RU2416072C1 - Turbine-inductive flow metre - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: flow metre consists of case (1) with calibrated channel, wherein there is installed turbine (8) and inductive sensor in form of coil of inductivity (12) with core (11). A direct magnet is secured on the core. Coil (12) envelopes part of core (11) projecting above the case; the core is built-in to a wall of the case and comes through with a minimal diametre gap to periphery of screw lugs (10) of the turbine. Depending on medium the core can be covered with anti-corrosion coating. The case of the flow metre is made out of material with essentially lower magnetic permeability, than materials of the core and screw lugs (10), while diametre of the core is manifold less, than thickness of the case (1) and less, than a pitch between similar coils of the turbine. The inductivity coil is electrically tied with a pulse counter through amplifier-signal shaper (16).

EFFECT: upgraded accuracy and reliability of measurement.

4 cl, 1 dwg

Description

The invention relates to measuring equipment, in particular to devices for measuring the flow (quantity) of moving liquids and gases (working bodies), driven by the flow of these bodies, and more particularly in high-pressure lines (over 50 MPa).

A known flowmeter comprising a housing with inlet and outlet nozzles, a turbine with blades, a glass fixed rigidly in the housing, in which a sensor with a magnetic core and an inductive coil, filled with polymer compound, is placed. A membrane is fixed in the bottom of the glass in the form of an intermediate partition separating the sensor from the working medium (medium).

When the turbine rotates with the movement of the working fluid (liquid or gas), each blade induces an EMF in the coil, that is, each blade gives an impulse. The frequency of change in the emf will correspond to the frequency of rotation of the turbine, the coil is connected to the flow meter of the flowing working fluid (see the passport of the flow meter in Livny, Oryol Oblast, Livnensky Zd liquid meters).

In accordance with the passport data, this flowmeter is guaranteed to work in the measured line under a pressure of not more than 6 MPa. With greater pressure, the glass squeezes out, and with an increase in the thickness of the walls of the glass and, consequently, the separation membrane, the magnetic flux perceived by the core and the depth of signal modulation decrease, which distorts the measurement accuracy.

Another flow meter is known, comprising an inductive sensor, which is installed in a through hole made in the body of the flow meter, so that a partition remains between the working medium and the sensor, which protects the sensor from the effects of the working fluid. Moreover, this hole is located opposite the turbine blade, which in turn is located in a thin-walled sleeve that creates a calibrated gap between the blades and the inner wall of the casing.

An inductive sensor with a core of a special design is mounted in the formed opening of the housing, which at the point of contact with the partition has the shape of a cone with its base facing the turbine blades.

The disadvantage of this design is that the base of the cone of the core is located at a considerable distance from the turbine blades, consisting of the gap between the base of the cone and the partition of the body, the thickness of the partition, the gap between the partition and the sleeve of the turbine, the thickness of the sleeve and the diametrical clearance between the turbine blades and the sleeve.

All of the gaps and obstacles listed above weaken the signal, therefore, its powerful amplification is necessary, in turn, increasing the pressure of the working medium requires increasing the strength of the partition due to the increase in its thickness, and this requires even more signal amplification. Ultimately, when operating at pressures of more than 40 MPa, an increase in the thickness of the partition leads to an uncontrolled decrease in the noise immunity of the device as a whole, since any objects in the vicinity of ferromagnetic materials begin to influence it.

This circumstance limits the pressure in the measured working medium to 40 MPa. Manual for technical operation of TPR7-TPR20, pages 8 and 9, Fig. 2 and 3, Arzamas instrument-making plant.

The listed disadvantages are inherent in the roller-blade flowmeter. Its internal volume is limited by the end caps of the housing, and inside its volume there is a diametrical jumper forming a working chamber with a turbine and an additional chamber isolated from the working chamber with a sensing element in the form of an impeller. During rotation, the impeller interrupts the pulse-magnetic flux of the sensing element, in the form of a rotor speed sensor. The separation wall thickness is up to 1 mm, plus the clearance from the wall to the impeller blades is 1.5 mm. The sensor is mounted in the end of the cover. Thus, the body of the flowmeter is strengthened, but the sensitivity of the sensor and, of course, the accuracy of its measurement are reduced (RF patent No. 2224985, G01F 3/06, G01F 3/08, 11/16/2000).

