KR101887201B1 - sterile washing equipment - Google Patents

Abstract

The present invention relates to household ultrasonic washing equipment to reduce deviation of ultrasonic strength, which comprises: an accommodation unit in which washing water and an object to be washed are accommodated; an ultrasonic generation unit providing ultrasonic waves to the washing water accommodated in the accommodation unit; a gas supply unit supplying gas to the washing water accommodated in the accommodation unit; and a control unit controlling operation of the gas supply unit and the ultrasonic generation unit. Moreover, the control unit has a dissolved gas control process controlling the amount of gas contained in the washing water by operating or stopping the gas supply unit.

Description

{Household ultrasonic cleaning apparatus}

TECHNICAL FIELD The present invention relates to a home ultrasonic cleaning apparatus, and more particularly, to a home ultrasonic cleaning apparatus capable of reducing variations in ultrasonic cleaning force.

Household ultrasonic cleaning apparatus is to clean foreign matter, soil or pesticide residues such as fruits, vegetables and dishes used at home.

A conventional ultrasonic cleaning apparatus constitutes an ultrasonic apparatus in a cleaning tank for containing water, and the ultrasonic wave is used to clean fruits, vegetables, tableware and the like contained in the cleaning tank.

Korean Patent Laid-Open Publication No. 10-2010-0037265 (Apr. 9, 2010) discloses an ultrasonic cleaner for cleaning water to be cleaned (20) contained in a cleaning tank by ultrasonic waves. The ultrasonic cleaner includes an electrolytic means The electrolytic means includes an electrode accommodating portion provided inside the washing tub and capable of flowing and discharging the washing water 10, and an anode and a cathode electrode accommodated in the electrode accommodating portion. Such a device can generate a hydroxyl group by a chemical reaction of an oxygen-based active species including a large amount of hydroxide ions generated by electrolysis of the washing water 10 at the same time as the washing power and the sterilizing power by the ultrasonic waves and effectively sterilize various bacteria and viruses in the washing water A tableware, a fruit or a vegetable, and the like.

In addition, in Korean Utility Model Application No. 20-2012-0008720 (published on December 20, 2012), an electrolytic electrode is provided inside a container capable of containing a solution, and further, Wherein a tubular ultrasonic nozzle capable of spraying is installed. The disclosed technique is capable of forming a suitable sterilizing material through electrolysis, and discloses a technique that can be easily used by spraying the sterilizing material to the outside.

Korean Patent Laid-Open Publication No. 10-2009-0097574 (published on Sep. 16, 2009) discloses a "single-wafer ultrasonic cleaning apparatus", which is a single-wafer ultrasonic cleaning apparatus capable of ultrasonic cleaning, rinsing, Which is made of a metal such as stainless steel and has a base having a predetermined thickness of about 1 cm and having a base having a space of a predetermined thickness, A plurality of ultrasonic generators for generating ultrasonic waves of one or more frequencies and a water spraying unit installed on the upper part of the washing tub to rinse the washing water in the washing tub with pure water and to precisely clean the washing water with an aqueous washing water containing detergent A technique capable of washing various kinds of washing water in addition to fruits and vegetables, and rinsing and precise washing of the water spraying part is disclosed There.

Conventional ultrasonic cleaning apparatuses utilize an ionization reaction to improve cleaning efficiency and constitute an ultrasonic apparatus that emits one or more frequencies to suit various cleaning objects. However, in the conventional ultrasonic cleaning apparatus, there is a problem that, when the cleaning water accommodated in the cleaning tank is used for a long time, the cleaning power due to ultrasonic waves is changed due to the cavitation phenomenon.

Therefore, the household ultrasonic cleaning apparatus disclosed in this specification is intended to provide a household ultrasonic cleaning apparatus capable of uniformly maintaining the cleaning power even when used for a long period of time, and cleaning various types of cleaning articles using only one frequency.

