KR101059004B1 - Insertion type constant flow valve - Google Patents

Abstract

PURPOSE: An insertion-type valve for controlling a flow rate is provided to simplify an installation process and save installation cost since a housing is simply inserted into a pipe without change in a pipe's structure. CONSTITUTION: An insertion-type valve for controlling a flow rate comprises a housing(110), a flow-rate control unit, an elastic member(150) and a noise reducing unit. Fluid passes through the inlet(111) and the outlet(112) of the housing. The raised part(114) of the housing is externally protruded along the outer circumferential surface and is inserted into a pipe. The flow-rate control unit moves depending on fluid pressure and controls the flow rate of the fluid. One end of the elastic member is supported on the inner stepped part(113) of the housing and the other end of the elastic member is supported on the flow-rate control unit.

Description

Insertion Type Constant Flow Valve

The present invention relates to a flow control valve, and more particularly, to an insertion type flow control valve that is simplified by the installation between the pipes connected by the flange to simplify the installation process and reduce the production cost.

In general, the water needed to live is supplied to each site by piping. The type of water for living water is largely divided into a direct feed water, a reservoir water supply, and a mixed feed water in which the direct water supply and the reservoir water are mixed.

Direct water supply is a form of water that is directly supplied from the water meter to each place of use without going through a primary storage facility such as a water tank or a water tank.Storage water is supplied from the water meter to the reservoir in the basement of the building and then to the water tank. It is a form to be supplied, and the mixed water is a form in which a direct feed water and a reservoir water supply are mixed and supplied.

In the direct feed water, the maximum concurrent use rate is 30-30% of the supply capacity in the form of water supply according to the water use time and the amount of use, so that no overflow occurs. However, in the case of water tank water supply, the water tank supply inlet valve in the machine room in which the water tank is located is used as a full on / off type electric valve, so when the valve flow rate is increased to 10-20m / s, the water flow meter design allowable flow rate is increased. Exceeding, causing breakage of the water meter-especially the impeller.

Accordingly, in order to prevent damage of the water meter due to the excess flow rate, a flow rate control valve is provided between the pipes so as to control the flow rate into the pipes. Piping structure in the water meter room is connected with inlet valve, single pipe, strainer, meter, expansion pipe and outlet valve sequentially. However, since the conventional flow control valve is installed in the form of connecting between the pipes already installed through the threads or flanges formed at both ends or welding the end and the end, it is required to secure the installation space as long as the flow control valve itself.

However, since the piping structure in the water meter room is standardized and structured, it is difficult to secure a satisfactory installation space for the installation of the flow control valve. Accordingly, there is a problem that the required cost is greatly increased when changing the structure of the pipe to secure the installation space for the installation of the flow control valve. In addition, even if the fixed flow rate valve is installed between the pipes, if the flow rate control valve itself is broken, there is a problem that the maintenance cost is increased because of difficulty in replacement.

Therefore, there is an urgent need for the development of a method capable of suitably controlling the flow rate without changing the piping structure in the water metering chamber.

The present invention is to solve the above problems, to provide an insertion-type flow control valve that can be installed by simply inserting the housing itself in the pipe at the connection portion connected by the flange without changing the existing pipe structure.

In addition, the present invention is to provide an insertion-type flow control valve that can reduce the noise generated by the change in the hydraulic pressure when the fluid is moved by forming a noise reduction portion in the valve itself.

In order to achieve the above object, the present invention provides a flow rate control valve installed in a pipe through which a fluid flows, and having an inlet and an outlet to allow the fluid to pass therethrough, and protruding a predetermined length outward along an outer circumferential surface thereof. A housing having a locking portion inserted into the pipe; A flow rate adjusting unit disposed inside the housing and moved according to hydraulic pressure to adjust a flow rate of the fluid; An elastic member having one end supported by a stepped portion formed inside the housing and the other end supported by the flow rate adjusting part to move the flow rate adjusting part according to hydraulic pressure; And a noise reduction part provided in at least one side of an outlet of the housing or at least one side of the flow rate control part to reduce noise generated when the fluid is moved, wherein the flow rate control part comprises a plurality of flow paths through which the fluid passes. Is equipped with a through-shaped base portion and a hollow extension portion extending a predetermined length in the center portion of the base portion to adjust the flow rate by moving to the outlet side in accordance with the hydraulic pressure, and one side is fixedly installed on the inner surface of the inlet port Comprising a disk guide for guiding the movement of the noise reduction portion provides an insertion type flow control valve, characterized in that provided with at least one noise reduction groove is formed in a predetermined depth cut along the circumferential direction on the outer peripheral surface of the extension.

