KR100993254B1 - Flowmeter - Google Patents

Abstract

PURPOSE: A flow meter is provided to prevent the omission of flow rate by measuring minute flow rate during the flow of fluid. CONSTITUTION: A flow meter comprises a housing(20), a rotor(30), a permanent magnet, a fixture(40), a supporter(50), and a magneto resistive sensor(60). The housing is formed of a single outer case integrated with a lower part and an upper part thereof. The rotor comprises a blade, a support stand, and a rotary shaft. The permanent magnet is inserted into the groove formed in the rotary shaft. The fixture is positioned on the front and rear of the rotor to rotate the rotor. The supporter is installed on the outer circumference of the fixture.

Description

Flowmeter

The present invention relates to a flow meter using a permanent magnet and a magnetoresistive sensor, and more particularly, it is possible to lighten the weight of the blade by placing the permanent magnet on the rotating shaft or the support of the rotor to facilitate the measurement of minute flow rate and more precise flow rate. It relates to a flow meter which can measure.

In general, the flow meter is to accurately measure the amount of fluid used in each home or other use, which is mounted at a predetermined position of the pipe to measure the flow of the fluid through the pipe. Conventionally, a variety of methods have been used with respect to a flow meter for measuring the amount of fluid, such as water, oil, gas, etc. flowing inside the tube, the flow meter can be divided into mechanical or electronic depending on its operation.

The mechanical flowmeter is a method of measuring the amount of usage by directly displaying the amount of rotation as the impeller or rotor rotates as the impeller or rotor rotates, and by attaching a permanent magnet to the impeller or rotor to the mechanical gear as the impeller or rotor rotates. A method has been used in which the attached permanent magnet rotates and the rotation speed of the mechanical gear is integrated to measure the amount of usage.

However, the mechanical flowmeter as described above rotates because a plurality of gears are engaged with each other, so that the gears wear out and the gears are misaligned when used for a long period of time, and foreign matter is caught between the gears. There was a problem in that accurate metering could not be achieved because a large error gradually occurred between the amount of the used fluid and the value measured by the flow meter.

Therefore, in order to solve the above problem, the electromagnetic flowmeter is used a lot. Electronic flowmeters use a method of installing a permanent magnet on an impeller or a rotor, and installing a permanent magnet or a sensor outside thereof to measure the number of fluids by measuring the rotational speed by magnetic force or interaction of the magnet.

Republic of Korea Utility Model No. 364971 is to install a permanent magnet on the blade of the impeller that rotates in accordance with the flow of fluid in the main body having an inlet and outlet, and a pair of reed switch is installed on the cover plate to measure the flow rate of the waste of fluid It is made to prevent the rotation failure caused by, and to detect the error caused by the backflow of the impeller.

However, according to the conventional technology, the signal input of the reed switch installed at a predetermined angle is difficult to distinguish between the normal flow and the reverse flow as a continuous pulse signal, and when the impeller rotates rapidly, the sensor is attached to the impeller. Inaccurate detection results in errors in flow measurement.

In addition, as shown in FIG. 1A, Patent Application No. 10-400405, filed and registered by the present applicant, has a connection portion 401 formed at both ends to be connected to a pipe, and both ends of the opening shape having an inner diameter equal to that of the pipe. A flow meter body 400; A rotating body 410 disposed on an inner circumference of the flowmeter body 400 having a plurality of blades 411 at an angle with respect to the inflow direction of the fluid; The front and rear fixed body 421 which is disposed inside the flow meter body 400 corresponding to the front and rear of the rotating body 410 to rotatably support the rotating body 410 via the rotating shaft 440. 431; A plurality of supporters 422 and 432 installed on the outer circumferential surfaces of the front and rear fixing bodies 421 and 431 at regular intervals to be fixed to the inner surface of the flowmeter main body 400; A plurality of magnetic inductors 450 installed at ends of the blades 411 of the rotating body 410 and made of a material capable of magnetization; A pickup sensor 460 installed at the flow meter body 400 corresponding to the blade 411 to sense the magnetic inductor 450; Computing means for sensing the fluid flowing inside the flowmeter main body 400 by the pickup sensor 460 to receive the detected signal and the display means 470 to visually display the flow rate connected by the calculating means Consists of.

