KR20050079442A - Water level controller for water storage tank - Google Patents

Abstract

The present invention relates to a water level control device for a water tank used in household, industrial equipment, such as a water purifier or a toilet, and more particularly, a water tank capable of precisely controlling the amount of fluid in the water tank, eliminating water leakage and reducing failures. It relates to a water level control device.

The present invention relates to a raw water inlet port for introducing water into a reservoir, a discharge port for supplying the introduced raw water into the reservoir, and a water level control window for the reservoir in the water level sensing means for sensing the water level in the reservoir. A pilot flow path branching an introduction port, a portion of the raw water introduction port, a valve chamber for controlling the supply of raw water from the raw water introduction port to the water reservoir, and a raw water discharge port through which the raw water flows through the valve chamber, Water level sensing means consisting of only a differential pressure generating tank and a diaphragm without a float or movable part such as a float or a float operating according to the water level of the reservoir, and the water level sensing means consisting of a float It is composed of movable poppet to block the detection port, so the more water pressure, the more water tank It is to make sure to cut off the supply of raw water to the erotic.

The present invention having the above configuration has the advantage of less leakage and noise and less trouble because it operates the on-off valve using the water pressure in the valve chamber and the reservoir.

Description

Water level controller for water tank {Water Level Controller For Water Storage Tank}

The present invention relates to a water level control device used to supply and shut off raw water to a water tank or a reservoir, and more particularly, to form an open / close valve body in a constant unit installed in the reservoir, and to supply the raw water into the reservoir ( Hereinafter referred to as "raw water introduction port") and a smaller diameter pilot supply pipe (hereinafter referred to as a "pirate flow path") formed on one side of the raw water introduction port to more reliably block the supply of raw water to the reservoir when the reservoir reaches a predetermined level. It relates to a device that allows.

In general, water tanks of water purifiers, residential water tanks, and other toilets have floats, ball taps, or floats that operate according to the water level to block the supply of water into the water tanks. Installation is used.

According to the conventional ball tap structure used for this purpose, all are installed into the water tank by installing a rod connecting the opening and closing valve to the upper side of the water supply pipe and opening and closing it to block the supply of water into the water tank. According to the water level, the float is operated up and down while the rod connected thereto is inclined in the horizontal direction to open and close the on / off valve installed at the top of the water supply pipe to block the supply of water into the reservoir. Due to this operation principle, if the water pressure is higher than the buoyancy, the water level rises, and the size of the ball must be increased proportionally in order to operate smoothly at high pressure. In addition, the high pressure buoyancy force is transferred to the body, the body is required a strong material, the most important problem is that the connection is often broken due to the stress that the rod is connected to the buoy, and in this case, artificial As a result, secondary damage occurs, causing water to flow continuously until the flow of the pipe is blocked.

In addition, the operation principle of the float valve applied to the conventional toilet, the water enters through the inlet and receives the buoyancy buoyancy through the support as a hinge point down the valve while the water is blocked by the force of buoyancy, lever When the siphon is opened by the operation, the filled water goes down to the toilet bowl, and the float goes down to gravity, and the valve opens and water comes out. In addition, by repeating the above operation, the toilet bowl is filled with a certain amount of water, and then comes down as needed, and the toilet has a disadvantage of leaking water and high noise as the float valve, as in the above-mentioned float valve. If you go out, there is a disadvantage that the water is continuously leaked until there is a block from the outside.

On the other hand, the conventional registered utility model No. 20-0207682 proposes a large-capacity valve opening and closing method for the water level valve for high and low water level control, but the device is large, complex, expensive manufacturing cost, and can not be used for household equipment. The invention also has the disadvantage that the water level is detected by the ball.

Therefore, the present invention has been made to solve the above problems, the object of the present invention is to ensure the supply of raw water when the water level in the reservoir tank is full water level, that is, the purified water in the case of water purifier, or in the toilet or home storage tank. The present invention provides a water level control device for a water tank that can be blocked to prevent leakage of water from an introduction port of raw water.

