KR101692293B1 - Valve having bypass pipe - Google Patents

Abstract

According to the present invention, a bypass-integrated valve comprises: a valve body (10) including a body (20) extended lengthwise in a front and a rear direction, in which three chambers (22, 21, 23) are sequentially formed in a longitudinal direction, separated from each other, and connected to each other by a flow passage (24) penetrated in the front and the rear direction, and a body flange (60, 61) disposed on a front and a rear end of the body (20) and mounted on a pipe flange (2) of a pipe (1) connected to the flow passage (24); a bypass pipe (70) having a bypass passage (71) formed therein, wherein both ends thereof are integrally installed on sides of side chambers (22, 23) installed on both sides of the body (20) to communicate with the flow passage (24); a flow control valve body (80) disposed on a center chamber (21) positioned on a center of the body (20) to adjust a width of the flow passage (24) to adjust a flow; and a pair of passage changing valve bodies (90, 91) disposed on the side chambers (22, 23) of the body to open and close the bypass passage (71).

Description

[0001] Valve having bypass pipe [0002]

The present invention relates to a bypass integrated valve, and more particularly, to a bypass integrated valve capable of controlling a flow rate while exchanging and checking parts of a flow control valve.

A flow control valve, such as a globe valve that is normally connected to a pipe and capable of controlling the flow rate, is required to be periodically checked and replaced. Accordingly, an opening / closing valve, such as a ball valve, is provided at the upstream and downstream pipes around the flow control valve to shut off the flow of the fluid, and to check and replace the components of the flow control valve. At this time, the bypass pipe is installed because there is a need to continuously move the fluid even during the check of the flow control valve. The bypass pipe is equipped with an opening / closing valve that normally closes the flow path of the bypass pipe so that the fluid flows to the original pipe. When the flow control valve is inspected, the flow path of the bypass pipe is opened, And flows into the pipe.

However, in order to check the flow rate control valve, the front and rear ends of the pipe are closed and the bypass pipe is opened. However, there is a problem that the flow rate can not be controlled through the bypass pipe. Accordingly, when it is necessary to continuously adjust the flow rate, it is difficult to check the flow rate control valve. Further, since the flow control valve and the opening / closing valve must be separately installed in the piping, there is a problem that the operation is troublesome.

Korean Patent Publication No. 10-2010-0015148

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a bypass integral valve which is composed of a single unit and which is easily installed, And the like.

According to an aspect of the present invention, three chambers 22, 21, and 23 are sequentially and longitudinally spaced apart from each other in a longitudinal direction and are extended in the front and rear directions. The main chambers 24, A body flange 60 provided at the front and rear ends of the body 20 and coupled to the pipe flange 2 of the pipe 1 communicating with the main flow channel 24, 61); And a bypass pipe 71 formed integrally with both sides of the side chambers 22 and 23 at both ends of the body 20 so as to communicate with the main flow path 24, (70); A flow rate regulating valve body 80 provided in the central chamber 21 located at the center of the body 20 to regulate the flow rate of the main flow channel 24; And a pair of passage switching valve bodies (90, 91) provided in the respective side chambers (22, 23) of the body (20) for opening and closing the bypass passage (71) A bypass integral valve is provided.

According to another aspect of the present invention, the body 20 includes the center chamber 21 provided at the center, and an inlet port 31 (see FIG. 1) provided at the center side and into the central chamber 21 for receiving the flow control valve body 80 A pair of first lateral split chambers 33 and 34 provided at both ends and forming a part of each of the lateral chambers 22 and 23, A central body 30 having central flanges 35, 36 provided at the ends of the first lateral split chambers 33, 34; And a second side partitioning chamber 41 and 51 provided at one end and aligned with the first side partitioning chambers 33 and 34 to form side chambers 22 and 23, Side flanges 42 and 52 provided at the ends of the central body 30 and coupled to the central flanges 35 and 36 of the central body 30 and the body flanges 60 and 61 provided at the other end, And a pair of side bodies (40, 50).

According to another aspect of the present invention, there is further provided an auxiliary flow control valve body 100 on the bypass flow path 71 of the bypass pipe 70 for controlling the flow rate by adjusting the width of the bypass flow path 71 Wherein the bypass valve is provided with a bypass valve.

As described above, according to the present invention, a single valve body 10 is provided with a central chamber 21 in which a flow control valve body 80 and a pair of passage switching valve bodies 90, 91 are mounted, By providing chambers 22 and 23 and a bypass pipe 70 integrally communicating with the side surfaces of the side chambers 22 and 23 so that the respective valve bodies are spaced apart from each other in the pipes 1 and 3 Since only a single valve body 10 is required to be installed in the pipes 1 and 3, the time is shortened and the number of components is reduced.

