KR200348133Y1 - A electromagnetic flow-meter - Google Patents

Abstract

The present invention relates to an electromagnetic flowmeter, according to the present invention, a measuring tube flowing inside and a flange portion at the front and rear ends, and is placed in close contact with the inner wall side of the measuring tube fluid flowing through the inside of the measuring tube Insulating, the lining is formed with a "shade" shaped front and rear ends, coupled with the flange portion of the measuring tube with the shade of the front and rear ends of the lining, while grounding the fluid passing on the inlet and outlet side of the measuring tube And a pair of grounding rings (or stabilizing rings) for stabilizing the lining, wherein the pair of grounding rings have a wider area of flowing fluid, and the shades at the front and rear ends of the linings are compressed by the pressing force of the flanges and the grounding rings. Disclosed is an electromagnetic flowmeter, characterized in that the ground extension jaw (or the jungle blocking jaw) protrudes inwardly of the lining to prevent the phenomenon of sliding. The. According to the present invention, the flow rate can be precisely measured, and there is an advantage of extending the life of the lining, and moreover, the life of the electromagnetic flowmeter.

Description

A electromagnetic flow meter

The present invention relates to an electromagnetic flow meter, and more particularly, to an improvement of a pair of grounding rings provided to ground the fluid flowing on the inlet and outlet sides of the measuring tube and stabilize the lining.

In general, the electromagnetic flowmeter has a shape as briefly shown in FIG. The electromagnetic flowmeter 100 uses Faraday's electromagnetic induction principle, as disclosed in Korean Patent Laid-Open Publication Nos. 2001-0097502 and 2003-0042901, and is perpendicular to the flow rate of the flowing conductive fluid and the applied magnetic field. It is an instrument that measures the average flow rate of liquid from the induced electromotive force generated in proportion to the flow velocity and the magnetic field strength in the phosphorus direction.

FIG. 2 is a block diagram of a flow management system to which the electromagnetic flowmeter 100 of FIG. 1 is applied. Referring to this, generally, when a fluid is input and output to the electromagnetic flowmeter 100 by a pipe 200, the electromagnetic flowmeter 100 The flow rate is detected and output to the controller 400, and the controller 400 controls the flow of the fluid by operating the valve 300 according to the flow rate input from the electromagnetic flowmeter 400 to manage the flow rate.

3 is a front sectional view of a general electromagnetic flowmeter 100, with reference to this will be described in more detail the configuration of the general electromagnetic flowmeter 100. Hereinafter, the same reference numerals are used for components having the same role.

As shown in FIG. 3, a general electromagnetic flowmeter 100 is disposed in close contact with a measuring tube 12 through which a measuring fluid flows and an inner wall side of the measuring tube 12, and thus, inside the measuring tube 12. Lining (11) to insulate the fluid flowing therethrough, a pair of electrodes (13a, 13b) provided to contact the fluid flowing through the inside of the measuring tube 12, and the fluid flowing inside the measuring tube (12) Electromagnets 14a and 14b arranged to form a magnetic field in a direction perpendicular to the direction of movement of the magnets, and are configured outside of the components, thereby shielding the components from external electromagnetic phenomena and being magnetic together with the electromagnets 14a and 14b. And a shield case 15 constituting a circuit, a case 16 enclosing all the above-described configurations, and the like. The pair of electrodes 13a and 13b are provided inside the case 16. And the electrodes 13a, according to the operation of the electromagnets 14a, 14b. The electrode voltage detected from 13b) as a specific signal (the specific signal may be an analog DC current signal, an analog DC voltage signal, a scaled or unscaled pulse signal, a digital communication signal, etc., depending on the electromagnetic flowmeter). The conversion unit 17 which converts and outputs it to the controller 400 is comprised.

Figure 4 shows a side cross-sectional view of the main portion of the conventional electromagnetic flowmeter 100 associated with the present invention.

