KR20180045207A - An ultrasonic cleaning apparatus - Google Patents

Abstract

An ultrasonic cleaning apparatus according to the present invention relates to an ultrasonic generating apparatus capable of efficiently transferring an ultrasonic wave released from an ultrasonic wave generating apparatus to a cleaning solution by using a carrier. The ultrasonic cleaning apparatus comprises: a distribution case; an accommodation case; an ultrasonic wave generator; a compact unit; a transmission body; and a porous nano-structure.

Description

An ultrasonic cleaning apparatus comprising:

The present invention relates to an ultrasonic cleaning apparatus and a cleaning system including the ultrasonic cleaning apparatus, and more particularly, to an ultrasonic cleaning apparatus for cleaning a general industrial apparatus or a semiconductor substrate and a cleaning system including the ultrasonic cleaning apparatus.

In general industrial washing machines and industrial washing machines, parts or minerals (hereinafter referred to as "washed articles") processed and manufactured by machining, parts manufacturing or quarrying are washed to remove impurities or oil which are on the articles to be cleaned , Components used to assemble parts, packaging goods, or improving product value.

In addition, the semiconductor washer is a device used to clean parts of a semiconductor substrate to remove foreign substances or oil, etc., on the semiconductor substrate, thereby assembling parts, packaging, or enhancing the product value.

Industrial washing machines or semiconductor washing machines are classified into a spray type washing machine for spraying the washing liquid at a high pressure according to a washing method or an ultrasonic washing machine for washing the components by ultrasonic wave after immersing the washing liquid in a washing liquid (hereinafter referred to as an ultrasonic washing machine) do.

The conventional ultrasonic cleaner includes a main body, cleaning means including a plurality of nozzles formed inside the main body and spraying a cleaning liquid, a transfer table formed at an outer side of the main body, A separating means for separating the cleaning liquid discharged through the discharging means, that is, the separating means for separating the oil and the cleaning liquid, from the main body separately from the main body do.

At one side of the main body, there are formed an opening and a door for opening and closing the opening, and a guide rail and elevating means for guiding the door up and down.

In the conventional ultrasonic cleaner, the object to be cleaned is placed on a transfer table constructed on the outside of the main body, the transfer table is transferred to the inside through the opening of the main body, the opening is closed by the door formed in the main body, When the cleaning liquid to which the ultrasonic wave is applied is jetted from the nozzle, the object to be cleaned is cleaned by the cleaning liquid.

In addition, the cleaning liquid generated after cleaning the object to be cleaned is collected by the downward discharge means, and the collected cleaning liquid is transferred to the separation means formed on the outside of the body, and the foreign substance, that is, the oil and the cleaning liquid are separated through the separation means The separated oil or cleaning liquid is recycled or discarded through a reprocessing process.

However, in the conventional ultrasonic cleaner, since the cleaning liquid is sprayed at a high pressure to clean the object to be cleaned, foreign matter adsorbed on the surface of the object to be cleaned, particularly oil and deposited dust, is not removed, .

After the cleaning is completed, the object to be cleaned, which is discharged to the outside along the transfer table, is conveyed to the next process in a state where the cleaning liquid is buried, whereby the cleaning liquid buried in the object to be cleaned is dropped, There was a problem to be contaminated.

In addition, the cleaning liquid dropped on the floor of the workplace has a risk of a safety accident that an operator may slip on the move due to the inclusion of oil components.

On the other hand, if the object to be cleaned is left in the air in a state in which the cleaning liquid is buried, dust or other foreign substances contained in the air are adsorbed on the surface of the object to be cleaned, and the effect of the original cleaning operation is canceled.

When the washed object to be cleaned is discharged to the outside due to the above problems, the worker uses the high-pressure air supplied from a separate compressor to dry the cleaning liquid buried on the surface of the object to be cleaned. There is a problem that the working efficiency is lowered.

Korean Patent Laid-Open Publication No. 2011-0090120 discloses an upper nozzle housing having ultrasonic waves applied to a supplied cleaning liquid and spraying the ultrasonic waves onto the cleaning liquid to clean the surface thereof. The upper nozzle housing has an inlet portion into which the cleaning liquid flows, A nozzle housing including a lower nozzle housing having a spray hole at a position corresponding to the nozzle and a gas supply part for supplying gas to one side thereof; A piezoelectric ceramic disposed around the inlet to generate ultrasonic waves; And a through hole for allowing the cleaning liquid introduced into the inflow portion to pass through and sprayed to the injection hole, wherein the through hole is disposed inside the nozzle housing in a state where one side is in contact with the piezoelectric ceramics, Wherein the cleaning liquid introduced into the inlet portion receives ultrasonic waves while passing through the through hole of the vibration element vibrating by the piezoelectric ceramic, and at the same time, the ultrasonic wave is transmitted from the gas supply portion to the passage And is finely sprayed to the surface of the cleaned object through the injection hole by the gas supplied through the nozzle.

