KR101821764B1 - CIRCULATING FLOW EQUALIZED DEVICE for bubble collecting - Google Patents

Abstract

The circulating water flow equalizing apparatus for air collection according to the present invention comprises a circulating water flow equalizing apparatus for air collection for homogenizing the flow of water flowing into a tunnel observing section, An inlet expansion portion extending from the inlet so as to gradually increase in diameter as compared with the diameter of the inlet, and a flow control portion that has a diameter the same as the largest diameter of the inlet expansion portion, And a discharge shaft portion extending from the body portion and having a diameter gradually smaller than the diameter of the body portion and connected to the tunnel observation portion, wherein circulating water is reduced through the inflow and outflow tube portion , The same flow rate is attained according to the depth in the body portion. Therefore, turbulent flow of water flowing into the tunnel observation portion Minimized, thereby providing a circulating water flow uniforming device for an air trap with an effect of stabilizing the flow of the circulating water flowing in the tunnel section observation.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a circulating water flow equalizing apparatus for air collection,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circulating water flow equalizing apparatus for air collection, and more particularly, to a circulating water flow equalizing apparatus for air collection to uniformize the flow of water flowing into a tunnel observing unit where cavitation occurs.

SUPER CAVITATION refers to a phenomenon in which the frictional resistance in water becomes similar to the frictional resistance in air when an underwater sieve is covered with air bubbles.

As a method for generating transvaginary cavitation, there are a method of designing a tip of an underwater body in a specific shape, a method of causing bubbles to be generated at the tip of an underwater body by a specific shape when an underwater body moves at a critical velocity or more, Thereby generating air bubbles.

Therefore, it is very important to know the cavitation characteristics in the submersible design to reduce the drag of the water body.

In general, the cavitation test is carried out by a device called a circulating cavitation tunnel which artificially forms a situation in which a water body is propelled at a constant speed by circulating water at a constant flow rate while the water body is mounted in a closed circulating tunnel .

Since the water circulating in the tunnel is not discharged to the outside, the longer the test time, the more cavitation is generated and the amount of bubbles contained in the water is increased by the test apparatus.

That is, as the test time becomes longer, the test error becomes larger and it becomes difficult to obtain accurate cavitation test results.

On the other hand, if the tunnel is filled with water to perform a cavitation model experiment, air will be present in a space partially unfilled by the shape of the tunnel.

When model cavitation tests are performed without water being pumped into these spaces, a great amount of bubbles are created in the flow circulating through the circulation tunnels.

In this case, there is a high possibility that cavitation is difficult to observe due to bubbles, and the amount of cavitation generated by the propeller shape can be increased.

In addition, the flow field of water circulating in the tunnel is unstable, and the uniformity of the flow field is lowered, and the reproducibility and the consistency of the cavitation generation can be lowered.

However, in order to minimize errors in designing and manufacturing the tunnel, the difficulty in designing and manufacturing is unnecessarily increased, and it is also difficult to separately fill the space in which the water that can be filled in the tunnel is not filled.

Korean Registered Patent No. 10-1508982 (March 31, 2015) Korean Registered Patent No. 10-1283320 (Feb.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention, which has been made in view of the above, to provide an ultra-cavitation circulating water flow equalizing apparatus that stabilizes a flow field of water flowing toward an aquatic body during a transcave cavitation test.

It is another object of the present invention to provide a circulating water flow equalizing apparatus for air collection capable of obtaining more accurate transvagation cavitation test results by removing bubbles contained in circulating water .

In order to achieve the above object, the circulating water flow equalizing apparatus of the present invention for air capturing is characterized in that it is provided at the front end of a tunnel observing section for observing superabsorbent cavitation of an underwater sieve, An apparatus for circulating water flow uniformity for collecting, comprising: an inlet expanding portion formed from an inlet through which water discharged from a tunnel observing portion is circulated and which is extended from an inlet so as to gradually have a diameter larger than a diameter of the inlet; And a discharge shaft portion extending from the body portion and having a diameter gradually smaller than a diameter of the body portion and connected to the tunnel observing portion, the body portion having a diameter equal to the largest diameter of the tube portion and extending from the inflow and outflow tube portion.

