JP7236743B2 - bubble agitator - Google Patents

Description

TECHNICAL FIELD The present invention relates to a bubble stirrer for discharging fan bubble water in which fine bubbles are mixed and dissolved at a high concentration.

As a technique for generating fan bubbles, Patent Document 1 discloses an ultra-fan bubble generator. The ultrafun bubble generator includes a main body, a conduit formed in the main body, an A airfoil and a B airfoil. The pipeline has a constricted inclined surface near the inlet and an enlarged inclined surface near the outlet. The A airfoil and the B airfoil are fixed near the center of the pipeline. The ultrafun bubble generator accelerates the fluid that has flowed into the pipe on the slanted surface of the throttle, and then accelerates the rectifying spin with the A and B blades, thereby changing the gas component of the fluid into extremely fine bubbles. .

JP 2019-162605 A

In Patent Document 1, by accelerating the fluid and further accelerating the rectifying spin, the gas component of the fluid can be changed into extremely fine bubbles, and although fan bubbles can be generated to some extent, they are further mixed and dissolved in the fan bubble water. It is desired to increase the amount of fan bubbles to mix and dissolve the fan bubbles at a high concentration.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a bubble stirrer capable of discharging fan bubble water in which fan bubbles are mixed and dissolved at a high concentration by pulverizing (shearing) the air bubbles in the fan bubble water.

Claim 1 of the present invention has a flow hole, an inlet and an outlet opening to the flow hole, and fine bubble water flows into the flow hole from the inlet and flows out from the outlet. A flow cylinder and a plurality of turbulent flow cylinders formed in a cylinder with one end open , each of the turbulent flow cylinders located between the inlet and the outlet It is arranged in the flow hole, one cylinder end is directed toward the inlet, and a plurality of cylinders are stacked in the direction of the hole center line of the flow hole, separated by a flow gap on the inner periphery of the flow hole. , the odd-numbered turbulent flow cylinders arranged concentrically with the flow hole, and the other cylinder end of the odd-numbered turbulent flow cylinders in the direction of the hole center line of the flow hole. and a circulation hole arranged at one end of the cylinder, passing through the turbulent flow cylinders of odd numbers and opening to the flow gap . abutting one end of the adjacent even-numbered turbulent flow cylinder from the inlet side to block one end of the adjacent even-numbered turbulent flow cylinder; The even-numbered turbulent cylinders from the inlet side are arranged between the cylinder ends of the even-numbered turbulent cylinders with a hole interval from one cylinder end. It has an outflow throttle hole that penetrates and opens into the flow gap, and the other cylinder end is connected to one of the adjacent odd-numbered turbulent flow cylinders from the inlet side. A bubble agitator characterized by closing one end of an adjacent odd-numbered turbulent flow cylinder by abutting on the end .
Claim 2 of the present invention has a flow hole, an inlet opening to the flow hole, and an outlet opening, and fine bubble water flows into the flow hole from the inlet and flows out from the outlet. a flow cylinder; and a plurality of turbulent flow cylinders formed in a cylinder with one end open, wherein each of the turbulent flow cylinders is adapted to control the flow between the inlet and the outlet. arranged in a hole, with one cylindrical end facing the inlet side, arranged adjacent to each other in a plurality of rows in the direction of the hole center line of the flow hole, separated by flow gaps on the inner periphery of the flow hole, The odd-numbered turbulent cylinders arranged concentrically with the flow hole pass through the other end of the odd-numbered turbulent cylinders in the direction of the hole center line of the flow hole. and a circulation hole disposed on one cylinder end side and penetrating through the odd-numbered turbulent flow cylinders and opening into the flow gap, and the other cylinder end is connected to the flow gap. abutting one end of the adjacent even-numbered turbulent flow cylinder from the inlet side to block one end of the adjacent even-numbered turbulent flow cylinder; The even-numbered turbulence cylinders from the inlet side are arranged between the cylinder ends of the even-numbered turbulence cylinders with a hole interval from one cylinder end, and pass through the even-numbered turbulence cylinders. and has an outflow throttle hole that opens into the flow gap, and the other cylinder end is connected to one cylinder end of an adjacent odd-numbered turbulent flow cylinder from the inlet. This bubble stirrer is characterized in that it abuts to close one end of adjacent odd-numbered turbulent flow cylinders.
According to claim 3 of the present invention, there is a flow hole, an inlet and an outlet opening to the flow hole, and fine bubble water flows into the flow hole from the inlet and flows out from the outlet. a flow cylinder, a first turbulent flow cylinder formed in a cylinder with one end open, and a cylinder with one end open and the other end closed. and a second turbulent flow cylinder, wherein the first and second turbulent flow cylinders are arranged in the flow hole between the inlet and the outlet with one tube end facing the inlet side. are arranged alternately from the inlet toward the outlet in the direction of the center line of the flow hole, the first turbulent flow cylinders are arranged in odd-numbered order from the inlet side, and the inlet side The second turbulent flow cylinders are arranged even-numbered from the In the direction of the hole center line of the flow hole, an injection throttle hole penetrating the other cylinder end of the odd-numbered first turbulent flow cylinder, and the odd-numbered first turbulent flow arranged on the one cylinder end side. and a flow hole penetrating through the cylinder and opening to the flow gap, and the other cylinder end is connected to one of the even-numbered second turbulent flow cylinders adjacent to each other. The even-numbered second turbulent flow cylinder abuts against the cylinder end to close one cylinder end of the two adjacent turbulent flow cylinders, and the even-numbered second turbulent flow cylinder is separated from the one cylinder end by a hole interval. Disposed between the ends of the second turbulent flow cylinders, penetrating through the even-numbered second turbulent flow cylinders and having an outflow throttle hole opening into the flow gap, the other cylinder end is abutting one cylinder end of the adjacent first turbulence cylinders among the odd-numbered first turbulence cylinders to close the other cylinder end of the adjacent first turbulence cylinders It is a bubble stirrer characterized by
In the present invention, fine bubbles are bubbles with a bubble diameter of less than 100 micrometers (μm). In the present invention, fine bubble water is water in which fine bubbles (bubbles with a bubble diameter of less than 100 micrometers) are mixed and dissolved, and is water in which microbubbles and ultra-fine bubbles are mixed and dissolved (hereinafter the same ). The international standard "ISO20480-1" of the International Organization for Standardization (ISO) defines bubbles with a bubble diameter of 1 micrometer (μm) or more and less than 100 micrometers (μm) as "microbubbles" and a bubble diameter of 1 micrometer (μm). ) are defined as “ultra-fine bubbles” (the same shall apply hereinafter).

In the present invention, the fine bubble water flows from the inlet into the first (odd-numbered) turbulent flow cylinder and becomes turbulent in the first turbulent flow cylinder. In the first (odd-numbered) turbulent flow cylinder, the turbulent fine bubble water is jetted into the second (even-numbered) turbulent flow cylinder through the injection throttle hole to form a turbulent flow. In the second (even-numbered) turbulence cylinder, the turbulent fine bubble water flows out through the outflow throttle hole into the flow gap between the flow hole and each turbulence cylinder. The fine bubble water flowing out to the flow gap becomes a laminar flow in the direction of the hole center line of the flow hole due to the inner circumference of the flow hole and the outer circumference of each turbulent flow cylinder, and flows through the flow gap toward the outlet. . A part of the fine bubble water flowing through the flow gap flows into the third (odd-numbered) turbulent flow cylinder through the circulation hole and becomes turbulent. In this way, the present invention repeats the flow of fine bubble water in the order of turbulent flow and laminar flow by using each turbulent flow cylinder and the flow gap (the inner circumference of the hole of the flow hole and the outer circumference of each turbulent flow cylinder). , to crush (shear) the air bubbles in the fan bubble water.

The present invention repeats the flow of fine bubble water in the order of turbulent flow and laminar flow to crush (shear) the bubbles in the fine bubble water, so that fine bubbles (microbubbles and ultrafine bubbles) are mixed at high density, Dissolved fan bubble water can flow out.

