KR102147271B1 - Flowmeter with check valve - Google Patents

Abstract

The present invention provides a check valve combined flow meter capable of reducing the installation cost and maintenance cost of a flow meter and a check valve by integrating a check valve required for preventing backflow of fluid in a fluid flow system and a flow meter for measuring the flow rate. The purpose.
In order to achieve the above object, a flow meter for a check valve according to an embodiment of the present invention includes a tapered flow path 100 having a diameter of one side greater than the diameter of the other side in a vertical direction and penetrating the inside thereof, and the flow path 100 ), and a float 200 positioned within and maintaining a balance, and a stopper 500 having a stepped portion along the inner wall of the flow path 100 and passing through the center portion thereof.

Description

Flowmeter with check valve {FLOWMETER WITH CHECK VALVE}

The present invention relates to a flow meter combined with a check valve, and more particularly, to a flow meter combined with a check valve capable of not only measuring a flow rate but also preventing backflow of a fluid.

In general, a flow meter is a device capable of measuring a flow rate, and the types thereof include a differential pressure type flow meter, an area type flow meter, an electronic flow meter, an ultrasonic flow meter, a turbine flow meter, a positive displacement flow meter, and a vortex flow meter.

Among them, the area type flowmeter is composed of a tapered transparent glass tube or metal tube and a float vertically moving inside the tube (see FIG. 1).

Since such an area type flowmeter has a structure in which the passage of the fluid can be changed according to the flow rate, the pressure difference between the top and the bottom of the float is always kept constant. That is, in an area type flow meter, since the change in the area of the flow path through which the fluid flows is a function of the flow rate, the use of a tapered tube makes it possible to make the flow rate and the flow channel area change in a linear relationship.

1 is a diagram showing the principle of a conventional general area type flow meter.

Referring to FIG. 1, in a conventional area type flow meter, when fluid flows into the lower part of the pipe, the float rises upward, and the pressure difference, buoyancy, gravity and viscous forces acting on the float are stopped at a position in parallel. do.

Therefore, when the float is in balance at a predetermined position, the force pushing the float down and the force pushing it upward are the same. In this way, the flow rate is measured by detecting the position of the float being balanced.

Meanwhile, the Fluid Flow System, in which the fluid flow rate changes, is used for fluid transfer in plants, etc., and mechanisms such as pumps, turbines, and condensers are installed to increase pressure or cool down while fluid flows along the pipe. Etc.

When the above-described area type flowmeter is installed in such a fluid flow system, the float is operated to balance the flow as the fluid flows through the flowmeter.

In addition, in such a fluid flow system, a check valve is used to prevent the flow of flow in the reverse direction when the flow of fluid flows backward. That is, such a check valve is a one-way flow valve that allows fluid to flow in only one direction and not in the opposite direction, and is mainly used for water supply and drainage pipes.

However, if the area type flowmeter and the check valve described above are separately installed in such a fluid flow system, there is a problem in that the installation cost and maintenance cost increase.

For this reason, there is a demand for a flow meter combined with a check valve capable of measuring a flow rate while serving as a check valve.

Accordingly, the present invention was derived in order to solve the above demands, and its purpose is to simultaneously perform the function of the flow meter for measuring the flow rate as well as the function of the check valve required for preventing backflow of the fluid, thereby providing a flow meter and a check valve. It is to provide a flow meter with a check valve that can reduce installation and maintenance costs incurred when separately installed.

In order to achieve the above object, the flow meter for combined use of a check valve according to an embodiment of the present invention includes a tapered flow path 100 having a diameter of one side greater than the diameter of the other side in a vertical direction and penetrating the inside thereof, and the flow path 100 ), and a float 200 positioned within and maintaining a balance, and a stopper 500 having a stepped portion along the inner wall of the flow path 100 and passing through the center portion thereof.

In addition, in the flow meter with check valve according to another embodiment of the present invention, when the fluid flowing in one direction in the flow path 100 flows backward, the float 200 is caught by the stopper 500 to block the flow of the fluid. To prevent backflow.

