DE1019375B - Receiving device with synchronous dialers for a central remote control system working according to the pulse method with audio frequency overlay on power networks - Google Patents

Description

Receiving device with synchronous dialers for after deal impulse process working central remote control system with audio frequency overlay on power networks In central remote control systems with audio frequency overlay on power networks, their Receivers are controlled according to the pulse method, can produce audio-frequency interference voltages occur which cause the receiver to respond and thereby interferences and Can cause incorrect switching. Since it is not possible to have such interference voltages on power grids, attempts have been made by suitable means in to make these interference voltages ineffective for the receivers. The interference voltages can as single or a series of short-term voltage peaks, so-called interference peaks, or as more or less constant voltages from a few seconds to a few Minutes duration, so-called continuous voltages occur. To ineffective cheat tensions To make it, one has increased the circuit selectivity of the receivers by adding several Pulses at selected time intervals and several control relays in the receiver in Cascade connection before, has seen. Through this measure, the addressing of Recipients on jammer will probably be reduced, but not excluded. Around It is in the receivers to render the effect of permanent voltages harmless the switch-off position arranged after the switch-on position, so that continuous voltages Do not switch the receiver on all the time, but also switch it off again, thereby but also unintentionally switch off switched-on receivers. This measure- led however, to another annoying disturbance by adding interference voltages that are multiple Tax flows outlast during 'each tax flow the recipients in and again switch off, which results in the so-called "pumping" of the receiver.

The present invention has for its object a remote control receiver to create, which does not execute any commands on interference voltages. In the previously known Control and test organs always acted in the pulse times for the recipients. The present The invention relates to a receiving device with a synchronous selector and in the switching position Maintained relay with electrical switch-off for working according to the pulse method Central remote control system with audio frequency overlay on power networks, which is characterized by a control body, which after the preparation of the tax readiness the telecontrol channel checked for interference voltages in interpulse times, and which Has switching means, which in the presence of an interference voltage, a control impede. Appropriately, a test relay with a switch-on and disconnection circuit arranged, the switch-on circuit at the same time with the synchronous selector via a contact of the frequency-dependent receiving relay as a result of the start pulse and is again de-energized after the start pulse and its Cut-off circuit prepared in interpulse times and when the receiving relay is excited is excited.

Embodiments of the invention are explained in more detail with reference to the drawing explained.

Fig. 1 shows the circuit of a receiver with a synchronously driven Rotary selector; Fig.2 shows a receiver with a synchronously driven control shaft with adjustable cam disks and contacts actuated by them for several Switching relay, Fig. 3 the circuit of such a receiver for only one switching relay, 4 and 5 show a cam control disk in elevation and plan, FIG. 6 shows an impulse schedule.

