KR101854733B1 - Flow rate measuring device for pipe and flow rate measuring system including the same - Google Patents

Abstract

The present invention relates to a flowmeter for a pipe that can accurately measure a flow rate of fluid flowing in the pipe. The flowmeter includes: a pipe in which a fluid flows; a level measuring unit installed to a side of the pipe to measure a level of a fluid passing the pipe; a connecting member for connecting the pipe and the level measuring unit; and a computing processor receiving a level value measured by the level measuring unit to compute a flow rate. The level measuring unit has a meter body with a measuring chamber extending in a vertical direction in an inside thereof, a floating member positioned in the measuring chamber and floated by the fluid coming in the measuring chamber, and a distance sensor installed to an upper portion of the measuring chamber to detect a distance from the floating member and sending the detected distance to the computing processor. The connecting member has a passage for communicating a lower portion of the inner space of the pipe with a lower portion of the measuring chamber.

Description

TECHNICAL FIELD [0001] The present invention relates to a flowmeter for a tubular body and a flowmeter including the flowmeter,

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an apparatus for measuring a flow rate of a tubular body and a flow rate measuring system including the same, and more particularly to a flow rate measuring apparatus for measuring a flow rate of a flowing fluid by measuring a level of a tubular body, , A flow measurement system capable of confirming the total flow rate of the fluid in which it is installed and stored.

Recently, there have been many attempts to utilize water resources efficiently by collecting and collecting stormwater flowing down from buildings, ground, and so on.

It is necessary to increase the utilization of water resources by checking the inflow amount of the fluids in the collection facilities of excellent fluids so as not to place burden on the collection facilities and checking the stored available fluxes.

Various apparatuses have been developed for measuring the flow rate of the fluid flowing in the inflow channel and checking the accumulated flow rate.

1 (a) shows a flow rate measuring apparatus using an ultrasonic sensor and is described in Korean Patent Publication No. 10-0784415.

1 (a), the water level sensor 2 emits an ultrasonic wave into the inside of the tube 1, receives the ultrasonic wave reflected wave, and transmits the corresponding electric signal to the controller.

The control unit calculates the water level by the input signal, calculates the cross-sectional area of the fluid on the basis of the cross-sectional area of the pipe previously input, and calculates the flow rate of the fluid (3) flowing through the pipe by the separately measured flow rate.

On the other hand, FIG. 1 (b) relates to a real-time flow rate measuring apparatus for irrigation water and is disclosed in Korean Patent Laid-Open Publication No. 10-2013-0030076.

1 (b), a weir 5 is installed in the tube 1, and the weir 5 measures or controls the flow of the water to determine the characteristics of the flow rate flowing along the tube 1 ≪ / RTI > Since the weir 5 is installed in a triangular shape and blocks a part of the water 3, only a part of the water flows through the weir 5, so that a certain level of water level is formed in the tube 1.

The water level in the weir (5) is measured by the water level measuring unit (2).

The water level measurement unit 2 transmits the actual water level in the weir 5 to the calculation unit via the transmission unit 4 and the calculation unit calculates the flow rate data by the flow rate conversion formula pre- . The accumulated flow rate can then be calculated by integrating the calculated real time flow rate.

1 (a), ultrasonic waves are transmitted from the outside of the tubular body 1 to the inside of the tubular body 1, and the water level is measured. Therefore, the tubular body 1 and the fluid The ultrasonic waves are not transmitted smoothly at the portion where the ultrasonic waves are in contact with each other and the ultrasonic waves are reflected by foreign substances flowing together with the fluid.

1 (b), the water level is measured by ultrasonic waves emitted from the water level measuring unit 2. However, when the fluid flowing inside the tube 1 flows irregularly, Waves are generated and waves can not be brought into a uniform state, and foreign matter flows in a floating state on the water surface, so that the reflection action of ultrasonic waves can not be smoothly performed on the water surface.

As a result, it is difficult to continuously measure the accurate water level, and thus the accuracy is lowered in the process of calculating the cumulative flow rate.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a flow meter for a pipe having a structure capable of relatively accurately measuring a flow rate of a fluid flowing in the tube.

It is another object of the present invention to provide a fluid storage system having a structure capable of relatively accurately measuring a flow rate of a fluid flowing through a tube and obtaining accurate information on the stored flow rate.