Fig. 3 is an assembled front view of the bubble stirrer, bubble generator, inflow pipe and outflow pipe; FIG. 2 is a top view (plan view) of FIG. 1; FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1; 4 is an enlarged sectional view of FIG. 3; FIG. 5 is an enlarged cross-sectional view taken along line BB of FIG. 4; FIG. 5 is an enlarged cross-sectional view taken along line CC of FIG. 4; FIG. FIG. 5 is an enlarged sectional view taken along line DD of FIG. 4; 5 is an enlarged cross-sectional view taken along line EE of FIG. 4; FIG. FIG. 5 is an enlarged sectional view taken along line FF of FIG. 4; 5 is an enlarged cross-sectional view taken along line GG of FIG. 4; FIG. 5 is an enlarged cross-sectional view taken along line HH of FIG. 4; FIG. FIG. 5 is a partially enlarged cross-sectional view of FIG. 4 showing the flow of fine bubble water in the inlet side of the bubble agitator and in the bubble generator. 5 is a partially enlarged cross-sectional view of FIG. 4 showing the flow of fine bubble water on the outlet side of the bubble stirrer. FIG. It is a figure which shows the 1st flow cylinder main body of a flow cylinder, Comprising: (a) is a perspective view, (b) is a top view. 15(a) is a bottom view and (b) is a partially enlarged view of FIG. 15(a). FIG. 16(a) is a cross-sectional view taken along line II of FIG. 14(b), and FIG. 16(b) is a partially enlarged view of FIG. 16(a). FIG. It is a figure which shows the 2nd flow cylinder main body of a flow cylinder, Comprising: (a) is a perspective view, (b) is a bottom view. 18(a) is a top view and (b) is a cross-sectional view taken along line JJ in FIG. 18(a). FIG. It is a figure which shows a turbulent flow cylinder (1st turbulent flow cylinder), (a) is a front view, (b) is a side view, (c) is a top view. 19(a) is a bottom view, (b) is a KK sectional view of FIG. 19(a), and (c) is FIG. 19(b). ) is a cross-sectional view taken along line LL. It is a figure which shows a turbulent flow cylinder (2nd turbulent flow cylinder), (a) is a front view, (b) is a side view, (c) is a top view. 21(a) is a bottom view, (b) is a cross-sectional view taken along line MM of FIG. 21(a), and (c) is FIG. 21(b). ) is a sectional view taken along line NN. It is a figure which shows a bubble generator, Comprising: (a) is a front view, (b) is a top view. 23(a) is a bottom view and (b) is a cross-sectional view taken along line OO of FIG. 23(b). FIG.

A bubble stirrer according to the present invention will be described with reference to FIGS. 1 to 24. FIG.

12 and 13, the bubble stirrer X is connected (coupled) to the bubble generator Y, and fine bubble water BW (fine bubble liquid) generated by the bubble generator Y flows into it. The bubble agitator X agitates (pulverizes) the air bubbles in the fine bubble water BW that has flowed in, and discharges the fan bubble water JW in which the fan bubbles are mixed and dissolved at a high concentration.
The bubble agitator X comprises a flow tube 1 and a plurality of turbulent flow tubes 2, as shown in FIGS. 1-22.

As shown in FIGS. 3 and 4 , the flow tube 1 has a flow hole 3 (circular flow hole), an inlet 4 opening to the flow hole 3 , and an outlet 5 opening to the flow hole 3 . Fine bubble water is introduced (injected) into the flow hole 3 from the inlet 4 and discharged from the outlet 5 of the flow cylinder 1 .

The flow tube 1 is formed into a cylindrical body, as shown in FIGS. 1-18. The flow tube 1 (flow cylinder) comprises a first flow tube main body 6 (upper flow tube main body) and a second flow tube main body 7 (lower flow tube main body).

The first flow tube main body 6 is formed in a cylindrical body, as shown in FIGS. 14 to 16 . The first flow tube main body 6 includes a first tube portion 8, a first threaded tube portion 9, a first flange portion 10, a first guide plate portion 11, a plurality of outflow guide grooves 12, a plurality of first retaining pieces 13, and It has a plurality of first rectifying projections 14 .

The first tubular portion 8 has a first flow hole portion 15 (first circular flow hole portion), as shown in FIGS. 15 and 16 . The first flow hole portion 15 is arranged concentrically with the cylinder center line a of the first flow cylinder main body 6 . The first flow hole portion 15 extends in the direction A of the cylinder center line a of the first flow cylinder main body 6 and opens at one cylinder end 8A of the first cylinder portion 8 .

As shown in FIGS. 14 and 16 , the first screw cylinder portion 9 is formed integrally with the first cylinder portion 8 and arranged concentrically with the first cylinder portion 8 . The first threaded tube portion 9 extends from the other tube end 8B of the first tube portion 8 in the direction A of the tube center line a of the first flow tube body 6 .

The first flange portion 10 is formed as an annular plate, as shown in FIGS. 14 to 16 . The first flange portion 10 is disposed on the side of one tube end 8A of the first tube portion 8 in the direction A of the tube center line a of the first flow tube main body 6, and is formed integrally with the first tube portion 8. be. The first flange portion 10 protrudes radially outward of the first flow tube main body 6 from the outer periphery (outer peripheral surface) of the first tube portion 8 .
The first flange portion 10 has a plurality of first through holes 16 . Each of the first through holes 16 is, for example, six holes arranged on a circle centered on the tube center line a of the first flow tube main body 6 . The first through holes 16 are arranged at regular intervals in the circumferential direction G of the first flow tube main body 6 . Each first through hole 16 penetrates the first flange portion 10 in the direction A of the cylinder center line a of the first flow cylinder main body 6 and extends to the top plate surface 10A and the back plate surface 10B of the first flange portion 10. Open your mouth.

The first guide plate portion 11 is formed integrally with the first cylindrical portion 8 as shown in FIGS. The first guide plate portion 11 is arranged on the other tube end 8B side of the first tube portion 8 and closes the other tube end 8B of the first tube portion 8 .
The first guide plate portion 11 has a flow outflow hole portion 17 . The flow outflow hole portion 17 is arranged concentrically with the cylinder center line a of the first flow cylinder main body 6 . The flow outflow hole portion 17 penetrates the first guide plate portion 11 in the direction A of the cylinder center line a of the first flow cylinder main body 6 and extends to the surface plate surface 11A of the first guide plate portion 11 (the other cylinder end). 8B) and back plate surface 11B. The flow outflow hole portion 17 passes through the first guide plate portion 11 and communicates with the inside of the first screw cylinder portion 9 and the first flow hole portion 15 . The flow outflow hole portion 17 opens in the top plate surface 11A (the other cylinder end 8B) of the first guide plate portion, and forms the outflow port 5 in the other cylinder end 8B of the first flow cylinder main body 6 . The outflow port 5 is opened in the front plate surface 11A (the other cylindrical end 8B) of the first guide plate portion 11 and is opened in the first flow hole portion 15 through the flow outflow hole portion 17 .

For example, four outflow guide grooves 12 (four outflow guide grooves) are formed in the first guide plate portion 11, as shown in FIGS. The outflow guide grooves 12 are arranged in the circumferential direction G of the first flow tube main body 6 at regular intervals (intervals at an angle of 90 degrees). Each outflow guide groove 12 has a groove width D in the circumferential direction G of the first flow tube main body 6 and is formed between the top plate surface 11A and the back plate surface 11B of the first guide plate portion 11 . As shown in FIG. 13, each outflow guide groove 12 extends from the outflow port 5 of the first guide plate portion 11 (the top surface 11A of the first guide plate portion 11) to the center line a of the first flow tube main body 6. , and extends radially outward and inclined to the back plate surface 11B of the first guide plate portion 11 .

As shown in FIGS. 15 and 16 , for example, four first retaining pieces 13 (four first retaining pieces) are integrally formed with the first guide plate portion 11 . The first retainer pieces 13 are arranged at intervals in the circumferential direction G of the first flow tube main body 6 (equal intervals: intervals at an angle of 90 degrees). Each first retaining piece 13 is formed between each outflow guide groove 12 in the circumferential direction G of the first flow tube body 6 . Each second retaining piece 13 is arranged adjacent to each outflow guide groove 12 on both sides in the circumferential direction G of the first flow tube main body 6 .
Each first retainer piece 13 has the same thickness as the first guide plate portion 11 in the direction A of the cylinder center line a of the first flow cylinder main body 6 , and has the same width in the circumferential direction G of the first flow cylinder main body 6 . It has T and extends in the radial direction of the first flow tube body 6 . Each first retainer piece 13 extends from the lower end of each outflow guide groove 12 (the lower end intersecting the back plate surface 11B of the first guide plate portion 11) to the flow outflow hole portion 17 in the radial direction of the first flow cylinder main body 6. (Outflow port 5 ) and arranged between each outflow guide groove 12 and flow outflow hole 17 . The width T of each first retainer piece 13 is smaller than the groove width D of each outflow guide groove 12 .

As shown in FIGS. 15 and 16 , for example, eight (eight first rectifying projections) of the first rectifying projections 14 are formed integrally with the first tubular portion 8 . The first rectifying protrusions 14 are arranged at regular intervals in the circumferential direction G of the first flow tube main body 6 (equal intervals: intervals of an angle of 45 degrees). Each first straightening protrusion 14 extends between each first retaining piece 13 and one tube end 8A of the first tube portion 8 in the direction A of the tube center line a of the first flow tube main body 6. . Each first rectifying protrusion 14 is formed, for example, in a crown-shaped (hemispherical) cross section.
Each first rectifying protrusion 14 has a second projection amount R from the first flow hole portion 15 (inner peripheral surface of the first cylinder portion 8) toward the cylinder center line a of the first flow cylinder main body 6. Protruded.