The flow path switching valve body (90, 91) can switch the flow path to the bypass pipe (70) and check and replace the flow rate control valve body (80) for use. At this time, the auxiliary flow control valve body 100 is provided in the bypass pipe 70 so that the flow rate of the fluid flowing through the bypass pipe 70 can be adjusted even when the flow control valve body 80 is checked do. Accordingly, even when the flow rate control is continuously required, the flow rate control valve body 80 can be easily checked and replaced. On the other hand, since the flow path switching valve bodies 90 and 91 close the bypass flow path 71, the fluid does not flow into the bypass pipe 70 at normal times. Therefore, the use time of the bypass pipe 70 is reduced, And the cleaning is also simplified.

Meanwhile, the valve body 10 is composed of the central body 30 and the pair of side bodies 40, 50, and the side chambers 22, 23, in which the flow path switching valve bodies 90, 91 are installed, And the second side partitioning chamber 41 and the second side partitioning chamber 41 are formed in the side body 30 and the side bodies 40 and 50, Since the switching valve bodies 90 and 91 can be easily mounted and used, the manufacturing cost of a separate mold for manufacturing a new type of valve can be reduced and the installation convenience can be improved. The bypass pipe 70 is fitted to the side surfaces of the side chambers 22 and 23 to be divided, and the first and second side partitioning chambers 33, 34, 41, By fitting, it is possible to reduce the number of parts and to assemble easily. Also, since the bypass pipe 70 is separated from the valve body 10, the bypass flow path 71 is more easily cleaned.

1 is a perspective view showing an embodiment of a bypass integral valve according to the present invention;
2 is an exploded perspective view of the above-
3 is a plan view of the disassembled state of the above embodiment
4 is a plan view showing the first operation of the above-
5 is a plan view showing the second operation of the above-

The objects, features and advantages of the present invention will become more apparent from the following detailed description. Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 to 5 are views showing a bypass integrated valve according to an embodiment of the present invention. As shown in the figure, the bypass integrated valve according to an embodiment of the present invention includes a valve body 10 having a main flow path 24 formed therein, and a bypass flow path 71 formed integrally with the valve main body 10 A flow control valve body 80 provided at the center of the valve body 10 and a valve body 80 provided at both sides of the flow control valve body 80, A pair of flow path switching valve bodies 90 and 91 and an auxiliary flow rate adjusting valve body 100 provided in the bypass pipe 70.

The valve body 10 includes a body 20 elongated in one direction and two pipe flanges 2 and 4 of the inlet pipe 1 and the discharge pipe 3 provided at both ends of the body 20, And body flanges 60 and 61 connected to the body flanges 60 and 61, respectively.

In the body 20, three chambers 22, 21, and 23 are sequentially spaced along the longitudinal direction. The chamber 20 includes a central chamber 21, a pair of side chambers 22 provided on both sides of the central chamber 21, , 23). At this time, the central chamber 21 and the side chambers 22 and 23 are preferably spherical. A main passage 24 is formed in the body 20 along the longitudinal direction so that the central chamber 21 and the pair of side chambers 22 and 23 are communicated with each other by the main passage 24. On the other hand, the communication holes 25 and 26, to which the bypass pipe 70 is detachably coupled, are formed on the side surfaces of the pair of side chambers 22 and 23, respectively.

The body 20 includes a long central body 30 in one direction and a pair of side bodies 40 and 50 coupled to both sides of the central body 30. 3, the central body 30 includes a central chamber 21 provided at the center, an entrance 31 provided at the center side of the central chamber 21 for receiving and exiting the flow control valve body 80, A lid 32 for opening and closing the entrance 31, a pair of first lateral split chambers 33 and 34 provided at both ends of each of the lateral chambers 22 and 23 to form a part of each of the lateral chambers 22 and 23, A center flange 35 and 36 provided at an end of the side partitioning chambers 33 and 34 and a portion of the outer side of the bypass pipe 70 formed at one side of the first side partitioning chambers 33 and 34 And a first concave groove 37 of a wrapping shape.

The pair of side bodies 40 and 50 are provided at one end and are aligned with the first lateral split chambers 33 and 34 to form second lateral split chambers 41 and 51 Side flanges 42 and 52 provided at the ends of the second lateral split chambers 41 and 51 and coupled to the central flanges 35 and 36 of the central body 30, A second concave groove 38 formed at one side of the split chambers 41 and 51 and surrounding a part of the outer surface of the bypass pipe 70 and the body flanges 60 and 61 provided at the other end. When the side bodies 40 and 50 are coupled to the central body 30 as shown in FIGS. 3 and 4, the second concave groove 38 of the side bodies 40 and 50 and the second body 40 of the central body 30 1 concave grooves 37 are matched to form the communication holes 25 and 26 to which the bypass pipe 70 is detachably coupled. On the other hand, a packing is provided between the central flanges 35, 36 and the side flanges 42, 52.

Since the side chambers 22 and 23 are divided into the first side partitioning chambers 33 and 34 and the second side partitioning chambers 41 and 51 as described above, the flow path switching valves 90 and 91 are disposed in the side chambers 22 and, 23). Further, an entrance 31 is formed in the central chamber 21 so that the flow control valve 80 can be easily installed.