The apparatus for measuring a flow rate of a pipe according to the present invention comprises a pipe body through which fluid flows in an inner space, a water level meter installed at a side of the pipe body to measure the level of the fluid passing through the pipe body, And a calculation processor for calculating a flow rate by receiving the measured value from the water level measuring instrument, wherein the water level measuring instrument comprises: a measuring body formed in the measuring chamber so as to extend in the vertical direction; A distance measuring unit for measuring a distance between the float floating by the fluid flowing into the measurement chamber and the float disposed on the upper part of the measurement chamber and transmitting the measured value about the sensed distance to the calculation processor, Wherein the connecting member includes a communication passage for communicating a bottom portion of the inner space of the tubular body and a lower portion of the measurement chamber with each other, It characterized in that it comprises.

The buffer tank for stabilizing the flow of the fluid flowing into the tubular body is provided at a front side of the tubular body. The buffer tank includes an inlet through which the fluid flows, A buffer space in which a fluid introduced between the inlet and the outlet is temporarily stored and a buffer space in which a lower end is positioned in the buffer space at a lower height than the inlet and a top end is vertically higher than the inlet, And an outlet plate provided so as to face the inlet so that the fluid introduced into the inlet flows through the lower side of the lower end thereof toward the outlet, and the outlet has a diameter decreasing from the buffer space toward the tube side And a horn shape is formed.

The apparatus for measuring flow rate for a tubular body according to the present invention may further comprise an upper cover on the upper side of the measuring instrument body to cover the measurement chamber from above and a sensor fixing member coupled to the upper cover and to which the distance detection sensor is fixed, The lower part of the body of the measuring instrument is provided with a level adjusting part for covering the measuring chamber from the lower side and provided with a supporting part for supporting the floating body when the floating body is lowered and adjusting the height of the supporting part.

Further, in the flowmeter for a tubular body according to the present invention, the measurement chamber is a cylindrical-shaped space having a predetermined diameter, the float has a planar upper surface and a cylindrical side wall opened to the lower side and is formed inside the cylindrical side wall And a weight attached to a lower end of the conical body, wherein a plurality of fluid discharge holes are formed in the cylindrical side wall.

The flowmeter for a tubular body according to the present invention is characterized in that the floating body has a hemispherical shape, and the upper face is flat and a surface of a hydrophobic material is embedded in the upper face, and a weight is additionally provided to the lower end of the floating body The weight weight is conical at its lower end and is formed with a hanging head at its upper end. A weight weight installation space is formed in the float body. The weight weight installation space is formed inside the float body, A conical space formed in the central portion of the lower end of the float to receive a conical portion at the lower end of the weight, And a connection space for connecting the conical spaces. Thus, when no external force acts on the body weight, The lower end of the weight protrudes from the lower end of the float in a state in which the latching head is hooked on the bottom surface of the latching space and the latching head rises in the latching space when the weight is further pushed up by an external force, And the conical portion of the lower end of the second end portion is seated in the conical space.

According to another aspect of the present invention, there is provided an apparatus for measuring a flow rate of a tubular body, comprising: a tubular flowmeter having the above-described configuration; a collecting pipe for collecting fluid and introducing the collected fluid into the tubular body; a fluid reservoir for collecting fluid flowing out of the tubular body; An open / close valve installed in a discharge pipe branched from a connection pipe connecting the fluid reservoir to allow or block the discharge of fluid flowing out of the pipe, and a storage tank water level sensor installed in the fluid reservoir and measuring the water level, And a controller for controlling the opening / closing valve to allow the discharge of the fluid when the flow rate measured by the flow rate measuring device reaches a set value or when the measured water level reaches the set value in the storage tank level sensor .

The flowmeter for a pipe according to the present invention and the flowmeter using the same according to the present invention have a structure for indirectly measuring a water surface inside a pipe through a water level measuring device and thus measuring by a foreign substance floating on the water surface inside the pipe It is possible to solve the problem of defects.

Further, in the flowmeter for a tubular body of the present invention and the flowmeter using the same, the fluid is stabilized by the buffer tank and the fluid is supplied to the tubular body and the level gauge. Accordingly, it is possible to suppress the instantaneous fluctuation of the water level due to the wave of the water surface, to solve the problem of the measurement failure of the distance detection sensor, and to continuously measure the water level in a relatively stable state.

