KR20090070553A - A constant flow control valve - Google Patents

Abstract

A constant flow rate control valve is provided to simplify component parts and to reduce the size of valve using a conical coil spring. A constant flow rate control valve comprises: a flux controller discharging the drain water of fixed amount regardless of the variable supply water amount; an exhausting part(140) discharging the fluid passing through the flux controller, supporting the to the power of the stream passage direction; and a valve cover(110) connected with the exhausting part in order to prevent flux controller from being separated from the exhausting part by the power of the flow path opposite direction.

Description

Constant flow control valve

The present invention relates to a valve for supplying a constant flow rate liquid, and more particularly, by using a conical coil spring, as the supply flow rate increases, the conical coil spring is compressed to reduce the flow path area of the liquid passing between the coil springs. It relates to a valve that always maintains a constant flow rate through the valve.

In general, valves are devices that regulate the flow or volume of fluid. That is, the valve is installed in the pipe or the container to control the flow rate or pressure of the fluid, etc. There are various types according to the purpose.

1 is a cross-sectional view for explaining a constant flow rate control valve according to the prior art.

In the case of a valve in which a flow rate is controlled by a conventional spring, two valve bodies 10a and 10b and a spring 20 fastened with screws, a disk 30 moving according to the pressure of the fluid, and a flow path according to the pressure of the fluid A guide body 50 for guiding the movement path of the disk 30, the holder 60 for connecting the guide body 50 and the spring 20, the flow rate of the fluid to increase the flow rate It consists of an orifice (40) for lowering the pressure of the spring, the spring 20 absorbs the differential pressure (P = P1-P2) before and after the disk 30 generated by the flow of the fluid and the spring 20 The opening area of the orifice 40 changes according to the movement of the orifice.But when the differential pressure increases, the flow rate increases, so that the opening area is reduced and the opening area is largely automatically controlled when the differential pressure decreases so that a constant flow rate Note is a structure. In other words, as the flow rate increases and the spring 20 is compressed, the disk 30 moves along the flow path direction and the opening area of the orifice 40 decreases, so that a constant flow rate may pass even though the flow rate increases. Can be.

However, the valve of the above structure has a lot of components constituting the valve is complicated to assemble, when the large volume of the valve body requires a large flow rate there is a problem that the size of the valve considerably larger than the pipe size is difficult to use. Therefore, the structure of the holder connecting the disc, the guide body and the spring is made of hard metal. In addition, the installation of the valve is connected between the pipe is required a separate connecting means for connecting the pipe and the valve has the disadvantage that the length of the pipe increases by the length of the valve.

The technical problem to be solved by the present invention is to improve the problem of increasing the size of the valve, the number of components in the case of difficulty in installing the valve for supplying a constant flow rate using the conventional compression coil spring and a large flow rate To provide a constant flow control valve.

According to an aspect of the present invention for achieving the above object, there is provided a flow rate control unit for discharging a predetermined amount of discharge water regardless of the variable supply water amount. And a discharge part for supporting the flow control part against the force in the flow direction and discharging the fluid passing through the flow control part.

In some embodiments of the present invention, the flow control part further includes a valve cover engaged with the discharge part to prevent separation from the discharge part due to the force in the opposite direction of the flow path.

In another embodiment of the present invention, the flow control unit has a valve body that moves in accordance with the inflow of the feed water. The valve body is inserted and moves together, the spring spring is changed in accordance with the inflow of the feed water includes a coil spring. Wherein the coil spring passes the fluid through the gap between the spring pitch.

In another embodiment of the present invention, the discharge portion forms a guide hole for guiding the direction in which the valve body moves. Here, the discharge portion is characterized in that for supporting the coil spring against the force in the flow direction.

In another embodiment of the present invention, the valve body is divided into a head portion and a leg portion. Here, in order to prevent the valve body and the coil spring from being separated from the discharge part, a protrusion is formed at the lower end of the leg part.

In another embodiment of the present invention, the leg portion of the valve body is characterized in that it is opened by separating the protrusions at regular intervals to be inserted into the guide hole.

In another embodiment of the present invention, the coil spring is characterized in that formed in a conical shape that the outer diameter is increased in the flow direction.

As described above, in the present invention, the pitch of the coil spring is fluctuated according to the hydraulic pressure so that the fluid passes through the gap between the spring pitches, and the flow rate can be constant by adjusting the area through which the fluid passes. In addition, by using a conical coil spring to realize a constant flow valve it is possible to simplify the components and reduce the size of the valve.

