SU1239513A1 - Transformer transducer of shifts - Google Patents

Abstract

The invention relates to a measurement technique and makes it possible to increase the accuracy of converting linear displacements by attenuating the sensitivity of the transducer to transverse (non-working) shapes of its moving element associated with the test object during the measurement process. The displacement transducer contains a zone of measurable displacements along the specified range of the excitation winding and two measuring coils with current leads spaced from one another at a distance equal to the length of the movable ferromagnetic element of the transducer. Measuring windings are located. In parallel, one OTHER as well. their opposite sections in the direction of transverse displacements along the V axis are located in the same part of the moving range of the transducer movable element and interconnected in succession. Between their current leads included resistors with the same resistance. Due to this, at displacements of the moving element along the Y axis, a differential change in the emf induced in the opposite sections of the measuring windings is provided. This provides stabilization of the current flowing in the resistors connecting these sections. and in the sections themselves, owing to them according to the series connection. Thus, the magnitude of the current in the sections of the measuring windings, and hence the output voltage of the converter, are uniquely related to the movement of the moving element along the longitudinal axis of the converter, which coincides with the direction of measurement; displacements X. 1 il. from 9 (L N) SO co 00 00

Description

The invention relates to a measurement technique and can be used © - / in various automation devices for measuring the position of linearly moving objects.

The purpose of the invention is to increase the accuracy of the displacement conversion of a proportional electrical signal by attenuating the sensitivity of the transducer to the transverse displacements of its ferromagnetic element associated with the test object during the measurement process.

The drawing shows a circuit diagram of a transformer linear displacement transducer.

The displacement transducer contains a ferromagnetic movable element 1 mounted for movement along the longitudinal axis 0-0 of the transducer, coinciding with the direction of the measured displacements, and two sectioned measuring windings 2 and 3, distributed along this axis, equipped with current leads one from at a distance equal to the length of the movable ferromagnetic element 1. These windings are placed parallel to each other, and their opposite in the direction of transverse displacements

The first element 1 coinciding with the axis V of the section is placed on one part of the range of movement of the movable element and connected in series.

Between the down-conductors and the ends of the windings 2 and 3 are included resistors 4, having the same nominal resistance. The drive winding 5 is also distributed along the same longitudinal axis of the 0-0 converter and can be. common for both measuring windings, if they are located in close proximity to one another, or may consist of two identical sections connected in series, each of which is wound on a common frame 6 or 7 with a corresponding measuring winding. AC power supply, and output terminals are removed from terminals 9 connected between the ends of the measuring windings at the end of the range of measured displacements

five

0

proportional to the position of the movable element 1.

The displacement transducer works as follows.

When an alternating current is passed through the excitation winding 5, the magnetic flux generated by it induces an emf in sections of measuring windings 2 and 3, the value of which is maximum in those sections against which movable element 1 is located. Opposite sections of windings 2 and 3 with maximum levels of emf resistors 4 are divided into two groups, in one of which the number of rotors of the controllers included in it increases, and in the other decreases as element 1 moves, which causes the redistribution of currents p resistors 4.

As rolling element 1 approaches winding sections 2 and 3, located at the end of the range of measured displacements X, the voltage drop across resistor 4 connected between the ends of these sections increases monotonically and reaches a maximum when element 1 enters the placement zone of these end sections. The transverse (non-working) displacements of the moving element 1 along the V coordinate differentially change the levels of maximum emf induced in opposite sections

5 qi windings 2 and 3, which are in the area of placement of this element.

- As a result, the total emf in these. The sections, and therefore also the current in them and the resistors connecting them, do not depend on the transverse displacements of the movable element, thereby ensuring independence as well. the output signal of the converter from this destabilizing effect, which enhances the accuracy of the displacement conversion.

five

0

45

Claims (1)

Invention Formula 50 A transformer displacement transducer, containing, a ferromagnetic element mounted for movement along the longitudinal axis of the transducer, 55 excitation winding distributed along the longitudinal axis and two sectioned measuring windings with current leads 55 different from the other, equal to the length of the ferromagnetic element, and attached to the current. to the waters of the first measuring winding with their clamps resistors with the same nominal resistance, 5 characterized in that, in order to increase the accuracy of conversion by attenuating the sensitivity to transverse displacements of its ferromagnetic element i of the second measuring winding the first measuring winding and connected with. they are consistent in series, and the resistors are connected with their other clips to the down-conductors of the second measuring winding.