Further, in the flow meter for a tubular body of the present invention and the flow rate measuring system using the same, the weight of the float can be suppressed by installing a weight on the float, So that the weight is not further disturbed when descending.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a block diagram of a flow measuring apparatus for a fluid flowing in a conventional tube;
2 is an exploded cross-sectional view of a flowmeter for a pipe according to an embodiment of the present invention
FIG. 3 is a cross-sectional view of an apparatus for measuring a flow rate of a pipe according to an embodiment of the present invention
FIG. 4 is a schematic view showing a coupling state diagram showing a coupling state of a connecting member and a measuring instrument body in a flowmeter for a tubular body according to an embodiment of the present invention. FIG.
5 is a diagram illustrating the configuration and operation of a buffer tank in a flowmeter for a pipe according to an embodiment of the present invention.
6 is a perspective view of a buffer tank in a flowmeter for a pipe according to an embodiment of the present invention.
FIG. 7 is a block diagram of a fluid storage system capable of measuring a flow rate of a fluid in which a flowmeter for a tubular body is installed and stored according to an embodiment of the present invention.
8 is a graph showing the relationship between the water level and the flow rate for calculating the flow rate according to the water level in the flow rate measuring apparatus for a pipe according to the embodiment of the present invention
FIG. 9 is an explanatory diagram for explaining a state in which a floating body is lowered in a flow measuring apparatus for a pipe according to an embodiment of the present invention; FIG.
10 is a cross-sectional view of a flowmeter for a pipe with a floating body of a modified configuration according to another embodiment of the present invention
Fig. 11 is a perspective view showing the concrete structure of the float shown in Fig. 10; Fig.
12 is a cross-sectional view of a flow measuring apparatus for a pipe provided with a floating body of a modified configuration according to another embodiment of the present invention
13 (a) and 13 (b) are sectional views showing the concrete structure of the float shown in Fig. 12
14 is an explanatory view for explaining the action of the floating body of Fig. 13 in a state where the floating body is lowered to the bottom of the measurement chamber in which the foreign matter is accumulated; Fig.

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

FIG. 2 is an exploded cross-sectional view of a flowmeter for a pipe according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of the pipe flowmeter for a pipe according to an embodiment of the present invention.

2 and 3, the flow meter 200 for a tubular body includes a tubular body 20 through which a fluid flows in an inner space, a tubular body 20 provided at a side of the tubular body 20, A connection member 40 connecting the tubular body 20 and the level gauge 30 to each other to measure the level of the fluid; And an operation processor (not shown).

The tubular body 20 is a part through which the fluid flows in the inner space and constitutes a part of the pipe connecting the water pipe 100 and the fluid reservoir 300 as shown in FIG. Is fluidly flowing toward the fluid reservoir 300 and must pass through.

The level gauge 30 is installed on the side of the gauge body 20 to measure the level of the fluid passing through the gauge body 20. This is installed to check the flow rate of the fluid flowing inside the tubular body 20 by monitoring the level of the fluid flowing inside the tubular body 20 in real time.

The connecting member 40 connects the tubular body 20 and the water level measuring instrument 30 so that the water level measuring instrument 30 can be fixed to the side of the tubular body 20.

The connecting member 40 also includes a communication passage 42 for communicating the bottom of the inner space of the tube 20 and the lower portion of the measurement chamber 31a of the level gauge 30 with each other. The communication passage 42 is an internal passage formed by the lower connection portion 40a connecting the lower end of the tube 20 and the lower portion of the measuring instrument body 31 of the level gauge 30 to form a hollow tube.

The connecting member 40 includes an upper connecting portion 40b for connecting the upper end of the tube 20 and the measuring instrument body 31 of the water level measuring instrument 30 to support the measuring instrument body 31. [

2 and 4, the upper connection part 40b is formed with a threaded rod 46 fixed to the upper end of the tube 20 and an elastic clamping part 46 connected to the threaded rod 46 and surrounding the upper part of the measuring instrument body 31. [ Member (47). The elastic clamping member 47 is provided with both side elastic vanes 47a and 47b surrounding the seating space 47c and the side elastic wings are opened by the elastic force when the measuring instrument body 31 enters the seating space And the upper outer surface of the measuring instrument body 31 is wrapped around the upper surface of the measuring instrument body 31 to engage with each other.

