KR20100101038A - The valve possible temporary efflux of fluid - Google Patents

Abstract

PURPOSE: A valve possible temporary efflux of a fluid is provided to flow out small amount of fluid by selectively opening a second outlet. CONSTITUTION: A valve comprises a housing(10), a stopper(20), and a c(30). The housing has a first outlet(12) and a second outlet(13) flowing out liquid received from a fluid inlet. The stopper in interposed between the second outlet and the fluid inlet and is moved to the second outlet to block the second outlet while is moved to the fluid inlet to open the second outlet. The stopper moving unit is separated from the stopper if force applied to the stopper is larger than a predetermined level.

Description

VALVE POSSIBLE TEMPORARY EFFLUX OF FLUID

The present invention relates to a valve installed in the middle of a pipeline, a container, or the like to control the flow of a fluid.

Various types of valves have been developed to control the flow of the fluid, the basic shape of which depends on how to control the flow of the fluid.

In controlling the flow of the fluid, there is a case where the selective flow of the fluid occurs in a direction different from the normal flow direction, but the flow of the fluid occurs only for a short time.

For example, it may be necessary to secure a small amount of tap water samples to check the condition (eg, contamination) of tap water flowing through a specific point of a water pipe.

For this purpose, a valve may be installed at a specific point of the water pipe, and the tap water in the water pipe may be selectively discharged through the valve.

However, if the tap water can be continuously drawn out through the valve as described above, it is a considerable loss in terms of the company running the water supply business.

In other words, the user must use only the tap water that has passed through the water meter and pay for the amount used so that the water supply business can operate normally.

Therefore, it is possible to flow the fluid in a direction different from the normal flow direction, but it is necessary to allow the fluid to flow only for a short time.

This necessity is more urgently needed if the effluent fluid is expensive, such as oil.

As another example, there is a case where the foreign matter mixed in the fluid is filtered at a specific point, and the filtered foreign matter may be selectively discharged.

Even in this case, the valve may be installed on the flow path of the fluid, and the fluid may be selectively discharged through the valve, but when the fluid is discharged, foreign substances may be discharged together.

However, if a large amount of fluid, such as tap water, oil, natural gas, etc. can be taken out through the valve installed to remove foreign substances as described above, considerable damage may occur.

Therefore, even in the above case, it is possible to flow the fluid in a direction different from the normal flow direction, but it is necessary to allow the fluid to flow only for a short time.

Korean Utility Model Application No. 20-2006-0020839 discloses a technique for installing two valves and allowing two valves to interlock so as to prevent unauthorized extraction of fluid through the valve.

However, the prior art as described above has a problem that the valve can be disconnected in a simple manner because the core components are exposed to the outside, and in such a case, the fluid can be withdrawn.

In addition, in order for the fluid to flow in a direction different from the normal flow path, the normal flow path must be blocked, and two valves have to be installed, which causes problems such as high manufacturing costs.

The present invention is to solve the above problems, more specifically, the fluid can be flowed in a direction different from the normal flow path, but the fluid flows out only for a short time to minimize the loss of the fluid, the fluid is unauthorized The purpose is to provide a valve that cannot be pulled out.

In particular, it is intended to prevent the unauthorized extraction of the fluid by placing a configuration inside the valve to prevent the unauthorized extraction of the fluid by modifying the valve from the outside of the valve.

In the present invention, the fluid flowing into the fluid inlet forms a first outlet and a second outlet which can be discharged, the second outlet is to be opened and closed selectively by the movement of the stopper, the stopper moving means and the stopper When the stopper is moved to open the second outlet, the stopper is separated from the stopper moving means by the force in the direction of the second outlet, which blocks the second outlet so that the fluid can be continuously drawn off to the second outlet. Can be.

In addition, it is difficult to continuously open the second outlet by making changes to the valve and to save manufacturing costs.

The valve of the present invention has a housing having a first outlet port and a second outlet port through which the fluid introduced into the fluid inlet port can be discharged.