The prior art as described above uses a pickup sensor 460 as a detection means, the pickup sensor 460 is a method of generating induced electromotive force by the rotation of the blade 411, so the rotational speed of the blade 411 When is very slow, the induced electromotive force hardly occurs, so there was a limit in detecting the small flow rate. In addition, the pick-up sensor 460 using the induced electromotive force has a problem that the induced electromotive force is generated when there is a vibration or impact of the sensor unit due to the structure of the sensor and malfunctions regardless of the actual flow rate.

In addition, as shown in FIG. 1B, in order for the magnetic inductor 450 to be installed at the end of the blade 411, the thickness of the blade 411 must be thicker than the magnetic inductor 450. That is, in order to increase the sensitivity of the magnetic inductor 450, the size of the magnetic inductor 450 should be increased or the weight should be heavy. Accordingly, the weight of the blade 411 becomes naturally heavy. Therefore, when the amount of the fluid flowing inside the flow meter is small, there is a problem that it is impossible to measure the minute flow rate because of insufficient force to rotate the blade 411.

Similarly, as shown in FIG. 2A, Patent No. 10-412335, filed and registered by the present applicant, calculates a flow rate of a fluid flowing in a pipe and calculates a detected signal and calculates the detected signal. A flowmeter comprising display means for visually displaying the flow rate, comprising: a flow meter body (400) having an opening portion at both ends and having an inner diameter equal to the inner diameter of the pipe, the connecting portion (401) being formed at both ends; A rotating body 410 disposed on an inner circumference of the flowmeter body 400 having a plurality of blades 411 at an angle inclined with respect to an inflow direction of the fluid; The front and rear fixed body 421 which is disposed inside the flow meter body 400 corresponding to the front and rear of the rotating body 410 to rotatably support the rotating body 410 via the rotating shaft 440. 431; A plurality of supporters 422 and 432 installed on the outer circumferential surfaces of the front and rear fixing bodies 421 and 431 at regular intervals and fixed to the inner surface of the flowmeter main body 400; Permanent magnet 451 is installed at the end corresponding to the inflow direction of the fluid of the both ends of the blade (411) of each of the rotating body (410); The MR sensor 461 is installed in the flowmeter main body 400 so as to be close to the blade 411 and outputs a signal obtained by sensing the permanent magnet 451 to the calculation means.

As described above, the MR sensor 461 instead of the pick-up sensor 460 has an advantage that the rotation of the permanent magnet 451 located on the blade 411 can be precisely measured even at a low rotational speed. As shown in FIG. 2B, the permanent magnet 451 is installed at an end portion corresponding to the inflow direction of the fluid among the blades 411 of each of the rotors, so that the thickness of the blade 411 is the permanent magnet. It must have been thicker than the size of (451). Similarly, when the amount of the fluid flowing inside the flowmeter is small, there is a problem in that it is impossible to measure the minute flow rate because of insufficient force to rotate the blade 411.

In order to solve the above problems, there is a method of increasing the size of the permanent magnet used in the flowmeter to increase the magnetic force, increasing the number of sensors capable of detecting the magnetic force of the permanent magnet, or increasing the sensitivity of the sensor used. In order to increase the magnetic force of the permanent magnets, the size of the permanent magnets must be larger, and accordingly, the weight of the magnets and the blades becomes heavier, thereby increasing the resistance in the rotation of the impeller or the rotor and there is a problem in that accurate measurement cannot be performed. In addition, when the number of sensors or the method of increasing the sensitivity of the sensor is used, the cost of manufacturing the flowmeter becomes too high, and there is a problem that it cannot be practically used.

