KR0131527Y1 - Level control valve - Google Patents

Abstract

The present invention relates to a water level control valve.

The configuration forms a flow regulating portion A having a flow regulating mechanism 14 above the diaphragm 5, the flow regulating mechanism 14 having a leaf spring 16, and the leaf spring 16. It is possible to prevent the malfunction due to a small amount of leakage by the change of, as well as easy operation by removing the needle valve, easy to install and handle piping.

Description

Water level control valve

1 is a front sectional view showing a water level control valve according to the present invention.

Figure 2 is a front sectional view showing a conventional water level control valve.

3 is a view for explaining the operation of the conventional water level control valve,

a) is a state diagram when the valve is closed.

b) is the state when the valve is opened.

Figure 4 is a detailed view showing the flow control portion constituting the water level control valve according to the present invention,

a) is a state diagram when the valve is opened.

b) is the state diagram when the valve is closed.

* Explanation of symbols for main parts of the drawings

1: valve body 5: diaphragm

7: pressure transfer hole 13, 17c: orifice

14 flow control mechanism 16 leaf spring

The present invention relates to a water level control valve (Level Control Valve), and more particularly to a water level control valve to facilitate the installation of the pipe, compact and lightweight, to prevent the occurrence of defects due to malfunction.

The water level control valve is used to automatically open / close a large-diameter valve and maintain a constant water level of a water tank, a sedimentation tank, a pressure regulating tank, and a swimming pool without any external power in general piping equipment. It is a control valve that plays a role.

In the conventional water level control valve, as illustrated in FIG. 2, a diaphragm 101 is installed at the center of the main body 102, and a spring 107 is provided at the upper portion 108 of the diaphragm 101. A disk 103 is integrally mounted to the lower portion 109, and a seat 104 is formed below the disk 103, and the sheet 104 is fixed to the main body 102. . In addition, the copper pipe 110 is installed on the upper portion 108 of the diaphragm 101, the copper pipe 110 is connected to the fluid inlet 111 side, the needle valve (Niddle) in the middle of the copper pipe 110 Valve 106 is installed, and the needle valve 106 is connected to a solenoid valve 105 as another copper pipe 112.

3 is a view illustrating an operation state of a conventional water level control valve. At first, the disc 103 is lowered by the load of the spring 107 installed as the upper portion 108 of the diaphragm 101 and the self load. Is kept in contact with (a in FIG. 3), and when the fluid flows into the fluid inlet 111, the pressure is applied to the lower portion 109 of the diaphragm 101 to raise the disk 103 (see FIG. b) the fluid is discharged to the fluid outlet (113).

On the other hand, the fluid at the fluid inlet 111 side flows through the needle valve 106 formed in the copper pipe 110 to the upper portion 108 and the copper pipe 112 of the diaphragm 101, to the copper pipe 112 When the installed solenoid valve 105 is closed, the pressures of the upper portion 108 and the lower portion 109 of the diaphragm 101 are equal, and the diaphragm 101 is lowered by the spring 107 to be in the state of a) in FIG. When the solenoid valve 105 is opened, the pressure of the upper portion 108 of the diaphragm 101 is lowered and the diaphragm 101 is raised to the state of b) of FIG. That is, when the solenoid valve 105 is opened and closed by the water level of the tank (not shown), the flow rate of the fluid flowing into the tank (not shown) and the water level of the tank (not shown) are adjusted.

However, the above conventional water level control valve has a first problem that is difficult to control the water level due to a malfunction when a small amount of leakage occurs in the solenoid valve 105 or the ball top (not shown) because the malfunction prevention device is not installed. Second, the needle valve 106 to control the opening and closing speed of the valve in order to prevent the occurrence of noise during sudden opening and closing of the valve, and when the valve is installed manually (Setting) in the field (Field), valve noise ( For example, in the event of a chattering phenomenon, the needle valve 106 is manually operated so that a sudden opening and closing of the valve occurs, and a third assembly of the needle valve 106 and the external copper tube (not shown) increases the number of assembly parts. Since assembly takes a long time and most of the parts are made of cast iron products, corrosion and scale may occur in pipes for a long time, which may cause contamination of drinking water. Ron, because the fifth valve is medium-weight is that it is difficult to handle and requires a lot of installation space for piping installation.

