SU815505A1 - Device for measuring current-conductive liquid consumption - Google Patents

Description

The invention relates to measuring the flow rate of electrically conductive liquids.

Devices are known for measuring the flow rate of electrically conductive liquids with a constant magnetic field of excitation, based on the effect of distortion of the initial field of excitation by the flow of the measured liquid. The degree of distortion is measured by two magnetosensitive elements (Hall sensors, magnetosensitive resistances) located at the edges of one of the pole pieces, in the gap of which a pipe section is located. Magnetosensitive elements are included in adjacent shoulders of a balanced four-armed bridge [1].

A disadvantage of the known devices is the low accuracy of measuring the flow rate when the temperature of the surrounding and controlling environment changes, since magnetically sensitive elements, operating at different values of the magnetic flux, have different temperature coefficients. In addition, the known devices have low sensitivity to low flow rates.

The purpose of the invention is to increase the sensitivity and increase the accuracy of flow measurement.

_ This goal is achieved by the fact that “ ^a device for measuring the flow rate of electrically conductive liquids with a constant magnetic field of excitation, based on measuring the degree of use of _{1P of the} main magnetic field” “by the flow of a controlled fluid, containing a pipe section located between two pole tips of the magnetic system, two magnetically sensitive elements located at the edges of one of the pole pieces and included in two adjacent arms of a balanced four shoulders, bridge, bridge power supply, s unbalance the bridge and the control pri20 boron is additionally provided with a second pair of magnetosensitive elements arranged at the edges of the second pole piece is symmetric relative to the first pair of pipe section and included in the other two of adjacent arm of the balanced bridge chetyrehplechego.

The magnetosensitive elements are made of semiconductor material with the same magnetosensitivity, the magnetosensitive elements of each pair have opposite magnetosensitivity, and magnetosensitive elements with the same sensitivity are located in the same magnetic field distortion. .

On fiG. 1 shows the layout of magnetically sensitive elements (magnetodiodes) at the edges of the pole tips of an electromagnet; in FIG. 2 - schematic diagram of the inclusion of magnetodiodes'.

The device is made in the form of a section of pipe 1, located between the pole pieces 2 and 3, where at the edges of one of the pole pieces there is a first pair of magnetodiodes 4 and 5 ^ and at the edges of the other a second pair of magnetodiodes 6 and 7, similar to the first, symmetrically to the pipe section. Magnetodiodes are arranged so that in the absence of movement of the controlled fluid they are pierced by a magnetic field of the same inductance, and when the fluid moves, the field at their locations changes to the greatest extent.

Magnetodiodes are included in the arms of the four-arm bridge in such a way that the pairs of magnetodiodes 4,5 and 6, 7 are located in adjacent shoulders, a power supply unit 8 is connected to one of the diagonals of the bridge, and an amplifier 9 and a recording device 10 are connected to the second diagonal.

The device operates as follows.

In the absence of a magnetic field (the electromagnet is turned off), the magnitudes of the resistance of the magnetodiodes are equal to each other (P ^ = P ₅ = P ₄ »P ₇ ), and in the presence of a magnetic field (the electromagnet is turned on) and the absence of fluid in the pipeline, the values of the resistance of the magnetodiodes change to + P, where the signs + depend on the voltage of the magnetic field, i.e. from the location of the magnetodiodes with respect to the opposite pole tips. Then the new resistance values of the magnetodiodes are pairwise equal to each other (P4 = Pj, and P ₄ = P ₇ ), and although the resistance values of one pair are not equal to the resistance values of the other pair (fyirPs) A (P ₄ = P _t ), in both cases the bridge , which consists of four identical magnetodiodes, is balanced.

In the presence of a fluid flow in the pipeline, the resistance of the magnetodiodes changes depending on the flow rate of the controlled fluid and the ambient temperature or fluid flow, the bridge will be unbalanced.

Since, in the presence of fluid flow, the magnetodiodes 4 and 6 included in the upper arms of the bridge are in identical magnetic conditions, and the magnetodiodes 5 and 7 included in the lower arms of the bridge are in other identical magnetic conditions, their temperature coefficients accordingly, their sensitivity to temperature changes is the same, and therefore equal. Therefore, the error from the influence of the temperature of the environment or the flow of conductive fluid is compensated.

Thus, the change in the resistance of the magnetodiodes depends only on the flow rate of the controlled fluid. In the magnetodiodes of the first pair, the resistance of one magnetodiode increases, in the second pair it decreases, on the contrary, which leads to an inequality of the resistance values (¾ of the magnetodiodes with a corresponding increase in sensitivity. The signal in the form of the unbalance voltage from the bridge output, determined by the change in the magnetodiode resistance, depends on fluid flow rate, amplified by an amplifier 9, is fed to a recording device 10.

Claims (1)

1. USSR author's certificate 172073, cl. G 01 F 1/56, 1963. Yu