripple control receiver working according to the synchronous selector principle and can be realized in such a way that in one of the switching relays to be controlled common control current path is a control contact whose actuating lever by means of one with two grooves or. Cam discs cooperating control lever in the Way is controlled that the control lever, as a result of the arrival of a control pulse within the time interval given by the groove widths in a groove of the first Control disc intervenes when the control pulse is pending beyond this interval is brought into the effective range of the second control disk at the end of the interval, which is designed with their grooves or cams so that their control effect on the control contact staggered in time after the control effect of the first control disk begins.

According to the invention, the problem described above can not only be used for starting the ripple control receiver, but also a selectable one for the command pulses To stipulate the minimum duration that they must adhere to in order to take effect, including through Such a training of the receiver can be solved that a control contact, the in a control path common to the switching relay to be controlled, made up of two resilient, moved parallel to each other by cam disks driven by the synchronous motor There is tongues and one of these disks is so resiliently coupled to the other disk is that when a control pawl engages in one with the one cam disc fixed connected ratchet wheel the cams of the two cam disks against each other by one be offset at such a large angle that the resilient tongues then move against each other are, and that the control pawl of a clutch relay receiving the control pulses is arranged movably.

In Fig. 2 an embodiment of the arrangements characterized in the claims is shown. V is the control contact that is in the control current path of the switching relay to be controlled. An actuating lever Hl, which is attached to the axis A, acts on this control contact. On the axis A there is also a lever H, on the end of which a spring F acts, which endeavors to bring the actuating lever H1 into such a position that the control contact V is open. The rotatable armature of the relay K acts via the lever H on the axis A and thus on the operating lever H1. As long as there is a command pulse, a torque is exerted on the armature of the relay K in the indicated direction of the arrow, so that the relay tries to close the control contact V. However, the control contact V can only be closed when the control lever BV , which is also attached to the axis A, can turn far enough in the counterclockwise direction. The angle through which the control lever BV can be pivoted is controlled by a device which essentially consists of the two control disks P and S.

The two control disks P and S , designed as cam disks, are fastened on an axis a in such a way that their mutual angular position can be set in a selectable manner. They are driven counterclockwise by a synchronous motor Sy via two transmission gears iii and ii.

A spring F3, bent at right angles, is attached to the control lever BV and initially lies on the circumference of the control disk P when the relay K is energized. Depending on the position of the control disk P, the spring F3 can hit the outer circumference p or in a groove h of the control disk P. In both cases, the angle through which the control lever BV can be pivoted is not yet sufficient to close the control contact V. However, if the relay K remains energized until finally the spring F3 hits the radial end edge of the groove n, the spring F3 is pushed away in the axial direction, so that its end edge finally along the front face of the control disk P onto the second control disk S can fall.

After one by the chosen mutual position of the control discs P and S for a certain time, provided that the relay K remains energized, the spring F .; finally in a groove s of the second control disk S and thus finally arrives into the position in which the operating lever H1 closes the control contact V and in order to brings the associated switching relay to respond.

Brief glitches that excite relay K while the spring is running F, is still opposite the outer path p of the control disk P, so can do not cause the associated switching relay to switch. The same applies Interference pulses that arrive when the tongue F3 is already over the groove n. A closing of the control contact V can only be triggered by such impulses which begin at the latest before the tongue F has reached the end of the groove n, and which also last until said spring s the beginning of the groove second control disk S has reached. So that is not just the minimum duration, but the latest possible starting point of the command impulses can also be selected.

Another embodiment of the invention is shown in FIG. 3. Here, the synchronous motor Sy drives the two cam disks RPl and PT via the two transmission gears isl and u. On the same axis as this, the two interconnected cam disks RP, and S are loosely rotatably seated. The two last-mentioned cam disks are coupled to the first two by a spring F1, F., in such a way that they can rotate through a certain angle with respect to them .

The relay K tries, as soon as it is energized, the double lever H, which is rotatable about the axis A , to pivot counterclockwise. One arm BU of the double lever H lies on the slide t of the cam disk PT and the other arm VU on the slide 5 of the cam disk S. The action of the relay K on the double lever H takes place via the auxiliary lever hl, the axis b and the Auxiliary lever h ,.