As shown in FIG. 4, the measuring tube 12 flows inside the measuring tube and has flange portions 12a and 12b at the front and rear ends thereof. The lining 11 has a fluid flowing inside the measuring tube 12. Bobbin composed of tubular flow path portion 11a directly contacting the blade portion, and shade portions 11b and 11c formed in the shape of " fresh " toward the flange portions 12a and 12b at the front and rear ends of the flow passage portion 11a. ) Is shaped. Before and after both sides of the measuring tube 12, the pipe 200 for providing a flow path of the fluid input and output to the electromagnetic flowmeter 100 is connected using the flanges (200a, 200b), at this time, the flow path (19) In order to completely seal the flanges 12a and 12b and the flanges 200a and 200b, the flanges 12b and 11b are tightly adhered with each other (between the flanges 11b and 11c). Insertion method, sanitary connection method, screw connection method, but there is a flange inserting method in the drawings for the present description as an example).

On the other hand, the lining 11 is made of a material such as a thermoplastic resin (particularly a Teflon material is suitable and will be described below using Teflon material as an example), which is suitable for minimizing the flow resistance of the fluid while insulating the flowing fluid.

However, as shown in the reference diagram of FIG. 5, since the teflon-lined lining 11 is malleable, the cap 11b is formed by the pressing force by the flange portions 12a and 12b and the flanges 200a and 200b. The front and rear ends of the lining 11 including 11c are pushed toward the flow path 19 as indicated by the dotted line in FIG. At this time, the portion pushed toward the flow path 19 prevents the fluid from moving and generates vortices so that sophisticated flow rate cannot be measured, and is gradually worn out by the moving fluid (particularly, a fluid serving as an abrasive such as cement milk). In one case more prominent) to shorten the life of the lining (11), and further shortened the life of the electromagnetic flowmeter (100). This phenomenon was more severe when the shade portions 11b and 11c reconnected the pipe 200 in a state where the shade portions 11b and 11c were excited from the surfaces of the flange portions 12a and 12b by the use of the electromagnetic flowmeter 100.

Therefore, in order to stabilize the lining 11 and to prevent the lifting of the shades 11b and 11c, a pair of stabilization rings (or ground rings, which will be described later) are formed on the front and rear sides of the measuring tube 12. This prior art will be described with reference to FIG.

Fig. 6 is a sectional view of an essential part of the electromagnetic flowmeter according to the prior art to which a pair of stabilization rings 18a and 18b are applied.

As shown in FIG. 6, a pair of stabilization rings 18a and 18b are provided at the front and rear ends of the flange portions 12a and 12b to stabilize the lining 12 to prevent lifting of the shade portions 11b and 11c. 11b and 11c are sandwiched by coupling means. The stabilization rings 18a and 18b stabilize the lining 11 to prevent lifting of the lampshades 11b and 11c, while grounding the fluid flowing on the inlet and outlet sides of the measuring tube 12 to internally the measuring tube 12. It serves to block the fluid flowing through the external electrical influences. In general, to precisely measure the flow rate, the fluid flowing on the inlet and the outlet of the measuring tube 12 should be completely grounded, which is very important in the electromagnetic flowmeter 100. Therefore, these stabilization rings (18a, 18b, hereinafter referred to as the ground ring) is called the ground ring (18a, 18b). On the other hand, in the case of the prior art referenced in Figure 4, the flange (200a, 200b) serves such a ground. Reference numerals 20a to 20c denote seal-rings for completely sealing between the flanges 200a and 200b and the ground rings 18a and 18b and between the ground rings 18a and 18b and the shades 11b and 11c. to be.

However, even in the prior art according to FIG. 6, the coupling force between the ground rings 18a and 18b and the flanges 12a and 12b acts as a compressive force on the shades 11b and 11c to include linings including the shades 11b and 11c. The problem that the front and rear portions of 11) are pushed toward the flow path 19 still exists.

Therefore, as shown in FIG. 7, taper surfaces A ₁ and A ₂ are formed on each of the pair of ground rings to minimize the pressing force applied to the lampshade by the flange portion and the pair of ground rings. Even in the case of the electromagnetic flowmeter to which the grounding ring formed with (A ₁ , A ₂ ) is applied, the phenomenon in which the front and rear ends of the lining including the shade portion are pushed toward the flow path still exists.