In addition, it is located between the second outlet and the fluid inlet in the flow path of the fluid has a stopper for blocking the second outlet when moved in the direction of the second outlet, opening the second outlet when moved in the direction of the fluid inlet.

In addition, the stopper can be separated and combined with the stopper, but when coupled, the stopper can be moved to open the second outlet, and the stopper moves to be separated from the stopper when the force in the direction of the second outlet upon the stopper is greater than the set value. Have the means.

Therefore, when the stopper is moved by the stopper moving means to open the second outlet, the fluid flows out to the second outlet, and when the fluid flows out to the second outlet, the stopper moving means and the stopper are separated by the force applied to the stopper. The outlet is blocked by a stopper.

In the valve of the present invention, a first outlet and a second outlet are formed to allow the fluid introduced into the fluid inlet to flow out, and the second outlet is selectively opened and closed by the movement of the stopper. When the stopper is combined and the stopper moves to open the second outlet, the stopper is separated from the stopper moving means to block the second outlet. Therefore, the second outlet can be selectively opened to draw out the fluid, but only a small amount of fluid is instantaneously. It can only be pulled out but not continuously.

In addition, it is difficult to continuously open the second outlet by applying a deformation to the valve, the configuration is simple, the manufacturing cost is low, and the occurrence rate of failure is very low.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

However, since the accompanying drawings are only examples illustrated to specifically describe the technical idea of the present invention, the technical idea of the present invention is not limited to the form of the accompanying drawings.

The present invention relates to a valve which may be flowed in a direction of a first outlet, which is a normal flow direction of a fluid, and may be caused to flow in a direction of a second outlet which is different from a normal flow direction.

Therefore, the valve of the present invention has a housing in which a fluid inlet port 11 is formed, and a first outlet port 12 and a second outlet port 13 are formed so that the fluid introduced into the fluid inlet port 11 can flow out. 10)

However, the present invention has the purpose of allowing the fluid to flow out in a direction different from the normal flow direction, but the fluid flows out only for a short time so that the loss of the fluid is minimized and the fluid cannot be continuously drawn out.

For this reason, the second outlet 13 of the present invention can be selectively opened.

That is, the valve of the present invention is provided with a flow path 14 from the fluid inlet 11 to the first outlet 12 and a flow path 15 from the fluid inlet 11 to the second outlet 13. The fluid flowing in the direction of the first outlet 12 is the normal flow direction of the fluid, and the fluid flowing in the direction of the second outlet 13 flows in a direction different from the normal flow direction.

The inventors of the present application, after long research and effort, selectively open and close the second outlet 13 by a stopper, but when the second outlet 13 is opened, the force of the fluid flowing out to the second outlet 13 ( The stopper 20 is directed toward the second outlet 13 by the flow velocity), thereby conceiving a structure for blocking the second outlet 13.

Referring to the accompanying drawings, a stopper 20 is located between the second outlet 13 and the fluid inlet 11 in the flow path of the fluid, the stopper 20 is moved to the second outlet 13 when the second stopper (13) When the outlet 13 is blocked and the stopper 20 moves in the direction of the fluid inlet 11, the second outlet 13 is opened.

In addition, the stopper 20 is provided with a stopper moving means 30 capable of being separated and coupled with the stopper 20. When the stopper moving means 30 is coupled with the stopper 20, the stopper 20 moves to the second outlet 13. To open the door.

In the accompanying drawings, the coupling force of the stopper 20 and the stopper moving means 30 is that the stopper 20 can move together when the stopper moving means 30 is moved, but the second outlet 13 applied to the stopper 20. If the force in the direction is greater than the set value is the degree of separation of the stopper 20 and the stopper moving means 30.

In the above description, the force in the direction of the second outlet 13 applied to the stopper 20 is generated by the flow rate of the fluid flowing in the direction of the second outlet 13, the weight of the stopper 20 itself, and the like.

Therefore, the plug 20 and the plug moving means 30 may be separated by implementing the plug 20 to be affected by the force (flow rate, etc.) of the fluid flowing to the second outlet 13.

