KR101991817B1 - Water meter - Google Patents

Abstract

The present invention relates to a water meter, and more specifically, relates to a water meter which measures the flow rate through fluid pressure. According to the present invention, the water meter is able to measure the flow rate through the pressure of flowing water and to display the flow rate on a metering device (400), comprising: a housing (100) whose one side has an inlet (111) through which a fluid is introduced, and whose other side has an outlet (113) through which the introduced fluid is discharged; a rotation unit (200) detachably mounted inside the housing (100) to rotate by a pressure of the fluid introduced; a gear unit (300) gear-engaged with the rotation unit (200) to rotate, and to transfer a rotatory power received from the rotation unit (200) to the metering device (400) by magnetism; an external case (700) which includes the housing (100) installed inside, and an internal structure engaged with a lower side of the housing (100) to have a pipe through which the fluid passes; and a fixed plate (500) engaged with an upper end of the external case (700) by a bolt, on which the metering device (400) is installed.

Description

Water meter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water meter, and more particularly, to a water meter that measures a flow rate through a pressure of a fluid.

In general, various kinds of water meters used for measuring the amount of water used in each customer connected to the middle portion of the water pipe have been developed and widely used. Specifically, the water meter measuring the flow rate of the flowing water, , And a volumetric formula for measuring the volume of water.

Currently, the most widely used water meter is mostly flow velocity type, and it is configured to measure the amount of water used through the rotating wiping by rotating the wiping using the pressure of the flowing water.

On the other hand, the conventional flow rate water meter is manufactured by casting, injection molding or the like for each of the inlet arm, the outlet arm, and the support case, which are the components forming the turbine, There is a problem that a cost is high and a structure is complicated and a failure occurs in the assembling process.

Further, when the fastening elements between the respective components are loosened due to the long time water pressure, it is difficult to realize a smooth function as a water meter, and in the case of an assembly using a fastening element, durability is poor.

The conventional regulated utility model No. 20-0283125 discloses a structure in which the inlet arm, the outlet arm, and the support case constituting the turbine are integrally formed to simplify the structure of the turbine, thereby reducing the manufacturing cost. In this case, And the outlet arm are formed to be symmetrical, there is a problem that the flow resistance of the outlet arm being discharged is large and the inflow fluid can not be discharged smoothly.

Furthermore, since the outer case coupled with the turbine at the lower side of the turbine is not tightly coupled to the turbine, there is a problem that the up-down flow and downward deflection of the turbine occur according to the inflow pressure.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a metering device in which fluid flows smoothly by forming asymmetry between an inlet through which a fluid flows and an outlet through which the fluid flows.

The present invention has been made in order to achieve the above-mentioned object of the present invention. The present invention provides a water meter for measuring a flow rate through an oil pressure and displaying it on a meter (400) A housing (100) having an inlet (111) and an outlet (113) through which the fluid introduced into the other side is discharged; A rotating part 200 which is detachably inserted into the housing 100 and rotates through a pressure of the inflow fluid; A gear unit 300 that gears to the rotary unit 200 and rotates, and transmits a rotational force transmitted from the rotary unit 200 to the meter 400 through a magnetic force; An outer case 700 having an inner structure in which the housing 100 is installed and which is coupled with the housing 100 to form a clearance through which fluid flows; And a fixing plate 500, which is bolted to an upper end of the outer case 700 and on which the meter 400 is installed.

The housing 100 includes an inlet arm 112 formed with an inlet 111 corresponding to the shape of the rotary unit 200 and an outlet 112 formed at the outlet 113 opposite to the inlet 112, An arm 114 and a horizontal hub portion 130 connecting the inlet arm 112 and the outlet arm 114 along the bottom edge.

The hub 130 may be in surface contact with the first step 721 provided on the inner side wall of the outer case 700 such that the housing 100 is hooked inside the outer case 700.

More specifically, the hub unit 130 includes a contact portion (not shown) which is in surface contact with the first step 721 provided on the inner side wall of the outer case 700 so that the housing 100 is hooked inside the outer case 700, And a connecting portion 132 connecting the contact portion 131 with the inlet arm 112 and the outlet arm 114. [

The housing 100 includes a step 140 protruding radially from an upper end of the housing 100. The step 140 includes a second step 722 formed on an inner surface of the outer case 700, As shown in Fig.