However, in the prior art, ultrasonic waves generated in the piezoelectric ceramics are transferred to the cleaning liquid without a transfer medium, so that the ultrasonic waves are weakly transferred to the gas, thereby deteriorating the cleaning effect of the cleaning liquid.

Therefore, it is necessary to develop various ultrasonic cleaning apparatuses and a cleaning system including the same for solving the above-mentioned problems.

Korean Patent Publication No. 2011-0090120 (2011.08.10) Korean Patent No. 1599214 (2014.07.28) Korean Patent No. 1544504 (Oct. 14, 2013)

An object of the present invention is to control the acoustic impedance value of a transporter that transmits ultrasonic waves to a cleaning material so that ultrasonic waves emitted from the ultrasonic generator are efficiently transmitted to a cleaning material.

The ultrasonic cleaning apparatus according to the present invention includes: a circulation case (100) having a receiving part (110) and a first circulation part (130) formed therein; A receiving case 200 including a first receiving part 220 communicating with a lower end of the first circulating part 130; A compact unit 300 provided in the first circulation unit 130 and supplying liquid and gas for generating cleaning material to the first storage unit 220; An ultrasonic generator (400) installed at the receiving part (110) and emitting ultrasonic waves toward the first receiving part (220); A carrier (500) on which the ultrasonic waves emitted from the ultrasonic generator (400) are positioned on a path for moving to the first accommodating part (220); And a plurality of ejection holes (620) through which the cleaning material located in the first accommodating portion (220) is ejected as an object to be cleaned; And a control unit.

The carrier 500 is a medium having an acoustic impedance value located between the acoustic impedance value of the cleaning material located in the first storage part 220 and the acoustic impedance value of the ultrasonic generator 400 .

In addition, the carrier 500 is formed of a plurality of matching layers that gradually decrease in acoustic impedance as the first receiving portion 220 approaches.

In addition, the carrier 500 may be provided at one or more positions where the plurality of the matching layers face each other and the outermost bottom side of the matching layer and the matching layer facing the first receiving portion 220, Is formed.

The compact unit 300 further includes a liquid supply pipe 310 for supplying the liquid to the first accommodating unit 220, a gas supply pipe 320 for supplying gas to the first accommodating unit 220, And a sparger (330) for separating the gas supplied to the first accommodating part (220) from the gas supply pipe (320) into fine particles.

The compact unit 300 may further include a liquid discharge pipe 340 for discharging the cleaning material that exceeds the space of the first accommodating part 220 and an amount of gas located in the first accommodating part 220 And a gas discharge pipe (350) for controlling the gas discharge pipe (350).

The compact unit 300 is characterized in that the liquid supply pipe 310, the gas supply pipe 320, the liquid discharge pipe 340, and the gas discharge pipe 350 are integrally coupled to each other.

The compact unit 300 is characterized in that the liquid supply pipe 310 is inserted into the liquid discharge pipe 340 and the gas supply pipe 320 is inserted into the gas discharge pipe 350 .

The compact unit 300 further includes an integration pipe 360 in which the liquid supply pipe 310, the gas supply pipe 320, the liquid discharge pipe 340, and the gas discharge pipe 350 are inserted at predetermined intervals .

Accordingly, the ultrasonic cleaning apparatus according to the present invention is advantageous in that the ultrasonic wave generated in the ultrasonic wave generator is transmitted to the cleaning substance through the carrier to prevent the ultrasonic wave from weakening in the ultrasonic wave transmission process.

Then, the ultrasonic wave is transmitted to the cleaning substance at a predetermined intensity, and the cleaning substance can be emitted toward the object to be cleaned at a constant speed (intensity), so that the cleaning effect can be maximized.

1 is a schematic view of an ultrasonic cleaning apparatus according to the present invention;
2 to 3 are perspective views showing a first embodiment of a compact unit according to the present invention.
4 is a perspective view showing a second embodiment of the compact unit according to the present invention.
5 is a perspective view showing a third embodiment of the compact unit according to the present invention.
6 is a perspective view illustrating a height adjusting unit according to the present invention;

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the technical concept of the present invention, are incorporated in and constitute a part of the specification, and are not intended to limit the scope of the present invention.

