KR200354381Y1 - Inhalation discharge valve - Google Patents

Abstract

The present invention is installed in the water supply pipe to prevent water leakage in the water supply pipe by construction, etc., and to smoothly discharge only the air mixed with the liquid during the liquid supply when the liquid is filled in the water supply pipe by re-water supply in the pipe. It relates to an intake and exhaust valve.

The intake and exhaust valve of the present invention is the valve body is formed with a space portion is formed so that the upper portion is opened and the water supply hole associated with the space portion at the lower end; A lid having a first and second fastening holes formed therein, wherein a stepped portion is formed inside the fastening hole and provided around the second fastening hole so as to be directed toward a lower end thereof, and a lid fastened to the valve body; A plurality of intake and exhaust caps formed in the circumferential direction and fastened to the lid; First and second exhaust means coupled to the first and second fastening holes of the lid to open and close according to the water level and the internal pressure of the valve body; And a float valve having a through hole fitted between the guides of the lid and having a guide groove associated with the through hole.

Therefore, the present invention blocks the rapid flow generated when the large amount of water is blown out immediately before the air outlet hole is closed, or the air outlet hole is closed, by the flow valve. It is to prevent the water hammer phenomenon.

Description

Inhalation discharge valve

The present invention relates to an intake / exhaust valve, and more particularly, it is installed in a water supply pipe to prevent leakage of water in the water supply pipe by construction, etc., and mixes with liquid during liquid supply when the liquid is filled in the water supply pipe by re-water supply in the pipe. It relates to an intake and exhaust valve for smoothly discharging only the introduced air.

In general, the intake / exhaust valve performs intake and exhaust by air exhaust and intake and exhaust air, and when the internal pressure in the valve body generated by the drainage of water in the pipe is at or below atmospheric pressure, both the air exhaust and intake and exhaust holes are opened to become intake and exhaust state. When the liquid is supplied, the flow valve and the float valve are pressed while the water level in the valve body rises due to the discharge of air, thereby closing the air discharge hole and the intake / exhaust hole to prevent the discharge of the liquid.

However, when the liquid is supplied into the valve body in a state in which the air discharge hole and the intake / exhaust hole are closed, the air remaining in the water supply pipe is sent into the valve body as the liquid, and the water level in the valve body is lowered. At this time, the float valve closing the intake and exhaust pores goes down to the water surface, and the intake and exhaust pores are opened to release air.

The operation in which the air outlet hole of the flow valve is brought into close contact with the above-described operation depends on the water level in the valve body, the buoyancy of the flow valve associated therewith, and the internal pressure in the valve body.

Therefore, the conventional intake and exhaust valves depend on the water level in the valve body, the buoyancy of the flow valve associated therewith, and the internal pressure in the valve body to close the air discharge hole of the flow valve by pressure. It is impossible to adjust artificially.

For this reason, when a large amount of air in the pipe for sending liquid flows into the valve body when the liquid is supplied, the atmospheric pressure in the valve body increases momentarily, and further the liquid comes to the flow valve, and the timing at which the air outlet hole is closed and the liquid is air The time with the timing passing through the discharge hole is shifted, which causes a large amount of liquid to be blown just before the air discharge hole is closed.

In addition, when blocking the air outlet hole, water hammer phenomenon is likely to occur because the rapid flow is fixed by the flow valve instantaneously. Especially in the case of piping in buildings, the water hammer phenomenon causes the failure of the equipment, and the liquid is blown out of the exhaust hole. Since this phenomenon is flooded, the piping equipment is required to receive the liquid and to flow it downward. There was a problem such as remission.

Furthermore, the flow regulator of the float valve has a large range because the float valve requires a fairly free flow state at the bottom of the flow valve, and blocks the intake and exhaust of the water inlet which supplies the liquid flowing from the main pipe when the float valve descends. In addition to the valve case, a separate structure capable of opening and closing the float valve is required, and thus the structure becomes more complicated.