In Fig. 1, O and R denote two conductors of a network overlaid with an audio-frequency control voltage. A series resonant circuit tuned to the control frequency consists of a capacitor C and a highly sensitive AC relay RE, the inductance of which, together with the capacitor C, is tuned to the resonance. The relay RE has a contact re. The receiver has two relays K and P, each with a switch-on winding K i_. or P1-2 and a switch-off winding K._4 or P ..- 4, the relay armature in question being held in the switching position reached after one winding is excited and the other winding is excited to change the switching position. The maintenance can be done electrically or mechanically. In the exemplary embodiment according to FIG. 1, relays with mechanical hold, so-called toggle relays, are provided. The contact of the relay P is marked with p, the contact of the relay K with k _. The latter is a high-voltage contact for switching a consumer on and off. To control the switching relay K by means of audio-frequency pulses, a rotary selector driven by a synchronous motor S with two segment tracks D1 and D2 and two shaft contacts Da and De is arranged. The shaft contact Da is used to start and stop the synchronous motor, the shaft contact De for switching off the test relay P on the last control step before the completion of a control cycle, e.g. B. 51st step. If the resonance relay RE is excited as a result of a start pulse, contact re closes and the synchronous motor receives voltage from conductor 0 via winding S, the middle contact spring of contact Da to the left contact spring, selector segment Dl step 0, switching arm, contact ye to conductor R. The synchronous motor starts up, the contact Da flips and connects the synchronous motor directly to the mains until step 0 is reached again after one cycle. At the same time as the start, winding P1-2 of the test relay is also energized. This closes contact p. If the switching arm of selector segment Dl reaches step 5 and if the relay RE is energized as a result of a pulse at this point in time, the winding K1-2 is energized and the contact switches on the consumer. In step 6, the winding K3_4 is connected to switch off the consumer in the same way. To ensure that no interference pulses can affect relay K on step 5 or 6, the switch-off winding P3-4 is connected to selector segment D2 on steps 5 and 6. The selector segment D2 and its switching arm are arranged with respect to the selector segment Dl and its switching arm so that the steps of the segment D2 are reached half a pulse time before the steps of the segment Dl. In the drawing, FIG. 1, this offset is shown as a crank of the switching arm D2. In the practical embodiment, the switching arm D2 is expediently set forward by half a step with respect to the switching arm Dl in the case of superposed contacts or the segment D2 is set back by half a step in relation to the segment Dl in the case of superimposed switching arms. This has the effect that if an audio frequency interference voltage is present in the interpulse period before the switching time via contact re of the energized resonance relay and via selector segment D2 in step 5 or 6, the switch-off winding P3-4 energizes the test relay and thereby opens contact p. The interference voltage existing in the contact time 5 or 6 of the selector segment Dl cannot influence the switching relay K as a result. If the selector goes through a handling without an occurring interference voltage switching off the test relay. so the excitation of the switch-off winding P3-4 takes place via the contact De, which on the last step before reaching the zero position, z. B. 51st step is reached.

A receiver according to FIG. 2 again has a series resonance circuit with the capacitor C and the inductance of a highly sensitive resonance relay RE, which is connected to the two mains conductors 0, R. The synchronous motor S drives a control shaft with two fixed control cams Da, De and the associated contacts dl, d2. These two shaft contacts correspond in their arrangement and function to the contacts Da and De in FIG first switching relay KI and a further, gradually adjustable cam disk D5 and associated contact set d5 for controlling a second switching relay K II. Further control disks and switching relays can be arranged in the same way. If the resonance relay is excited as a result of a start pulse, the Kontaktre closes and the synchronous motor S starts up, as described for FIG. At the same time, winding P1-2 of the test relay is excited via contact d3 and contact p is closed. The relays KI and KII can perform switching functions, if the middle contact spring of the contacts d4, d5 is turned down or up at the set steps by the cams or gaps and the resonance relay is excited as a result of a control pulse. To prevent control functions due to interference voltage, the control disk D3 has as many cams as there are control steps on an entire shaft revolution, these cams being offset by half a step division with respect to the cams and gaps in the disks D4, D5. This has the effect that the switch-on winding P1_-. is switched on via contact d3, but the switch-off winding P3_4 is switched on in each pulse interval. If an interfering voltage occurs at any pulse interval, regardless of the setting of the switching steps of the control disks D4, D5, the switch-off winding P3-4 is excited and the contact p is opened, which prevents the relays KI and K II from being influenced.

A receiver according to FIG. 3 differs from the receiver according to FIG Fig. 2 in that only one switching relay K is arranged. In this case it is not necessary that the test relay P in all pulse intervals during a Checks circulation, but it is sufficient that the relay P in the control steps checks previous interpulse times. For this purpose, the control disk D3 only has two cams. Is, as indicated in the embodiment of Fig. 3, the cam disk D4 is set to step 2 »ON«, to step 3 »OFF« the control cams of disc D3 between steps 1-2 and 2-3. On this The switch-off winding P3-4 is switched on during both intermediate steps the switch-on winding on all switching steps and all other intermediate positions p1-, is switched on. It is useful to fix the two disks D3 and D4 to connect together, as shown in Figs. 4 and 5, the disc D3 is shown with a smaller diameter for the sake of clarity. The disc D3 is provided with locking cams N, and a locking spring F is firmly seated on the shaft, so that the double disc rotatably arranged on the shaft to each switching step is adjustable and is held by the detent spring.