The control contact vu consists of two resilient tongues k1 and k ,. As long as the relay K is not energized, the two cam disks RPi rotate and RP, in such a position relative to one another that their cams or grooves are axially align exactly. As a result, the two springs k, and k_, of the control contact vu always move exactly parallel to each other, so that the control contact vu constantly stays open.

If, however, the relay K is now energized, the double lever H is pivoted counterclockwise and its arm VU engages in the cam disk S, which is firmly connected to the cam disk RP. As a result, these two cam disks are temporarily held while the cam disks PT and RPl continue to rotate unhindered. There is a relative rotation between the two cam disks RPi and RP ,, which has the consequence that the control contact vu now closes because the two springs k1 and k., Now no longer move parallel to each other. The end of the groove S thus determines the latest point in time at which an effective command pulse must begin, while the minimum duration of this command pulse is determined by the possible angular rotation of the two cam disks RPi and RP, "relative to one another.

The embodiment described above is designed so that it also ensures protection against incorrect switching due to continuous pulses. For this purpose, in the course of the power transmission path from the relay K to the double lever H, a stationary, rotatable permanent pulse pawl i is inserted such that lever h. acts via the spring F and the pawl i on the lever H sitting loosely on the shaft A. The slideway pt of the cam plate PT is designed in such a way that if the relay K is tightened for too long, the double lever H is pivoted clockwise to such an extent that the pawl i, of the shoulder o of the auxiliary lever h. no longer held, snaps to the right under the tension of a spring f, so that its cranked part now lies against the vertical surface of the projection o and thus the lever H with its arms BU and VU against the action of the cam disks Pt and S for so long blocks until the relay K is energized again, which then the readiness position is restored.

The exemplary embodiments described are particularly suitable for construction as a closed construction unit that does not interfere with the construction of the Normal receiver can also be installed at any time.

Claims (3)

PATENT CLAIMS: 1. Ripple control receiver working according to the synchronous selector principle, characterized in that a control current path (V) is located in a control current path that is common to the switching relay to be controlled, the actuating lever (H1) of which is in the control lever (BV) by means of a control lever (BV) which cooperates with two grooved or cam disks It is controlled in such a way that the control lever (BV), as a result of the arrival of a control pulse within the time interval given by the groove widths, engages in a groove (s) of the first control disk (P), if a control pulse is pending beyond this interval at the end of the interval in the effective range of the second Control disk (S) is brought, which is designed with its grooves (s) or cams so that its control effect on the control contact (V) begins offset in time after the control effect of the first control disk (P). 2. Ripple control receiver working according to the synchronous selector principle, characterized in that a control contact (vu), which is located in a control path common to the switching relay to be controlled, consists of two resilient cam disks (RPl, RP,) driven by the synchronous motor (Sy), moving parallel to one another Tongues and one of these disks (RP ") is so resiliently coupled to the other disk (RPi) that when a control pawl (VU) engages in a ratchet wheel (S) firmly connected to the one cam disk (RP), the cams of the two Cam disks (RPl, RP,) are offset against each other by such a large angle that the resilient tongues are then moved against each other, and that the control pawl (VU) is arranged to be movable by a clutch relay (K) which receives the control pulses. 3. ripple control receiver according to claim 2, characterized in that a control pawl (VU) carrying lever is designed as a double lever (H) , the second arm (BU) when pivoting the control pawl (VU) in a groove (p) of the ratchet wheel (P ) comes into the effective range of another cam disk (PT) which, if the limit permitted for the pulse duration is exceeded, swings back the lever (H) coupled to the pulse relay (K) via a spring (f4) without changing the position of the pulse relay (K) and thereby a pawl (i) triggers, which holds the lever (H) in the swiveled back position and only releases it again after the impulse relay M has been de-energized. Documents considered: German Patent No. 968 664; German Auslegeschrift No. 1006 488; Austrian Patent No. 167 803; AEG-Mitteilungen, 1956, p. 248.