A first sealing member 150 may be inserted between the step 140 and the second step 722.

The outlet arm 114 may be asymmetrical with the inlet arm 112 to minimize the flow resistance of the discharged fluid.

The rotation unit 200 includes a rotation shaft 210 installed parallel to an imaginary line L connecting the inlet 111 and the outlet 113 and a rotation shaft 210 coupled to the rotation shaft 210, (Not shown). The blade 220 may rotate through the pressure of the fluid flowing into the blade 220.

The blade 220 may be formed such that the contact surface is inclined to face the inlet 111 so that the contact surface with the fluid increases in order to rotate according to the pressure of the fluid flowing through the inlet 111.

The worm 211 for coupling the worm gear with the gear unit 300 may be formed at a position corresponding to the gear unit 300.

The worm gear 300 is formed to penetrate the upper end of the housing 100 and has a worm gear 311 formed at one end thereof to be engaged with the worm 211 and a first gear 312 formed at the other end A second gear 321 that is gear-coupled to the first gear 312 at one end and a magnetic portion 322 that transmits a rotational force to the meter 400 at the other end via a magnetic force, And a second gear portion 320 including the first gear portion 320 and the second gear portion 320.

The first gear portion 310 may be installed through the upper end of the housing 100 at a position adjacent to the inlet 110.

The magnetic portion 322 is provided at the end of the second gear portion 320 on the side of the meter 400 and rotates the metal portion 410 installed on the bottom surface of the meter 400 through a magnetic force And a magnet 323 for transmitting the rotational force of the rotation unit 200 to the meter 400. [

The water meter according to the present invention simplifies the structure and reduces the manufacturing cost, and is easy to assemble to increase the durability,

Further, the water meter according to the present invention is advantageous in that it is robust, stable in its assembled state, and is small in size and weight, and is practical and economical, and is easy to manufacture.

Furthermore, the water meter according to the present invention has a merit that the flow resistance can be minimized by making the structure of the discharge port through which the inflow fluid is discharged, so that accurate flow rate measurement can be performed.

Further, in the water meter according to the present invention, the joining structure for forming the clearance is stably and firmly coupled through the surface contact, so that there is an advantage that the durability is increased even when the inflow water pressure does not cause up-down flow or downward deflection.

1 is a perspective view showing a water meter according to the present invention.
Fig. 2 is an exploded perspective view showing the configuration of the water meter according to Fig. 1; Fig.
Fig. 3 is an exploded cross-sectional view showing a state of the housing of the water meter according to Fig. 1;
Fig. 4 is a plan view showing the housing of the water meter according to Fig. 1; Fig.
Fig. 5 is a bottom view showing the housing of the water meter according to Fig. 1; Fig.
FIG. 6 is a cross-sectional view showing a state in which a housing, a fixing plate, and an outer case in the direction of the housing inlet arm of the water meter according to FIG. 1 are engaged.
FIG. 7 is a cross-sectional view showing a state in which a housing, a fixing plate, and an outer case in the direction of the housing outlet arm of the water meter according to FIG. 1 are engaged.
Fig. 8 is a side elevational longitudinal sectional view showing a state where the housing, the fixing plate and the outer case of the water meter according to Fig. 1 are engaged. Fig.
9 is a plan view showing the outer case of the water meter according to Fig. 1;
10 is a cross-sectional view showing a state of a second gear portion and a meter of the water meter according to Fig. 1;

Hereinafter, a water meter according to the present invention will be described with reference to the accompanying drawings.

3 to 10, the water meter according to the present invention measures the flow rate through the water pressure and displays it on the meter 400. The water meter includes an inlet 111 , And a discharge port (113) through which the fluid introduced into the other side is discharged; A rotating part 200 which is detachably inserted into the housing 100 and rotates through a pressure of the inflow fluid; A gear unit 300 that gears to the rotary unit 200 and rotates, and transmits a rotational force transmitted from the rotary unit 200 to the meter 400 through a magnetic force; An outer case 700 having an inner structure in which the housing 100 is installed and which is coupled with the housing 100 to form a clearance through which fluid flows; And a fixing plate 500 bolted to an upper end of the outer case 700 and provided with the meter 400.

