KR102300883B1 - Device for opening and closing fluid flow by electric signal - Google Patents

Abstract

Disclosed is an electronically-controlled device for opening and closing a fluid flow, which easily controls a fluid flow in a pipe even by very small electric energy, and has excellent durability and maintainability. According to an embodiment of the present invention, the electronically-controlled device for opening and closing a fluid flow comprises: a housing having a first chamber and a second chamber in a longitudinal direction therein, and a ventilation hole communicating with the second chamber and formed on the outside thereof; an input channel formed on a side of the housing to be connected to the first chamber; an output channel formed on the front surface of the housing to be connected to the first chamber; a poppet valve provided in the output channel, and closing an inlet of the output channel; a spring unit provided in the output channel, and pressing the poppet valve toward the first chamber; a piston provided in the second chamber; a rod penetrating a wall between the first chamber and the second chamber, wherein one end thereof is coupled to the poppet valve and the other end thereof is coupled to the piston; a bypass channel provided in the housing to connect the input channel and the second chamber; and a solenoid valve provided on the housing to open and close the bypass channel.

Description

Electronically controlled fluid flow switchgear {DEVICE FOR OPENING AND CLOSING FLUID FLOW BY ELECTRIC SIGNAL}

The present disclosure (The Present Disclosure) relates to a device installed in a pipeline or the like to open and close a fluid flow.

Solenoid valves are mainly used in industrial sites to operate (open/close) the fluid flow inside the pipeline with electrical signals.

Korean Patent Publication No. 10-1155658 discloses an example of a solenoid valve.

The solenoid valve disclosed in the above publication has a structure in which a plunger moving in a vertical direction directly opens and closes the inside of the valve body by the electrical action of a coil and a permanent magnet.

On the other hand, in the case of the solenoid valve disclosed in the above-mentioned publication, since a large amount of electrical energy is required to operate the plunger as the overall size increases, it is difficult to apply the solenoid valve to a large pipeline.

An object of the present invention is to provide an electronically controlled fluid flow switchgear that can easily operate (open/close) the flow of fluid inside a pipeline even with a small amount of electrical energy, and have excellent durability and maintainability (assembly).

An electronically controlled fluid flow opening/closing device according to an embodiment includes: a housing having a first chamber and a second chamber provided therein along a longitudinal direction, and having a ventilation hole communicating with the second chamber to the outside; an input channel formed on a side surface of the housing and connected to the first chamber; an output channel formed on a front surface of the housing and connected to the first chamber; a poppet valve provided inside the output channel and closing the inlet of the output channel; a spring unit provided inside the output channel and urging the poppet valve in the direction of the first chamber; a piston provided inside the second chamber; a rod passing through a wall between the first chamber and the second chamber, one end coupled to the poppet valve and the other end coupled to the piston; a bypass channel provided inside the housing and connecting the input channel and the second chamber; and a solenoid valve provided in the housing to open and close the bypass channel.

The electronically controlled fluid flow opening/closing device according to the embodiment may further include a silencer provided in the ventilation hole.

In addition, the wall may be configured to be detachable from the housing.

In addition, a ring portion is formed to protrude around the inlet of the output channel, and the poppet valve includes: a head portion having a front portion inserted inside the ring portion; a first body part provided at the rear of the head part, having a diameter corresponding to the diameter of the output channel, and having a plurality of openings formed along the periphery; and a second body part provided at the rear of the first body part, the second body part having a smaller diameter than the first body part.

In addition, the spring unit, doedoe surrounding the outside of the second body portion, one side of the spring in contact with the first body portion; and a flange coupled to the front surface of the housing to support the other side of the spring.

In addition, the piston may include a cylindrical body; and a protrusion formed to protrude from the center of the rear surface of the body.

In addition, a through portion communicating with the second chamber may be formed on the rear surface of the housing, and a cover may be coupled to the through portion.

If the electronically controlled fluid flow opening/closing device according to the embodiment is installed in the pipeline, the fluid flow in the pipeline can be easily operated (opened and closed) even with a small amount of electrical energy.

In addition, the electronically controlled fluid flow switchgear according to the embodiment has excellent durability and maintainability (assembly) in terms of its structure, and is easy to enlarge.

1 is a perspective view of an electronically controlled fluid flow opening/closing device according to an embodiment.
2 is an exploded perspective view of an electronically controlled fluid flow opening/closing device according to an embodiment.
FIG. 3 shows a view of FIG. 2 from another side.
4 is a cross-sectional view illustrating a state cut along line AA' of FIG. 1 .
FIG. 5 is a diagram schematically illustrating a fluid flow when the bypass channel is opened in FIG. 4 .

Hereinafter, an electronically controlled fluid flow opening/closing device according to an embodiment will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an electronically controlled fluid flow switchgear 100 (hereinafter referred to as 'fluid flow switchgear 100') according to an embodiment, and FIGS. 2 to 3 are exploded perspective views of the fluid flow switchgear 100. and FIG. 4 is a cross-sectional view of the fluid flow opening/closing device 100 .