The calculation processor receives the measured value from the water level meter 30 and calculates the flow rate. A controller 500, which will be described later, which controls the operation of the entire system, may be used as the controller 500, or may be provided as a separate processing device from the controller 500.

3, the water level meter 30 includes a measuring body 31 formed inside the measuring chamber 31a so as to extend in the vertical direction, and a measuring chamber 31a located in the measuring chamber 31a. (33) floated by the fluid flowing into the measurement chamber (31a) and the lower float (33) installed on the upper portion of the measurement chamber (31a) and measures the measured distance And a distance sensor 34 for transmitting the distance.

The measuring instrument body 31 has a hollow bar shape such as a cylinder. The measuring chamber 31a is formed so as to extend in a vertical direction. The measurement chamber 31a is a columnar space having a constant diameter.

An upper cover 35 covering the measuring chamber 31a from above and a sensor fixing member 36 coupled to the upper cover 35 and fixed to the distance sensor 34 are provided at the upper end of the measuring instrument body 31 Respectively.

The sensor fixing member 36 is fitted to the upper end of the measuring instrument body 31 in a state where the upper lid 35 is engaged and is fixed to the sensor fixing member 36 through a sensor fixing hole 36a, A distance detection sensor 34 is installed.

The distance sensor 34 is a non-contact type sensor that detects the distance to the float 33 by using ultrasonic waves, a laser, infrared rays, etc., and can transmit the measurement value to the calculation processor to check the water level of the tubular body 20 .

The lower end of the measuring instrument body 31 is provided with a receiving portion 37a for covering the measuring chamber 31a from the lower side and supporting the float 33 when the float 33 is lowered, (37).

The level adjusting unit 37 can be raised and lowered by the rotation by the helical joining 37a and 32b with the lower end of the measuring device body 31 so that the level adjusting unit 37 can be raised and lowered, (37a) can also be adjusted in height below the measurement chamber (31a).

The height of the receiving portion 37a of the level adjusting portion 37 is set lower than the bottom surface of the tubular body 20 so that when the fluid in the tubular body 20 is depleted, the float 33 only contacts the receiving portion 37a The height is set so that it can be done.

The float 33 does not contact the receiving portion 37a of the level adjusting portion 37 even if a small amount of fluid flows through the tubular body 20 so that the height of the float 33 can be adjusted according to the flow rate of the tubular body 20 And the float 33 is in a stopped state only when the fluid in the tubular body 20 is completely depleted.

The lowest height at which the float 33 descends can be set by adjusting the height of the receiving portion 37a so that the height of the float 33 can be set when there is no fluid in the tubular body 20 .

The buffer tank 50 for stabilizing the flow of the fluid flowing into the tube 20 is provided on the front side of the tube 20 in the tube flow measuring apparatus 200 of the present embodiment.

5 and 6, the buffer tank 50 includes an inlet 54 through which the fluid flows, an outlet 55 connected to the tube 20, an inlet 54 and an outlet 55, And the lower end 53a is positioned in the buffer space 52 at a lower height than the inlet 54 and the upper end 53b is positioned at a height higher than the inlet 54 And a water level plate 53 provided so as to face the inflow port 54 so as to face the inflow port 54 so as to hit the fluid introduced into the inflow port 54 and to pass through the lower side of the lower end thereof toward the outflow port 55 .

The inlet port 54 is connected to the collector pipe 100 to receive the fluid and the outlet port 55 is a portion to which the fluid flows out from the buffer space 52.

The outlet 55 has a horn shape whose diameter decreases from the buffer space 52 to the tubular body 20 side. This horn shape can form a laminar flow along the horn-like curved surface of the fluid flowing to the outlet 55, thereby stabilizing the flow of the fluid.

The buffer space 52 is a space in which the fluid flowing into the inlet 54 temporarily retreats, and foreign substances contained in the fluid are precipitated.

The water level plate 53 is a vertical plate in which a lower end 53a is positioned in the buffer space 52 at a lower level than the inlet 54 in the buffer space 52. [ The upper end 53b of the water level plate 53 is installed vertically so as to be higher than the inlet 54 so as to face the inlet 54.

