KR101479648B1 - Volumetric flow meter - Google Patents

Abstract

The present invention is to improve accuracy of detecting a supply amount of a flow rate according to a detection of a location of a magnetic sensor installed on a supporting plate on a mark sensing device after sensing a rotor rotation of a volumetric flow meter, and transmitting the same in a gear method. The volumetric flow meter of the present invention comprises: a flow rate detecting part where a pair of driving gears and a flowing gear are installed in an upper part of a rotary axis wherein a rotor is installed inside a body connected with a flange in between a pipe; a mark sensing device detecting a rotary force delivered to an upper part of the flow rate detecting part through a conversion axis; and a flow rate displaying part converting a signal of the mark sensing device into a digital signal.

Description

[0001] The present invention relates to a volumetric flow meter,

The present invention relates to a volumetric flow meter, and more particularly, to a volumetric flow meter that senses a flow rate of a flowing type oil flowing through a channel, To represent the flow rate digitally; The present invention relates to a volumetric flow meter that combines magnetism with a magnetic insertion hole provided on the sensing plate and easily fixes the magnet by inserting a fixing groove on both sides of the insertion hole of the magnetic sensor, and improves detection efficiency according to installation of the magnet.

Conventionally, steam, gas, low-viscosity liquid, etc. are supplied through a pipeline. A flow meter is installed in a part of the pipeline, and the flow rate of the flowing species is measured and detected.

These flowmeters must have very high precision of measurement, and the installation conditions are poor, so that when the flow rate detection part of the flowmeter is abnormal, it is impossible to cut off the flow path or disassemble the pipeline, so that the durability characteristic is given the highest priority. An excellent orifice flowmeter was installed.

However, since the orifice flowmeter requires a separate installation pipe, it has a large installation space and is greatly influenced by the shape of the pipe and the flow state of the fluid. Therefore, the flow measurement accuracy is low and the pressure loss is large. have.

Recently, measurement accuracy is high and flow meters are being replaced by flow meters that are not affected by density, pressure, and temperature and are suitable for hazardous or toxic fluids.

On the other hand, high accuracy and costly volumetric flowmeters are often used to measure accurate flow rates related to sales such as fuel and other oils.

For example, when shipping a product from an oil refinery, when moving expensive oil or petrochemical feedstock from one storage tank to another, such as a petrol station or a central heating system, They are transferred using oil tanks (tank lorries, etc.).

At this time, the oil tanker is equipped with a volumetric flowmeter for accurately measuring the flow rate of the oil, and a totalizer (electronic integration counter) for setting the flow rate desired by the consumer so that the supplied flow rate can be easily confirmed.

Such a volumetric flowmeter can be classified into an electromagnetic type and a mechanical type, and since the present invention relates to a mechanical flowmeter using a rotor, the description of the electromagnetic type is omitted.

 In a conventional mechanical flowmeter, a pair of rotors are axially coupled to an inside of a housing forming an outer tube. One end of the housing is formed with an inflow portion for inflow of fluid into the housing, and at the other end of the housing, A discharge portion of a fluid discharging fluid from the inside to the outside is formed and a flange portion to which a pipe is coupled is generally formed at an end portion of the inlet portion and a discharge portion.

Such a mechanical flowmeter has a pair of rotors rotating in opposite directions with each other being engaged with each other so that the fluid flowing through the inlet of the housing flows through a rotating space provided with a pair of rotors rotating in the engaged state, Direction, and the fluid is discharged to the outside of the flow meter while being pushed by the fluid conveyed by the rotor, which is continuously rotated.

However, in the conventional mechanical flowmeter, various measurement errors occur in the course of the flow of the fluid being transferred by the rotational motion of the rotor.

A conventional mechanical flowmeter is a system in which two rotatable meshing rotors are inserted into a housing circumscribing them and the rotor is rotated to allow the fluid to flow through the space between the rotor and the inner wall of the housing, A minute gap is formed between the rotor and the inner wall of the housing.

There are two types of clearance between the rotor and the inner wall of the housing. There are two types of clearance between the rotor and the inner wall of the housing: a clearance between the tooth tip of the rotor and the inner wall of the housing; top clearance; That is the niche that exists, the side clearance.

Therefore, when the rotor is rotated by the energy of the fluid to be measured, there is a slight leakage from the inlet side to the outlet side due to the leakage in the clearance, and the error of the flow rate measurement occurs. Such a leakage amount is much larger in the side clearance side than in the top clearance side .

This is because the fluid introduced through the inlet of the housing will enter into a strong pressure without any resistance to the side clearance. For this reason, prevention of fluid leakage through the side clearance has the greatest effect on improving the accuracy of the flowmeter.

