RU1781621C - Pickup of parameters of movement - Google Patents

Abstract

The invention relates to the field of measurement technology and is intended to measure linear accelerations and speeds of movement of elements of mechanisms and machines, structures of structures and platforms of calibration stands. The essence of the invention is that the sensor includes a magnetic circuit, a permanent magnet with a rod, movable and fixed measuring windings, two cylindrical cylindrical sleeves short-circuited from non-ferromagnetic material. A movable winding is mounted inside a sleeve of a smaller diameter and is movable along the axis of the sensor together with the magnet. The length of the movable winding is chosen equal to two lengths of the magnet. The magnetic circuit is made with a slot along the generatrix. 1 ill.

Description

AND

The invention relates to measuring equipment and is intended for measuring linear accelerations H (CKOpocteu of movements of elements of mechanisms and machines, structures of structures and platforms of calibration stands.

A device is known for non-contact measurement of velocities and accelerations of moving electrically conductive bodies. The device comprises a three-core magnetic circuit, an excitation winding, mounted on the middle rod and powered by alternating current, two measuring windings, mounted on the extreme rods and turned towards each other. A disadvantage of the device is the need to use special high-frequency generators to power the field winding, as well as the fact that a uniform signal proportional to speed and acceleration of movement is induced in the measurement windings connected in series to each other.

A motion parameter sensor is known which includes an E-shaped magnetic circuit, at the base of which are installed two permanent magnets, an excitation winding powered by alternating current, and a measuring winding directly bonded to the object under study. The field coil and the measurement coil are seated on the middle core of the magnetic circuit. The output signal taken from the secondary winding of the transformer connected in series with the measuring winding is proportional to the amount of movement, and the signal taken from the capacitance (capacitor) shunting the measuring winding together with the primary winding of the transformer is proportional to the speed of this movement, i.e. the sensor is designed to measure speed and veVI

with

about y

disguises of displacement. The most important parameter determining the dynamic processes is acceleration and speed of movement. For this purpose, the sensor under consideration does not fully respond. In addition, due to the finite magnetizing forces of the permanent magnets, the sensor has a limited range of linear characteristics.

Sensors of motion parameters are also known which are functionally designed to measure speed and magnitude of movement, and are not intended to measure acceleration.

The closest in technical essence and achieved positive effect to the claimed invention should be considered a linear velocity sensor containing a T-shaped magnetic circuit, at the ends of which two permanent magnets are installed. A magnetic core with permanent magnets form a three-rod magnetic system. Moving and stationary measuring windings are planted on the middle rod. The movable winding is held together by the test object. The signal induced in a stationary winding is proportional to the acceleration, in the LARGE - to the speed. To pick up a signal proportional to acceleration, the movable coil is short-circuited by means of a key. A disadvantage of the sensor is the limited range of the linear characteristic due to the inability to create a uniform magnetic field in the gap of the magnetic system at large displacements, as well as the impossibility of simultaneously registering speed and acceleration signals.

The objectives of the invention are to increase the sensitivity and range of linear acceleration characteristics and to increase the accuracy of speed measurements.

An increase in the sensitivity and range of the linear characteristic for acceleration is achieved by the fact that in the motion sensor containing a magnetic circuit, a permanent magnet with a rod, a movable and fixed measuring windings between a movable and a stationary measuring windings, a short-circuit made of non-ferromagnetic metal cylindrical sleeve is mounted, the movable winding is inserted with the possibility of moving together with the magnet, and its length is selected from the ratio where L is the length of the winding, H is the length of the magnet.

An increase in the accuracy of measuring speed is achieved by introducing a second cylindrical sleeve short-circuited from a non-ferromagnetic metal into the sensor between the stationary winding and the magnetic circuit, and the magnetic circuit is made with a slot along the generatrix.

Distinctive features are:

Two short-circuited cylindrical sleeves made of non-ferromagnetic metal are introduced into the sensor, one of which is installed between the movable and fixed windings, the other - between the fixed winding and the magnetic circuit, a measuring winding is installed inside the sleeve of a smaller diameter with the possibility of movement together with the magnet, and its length

5 is selected from the ratio

,

where L is the length of the winding, N is the length of the magnet, the magnetic circuit is made with a slot

0 along the generatrix.

The inventors of the present invention did not find solutions with similar features, therefore, the considered technical solution has significant differences.

The essence of the proposed device is based on the induction method of converting the measured value into an electrical signal. To obtain a signal proportional to acceleration, a cylindrical sleeve is used in the sensor, short-circuited from non-ferromagnetic metal, inside which a measuring winding is placed with the possibility of

5 movements in conjunction with a magnet.

When the permanent magnet C is wound along the axis of the sensor, significant ring currents are induced in the body of the sleeve, since the electrical resistance of the sleeve is practically zero. These currents, proportional to the speed of movement of the magnet, create a magnetic field, the change of which induces an EMF in the turns of the measuring winding. This emf

5 is proportional to the rate of change of the induced magnetic field. Since the rate of change of the induced magnetic field is equal to the rate of change of the ring currents induced in the body of the sleeve or the speed of movement of the magnet, the signal in the measuring winding is proportional to the measured acceleration.

Ring currents are induced only in that part of the body of the sleeve, which is pierced

5 by the magnetic field of a permanent magnet. Therefore, the use of a cylindrical sleeve provides equal conditions for inducing EMF, no matter where the magnet is located on the axis of the sleeve, which provides linearity of the sensor's characteristics for paving (according to the measured acceleration of movement of the test object),

Experimental studies conducted by the authors to determine the spatial distribution of the magnetic induction of the magnet along the axis and radius of the sensor showed that the magnetic induction at the level of the location of the sleeve approaches zero at a distance from the pole of the magnet equal to half the length of the magnet. Therefore, in order to more effectively convert the measured acceleration into a signal value, i.e., to increase sensitivity, the length of the measuring winding is chosen to be equal to two magnet lengths.