In addition, in the flow meter for combined use of a check valve according to another embodiment of the present invention, the flow path 100 is spaced apart from the float 200 at a predetermined interval on one side of the flow path 100 from the center of the diameter of the flow path 100. It includes a fixing part 300 to which a plurality of rods are connected toward an inner wall of the flow path 100, and an elastic member 400 is formed from the center of the diameter toward the float 200.

In addition, a flow meter for combined use of a check valve according to another embodiment of the present invention includes a flow path 100 ′ penetrating the inside in a horizontal direction and a float 200 ′ located in and balancing the flow path 100 ′. And a stopper 500 ′ having a stepped portion along the inner wall of the flow path 100 ′ and passing through a central portion thereof.

In order to achieve the above object, in the check valve combined flow meter according to another embodiment of the present invention, the float 200 ′ has a disk-shaped head 210 ′, and from one side of the head 210 ′ It includes a rod 220' extending toward the other side.

In addition, a flow meter for combined use of a check valve according to another embodiment of the present invention is spaced apart from the float 200 ′ at a predetermined distance on an inner side of the flow path 100 ′, so that the diameter of the flow path 100 ′ is It includes a fixing portion 300 ′ in which a plurality of rod shapes are connected from the center toward the inner wall of the flow path 100 ′, and an elastic member 400 from the center of the diameter toward the float 200 ′. ') is formed.

In addition, in the flow meter for use with a check valve according to another embodiment of the present invention, the flow path 100 ′ is connected to and integrated with the pump 700, and measures the discharge amount of the fluid generated by the pump 700. .

According to the present invention, by simultaneously performing the function of the flow meter for measuring the flow rate as well as the function of the check valve required to prevent backflow of fluid, it is possible to reduce the installation cost and maintenance cost incurred when the flow meter and the check valve are separately installed. There is an effect of providing a flow meter for both check valves.

1 is a view showing the principle of a conventional general area type flow meter.
2 is a perspective view showing a cross section of a flow path and a float according to the present invention.
Figure 3 is a cross-sectional view showing a cross-section of a flow meter combined with a check valve according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing a state inclined shape of the opposite portion of the flow meter combined check valve according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing a cross-section of a flow meter combined with a check valve according to another embodiment of the present invention.
6 is a cross-sectional view showing a cross-section of a pump connected to a flow meter combined with a check valve according to another embodiment of the present invention.

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

The area type flowmeter has a fixed fluid flow path, and the differential pressure measured upstream and downstream of the cooking appliance has a function of the flow rate. However, since the area type flowmeter has a structure in which the flow path area of the fluid can be changed according to the flow rate, the pressure difference between the top and the bottom of the float is always kept constant.

That is, in an area type flow meter, since the change in the area of the flow path through which the fluid flows is a function of the flow rate, the use of a tapered tube makes it possible to make the flow rate and the flow channel area change in a linear relationship.

There are various types of area type flowmeters, but the simplest type of area type flowmeter consists of a tapered transparent glass tube or plastic tube, and a float that moves vertically in the tube. When the fluid flows into the lower part of the tube, the float rises upward and stops at a position where the pressure difference, buoyancy, gravity and viscous forces acting on the float are parallel.

Representative area-type flowmeters include a field-indicating glass tube tapered tube type, a site-indicating metal tube type, and a transmission type metal tapered tube type.

The field-indicated glass tube tapered tube type is composed of a transparent material such as hard glass and acrylic resin tapered tube and float. It is installed vertically and directly sees the position of the float and measures the flow rate by directly reading the scale on the tapered tube. When the float moves up and down, there are ones that move along the guide axis in the center of the inclined pipe and one that moves independently without an axis. The float material is selected according to the measurement fluid, such as stainless steel, Teflon, and PVC.

The field-indicated metal tube type is composed of a full lot on the float axis like a metal taper, and a transparent straight tube is installed on the top of the tapered tube in a movable part, and by reading the position of the movable part to be viewed, direct flow rate is obtained and withdrawn to the outside. There is an indirect flow rate indication, and as an advantage, it has excellent mechanical strength against temperature and pressure compared to a glass tube type, and can be applied to opaque fluids.