Also, in a mechanical flow meter, when a pair of rotors rotates, fluid sometimes leaks to various connecting portions of the housing connected to the rotating space, which also causes a flow measurement error.

In the case of a conventional mechanical flow meter using an oval gear as the rotor, the inside of the oval gear is empty, and the flowing fluid is also filled in the inside of the oval gear.

Therefore, when the oval gear, which is an elliptical gear performing the non-uniform motion, rotates, the mass moment of inertia rises and the filled fluid causes frictional resistance when the oval gear rotates inside the oval gear. This causes instability in the rotation of the oval gear Thereby causing an increase in the amount of fluid leakage through the top clearance, which causes an error in the flow measurement.

It is also ideal that both side surfaces of the oval gear rotate in a floating manner with the gap between the inner wall of the housing and the rotating side of the oval gear. In actual rotation, however, The frictional resistance is inevitably generated, which hinders precise measurement of the flow rate.

In order to solve the problems described above, conventionally, a method of minimizing the clearances and obtaining homogeneity of the rotor rotational motion by precisely machining the rotor and the housing has been used. In this case, There arises a problem in that it becomes disadvantageous in terms of the aspect.

Particularly, in the conventional sensing apparatus, when detecting rotation of the plate, the detection error occurs when sensing one rotation of the plate, so that accuracy is degraded.

Literature 1. Patent Registration No. 0163353 (registered on May 09, 1998) Document 2. Patent Registration No. 0556014 (registered on February 21, 2006) Literature 3. Patent Publication No. 1996-015059 (registered on October 24, 1996) Document 4. Patent Registration No. 0629027 (registered on September 20, 2006)

Accordingly, the present invention has been made to solve the conventional drawbacks, and it is an object of the present invention to provide a mark sensing device for sensing the rotation of a rotor of a volumetric flow meter, And an object of the present invention is to improve the accuracy of the supply amount detection of the flow rate.

The present invention relates to a flow rate sensing device having a pair of driving gears and a pair of driving gears disposed above a rotating shaft provided with a rotor inside a body connected to a flange between pipelines, A mark sensing device for sensing the signal when the signal is transmitted; and a flow rate display unit for digitizing the signal of the mark sensing device; The mark sensing device includes a sensing plate for fixing a magnetic sensor through a sensing axis connecting a conversion axis with a connection member and forming a plurality of magnetic insertion holes at regular intervals in a circumferential direction; A sensing sensor installed at the upper side of the sensing plate and sensing a rotation of the magnetic sensor to send a signal having improved resolution to a flow rate display unit; An upper case provided above the sensing shaft and fixed to the housing at an assembly hole; And a lower case coupled to the upper case with a fastening bolt and through which a sensing shaft passes,
Wherein the sensing plate is installed such that a magnetic sensor is coupled to a magnetic insertion hole formed in a range of 10 to 50 in a circumferential direction through a sensing axis and a magnetic sensor is fixed to both sides of the magnetic sensor with a magnetic fixing groove, will be.

delete

delete

delete

delete

The present invention detects rotation of a rotor of a volumetric flow meter and transmits it in a gear mode, and then detects a position of a plurality of magnetic sensors installed at equal intervals on a sensing plate in a mark sensing device, It is possible to improve the accuracy of the supply amount detection of the flow amount due to the improvement of the resolution, thereby providing reliability.

The present invention provides an effect of detecting a change in position of a magnetic sensor with a sensor and accurately displaying the flow rate digitally and providing an effect that a plurality of magnetic sensors can be installed on the detection plate at an equal interval quickly and easily at an accurate position will be.

1 is a front view showing an embodiment of a volumetric flow meter of the present invention;
2 is a cross-sectional view of the volumetric flowmeter of the present invention
3 is a cross-sectional view of the mark sensing device of the present invention
4 is a plan view of the sensing plate for the mark sensing device of the present invention
5 is an enlarged cross-sectional view of the magnetic sensor of the present invention,

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

FIG. 1 is a front view showing an embodiment of a volumetric flowmeter of the present invention, and FIG. 2 is a sectional view of a volumetric flowmeter according to the present invention.

A volumetric flow meter 10 installed at a portion of a conduit 16 for supplying steam, gas, low viscosity liquid or the like forms a flange 15 on both sides of the body 11 and is fixed And a flow sensing unit 20 having a lower cover 12 formed on the lower side of the body 11 and an upper cover 13 formed on the upper side thereof.