Further, it may further include a perforated plate built in the inflow and outflow tube portion so as to be perpendicular to the longitudinal central axis of the inflow and outflow tube portion.

In addition, a plurality of perforated plates may be incorporated in the inflow-outflow tube, and the diameter and density of the perforated plate formed in the plurality of perforated plates may be different from each other.

The body portion includes a protruding portion protruding from an outer side portion forming an outer shape of the body portion and collecting bubbles contained in the water and a honeycomb portion positioned at a contact point between the body portion and the discharge shaft portion and making the flow of water uniform .

Further, the projecting portion can form a conical or polygonal space on the inner side of the outer side surface portion.

Further, the body portion may include a suction pipe penetrating the protruding portion to discharge the air trapped inside the protruding portion, or to selectively communicate the inside and the outside of the protruding portion.

Further, it may further include a circulation pipe bent many times so as to connect the tunnel observation portion and the inlet, and to guide the water discharged from the tunnel observation portion to the inlet.

The apparatus may further include a diffusion unit mounted between the tunnel observation unit and the circulation pipe and configured to decelerate the flow rate of water discharged from the tunnel observation unit.

The circulation pipe may include a pump for pressurizing the water existing in the circulation pipe and a guide vane formed in the bent portion of the circulation pipe and having a damping member therein.

In addition, the inlet and the longitudinal center axis of the tunnel observing portion are coaxial, and the diameter of the inlet may be larger than the diameter of the tunnel observing portion.

According to the circulating water flow equalizing apparatus of the present invention as described above, the circulating water is reduced through the inflow and outflow tube portion, and the same flow rate is formed according to the depth in the body portion. Therefore, turbulent flow of water, So that the flow of the circulating water flowing into the tunnel observation portion is stabilized.

In addition, since water in a state in which air bubbles are removed flows into the tunnel observation portion, bubbles due to transient cavitation generation can be measured more accurately than external factors.

In addition, since the guide vane is formed in the bent portion of the circulation pipe, the noise and vibration generated as the water rubs against the bent portion are minimized.

1 is an outline view of a transcontinental cavitation tunnel system equipped with an overflow cavitation circulation water flow equalizing apparatus according to an embodiment of the present invention,
Fig. 2 is a cross-sectional view of the transcontinental cavitation circulating water flow equalizing apparatus of Fig. 1;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals whenever possible. In the following description of the present invention, a detailed description of related arts will be omitted so as not to obscure the gist of the present invention.

FIG. 1 is a schematic view of a transcontinental cavitation tunnel system equipped with a circulating water flow equalizing apparatus for air collection according to an embodiment of the present invention, and FIG. 2 is a sectional view of a circulating water flow equalizing apparatus for air collection of FIG.

The circulating water flow equalizing apparatus 100 for air collection according to the present invention is included in the transient cavitation tunnel system CS to observe transient cavitation of an underwater sieve and is located at the front end of the tunnel observation portion TO, Thereby making the flow of the water flowing into the portion (TO) uniform.

As shown in Fig. 1, the transcontinental cavitation tunnel system CS includes a tunnel observation portion TO for observing transient cavitation of an underwater sieve, and a tunnel observation portion TO for slowing down the flow rate of water discharged from the tunnel observation portion TO And a circulation pipe (RP) connecting the diffusion part (E) and the transient cavitation circulating flow equalizing device (100) of the embodiment of the present invention.

The circulation pipe RP includes a first column portion L1, a lower end portion B and a second column portion L2.

The first column portion L1 extends perpendicularly from the one end of the diffusion portion E to the ground.

The lower end portion B extends from one end of the first post L1 to be parallel to the transcontinental cavitation circulating flow equalizing device 100 of the embodiment of the present invention, the tunnel observation portion TO and the diffusion portion E.