An object of the present invention for solving the above problems,

When the fluid flows, it is possible to measure the minute flow rate so that there is no missing flow rate, and at the same time to insert a protective tube of environmentally friendly synthetic resin material inside the flowmeter to further prevent corrosion of the flowmeter.

The configuration of the present invention for achieving the above object,

A housing made of a single cylindrical outer shell, a rotor having a plurality of blades inclined at a predetermined angle with respect to the inflow direction of the fluid flowing into the housing, a permanent magnet attached to a predetermined position of the rotor, the permanent magnet It includes a magnetoresistive sensor that is located in close proximity to detect the electrical signal induced by the rotation of the permanent magnet and the indicator for calculating and displaying the amount of fluid passing through the electrical signal from the magnetoresistive sensor.

The permanent magnet may be attached to the rotating shaft or the support of the rotor, the magnetoresistive sensor preferably includes a reverse flow detection function for detecting the reverse rotation of the permanent magnet, the inner diameter of the housing to the inside of the housing It is preferable to further include a protective tube inserted in close contact and made of a synthetic resin material.

In addition, the indicator is preferably made of a microprocessor and an image output device, the housing further comprises a wireless transmission unit for wirelessly transmitting an electrical signal from the magnetoresistance sensor, the indicator is a wireless reception of the electrical signal It further comprises a wireless receiving unit, wherein the indicating unit preferably receives an electrical signal generated from the magnetoresistive sensor by a wireless communication method.

In addition, the wireless receiving unit for receiving the electrical signal is preferably a portable wireless communication device or a wireless communication device that can be attached to the vehicle, the wireless communication method is a local area network (WLAN), code division multiple access ( Selected and used among CDMA) wireless network, satellite communication network using GPS, Zigbee wireless network, wireless network using infrared communication, and Bluetooth wireless network. More preferably.

The effect of the present invention having the configuration as described above,

By installing a permanent magnet on a rotating shaft or a support without installing a magnetic inductor or permanent magnet at the blade end of the rotor, more accurate flow rate measurement is possible. That is, a larger permanent magnet can be installed than the permanent magnet at the end of the blade and can be detected by a magnetoresistive sensor, thereby measuring a fine flow rate.

In addition, since the permanent magnet is attached to a rotating shaft or a support rather than the blade, the blade can be made very thin. Accordingly, the rotor can be easily rotated, even when there is a fine flow or a very low flow rate. Since the rotor can rotate, the flow rate can be measured, thereby minimizing the error in the flow rate measurement.

In addition, the reverse rotation of the permanent magnet can be detected by adding a reverse flow detection function to the magnetoresistive sensor that detects the permanent magnet or by installing a separate reverse flow sensor. Even when the fluid is backflowed arbitrarily, the amount of fluid flowing back can be measured, so that the amount of fluid used can be measured more accurately without dropping.

In addition, by inserting a protective tube made of a synthetic resin material further inside the housing through which the fluid flows to prevent corrosion of the housing made of a metal material, it is possible to prevent the mixing of impurities in the fluid flowing inside the flowmeter have.

In addition, since the communication between the housing and the indicator can be performed using various methods of wireless communication, the flowmeter can be installed even at a position where the indicator cannot be directly measured, and the radio receiver that receives the electrical signal can be carried wirelessly. Since the communication device can be configured as a communication device, the flow rate of the fluid can be measured while freely moving within the range in which the wireless communication is possible, so that the flow rate can be measured easily and quickly.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing the internal configuration of the flow meter 10 according to the present invention. The present invention is similar to the conventional flow meter, the cylindrical housing 20, the rotor 30 having a plurality of blades 31 located inside the housing 20, and the rotating shaft of the rotor 30 (33) or the permanent magnet 34 attached to the support 32, the magnetoresistive sensor 60 located in close proximity to the permanent magnet 34, and receives the electrical signal from the magnetoresistive sensor 60 And an indication unit 70 for calculating and displaying the amount of the fluid passing through it.

