KR101588165B1 - Control method of fine water bubble generating apparatus with water screen function and purification function - Google Patents

Abstract

The present invention relates to a fine water bubble generator generating nano or micro size water bubbles (hereafter called fine water bubbles) and, more specifically, to a method for operating a fine water bubble generator with a water screen, generating fine water bubbles for generating a water screen above water, and generating fine water bubbles for purifying water in water.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a water bubble generating device,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a micro-water bubble generating device for generating nano or micro-sized water bubbles (hereinafter referred to as "micro-water bubbles"), and more particularly, And a fine water bubble for purifying water in the water. The present invention also relates to a method of driving a water bubble generator for a water screen.

Due to recent climate change, there is a great deal of green algae in rivers. The algae phenomenon means that the eutrophic lake or the floating algae (phytoplankton) in the slow flow stream are massively multiplied and accumulated on the water surface, thereby transforming the water color significantly into green. This algae phenomenon causes species diversity to disappear in the eutrophicated waters, and one or a small number of blue algae to dominate, causing not only the destruction of the ecosystem of the water body but also the social, economic and environmental problems.

A method of purifying fresh water by injecting a chemical such as aluminum sulfide to remove algae phenomenon or a method of purifying fresh water biologically by spraying loess is being used.

However, the method of injecting chemicals may cause a lot of environmental problems, and there is a problem that a lot of manpower and a lot of time are consumed because a method of injecting loess must be carried out by people on a boat.

In addition, the above-mentioned two methods can prevent the algae phenomenon in advance by a post processing method, and a method for removing the algae phenomenon even when the algae phenomenon occurs is required.

There has been actively developed a washing, cleaning and purging apparatus using micro-sized bubbles, that is, micro-water bubbles in nano and micro units. In general, fine water bubbles are used for decomposing and cleaning dirty materials such as laundry washing and semiconductor cleaning.

However, there has been developed a water bubble generating device for a washing machine, a water purification plant, a semiconductor cleaner, and the like, and it is an object of the present invention to provide a water bubble generating device for purifying fresh water by using a micro-water bubble A concrete fine water bubble generating device is required.

Patent No. 10-0843970

Accordingly, an object of the present invention is to provide a method for generating a micro-water bubble for generating a water screen on a water surface, and a micro-water bubble for purifying water in water, .

According to another aspect of the present invention, there is provided an apparatus for generating a water bubble, the water bubble generator including: a moving space formed inside the moving body so that the moving body can move; an upper portion rising above a predetermined height above the water surface; A movement guide portion arranged to be locked at a predetermined depth or more; And a micro-water bubble generation module that moves up and down along the movement space of the movement guide unit to generate and emit micro-water bubbles in an upper end portion of the movement guide unit or in a water having a depth greater than a predetermined depth, Wherein the module determines whether the water bubble generating event is a water screen function mode or a purifying function mode in the event of occurrence of a micro-water bubble generation event, and moves to an upper end of the movement guide unit in the water screen function mode to spray a micro-water bubble for making a water screen, In the purifying function mode, the water is moved in a water having a depth greater than a predetermined depth along the movement guide unit to spray fine water bubbles into the water.

The movement guide unit includes a screw guide formed to be long along the vertical direction of the moving space; And a water bubble generator guiding part in which a groove is formed so that the micro-water bubble generating module can be moved up and down. When the micro bubble generator is inserted into the moving space, the micro bubble generating module contacts the screw guide, And a screw conveying unit for moving the guide member upward and downward along the guide.

The micro-water bubble generation module includes: a micro-water bubble generation unit for generating micro-water bubbles by receiving water and air, and generating micro-water bubbles; A guide member connected to the fine water bubble generator and reciprocating between an upper end and a lower end of the movement guide unit along the screw guide unit by the screw feed unit connected to the screw guide unit; And a micro-water bubble generating unit for determining whether the micro-water bubble generating event is a water-screen function mode or a purifying function mode when the micro-water bubble generating event is generated, And a control module for controlling the micro-water bubbles for spraying the micro-water bubbles in the water through the micro-water bubble generator in the purifying function mode, .