In the direction display of the present invention, the upper side of the drawing is defined as the upper side, and the lower side of the drawing is defined as the lower side.

1 is a schematic view of an ultrasonic cleaning apparatus according to the present invention.

1, the ultrasonic cleaning apparatus according to the present invention includes a flow case 100 in which a receiving portion 110, a first flow portion 130, a second flow portion 120 are formed, A receiving case 200 including a first receiving part 220 communicating with the lower end of the first circulating part 130 and a second receiving part 210 communicating with the lower end of the second circulating part 120, A compact unit 300 provided in the first circulation unit 130 for supplying liquid and gas for generating cleaning material to the first storage unit 220, The ultrasonic generator 400 includes an ultrasonic generator 400 for emitting ultrasonic waves toward the first accommodating part 220 and a carrier 500 positioned on a path for moving the ultrasonic waves emitted from the ultrasonic generator 400 to the first accommodating part 220. [ A porous nanostructure 600 including a plurality of ejection holes 620 through which a cleaning material located in the first accommodating portion 220 is ejected as an object to be cleaned, It comprises an ejecting portion (610) for guiding the cleaning material to be located in the part 210 to be washed with water.

The compact unit 300 supplies the liquid and the gas to the first accommodating unit 220 formed in the accommodating case 200 so that the liquid and the gas are mixed on the first accommodating unit 220 The cleaning material is generated and the ultrasonic wave is applied to the generated cleaning material by the ultrasonic generator 400. The cleaning material is ejected through the ejection hole 620 formed in the porous nanostructure 600 into the object to be cleaned, To clean the cleaning water.

At this time, the compact unit 300 can supply various kinds of liquid and gas used for generating cleaning material to the first accommodating unit 220, and the liquid can be ultrapure water, and the gas can be nitrogen, hydrogen, Oxygen, or the like.

That is, it is possible to clean the object to be cleaned by generating a cleaning material having various functions in the first accommodating portion 220 corresponding to the object to be cleaned.

The cleaning material may be a liquid, a gas, or a cleaning liquid in which fine gas particles are dissolved.

In the ultrasonic cleaning apparatus according to the present invention, since the jetting hole 620 has a diameter of several nanometers to several micros, the cleaning substance passing through the jetting hole 620 can be uniformly divided and ejected into the object to be cleaned, , It is of course possible to prevent breakage of the fine pattern formed on the surface of the object to be cleaned.

In addition, the second circulation unit 120 receives the cleaning liquid including the functional water, the bubble number, the supernatant, and the like from the outside, and receives the cleaning liquid through the second containing unit 210 and the jetting unit 610 Guide the cleaning liquid.

In general, when cleaning the object to be cleaned, it is sufficient to use only the cleaning material which is discharged into the object to be cleaned through the discharge hole 620. However, if additional cleaning is necessary in the cleaning process, or when a rinse process is required The cleaning liquid corresponding to the required process is discharged through the second circulation part 120, the second storage part 210 and the jet part 610, and various cleaning processes can be performed through the ultrasonic cleaning device of the present invention It is.

In the present invention, the carrier 500 efficiently transfers the ultrasonic waves emitted from the ultrasonic generator 400 to the cleaning material located in the first accommodating part 220, thereby maximizing the precision and reliability of cleaning.

More specifically, when an ultrasonic wave is transmitted through any medium, if the target object to which the ultrasonic wave is transmitted and the acoustic impedance value of the medium that transmits the ultrasonic wave differ by more than a predetermined value, the ultrasonic wave can not be transmitted to the target object.

Therefore, in the present invention, the delivery unit 500 is positioned between the ultrasonic generator 400 and the first accommodation unit 220, so that the ultrasonic wave is effectively transmitted.

At this time, the carrier 500 is made of a medium having an acoustic impedance value between the ultrasonic generator 400 and the acoustic impedance value of the cleaning material located in the first storage unit 220, 500 in the process of being transferred to the cleaning material.

In addition, the carrier 500 may be formed of a plurality of matching layers whose impedance values gradually decrease as they approach the first receiving portion 220. In order to facilitate fixing of the matching layers, A fixing plate may be formed at an inner side of the matching layer facing each other or at least one of the matching layer and the lowermost side of the matching layer facing the first receiving portion 220.