Preferably, the housing may be provided in a form in which the cross-sectional area of the interior gradually decreases from the middle to the outlet side.

Preferably, the noise reduction part may be provided with at least one noise reduction groove which is formed in a predetermined depth in the circumferential direction on the inner surface of the outlet.

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Preferably, the extension may be further provided with a discharge path for preventing the vacuum and the discharge of foreign matter in the central region.

Preferably, the disk guide includes a fixing portion fixed to the inner surface of the housing and a guide portion extending a predetermined length from the center portion of the fixing portion to guide the movement of the disk, the fixing portion inside the housing Surfaces and threads corresponding to each other may be formed to be fixedly coupled to the inner surface of the housing through screwing.

Preferably, an airtight member that is tightly fixed along the edge of the locking portion may be further provided.

Preferably, the locking portion and the airtight member may be provided with grooves and protrusions corresponding to each other on the contact surface so as to increase the adhesion.

Preferably, the airtight member may further include at least one raised portion protruding a predetermined height in the radial direction on the outer surface.

Preferably, the end of the elastic member supported by the stepped portion may be provided with a processing surface that is polished to be in surface contact with the stepped portion as a whole.

According to the present invention as described above, by simply inserting the housing itself into the pipe at the connection portion connected by the flange without changing the existing pipe structure, the installation process is simple and the installation cost can be reduced.

In addition, the present invention has an effect that can reduce the noise generated by the change of the hydraulic pressure during the movement of the fluid by forming a noise reduction portion in the valve itself.

1 is an external perspective view of an insert-type flow control valve according to the present invention.
2 is a partial cross-sectional view of FIG.
3 is an exploded view of FIG. 2;
Figure 4 is an installation state of Figure 1;
5 is a graph showing the flow performance of the insertion-type flow control valve according to the present invention.

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

In the following description, the same reference numerals will be used to refer to the same elements even though they are shown in different drawings in order to add reference numerals to help the understanding of the present invention.

Insertion type flow control valve 100 according to a preferred embodiment of the present invention is a pipe (10a, 10b) connected to each other via a pair of flanges (15a, 15b) so that fluid flows continuously (for example, living water Is installed in a large metering room for supplying gas, and is adjusted so that the fluid flowing in the pipes 10a and 10b flows in a constant amount regardless of the hydraulic pressure change. The middle of the pipes 10a and 10b are cut and the flange Unlike the conventional art of connecting a valve having a certain length between the pipe 10a and the pipe 10b after welding the pipes as shown in FIG. 4, the pipes 10a and 10b connected to the flanges 15a and 15b are connected to each other. It is a technical feature to simply insert the valve itself into the installation.

Insertion type flow control valve 100 of the present invention as described above includes a housing 110, the flow control unit 120, the elastic member 150 and the noise reduction portion (161,162).

The housing 110 is inserted into the pre-installed pipe to form the overall appearance of the flow control valve 100, and is provided as a hollow member having both ends open to allow fluid flowing in the pipes 10a and 10b to pass therethrough. do.

That is, the open both ends serve as the inlet 111 through which the fluid enters and the outlet 112 through which the fluid flows out, and the stepped portion 113 is provided in the middle of the inner length of the elastic member 150. Make sure one end is supported.

In addition, the inlet 111 of the housing 110 is provided with a locking part 114 protruding a predetermined length outward along the outer circumferential surface of the housing 110. As shown in FIG. 4, the locking portion 114 is interposed between the pair of flanges 15a and 15b when the locking portion 114 is inserted into the housing 110 into the previously installed pipes 10a and 10b. By being disposed in the remaining portion except the locking portion 114 is fixed to be installed in the inserted state in the pipe (10a, 10b).