A pair of rotary shafts 21 are installed at predetermined intervals in the body 11 so that the loader 25 is rotated and a driving gear 22 is mounted on the rotary shaft 21 to rotate the flowering gear 23 So that the rotational force is transmitted.

A mark sensing device 30 for sensing the flow rate of the flow rate sensing part 20 and sensing the flow rate of the flow rate sensing part 20 is installed on the upper side of the conversion shaft 24 which rotates in accordance with the rotation of the flow gear 23.

The mark sensing device 30 is connected to the lower side of the housing 14 and a flow rate display part 40 is provided on the upper side of the housing 14 to connect the mark sensing device 30 and the flow rate display part 40 So that the flow rate can be digitally displayed.

3 is a sectional view of the mark sensing device of the present invention. The mark sensing device 30 installed in the housing 14 is connected to the sensing shaft 33 via the connecting member 33a, And the sensing shaft 33 is connected to the lower case 32 on the lower side and the upper case 31 on the upper side via the bearings 33b.

A sensing plate 34 is connected to the sensing shaft 33 to detect a flow rate of the sensing plate 34.

In the upper case 31, a sensing shaft 33 is rotatably coupled to a central bearing 33b, and at least two line connecting holes 31a are formed in the upper case 31. The flow rate indicator 40 and the MR sensor 35, and a plurality of through holes 31b are formed so as to allow ventilation for discharging the heat generated from the internal sensor 35 to the outside, and then an assembly hole 31c formed at the outer end, To the housing (14).

The lower case 32 is formed with a coupling step 32b on its upper side to be assembled with the upper case 31 and coupled with the upper case 31 with a fastening bolt 32a.

A sensing sensor 35 is installed above the sensing plate 34 to sense a flow rate of the sensing signal.

FIG. 4 is a plan view of a sensing plate for a mark sensing device of the present invention, and FIG. 5 is an enlarged cross-sectional view of a magnet sensor for a sensing plate of the present invention.

The detection plate 34 formed in a circular shape penetrates the detection shaft 33 at the center and has a magnetic insertion hole 34a formed at regular intervals in the circumferential direction to insert the magnetic sensor 36, The magnetic sensor 36 can be fixed by pressing the magnetic fixing grooves 34b at both sides thereof.

Although the number and size of the magnetic insertion holes 34a can be adjusted, it is preferable to install the magnetic insertion holes 34 in a range of 10 to 50 because the number of the magnetic insertion holes 34a increases.

In the present invention having such a configuration, the channel 16 is connected to both sides of the body 11 of the volumetric flow meter 10 by using the flange 15. The flow sensing unit 20 is provided with mark sensing The apparatus 30 and the flow rate display unit 40 are continuously installed.

The rotor 25 is rotated by the fluid in the process of supplying steam, gas, low-viscosity liquid, etc. through the pipeline 16, and the rotary shaft 21 is rotated by the rotation of the rotor 25, (22) and the floating gear (23) rotate.

The sensing shaft 33 rotates through the connecting member 33a because the floating gear 23 rotates the conversion shaft 24. [

As the sensing shaft 33 rotates, the sensing plate 34 connected thereto integrally rotates, and the sensing sensor 35 senses the rotation of the sensing plate 34.

The signal sensed by the sensing sensor 35 is transmitted to the flow rate display unit 40 through an electric wire and converted into a digital signal.

Here, since the magnetic sensor 36 is installed in the magnetic insertion hole 34a of the sensing plate 34, the sensor 35 senses the sensing signal through the magnetic sensor 36 according to the rotation of the sensing plate 34, To the flow rate display unit (40).

At this time, since a plurality of magnetic sensors 36 are installed at a very short distance in the range of 10 to 50 in the circumferential direction, it is possible to improve the resolution through the sensing sensor 35 and to accurately sense the supply amount of the flow amount .

The number of the magnetic sensors 36 can be adjusted in the circumferential direction, and the sensing sensor 35 can be used for a long time by installing a battery by implementing a low power consumption by using the MR sensor.

Particularly, since the magnetic sensor 36 is fixed by pressing the magnetic fixing grooves 34b on both sides of the magnetic insertion hole 34a, it is possible to quickly fix a plurality of magnets. Therefore, will be.

The sensing plate 34 provided with the magnetic sensor 36 is manufactured by assembling the lower case 32 and the upper case 31 in a state where they are integrally formed with the fastening bolts 32a, It is possible to protect it.

The present invention is to detect the flow rate sensed by the flow rate sensing unit in the volumetric flow meter by a mark sensing device and to digitally display the flow rate on the flow rate display unit and to improve the resolution by installing a plurality of magnetism sensors on the sensing plate of the mark sensing device It is possible to precisely sense the flow rate, thereby reducing the error of the flow rate.