As shown in FIGS. 17 and 18, the second flow tube main body 7 is formed into a cylindrical body. The second flow tube main body 7 has a second tube portion 21 , a second threaded tube portion 22 , a second flange portion 23 , a second guide plate portion 24 and a plurality of second straightening projections 27 .

The second tubular portion 21 has a second flow hole portion 28 (second circular flow hole portion), as shown in FIG. 18 . The second flow hole portion 28 is arranged concentrically with the cylinder center line a of the second flow cylinder main body 7 . The second flow hole portion 28 extends in the direction A of the cylinder center line a of the second flow cylinder main body 7 and opens at one cylinder end 21A of the second cylinder portion 21 .

As shown in FIGS. 17 and 18 , the second screw cylinder portion 22 is formed integrally with the second cylinder portion 21 and arranged concentrically with the second cylinder portion 21 . The second threaded tube portion 22 extends from the other tube end 21B of the second tube portion 21 in the direction A of the tube center line a of the second flow tube body 7 .

The second flange portion 23 is formed in an annular plate as shown in FIGS. 17 and 18 . The second flange portion 23 is arranged on the side of one tube end 21A of the second tube portion 21 in the direction A of the tube center line a of the second flow tube main body 7, and is formed integrally with the second tube portion 21. be. The second flange portion 23 protrudes radially outward of the second flow tube main body 7 from the outer circumference (outer peripheral surface) of the second tubular portion 21 .
The second flange portion 23 has a plurality of second through holes 29 . Each of the second through holes 29 is, for example, six holes arranged on a circle centered on the tube center line a of the second flow tube main body 7 . The second through holes 29 are arranged at regular intervals in the circumferential direction G of the second flow tube main body 7 . Each of the second through-holes 29 penetrates the second flange portion 23 in the direction A of the cylinder center line a of the second flow cylinder main body 7 and extends to the top plate surface 23A and the back plate surface 23B of the second flange portion 23. Open your mouth.

The second guide plate portion 24 is formed integrally with the second tubular portion 21 as shown in FIGS. The second guide plate portion 24 is arranged on the other tube end 21B side of the second tube portion 21 and closes the other tube end 21B of the second tube portion 21 . The second guide plate portion 24 has a flow inflow hole portion 30 . The flow inflow hole portion 30 is arranged concentrically with the cylinder center line a of the second flow cylinder main body 7 . The flow inflow hole portion 30 penetrates the second guide plate portion 24 in the direction A of the tube center line a of the second flow tube main body 7 and extends to the surface plate surface 24A of the second guide plate portion 24 (the other tube end). 21B) and back plate surface 24B. The flow inflow hole portion 30 passes through the second guide plate portion 24 and communicates with the inside of the second screw cylinder portion 22 and the second flow hole portion 28 . The flow inflow hole portion 30 opens to the front plate surface 24A (the other cylindrical end 21B) of the second guide plate portion 24 and forms the inflow port 4 in the other cylindrical end 21B of the second cylindrical portion 21 . The inflow port 4 is opened in the top plate surface 24A (the other cylindrical end 21B) of the second guide plate portion 24 and is opened in the second flow hole portion 28 through the flow inflow hole portion 30 .

As shown in FIG. 18, for example, eight second straightening protrusions 27 (eight second straightening protrusions) are integrally formed with the second cylindrical portion 21 . The second rectifying protrusions 27 are arranged at intervals (equal intervals: intervals of 45 degrees) in the circumferential direction G of the second flow tube main body 7 . Each second straightening protrusion 27 extends between each second retaining piece 26 and the other tube end 21A of the second tube portion 21 in the direction A of the tube center line a of the second flow tube main body 7. . Each second rectifying protrusion 27 is formed, for example, in a crown-shaped (hemispherical) cross section.
Each of the second rectifying projections 27 protrudes from the second flow hole portion 28 (the inner peripheral surface of the second cylindrical portion 21) toward the cylinder center line a of the second flow cylinder main body 7 with a projection amount R. be.

The flow tube 1 is constructed by combining a first flow tube main body 6 and a second flow tube main body 7, as shown in FIGS.
The first flow tube main body 6 is arranged with the first flange portion 10 (upper flange) facing the second flange portion 23 (lower flange) of the second flow tube main body 7 .
As shown in FIGS. 1, 3 and 4, the first and second flow tube main bodies 6 and 7 have one tube end 8A of the first tube part 8 and one tube end 21A of the second tube part 21. The back plate surface 10B of the first flange portion 10 and the back plate surface 23B of the second flange portion 23 are arranged in close contact and continuously in the direction A (vertical direction) of the cylinder center line a of the flow cylinder 1. be done. The first and second flow tube bodies 6 and 7 are in close contact with the first and second flange portions 10 and 23 with an annular seal 38 interposed between them.

The first and second flow tube main bodies 6, 7 are aligned with the tube center lines a (hole center lines a) of the first and second tube portions 8, 21 (first and second flow hole portions 15, 28). are arranged concentrically.

As shown in FIGS. 3 and 4 , the first flow tube main body 6 has first through holes 16 of the first flange portion 10 and second through holes of the second flange portion 23 of the second flow tube main body 7 . 29 coincidentally (consecutively).
As a result, the flow tube 1 is composed of a first flow tube main body 6 on the upper side and a second flow tube main body 7 on the lower side of the flow tube 1, and the first and second flow holes 15 and 28 (second A flow hole 3 is formed in the first and second cylindrical portions 8, 21).
The flow hole 3 is formed in the inlet 4 opening in the direction A of the cylinder center line a of the flow cylinder 1 to the other cylinder end 8B of the first cylinder part 8 (the top plate surface 11A of the first guide plate part 11). It is continuous and continues to the outflow port 5 that opens to the other cylindrical end 21B of the second cylindrical portion 21 (the surface plate surface 24A of the second guide plate portion 24). The inflow port 4 opens into the flow hole 3 (second flow hole portion 28 ) through the flow inflow hole portion 30 . The outflow port 5 opens into the flow hole 3 (first flow hole portion 15 ) through the flow outflow hole portion 17 .

In the flow tube 1, the first and second flow tube bodies 6 and 7 are connected by a plurality of bolt screws 35, a plurality of spring washers 36 and a plurality of nuts 37, as shown in FIGS.
3 and 4, each bolt screw 35 passes through each spring washer 36, each first through hole 16 of the first flange portion 10, and each second through hole 29 of the second flange portion 23. ) and arranged in the flow tube 1 (the first and second flow tube bodies 6 and 7). Each bolt screw 35 protrudes from each second through hole 29 (top plate surface 23A) of the second flange portion 23 in the direction A of the tube center line a of the flow tube 1 .
Each nut 37 is screwed onto each bolt screw 35 protruding from each second through hole 29 of the second flange portion 23, as shown in FIGS.
Rotate each bolt screw 35 or each nut 37 to bring each spring washer 36 and each nut 37 into contact with the first and second flange portions 10 and 23, tighten the first and second flange portions 10 and 23, and 1 and the second flow tube bodies 6, 7 are connected.

As shown in FIGS. 19 to 22, each turbulent flow tube 2 is formed into a cylindrical body with one tube end 2a open and the other tube end 2b closed. Each turbulent flow cylinder 2 has a cylinder outer diameter Da (outer diameter) and a cylinder inner diameter da (inner circumference diameter). In each turbulent flow cylinder 2, the cylinder outer diameter Da is smaller than the hole diameter of the flow hole 3 (circular flow hole).

The other cylindrical end 2b (closed cylindrical end) of each turbulent flow cylinder 2 is, as shown in FIGS. Hemispherical).

Each turbulence cylinder 2 is composed of a first turbulence cylinder 2X and a second turbulence cylinder 2Y.

Among the turbulence cylinders 2, each first turbulence cylinder 2X includes, as shown in FIGS. It has a plurality (pairs) of first outflow throttle holes 47 .

As shown in FIGS. 19C and 20, the injection throttle hole 45 (injection throttle circular hole) is arranged concentrically with the cylinder center line b of the first turbulent flow cylinder 2X. The injection throttle hole 45 penetrates the other tube end 2b in the direction B of the tube center line b of the first turbulent flow tube 2X and opens to the inside and outside of the first turbulent flow tube 2X.

As shown in FIGS. 19(b) and 20, each first circulation hole 46 is arranged on one cylinder end 2a side in the direction B of the cylinder center line b of the first turbulent flow cylinder 2X. The first circulation holes 46 are arranged at regular intervals (an interval of 180 degrees) in the circumferential direction C of the first turbulent flow cylinder 2X.
Each first circulation hole 46 (circulation hole) penetrates the first turbulent flow cylinder 2X in a direction perpendicular to (intersects) the cylinder center line a of the first turbulent flow cylinder 2X. An outer periphery 2c (outer peripheral surface) and an inner periphery 2d (inner peripheral surface) of the body 2X are opened at one cylindrical end 2a.

