RU2490608C2 - Measurement of parameters of controlled object mechanical oscillations - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: proposed method comprises excitation of electromagnetic field resonance oscillations in oscillatory circuit including inductance and capacitor. Note here that mechanical oscillations originate in inertial body made from magnetostrictive material and placed in gas that results from the effects of variable magnetic field. Said inertial body is displaced relative to the case. Note also that oscillatory circuit capacitance galvanically isolated from measuring circuit varies. Parameters of mechanical oscillations of inertial body relative to the case is measured by variation in electromagnetic field resonance oscillation frequency.

EFFECT: accurate and fast measurement.

1 dwg

Description

Technical field

The invention relates to measuring technique and can be used to measure the amplitude, speed and acceleration of mechanical vibrations of a controlled object.

State of the art

The closest analogue to the prototype of the proposed method for measuring the parameters of mechanical vibrations of controlled objects is a method for determining the amplitude of mechanical vibrations of an object (see description in AS USSR No. 13225305 A1, IPC G01H 11/00).

In this method, the parameters of electrical vibrations are measured in a circuit with a dynamic capacitor, one plate of which serves as the surface of the object, and the other is a measuring electrode. The measuring electrode is driven into oscillations with a given amplitude and with a frequency different from the oscillation frequency of the object. The amplitude of the mechanical vibrations of the object is determined by the measured parameters of electrical vibrations, taking into account the given amplitude of the oscillations of the measuring electrode.

A resonant circuit is formed from a dynamic capacitor and an inductor, resonant oscillations of an electrical signal in a circuit are excited with a frequency exceeding the frequency of mechanical vibrations of the object and the measuring electrode.

The direction of mechanical vibrations of the measuring electrode in two planes is successively changed, in each direction of the mechanical vibrations of the measuring electrode, the moment values of the frequency of the resonant electric oscillations in the circuit are measured, which are squared using the Fourier function — transforming the squares of the resonant frequency of the electric oscillations determines the Fourier coefficient modulus corresponding to the frequency mechanical vibrations of the measuring electrode.

First, the direction of the mechanical vibrations of the measuring electrode is changed in an arbitrarily selected plane, the direction of the mechanical vibrations of the measuring electrode is fixed, in which the Fourier coefficient modulus has a maximum value, then in the other plane perpendicular to the first plane and passing through the fixed direction of mechanical vibrations of the measuring electrode.

In the future, the direction of the mechanical vibrations of the measuring electrode is again fixed, in which the modulus of the Fourier coefficient corresponding to the frequency of the mechanical vibrations of the measuring electrode has a maximum value. In the last direction of the mechanical vibrations of the measuring electrode, the Fourier coefficient modulus corresponding to the frequency of the mechanical vibrations of the object is also determined using the Fourier transform function of the squares of the resonant frequency of the electrical vibrations.

The ratio of the second module of the Fourier coefficient to the first, taking into account the given amplitude of the oscillations of the measuring electrode, determines the amplitude of the oscillations of the object.

The low accuracy of the method for determining the amplitude of mechanical vibrations of an object - a prototype, is determined by the absence of galvanic isolation between the oscillatory circuit and the measuring circuit. As a result of this, the measurement accuracy is affected by changes in the capacitance, inductance and electrical resistance of the external connecting conductors, for example, when the temperature of the external environment changes.

In the specified method, it is necessary to change the direction of mechanical vibrations of the measuring electrode in two planes, which reduces the manufacturability of the manufacture of a device that implements the technical implementation of the specified method.

The low speed of the device implementing the technical implementation of this method is determined by the need to change the direction of the mechanical vibrations of the measuring electrode in two planes in the process of measuring the amplitude of the mechanical vibrations of the object.

Disclosure of invention

The objective of the invention is to increase the accuracy of measurement, manufacturability and speed of the device that implements the technical implementation of the proposed method for measuring the parameters of mechanical vibrations of controlled objects.

