DE500805C - Device for remote control of power plants interconnected on the high voltage side by a central office - Google Patents

Description

Device for remote control of high-voltage side interconnected Power plants through a central point In energy distribution networks, the high-voltage side contain interconnected power plants, the need has emerged the electrical output values of the individual works to control either the load distribution between the individual Power plants or to regulate the voltage of the network. Come for this check in question: voltage measurement, current measurement, kilowatt measurement, kilowatt hour measurement and measurement of the power factor (cosine (j).

It has been proposed for this purpose to use a high frequency current to send via the high voltage line and the oscillation circuit sizes of the transmitter tube to change depending on the controlled measuring instrument, with the high frequency receiver the central office suitable means differently on the different frequencies speak to. As an optical frequency receiver, it comes primarily from the familiar electromagnetic frequency meters with vibrating tongues in question. The high frequency current is here only carrier current whose some low-frequency variation is imposed (Modulierv experienced), and the frequency meter is behind the demodulation tube Recipient.

However, this procedure is not due to the information facility very easily. Furthermore, the frequency meter has too large a reception width, which makes a quick and accurate measurement very difficult. It is well known that it does not vibrate only the tongue that corresponds exactly to the transmitted frequency, but with smaller ones Amplitudes also the neighboring tongues, so that always' from a series of vibrating Tongues the tongue that vibrates to the maximum must be recognized. The procedure has therefore found no application.

The other possible method, the transmission frequency itself directly to change by the controlled measuring instrument is generally not applicable, because the separation points arranged in the line are coordinated bridges for each of the measurement frequencies used would have to have, which would be extensive and expensive. Facilities would lead.

According to the invention, the last-mentioned method is made usable by that the narrow frequency range at the bridging point is not too sharp Experience has shown that voting can be transferred to the known via a receiver tube Ouarz frequency meter is transmitted, which consists of a number of parallel-connected, in a certain way cut to their optical axes by the quartz crystals of of different lengths. These crystals speak even when very close together lying frequencies individually sharply, and each crystal only glows then on when the electric field in which it is arranged, vibrates at the frequency to which it is tuned by its length. This is based on the fact that elastic in the crystal under the action of the oscillation frequency Longitlidirial swings occur. The crystal is in an evacuated vessel between two opposing electrodes that are fed by the alternating field, at a distance from: the same arranged, e.g. B. hung. A number of such different Matched crystals is advantageously arranged in such a way that the crystals form a row from the shortest to the longest and thus by lighting them up reflect the setting of the remotely controlled instrument in a scale-like manner and make it visible.

The invention is illustrated schematically in the drawing. Fig. T shows a high-voltage connection between two power plants A, B, whose machine sets are not shown. A is .the controlled, B the controlling power plant. In the power station A , the anode circuit of a transmitter tube S is inductively connected via capacitors k. The oscillation circuit of this transmitter tube contains a capacitor K parallel to the induction coil i, which is shown in Fig. Q. and Fig. 5 is shown on an enlarged scale. The capacitor consists of two plates d, between which a semicircular metal plate b can be swiveled about the axis d; in Fig. 5 three positions b1, b2, b3 of the metal segment b are shown, and it can be seen in what way the capacitance of the capacitor K. The axis d is the continuation of the pointer axis of the controlled instrument T (Fig. 3), whose pointer (see also Fig. q.) plays in front of the scale S. When the pointer touches the scale passes through, the rotated metal segment b changes the capacitance of the capacitor K and thus the oscillation circuit of the transmitter tube S, so d, the high frequency flowing over the high-voltage line is changed accordingly.

A double separation point is indicated in the high-voltage line, which are bridged by the oscillation circuits I, 1I, 111 for the above-mentioned purpose is. When the isolating switch is open, the high-frequency current runs across the bridge I, II, III to the main plant B, where the receiver tube E also has capacitors k is connected. In the anode circle of the tube E is the one shown enlarged in Fig. Z optical frequency receiver M. The same consists, for example, of five different long crystals q, which in -the apparent type parallel to each other between two electrodes are arranged each. each crystal is behind a column of the scale f arranged. The setting levels of the instrument .T are determined by these crystals indicated in such a way that at five certain different frequencies each one Column lights up through the crystal arranged behind it. On the one above The scale mark is .the relevant setting of the pointer z of the instru; inentes 7 noted.

The number of crystals can be increased without difficulty in such a way that that a practically continuous reading of the controlled instrument is achieved will.

Claims (1)

PATCNTANSPRUCII: Device for remote control of the high voltage side interconnected power plants through a central point for transmission of the control currents the high-voltage line is used in such a way that one over The high-frequency current sent by the high-voltage line by changing the oscillatory circuit sizes the transmitter tube is changed depending on the controlled measuring device, .thereby characterized in that on the center a number of quartz crystals connected in parallel is provided, which corresponds to the change in the oscillation angular frequency changed anode current is supplied to a receiver tube and which is through different Length are tuned in a known manner to different frequency.