The housing 20 is formed in a cylindrical shape through both ends, the inner diameter is preferably formed to be the same as the inner diameter of the pipe to be connected so that the flow rate of the fluid does not occur. In addition, since the housing 20 may be manufactured in a single outer shell, the housing 20 may be manufactured to be completely circular, so that the inner diameter of the housing 20 and the center of the rotor 30 may be accurately set. Straightness can be greatly improved, and the weight of the flowmeter can be lighter and easier to handle.

The fixing body 40 and the supporter 50 are attached to the inside of the housing 20, and the fixing body 40 is disposed before and after the rotor 30 among the housings 20, so that the rotor It serves to support the rotatable 30. In this case, the rotation shaft 33 formed on the rotor 30 may be formed in advance in the fixed body 40, or may be formed in advance to protrude in the center of both ends of the rotor (30).

The supporter 50 is installed at regular intervals radially on the outer circumferential surface of the fixed body 40 to allow fluid to flow into the housing 20, and the other end is provided on the inner surface of the flowmeter housing 20. It is preferable to be fixed.

As shown in FIG. 4, the rotor 30 rotatably connected to the fixed body 40 has a plurality of blades inclined at a predetermined angle with respect to an inflow direction of the fluid flowing into the housing 20. (31), the support (32) to which the blade 31 is attached to receive the resistance, the rotary shaft 33 is located in the center to allow the rotor 30 to rotate and the rotor 30 is inserted It consists of a permanent magnet 34 is made.

When the fluid is introduced into the flowmeter, each blade 31 of the rotor 30 is resisted by the fluid, thereby causing the rotor 30 to rotate, the fluid between each blade 31 It exits the flowmeter through and flows into the pipe. At this time, as the rotor 30 rotates, the permanent magnet 34 inserted into the rotor 30 rotates at the same time, and the rotation of the permanent magnet 34 causes the magnet located outside the rotor 30 to rotate. The resistance sensor 60 may detect and measure the flow amount of the fluid.

The rotor used in the related art as shown in FIGS. 1B and 2B was attached with a magnetic derivative or permanent magnet to measure the rotation of the rotor and to measure the amount of fluid flowing inside the flowmeter. However, since the magnetic derivative or permanent magnet is inserted into the blade of the rotor, the magnetic derivative or permanent magnet has to be maintained at a thickness greater than a predetermined thickness in order to be stably inserted. Accordingly, it was not easy to measure the flow of a small amount of fluid by reducing the weight of the blade, and the amount of the missing fluid was large.

In other words, if the size of the permanent magnet attached to the blade is reduced, the weight of the blade can be reduced, but it is difficult to detect the permanent magnet. If the size of the permanent magnet attached to the blade is increased, the detection is easy, but the blade is There was a problem in that the resistance required to rotate thickened to increase, so that the flow of minute flow rates could not be detected.

In the present invention, in order to enable the rotation of the rotor 30 even in the presence of a minute flow rate, the blade 31 is manufactured to have a small thickness to minimize the weight, and thus the permanent magnet 34 is the blade 31. It is characterized in that the manufacturing to be positioned on the rotary shaft 33 or the support (32).

In FIG. 5, the permanent magnet 34 is attached to the support 32 of the rotor 30. In FIG. 6, the permanent magnet 34 is attached to the rotation shaft 33 of the rotor 30. The figure is shown. Of course, the permanent magnet 34 may be attached to either the support 32 or the rotation shaft 33 may be attached to both.

In addition, in order to better sense that the permanent magnet 34 is rotated, a larger permanent magnet 34 may be used. In this embodiment, the permanent magnet 34 attached to the blade 31 is 1. Although illustrated as a dog, a plurality of rotor 30 may be attached around the rotating shaft 33 and the support 32 in order to measure the rotation value more accurately even if only part of the rotation.

