KR101910585B1 - Automatic air discharge device - Google Patents

Abstract

The present invention provides an automatic air discharge device, in which bubbles or foams are automatically broken inside so that very small amount of water particles are prevented from being leaked through an air discharge hole, and the automatic air discharge is smoothly performed even when a float having a specific gravity higher than water is adopted. The automatic air discharge device includes: a housing having a conical elevation chamber having a tapered inner circumferential surface having an inner diameter narrowed upward, a valve moving groove formed in an upper portion of the conical elevation chamber, an air discharge hole formed in an upper portion of the valve moving groove, an intake chamber communicating with a lower portion of the conical elevation chamber, and an inlet hole communicating with the intake chamber; and a conical float having a plurality of tapered ribs protruding from an outer circumferential surface in the longitudinal direction at the same inclination angle as the taper inner circumferential surface, a plurality of bubble rising pathways provided between the tapered ribs, a valve protrusion wheel portion provided at an upper center thereof to open/close the air discharge hole, and having a diameter relatively smaller than that of the valve moving groove, and an air buoyancy chamber provided inside to be opened in the downward direction opposite to the valve protrusion wheel portion.

Description

[0001] Automatic air discharge device [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for automatically discharging air contained in water flowing into a piping, and more particularly, to an improved automatic air discharge apparatus that prevents very little water from being discharged at all.

Prior art automatic air ejection devices as described in the prior art documents are disclosed.

However, in the above-described prior art, the float can be moved up and down only by using a float having a specific gravity lower than that of water, so that the automatic air discharging operation is performed. Therefore, when a float having a specific gravity higher than that of water is employed, There is a problem that the float can not be moved up and down.

Therefore, a float made of a material having a specific gravity lower than that of water has conventionally been used, and when a bubble bursts from the inside of the automatic air discharge device to the air discharge hole at the uppermost position, There is a problem that the fine water particles are discharged to the outside through the air discharge hole, resulting in a problem that the product reliability is deteriorated.

KR 10-1717991 B1 2017.03.20

It is an object of the present invention to provide an improved automatic air discharge device in which air bubbles or bubbles are automatically broken inside, so that no very small amount of water particles are leaked to the air discharge hole.

It is another object of the present invention to provide an automatic air discharge apparatus capable of satisfactorily performing an air discharge action even if a float having a specific gravity higher than that of water is adopted and cost reduction can be achieved.

The present invention relates to a conical elevating and lowering chamber having a tapered inner circumferential surface having an inner diameter narrowed toward an upper portion thereof, an air discharging hole provided in an upper portion of the valve moving groove and an upper portion of the valve moving groove, A housing having a receiving chamber communicating with a lower portion of the chamber and a receiving hole communicating with the receiving chamber; a plurality of tapers formed in a longitudinal direction on the outer circumferential surface at the same inclination angle as the tapered inner circumferential surface, A plurality of bubble rising paths provided between the plurality of tapered ribs; a valve stem ring portion provided at the upper center and having a diameter smaller than that of the valve moving hole to open and close the air discharge hole; A cone-shaped flume having an air buoyancy chamber provided therein so as to open in a downward direction It should be made that comprises a bit in its features.

And a bubble destroying groove portion having a plurality of toothed protrusions on the bubble destruction groove portion or the inner circumferential surface outside the valve movement groove of the housing and an air U-turn protrusion portion provided between the bubble destruction groove portion and the valve movement groove, .

The air float chamber of the float has an air concentrating groove portion formed in the shape of "∧" so that the central portion is higher, and an air waiting chamber is provided between the plurality of tapered ribs and the valve stone wheel portion at the center, And the upper end of the valve stem is configured to have a relatively higher upper end than the upper end of the valve stem.

The present invention has the effect that the air bubbles or bubbles are automatically broken in the inside, so that no very small amount of water particles are leaked to the air discharge hole, and the product reliability is greatly improved.

