DE738528C - Arrangement for remote control - Google Patents

Description

Arrangement for remote control The invention relates to an arrangement for remote control via electrical distribution networks. Such a remote control , can be used for many purposes, @z. B. to ignite and extinguish street lights. for switching various consumers on and off, for switching counters in electrical, counters for different tariffs or for flight alarms. Such a one Remote control of a plurality of connected to the eirl electrical distribution network Receivers is achieved by one or more Seniler connected to the network. The invention particularly relates to remote control over AC networks, can but also with direct current networks, use -Remote control via such Networks can be reached in two fundamentally different ways, namely once by changes in the character of the mains current and secondly by transmission by means of special superimposed, ordinary audio-frequency signal streams, which then affect frequency-sensitive receivers. Changes in the character of the network current can e.g. B. consist of brief interruptions in a phase, increases the voltage, modulating the mains frequency or shifting a voltage in a Phase.

With another well-known. Method, direct current pulses are sent out. .A direct current source of 6 to 12 V in the earth line of an alternating current network switched on. In the receiver is the direct current sifted out by means of a throttle and can influence a relay. Although at the signaling increases the mains voltage, but the receivers are not through this, but only influenced by the superimposed, screened signal voltage.

In the invention, the remote control is achieved by increasing the voltage of the current in the network. The invention relates to an arrangement in which the amplitude of the mains voltage in interaction with the voltage increase the Recipient influences. As a result, the recipients need for the character of the voltage increase, z. B. for the differences in frequency between the mains voltage and the imprinted Tension, don't be sensitive. Such a remote control is a consequence the differences in voltage drop in different points of the distribution network associated with certain difficulties. If you want individually set recipients, which have to be very expensive, so it is necessary to avoid the voltage increase to choose quite high, so that the recipient is safe in the various points speak to.

To operate .Schalttrelais it is known that a half period to distort a voltage by switching on valves. With these well-known Arrangements, however, the actuation is not achieved by increasing the voltage amplitude, but achieved through the difference between the two half-periods. According to the invention one can avoid excessively high rms values of the voltage by increasing the the mains voltage amplitude to the value required for the receiver without a A corresponding increase in the rms value of the mains voltage takes place.

The invention is described in more detail with reference to the drawing. Fig. I and FIG. 2 show schematically how an increase in the line voltage in an alternating current network can be made possible by means of a direct voltage or an alternating voltage.

3 to 6 show circuits of various forms of transmitters, and Fig. 7 shows an example of an arrangement for transmitting remote control signals from a main station via the high-voltage network to a distribution transformer and beyond this transformer.

The necessary voltage increase can, as mentioned at the beginning, through DC or AC voltage can be achieved. When using a positive DC voltage V (see Fig. I) a shift of the entire AC voltage curve is obtained in the positive direction, so that the positive amplitudes are increased and the negative ones be reduced. When using an alternating voltage, corresponding to the third Harmonics of the fundamental frequency, a distortion of the voltage curve is obtained; the The image of the resulting stress is shown in FIG. 2.

In AC networks with a nominal phase voltage of 127 V, during normal operation one must reckon with voltages at various points between 115 and 140 V, i.e. voltage amplitudes between 163 and 198 V. In order to have a certain margin in the receivers, the increase in The voltage amplitude should be at least zoo to 163 = 37 V, ie 20 °%.

In the types of voltage increase shown in FIGS. 1 and 2 and in the case of increasing the voltage in direct current networks by means of an alternating voltage, however, a relatively large increase in the voltage amplitude corresponds to only a moderate increase in the effective value. This emerges from the fact that with an effective voltage of the fundamental wave = Ei and an effective voltage of the increase = E3, the resulting effective voltage is E_E, 2 -f- F_ 3z. With E, - o, 2o # E, E =, o: # E1 - E3 = 0.30 # E, - - E - 1.04 # E, and - E3 = 0.40 # egg - - E =, o8 # el. So you get a 2.4 or 8 0% increase in the effective voltage with a 20, 30 or 40 0/0 increase in the voltage amplitude.

The above-mentioned necessary increase in the voltage amplitude of 2o So 0% results in an increase in the rms voltage of only 2 0/0. In certain cases can. however, an increase in amplitude of 35% may be necessary, which is the phase voltage limits i io to 15O V corresponds to, in which case the increase in the rms voltage approximately 6 0; o will.