In one embodiment, a household ultrasonic cleaning device is disclosed

An ultrasonic wave generator for supplying ultrasonic waves to the washing water accommodated in the washing water accommodated in the washing water and the washing object, and a control part for controlling the operation of the ultrasonic wave generator and the gas supplying part for supplying the gas to the washing water accommodated in the receiving part Wherein the control unit includes a dissolved gas adjusting process for adjusting the amount of gas contained in the washing water by operating the gas supplying unit or stopping the operation of the gas supplying unit.

The gas supply unit includes an air supply unit that sucks air outside the accommodation unit and discharges outside air into the accommodation unit.

The gas supply unit includes an electrolytic device that electrolyzes water contained in the container to generate gas.

The time at which the gas supply portion of the dissolved gas adjustment process stops is at least 10% to 200% of the time when the ultrasonic generator operates.

And a gas receiving part for receiving gas bubbles discharged from the gas supplying part, the gas receiving part being partly opened to be in contact with the washing water.

The gas accommodating portion includes a box-shaped gas accommodation box in which a lower portion of the gas accommodation portion is located on a path through which the gas discharged from the gas supply portion moves by buoyancy.

The time when the gas supply unit stops in the dissolved gas adjusting process includes the sensing unit of the sensor unit.

And a turbulence generator for generating a turbulent flow of the washing water by opening and then opening at least one bubble discharged from the gas supply unit.

The turbulent flow generation unit includes a bubble storage unit for collecting one or more gas bubbles discharged from the gas supply unit in the wash water, and a bubble discharge unit for moving the bubbles collected in the bubble storage unit to the water surface.

The turbulence generating unit includes a bubble holding process for stopping the operation of the ultrasonic generator when the gas accommodated by the bubble receiver moves over the water surface.

Thus, the ultrasonic cleaning apparatus for household use disclosed in the present specification is capable of cleaning the various types of cleaning products with only one frequency, by which the cleaning efficiency can be maintained even when the amount of dissolved gas in the cleaning water is controlled, ≪ / RTI >

The foregoing provides only a selective concept in a simplified form as to what is described in more detail hereinafter. The present disclosure is not intended to limit the scope of the claims or limit the scope of essential features or essential features of the claims.

1 is a view showing an embodiment of a domestic ultrasonic cleaning apparatus.
2 is a view showing an embodiment of a gas supply unit.
3 is a view showing an embodiment of the gas receiving portion.
4 is a view showing an embodiment of the dissolved gas adjusting process.
5 is a view showing an embodiment of the bubble holding process.
6 is a view showing an embodiment of a turbulent flow generating section.

Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the drawings. Like reference numerals in the drawings denote like elements, unless the context clearly indicates otherwise. The exemplary embodiments described above in the detailed description, the drawings, and the claims are not intended to be limiting, and other embodiments may be utilized, and other variations are possible without departing from the spirit or scope of the disclosed technology. Those skilled in the art will appreciate that the components of the present disclosure, that is, the components generally described herein and illustrated in the figures, may be arranged, arranged, combined, or arranged in a variety of different configurations, all of which are expressly contemplated, It can be easily understood that a part is formed. In the drawings, the width, length, thickness or shape of an element, etc. may be exaggerated in order to clearly illustrate the various layers (or films), regions and shapes.

When a component is referred to as being "positioned" to another component, it may include a case where the component is directly disposed on the other component as well as a case where an additional component is interposed therebetween.

When one component is referred to as being "connected" to another component, it may include a case where the one component is directly connected to the other component as well as a case where additional components are interposed therebetween.

When one element is referred to as being "formed" to another element, it may include the case where the one element is formed directly on the other element, as well as the case where additional elements are interposed therebetween.

When one element is referred to as being "coupled" to another element, it may include the case where the one element is directly coupled to the other element as well as the case where additional elements are interposed therebetween.

The description of the disclosed technique is merely an example for structural or functional explanation and the scope of the disclosed technology should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the rights of the disclosed technology should be understood to include equivalents capable of realizing the technical ideas.