The housing 100 is configured to form a clearance through which the fluid flowing through the outer case 700 flows and the inflowed fluid is discharged, and various configurations are possible.

For example, the housing 100 is provided with an inlet 111 through which fluid flows into one side and an outlet 113 through which the fluid introduced into the other side is discharged, and is installed inside the outer case 700 Clearance can be formed.

The housing 100 is configured to have an inlet 111 through which a fluid flows into one side and a discharge hole 113 through which the fluid introduced into the other side is discharged, respectively, and may have various configurations.

For example, the housing 100 includes an inlet arm 112 formed with an inlet 111 corresponding to the shape of the rotary part 200, an outlet 112 formed at an outlet 113 opposite to the inlet arm 112, And a horizontal hub portion 130 connecting the inlet and outlet arms 112 and 114 along the bottom edge of the housing 100. [

That is, the housing 100 includes a cylindrical main body portion 115, an inlet arm 112 through which fluid flows from one side of the main body portion 115, an outlet arm 114 through which fluid is discharged from the other side, 112 and a horizontal hub portion 130 connecting the outlet arm 114 along the outer periphery of the bottom surface of the main body portion 115.

In this case, since the housing 100 is formed integrally with the inlet arm 112, the outlet arm 114, the main body portion 115, and the hub portion 130, the structure is simple, And the like.

In addition, the housing 100 may further include a stepped portion 140 formed by protruding an upper end in a radial direction.

The inlet arm 112 has a configuration in which an inlet 111 through which a fluid flows is formed corresponding to the shape of the rotary part 200, and various configurations are possible.

For example, the inlet arm 112 may have a plurality of inlet ports 111 radially formed on one side of the cylindrical main body portion 115 so as to correspond to the shape of the rotation portion 200.

The inlet arm 112 may be formed with an insertion groove 116 into which the support pin 231 is inserted to prevent the rotation shaft 210 from rotating smoothly.

The inlet arm 112 may also include a plurality of frames 118 positioned radially to correspond to the shape of the rotatable portion 200 to form an inlet 111 through which the fluid flows.

The frame 118 forms an inlet 111 through which the fluid flows and is separated from the bottom surface of the outer case 700 when the housing 100 is seated inside the outer case 700 It is possible to prevent rotational interference between the rotary part 200 and the bottom surface of the outer case 700. [

The outlet arm 114 is opposed to the inlet arm 112 and has a discharge port 113 through which the inflow fluid is discharged. Various configurations are possible.

For example, the outlet arm 114 may be provided on the opposite side of the inlet arm 112 of the cylindrical main body portion 115, and may be provided with an inlet port 111 for smooth fluid discharge through minimization of flow resistance, A plurality of discharge openings 113 having a larger area can be formed.

That is, the outlet arm 114 may have an asymmetrical shape with respect to the inlet arm 112 to minimize the flow resistance of the fluid to be discharged. More specifically, the outlet arm 114 has a larger area than the inlet 111 And can be formed in a simple structure as compared with the inlet arm 112 having a shape corresponding to the rotary part 200.

In addition, the outlet arm 114 is formed so as to minimize the flow resistance of the fluid to be discharged unlike the inlet port 111 and to have a discharge port 113 formed in a donut shape around the fixing member 230 on the side surface .

At this time, by minimizing the frame 120 for forming the discharge port 113, the flow resistance can be minimized, and a donut shape having a radius smaller than that of the discharge port 113, 2 outlet 119 may be additionally formed.

In this case, the second outlet 119 can be selectively used, for example, opened or closed, and as another example, it can be always closed.

The hub unit 130 is configured to connect the inlet arm 112 and the outlet arm 114 along the bottom edge of the housing 100, and various configurations are possible.

For example, the hub unit 130 includes an inlet arm 112 through which fluid flows from one side of the cylindrical main body unit 115, and an outlet arm 114 through which the fluid is discharged from the other side of the main body unit 115 May be formed along the bottom edge, and may be horizontal so as to be parallel to the ground.

Accordingly, when the housing 100 is installed inside the outer case 700 to be described later, the hub unit 130 is in surface contact with the first step 721 provided on the inner wall of the outer case 700 So that it is possible to prevent upward flow and downward sagging of the housing 100 due to a strong water pressure or the like passing through the inside of the housing 100.