A very simple way of measuring the voltage amplitude in an alternating current network to increase is to connect a source of direct current to the earth line, as Fig.3 shows. On the connection between the star point on the secondary side a distribution transformer Td and earth is a means of a contact arrangement r shorted Resistor W switched on normally. When signaling the contact arrangement r is transferred to the signal layer, with the short circuit over W is interrupted and a direct current source B is switched on in parallel with W. the In this case, amplitude values of the phase voltages are increased, as shown in FIG. This type of voltage increase that is very easy because the DC voltage source can consist of an ordinary auto-accumulator, unfortunately it cannot with. -networks which have a significant inductive load between phase and Earth included as the direct current is diverted into the inductive loads. In such a case, it is more appropriate to follow the methods described below to increase the network voltage amplitude.

According to FIGS. 4 and 5, the voltage increase is achieved by superimposing the third harmonic of the fundamental wave. On the low-voltage side of a distribution transformer Td, remote control signals with a voltage increase are to be sent out. For this purpose, the one winding of a small signal transformer T f is connected between the star point and earth on the secondary side of the transformer Td. Three coils S can be connected to the phases z, 2, 3, on the secondary side of the transformer Td by means of a three-pole switch K. The coils are. interconnected and connected to the star point of Td via the second winding of the transformer T f. The coils are: dimensioned so that the current in them, when connected to the mains by means of the switch K, brings about an approximate saturation in the iron cores. This creates a current of the third harmonic of the mains frequency between the star points of the coil arrangement and the transformer Td. A voltage of this harmonic is thus impressed on the second winding of the transformer T f connected to the earth line, whereby the amplitude of the phase voltage is increased and amplitude-sensitive receivers connected to the network are influenced. The phase voltages are distorted in this case and are given the appearance illustrated in FIG. 2. The transformer T f can also be replaced by a simple coil; the star point of the coils S is then; connected directly to the earth line.

The saturation in the iron cores of the coils S can also be achieved by direct current in transducers, as illustrated in FIG. A rectifier bridge List with the one diagonal connected between phases .2 and 3. The other diagonal is closed in the idle state via a normally closed contact r1 of a relay R and a special winding M of the signal transformer Tf. The relay R interrupts the contact r when a signal is generated, and closes the contact r2, the winding M being switched off and the direct current windings of the transducers D being switched on instead. Here, saturation is achieved in the transducers; it is thus basically achieved the same effect as in the circuit in Fig. q .. In the rest state, ie when no signals are sent and the relay R is unmagnetized, a current flows through the coil M. The iron core of the Tranformators T f is in this case saturates, and the impedance of the winding in the earth line is reduced to a moderate value. It. however, it is not always necessary to use such a direct winding, since the impedance can also be kept low for the normal mains frequency in a different way.

Another possibility of increasing the amplitude value of the alternating voltage without a corresponding increase in the effective value is illustrated in FIG. 6. The connection terminals a, b in the circuit diagram can be connected between two phases or between one phase and earth. A voltage tap or one end point of the winding of an autotransformer Ts is connected to the terminals a and are. The whole transformer winding is through a capacitor. C (from about ro to, 2o, uF, for example) is bridged in series with a resistor Ws. At the connection point of Ws and C and: at the input terminal a there is a glow lamp Gs. The structures are dimensioned so that a half cycle of the mains voltage, for example a positive half cycle, runs as follows: If the voltage between a and b has a certain If the value increases, the voltage over the entire transformer Ts (ie also over C) increases with a higher value. If the difference between the two voltages exceeds the ignition voltage of the glow lamp Gs, it ignites and closes the connection between the terminal a and the capacitor C, which discharges and sends a discharge current surge into the network. The peak value of the voltage surge: is the voltage across C at the instant of voltage, reduced by the burning voltage of the glow lamp Gs. The process is repeated for every positive half-cycle in the example and in this way causes an increase in the amplitude of the mains voltage, which is amplitude-sensitive Receiver affected. - A rectifier circuit can also be used to distort the sinusoidal alternating voltage. In an example of such a circuit, the coils S in FIG. 4 are replaced by rectifier elements (for example copper oxide rectifiers), each of which has a capacitor connected in parallel. The rectifier circuit is connected to T f via a capacitor. The voltage across the latter, which has the same profile as the rectified three-phase voltage, but is symmetrical in relation to the zero voltage, is superimposed on the phase voltages and causes the desired increase in amplitude.

It is also possible to appropriately distort the voltage curve with the help of a grid-controlled three-phase mercury rectifier: to achieve which is connected to the network via a coupling transformer. The pressed one On the one hand, voltage is generated from the neutral point on the secondary side of the coupling transformer and on the other hand supplied from the cathode of the rectifier. One obtains here a sawtooth curve.