It is to be understood that the singular " include " or " have ", if any, Or combinations thereof, and does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the disclosed technology belongs. Commonly used dictionary defined terms should be interpreted to be consistent with the meanings in the context of the related art and can not be interpreted as having ideal or overly formal meaning unless explicitly defined in the present application.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram illustrating an embodiment of a domestic ultrasonic cleaning apparatus. 2 is a view showing an embodiment of a gas supply unit. 3 is a view showing an embodiment of the gas receiving portion. 4 is a view showing an embodiment of the dissolved gas adjusting process. 5 is a view showing an embodiment of the bubble holding process. 6 is a view showing an embodiment of a turbulent flow generating section.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a household ultrasonic cleaning apparatus disclosed in this specification will be described with reference to the drawings. The household ultrasonic cleaning apparatus according to the present invention includes a housing 100 in which washing water 10 and a subject to be cleaned 20 are accommodated and an ultrasonic wave generator 210 for supplying ultrasonic waves 210 to the washing water 10 housed in the housing 100 A gas supplying unit 300 for supplying gas to the washing water 10 accommodated in the accommodating unit 100 and a control unit 400 for controlling operations of the gas supplying unit 300 and the ultrasonic generating unit 200, The control unit 400 includes a dissolved gas adjusting process S100 for adjusting the amount of gas contained in the washing water 10 by activating or deactivating the gas supplying unit 300.

The gas supply unit 300 includes an air supply unit 310 that sucks air outside the accommodating unit 100 and discharges outside air into the accommodating unit 100.

The gas supply unit 300 includes an electrolytic device that electrolyzes water contained in the accommodating unit 100 to generate gas.

The stopping time of the gas supply part 300 in the dissolved gas adjusting step S100 includes at least 10% to 200% of the time when the ultrasonic generator 200 is operated.

And may optionally include a gas receiving portion 500 which receives gas bubbles discharged from the gas supplying portion 300 and is partially opened to contact the washing water 10. [

The gas accommodating part 500 includes a box-shaped gas accommodating chamber 510 in which a lower part of the gas accommodating part 500 is located in a path where the gas discharged from the gas supplying part 300 moves by buoyancy.

The time period during which the gas supply unit 300 stops in the dissolved gas adjustment process S100 is a detection signal of the sensor unit 600 .

A turbulence generator 700 may be further included to accommodate one or more bubbles discharged from the gas supplier 300 and then open the turbulence generator 700 to generate turbulence of the washing water.

The turbulence generator 700 includes a bubble reservoir 710 for collecting one or more gas bubbles discharged from the gas supplier 300 in the wash water 10 and bubbles collected in the bubble reservoir 710 to move to the water surface (Not shown).

The control unit 400 may optionally include a bubble holding process S200 for stopping the operation of the ultrasonic generator 200 when the gas contained in the bubble receiver 710 moves over the water surface.

The receptacle 100 is composed of a conventional container capable of storing the washing water 10 and the object 20 to be cleaned.

1 and 2 according to one embodiment may be made of a nonconductive material. On the other hand, it may further include a pot (not shown) having one or more holes inserted into the container. The receiving portion 100 accommodates the washing water 10 and the object to be cleaned 20. The washing water 10 contained in the receptacle 100 may be a general water or a chemically processed washing agent, and the washing object 20 is a fruit, a vegetable, a grain, a tableware, or the like.

The ultrasonic wave generator 200 includes a conventional ultrasonic wave generator which generates cavitation by providing the ultrasonic waves 210 to the washing water 10 stored in the storage 100.