That is, the hub unit 130 may be in surface contact with the first step 721 provided on the inner side wall of the outer case 700 so that the housing 100 is hooked inside the outer case 700.

More specifically, the hub unit 130 is formed to horizontally connect the inlet arm 112 and the outlet arm 114 of the housing 100. To this end, the first step 721 is connected to the outer case 700 (Not shown in the drawing).

The stepped portion 140 is configured to protrude in the radial direction from the upper end of the housing 100 so that the housing 100 can be stably installed in the outer case 700 to be described later, .

For example, the stepped portion 140 may be hooked on a second step 722 protruding from the inner surface of the outer case 700, so that the housing 100 stably supports the outer case 700 700).

In this case, the first sealing member 150 can be inserted between the step 140 and the second step 722, thereby preventing water from leaking between the outer case 700 and the housing 100 .

In addition, the housing 100 may include a support portion 117 protruding downward from the exit arm 113.

The support portion 117 contacts the bottom surface of the outer case 700 when the housing 100 is inserted into the outer case 700 and rotates between the rotation portion 200 and the bottom surface of the outer case 700 As a configuration for preventing interference, various configurations are possible.

In order to maximize the discharge area between the outer casing 700 and the outlet arm 113 forming the discharge pipe through which the fluid in the housing 100 is discharged, the support portion 117 may have a cross- Lt; / RTI >

The housing 100 is provided with a guide protruding upward at a corresponding position to be inserted into a guide groove 550 formed on the bottom surface of the fixing plate 500 so that the fixing plate 500, Unit 160 may be included.

The rotating part 200 is configured to be detached from the housing 100 and rotate through the pressure of the inflowing fluid, and various configurations are possible.

The rotation unit 200 includes a rotation shaft 210 installed parallel to an imaginary line L connecting the inlet 111 and the outlet 113 and a rotation shaft 210 coupled to the rotation shaft 210, (Not shown). The blade 220 may rotate through the pressure of the fluid flowing into the blade 220.

The rotation unit 200 may include a fixing member 230 inserted into the insertion groove 116 of the housing 100 so that the rotation shaft 210 can rotate smoothly at a predetermined position.

The rotating shaft 210 is provided in parallel with an imaginary line L connecting the inlet 111 and the outlet 113 to allow the blade 220 to rotate.

For example, the rotation shaft 210 may be formed at a position corresponding to the gear portion 300, such that the worm 211 for coupling the worm gear with the gear portion 300 described later may be formed.

The blade 220 is configured to rotate through a pressure of a fluid that is coupled to the rotating shaft 210 and flows into the inlet 111, and may have various configurations.

For example, the blade 220 may be formed such that the contact surface is inclined to face the inlet 111 so that the contact surface with the fluid increases in order to rotate according to the pressure of the fluid flowing through the inlet 111.

That is, the blade 220 includes a circular main body 221 and a plurality of blades 222 provided on an outer circumferential surface of the main body 221. The blades 222 are inclined to face the inlet 111 .

The fixing member 230 is inserted into insertion grooves 116 formed in the inlet and outlet arms 112 and 114 of the housing 100 so that the rotary shaft 210 can rotate smoothly at a predetermined position Various configurations are possible.

For example, the fixing member 230 includes a support pin 231 inserted into the insertion groove 116 so that the end of the rotation shaft 210 is inserted and smoothly rotated at a predetermined position, And a cap part 232 installed to surround the upper and lower surfaces of the support pin 231 in the insertion groove 116 to prevent detachment.

The gear portion 300 is configured to rotate gear-coupled to the rotary portion 200 and transmit the rotational force transmitted from the rotary portion 200 to the meter 400 through a magnetic force, and various configurations are possible.

For example, the gear unit 300 is installed through the upper end of the housing 100 and has a worm gear 311 which is gear-coupled with the worm 211 at one end and a first gear 312 at the other end A second gear 321 that is gear-engaged with the first gear 312 at one end and a magnetic portion 322 that transmits a rotational force to the meter 400 at the other end through a magnetic force, And a second gear portion 320 including the first gear portion 320 and the second gear portion 320.

The first gear portion 310 and the second gear portion 320 are configured to rotate according to the rotation of the rotation portion 200 and to transmit the rotational force of the rotation portion 200 to the meter 400, .