That is, as shown in the drawing, the carrier 500 includes a first matching layer 510 directly connected to the lower side of the ultrasonic generator 400, and a second matching layer 510 formed on the lower side of the first matching layer 510, A fixing plate may be formed between the first matching layer 510 and the second matching layer 520 and below the second matching layer 520. [

In the present invention, the upper part of the carrier 500 is coupled to the lower side of the ultrasonic generator 400, and the lower part thereof is in direct contact with the cleaning material located in the first accommodation part 220, Of course it is.

In addition, the first matching layer 510 and the second matching layer 520 may be formed of a composite material such as glass or resin, and may be formed of graphene. When the first matching layer 510 and the second matching layer 520 are formed of graphene, Can be used for connection.

Hereinafter, various embodiments of the compact unit according to the present invention will be described.

≪ Embodiment 1 of the compact unit 300 >

2 to 5 show a first embodiment of the compact unit 300 according to the present invention.

2 to 5, the compact unit 300 includes a liquid supply pipe 310 for supplying a liquid to the first accommodating unit 220, 1, the gas supply pipe 320 includes a gas supply pipe 320, a liquid discharge pipe 340, and a gas discharge pipe 350. The gas supply pipe 320 is connected to the first storage unit 220, And a sparger 330 for separating the fine particles into fine particles.

The liquid supply pipe 310 supplies the liquid to the first accommodating part 220 and the gas supply pipe 320 supplies the gas to the first accommodating part 220 so that the first accommodating part 220 The gas is passed through the sparger 330 when the gas is supplied to the first accommodating portion 220 through the gas supply pipe 320 so that the gas passes through the sparger 330, So that it can be dissolved in the liquid supplied from the liquid supply pipe 310.

At this time, the sparger 330 may have various structures and shapes because it is enough to separate the gas passing through it into fine gas particles. However, it is recommended that the sponge 330 is a nano micro structure, and the nano micro structure may have nano- It is a matter of course that the mesh shape may be formed.

The liquid discharge pipe 340 can discharge the liquid cleaning material and the cleaning liquid that exceed the space of the first accommodating part 220. The gas exhaust pipe 350 is connected to the first accommodating part 220, It is possible to control the amount of the gas to be placed.

More specifically, when liquid and gas are continuously supplied from the outside through the liquid supply pipe 310 and the gas supply pipe 320, a cleaning liquid or a liquid cleaning material exceeding the volume of the first storage part 220 The amount of the liquid cleaning material or the cleaning liquid located in the first accommodating portion 420 through the liquid discharge pipe 340 is controlled.

In this case, it is needless to say that the gas exhaust pipe 350 can also control the amount of gas dissolved in the cleaning liquid located in the first accommodating portion 220.

2, the compact unit 200 according to the present invention includes the liquid supply pipe 310, the gas supply pipe 320, the liquid discharge pipe 340, and the gas discharge pipe 350, And each of the supply pipes and the discharge pipes may have a circular cross-sectional shape as shown in FIG. 3, and the outer peripheral surfaces may be connected to each other. In addition, it is possible to have various structures disclosed below.

≪ Embodiment 2 of the compact unit 300 >

4, the compact unit 300 has a structure in which the liquid supply pipe 310 is inserted into the liquid discharge pipe 340 and the gas supply pipe 320 is inserted into the gas discharge pipe 350 And the liquid discharge pipe 340 and the gas discharge pipe 350 may have an outer peripheral surface connected to each other.

≪ Embodiment 3 of the compact unit 300 >

5, the compact unit 300 further includes an integration pipe 360, and the liquid pipe 310, the gas supply pipe 320, the liquid discharge pipe 320, (340), and the gas discharge pipe (350) may be spaced apart from each other by a predetermined distance.

Referring to FIG. 6, the ultrasonic cleaning apparatus of the present invention may further include a cleaning liquid height adjusting unit 10 for uniformizing the thickness of the cleaning liquid applied by the object to be cleaned.

In detail, when the cleaning liquid is applied to the object to be cleaned, the thickness of the cleaning liquid applied to the object to be cleaned becomes uneven, so that the pressure wave generated by the cleaning liquid discharged through the ejection hole 620 is not constant, Since the cleaning of the object to be cleaned can be made non-uniform, the thickness of the cleaning liquid applied to the object to be cleaned is uniformized by using the cleaning liquid height adjusting portion 10.

At this time, the height adjusting unit 10 is coupled to the flow case 100, the case 200, or any arbitrary object through the connection unit 13, and is fixed to the upper side of the object to be cleaned with a predetermined distance And the cleaning liquid discharged through the jetting unit 610 flows into the space 11 formed inside the height adjusting unit 10.

