RU2310816C2 - Vortex electromagnetic converter of liquid metal flow rate - Google Patents

Abstract

FIELD: measuring technique.

SUBSTANCE: converter comprises pipe section with nonmagnetic conducting wall and rod that generates vortex in the flow and whose axis is perpendicular to the axis of the pipe. The magnet mounted outside of the pipe generates magnetic field downstream of the rod. The component of the magnetic induction of the magnetic field is parallel to the axis of the rod. The electrodes of the sensor of the converter is welded to the surface of the pipe. According to the second version, two indicating electrodes are mounted in the cross-sections of the pipe that are located at a given distance one from the other.

EFFECT: enhanced precision.

1 cl, 1 dwg

Description

The invention relates to measuring technique, mainly to means for controlling the flow of liquid metals, and can be used, for example, to measure the flow rate and amount of liquid metal coolants in nuclear power plants.

Known vortex electromagnetic flowmeter-liquid meter (RF Patent No. 2085854 C1, G01F 1/32, 07/27/1997), which in the corresponding embodiment can be used for liquid metal. The principle of operation of the device is based on the interaction of the Karman vortex track with a longitudinal magnetic field directed parallel to the axis of the pipeline. The device comprises a pipeline of non-magnetic material with a flow body, the axis of which is perpendicular to the axis of the pipeline, a magnetic system, a sensing element in the form of two electrodes, at least one of which is placed in the field of application of the magnetic field, and a signal processing unit. The magnetic system of the device is made in the form of a bipolar C-shaped magnet, the poles of which are placed sequentially along the line of intersection of the outer surface of the pipe with the plane of the longitudinal axes of the pipeline and the flow body. The electrodes of the device are installed on the surface of the pipe between the poles of the magnet on a generatrix parallel to the axis of the pipeline.

The disadvantage of the device with real magnetic and weight-dimensional parameters of the C-shaped magnet is the insufficient concentration of magnetic induction in the controlled flow zone, due to the high degree of dispersion of the magnetic field in space. In this case, with a decrease in the flow rate, the sensitivity of the device decreases, which significantly limits the range of its operability in terms of fluid flow.

A known vortex electromagnetic flow transducer for electrically conductive liquids, the principle of which is based on the interaction of the Karman vortex path with a transverse magnetic field directed perpendicular to the axis of the pipeline (RF Patent No. 1838789, class 5G01P 5/08, G01F 1/32, 1992). The device comprises a pipe section with a non-magnetic electrically conductive wall, a flow around body in the form of a vortex-forming rod, the longitudinal axis of which is perpendicular to the pipe axis, a magnet placed outside the pipe, creating a transverse magnetic field inside the pipe behind the flow body, parallel to the longitudinal axis of the flow body, and a sensing element in the form two indicator electrodes electrically insulated from the pipe wall mounted on the inner surface of the pipe in series along one pipe generatrix, while -plane in which lie said generatrix and the axis of the tube, perpendicular to the magnetic field vector, and used to connect the measuring circuit of the third electrode electrically connected to the pipeline, performing the role of the ground or common point.

With an appropriate embodiment of indicator electrodes (see, for example, N.I. Loginov. Electromagnetic flow converters for liquid metals, M .: Energoizdat, 1981, pp. 23-24), the device can be used for liquid metal flows. If the contact resistance is insignificant at the interface between the liquid metal and the pipe wall, for example, in a steel pipe with a sodium coolant, the indicator electrodes can be made electrocontact with the pipe wall, including in the form of rods welded to the outer surface of the pipe (N.I. Loginov Electromagnetic flow rate converters of liquid metals, M .: Energoizdat, 1981, pp. 11-18).

The disadvantage of the described device is its low sensitivity, which is due to the non-optimal placement of the electrodes in the transducer, namely their placement in the region of the minimum values of the ripple amplitude of the induced electric potential.

The aim of the invention is to increase the sensitivity without increasing the magnetic and weight-dimensional characteristics of the magnetic system and without complicating the design of the sensitive element of the transducer.

This goal is achieved by the fact that in a vortex electromagnetic liquid metal flow transducer containing a pipe section with a non-magnetic electrically conductive wall, the flow body in the form of a vortex-forming rod, the longitudinal axis of which is perpendicular to the pipe axis, a magnet placed outside the pipe, creating a magnetic field inside the pipe behind the flow body, having a component of the magnetic induction vector directed parallel to the longitudinal axis of the flow body, and a sensing element in the form of welded e electrodes, at least one of which is indicator. In this case, the indicator electrode is installed under one of the poles of the magnet on the generatrix of the pipe having an intersection with the longitudinal axis of the flow body, or close to the specified generatrix within the tolerance band. The converter may contain two indicator electrodes installed in pipe sections spaced from each other at a distance L = 0.5D, where D is the inner diameter of the pipe.

It has been experimentally established that for a given mutual arrangement of the flow around the body and the magnetic system, the geometrical location of the points on the pipe wall, at which the amplitude of the electric potential oscillations induced by the Karman vortex path, has a maximum value, is a pipe generatrix that intersects with the longitudinal axis of the flow around the body. Accordingly, indicator electrodes in the converter should be installed on such a generatrix, or close to it at a distance of no more than δ = 0.15D, where D is the internal diameter of the pipeline.

The maximum amplitude of the output signal has a converter with two indicator electrodes mounted in series along the specified generatrix pipe at a distance from each other equal to half the geometric period of the Karman vortex track. Approximately it is equal to half the inner diameter of the pipe. With this interelectrode distance, the potentials at the points of electrode installation pulsate in antiphase, and the amplitude of the difference signal has a maximum value. As the interelectrode distance decreases or increases as a result of the out-of-phase pulsations, the amplitude of the difference signal decreases.

