SU1012149A1 - Current measuring transformer - Google Patents

Abstract

1. MEASURING CURRENT TRANSFORMER, containing a toroidal winding from Vi sections located in the cavity of an electrical shield, from an azimuth gap, And resistors and a summing node with transmission lines, the inputs of which are connected to the outputs of the winding sections, about T and L U and, and with the aim of simplifying the design, the X1 section is made in the form of two spiral windings which are oppositely connected, arranged symmetrically relative to the corresponding resistor, which is connected between the ends of the spiral windings and a static screen connected to the other ends of the spiral windings, the azimuthal length of which is determined from the ratio tf n C is the azimuthal length of the windings; {f - specified relative measurement error; (L D - diameter of the toroidal winding guide. A-L CE-4 CO

Description

2. Current transformer pop. 1 characterized by the fact that the characteristic impedance W of the resuscitation of the lines of the summing node is determined from copjTHomeHHH

.

where ft is the resistor rating

W is the characteristic impedance of the spinRs windings ...

3. Current transformer according to claim 1,. characterized in that the relocation of the line of the summing node is combined in pairs, with one end of each transmission line connected to the combined ends of the previous pair of lines equal to each other along the length, and the other to the adjacent transmission line equal to it in length and the subsequent transmission line, with the wave impedance of the lines, each subsequent pair of a pair equal to half the wave impedance of the lines of the previous pair, and the wave impedance of the transmission lines connected directly to the outputs of the sections is equal to i the resistance of these sections.

The invention relates to a pulse technique and can be used to measure nanosecond current pulses. Known from C Rogowski, containing a toroidal winding placed in an electrostatic screen with an azimuthal gap and a load resistance connected between the end winding of the winding and the electrostatic screen, number 1.. The disadvantage of this device is low accuracy, which is caused by the distortion of the output signal when the conductor is displaced with the measured current relative to the axis of the toroidal winding due to the commensurability of the time of the electromagnetic wave passing along the pulse and the duration of the measured pulse. A measuring current transformer containing a toroidal winding of M sections, located in the cavity of an electrostatic shield with an azimuthal gap, P resistors connected between the ends of the sections and a summing node, whose inputs are connected to the outputs of the sections, known as equal lengths of transmission lines, is known connected to the output of the summing up node through matching resistors C 2. A disadvantage of the known HOi meter: o a transformer is a design complexity associated with a large number of sections, providing These are the specified measurement error and the need to draw from each section extended front lines with a matching resistance, the presence of which increases the power loss. In addition, the sensitivity of the measuring transformer, whose sections contain one or several toroidal turns, can only be determined experimentally. The purpose of the invention is to simplify the design. The goal is achieved by the fact that in a measuring current transformer containing a toroidal winding from K1 sections located in the cavity of an electrostatic shield with an azimuthal slit, n resistor and summation, the node with transmission lines, whose inputs are connected to the outputs of the winding sections, is made in two oppositely connected spiral windings located symmetrically with respect to the corresponding resistor, which is connected between connected with the other ends of the spiral windings, the azimuthal length of which is defined cases where a ratio of 6 - azimuthal winding length / O - Specifies the relative measurement error; E is the diameter of the toroidal winding guide. In addition, the characteristic impedance vt of the transmission lines is determined by the ratio Z.ft + Wo where I is the resistor rating, the characteristic impedance of the spiral windings. In addition, the transmitting lines of the summing node are connected in pairs, with one end of each transmission line connected to the combined ends of the transmitting pair of lines equal to each other along the length, and the other end to the adjacent transmission line equal to it in length, and with the subsequent transmission

Claims (3)

1.- MEASURING CURRENT TRANSFORMER, containing a toroidal winding from and sections located in the cavity of the electrostatic screen with an azimuthal gap, and resistors and a summing unit with transmission lines, the inputs of which are connected to the winding With the moves of the sections of the winding, I cast off U and I, in order to simplify the design, each section is made in the form of two counter-connected spiral windings located symmetrically relative to the corresponding resistor, which is connected between one end of the spiral windings electrostatic screen connected to other ends of spiral windings, the azimuthal length of which is determined from the ratio 64 -JL_ -fcb η azimuthal length of the windings ;, ¹ specified relative measurement error; toroidal guide diameter t 2. Current transformer pop. 1 ', characterized in that the wave impedance W of the transmission lines of the summing node is determined from the relation W / _ * 2R + W ₀ 'where ft is the resistor rating, w ~ wave resistance of spiral windings, .. 3. Current transformer according to π. 1, · characterized in that the movement of the line of the summing node from one is united in pairs, with one end of each transmission line connected to the combined ends of the previous pair equal along the length of the lines, and the other to the adjacent transmission line equal to its length, and the next transmission line, and the wave impedance of the lines of each subsequent pair is equal to half the wave impedance of the lines of the previous pair, and the wave impedance of the transmission lines connected directly to the outputs of the sections is equal to the total wave • The resistance of these sections.