In this case, the force applied to the plug 20 by the fluid flowing in the direction of the second outlet 13 varies depending on how much the plug 20 is affected by the fluid flowing into the second outlet 13.

That is, the degree to which the stopper 20 is influenced by the fluid is determined according to how much the fluid flowing into the second outlet 13 hits the stopper 20. If the area where the fluid collides with the stopper 20 is large, the stopper 20 is subject to a lot of influence of the fluid (force), and if the area hit is small, the plug 20 is less affected by the fluid (force).

Therefore, the coupling force of the stopper 20 and the stopper moving means 30 for achieving the object of the present invention is the degree of influence of the force of the fluid flowing into the second outlet 13 and the stopper 20 is affected by the force of the fluid , It is determined in consideration of the weight of the stopper 20, and the like, since the matter can be obtained through a well-known calculation method by those of ordinary skill in the art will not be described in detail.

When the stopper 20 is moved by the stopper moving means 30 and the second outlet 13 is opened, the fluid is discharged to the second outlet 13, and the stopper is driven by the force of the fluid discharged to the second outlet 13. The coupling structure of the stopper 20 and the stopper moving means 30 for separating the moving means 30 and the stopper 20 and blocking the second outlet 13 by the stopper 20 may be implemented in various forms. Can be.

Referring to a specific example, it can be implemented to be a combination of the plug 20 and the plug moving means 30 by a magnetic force.

In FIG. 1, the magnet 31 is positioned at a portion of the plug movement means 30 that comes into contact with the plug 20 so that the plug 20 contacts the magnet 31 of the plug movement means 30. And stopper movement means 30 are combined, and if the force in the direction of the second outlet 13 applied to the stopper 20 is greater than the coupling force of the stopper 20 and the stopper movement means 30 (second outlet (13) Occurs when the stopper 20 and the stopper moving means 30 are separated.

Portion and the stopper of the stopper moving means in contact with the fluid is preferably implemented by a material such as brass or stainless steel that is highly corrosion-resistant, some of the materials do not respond to magnetic forces.

In this case, it is possible to use a method of attaching a strong corrosion-resistant magnetic material to the magnet and the portion to be attached.

If a magnet is provided on the stopper moving means 30, the magnetic material is attached to the stopper. On the contrary, if the stopper is provided with a magnet, the magnetic body is attached to the stopper moving means.

In the structure in which the stopper 20 and the stopper moving means 30 are coupled by magnetic force, it is necessary to prevent the magnetic force acting on the outside of the housing 10 from being transmitted to the stopper 20 inside the housing 10. .

This is to prevent the movement of the stopper 20 by placing a separate magnetic force generating means on the outside of the housing 10 in an unintended intention.

To this end, it is preferable to implement the housing 10 with a nonmagnetic material, and thick.

Of course, in implementing the housing, it is more preferable to implement the material by which magnetic force does not pass or to post-process the magnetic force after the housing is manufactured.

As a further coupling structure of the stopper 20 and the stopper moving means 30, the groove 32 having the locking jaw 32a and the groove 32 are fitted to the locking jaw 32a, but not to the stopper 20. When the force in the direction of the applied second outlet 13 is greater than the set value it can be implemented in the form having a locking projection 33 is separated from the groove (32).

The shape of the locking protrusion having the above structure may be implemented in various ways.

In FIG. 5, the stopper 20 has a groove 32 having a catching jaw 32a, and the stopper moving means 30 has a catching protrusion 33 that is fitted into the groove 32 and is caught by the catching jaw 32a. have.

In addition, the locking protrusion 33 is formed into a plurality of parts, so that when the force in the direction of the second outlet 13 applied to the stopper 20 is strong, each part of the locking protrusion 33 (of a split shape) Part), the locking projection 33 is separated from the locking groove 32.

When engaging, it may be inserted into the locking groove 32 because the locking projection 33 is retracted.