At the same time, when the magnet moves, the EMF in the stationary winding is proportional to the speed of movement, However, due to the use of a magnetic circuit in the induction transducers, ring currents are induced in the body of the latter, which in turn induce EMF in the measuring winding, which are proportional to the acceleration, i.e. the speed signal is distorted by the acceleration signal or the measurement accuracy is reduced.

Thus, the accuracy of the speed measurement is affected by a metal sleeve mounted in the sensor between the movable and fixed windings.

In order to increase the accuracy of measuring the speed in the sensor, the magnetic circuit is cut along the generatrix and a second short-circuited cylindrical sleeve is introduced from the non-ferromagnetic metal between the magnetic circuit and the stationary winding. The slit in the magnetic conductor excludes the circulation of ring currents in its body, thereby excluding the induction of a signal proportional to acceleration in the measuring winding. The ring currents induced in the sleeve installed between the magnetic conductor and the stationary measuring winding compensate for the influence of the other sleeve on the distortion of the speed signal, thereby increasing the accuracy of the measurement.

But the drawing shows the proposed device.

The sensor consists of a rod 1, rigidly fastened to a magnetic core 2, on the surface of which a two-section coil 3 with an i / nr / measuring winding 4 is installed. Turnover a 4 is made different in length along the coil with the opposite direction of winding of the turns in each of the coil sections. The length of the winding 4 is chosen equal to two lengths of the magnet. Coil with winding and magnet placed in

an internal cavity of a short-circuited cylindrical sleeve 5 made of non-ferromagnetic metal 5. A coil 8 with a measuring winding 7 is planted on the sleeve 5,

made with a uniformly varying along the length of the coil winding step. All of the above structural elements of the sensor are placed in the inner half of the second short-circuited

0 non-ferromagnetic metal of a cylindrical sleeve 8, placed in the housing - a magnetic core 9 with two covers 10 and 11. The magnetic core has a through slot along the cutting (not shown),

5 The converter operates as follows.

When moving the rod 1, bonded to the test object, the magnetic core 2 together with the coil 3 and

0, the measuring coil 4 moves along the axis of the sensor. When the magnet B is moved by a sleeve 5 made of a non-ferromagnetic metal, significant ring currents are induced,

5 are proportional to the speed of movement of the magnet. These currents create a magnetic field, the change of which induces in the windings of the winding 4 EMF proportional to the rate of change of the induced field or acceleration of the displacements of the object under study. So as winding 4 is made two-section with the opposite direction of winding coils in each section, then the EMF under the opposite poles of the magnet,

5 are summed up. Choosing a winding length equal to two magnet lengths provides an increase in the sensitivity (signal) of the sensor, since the spatial distribution of the magnetic field of each magnet pole is used more effectively.

At the same time, when the magnet moves in the turns of the stationary measuring winding, an EMF is proportional to the speed of the test

5 objects. In this case, due to the fact that the magnetic conductor is made with a slot along the generatrix, the guidance of the annular guides and their influence on the output signal is excluded. Introduction between the magnetic circuit

A 0-liter stationary winding of a short-circuited sleeve made of non-ferromagnetic metal compensates for the induction of a distorting signal from the sleeve installed between the movable and stationary windings, since the magnetic currents from the ring currents of these sleeves in the measuring winding (fixed) are directed to each other.

The use of a short-circuited sleeve made of non-ferrochromatic metal, fitted with a fur; for movable and fixed

measuring windings, provides an increase in the range of linear characteristics of the sensor for acceleration.

The implementation of a movable winding with a length equal to two lengths of a permanent magnet provides an increase in the acceleration sensitivity of the sensor.

The use of a squirrel-cage made of metal-clad metal installed between the magnetic circuit and the stationary winding, and the implementation of magnetic tape guides with a slot along the generatrix increases the accuracy of speed measurement.

According to the invention, sensors with the main parameters are manufactured:

Amount of free

stroke of a magnet, mm 350

Sensitivity by

acceleration, ma / d5

Sensitivity by

speeds, MD / CM / C8

The sensors are tested in laboratory conditions. The test results showed that the objectives of the proposed technical solution have been achieved. There are no deviations from the linearity of sensitivity for acceleration over the entire range of movements. Acceleration sensitivity of the sensor allows registration on modern

accelerometer oscilloscopes from fractions of units of terrestrial acceleration. Errors due to distortion of the speed signal by the acceleration signal are absent.

Claims (1)

The claims A motion parameter sensor consisting of a magnetic core, a cylindrical permanent magnet, movable and fixed windings, characterized in that that, in order to expand the range of the linear characteristic and increase the sensitivity for acceleration and increase the accuracy in measuring speed, a rod and two concentric short-circuited non-ferromagnetic metal cylindrical sleeves are introduced into it, one of which is installed between the movable and fixed windings, and the other between the stationary winding and magnetic circuit, while a movable measuring winding is located inside a sleeve of a smaller diameter and is fixed motionless and symmetrically on the outer cylindrical surface of the magnet, and its length L is selected from the relation L / 2H-1, where L is the length of the winding, N is the length of the magnet, moreover, the magnetic conductor is made with a slot along the generatrix, and the rod is connected with an end face of a permanent magnet.