MR sensor is mainly used as a magnetoresistive sensor 60 for detecting the rotation of the rotor 30. If a magnetizing sensor 60 generates a detection signal according to the rotation of the rotor 30 detected by the magnetoresistive sensor 60, The detection signal is sent to the microprocessor (not shown) included in the indicating unit 70, the microprocessor calculates the amount of fluid in accordance with the received detection signal and delivers a signal output to the image output device (not shown) The amount of fluid used is output to the image output device.

The magnetoresistive sensor 60 uses a principle of magnetic induction, in which a voltage is generated when a coil is wound around the permanent magnet 34 to reach a conductor, and is mainly used to check the speed or position of the rotating shaft 33. . That is, when the magnetoresistance sensor 60 is attached to the rotor 30 and the rotor 30 is attached to the rotating rotor 30, the magnetic poles of the N and S poles alternate with each other to change the magnetic field strength. As a result, the resistance value changes, and thus, a sinusoidal voltage is repeatedly generated. The rotation speed of the rotor 30 may be measured by measuring a time for completing the sinusoid or by measuring a frequency generated. The magnetoresistive sensor 60 has a fast response speed, high sensitivity in a weak magnetic field, and is hardly affected by dust, oil, or the like, so that more accurate flow rate measurement is possible.

In addition, the magnetoresistive sensor 60 preferably includes a reverse flow detection function for detecting the reverse rotation of the permanent magnet 34, the magnetic field strength of the permanent magnet as a method for detecting the reverse rotation It is more desirable to use a method of sensing that the direction of the repeated sinusoidal voltage changes as it changes. In addition, a reverse flow sensor (not shown) may be further installed in proximity to the magnetoresistive sensor 60 to independently detect reverse rotation of the rotor 30. The backflow detection sensor may use a known backflow detection sensor such as a cyble sensor.

According to the method as described above, since the rotor 30 can be accurately measured up to the number of times of reverse rotation, the amount of fluid flowed back due to the backflow due to the defect of the device or the intention of the user can be measured. The advantage is that you can measure usage.

The protective tube 80 shown in Figure 3 is preferably inserted in close contact with the inner diameter of the housing 20 to the inside of the housing 20, the protective tube 80 is more preferably made of a synthetic resin material. Accordingly, since the fluid flowing in the housing 20 is completely isolated from the housing 20, it is possible to prevent corrosion of the housing 20 made of a metal material, and to mix impurities in the fluid flowing inside the flowmeter. It can prevent.

Synthetic resin material used in the protective tube 80, polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polyamide (polyamide), polyethylene (polyethylen), polypropylene ( polypropylene) may be used, and two or more kinds of these materials may be mixed and used.

The indicator unit 70 receives a guided electric signal detected by the magnetoresistive sensor 60 and calculates the amount of fluid passing therethrough, and the outside of the measuring unit according to the output signal received from the microprocessor. And an image output device for displaying.

The microprocessor receives a sinusoidal induction electric signal generated in accordance with the rotation of the rotor 30, calculates the rotational speed of the rotor 30 by calculating the electric signal according to a pre-stored value, and the rotor It calculates the amount of fluid passing through the flowmeter according to the rotation speed of 30, and controls the entire process of transferring the resulting output signal to the image output device for display.

LCD or LED may be used as the image output device, and the instantaneous flow rate and the accumulated flow rate can be displayed at the same time so that the observation is easy. The total flow rate can be selected as Grand Total and Sub Total. It is possible to switch to, so record management is very easy. In addition, it is possible to further check the battery replacement time by further adding a battery remaining indicator for displaying the remaining battery of the battery used in the flow meter can minimize the amount of missing in the flow rate measurement. A battery may be used to supply power to the indicator unit 70 having the above configuration, and may also be directly connected to an external power source.

