KR101475508B1 - fine bubble generator - Google Patents

Abstract

The present invention relates to a bubble generation device having a new structure in which a lot of bubbles are effectively generated. The bubble generation device includes: water tubes (13, 14) in which water flows therein; a pump (20) having an introduction hole (41a) and a discharge part and connected to central portions of the water tubes (13, 14); an air supply tube (30) connected to the water tubes (13, 14) so that the air supply tube (30) is disposed at a front side of the pump (20), the air supply tube (30) supplying air to the water flowing through the water tubes (13, 14); and a bubble generation unit (40) connected to the water tubes (13, 14) so that the bubble generation unit (40)n disposed between the pump (20) and the air supply tube (30) to mix the water flowing through the water tubes (13, 14) with the air supplied to the water through the air supply tube (30), thereby generating bubbles in the water, wherein, when the pump (20) operates, external air is automatically supplied into the water tubes (13, 14) through the air supply tube (11) by vacuum formed in the water tubes (13, 14). Thus, it is unnecessary to forcibly supply the air into the water by using a separate air compressor. Also, bubbles enough to be supplied to a tube (8) having a large diameter connected to a boiler (7) used in a large-scaled factory may be effectively generated.

Description

[0001] The present invention relates to a fine bubble generator,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bubble generator having a new structure capable of effectively producing a large number of bubbles.

Recently, it has been known that when a large amount of air bubbles are formed in the water, bubbles burst, resulting in strong cleaning and disinfecting power.

Therefore, in recent years, various types of bubble generating devices capable of producing water, that is, water bubbles, in which a minute amount of bubbles have been formed have been developed and widely used.

1 shows a general example of such a bubble generator. The bubble generator includes a water tank 1 in which water is stored, a water discharge pipe 2 whose both ends are in the water tank 1, A bubble generating unit 3 connected to the bubble generating unit 3 so as to be positioned at a midpoint between the water tank 1 and the bubble generating unit 3 to supply water stored in the water tank 1 to the bubble generating unit 3, A pump 4 for supplying the generating unit 3 and an air supply means 5 connected to the bubble generating unit 3 and supplying air to the water passing through the bubble generating unit 3. [

Although the water to be stored in the water tank 1 is generally water, various kinds of water may be used depending on the application.

The bubbling unit 3 has a plurality of partition walls 3a formed therein so that the air supplied by the air supply unit 5 and the water supplied by the pump 4 collide with the partition wall 3a So that minute bubbles are generated inside the water.

The air supply means 5 uses a general air compressor.

Therefore, when high-pressure air and water are supplied to the bubble generating unit 3 using the air supply unit 5 and the pump 4, water and air are mixed with each other inside the bubble generation unit 3 , A number of bubbles containing a large number of minute bubbles are produced.

The bubble generating device thus constructed is connected to the boiler pipe and is used to remove the scale attached to the inside of the pipe, or to supply a place where sterilization is necessary, such as a fish farm, to remove bacteria or microorganisms.

On the other hand, in this bubble generating device, high-pressure water is supplied to the bubble generating unit 3 by the pump 4.

Therefore, in order to supply air to the water passing through the bubble generating unit 3 using the air supply means 5, air must be supplied at a very high pressure.

Therefore, there has been a problem that the output of the bubble generating unit 3, that is, the air compressor, must be very large.

Particularly, in the case of a boiler used in a large-scale plant, the diameter of the pipe is large, and in order to remove the scale of the pipe by supplying water containing bubbles to the pipe, a large amount of bubbles must be supplied. It is difficult to supply a large amount of air enough to make a sufficient number of bubbles. Therefore, it is practically difficult to remove the scale of a large-capacity boiler or a pipe connected to such a boiler by using the number of bubbles produced by the bubbler.

Therefore, there is a need for a new method to solve such a problem.

On the other hand, recently, it has been known that, in addition to colliding water and air with the partition wall 3a, air and water are mixed with water even when the air and water are rotated at a high speed, and fine bubbles are generated. A bubble generating unit for producing water has been developed and used.

Patent Document 10-2013-0078330 Patent No. 10-0577830

SUMMARY OF THE INVENTION It is an object of the present invention to provide a bubble generator having a novel structure capable of efficiently forming a large number of bubbles.