Wherein the micro-water bubble generating unit comprises: a main pipe including a water supply passage for receiving water and an air supply passage for supplying air; And at least one bubble generating module, which is disposed inside the main tube, generates air, water, reacts and finely pulverizes the water to generate and spray fine water bubbles.

The bubble generation module may include a bubble generator formed in a funnel shape to generate and react with the air and water to generate bubbles; And a sheave for finely grinding the bubbles ejected from the bubble generator while being formed in a fine shape.

The bubble generation module includes an air supply unit configured to rapidly move supplied air; A water supply unit formed at the center of the funnel shape and configured to rapidly move the supplied water; A water pump for supplying water from the water supply passage to the water supply unit; A fan for supplying air from the air supply path to the air supply unit; And a bubble discharging unit formed in the funnel-shaped nip portion and discharging water and air so that water and air discharged through the air supply unit and the water supply unit react with each other to generate bubbles.

The water bubble generator further includes a heater for raising the temperature of the bubble discharge portion of the bubble generator.

The micro-water bubble generator may include at least two bubble generation modules.

And the bubble generator is configured to rotate in a direction opposite to the rotation direction of the sheave.

The control module includes: a pump driving unit connected to the pump and supplying water to the micro-water bubble generating unit; A fan driving unit connected to the fan to supply air to the micro-water bubble generating unit; A motor driving unit connected to the motor for rotating the screw guide to rotate the motor; And a micro-water bubble generating unit for determining whether the micro-water bubble generating event is a water screen function mode or a purification function mode when the micro-water bubble generating event is generated, and in the water screen function mode, And controls the second motor driving unit to move in the water of a predetermined depth or more along the movement guide unit in the purifying function mode, And a control unit for controlling the micro-water bubbles to be sprayed in the water through the micro-water bubble generating unit.

According to another aspect of the present invention, there is provided a method of operating a water bubble generator for a water screen combined with a water screen, the method comprising: determining whether a control module is in a water screen mode or a purge mode; And when the control module determines that the operation mode is the water screen function mode, it moves to the upper end of the movement guide part to spray a fine water bubble for making the water screen, and in the purification function mode, moves the water to a predetermined depth or more along the movement guide part, And a micro-water bubble generating process of spraying the bubble.

The mode determination step may include: a time information obtaining step of obtaining current time information; A mode time determination step of determining whether the obtained current time is a predetermined water screen function execution time or a purification function execution time; And a mode determining step of determining a water screen function mode if the acquired time is the water screen function execution time zone and a cleaning function mode if the time is the cleaning function execution time zone.

Wherein the mode determination step includes: monitoring whether an operation command signal is received through the communication unit; Determining a mode by checking whether the operation command signal is a water screen function execution command or a purification function execution command when the operation command signal is received; And a mode determining step of determining a mode according to the determined mode.

The water bubble generating step may include: a water supplying step of driving the pump to supply the water to the water supplying part of the funnel-shaped bubble generating part; An air supply step of supplying air to the air supply part of the funnel-shaped bubble generating part by driving the fan; And a pulverizing step of finely pulverizing the water bubbles generated by the reaction of air and water supplied from the bubble generator to the air supply unit and the water supply unit by rotating the sheave.

The water bubble generating step may further include a water temperature raising step of raising a temperature of a portion of the air blow-out port of the bubble generator by driving a heater.

The apparatus for generating micro-water bubbles of the present invention can perform both the water screen function and the purge function, so that the efficiency can be improved and the effect of providing a plurality of benefits to people can be obtained.

Further, since the present invention uses a sieve having a high rotation speed, it is possible to produce finer (nano) water bubbles while lowering the production cost of the system.

Further, the present invention can improve the reactivity due to expansion of air by using a heater, so that it is possible to produce a finer water bubble.

In addition, the present invention has the effect of generating finer water bubbles by pulverizing the bubble over various stages.