At this time, the housing 110 is preferably provided so that a predetermined length gradually decreases the cross-sectional area therein from the inlet 111 side toward the outlet 112 side. This reduces the flow rate of the fluid passing through the housing 110 by forming the diameter of the outlet 112 smaller than the diameter of the inside of the pipe (10a, 10b) to prevent damage (ex, impeller of the meter) installed in the rear To do this.

In addition, when the fluid flows inside the previously installed pipes 10a and 10b for a long time, the inner surface of the pipes 10a and 10b accumulates a certain height of foreign matter contained in the fluid or rust due to corrosion and the diameter of the inside of the pipe. This will be somewhat less than during initial production.

Accordingly, if the outer diameter of the housing 110 is formed to be constant, it is disturbed by foreign matters accumulated in the tube when the tube 110 is inserted into the tube.

Therefore, the predetermined portion of the housing 110 as described above is formed so that its cross-sectional area is gradually reduced in the insertion direction can be easily inserted without being disturbed when foreign matters.

In addition, the cross-sectional area of the outlet 110 side of the housing 110 is formed to have a smaller cross-sectional area than the pipes 10a and 10b, whereas the cross-sectional area of the inlet 111 side of the housing, that is, the diameter of the inlet 111 is inside the pipe. By being provided with a size similar to the diameter of the flow control valve 100, even if installed in the interior of the pipe will have the side effect that can facilitate the movement of the fluid as possible.

The housing 110 is disposed so that the engaging portion 114 is positioned between the pair of flanges 15a and 15b provided at the ends of the pipes 10a and 10b and then fixing means such as a screw bolt 20. When the flanges 15a and 15b are fastened, both sides of the locking portion 114 are installed to be pressed and fixed by the flanges 15a and 15b disposed at both sides thereof.

Accordingly, the flow control valve 100 of the present invention can be installed by simply inserting the housing 110 into the pipe at the connection portion of the pipes 10a and 10b connected through the flanges 15a and 15b. The process is very simple, which increases work productivity.

In addition, unlike the conventional method of cutting a part of the pipe and discarding the cut pipe in order to install the flow control valve, there is no need to cut a part of the installed pipe so that no waste pipe is generated. The side effect can be reduced.

At this time, as shown in Figures 1 to 3, the engaging portion 114, such as rubber packing along the rim so as to prevent the fluid from leaking to the outside when fastening with the pair of flanges (15a, 15b) An airtight member 115 may be provided.

The airtight member 115 is provided in a substantially "c" shape to completely surround the edge of the locking portion 114, and is fixed to the locking portion 114 by an adhesive or the like so as not to be separated. As shown in FIG. 2, grooves 116 and protrusions 117 corresponding to each other are formed on surfaces where the airtight member 115 and the catching portion 114 contact each other to form the airtight member 115 and the catching portion. By increasing the adhesion between the 114 and the coupling force to prevent the airtight member 115 is easily separated or separated from the locking portion 114.

In addition, it is preferable that at least one ridge 118 protrudes from the outer surface of the airtight member 115-more specifically, the contact surface with the flange. This ensures that the contact surfaces of the airtight member 115 and the flanges 15a and 15b are in line contact by the ridge 118 when the housing 110 is installed, so that the flanges 15a when the flanges 15a and 15b are fastened. And 15b) to increase the airtightness between the airtight member 115. That is, even when the surfaces of the flanges 15a and 15b and the engaging portion 114 are not evenly processed, the ridges 118 are pressed by the pressing force when the flanges 15a and 15b are fastened to the flanges 15a and 15b. By being in line contact with the surface of the airtightness between the flange (15a, 15b) and the airtight member 115 is to be improved.