Another object of the present invention is to provide a water level control device for a water tank that can prevent the occurrence of noise while having a simple configuration and low production cost and failure.

In order to achieve the above object, the present invention can effectively supply and block the raw water supplied to store the introduced water (hereinafter referred to as " raw water ") in the reservoir according to the level of the reservoir. A water level control device for a water tank configured to be capable of supplying water, comprising: a raw water inlet port and a valve chamber in communication with the raw water inlet port; a movable valve body in the valve chamber; and a pilot flow path formed at one branch of the raw water inlet port. A discharge port through which the raw water passing through the valve chamber flows into the water storage tank; Having a water level detecting means interlocked with the height of the water level stored in the reservoir; The water level sensing means is composed of a differential pressure generating tank and a diaphragm (Diaphragm) only without moving parts such as a ball, or a water level sensing means for improving an existing float method operating according to the water level of the water storage tank; When the water level detecting means is configured as a float has a movable poppet for detecting the water level of the raw water in conjunction with the float and to block the high water level detection port when the raw water reaches a predetermined high water level; The raw water supplied to one side of the valve chamber through the pilot flow passage is characterized in that it has a full water level detection port configured to allow entry and exit to the float chamber.

Hereinafter, a preferred embodiment of the water level control device for a reservoir according to the present invention will be described in detail with reference to the accompanying drawings.

First, Figure 1 shows an overall cross-sectional view of one embodiment in which the reservoir water level control device of the configuration of the present invention in the reservoir 100 is installed and operated.

It will be described in more detail, Figure 2 is a cross-sectional view showing the configuration of the water level control device for the reservoir according to the present invention is the case where the water level detection means is a float. According to this, the water level control device of the present invention is installed in a suitable upper portion in the reservoir (100) according to the water level. The water level control device is divided into two chambers (Chamber), one chamber is called the valve chamber 10, the other chamber is called the float chamber (50). Each chamber is interlocked with each other by the raw water through the full water level detection port (25). An introduction port 1 for introducing raw water introduced into the water storage tank 100 through the valve chamber 10, and the introduced raw water passes through the introduction port 1 to pass the valve body 15 through the valve body. Raw water is stored in the reservoir 100 through the discharge port 11 formed at one side of the 15 and continues to flow into the reservoir 100 until it reaches a constant level. In addition, the float chamber 50 formed in the lower portion of the valve chamber 10 is a float 51 which is formed to be movable up and down in the float guide 55 in accordance with the water level in the reservoir 100, It consists of a movable poppet 52 configured in the float 51. The operation of the float 51 is to raise the float 51 in the float guide 55 by buoyancy as the water level in the reservoir 100 rises, so that the movable poppet 52 in the float 51. ) Is configured to close the water level detecting port 25 on one side of the lower end of the valve chamber 10.

On the other hand, there are a plurality of holes (56, 56 ') on the side of the float guide 55, these holes are for the smooth flow of pressure when the float 51 operates in the float guide 55, In addition, after the raw water supplied through the pilot flow passage 2 passes through the full water level detection port 25, the float chamber 50 is finally provided to smoothly move into the reservoir 100.

And, as shown in Figure 2 or 5a and 5b on one side of the movable poppet 52, when the reservoir 100 reaches a predetermined high water level, the high water level detection port ( A closure 53 in which a soft member is inserted into and attached to one side of the movable poppet 52, which is a surface directly in contact with 25, is formed. In addition, in order to prevent the movable poppet 52 from being separated from the float 51, a fixing piece 57 (Push Washer) is formed at one side of the lower end of the movable poppet 52.

On the other hand, when the water tank 100 is in the water supply rather than the predetermined water level, most of the raw water supplied through the introduction port (1) through the valve body 15 through the introduction port rear portion (1-a) through the discharge port It is introduced into the reservoir 100 through (11).

