RU2574321C2 - Method to measure fluid medium flow and device for its realisation - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: device to measure fluid medium flow comprises a pipeline from dielectric material, permanent magnets arranged at different sides from a pipeline, and an oscillating circuit made of an inductance coil and a capacitor, armatures of which are located at both sides of the pipeline. In the oscillating circuit they excite resonant oscillations of electromagnet field. Fluid medium moving in the permanent magnetic field is polarised under action of Lorentz forces, as a result of which the electric field of the oscillating circuit capacitor varies, as well as dielectric permeability of fluid medium and duration of the first and second half-periods of resonant oscillations of the electromagnetic field of the oscillating circuit. Fluid medium flow is determined by variation of duration of the first or second half-periods of resonant oscillations of the oscillating circuit electromagnetic field.

EFFECT: increased accuracy of measurements.

5 cl, 1 dwg

Description

Technical field

The invention relates to the field of measuring equipment and can be used to measure the flow of water, gasoline, diesel fuel, kerosene.

State of the art

A known method of determining fuel consumption (see description to the USSR AS No. 1835490 A1, IPC G01F 1/66) is an analog of the proposed method for measuring the flow rate of a liquid medium, which consists in periodically moving the diaphragm of the fuel pump, according to the extreme positions of which the fuel consumption is judged from the supra-diaphragm cavity of the pump to the pressure pipe of dielectric material.

In this case, the pressure pipe is pre-filled with fuel with a minimum content of gas inclusions, electromagnetic waves are excited in the pressure pipe and the reference value of the resonant frequency is fixed, electromagnetic waves are excited in the sub-diaphragm cavity of the fuel pump and pressure pipe during periodic movement of the diaphragm, and the maximum difference in the resonance values is measured frequencies for one cycle of diaphragm movement and the value of the current resonant frequency in the pressure pipe e, the difference is determined between the reference and the current values of the resonance frequencies in the flowline, and the fuel consumption is determined by the product of these differences.

In the specified analogue method, fuel consumption is determined by the product of the above resonance frequency differences.

With periodic movement of the diaphragm of the fuel pump, mechanical wear and fatigue of materials of the moving parts of the fuel pump occur, which reduces the accuracy of the measurement of the method for determining fuel consumption.

The closest analogue is the prototype of the proposed method for measuring the flow rate of a liquid medium is a method for determining the flow rate of a liquid in a pipeline (see the description of the patent of the Russian Federation No. 2190833 C2, IPC G01F 1/58).

In the specified method for determining the flow rate of a liquid in a pipeline, a magnetic field is extracted at any point along the perimeter of the measuring section of the pipeline associated with the electric charge of the liquid, it is converted using an electric transformer covering the pipeline into an electrical signal proportional to the flow.

In this case, the measuring section of the pipeline is made of a polymeric material with high triboelectric ability and an internal variable cross-section, having the form of tapering and expanding cones in series, and supply it with metal grounding, thereby providing a high degree of polarization of the moving fluid.

In the method for determining the flow rate of a liquid in a pipeline, the flow rate of a liquid medium is measured by changing the magnetic field at any point along the perimeter of the measuring section of the pipeline associated with the electric charge of the liquid. In this case, the magnetic field is transformed using a current transformer covering the pipeline into an electrical signal proportional to the flow rate.

In the prototype method, the measuring section of the pipeline is made of a polymer material that has low wear resistance (abrasion resistance).

As a result of this, during friction of a moving fluid against the walls of the pipeline, mechanical wear of the measuring section of the pipeline occurs, a decrease in the degree of triboelectrification and a decrease in the charge of the flowing liquid, which reduces the sensitivity and accuracy of the measurement.

Known polarization flow meter (see the description to the AS of the USSR No. 1553831 A1, IPC G01F 1/56) is an analogue of the proposed device for measuring the flow rate of a liquid medium, carrying out the technical implementation of the proposed method.