The closest technical solution for the combination of features and functional purpose is a flow meter containing a housing with a calibrated channel and holes for supplying and discharging a working fluid (liquid or gas), in which a turbine with rims is placed. A parasitic chamber is made in the housing, communicating with the calibrated channel through two holes made in the bottom of the chamber.

A glass (bowl) is installed in the chamber, in which a sensor is installed in the form of an inductive coil with a core of magnetic material and a magnetic plate swinging on the axis is mounted in the form of a rocker, the ends of which are opposite the said holes. The core is in contact with the working fluid. The coil is electrically connected to a pulse counter (RF patent No. 2029243, G01F 3/10, 1990). Known flowmeter, adopted for the prototype, has "disadvantages in the form of:

- the complexity of the design, due to the additional parasitic chamber and the swinging magnetic plate in the form of a rocker arm, a complex turbine with oppositely located samples;

- a parasitic chamber and alternately opening and closing holes create the effect of flowing around a part of the flow not on the screw surface of the turbine and also creates turbulence in the fluid, leading to uncontrolled error, which negatively affects the measurement accuracy;

- the use of magnetic materials for the core and rocker leads to their magnetic sticking, and for their opening requires additional force, which can be obtained only by increasing the centrifugal forces created by the turbine, this will require an increase in the volume of flow, that is, measuring small flows becomes impossible;

- at high speeds of the turbine, the rocker-core system may not operate as a mechanical system with the effect of mechanical inertia, or a hydraulic system with the effect of hydraulic inertia in the parasitic chamber.

On the whole, this system can be considered as a hydromechanical oscillatory circuit, and with pulsating loads, negative resonance phenomena can occur.

It can be seen from the description that the transverse base of the cross section of the glass (bowl) corresponds to the length of the turbine, and its area is many times greater than the core area, which excludes the possibility of using this design of the flowmeter in measuring systems with high pressure of the working fluid.

The basis of the present invention is the task of creating a flow meter for measuring the flow rate of a liquid or gas (working fluid) moving with high pressure, above 50 MPa, in the main pipelines, increasing its reliability and measuring accuracy by reducing the intermediate links in the core-coil magnetic circuit .

The task is achieved by the fact that the flowmeter uses a turbine-inductive principle of operation. Structurally, this is a turbine-inductive flowmeter containing a housing with a calibrated channel and openings for supplying and discharging a working fluid, a turbine located in it, an inductive sensor including a core, an inductor and a pulse counter.

The novelty is that the core is mounted directly through the casing wall through, with a minimum diametrical clearance to the periphery of the turbine screw protrusions, taking into account thermal viscosity characteristics and the degree of filtration of the working fluid. The inductive coil is located outside the housing, covering the core part protruding above the housing and is equipped with a signal conditioning amplifier interconnected with the inductive coil and the pulse counter, while the flowmeter housing and the core are made of materials significantly different from each other by magnetic permeability, and the core diameter is taken many times less than the thickness of the body of the flow meter and less than the step between the same turns.

Another difference is that the core is mounted in the wall of the housing with the possibility of its adjusting movement, for example, by means of a threaded connection, and the turbine has a multi-start screw profile.

According to the invention, the core may have corrosion protection.

The design is illustrated in the drawing of the flow meter in the context.

The flow meter comprises a housing 1 with a calibrated channel 2 and flow dividers 3 and 4, openings for exhaust 5 and supply 6 of the working fluid. Inside the housing 1, in the dividers 3 and 4 on the bearings 7, a turbine 8 is mounted, formed by a drum 9 and screw projections 10 on it. The turbine may also be lobed.

A core 11 is mounted through the wall of the housing, which can have various options for connecting to the housing: welding, soldering, press-fitting, thread with the possibility of adjustment, for example, using micrometric threads, as shown in the drawing.

The core 11 with the coil 12 forms an inductive sensor. Above the coil 12, a permanent magnet 13 can be mounted rigidly connected to the core 11 to increase sensitivity by magnetizing the latter. A permanent magnet creates a more powerful permanent magnetic field, which in turn increases the depth of modulation of the received signal when the helical protrusions of the same named turns of the turbine pass by the core.