The structure having the engaging protrusion and the locking groove as described above is characterized in that it is more difficult to apply a deformation to the valve so that the fluid flows into the second outlet (13).

As another coupling structure of the stopper 20 and the stopper moving means 30, there is a form that the coupling is made by the friction force between the stopper 20 and the stopper moving means (30).

That is, when the stopper 20 and the stopper moving means 30 are coupled to each other, a protrusion is inserted into the groove or the hole to be coupled, but is rigidly coupled to generate a strong frictional force, and the frictional force is such that the second outlet 13 is opened. While the stopper 20 can be moved as far as possible, a strong force is applied to the stopper 20 so that the stopper 20 and the stopper moving means 30 can be separated. (Not shown)

That is, when the force of the fluid directed toward the second outlet 13 is applied to the stopper 20 while the second outlet 13 is open, the friction force generated between the stopper 20 and the stopper moving means 30 is reduced. Is to be released.

In this case, a method for tightly coupling the protrusion when the protrusion is inserted into the groove or the hole may be implemented in various forms known in the art.

However, a structure in which the groove or the hole is elastic like rubber or the outer diameter of the protrusion is elastic like rubber is preferred to have a rigid fit.

The plug moving means 30, which is a component of the present invention, may be implemented in various forms.

However, implementation in the form as shown in the figure is preferable because the structure is simple and fewer failures.

In FIG. 1, the housing 10 has a packing installation space 16 extending in the opposite direction of the second outlet 13 and a packing installation hole 17 formed at an upper portion of the packing installation space 16.

In addition, the stopper moving means 30 has a cover 34 which is movable in the direction of the second outlet 13 in the outer side of the packing installation space 16 or in the opposite direction, one side of the cover 34 It is connected to move with the cover 34 and is configured to include a moving rod (35) having a portion that is separated, combined with the stopper (20).

In addition, the packing installation space 16 of the housing 10 is blocked to prevent leakage, but the packing 50 is further provided with a moving rod 35 is inserted into the two rod installation hole 51 formed inside.

Therefore, when the cover 34 is pulled in the opposite direction of the second outlet 13, the moving rod 35 is moved in the opposite direction of the second outlet 13 without leaking.

Of course, the movable rod 35 may be moved in the direction of the second outlet, and even in this case, no leakage occurs.

Such a structure does not require complicated processing at the time of fabrication of the component, has a small number of components, and has a very low probability of failure.

The stopper movement means 30 may be implemented in the form of having a bolt that is spirally coupled to move in the direction of the second outlet 13 or in the opposite direction when the screw is rotated.

That is, the spirally coupled bolts are rotated forward or reversely so that the bolts move in the stopper 20 direction or the opposite direction, and the bolts move in the stopper 20 direction so that the bolts are coupled with the stopper 20 and the bolts. It may be implemented in the form of moving the stopper 20 by moving in the opposite direction.

As shown in the accompanying drawings, the stopper 20 for opening and closing the second outlet 13 is located inside the valve, and the part controlling the movement of the stopper 20 is also located mostly inside the stopper 20. It is not possible to withdraw the fluid continuously through the valve of the present invention.

In particular, the structure having the movable rod 35 and the cover 34 as shown in FIG. 1 is difficult to deform the part controlling the blocking of the second outlet 13 in order to continuously drain the fluid to the second outlet 13. Because it is very stable.

In implementing the stopper moving means 30, it is implemented to be movable in the coupling direction with the stopper 20 (the direction in contact with the stopper 20 in the state blocking the second outlet 13), the external force acts In the non-state state, it is preferable that the stopper moving means 30 moves naturally in the coupling direction with the stopper 20 by the spring 40.

That is, by removing the force applied to the stopper moving means 30 in the state in which the stopper 20 is moved by moving the stopper moving means 30, the stopper moving means 30 is returned to its original position by a spring.

In the present invention, the stopper 20 moves in the direction of the second outlet 13 to block the second outlet 13 can be implemented in various forms already known.

