DE102017125593A1 - Electromagnetic flowmeter with adjustable electrode structures - Google Patents

Abstract

An electromagnetic flowmeter (1) is created. A measuring tube (10) has a mounting tube liner (11) and on an outer side of the measuring tube (10) a control module (20) is installed. A magnetic field module (30) is electrically connected to the control module (20) and is installed on an outer side orthogonal to a shaft of the measuring tube (10) without contacting the working fluid. An electrode structure (40) is electrically connected to the control module (20) and disposed on an outer surface of the measuring tube (10) and partially extends into the mounting tube liner (11) to contact the working fluid. The actuator element (50) is electrically connected to the control module (20) and is connected to the electrode structure (40). The actuator element (50) is driven by an external force to drive the electrode structure (40) in the direction of the mounting tube liner (11) inside, and is orthogonal to the mounting tube liner (11) to prevent the wear of the electrode structure (40 ) in order to obtain a correct measurement result and to increase the service life.

Description

BACKGROUND OF THE INVENTION

Field of the invention

The present invention relates generally to an electromagnetic flowmeter, and more particularly to an electromagnetic flowmeter having adjustable electrode structures.

Description of the Related Art

An electromagnetic flowmeter typically measures a flow of a conductive fluid (such as water, etc.) using electromagnetic induction. Mainly, the electromagnetic flowmeter consists of a measuring tube, a pair of electrode structures disposed on the measuring tube, and a pair of coils. After the coils have been energized, a magnetic field is additionally formed in the measuring tube and a source voltage is generated between the electrodes. Thus, the source voltage of the magnetic field is changed when a fluid passes through the measuring body, whereupon the flow of the fluid can be calculated.

Typically, an electromagnetic flowmeter detects the fluid in the tube via the electrode structures. However, a fluid in the tube could cause damage to detection sections of the electrode structures. Thus, defects or inaccuracies in the measurement of the electromagnetic flowmeter may occur after it has been used for a considerable period of time, so that noise of the electronic signal is generated. In addition, metal capsules of conventional electromagnetic flowmeters are usually sealed by welding to prevent ingress of moisture to ensure normal operations of the internal electrode structures and coils, but this welding process causes difficulty in replacing the electrode structures within the metal capsule. As a result, devices associated with the pipeline must be shut down to replace the electromagnetic flowmeter, resulting in production interruptions, lower capacity, and higher costs.

In view of the above drawbacks, the inventor, on the basis of his knowledge and careful research, proposes the present invention to solve the problems of the prior art.

SUMMARY OF THE INVENTION

Accordingly, it is an object of the present invention to provide an electromagnetic flowmeter having adjustable electrode structures for compensating for wear of the electrode structures and adjusting the relative position of the electrode structures; thus, the flow field may be perpendicular and orthogonal to the flow direction to maintain proper measurement results and reduce noise of the electronic signal, so that maintenance time may be short and the process simplified to maintain capacity and increase the useful life of the electromagnetic flowmeter.

In order to achieve the above-mentioned object, the present invention provides an electromagnetic flowmeter having adjustable electrode structures including a measuring tube, a control module, a magnetic field module, an electrode structure, and at least one actuator element. The metering tube has a mounting tube liner for a working fluid flowing therein, and the control module is installed on an outside of the metering tube without contacting the working fluid. The magnetic field module is electrically connected to the control module and installed on an outer surface of the measuring tube in a first outer side direction and orthogonal to a shaft of the measuring tube without contacting the working fluid. The magnetic field module is driven by an external force in such a way that an electromagnetic field is generated in the mounting tube liner. The electrode structure is electrically connected to the control module and disposed on an outer surface of the measuring tube in a second outer side direction and orthogonal to the measuring tube. The electrode structure partially extends into the mounting tube liner. The actuator element is electrically connected to the control module and connected to the electrode structure. The actuator element is driven by an external force in such a way that the electrode structure in the direction of the mounting tube liner 11 is taken inside, and is orthogonal to a shaft of the mounting tube liner.

Compared to the prior art, the actuator element of the present invention is electrically connected to the control module and to the electrode structures. The actuator element is driven by an external force to one of the electrode structures in the direction of the mounting tube liner 11 is orthogonal to a shaft of the mounting tube liner to compensate for the wear of the electrode structure to obtain a correct measurement result and increase the useful life. In addition, the position of the electrode structure on the measuring tube in Dependence on actual situations to be discontinued; thus, the flexibility of the electromagnetic flowmeter is increased.

list of figures

• 1 eine schematische Explosionsdarstellung des elektromagnetischen Durchflussmessers mit einstellbaren Elektrodenstrukturen der vorliegenden Erfindung ist;
• 2 eine perspektivische schematische Ansicht des elektromagnetischen Durchflussmessers mit einstellbaren Elektrodenstrukturen der vorliegenden Erfindung ist;
• 3 eine Querschnittsansicht aus 2 entlang der Linie 3-3 ist;
• 4 eine Querschnittsansicht von Montageabschnitten des elektromagnetischen Durchflussmessers der vorliegenden Erfindung ist;
• 5 eine schematische Einstellansicht der Elektronenstrukturen des elektromagnetischen Durchflussmessers der vorliegenden Erfindung ist;
• 6 eine Querschnittsansicht aus 2 entlang der Linie 6-6 ist.