The second post L2 extends vertically from one end of the lower end B to the ground and is connected to the transcontinental cavitation circulating flow equalizing device 100 of one embodiment of the present invention.

The circulation pipe RP includes a pump PP for pressurizing the water present in the circulation pipe RP and a circulation pipe RP for minimizing the vibration caused by water in the bent portion C of the circulation pipe RP The guide vanes GV formed in the bent portions C of the protrusions RP. A damming material is inserted into the guide vane (GV).

1 and 2, a circulating water flow equalizing apparatus 100 for air collection according to an embodiment of the present invention includes an inflow and outflow tube 110, a perforated plate 120, a body 130, And includes an axial tube portion 140.

The inlet tube portion 110 is formed with an inlet 111 through which the water discharged from the tunnel observation portion TO is circulated and formed so as to have a diameter gradually larger than the diameter of the inlet 111, .

The perforated plate 120 is embedded in the inflow and outflow tube portion 110 so as to be perpendicular to the longitudinal center axis of the inflow and outflow tube portion 110. In one embodiment of the present invention, a total of three perforated plates 120 are embedded in the inflow and outflow tube 110.

At this time, the thickness of the perforated plate 120, the diameter and density of the perforations H formed in the perforated plate 120 are determined by the predicted speed of the circulating water flowing into the inflow and outflow tube portion 110, And the target speed of the circulating water to be introduced into the unit (TO).

The body portion 130 has a diameter equal to the largest diameter of the inlet tube portion 110 and extends from the inlet tube portion 110.

The body 110 includes a protrusion 131 protruding from an outer side portion forming an outer shape of the body 110 and collecting air bubbles contained in the water, And includes a honeycomb unit 132 that uniformizes the flow of water.

The body portion 110 includes a suction pipe 133 penetrating the outer side portion so as to discharge the air collected in the protrusion 131 to the outside or selectively communicate with the inside and the outside of the protrusion 131 .

The protrusion 131 protrudes outward from the inner surface of the body part 130 in the form of a cone or a polygonal pyramid, thereby forming a space in which bubbles contained in water are collected.

In one embodiment of the present invention, a total of two protrusions 131 protrude from the top surface of the body part 130 in the form of a quadrangular pyramid. A pressure sensor (not shown) for sensing the pressure change inside the protrusion 131 and sending a signal to the control unit, and a pressure sensor (not shown) for discharging the air inside the protrusion 131 to the outside A vacuum pump (not shown) is provided at one side of the projection 131. That is, the vacuum pump provided in the suction pipe 133 is actuated to actively discharge the air inside the protrusion 131 to the outside.

Alternatively, it is also possible to open the protruding portion 131 to the atmosphere through the suction pipe 133 and expose the protruding portion 131 to the atmosphere.

In this case, the air collected by the protruding portion 131 is scattered to the atmosphere by the atmospheric change. That is, it is also possible to passively collect the air collected in the projecting portion 131 to the outside.

The discharge shaft portion 140 extends from the body portion 130 and is connected to the tunnel observation portion TO with a gradually smaller diameter than the diameter of the body portion 130. [

In one embodiment of the present invention, the longitudinal center axes of the inlet tube portion 110, the body portion 130, the drainage tube portion 140, and the tunnel viewing portion TO are coaxial.

Further, the inflow-outflow tube portion 110 is manufactured so that the diameter of the inlet 111 is larger than the diameter of the tunnel-side portion TO.

The operation of the circulating water flow equalizing apparatus 100 for air collection according to an embodiment of the present invention will be described as follows.

As the pump PP is operated, the circulating water built in the transient cavitation tunnel system CS flows into the inflow and outflow tube unit 110. At this time, as the inner diameter of the inflow-outflow tube portion 110 gradually increases, the flow rate of the circulating water flowing into the inflow-outflow tube portion 110 is slowed down.