It is a first object of the present invention to provide an electromagnetic flowmeter, which is devised to solve the above-described problems, and the phenomenon in which the front and rear ends of the lining including the shade portion is pushed toward the flow path side is suppressed.

Further, a second object of the present invention is to provide an electromagnetic flowmeter with improved grounding capability for grounding the fluid flowing on the inlet and outlet side of the measuring tube.

1 is a front view of a general electromagnetic flowmeter.

FIG. 2 is a block diagram of a flow management system to which the electromagnetic flowmeter of FIG. 1 is applied.

3 is a schematic shear cross-sectional view of a general electromagnetic flowmeter.

4 to 7 are side cross-sectional views of major portions of a conventional electromagnetic flowmeter.

8 is a side sectional view of a main portion of an electromagnetic flowmeter according to an embodiment of the present invention.

9 is a perspective view of a ground ring (or stabilization ring) applied to the electromagnetic flowmeter of FIG.

FIG. 10 is a reference diagram for explaining the role of the ground ring (or stabilization ring) in FIG.

11 is a side sectional view showing an application example of the present invention.

* Description of the symbols for the main parts of the drawings *

11: lining 12: measuring tube

61, 62: ground ring 61a, 61b: jungle blocking jaw (grounding extension jaw)

Therefore, the flow sensor according to the present invention for achieving the above object, the measuring tube flows inside the measuring tube having a flange portion in the front and rear ends; A lining disposed in close contact with an inner wall of the measuring tube to insulate the fluid flowing inside the measuring tube, and having a lampshade having a "shade" shape in front and rear ends; A pair of nonmagnetic electrodes installed in contact with the fluid flowing inside the measurement tube; An electromagnet disposed to form a magnetic field in a direction perpendicular to a moving direction of the fluid flowing inside the measurement tube; A pair of grounding rings coupled to the flanges of the front and rear ends of the measuring tube with the shades of the front and rear ends interposed therebetween to ground the fluid passing through the front and rear ends of the linings; And a converting unit converting the electrode voltage detected from the electrode into a specific signal and outputting the specific signal according to the operation of the electrode and the electromagnet. It includes, The pair of ground ring, characterized in that the ground extension projection protrudes into the lining to widen the ground area of the fluid flowing on the inlet and outlet side of the measuring tube.

The ground extension jaw is characterized in that the shape of the cylindrical protruding into the lining more specifically.

In addition, the electromagnetic flowmeter according to the present invention for achieving the above object, the measuring tube flows therein and has a measuring tube having a flange portion at the front and rear ends; A lining disposed in close contact with an inner wall of the measuring tube to insulate the fluid flowing inside the measuring tube, and having a lampshade having a "shade" shape in front and rear ends; A pair of nonmagnetic electrodes installed in contact with the fluid flowing inside the measurement tube; An electromagnet disposed to form a magnetic field in a direction perpendicular to a moving direction of the fluid flowing inside the measurement tube; A pair of stabilization rings coupled to the flanges of the front and rear ends of the measuring tube with the shades of the front and rear ends interposed therebetween to stabilize the linings; And a converting unit converting the electrode voltage detected from the electrode into a specific signal and outputting the specific signal according to the operation of the electrode and the electromagnet. To include, the pair of stabilization ring, the pair of stabilization ring, respectively, to prevent the phenomenon that the shade of the front and rear ends of the lining is pushed toward the flow path side by the malleability by the coupling force coupled to the flange portion of the measuring tube It is characterized in that the jaw blocking jaw is protruded into the lining.

The jungle blocking jaw is characterized in that the cylindrical shape protruding into the lining more specifically.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the electromagnetic flowmeter according to the present invention as described above will be described in more detail. For convenience of description, the same reference numerals are used for the same configurations as the conventional configurations.

