SU1119182A1 - High-frequency wavetrap - Google Patents

Abstract

HIGH FREQUENCY ZAGRLdaTVL for vgsszhovolt th YA1SHYAI (ektro, transmission containing a power coil inductance spine included in the high voltage line elektrsshereda- gap. Chi, the end o (h4OtKHKOTOp tt connected to one terminal of the tuning element about -m l and u and w ca and By the fact that, in order to increase reliability and reduce the cost of a high-frequency barrier, by reducing the magnitude of the voltage acting on the setting element I, an additional 1 inductor was introduced inductively connected to the power inductor, and The windings of the power and additional inductors are combined, and the end; the windings of the additional inductance coil are connected to a different output; setting element. 2. The bargainer according to p, which is so that, in order to achieve maximum mutual inductance , the windings of the additional coil inductance races between the coils of the winding of the power inductance.

Description

00

The invention relates to electrical engineering and can be used in devices that ensure the utilization of high-voltage power transmission lines (HVL) for high-frequency communications, in particular high-frequency barriers, through which the attenuation of high-frequency signals transmitted via high-voltage transmission lines is achieved. A high-frequency protector is known that contains a power induction element - a transformer with a magnetic core and windings, of which the primary winding is represented by a single turn of the power supply line, and a tuning element that forms an oscillatory circuit tuned to the frequency of the high-frequency signal DJ is connected to the multi-turn secondary winding high-frequency contactor cannot be applied in high-power high-voltage lines, since the presence of a magnetic conductor leads to St inductance of a power inductive element from the main frequency current and inoperability of this circuit in emergency modes of high-voltage power lines. The closest to the proposed is a high-frequency arrester of a high-voltage power line dp containing a power inductor included in the break of a high-voltage power line, to the end of which winding one output of the setting element is connected, the other output of which is connected to the beginning of the winding of the power inductance. The high-frequency barrier is a three-circuit circuit, the first circuit of which contains a power inductor included in the break of the high-voltage transmission line and a capacitor of the element connected in parallel with it. settings. In order to expand the tuning range (barrier) in parallel with the primary circuit capacitor, the second and third circuits, formed by the inductance coils and the tuning element capacitors, are interconnected 2J. The disadvantage of this circuit is the appearance of a high voltage pro-. the frequency of the tuning element during the flow of short-circuit currents of the high-voltage line through the high-frequency interceptor. electricity transmissions, as well as in the event of switching and thunderstorm overvoltages. So, if, at the normal, maximum operating mode, the voltage on the power inductor and the setting element 1 is hundreds of volts and this voltage corresponds to the operating voltage of the capacitors used in the setting element, then in the short-circuit mode in high voltage, power transmission lines the voltage power frequency on the power inductor and the setting element can briefly reach several kilovolts. The most prominent design element of the circuit is the high-frequency capacitors of the tuning element, which basically determine the reliability of the high-frequency barrier. The purpose of the invention is to increase the reliability and reduce the cost of the high-frequency prohibitor by reducing the voltage value acting on the tuning element, as well as achieving the maximum mutual inductance. To achieve this goal, a high-frequency haulbreaker for a high-voltage power line containing a power inductor included in the break of a high-voltage power line, to the end of the winding of which one pin of the tuning element is connected, introduced an additional inductor inductively connected to the power coil of the inductance, and the beginning of the windings power and additional inductors are combined, and the end of the winding of the additional inductance is connected to another output item settings. In addition, the windings of the additional coil inductance are located between the windings of the power coil inductance. The drawing shows an electrical schematic diagram of a high frequency barrier. The high-frequency arrester contains the power coil 1 inductance, tuning element 2, consisting of inductors 3, capacitors 3 and resistor 5, additional inductance coil 6, the power and auxiliary inductance coils 1 and 6 and tuning element 2 forming a three-loop circuit tuned to the frequency of the high frequency signal, providing a predetermined range of the barrier. High-frequency stopper works as follows. When the high-frequency protector is turned on, a high-voltage transmission line breaks the industrial and high frequency windings through the windings of the coil 1 inductance, and only the high frequency current in the secondary coil 6 and the control element 2. Due to the fact that the oscillatory circuits formed by the winding of the power coil 1, the auxiliary coil 6, the capacitors 4 and the coils 3 of the inductance of the tuning element 2 are tuned to the frequency range of the barrier, a high value of the high-frequency barrier barrier is obtained. Due to the presence of mutual inductance between the winding of the power coil 1 and the auxiliary coil 6 and their opposite switching on, the voltage of the industrial frequency on the setting element 2 is both in the operating mode and in the case of a short circuit (short-circuit) in the high-voltage electric current transmission line k.z. through the power coil t there will be equal differences in voltages on the winding of the power coil 1 and the additional coil 6 inductance. Thus, the limiting applied voltage when short-circuit currents flow through the winding of a power coil t can be reduced from a few 824 kilovolts to several hundred volts, which makes it possible to use cheap low-voltage capacitors in setting 2. The counter-series connection of power 1 and an additional 6 coils makes it possible to carry them out with a small difference in the number of turns, and therefore, with axial dimensions close to each other. When this is achieved the least. neck value of inductance, power dispersion 1 and an additional 6 coils, which contributes to the preservation of the range of the barrier described by the outgoing frequency barrier. When subjected to pulsed overvoltages, as a result of the counter-series connection of the power 1i and the additional 6 coils, their effect on the tuning element 2 is sharply reduced. Thus, by performing a high-frequency barrier with the use of an additional -cushion 6, the structural elements of the high-frequency circuits in the element 2 can be tuned to much smaller values of the maximum permissible stresses. In particular, its most expensive elements — high-voltage capacitors characterized by low reliability — can be replaced with cheaper and reliable low-voltage capacitors. The additional inductance coil 6 inserted for passing only the high frequency current, in contrast to the winding of the power coil 1, is made of a thin wire and the associated costs are significantly less than the savings obtained by simplifying the tuning element 2. . .

if

Claims (1)

HIGH-FREQUENCY LOAD '' TEL for high-voltage line / power transmission, containing a power inductor included in the gap of the high-voltage power line, which has one output of the tuning element connected to the end of the winding, which is connected with the fact that , in order to increase the reliability and reduce the cost of the high-frequency trap by reducing the voltage acting on the setting element I, an additional inductor is introduced, inductively connected to the power inductor, Ala windings of the power and additional inductors are combined, and the end of the winding of the additional inductor is connected to the other output of the tuning element. .2. The suppressor according to claim 1, wherein the, in order to achieve maximum mutual inductance, the turns of the winding of the additional inductor are located between the turns of the winding of the power inductance coil. CO * 0 1 1119182 2