The bypass pipe 70 is formed with a bypass passage 71 therein and is bent in a substantially diagonal shape so that both ends of the bypass pipe 70 are connected to the communication holes 25 and 26 of the side chambers 22 and 23 of the valve body 10, Respectively. The bypass passage 71 of the bypass pipe 70 and the main passage 24 of the body 20 are communicated with each other. At this time, an opening 72 opened and closed by a lid 73 is formed in the middle portion of the bypass pipe 70.

The flow rate control valve body 80 is provided in the central chamber 21 of the body 20 to adjust the flow rate by adjusting the width of the main flow channel 24. In the illustrated embodiment, the flow control valve body 80 is made of a spherical body, and a V-groove 81 is formed, and the flow rate is controlled by a change in cross-sectional area of the main flow path 24 as it is rotated by an unillustrated lever However, various types of valve bodies capable of controlling the flow rate such as globe valves are possible.

The pair of flow path switching valve bodies 90 and 91 are provided in the pair of side chambers 22 and 23 of the body 20 to open and close the bypass flow path 71 of the bypass pipe 70. In the illustrated embodiment, the flow path switching valve bodies 90 and 91 are made of spheres and have been perforated in three directions. Such a flow path switching valve body 90 or 91 normally closes the bypass flow path 71 as shown in FIG. 4 so that the main flow path 24 passes through the flow rate regulating valve body 80. When the flow control valve body 80 is to be inspected or replaced, as shown in FIG. 5, the flow path switching valve bodies 90 and 91 open the bypass flow path 71, (24) to block the flow of the fluid into the flow control valve body (80).

The auxiliary flow rate regulating valve body 100 is provided on the bypass flow path 71 of the bypass pipe 70 to regulate the flow rate of the fluid flowing through the bypass flow path 71. The auxiliary flow control valve body 100 has the same shape as the flow control valve body 80.

The bypass integrated valve according to one embodiment of the present invention configured as described above includes a flow control valve body 80 and a pair of flow path switching valve bodies 90 and 91 to a single valve body 10, Since the bypass pipe 70 selectively opened and closed can be integrally provided, only the valve body 10 can be connected to the pipes 1 and 3, thereby facilitating the installation. Further, the bypass flow path 71 can be opened to easily check and replace the flow rate control valve body 80. At this time, even when the flow control valve body 80 is checked, the flow rate of the fluid flowing along the bypass pipe 70 is controlled by the auxiliary flow control valve body 100. Accordingly, even when the flow rate should be continuously controlled, the flow rate control valve body 80 can be easily checked and replaced, thereby improving the durability of components and controlling the flow rate more precisely.

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 inventions. It will be apparent to those of ordinary skill in the art.

Claims (3)

And a central chamber 21 and two side chambers 22 and 23 located on both sides of the center chamber 21 are spaced apart from each other and the main chambers 21 are provided with the three chambers 21 A body flange 2 provided at both ends of the body 20 and connected to the pipe flange 2 of the pipe 1 communicating with the main flow channel 24, (10) comprising a valve body (60, 61);
A bypass passage 71 is formed in the body 20 and both ends of the bypass passage 71 are connected to the side walls of the side chambers 22 and 23 of the body 20 of the valve body 10, A tube 70;
A flow control valve body 80 provided in the central chamber 21 of the body 20 of the valve body 10 to adjust the flow rate of the main flow channel 24; And
A pair of flow path switching valve bodies 90 and 91 provided in a pair of side chambers 22 and 23 of the body 20 of the valve body 10 to open and close the bypass flow path 71; ≪ / RTI &
The body 20 of the valve body 10 includes a central chamber 21 therein and an inlet 31 through which the flow control valve body 80 is inserted into and out of the central chamber 21, A pair of first lateral split chambers 33 and 34 provided at both ends of each of the lateral chambers 22 and 23 for opening and closing the first lateral split chambers 31 and 31, A pair of central flanges 35 and 36 provided at the ends of the chambers 33 and 34 and a plurality of outer flanges 35 and 36 formed at one side of the first lateral split chambers 33 and 34, And a first concave groove (37) surrounding the central body (30). And
And a part of each of the side chambers 22 and 23 is formed at one end to form the side chambers 22 and 23 as they are aligned with the respective first side split chambers 33 and 34 of the central body 30 And a side flange 42 provided at an end of each of the second lateral split chambers 41 and 51 and coupled to the central flanges 35 and 36 of the central body 30, And a second concave groove (38) formed on one side of the second side partitioning chamber (41, 51) and surrounding a part of an outer surface of the bypass pipe (70) And a pair of side bodies (40, 50) provided with a pair of side plates (60, 61)
When the side chambers 22 and 23 are formed as the first and second side partitioning chambers 33 and 34 are mated with the central body 30 and the side bodies 40 and 50 are coupled to each other, 70 are detachably fitted to the communication holes 25, 26 formed by matching the first concave groove 37 of the central body 30 and the second concave groove 38 of the side bodies 40, Wherein the bypass valve is provided with a bypass valve.


delete The apparatus according to claim 1, further comprising an auxiliary flow rate regulating valve body (100) for regulating a flow rate of the bypass flow path (71) on a bypass flow path (71) of the bypass pipe (70) By-pass valve.

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