SU1019649A1 - Device for signal transmission through electric network wires - Google Patents

Abstract

THE DEVICE IS IN TRANSMITTING SIGNALS THROUGH THE ELECTRIC NETWORK WIRES, containing a series-connected capacitor and an inductor, the junction point of which is connected to the cathode thyristor, as well as a storage capacitor and discharge coil. an inductance, the first output of which is connected to the thyristor anode, the control electrode of which is connected to a source of information connected to the thyristor cathode, characterized in that, in order to increase the signal transmission coefficient, the second terminals of the capacitor and the inductance coil are connected to the wires of the electrical network and entered additional condeisagor, transformer and diode bridge, and in parallel to the capacitor and the inductor connected in series are connected an additional capacitor and the primary transformer winding point § g of which is connected to a first terminal of the storage capacitor, a second terminal coupled to a second terminal of the discharge inductors ,, moreover the second winding of the transformer is connected via a rectifying bridge -2 mitelny Nome parallel storage capacitor.

Description

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The invention relates to communication devices, in particular, to devices for transmitting information by wire to an electrical network. It is known a device for transmitting information through wires of an electrical network / which uses the principle of distorting the shape of a load current curve by introducing into its circuit a transformer connection of a nonlinear element - controlled one or two; However, oscillations 9 occur in this device in an electric network; even harmonics, the frequency of which is a multiple of twice the frequency pitakadey network. The level of individual harmonics is not adjustable. In addition, the sum level of harmonics depends on the magnitude of the load current and will change with when it is changed. Generation of harmonics in idle mode is not possible. The presence of a large number of oscillations of various frequencies in the generated signal has a negative effect on the operation of other devices of mechanics and communication. . The closest in technical essence to the inventor is the mouth. Signal transmission via electrical wires containing a series-connected capacitor and inductance coil, the connection point of which is connected to the thyristor cathode, as well as a storage capacitor and discharge inductance coil, the first output of the coT; The Oura is connected to the thyristor anode, control electrode which is connected to a source of information connected to the thyristor cathode {2, However, the known device has a low signal transmission coefficient. The purpose of the invention is to increase the transmission coefficient and signals. Set goal Achieved by the fact that in a device for transmitting signals, through wires of an electrical network, 1 containing a series-connected capacitor and inductor, the connection point of which is connected to the thyristor cathode, as well as a storage capacitor and discharge inductor, the first lead of which is connected to the anode thyristor, the control electrode of which is connected to an information source connected to the thyristor cathode, the second terminals of the capacitor and the inductance coil are connected to electric wires An additional capacitor, a transformer and a diode bridge are introduced, and parallel to the capacitor and the inductor are connected in series an additional capacitor and the first winding of the transformer, the connection point of which is connected to the first terminal of the storage capacitor, the second terminal of which is connected to the second output of the discharge coil The second winding of the transformer is connected via a rectifying bridge parallel to the storage capacitor. The drawing is an electrical schematic diagram of the proposed device for transmitting signals through electrical wires. The device for transmitting signals through the electrical network leads contains a capacitor 1, an inductor 2, a thyristor 3, a storage capacitor, a capacitor 4, an inductance discharge coil 5, an additional capacitor 6, a transformer 7 and a diode bridge 8, wires 9 of the electrical network, information source 10 . The device works as follows. When the device is connected to the wires 9 of the electrical network, the rectified voltage taken from the secondary winding of the transformer 7, accumulative capacitor 4 is charged. When the pulse source 10 is supplied, the thyristor 3 opens and the storage capacitor 4 is discharged through the circuit: the discharge coil 5 - thyristor 3 - capacitor 1 - additional capacitor 6. Due to the inductance of the discharge coil 5, this discharge is oscillatory. Upon transition of the discharge current through zero, the thyristor 3 is closed. The natural frequency of the discharge circuit is much greater than the natural frequency of the oscillating circuit. The capacitance of capacitor 1 is several times smaller than the capacity of the additional capacitor b. In connection with this, the energy of the discharge accumulate the capacitor 4, basically, is transferred to the capacitor 1. Then the oscillating discharge of the capacitor 1 through the coil 2 circuit - the wire 9 of the electrical network begins. After a time equal to or a multiple of the frequency of the oscillating circuit, the control pulse of the thyristor 3 from the source 10 enters the control. The process is repeated. The pulse discharge energy of the storage capacitor 4 transferred to the capacitor b is also returned to the electrical network. The discharge current of the storage capacitor 4 practically does not pass through the coil 2 circuit - the primary winding of the transformer 7, since these inductive elements represent for it a much greater resistance than the circuit capacitor 1 - capacitor 7. In connection with this, the shape of the current caused by co-flex By the contour of the circuit 1 - coil 2, almost sinusoidal. Since the inductive resistances of the primary winding of the transformer 7 and coil 2 at the frequency of the power supply to the network are much less than the resistance of capacitors .6 and 1 /, the voltage drop from the currents at this frequency between the connection point of the storage capacitor 4k of the capacitor circuit b is the primary trans winding 1ator 1 7 and the connection point of the thyristor cathode 3 are not lighter. Therefore, the presence of an industrial frequency voltage does not affect the process of discharge of the storage capacitor 4 and, consequently, the operation of the entire device. In this connection, in the oscillatory circuit, the capacitor 1 - coil 2 - network (it is also an element of this circuit, as the generated current is closed through it) flows almost without amplitude modulated sinusoidal | LY current with the frequency / frequency of the oscillatory frequency circuit (- and the frequency of arrival of pulses from source 10). This current is superimposed on the current of the intermediate frequency, due to the connection to the network of the device elements, basically, the resistance of the capacitors 1 and 6 at the industrial frequency. With this design of the device, the generated current is intercepted only through the network, which is an element of the oscillatory circuit, which gives a significant positive effect. There will be no need for a transformer in connection with the network. In addition, if the thyristor 3 due to some reason cannot close when the discharge current passes through zero and the short-circuit mode occurs, the device will not fail and its operation will self-recover, since in the short-circuit mode the diode bridge 8 is discharged bottom coil 5 - thyristor 3 - coil 2 is short-circuited for the time of the positive half-period about the primary winding of the transformer 7 devoid of frequency, the storage capacitor 4 is discharged and the voltage disappears, causing the current to flow through the thyristor 3. T Ristori 3 zakroets. The current flowing through the thyristor 3, due to the voltage of the industrial frequency, is limited by the capacitor 6, which has a large resistance at this frequency. Thus, in the proposed device, the short circuit mode of the thyristor 3 does not lead to a failure of the device, which significantly increases its reliability. The device due to its simplicity, reliability and efficiency can be widely used in telemechanics systems that use electrical networks as communication channels, as well as in relay protection devices using superimposed currents.

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Claims (1)

SIGNAL TRANSMITTER FOR ELECTRIC NETWORKS, containing a capacitor and an inductor connected in series, the connection point of which is connected to the cathode. thyristor, as well as a storage capacitor and a discharge coil. inductance, the first terminal of which is connected to the thyristor anode, the control electrode of which is connected to an information source connected to the thyristor cathode, characterized in that, in order to increase the signal transmission coefficient, the second terminals of the capacitor and inductance coils are connected to the wires of the electric network and additional a capacitor, a transformer and a diode bridge, and in parallel with the capacitor and inductance coil, an additional capacitor and primary coil are connected in series transformer failure, the connection point § of which is connected to the first output of the storage capacitor, the second output of which is connected to the second output of the discharge inductance coil, and the second winding of the transformer is connected via a rectifier bridge parallel to the storage capacitor.