The features of the invention which are believed to be novel are set forth with particularity in the appended claims. However, the invention itself may best be understood by reference to the following detailed description of the invention, which describes a number of exemplary embodiments of the invention in conjunction with the accompanying drawings, in which:

• 1 Figure 4 is a schematic exploded view of the electromagnetic flowmeter with adjustable electrode structures of the present invention;
• 2 Figure 3 is a perspective schematic view of the electromagnetic flowmeter with adjustable electrode structures of the present invention;
• 3 a cross-sectional view 2 along the line 3 - 3 is;
• 4 Fig. 12 is a cross-sectional view of mounting portions of the electromagnetic flowmeter of the present invention;
• 5 Fig. 12 is a schematic adjustment view of the electronic structures of the electromagnetic flowmeter of the present invention;
• 6 a cross-sectional view 2 along the line 6 - 6 is.

DETAILED DESCRIPTION OF THE PREFERRED

EMBODIMENTS

The technical content and a detailed description of the invention are described below together with the accompanying drawings in accordance with a number of preferred embodiments, which are not used to limit its scope of execution. Any equivalent variation and modification made in accordance with the appended claims is fully included in the claims claimed by the present invention.

It is referred to 1 to 3 , which show a schematic perspective exploded view, a perspective schematic view and a cross-sectional view of one side of the electromagnetic flowmeter with adjustable electrode structures. The electromagnetic flowmeter 1 with adjustable electrode structures contains a measuring tube 10 , a control module 20 , a magnetic field module 30 , an electrode structure 40 and at least one actuator element 50 , The magnetic field module 30 and the electrode structure 40 are separated on two opposite sides of the measuring tube 10 attached. In addition, the control module controls 20 the magnetic field module 30 , the electrode structure 40 and the actuator element 50 , This allows the electromagnetic flowmeter 1 the flow of the fluid in the measuring tube 10 measure, taking the distance over which the electrode structure 40 into the measuring tube 10 extends, by driving the actuator element 50 can be adjusted. The structures of the electromagnetic flow meter 1 are described in more detail as follows.

As in 1 is shown, the measuring tube 10 a mounting tube liner 11 for a working fluid flowing therein and is the control module 20 on an outside of the measuring tube 10 built-in. In addition, the magnetic field module 30 with the control module 20 electrically connected and on the outer surface of the measuring tube 10 in a first outside direction 300 installed and it is orthogonal to a shaft of the measuring tube 10 without touching the working fluid. The magnetic field module 30 is driven by an external force and by the control module 20 controlled in the way that in the mounting tube liner 11 an electromagnetic field is generated. In the present embodiment, the magnetic field module includes 30 a pair of magnetic plates.

In addition, the electrode structure 40 with the control module 20 electrically connected and in a second outside direction 400 on an outer surface of the measuring tube 10 arranged and orthogonal to a shaft of the measuring tube 10 , The electrode structures 40 partially extend into the mounting tube liner 11 to touch the working fluid. In addition, the electromagnetic flowmeter contains 1 in the present embodiment, a pair of electrode structures 40 on two sides of the measuring tube 10 are combined separately. The actuator element 50 is with the control module 20 and with at least one of the electrode structures 40 electrically connected. The actuator element 50 is driven by an external force to at least one of the electrode structures 40 in the direction of the mounting tube liner 11 on the inside, and is orthogonal to a shaft of the mounting tube liner 11 (second outside direction 400 ) to the wear of the electrode structure 40 to compensate for a correct measurement result.

It is noted that the first outside direction 300 and the second Outside direction 400 in an orthogonal plane to a flow direction of the working fluid an angle A form. The angle A is 90 degrees, but is not limited to this. In addition, the external force is a driving force generated by electricity, magnet, light or sound; or the external force is an external mechanical force that drives the pair of electrode structures to move.

Based on 3 contains the measuring tube 10 in an embodiment of the present invention, further comprising a mounting tube 12 that the mounting tube liner 11 envelops. The mounting tube 12 has two mounting sections 13 on, which are arranged opposite, and each of the two mounting sections 13 has a through hole, which individually with the mounting tube liner 11 communicates. The pair of electrode structures 40 is corresponding in the two mounting sections 13 and through the through holes in the mounting tube liner 11 extending provided.