1 to 4, the fluid flow switchgear 100 includes a housing 110, an input channel 120, an output channel 130, a poppet valve 140, a spring unit 150, a piston ( 160), the rod 170, the bypass channel 180, and the solenoid valve 190 as essential components, and may further include a silencer 192 as an additional component.

(Definition of each direction) Based on the housing 110 shown in FIG. 1 , the x-axis is defined as the width direction of the housing 110 , the y-axis is defined as the height direction of the housing 110 , and the z-axis is defined as the length direction of the housing 110 . In addition, terms ('front', 'side', 'rear', etc.) referring to the cross-section of things (components) are also defined with reference to FIG. 1 . However, the poppet valve 140 is described based on the direction in which it is installed in the housing 110 .

The housing 110 has a three-dimensional shape having a predetermined volume. The housing 110 may be made of a metal material. Inside the housing 110 , a first chamber 111 and a second chamber 112 are provided along the longitudinal direction of the housing 110 .

The first chamber 111 and the second chamber 112 are completely separated by a wall 113 . The first chamber 111 and the second chamber 112 may have a cylindrical shape. The first chamber 111 and the second chamber 112 are disposed on the same axis.

The housing 110 has a second chamber 112 on the rear surface of the housing 110 in consideration of assembly convenience of some components (poppet valve 140, spring unit 150, piston 160, rod 170). ) and a through-portion communicating with it is formed, and the through-portion may be configured to be closed by a separate cover 115 . In this case, when the cover 115 is separated from the housing 110 , the second chamber 112 is exposed to the outside.

The wall 113 provided inside the housing 110 to partition the first chamber 110 and the second chamber 112 may be configured to be separately separable from the housing 110 . For example, a screw thread 113b is formed on the inner wall of the housing 110 surrounding the second chamber 112, and the wall 113 has a cylindrical shape having a screw thread 113a fastened to the aforementioned screw thread 113b on the outer circumferential surface. can

A ventilation hole 114 communicating with the second chamber 112 is formed outside the housing 110 .

The input channel 120 (Input Channel 120 ) is formed on the side surface of the housing 110 and is connected to the first chamber 111 . A central axis of the input channel 120 and a central axis of the first chamber 111 are perpendicular to each other.

The output channel 130 (Output Channel 130 ) is formed on the front surface of the housing 110 and is connected to the first chamber 111 . The output channel 130 is disposed on the same axis as the first chamber 111 . The fluid supplied to the input channel 120 passes through the first chamber 111 and then is discharged to the outside of the housing 110 through the output channel 130 .

A ring portion 131 may be formed around the entrance of the output channel 130 .

The input channel 120 and the output channel 130 are connected to an external pipe (not shown).

The poppet valve 140 is provided inside the output channel 130 and is configured to move in the longitudinal direction of the housing 110 inside the output channel 130 . The front of the poppet valve 140 faces the output channel 130 , and the poppet valve 140 functions to close the inlet of the output channel 130 . When the poppet valve 140 moves away from the output channel 130 , the inlet of the output channel 130 is opened.

The poppet valve 140 may include a head portion 141 , a first body portion 142 , and a second body portion 143 . Based on the direction in which the poppet valve 140 is installed in the housing 110 , the front portion of the head portion 141 is inserted into the ring portion 131 . The front surface of the head unit 141 may have a convex shape so that the fluid flowing into the output channel 130 is easily deployed (radiated) toward the edge of the head unit 140 .

The first body 142 is provided at the rear of the head 140 , and the first body 142 may be in the form of a pipe having a diameter corresponding to the output channel 130 . A plurality of openings 142a are formed around the head 140 . The opening 142a provides a movement path of the fluid.

The second body portion 143 is provided at the rear of the first body portion 142 and may be in the form of a pipe having a smaller diameter than the first body portion 142 .

The spring unit 150 is provided in the output channel 130 , is disposed behind the poppet valve 140 , and functions to press the poppet valve 140 in the direction of the first chamber 111 .

The spring unit 150 surrounds the outside of the second body part 143, and one side of the spring 151 is in contact with the rear surface of the first body part 142, and the front surface of the housing 110 by a coupling element such as a bolt. It may be coupled to the flange 152 to support the other side of the spring 151 and block the spring 151 from being separated to the outside of the housing 110 .

The piston 160 is provided in the second chamber 112 and is configured to move in the longitudinal direction of the housing 110 in the second chamber 112 . The piston 160 is formed to protrude from the center of the rear surface of the cylindrical body portion 160a and the aforementioned body portion 160a to form an empty space between the body portion 160a and the cover 115 of the housing 110 . It may be composed of a protrusion (160b).

The rod 170 passes through the wall 113 , one end of the rod 170 is coupled to the poppet valve 140 , and the other end of the rod 170 is coupled to the piston 160 . The rod 170 allows the movement of the poppet valve 140 and the piston 160 to interlock. The rod 170 may be integrally configured with any one of the poppet valve 140 and the piston 160 .

The bypass channel 180 is provided inside the housing 110 and connects the input channel 120 and the second chamber 112 (specifically, an empty space formed between the piston 160 and the cover 115 ).

