KR101437513B1 - bubble generating apparatus - Google Patents

Abstract

The present invention relates to a bubble generating apparatus which contacts an axial flow causing blade unit which causes a flow of water from the front end to the opposite end to be fixed on the outer side of the front end of a rotary axis, arranges a gas outlet adjacent to the upstream side of the blade unit, contacts a centrifugal force causing blade unit which provide a centrifugal force to water flowing with bubbles discharged from the gas outlet for the bubble to be forcibly moved in the outer direction of spinning with the outer side of a rotary axis adjacent to the axial flow causing blade unit to be fixed, arranges a bubble cutting unit which is a fixed body with slit protrusion parts and slit penetration holes alternately formed in a certain interval in the circumferential direction to surround the centrifugal force causing blade unit while separated from the centrifugal force causing unit in a certain distance in the outer direction of spinning, and contacts a cover plate with multiple blades fixed on the lower surface to disrupt water swirling in a water tank by the centrifugal force causing blade unit with a bearing interposed to the outer side of the other end of the rotary axis as a fixed body.

Description

A bubble generating apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bubble generator, and more particularly, to a bubble generator capable of self-excitation.

Bubbles are the pockets of gas in the liquid, that is, bubbles.

A small bubble having a bubble diameter of about 100 占 퐉 is called a micro bubble, Since the ratio of the surface area is large and the residence time in the liquid is long, various applications are expected by utilizing the transport of water in the gas-liquid interface, chemical reaction, physical properties, and chemical characteristics.

Generally, in a bubble generator for generating micro bubbles, a method of blowing gas into liquid through a porous body is used.

As such a bubble generator, gas is supplied through a porous body to a pipe through which water flows from a gas supply device such as a compressor, thereby generating fine bubbles.

In the recently developed bubble generator, a method of dividing the bubble by applying a shearing force to the bubble surface is often used.

The bubble generator includes a container body having a conical space, a pressurized liquid introduction port opened in a tangential direction on a part of the inner wall circumferential surface of the space, a gas introduction hole opened in the bottom of the conical space, There is a swirl bubble generator composed of a swirling gas-liquid outlet hole opened at the top of the space.

However, in the bubble generator using the porous body, since the bubble is not easily separated from the porous body, the generated bubble becomes larger than the pore diameter of the porous body, and a small bubble can not be generated.

In addition, as a method of rotating the porous body, large bubbles are generated from the vicinity of the center of the rotation axis in which the influence of rotation is small, so that the diameter of the bubbles generated under optimum conditions is limited to about 0.4 mm.

In this regard, in the swirl type bubble generator, since a shearing force is applied to the bubble surface, small bubbles can be generated. However, in order to forcibly apply the swirling flow to the fluid, since the gas is pressurized and supplied to the conical container body, the pressure loss increases and the ratio of the bubbles in the liquid becomes lower as compared with the case where the porous body is used It remained a problem.

In order to solve this problem, a discharge port of a gas supply pipe, which is driven to rotate by a pulley, is disposed in the axial axis of a motor disposed outside the water tank, and a gas inlet is connected to the discharge port, Korean Patent No. 10-1157719 proposes a method of generating minute bubbles by a shearing force generated by relative movement between water in a bubble generator and a rotating bubble in a bubble generator of the above- The water in the water tank adjacent to the gas inlet also flows in the rotating direction of the gas inlet so that the bubbles blown out from the gas inlet are not properly cut by the shear force and there is a limitation in making the size of the bubbles finer , And the bubbles ejected from the gas inlet are only injected into the gas inlet So that it can not be uniformly distributed throughout the water tank.

The present invention relates to an apparatus and a method for controlling the flow of water in a water tank in which a water tank is fixedly circumscribed at the tip of a rotary shaft to cause a flow of water to flow from a tip end of a rotary shaft to a base end, A centrifugal force induced blade for forcing the bubble to move in the radially outward direction by applying centrifugal force to the water flowing together with the bubble is fixedly circumscribed to the rotation axis adjacent to the axial flow induced blade, A centrifugal force inducing vane portion having a slit projection portion and a slit through hole formed therein and a bubble cutting portion fixedly disposed on the centrifugal force inducing vane portion so as to surround the centrifugal force inducing vane portion at a predetermined interval in a radially outward direction, To break the vortex in the water, In that via a bearing a plurality of blades are fixed cover plate can solve the above problems by an external congestion.

According to a preferred embodiment of the present invention, a water flow from a tip end to a base end of a rotary shaft is generated in the water tub by a wedge-driven wing portion as the rotary shaft rotates, and the bubble discharged to the water flow is blown by a centrifugal- The bubbles are divided into fine bubbles by the bubbles cut through the slit through-holes of the bubbles cut-out portion, and are uniformly distributed in the water tank. The water caused by the vortical flow of the water in the water tank caused by the centrifugal- It is possible to stabilize the water surface by breaking the water surface by a plurality of vanes of the cover plate, and to distribute the fine bubbles more easily and stably in the water tank than in the prior art.