On the other hand, the inner surface of the housing 110-more specifically, the inner surface of the outlet 112 side may be provided with at least one noise reduction groove 161 formed in a predetermined depth along the circumferential surface. Since the flow regulating valve 100 according to the present invention is inserted into a previously installed pipe, a differential pressure is generated between the inlet 111 and the outlet 112. Noise is generated when the fluid is moved by the differential pressure. In order to reduce the noise, in the present invention, the noise reduction groove 161 is provided around the outlet 112. The noise reduction groove 161 is formed to cut a predetermined length in the moving direction of the fluid in the inner surface of the housing 110 to reduce the noise generated by the differential pressure by widening the inner area of the housing 110 in contact with the fluid. .

The flow control unit 120 is disposed in the housing 110 to move in accordance with the hydraulic pressure to control the flow rate of the fluid discharged to the outlet 112 side, and includes a disk guide 130 and disk 140. .

The disk guide 130 is fixed to the inner side of the housing 110-in detail, the inlet 111 serves to guide the movement of the flow control unit 120 is moved by the pressure of the fluid.

The disk guide 130 extends a predetermined length from the center of the fixing portion 131 so as to guide the movement of the fixing portion 131 and the disk 140 fixed to the inner surface of the housing 110. It consists of a part 132.

As shown in FIG. 2, the fixing part 131 has a plurality of channels 133 formed therein so that the fluid flowing into the inlet 111 may pass through the channel 133 toward the outlet 112. In addition, the inner side of the housing 110 is in contact with the inner surface of the housing-more specifically, the threaded portion 134 corresponding to the threaded portion 119 formed on the inner surface of the inlet 111 side is provided with the housing 110. It is fixed by screwing it in.

In addition, a guide part 132 having a predetermined height is provided in the central area of the fixing part 131 so that the extension part 144 of the disk 140 is inserted to guide the moving direction when the oil pressure moves.

The disk 140 moves forward and backward along the moving direction of the fluid when the pressure of the fluid changes, thereby controlling the amount of fluid movement by variably adjusting the cross-sectional area of the outlet 112.

The disk 140 includes a base 141 through which a plurality of flow paths 142 are formed so that fluid can pass therethrough, and a hollow extension 144 extending to a predetermined height in a central region of the base 141. It is provided.

The base 141 is provided with a seating groove 143 which is stepped in a circumferential direction such that one side of the elastic member 150 is in contact with the seating groove 143. 143 and both sides may be supported by the stepped portion 113 provided between the inner length of the housing 110.

In this case, as shown in FIG. 4, the base 141 is disposed so that a portion of the base 141 spans the channel 133 provided in the disc guide 130. This is to allow the disk 140 to move in the moving direction of the fluid by allowing the fluid passing through the channel 133 provided in the disk guide 130 to pressurize one surface of the base 141 to transmit pressure. .

The extension part 144 is provided in a hollow shape having a predetermined length, and is provided with an insertion groove 145 formed to have a size substantially the same as the outer diameter of the guide part 132, so that the guide part (at The outer circumferential surface of the 132 is in sliding contact with the inner circumferential surface of the insertion groove 145.

At this time, the outer circumferential surface of the extension portion 144 may be provided with at least one noise reduction groove 162 formed in a predetermined depth and a predetermined length along the flow direction of the fluid. The noise reduction groove 162 serves to reduce noise generated by the pressure difference between the inlet 111 and the outlet 112, similarly to the noise reduction groove 161 formed at the outlet 112 side of the housing 110. Will be That is, when the pressure of the fluid changes, the disk 140 is moved along the guide part 132 and the fluid in the process of adjusting the flow rate of the fluid by varying the outlet area of the outlet 112 by the extension part 144. In contact with the outer circumferential surface of the extension portion 144 it causes noise. At this time, the noise reduction groove 162 is formed on the surface of the extension part 144 in contact with the fluid to reduce the noise generated by increasing the contact area with the fluid.

On the other hand, in the drawings and the description has been shown and described that the noise reduction grooves (161,162) are formed on both the inner surface of the outlet 112 side of the housing 110 and the outer peripheral surface of the disk 140, but the present invention is limited thereto. Note that it may be formed only on either the inner surface of the outlet 112 side of the housing or the outer circumferential surface of the disk 140.