1 is a side sectional view showing the construction of an apparatus for generating a water bubble in combination with a water screen according to the present invention.
2 is a front view showing a front view of a water-screen-combined micro-water bubble generating apparatus according to the present invention.
3 is a view showing a detailed configuration of a micro-water bubble generating unit of an apparatus for generating a micro-water bubble that serves as a water screen according to the present invention.
4 is a view showing a configuration of a control module of an apparatus for generating a water bubble for a water screen according to the present invention.
FIG. 5 is a flowchart illustrating a method of driving an apparatus for generating a water bubble in a water screen according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a configuration and operation of an apparatus for generating a water bubble and a water bubble according to the present invention will be described with reference to the accompanying drawings, and a method of driving the apparatus will be described.

FIG. 1 is a side sectional view showing the configuration of a water-screen bubble generating micro-water bubble generating device according to the present invention, and FIG. 2 is a front view showing a front view of a water / water bubble producing device according to the present invention. Hereinafter, description will be made with reference to Figs. 1 and 2. Fig.

The apparatus for generating a water bubble for both water screens according to the present invention includes a fine water bubble generating module 400 and a movement guide unit 500.

The movement guide unit 500 is vertically disposed in water such as fresh water. At this time, the movement guide unit 500 is disposed such that the upper part thereof is raised above a certain height above the water surface, and sinks to a certain depth or more into the water. The movement guide unit 500 may be configured to float in the water as described above by a proper buoyancy force. The movement guide unit 500 may be configured to move along the movement guide unit 500 as shown in FIG. It may be fixed. The fixing member 600 may be a steel pipe or the like, or may be a rope or a cable.

The movement guide portion 500 is formed with a space (hereinafter referred to as "moving space") at an inner central portion thereof and at least a bottom portion thereof is formed into a closed tube shape, a screw guide portion 510 is formed in the longitudinal direction of the inner side, And a water bubble generator guiding part 520 for guiding the fine water bubble generating module to be protruded outward in the vertical direction on the surface where the screw guide part 510 is not formed.

 The fine water bubble generation module 400 is divided into a water screen function mode and a purification function mode. The fine water bubble generating module 400 is disposed in the moving space of the movement guide unit 500 and moves up and down along the screw guide unit 510 and the water bubble generator guide unit 520 of the movement guide unit 500 , A micro-water bubble is generated at a specific position according to the mode, and is sprayed into the air or water of the water surface. The micro-water bubble generating module 400 may be configured to be able to be moved to a water of 4 m or more in which no air is supplied.

The fine water bubble generation module 400 includes a fine water bubble generation unit 100, a guide member 200, and a control module 300.

The micro-water bubble generator 100 generates micro-water bubbles of nano or micro and ejects micro-water bubbles. Detailed configuration and operation of the fine water bubble generator 100 will be described in detail with reference to FIG. 3 to be described later.

The guide member 200 is coupled to the micro-water bubble generator 100 so that the micro-water bubble generator 100 can rotate up and down at a predetermined angle, and is rotated by the second motor 303 on one side, The fine water bubble generator 100 is moved up and down from the inside of the guide moving part 500 by including the screw feed part 301 which is brought into contact with the screw guide part 510 to be engaged therewith. Conversely, the screw guide portion 510 of the movement guide portion 500 may be rotated to move the screw conveyance portion 301 along the screw guide portion 510.

The control module 300 is fixed to the inside of the guide member 200 to control the guide member 200 to move up and down from the inside of the guide moving part 500, And controls the vertical movement of the micro-water bubble generator toward the sky or toward the bottom of the water by controlling the vertical angle to control the overall operation related to the generation of the micro-water bubbles.

The configuration and operation of the control module 300 will be described in detail with reference to FIG. 4 to be described later.

3 is a diagram showing a detailed configuration of a micro-water bubble generating unit 100 of an apparatus for generating a micro-water bubble that serves as a water screen according to the present invention.

3, the detailed structure and operation of the micro-water bubble generator 100 will be described. The micro-water bubble generator 100 includes at least one bubble generator module 40 and a main tube 90.