The configuration of the valve body 15 is a fixture 14, rubber packing 15, valve stem 16 and the soft diaphragm 17 (hereinafter referred to as "first diaphragm") as shown in FIG. 2, some raw water not passing through the rear end of the introduction port 1-a is formed through the pilot flow path 2 formed with a diameter smaller than that of the introduction port. The lower side of the valve body, the flow of raw water is impossible to move toward the upper side of the valve body due to the first diaphragm 17, it is vented to the lower portion of the valve chamber 10 It is introduced into the water reservoir 100 through the float chamber 50 via the high water level sensing port 25. This flow of raw water continues until the reservoir 100 reaches a predetermined full water level.

And, the water level control device for the reservoir can be produced in a variety of sizes according to the use, when the production of a smaller size the pilot euro (2) is also formed of a relatively thinner diameter pipe. Therefore, when foreign matters and the like are introduced into the pilot passage 2 together with the raw water, there is a risk of blocking the pilot passage 2 having a small diameter, and thus, a kind of nonwoven fabric or a thin cloth at the entrance of the pilot passage 2. Formation of the back strainer 2-b can prevent this concern.

Another embodiment of this configuration of the valve body 15 is composed of only another shape of the diaphragm 17-2 (hereinafter referred to as "first 'diaphragm") as shown in FIG. In this case, the manufacturing method of the first 'diaphragm 17-2 is made of a synthetic rubber (NBR, etc.) in which a hard material such as metal is embedded in the center and a special fiber having excellent heat resistance and strength is inserted. If the diaphragm having excellent airtightness, durability and strength can be manufactured, the same performance can be achieved without the parts such as the valve stem 16 described in FIG. The first 'diaphragm is supported by a pressure induction spring 19-2 that initially induces a pilot pressure.

Referring back to FIG. 2, when the water reservoir 100 reaches a predetermined full water level, when the float 51 in the float guide 55 floats with buoyancy, the movable poppet 52 and the movable poppet 52 in the float 51 are floated. One side of the guide spring 54 configured between the float 51 is pushed up and this force moves the movable poppet 52 which is in contact with the opposite side of the guide spring 54 upward. The movable poppet 52 moved upwards closes the water level detecting port 25 formed at the lower end of the valve chamber 10, thereby preventing the raw water at the lower end of the valve chamber 10 from entering the float chamber 50. do. In addition, when the water level detecting port 25 is closed, that is, referring to FIGS. 2 and 5B, the pressure of the lower portion 10-a in the valve chamber 10 increases to push the first diaphragm 17. Up. Then, the valve stem 16 connected to the center of the first diaphragm 17 is also operated to close the raw water supply path to the discharge port 11.

On the other hand, the valve stem 16 has a constant size and initial tension and is supported by a pressure induction spring 19 to induce a pilot pressure initially, the pressure induction spring 19 is the valve chamber 10 It is fixedly supported by the some support protrusion 19a, 19b formed in the lower side. In addition, the material of the first diaphragm 17 is made of rubber cloth such as glass cloth, glass fiber, steel wire, or the like when rubber is molded so as to be pressure-reinforced with a rubber material. It is enough if the material is molded in the center.

As a result, in the operation of the present invention configured as described above, when the raw water supply to the water storage tank 100 is blocked by the valve body 15, the supply of raw water before the introduction port 1 is not interrupted. The supply of raw water through the introduction port 1 continues, but since the raw water is not supplied into the water storage tank 100, the raw water remains in the valve body 15. In addition, if the pressure of the raw water supplied to the introduction port 1 increases and acts harder, the pressure toward the pilot flow path 2 increases, and the valve body 15 is operated to the upper part more firmly. It completely cuts off the supply of raw water into the reservoir 100. Further, the pressure of the raw water is reduced only by the area difference ("A"-"B") of the cross-sectional area ("B" cm <2>) on the blocking side of the first diaphragm 17 and the cross-sectional area ("A" cm <2>) on the open side. This protects the packing by preventing excessive shutoff pressure. Since the pressure through the pilot flow path 2 increases and the first diaphragm 17 is operated and closed once, it is not opened again until there is a fluctuation enough to overcome the pressure equal to the area difference between the blocking side and the opening side. Can be prevented, and the pressure difference between the blocking side and the opening side is not large, so it closes and opens slowly.