In addition, the disk 140 has a discharge passage 146 extending from the insertion groove 145 into which the guide portion 132 is inserted to the end as shown in FIG. 4 along the longitudinal direction of the disk 140. It is preferably formed through.

When the inside of the insertion groove 145 into which the guide part 132 is in sliding contact becomes a vacuum state, the guide part 132 is caught in the insertion groove 145 so that the disk 140 moves even if the hydraulic pressure is changed. This becomes impossible. The discharge path 146 penetrates from the end of the disk 140 to the insertion groove 145 to serve as a passageway through which the fluid flows into the insertion groove 145, so that the insertion groove 145 is in a vacuum state. By preventing the disk 140 to move smoothly in accordance with the change in the hydraulic pressure.

In addition, the discharge path 146 serves as a passage for discharging the foreign matter contained in the fluid into the insertion groove 145 to the outside of the disk 140, so that the disk 140 operates smoothly. It also plays a role.

Both ends of the elastic member 150 are supported by the seating groove 143 of the disk guide 130 and the stepped portion 113 formed inside the housing 110, so that the elastic force is applied to the disk 140 according to a change in hydraulic pressure. By adjusting the position of the disk 140 by applying a serves to maintain a constant amount of the fluid discharged through the outlet 112.

That is, when the hydraulic pressure is large, the disk 140 is moved to the right side with reference to FIG. 4 to narrow the outlet area of the outlet 112 and at the same time the elastic member 150 is compressed to store the elastic force. In the small case, the disk 140 is moved to the left side by the elastic force stored in the elastic member 150 to widen the outlet area of the outlet 112 so that a certain amount of fluid flows in the pipe regardless of the hydraulic pressure.

On the other hand, one side end of the elastic member 150-in detail, the end in contact with the stepped portion 113 may be provided with a machining surface 152 that is flat polished for smooth contact with the stepped portion 113. have. When the elastic member 150 is installed in the pipe, the end surface of the elastic member 150 and the contact surface of the stepped portion 113 are entirely in surface contact with the processing surface 152 so that the elastic member 150 may be installed in parallel with the moving direction of the fluid. To do this. Accordingly, when the hydraulic pressure is changed, the direction of action of the force of the elastic member 150 that presses the disk 140 acts in parallel with the moving direction, thereby making it possible to more effectively control the flow rate.

5 and Table 1 below shows the performance of the flow rate according to the differential pressure of the outlet 112 and the inlet 111 when the diameter of the inlet 111 is 80mm, the pressure of the inlet 111 4.0kgf / cm ² The flow rate according to the differential pressure in the case of maintaining a constant and the pressure of the outlet 112 is sequentially changed.

Primary pressure (Kgf / cm ² ) 4.0 4.0 4.0 4.0 Secondary pressure (Kgf / cm ² ) 2.0 1.5 1.0 0.5 Differential pressure (Kgf / cm ² ) 2.0 2.5 3.0 3.5 Flow rate (M ³ / hr) 70.5 73.9 74.3 72.8

Here, the primary pressure represents the pressure at the inlet side, and the secondary pressure represents the pressure at the outlet side.

As can be seen through FIG. 5 and Table 1, even though the hydraulic pressure flowing through the pipe is changed to generate a differential pressure between the inlet 111 and the outlet 112, the flow rate of the fluid passing through the flow control valve is about 70 to 74M ³ /. It can be seen that it passes constantly in the hr range.

Insertion type flow control valve 100 according to the present invention is installed after the flow control valve 100 itself is inserted into the interior of the pre-installed pipe, when the pressure of the fluid flowing in the pipe is strong, the fluid pressurized the disk 140 And compress the elastic member 150 to move forward to narrow the outlet cross-sectional area of the outlet 112, and when the pressure of the fluid is weakened, the disc 140 retreats by the elastic force accumulated in the elastic member 150 to exit the outlet. By increasing the outlet cross-sectional area of 112, the fluid flowing in the pipe can flow in a constant amount.