The present invention has been devised to improve the above-mentioned problems. The object of the present invention is to provide a malfunction prevention device to stably maintain the water level, and to provide a water hammer and siphon. It is to provide a water level control valve that can prevent the noise caused by the phenomenon.

The present invention as a technical configuration for achieving the above object,

In the water level control valve which forms a diaphragm inside the valve body, and controls the water level by opening and closing the flow of fluid in the rising and falling of the diaphragm,

A flow control mechanism formed with an orifice is installed in the flow control unit connected to the upper portion of the diaphragm through the pressure transfer hole, and the bracket of the flow control mechanism is assembled to be movable in the lower end of the cap. The upper hollow portion formed between the lower end portion is provided with a plate-shaped leaf spring, the cap forms another orifice in communication with the orifice of the flow control mechanism, and the first and second passages facing each other By forming a 1,2,3 fluid movement passage is provided by the water level control valve, characterized in that installed in the valve body.

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

1 is a front sectional view showing a water level control valve according to the present invention, the valve body (1) is provided with a diaphragm (Diaphragm) (5), the diaphragm (5) is a spring (3) on the upper portion (2) The lower part 4 is provided with a seat 6.

The upper portion 2 of the diaphragm 5 is connected to the flow rate control part 1a and the pressure transfer hole 7, and the flow rate control part 1a is connected to a solenoid valve (not shown). The second passage 12 connected to the first pipe 11 and the copper pipe 10 of the fluid inlet 9 is formed to face each other.

4 is a detailed view showing the flow rate control part 1a constituting the water level control valve of the present invention, wherein the flow rate control mechanism 14 having the orifice 13 is positioned above the pressure transfer hole 7. The flow regulating mechanism 14 is made of rubber (for example, NBR), and a plate-shaped leaf spring 16 having a hole formed in the center thereof is mounted in an inner space of the upper hollow portion 15 having a cramp portion 14a at the top thereof. The lower end 17a of the cap 17 on which the orifice 17c is formed is inserted into the upper portion of the leaf spring 16. That is, as the angular portion 14a of the flow regulating mechanism 14 is assembled at the lower end 17a of the cap 17, the flow regulating mechanism 14 may be moved upward or downward, and the leaf spring 16 is installed in the inner space of the upper hollow portion 15, the upper and lower widths change in accordance with the up and down movement of the flow rate control mechanism 14 can be convex downward, or can be changed convex upward will be.

The cap 17 is formed with a screw portion 17b and fixedly coupled to the valve body 1, and a first fluid movement connecting the first passage 11 and the second passage 12 to the lower side of the screw portion 17b. A passage 18 is formed, and a second fluid movement passage 19 is formed above the lower end portion 17a, and the first and second fluid movement passages 18 and 19 are a third fluid movement passage ( It is configured to be connected to each other by 20).

Reference numeral 21 is a fluid outlet port.

Referring to the operation and effects of the present invention configured as described above are as follows.

As shown in FIGS. 1 and 4, the fluid enters the fluid inlet 9, and the lower part 4 of the diaphragm 5, which has been placed on the seat 6 by means of a spring 3 and its own weight. ), The diaphragm 5 is raised by the pressure, and flows out through the fluid outlet 21.

The fluid flowing into the flow rate control section 1a from the fluid inlet port 9 through the copper pipe 10 from the side of the flow rate control section 1a and the passage 12 is connected to a solenoid valve (not shown). 11) and flows to the upper portion 2 of the diaphragm 5, the flow of the fluid is controlled by the operation of the flow control mechanism 14 by opening and closing the solenoid valve (not shown).

That is, a) in FIG. 4 is a case where the diaphragm 5 is opened by opening a solenoid valve (not shown), and a large amount of fluid flowing through the pressure transfer hole 7 flows into the first passage 11, As a result, the pressure of the second, third, fluid movement passages 19, 20 is lowered.