The specified polarization flow meter consists of a dielectric housing, a cover, an input and output channels, a flow part, a working electrode, a measuring electrode, a working electrode, a measuring device and studs, the measuring device being connected between the measuring electrode and a common bus with a pin, the working electrode is connected to a common bus with a pin, and a working electrode with a pin connected to a power source.

The polarization flowmeter operates as follows.

The dielectric fluid enters the flowmeter through the inlet channel to the flow part. Two working electrodes supply a high voltage from a power source. An electric field is created in the liquid, under the action of the forces of which the dielectric of the liquid is polarized.

The density of the bound charges formed in the liquid is proportional to the voltage of the power source and the flow rate. Thus, the signal of the measuring device is proportional to the number of charges carried by the flow, and unambiguously corresponds at a constant voltage of the power supply to the flow of liquid.

In a polarizing flow meter, fluid flow is measured by changing the density of the bound charges that are formed in the fluid when it is polarized by an electric field.

To polarize a liquid, a high voltage power supply is required. As a result, a polarizing flowmeter cannot measure the flow of flammable liquids, such as gasoline, diesel, kerosene, which narrows the scope of a polarizing flowmeter. In this case, a decrease in the electrical safety of the polarization flow meter occurs.

The closest analogue is the prototype of the proposed device for measuring the flow rate of a liquid medium, which implements the technical implementation of the proposed method, is a liquid and gas flow meter (see description to AS USSR No. 1296845 A1, IPC G01F 1/56).

The liquid and gas flow meter comprises a housing with a channel made of a non-magnetic material, for example, fiberglass. An elastic plate of ferromagnetic material, the free end of which is provided with a permanent magnet, is cantilevered on the inner wall of the channel of the housing. An electromagnet is mounted on the body in the form of a pipeline section so that the elastic plate is in its magnetic field. An electromagnet coil is fed by a controlled sawtooth generator through a switching unit. The generator control circuit includes a power supply connected via a magnetically controlled contact to the trigger input.

A magnetically controlled contact is mounted on the body of the flowmeter in such a way that the axis passing through its contacts is parallel to the axis of the body. The magnetically controlled contact is protected from the action of the electromagnet field by a screen. The permanent magnet is located on the plate parallel to the axis of the magnetically controlled contact, and its north pole is directed to the entrance to the channel. The trigger input via a magnetically controlled contact is connected to the power supply. The trigger is used to form a rectangular voltage pulse and to eliminate unnecessary triggering of the control circuit during the "bounce" of the element contacts. The trigger output is connected to the input of the differentiating circuit, which shortens the trigger pulse. The output of the differentiating circuit is connected to the input of the waiting multivibrator, which serves to generate a pulse, normalized in amplitude and duration, necessary for stable control of the switching unit and the sawtooth voltage generator. The standby multivibrator is also connected to a frequency meter.

The flow meter of liquid and gas works as follows.

In the initial state, when there is no flow movement, the generator generates a sawtooth-varying voltage supplying the electromagnet coil. The current in the coil rises to a maximum value, and then abruptly changes to zero. Such a change in current is necessary in order for the plate with a permanent magnet to deviate smoothly from its original position to the element actuation zone and return to its original position under the action of its own elastic forces when the current in the coil changes to zero. Under the influence of an electromagnetic field, a plate with a permanent magnet moves towards the element, while the permanent magnet moves translationally perpendicular to the axis of the element and crosses only a single zone of the closed state of the element contacts. When the magnet reaches the response zone, the element contacts close, the voltage from the block is fed to the input of the trigger, which forms a rectangular pulse. Since during operation the waiting multivibrator is not disconnected from the start-up circuit, then to weaken the influence of the start-up circuit on its operation, the start-up pulses are shortened by the differentiating circuit. Next, the pulse enters the standby multivibrator connected to the frequency meter. The waiting multivibrator generates a rectangular pulse, the duration of which is sufficient for the plate to return to its original state. The pulse generated by the waiting multivibrator is supplied simultaneously to the input of a sawtooth voltage generator, a frequency meter and a switching unit. In this case, the switching unit is opened for a time equal to the pulse duration, as a result of which the electromagnet coil circuit is opened. A plate with a permanent magnet fixed to it under the action of elastic forces returns to its original state. The pulse affects the operation of the generator in such a way that the next increase in voltage at the generator output occurs after a time equal to the duration of the pulse of the waiting multivibrator.