For example, the first gear portion 310 is installed through the upper end of the housing 100 and includes a worm 211 formed on the rotary shaft 210 at one end located inside the housing 100, And the first gear 312 may be formed at the other end of the housing 100 located at the outer upper end of the housing 100.

The second gear portion 320 includes a second gear 321 that meshes with the first gear 312 of the first gear portion 310 and a second gear 322 that transmits a rotational force to the meter 400 through a magnetic force Magnetic portion 322. [0033]

Particularly, the second gear portion 320 is installed at the end of the meter 400, and rotates the metal portion 410 installed on the bottom surface of the meter 400 through the magnetic force, And a magnet 323 that transmits the rotational force to the meter 400. [

The meter 400 is configured to display the measured flow rate so that the user can know the flow rate, and various configurations are possible.

For example, the meter 400 includes a metal part 410 installed on the bottom surface and rotating through the magnetic part 322 of the second gear part, a shaft part (not shown) for rotation through the magnetic force of the metal part 410 And a gear 430 that is gear-meshed with the displayed number and displays the measured flow rate by rotating together with the rotation of the metal part 410.

1 and 2, the water meter according to the present invention includes an outer case 700 having a flange shape at both ends so that a housing 100 is installed therein and pipes can be connected thereto; A fixing plate 500 bolted to an upper end of the outer case 700 and provided with a meter 400; The cover 400 may further include a cover portion 600 that surrounds the meter 400 and is bolted to the fixing plate 500 so that the meter 400 is fixed to the fixing plate 500.

The outer case 700 has a flange shape at both ends so that a pipe can be connected to the inner case 700. The outer case 700 has an inner structure in which the housing 100 is installed inside and the bottom of the housing 100 is coupled to form a clearance Various configurations are possible.

For example, the outer case 700 includes a case body 720 having an inner space in which the housing 100 is installed, a flange portion 710 formed at both ends of the case body 720 and coupled to the outer pipe, )Wow. And a plate top 730 provided at the upper end of the case body 720 and coupled with the fixing plate 500.

The upper plate 730 may be formed in correspondence with the area of the fixing plate 500 and coupled to the fixing plate 500. An opening may be formed at the upper end of the upper plate 730 so that the second gear 320 may be installed .

The plate top 730 may be formed with a bolt hole in which the fixing bolt 510 is installed for the attachment of the fixing plate 500.

The case body 720 has a structure in which an inner space in which the housing 100 is installed is formed, and various configurations are possible.

For example, the case body 720 may be formed by protruding the first step 721 on the inner side to support the housing 100 in a proper position by the surface contact of the hub 130 described above .

The case body 720 may be formed by protruding a second step 722 on the inner side surface of the case body 720 so that the stepped portion 140 is hooked on the case body 720 to support the housing 100 in a fixed position.

The first step 721 is formed inside the case body 720 and can have any structure as long as it is in contact with the hub 130 to support the housing 100. [

For example, the first step 721 corresponds to the position of the hub part 130 in the inside of the case body 720, which is circular in plan view, and is a virtual line connecting the inlet 111 and the outlet 113 And may be formed so as to protrude to a parallel hypothetical string.

Thus, vibration and downward deflection during the fluid metering process of the housing 100 can be prevented.

The second step 722 has a configuration in which the step 140 is engaged when the housing 100 is inserted into the case body 720, and various configurations are possible.

The second step 722 may protrude from the inner surface of the case body 720 in a circular shape in plan view corresponding to the stepped portion 140.

The fixing plate 500 is bolted to the upper end of the outer case 700, and the meter 400 is installed, and various configurations are possible.

For example, the fixing plate 500 may include a plate 520 contacting the plate 730, and a plurality of bolt holes formed at each corner of the plate 520.

The fixing plate 500 may be coupled to the outer case 700 through fixing bolts 510 provided in a plurality of bolt holes.

The fixing plate 500 is configured to be coupled to the upper end of the outer case 700 in a state where the housing 100 is inserted into the outer case 700. The guide plate 160 May be formed in the guide groove 550.

In addition, the fixing plate 500 may be formed with a step 540 at the bottom edge thereof for stable connection with the outer case 700.

At this time, the step 540 is formed on the bottom edge of the fixing plate 500, and more specifically, the first and second steps 541 and 542 may be formed in the radial direction.