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

Figure 2 is an exploded perspective view for explaining a constant flow rate control valve according to an embodiment of the present invention. Figure 3 is a partial cutaway perspective view for explaining a constant flow control valve according to an embodiment of the present invention. 4A is a cross-sectional view illustrating a state in which a fluid below a design flow rate is supplied according to an embodiment of the present invention. 4B is a cross-sectional view illustrating a state in which a fluid having a design flow rate or more is supplied according to an embodiment of the present invention. 5 is an exploded perspective view for explaining a constant flow rate control valve according to another embodiment of the present invention. 6 is a combined perspective view for explaining a constant flow rate control valve according to another embodiment of the present invention. 7A is a cross-sectional view illustrating a state in which a fluid below a design flow rate is supplied according to another embodiment of the present invention. 7B is a cross-sectional view illustrating a state in which a fluid having a design flow rate or more according to another embodiment of the present invention is supplied.

2 to 4B, a flow rate control unit including a valve body 120 and a coil spring 130 is provided. The flow rate controller may pass a fluid having a certain flow rate by moving according to the inflow of the feed water. The valve body 120 may move according to the inflow of the feed water. The valve body 120 is inserted into the coil spring 130, when the valve body 120 moves, the coil spring 130 may be compressed. The coil spring 130 may supply fluid to a gap between the spring pitches by changing the spring pitch according to the inflow of the feed water.

It is provided with a discharge portion 140 having a guide hole 144 for guiding the direction in which the valve body 120 moves. Here, the discharge unit 140 may support the coil spring 130 with respect to the force in the flow direction.

The coil spring 130 may have the same pitch. Here, the pitch refers to the distance in the axial direction of the corresponding point of the neighboring coil windings, so that one revolution of the coil advances by the distance in the axial direction.

The valve body 120 may be divided into a head 124 and a leg 128. The head 124 may be a plate-shaped structure of a circular or specific shape having a predetermined thickness perpendicular to the flow direction. The leg portion 128 extends in the flow path direction and is inserted into the coil spring 130 to be in contact with the coil spring 130 at the upper end, and at the lower end of the guide hole 144 of the discharge part 140. It may be a structure that can move up and down in the flow direction along the. The shape of the leg 128 may be a variety of shapes, such as a cross-section circular, square, hexagonal.

The coil spring 130 may be formed in a conical shape in which the outer diameter becomes larger and larger in the flow path direction and may be disposed on the discharge part 140. When a fluid having a design flow rate or less is supplied, the tension of the coil spring 130 supports hydraulic pressure so that the fluid may pass through the gap between the pitches of the coil spring 130 as it is. If a fluid having a design flow rate or more is supplied, the hydraulic pressure exceeds the tension of the coil spring 130 so that the head 124 of the valve body 120 coupled with the coil spring 130 is pressed in the flow direction and moved therein. Accordingly, the coil spring 130 is compressed to reduce the pitch and the area of the flow path passing through the valve is reduced.

Since the flow rate value is equal to the flow rate value multiplied by the flow path area, the supply flow rate increases and the flow rate increases due to the hydraulic rise, but the area of the flow path decreases so that a constant flow rate can always be supplied. At this time, when supplying a flow rate exceeding the tension of the coil spring 130 or more than a threshold value, the coil spring 130 has a constant pitch that is not compressed to the smallest portion of the inner diameter, the coil spring 130 Even at this maximum compression, it is desirable to allow fluid to flow through the gap between the pitches. This is because the coil spring 130 is compressed to the maximum, so that the flow path area becomes zero, and fluid may not pass at all.

The discharge unit 140 may be formed in a cylindrical structure having a predetermined thickness in accordance with the shape of the pipe to be inserted and fixed inside the pipe (not shown). A packing may be inserted into an outer wall of the discharge part 140 to fix a leak that may occur in a gap between the pipe and the discharge part 140 and to fix the discharge part 140 itself. In the middle of the discharge unit 140, when the valve body 120 moves up and down by hydraulic pressure, a guide hole 144 may be formed to guide the movement, and to support the guide hole 144 Except for a certain thickness of flesh for the remaining portion may be a space for the fluid passing through the coil spring 130 can be discharged to the discharged water.

The valve body 120 and the coil spring 130 further includes a valve cover 110 that is coupled to the discharge portion 140 to prevent separation from the discharge portion 140 due to the force in the opposite direction of the flow path can do. The valve cover 110 is a cylindrical structure having a predetermined thickness, the bridge-shaped structure in the middle of the valve cover 110 is connected to both ends in a straight line, and is coupled to the discharge portion 140 is the valve cover 110 The coil spring 130 and the valve body 120 enter between the discharge part 140 and constitute a single valve. The leg-shaped structure is usually in contact with the head 124 of the valve body 120 so that the valve body 120 and the coil spring 130 in the discharge portion 140 against the force of the reverse direction of the flow path It can serve to prevent separation.