In order to accomplish the above object, the present invention provides a water treatment system comprising: a water pipe (13,14) having water flowing therein; a pump (20) having an inlet and an outlet and connected to an intermediate portion of the water pipe (13,14) A water supply pipe 30 connected to the water pipes 13 and 14 to be positioned in front of the pump 20 to supply air to the water flowing through the water pipes 13 and 14, 14 which are connected to the water pipes 13 and 14 so as to be located at the rear of the water pipe 30 and mix the water flowing through the water pipes 13 and 14 with the air supplied to the water through the water pipe 30, And a generating unit (40).

According to another aspect of the present invention, the air supply tube (30) extends in the vertical direction and the lower end thereof includes a supply portion (31) extending into the water pipe (13, 14) And an extension portion (32) extending in a direction in which water in the water pipe (13, 14) flows in the bubble generating device.

According to another aspect of the present invention, the bubble generating unit (40) includes a housing (41) formed in the form of a circular tube extending to one side and having an inlet (41a) and an outlet (41b) And the induction blades (42, 43), which are formed in the shape of a coil wound in the direction of the arrow, are provided inside the housing (41).

According to another aspect of the present invention, the guide blades 42 and 43 are formed by bending a metal plate in a spiral shape, and are fixed to the inside of the housing 41 so that the circumferential surface thereof closely contacts the inner circumferential surface of the housing 41, And a linear passage (44) through which water and air pass is formed in the center of the housing (41).

The induction blades 42 and 43 may include a primary induction blade 42 positioned at the inlet 41a of the housing 41 and an outlet 41b of the housing 41. [ The primary induction blade 42 and the secondary induction blade 43 are disposed so as to be spaced apart from each other inside the housing 41 so as to form a space therebetween, , And the primary induction blade (42) and the secondary induction blade (43) are configured to draw a spiral in mutually opposite directions.

According to another aspect of the present invention, a plurality of through holes 47a are formed to penetrate the front and rear surfaces, and are provided inside the housing 41 so as to block the front of the induction blades 42 and 43, A primary diaphragm 47 forming a primary chamber 45 located in front of the induction blades 42 and 43 in the interior of the primary chamber 45 and a plurality of balls The bubble generating device according to claim 1,

According to another aspect of the present invention, a plurality of through holes 48a are formed through the front and rear surfaces and are provided inside the housing 41 so as to block the rear of the induction blades 42 and 43, A secondary partition 46 for forming a secondary chamber 46 located in the rear of the induction blades 42 and 43 in the interior of the secondary chamber 46 and a plurality of balls The bubble generating device according to claim 1,

According to another feature of the present invention, the ball 49 occupies 50 to 60% of the internal volume of the primary or secondary chamber 45, 46, Characterized in that the ball (49) flows inside the primary or secondary chamber (45, 46).

According to another aspect of the present invention, there is provided a water treatment system including a water tank 10 in which water is stored, wherein both ends of the water tube 13, 14 are stored in the water tank 10 and stored in the water tank 10 And water is circulated through the water pipes (13, 14).

A bubble generator according to the present invention includes a water pipe 13, 14 through which water flows, a pump 20 connected to an intermediate portion of the water pipe 13, 14 and having an inlet port 41a and a discharge port, (30) for supplying air to the water flowing through the water pipes (13, 14) in the water pipes (13, 14) so as to be positioned in front of the pump (20) (13, 14) so as to be positioned between the water supply pipes (30), and the water supplied through the water pipes (13, 14) and the air supplied through the water supply pipe And a bubble generating unit 40 for generating air bubbles in the water. When the pump 20 is operated, external air is automatically supplied to the water supply pipe 11 by negative pressure formed in the water pipes 13, To the inside of the water pipes (13, 14).

Therefore, it is not necessary to supply air forcibly to the water by using a separate air compressor, and it is possible to provide a sufficient amount of bubbles to supply the large-diameter pipe 8 connected to the boiler 7 used in a large- It is advantageous to effectively make it.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing a conventional conventional bubble generator,
2 is a configuration diagram showing a bubble generator according to the present invention,
3 is a side cross-sectional view of a bubble generator of a bubble generator according to the present invention,
4 is a side cross-sectional view showing the bubble generating unit of the bubble generator according to the present invention,
FIG. 5 is a plan sectional view showing a cross-section taken along line AA of FIG. 4,
6 and 7 are reference views for explaining the operation of the bubble generating unit of the bubble generating device according to the present invention.
8 is a reference view showing a modified example of the bubble generator according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 to 7 show a bubble generator according to the present invention which is connected to a pipe 8 of a boiler 7 and which is used for removing a scale accumulated in a pipe 8 of a boiler 7 .

