KR101125414B1 - Ultrasonic Washing Apparatus - Google Patents

Abstract

The present invention provides an ultrasonic cleaner including an ultrasonic vibrator having an ultrasonic vibrator, a flow channel channel for guiding introduced raw water to the ultrasonic vibrator, and a nozzle provided below the ultrasonic vibrator to spray raw water. The ultrasonic cleaner vibrates by the ultrasonic vibrator, and provides an ultrasonic cleaner, in particular, the domestic water-type ultrasonic cleaner characterized in that it comprises a central hole for continuously spraying the stream of raw water discharged to the predetermined length without interruption. In addition, the raw water flowing into the ultrasonic vibration unit does not form an air layer, thereby further increasing the cleaning effect, and simultaneously controlling the current applied to the ultrasonic vibration unit so as not to harm the human body.

Ultrasonic cleaner, flow type, vibrator

Description

Ultrasonic Washing Apparatus

The present invention relates to an ultrasonic cleaner, and more particularly, to a household-type ultrasonic cleaner for washing fruits, vegetables, dishes and the like by ultrasonically vibrating and spraying the introduced raw water.

In general, ultrasonic cleaning mainly uses cavitation (cavitation), spray atomization, or water particle acceleration by ultrasonic waves.

Cavitation is a phenomenon in which microbubbles are generated and dissipated by the pressure of ultrasonic waves when energy of ultrasonic waves propagates in a solution, accompanied by very high pressure and high temperature. Such an impact makes it possible to clean within a short time to the place where the inside of the object to be cleaned contained in the solution is not visible. In practice, the effect of stirring, thermal operation, etc., by the radial pressure of the ultrasonic wave itself on the impact energy caused by cavitation synergizes with the detergent, resulting in a high cleaning effect.

In addition, when the flowing water is irradiated with ultrasonic energy, the particle acceleration of the water is increased by the capillary wave, and by using this force, fine particles such as pesticides or impurities adhered to the object to be cleaned can be washed. In addition, such a cleaning method is applied to precision cleaning of semiconductors and the like because there is no possibility of re-contamination after washing, and less damage to the cleaned object.

In addition to the industrial ultrasonic cleaners used for precision cleaning of semiconductors, household ultrasonic cleaners can be used to save water at home and to remove foreign substances from fruits, vegetables and tableware (hereinafter referred to as `` cleaned objects ''). Is being developed.

In the case of such a household ultrasonic cleaner, a storage structure for applying ultrasonic vibration to the washing water stored in the storage tank in which the object to be cleaned and ultrasonic wave of the raw water introduced into the washing machine and flowing the ultrasonically vibrated water to the outside through a nozzle or the like. It is divided into a flow structure.

Figure 1 is a schematic diagram schematically showing the configuration of one embodiment of a conventional water-type ultrasonic cleaner.

As shown in FIG. 1, the conventional water-type ultrasonic cleaner 10 includes a housing 11 accommodating internal mounting parts, an ultrasonic oscillation circuit part 16 generating electric vibration, and high frequency electric vibration into mechanical vibration. The ultrasonic vibrator 12, an input cord 13 to which an external power source and an operating signal are applied to drive the ultrasonic vibrator 12, and bending of the coaxial cable 14 of the input cord 13. Protective gasket 15, a gasket 19 for preventing the washing water of the reservoir 21 from leaking to the periphery of the ultrasonic vibrator 12, and the ultrasonic vibrator 12 from the ultrasonic oscillation circuit portion 16. A metal plate 17 serving as a terminal for applying power to the power source; 20) And, the enemy house ultrasonic And a reservoir 21 for storing a predetermined amount of raw water to be irradiated, and includes an ultrasonic vibration spraying wash water exiting the spray nozzle (22).

Figure 2 is a schematic diagram schematically showing the configuration of another embodiment of a conventional domestic water-type ultrasonic cleaner.