The bubble generating module 40 includes a bubble generator 10 and a sieve 30 and may further include a heater 20 according to an embodiment.

The main pipe 90 according to the present invention includes a water supply path 70 to which water is supplied and an air supply path 80 to which air is supplied. As shown in FIG. 3, the water supply path 70 may be formed at the central portion, and the air supply path 80 may be formed at the inner circumferential surface side. But it could be constructed in reverse. The starting end of the air supply path 80 is connected to the air suction pipe 110 of FIG. 1 and the pump 14 of the water supply path 70 is connected to the water suction pipe 120. And an air supply groove 81 for supplying air from the air supply path 80 to the bubble generating unit 10 and the air supply groove 81 may be constituted by an air injection nozzle . The fan 13 may be formed in the air supply groove 81. In addition, it is preferable that the water supply path 70 is provided with a pump 14 for drawing water up through the water suction pipe 120.

3, the bubble generator 10 is formed into a conical shape, that is, a funnel shape, and has an inner side thereof penetrating to form an air supply passage A water supply unit 12 for supplying water from the water supply path 70 and a discharge port 15 for discharging the supplied water and the air at a higher speed. The discharge port 15 of the air supply unit 11 may be formed as shown in the enlarged view of FIG. The air supply unit 11 may be divided into two or more units 11-1 and 11-2 as shown in FIG. This is to increase the speed of air movement to increase the reactivity.

The sheave 30 finely crushes the bubbles generated by the discharge port 15 of the bubble generator 10 as a sieve as shown in Fig. The sheave 30 is configured to rotate in one direction to more finely divide the bubble. 3, the sheave 30 has a gear 32 formed along the outer circumferential surface of the circular body 31, a third motor 35 for rotating the gear 33 engaged with the gear, As shown in FIG. Reference numeral 34 in the drawing indicates that the gear 33 is rotated by being connected to the gear 33 by the rotation axis of the third motor 35. [

When the temperature is high, the heater 20 increases the reactivity between water and air, and raises the temperature of the reaction zone between water and air at the discharge port 15. [

In addition, the bubble generator 10 of the present invention may be configured to rotate in order to improve the reactivity of water and air. The bubble generator 10 may also be formed in a circular shape so that it can be rotated by gears and motors like the sheave 30 and can be rotated by the air supply passage 80 through the air supply groove 81, The air to be supplied may be configured to enter the side of the air supply part 11 and rotated by the force of the air and water. In addition, it is preferable that the rotation direction of the bubble generator 10 is rotated in a direction opposite to the rotation direction of the sheave 30. This is for activating the motion of the generated bubbles in the direction opposite to the rotation direction of the sheave 30 to finely crush the sheave 30 in the sheave 30.

4 is a view showing a configuration of a control module 300 of an apparatus for generating a water bubble in combination with a water screen according to the present invention. The configuration and operation of the control module 300 will be described below with reference to FIG.

The control module 300 includes a control unit 310, a storage unit 320, a communication unit 330, a pump driving unit 340, a fan driving unit 350, a heater driving unit 360, and a motor driving unit 370.

The controller 310 controls the overall operation of the water-screen-combined micro-water bubble generator according to the present invention. The operation of the control unit 310 will be described in detail with reference to FIG.

The storage unit 320 stores the water screen function mode time and the purge function mode time according to the embodiment of the present invention.

The communication unit 330 performs communication with a remote terminal. The communication unit 330 includes a wired communication unit 332 and a wireless communication unit 331 that perform wired communication with a remote terminal through wired connection and wireless communication. The terminal may be a general wireless or wired control terminal or a smart device such as a smart phone, which is a terminal dedicated to controlling a water bubble generator combined with a water screen. When a smart device such as a smart phone is applied, a control application for controlling a water bubble generator combined with a water screen must be installed in the smart device. The wireless communication unit 331 is a communication device that performs communication through 3G and 4G mobile communication networks And an application server that receives the control command from the application of the smart device and provides the control data to the control module 300.