The transmission type metal taper tube directs the movement of the moving part in the metal taper tube by means of an external withdrawal guide by magnetic coupling, and at the same time, an electrical signal of 4㎃ ~ 20㎃ or an air pressure signal (0.2kgf/㎠ ~ 1.0kgf/㎠) It converts and transmits the flow signal remotely.

The feature of the area type flowmeter is applied as it is to the check valve combined flowmeters 1000 and 1000' according to the present invention. That is, the present check valve combined flow meters 1000 and 1000 ′ perform all functions as flow meters and may use various types of flow meters according to each function. In addition to the functions of these various flow meters, it has a check valve function.

2 is a perspective view showing a cross section of a flow path and a float according to the present invention.

Referring to FIG. 2, a flow meter 1000 for a check valve according to an embodiment of the present invention includes a flow path 100 and a float 200.

The flow path 100 is a path through which water flows, and as described above, in order to make the flow rate and the area change of the flow path in a linear relationship, the diameter of one side (upstream: A) is larger than the diameter of the other side (downstream: B), and Is formed in a tapered shape through which is passed through.

In this embodiment, the flow path 100 is formed in a vertical direction.

In addition, the float 200 is located in the flow path 100 and is balanced in a position where the pressure difference, buoyancy, gravity, and viscous forces acting on the float 200 are parallel.

The float 200 may include, for example, a disk-shaped head 210 and a rod 220 extending from one side of the head 210 toward the other side.

At this time, the rod 220 serves as a weight balance for maintaining the balance of the head 210.

When the float 200 is formed in the shape of the head 210, the head 210 may not maintain a balance in the process of passing a fluid with strong hydraulic pressure in the flow path 100 and may be turned over with shaking (shake). have.

In order to prevent this, the head 210 includes a rod 220, and the rod 220 serves as a weight balance preventing shaking or overturning of the head 210.

For example, when the head 210 is shaken and overturned by a fluid with strong hydraulic pressure, the rod 220 can be prevented from being overturned by being caught on the inner wall of the flow path 100 or descending under its own weight.

The flow path 100 and the float 200 serve as an area type flow meter.

On the other hand, in the present embodiment, the flow path 100 includes a stopper 500.

The stopper 500 forms a step along the inner wall of the flow path 100 and is formed in a shape in which the center portion penetrates.

Accordingly, when the fluid flowing in one direction in the flow path 100 flows backward, the float 200 is caught by the stopper 500 to block the flow of the fluid, thereby preventing the flow. That is, the float 200 and the stopper 500 function as a check valve.

In addition, the stepped surface of the stopper 500 may be formed to be inclined, which can be confirmed through FIG. 4.

At this time, the bottom surface of the head 210 in contact with the stepped surface of the stopper 500 is formed to be inclined to correspond to the stepped surface.

Accordingly, when the fluid flows back, the inclined bottom surface of the head 210 and the inclined stepped surface of the stopper 500 contact each other, thereby preventing the flow of the fluid and preventing the backflow.

3 is a cross-sectional view showing a cross-section of a flow meter combined with a check valve according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view showing an inclined cross-section of a flow meter combined with a check valve according to an embodiment of the present invention.

Referring to FIG. 3, the check valve combined flow meter 1000 according to an embodiment of the present invention may further include a fixing part 300 and an elastic member 400.

The fixing part 300 is formed to be spaced apart from the float 200 at a predetermined interval on one inner side (B side) of the flow path 100.

The fixing part 300 is formed in the shape of a plurality of rods from the center of the diameter of the flow path 100 toward the inner wall of the flow path 100.

For example, from the center of the diameter of the flow path 100 toward the inner wall of the flow path 100, two rod shapes may have a central angle of 180°, and three rod shapes may have a central angle of 120°, or four The rod shape may form a central angle of 90°.

That is, a plurality of rod shapes may be variously formed.

Meanwhile, in a state in which the fixing part 300 is formed, the elastic member 400 may be formed from the center of the diameter toward the float 200.

The roles of the fixing part 300 and the elastic member 400 are as follows. That is, in the check valve combined flow meter 1000 according to an embodiment of the present invention, when the fluid flowing in one direction (B→A) in the flow path 100 is reverse flow (A→B), the end of the rod 220 The elastic member 400 is in contact to mitigate the impact between the head 210 and the stopper 500 of the float 200 to prevent damage that may occur.