The flow-type ultrasonic cleaner 30 includes a main flow path 31 through which raw water flows from the raw water inlet 39, a branch flow path 32 that is separated from the main flow path 31 and supplies raw water to a plurality of nozzles; An injection nozzle 33 for temporarily storing the raw water and ejecting it to the outside, an ultrasonic vibrator 34 for applying ultrasonic vibration to the raw water, and a gasket 35 provided between the ultrasonic vibrator 34 and preventing leakage; On the friction surface between the injection nozzle 33 and the housing 38, the oscillation circuit part 36 is mounted with various components for generating a driving signal for driving the ultrasonic vibrator 34 after receiving power from the outside. The shock absorber 37 is provided, and the power line unit 40 for transmitting the driving signal of the oscillation circuit unit 36 to the ultrasonic vibrator 34. The power line part 40 includes a coaxial cable 41, an insulation cap 42, and a spacer 43 for supporting and adjusting the distance of the coaxial cable 41 to attenuate the vibration of the ultrasonic vibrator 34. And so on.

However, in such a structure, when the ultrasonically vibrated raw water is ejected to the outside, the stream of water does not continue continuously and is cut off. In this case, ultrasonic waves are not delivered to the raw water that reaches the position where the washing of the object is substantially performed, and is lost in the air in the form of atomization, thereby reducing the cleaning effect.

In addition, the air layer is likely to be formed in the raw water introduced into the ultrasonic cleaner. There is a problem in that the ultrasonic wave is not sufficiently delivered to the raw water by the air layer to reduce the cleaning effect.

The present invention is to solve the above-mentioned conventional problems, an object of the present invention is to provide an ultrasonic cleaner including a central hole for continuously spraying ultrasonic streams of the raw water discharged to the outside without interruption to a predetermined length. . Here, the predetermined length means the length from the nozzle to the washing position where the object to be cleaned is located.

In addition, the ultrasonic cleaner to prevent the interruption of the water stream of the raw water discharged to the outside so that the ultrasonic wave is delivered to the position where the washing of the cleansing water is performed well, and the raw water introduced into the ultrasonic vibration unit does not form an air layer. It aims to provide.

In addition, an object of the present invention is to provide an ultrasonic cleaner with safety so as not to damage the human body.

As an aspect for achieving the above object, the present invention is provided with an ultrasonic vibration unit having an ultrasonic vibrator, a flow channel for guiding the incoming raw water to the ultrasonic vibration unit, and provided in the lower portion of the ultrasonic vibration unit In the ultrasonic cleaner comprising a nozzle for injecting, the nozzle is ultrasonically vibrated by the ultrasonic vibrator and the ultrasonic cleaner comprising a central hole for continuously spraying a stream of raw water discharged to the outside to a predetermined length to provide.

Further, the predetermined length is preferably a length from the nozzle to the washing position where the washing of the object is performed.

In addition, the diameter of the central hole is preferably proportional to the predetermined length.

In addition, the diameter of the central hole is preferably 6 to 15mm, in another embodiment is preferably 10mm or more.

In addition, the length of the central hole is preferably proportional to the diameter of the central hole.

In addition, when the diameter of the central hole is 6 to 15mm, the length of the central hole is preferably 10 to 30mm.

In addition, the ultrasonic cleaner preferably further comprises a plurality of outer holes for discharging the raw water to the outside.

In addition, the flow channel is two or more, any one of which is preferably at an angle in the direction in which the raw water flows. The other may be straight. In addition, the angle is 30 degrees or more, and the area of the flow channel is preferably 7 to 11 mm ² , respectively.

In addition, the current applied to the ultrasonic vibration unit is preferably controlled to adjust the sound pressure intensity of the raw water at the predetermined length.

In addition, the current applied to the ultrasonic vibration unit is preferably 200 to 700mA.

Moreover, it is preferable that the said sound pressure intensity | strength of the raw water in the said predetermined length is 0.3 Mpa or less.

In addition, the current applied to the ultrasonic vibration unit is preferably 600 mA or less, or preferably 300 mA or less.