The problem is solved using the characteristics specified in the 1st paragraph of the claims common with the prototype, such as in an oscillatory circuit containing an inductor and a capacitor, excite resonant vibrations of the electromagnetic field, and distinctive essential features, such as an inertial body made of magnetostrictive material is placed in a gaseous medium. Mechanical vibrations in an inertial body are excited by the action of an alternating magnetic field applied to it, they move the inertial body relative to the housing, and the capacitance of the oscillating circuit, which is galvanically isolated from the measuring circuit, is changed. The parameters of the mechanical vibrations of the inertial body relative to the housing are measured by changing the frequency of the resonant vibrations of the electromagnetic field of the oscillatory circuit.

The high accuracy of the measurement of the device implementing the technical implementation of the proposed method is determined by the galvanic isolation of the oscillating circuit from the measuring circuit. As a result, there are no connecting conductors between the oscillatory circuit and the measuring circuit, which increases the accuracy of the measurement.

In the proposed method, aerodynamic weighing of the inertial body occurs inside the body in a gaseous medium. As a result, dry friction between the inertial body and the housing is completely absent, which increases the measurement accuracy.

The above set of essential features allows you to get the following technical result - improving the accuracy of measurement, manufacturability and speed of the device that implements the technical implementation of the proposed method for measuring the parameters of mechanical vibrations of controlled objects.

Brief Description of the Drawing

The drawing shows a structural diagram of a device that implements the technical implementation of the proposed method for measuring the parameters of mechanical vibrations of controlled objects.

The implementation of the invention

A device that implements the technical implementation of the proposed method for measuring the parameters of mechanical vibrations of controlled objects contains a housing (a longitudinal section of the housing is shown in the figure), an inertial body 3, an exciting inductor 6, an oscillating circuit, and a measuring circuit 5.

The housing consists of a base 7, a cover 8, a disk 9 and a ring 10 made of glass. The base 7 and the cover 8 are made in the form of two disks. In the figure, the places of diffusion compounds are indicated by lines of double thickness.

The inertial body 3 is made of magnetostrictive material.

The exciting inductor 6 is made by winding a wire on a dielectric frame. The first and second terminals of the exciting inductor 6 are connected to an alternating voltage generator of ultrasonic frequency of the measuring circuit 5 (not shown in the figure).

The oscillating circuit contains an inductor 1 and a capacitor 2. The capacitor 2 is made in the form of three metal rings. Two metal rings are placed on the side of the base 7, facing the disk 9 and connected to the first and second terminals of the inductor 1. The third metal ring of the capacitor 2 is located on the surface of the inertial body 3, facing the disk 9, and covers two metal rings that are placed on side of the base 7 facing the disk 9.

The inertial body 3 is placed with the possibility of movement in a gaseous medium 4 (preferably argon) inside the housing. Gaseous medium 4 has a high pressure.

The measuring circuit 5 comprises an inductor 11 for pumping energy into the oscillatory circuit, an inductor 12 for reading the frequency of the resonant oscillations of the oscillatory circuit, an OR element 13, transistor 14, comparator 15, and a computing device (not shown in the figure).

The second 16 input element OR 13 is the input trigger continuous undamped resonant vibrations of the electromagnetic field of the oscillatory circuit. The output of the OR element 13 is connected to the base of the transistor 14, the emitter of which is connected to the output "General" power.

The first and second terminals of the inductance coil 11 for pumping energy into the oscillating circuit are connected respectively to the collector of the transistor 14 and the positive terminal 17 of the DC power source (not shown) of the measuring circuit 5.

The first and second conclusions of the inductance coil 12 for reading the frequency of the resonant oscillations of the oscillatory circuit are connected respectively to the output "General" power and direct input of the comparator 15, to the inverse input of which a reference voltage is supplied. The output of the comparator 15 is connected to the first input of the OR element 13 and the computing device.

An inductor 1, an inductor 11 for pumping energy into the oscillating circuit and an inductor 12 for reading the frequency of the resonant oscillations of the oscillatory circuit are made by winding the wire onto the dielectric frame.