1 is a conceptual diagram showing a bubble generator in an embodiment of the present invention,
Figure 2 is an exploded perspective view of the bubble generator of Figure 1, and
Figure 3 is an exploded perspective view of the bubble generator of Figure 1;

In the following description of the embodiment, the description will be made on the assumption that the pressure for supplying the gas is larger than the water pressure of the water tank.

Hereinafter, the bubble generator of the embodiment according to the present invention will be described in detail with reference to Figs.

In Fig. 1, the bubble generator of the embodiment is indicated at 100.

1 to 3, the bubble generator 100 includes a motor M mounted on a bracket la fixed to the water tub 1; A rotation shaft 2 having a base end coupled to a drive shaft of the motor M and a tip end extending into the water of the water tank 1; (3) fixedly circumscribed to the tip of the rotary shaft (2) for imparting to the water of the water tub (1) the flow from the front end to the base end of the rotary shaft (2); A gas supply pipe 5 having an upstream end connected to the gas supply source 4 and a downstream end disposed adjacent to the upstream side of the axial flow-inducing wing 3; A centrifugal force is exerted on the water flowing by the axial flow induced vane portion 3 together with the bubbles discharged from the gas supply pipe 5 fixedly circumscribed to the rotary shaft 2 adjacent to the axial flow induced blade portion 3 A centrifugal force inducing vane portion (6) for forcibly causing water containing the bubble to move in the radially outward direction; And a plurality of slit projections 7a extending in the axial direction of the rotary shaft 2 and extending radially inwardly of the rotary shaft 2 at regular intervals in the circumferential direction on the inner peripheral surface of the side wall 7c parallel to the rotary shaft 2, And a plurality of slit through holes 7b are formed in the side wall 7c between the plurality of slit projections 7a so as to form a bubble cut portion in which the centrifugal force induced blade portion 6 is radially outward And the bubble cutting portion 7 having a cylindrical shape surrounding the centrifugal force induced blade portion 6 at a predetermined interval in the direction of the axis.

The radial length of the blades of the centrifugal force induced blade portion 6 is longer than the radial length of the blades of the axial flow induced blade portion 3. [

The bubble generator 100 has a plurality of vanes 8a fixed to the bottom surface of the bubble generator 100 so that the rotating shaft 2 is rotatable around the rotating shaft 2 via a bearing, And a lid plate 8 as a fixed body arranged on the upper part of the water tank (when the rotation shaft is disposed vertically) or on one side of the water (when the rotation shaft is disposed horizontally).

The cover plate 8 acts to break the vortex of water in the water tub 1 by the centrifugal force induced vane 6.

The bubble cutting section 7 is configured such that the rotation axis 2 can rotate so that water flowing by the axial flow induced blade section 3 can no longer flow toward the proximal end side in the axial direction of the rotation axis 2, And a barrier plate 7d which is circumscribed on the rotary shaft 2 and whose rim is fixed to the end of the side wall 7c on the base end side in the axial direction of the rotary shaft 2. [

The axial flow-induced wings 3 are arranged in the water of the water tank 1 to facilitate the axial flow of the water in the water tank 1. The axial flow-induced wing 3 is provided with a hopper Shaped housing (3a); A male threaded crawler 3b fastened to the female threaded crawler 7e formed on the inner circumferential surface of the end of the side wall 7c in the axial direction of the rotary shaft 2 in the axial direction of the rotary shaft 2 A flange portion 3c formed on an outer circumferential surface of the proximal end portion and having an end on the proximal end side of the housing 3a in the axial direction of the rotatable shaft 2 fixedly inscribed; And an inlet (3d) formed at an end side end of the housing (3a) in the axial direction of the rotating shaft (2), the downstream end being detachably connected via a seal, And a guide tube 3e disposed in the guide tube 3e.

The downstream end of the gas supply pipe 5 passes through the tapered portion of the hopper-shaped housing 3a and is disposed on the upstream side of the axial flow-induced vane 3.

The side wall 7c is fixed to the cover plate 8 and the cover plate 8 is fixed to the bracket 1a in order to make the bubble cutting portion 7 into a fixed body.

In the present embodiment, if a plurality of through holes 3f are formed in the adjacent flange portion 3c of the housing 3a at predetermined intervals in the circumferential direction of the housing 3a, Wherein the amount of water flowing into the bubble cutting portion (7) by the axial flow induced blade portion (3) is larger than the amount of water of the bubble cutting portion (7) discharged through the plurality of slit through holes (7b) The excessive water flowing into the bubble cutting portion 7 through the plurality of through holes 3f is discharged so that when the rotary shaft 2 is rotated all the time, It is preferable from the viewpoint of being able to perform.

  The bubble generator of the above-configured embodiment can be operated as follows.

As the rotary shaft is rotated in one direction by the driving of the motor M, the axial flow-induced wing portion 3 is rotated and the velocity head of the housing 3a is increased by the rotated axial flow-induced wing portion 3 The pressure head is lowered, and self-suction force is generated, so that the water in the water tank flows into the housing 3a via the induction pipe 3e.