In order to match a central broadcast to allow larger network, e.g. B. for an air raid alarm in a larger air protection area, it may be necessary to the central transmitter at a main transformer station in the power network. to connect. The signals must be sent to a distribution transformer (to reduce the voltage to 22o V), which according to the invention, for example, by means of a transmission circuit according to Figure 7 can be achieved.

In the main station, voltage increase signals in the form of the third harmonic are sent from the secondary side of a high-voltage transformer Tla by means of an arrangement which is denoted by o in the figure and which can be implemented according to FIG. If the effective voltage on the high-voltage line is increased when the signals are transmitted via the signal transformer T f , an amplitude-sensitive receiver connected to the primary side of a distribution transformer is affected. This consists of a transformer T f connected between a phase and earth, a series connection, connected to the secondary circuit of the transformer, of a glow lamp G and a relay R (which corresponds to the relay with the same designation in FIG. 4). As soon as the voltage amplitude over the glow lamp exceeds the ignition voltage in the signal, a current flows through the lamp G and the relay R, as a result of which the direct current windings of the transducers D receive current via the contact r. And a signal goes out to the low-voltage network.

The circuits described above relate to AC networks. However, for signaling according to the invention it is also possible to use the voltage amplitude a direct current network without a corresponding increase in the effective value by means of a Increase AC voltage. The transmitter consists of a suitable alternator, which is switched into the earth line of a three-wire network. The recipients can be of the same kind as in the examples described above.

The circuits described are only intended as exemplary embodiments for the possibilities within the scope of the invention to consider the amplitude the mains voltage to a value required for amplitude-sensitive receivers without increasing the rms value of the voltage accordingly.

Claims (1)

PATENT CLAIMS: i. Arrangement for remote control via electrical distribution networks by influencing amplitude-sensitive receivers by increasing the mains voltage, characterized in that the increase in the mains voltage amplitude to that required for the receiver. Value is made without a corresponding increase in the rms value of the mains voltage. - ;, . Arrangement according to Claim i, characterized by receivers which are sensitive exclusively to the resulting amplitude of the normal mains voltage and the increase in voltage originating from the transmitter and not to the character (for example frequency) of the increase in voltage. 3. Arrangement according to claim i in an alternating current network, characterized in that the transmitter consists of a DC voltage source with a relatively high voltage (for example 4o V), which is switched on when sending the signals in the neutral line. 4. Arrangement according to claim i for an alternating current network, characterized in that the transmitter consists of a device for superimposing the third harmonics of the network frequency on one or more phases of the main voltages. 5. Arrangement according to claim 4, characterized in that a star-connected three-phase choke, which is dimensioned so that its iron core is approximately saturated when connected to the three-phase line, with the star point at the zero point of a power line transformer via a coupling with the neutral line, in particular a coil or a transformer. 6. Arrangement according to claim q., Characterized in that a star-connected three-phase choke, which is dimensioned so that its iron core is not saturated when connecting the choke to the three-phase line, is provided with direct current windings to saturate the iron core, which is provided when signaling via a Be connected to a DC power source. 7. Arrangement according to claim: 6, characterized in that the signal transmitter in the idle state a special DC winding m switches on a signal transformer connected to the neutral line. 8. Arrangement according to claim 6, characterized in that the direct current source consists of a rectifier bridge, one diagonal of which between; two phases of the three-phase line is connected. G. Arrangement according to claim i in an alternating current network, characterized in that the transmitter consists of a transformer arrangement connected between two phases or one phase and the neutral line for increasing the voltage, a device connected to it for charging a capacitor with the increased voltage and in particular a glow lamp exists, which transfers the increased voltage (reduced by the burning voltage of the glow lamp) in the form of a capacitor discharge surge to the network. ok Arrangement according to claim i for an alternating current network, characterized in that the transmitter consists of a three-phase rectifier circuit which can be connected to the distribution network and which is capacitively connected with its zero point to the zero point of a transformer via a coupling to the neutral line; is. i i. Arrangement according to Claim 10, characterized in that the rectifier circuit contains a rectifier with a capacitor connected in parallel in each phase. 12. The arrangement according to claim io, characterized in that the rectifier circuit contains a grid-controlled mercury vapor rectifier. 13. The arrangement according to claim i in a direct current network with two or three conductors, characterized in that an alternating voltage source is switched on in a conductor, for example the neutral conductor. 1q .. Arrangement according to claim a, characterized by a transmission arrangement for the transmission of the signals between two line parts separated by transformers or switches from a receiver connected to one line part, with a glow lamp and a relay in series with it and a connected to the other line part, Transmitter controlled by the relay to increase the mains voltage amplitude.