On the other hand, the introduction port (1) can be easily connected to the raw water supply hose, preferably by installing a press fitting hose connection fitting (Fitting) to facilitate the raw water connection.

Next, referring to another embodiment of such a configuration, FIGS. 6A (when full water level) and FIG. 6B (when water supply water) shows that the level sensing means is a level sensing diaphragm (hereinafter referred to as a "second diaphragm"). It is characterized by consisting of (61). In the present embodiment, as shown in the conventional configuration, the means for detecting the height of the water level of the reservoir 100 is not a float, a ball tap, or a float, but only a diaphragm means for detecting the water level. will be.

In the present use example, the configuration of the water level detecting diaphragm means includes a differential pressure generating tank 62 which generates pressure due to a difference in water level between the second diaphragm 61 and the water storage tank 100. It consists of).

On the other hand, the shape of the second diaphragm 61 is given a predetermined protrusion on the portion in contact with the high water level detection port 25 is formed in a structure to block the hole is inserted into the high water level detection port 25 at the time of high water level It may be a shape that reduces the use of another component. In addition, the length of the differential pressure generating tank 62 may be changed according to the depth of the reservoir 100 in order to sufficiently secure the air chamber 65 in the differential pressure generating tank 62. The method of changing the length of the differential pressure generating tank 62 is formed by connecting a general connector of a desired depth having a constant diameter when the connecting connector 63 such as a thread or a separate connector or integrally is formed at the end of the differential pressure generating tank 62.

Looking at the raw water supply process until the water tank 100 reaches the full water level in the present use example, when the raw water is supplied from the raw water introduction port 1, most of the raw water is discharged as in FIG. 3. Through the flow into the reservoir 100, some of the raw water is introduced into the pilot flow path (2). Thereafter, the raw water introduced through the pilot flow passage 2 flows into the second diaphragm 61 through the full water level detection port 25, and all the raw water introduced therein is the second diaphragm ( 61 has a path flowing into the reservoir 100 through a plurality of openings 63-a and 63-b provided at both side surfaces of the differential pressure generating tank 62.

On the contrary, a process in which raw water is sufficiently supplied to the reservoir 100 to reach a predetermined full water level will be described with reference to FIG. 6B. Since the water level in the reservoir 100 gradually increases and the surface of the reservoir and the surface of the differential pressure generating tank 62 first contact each other, the inside of the differential pressure generating tank 62 has an air chamber 65. The internal pressure of the differential pressure generating tank 62 also reaches a maximum until the pressure of the differential pressure generating tank 62 is increased and the water surface of the reservoir 100 reaches the full water level. The second diaphragm 61 is operated through the differential pressure transmission hole 64 to be pushed toward the high water level detection port 25 to close the water level detection port 25 to close the water level detection port 25. do. Subsequently, when the water level detecting port 25 is closed, inflow of raw water at the lower end of the valve chamber 10 toward the second diaphragm 61 is blocked. In addition, when the water level detecting port 25 is closed, the pressure of the lower portion (10-a) in the valve chamber 10 is increased to push up the first diaphragm (17). In addition, it is also possible to operate the valve stem 16 formed through the center of the first diaphragm 17 so that the raw water supply path to the discharge port 11 is closed. Is operated in the same manner as when used as the float means, and the pressure of the raw water acting per unit area is also equally applied even when the water level sensing means is used as the float means or as the second diaphragm 61.

Although the preferred embodiments of the present invention have been described above by way of example, the scope of the present invention is not limited to these specific embodiments, and may be appropriately changed within the scope of the claims.