In this state, when the gas supply source 4 is operated to supply the gas into the housing 3a via the gas supply pipe 5, the gas becomes bubbles and is contained in the water introduced into the housing 3a, The water containing the bubbles is forcibly flowed from the tip end of the rotary shaft 2 to the base end by the wings of the axial flow-inducing wing portion 3 and flows into the bubble-cutting portion 7.

The bubble inclusions introduced into the bubble cutting portion 7 are prevented from flowing toward the base end side from the tip end of the rotation shaft 2 by the barrier plate 7d, The bubble inclusion 6 rotates in the direction of rotation of the centrifugal force induced blade portion 6 and the rotating bubble inclusion is rotated by the centrifugal force while flowing toward the inner peripheral surface of the side wall 7c of the bubble cutting portion 7 The bubbles contained in the water are divided into a plurality of slit protrusions 7a formed on the inner circumferential surface of the side wall 7c so that the bubbles contained in the water are finely divided and discharged through the plurality of slit through holes 7b, Is cut again by the plurality of slit through holes (7b), and the fine bubbles are discharged into the water tank.

The discharged fine bubble inclusion still has the rotational directional direction obtained by the centrifugal force induced wing 6, so that it rotates in the water tank 1. By this rotation, the fine bubbles are uniformly distributed in the water tank And the curvature of the water surface due to the swirling motion of the water in the water tank caused by the centrifugal force induced blade portion is broken by the plurality of vanes 8a of the cover plate 8 to stabilize the water surface.

In the above embodiment, the bubble generator 100 includes the induction pipe 3e whose upstream end is immersed in water in the water tank 1 and whose downstream end is connected to the inlet 3d of the housing 3a 1, but the present invention is not limited thereto. When the suction force of the axial flow-inducing wing 3 is large, the guide tube 3e is excluded from the bubble generator 100 .

The bubble generator in the above embodiment can be applied to a water tank, a malodor treatment tank, a water treatment tank, and the like.

One; Aquarium, 2; Rotation axis, 3; axial flow induced blade, 4; Gas source, 5; Gas supply line, 6; Centrifugal force induced wing portion, 7; Bubble cutting section, 8; Cover plate

Claims (7)

A motor M mounted on a bracket la fixed to the water tub 1;
A rotating shaft 2 having a base end coupled to the motor M and a tip end extending into the water of the water tub 1;
(3) fixedly circumscribed to the tip of the rotary shaft (2) for imparting to the water of the water tub (1) the flow from the front end to the base end of the rotary shaft (2);
A gas supply pipe 5 having an upstream end connected to the gas supply source 4 and a downstream end disposed adjacent to the upstream side of the axial flow-inducing wing 3;
A centrifugal force is exerted on the water flowing by the axial flow induced vane portion 3 together with the bubbles discharged from the gas supply pipe 5 fixedly circumscribed to the rotary shaft 2 adjacent to the axial flow induced blade portion 3 A centrifugal force inducing vane portion (6) for forcibly causing water containing the bubble to move in the radially outward direction; And
A plurality of slit projections 7a extending in the axial direction of the rotary shaft 2 and extending radially inwardly of the rotary shaft 2 at regular intervals in the circumferential direction on the inner peripheral surface of the side wall 7c parallel to the rotary shaft 2, And a plurality of slit through holes (7b) formed between the plurality of slit projection portions (7a) on the side wall (7c), wherein the bubble cutting portion (7) having a cylindrical shape to enclose the centrifugal force induced blade (6) at a predetermined interval,
The bubble cutting portion 7 is formed in such a manner that the rotating shaft 2 can rotate so that water flowing by the axial flow induced vane portion 3 can no longer flow toward the proximal end side in the axial direction of the rotating shaft 2, And a barrier plate (7d) circumscribed on the rotary shaft (2) and having a rim fixed to an end of the side wall (7c) on the base end side in the axial direction of the rotary shaft (2). The method according to claim 1,
A plurality of vanes 8a radially extending on the bottom surface of the rotary shaft 2 are rotatably mounted on the rotary shaft 2 via bearings and fixed to the upper portion of the water in the water tank 1, And a cover plate (8) as a fixing body disposed on the cover plate (8). delete The method according to claim 1,
The axial flow-induced wing portion (3)
A housing (3a) in the form of a hopper which surrounds the axial flow-inducing wing (3); And
A male threaded crawler 3b fastened to the female threaded crawler 7e formed on the inner circumferential surface of the end of the side wall 7c in the axial direction of the rotary shaft 2 in the axial direction of the rotary shaft 2 And a flange portion (3c) formed on an outer peripheral surface of the base end side end portion and having an end portion on the base end side of the housing (3a) fixedly inserted in the axial direction of the rotating shaft (2) . 5. The method of claim 4,
Wherein the downstream end of the gas supply pipe (5) is passed through the tapered portion of the hopper-shaped housing (3a) and is disposed to face the upstream side of the axial flow-induced wing portion (3). 5. The method of claim 4,
Wherein a plurality of through holes (3f) are formed in the adjacent flange portion (3c) of the housing (3a) at a predetermined interval in the circumferential direction of the housing (3a). 3. The method of claim 2,
Characterized in that a side wall (7c) is fixed to the cover plate (8) and the cover plate (8) is fixed to the bracket (1a).

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