The present invention was devised to solve such a problem, and is installed in a water supply pipe to prevent water from leaking into the water supply pipe by construction, etc., and when the liquid is filled in the water supply pipe by rewatering the pipe, Because the air is located at a high place, it only smoothly discharges the air in the pipe to prevent the leakage of fluid. Also, when the liquid filled in the pipe is discharged, the outside air is sucked in to increase the efficiency of drainage and the vacuum in the pipe. The purpose is to prevent damage by the negative pressure in the pipe to prevent the state.

1 is an exploded perspective view showing an intake and exhaust valve according to the present invention.

Figure 2 is a perspective view showing a combined state intake and exhaust valve according to the present invention.

Figure 3 is a cross-sectional view showing a state intake and exhaust valve according to the present invention.

Figure 4 shows the intake and exhaust valve of the present invention, a longitudinal cross-sectional view of a state in which the float valve is lowered in the state that the liquid is supplied, the intake and exhaust hole is opened and the air of the valve body is discharged.

Figure 5 is a longitudinal cross-sectional view showing the intake and exhaust valve of the present invention, the liquid is supplied and filled.

Figure 6 shows the intake and exhaust valve of the present invention, a vertical cross-sectional view of the intake and exhaust hole is opened by the slope of the float valve is inclined by the air mixed into the water flow.

Figure 7 shows the intake and exhaust valve of the present invention, a longitudinal cross-sectional view of a state in which a negative pressure is generated in the valve body by the air supply and the air intake and exhaust holes open.

** Description of the symbols for the main parts of the drawings **

10: valve body 20: lid

30,40: first and second exhaust means 32: guide member

35 fluid 36 fixed member

37, 49: intake and exhaust holes 42: screwed member

46: support member 48: valve seat

50: float valve 60: intake and exhaust cap

62: intake and exhaust

The present invention is the valve body is formed with a space portion is formed so that the upper portion is open and the water supply hole associated with the space portion at the lower end; A lid having a first and second fastening holes formed therein, wherein a stepped portion is formed inside the fastening hole and provided around the second fastening hole so as to be directed toward a lower end thereof, and a lid fastened to the valve body; A plurality of intake and exhaust caps formed in the circumferential direction and fastened to the lid; First and second exhaust means coupled to the first and second fastening holes of the lid to open and close according to the water level and the internal pressure of the valve body; And a float valve having a through hole fitted between the guides of the lid and having a guide groove associated with the through hole.

Hereinafter, described in detail with reference to the accompanying drawings an embodiment according to the present invention.

1 is an exploded perspective view showing an intake and exhaust valve according to the present invention, Figure 2 is a perspective view of the coupling state showing the intake valve according to the present invention, Figure 3 is a cross-sectional view of the combination state showing the intake valve according to the present invention.

1 to 3, the space portion 12 is formed therein, and a water hole 14 is formed inside the lower end, the water net 14 is fastened to the mesh-shaped net 16, A male screw 18 is formed in the outer circumferential direction of the upper end to provide a valve body 10 to which the lid 20 is fastened and fixed.

The lid 20 has a female screw 21 formed at the lower end thereof to be fastened to the male screw 18 of the valve body 10, and a male screw 22 is formed at the outer circumferential surface thereof so that the intake and exhaust cap 60 is fastened. The stepped portions 28a and 28b are formed on the protrusions 24 protruding upward, and the first fastening holes 26a and the second fastening holes 26b penetrating the protrusions 24 are formed.

A guide rod 29 is provided in the lid 20 so as to face the bottom thereof, and the float valve 50 is fastened to be movable.

Female threads 27a and 27b are formed on the inner circumferential surfaces of the first and second fastening holes 26a and 26b, respectively, and the first and second exhaust means 30 are formed in the first and second fastening holes 26a and 26b. 40 are fastened respectively.

The first exhaust means 30 includes a guide member 32 having a central portion and a plurality of ribs 33 formed in a circumferential direction, and having a space 34 formed therein.

A fluid 35 capable of flowing in accordance with the level of the liquid filled in the valve body 10 is provided inside the guide member 32.

Intake and exhaust hole 37 is formed in the central portion and the male screw 38 is formed on the outer peripheral surface is fastened to the first fastening hole (26a) of the lid 20, the fixing member for preventing the separation of the guide member 32 36 is provided.