2, the bubble generator according to the present invention includes a water tank 10 in which water is stored, water tubes 13 and 14 connected to the water tank 10, A pump 20 connected to an intermediate portion of the water tank 13 for circulating water stored in the water tank 10 through the water pipes 13 and 14, (30) connected to the water pipes (13, 14) and supplying air to the water flowing through the water pipes (13, 14), and water pipes And a bubble generating unit 40 connected to the water pipes 13 and 14 to mix the water flowing through the water pipes 13 and 14 with the air supplied to the water through the air supply pipe 30 to make bubble water.

To explain this in more detail, the water tank 10 is made of a metal material having high strength, and the water to be stored in the water is generally water.

The water tank 10 is provided with a separate water supply pipe 11 connected to a water supply pump 12 at an intermediate portion thereof and connected to the pipe 8 of the boiler 7, So that the number of bubbles stored in the water tank 10 can be supplied to the pipe 8 of the boiler 7.

The water pipes 13 and 14 are made of a general metal tube and are connected at both ends to the water tank 10 so that the water stored in the water tank 10 is repeatedly discharged through the water pipes 13 and 14 As shown in FIG.

The pump 20 uses a general high-pressure centrifugal pump 20 having a suction port and a discharge port for sucking the water into the suction port and discharging the water to the discharge port.

The water pipes 13 and 14 include a primary water pipe 13 for connecting the water tank 10 and the suction port of the pump 20 and an outlet port for the pump 20 and a water tank 10 And when the pump 20 is operated, a negative pressure is generated in the primary water pipe 13 so that the water stored in the water tank 10 flows into the primary water pipe 13, and is then circulated to the water tank 10 through the secondary water pipe 14.

As shown in FIG. 3, the air supply tube 30 is formed of a tube having a diameter smaller than that of the water tubes 13 and 14, and is positioned in front of the bubble generating unit 40, 13 extending in the vertical direction and having a lower end extending through the upper surface of the primary water pipe 13 and extending into the interior of the primary water pipe 13, And an extension part (32) extending in a direction in which the water in the water pipes (13, 14) flows from the lower end of the supply part (31).

At this time, the diameter of the extension portion 32 is set to be 1/5 or more of the primary water pipe 13.

Therefore, when the pump 20 is driven, external air is supplied as water flowing through the primary water pipe 13 through the air supply pipe 30.

That is, when the pump 20 is driven, a negative pressure lower than the atmospheric pressure is generated in the primary water pipe 13, so that external air at atmospheric pressure is introduced into the primary water pipe 13).

Particularly, the branch pipe (30) is provided with an extension part (32) extending in the direction in which the water flows in the primary water pipe (13), and the area through which the water passes in the peripheral part of the extension part .

Therefore, the flow velocity of the water passing through the periphery of the extension portion 32 is increased, and the pressure at the periphery of the extension portion 32 is further lowered by the Bernoulli effect generated at the periphery of the extension portion 32, Is more efficiently supplied to the water flowing through the primary water pipe (13) through the air supply pipe (30).

As shown in FIGS. 4 and 5, the bubble generating unit 40 includes a housing 41 having a circular tubular shape elongated in the up-and-down direction, a coil 41 wound in a spiral direction, And is connected to the middle portion of the primary water pipe 13 so as to be positioned between the pump 20 and the air supply pipe 30.

The housing 41 is formed in a tubular shape having a high strength and has an inlet port 41a and an outlet port 41b connected to the primary water pipe 13 at both longitudinal ends thereof.

The induction blades 42 and 43 have a function of a partition wall for causing water to collide with air introduced into the inlet 41a of the housing 41 and a function of guiding air and water to be advanced while being rotated in a spiral direction A primary induction blade 42 positioned on the inlet 41a of the housing 41 and a secondary induction blade 43 disposed on the outlet 41b of the housing 41, The secondary induction blades 42 and the secondary induction blades 43 are disposed to be spaced apart from each other inside the housing 41 so as to form a space therebetween.

