RU43362U1 - ELECTROMAGNETIC FLOW SENSOR - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used as an electromagnetic flow sensor designed to measure the flow rate of electrically conductive fluid in pipelines. The purpose of this solution is to improve the electromagnetic flow sensor so that the formation of capacitive noise voltage in the signal circuit is practically eliminated even with a measuring pipe made of insulating material. The electromagnetic flow sensor contains a non-ferromagnetic all-metal screen to protect the signal circuit of the flow sensor from capacitive interference voltage. A non-ferromagnetic all-metal shield protects the measuring tube together with electrode devices and signal wires from the electric field of the windings and power wires of the windings, eliminating the capacitance between them and this eliminates the possibility of generating capacitive noise voltage in the signal circuit, thereby increasing the accuracy of the electromagnetic flow sensor.

Description

The utility model relates to the field of electrical engineering and can be used as an electromagnetic flow sensor designed to measure the flow rate of electrically conductive fluid in pipelines.

Known electromagnetic flowmeter, which contains a measuring tube, electrode devices, signal wires, windings, power wires of the windings and a magnetic circuit (JP patent No. 10332451, G 01 F 1/58, 1998, Electromagnetic flowmeter).

In use in serial production, the owner of the utility model has an electromagnetic flow sensor, which contains a measuring tube, electrode devices, signal wires, windings, winding power wires and a magnetic circuit.

The signal wires of a known electromagnetic flowmeter are laid in ferromagnetic tubes, which are brought to the measuring tube. In the case of a metal measuring tube, the signal circuit is protected from capacitive interference caused by the capacitance between the signal circuit and the windings, while the signal circuit is formed by signal wires, electrode devices and the area inside the measuring tube between the electrode devices, which, under the influence of a magnetic field penetrating the measuring tube a flow signal corresponding to the speed of the fluid is induced.

This solution is not suitable for large electrode devices, because in this case, respectively, large screens are required to protect the electrode devices, which, due to their large ferromagnetic mass, cause changes in the distribution of the magnetic field of the electromagnetic flowmeter and thereby cause unpredictable changes in the metrological parameters of the flowmeter.

In the absence of shielding of the electrode devices in the signal circuit, capacitive noise voltage arises and is superimposed on the flow signal. Since the capacitive interference voltage is in phase with the flow signal, it is almost impossible to separate it from the flow signal. Superimposing capacitive noise on the flow rate signal reduces the accuracy of the flowmeter.

The known solution is also not suitable for a measuring pipe made of insulating material, since the region of the signal circuit between the electrode devices,

which, with a metal measuring tube, is shielded by the named tube, remains unscreened.

For the used electromagnetic flow sensor, the signal wires are laid in non-ferromagnetic shielding braids to protect capacitive noise from voltage. The disadvantage of this flow sensor is the inadequate protection of the signal wires, since shielding of the signal wires remains insufficient due to gaps between the braid wires. The disadvantage of the used electromagnetic flow sensor is also the lack of screens on the electrode devices and the inability to use a measuring pipe of insulating material due to insufficient shielding of the signal circuit.

The purpose of this solution is to improve the electromagnetic flow sensor so that the formation of capacitive noise voltage in the signal circuit is practically eliminated even with a measuring pipe made of insulating material.

This goal is achieved by the fact that a non-ferromagnetic all-metal screen is installed in the electromagnetic sensor, which shields the signal circuit from the electric field of the windings and power wires of the windings without changing the distribution of the magnetic field of the flow sensor. The all-metal screen eliminates the capacitance between the named circuits and the occurrence of capacitive noise voltage in the signal circuit.

This electromagnetic flow sensor contains a measuring tube, electrode devices, signal wires, windings, power wires of the windings, a magnetic circuit and a non-ferromagnetic all-metal screen.

The figure shows a general view of the electromagnetic flow sensor. The electromagnetic flow sensor contains a measuring tube 1, electrode devices 2, signal wires 3, windings 4 and 5, a magnetic circuit 6, power wires of the windings 7 and a non-ferromagnetic all-metal shield 8, which in this case consists of components 8a, 8b, 8c and 8d .

The plates of the non-ferromagnetic all-metal screen 8a and 8b shield the measuring tube 1 together with electrode devices and signal wires from the electric field of the windings 4 and 5, the screen tube 8c screens the measuring tube together with electrode devices and signal wires from the electric field of the winding 5 wires, screen tube 8d shields the signal wires 3 from the electric field of the winding 4.

As a result, the measuring tube, together with the electrode devices and signal wires, is shielded from the electric field of the windings and the power supply wires of the windings and, due to the lack of capacitance between them, there is no capacitive interference voltage in the flow signal, thereby increasing the accuracy of the measurement by the sensor also in the case when the measuring the pipe is made of insulating material.

Claims (1)

An electromagnetic flow sensor comprising a measuring tube, electrode devices, signal wires, windings, power wires of the windings and a magnetic circuit, characterized in that it comprises a non-ferromagnetic all-metal screen that is located between the measuring tube, electrode devices and signal wires on one side and the windings and wires power windings on the other hand.