However, the structure using the packing, that is, the structure so that the second outlet 13 is blocked through the leak-proof structure in which the packing is located between the housing 10 and the stopper 20 has a high failure rate.

This is because over time, the packing will not be able to fully perform its function, and the packing will be damaged during operation.

Therefore, the stopper 20 moves in the direction of the second outlet 13 to block the second outlet 13 in the form of an attached drawing such that the inclined surface and the inclined surface are in close contact with the second outlet 13. It is desirable to implement.

That is, the inclined surface 18 in which the inclined surface 21 is formed in the stopper 20, and the inclined surface 21 formed in the stopper 20 is in close contact between the second outlet 13 and the fluid inlet 11 of the housing 10. ) Is formed so that the inclined surface 21 of the plug 20 is in close contact with the inclined surface 18 of the housing 10 by a force in the direction of the second outlet 13 applied to the plug 20. (13) is to be blocked.

In the present invention, the foreign matter mixed in the fluid in the process of the fluid via the flow paths (14, 15) can be implemented to be discharged to the second outlet (13).

To this end, on the flow path from the fluid inlet 11 to the first outlet 12 is provided with a strainer (60) for filtering the foreign matter mixed in the fluid, foreign matter filtered by the strainer (60) from the fluid inlet (11) It can be implemented to collect on the flow path 15 toward the second outlet (13).

When implemented in this way, foreign substances filtered together with the fluid may be discharged when the second outlet 13 is opened.

Particularly, in the present invention, when the second outlet 13 is opened by the stopper 20, the fluid on the flow path 15 is strongly discharged to the second outlet 13 due to the pressure, so that the foreign matter flows out cleanly.

In the present invention, when the second outlet 13 is blocked by the plug 20, it is possible to open the second outlet 13 by moving the plug 20 without using the plug moving means 30. It is desirable to make it impossible.

In the case of FIG. 1, the stopper 20 may move by pushing the wire toward the stopper 20 through the second outlet 13, so that the second outlet 13 may be opened.

Therefore, it is preferable to implement so that the plug 20 can not move through the second outlet (13).

To this end, in implementing the housing 10, when the straight object without bending is pushed in the direction of the stopper 20 through the second outlet 13, the straight object without bending does not come into contact with the stopper 20. It can be implemented in the form

In FIG. 4, when the straight object 2 without bend is pushed into the second outlet 13, the straight object without bending is blocked by the inner wall of the housing 10 before contacting the stopper 20. It may not be in contact with the stopper 20 through.

In addition, even if the flexible wire is pushed in the direction of the plug 20 through the second outlet 13, the flexible wire is blocked by the inner wall of the housing 10, so that the flexible wire must move in a direction different from the direction in which the plug 20 is installed. The plug 20 cannot be moved even through a flexible wire.

In the accompanying drawings, the flow path 15 directed to the second outlet 13 is formed perpendicular to the flow path 14 directed to the first outlet 12.

However, the flow path 15 toward the second outlet 13 is preferably formed to be inclined toward the first outlet 12.

According to such a configuration, the plug 20 can receive a large pressure of the fluid directed toward the first outlet 12.

The valve of the present invention may be provided in an object such as a water meter.

Reference numeral 1 is a fluid flow pipe connected to the fluid inlet 11 and the first outlet 12 of the present invention.

In addition, reference numeral 22 denotes a region which is engaged with the cap moving means.

That is, the portion indicated by the oblique line in FIG. 5 indicates an area that is coupled with the cap moving means.

Therefore, the outer side of the region 22 coupled with the stopper moving means among the upper portions of the stopper 20 shown in FIG. 5 corresponds to a portion subjected to a force hit by the fluid flowing toward the second outlet 13.

1 is a view illustrating a valve of the present invention having a structure in which a stopper and a stopper moving means are coupled by a magnetic force, and a schematic view of a use state in which a second outlet is blocked by a stopper;

Figure 2 is a schematic view of a state in which the second outlet is opened by moving the stopper through the stopper moving means in the same state as in FIG.