In addition, the present invention has an effect that a float is well operated even if a float having a specific gravity higher than that of water is adopted, and a float having a specific gravity higher than that of a material having a relatively lower material cost than a material having a specific gravity lower than that of water It is possible to reduce the manufacturing cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall sectional view of an automatic air venting apparatus embodying the present invention;
2 is a perspective view showing a float according to the present invention,
3 is an overall longitudinal sectional view of an automatic air discharge apparatus according to the present invention,
FIG. 4 is a planar view of a cross-sectional state taken along line Y-Y 'of FIG. 3,
5 is a schematic view for explaining a state in which the float of the present invention is moved up and down;
6 is an overall cross-sectional view illustrating the operation of the present invention,
7 is a longitudinal sectional view showing a state in which the float of the present invention is moved downward;
8 is a ladder action explanatory diagram explaining the action of air bubbles and air bubbles in the present invention,
9 is a structural view showing another embodiment of the bubble breaking groove according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail with reference to the accompanying drawings.

1 to 4, the present invention mainly includes a housing 10 and a float 20 that moves up and down in the housing 10.

The housing 10 is preferably composed of an upper housing 10a and a lower housing 10b in order to house the float 20 therein and has a screw hole 101 and a screw portion 101 ' And it is preferable that the packing 11 is put on the part to be fastened by the upper and lower housings 10a and 10b so as to be fastened.

 5, the housing 10 having the upper and lower housings 10a and 10b fastened to each other has a tapered inner circumferential surface 131 having an inner diameter narrowed toward the upper portion from the inside thereof, 13).

Further, the valve-moving groove 15 is provided at the center of the conical lifting and lowering chamber 13, and the air discharge hole 16 communicates with the upper portion of the valve-moving groove 15.

And an air U-turn projection 17 is provided between the bubble breaking groove 14 and the valve movement groove 15.

As shown in Fig. 9, a plurality of fine toothed protrusions 14a may protrude from the inner circumferential surface of the bubble-breaking trench 14.

The inlet pipe 12 communicates with the inlet chamber 12 and is connected to the pipe P so as to be fastened to the pipe P. The inlet pipe 12 is provided at a lower portion of the conical lifting and lowering chamber 13, (19).

5, the float 20 is formed in the longitudinal direction at the same tilt angle as the tapered inner peripheral surface 131 of the conical elevating and lowering chamber 13 of the housing 10, And a plurality of tapered ribs 21 protruding from the outer circumferential surface at regular intervals in the main surface direction. Thus, a plurality of bubble rising paths 22 are provided between the plurality of tapered ribs 21.

A valve stone ring portion 23 having a diameter smaller than that of the valve movement groove 15 is protruded at the center of the upper portion of the float 20 so that the air discharge hole 16 can be opened and closed.

It is preferable that a silicon packing 23a is provided at the upper end of the valve bore portion 23 in order to improve the close contact with the air discharge hole 16, It is preferable to provide the circular protrusion 16a for allowing the silicon packing 23a to closely contact with each other.

It is preferable to provide the air waiting chamber 24 between the plurality of tapered ribs 21 of the float 20 and the central valve stem ring portion 23. In this case, (23) so that the upper end portion is configured to have a relatively higher upper end portion. However, as shown in Fig. 5, only the valve bogie ring portion 23 may protrude from the upper end of the float 20. [

The float 20 is constructed to have an air buoyancy chamber 25 provided so as to open in a downward direction opposite to the valve bore portion 23 and the upper portion of the air buoyancy chamber 25 has a central portion And the air concentration groove portion 25a is formed so as to be higher.

Therefore, the action of the valve stator wheel portion 23 of the float 20 of the present invention in close contact with the air discharge hole 16 in the upper portion of the conical elevating and lowering chamber 13 will be described as follows.