In Fig. 6 the schedule for the relays RE, K and P is shown. In the RE line, the black spaces mean the times during which control pulses can be sent to the line and thus the RE relay can be switched on. In line K, the black digit E means the switch-on pulse, the digit 4 means the switch-off pulse. In line P, the sections E mean the time during which the test relay P is switched on when relay RE is switched on, ie when a control or interference voltage is on the network. If an interference voltage is present in times A, black spots, relay P is switched off and thus prevents voltages in pulse times E and A of relay K from taking effect.

The arrangement according to the invention has the result that interference voltages with a frequency to which the receiving relay RE responds cannot trigger any switching functions of the receiver.

Claims (10)

PATENT CLAIMS: 1. Receiving device with synchronous dialers and with Relay held in the switching position with electrical switch-off for using the pulse method working central remote control system with audio frequency overlay on power networks, characterized by a control body (P), which after the preparation of the tax readiness the telecontrol channel (0R) is checked for interference voltages and which switching means (p), which in the presence of an interference voltage prevent control. 2. Receiving device with synchronous dialers according to claim 1, characterized in that a test relay (P) with a switch-on and a switch-off circuit is arranged, the switch-on circuit (winding P1-2) simultaneously with the synchronous selector via a contact of the frequency-dependent Receiving relay energized as a result of the start pulse and again after the start pulse becomes de-energized and its switch-off circuit (winding P3-4) in the interpulse periods prepared and energized when the receiving relay is energized. 3. Receiving facility with synchronous selectors according to claim 2, characterized in that the switch-off circuit of the test relay is energized during the last switching step of a control cycle. 4. receiving device with synchronous dialers according to claim 3, characterized in that that the test relay (P) controls at least one switching relay (K) by the latter in their switch-on and switch-off circuits at least one node (p) of the test relay exhibit. 5. Receiving device with synchronous dialers according to claim 2, characterized in that that the switch-off circuit (winding P3_4) of the test relay only occurs in the interpulse period is prepared before a control step and is energized when the receiving relay is energized. 6. receiving device with synchronous dialers according to claim 2, characterized in that that the switch-off circuit (winding P3- ") of the test relay in all pulse intervals prepared during a control cycle and energized when the receiving relay is energized will. 7. Receiving device with synchronous dialers according to claims 1 to 6, characterized by a synchronously driven rotary selector with a first segment ba, hn (D1) for connecting the switching relays (K) and a second segment track (D2) for connecting the switch-off winding of the test relay (P), the switching arm of the second segment track (D2) the switching arm of the first segment track (D1) by half of a switching step rushes ahead. B. Receiving device with synchronous dialers according to Claims 1 to 6, characterized by a synchronously driven control shaft with adjustable Cam disks (D4 and D5) and contact spring sets under their influence (d4, d5) for switching the switching relays (KI, KII) on and off and one on the shaft Fixed cam disc (D3) with associated contact spring set (d3) for insertion and Switching off the test relay, with the latter cam disk (D3) so, many Cam has how control pulses are provided for a shaft rotation and these The cams are set angularly with respect to the cams of the other cam disks (D4, D.) are that in the times of the impulses the switch-on winding (P1-2), in the intermediate impulse times the switch-off winding (P3-4) of the test relay is switched on. 9. Receiving device with synchronous selectors according to claims 1 to 6, characterized by a synchronously driven control shaft with an adjustable cam disk (D4) and a contact spring set (d4) under their influence for switching the switching relay (K) on and off and one with the former Cam disk (Da) firmly connected second cam disk (D3) tn with associated contact spring set (d3) for switching the test relay on and off, the second cam disk (D3) having two cams, which is set at an angle with respect to the first cam disk so that in the The switch-off winding (P3-4) is switched on at all other times and the switch-on winding (P1-2) of the test relay is switched on at all other times. 10. Receiving device with synchronous selectors according to claims 1 to 6, characterized by a first shaft contact (Da) for starting and stopping the synchronous motor and a second shaft contact (De) for switching off the test relay on the last switching step before the completion of a control cycle. Considered publications: German Patent Nos. 680 126, 844 189, 412 575, 687 714; Swiss patent specification No. 195 750.