As shown in FIGS. 19A and 20, each first outflow throttle hole 47 (first outflow throttle circular hole) is arranged in the direction B of the cylinder center line b of the first turbulent flow cylinder 2X. It is arranged between each first circulation hole 46 and the other cylindrical end 2b with a hole interval δ1 from the end 2a.
The first outflow throttle holes 47 are arranged between the first circulation holes 46 at equal intervals (an interval of 180 degrees) in the circumferential direction C of the first turbulent flow cylinder 2X. Each first outflow throttle hole 47 is arranged at an interval (for example, an interval of 90 degrees) from each first circulation hole 46 in the circumferential direction C of the first turbulent flow cylinder 2X.
Each first outflow throttle hole 47 penetrates through the first turbulent flow cylinder 2X in a direction B perpendicular to (intersects) the cylinder center line b of the first turbulent flow cylinder 2X. It opens to the outer circumference 2c and the inner circumference 2d.

Among the turbulent flow cylinders 2, the second turbulent flow cylinder 2Y has a plurality (pair) of second circulation holes 56 and a plurality (pair) of second outflow throttle holes, as shown in FIGS. 57 (outflow throttle hole).

As shown in FIGS. 21(b) and 22, each second circulation hole 56 is arranged on one cylinder end 2a side in the direction B of the cylinder center line b of the second turbulent flow cylinder 2Y. The second circulation holes 56 are arranged at regular intervals (an interval of 180 degrees) in the circumferential direction C of the second turbulent flow cylinder 2Y.
Each second flow hole 56 penetrates the second turbulent flow cylinder 2Y in a direction perpendicular to (intersects) the cylinder center line b of the second turbulent flow cylinder 2Y, and extends to the outer circumference of the second turbulent flow cylinder 2Y. 2c (outer peripheral surface) and inner peripheral surface 2d (inner peripheral surface) are opened at one tube end 2a.

As shown in FIGS. 21A and 22, each second outflow throttle hole 57 (second outflow throttle circular hole) is arranged in the direction B of the cylinder center line b of the second turbulent flow cylinder 2Y. It is arranged between each second circulation hole 56 and the other cylindrical end 2b with a hole interval δ1 from the end 2a.
The second outflow throttle holes 57 are arranged between the second circulation holes 56 at equal intervals (an interval of 180 degrees) in the circumferential direction C of the second turbulent flow cylinder 2Y. Each second outflow throttle hole 57 is arranged at intervals (for example, intervals of 90 degrees) from each second circulation hole 56 in the circumferential direction C of the second turbulent flow cylinder 2Y.
Each second outflow throttle hole 57 penetrates the second turbulent flow cylinder 2Y in a direction perpendicular to (intersects) the cylinder center line b of the second turbulent flow cylinder 2Y. It opens to the outer circumference 2c and the inner circumference 2d.
Each second turbulent flow cylinder 2Y does not have the injection throttle hole 45 with respect to the first turbulent flow cylinder 2X, and the rest of the construction is the same as that of the first turbulent flow cylinder 2X.

Each turbulent flow cylinder 2 (first and second turbulent flow cylinders 2X, 2Y) has a hole center line a of the flow hole 3 (cylinder center line a of the flow cylinder 1), as shown in FIGS. ) in the flow hole 3 between the inlet 4 and the outlet 5 . Each turbulent flow cylinder 2 has one cylinder end 2a (open cylinder end) directed toward the inlet 4 (inlet 4) and the other cylinder end 2b (closed cylinder end) directed toward the outlet 5 (outlet). 5), in the direction A of the center line a of the flow hole 3, a plurality of rows (plurality/plurality) are arranged side by side.
For example, each turbulent flow cylinder 2 is plural in the direction A of the hole center line a of the flow hole 3, and arranged in an odd number row (odd number/odd number). In each turbulent flow cylinder 2, the first turbulent flow cylinders 2X are arranged in odd-numbered rows (odd-numbered rows) from the inlet 4 side (inlet 4), and even-numbered rows from the inlet 4 side (inlet 4). The second turbulent flow cylinders 2Y are arranged in (even-numbered rows) and arranged adjacent to the flow holes 3 . Each turbulent flow cylinder 2 is the first (first row) from the inlet 4 side (inlet 4) to the outlet 5 side (outlet 5) in the direction A of the hole center line a of the flow hole 3. ), 2nd (2nd column), 3rd (3rd column), 4th (4th column), ..., Nth (Nth column) (N = 2, 3, 4, ...).
As a result, each turbulent flow cylinder 2 has a first The turbulent flow cylinders 2X and the second turbulent flow cylinders 2Y are alternately arranged and arranged adjacent to the flow holes 3. As shown in FIG.

Each turbulent flow cylinder 2 (first and second turbulent flow cylinders 2X, 2Y) has a flow hole 3 (hole inner circumference 3A of flow hole 3), as shown in FIGS. are arranged concentrically with each other and concentrically with the hole center line a of the flow hole 3 (cylinder center line a of the flow cylinder 1) across a first flow gap δA (flow gap).
Each turbulent flow cylinder 2 (first and second turbulent flow cylinders 2X, 2Y) includes first straightening protrusions 14 of the first flow tube body 6 or second flow straightening protrusions 27 of the second flow tube body 7. are arranged concentrically with each other and concentrically with the hole center line a of the flow hole 3 (flow cylinder 1) across a second flow gap δB.
As a result, each turbulent flow cylinder 2 (first and second turbulent flow cylinders 2X, 2Y) is arranged between the hole inner circumference 3A of the flow hole 3 and between the first and second rectifying projections 14, 27 in the second direction. A guide channel Q (laminar flow channel) of the first flow gap δA or the second flow gap δB is formed. The guide channel Q extends in the direction A of the hole center line a of the flow hole 3 (the cylinder center line a of the flow cylinder 1).

Among the turbulent flow cylinders 2, in the first turbulent flow cylinder 2X (the turbulent flow cylinder 2) on the odd-numbered (odd-numbered) side from the inlet 4 side (the inlet 4), the injection throttle hole 45 is 4, in the direction A of the hole center line a of the flow hole 3, it penetrates the other tubular end 2b (closed tubular end) of the odd-numbered first turbulent flow tubular body 2X (turbulent flow tubular body 2). .

In the odd-numbered first turbulent flow cylinders 2X, as shown in FIGS. 4, 7 and 11, each first circulation hole 46 is located on one cylinder end 2a side of the odd-numbered first turbulent flow cylinders 2X. (Open tube end side). The first circulation holes 46 are arranged at equal intervals (an interval of 180 degrees) in the circumferential direction of the flow hole 3 (circumferential direction of the flow cylinder 1). Each of the first circulation holes 46 penetrates the odd-numbered first turbulent flow cylinders 2X (turbulent flow cylinders 2) in a direction perpendicular to (intersects) the hole center line a of the flow hole 3, and It opens at the second flow gaps δA, δB (guide flow path Q) and one tube end 2a (open tube end).

In the odd-numbered first turbulent flow cylinders 2X, the first outflow throttle holes 47 are equally spaced in the circumferential direction of the flow holes 3 (intervals of 180 degrees), as shown in FIGS. are arranged between the respective first circulation holes 46 with a space between them. Each first outflow throttle hole 47 penetrates the odd-numbered first turbulent flow cylinders 2X (turbulent flow cylinders 2) in a direction perpendicular to (intersects) the hole center line a of the flow hole 3, and second flow gaps δA and δB (guiding channels Q).

As shown in FIGS. 3 and 4, the odd-numbered first turbulent flow cylinders 2X are arranged from the inlet 4 side (inflow port 4) to the even-numbered (even-numbered) second turbulent flow cylinders 2Y (turbulent flow cylinders). Among the flow cylinders 2), one cylinder end 2a (open cylinder end) of each of the adjacent even-numbered second turbulent flow cylinders 2Y is closed.
Each odd-numbered first turbulent flow cylinder 2X extends from the direction A of the hole center line a of the flow hole 3 (the direction A of the cylinder center line a of the flow cylinder 1) to the other cylinder end 2b (closed cylinder end). , abuts on one cylinder end 2a (open cylinder end) of the adjacent even-numbered second turbulent flow cylinder 2Y to close one cylinder end 2a of the adjacent even-numbered second turbulent flow cylinder 2Y. .
As a result, the even-numbered second turbulent flow cylinders 2Y from the inlet 4 side have one cylinder end 2a (open cylinder end) of the adjacent odd-numbered (odd-numbered) first turbulent flow cylinders 2X. It has a turbulent flow space CA (internal space) that is closed at the other tube end 2b (closed tube end). In the even-numbered second turbulent flow cylinders 2</b>Y, the turbulent flow space CA communicates with the guide channel Q through each second flow hole 56 and each second outlet throttle hole 57 .