3 is a schematic view showing a process in which the stopper and the stopper moving means are separated and the stopper is moved in the direction of the second outlet by the force in the direction of the second outlet in the same state as in FIG.

4 is a view illustrating a valve of the present invention having a structure in which a stopper and a stopper moving means are coupled to each other by a groove having a stopper and a stopper, and the stopper cannot move even when a wire or the like is pushed into the second outlet. 2 Schematic diagram of the use state where the outlet is blocked by a stopper

5 is a perspective view of a plug which is a component of the present invention;

<Explanation of symbols for main parts of drawing>

1. Fluid flow tube 2. Straight object

10. Housing 11.Fluid inlet

12. Outlet 1 13. Outlet 2

14. 15. Flow path 16. Packing space

17. Packing hole 18. Slope

20. Spigot 21. Slope

22. Area to be combined with plug moving means 30. Plug moving means

31. Magnet 32. Groove

32a. Jam Jaw 33.

34. Cover 35. Moving rod

40.Spring 50. Packing

51. Moving rod mounting hole 60. Filtering net

Claims (9)

In the valve, A housing having a first outlet port and a second outlet port through which fluid introduced into the fluid inlet port can be discharged; A stopper positioned between the second outlet and the fluid inlet of the flow path of the fluid and blocking the second outlet when moved in the direction of the second outlet, and opening the second outlet when moved in the direction of the fluid inlet; A stopper moving means adapted to be detachable from the stopper and coupled to the stopper so as to move the stopper so that the second outlet can be opened, and the stopper can be separated from the stopper when the force applied to the stopper in the direction of the second outlet is greater than a predetermined value; When the stopper is moved by the stopper moving means and the second outlet is opened, the fluid flows out to the second outlet, and the stopper moving means and the stopper are driven by the force applied to the stopper when the fluid flows out to the second outlet. A valve capable of temporarily draining a fluid, such that the second outlet is separated and blocked by a stopper. The method of claim 1, Combination of the stopper and the stopper moving means is a valve capable of temporarily draining the fluid is made by a magnetic force The method of claim 1, The combination of the stopper and the stopper moving means is made by the friction force between the stopper and the stopper moving means, a valve capable of temporarily draining the fluid The method of claim 1, Coupling of the stopper and the stopper moving means is made by a groove having a locking jaw and the locking projection is separated from the groove when the force applied to the plug in the direction of the second outlet is greater than the set value is fitted to the locking jaw, Valves for temporarily draining fluid 5. The method according to any one of claims 1 to 4, An inclined surface is formed on the stopper, and an inclined surface is formed between the second outlet and the fluid inlet of the housing to be in close contact with the inclined surface of the stopper so that the second outlet is blocked by being in close contact with the inclined surface of the housing. Valve that can temporarily drain the 5. The method according to any one of claims 1 to 4, A valve for temporarily discharging the fluid further provided with a spring for moving the stopper moving means in the engagement direction with the stopper 5. The method according to any one of claims 1 to 4, On the flow path from the fluid inlet to the first outlet is provided with a strainer for filtering foreign matter mixed in the fluid, A valve capable of temporarily draining a fluid, wherein foreign matter filtered by the strainer is collected on a flow path from the fluid inlet to the second outlet. 5. The method according to any one of claims 1 to 4, The housing is a valve capable of temporarily draining a fluid such that a non-bending straight object cannot be contacted with the stopper when the straight object without bending is pushed in the direction of the plug through the second outlet. 5. The method according to any one of claims 1 to 4, The housing has a packing installation space extending in the opposite direction of the second outlet and a packing installation hole formed in an upper portion of the packing installation space, The stopper moving means has a cover which is movable in the direction of the second outlet or in the opposite direction from the outer side of the packing installation space, and has one side connected to the cover and moving together with the cover, and having a portion separated from the stopper and engaged. It consists of a moving rod, Blocking the packing installation space of the housing to prevent leakage but the packing is inserted into the movable rod installation hole formed in the inner side; further provided, the valve which can temporarily flow the fluid.

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