In addition, each of the electrode structures has 40 an electrode probe 41 and a carrier plate 42 around an outer circumference of the electrode probe 41 is arranged on. The actuator element 50 is on the carrier plate 42 arranged. In addition, the measuring tube contains 10 also two end caps 14 showing the two mounting sections 13 cover accordingly, and a holding seat 15 in the mounting sections | 15 | _{[tm1] is} formed. The holding seat 15 is with the mounting tube liner 11 formed in one piece and provided with the through hole. More specifically, each of the pair of electrode structures 40 individually with the actuator element 50 connected. The control module 20 also contains a cable 21 , The actuator element 50 is over the cable 21 through the control module 20 controlled in such a way that the electrode structures 40 be set in motion.

It is noted that the amount of electrode structures 40 and the mounting sections 13 can be adjusted depending on actual situations.

Furthermore, the electromagnetic flowmeter contains 1 in the present embodiment, a protective capsule 60 and a plurality of fasteners 70 , The protective capsule 60 is with the control module 20 connected and covered the measuring tube 10 , More precisely contains the protective capsule 60 a first capsule 61 and a second capsule 62 covering each other. The first capsule 61 and the second capsule 62 are about the fasteners 70 accordingly with the measuring tube 10 combined.

It is referred to 4 and 5 13, which shows a schematic cross-sectional view of mounting portions and a schematic adjustment view of electrode structures of an embodiment of the present invention. As in 4 is shown is the actuator element 50 of the present embodiment, preferably a set of piezoelectric elements, wherein two sides of the set of piezoelectric elements of the end cap 14 or the carrier plate 42 resist, wherein the set of piezoelectric elements is a combination of conventional piezoelectric materials and Keramikisoliermaterialien. The set of piezoelectric elements is driven by an external force to deform and the backing plate 42 is pushed to the electrode structures 40 in the direction of the mounting tube liner 11 to move inside and is orthogonal to a shaft of the mounting tube liner 11 , Thereby, a purpose of adjusting the position of the electrode structure becomes 40 Fulfills.

It is noted that in the present embodiment, an inner wall of the restrictive seat 15 several positioning sections 151 and the carrier plate 42 by driving the actuating element 50 at one of the positioning sections 151 is positioned. The deposition of the positioning sections 151 can the tightness between the carrier plate 42 and the restriction seat 15 maintained to prevent the carrier plate 42 in one direction from the mounting tube liner 11 moved away.

More precisely, the positioning section 151 a catch. The carrier plate 42 has a flat contact surface 421 and a sloping surface 422 pointing to one side of the positioning section 151 is adjacent to. In addition, the hook has an inclined guide surface 1511 that of the sloping surface 422 corresponds, and a flat stop surface 1512 , the support plate 42 to oppose a resistance to. Furthermore, the inclined surface moves 422 the carrier plate 42 through the guidance of the inclined surface 1511 in the direction of the other positioning section 151 on the inside, when the backing plate 42 by driving the actuator element 50 toward the inner bottom of the restriction seat 15 emotional. Thus, the flat contact surface 421 the carrier plate 42 on the flat stop surface 1512 of the positioning section 151 be positioned on the inside. Accordingly, the position of the electrode structure becomes 40 that are in the mounting tube liner 11 extends, set.

Based on 5 becomes the carrier plate 42 towards the middle of the measuring tube 10 pushed and moved when the set of piezoelectric elements is deformed by driving an external force. At this moment, the carrier plate moves 42 by pushing the set of piezoelectric elements towards the inner bottom of the restriction seat 15 and is at another positioning section 151 on the inside. Thus, the electrode structures move 40 (the electrode probe 41 and the carrier plate 42 ) in the direction of the mounting tube liner 11 inside and are orthogonal to a shaft of the mounting tube liner 11 ; thereby, the purpose of adjusting the position of the electrode structure becomes 40 Fulfills.

6 shows a schematic view of the movement of the electrode structure of the electromagnetic flowmeter of the present invention. In the present invention, the electrode structures 40 on two sides of the measuring tube 10 separated with an actuator 50 (the set of piezoelectric elements) connected. The two actuators 50 be through the control module 20 controls and displaces the connected electrode structures 40 moving.

When the pair of electrode structures 40 is damaged, so that during the measurements errors or inaccuracies occur, the electromagnetic flow meter 1 of the present invention via the control module 20 by adjusting the position of the electrode structure 40 , which is in the measuring tube 10 extends, driving the actuators 50 control. In real practice, the position of the electrode structures 40 be adjusted depending on actual situations; bringing the flexibility and service life of the electromagnetic flow meter 1 increase.