Accordingly, the fluid flowing into the inlet port (54) collides with the water level plate (53) to form a flow that flows through the lower end of the water level plate (53) and flows toward the outlet port (55) side. As a result, irregular amounts are introduced into the inlet 54 in the process, so that the severe waves generated on the surface of the fluid can be relaxed and stabilized at the rear of the water receiving plate 53. In addition, since the horn-shaped outlet 55 allows the fluid flowing out along the horn-shaped curved surface to be formed as a laminar flow, the flow of the fluid can be further stabilized.

On the other hand, the float 33 floats on the surface of the fluid due to its specific gravity lower than that of the fluid, and moves up and down in the measurement chamber 31a in accordance with the rise and fall of the water level.

The upper surface of the float 33 is formed in a plane, and the distance sensor 34 is a surface reflecting ultrasound, laser, infrared rays, and the like.

Meanwhile, FIG. 7 shows a configuration of a fluid storage system capable of measuring a flow rate of a fluid in which the above-described flow measurement device is installed and stored.

Referring to FIG. 7, the fluid storage system according to the present invention includes a pipe flow meter for measuring the flow rate of the pipe 20 through which the fluid passes, a collector pipe for collecting the fluid and introducing the fluid into the pipe 20 A fluid reservoir 300 for collecting fluid flowing out of the tubular body 20 and a discharge tube 630 branched from a connection tube 620 connecting the tubular body 20 and the fluid reservoir 300, An open / close valve 650 installed in the fluid storage tank 300 for allowing or blocking the discharge of the fluid flowing out from the tube 20; and a storage tank level sensor 400 installed in the fluid storage tank 300 for measuring the level of the fluid, And a controller 500 that controls the opening / closing valve 650 to allow the discharge of the fluid when the flow rate measured by the apparatus reaches the set value or when the measured water level reaches the set level in the storage tank level sensor 400. [

As described above, the flowmeter for a tubular body is for measuring the flow rate of a fluid flowing in the tubular body 20 in real time to confirm the total flow rate collected.

The collected water pipe 100 is a pipe for collecting and flowing fluids such as stormwater collected from a building or an earth surface. The fluid collected in the collecting pipe is passed through the pipe 20 of the pipe fluid measuring device to the fluid reservoir 300, ≪ / RTI >

The fluid reservoir 300 is a portion for collecting and storing a target fluid such as a water tank for collecting storm clouds. The fluid reservoir 300 collects the fluid flowing out of the tube 20 through the tube 20 of the flowmeter for the tube.

In the fluid storage tank 300, a storage tank water level sensor 400 for measuring the water level is provided and the measured value of the water level is transmitted to the controller 500.

The open / close valve 650 is installed in a discharge pipe 630 branched from a connection pipe 620 connecting the tube 20 and the fluid reservoir 300 to allow discharge of the fluid discharged from the tube 20, .

The open / close valve 650 includes a storage tank level sensor 400 that receives a control signal from the controller 500 and operates the fluid tank 300 to measure the level of the fluid. Closing valve 650 is controlled to allow the discharge of the fluid when the flow rate reaches the set value or when the measured water level in the storage tank level sensor 400 reaches the set value.

The controller 500 controls the overall operation of the fluid storage system. When the flow rate measured by the flow rate measuring device reaches a set value or the measured water level in the storage tank level sensor 400 reaches a set value, the controller 500 controls the opening / 650 to allow discharge of the fluid.

Reference numeral 700 denotes a screen for filtering foreign matter.

Hereinafter, an operational process of the flowmeter for a tubular body according to the present embodiment and the fluid storage system including the tubular flowmeter will be described.

First, fluids such as storm fluids flow into the inlet (54) of the buffer tank (50) through the collection pipe (100).

5, since the flow rate of the inflowing fluid is irregular, severe waves are generated on the water surface, so that the height of the water surface can not be accurately measured in the flowmeter for a pipe. However, And the surface wave can be alleviated in the process of flowing down the lower side of the water level plate 53 and flowing to the outflow port 55.

Since the outlet 55 of the buffer tank 50 has a horn shape, the flow of the fluid flowing to the outlet 55 can be formed as a laminar flow along the horn-like curved surface, .