As shown in FIG. 4, the first turbulent flow cylinder 2X on the first (first row) side from the inlet 4 side has one cylinder end 2a (open cylinder end) connected to the second flow cylinder body 7 of the second flow cylinder main body 7, as shown in FIG. It is arranged in the flow hole 3 in contact with the back plate surface 24B of the guide plate portion 24 (the other cylindrical end 21B of the second cylindrical portion 21).
As a result, the first turbulent flow cylinder 2X, which is the first from the inlet 4 side, has a turbulent flow space formed by closing one cylinder end 2a with the second guide plate portion 24 (the other cylinder end 21B). It has a CA (internal space). In the first first turbulent flow cylinder 2X, the turbulent flow space CA communicates with the guide flow channel Q through each first circulation hole 46 and each first outflow throttle hole 47, as shown in FIGS. be done.

The first turbulent flow cylinder 2X that is the first from the inlet 4 side communicates the turbulent flow space CA with the inlet 4 from one tubular end 2a, as shown in FIG. In the first turbulent flow cylinder 2X, the turbulent space CA communicates with the second threaded cylinder 22 through the inlet 4 and the flow inflow hole 30 of the second flow cylinder main body 7 .

Of the odd-numbered (odd-numbered) first turbulent flow cylinders 2X, the last (last row/Nth, Nth row) first turbulent flow cylinder from the inlet 4 side (inlet 4) 2X is arranged in the flow hole 3 with the other tube end 2b (closed tube end) in contact with each of the first retaining pieces 13 of the first flow tube main body 6, as shown in FIGS. be.

As shown in FIGS. 4, 5, and 13, the final first turbulent flow cylinder 2X has its other cylinder end 2b (closed cylinder end) in contact with each first retaining piece 13 to A plurality of guide outflow paths P (guide outflow holes) are formed between the guide groove 12 and the other cylinder end 2b. Each guide flow channel P opens to the guide flow channel Q and the flow flow hole portion 17 (outflow port 5), and communicates the guide flow channel Q with the flow flow port 5 (first flow flow flow hole portion 17). The guiding channel Q communicates with the outflow port 5 through each guiding outflow channel P and the flow outflow holes 17 .
In the final first turbulent flow cylinder 2X, as shown in FIGS. is communicated with the outflow port 5 through the .

Among the turbulent flow cylinders 2, in the even-numbered second turbulent flow cylinders 2Y from the inflow port 4 side (inflow port 4), each second circulation hole 56 has a flow path as shown in FIGS. They are arranged at regular intervals (an interval of 180 degrees) in the circumferential direction of the hole 3 . Each of the second flow holes 56 penetrates the even-numbered second turbulent flow cylinders 2Y (turbulent flow cylinders 2) in a direction perpendicular to (intersects) the hole center line a of the flow hole 3 to It opens at the second flow gaps δA, δB (guide flow path Q) and one tube end 2a (open tube end).

In the even-numbered second turbulent flow cylinders 2Y, the second outflow throttle holes 57 (outflow throttle holes) are, as shown in FIGS. are arranged between the second circulation holes 56 with an interval) therebetween. Each of the second outflow throttle holes 57 penetrates the even-numbered second turbulent flow cylinders 2Y (turbulent flow cylinders 2) in a direction perpendicular to (intersects) the hole center line a of the flow hole 3, and second flow gaps δA and δB (guiding channels Q).

As shown in FIGS. 3 and 4, the even-numbered second turbulent flow cylinders 2Y are adjacent odd-numbered first turbulent flow cylinders 2X (turbulent flow cylinders 2) among the odd-numbered first turbulent flow cylinders 2X. It is arranged to close one cylinder end 2a (open cylinder end) of the turbulence cylinder 2X.
The even-numbered second turbulent flow cylinders 2Y move the other tubular end 2b (closed tubular end) from the direction A of the hole center line a of the flow hole 3 to one of the adjacent odd-numbered first turbulent flow cylinders 2X. , and closes one cylinder end 2a of the adjacent odd-numbered first turbulent flow cylinder 2X.
As a result, the odd-numbered first turbulent flow cylinders 2X excluding the first one from the inlet 4 side have one cylinder end 2a (open cylinder end) connected to the adjacent even-numbered (even-numbered row) second turbulent flow cylinder. It has a turbulent space CA (internal space) that is closed at the other cylindrical end 2b (closed cylindrical end) of the cylindrical body 2Y. In the odd-numbered first turbulent flow cylinders 2X excluding the first one, the turbulent flow space CA is, as shown in FIGS. (first and second flow gaps .delta.A, .delta.B), and communicates with the adjacent even-numbered second turbulent flow cylinders 2Y (turbulent flow space CA) through the injection throttle hole 45. As shown in FIG.
In this way, each turbulent flow cylinder 2 has first and second turbulent flow cylinders 2X and 2Y arranged side by side in odd-numbered rows (multiple rows) in the direction A of the hole center line a of the flow hole 3. Thus, a cylindrical body having an outer diameter Da is formed (formed).
Each turbulent flow cylinder 2 (first and second turbulent flow cylinders 2X, 2Y) is moved in the direction A of the hole center line a of the flow hole 3 by the second guide plate portion 24 and each first retaining piece 13. movement is regulated, and the flow hole 3 is prevented from coming off in the direction A of the hole center line a.

In the bubble stirrer X, each turbulent flow cylinder 2 is arranged adjacently in three rows (odd number rows) in the direction of the hole center line a of the flow hole 3, as shown in FIGS. .
Three turbulence cylinders 2 are arranged in the flow hole 3 between the inlet 4 and the outlet 5 . Each turbulent flow cylinder 2 has a first turbulent flow cylinder 2X on the first (first row) from the inlet 4 side (inflow port 4), a second turbulent flow cylinder 2Y on the second (second row), And the first turbulent flow cylinder 2X is arranged in the third (third row), and a plurality (two) of the first turbulent flow cylinders 2X and one second turbulent flow cylinder 2Y are adjacently arranged in parallel. do. The first (first row) and third (third row) first turbulent flow cylinders 2X are odd-numbered (odd-numbered rows), and the second second turbulent flow cylinders 2Y are even-numbered (even-numbered column). The third (third row) first turbulent flow cylinder 2X is the last (last row). The second (even-numbered) second turbulent cylinders 2Y (turbulent cylinders 2) from the inlet 4 side are the first and third (odd-numbered) first turbulent cylinders 2X from the inlet 4 side. (turbulence cylinder 2).

The bubble stirrer X is connected (coupled) to the bubble generator Y as shown in FIGS. The bubble stirrer X and the bubble generator Y constitute a bubble generating stirrer.

The bubble generator Y includes a bubble tube main body 61, as shown in FIGS. The bubble cylinder main body 61 has a bubble generation hole 62 and a screw portion 63 .

The bubble generation hole 62 is arranged concentrically with the tube center line e of the bubble tube body 61, as shown in FIGS. The bubble generating hole 62 penetrates the bubble cylinder main body 61 in the direction E of the cylinder center line e of the bubble cylinder main body 61 and opens at the respective cylinder ends 61A and 61B of the bubble cylinder main body 61 . The bubble generating hole 62 has a screw hole portion 64 , a wide-angle hole portion 65 , a jet throttle hole portion 66 , a relay hole portion 67 and a plurality of introduction hole portions 68 .

23(b) and 24, the screw hole portion 64 is arranged on one tube end 61A side of the bubble tube main body 61. As shown in FIG. The screw hole portion 64 extends in the direction E of the tube center line e of the bubble tube main body 61 and opens at one tube end 61A of the bubble tube main body 61 .

The wide-angle hole portion 65 is arranged on the other tube end 61B side of the bubble tube body 61, as shown in FIGS. 23(b) and 24(b). The wide-angle hole portion 65 is arranged concentrically with the screw hole portion 64 . The wide-angle hole portion 65 extends toward the other tube end 61B of the bubble tube main body 61 while increasing in diameter, and opens at the other tube end 61B of the bubble tube main body 61 .

The ejection throttle hole portion 66 is arranged between the screw hole portion 64 and the wide-angle hole portion 65, as shown in FIGS. 23(b) and 24(b). The ejection throttle hole portion 66 is arranged concentrically with the wide-angle hole portion 65 and opens to the wide-angle hole portion 65 . The ejection throttle hole portion 66 extends from the wide-angle hole portion 65 toward the screw hole portion 64 in the direction E of the cylinder center line e of the bubble cylinder main body 61 .