The second step 542 may be formed at the outermost surface of the bottom surface of the fixing plate 500 to contact the top surface of the outer case 700 to support the fixing plate 500.

The first step 541 may be provided with a spacing space between the first step 541 and the upper end of the housing 100 so that the second sealing member 530 can be inserted.

That is, the first step 541 is formed to form a spacing space in which the second sealing member 530 is inserted between the stepped portion 140 of the housing 100 and the second sealing member 530, The leakage of water through the space between the fixing plate 500 and the housing 100 can be prevented.

The cover unit 600 is configured to surround the meter 400 and be bolted to the fixing plate 500 so that the meter 400 is fixed to the fixing plate 500.

For example, in order to prevent rotation of the fixing bolt 510 installed to engage the fixing plate 500 with the outer case 700, the cover unit 600 may be fixed to the upper surface of the fixing bolt 510, And a bolt lid 610 for preventing the bolt 510 from being exposed.

The cover unit 600 includes a through hole 621 through which a bolt 622 is inserted for bolt connection with the fixing plate 500 and includes a sealing clip 630 for sealing the bolt 622, The seal clip mounting groove 620 can be formed.

The cover part 600 includes a body part 640 surrounding the outer periphery of the meter 400 and a cover cap hinged to the body part 640 to be opened and closed for exposure of the upper part of the meter 400. [ (650). ≪ / RTI >

The bolt lid 610 protrudes in a radial direction from the side of the cylindrical body portion 640 of the cover portion 600 and is fixed to the fixing plate 500 and the outer case 700 ), And various configurations are possible.

The bolt lid 610 prevents the fixing bolt 510 from being manipulated by an arbitrary user by preventing the fixing bolt 510 from being separated so as to prevent the outer case 700 from being detached, .

The bolt lid 610 may be formed to correspond to the number of the fixing bolts 510 and may be formed to cover only a part of the plurality of fixing bolts 510.

The cover unit 600 includes a through hole 621 through which a bolt 622 is inserted for bolt connection with the fixing plate 500 and includes a sealing clip 630 for sealing the bolt 622, The seal clip mounting groove 620 can be formed.

The sealing clip installation groove 620 has a structure in which a sealing clip 630 installed to prevent the cover unit 600 from being detached from the fixing plate 500 is installed to prevent arbitrary manipulation of the meter 400, Configuration is possible.

For example, the sealing clip mounting groove 620 may be formed in a long side in the height direction on the side of the cylindrical main body portion 640, and may be in the form of a groove.

The sealing clip mounting groove 620 may be formed with a through hole 621 through which a bolt 622 is inserted for bolt connection with the fixing plate 500.

The seal clip 630 seals the bolt 622 that connects the fixing plate 500 and the cover unit 600 to prevent the fixing plate 500 and the cover unit 600 from being separated from each other. Do.

For example, the sealing clip 630 includes a first clip piece 633 formed with a bolt through-hole 631 through which the bolt 622 passes, and a second clip piece 633 folded in a side- The second clip piece 632 covering the bolt 622 and the first and second clip pieces 632 and 633 in close contact with each other while the first clip piece 633 and the second clip piece 632 are folded And may include a population of rods to seal.

That is, the sealing clip 630 is formed such that the first clip piece 633, in which the bolt through-hole 631 is formed, corresponds to the through-hole 621 of the clip installation groove 620 in which the bolt through- And then the sealing clip 630, the cover portion 600 and the fixing plate 500 are coupled through the bolts 622 and the second clip pieces 632 are folded to cover the upper ends of the bolts 622, Any manipulation of the bolt 622 can be prevented.

In this case, the sealing member may have a variety of configurations in which the folded first clip piece 633 and the second clip piece 632 are tightly fixed to each other and sealed.

For example, the seal has a clip through-hole through which both ends of the first and second clip pieces 633 and 632 are passed, and the first and second clip pieces 633 and 632 folded in a side- The clip first and second clip pieces 633 and 632 can be prevented from spreading again through the clip through-hole.

As another example, the sealing member may be configured to bundle both ends of the first and second clip pieces 633 and 632 to prevent the first and second clip pieces 633 and 632 from being unfolded.

The main body portion 640 surrounds the outer periphery of the meter 400 and can prevent any detachment of the meter 400 and protect it from an external impact.

