SU1525595A1 - Contactless converter of strong d.c. - Google Patents

Abstract

The invention relates to electrical measuring technology and can be used for contactless measurements of high direct currents. The purpose of the invention is to improve the accuracy of the conversion. The converter of large direct currents contains a detachable magnetic core made of separate ferromagnetic elements 1, 2 with longitudinal gaps, Hall elements 3 and 5 placed in transverse gaps between ferromagnetic elements 1 and ferromagnetic elements 2 and a recording device 9. In addition, the converter is inserted similar ferromagnetic elements 1, which form with ferromagnetic elements 2 additional transverse gaps, in which Hall elements 4 and 6 are placed, comprising a pair of elements with Hall elements 3 and 5 s 3, 4 and 5, a Hall 6 disposed substantially at one point of the magnetic circuit. As a result of the arrangement of the pairs of Hall elements and the counter-incorporation of the Hall electrodes of the Hall elements in these pairs, a greater degree of compensation is provided for the effect on the transducer of external non-uniform magnetic fields, which increases its conversion accuracy. 3 il.

Description

MI 3 and 5 Hall pair of elements 3, A and 5, 6 Hall, located almost at one point of the magnetic circuit. As a result of the arrangement of the pairs of Hall elements and the counter-incorporation of the Hall electrodes of the Hall elements in these pairs, the degree of compensation for the transducer of external inhomogeneous magnetic fields is enhanced, which improves its conversion accuracy. 3 il.

The invention relates to electrical measuring equipment and can be used for non-contact measurement of large direct currents.

The purpose of the invention is to increase the conversion accuracy by reducing the influence on the measurement result of external inhomogeneous magnetic fields.

Fig. 1 shows a contactless converter of high direct currents; in fig. 2 - flux distribution in part of the magnetic circuit of the converter; in fig. 3 - diagram of the output circuit of the converter.

The converter contains a detachable closed magnetic core (Fig. 1) consisting of separate external 1 and internal 2 ferromagnetic elements. Ferromagnetic elements 1 as well as ferromagnetic elements 2 are installed with longitudinal gaps. Neighboring ferromagnetic elements 1 and 2, in addition, form between themselves over n pairs of transverse gaps lying in two parallel planes. Elements 3–6 of the Hall are placed in these gaps (Figs. 1, 2, and 3). The closed magnetic circuit with the elements of the Hall is placed in the insulating body 7, which in the process of measurement covers the bus 8 with a controlled current. The current electrodes of Hall elements 3-6 are connected to a power source, and their Hall electrodes are connected to each other in series, with the Hall electrodes of Hall elements 3 and 5 placed in each pair of transverse gaps formed by one ferromagnetic element 2 and two ferromagnetic elements 1. - in the same plane, and Hall. The electrodes of Hall elements 3 and 4 placed in each pair of transverse gaps formed by one ferromagnetic element 2 and two ferromagnetic elements 1 lying in parallel planes are connected

opposite, and the Hall electrodes of the Hall elements 4 and 5, placed in each pair of transverse gaps adjacent to the two ends of each ferromagnetic element 2, are connected according to. To display the measurement results, a registering device 9 is switched on in the circuit of series-connected Hall electrodes of Hall elements 3-6.

The Converter operates as follows.

After covering the bus 8 with a controlled direct current by a detachable magnetic pipe, a permanent magnetic flux φ is created in the latter controlled current, which penetrates Hall 3 and D, 5 and 6 elements (Figures 2 and 3) on their Hall electrodes The EMF of the Hall, which, due to the counter-switching on of the Hall electrodes in each pair of elements 3, 4 and 5, 6 of the Hall and the consistent consonance of the Hall electrodes of these pairs of Hall elements (phi1. 3), are arithmetically summed, causing the output at the output of the circuit orally connected hall electrodes 3–6 of the Hall, the total Hall emf proportional to the magnitude of the controlled direct current. The value of this total Hall EMF is measured using a recording device 9.

In the presence of external non-uniform magnetic fields, including those created by adjacent current-carrying conductors, for example, f (Aig. 2 and 3), the latter penetrate Hall elements 3–6 and cause Hall electromotive forces on their Hall electrodes that are not connected to a controlled constant current, i.e. emf interference. At the same time, these EMF interference due to the location of every two elements 3, 4 and 5, 6 of the Hall in each pair of them, practically at one point of the separable magnetropod will be pairwise the same both in magnitude and in direction, and therefore due to counter-switching Hall electrodes in each pair of elements 3, A and 5, 6 of the Hall will almost completely mutually compensate each other, without causing a change in the total EMF of the Hall transducer, which improves the accuracy of the conversion of the proposed device in comparison with the prototype.

Claims (1)

Invention Formula A contactless converter of large direct currents containing a detachable closed magnetic circuit made of separate first ferromagnetic elements with longitudinal gaps and second ferromagnetic elements forming adjacent transverse gaps with adjacent first ferromagnetic elements, including ferromagnetic elements and pairs of next continuous gaps which are located the first elements of the Hall, the current electrodes of which are connected to the power source, and the Hall electrodes are connected in series River, and recording device included The first Hall elements connected to the circuit of series-connected Hall electrodes are characterized in that, in order to increase the conversion accuracy, third ferromagnetic elements are added to it, forming similar pairs of successive identical transverse gaps with adjacent first ferromagnetic elements which are located the second, additionally introduced Hall elements, with the Hall electrodes in each pair of Hall elements formed by one of the first and one of the second elements of the Hall placed in each pair of transverse gaps adjacent to the same end of each The counter electrodes and the Hall electrodes in each pair of Hall elements formed by one of the first and one of the second Hall elements placed in each pair of transverse gaps adjacent to the two ends of each of the first ferromagnetic elements are connected according to. WITH - Fm, 3