A packing P is provided between the guide member 32 and the fixing member 36 to maintain airtightness.

The second exhaust means 40 is provided with a through-hole 43 penetrating the center portion, an external thread 27b is formed on the outer circumferential surface thereof, and has an O-ring O fitted in a circumferential direction at a predetermined position. It includes a screwing member 42 is formed in the stepped 45.

The support member 46 is fastened to the lower end step 45 of the screwing member 42, and the intake and exhaust hole 49 is connected to the through hole 43 of the screwing member 42 inside the support member 46. The formed valve seat 48 is provided to protrude to the outer lower end.

The float valve 50 has a through hole 52 that is inserted into the guide section 29 to be fluidly fastened and a guide groove 54 associated with the through hole 52 is formed.

The intake and exhaust cap 60 is formed with a plurality of air intake and exhaust mechanism 62 through which air flows outwardly or outside air flows in the circumferential direction, and an internal thread 64 is formed therein so that the male screw of the lid 20 is formed. Tighten to (22).

As such, the present invention discharges only the air contained in the water to the outside when satisfying the water in the pipe, and on the contrary, when the water filled in the pipe is discharged, the external air is introduced to smoothly drain the work. .

4 shows a state of discharging air in the pipe through the valve body, and before the water is supplied into the pipe, the fluid 35 and the float valve 50 are located at the lower end of the lid 20. The intake and exhaust holes 37 and 49 of the first and second exhaust means 30 and 40 fastened to the two fastening holes 26a and 26b are kept open.

When water is supplied into the tube in this state, water is supplied while pushing the air remaining in the tube. The pushed air is introduced into the space 12 through the water passage 14 of the valve body 10. The air introduced into the space 12 of the valve body 10 is discharged to the outside through the intake and exhaust holes 37 and 49 of the 1.2 exhaust means 30 and 40 provided in the lid 20 again. In addition, the air discharged to the first and second exhaust means 30 and 40 is discharged to the outside through the intake and exhaust mechanism 62 of the intake and exhaust cap 60.

At this time, the liquid is introduced into the valve body 10 while being filled with air while discharging the air in the valve body 10 to the outside.

5 shows a state in which the liquid is filled in the space of the valve body, when the liquid flows into the valve body 10, the float valve 50 floats along the guide section 29, and the second exhaust means 40 It is in close contact with the lower end of the valve seat 48 provided in the) to block the intake and exhaust holes 49 to prevent the liquid outflow. In addition, the fluid 35 provided in the first exhaust means 30 is also lifted by the buoyancy on the guide member 32 to be in close contact with the lower end of the packing (P) to block the intake and exhaust hole 37 to leak the liquid Will be prevented.

Therefore, when the liquid is filled in the valve body 10, the fluid 35 and the float valve 50 block the intake and exhaust holes 37 and 49 of the first and second exhaust means 30 and 40, respectively. In this state, the liquid is prevented from flowing out of the intake / exhaust valve at all times.

FIG. 6 illustrates a state in which the float valve descends inclined as the liquid level decreases and the intake and exhaust holes of the second exhaust means are opened. The liquid flowed into the valve body 10 and air contained therein are separated from the valve body ( 10) in the stacked state in the liquid level in the valve body 10 is gradually lowered buoyancy acting on the float valve 50 is lost.

When the buoyancy applied to the float valve 50 disappears and gradually descends, the intake and exhaust holes 49 provided in the valve seat 48 of the second exhaust means 40 that the float valve 50 is blocked open. Only the air separated from the liquid is discharged to the outside through the intake and exhaust holes 49 of the second exhaust means 40,

At this time, the fluid 35 blocking the intake and exhaust holes 37 of the first exhaust means 30 always blocks the intake and exhaust holes 37 of the first exhaust means 30 by the internal pressure of the valve body 10. Keep doing it.

7 shows a state in which the negative pressure is generated in the valve body to open the intake and exhaust pores of the first and second exhaust means. When the liquid in the pipe is removed, external air is sucked in to increase the efficiency of the drainage operation. This prevents damage such as crushing.

