DE1275664B - Method for remote control and monitoring of audio frequency ripple control transmitters from a command center - Google Patents

Description

Procedure for remote control and monitoring of audio frequency ripple control transmitters from a command center The invention relates to a method for Remote control and monitoring of audio frequency ripple control transmitters from a command center in which the control commands by changing the polarity on a double line of the current and the monitoring of the operational readiness of the transmission line and the ripple control transmitter (s) takes place by means of quiescent current of one polarity. The recipients are distributed over the low voltage network.

It is known to transmit a large amount of information between a control center and one or more substations through a multiple conductor, a frequency multiple or by pulse telegrams of different structure, in particular using a frequency multiplex method with little circuit complexity. In the subject matter of the invention, the control commands are transmitted using direct current methods via a double line. .

There are also methods for direct current transmission of a Command pair and a feedback via a double line with polarity change known. The line monitoring is carried out using the signal current method Wire connection. Also the possibility of line monitoring with quiescent current for itself belongs to the general state of the art.

The object of the present invention is to provide a larger number of control commands than previously known via a double line by changing the polarity of the current to send. According to the invention, in a method this becomes the one mentioned at the outset Kind achieved in that the change from quiescent current polarity to the opposite Open-circuit polarity switches on the ripple control transmitter and the following Change to quiescent current polarity and back to keying the ripple control transmitter (s) serve and a subsequent, time-limited power interruption during a The transition to quiescent current polarity causes the ripple control transmitter (s) to be switched off.

According to the method according to the invention, a monitoring of the System carried out with quiescent current, causing both a line break and a Failure of the ripple control transmitter is shown. This transmitter is switched off by power interruption (potential 0). As a result, the sender will respond in the event of errors automatically shut down in the transmission system immediately, so none can wrong commands are triggered. Because all the required functions are on a double line Can be transmitted with a stream is for the creation of the plant only a little effort required.

In the drawing is an embodiment according to. the invention shown, namely, FIG. 1 the selected pulse train and F i g. 2 the associated Circuit.

The monitoring should according to the invention by a quiescent current z. B. positive polarity (-f-), as shown in FIG. 1 through the with the Part of the pulse telegram plotted over time t, identified by reference number 1 emerges. If the ripple control transmitter S is to be switched on, this is done by causes a change to the opposite polarity (-), like part 2 of the pulse telegram reveals. The pulses in the telegram are changed accordingly sent to the original polarity (-f-) in the natural measure of time. The part 3 of the in F i g. 1 shows, for example, three pulses. the The transmitter S is shut down by a time-limited power interruption (Potential 0) Part 4 of the telegram and subsequent change to the original Polarity (-f-) brought about so that the initial state (line monitoring) is restored is.

In the circuit according to FIG. 2 is in the idle state the battery Bi via the contacts b, a1, c on the double line L. On the command side K, the relay Ü is excited by the line current, the contact ü switches on a relay CH, whose contact üh a monitoring lamp ÜL on voltage lays. When the lamp lights up, this indicates that the transmission path is error-free. On the transmitter side S, a polarized relay E and a contact x are provided in the line loop, which opens if the transmitter S fails and then indicates a fault on the command side K by dropping relay 0 and the delayed relay CH by extinguishing the monitoring lamp VL. The relay E is excited by the line current, so that its contact e rests on the upper mating contact and allows a relay F to respond. The contact f3 switches on a monitoring indicator VS , which indicates on the transmitter side S that the line is not disturbed.

If the start contact st in the command device K closes to send a ripple control telegram, a relay A is energized. The contact a1 switches the line L to the battery B2, so that the line is traversed by a current in the opposite direction. The contact a2 energizes the delay relay B. On the transmitter side S, the relay E puts the contact e downwards through the opposite line current, so that the delay relay G responds after a short time and switches the transmitter S on via its contact g2 and a relay H. In the rhythm of the pulse telegram, contact s is actuated in command device K. This energizes relay C. The contact c switches the transmission line L from the battery B2 to the battery Bi in the same rhythm. According to the pulse sequence, relay E also moves contact e upwards and thus energizes relay F, while relay G remains attracted due to its delay and self-holding via f1 and g1. The contacts f 2 and g3 touch the transmitter S via the relay J.

When the pulse telegram ends, contact st in command unit K opens. Relay A drops out, while relay B drops out with a delay when contact a2 opens, during this delay time line L on command side K is switched through contacts a1 and b shorted. On the transmitter side S, the contact e assumes its central position as a result of the currentlessness of the line. Relays F and G, whose delay time is shorter than that of relay B, drop out. Contact g2 opens and stops the transmitter. After the delay time of relay B has elapsed, contact b switches line L back to battery Bi. The hibernation is . restored. The relay E puts its contact e upwards. The relay F picks up. The operating status of the transmission path is monitored.

Claims (1)

Claim: Method for remote control and monitoring of audio frequency ripple control transmitters from a command center, in which the control commands are given on a double line by changing the polarity of the current and the operational readiness of the transmission line and the ripple control transmitter (s) is monitored by means of a quiescent current of one polarity, since - characterized in that the change from the quiescent current polarity (1) to the opposite operating current polarity (2) switches on the ripple control transmitter (s) and the subsequent changes to the quiescent current polarity and back (3) are used to key the ripple control transmitter (s) and a subsequent, time-limited Current interruption (4) during a transition to the cow current polarity causes the ripple control transmitter (s) to be switched off. Documents considered: German Auslegeschrift No. 1069 754; W. Henning, "Remote control technology in the service of electricity supply", Munich, 1950, pp.177 to 179 and 17, 18 and 22. Older patents considered: German Patent No. 1145 260.