Although the present invention has been described in terms of its preferred embodiment, it should be understood that the invention is not limited to the details thereof. Various substitutions and improvements have been suggested in the foregoing description, and others will occur to one of ordinary skill in the art. Thus, it is intended that all such substitutions and improvements be included within the scope of the invention as defined in the appended claims.

Claims (12)

Electromagnetic flowmeter with adjustable electrode structures, wherein the electromagnetic flowmeter comprises: a metering tube (10) having a mounting tube liner (11) for a working fluid flowing therein; a control module (20) installed on an outside of the meter tube (10) without contacting the working fluid; a magnetic field module (30) electrically connected to the control module (20) and installed on an outer surface of the measuring tube in a first outer side direction (300) orthogonal to a stem of the measuring tube (10) without contacting the working fluid; wherein the magnetic field module (30) is driven by an external force such that an electromagnetic field is generated in the mounting tube liner (11); an electrode structure (40) electrically connected to the control module (20) and disposed on an outer surface of the measuring tube in a second outer side direction (400) and orthogonal to a shaft of the measuring tube (10); wherein the electrode structure (40) extends partially into the mounting tube liner (11) to contact the working fluid; and at least one actuator element (50) electrically connected to the control module (20) and connected to the electrode structure (40); wherein the actuator element (50) is driven by an external force such that the electrode structure (40) is taken in the direction of the mounting tube liner (11) inside, and orthogonal to a shaft of the mounting tube liner (11). Electromagnetic flowmeter according to Claim 1 wherein the measuring tube (10) further includes a mounting tube (12) wrapped around the mounting tube liner (11); wherein the mounting tube (12) has a mounting portion (13); wherein the mounting portion (13) has a through hole communicating with the mounting tube liner (11), and wherein the electrode structure (40) is provided in the mounting portion (13) and penetrates through the through hole in the mounting tube liner (11 ). Electromagnetic flowmeter according to Claim 2 wherein the electrode structure (40) comprises an electrode probe (41) and a support plate (42) disposed around an outer periphery of the electrode probe (41), and wherein the actuator element (50) is disposed on the support plate (42). Electromagnetic flowmeter according to Claim 1 wherein the first outside direction (300) and the second outside direction (400) form an angle (A) in an orthogonal plane of a flow direction of the working fluid. Electromagnetic flowmeter according to Claim 2 wherein the measuring tube (10) further includes an end cap (14) covering the mounting portion (13) and a restricting seat (15) formed in the mounting portion (13); wherein the restriction seat (15) is integrally formed with the mounting tube liner (11) and provided with the through hole. Electromagnetic flowmeter according to Claim 5 wherein the actuator element (50) is a set of piezoelectric elements and wherein two sides of the set of piezoelectric elements of the end cap (14) and the carrier plate (42), respectively Oppose resistance; wherein the set of piezoelectric elements is driven by an external force to deform and wherein the support plate (42) is slid to move the electrode structure (40) toward the mounting tube liner (11) internally and orthogonally a shank of the mounting tube liner (11). Electromagnetic flowmeter according to Claim 5 wherein an inner wall of the restriction seat (15) has a plurality of positioning portions (151); wherein the carrier plate (42) is driven by the actuator element (50) and positioned at one of the positioning portions (151). Electromagnetic flowmeter according to Claim 7 wherein the positioning portion (151) is a hook; wherein the carrier plate (42) has a flat contact surface (421) and an inclined surface (422) adjacent one side of the carrier plate (42); the hook having an inclined guide surface (1511) corresponding to the inclined surface (422) and a flat abutment surface (1512) capable of resisting the support plate (42). Electromagnetic flowmeter according to Claim 1 further comprising a protective capsule (60), wherein the protective capsule (60) is connected to the control module (20) and covers the measuring tube (10). Electromagnetic flowmeter according to Claim 9 further including a plurality of fasteners (70), the protective capsule (60) including a first capsule (61) and a second capsule (62) covering each other; wherein the first capsule (61) and the second capsule (62) are combined with the measuring tube (10) via the fasteners (70), respectively. Electromagnetic flowmeter according to Claim 1 wherein the electromagnetic flowmeter (1) includes a pair of electrode structures (40); wherein each of the pair of electrode structures (40) is individually connected to an actuator element (50); wherein each of the actuator elements (50) is controlled by the control module (20) such that the associated electrode structure (40) is set in motion. Electromagnetic flowmeter according to Claim 1 wherein the external force is a driving force generated by electricity, magnet, light or sound; or wherein the external force is an external mechanical force that drives the pair of the electrode structure to move.

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