Instead of a magnet, magnetization of the coil with direct current can be used, or an additional coil can be used.

The end part 14 of the core 11, immersed in the working fluid 2, may have a different configuration: conical, as shown in the drawing, with a flat end or end in shape adequate to the screw protrusion 10 of the turbine 8. The diameter of the core is taken many times less than the thickness of the flowmeter body and less than a step between the tops of the same-name screw protrusions of the same name turns.

The core 11, depending on the thermal-viscosity characteristics and the degree of filtration of the liquid (working fluid), is installed with a minimum diametrical gap 15 to the periphery of the protrusions 10.

The coil 12 is connected through a signal conditioning amplifier 16 to a pulse counter 17. The core 11 may have an anti-corrosion coating depending on the medium with which it is mated.

The materials of the housing 1 should have significantly lower magnetic permeability than the materials of the core 11 and screw projections 10 of the turbine 8. The core 11 is made of soft magnetic materials.

As a sensor, a standardized magneto-induction generator can be used, which is an oscillating circuit with a given frequency, which changes sharply when passing protrusions in the immediate vicinity of the core or other sources whose functional purpose is aimed at increasing noise immunity.

The diameter of the core is taken many times less than the wall thickness of the flowmeter body and less than the step between the vertices of the screw protrusions of the same name, this is due to the fact that with an increase in the cross-sectional area of the core, its conductivity decreases and the smaller the indicated area, the lower the eddy currents in it.

The flow meter operates as follows.

The flow of liquid or gas, passing through a calibrated channel 2, rotates the turbine 8, and the vertices of the screw protrusions of the same turns, passing at the required distance from the base of the core 11 will cause a modulation of the magnetic flux in it. According to the law of electromagnetic induction, a variable EMF will be induced in the core coil, with a frequency corresponding to the frequency of passage of the screw protrusions. This frequency in the form of pulses will be recorded through an amplifier-driver of signals on the pulse counter, which are converted into the amount of flowing working fluid.

Since the quality of recording an alternating emf signal weakly depends on the length of the core, and the core itself has a small diameter and the wall thickness of the casing slightly weakens the magnetic flux, there is practically no restriction on the wall thickness of the casing of the flowmeter, in contrast to the wall thickness in known designs, which allows measuring the amount of flowing working medium per unit time in pipelines with ultrahigh pressure above 50 MPa. In the case of measuring the flow rate of an aggressive medium, any anti-corrosion coating can be applied to the core without deterioration of the quality of the recorded signal.

Simplification of the design of the inductive sensor and the introduction of a small-diameter core allows, by reducing the contact area of the sensor with the working medium, significantly reducing the pressure force of the latter on it. This increases not only the strength of the sensor and the housing, but, using more technological installation methods (welding, soldering, threaded connection, press-in) increases the reliability of the connection of the core with the housing. The design of the flow measurement device itself is greatly simplified and its operational capabilities expanded. The flow meter is manufactured and tested in the line under a pressure of 80 MPa.

Claims (4)

1. A turbine-inductive flow meter comprising a housing with a calibrated channel and openings for supplying and discharging a working fluid, a turbine and an inductive sensor located therein, including a core with an inductor and a pulse counter, characterized in that the core is mounted directly through the housing wall, with a minimum diametrical clearance to the periphery of the screw protrusions of the turbine, taking into account the thermal viscosity characteristics and the degree of filtration of the working fluid, the inductive coil is placed outside the housing, covering the protrusion part of the core above the housing, and is equipped with a signal conditioning amplifier interconnected with an inductive coil and a pulse counter, while the flowmeter housing and the core are made of materials significantly different from each other by magnetic permeability, and the core diameter is taken many times smaller than the thickness of the flowmeter housing and less step between the same turns of the turbine. 2. The turbine-inductive flowmeter according to claim 1, characterized in that the core is mounted through the housing wall through with the possibility of its adjusting movement, for example, by means of a threaded connection. 3. The turbine-inductive flow meter according to claim 1, characterized in that the core has anti-corrosion protection. 4. The turbine-inductive flow meter according to claim 1, characterized in that the turbine has a multi-helical profile, and the step is determined by the distance between the vertices of the screw protrusions of the same named turns of the turbine.