The ultrasonic wave generator 200 according to one embodiment may be installed on the lower surface of the receiver 100. The ultrasound generating unit 200 generates a cavitation phenomenon in the washing water 10 to wash the object to be cleaned 20 with the ultrasonic waves 210. Conventional cleaning of the ultrasonic wave 210 is performed by cleaning the object to be cleaned 20 by cavitation 220 by the ultrasonic wave 210. Cavitation 220 is a phenomenon in which the pressure applied to the fluid through the ultrasonic wave 210 Is a phenomenon in which a cavity (cavity) is generated and destroyed in the fluid according to the change of the fluid. When the fluid pressure is lower than the saturated vapor pressure due to the ultrasonic waves 210 applied to the fluid, a part of the fluid is vaporized and a cavity is formed in the fluid. Then, the generated cavity is contracted and exploded by applying a positive pressure higher than the surface tension of the fluid to the cavity by the ultrasonic waves 210 applied to the fluid.

Meanwhile, the ultrasonic wave generator 200 may provide the ultrasonic waves 210 to the inside of the receiver 100, and the type and location of the ultrasonic wave generator may be variously changed.

The gas supplying unit 300 is configured to supply gas to the washing water 10 accommodated in the accommodating unit 100.

The gas supply unit 300 according to one embodiment includes an air supply unit 310 for sucking air outside the accommodating unit 100 and discharging outside air into the accommodating unit 100 . The air supply device 310 may be composed of a conventional pump. The air supply device 310 may be installed on the lower surface of the receiving part 100. The air supply device 310 communicates with the outside of the housing part 100 to suck the outside air, and discharges the sucked outside air into the housing part 100. The air supply device 310 is configured to supply various gases contained in the air to the washing water 10 to be dissolved therein.

The type of the air supply device 310 and the installation position may be variously changed, and the air supply device 310 may be installed in the air supply device 310, The air in the desired position may be sucked or discharged through a method of connecting the piping to the air inlet or air outlet of the air conditioner 310.

The gas supply unit 300 referring to another embodiment may be constituted of an electrolytic device (not shown) for electrolyzing water contained in the accommodating unit 100 to generate gas. The electrolytic device is installed inside the housing part (100). The electrolytic device may be installed on the inner bottom of the accommodating part (100). The electrolytic apparatus electrolyzes the washing water 10 contained in the receiving portion 100 to generate a hydroxyl group by a chemical reaction of oxygen-containing active species including a large amount of hydroxide ions. The wash water 10 used here is conventional water. The hydroxyl group can sterilize various bacteria and viruses. On the other hand, the electrolytic apparatus separates water into oxygen and hydrogen and electrolyzes water in the electrolytic water to generate gas (gas) such as oxygen or hydrogen while generating sterilizing ions, The gas can dissolve in water and the amount of dissolved gas can be increased. Furthermore, the gas supply unit 300 can electrolyze water to lower the mass of water to further increase the concentration of dissolved gas.

The gas supplying unit 300 described above allows the gas (dissolved gas) contained in the washing water 10 to be supplemented by the continuous cavitation 220 phenomenon. More specifically, the amount of dissolved gas in the wash water 10 affects the development and effect of the cavitation 220 by the ultrasonic waves 210, and the amount of dissolved gas per second (10) per second compared with the amount of dissolved gas per second lost by the cavitation 220 (Gas) is supplied to the washing water 10, the change in the amount of the dissolved gas in the washing water 10 can be minimized. When the amount of gas dissolved in the washing water 10 per second by the amount of the dissolved gas per second lost by the cavitation 220 is supplied to the washing water 10, the variation width of the dissolved gas amount of the washing water 10 is reduced, It may be kept uniform. Further, the gas by the gas supply unit 300 is kept in the form of bubbles. The bubbles absorb the ultrasonic waves 210 to lower the ultrasonic waves 210, and the amount and the size of the bubbles can be adjusted, It may also provide an appropriate cleaning force. In addition, the bubbles may change the position of the object to be cleaned 20 by forming turbulence in the washing water 10 due to movement of the air bubbles to the water surface of the washing water 10 or rupture at the water surface. As the position of the object to be cleaned 20 is changed, the cavitation 220 can act on the entire surface and the clearance of the object to be cleaned 20.

