RU137365U1 - ELECTROMAGNETIC FLOW METER - Google Patents

Abstract

An electromagnetic flowmeter containing a pipe section placed in the housing made of non-magnetic material, coated inside with a layer of non-conductive insulation, in which a measuring channel is formed with a rectangular section located between two magnetic field excitation coils with cores, on the walls of a rectangular section parallel to the magnetic direction fields, electrodes are installed, inside the pipe on both sides of the rectangular section of the measuring channel are placed concentrators magnetic field, characterized in that the electrodes have a circular shape, and their diameter is equal to the height of the wall along the direction of the magnetic field, and each magnetic field concentrator is a single part with a corresponding core of the magnetic field excitation coil.

Description

The utility model relates to the field of instrumentation, in particular, to heat and flow metering and allows measuring the flow rates of electrically conductive liquid and coolant in pressure pipelines.

A known electromagnetic flowmeter comprising a housing, a terminal box, a measuring pipe with flanges at its ends, on the outer surface of which is a magnetic system consisting of two magnetic field excitation coils with magnetic cores, two counter-holes are made in diameter in the cross section of the measuring pipe in diameter, of which two electrodes are installed, while the electric wires from the excitation coils and electrodes are brought out into the terminal box; the measuring tube is made of two layers, the outer and inner, the outer layer is made of non-magnetic material, and the inner layer is of a chemically resistant non-conductive polymer material, the length of the inner layer exceeds the length of the outer layer, while the ends of the inner layer are flared and pressed to the flanges by means of pressure rings , RU 107859 U1.

The disadvantage of this flow meter is the dependence of its readings on the flow regime of the liquid in the measuring tube, and therefore it is necessary to use additional elements to stabilize the flow regime after flow perturbators - curved sections, in particular, a straight section of the pipeline must be in front of the flow meter.

Known electromagnetic flowmeter containing placed in the body of the pipeline section made of non-magnetic material, coated inside with a layer of non-conductive insulation, in which a measuring channel is formed with a rectangular section located between the poles of an electromagnet closed by a magnetic circuit, and on the walls of a rectangular section parallel to the magnetic direction fields, electrodes are installed in the form of rectangular plates, and their height coincides with the height of this wall along the direction I magnetic field, inside the pipe on both sides of the rectangular section of the measuring channel placed magnetic field concentrators, each of which is connected to the corresponding core, and their width overlaps the width of the electrodes over which they are placed, RU 124792 U1.

This technical solution, adopted as a prototype of this utility model, ensures that the flowmeter readings are independent of the fluid flow in the measuring tube and improves the measurement accuracy.

However, the disadvantage of this flow meter is its low manufacturability, due to the complexity of the assembly of the device, as well as the low-tech manufacturing of some parts. In addition, there is a non-magnetic gap between the core and the concentrator of the magnetic field - the pipe wall, which reduces the induction of the magnetic field, and therefore reduces the sensitivity of the sensor.

The objective of this utility model is to increase the manufacturability of the device, improve the sensitivity of the sensor of the flow meter, as well as the reliability of the device as a whole.

According to a utility model, an electromagnetic flowmeter comprises a pipe section placed in the housing made of non-magnetic material, coated inside with a layer of non-conductive insulation, in which a measuring channel is formed with a rectangular section located between two magnetic field excitation coils with cores 6, on the walls of a rectangular section parallel to the direction of the magnetic field, electrodes are installed inside the pipe on both sides of the rectangular section of the measuring channel mescheny magnetic field concentrator, the electrodes have a circular shape, their diameter being equal to the wall along the height direction of the magnetic field, and each magnetic field concentrator is a single piece with the respective core of the excitation coil the magnetic field.

The applicant has not identified any technical solutions identical to the claimed one, which allows us to conclude that the utility model meets the criterion of “Novelty”.

The essence of the utility model is illustrated by drawings, which depict:

figure 1 is a longitudinal section of a device;

figure 2 is a section aa in figure 1.

The electromagnetic flow meter contains placed in the housing 1 a section of the pipeline 2, made of non-magnetic material. A section of the pipeline 2 is coated inside with a layer of non-conductive insulation 3, in which a measuring channel 4 is formed with a rectangular section. Outside of the rectangular section of the magnetic field excitation coil 5 with cores 6. On the walls of the rectangular section 4 parallel to the direction of the magnetic field, round electrodes 7 are installed with a diameter equal to the height of the wall along the direction of the magnetic field. Inside the pipe, on both sides of the rectangular section of the measuring channel, magnetic field concentrators 8 are placed, each of which is a single part with a corresponding core 6 of the magnetic field excitation coil 5.

For the manufacture of round electrodes, additional operations on a milling machine are not required, which increases the manufacturability of their manufacture, and, accordingly, affects the cost of the part.

The electrodes 7 are installed in non-conductive insulation 3 at the stage of forming channel 4, which leads to improved manufacturability by eliminating the operation of installing the electrode in the finished channel and increasing the reliability of the electrode assembly, since there are no leaks.

Hubs 8 of the magnetic field are a single part with the corresponding cores 6 of the coils 5 of excitation of the magnetic field, which also increases the manufacturability of the device by reducing the number of parts. In addition, the processing of the pipeline for the installation of magnetic field concentrators 8 is simplified - the installation occurs by pressing them into the holes in the pipe 2, thereby eliminating the non-magnetic gap, which reduces the magnetic field induction and can lead to a decrease in the sensitivity of the device.

Thus, as a result of the implementation of the features of this utility model, a technical result is achieved consisting in increasing the manufacturability of the device, improving the sensitivity of the sensor of the flow meter, as well as the reliability of the device as a whole.

Claims (1)

An electromagnetic flow meter containing a pipe section placed in the housing made of non-magnetic material, coated inside with a layer of non-conductive insulation, in which a measuring channel is formed with a rectangular section located between two magnetic field excitation coils with cores, on the walls of a rectangular section parallel to the magnetic direction fields, electrodes are installed, inside the pipe on both sides of the rectangular section of the measuring channel are placed concentrators magnetic field, characterized in that the electrodes have a circular shape, and their diameter is equal to the height of the wall along the direction of the magnetic field, and each magnetic field concentrator is a single part with a corresponding core of the magnetic field excitation coil.

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