KR950007457Y1 - Air discharge device - Google Patents

Abstract

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Description

Separator and Automatic Air Discharge Device

1 is an exploded perspective view of the separator and air automatic discharge device of the present invention.

2 is a longitudinal sectional view of the main part of the separator and air automatic discharge device of the present invention.

3 is a side view of the present separator and automatic air discharge device.

* Explanation of symbols for main parts of the drawings

1: upper body 2: lower body

3: float 4: float tank

5: lid body 6: lever

7: rubber packing 9: cap

10 connector 11 water inlet

21: water discharge outlet 22: induction separator

32: lever engaging jaw 34: T-shaped through hole

35 balance bar 51 exhaust port

100: separator separator 200: air vent

The present invention relates to a separator and air automatic discharge device installed in the heating coil of the gas boiler, and in particular, the separator separated with the induction pipe is formed integrally with a predetermined air vent induction separator pipe of the separator The present invention relates to a radiator and an automatic air discharge device for allowing air in the heating water separated by centrifugal force to be discharged directly through the upper air vent in a short time.

The automatic exhaust device (aka air vent) of the gas boiler heating water pipe, which has been previously disclosed and disclosed (public number: 92-1071), is configured to be directly coupled to the heating water pipe through a separate housing provided with a valve. As the bubbles contained in the water flowing along the heating water pipe are naturally separated and collected in the float tank to lower the float, the float opens a blocking pin that blocks the exhaust passage by operating a lever. It is discharged to the outside, such a configuration is provided with a separate housing provided with a valve is coupled to the heating water pipe, so the installation work is very complicated, there is a problem that the production cost of the product rises.

In addition, Japanese Utility Model Publication No. 49-32284, previously published and released as an air separator (aka water separator) of a hot water circulation system, has an air discharge hole and an inlet side and an inner wall of a case coupled to a hot water pipe. And forming a separation wall at a right angle and an inclination direction with respect to the inflow direction of the hot water so that bubbles contained in the water flowing through the hot water pipe with a predetermined water pressure collide with the separation wall to separate and destroy. It was configured to be.

That is, the water separator and air vent installed in the hot water circulation system including the conventional gas boiler are formed of separate items and are connected to each other through a separate air discharge pipe in the device or the tubular body, and thus the water separator And the installation of the air vent in the boiler, etc. is very complicated, and the separation of air (that is, air bubbles) contained in the water is made naturally or through the separation wall, so that the exhaust time of the air takes a lot of heat efficiency of the heat exchanger This is lowered, there is a problem that the production cost of the product is increased as each component is configured separately.

The present invention is devised to solve such a conventional problem, the water separator is formed by integrally forming a conventional air vent on top of the separator to separate the bubbles contained in the water by circulating the heating circulation water by centrifugal force Since the air in the heating water separated through the induction separator of the discharge can be directly discharged out through the air vent on the top of the separator, the separated air is discharged out in a short time to improve the thermal efficiency of the heat exchanger, As each part is formed integrally, installation and disassembly work is very simple, and the production cost of the product can be greatly reduced.

Referring to the present invention based on the accompanying drawings as follows.

The separator and air automatic discharge device of the present invention, as shown in Figures 1 to 3, the lever flow groove 31, the lever locking jaw 32, the guide groove 33, T-shaped through hole 34 And a float (3) integrally provided with a balance holding rod (35) so as to flow freely in the float tank (3) having internal space areas of a predetermined size so as to flow therethrough, and coupling with a tubular body and inducing air at the bottom thereof. The upper portion of the float tank (4) formed integrally with the connecting pipe (10) for screwing the lid body 5 is formed with the exhaust port 51 protruding on the main surface, a predetermined spring (8) to the exhaust port 51 And the lever 6 having the blocking plate 61 fixed at one end thereof and the rubber packing 7 having the hole 71 drilled in the center thereof in sequence, thereby screwing the cap 9 drilled with the exhaust hole 91. In the air vent 200 of the combined configuration, the water inlet 11 is formed in the upper periphery (1) formed on the side peripheral portion, the water discharge port 21 is the bottom peripheral edge The separator 2 is formed by mutually coupling the lower body 2 having the induction separation pipe 22 formed therein and having an inflow gap 221 protruding therebetween to form a separator 100, but the upper body of the separator 100 1) It is characterized in that the upper surface is formed so as to penetrate through the float tank (4) through the connection pipe (10).

Here, reference numeral 52 is an oil ring, 53 is a locking jaw, 611 is a projection.

The effect of the present invention configured as described above is as follows.

First, the water suction port 11 and the mole discharge outlet 21 of the separator 100 are formed in the upper and lower portions in the direction orthogonal to each other, because they are each formed in the maximum close to the circumferential surface through the water suction port 11 The introduced heating water is rotated as shown by the arrow on the walls of the upper and lower bodies (1, 2), and a part thereof is moved to the water discharge port 21 to which the pump is connected, and the residual water remaining in the internal space of the separator 100 is left. The fluid remains in the rider 100 and continues to rotate at an arbitrary angular velocity ω by the flow velocity of the fluid which is continuously supplied.