According to the present invention as described above, by simply inserting the housing itself into the pipe at the connection portion connected by the flange without changing the existing pipe structure, the installation process is simple and the installation cost can be reduced.

In addition, the present invention has an effect that can reduce the noise generated by the change of the hydraulic pressure during the movement of the fluid by forming a noise reduction portion in the valve itself.

In addition, by providing the airtight member 115 in the locking portion 114 disposed between the flanges (15a, 15b) there is an effect that can prevent the leakage of the fluid and can be installed stably.

While specific embodiments of the present invention have been described in detail with reference to the drawings, the present invention is not limited to such specific structures. Those skilled in the art will be able to modify or modify the present invention without departing from the spirit of the following claims. However, equivalents, replacements, and modifications through these simple modifications or changes are all clearly stated to be within the scope of the present invention.

100: insertion type flow control valve
110 housing 111 inlet
112: outlet 113: stepped portion
114: engaging portion 115: airtight member
116: groove 117: protrusion
118: ridge portion 119: screw portion
120: flow control unit 130: disk guide
131: fixed portion 132: guide portion
133: channel 134: threaded portion
140: disk 141: base
142: Euro 143: seating groove
144: extension portion 145: insertion groove
146: discharge path 150: elastic member
152: machining surface 161,162: noise reduction groove

Claims (11)

In the flow control valve is installed in the pipe through which the fluid flows to control the flow rate,
A housing having an inlet and an outlet to allow the fluid to pass therethrough, and having a catching portion protruding a predetermined length outwardly along an outer circumferential surface thereof and inserted into the pipe;
A flow rate adjusting unit disposed inside the housing and moved according to hydraulic pressure to adjust a flow rate of the fluid;
An elastic member having one end supported by a stepped portion formed inside the housing and the other end supported by the flow rate adjusting part to move the flow rate adjusting part according to hydraulic pressure; And
And a noise reduction unit provided along at least one side of an outlet of the housing or a flow control unit along a moving direction of the fluid to reduce noise generated when the fluid is moved.
The flow rate control unit has a base portion through which a plurality of flow paths through which the fluid passes and a hollow extension portion extending a predetermined length in the center portion of the base portion to adjust the flow rate by moving to the outlet side according to the hydraulic pressure, and one side It is fixed to the inner surface of the inlet is composed of a disk guide for guiding the movement of the disk,
The noise reduction part is an insertion type flow control valve, characterized in that provided with at least one noise reduction groove is formed in a predetermined depth in the circumferential direction on the outer peripheral surface of the extension. The method of claim 1,
The housing is an insertion-type flow control valve, characterized in that the cross-sectional area of the inside is gradually reduced from the middle to the outlet side. The method of claim 1,
Insertion flow control valve, characterized in that the noise reduction portion formed around the outlet of the housing is provided with at least one noise reduction groove is formed in a predetermined depth in the circumferential direction on the inner surface of the outlet. delete delete The method of claim 1,
The extension part is an insertion type flow control valve, characterized in that additionally provided in the central area with a discharge path for preventing the vacuum and the discharge of foreign matter. The method of claim 1,
The disk guide includes a fixing part fixed to the inner surface of the housing and a guide part extending a predetermined length from the center of the fixing part to guide the movement of the disk, wherein the fixing part corresponds to the inner surface of the housing. Inserted flow rate control valve, characterized in that the screw is formed is fixed to the inner surface of the housing through the screw coupling. The method of claim 1,
Insertion type flow control valve, characterized in that additionally provided with an airtight member fixed tightly along the edge of the locking portion. The method of claim 8,
Insertion flow control valve, characterized in that the locking portion and the airtight member are provided with grooves and protrusions corresponding to each other on the contact surface so as to increase the adhesion. The method of claim 8,
The hermetic member is an insertion type flow control valve, characterized in that additionally provided with at least one raised portion protruding a predetermined height in the radial direction on the outer surface. The method of claim 1,
Inserted flow control valve, characterized in that the end surface of the elastic member supported by the stepped portion is provided with a processing surface that is polished so that the entire surface contact with the stepped portion.

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