The relay hole portion 67 is arranged between the ejection throttle hole portion 66 and the screw hole portion 64, as shown in FIG. 24(b). The relay hole portion 67 is arranged concentrically with the wide-angle hole portion 65 (the ejection throttle hole portion 66 ) and communicates with the ejection throttle hole portion 66 . The relay hole portion 67 expands in diameter from the ejection throttle hole portion 66 and extends toward the screw hole portion 64 in the direction E of the cylinder center line e of the bubble cylinder main body 61 .

Each introduction hole portion 68 is arranged between the relay hole portion 67 and the screw hole portion 64, as shown in FIG. The introduction holes 68 are arranged at regular intervals in the circumferential direction of the bubble cylinder main body 61 . Each introduction hole portion 68 extends in the direction E of the cylinder center line e of the bubble cylinder body 61 and opens (communicates) with the relay hole portion 67 and the screw hole portion 64 .

As shown in FIGS. 23 and 24(b), the threaded portion 63 is arranged on the other tube end 61B side of the bubble tube main body 61. As shown in FIG. The threaded portion 63 is formed on the outer periphery of the bubble cylinder main body 61 .

As shown in FIGS. 3 and 4, the bubble generator Y inserts the threaded portion 63 of the bubble tube body 61 into the second threaded tube portion 22 of the second flow tube body 7, and inserts the threaded portion 63 into the second threaded tube body 7. It is screwed (screwed) into the threaded cylinder portion 22 and connected (coupled) to the bubble stirrer X (second flow cylinder main body 7).
Thereby, in the bubble generator Y, the bubble generation hole 62 is arranged concentrically with the hole center line a of the flow hole 3 . In the bubble generator Y, the ejection throttle hole portion 66 communicates with the inlet 4 through the wide-angle hole portion 65 , the inside of the second threaded cylinder portion 22 , and the flow inlet hole portion 30 .

As shown in FIGS. 1 to 4, 12 and 13, the bubble agitator X is connected (coupled) to the outflow pipe RP, and the bubble generator Y is connected (coupled) to the inflow pipe EP.
As shown in FIGS. 3, 4, and 123, the outflow pipe RP has one pipe end side screwed (screwed) into the first threaded cylinder portion 9 of the first flow pipe main body 6 so that the flow is It is connected (coupled) to the cylinder 1 .
As shown in FIGS. 3, 4, and 13, the inflow pipe EP is connected to the bubble cylinder main body 61 by screwing one pipe end side into the screw hole portion 64 of the bubble cylinder main body 61. (linked).

In FIGS. 12 and 13, water (or hot water) in which air bubbles are mixed and dissolved, for example, pressurized water AW in which air bubbles are mixed and dissolved (hereinafter referred to as “air bubble water AW”) flows into the inflow pipe EP. be done. The bubble water AW flows into the bubble generation hole 62 of the bubble generator Y through the inflow pipe EP.

In the bubble generator Y, as shown in FIG. 12, the bubbled water AW flows from each introduction hole 68 into the relay hole 67. As shown in FIG. The bubbled water AW that has flowed into the relay hole portion 67 is ejected from the ejection throttle hole portion 66 to the wide-angle hole portion 65 .
In the bubble generator Y, the bubbly water AW that has flowed into the ejection throttle hole portion 66 flows through the ejection throttle hole portion 66 while increasing and reducing the flow velocity, and is ejected to the wide-angle hole portion 65 . The jet throttle hole portion 66 flows the bubble water AW while increasing the flow velocity and reducing the pressure, and jets the bubble water AW to the wide-angle hole portion 65 .

When the bubbly water AW is jetted from the jet throttle hole portion 66 to the wide-angle hole portion 65, the flow velocity of the bubbly water AW is reduced, the pressure of the bubbly water AW is increased, and the turbulent flow is generated.
The bubbles in the bubbled water AW are pulverized (sheared) into microbubbles and ultra-fine bubbles by the venturi effect and the turbulent flow of the bubbled water AW. The microbubbles and ultrafun bubbles pulverized (sheared) by the bubble generator Y are mixed and dissolved in water to form fine bubble water BW.

The fine bubble water BW generated by the bubble generator Y, as shown in FIG. is flowed (injected) into the flow hole 3 of the

As shown in FIG. 12, the fine bubble water BW is flowed (injected) from the inlet 4 into the first (odd-numbered) first turbulent flow cylinder 2X. The fine bubble water BW passes through the inlet 4 of the flow tube 1 and is jetted into the turbulent space CA from one tube end 2a of the first turbulent flow tube 2X to become a turbulent flow. collides with the first turbulent flow cylinder 2X and becomes turbulent.
In the turbulent flow space CA of the first first turbulent flow cylinder 2X, the fine bubble water BW is agitated by turbulent flow and collision, and the bubbles in the fine bubble water BW are stirred by turbulent flow and the first turbulent flow. By the collision of the cylinder 2X, it is further pulverized (sheared) into microbubbles and ultrafan bubbles.
The microbubbles and ultrafine bubbles crushed (sheared) by the first turbulent flow cylinder 2X are mixed and dissolved in the ultrafine water BW to form fine bubble water CW.
The mixing and melting amount of microbubbles and ultrafan bubbles in the fine bubble water CW generated in the first turbulent flow cylinder 2X is the amount of microbubbles and ultrafan bubbles in the fine bubble water BW generated in the bubble generator Y. It will be in a state where the amount is greater than the amount of mixing and melting.
As a result, the fan bubble mixture/melting concentration εc of the fan bubble water CW becomes higher than the fan bubble mixture/melting concentration εb of the fan bubble water BW (εc>εb).

As shown in FIGS. 11 and 12, part of the fine bubble water BW that has flowed into the turbulent flow space CA of the first first turbulent flow cylinder 2X enters the turbulent flow of the first first turbulent flow cylinder 2X. It flows out from the space CA through each first flow hole 46 to the flow hole 3 (guide flow path Q). In the first first turbulent flow cylinder 2X, part of the fine bubble water BW passes through each first circulation hole 46 and flows into the hole inner circumference 3A of the flow hole 3 and the first first turbulent flow cylinder 2X. It flows out into the guide channel Q between the outer circumference 2c (first flow gap δA) and between the outer circumference 2c (second flow gap δb) of each of the second straightening protrusions 27 and the first first turbulent flow cylinder 2X. .

In the first first turbulent flow cylinder 2X, as shown in FIGS. 10 and 12, part of the fine bubble water CW flows from the turbulent flow space CA of the first turbulent flow cylinder 2X into the respective first outflow throttle holes. 47 to flow out into the flow holes 3 (guide flow paths Q), and mixed (joined) with the fine bubble water BW flowed out into the flow holes 3 (guide flow paths Q) through the respective first flow holes 46. and becomes fan bubble water DW.

As shown in FIGS. 10 to 12, the fan bubble water DW is distributed through the second rectifying projections 27 of the second flow cylinder main body 7, the outer circumference 2c of the first first turbulent flow cylinder 2X, and the inner circumference of the flow hole 3. 3A, and in the direction A of the hole center line a of the flow hole 3, from each first outflow throttle hole 47 to the hole inner circumference 3A of the flow hole 3, each second straightening projection 27, and the first first turbulence Along the outer circumference 2c of the fluid cylinder 2X, it flows through the guide channel Q toward the second (even-numbered) second turbulent flow cylinder 2Y.
As a result, the fan bubble water DW becomes a laminar flow in the direction A of the hole center line a of the flow hole 3 and flows through the guide flow path Q toward the second second turbulent flow cylinder 2Y.

In the first turbulent flow cylinder 2X, as shown in FIGS. 12 and 13, the fan bubble water CW flows from the injection throttle hole 45 into the turbulent flow space CA of the second turbulent flow cylinder 2Y. be jetted. In the first turbulent flow cylinder 2X, the fan bubble water CW that has flowed into the injection throttle hole 45 flows through the injection throttle hole 45 while increasing the flow velocity and reducing the pressure, and flows into the second turbulent flow cylinder 2Y. is injected into the turbulent space CA of
In the first 1 turbulent flow cylinder 2X, the injection throttle hole 45 increases the flow velocity of the fine bubble water CW and decreases the pressure to flow the fan bubble water CW into the turbulence of the second turbulent flow cylinder 2Y. Inject into flow space CA.

In the first turbulent flow cylinder 2X, when the fine bubble water CW is injected from the injection throttle hole 45 into the turbulent space CA of the second turbulent flow cylinder 2Y, part of the fine bubble water DW is As shown in FIGS. 9, 12 and 13, from the guide channel Q, it flows into the turbulent flow space CA of the second second turbulent flow cylinder 2Y through each of the second circulation holes 56, and flows into the second turbulent flow space CA. It is mixed (joined) with the fine bubble water CW jetted into the turbulent space CA of the second turbulent flow cylinder 2Y.