5, since the conical lifting and lowering chamber 13 and the float 20 are formed in a conical shape, the float 20 is moved downward as shown in a phantom line in FIG. 5, The tapered rib 21 is guided by the inner circumferential surface 131 and moved upward so that the float 20 is automatically centered and moved upwardly as the float 20 is tilted to one side .

Therefore, when the float 20 is moved to the uppermost position, the tapered inner circumferential surface 131 of the conical elevating and lowering chamber 13 and the tapered rib 21 are perfectly matched as shown by the solid line in FIG. 5, 23 block the air discharge hole 16.

4, when the float 20 is moved as shown in FIG. 4, the end of the tapered rib 21 is rounded to have a curved surface, so that the tapered rib 21 contacting the tapered inner peripheral surface 131 is linearly moved and moved The float 20 moves smoothly.

The float 20 can move in the lateral direction when the float 20 in the conical lifting and lowering chamber 13 is moved down so that the vertical center line (not shown) of the float 20 The float 20 is moved upward so that the tapered inner circumferential surface 131 of the conical elevated and lowered steel chamber 13 and the tapered inner circumferential surface of the tapered inner circumferential surface 13 When the ribs 21 are completely matched with each other, since the vertical center line (not shown) of the float 20 and the vertical center line (not shown) of the air discharge hole 16 are exactly aligned, So that the air discharge hole 16 is brought into close contact with the air outlet 16 and automatically closed.

6 and 7, when the float 20 of the present invention is made up of a material having a specific gravity higher than that of water, the movement of the float 20 upward to close the air discharge hole 16 will be described As follows.

6, the fastening nipple part 18 of the housing 10 is fastened and fixed to the pipe P, and water and air bubbles flowing in the pipe P are introduced into the intake hole 19 To the input / output chamber 12 through the input /

At this time, when the housing 10 is first installed in the pipe P, the air bubble b flowing into the inflow chamber 12 is not moved upward to the bubble rising path 22, Bubbles b are gathered in the air buoyancy chamber 25 so that the air is completely filled in the air buoyancy chamber 25. As a result,

Accordingly, the present invention is in a state in which the air is completely filled in the air buoyancy chamber 25, so that buoyancy is generated, so that the float force floating on the water W in the water inlet chamber 12 Even if the float 20 is formed of a material having a specific gravity higher than that of water, the float 20 is lifted by the floating force due to the buoyancy generated by the air filled in the air buoyancy chamber 25, (23) blocks the air discharge hole (16).

At this time, since the air in the air buoyancy chamber 25 is automatically concentrated to the air concentration concentrating groove portion 25a of "∧" shape formed so that the central portion is higher at the upper portion, the buoyancy is concentrated inthe center portion of the upper side of the float 20 So that the float 20 can be moved linearly upward in the upward direction while being prevented from shaking in the lateral direction as much as possible.

Then, the air is filled in the air buoyancy chamber 25 so as to completely fill the air, so that the float 20 is moved upward by the buoyancy force so that the valve wheel ring 23 closes the air discharge hole 16 The bubbles b flowing into the inflow chamber 12 are prevented from flowing into the air-filled buoyancy chamber 25 where the air is completely filled, and thus the bubbles b are directly moved upwardly through the bubble rising path 22, ) To the air waiting chamber 24 on the upper side.

The air pressure in the air waiting chamber 24 is lower than the air pressure in the air buoyancy chamber 25 when the valve bore ring 23 is closed and the air bubbles gradually accumulate in the air waiting chamber 24, The float 20 is moved downward as shown in the solid line as shown in Fig. 7, so that the valve stem ring portion 23 is moved downward as shown by the solid line in Fig. 7, So that the air in the air waiting chamber 24 is exhausted to the air exhaust hole 16. As a result,

As the air in the air waiting chamber 24 is discharged to the air discharge hole 16, the air pressure in the air waiting chamber 24 becomes relatively weaker than the buoyancy of the air buoyancy chamber 25 and gradually weakens.