The cover cap 650 may be hinged to the main body 640 and may be opened and closed to expose the upper part of the meter 400 for the purpose of checking the quantity.

The cover cap 650 is hinged to the main body 640 and hinged to the main body 640 and corresponds to the protrusion formed on the upper surface of the main body 640, So that it is possible to stably open and close.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100: housing 200:
300: gear part 400: meter
500: fixing plate 600: cover part
700: outer case

Claims (12)

In a water meter for measuring a flow rate through an oil pressure and displaying it on a meter (400)
A housing (100) having an inlet (111) through which fluid flows into one side and an outlet (113) through which fluid introduced into the other side is discharged;
A rotating part 200 which is detachably inserted into the housing 100 and rotates through a pressure of the inflow fluid;
A gear unit 300 that gears to the rotary unit 200 and rotates, and transmits a rotational force transmitted from the rotary unit 200 to the meter 400 through a magnetic force;
An outer case 700 having an inner structure in which the housing 100 is installed and which is coupled with the housing 100 to form a clearance through which fluid flows;
And a fixing plate 500 bolted to an upper end of the outer case 700 and installed with the meter 400,
The housing (100)
An inlet arm 112 formed with the inlet 111 corresponding to the shape of the rotary part 200 and an outlet arm 114 formed with the outlet 113 facing the inlet arm 112; And a horizontal hub portion (130) connecting the inlet arm (112) and the outlet arm (114) along the bottom edge,
The outlet arm 114 is asymmetrical with the inlet arm 112 to minimize the flow resistance of the discharged fluid,
The inlet arm 112 has a plurality of radial inlet ports 111 through which the fluid flows, corresponding to the shape of the rotary section 200,
The outlet arm 114 further has an outlet 113 formed at an inner lower end surface of the outer case 700 and below the hub 130 through the hub 130,
The outlet arm 114 is in contact with the bottom surface of the outer case 700 when the housing 100 is inserted into the outer case 700, And a support portion (117) protruded downward to prevent rotational interference between the bottom surfaces,
In order to maximize the discharge area between the outer case 700 and the outlet arm 114 forming the discharge pipe through which the fluid in the housing 100 is discharged, the support portion 117 has a cross sectional area Is a reduced shape. delete The method according to claim 1,
The hub unit 130 includes:
Is in surface contact with the first step (721) provided on the inner side wall of the outer case (700) so that the housing (100) is hooked inside the outer case (700). The method according to claim 1,
The housing (100)
And a step 140 protruding radially from the upper end of the outer case 700. The step 140 is hooked on a second step 722 formed on an inner surface of the outer case 700 Water meter. The method of claim 4,
And a first sealing member (150) is inserted between the step (140) and the second step (722). delete The method according to claim 1,
The rotation unit 200,
A rotation shaft 210 installed parallel to an imaginary line L connecting the inlet 111 and the outlet 113 and a pressure sensor connected to the rotation shaft 210 for controlling the pressure of the fluid flowing into the inlet 111, And a blade (220) rotating therethrough. The method of claim 7,
The blade (220)
Wherein the contact surface is inclined so as to face the inlet (111) so as to increase the contact surface with the fluid for rotation according to the pressure of the fluid flowing through the inlet (111). The method of claim 7,
The rotating shaft 210 is rotatably supported,
And a worm (211) for worm gear engagement with the gear part (300) is formed at a position corresponding to the gear part (300). The method of claim 9,
The gear portion (300)
A first gear portion 310 formed to penetrate the upper end of the housing 100 and having a worm gear 311 formed at one end to be engaged with the worm 211 and a first gear 312 formed at the other end, ,
A second gear portion 320 including a second gear 321 that is gear-engaged with the first gear 312 at one end and a magnetic portion 322 that transmits a rotational force to the meter 400 at the other end through a magnetic force, And a water meter The method of claim 10,
The first gear portion 310 includes a first gear portion 310,
Is installed through the upper end of the housing (100) at a position adjacent to the inlet (111). The method of claim 10,
The magnetic portion (322)
The rotation of the rotating part 200 can be prevented by rotating the metal part 410 installed on the bottom surface of the meter 400 by the magnetic force, which is provided at the end of the second gear part 320 on the side of the meter 400, And a magnet (323) for transferring the fluid to the meter (400).

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