Electromagnetic flowmeter according to the embodiment of the present invention is basically a cross-section of the general electromagnetic flowmeter 100, as shown in Figure 3, the measuring tube 12 and the measuring tube 12 flowing the measurement fluid therein, A pair of electrodes 13a disposed in close contact with an inner wall of the c) and insulated from the fluid flowing through the inside of the measuring tube 12, and installed in contact with the fluid flowing through the inside of the measuring tube 12. And 13b), electromagnets 14a and 14b disposed so as to form a magnetic field in a direction perpendicular to the moving direction of the fluid flowing through the inside of the measuring tube 12, and configured to be external to the components, thereby And a shield case 15 which shields from electromagnetic phenomena and constitutes a magnetic circuit together with the electromagnets 14a and 14b, and a case 16 which encloses all the above configurations. 16) Inside the upper side The converter 17 converts the electrode voltage detected from the electrodes 13a and 13b into a specific signal and transmits it to the controller 400 according to the operation of the pair of electrodes 13a and 13b and the electromagnets 14a and 14b. ) Is configured.

However, according to the present invention, it has the same characteristic structure as in the embodiment referred to in FIG.

8 is a cross-sectional view of the main part of the electromagnetic flowmeter according to an embodiment of the present invention, and looks at the configuration of the main part of the electromagnetic flowmeter according to the embodiment of the present invention with reference to this.

The measuring tube 12 has a measuring fluid flowing therein like a general electromagnetic flowmeter 100 and has flange portions 12a and 12b at front and rear ends, and the lining 11 also has the same characteristics as the general electromagnetic flowmeter 100. A tubular flow path portion 11a which is in direct contact with the fluid flowing inside the measuring tube 12 and a lampshade formed in the shape of a "shade" at the front and rear ends of the flow path portion 11a toward the flange portions 12a and 12b. It has a bobbin shape composed of (11b, 11c).

However, as long as the lining 11 is stabilized at the front and rear ends of the flange portions 12a and 12b to prevent the lifting of the shade portions 11b and 11c, while the fluid flowing on the inlet and outlet sides of the measuring tube 12 is grounded. The pair of ground rings 61 and 62 are coupled by the coupling means with the shades 11b and 11c interposed therebetween, and the ground rings 61 and 62 are provided inside the lining 11 as a characteristic configuration of the present invention. Cylindrical protruding jaws 61a, 62a, which may be defined as ground extension jaws, and are described later, are formed in a cylindrical shape.

9 is a perspective view of the ground ring 61/62 having the characteristic configuration of the present invention as described above.

9, it can be seen that the jungle barrier jaw 61a / 62a (ground extension jaw) protrudes in a cylindrical shape from the inner diameter of the ground ring 61/62.

FIG. 10 is a reference diagram for explaining the role of the jungle barrier jaw 61a / 62a as described above, and the role of the jungle barrier jaw 61a / 62a will be described with reference to the figure.

In general, when assembling the electromagnetic flowmeter, the flange portions 12a and 12b at the front and rear ends of the measurement tube 12 and the pair of ground rings 61 and 62 are strongly coupled by the coupling means. At this time, between the pair of ground rings 61 and 62 and the flange portions 12a and 12b, the shade portions 11b and 11c are arranged as described in the prior art, and the shade portions 11b and 11c are flange portions. A strong compressive force is received in the direction of the thick arrow shown in FIG. 10 by the coupling force between the 12a and 12b and the ground rings 61 and 62. Since the lining 11 is made of a malleable Teflon material, the front and rear portions of the lining 11 including the shades 11b and 11c are pushed toward the flow path 19 as shown by the dotted arrow in FIG. Although a force is received, this pushing force is canceled by the jungle blocking jaws 61a and 62a, so that a phenomenon in which the front and rear ends of the lining 11, which has occurred conventionally, is pushed toward the flow path 19 side, is suppressed.