In addition, after measuring the number of revolutions of the rotor 30, and transmitting it to the microprocessor of the indicator 70 may be used both wired or wireless transmission. That is, when the indicator 70 is coupled to the housing 20 or located in close proximity to the housing 20, a signal may be transmitted by using a wired transmission method, and the wired connection method is easy because it is far from the housing 20. If not, the housing 20 further includes a wireless transmission unit for wirelessly transmitting an electrical signal from the magnetoresistive sensor 60, and the indicating unit 70 further includes a wireless receiving unit for wirelessly receiving the electrical signal. In addition, the indicator 70 may receive an electrical signal generated from the magnetoresistive sensor 60 by a wireless communication method.

Such wireless communication methods include a local area network (WLAN), a code division multiple access (CDMA) wireless network, a satellite communication network using GPS, a Zigbee wireless network, and infrared communication. Wireless networks capable of exchanging information may be employed, such as wireless networks using lazer communication, wireless networks of Bluetooth type, and the like. In addition, in the communication network between the wireless transmitter and the wireless receiver, communication may be performed via a normal repeater in consideration of the magnitude of the information amount and the range of signal amplification and reception.

In addition, in receiving the electrical signal wirelessly transmitted from the wireless transmitter to the wireless receiver, the portable radio communication device including the wireless receiver can be directly carried by the measurer to move freely within the range where wireless communication is possible. While measuring the flow amount of the fluid can be measured.

In addition, by attaching the wireless receiver to the movable vehicle to receive the electrical signal transmitted from each flow meter as the vehicle moves, it is also possible to measure the flow amount of the fluid by receiving the electrical signal while moving a wide range have.

In addition, a pulse correction device (not shown) may be further added to the indicating unit 70. When the microprocessor receives the induced electric signal generated by the rotor 30 and converts it into an output signal, the pulse compensator is in a necessary range when the output signal does not match the minimum integration unit of the indicating unit 70. Since the pulse is corrected to be displayed on the image output device, it can be easily used according to the needs of the user.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1A is a cross-sectional view showing the internal configuration of a conventionally used flow meter.

Figure 1b is a perspective view showing a rotating body of a conventional flow meter.

2A is a cross-sectional view showing the internal configuration of a conventionally used flow meter.

Figure 2b is a perspective view showing a rotating body of a conventional flow meter.

3 is a cross-sectional view showing the internal configuration of the flow meter according to the present invention.

4 is a perspective view showing the rotor of the flow meter according to the present invention.

5 is a plan view showing the rotor of the flow meter according to the present invention.

6 is a side view showing the rotor of the flow meter according to the present invention.

Description of the Related Art

10: flow meter 20: housing

30: rotor 31: blade

32: support 33: axis of rotation

34: permanent magnet 40: fixed body

50: supporter 60: magnetoresistance sensor

70: indicator 80: protection officer

Claims (12)