Further, the flow velocity is lowered by the perforated plate 120, and as the fluid passes through the perforation H, the flow velocity and the flow direction of the circulating water at the same depth become the same.

The flow of the circulating water flowing into the body portion 130 continues and the bubble moves to the upper portion of the circulating water.

That is, the bubbles contained in the circulating water are transferred to the projecting portion 131. Thereafter, the bubbles are discharged to the outside through the suction pipe (133) provided in the protrusion (131).

The flow direction of the circulating water at the same depth is more uniformly guided through the honeycomb unit 132 provided in the body portion 130. [

The circulating water flow rate at the same depth is constantly increased while passing through the constantly narrowing outlet shaft portion 140 and is ultimately guided to have the same flow rate and the same flow direction at the same depth.

Accordingly, turbulent flow of water flowing into the tunnel observation portion TO through the discharge shaft portion 140 is minimized. Bubbles contained in the circulating water are also removed.

As described above, the circulating water flow equalizing apparatus for collecting air according to the present invention has been described with reference to the drawings. However, the present invention is not limited to the embodiments and the drawings disclosed herein, It will be understood by those skilled in the art that various changes may be made therein without departing from the spirit and scope of the invention.

100: Circulating water flow equalizing device for air collection
110: inlet expansion tube 111: inlet
120: perforated plate 130:
131: protruding portion 132: honeycomb portion
133: Suction pipe 140:
CS: Transcendent cavitation tunnel system TO: Tunnel observation part
E: Diffusion part RP: Circulation pipe
PP: Pump GV: Guide vane
L1: first column L2: second column
B: Lower end

Claims (10)

1. A circulating water flow equalization apparatus for air collection, which is located at a front end of a tunnel observing unit for observing transient cavitation of an underwater sieve, and which uniformizes the flow of water flowing into the tunnel observing unit,
An inlet extension part extending from the inlet so as to have an inlet through which water discharged from the tunnel observation part is circulated and has a gradually larger diameter than a diameter of the inlet;
A body portion having a diameter equal to the largest diameter of the inflow and outflow tube portion and extending from the inflow and outflow tube portion; And
And a discharge shaft portion extending from the body portion and having a diameter gradually smaller than a diameter of the body portion and connected to the tunnel observing portion,
And a plurality of perforated plates embedded in the inflow-outflow tube portion so as to be perpendicular to a longitudinal center axis of the inflow-out tube portion,
The pores formed in the plurality of perforated plates have different diameters and densities,
The body portion
A projection protruding from an outer side surface forming an outer shape of the body part, the protrusion being configured to collect air bubbles contained in water; And
And a honeycomb portion located at a contact point between the body portion and the discharge shaft portion and making the flow of water uniform,
The projection
Wherein a space of a cone or polygonal pyramid is formed inside the outer side surface portion,
The body portion
And a suction pipe penetratingly mounted on the protrusion so as to discharge the air trapped inside the protrusion or selectively communicate with the inside and outside of the protrusion,
A control unit for controlling the operation of the suction pipe;
A pressure sensor for sensing a pressure change inside the protrusion and sending a signal to the control unit; And
And a vacuum pump provided at one side of the protrusion for discharging the air inside the protrusion to the outside.
delete delete delete delete delete The method according to claim 1,
Further comprising a circulation pipe that connects the tunnel observing unit and the inlet and is bent many times so as to guide the water discharged from the tunnel observing unit to the inlet.
8. The method of claim 7,
And a diffusion unit mounted between the tunnel observing unit and the circulation pipe and configured to decelerate the flow rate of water discharged from the tunnel observing unit.
8. The method of claim 7,
The circulation pipe
A pump for pressurizing water present in the circulation pipe; And
And a guide vane formed in a bent portion of the circulation pipe and having a damping member embedded therein.
The method according to claim 1,
Wherein the inlet and the longitudinal center axis of the tunnel observing portion are coaxial,
Wherein the diameter of the inlet is larger than the diameter of the tunnel observation portion.

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