KR102038706B1 - Electromagnetic flowmeter - Google Patents

Abstract

The present invention provides a separate type electromagnetic flowmeter, which can maintain accuracy even when the distance between a sensor unit and an indication unit is longer than a conventional separate type electromagnetic flowmeter. The separate type electromagnetic flowmeter comprises: the sensor unit (100) provided between a pair of pipes (30) in series with the pipes (30) to generate induced electromotive force according to the flow of a fluid; a circuit unit (200) which is provided integrally with the sensor unit (100), measures the electromotive force generated by the sensor unit (100), converts the measured electromotive force into a digital value, and transmits the digital value; the indication unit (300) which is provided to be spaced apart from the circuit unit (200), receives the digital electromotive force value from the circuit unit (200), and converts the received electromotive force value into a flow rate of the fluid; and a cable unit (400) connecting the circuit unit (200) and the indication unit (300).

Description

Electromagnetic flowmeter

The present invention relates to an electromagnetic flowmeter, and more particularly to a separate electromagnetic flowmeter, relates to an electromagnetic flowmeter that can extend the distance between the sensor portion and the indicator.

Electromagnetic flowmeter is one of the measuring equipment to measure the flow rate by using electromagnetic induction phenomenon, it is installed inside the pipe, it does not form a separate obstacle in the flow direction of the fluid, it is easy to measure the conductive chemical fluid and slurry for cost, It has the advantage of high volume flow measurement accuracy.

FIG. 1 schematically illustrates a conventional electromagnetic flow meter, and will be briefly described with reference to FIG. 1.

The conventional electromagnetic flow meter 1 shown in FIG. 1 may include a sensor unit 10 and an indicator unit 20. In the sensor unit 10, electromotive force is generated according to the flow of the fluid, and the indicator unit 20 is provided. ) Is responsible for the calculation and output of the generated electromotive force to the flow rate of the fluid.

For the above operation, the sensor unit 10 is disposed between a pair of pipes 30 located on both sides and connected in line with the pipe 30, and a coil (not shown) installed around the flow of fluid. It may include a pair of electrodes (not shown), the fluid passing through the sensor unit 10 and the pipe 30 may have a conductivity of a certain degree or more.

Conventional electromagnetic flowmeter according to the installation type, as shown in FIG. 1, the integrated electromagnetic flowmeter is directly connected to the upper portion of the sensor unit 10 as shown in FIG. 1, and unlike the integrated electromagnetic flowmeter shown in FIG. 20 may be divided into a separate electromagnetic flow meter spaced apart from the sensor unit 10.

In the case of the separate flow meter, the sensor unit 10 and the indicator unit 20 are connected by a cable, so that the electromotive force generated by the sensor unit 10 is transmitted to the indicator unit 20. In general, the cable is composed of two lines, one of which is an electromagnet. The polarity of the electrode is continuously converted to obtain instantaneous electromotive force in the pipe through which the fluid flows through the generating drive cable, and the other is the generator electromotive force measuring cable, which indicates an analog state value of the electromotive force measured by the sensor unit 10. It serves to deliver up to 20).

Since the cable of the two lines in the separate electromagnetic flow meter transmits the analog signal to the indicator 20, the length of the cable may be limited to a maximum of about 40 m due to noise caused by the environment around the cable.

The noise of the analog signal transmitted to the cable may be due to electromagnetic waves generated by electronic devices such as a pump around the cable, an inverter, vibration of the pump or pipe around the cable, and deformation of the cable itself. Noise due to this has the problem of reducing the accuracy of the separate electromagnetic flow meter.

Korean Registered Patent Publication No. 10-1357619 (“Electromagnetic Flowmeter with Built-in Battery in Body”, Announcement Date 2014.02.06.)

The present invention has been made to solve the problems described above, the purpose of the electromagnetic flowmeter according to the present invention, in the separate electromagnetic flowmeter, even if the distance between the sensor portion and the indicator portion from each other longer than the conventional separate electromagnetic flowmeter, It is to provide a separate electromagnetic flow meter that can maintain accuracy.