Therefore, even if the fluid flowing into the buffer tank 50 flows into the buffer tank 50 at an irregular amount and generates waves on the surface thereof, the fluid flows through the water level plate 53 and the horn- Can be relaxed to a predetermined level.

The fluid flowing out of the buffer tank passes through the tube 20 of the flowmeter for a tube.

3, the fluid passing through the tubular body 20 includes a connection member 40 for communicating the bottom of the internal space of the tubular body 20 and the lower portion of the measurement chamber 31a of the level gauge 30 And flows into the measurement chamber 31a through the communication passage 42 to float the float 33.

The fluid level can be freely moved through the communication path 42 so that the level of the measurement chamber 31a of the level gauge 30 becomes equal to the level of the measurement chamber 31a, When the sensor 34 measures the distance, the measured distance has an inverse relationship with the water level.

When the distance detection sensor 34 transmits the measurement value to the operation processor, the operation processor displays experimental data on the level and the flow rate of the fluid that has passed through the buffer tank 50, It is possible to confirm the flow rate of the tubular body 20 corresponding to the measured value at the present time by receiving the measured value of the water level flowing in the tubular body 20. That is, since the flow rate per unit time for each water level is measured and stored experimentally in the graph of FIG. 8, the flow rate per unit time that matches the water level at the current point can be immediately obtained by measuring the water level.

Accordingly, when the operation processor transfers information on the flow rate to the controller 500, when the flow rate measured by the flow rate measuring apparatus reaches the set value, the controller 500 opens the opening / closing valve 650, 300 to prevent fluid from entering the fluid reservoir 300.

Also, the controller 500 opens the on-off valve 650 to allow the fluid to be discharged to the outside even when the measured water level reaches a preset value in the storage tank level sensor 400 of the fluid reservoir 300. [

9, the float 33 descends to be in a state of being seated on the receiving portion 37a of the level adjusting portion 37 in the state where there is no fluid flowing in the tubular body 20.

The level adjusting section 37 is provided so as to land on the receiving section 37a of the level adjusting section 37 due to the weight of the float 33 even if a slight amount of fluid accumulates on the bottom of the measuring chamber 31a provided with the level adjusting section 37. [ Respectively.

Even if there is a slight error in the minimum point of the float 33 and the zero point of the distance detection sensor 34 due to an installation error or the like because the height of the landed float 33 can be finely adjusted by rotating the level adjusting unit 37, The lowest point of the float 33 and the zero point of the distance detecting sensor 34 can be made coincident by finely adjusting the height of the receiving portion 37a of the level adjusting portion 37 by rotating the adjusting portion 37. [

This is to match the height of the upper surface of the float 33 with the reference height at which the distance sensor 34 becomes zero when no fluid flows through the tube 20.

The flowmeter for a tubular body of the above-described embodiment is provided with a water level meter 30 having a water level equal to the level of the tubular body 20 and measuring the height of the float 33 therein, .

In addition, the buffer tank 50 is provided on the front side of the level gauge 30 to stabilize the water surface wave of the fluid to be measured and to flow out, thereby stabilizing the fluid in the region to be measured, thereby alleviating the sudden change of the water surface due to the wave.

Accordingly, since the water surface of the tubular body 20 is not directly measured, it is possible to solve the problem of measurement failure due to foreign substances floating on the water surface. In addition, the buffer tank 50 stabilizes the fluid flow, thereby solving the problem of poor measurement of the distance sensor 34 due to the instantaneous fluctuation of the water level due to the wave of the water surface, and the continuous water level measurement in a relatively stable state It is possible.

10 is a cross-sectional view showing a modified structure of the float 60 according to another embodiment of the present invention, and FIG. 11 is a perspective view showing a specific structure of the float 60.

10 and 11, in the present embodiment, the float 60 has a planar upper surface 61 and a cylindrical side wall 62 opened downward, and is formed on the inner side of the cylindrical side wall 62, And a weight 64 attached to the lower end of the conical body 63. The weight 64 is attached to the lower end of the conical body 63,

A plurality of fluid discharge holes (65) penetrate the cylindrical side wall.

A void space 66 is formed between the conical body 63 and the side wall 62 at the lower part of the float 60 and a weight 64 is provided at the lower end of the conical body 63, And the entire center of gravity of the float 60 is located at the lowest position.