delete In the flow meter, A housing 20 formed of a cylindrical shape having a constant inner diameter consisting of a single outer shell having an upper portion and a lower portion integrally formed thereon; A plurality of blades 31 inclined at a predetermined angle with respect to the inflow direction of the fluid flowing into the housing 20, one side of the blade 31 is attached to form an inclined and cylindrical along the outer circumference and the cylindrical support 32, one or more grooves are formed from the outer surface toward the inside, and is formed so as to penetrate the central portion of the support 32 to rotate the blade 31 and the support 32 is rotatable 33 Rotor 30; A permanent magnet 34 fitted into the groove formed in the rotation shaft 33 to be parallel to an outer circumference of the rotation shaft 33; A fixed body (40) disposed before and after the rotor (30) to support the rotating shaft (33) so that the rotor (30) is rotatable; A supporter 50 installed at an outer circumferential surface of the fixed body 40 at regular intervals so that the other end is fixed to an inner surface of the flowmeter housing 20; Extends from an upper portion of the housing to be in close contact with one side of the support 32 and an outer circumferential surface of the rotation shaft 33, and detects a forward electrical signal induced by rotation of one direction of the permanent magnet 34; Magnetoresistive sensor 60 for sensing the electrical signal of the reverse direction induced by the rotation in the opposite direction; A microprocessor that receives the electrical signal sensed by the magnetoresistive sensor 60 and calculates the amount of fluid passing through the magnetoresistive sensor 60. An image output device for selectively converting oil flow rate to be displayed externally, a pulse compensator for selectively converting and outputting the output signal into a correction pulse and an uncorrected pulse according to the needs of the measurement instrument, and displaying the remaining amount of the battery powered An indicator 70 including an indicator for predicting remaining battery power; It is inserted into the housing 20 to be in close contact with the inner diameter of the housing 20 to isolate the fluid between the housing 20 and the inside of the polyethylene (PE) material that is detachably coupled to the housing 20 Including the protective tube 80, The housing 20 further includes a wireless transmitter for wirelessly transmitting the electrical signal detected by the magnetoresistive sensor 60, and the indicator 70 further includes a wireless receiver for wirelessly receiving the received electrical signal. When the indicating unit 70 receives the electrical signal from the magnetoresistive sensor 60, the local area network type wireless network (WLAN), code division multiple access (CDMA) type wireless network, satellite navigation device (GPS) The electrical signal is received by a wireless communication method selected from a satellite communication network, a Zigbee wireless network, a wireless network using an infrared communication, and a Bluetooth wireless network. The wireless receiver is a wireless communication device configured to be portable by a measurer or a wireless communication device configured to be attachable to a vehicle. In the flow meter, A housing 20 formed of a cylindrical shape having a constant inner diameter consisting of a single outer shell having an upper portion and a lower portion integrally formed thereon; A plurality of blades 31 inclined at a predetermined angle with respect to the inflow direction of the fluid flowing into the housing 20, one side of the blade 31 is attached to form a predetermined inclined and cylindrical along the outer circumference At least one groove is formed toward the inside from the outer surface 32, the rotary shaft 33 is positioned so as to penetrate the center of the support 32 so that the blade 31 and the support 32 is rotatable A rotor 30 formed; A permanent magnet 34 fitted into the groove formed in the support 32 to be parallel to one side of the support 32; A fixed body (40) disposed before and after the rotor (30) to support the rotating shaft (33) so that the rotor (30) is rotatable; A supporter 50 installed at an outer circumferential surface of the fixed body 40 at regular intervals so that the other end is fixed to an inner surface of the flowmeter housing 20; Extends from an upper portion of the housing to be in close contact with one side of the support 32 and an outer circumferential surface of the rotation shaft 33, and detects a forward electrical signal induced by rotation of one direction of the permanent magnet 34; Magnetoresistive sensor 60 for sensing the electrical signal of the reverse direction induced by the rotation in the opposite direction; A microprocessor that receives the electrical signal sensed by the magnetoresistive sensor 60 and calculates the amount of fluid passing through the magnetoresistive sensor 60. An image output device for selectively converting oil flow rate to be displayed externally, a pulse compensator for selectively converting and outputting the output signal into a correction pulse and an uncorrected pulse according to the needs of the measurement instrument, and displaying the remaining amount of the battery powered An indicator 70 including an indicator for predicting remaining battery power; It is inserted into the housing 20 to be in close contact with the inner diameter of the housing 20 to isolate the fluid between the housing 20 and the inside of the polyethylene (PE) material that is detachably coupled to the housing 20 Including the protective tube 80, The housing 20 further includes a wireless transmitter for wirelessly transmitting the electrical signal detected by the magnetoresistive sensor 60, and the indicator 70 further includes a wireless receiver for wirelessly receiving the received electrical signal. When the indicating unit 70 receives the electrical signal from the magnetoresistive sensor 60, the local area network type wireless network (WLAN), code division multiple access (CDMA) type wireless network, satellite navigation device (GPS) The electrical signal is received by a wireless communication method selected from a satellite communication network, a Zigbee wireless network, a wireless network using an infrared communication, and a Bluetooth wireless network. The wireless receiver is a wireless communication device configured to be portable by a measurer or a wireless communication device configured to be attachable to a vehicle. delete delete delete delete delete delete delete delete delete

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