Other things being equal, the amplitude of the output signal in the inventive device is an order of magnitude higher compared with the prototype device (RF Patent No. 1838789, CL 5G01P 5/08, G01F 1/32, 1992).

The drawing shows a schematic diagram of the inventive device.

A vortex electromagnetic liquid metal flow transducer comprises a pipe section with a non-magnetic electrically conductive wall 1, a flow body 2 in the form of a vortex-forming rod, the longitudinal axis 3 of which is perpendicular to the pipe axis, a magnet with poles 4 placed outside the pipe, creating a magnetic field inside the pipe behind the flow body, having a component magnetic induction vector 5, parallel to the longitudinal axis 3 of the body flow. The sensitive element of the transducer in this example is the electrodes 6, 7, 8. welded to the pipe wall. The electrodes are mounted in series along the generatrix of the pipe 9, which intersects with the longitudinal axis 3 of the flow body. The electrodes 6, 7 are indicator, placed on the wall of the pipe under one of the poles of the magnet. The electrode 8 acts as a ground or "common point". Indicator electrodes 6, 7 are installed at a distance L = 0.5D from each other, where D is the inner diameter of the pipe.

The converter is operable with the following options for connecting the electrodes to the measuring device: one indicator electrode 6 (or 7) paired with electrode 8; two indicator electrodes 6 and 7 paired with each other; two indicator electrodes 6 and 7 in conjunction with electrode 8 using a differential ripple detection circuit.

The converter operates as follows. Periodic disruption of the Karman vortices from one and the other side of the flow around the body 2 causes synchronous fluid oscillations on the pipe diameter line parallel to the longitudinal axis 3 of the flow body and in the region of the annular space adjacent to the diameter. These vibrations are directed perpendicular to the plane in which the axis of the pipe and the body flow around. A magnetic field with a component of the induction vector 5, directed parallel to the axis of the body of the flow around 3 and perpendicular to the direction of the indicated transverse vibrations of the liquid, induces synchronous alternating oscillations of the electric potential both on the diameter line parallel to the axis 3 of the body and around the electrically conductive wall ends of the specified diameter. Moreover, the amplitude of the pulsations at the end points of the diameter is maximum in comparison with other points of the circumference of the pipe section. Thus, the indicator electrode 6 (or 7) installed at the end point paired with the electrode 8 (“common point”) provides the highest amplitude of the output signal in the circuit with one indicator electrode.

The maximum amplitude of the converter output signal is achieved in circuits with two indicator electrodes 6 and 7 mounted along the generatrix pipe 9 at a distance L = 0.5D from each other, close in value to half the geometric period of the Karman vortex track. In this case, the potentials at the points of installation of the electrodes 6 and 7 pulsate almost in antiphase.

The output signal of the converter from the corresponding electrodes is supplied to the measuring device, where the flow rate and flow rate are determined from the measured value of the ripple frequency, and the amount of leaked fluid is determined from the total number of oscillation periods for a fixed period of time.

For experimental verification of operability, a prototype device with a nominal diameter Dy38 (pipe 44 × 3 made of stainless steel 12X18H10T) was manufactured. The magnetic system of the transducer with poles covering the pipe creates a magnetic field directed parallel to the vortex-forming rod. The value of magnetic induction in the center of the pole gap is B = 0.088T.

On the surface of the pipe under one of the poles of the magnet on one generatrix of the pipe, which intersects with the longitudinal axis of the vortex-forming rod, two electrodes are welded at a distance of 19 mm from each other, as well as a third electrode outside the magnetic field.

The device was mounted in the circuit of the sodium flow stand and tested. The electrodes of the device were connected to the input of the U71 amplifier according to the above schemes. From the output of the amplifier, the signal was applied to the frequency meter Ch3-54 and in parallel to the oscilloscope.

As a result of tests in the range of sodium flow rate Q = (0.25-20) m ³ / h, a high-quality output periodic signal was observed for all of the above electrode connection schemes. In particular, at a flow rate of Q = 20 m ³ / h (T _Na = 300 ° C) for single-electrode circuits (pairs 6–8 and 7–8, Fig. 1), a signal with a frequency of f = 120 Hz and amplitude A = ± 2.5 mV. For circuits with two indicator electrodes, the amplitude of the differential output signal is approximately 1.6 times higher, A = ± 4 mV. At the same time, the amplitudes of the output signals from the electrodes welded on the surface of the pipe according to the scheme of the prototype device were measured. The corresponding values were A = ± 0.3 mV for single-electrode and A = ± 0.45 mV for two-electrode converters, that is, 8-9 times less compared with the claimed device.

The high amplitude of the output signal in the inventive device provides high sensitivity and good noise immunity of the Converter, which greatly simplifies the development of secondary equipment.

Claims (2)

1. A vortex electromagnetic liquid metal flow transducer comprising a pipe section with a non-magnetic electrically conductive wall, a flow body in the form of a vortex-forming rod, the longitudinal axis of which is perpendicular to the pipe axis, a magnet placed outside the pipe, creating a magnetic field inside the pipe behind the flow body, which has a magnetic induction vector component directed parallel to the longitudinal axis of the flow body and the sensing element in the form of electrodes welded to the surface of the pipe, at least one of which rykh is indicator, and the indicator electrode is installed under one of the poles of the magnet on the generatrix of the pipe, which intersects with the longitudinal axis of the body around the flow, or close to the specified generatrix within the tolerance band. 2. The vortex electromagnetic transducer according to claim 1, characterized in that it contains two indicator electrodes mounted in pipe sections spaced apart by a distance L = 0.5D, where D is the inner diameter of the pipe.