Accordingly, even if the level fluctuates severely due to irregular inflow of the fluid, the weight 64 supports the float 60 at the lowermost end to inhibit the float 60 from swinging.

The fluid discharge holes 65 formed in the cylindrical side wall 62 may have air pockets formed in the empty space to affect the buoyancy. Therefore, air and fluid can be discharged have.

12 shows a sectional view in which the structure of the float 70 is changed according to another embodiment of the present invention, and Figs. 13 (a) and 13 (b) Fig.

In this embodiment, the float 70 has a hemispherical shape, and the upper surface is flat and the surface of the upper surface 72 is filled with a valve body 73 made of a hydrophobic material.

In the case of forming the float 70 in a hemispherical shape, even if the float 70 is inclined, the float 70 is caught in the side wall of the measurement chamber 31a, No reception occurs.

That is, since the distances (radii) to the outer surface are all the same with respect to the central point of the hemispherical upper surface, even if the float 70 is inclined due to the sloshing of the water surface, it is caught between the side walls of the measurement chamber 31a Can not occur.

The plate 73 of the hydrophobic material minimizes the covering of the fluid on the upper surface of the float 70 to minimize the problem of obstructing the reflection of the ultrasonic wave, laser, infrared rays, etc. of the distance sensor 34.

Hydrophobic materials have little or no affinity for water molecules, so they push out water from the surface, and wax, ceramics, etc. can be used.

In the float 70 of the present embodiment, a weight 74 is provided at the lower end of the float 70. The weight 74 of the float 70 has a conical bottom end 74b, And a weight weight setting space 75 is formed in the float 70.

The weighing space 75 is formed inside the float 70 and includes a latching space 75a having a predetermined height to allow the latching head 74a to be engaged with the bottom surface 75d and move up and down, A conical space 75b recessed in the central portion of the lower end of the float 70 to receive a conical portion of the lower end of the weight 74 and a conical space 75b in which the conical space 75b and the conical space 75b, And a connection space 75c for connecting the connection terminals 75a and 75b.

When the external force is not applied to the body weight, the lower end of the weight 74 is engaged with the bottom surface 75d of the fastening space 75a, When the weight 74 is pushed up by the external force, the latching head 74a is raised on the latching space 75a and the conical portion of the lower end of the weight 74 is seated in the conical space 75b .

12, the weight 74 is protruded downward as shown in FIG. 13 (b), and the total weight of the float 70 The center is located at the lowest position.

Accordingly, the weight 74 can relax the swinging motion of the float 70 on the swinging motion of the fluid, and the ultrasonic waves, the laser, and the infrared rays are reflected from the upper surface of the float 70 toward the distance detection sensor 34 Can be satisfactorily maintained.

14 illustrates the action of the weight 74 of the float 70 when foreign substances 80 such as debris are accumulated on the bottom of the measurement chamber 31a.

In the case where there is little or no fluid in the tubular body 20, the float 70 descends while the protruded weight 74 first contacts the accumulated foreign substances first.

When the float 70 continues to descend and the float 70 is landed on the receiving portion 37a of the level adjusting portion 37, the weight 74 is pushed by the accumulated foreign matter, And is inserted and seated in the space 75b, thereby preventing the float 70 from descending.

The weight 74 protrudes downward to form the center of gravity at the lowermost side and the float 70 is applied to the receiving portion 37a of the level adjusting portion 37, The weight 74 is prevented from interfering with the fall of the float 70 by inserting it into the float 70. In this case,

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. It goes without saying that other modified embodiments are possible.

20; Tube 30; Water level meter
31; Meter body 31a; Measuring chamber
32b, 37a; Spiral coupling 33; Float
34; A distance detection sensor 35; The upper cover
36; A sensor fixing member 36a; Sensor fixing hole
37; A level adjusting unit 37a; [0030]
40; A connecting member 40a; The lower connection
40b; An upper connecting portion 42; A communication path
46; Na Sa Bong 47; The elastic clamping member
47a, 47b; Elastic wings 50; Buffer tank
52; Buffer space 53; Order plate
53a; A lower end 53b; Top
54; Inlet 55; Outlet
60; Float 62; Side wall
63; Conical body 64; Weights
65; A fluid discharge hole 66; empty place
70; Float 72; Top surface
73; A plate body 74; Weights
74a; Jam head 74b; lower
75; Weight weight installation space 75a; Bottom surface
75b; Conical space 75c; Connection space
100; House water pipe 300; Fluid reservoir
400; Storage tank level sensor 620; Connector
630; A discharge pipe 650; Opening / closing valve