On the other hand, as described in the prior art, the ground rings 61 and 63 ground the fluid flowing on the inlet and outlet side of the measuring tube 12, so that the flow rate can be precisely measured. At this time, the jungle blocking jaw (61a, 62a) is formed to protrude to the inside of the lining 11 to expand the area that the fluid flowing on the inlet and outlet side of the measuring tube 12 can be grounded, measuring tube ( The fluid flowing on the inlet and outlet side of 12) can be completely grounded, and therefore, the jungle barrier jaws 61a and 62a can be defined as ground extension jaws.

<Application example>

The technique can be applied as referenced by FIG.

That is, when there is no ground ring as shown in Fig. 4 for explaining the prior art, the jungle barrier jaw 1a, 1b, or the ground extension jaw is formed in the flange for connecting the pipe.

However, such an application can be applied by any person skilled in the art having the technical idea of the present invention, and should be interpreted as belonging to the scope of the present invention, or it should be interpreted as a technology in the same area as the present invention. .

As described above, although the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, the above-described embodiments have only been described as a preferred example of the present invention, and the general knowledge in the technical field to which the present invention belongs. The person having the present invention can easily implement the present invention in another form within the same category as the above embodiment, or can devise an area equivalent to the present invention, only by the description of the embodiment of the present invention. Other scope of rights should not be understood to be limited to the above embodiments.

As described in detail above, the electromagnetic flowmeter according to the present invention can prevent the phenomenon in which the front and rear portions of the lining are pushed to the flow path side by the pressing force by the coupling of the flange portion and the ground ring, so that the flow rate can be precisely measured continuously. In addition, it has the effect of extending the life of the lining, and furthermore, the life of the flow sensor.

In addition, the electromagnetic flowmeter according to the present invention, the grounding ability of the fluid flowing on the inlet and outlet side of the measuring tube is improved, the precision of the flow rate measurement is improved.

Claims (4)

A measuring tube having a flange portion at the front and rear ends with a measurement fluid flowing therein; A lining disposed in close contact with an inner wall of the measuring tube to insulate the fluid flowing inside the measuring tube, and having a lampshade having a "shade" shape in front and rear ends; A pair of nonmagnetic electrodes installed in contact with the fluid flowing inside the measurement tube; An electromagnet disposed to form a magnetic field in a direction perpendicular to a moving direction of the fluid flowing inside the measurement tube; A pair of grounding rings coupled to the flanges of the front and rear ends of the measuring tube with the shades of the front and rear ends interposed therebetween to ground the fluid passing through the front and rear ends of the linings; And A conversion unit converting the electrode voltage detected from the electrode into a specific signal and outputting the specific signal according to the operation of the electrode and the electromagnet; Including, The pair of grounding rings, the electromagnetic flowmeter characterized in that the ground extension projection protruding into the lining to increase the ground area of the fluid flowing on the inlet and outlet side of the measuring tube. The method of claim 1, The ground extension jaw, the electromagnetic flowmeter, characterized in that the cylindrical projecting inwardly of the lining. A measuring tube having a flange portion at the front and rear ends with a measurement fluid flowing therein; A lining disposed in close contact with an inner wall of the measuring tube to insulate the fluid flowing inside the measuring tube, and having a lampshade having a "shade" shape in front and rear ends; A pair of nonmagnetic electrodes installed in contact with the fluid flowing inside the measurement tube; An electromagnet disposed to form a magnetic field in a direction perpendicular to a moving direction of the fluid flowing inside the measurement tube; A pair of stabilization rings coupled to the flanges of the front and rear ends of the measuring tube with the shades of the front and rear ends interposed therebetween to stabilize the linings; And A converting unit converting the electrode voltage detected from the electrode into a specific signal and outputting the specific signal according to the operation of the electrode and the electromagnet; Including, The pair of stabilization rings, the pair of stabilization ring, respectively, to prevent the phenomenon that the head portion of the front and rear ends of the lining is pushed to the flow path side by malleability by the coupling force coupled to the flange portion of the measuring tube An electromagnetic flowmeter, characterized in that the jungle blocking jaw protruded. The method of claim 3, The jungle blocking jaw, the electromagnetic flowmeter characterized in that the cylindrical projecting inwardly of the lining.