The controller 400 includes a conventional PCB substrate or a computer. The controller 400 is connected to the gas supplier 300 and the ultrasonic generator 200 to control the operation of the ultrasonic generator 200. And is also connected to the turbulence generator 700 to control the operation.

4 according to an embodiment of the present invention includes a control unit 400 connected to a gas supply unit 300 to operate or stop operation of the gas supply unit 300 to control the amount of dissolved gas contained in the wash water 10, (S100). The dissolved gas adjusting process S100 is to adjust the amount of the water or the fluid contained in the receiving portion 100 and the amount of the gas (gas) dissolved in the washing water 10. [ The dissolved gas adjusting process S100 operates the gas supplying unit 300 when the ultrasonic generator 200 is in operation and reaches the first operating condition and operates the gas supplier 300 when the first operating condition is not reached. To continue to stop. Thereafter, when the second operating condition is reached, the operation of the gas supplying unit 300 is stopped, and when the second operating condition is not reached, the gas supplying unit 300 is continuously operated. The first operating condition and the second operating condition may be a set time and a time of 10% to 200% of the time, respectively. More specifically, when the first operating condition is set to a time of 10 seconds and the second operating condition is set to a ratio of 90%, the ultrasonic wave generator 200 operates for 10 seconds and the gas supplier 300 operates for 9 seconds It works. The gas supply unit 300 stops operating after 9 seconds of operation. That is, the gas supplier 300 is operated at a ratio (%) with respect to the time when the ultrasonic generator 200 operates. The dissolved gas adjusting process S100 may be performed such that the amount of gas dissolved in the washing water 10 can be partially compensated for in response to the dissolved gas amount lost by the operation of the ultrasonic wave generator 200 according to the set percentage , To be close to or greater than the amount of dissolved dissolved gas. That is, through the dissolved gas control process S100, the control unit 400 controls the operation of the gas supply unit 300 such that the amount of the gas dissolved in the washing water 10 per second is smaller than the amount of dissolved gas per second that is lost by the cavitation 220 The change in the dissolved gas amount of the washing water 10 can be minimized. When the operation of the gas supply unit 300 is made to be the amount of gas dissolved in the washing water 10 per second by the amount of dissolved gas per second lost by the cavitation 220, the fluctuation width of the dissolved gas amount of the washing water 10 can be reduced . Further, when the operation of the gas supply unit 300 is made such that the amount of gas dissolved in the washing water 10 per second is larger than the amount of gas dissolved per second by the cavitation 220, the amount of bubbles increases so that the ultrasonic waves 210 are absorbed can do.

The first operating condition and the second operating condition may vary depending on the amount of the gas dissolved in the washing water 10 per second, such as the type or temperature of the supplied gas and the type of the washing water 10. Furthermore, by configuring the gas sensor for measuring the concentration of the gas contained in the washing water 10, the measurement value of the gas sensor can be used as a reference. Further, it may be constituted by the sensing signal of the sensor unit 600, which will be described below as the second operating condition.