In the presence of a flow of liquid or gas, a plate with a permanent magnet, due to an increase in the resistance of a moving medium, reaches a maximum deviation over a longer period of time. The operation of the element occurs at a later time compared to the initial one, since the response frequency of the magnetically controlled contact and, accordingly, the repetition rate of rectangular pulses generated by the trigger change. In this case, the pulse frequency of the waiting multivibrator changes, which controls the operation of the switching unit and the generator. The oscillation frequency of the generator output voltage changes and leads to a corresponding change in the frequency of the voltage in the coil.

Under the influence of the field of the electromagnet, the oscillation frequency of the plate changes. Thus, depending on the change in the flow rate of the liquid or gas, the oscillation frequency of the plate with the magnet changes.

The changed signal enters the generator control circuit and is displayed by a frequency flow meter.

In a liquid and gas flow meter, the measurement of the liquid or gas flow rate occurs due to a change in the oscillation frequency of an elastic plate with a magnet, which is displayed by a frequency flow meter.

With a large number of vibrations of an elastic plate with a magnet, the elastic properties of the plate change, which reduces the accuracy of measuring the flow of liquid or gas.

An elastic plate with a magnet is installed in the flowing part of the pipeline of the liquid and gas flow meter, which reduces the measurement accuracy and manufacturability.

Disclosure of invention

The objective of the invention is to develop a method for measuring the flow rate of a liquid medium, which expands the arsenal of technical means for measuring the flow rate of a liquid medium and increases the accuracy of measurement, as well as creating a device for measuring the flow rate of a liquid medium, which implements the technical implementation of the proposed method, which has higher measurement accuracy and manufacturability.

The problem is solved using the characteristics specified in the 1st paragraph of the claims common to the prototype method, such as a method for measuring the flow rate of a liquid medium, namely, that a liquid medium is placed, moved and polarized inside a pipeline of dielectric material, and distinctive essential features, such as - in the oscillatory circuit, which contains the inductance coil of the oscillatory circuit and the capacitor of the oscillatory circuit, excite the resonant oscillations of the electromagnetic field, moving t of the liquid medium in a magnetic field, they polarize the liquid medium under the action of the Lorentz force, as a result of which they change the electric field of the capacitor of the oscillatory circuit in the liquid medium, the dielectric constant of the liquid medium, as well as the duration of the first and second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit, and the liquid flow rate medium is measured by changing the duration of the first or second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit.

In paragraph 2 of the claims reflected the feature of the movement of the liquid medium in the pipeline, namely, they move the liquid medium in a constant magnetic field.

In paragraph 3 of the claims reflected the peculiarity of the pipeline, namely the pipeline is preferably made of ceramic material, which has high abrasion resistance.

In the proposed method, when moving a liquid medium in a constant magnetic field, a polarization of the liquid medium occurs under the action of the Lorentz force.

As a result, the electric field of the capacitor of the oscillatory circuit in the liquid medium, the dielectric constant of the liquid medium, and also the duration of the first and second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit are changed.

The flow rate of the liquid medium is measured by changing the duration of the first or second half-periods of the period of resonant vibrations of the electromagnetic field of the oscillatory circuit, which expands the arsenal of technical means for measuring the flow of the liquid medium.

The pipeline of the proposed method for measuring the flow rate of a liquid medium is preferably made of ceramic material, which has high abrasion resistance.

As a result, the mechanical deterioration of the pipeline when moving the liquid medium is reduced, which increases the measurement accuracy.

The problem is solved by using the characteristics specified in the 4th paragraph of the claims common to the prototype device, such as a device for measuring the flow rate of a liquid medium containing a liquid medium located in a pipeline, a magnet and an inductor, and distinctive essential features, such how the device contains an oscillatory circuit, which contains an inductor of the oscillatory circuit and a capacitor of the oscillatory circuit, while the liquid medium is placed in the pipeline between the pole pieces m agnit, as well as between the first and second plates of the capacitor of the oscillatory circuit.