Claims (6)

A tubular body 20 in which the fluid flows in the internal space,
A water level gauge 30 installed at a side of the body 20 to measure the level of the fluid passing through the body 20,
A connecting member 40 connecting the tubular body 20 and the level gauge 30,
And an operation processor for receiving the measurement value from the level meter 30 and deriving the flow rate,
The level gauge (30)
A measuring instrument body 31 formed inside the measurement chamber 31a so as to extend in the vertical direction,
A float floating in the measurement chamber (31a) and floated by the fluid flowing into the measurement chamber (31a)
And a distance detection sensor (34) installed at an upper portion of the measurement chamber (31a) to detect a distance between the sub-fluid and a measured value of the sensed distance to the calculation processor,
The connection member 40 includes a communication passage 42 for communicating the bottom of the internal space of the tube 20 and the lower portion of the measurement chamber 31a,
The float has a hemispherical shape. The float has a top surface and a surface of the upper surface is filled with a valve body 73 made of a hydrophobic material.
A weight is further added to the lower end of the float,
The weight
A lower end is conical, and a latching head 74a is formed at an upper end thereof,
A weight weight installation space is formed in the float,
The weight weight installation space
A latching space 75a formed inside the float and having a predetermined height to allow the latching head 74a to be engaged with the bottom surface 75d and move up and down,
A conical space 75b formed concavely at the center of the lower end of the float to receive the conical part of the lower end of the weight,
And a connection space 75c connecting the engagement space 75a and the conical space 75b,
When the external force does not act on the weight, the lower end of the weight is protruded from the lower end of the float in a state where the engagement head 74a is engaged with the bottom surface 75d of the engagement space 75a, When the weight is pushed up further, the latching head 74a rises on the latching space 75a, and a conical part of the lower end of the weight is seated in the conical space 75b. Device The method according to claim 1,
A buffer tank (50) for stabilizing the flow of fluid flowing into the tube (20) is provided at a front side of the tube (20)
The buffer tank (50)
An inlet 54 through which the fluid flows,
An outlet 55 connected to the tube 20,
A buffer space 52 in which the fluid introduced between the inlet 54 and the outlet 55 is temporarily stored,
The lower end of the buffer space 52 is located in the buffer space 52 at a lower height than the inlet port 54 and the upper end of the inlet port 54 extends in the vertical direction so as to be higher than the inlet port 54, And a water level plate (53) installed so as to oppose to the inlet (54) so that the fluid flows into the inlet (54) and passes through the lower side of the lower end thereof toward the outlet (55)
Characterized in that the outlet (55) is in the form of a horn whose diameter decreases from the buffer space (52) toward the tube (20) 3. The method of claim 2,
At the upper end of the measuring instrument body 31
An upper lid 35 covering the measurement chamber 31a from above,
A sensor fixing member 36 coupled to the upper cover 35 and to which the distance sensing sensor 34 is fixed,
At the lower end of the measuring instrument body 31
Wherein a level adjuster (37) for covering the measurement chamber (31a) from below and provided with a support portion (37a) for supporting the floating body when it is lowered is provided and the height of the support portion (37a) Flow meter for body delete delete A flow meter for a tubular body according to any one of claims 1 to 3,
A collecting pipe 100 for collecting the fluid and introducing the collected fluid into the pipe 20,
A fluid reservoir 300 for collecting fluid flowing out of the tube 20,
A valve 650 installed in a discharge pipe 630 branched from a connection pipe 620 connecting the tube 20 and the fluid reservoir 300 to allow or block the discharge of fluid flowing out of the tube 20; )Wow,
And a storage tank level sensor (400) installed in the fluid storage tank (300) for measuring the level,
The controller 500 controls the opening / closing valve 650 to allow the discharge of the fluid when the flow rate measured by the flow rate measuring device reaches the set value or when the measured water level reaches the set value in the storage tank level sensor 400 The fluid storage system < RTI ID = 0.0 >

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