5 according to another embodiment of the present invention is connected to the ultrasonic generator 200 to stop the operation of the ultrasonic generator 200 when the gas accommodated in the bubble receiver 710 moves over the water surface And a bubble holding process (S200). The bubble holding process (S200) includes a process of operating the gas supplier (300) and the ultrasonic generator (200). When the gas supplied from the gas supply unit 300 is accommodated in the turbulence generator 700 to be described below and the accommodated gas is lifted from the turbulence generator 700 and floated on the water surface with the bubbles, the operation of the ultrasonic generator 200 . The time when the gas leaves the turbulence generator 700 may be configured as a third operating condition. And operating the ultrasonic generator 200 again according to the fourth operation condition after the operation of the ultrasonic generator 200 is stopped. The third operating condition can be set as a signal of the sensor unit 600 to be described below. The turbulence generator 700, which will be described later, is operated by the buoyancy of the gas bubbles supplied from the gas supplier 300, It is possible to set the time at which the vehicle departs. The fourth operating condition may be set as a time when the gas bubbles rise above the water surface, or may be set as a sensing signal through the bubble detection sensor on the water surface of the washing water. The bubble holding process (S200) prevents the large bubbles that have separated from the turbulence generator 700 described below from being destroyed by the ultrasonic waves 210 while rising above the water surface. That is, the gas collected in the turbulence generating unit 700 to be described below may include a large lump of bubbles. When a large lump of bubbles floats above the water surface, the water is submerged in the washing water 10, 20 are pushed or rotated. Then, the bubbles burst on the water surface and generate a shock wave to push or rotate the cleaning object 20 in a secondary direction. In addition, turbulence in the washing water 10 can be formed through the movement of the bubbles and the shock waves, so that the washing object 20 can be pushed or rotated in a tertiary manner.

The controller 400 according to another embodiment may be configured to generate a turbulence generating process for rotating the turntable 722 of the turbulence generator 700, which will be described below. The turbulence generation process may be configured to determine that the gas contained in the turbulence generation unit 700 is sufficiently accommodated according to the signal of the sensor unit 600 and to drive the rotation device 722. This turbulent generation process allows one or more lumped bubbles to move over the surface of the water.

Meanwhile, the controller 400 may be configured to include at least one of the dissolved gas adjusting process S100, the bubble holding process S200, and the turbulent flow generating process, which will be described above, or a combination or all of them.

The gas accommodating part 500 is configured such that a gas (bubble) discharged from the gas supplying part 300 is accommodated and a part of the gas accommodating part 500 is opened to be in contact with the washing water 10.

3 according to an embodiment of the present invention. The gas receiving part 500 includes a box-like body (not shown) positioned in the water of the washing water 10 on the path where the gas discharged from the gas supplying part 300 moves by buoyancy, And an accommodation box 510. This gas accommodation box 510 allows the bubbles of the gas supplied from the gas supply part 300 to be placed in the water as one large lump shaped bubble 1. Also, a part of the air bubbles contained in the gas supply part 300 is kept in contact with the washing water 10.

The gas accommodation box 510 may include a gas accommodation support 520 which is fixed to the bottom of the accommodation space 100 and supports the gas accommodation box 510. The gas receiving support part 520 may be fixed at any part of the receiving part 100 and may be connected to the outside.

In another example, the gas accommodating portion 500 may be formed on the side surface of the accommodating portion 100 as described above. The gas accommodation box 510 is formed in the form of a box having a space in which the washing water 10 can be received, and the lower end can be configured to communicate with the accommodation portion 100. At this time, the gas supply unit 300 may be formed at the bottom of the gas accommodation box 510, or the like. The gas accommodating chamber 510 includes a gas supply unit 300 and a gas supply unit 500. The gas supply unit 500 includes a gas supply part 300 and a gas supply part 510. The gas supply part 500 includes a gas supply part 300, And contacts the washing water 10 at the lower end of the washing tub 510.

In another example, the gas accommodation box 510 may be formed at a side upper end of the accommodation portion 100. The gas accommodating chamber 510 may be formed in the form of a box having a space in which the washing water 10 can be accommodated, the lower end communicating with the accommodating portion 100, and the upper end opened. At this time, the gas supply unit 300 may be formed at the bottom of the gas accommodation box 510, or the like. The gas accommodating chamber 510 includes a gas supply unit 300 and a gas supply unit 500. The gas supply unit 500 includes a gas supply part 300 and a gas supply part 510. The gas supply part 500 includes a gas supply part 300, And contacts the washing water 10 at the lower end of the washing tub 510.