The primary induction blade 42 and the secondary induction blade 43 are formed by bending a metal plate in a spiral shape and are formed by bending the metal plate in a spiral shape so that the circumferential surface of the metal plate is in contact with the inner circumferential surface of the housing 41 And a straight passage 44 through which water and air pass is formed in the center of the housing 41. [

At this time, the primary induction blade 42 and the secondary induction blade 43 are configured to form spirals in mutually opposite directions.

That is, the primary induction blade 42 is formed in a right-handed screw shape, and the secondary induction blade 43 is formed in a left-handed screw shape.

A primary chamber 45 positioned in front of the primary induction blades 42 and a secondary chamber 46 positioned in the rear of the secondary induction blades 43 are disposed in the housing 41, And a plurality of balls 49 are provided in the primary and secondary chambers 45 and 46. [

A primary partition plate 47 is formed in the front of the primary induction blade 42 to form the primary chamber 45. The secondary chamber 41 is provided at the rear of the secondary induction blade 43, And a second diaphragm 48 for forming the second diaphragm 46.

The first and second diaphragms 47 and 48 are fixed to the inside of the housing 41 and are formed with a plurality of through holes 47a and 48a having a diameter smaller than that of the ball 49, 41a are configured to pass through the primary and secondary chambers 45, 46 through the through holes 47a, 48a.

The balls 49 are formed in the shape of a circle having a small diameter and are formed in the primary and secondary chambers 45 and 46 at 50 to 60% of the internal volume of the primary and secondary chambers 45 and 46, So that when water mixed with the air flows through the interior of the primary and secondary chambers 45 and 46, it flows properly within the primary and secondary chambers 45 and 46, To be mixed more finely.

The operation of the thus configured bubble generator will be described below.

The water in the water tank 10 is supplied to the pump 20 through the primary water pipe 13 when the pump 20 is operated with an appropriate amount of water stored in the water tank 10, At this time, due to the negative pressure generated in the primary water pipe 13, the external air is supplied to the water flowing through the primary water pipe 13 through the air supply pipe 30 and mixed And the mixed water and air thus supplied are supplied to the bubble generating unit 40 through the secondary water pipe 13 while being pressed while passing through the pump 20.

6, the water and air supplied to the bubble generating unit 40 are introduced into the interior of the housing 41 through the inlet 41a of the bubble generating unit 40 Thereafter, the air passes through the primary chamber 45, collides with the ball 49, and water and air are mixed first.

At this time, when the water and the air pass through the inside of the primary chamber 45, the ball 49 inside the primary chamber 45 flows and the water and the air are mixed with each other.

The air and water passing through the primary chamber 45 pass through the passage 44 formed by the primary induction blades 42 as shown by the arrows in Figs. 6 and 7, Collides with the respective portions of the induction blade 42 and is rotated in the right screw direction along the inclined surfaces of the primary induction blades 42 so that the air particles are finely chopped and bubble water having a small bubble size is generated.

The bubble count generated while passing through the primary induction blade 42 is stabilized while passing through the space portion and passes through the passage 44 formed by the secondary induction blade 43, Collides with each part of the blade (43) and is rotated in the left screw direction by the inclined surface of the secondary induction blade (43).

Therefore, the size of the bubbles included in the bubble number becomes smaller.

As a result, the water bubbles generated by the small-sized bubbles are passed through the secondary chamber 46, and the size of the bubbles becomes smaller. The bubbles thus generated are supplied to the pump 20 and the secondary water pipe 14 to the water tank 10.

As the operation is continuously repeated, the concentration of the bubble water stored in the water tank 10 is increased, and finally the entire water stored in the water tank 10 is converted into the bubble water.

At this time, the bubbles included in the bubble water generated through the above process have a diameter of 50 μm or less, and the minute bubbles are not easily removed even at the atmospheric pressure, and the bubbles are maintained in the bubbles more than a few minutes.

The scale formed in the pipe 8 can be removed by supplying the bubble water thus generated to the pipe 8 of the boiler 7 through the water supply pipe 11 connected to the water tank 10 .

