DE702291C - Device for sending remote control commands - Google Patents

Description

Device for sending remote control commands It is known In electrical distribution systems, gas discharge vessels in anti-parallel connection to provide an interruption of the conductor current in the zero crossing and thus to achieve a powerless shutdown.

It has also been suggested to apply this principle when the Interruption several times, for example at certain time intervals for the purpose of sending remote control commands for operating street lights, water storage tanks, multiple tariff meters, air raid protection signals and the like. Here you have a not inconsiderable number of circuits to be expected when the number of controlled devices and thus the number of devices to be sent out Commands is great. In addition, each switching command is used for reasons of distinction characterized by several such pulses, so that the application of the principle the powerless shutdown gives considerable advantages, especially in this case. In a proposed arrangement of this type, ignition pin vessels are in anti-parallel connection provided, the excitation of which is carried out with a higher frequency ignition voltage. If this ignition voltage is interrupted, the tubes lose their conductivity at the next zero crossing of the current and cannot ignite again until the ignition pins are connected to the higher-frequency ignition voltage again. Means this arrangement, it is possible to interrupt the conductor current in the natural To achieve zero crossing, however, the tubes or the Do not reconnect the higher-frequency voltage supplied to the ignition pins clearly defined. If the higher frequency voltage in one The moment in which the current of the stationary end state is just beginning When the peak value is reached, the reconnected current can possibly be a multiple reach its stationary end value, especially when this current is saturated with iron Flows through circles.

The invention also relates to a device for transmitting Remote control commands through one or more short-term interruptions, preferably a network conductor, by means of the known anti-parallel connection of gas-filled discharge vessels, especially firing pin vessels. Exactly for the purpose of reconnecting the gated current According to the invention, a is in the lulldurcligang of the current of the stationary end state Phase shift provided, which unaffected by the keying line-to-line voltage is supplied and which of these derived voltage is a such a phase shift with respect to the line-to-line output voltage gives that it with your current of the stationary final state of the gated phase is in phase.

An exemplary embodiment for a circuit according to the invention is shown in Fig. I, while the mode of operation is explained with reference to Fig. 2. It is assumed that a three-phase network with the phases R, S, T is present and that the phase R is to be keyed. To control the ignition pin voltage, an auxiliary voltage is derived from the chained voltage that undergoes practically no change during keying, i.e. from the voltage between S and T, and fed to a converter i. This voltage is first fed to a rectifier 2 and a capacitor 3 connected in series via a plias displacement circuit 9, the meaning of which will be explained later. Furthermore, a 'resistor d. present, the voltage drop is rectified by a rectifier 5 and a grid-controlled gas or vapor discharge path 6 is fed. The current starting in the discharge path flows through a transformer 7, the secondary winding of which is connected on the one hand to the cathode and on the other hand to the firing pin of the firing pin vessel 8.

The change in voltage brought about by the individual elements of this circuit arrangement is shown in diagram form in Fig. 2, and the numbers next to the individual diagrams give an indication of the corresponding elements of the circuit arrangement. An alternating voltage is thus present in the converter i, which is an exact replica of the concatenated voltage between the network phases. The course of this voltage is shown in Fig. 2 under (i). The negative half-wave is cut off by the rectifier 2, so that a voltage is present behind this rectifier which corresponds to the curve (2) in FIG. The voltage obtained in this way feeds the capacitor 3, in which a current i flows, the magnitude of which is expressed The waveform of this current is indicated in Fig. 2 with (3). The current therefore corresponds to the first differential quotient of the voltage. This current flows through the resistor 4, at which, if R is the ohmic value of the resistor, a voltage drop e occurs, This voltage drop e is rectified in the rectifier 5, as a result of which the curve shape of DC voltage surges, denoted by (5) in Fig. 2, results. These direct voltage surges are fed to the discharge path 6, which ignites when the positive surges reach the grid. Under the influence of the current starting in the discharge path 6, which is fed by a battery, a voltage surge occurs on the secondary side of the transformer 7. Since the secondary winding is connected on the one hand to the cathode and on the other hand to the firing pin of the firing pin vessel assigned to it, an ignition surge occurs at the moment the output voltage crosses zero, which can also be converted into an ignition oscillation by suitable switching.

In the conductor R is a second, not shown detonator vessel present, which is in anti-parallel connection with the first, so that both half-waves of the current of this phase. The second detonator jar is made in the same way Affected way like the first, being merely on the correct phase relationship must be respected.

Since now the output voltage obtained by the converter i has a certain Has phase relation to the current of the stationary final state of the scanned conductor, a phase shift circuit 9 is provided, which is in the simplest manner of a cos püeßgerät is controlled. This phase shift circuit ensures that the voltage taken from its output terminals and supplied to rectifier 2 receives such a phase shift in relation to the line-to-line output voltage, that they are in phase with the current of the stationary final state in the gated phase will. The phase shift circuit ensures that the Zero crossings the voltage fed to the rectifier a with the zero crossings of the current of the stationary end state of the gated phase match. However, one can also the auxiliary voltage supplied to the converter r directly from the sampled phase derive, whereby it is only necessary by suitable attenuation of the cos cp measuring device to ensure that this and thus the phase shift circle adjusted by it 9 maintains its position during the scanning time. Such a damping can be done without further can be achieved, since the scanning time is in the order of magnitude of about a to 3 Periods.

Claims (1)

PATENT CLAIMS: r. Device for sending remote control commands through one or more brief interruptions, preferably a power line by means of the known antiparallel connection of gas-filled discharge vessels, in particular ignition pin vessels, characterized in that a phase shift circuit is provided for the purpose of reconnecting the gated current exactly - in the zero crossing, of the current of the stationary end state is to which the chained voltage unaffected by the keying is fed and which of this derived voltage gives such a phase shift with respect to the chained output voltage that it is in phase with the current of the steady end state of the keyed phase. Device according to Claim r, characterized in that the phase-shifted auxiliary voltage is rectified and then fed to a capacitor and a resistor in series therewith. 3. Device according to claim r and 2, characterized in that the voltage drop occurring across the resistor, which is proportional to the first differential quotient of the output voltage after time, is brought to act on the grid of a grid-controlled high-voltage gas or vapor discharge path via a rectifier will. -q .. Device according to claim z to 3, characterized in that the current impulses which start under the influence of the differential quotient of the output voltage and a further direct current source in the discharge path are fed to the primary winding of a transformer, the secondary winding of which on the one hand with the cathode and on the other hand with the ignition pin of the detonator vessel assigned to it is connected.