Therefore, when the air pressure in the air waiting chamber 24 is lower than the buoyancy in the air buoyancy chamber 25, the float 20 is moved upward again by the buoyancy of the air buoyancy chamber 25 as shown in FIG. 6, The float 20 moves up and down in the vertical direction due to the difference between the air pressure of the air waiting chamber 24 and the buoyancy force of the air buoyancy chamber 25, The operation of opening and closing the air discharge hole 16 is repeatedly performed, so that the air discharge to the air discharge hole 16 is automatically performed from time to time.

In the meantime, the air bubbles or bubbles are substantially blown up during the upward movement along the bubble rising path 22, so that only the air is moved upward.

However, there is a case where the bubbles are moved upward in a bubble state without bursting while passing through the bubble rising path (22). In this case, as shown in Fig. 8, the unfurled bubble b is first raised and inserted into the bubble breaking groove 14.

The air bubbles b inserted into the bubble destroying trench 14 are filled with air so that the air bubbles b which have entered into the bubble breaking trench 14 can never be moved downward again.

The bubbles b which enter the bubble breaking groove portion 14 are instantly blown off while being in contact with the inner peripheral surface of the bubble breaking groove portion 14 or are automatically broken into contact with other bubbles b .

At this time, the air bubbles bounce and water particles are splashed, but the water particles are clogged by the air-U-turn projections 17 and fall downward, and only the air moves around the air U-turn projections 17 to move into the valve movement grooves 15 The air is discharged to the air discharge hole 16 so that the water particles do not leak to the air discharge hole 16 even if the air bubble b is blown. There is no leakage of water, but only air.

In the present invention, as shown in Fig. 9, when a large number of fine toothed protrusions 14a are projected on the inner circumferential surface of the bubble destroying groove portion 14, the bubble b is struck by the sharp toothed protrusion 14a, So that the bubble (b) bursts more reliably and more rapidly.

Accordingly, the present invention is not limited to the embodiments shown in the drawings, but may be modified in various ways by those skilled in the art. Accordingly, the present invention is not limited thereto. It is self-evident to be.

10: housing 10a: upper housing
10b: lower housing 11: packing
12: Receiving room 13: Conical elevating room
131: tapered inner circumferential surface 14: bubble breaking groove portion
14a: serration 15: valve movement groove
16: Air discharge hole 16a: Circular protrusion
17: air U-turn projection 18: fastening nipple
19: Acquired ball 20: Float
21: tapered rib 22: bubble rising path
23: valve wheel portion 23a: silicone packing
24: Air waiting chamber 25: Air buoyancy chamber
25a: air concentrating groove portion b: bubble
W: Water
P: Piping

Claims (3)

delete A conical elevating and lowering chamber 13 having a tapered inner circumferential surface 131 having an inner diameter narrowed toward an upper portion thereof and a valve moving groove 15 and a valve moving groove 15 provided in the upper portion of the conical elevating and lowering chamber 13, A housing 10 having an air discharge hole 16 provided at an upper portion thereof and an inlet chamber 12 communicating with the lower portion of the conical lifting and lowering chamber 13 and an intake hole 19 communicating with the inlet chamber 12, )and;
A plurality of tapered ribs 21 formed in a longitudinal direction on the outer circumferential surface at the same inclination angle as the tapered inner circumferential surface 131 and protruding at equal intervals in the circumferential direction, A valve bore ring portion 23 provided at an upper center of the bore upward portion 22 and having a diameter smaller than that of the valve movement groove 15 to open and close the air discharge hole 16, And a float (20) in the form of a cone having an air buoyancy chamber (25) provided therein so as to open in a downward direction opposite to the direction of the float (23);
And a bubble breaking groove portion 14 having a plurality of teeth protrusions 14a on the inner peripheral surface on the outer side of the valve movement groove 15 of the housing 10, And an air U-turn protrusion (17) is provided on the air vent.

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