Electromagnetic flowmeter according to the present invention for solving the above problems, is installed in a line with the pipes 30 between a pair of pipes 30, the sensor unit for generating an induced electromotive force according to the flow of the fluid 100 is integrated with the sensor unit 100, the circuit unit 200 for measuring the electromotive force generated by the sensor unit 100, converts the measured electromotive force into a digital value and transmits it, the circuit unit 200 ) Is spaced apart from the circuit unit 200, and receives the digital electromotive force value from the circuit unit 200 and converts it into a flow rate and the cable unit 400 for connecting the circuit unit 200 and the indicator 300 It characterized by including).

In addition, the circuit unit 200 and the indicating unit 300 is characterized in that the communication via the digital communication method CAN, Ethernet or RS232 / 485 Modbus / ASC / Profibus communication method.

In addition, the length of the cable unit 400 is characterized in that less than 600m.

In addition, the sensor unit 100 is installed in the form of surrounding the periphery of the space where the fluid passes through the coil 110 to generate a magnetic field and a pair of electromotive force induced by the fluid passing through the magnetic field generated by the coil It characterized in that it comprises an electrode.

In addition, the circuit unit 200 includes an operation unit 210 for operating the coil and a sensor drive circuit 220 for measuring electromotive force induced in the electrode, converting the measured electromotive force into a digital form, and transmitting the same. It features.

In addition, the operation unit 210 is characterized in that the power is supplied from the indicating unit 300 through the cable unit 400.

In addition, the cable unit 400 is composed of a plurality of cables, it characterized in that it comprises a first cable for supplying power to the circuit unit 200 and a second cable in communication with the circuit unit 200.

According to the electromagnetic flowmeter according to the present invention as described above, the electromotive force of the analog / analog form measured by the sensor unit 100 is converted into a digital signal in the circuit unit 200 formed integrally with the sensor unit 100, Since the converted digital signal is transmitted to the indicator unit 300 through the cable unit 400, unlike the conventional method of transmitting the analog signal, the digital signal is less affected by the noise of the surrounding environment of the cable unit 400, The length of the part 400 can be formed longer than before, and the accuracy of the flow measurement can be improved.

1 is a perspective view of a conventional electromagnetic flow meter.
Figure 2 is a schematic diagram of a separate electromagnetic flow meter according to an embodiment of the present invention.
3 is a partially enlarged view of FIG. 2;

Hereinafter, exemplary embodiments of the electromagnetic flowmeter according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 schematically shows an electromagnetic flow meter according to an embodiment of the present invention.

As shown in FIG. 2, the electromagnetic flowmeter according to an embodiment of the present invention may include a sensor unit 100, a circuit unit 200, an indicator unit 300, and a cable unit 400.

Referring to Figure 2 briefly describe the positions of the components of the electromagnetic flowmeter according to an embodiment of the present invention, the sensor unit 100 and the circuit unit 200 is embedded in the lower portion of the ground surface 40, the indicating unit 300 The upper part of the stand 50, that is located on the ground, the cable unit 400 connects the sensor unit 100 and the circuit unit 200 and the indication unit 300 buried underground. However, the present invention does not limit the positions of the components of the present invention as described above, and there may be an embodiment in which the sensor unit 100, the circuit unit 200, and the indicator unit 300 are installed at different positions.

As shown in FIG. 2, the sensor unit 100 is installed in a line with the pipes 30 between a pair of pipes, and the fluid passing through the pipe 30 passes therethrough. The fluid may flow in the direction of the arrow shown in FIG. 2, that is, in the order of the pipe 30 on the left side, the inner space of the sensor unit 100, and the pipe 30 on the right side, but the present invention is not limited thereto. There may be embodiments in which a fluid flows.

In order to operate the electromagnetic flowmeter according to an embodiment of the present invention, the fluid flowing into the pipe 30 on the left side, the inside of the sensor unit 100 and the pipe 30 on the right side may be a fluid having a certain degree or more of conductivity. And examples of such fluids may be distilled water, hydrocarbons, aqueous wastewater or dirty liquids.