In paragraph 5 of the claims reflected the feature of the placement of the liquid medium in the pipeline, namely the liquid medium is placed in the pipeline between the pole pieces of a permanent magnet.

In the flow part of the pipeline there are no elements that make up the proposed device for measuring the flow rate of a liquid medium, which increases the accuracy of measurement and manufacturability.

In the proposed device, the liquid medium is polarized under the action of the Lorentz force, which is induced in the liquid medium when moving the liquid medium in a constant magnetic field of a permanent magnet. As a result, a polarization of the liquid medium does not require a power source, which increases the manufacturability of manufacturing a device that implements the technical implementation of the proposed method.

The above set of essential features allows you to get the following technical result - the expansion of the arsenal of technical means for measuring the flow rate of a liquid medium, improving the accuracy of measurement and manufacturability.

The drawing shows a structural diagram of a device for measuring the flow rate of a liquid medium.

The implementation of the invention

The proposed device for measuring the flow rate of a liquid medium contains a liquid medium 2 located inside the pipe 1 of a dielectric material (see drawing), a permanent magnet 4, an oscillatory circuit and a measuring circuit 5.

The function of the liquid medium 2 can be performed by a dielectric liquid medium, for example gasoline, diesel fuel, kerosene, or a low conductive (or weakly conductive) liquid medium, for example tap water.

The pipe 1 is preferably made of ceramic material, which has a high abrasion resistance.

The pipe 1 has an internal cross section in the form of a circle. In the General case, the pipe 1 may have an internal cross section in the form of a rectangle.

The drawing shows the pole pieces (north N and south S poles) of a permanent magnet 4.

The oscillatory circuit contains an inductor 3 of the oscillatory circuit and a capacitor of the oscillatory circuit, and the liquid medium 2 is placed in the pipe 1 between the pole pieces of the permanent magnet 4, and also between the first 6 and second 7 plates of the capacitor of the oscillatory circuit.

In this case, the straight line passing through the centers of the first 6 and second 7 plates of the capacitor of the oscillatory circuit and the axis of the pipe 1 is perpendicular to the straight line passing through the centers of the pole pieces of the permanent magnet 4 and the axis of the pipe 1.

The first 6 and second 7 plates of the capacitor of the oscillatory circuit are located on the outer surface of the pipeline 1. In general, the first 6 and second 7 plates of the capacitor of the oscillatory circuit can be placed on the inner surface of the pipeline 1.

The first terminal of the inductance coil 3 of the oscillatory circuit is connected to the first 6 plate of the capacitor of the oscillatory circuit, and the second terminal of the inductance coil 3 of the oscillatory circuit is connected to the second 7 plate of the capacitor of the oscillatory circuit.

The measuring circuit 5 comprises an inductor 8 for pumping energy into the oscillatory circuit, an inductor 9 for reading the frequency of the resonant oscillations of the oscillatory circuit, an OR element 10, transistor 11, comparator 12, resistor 13, and a computing device (not shown).

The second input 14 of the element OR 10 is the input of the start of continuous undamped resonant vibrations of the electromagnetic field of the oscillatory circuit. The output of the OR element 10 is connected to the base of the transistor 11, the emitter of which is connected to the output "General" power.

The first and second conclusions of the inductor 8 of pumping energy into the oscillating circuit are connected respectively to the collector of the transistor 11 and the first output of the resistor 13, the second terminal of which is connected to the positive terminal 15 of the power source of the measuring circuit 5.

The first and second conclusions of the inductance coil 9 of reading the frequency of the resonant oscillations of the oscillatory circuit are connected respectively to the output “General” of the power supply and the direct input of the comparator 12, to the inverse input of which a reference voltage is supplied. The output of the comparator 12 is connected to the first input of the OR element 10 and the computing device.