In this case, since the pressure of the upper portion 2 of the diaphragm 5 is a relatively high pressure compared to the pressure of the second and third fluid movement passages 19 and 20, the lower end portion 17a of the cap 17 is ), A force to rise is generated in the flow rate control mechanism 14 in which the clamp portion 14a is assembled to be movable. That is, when the flow regulating mechanism 14 is lowered by the pressure difference, when the fixed lower end portion 17a and the moved flow regulating mechanism 14 move upward, the cap 17, which is a fixing member, Since the upper and lower widths of the inner space of the upper hollow portion 15 formed between the lower end portion 17a and the flow regulating mechanism 14, which is a moving member, are reduced, as shown in b) of FIG. Thus, the leaf spring 16 installed in the upper hollow portion 15 is changed into a convex shape downward. Therefore, the flow regulating mechanism 14 is maintained in an elevated state so that the fluid flowing from the upper portion 2 flows through the first passage 11 to lower the pressure of the upper portion 2 of the diaphragm 5. The diaphragm 5 is to remain open.

On the other hand, b) of FIG. 4 is a case in which the diaphragm 5 descends by closing a solenoid valve (not shown). When the solenoid valve (not shown) is closed, there is no flow of fluid through the first passage 11. The internal pressure of the second, third, fluid passages 18 and 19 is increased.

In this case, since the pressure of the upper portion 2 of the diaphragm 5 is relatively low compared to the pressures of the second and third fluid passages 18 and 19, the lower end portion 17a of the cap 17 On the contrary to the above, a force that is lowered is generated in the flow rate control mechanism 14 in which the clamp portion 14a is assembled to be movable. That is, the upper and lower widths of the inner space of the upper hollow portion 15 formed between the flow rate regulating mechanism 14 due to the pressure difference are longer than the above, so as shown in a) of FIG. The leaf spring 16 installed in the upper hollow portion 15 in a shape is changed into a concave shape downward. Therefore, the flow regulating mechanism 14 is maintained in the lowered state, the pressure of the upper portion 2 of the diaphragm 5 is increased, and the diaphragm 5 is maintained in the closed state.

On the other hand, when the diaphragm 5 is closed and a small amount of leakage (for example, 80 l / min) occurs in the solenoid valve or ball top (not shown), the trace amount in the direction of the first passage 11 is small. Even though there is a fluid flow, the pressure difference due to the minute is offset by the orifices 17c and 13 formed in the cap 17 and the flow regulating mechanism 14 and communicated with each other, so that the pressure change of the upper portion 2 of the diaphragm 5 is reduced. Does not interfere with. That is, malfunction due to a small amount of leakage is prevented.

As described above, according to the water level control valve of the present invention, the malfunction due to a small amount of leakage is prevented by the flow control mechanism 14 having the first orifice 13, and the inconvenience of operation by removing the second needle valve Not only is the box removed, there is an effect of cost reduction, and also because of the compact and lightweight, there is an excellent effect that the pipe installation and handling is easy.

Claims (1)

A diaphragm 5 is formed inside the valve body 1, and in a water level control valve for controlling a water level by opening and closing a flow of fluid by rising and falling of the diaphragm 5, the upper portion of the diaphragm 5 ( 2) and the flow rate control unit 1a connected through the pressure transfer hole 7 is provided with a flow rate control mechanism 14 having an orifice 13, and the clamp portion 14a of the flow rate control mechanism 14 is provided. Is assembled to be movable in the lower end portion 17a of the cap 17, and the plate-shaped leaf spring 16 is formed in the upper hollow portion 15 formed between the flow regulating mechanism 14 and the lower end portion 17a. And the cap 17 forms another orifice 17c in communication with the orifice 13 of the flow regulating mechanism 14, and the first and second passages 11 and 12 opposing each other. The first, second, third fluid movement passages (18), (19), (20) in communication with the water level control valve, characterized in that installed in the valve body (1).