The bubble generator includes a water pipe (13,14) for flowing water therein, a pump (20) having an inlet (41a) and a discharge part and connected to the middle part of the water pipe (13,14) (30) for supplying air to the water flowing through the water pipes (13, 14) in the water pipes (13, 14) so as to be positioned in front of the pump (20) And the water supplied to the water through the water supply pipe (30) is mixed with the water supplied to the water pipe (13, 14) When the pump 20 is operated, external air is automatically supplied to the water supply pipe 11 by the negative pressure formed in the water pipes 13 and 14. [ To the inside of the water pipes (13, 14).

Therefore, it is not necessary to supply air forcibly to the water by using a separate air compressor, and it is possible to provide a sufficient amount of bubbles to supply the large-diameter pipe 8 connected to the boiler 7 used in a large- It is advantageous to effectively make it.

Particularly, the bubble generating unit 40 is connected to the rear of the pump 20, so that the air and the water are supplied to the bubble generating unit 40 while being passed through the pump 20.

Therefore, there is an advantage that air and water are effectively intermixed while passing through the bubble generating unit 40.

The lower end of the air supply pipe 30 extends in the vertical direction and the lower end of the supply pipe 31 extends into the water pipes 13 and 14. The water pipe 13 And the extension portion 32 extends in the direction in which the water flows in the water tubes 14 and 14 so that the Bernoulli effect is generated in the water flowing in the water tubes 13 and 14 by the extension portion 32, Is more effectively supplied to the inside of the water pipes (13, 14).

The bubble generating unit 40 includes a housing 41 having a circular tubular shape extending to one side and having both an inlet 41a and an outlet 41b at both ends in the longitudinal direction and a coil 41 wound in a spiral direction And guide blades 42 and 43 provided in the housing 41. The water and air introduced into the housing 41 impinge on the guide blades 42 and 43, And is rotated along the inclined surfaces of the blades 42 and 43.

Therefore, it is possible to obtain both the effect of mixing water and air with other objects to be mixed, and the two effects of mixing the water and air with each other while being rotated, so that the size of bubbles contained in the number of bubbles can be further reduced There is an advantage.

Particularly, the induction blades 42 and 43 are formed by bending a metal plate in a spiral shape. The induction blades 42 and 43 are fixed to the inside of the housing 41 so that the circumferential surface thereof closely contacts the inner circumferential surface of the housing 41, The water and the air are guided by the induction blades 42 and 43 while minimizing the resistance generated when the water and the air pass through the induction blades 42 and 43, So that the bubbles are more finely cut by the induction blades 42 and 43. [0064] As shown in Fig.

The induction blades 42 and 43 include a primary induction blade 42 positioned at the inlet 41a of the housing 41 and a secondary induction blade 42 disposed at the outlet 41b of the housing 41. [ And the primary induction blade 42 and the secondary induction blade 43 are spaced apart from each other inside the housing 41 so as to form a space therebetween, The secondary induction blades 42 and the secondary induction blades 43 are configured to form spirals in mutually opposite directions.

Therefore, the water and air rotated to one side while passing through the primary induction blade 42 are stabilized in the space, and then are rotated in the opposite direction while passing through the secondary induction blade 43, There is an advantage that the bubbles can be cut more finely.

Primary and secondary chambers 45 and 46 partitioned by a primary partition plate 47 and a secondary partition plate 48 are formed in the housing 41. The primary and secondary chambers 45 and 46 are provided with a plurality of balls 49 so that water and air passing through the primary and secondary chambers 45 and 46 can be mixed more effectively.

The water pipes 13 and 14 are connected at both ends to a water tank 10 in which water is stored to convert the water stored in the water tank 10 into water bubbles.

Therefore, it is possible to supply a large amount of bubble water to the pipe 8 at a time through the water supply pipe 11 connected to the water tank 10 after manufacturing a large amount of bubble water at a time.

In the present embodiment, the housing 41 is arranged so as to extend in the vertical direction. However, the housing 41 may be arranged to extend in the left-right direction.