The gas receiving part 500 described above is stored in the form of bubbles in the water of the washing water 10 supplied from the gas supplying part 300. The stored gas is configured to be dissolved in the washing water 10 in contact with the washing water 10. Furthermore, the gas accommodation part 500 prevents the gas bubbles supplied from the gas supply part 300 from moving on the water surface, thereby suppressing the absorption of the bubbles of the gas by the ultrasonic waves 210 emitted to the cleaning water. The absorption of the ultrasonic waves 210 by the gas supplied from the gas supplying unit 300 is suppressed and the phenomenon of the cavitation 220 by the ultrasonic waves 210 is prevented from being reduced. That is, it is possible to prevent the cleaning force of the ultrasonic waves 210 from being lowered by the gas supplied to replenish the dissolved gas of the washing water 10.

The sensor unit 600 is configured to detect the presence or absence of gas in the gas accommodation box 510. The sensor unit 600 is electrically connected to the controller 400 described above.

The sensor unit 600 referring to FIG. 3 illustrating one embodiment may be configured with a conventional level sensor. The level sensor can be configured to stop at the inside of the gas receiver 510. The water level sensor can sense that the gas is received in the gas container 510 to form another water surface in the water. That is, when gas is received in the gas accommodation box 510 and the water surface of the cleaning water 10 is positioned at the lower end of the gas accommodation box 510, gas contained in the gas accommodation box 510 is dissolved in the cleaning water 10, . At this time, the water level sensor senses the water surface of the washing water 10 and transmits the detection signal to the controller 400.

On the other hand, instead of the water level sensor, various sensors capable of sensing gas or liquid may be used.

The sensor unit 600 transmits a signal to the controller 400 to prevent the amount of gas contained in the gas receiver 510 from being received by the gas receiver 510 in an amount larger than the amount that can be accommodated in the gas receiver 510 . That is, the sensor unit 600 prevents an excessive amount of gas supplied to the gas receiver 510 from being accommodated therein, so that the gas bubbles supplied from the gas supplier 300 are not moved over the water surface.

The turbulence generator 700 is configured to open after opening one or more bubbles discharged from the gas supply unit 300. The turbulence generator 700 is configured to generate turbulence in the wash water 10.

The turbulence generator 700 referring to FIG. 6 described in the embodiment may be configured to include a bubble reservoir 710 that collects one or more bubbles discharged from the gas supply unit 300 in the wash water 10. The air bubble accommodating portion 710 may be configured in the same manner as the gas accommodating portion 500 described above. And may include a gas accommodation box 510 and a gas reception support part 520 for supporting the gas accommodation box 510. The turbulence generator 700 may include a bubble opening part 720 for allowing the bubbles collected in the bubble storage part 710 to move to the water surface. The bubble opening portion 720 may be constituted by a rotation axis 721 for allowing the bubble accommodation portion 710 to rotate freely. The turbulent flow generating unit 700 receives bubbles of the gas supplied from the gas supplying unit 300 in the bubble accommodating unit 710 and is accommodated in at least one large bubble shape. Thereafter, the bubble storage portion 710 is rotated through the rotation axis 721 of the bubble open portion 720 by buoyancy of the accommodated bubble. When the bubble storage portion 710 is rotated through the rotary shaft 721, the opened lower portion of the bubble storage portion 710 is moved upward, and the accommodated bubble is moved above the water surface.

6, the turbulence generator 700 may include a rotating device 722 on the rotating shaft 721 described above. The rotation shaft 721 may be configured to be coupled to the gas accommodation box 510 through the gas accommodation support part 520. The rotating device 722 may be constructed of a conventional motor and connected to the control unit 400 described above. The turbulent flow generating unit 700 receives bubbles of the gas supplied from the gas supplying unit 300 in the bubble accommodating unit 710 and is accommodated in at least one large bubble shape. Thereafter, in accordance with the turbulent flow generation process (S300) of the control unit 400, the rotary device 722 of the bubble open portion 720 is operated to rotate the rotary shaft 721. [ When the rotating shaft 721 is rotated, the bubble accommodating portion 710 is rotated, and the opened lower portion is moved upward, and the lump-shaped bubble 1 accommodated therein is moved over the water surface.