5 to 7B, a valve body 210 that is movable according to the inflow amount of the feed water is provided. The valve body 210 is inserted and is provided with a coil spring 220 that can move with the valve body 210. The coil spring 220 may supply a fluid to a gap between the pitches by changing the pitch of the spring according to the inflow of the feed water. It is provided with a discharge portion 230 having a guide hole 234 for guiding the direction in which the valve body 210 moves. Here, the discharge unit 230 may support the coil spring 220 with respect to the force in the flow direction.

 The valve body 210 may be divided into a head 214 and a leg 218. Here, in order to prevent the valve body 210 and the coil spring 220 from being separated from the discharge part 230, a lower end of the leg part 218 may be formed as a protrusion 216.

The leg portion 218 of the valve body 210 may be opened by separating the protrusion 216 at regular intervals to be inserted into the guide hole 234. In detail, the valve body 210 and the coil spring 220 are separated from the discharge part 230 by the reverse triangular round protrusion at the end of the leg part 218. Can function to prevent In addition, an empty space having a predetermined distance and a thickness in the opposite direction from the end of the leg portion 218 is made, and despite the outer diameter of the lower end of the leg portion 218 increased due to the protrusion 216, the leg portion ( When the 218 is inserted into the guide hole 234 of the discharge part 230, the lower end of the leg part 218 can be easily inserted by an empty space, and after insertion, the shape of the leg part 218 can be achieved. This restoration may prevent the valve body 210 from escaping from the discharge part 230 in the direction opposite to the flow path by the protrusion 216. At this time, since the discharge unit 230 does not use a valve cover unlike the embodiment of the present invention described with reference to Figures 1 to 3b, there is no need to form a coupling structure with the valve cover, the valve By forming the protrusion 216 at the lower end of the leg portion 218 of the body 210, the length of the guide hole 234 is shortened, and thus, the structure of the discharge part 230 may be simplified and smaller.

The discharge unit 230 is a cylindrical structure having a predetermined thickness in accordance with the shape of the pipe in a structure that can be fixed to the pipe is inserted into the pipe, the leakage in the gap between the pipe and the discharge unit 230 and the discharge A packing may be inserted into the outer wall of the discharge part 230 to fix the part 230 itself.

Hereinafter, the present invention is not limited to the above specific preferred embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. Of course, such changes are within the scope of the claims.

1 is a cross-sectional view for explaining a constant flow rate control valve according to the prior art.

Figure 2 is an exploded perspective view for explaining a constant flow rate control valve according to an embodiment of the present invention.

3 is a partial cutaway perspective view for explaining a constant flow rate control valve according to an embodiment of the present invention.

4A is a cross-sectional view illustrating a state in which a fluid below a design flow rate is supplied according to an embodiment of the present invention.

4B is a cross-sectional view illustrating a state in which a fluid having a design flow rate or more is supplied according to an embodiment of the present invention.

5 is an exploded perspective view for explaining a constant flow rate control valve according to another embodiment of the present invention.

6 is a combined perspective view for explaining a constant flow rate control valve according to another embodiment of the present invention.

7A is a cross-sectional view illustrating a state in which a fluid below a design flow rate is supplied according to another embodiment of the present invention.

7B is a cross-sectional view illustrating a state in which a fluid having a design flow rate or more according to another embodiment of the present invention is supplied.

Claims (7)

A flow rate controller for discharging a predetermined amount of discharge water regardless of the variable supply water amount; And And a discharge part for supporting the flow rate control part against a force in a flow path direction and discharging the fluid having passed through the flow rate control part. The method of claim 1, And a valve cover coupled to the outlet to prevent the flow controller from being separated from the outlet by force in the opposite direction of the flow path. The method of claim 1, The flow control unit A valve body moving according to the inflow of the feed water; And a coil spring in which the valve body is inserted and moved together, wherein a spring pitch is changed according to the inflow of the feed water, wherein the coil spring passes a fluid through a gap between the spring pitches. The method of claim 3, wherein And a guide hole for guiding a direction in which the valve body moves in the discharge part, wherein the discharge part supports the coil spring with respect to a force in a flow path direction. The method of claim 4, wherein The valve body is divided into a head portion and a leg portion, a constant flow rate control valve, characterized in that a projection formed at the bottom of the leg portion to prevent the valve body and the coil spring from being separated from the discharge portion. The method of claim 5, wherein The leg portion of the valve body is a constant flow rate control valve, characterized in that open by separating the projections at regular intervals so that it can be inserted into the guide hole. The method of claim 3, wherein The coil spring is a constant flow rate control valve, characterized in that formed in a conical shape that the outer diameter increases in the flow direction.

Images