The pump driving unit 340 is connected to the water pump 14 and drives or turns off the water pump 14 under the control of the control unit 310.

The fan driving unit 350 is connected to the fan 13 and drives or turns off the fan 13 under the control of the control unit 310.

The heater driving unit 360 is connected to the heater 20 and under the control of the control unit 310, supplies the heating current to the heater 20 to heat or turn off the heater 20.

The motor driving unit 370 controls the rotation speed and the direction of the motor by outputting the motor control signal to the motors configured according to the present invention under the control of the control unit 310. [

The motor used according to the present invention includes a first motor 302 for moving the fine water bubble generator 100 up and down to adjust the angle, a second motor 303 for rotating the screw feeder 301, And a third motor 35 for rotating the motor 30. Further, when the motor system is applied as a method of rotating and rotating the bubble generator 10, a fourth motor (not shown) may be further included.

The motor drive unit 370 drives the first motor drive unit 371 that drives the first motor 302, the second motor drive unit 372 that drives the second motor 303, And a third motor driver 373.

FIG. 5 is a flowchart illustrating a method of driving an apparatus for generating a water bubble in a water screen according to the present invention.

Referring to FIG. 5, the control unit 310 obtains the current time by a timer (not shown) provided therein (S111).

If the current time is obtained, the control unit 310 determines whether the current time is the water screen function mode time zone (S113) stored in the storage unit 320, the purifying function mode time zone (S115) (Control signal) is received (S117) to determine whether a micro-water bubble generation event has occurred.

If the obtained time information is the water screen function mode time or the operation command signal received through the communication unit 330 is the water screen function mode operation signal, the control unit 310 drives the second motor 303 to operate the water screen The fine water bubble generator 400 is moved to the upper end of the movement guide unit 500 at step S121 and then the first motor 302 is driven to move the fine water bubble generator 100 upward The angle of the fine water bubble generator 100 is increased (S122).

On the other hand, when the acquired time is the purifying function mode time zone or when the purifying function mode operation command signal is received, the control unit 310 controls the second motor 303 to move the fine water bubble generating module 400 to the water by a predetermined depth or more (S123), the first motor 302 is driven to adjust the angle of the fine water bubble generator 100 appropriately (S124).

When the position of the fine water bubble generation module 400 and the angle of the fine water bubble generation unit 100 are determined as described above, the pump drive unit 340, the fan drive unit 350, the heater drive unit 360, The sheave 30 is rotated by the driving of the water pump 373 to generate a fine water bubble and the air or water is injected (S125).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be easily understood. It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, it is intended to cover various modifications within the scope of the appended claims.

10: bubble generating unit 11: air supply unit
12: water supply unit 13: fan
14: pump 15: outlet
20: heater 30:
40: bubble generating module 70: water supply path
80: air supply path 81: air supply groove
90: main pipe
100: a fine water bubble generating unit 110: an air suction pipe
120: water suction pipe 200: guide member
300: Control module 301: Screw conveying part
302: first motor 303: second motor
310: Control section 320:
330: communication unit 340: pump driving unit
350: Fan driving part 360: Heater driving part
370: motor driving part 400: fine water bubble generating module
500:
510: screw guide 520: water bubble generating part guide part
600: Fixing member

Claims (1)

A mode determining process for determining whether the control module is in the water screen function mode or the purification function mode; And
If the control module determines that the water bubble generating module is in the water screen function mode, the control module moves the water bubble generating module to the upper end of the water surface along the movement guide portion, reacts water and air to generate a water bubble, The fine water bubble generating module is moved in the water of a predetermined depth or more along the movement guide portion to generate a fine water bubble in the water to be sprayed to form fine water bubbles in the water, A water bubble generation process,
The mode determination process includes:
A monitoring step of monitoring whether an operation command signal is received through the communication unit;
Determining a mode by checking whether the operation command signal is a water screen function execution command or a purification function execution command when the operation command signal is received; And
And determining a mode according to the determined mode. The method of claim 1, further comprising: determining a mode according to the determined mode.

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