The turbulence generator 700 according to another embodiment may be configured such that the upper surface of the gas accommodation box 510 described above is separated from the gas accommodation box 510. The separating upper surface and the gas accommodation box 510 may be coupled to each other by a hinge structure for freely rotating by the rotation axis 721. The above-described rotating device 722 can be configured on the rotating shaft 721.

The turbulence generator 700 described above can be configured such that the bubbles of the gas supplied from the gas supplier 300 are accommodated in the washing water 10 so that at least one bubble is kept in the form of at least one large bubble, So that it can be moved over the surface of the water.

From the foregoing it will be appreciated that various embodiments of the present disclosure have been described for purposes of illustration and that there are many possible variations without departing from the scope and spirit of this disclosure. And that the various embodiments disclosed are not to be construed as limiting the scope of the disclosed subject matter, but true ideas and scope will be set forth in the following claims.

1: lump-shaped bubble
10: Wash water
20: cleaning object
100:
200: Ultrasonic wave generating unit
210: Ultrasound
220: Cavitation
300:
310: air supply device
400:
S100: Dissolved gas control process
S200: Bubble keeping process
500: gas receiving portion
510: Gas container
520: gas receiving support
600:
700: turbulent flow generator
710:
720: bubble opening
721:
722: Rotating device

Claims (10)

A receiving portion for receiving the washing water and the object to be cleaned;
An ultrasonic generator for providing ultrasonic waves to the washing water accommodated in the accommodating portion;
A gas supply unit for supplying gas to the washing water accommodated in the accommodating portion; And
And a control unit for controlling operations of the gas supply unit and the ultrasonic generator,
The control unit includes a dissolved gas adjusting process for adjusting the amount of gas contained in the washing water by activating or stopping the gas supplying unit,
A household ultrasonic cleaning apparatus for containing gas bubbles discharged from a gas supplying unit, the gas containing unit being partially opened to be in contact with washing water. The method according to claim 1,
Wherein the gas supply unit is an air supply unit that sucks air outside the accommodating unit and discharges outside air into the accommodating unit. The method according to claim 1,
Wherein the gas supply unit is an electrolytic apparatus for electrolyzing water contained in the housing unit to generate gas. The method according to claim 1,
Wherein the time of stopping the gas supply part of the dissolved gas adjusting step is at least 10% to 200% of the time when the ultrasonic generator operates. delete The method according to claim 1,
The gas receiving portion
And a gas accommodation box in the form of a box in which a lower portion of the box-shaped gas accommodation box is located on a path where the gas discharged from the gas supply portion moves by buoyancy. The method according to claim 6,
And a sensor portion in the gas accommodation box,
Wherein the time of stopping the gas supply part of the dissolved gas adjusting process is a sensing signal of the sensor part. A receiving portion for receiving the washing water and the object to be cleaned;
An ultrasonic generator for providing ultrasonic waves to the washing water accommodated in the accommodating portion;
A gas supply unit for supplying gas to the washing water accommodated in the accommodating portion; And
And a control unit for controlling operations of the gas supply unit and the ultrasonic generator,
The control unit includes a dissolved gas adjusting process for adjusting the amount of gas contained in the washing water by activating or stopping the gas supplying unit,
And a turbulence generating unit for generating at least one bubble discharged from the gas supply unit after receiving the turbulence of the washing water. 9. The method of claim 8,
The turbulence generating portion
A bubble storage unit for collecting one or more gas bubbles discharged from the gas supply unit in the wash water; And
And a bubble opening portion for moving the bubbles collected in the bubble storage portion to the water surface. 10. The method of claim 9,
The control unit
And a bubble holding step of stopping the operation of the ultrasonic wave generating part when the gas accommodated by the bubble storing part moves over the water surface.

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