Therefore, since the fluid in the separator 100, that is, the heating water, rotates in a state having a constant flow line and centrifugal force, the laminar flow of the fluid is caused by friction with the floor in the portion close to the space bottom of the separator 100. And a gradient of constant pressure is formed.

Due to the pressure gradient, the flow velocity of the fluid located at the lower end becomes smaller than the flow rate of the upper portion thereof, so that the radius of curvature naturally decreases.

Therefore, since the heating water located at the upper portion of the lower layer rotates without friction, the secondary flow is formed in the lower layer by the primary flow and the pressure gradient of the upper layer which is concentrically moved by the centrifugal force in the separator 100.

In addition, according to the flow as described above, the fluid is made a spiral movement toward the center of the separator having a predetermined centrifugal force so that the air bubbles introduced into the heating water are collected in the center of the separator 100. That is, due to the circumferential area of the induction separation pipe 22 protruding from the lower body 2 of the separator 100, a predetermined rotational frictional force is formed in the heating water in contact therewith, thereby facilitating secondary flow. The pores are quickly collected to the center side is conveyed to the air vent 200 formed integrally with the upper body 1 through the connecting pipe (10).

At this time, the inlet separation pipe 22 having a volume of about 30-50% of the volume of the separator 100 is formed in the longitudinal inlet gap 221 is formed around the periphery of the induction separator 22 When the heating water having a flow rate reduced by the rotating frictional force passes near the inflow gap 221 to the sieve including the bubbles, the air bubbles flow into the induction separation pipe 22 through the inflow gap 221 and are collected and the upper body 1 and It is conveyed to the air vent 200 through the air induction pipe (10).

On the other hand, the float 3 installed in the float tank 4 of the air vent 200 is normal, that is, when the air is not introduced from the separator 100, the heating water flows to the float tank 4, so that the buoyancy By floating upward, the lever 6 fitted into the upper lever flow groove 31 of the float 3 is kept in parallel with the lid 5.

Therefore, the protrusion 611 of the blocking plate 61 provided at one end of the lever 6 blocks the hole 71 of the rubber packing 7 to block the release of air or water.

However, the air contained in the heating water is separated from the water separator 100, and predetermined air is different in the float tank 4 formed thereon through the connection pipe 10 constituting the air vent 200. If this occurs, the water level in the float tank 4 is lowered.

At this time, the air separated in the separator 100 and flows into the float tank 4 through the connection pipe 100 of the air vent 200 is a T-shaped through-hole which is drilled to the balance bar 35 of the float 3 It is introduced to the upper through 34.

Accordingly, since the float 3 installed in the float tank 4 so as to flow up and down moves downward along the water level, the lever 6 having the free end at the lever latching jaw 32 of the float 3. ) Rotates downwardly around the exhaust port 51 of the lid 5 by a predetermined angle, so that the projection 611 of the blocking plate 61 comes out of the hole 71 of the rubber packing 7. Air introduced into the float tank 4 is automatically discharged through the exhaust hole 91 of the cap 9.

At this time, the float 3 is not lowered to the separator 100 by the connecting portion of the connecting pipe 10 formed smaller than the diameter of the float tank (3).

That is, since the air in the heating water separated from the water separator 100 is discharged directly through the air vent 200 formed integrally with the water separator 100 without passing through a separate air discharge pipe, the air separated from the air is fast. It can be discharged out in time to prevent the heat efficiency of the heat exchanger from dropping in advance.

As described above, according to the device of the present invention, the water separator circulates the heating circulating water by centrifugal force to form an integrally formed water separator and a predetermined air vent known in the art. Since the air in the heating water separated through the induction separator pipe is discharged directly through the Ever Vant, which is integrally installed on the top of the separator, instead of through a separate air discharge pipe, the separated air can be discharged out in a short time. It is possible to improve the thermal efficiency of each part, and as each part is formed integrally, the installation and disassembly work on the gas boiler becomes very simple, which greatly reduces the production cost of the product and improves the reliability of the product. It can be improved further.

Claims (1)

Float 3 which is provided with lever flow groove 31, lever latching jaw 32, guide groove 33, T-shaped through hole 34 and balance retaining rod 35 integrally has a predetermined inner space area. In the float tank (3) having the upper and lower parts to be flowable, the upper part of the float tank (4) formed with a coupling pipe (10) for coupling to the pipe and guide the air in the bottom portion of the exhaust port ( 51 is screwed into the lid body 5 protruding, a predetermined spring (8) to the exhaust port 51, the lever 6, the blocking plate 61 is fixed to one end and the hole 71 in the center In the air vent 200 having a configuration in which the perforated rubber packing 7 is sequentially inserted and the exhaust hole 91 is screwed to the perforated cap 9, the water suction port 11 is formed at the circumference of the side surface. The upper body 1 and the water discharge port 21 are formed at the bottom periphery, and the induction separation pipe 22 having the inflow gap 221 on the bottom surface thereof is integrally projected. Combining the lower body (2) formed to form a separator 100, the upper body (1) upper surface of the separator 100 is characterized in that it is formed so as to penetrate the float tank (4) through a connecting pipe (10) Separator and automatic air exhauster.