KR20030061603A - anti-freezing device - Google Patents

Abstract

PURPOSE: A freeze protection unit is provided to function as a valve in a tap, a water gauge, or a pipeline at ordinary times and to protect a pipeline from freezing and being frozen to burst by operating a valve automatically. CONSTITUTION: The freeze protection unit comprises: a main body(A) formed in the cylindrical shape whose upper side is closed and lower side is opened and coupled with a conveyance unit(C) and a handle(1); a contraction unit(B) composed of a housing(10), contractile materials, a rubber cap(30), inelastic rubber(40), a slider pin(50), a slider(60), a conic coil spring(70) and a coil spring(80) and expanded or contracted according to a variation of temperature to open and shut an inlet(2) of a conveyance unit(C); and a conveyance unit(C) formed in a hollow cylindrical shape, provided with an inlet(2) and an outlet(3), and coupled with the main body(A).

Description

Freeze Blocker {anti-freezing device}

The present invention relates to a freeze blocker. More specifically, the present invention relates to a freeze blocker capable of preventing freezing and freezing by automatically discharging water inside a conduit according to an external temperature drop in order to prevent freezing caused by volume expansion due to freezing of water remaining in the conduit.

According to the Seoul Metropolitan Waterworks Division's statistical data (Table 1), about 30% of the causes of replacement of water meters in Seoul accounted for about 30% of replacement causes due to abnormal failures except replacement due to freezing of the meters due to freezing. The amount is large (Source: www.water.seoul.kr), and especially in the winter of 2000, 63,000 households were damaged due to freezing due to the cold.

The cost of simple meter replacement due to such freezing costs is incurred as much as billions of dollars in Seoul alone. Is a huge socioeconomic loss.

Although such a socioeconomic problem exists, the development of a suitable device for freezing prevention is not very practical, and there are almost no freezing prevention devices that are practically used effectively in the field.

Until now, the freezing prevention method has been mainly used to continuously discharge the tap water by artificially opening the water valve in the weather where cold weather is expected, and to insulate the pipes, valves and water meters around by using various thermal insulation materials.

This method of freeze protection has the advantage that it can be easily applied in general homes, but it is a waste of tap water because it has to be continuously flowed, and it is inconvenient for manual valve operation and unexpected unexpected temperature change. The disadvantage is that there is no countermeasure. In addition, the freeze protection method using the thermal insulation material is applicable only to the externally exposed parts, it is not applicable to the pipes embedded in the wall, floor, etc., and if there is a problem in the insulation of some parts, freezing and freezing will eventually occur. There is a problem.

Heat and expansion absorption methods have been devised in an effort to escape the primitiveness of such freeze protection methods.

First, the heating type is a method of installing a separate heater around the valve and the pipe to prevent the water temperature inside the pipe from falling below the freezing point. The temperature retention effect is better than the conventional heat insulation method, but economic loss due to the operation of a separate heating device. In the case of this excessively embedded pipe there is a disadvantage that the entire heating of the pipe is difficult.

The expansion absorption type inserts an elastic body that absorbs the expansion of water due to freezing inside the pipe or valve to prevent freezing of the faucet or meter even if freezing inside the pipe occurs.

However, the above-mentioned expansion absorption type is basically not freezing prevention function, and the freezing prevention effect is possible only in a valve in which the expansion absorption elastic body is embedded, and there is a problem in that the freezing prevention function for the whole pipe cannot be expected.

The present invention has been made to solve the above problems, an object of the present invention is to provide a freeze arrester that can prevent freezing in the pipe by opening and closing the valve automatically responds to changes in the water temperature in the pipe without any additional operation. .

In addition, an object of the present invention is to provide a freeze blocker that can be installed anywhere in the faucet, water meter or water pipe and is easily removable, and can be used as a valve.

1 is an exploded perspective view of a freeze blocker of the present invention.

Figure 2 is a standard sectional view of the freeze blocker of the present invention.

3 is an operating state diagram of the freeze blocker of the present invention.

4 is a cross-sectional view showing a specific example 1 of the present invention.

5 is a cross-sectional view showing a concrete example 2 of the present invention.

<Description of Main Reference Codes>

A: Body B: Shrinkage

C: water passage 1: handle

2: inlet port 3: outlet port

4 packing 10 housing

20: shrinkage material 30: rubber cap

40: inelastic rubber 50: slider pin

60: slider 70: conical coil spring

80: coil spring

In order to achieve the above object, the present invention uses a shrinkage material that expands and contracts precisely in response to a temperature change, and includes a shrinkage part that opens and closes the flow of water in a pipeline according to a temperature change, including the shrinkage material. A main body surrounding the contraction part and a water supply part coupled to the main body to become a flow passage of water are configured to be integrally combined.