That is, when the liquid in the pipe is removed, the level of the liquid filled in the space portion 12 of the valve body 10 is lowered. At this time, the outside air is introduced and supplied to smoothly drain the liquid. The inflow is introduced through the intake and exhaust port 62 of the intake and exhaust cap 60, and the fluid 35 blocking the intake and exhaust hole 37 of the first exhaust means 30 of the lid 20 is introduced by the inflowed air. It descends to the lower end and the intake and exhaust holes 37 are opened.

At the same time, the float valve 50 blocking the intake and exhaust pores 49 of the second exhaust means 40 is also lowered to the lower end by the guide section 29 to the intake and exhaust pores 49 of the second exhaust means 40. Is opened.

Therefore, the inlet of the outside air flows into the intake and exhaust holes 62 of the intake and exhaust cap 60 through the intake and exhaust holes 37 and 49 of the first and second exhaust means 30 and 40. The liquid flowing into the space portion 12) remaining in the valve body 10 is smoothly discharged.

Although the preferred embodiments of the present invention have been described in detail above, those of ordinary skill in the art to which the present invention pertains may devise the present invention without departing from the spirit and scope of the present invention as defined in the appended claims. It will be appreciated that the modifications can be made by modifying or modifying them.

As described above, the air intake and exhaust valve according to the present invention is stored in the valve body only in the air discharged to the outside through the intake and exhaust air from the water inlet through the intake and exhaust hole, the liquid level of the stored liquid is lowered float valve Is lowered inclined at the point between the guides to open the intake and exhaust holes of the second volleyball means so that the intake air stored in the valve body is discharged, and if the negative pressure is generated in the valve body by supplying air, the intake and exhaust holes of the first and second exhaust means are negative pressure. Is opened according to.

In addition, when a large amount of air and liquid are introduced into the valve body when removing water from the water pipe, the degree of opening of the intake and exhaust holes is adjusted according to the supply amount of the liquid so that only air is discharged. Since the intake and exhaust holes of the exhaust means are closed and the opening and closing of the intake and exhaust holes of the second exhaust means and control of the opening area are carried out, it is possible to suppress the flow rate of air during discharge and to prevent the liquid from flowing out to the outside. do.

The lowering of the atmospheric pressure in the valve body generated when the water level in the valve body is lowered discharges air by the intake operation in which the intake and exhaust holes formed in the second exhaust means are opened, thereby preventing a sudden change in the atmospheric pressure in the valve body.

When the intake and exhaust holes are closed, there is liquid in the valve body or internal pressure in the valve body after closing once, but at that point, when air is supplied into the valve body, the water level is lowered, so the float valve is lowered. Exhaust air remaining in the body.

As described above, the phenomenon of liquid swelling during rapid exhaust, which is a conventional problem, amplification of the water hammer phenomenon due to the air staying in the tube, and the water hammer phenomenon occurring when the air outlet hole is closed can be prevented. It can be seen that having.

Claims (3)

A valve body having a space portion formed to open at an upper portion thereof, and a through hole connected to the space portion at a lower portion thereof; A lid having a first and second fastening holes formed therein, wherein a stepped portion is formed inside the fastening hole and provided around the second fastening hole so as to be directed toward a lower end thereof, and a lid fastened to the valve body; A plurality of intake and exhaust caps formed in the circumferential direction and fastened to the lid; First and second exhaust means coupled to the first and second fastening holes of the lid to open and close according to the water level and the internal pressure of the valve body; And Intake and exhaust valves comprising a float valve is formed between the guide of the lid is formed with a guide groove associated with the through hole. The method of claim 1, wherein the first exhaust means A guide member having a plurality of ribs is provided and a fluid flowing inside the guide member is provided, and a suction member is formed in a central portion thereof, and a fixing member is provided to be fastened to the first fastening hole of the lid to prevent separation of the guide member. And a packing provided between the guide member and the fixing member. The method of claim 1, wherein the second exhaust means An intake and exhaust valve is formed in the intake and exhaust hole penetrating the center portion is provided with a stepped lower end, and the support member is fastened to the lower end of the fastening member, the valve seat is protruded to the inside of the support member.