The inductor 3 of the oscillatory circuit has a minimum intrinsic capacitance and maximum inductance, which increases the sensitivity of the device for measuring the flow rate of a liquid medium.

An inductor 8 for pumping energy into the oscillatory circuit and an inductor 9 for reading the frequency of the resonant oscillations of the oscillatory circuit is performed by winding an insulated wire over the inductor 3 of the oscillatory circuit.

In the drawing, the flow direction of the liquid medium 2 is indicated by an arrow.

A device for measuring the flow rate of a liquid medium, carrying out the technical implementation of the proposed method, works as follows.

Inside the pipe 1 of the dielectric material is placed a liquid medium 2.

After turning on the power to the second input 14 of the element OR 10 from a parallel channel of the measuring circuit 5 serves a single positive pulse. From the output of the OR element 10, a positive pulse arrives at the base of the transistor 11 and opens it.

At the moments of changes in the currents in the inductor 8 of pumping energy into the oscillating circuit induce EMF - electromotive forces of induction in the inductor 3 of the oscillating circuit and excite in the oscillating circuit resonant oscillations of the electromagnetic field.

The frequency of the resonant oscillations of the electromagnetic field of the oscillating circuit is removed from the inductor 9 of reading the frequency of the resonant oscillations of the oscillatory circuit and is fed to the input of the comparator 12. From the output of the comparator 12, positive rectangular signals are sent to the computing device of the measuring circuit 5 and to the first input of the OR element 10.

From the output of the OR element 10, rectangular pulses are fed to the base of the transistor 11, when opening it, currents flow through the inductor 8 of the pumping energy into the oscillating circuit, when they change, the induction EMF is induced in the inductor 3 of the oscillating circuit.

In this case, in the first (or positive) half-periods of the electromagnetic field oscillations of the oscillatory circuit, the energy is pumped into the oscillating circuit during an increase in the current in the inductor 8 of the energy pumped into the oscillatory circuit, and in the second (or negative) half-periods of the electromagnetic field oscillations of the oscillatory circuit, the energy is pumped during current reduction.

Since the transfer of energy to the oscillatory circuit occurs at the moments of changes in the currents in the inductor 8 of pumping energy into the oscillatory circuit (under the influence of EMF induction, currents are induced that are consistent with the direction of the currents in the oscillatory circuit). In this case, the amplitudes of the currents of the resonant vibrations of the electromagnetic field of the oscillatory circuit are increased and the frequency of the resonant oscillations of the electromagnetic field of the oscillatory circuit is determined.

Thus, in the oscillatory circuit, which contains the inductor 3 of the oscillatory circuit and the capacitor of the oscillatory circuit, resonant vibrations of the electromagnetic field are excited.

In the first half-period of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit, the electric field vector of the capacitor of the oscillatory circuit is directed from the first 6 to second 7 lining of the capacitor of the oscillatory circuit (from top to bottom).

In the second half-period of the period of resonant vibrations of the electromagnetic field of the oscillatory circuit, the electric field vector of the capacitor of the oscillatory circuit is directed from the second 7 to the first 6 lining of the capacitor of the oscillatory circuit.

The liquid medium 2 is moved in the constant magnetic field of the permanent magnet 4 and the liquid medium 2 is polarized under the action of the Lorentz force.

As a result, the electric field of the oscillator circuit capacitor (external electric field) in the liquid medium 2 is changed, the dielectric constant of the liquid medium 2, as well as the duration of the first and second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit, and the flow rate of the liquid medium 2 is measured by changing the duration of the first or the second half-period of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit.

During the first half-period of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit, the direction of the Lorentz force and the direction of the electric field vector of the capacitor of the oscillatory circuit coincide.

During the second half-period of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit, the direction of the Lorentz force is opposite to the direction of the electric field vector of the capacitor of the oscillatory circuit.

With an increase in the flow rate of the liquid medium 2, an increase in the Lorentz force in the liquid medium 2 occurs, and with a decrease in the flow rate of the liquid medium 2, a decrease in the Lorentz force in the liquid medium 2 occurs.