When the fine bubble water CW is injected from the injection throttle hole 45 of the first turbulent flow cylinder 2X into the turbulent flow space CA of the second turbulent flow cylinder 2Y, the fine bubble water CW is as shown in FIG. As shown, the flow speed is decelerated, the pressure becomes turbulent, and the fine bubble water CW generates negative pressure due to the venturi effect.
The fine bubble water CW injected into the second turbulent flow cylinder 2Y and the fine bubble water DW flown into the second turbulent flow cylinder 2Y are turbulent as shown in FIG. In the flow space CA, it collides with the second turbulent flow cylinder 2Y and becomes turbulent.
In the turbulent flow space CA of the second second turbulent flow cylinder 2Y, the fine bubble water CW and the fine bubble water DW are agitated by turbulence and collision, and the bubbles in the fine bubble water CW and the bubbles in the fine bubble water DW The bubbles are further pulverized (sheared) into microbubbles and ultra-fine bubbles by the venturi effect, turbulence, and collision with the second turbulent cylinder 2Y. The microbubbles and ultra-fine bubbles pulverized (sheared) by the second second turbulent flow cylinder 2Y are mixed and dissolved in the fine bubble water CW and the fine bubble water DW to form the fan bubble water EW.
The amount of microbubbles and ultra-fun bubbles mixed in and dissolved in the fine bubble water EW generated in the second turbulent flow cylinder 2Y is the same as that of the fine bubble water CW generated in the first turbulent flow cylinder 2X. Bubbles and ultra-fine bubbles are mixed, and the amount is greater than the dissolved amount.
As a result, the fan bubble mixture/melting concentration εe of the fan bubble water EW is higher than the fan bubble mixture/melting concentration εc of the fan bubble water CW (εe>εc).

As shown in FIGS. 12 and 13, the fine bubble water DW is distributed from the second second turbulent flow cylinder 2Y to the third (odd number/final) in the direction A of the hole center line a of the flow hole 3. flows through the guide channel Q toward the first turbulent flow cylinder 2X.
As shown in FIGS. 8, 9 and 13, the fine bubble water DW is distributed through the inner circumference 3A of the flow hole 3, the first rectifying projections 14 of the first flow tube main body 6, and the second turbulent flow tube. 2Y, along the hole inner circumference 3A of the flow hole 3, the first straightening projections 14 and the outer circumference 2c of the second second turbulence cylinder 2Y, the second second turbulence cylinder It flows through the guide channel Q toward each second outflow throttle hole 57 of the body 2Y.
As a result, the fine bubble water DW becomes a laminar flow in the direction A of the hole center line a of the flow hole 3, and flows through the guide flow channel Q toward the third first turbulent flow cylinder 2X (outflow port 5). flow.

In the turbulent flow space CA of the second turbulent flow cylinder 2Y of No. 2, as shown in FIGS. Q), and mixed (joined) with the fine bubble water DW flowing through the guide channel Q to form fine bubble water FW.

As shown in FIGS. 8 and 13, the fine bubble water FW is distributed through the first straightening projections 14 of the first flow tube main body 6, the outer circumference 2c of the second second turbulent flow tube 2Y, and the inside of the flow hole 3. In the direction A of the hole center line a of the flow hole 3, the turbulent flow flows from each first outflow throttle hole 57 of the second second turbulent flow cylinder 2Y to the hole inner circumference 3A of the flow hole 3, each Along the first rectifying projection 14 and the outer circumference 2c of the second second turbulent flow cylinder 2Y, it flows through the guide channel Q toward each first outflow throttle hole 47 of the third first turbulent flow cylinder 2X. .
As a result, the fine bubble water FW becomes a laminar flow in the direction A of the hole center line a of the flow hole 3 and flows through the guide channel Q toward the third first turbulent flow cylinder 2X.

As shown in FIGS. 7 and 13, part of the fine bubble water FW passes from the guide flow path Q through each first flow hole 46 of the third first turbulent flow cylinder 2X to the third first It flows into the turbulent flow space CA of the turbulent flow cylinder 2X and becomes turbulent, and collides with the third (final) first turbulent flow cylinder 2X to become turbulent.
In the turbulent flow space CA of the third first turbulent flow cylinder 2X, the fine bubble water FW is agitated by turbulent flow and collision, and the bubbles in the fan bubble water FW are stirred by the turbulent flow and the third first turbulent flow. By the collision of the cylindrical body 2X, it is further pulverized (sheared) into microbubbles and ultrafine bubbles. The microbubbles and ultra-fine bubbles crushed (sheared) by the third first turbulent flow cylinder 2X are mixed and dissolved in the fine bubble water FW to form the fine bubble water GW.

The amount of microbubbles and ultra-fine bubbles mixed in and dissolved in the fine bubble water GW generated in the first turbulent flow cylinder 2X, which is the third, is the amount of microbubbles in the fine bubble water EW generated in the second turbulent flow cylinder 2Y. Bubbles and ultra-fine bubbles are mixed, and the amount is greater than the dissolved amount.
As a result, the fan bubble mixture/melting concentration εg of the fan bubble water GW becomes higher than the fan bubble mixture/melting concentration εe of the fan bubble water EW (εg>εe).

In the turbulent flow space CA of the third first turbulent flow cylinder 2X, as shown in FIGS. (Guiding channel Q), and mixed (joined) with fine bubble water FW flowing through the guiding channel Q to form fine bubble water HW.

As shown in FIGS. 6 and 13, the fine bubble water HW is distributed through the first straightening projections 14 of the first flow tube main body 6, the outer circumference 2c of the third first turbulent flow tube 2, and the inside of the flow hole 3. In the direction A of the hole center line a of the flow hole 3, the turbulent flow flows from each first outflow throttle hole 47 of the third first turbulent cylinder 2X to the hole inner circumference 3A of the flow hole 3, each third It flows toward each guide outflow passage P (each outflow guide groove 12) along the outer circumference 2c of the first straightening projection 14 and the second first turbulent flow cylinder 2X.
As a result, the fine bubble water HW becomes a laminar flow in the direction A of the hole center line a of the flow hole 3 and flows through the guide flow path Q toward each outflow guide path P (outflow port 5).

In the turbulent space CA of the third first turbulent flow cylinder 2X, as shown in FIGS. inside, and flows out from the outflow port 5 to the outflow pipe RP.
In the third first turbulent flow cylinder 2X, the fine bubble water GW that has flowed into the injection throttle hole 45 flows through the injection throttle hole 45 while increasing the flow velocity and reducing the pressure, and flows through the flow outflow hole of the first flow cylinder main body 6. It is injected to the part 17 and the outflow pipe PR.
In the third first turbulent flow cylinder 2X, the fine bubble water GW is caused to flow through the injection throttle hole 45 while increasing the flow velocity and reducing the pressure, so that the fine bubble water GW flows through the flow outflow hole portion of the first flow cylinder main body 6. 17 (outlet 5) and outflow pipe PR.

In the third first turbulent flow cylinder 2X, when the fine bubble water GW is injected from the injection throttle hole 45, the fan bubble water HW flowing through the guide flow path Q is, as shown in FIGS. It flows through the guide channel Q along the other tube end 2b of the first turbulent flow tube 2X, and flows into each guide outflow channel P. As shown in FIG. The fan bubble water HW flows through each guiding and outflow passage P to the flow outflow hole portion 17 of the first flow tube main body 6 and is mixed (merged) with the fine bubble water GW jetted from the jet throttle hole 45 . be.

When the fine bubble water GW is injected from the injection throttle hole 45 of the third first turbulent flow cylinder 2X into the flow outflow hole portion 17 of the first flow cylinder main body 6, the fine bubble water GW is as shown in FIG. , the flow velocity is decelerated, the pressure becomes turbulent, and the fan bubble water GW generates a negative pressure due to the venturi effect.
The fine bubble water GW and the fine bubble water HW are agitated by turbulent flow in the flow outflow hole portion 17 of the first flow tube main body 6, and the air bubbles of the fan bubble water GW and the air bubbles of the fan bubble water HW are generated by the Venturi effect and the fine air bubbles. The turbulent flow of the bubble water GW further pulverizes (shears) it into microbubbles and ultrafine bubbles. The microbubbles and ultra-fine bubbles crushed (sheared) in the flow outflow hole portion 17 are mixed and dissolved in the fine bubble water GW and the fan bubble water HW to form the fan bubble water JW.

The fine bubble water JW generated in the flow outflow hole portion 17 of the first flow tube main body 6 is mixed with the microbubbles and the ultra-fan bubbles, and the amount of melting is the fine bubble water generated in the third first turbulent flow tube 2X. The amount of GW microbubbles and ultra-fine bubbles mixed and melted is increased.
As a result, the fan bubble mixture/melting concentration εj of the fan bubble water JW is higher than the fan bubble mixture/melting concentration εg of the fan bubble water GW (εj>εg).

The fine bubble water JW is discharged from the outlet 5 of the flow tube 1 to the outflow pipe RP, as shown in FIG.

