RU2589945C1 - Induction linear displacement sensor - Google Patents

Abstract

FIELD: test and measurement equipment.

SUBSTANCE: invention relates to instrumentation and can be used, in particular, in control system of electrohydraulic and electromechanical drives of aircraft. Summary: sensor has coil consisting of two measurement windings and excitation windings wound on frame from nonmagnetic material, core made from magnetically soft material, which is connected mechanically to controlled object by means of nonmagnetic rod. Each of measuring windings is stepped throughout length of frame and has two rows of wire coils wound evenly along whole length. Excitation winding is wound on top of measuring windings. Measuring windings are made according to differential circuit.

EFFECT: technical result is reduction of dimensions of the sensor, possibility of accurate adjustment of steepness of output characteristics, elimination of errors caused by output characteristic oscillations of supply voltage sensor.

1 cl, 3 dwg

Description

The present invention relates to instrumentation and can be used, in particular, in the control system of electro-hydraulic and electromechanical drives of aircraft, where information is required on the movements of the executive links.

The closest in technical essence to the proposed invention, the prototype is an induction linear displacement sensor with a steel non-magnetic rod (see Patent RU 2367901 C1).

A disadvantage of the known device is the low fill factor of the winding window, which increases the size of the sensor. This is due to the fact that each measuring winding is located only half the length of the frame, and the middle part of the winding window remains empty. Also in the known device it is not possible to summarize the voltages removed from the measuring windings of the sensor. Fulfillment of the condition for maintaining the same value of the total signal of the measuring windings over the entire range of core motion is necessary to ensure linear transformation of the sensor output voltages when they are processed by a number of microcircuits. Also a disadvantage of this device is the high quality requirements of the supply voltage U _pit sensor. This is a consequence of the fact that with the sensor circuit according to which the known device is made, the output characteristic of the sensor is:

Y = U1-U2

With an unstable supply voltage U, the _pit voltage U1 and U2 on the measuring windings change, which introduces an additional error in the output characteristic Y.

The technical task of the proposed invention is to remedy these disadvantages.

The task in terms of reducing the size is solved by changing the winding circuit of the coil for more efficient use of the winding window. Also, to ensure accurate adjustment of the steepness of the output characteristic Y, two rows of coils were added to the measuring windings, wound uniformly along the entire length of the frame. The task of reducing the dependence of the output characteristic on the quality of the supply voltage is solved by using a different voltage processing circuit removed from the measuring windings of the sensor, for which the measuring windings were made differentially.

The essence of the invention is illustrated in FIG. one.

The induction linear displacement sensor contains a coil, inside of which is placed a movable core 4 made of soft magnetic material, which is connected mechanically to the controlled object using the rod 6.

The coil consists of a field winding 1 and two measuring windings 2, 3. The windings are wound as follows. A measuring winding 3 is wound onto a frame 5 of non-magnetic material. The first two rows of turns are wound evenly along the entire length of the frame. Subsequent rows are wound in such a way that the number of turns in each subsequent row is less than in the previous one, by an amount equal for all rows of the winding and depends on the size of the winding window, as well as the required voltage U1 and its increment depending on the position of the core.

The measuring winding 2 is wound over the measuring winding 3, and the number of turns in each subsequent row is greater than in the previous row by an amount equal to the decrease in the number of turns of the measuring winding 3. The last two rows of turns of the measuring winding 2 are wound evenly along the entire length of the frame.

The first two rows of the measuring winding 3 and the last two rows of the measuring winding 2 are uniformly distributed over the entire length of the frame so that the number of turns in these rows is the same for both measuring windings.

A more efficient use of the coil volume reduces the overall dimensions of the sensor.

The field winding 1 is wound on top of the measuring windings 2 and 3. The field winding 1 is winded uniformly along the entire length of the frame 5. This ensures that the dimensions of the field winding 1 are reduced at the same current consumption by excitation by increasing the length of the middle coil.

The output characteristic of the Y sensor is the ratio of the voltage difference taken from the measuring windings to their sum.

Y = U1-U2 / U1 + U2

Winding two rows in each measuring winding 2, 3 evenly over the entire length of the frame allows precise adjustment of the slope of the output characteristic Y by changing the number of turns in these rows and, as a result, changing the sum of the voltages (U1 + U2).

Variants of the electrical induction sensor circuits are shown in FIG. 2 and FIG. 3.

The sensor operates as follows.

The excitation winding 1 is supplied with an alternating current supply voltage U _pit , alternating current begins to flow through it, which creates a magnetic flux. The core 4 enhances the magnetic flux generated in the field coil 1 and concentrates it in the space around the core. When the core position is zero, the currents induced in the measuring windings 2 and 3 are equal in value but opposite in phase. When moving the moving part from the zero position, the equilibrium is violated - the output voltage of one measuring winding of each sensor output decreases, the other increases.

A more efficient use of the coil volume reduces the overall dimensions of the sensor. The winding of two rows in each measuring winding uniformly along the entire length of the frame allows precise adjustment of the steepness of the output characteristic Y. Differentially executed measuring windings in combination with the applied winding circuit, which provides a constant sum of output voltages U1 + U2 throughout the entire core stroke, made it possible to apply the output processing circuit voltage, at which the output characteristic of the sensor is the ratio of the voltage difference removed from the measuring windings to their total. This processing ensures the stability of the output characteristic and does not depend on fluctuations in the supply voltage.

The described device, tested in laboratory and industrial conditions, provided the required characteristics while reducing the size of the sensor.

Claims (1)

An induction linear displacement sensor containing a coil consisting of two measuring windings and an excitation winding on a frame made of non-magnetic material, a core made of soft magnetic material, which is connected mechanically to the controlled object by means of a non-magnetic rod, characterized in that each of the measuring windings is made stepwise in the entire length of the frame, and the field winding is wound over the measuring windings, the measuring windings are made according to the differential circuit and have two p poison of wire turns wound uniformly along the entire length, as a result of these changes, the dimensions of the sensor were reduced, it became possible to precisely adjust the steepness of the output characteristic and the possibility of using a processing circuit in which the output characteristic does not depend on the supply voltage.

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