The solenoid valve 190 is provided in the housing 110 and functions to open and close the bypass channel 180 by an electrical signal.

The silencer 192 is provided in the ventilation hole 114 . The silencer 192 functions to reduce noise generated by the fluid discharged to the ventilation hole 114 .

The operation of the fluid flow switchgear 100 will be briefly described.

4 shows the fluid flow when the bypass channel 180 is closed by the solenoid valve 190, and FIG. 5 is the fluid when the bypass channel 180 is opened by the solenoid valve 190. represents the flow.

Referring to FIG. 4 , when the bypass channel 180 is closed, even if a fluid of a predetermined pressure is supplied to the input channel 120 , the pressure of the fluid is higher than the pressure at which the spring unit 150 pushes the poppet valve 150 . When it is low, the inlet of the output channel 130 is closed by the poppet valve 150 , so that the fluid in the input channel 120 cannot move to the output channel 130 .

Referring to FIG. 5 , when the bypass channel 180 is opened, the fluid supplied to the input channel 120 is supplied to the inside of the second chamber 112 through the by-panel channel 180 in a predetermined amount, and the poppet valve (150) and the piston (160) is pressed at the same time. Accordingly, the inlet of the output channel 130 is opened. Subsequently, the fluid in the input channel 120 moves to the output channel 130 via the first chamber 111 .

The fluid flow switching device 100 described above is whether the bypass channel 180 having a significantly smaller diameter than the diameter of the input channel 120 (or the output channel 130) is opened or closed (manipulation of the solenoid valve 190) ], so that it has a structure in which fluid movement from the input channel 120 to the output channel 130 is determined. Accordingly, when the fluid flow opening/closing device 100 is installed in the conduit, it is possible to easily operate (open/close) the fluid flow in the conduit even with a small amount of electrical energy.

In addition, since the fluid flow opening/closing device 100 has a structure in which the number of parts is not large and the main parts are sequentially assembled in one direction inside the housing 110, durability and maintainability (assembly) are excellent.

Various expressions (terms, visualized images, etc.) used when describing the embodiment(s) of the present disclosure are merely selected for the purpose of an instrument to convey the essential technical idea of the present disclosure to the reader in an easy-to-understand manner.

In addition, those of ordinary skill in the art can devise a myriad of modified embodiments that are the same as the above-described embodiment(s) but have different appearances based on the embodiment(s) of the present disclosure. you can do it

Therefore, the scope of the present disclosure should not be limited by some expressions described in the 'description of the invention' and 'drawings', and should be broadly interpreted based on the essential technical idea of the present disclosure.

100... Electronically controlled fluid flow switchgear
--
110... housing
111... first chamber
112... second chamber
113... wall / 113a, 113b... thread
114... vent hole
115... cover
120... input channels
130... output channels
131... ring part
140... poppet valve
141... head
142... first body part / 142a... opening
143... second body
150... spring unit
151... spring
152... flange
160... piston / 160a... body / 160b... protrusion
170... load
180... bypass channel
190... solenoid valve
192... silencer

Claims (7)

a housing having a first chamber and a second chamber provided therein along a longitudinal direction, and a vent hole communicating with the second chamber on the outside;
an input channel formed on a side surface of the housing and connected to the first chamber;
an output channel formed on the front surface of the housing and connected to the first chamber;
a poppet valve provided inside the output channel and closing the inlet of the output channel;
a spring unit provided inside the output channel and urging the poppet valve in the direction of the first chamber;
a piston provided inside the second chamber;
a rod passing through the wall between the first chamber and the second chamber, one end coupled to the poppet valve and the other end coupled to the piston;
a bypass channel provided inside the housing and connecting the input channel and the second chamber; and
a solenoid valve provided in the housing to open and close the bypass channel;
The wall is configured to be detachably from the housing, and a thread is formed on an inner wall of the housing surrounding the second chamber, and a thread for fastening with the thread is formed on an outer circumferential surface of the wall. Fluid flow switchgear. According to claim 1,
The electronically controlled fluid flow opening/closing device further comprising; a silencer provided in the vent hole. delete According to claim 1,
A ring portion is formed protruding around the inlet of the output channel,
The poppet valve is
a head part having a front part inserted inside the ring part;
a first body portion provided at the rear of the head, having a diameter corresponding to the diameter of the output channel, and having a plurality of openings formed along the circumference; and
An electronically controlled fluid flow opening/closing device comprising a; a second body portion provided at the rear of the first body portion, the second body portion having a smaller diameter than the first body portion. 5. The method of claim 4,
The spring unit is
a spring surrounding the outside of the second body part, one side of which abuts on the first body part; and
A flange coupled to the front surface of the housing to support the other side of the spring; and an electronically controlled fluid flow opening/closing device. According to claim 1,
The piston is
a cylindrical body; and
An electronically controlled fluid flow opening/closing device comprising; a protrusion protruding from the center of the rear surface of the body. According to claim 1,
A through portion communicating with the second chamber is formed on the rear surface of the housing,
An electronically controlled fluid flow opening/closing device, characterized in that a cover is coupled to the through portion.

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