The shrinkage material should have excellent shrinkage capability at low temperatures where freezing occurs, and excellent reactivity with sudden temperature changes.

In the present invention, copper powder is used as a shrinkage material that satisfies all the above conditions, and an oil component is added thereto. Since the oil component has good expandability and the copper powder has excellent enthusiasm, the copper powder and oil are mixed at an appropriate ratio and used as a shrinkage material.

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

1 is an exploded perspective view of a freeze blocker according to the present invention. As shown, the freeze blocker of the present invention comprises a main body (A), a contraction (B) and a water passage (C).

The main body A has a cylindrical shape surrounding the contracting portion B, and the upper part is closed and the lower part is open. The water passage portion C is coupled to the open lower portion, and the handle 1 may be attached to the upper portion. Thus, the freeze blocker of the present invention can be easily installed anywhere, such as a faucet, a water meter, a water pipe, and the like, since the main body, the shrinkage part, and the water supply part are integrally combined to form one unit, and the attachment and detachment is easy and easy to maintain.

The water passage portion (C) has a hollow cylindrical shape, the upper part is open, the inlet port (2) is formed in the lower portion, the outlet port (3) is formed on the side is coupled to the main body (A). The outer surface of the inlet 2 forms a male screw so that the packing 4 is attached to the lower portion of the water passage part C by bolt-nut coupling.

Therefore, the freeze blocker of the present invention is usually used as a valve for opening and closing a faucet, a water meter, a pipe in a water pipe.

The water passage part C is coupled to the main body A to receive the contraction portion B, and the flow of water in the pipeline when the contraction portion B contracts while the packing 4 is blocking the pipeline. It is a passage.

The shrinkage portion (B) is a core part of the present invention, the housing 10, the shrinkage material 20, rubber cap 30, inelastic rubber 40, slider pin 50, slider 60, conical Composed of a coil spring 70 and the coil spring 80 is expanded or contracted in accordance with the temperature change to prevent freezing by opening and closing the flow of water.

Looking at the components of such a contraction in detail as follows.

The housing 10 has a cylindrical shape in which an upper part is opened and a lower part is closed, and a filling room for accommodating the shrinkage material 20 is formed inside. The outer diameter of the housing 10 is greater than the outer diameter of the lower portion of the housing 10 has a jaw formed on the upper side, the plunge 11 is attached to the lower portion.

A conical coil spring is installed between the jaw formed in the upper portion of the housing 10 and the lower portion of the outlet 3 of the water passage C, which will be described later.

The shrinkage member 20 is filled in the housing 10. The shrinkage member 20 is a mixture of copper powder and an oil component in an appropriate ratio as described above. The shrinkage member 20 does not shrink as shown in FIG. 2 when the ambient temperature is higher than an appropriate temperature (about 3 to 4 ° C before freezing starts), and thus, the shrinkage member 20 is attached to the bottom of the housing 10. The lunge 11 closes the inlet of the water passage so that the tap water does not pass. However, when the ambient temperature decreases to about 1.7 ° C. or less, as shown in FIG. 3, the shrinkage material 20 starts to shrink, and thus the shrinkage material 20 inside the housing 10 is filled. As the volume decreases, the housing 10 is moved upward by the elastic force of the conical coil spring 70 spanning the upper jaw of the housing 10. Therefore, the plunge 11 which was blocking the inlet 2 of the water passage part C moves together to open the inlet hole 2 of the water passage part C, so that tap water in the pipe flows to the outside to prevent freezing. .

The rubber cap 30 is inserted into the filling room inside the housing in a shape in which the bell is turned upside down to serve to maintain the airtightness of the filling room.

The inelastic rubber 40 has a double cylindrical shape having a lower diameter than a diameter of an upper portion thereof, and a lower portion thereof is formed inside the rubber cap 30 by forming a curved surface corresponding to an inner curved surface of the rubber cap 30. The upper part is inserted into the slider 60 mentioned later.

The slider pin 50 is connected to the upper portion of the non-elastic rubber 40 in a rod shape having the same diameter as the upper portion of the non-elastic rubber 40 is inserted into the slider 60 to be described later, a part of the slider 60 protrudes outward. A part of the slider pin 50 protruding to the outside is prevented by the snap ring 51 attached to the inside of the main body A, the plate 52 is coupled to the end.

The plate 52 is located between the coil spring 80 and the slide pin 50 which is installed at the closed end of the main body A in a disk shape having the same diameter as the inner diameter of the main body A. The elastic force of the coil spring 80 is transmitted to the slider pin 50.

