SU977932A2 - Displacement magnetomodulation type converter - Google Patents

Description

(B) MAGNETOMODULATOR DISPLACEMENT CONVERTER

Claims (1)

The invention relates to a measuring technique and can be used in devices for automatic control, control, measurement and control of non-electrical quantities by electrical methods in the metallurgical, chemical, petrochemical, instrument-making, engineering sectors of the industry. St. The f 59663 is known for a magnetic-modulated displacement transducer, containing two saturation throttles with magnetic conductors, a movable permanent magnet, a C-shaped magnetic core with Q clearance on its base, in which one of the saturation throttles is located, and with V-shaped cuts in the direction of displacement magnet on parallel plates. - like a magnetic circuit, and the second saturation throttle is coaxially aligned with the first between the ends of the parallel magnetic core plates, at THIS both saturation throttles and the permanent magnet are covered by the - like magnetic circuit Cl. A disadvantage of the known converter is comparatively low accuracy due to the large dynamic error caused by the large constant time of saturation throttles, as a result of which the emf induced in the windings of the saturation throttles lags behind the change in the magnetic flux of the permanent magnet, as a result of which the amplitude dynamic error of the large magnet the greater the speed of the rolling element. The purpose of the invention. - improving accuracy by reducing the dynamic error of the converter. This aim is achieved in that the movement converter magnitomodul insulating windings provided with two correction circuits dum two two-section matching and bias windings, the output of each correction coil is connected via a matching circuit to the bias coil two-section, each saturation throttle position, two-section .no one winding saturation , the sections of each of which are diametrically opposed and connected in series to the throat, the correction windings are located on portion cut V-shaped. FIG. 1 shows the transducer design; in fig. 2 - switching circuits of the converter windings. The magnet-modulating displacement transducer contains two throttles of villages 1 and 2 of saturation, a C-shaped magnetic conduit 3, between the ends of parallel plates of which a saturation choke 1 is located, and in the base of the magnetic conductor 3 there is a gap in which the second choke 2 of saturation coaxially with the first movable a permanent magnet 5 placed between parallel plains. of the magnetic core 3 and configured to move along them, two windings 6 and 7 of the correction on the magnetic core 3, two two-section windings from sections 8 and 9 10 and 11 years of magic, located on the throttles x 1 and 2, and two schemes 12 and 13 harmonization. Sections 8 and 9 of one bias winding winding are wound around the choke 1 of the saturation, and sections 10 and 11 of the second bias winding are wound around the choke 2 of saturation; Moreover, sections 8 and 9, 10 and 11 of each J i winding winding are located diametrically in the section of throttles 1 and 2 of saturation, respectively, not adjacent to the parallel plates of the magnetic circuit 3, and are connected in series to the common strip. On parallel plates of the magnetic circuit 3, sections 1A and 1 are V-shaped, with which the parallel plates of magnetic circuit 3 are divided into wedge-shaped and W-shaped sections. The correction winding 6 is wound on the wedge-shaped section of one of the parallel plates of the magnetic circuit 3, and the second winding 7 of the correction is on its W-shaped section. The saturation saturation switch 1 is located on the side of the bases of the wedge-shaped sections of the parallel plates of the magnetic circuit 3. The correction winding 6 is connected to the bias winding through the matching circuit 12 (sections 8 and 9). The correction winding 7 is connected via a matching circuit 13 with a bias winding (sections 10 and 11). The windings of the chokes 1 and 2 of the saturation are connected in series to one another and have terminals for connecting the load and the source of alternating current (not shown). . The matching circuits 12 and 13 can be made in the form of operating silicate with unipolar output. A permanent magnet 5 serves to create a magnetic flux. Magnetic conductors of saturation throttles 1 and 2, and Mai-conduits 3 are designed to create a magnetic flux path. The windings of the chokes 1 and 2 saturation are used to create the working magnetic flux and to remove the output signal from them. The It and 15 V-shaped cuts on parallel plates of the magnetic core 3 serve to redistribute the magnetic flux when moving the permanent magnet 5 and eliminate the error of the transverse displacement of the magnet 5. The windings 6 and 7 of the correction serve to correct the dynamic error of the displacement measurement by creating emf proportional to the speed of movement of the permanent magnet 5. The sections 8-11 of the bias windings are designed to correct the dynamic error of the measurement of movement by additionally go magnetic biasing. Matching circuits 12 and 13 are designed to amplify (match in amplitude) the correction signal and to create an output signal of one polarity independent of the direction of movement of the permanent magnet 5 The magnetic displacement transducer works as follows. When connecting the windings of chokes 1 and 2 saturation to an alternating current source (not shown) in the magnetic -. water, consisting of an I - shaped magnetic core 3 and magnetic cores of saturation throttles 1 and 2, is created by a variable operating magnetic flux Fre, b. A permanent magnet 5 creates a magnetic flux ф, which is divided into two parts: F | l MB magnetic flux, pass on the wedge-shaped sections of parallel plates of the magnetic core 3 to the left of magnet 5, penetrating the windings of the correction winding 6, and on the choke 1 of saturation, and Ф, lpr. magnetic flux passing through W-shaped sections of parallel plates of the magnetic circuit 3 to the right of magnet 5 piercing turns winding 7 correction, and the throttle 2 saturation. When moving the permanent magnet 5 from the midpoint, the magnetic fluxes F, the passage of the magnetic circuits of the chokes 1 and 2 of the saturation, respectively, change their degree of saturation in proportion to the displacement of the permanent magnet 5 from the middle position, thereby changing the inductance of each winding of the chokes 1 and 2 saturation. When the inductance of the windings of the bottoms of mudflows 1 and 2 of saturation changes, the total resistance in the load circuit changes, as a result of which the current in the load circuit changes in proportion to the movement of the permanent magnet 5 from the middle position. When moving a constant magnet 5 at some speed in the windings 6 and 7 of the correction, an electromotive voltage (E, p) is induced, the value of which depends on the speed of movement of the permanent magnet 5 According to the magnetic cores of chokes 1 and saturation, the total fluxes mv ave respectively (flow standing magnet and bias flux}, changing the degree of saturation of chokes 1 and 2 is proportional to the displacement x and the speed V of the permanent magnet 5. As a result, the inductance of each winding of the chokes 1 and 2 saturates. resistance in the load circuit and, consequently, the current in the load circuit is proportional to the displacement X and the speed V of the permanent magnet 5. By creating a magnetizing flow, the current in the load increases with increasing speed V of the magnet 5, resulting in compensation of the amplitude dynamic error of the displacement measurement. The proposed magnetic modulation displacement transducer allows reducing the dynamic error in comparison with the known one, which improves the measurement accuracy. A correction proportional to the speed of movement of the moving element can also be removed from the correction windings, which expands the functionality of the converter. Claims of Invention Magnetic Modulation Transducer Motion by Aut. St. No. 59663, characterized in that, in order to increase accuracy by reducing the dynamic error, it is equipped with two correction windings, two matching circuits and two two-section bias windings, the output of each correction winding is connected via a matching circuit to the two-section bias winding, at each saturation throttle located on one two-section saturation winding, sections of which are diametrically opposed and connected sequentially-counter, winding correction located Eny on the section of the V-shaped incision. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 59663, cl. G 01 B 7/10, 1975.