The bubble generator 30 is connected to a middle portion of the primary water pipe 13 so as to be positioned in front of the bubble generator unit 40 and extends in the vertical direction and has a lower end connected to the primary water pipe 13 in the direction of flow of the water in the water pipes 13, 14 from the lower end of the supply unit 31, 8, the extension portion 32 is provided at the inlet portion of the primary water pipe 13 so that the primary water pipe 13 is connected to the inlet portion of the primary water pipe 13, May be configured to be inserted into the inlet of the tube (13).

Although the primary induction blade 42 is configured as a right-handed screw and the secondary induction blade 43 is configured as a left-handed screw, the primary induction blade 42 may be configured as a left- And the secondary induction blades 43 may be formed in a right-handed screw shape.

Also, in the case of this embodiment, it is exemplified that it is used to remove the scale accumulated in the pipe 8 of the boiler 7, but the bubble generator according to the present invention can be used for sterilization or various other purposes in addition to descaling .

The water pipes 13 and 14 are connected at both ends to the water tank 10 so that the water stored in the water tank 10 is circulated through the water pipes 13 and 14. However, It is also possible to connect the water pipes 13 and 14 directly to the pipe 8 of the boiler 7 and supply the bubbles generated through the water pipes 13 and 14 directly to the pipe 8 It is possible.

10. Water tank 13,14. Water pipe
20. Pumps
40. Bubble generating unit

Claims (9)

A water pipe 13, 14 through which water flows,
A pump 20 having an inlet and an outlet and connected to a middle portion of the water pipe 13,
(30) connected to the water pipes (13, 14) so as to be positioned in front of the pump (20) and supplying air to the water flowing through the water pipes (13, 14)
(13, 14) so as to be located behind the pump (20) and mixes the water flowing through the water pipes (13, 14) and the air supplied to the water through the air supply pipe And a bubble generating unit (40) for producing bubble water,
The air supply /
And a lower end extending in the up and down direction and extending into the inside of the water pipe (13, 14)
And an extension part (32) extending from the lower end of the supply part (31) in a direction in which the water flows in the water pipes (13, 14).
delete The method according to claim 1,
The bubble generating unit (40)
A housing 41 having a circular tubular shape extending to one side and having inlet 41a and outlet 41b at both ends in the longitudinal direction,
(42, 43) formed in the shape of a coil wound in a spiral direction and provided inside the housing (41).
The method of claim 3,
The induction blades (42, 43) are formed by bending a metal plate in a spiral shape,
And a straight passage 44 is formed in the center of the housing 41 so as to allow water and air to pass therethrough, the passage 41 being fixed to the inside of the housing 41 so that the circumferential surface thereof is in close contact with the inner circumferential surface of the housing 41. [ .
The method of claim 3,
The induction blades (42, 43)
A primary induction blade 42 positioned on the side of the inlet 41a of the housing 41,
And a secondary induction blade (43) provided on the discharge port (41b) side of the housing (41)
The primary induction blade 42 and the secondary induction blade 43 are spaced apart from each other inside the housing 41 so as to form a space therebetween. Wherein the blade (43) is configured to draw a spiral in mutually opposite directions.
The method of claim 3,
A plurality of through holes 47a are formed in the housing 41 so as to pass through the front and rear surfaces of the housing 41 so as to block the front of the induction blades 42 and 43. The induction blades 42 and 43 are provided in the housing 41, , A first chamber (47) forming a primary chamber (45) located in front of the first chamber (43)
And a plurality of balls (49) provided inside the primary chamber (45).
The method according to claim 6,
A plurality of through holes 48a are formed in the housing 41 so as to penetrate the front and rear surfaces of the housing 41 so as to block the rear of the induction blades 42 and 43. The induction blades 42 and 43 are disposed inside the housing 41, A second partition 48 forming a secondary chamber 46 located behind the first and second chambers 43 and 43,
And a plurality of balls (49) provided inside the secondary chamber (46).
8. The method of claim 7,
The ball 49 occupies 50 to 60% of the internal volume of the primary or secondary chamber 45 and 46 so that the ball 49 is rotated by the water passing through the housing 41, Or in the interior of the secondary chamber (45, 46).
The method according to claim 1,
Further comprising a water tank (10) in which water is stored,
Wherein both ends of the water pipes (13, 14) are stored in the water tank (10) so that water stored in the water tank (10) is circulated through the water pipes (13, 14) .

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