In the bubble agitator X, the fan bubble water BW is flowed (injected) into the first (odd-numbered) first turbulent flow cylinder 2X (turbulent space CA), A turbulent flow occurs within the body 2X. Inside the first first turbulent flow cylinder 2X (turbulent flow space CA), part of the turbulent fine bubble water CW passes through each first outflow throttle hole 47 and flows through the flow hole 3 and the first turbulent flow hole 3. It flows out into the guide channel Q (the respective flow gaps δA and δB) between the fluid cylinders 2X. The fine bubble water CW (fine bubble water DW) that has flowed out from the inside of the first turbulent flow cylinder 2X (turbulent flow space CA) into the guide flow path Q flows into the layer in the direction A of the hole center line a of the flow hole 3. It becomes a flow and flows through the guide channel Q toward the second (even-numbered) second turbulent flow cylinder 2Y. Part of the fan bubble water DW flowing through the guide channel Q passes through each of the second circulation holes 56 of the second turbulent flow cylinder 2Y and enters the second second turbulent flow cylinder 2Y (turbulent flow space CA) and become turbulent in the second second turbulent flow cylinder 2Y (turbulent flow space CA). In the second (even-numbered) second turbulent flow cylinder 2Y (turbulent flow space CA), the turbulent fine bubble water EW passes through the second outflow throttle hole 57 and flows through the flow holes 3 and the second It flows out into the guide channel Q between the second turbulent flow cylinders 2Y. The fine bubble water EW (fine bubble water FW) that has flowed out from the second second turbulent flow cylinder 2Y (turbulent flow space CA) into the guide flow path Q flows in the direction A of the hole center line a of the flow hole 3. It becomes a laminar flow and flows through the guide channel Q toward the third (odd-numbered) first turbulent flow cylinder 2X. Part of the fan bubble water FW flowing through the guide channel Q passes through the first circulation holes 46 of the third first turbulent flow cylinder 2X, and flows into the third first turbulent flow cylinder 2X (turbulent flow space CA), and becomes turbulent in the third first turbulent flow cylinder 2X (turbulent flow space CA).
In this way, the bubble stirrer X repeats the flow of the fine bubble water in the order of turbulent flow and laminar flow, thereby pulverizing (shearing) the bubbles in the fine bubble water.
As a result, in the bubble agitator X, the turbulent flow of the fine bubble water is turbulent by the turbulent flow cylinders 2X and 2Y, the flow holes 3 (hole inner circumference 3A), the first rectifying protrusions 14, and the second rectifying protrusions 27. , repeatedly in order of laminar flow to pulverize (shear) the air bubbles in the fan bubble water, so that the fan bubble water JW in which fine bubbles are mixed and dissolved at a higher concentration than the fan bubble water BW generated by the bubble generator Y is generated. can flow out.

In the bubble stirrer X, each of the turbulent flow cylinders 2 (first and second turbulent flow cylinders 2X, 2Y) is plural in the direction A of the hole center line a of the flow hole 3, and arranged in even rows (even/ even number), and a configuration in which they are arranged adjacently in parallel can also be adopted. When the turbulent flow cylinders 2 are arranged in even-numbered rows, the last (even-numbered) turbulent flow cylinder 2 from the inlet 4 side (inflow port 4) becomes the second turbulent flow cylinder 2Y. The final (even-numbered) second turbulent flow cylinder 2Y is arranged with the other cylinder end 2b in contact with each of the first retainer pieces 13 in the same manner as described with reference to FIG. A plurality of guide outflow passages are formed between each outflow guide groove 12 of the main body 6 and the other cylinder end 2b.

INDUSTRIAL APPLICABILITY The present invention is most suitable for discharging fan bubble water in which fan bubbles are mixed and dissolved at a high concentration.

X bubble stirrer 1 flow cylinder 2 turbulent flow cylinder 2X first turbulent flow cylinder 2Y second turbulent flow cylinder 3 flow hole 4 inlet 5 outlet 45 injection throttle hole 46 first circulation hole 57 second outlet throttle hole

Claims (3)

a flow cylinder having a flow hole, an inlet opening to the flow hole, and an outlet opening, and allowing fine bubble water to flow into the flow hole from the inlet and to flow out from the outlet;
a plurality of turbulent cylinders formed in a cylinder with one cylinder end open ;
Each of the turbulence cylinders,
positioned in the flow hole between the inlet and the outlet;
A plurality of cylinders are stacked in the direction of the center line of the flow hole with one cylindrical end facing the inlet side,
arranged concentrically with the flow hole with a flow gap on the inner circumference of the hole of the flow hole,
The odd-numbered turbulent flow cylinders from the inlet side,
an injection throttle hole penetrating the other end of the turbulent flow cylinder of an odd number in the direction of the hole centerline of the flow hole;
a circulation hole disposed on one cylinder end side, penetrating through the odd-numbered turbulent flow cylinders and opening into the flow gap;
The other cylinder end is brought into contact with one of the even-numbered turbulent flow cylinders adjacent to the even-numbered turbulence cylinders from the inlet side, and block the end of the tube of
The even-numbered turbulent flow cylinders from the inlet side are
An outflow throttle hole is arranged between the ends of the even-numbered turbulence cylinders at a hole distance from one end of the cylinder, penetrates the even-numbered turbulence cylinders, and opens into the flow gap. have
The other cylinder end is brought into contact with one cylinder end of the adjacent odd-numbered turbulent cylinders from the inlet side so that one of the adjacent odd-numbered turbulent cylinders block the end of the tube
A bubble agitator characterized by: a flow cylinder having a flow hole, an inlet opening to the flow hole, and an outlet opening, and allowing fine bubble water to flow into the flow hole from the inlet and to flow out from the outlet;
a plurality of turbulent cylinders formed in a cylinder with one cylinder end open;
Each of the turbulence cylinders,
positioned in the flow hole between the inlet and the outlet;
A plurality of rows are arranged adjacent to each other in the direction of the hole center line of the flow hole with one cylindrical end facing the inlet side,
arranged concentrically with the flow hole with a flow gap on the inner circumference of the hole of the flow hole,
The odd-numbered turbulent flow cylinders from the inlet side,
an injection throttle hole penetrating the other end of the turbulent flow cylinder of an odd number in the direction of the hole centerline of the flow hole;
a circulation hole disposed on one cylinder end side, penetrating through the odd-numbered turbulent flow cylinders and opening into the flow gap;
The other cylinder end is brought into contact with one of the even-numbered turbulent flow cylinders adjacent to the even-numbered turbulence cylinders from the inlet side, and block the end of the tube of
The even-numbered turbulent flow cylinders from the inlet side are
An outflow throttle hole is arranged between the ends of the even-numbered turbulence cylinders at a hole distance from one end of the cylinder, penetrates the even-numbered turbulence cylinders, and opens into the flow gap. have
The other cylinder end is brought into contact with one cylinder end of the adjacent odd-numbered turbulent cylinders from the inlet side so that one of the adjacent odd-numbered turbulent cylinders block the end of the tube
A bubble agitator characterized by: a flow cylinder having a flow hole, an inlet opening to the flow hole, and an outlet opening, and allowing fine bubble water to flow into the flow hole from the inlet and to flow out from the outlet;
a first turbulent cylinder formed in a cylindrical body with one cylinder end open;
a second turbulent cylinder formed in a cylinder with one cylinder end open and the other cylinder end closed;
The first and second turbulence cylinders are
arranged in the flow hole between the inflow port and the outflow port with one cylindrical end facing the inflow port side;
alternately arranged from the inlet side toward the outlet side in the direction of the hole center line of the flow hole,
arranging the first turbulent flow cylinders in odd-numbered positions from the inlet side, and arranging the second turbulent flow cylinders in even-numbered positions from the inlet side;
arranged concentrically with the flow hole with a flow gap on the inner circumference of the hole of the flow hole,
The odd-numbered first turbulent cylinders are
an injection throttle hole penetrating the other cylindrical end of the odd-numbered first turbulent flow cylinder in the direction of the hole center line of the flow hole;
a circulation hole disposed on one cylinder end side, penetrating through the odd-numbered first turbulent flow cylinders and opening into the flow gap;
The other cylinder end is brought into contact with one cylinder end of the adjacent second turbulence cylinders among the even-numbered second turbulence cylinders, and one cylinder end of the two adjacent turbulence cylinders is pressed. occluded,
The even-numbered second turbulent flow cylinders are
Disposed between the ends of the even-numbered second turbulent flow cylinders at a hole interval from one end of the cylinder, penetrates the even-numbered second turbulent flow cylinders, and enters the flow gap having an open outflow throttle hole,
The other cylinder end is brought into contact with one cylinder end of the adjacent first turbulence cylinders among the odd-numbered first turbulence cylinders, and the other cylinder of the adjacent first turbulence cylinders close the ends
A bubble agitator characterized by:

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