The polarization of the liquid medium 2 can occur due to the polarization of molecules, positively charged ions and negatively charged ions.

When the molecules of the liquid medium 2 are polarized, an excess of bound charges of the same sign appears in a thin surface layer of the liquid medium 2 and the surface density of the bound charges changes.

With the polarization of positively charged ions and negatively charged ions of a liquid medium 2, the positively charged ions and negatively charged ions of a liquid medium 2 move and separate in the direction and opposite to the direction of the Lorentz force in the liquid medium 2.

In this case, a change in the density of positively charged ions and negatively charged ions in a liquid medium 2.

With an increase in the flow rate of liquid medium 2 during the first half-period of the period of resonant oscillations of the electromagnetic field of the oscillating circuit, the electric field of the capacitor of the oscillating circuit decreases (weakenes) in the liquid medium 2, the dielectric constant of the liquid medium 2 increases and the duration of the first half-period of the period of resonant oscillations of the electromagnetic field of the electromagnetic circuit .

In this case, in the general case, the resulting (total) electric field of the bound charges of the molecules of the liquid medium 2, positively charged ions and negatively charged ions is directed opposite to the direction of the electric field vector of the capacitor of the oscillatory circuit in the liquid medium 2.

With a decrease in the flow rate of the liquid medium 2 during the first half-period of the period of resonant oscillations of the electromagnetic field of the oscillating circuit, an increase (amplification) of the electric field of the capacitor of the oscillatory circuit in the liquid medium 2 occurs, a decrease in the dielectric constant of the liquid medium 2 and the duration of the first half-period of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit .

With an increase in the flow rate of liquid medium 2 during the second half-period of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit, an increase (amplification) of the electric field of the capacitor of the oscillatory circuit in the liquid medium 2 occurs, a decrease in the dielectric constant of the liquid medium 2 and the duration of the second half period of the period of resonant oscillations of the electromagnetic field of the electromagnetic circuit of the oscillatory circuit .

With a decrease in the flow rate of liquid medium 2 during the second half-period of the period of resonant oscillations of the electromagnetic field of the oscillating circuit, the electric field of the capacitor of the oscillating circuit decreases (weakenes) in the liquid medium 2, the dielectric constant of the liquid medium 2 increases and the duration of the second half-period of the period of the resonant oscillations of the electromagnetic field of the electromagnetic circuit .

As a result of this, the durations of the first and second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillatory circuit will differ from each other.

Industrial applicability

The proposed method for measuring the flow rate of a liquid medium and a device for its implementation will find wide application in devices of measuring equipment, other special cases of automation of measuring the flow rate of a liquid medium 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.

Claims (5)

1. The method of measuring the flow rate of a liquid medium, which consists in the fact that a liquid medium is placed, moved and polarized inside a pipeline of dielectric material, characterized in that resonant oscillations of the electromagnetic field are excited in the oscillatory circuit, which contains the inductance coil of the oscillatory circuit and the oscillator circuit capacitor. , move the liquid medium in a magnetic field, polarize the liquid medium under the action of the Lorentz force, as a result of this change the electric field of the oscillator the temperature in the liquid medium, the dielectric constant of the liquid medium, as well as the duration of the first and second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillating circuit, and the flow rate of the liquid medium is measured by changing the duration of the first or second half-periods of the period of resonant oscillations of the electromagnetic field of the oscillating circuit. 2. The method according to p. 1, characterized in that they move the liquid medium in a constant magnetic field. 3. The method according to p. 1, characterized in that the pipeline is preferably made of ceramic material, which has high abrasion resistance. 4. A device for measuring the flow rate of a liquid medium containing a liquid medium located in the pipeline, a magnet and an inductor, characterized in that the device comprises an oscillating circuit, which contains an inductance coil of the oscillating circuit and a capacitor of the oscillating circuit, while the liquid medium is placed in the pipeline between pole tips of the magnet, as well as between the first and second plates of the capacitor of the oscillatory circuit. 5. The device according to p. 4, characterized in that the liquid medium is placed in the pipeline between the pole pieces of a permanent magnet.