As described above, the water level control device for the water tank according to the present invention can make almost all the parts made of synthetic resin, which is environmentally friendly, easy to mass-produce, resistant to pollution, and has high thermal conductivity compared to metal products. Low and safe even in freezing. In addition, it is possible to fully enjoy the economic benefits to consumers because of the low manufacturing cost, and it is possible to maximize the space utilization by miniaturizing the valve chamber as well as the miniaturization of the float means according to the use.

In addition, in the conventional method, the operation level is uncertain depending on the water pressure, and the water level may change, such as leakage, the flow rate decreases as the flow path decreases, the pressure increases, the pressure energy is converted into noise energy, and the scattering of the supplied raw water occurs. do. However, the present invention has the advantage of maintaining a predetermined level without changing the water level according to the water pressure, there is also an effect that does not generate noise. When the water level sensing means is a diaphragm type, since there are no movable parts such as floats, ball taps, and floats, there is little contact contamination to foreign matters such as moss and scale, and the structure is simple. In particular, the moving parts are often sensitive to sensitive operation. It prevented the pulsation, noise and abrasion caused by opening and closing, and solved the problem that the moving parts should be large as before according to the capacity of the reservoir. In addition, the present invention can be applied to water level control devices for water purifiers, vending machines, double-sided devices, indoor and outdoor water tanks, and can also replace the present invention with non-powerless solenoid valves using other electric power, which has a great effect on energy saving. .

1 is a cross-sectional view showing the configuration of the water level control device for a reservoir according to the present invention;

2 is a cross-sectional view showing the configuration of the main part of the present invention;

3 is a cross-sectional view showing the configuration of the valve chamber of the present invention;

4 is a cross-sectional view showing a configuration of a first 'diaphragm of the present invention;

5A and 5B are sectional views showing the configuration of the main part for the case where the water level sensing means of the present invention is a float.

6A and 6B are sectional views showing the configuration of main parts of the case where the water level sensing means of the present invention is a second diaphragm.

♣ Explanation of symbols for main part of drawing ♣

1: inlet port 2: pilot euros

10: valve chamber 11: discharge port

15: valve body 16: valve stem

17: first diaphragm 25: high water detection port

50: float room 51: float

52: movable poppet 53: closure

61: second diaphragm 62: differential pressure generating tank

Claims (7)

A water level control device for water tank having an introduction port for introducing raw water, a discharge port for supplying the introduced water into the water tank, and a pilot flow path, and a water level sensing means configured to effectively supply and block the water according to the water level of the water tank. To A raw water introduction port and a pilot flow path branched from the raw water introduction port; A valve body composed of a first diaphragm operating in a valve chamber disposed over one end of the raw water introduction port and one end of the pilot flow path; A discharge port for discharging raw water passing through the valve chamber to the water storage tank; Water level sensing means comprising a differential pressure generating tank for generating pressure due to a difference in water level stored in the water storage tank, and a second diaphragm interlocked according to the pressure; And a high water level sensing port formed at one side of the valve chamber for passage of raw water so that the valve chamber and the water level sensing means can interlock with each other. The water level adjusting device for a water tank according to claim 1, wherein the valve body comprises a first diaphragm and a valve stem. The water level control device for a water tank according to claim 1 or 2, wherein the valve body is supported by a pressure induction spring. 2. The water level adjusting apparatus for a water tank according to claim 1, wherein said water level sensing means is a float means composed of a float and a movable poppet. The water level control apparatus according to claim 4, wherein one side of the movable poppet is supported on the float by a fixing piece, and the other side of the movable poppet is guided and supported by a guide spring. The water level control apparatus for a water tank according to claim 1, wherein at least one differential pressure transmission hole is formed at one side of the differential pressure generating tank. The water level control apparatus for a water tank according to claim 1 or 6, wherein a connection piece is formed at one end of the differential pressure generating tank so as to change the length of the generating tank.