The downward elasticity of the coil spring 80 is transmitted to the slider pin 50, the inelastic rubber 40, the rubber cap 30, the shrinkage member 20 via the plate 52, and the conical coil The upward elastic force of the spring 70 is transmitted to the housing 10. Therefore, while the downward elasticity of the coil spring 80 and the upward elasticity of the conical coil spring 70 are balanced, the contraction portion B is accommodated and fixed in the body A and the water passage C. In general, the inlet 2 of the water passage part C is blocked by the plunge 11 attached to the lower portion of the housing 10.

However, when the shrinkage member 20 shrinks due to a temperature drop, the filling room of the housing 10 in which the shrinkage member 20 is accommodated contracts, and the coil spring 80 and the conical shape are contracted according to the contraction of the filling room. Equilibrium of the elastic force of the coil spring 70 is broken. Therefore, the conical coil spring 70 is extended to maintain the equilibrium, so that the housing 10 is pushed up.

As the housing 10 is pushed upward, the plunge 11 attached to the lower portion of the housing 10 and blocking the inlet 2 of the water passage C also moves upward while the water passage C is moved. The inlet (2) of the is opened so that the water in the conduit is discharged to the outside and thus freezing does not occur to prevent freezing.

4 is a cross-sectional view showing a state in which the freeze blocker of the present invention is installed in a faucet as a first embodiment of the present invention.

As shown, when the freeze blocker of the present invention is installed in the faucet, it is usually used as a valve for opening and closing the faucet. That is, the body of the freeze blocker becomes a valve body, and the packing 4 attached to the lower portion of the water passage part C opens and closes the inlet pipe in the faucet so as to pass the tap water.

There is no problem because freezing does not occur while water flows, but if the temperature drops while the valve is closed and the flow of water is stopped, freezing occurs and the faucet is frozen. However, the faucet in which the freeze blocker of the present invention is installed has the shrinkage material 20 contracted as described above when the ambient temperature drops, and the housing 10 moves upward as much as the shrinkage material 20 contracts. Inlet (2) of the open) the water in the conduit flows into the water passage (C) is discharged to the outside through the outlet (3). Therefore, freezing is prevented by the flow of water.

5 is a cross-sectional view showing a state in which the freeze blocker of the present invention is installed in a pipe line as a second embodiment of the present invention.

As shown in the pipe line as shown in the above faucet acts as a valve for opening and closing the inlet in the pipeline, when the external temperature drops while the valve is locked operates as described above to discharge the water in the pipeline to the outside Will be prevented.

On the other hand, although not shown, the freeze arrester of the present invention is installed in the water meter as in the above-mentioned faucet or pipe line, and functions as a valve in normal times. Flowing water can prevent freezing of the water meter.

Freeze blocker of the present invention can automatically prevent the freezing by opening and closing the valve in response to the temperature change without a separate operation.

In addition, the freeze blocker of the present invention can be applied to a variety of pipes, such as faucets, water meters because the body, the water passage, the shrinkage unit is integrally combined to form a unit, and also functions as a valve of the faucet, etc. Easy removal and maintenance.

Claims (5)

A main body in which the upper part is closed and the lower part is open in a cylindrical shape, and a water passage fastening part is formed on the lower part thereof; An upper portion of the cylindrical shape having a hollow formed therein and an inlet portion formed at a lower portion thereof, and a water outlet portion formed at a side thereof and coupled to the main body; And A contraction part accommodated in the main body to expand or contract according to a change in ambient temperature to open and close the inlet of the water passage; Freeze blocker comprising a. The method of claim 1 wherein the contraction portion, A housing in which a contraction material is filled in the hollow cylindrical shape of which the upper part is opened and the lower part is closed, the jaw is formed on the upper side, and the plunge is attached to the lower end; A conical coil spring installed in the conduit of the water passage and fixed over the jaw of the housing; A rubber cap inserted into the housing in a shape in which the bell is turned upside down to maintain the airtightness of the shrinkage material; A non-elastic rubber having a double cylindrical shape different in diameter from an upper part and a lower part to form a curved surface corresponding to an inner curved surface of the rubber cap, and accommodated in the rubber gap, and an upper part inserted into a slider to be described later; A slider pin having a rod shape having the same diameter as the upper portion of the inelastic rubber and inserted into a slider to be described later, a portion of the end protruding out of the slider but having a plate coupled to the protruding end; A slider coupled to the housing in a hollow cylindrical shape having an upper portion and a lower portion open to insert the upper and slider pins of the inelastic rubber; A snap ring installed inside the main body to prevent movement of the protruding slider pin; And A spring coil installed at the closed end of the main body and bound by the plate; Freeze blocker comprising a. The freeze blocker of claim 1, wherein a packing is attached to a lower portion of the water passing portion. The freeze blocker of claim 2, wherein the shrinkage material comprises copper powder and oil. The method according to any one of claims 1 to 4, The freeze blocker is installed in any one of the faucet, water meter and water pipes, the freeze blocker, characterized in that it is usually used as a valve.