That is, the height adjusting unit 10 has a circular or polygonal shape corresponding to the object to be cleaned and has a predetermined thickness in the vertical direction, and the cleaning liquid applied to the object to be cleaned in the jetting unit 610 is supplied to the height adjusting unit 10 Of the thickness of the coating layer.

Therefore, the fine pattern formed on the surface of the object to be cleaned is prevented from being broken, and the cleaning can be made uniform.

The height adjuster 10 may be coupled to an external object through a connecting portion formed on the upper side, the upper side may be formed opposite to the porous nanostructure 600, and the lower side may be formed to be opposed to the object to be cleaned , And the upper surface must have a constant height.

The ultrasonic cleaning apparatus according to the present invention is characterized in that the second circulation part 120 and the second reception part 210 and the jet part 610 are disposed at the edges of the circulation case 100 and the case 200 The second housing part 210, the second housing part 210 and the jet part 610 may not be formed at the time of dry cleaning, .

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1000: The ultrasonic cleaning apparatus according to the present invention
100: Distribution case
110:
120: Second Distribution Section
130: first distribution section
200: housing case
210:
220: first accommodating portion
300: Compact unit
310: liquid supply pipe
320: gas supply pipe
330: Spas
340: liquid discharge pipe
350: gas discharge pipe
360: Integration Tube
400: Ultrasonic generator
500: carrier
510: first matching layer
520: second matching layer
600: Porous nanostructure
610:
620: Spout hole

Claims (10)

A distribution case 100 in which a storage part 110 and a first circulation part 130 are formed;
A receiving case 200 including a first receiving part 220 communicating with a lower end of the first circulating part 130;
A compact unit 300 provided in the first circulation unit 130 and supplying liquid and gas for generating cleaning material to the first storage unit 220;
An ultrasonic generator (400) installed at the receiving part (110) and emitting ultrasonic waves toward the first receiving part (220);
A carrier (500) on which the ultrasonic waves emitted from the ultrasonic generator (400) are positioned on a path for moving to the first accommodating part (220); And
A porous nanostructure 600 including a plurality of ejection holes 620 through which a cleaning substance located in the first accommodating portion 220 is ejected as an object to be cleaned; And an ultrasonic cleaning device.
The method according to claim 1,
The carrier 500 is a medium having an acoustic impedance value located between the acoustic impedance value of the cleaning material located in the first accommodating part 220 and the acoustic impedance value of the ultrasonic generator 400 , An ultrasonic cleaning device.
The method according to claim 1,
Wherein the transmitting body (500) is made of a plurality of matching layers whose acoustic impedance value gradually decreases as the first receiving part (220) gets closer to the receiving part (220).
The method of claim 3,
The carrier 500 has a fixing plate formed at an inner side where a plurality of the matching layers face each other and at least one position selected from among a matching layer and a lowermost side of a matching layer facing the first receiving portion 220 Wherein the ultrasonic cleaning apparatus comprises:
The method according to claim 1,
The compact unit 300 includes a liquid supply pipe 310 for supplying liquid to the first accommodating portion 220, a gas supply pipe 320 for supplying gas to the first accommodating portion 220, And a sparger (330) for separating the gas supplied to the first accommodating part (220) from the second accommodating part (320) into fine particles.
6. The method of claim 5,
The compact unit 300 further includes a liquid discharge pipe 340 for discharging a cleaning liquid in a liquid state that exceeds a space of the first storage unit 220 and a liquid discharge pipe 340 for discharging the cleaning liquid, Further comprising a gas exhaust pipe (350) for controlling the amount of gas.
The method according to claim 6,
Wherein the compact unit 300 is integrally coupled to the liquid supply pipe 310, the gas supply pipe 320, the liquid discharge pipe 340, and the gas discharge pipe 350.
The method according to claim 6,
The compact unit 300 is characterized in that the liquid supply pipe 310 is inserted into the liquid discharge pipe 340 and the gas supply pipe 320 is inserted into the gas discharge pipe 350. Device.
The method according to claim 6,
The compact unit 300 further includes an integrated pipe 360 in which the liquid supply pipe 310, the gas supply pipe 320, the liquid discharge pipe 340, and the gas discharge pipe 350 are inserted at predetermined intervals, The ultrasonic cleaning apparatus comprising:
10. The method according to any one of claims 1 to 9,
A second accommodating portion 210 formed in the accommodating case 200 and communicating with a lower end of the second accommodating portion 120; Further comprising a jetting section (610) for guiding the cleaning liquid located in the second containing section (210) to the object to be cleaned.

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