On the other hand, the check valve combined flow meter 1000 according to an embodiment of the present invention further includes a rod-shaped support member 600.

Such a support member 600 is attached to the elastic member 400 so that the head 210 of the float 200 slightly collides with the rod 220 immediately before colliding with the stopper 500, while the head 210 or the stopper 500 ) Or to prevent damage to the float 200.

That is, in the flow meter 1000 for use with a check valve according to an embodiment of the present invention, the fluid flowing in one direction (B→A) in the flow path 100 is reverse flowed (A→B), and the end of the rod 220 is supported. When hitting the member 600, the impact of the support member 600 is alleviated by the elastic member 400.

Accordingly, the collision between the lower portion of the head 210 and the stopper 500 is weakened, and damage due to the collision may be prevented.

At this time, the lower portion of the head 210 and the stopper 500 collide with each other and perform a function as a check valve preventing the backflow of fluid (A→B).

As described above, the check valve combined flow meter 1000 according to the present invention not only can measure the flow rate, but also has the effect of preventing the backflow of the fluid at a simple and low cost.

5 is a cross-sectional view of a flow meter for both check valves according to another embodiment of the present invention.

Referring to FIG. 5, a flow meter 1000 ′ for a check valve according to another exemplary embodiment of the present invention includes a flow path 100 ′ and a float 200 ′.

Unlike the previous embodiment, the flow path 100 ′ is formed in a horizontal direction and penetrates the inside.

This flow path 100' is a path through which water flows.

In addition, the float 200 ′ is located in the flow path 100 ′ and is balanced at a position where the pressure difference, buoyancy, gravity, and viscous forces acting on the float 200 ′ are parallel.

The float 200 ′ may include, for example, a disk-shaped head 210 ′ and a rod 220 ′ extending from one side of the head 210 ′ toward the other side.

Meanwhile, the flow path 100 ′ includes a stopper 500 ′ on its inner wall, and the stopper 500 ′ forms a step along the inner wall of the flow path 100 ′ and penetrates the center portion.

Thereby, when the fluid flowing in one direction (B→A) in the flow path 100' is in reverse flow (A→B), the float 200' is caught by the stopper 500' and prevents the flow of the fluid, thereby preventing reverse flow. do. That is, the float 200 ′ and the stopper 500 ′ serve as a check valve.

In addition, the stepped surface of the stopper 500 ′ may be formed to be inclined.

At this time, the bottom surface of the head 210 ′ in contact with the stepped surface of the stopper 500 ′ is formed to be inclined to correspond to the stepped surface, which can be confirmed through FIG. 4.

Accordingly, when the fluid flows back, the inclined bottom surface of the head 210 ′ and the inclined stepped surface of the stopper 500 ′ come into contact with each other, thereby preventing the flow of the fluid and preventing the back flow. That is, it functions as a check valve.

In addition, the check valve combined flow meter 1000' according to another embodiment of the present invention further includes a fixing part 300' and an elastic member 400'.

The fixing part 300 ′ is formed to be spaced apart from the float 200 ′ at a predetermined interval on the inner side of the flow path 100 ′, and extends the inner wall of the flow path 100 ′ from the center of the diameter of the flow path 100 ′. Towards a plurality of rod shapes are connected.

For example, from the center of the diameter of the flow path 100 ′ toward the inner wall of the flow path 100 ′, two rod shapes may have a central angle of 180°, or three rod shapes may have a central angle of 120°, Four rod shapes may form a central angle of 90°.

That is, a plurality of rod shapes may be variously formed.

The elastic member 400 ′ is formed from the center of the diameter of the flow path 100 ′ (the center of the fixing portion 300 ′) toward the float 200 ′.

The roles of the fixing part 300' and the elastic member 400' are as follows. That is, in the flow meter 1000' for combined use of a check valve according to an embodiment of the present invention, when a fluid having a strong hydraulic pressure in the flow path 100' flows in one direction (B→A), the rod 220' is elastic. It is guided into the member 400 ′ and serves to make the head 210 ′ and the elastic member 400 ′ contact each other.