As shown in FIG. 2, the sensor unit 100 and the pipes 30 positioned at both sides of the sensor unit 100 may be coupled to each other through flanges 101 and 31 installed at respective ends thereof.

As shown in FIG. 2, the sensor unit 100 may include a coil 110, an electrode (not shown), and a liner (not shown).

As shown in FIG. 2, the coil 110 is installed in a form that surrounds a part of the periphery of the space through which the fluid passes (for example, the up and down direction based on FIG. 2) in the sensor unit 100, and supplies power. Receives a magnetic field to the space where the fluid passes inside the sensor unit 100. The magnetic field formed by the coil 110 allows the fluid passing through the coil 110 to flow separately from the negative and proton.

A pair of electrodes may be formed and installed in a space through which the fluid passes in the sensor unit 100, and installed to contact the flowing fluid so as to face each other. Electromotive force may be induced in the electrode by a fluid that is separated from the negative and protons by the magnetic field of the coil 110.

The liner is a portion that maintains insulation between the liquid in the sensor unit 100 and the hardware, and the hardware may be representatively the coil 110 described above.

The material of the liner may be Teflon, ethylene propylene rubber, soft rubber, ceramic, and the like, and other materials may be selected depending on the corrosiveness, chemical reactivity, and wear property of the fluid.

As shown in FIG. 2, the circuit unit 200 is integrally formed with the sensor unit 100, and measures the electromotive force generated from the electrode of the sensor unit 100, in more detail, the measured electromotive force. Is converted into a digital value and transmitted to the indicating unit 300 to be described later.

3 is an enlarged view of a portion of FIG. 2.

As shown in FIG. 3, the circuit unit 200 may include an operation unit 210 and a sensor drive circuit 220 for the operation as described above.

The operation unit 210 shown in FIG. 3 supplies power to the coil 110 to flow a current, so that a magnetic field is formed in the coil 110, and at the same time, an operation for continuously obtaining an electromotive force in the pipe through which the fluid flows. That is, the operation of converting the polarity of the coil 110 about 20 times per second.

A cable may be formed between the operation unit 210 and the coil 110 to supply power and to convert a current applied to the coil 110.

The operation unit 210 may have an embodiment of supplying power to the coil 110 from a battery built in the circuit unit 200, but in the electromagnetic flowmeter according to an embodiment of the present invention is supplied with power from the outside, the operation unit The configuration for supplying power to 210 will be described later.

The sensor drive circuit 220 measures the electromotive force induced by the electrode described above, and the sensor drive circuit 220 may be connected to the electrode through a separate cable.

The electromotive force of the electrode measured by the sensor drive circuit 220 is an analog signal of a very small value of several mV, and the sensor drive circuit 220 converts the electromotive force of the measured electrode into a digital signal, and the digital signal becomes a numeric form. Can be. That is, the sensor drive circuit 220 serves as an analog-to-digital converter (ADC).

As shown in FIG. 2, since the circuit unit 200 is integrally formed with the sensor unit 100 to measure the electromotive force of the electrode in the sensor drive circuit 220 using a relatively short cable, the measured electromotive force is measured in an external environment. May be less affected.

As shown in FIG. 2, the indicating unit 300 may be spaced apart from the sensor unit 100 and the circuit unit 200, and the indicating unit 300 may be installed in the stand 50 installed on the ground surface 40. have.

The indicator 300 is a part for calculating the flow rate through the digital electromotive force measured in the circuit unit 200, and calculates the flow rate through the surface area of the pipe 30 and the measured digital electromotive force in advance.

The indicating unit 300 may include output means (display) for outputting the calculated flow rate of the fluid.

As illustrated in FIGS. 2 and 3, the circuit unit 200 and the indicator unit 300 may be connected to each other through the cable unit 400.

As shown in FIG. 2 and FIG. 3, the cable unit 400 may be formed of a plurality of cables, some of which may be used to supply power to the operation unit 210 of the circuit unit 200. The second cable, which is different from the first cable, can be used to receive the digital signal of the electromotive force measured from the sensor drive circuit 220.