A device that implements the technical implementation of the proposed method for measuring the parameters of mechanical vibrations of controlled objects, works as follows.

After turning on the power from the parallel channel of the computing device to the second 16 input element OR 13 serves a single positive impulse. As a result of this, a positive pulse arrives at the base of transistor 14, which opens transistor 14 and a current begins to flow through the inductor 11 to pump energy into the oscillating circuit, which induces EMF, the electromotive force of induction in the oscillatory circuit, in which resonant oscillations of the electromagnetic field occur.

The frequency of the resonant oscillations of the electromagnetic field of the oscillating circuit is measured by taking the frequency from the inductor 12 to read the frequency of the resonant oscillations of the oscillating circuit, which then goes to the direct input of the comparator 15, to the inverse input of which the reference voltage is supplied. From the output of the comparator 15, the positive rectangular signals are fed to the first input of the OR 13 element (the second 16 input of the OR 13 element is supplied with a logic zero level) and to the computing device.

From the output of the OR element 13, rectangular pulses arrive at the base of the transistor 14, upon opening of which a current flows through the inductor 11 to pump energy into the oscillating circuit, upon changing which an induction emf arises in the oscillating circuit, under the action of which currents appear in the oscillating circuit, consistent with the direction current in the oscillatory circuit in each half-period of oscillation of the oscillatory circuit.

In a positive half-cycle of oscillations in the oscillatory circuit, energy is pumped during an increase in the current in the inductor 11 of energy pumping into the oscillatory circuit. In the negative half-cycle of oscillations, the energy is pumped during a decrease in the current in the inductance coil 11 of the energy pumping into the oscillating circuit, since the energy transfer occurs when the current changes in the inductor 11 of the energy pumping in the oscillation circuit.

Thus, continuous undamped resonant oscillations of the electromagnetic field with energy pumping at certain points in time are excited in the oscillatory circuit, increase the amplitude of the oscillations at these moments, and transform these oscillations into positive rectangular signals.

An alternating voltage of ultrasonic frequency is supplied from the generator of the measuring circuit 5 to the exciting inductor 6 (this alternating voltage may have a constant magnetizing component). As a result of this, the excitation of mechanical vibrations in the inertial body 3 under the action of an alternating magnetic field applied to it and aerodynamic weighing of the inertial body 3 inside the body.

With mechanical vibrations of the controlled object, the inertial body 3 moves relative to the body and the capacitor 2 changes in capacity.

The amplitude, speed and acceleration of mechanical vibrations of the controlled object is measured by changing the frequency of the resonant vibrations of the oscillatory circuit.

Industrial applicability

A device that implements the proposed method for measuring the parameters of mechanical vibrations of controlled objects can be made of available elements and materials in the conditions of radio production. The proposed method for measuring the parameters of mechanical vibrations of controlled objects will find wide application in the application devices of the present invention, other special cases of measuring the parameters of mechanical vibrations of controlled objects, for example, electric machines, will be obvious to specialists.

This description and examples are considered as material illustrating the invention, the essence of which and the scope of patent claims are defined in the following claims, a combination of essential features and their equivalents.

The technical result is an increase in measurement accuracy, manufacturability and speed of the device implementing the technical implementation of the proposed method.

Claims (1)

A method of measuring the parameters of mechanical vibrations of controlled objects, namely, that in an oscillating circuit containing an inductor and a capacitor, resonant vibrations of an electromagnetic field are excited, characterized in that the inertial body made of magnetostrictive material is placed in a gaseous medium, and mechanical vibrations are excited in inertial body under the action of an alternating magnetic field applied to it, move the inertial body relative to the body, change the capacitance ebatelnogo circuit which is electrically isolated from the measuring circuit, and the parameters of the inertial body relative to the housing of mechanical oscillations is measured by changing the resonant frequency of the electromagnetic field oscillations of the oscillatory circuit.