10: volumetric flow meter 11: body
12: lower cover 13: upper cover
14: housing 15: flange
16: pipeline 20: flow rate sensing unit
21: rotating shaft 22: driving gear
23: Flowing gear 24: Conversion axis
25: rotor 30: mark sensing device
31: upper case 31a: line connecting hole
31b: through hole 32: lower case
32a: fastening bolt 32b:
33: sensing shaft 33a: connecting member
33b: bearing 34: sensing plate
34a: Magnetic insertion hole 34b: Magnetic fixing groove
35: detection sensor 36: magnetic sensor
40: Flow rate indicator

Claims (4)

A pair of driving gears 22 and a floating gear 23 are provided on the upper side of a rotary shaft 21 provided with a rotor 25 inside a body 11 connected by a flange 15 between the ducts 16 A mark sensing device 30 for sensing the flow of the rotational force transmitted through the conversion shaft 24 to the upper side of the flow sensing part 20, And a flow display unit (40) for converting the signal into a digital signal; The mark sensing device 30 includes a sensing shaft 33 through which a conversion shaft 24 is connected by a connecting member 33a and a plurality of magnetic insertion holes 34a are formed at regular intervals in the circumferential direction, 36) for fixing the detection plate (34); A sensing sensor 35 installed at the upper side of the sensing plate 34 for sensing a rotation of the magnetic sensor 36 and sending a signal having improved resolution to the flow rate display unit 40; An upper case 31 provided above the sensing shaft 33 and fixed to the housing 14 at an assembly hole 31c; And a lower case (32) which is coupled to the upper case (31) by a fastening bolt (32a) and through which the sensing shaft (33) penetrates,
The sensing plate 34 is connected to the magnetic sensor 36 through a magnetic insertion hole 34a formed in the range of 10 to 50 in the circumferential direction through the sensing axis 33, And the magnetic sensor (36) is fixed to the magnetic fixing groove (34b).
delete A pair of driving gears 22 and a floating gear 23 are provided on the upper side of a rotary shaft 21 provided with a rotor 25 inside a body 11 connected by a flange 15 between the ducts 16 A mark sensing device 30 for sensing the flow of the rotational force transmitted through the conversion shaft 24 to the upper side of the flow sensing part 20, And a flow display unit (40) for converting the signal into a digital signal; The mark sensing device 30 includes a sensing shaft 33 through which a conversion shaft 24 is connected by a connecting member 33a and a plurality of magnetic insertion holes 34a are formed at regular intervals in the circumferential direction, 36) for fixing the detection plate (34); A sensing sensor 35 installed at the upper side of the sensing plate 34 for sensing a rotation of the magnetic sensor 36 and sending a signal having improved resolution to the flow rate display unit 40; An upper case 31 provided above the sensing shaft 33 and fixed to the housing 14 at an assembly hole 31c; And a lower case (32) which is coupled to the upper case (31) by a fastening bolt (32a) and through which the sensing shaft (33) penetrates,
The upper case 31 is formed with a line connecting hole 31a through which the sensing shaft 33 is coupled to the bearing 33b and the sensing sensor 35 is connected to the electric wire and the through hole 31b is formed, 31c to the housing (14).
A pair of driving gears 22 and a floating gear 23 are provided on the upper side of a rotary shaft 21 provided with a rotor 25 inside a body 11 connected by a flange 15 between the ducts 16 A mark sensing device 30 for sensing the flow of the rotational force transmitted through the conversion shaft 24 to the upper side of the flow sensing part 20, And a flow display unit (40) for converting the signal into a digital signal; The mark sensing device 30 includes a sensing shaft 33 through which a conversion shaft 24 is connected by a connecting member 33a and a plurality of magnetic insertion holes 34a are formed at regular intervals in the circumferential direction, 36) for fixing the detection plate (34); A sensing sensor 35 installed at the upper side of the sensing plate 34 for sensing a rotation of the magnetic sensor 36 and sending a signal having improved resolution to the flow rate display unit 40; An upper case 31 provided above the sensing shaft 33 and fixed to the housing 14 at an assembly hole 31c; And a lower case (32) which is coupled to the upper case (31) by a fastening bolt (32a) and through which the sensing shaft (33) penetrates,
The lower case 32 is formed with a coupling step 32b on the upper side and connected to the upper case 31. The lower case 32 is fixed integrally with the upper case 31 by fastening bolts 32a, (33) is formed to pass therethrough.

Images