The first cable and the second cable may each be a plurality of cables, not a single cable.

The sensor drive circuit 220 and the indicator 300 may communicate with each other through a serial communication method such as CAN, Ethernet, or RS232 / 485 Modbus / ASC / Profibus, which are digital communication methods.

CAN and RS-485 are representative standards for fieldbus systems, and CAN is a communication method specialized in stability and device simplification, and can be implemented at low power, device simplification, and operation reliability of the device. In view of the above, the present invention is suitable for electromagnetic flowmeters such as the present invention.

The present invention converts the electromotive force measured by the sensor unit 100 and the circuit unit 200 as a digital signal as described above, and then converts the cable unit 400 to CAN, Ethernet, or RS232 / 485 Modbus / ASC / Profibus. Transmit to the indicating unit 300 through.

The present invention measures the measured value from the environmental and physical influences around the cable unit 400 (influence of electromagnetic noise around the cable, the vibration applied to the cable, the deformation of the cable, the temperature change applied to the cable) through the above-described method. The accuracy of the electromagnetic flowmeter can be improved by preventing distortion of the wire, and the length of the cable part 400 can be increased to about 600m, more specifically, to about 500m, thereby achieving the same effect as the free arrangement of observation points.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

10 sensor part 11 flange
20: indicator
30: pipe 31: flange
40: surface
50: stand
100: sensor unit 110: coil
200: circuit part
210: operation unit 220: sensor drive circuit
300: indicator
400: cable part

Claims (6)

A sensor unit 100 installed in line with the pipes 30 between the pair of pipes 30 to generate induced electromotive force according to the flow of the fluid;
A circuit unit 200 which is installed integrally with the sensor unit 100 and measures an electromotive force generated by the sensor unit 100, converts the measured electromotive force in a digital form into a digital value and transmits the digital value;
An instructor 300 spaced apart from the circuit unit 200 and configured to receive the digital electromotive force value from the circuit unit 200 and then convert the received electromotive force value into a flow rate of the fluid; And
In the separate electromagnetic flow meter comprising a; cable unit 400 for connecting the circuit unit 200 and the indicator unit 300,
The sensor unit 100 is installed so as to surround the periphery of the space through which the fluid passes, so long as electromotive force is induced by the coil 110 generating a magnetic field and the fluid passing through the magnetic field generated by the coil 110. Includes a pair of electrodes,
The circuit unit 200 includes an operation unit 210 for operating the coil 110 and a sensor drive circuit 220 for measuring the electromotive force induced by the electrode, converting the measured electromotive force into a digital form, and transmitting the same.
The circuit unit 200 and the indicating unit 300 communicate with each other through a CAN, Ethernet or RS232 / 485 Modbus / ASC / Profibus communication method,
The cable unit 400 is composed of a plurality of cables, and includes a first cable for supplying power to the circuit unit 200 and a second cable in communication with the circuit unit 200,
The sensor unit 100 and the circuit unit 200 are buried under the ground surface 40, the indicating unit 300 is located on the ground,
Since the circuit unit 200 is formed integrally with the sensor unit 100 to measure the electromotive force of the electrode in the sensor drive circuit 220 and convert the measured electromotive force into a digital value, the measured electromotive force may be affected by an external environmental influence. Receive less,
The electromotive force in analog form generated by the sensor unit 100 is converted into a digital signal in the circuit unit 200 which is integrally formed with the sensor unit 100, and the converted digital signal is indicated by the indicator unit 300 through the cable unit 400. Unlike the case where the analog signal is transmitted to the indicating unit 300, the signal is less affected by the noise of the surrounding environment of the cable 400, the length of the cable 400 can be formed to 600m long Can improve the accuracy of flow measurement,
Separating electromagnetic flowmeter, characterized in that the distance between the circuit portion 200 and the indicating portion 300 and the length of the cable portion 400 can be increased to freely arrange the flow meter.
delete delete delete The method of claim 1,
The operation unit 210 is a separate type electromagnetic flow meter, characterized in that the power is supplied from the indicating unit 300 through the cable unit 400.
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