That is, the rod 220 in one embodiment of the present invention serves as a center of gravity so that the head is balanced, but the rod 220 ′ in another embodiment of the present invention has the head 210 ′ and the elastic member It serves to guide the (400') to abut.

In addition, the elastic member 400 ′ provides a force acting on the float 200 ′ and has an effect of replacing gravity when the horizontal flow path is formed.

6 is a cross-sectional view showing a cross-section of a pump connected to a flow meter for combined use of a check valve according to another embodiment of the present invention.

Referring to FIG. 6, in the flow meter 1000' for a check valve according to another embodiment of the present invention, the flow path 100' is connected to the pump 700, and the flow path 100' and the pump 700 are screwed. It may be connected by bonding, welding or flange bonding.

The discharge amount of the fluid generated by the pump 700 may be measured through the check valve combined flow meter 1000' according to the present embodiment.

Among the national fire safety standards notified by the Commissioner of Fire and Disaster Prevention, pumps must be installed on the discharge side piping of an indoor fire hydrant system or sprinkler system in accordance with the technical standards for indoor fire hydrant facilities (NFSC 102) and sprinkler facilities (NFSC 103). That is, a flow meter that measures the discharge amount at that time while changing the discharge amount during operation of the pump is installed in the pipe branched between the check valve and the on-off valve of the discharge side pipe of the pump. Since the measuring and check valve is used only as a means to prevent backflow of water, installation and maintenance costs are high.

However, since the check valve combined flow meter 1000 ′ according to the present invention measures the flow rate of the fluid and can perform the function of a check valve that prevents reverse flow of water, the installation cost rather than the individual use of the flow meter and the check valve And there is an effect that can reduce the maintenance cost.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100, 100': Euro
200, 200': float
210: head
220: rod
300, 300': fixed part
400, 400': elastic member
500: stopper
600: plate
1000, 1000': Flow meter with check valve

Claims (7)

A tapered flow path 100 having a diameter of one side greater than that of the other side in a vertical direction and penetrating the inside thereof,
A float 200 positioned in the flow path 100 and balancing,
A stopper 500 having a stepped portion along the inner wall of the flow path 100 and penetrating the central portion thereof,
A plurality of rod shapes are connected from the center of the diameter of the flow path 100 toward the inner wall of the flow path 100 by being spaced apart from the float 200 at a predetermined interval on the inner side of the flow path 100 It includes a fixed portion 300,
A flow meter combined with a check valve in which an elastic member 400 is formed from the center of the diameter toward the float 200. The method of claim 1,
When the fluid flowing in one direction in the flow path 100 flows backward, the float 200 is caught by the stopper 500 and blocks the flow of the fluid, thereby preventing the flow of the fluid. delete A flow path 100 ′ through which the fluid flows in the horizontal direction,
And a float 200 ′ that is positioned within the flow path 100 ′ and is balanced,
And a stopper 500 ′ having a stepped portion along the inner wall of the flow path 100 ′ and penetrating a central portion thereof,
The stopper 500' is formed on an upstream side of the float 200' in the direction in which the fluid flows, and when the fluid flows backward in the direction opposite to the direction in which the fluid flows, the float 200' A flow meter combined with a check valve that prevents backflow by being caught by the stopper 500' and blocking the flow of the fluid. The method of claim 4,
The float 200 ′,
A disk-shaped head 210',
A combined check valve flowmeter comprising a rod 220' extending from one side of the head 210' toward the other side. The method of claim 4,
A plurality of rods are spaced apart from the float 200 ′ at a predetermined distance from the inner side of the flow path 100 ′ and from the center of the diameter of the flow path 100 ′ toward the inner wall of the flow path 100 ′. ) It includes a fixing part (300') to which the shape is connected,
A flow meter combined with a check valve in which an elastic member 400' is formed from the center of the diameter toward the float 200'. The method of claim 1 or 4,
The flow path is connected to and integrated with the pump 700,
Check valve combined flow meter for measuring the discharge amount of the fluid generated by the pump 700.

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