As another aspect for achieving the above object, the present invention is provided with an ultrasonic vibration unit having an ultrasonic vibrator, a flow channel channel for guiding the introduced raw water to the ultrasonic vibration unit, and is provided in the lower portion of the ultrasonic vibration unit In the ultrasonic cleaner including a nozzle for injecting the raw water, it is controlled that the current applied to the ultrasonic vibrating unit to control the sound pressure intensity at a predetermined length of the raw water is ultrasonically vibrated by the ultrasonic vibrating unit and outflowed to the outside. desirable.

According to the present invention as described above, the cleaning effect is significantly increased by providing a flow type ultrasonic cleaner including a central hole for continuously spraying the water stream of ultrasonically vibrated and discharged to the outside without interruption to a predetermined length. .

In addition, in the washing machine, the washing effect is further increased by preventing the raw water flowing into the ultrasonic vibration unit from forming an air layer.

In addition to this washing effect, safety is provided so as not to damage the human body.

At the same time, by using the frictional force between the inner wall of the nozzle and the raw water to prevent the damage of the ultrasonic vibrator to increase the durability and life of the ultrasonic cleaner.

3 is a perspective view of one embodiment of the ultrasonic cleaner 100 according to the present invention.

As shown in FIG. 3, the ultrasonic cleaner 100 viewed from the outside includes a raw water inlet 110 through which raw water is introduced, an upper housing 180, a lower housing 190, and a nozzle 200.

4 is a cross-sectional view of an embodiment of the ultrasonic cleaner 100 according to the present invention as viewed along line AA ′ of FIG. 3.

As shown in FIG. 4, the ultrasonic cleaner 100 includes a raw water inlet 110 through which raw water is introduced, an ultrasonic vibration unit 150 for ultrasonically vibrating the introduced raw water, and a nozzle for radiating ultrasonically vibrated raw water to the outside. 200, and an upper housing 180 and a lower housing 190 for receiving mounting components therein.

The ultrasonic vibrator 150 includes an oscillator circuit 120 including a substrate 121 on which the transistor 122 is mounted, and an ultrasonic vibrator 130 that is disposed under the oscillator circuit 120 to apply ultrasonic vibrations to the introduced raw water. And a heat sink 140 having a vibrator seating opening 141 for mounting the ultrasonic vibrator 130.

The oscillation circuit part 120 receives electric power from the outside and generates high frequency electric vibration by a component mounted therein. The oscillation circuit unit 120 may be configured to be connected to a controller (not shown) separately installed to control the driving thereof.

The oscillation circuit unit 120 includes a plurality of components mounted on and / or under the substrate 121, and such components include heat generating components such as the transistor 122.

The ultrasonic vibrator 130 is disposed below the oscillation circuit 120, and is electrically connected to the oscillation circuit 120 to generate ultrasonic vibration (mechanical vibration).

The electrode of the ultrasonic vibrator 130 may be formed in a general shape such as a circle, but this is only an embodiment of the present invention and may have any other shape corresponding to the shape of the injection nozzle.

In addition, the ultrasonic vibrator 130 is configured to be electrically connected to the lower portion of the oscillation circuit 120 directly, it is possible to minimize the gap between the oscillation circuit 120 and the ultrasonic vibrator 130. Accordingly, in the driving voltage and signal voltage transmission process according to the present invention, the attenuation is minimized to improve efficiency, and the manufacturing cost can be obtained by using a general wire instead of a coaxial cable.

On the other hand, the heat sink 140 has a predetermined space formed on the side to accommodate the oscillator circuit 120 and the ultrasonic vibrator 130, the inside of the oscillator seating opening 141, the ultrasonic vibrator 130 is seated is formed. .

In one embodiment of the present invention, the heat sink 140 is made to contact the raw water to cool the heat generated from the oscillation circuit portion 120 through the raw water. In particular, in order to maximize the heat dissipation effect, at least one of the heat generating parts such as the transistor 122 of the oscillation circuit unit 120 may be brought into contact with the heat sink 140 to implement heat transfer by conduction. Excellent heat dissipation effect can be achieved by.

In the figure, the heat sink 140 is made of a cylindrical integral structure, but this is only one embodiment of the present invention, any shape corresponding to the size of the nozzle is possible, and other structures other than the integral structure for the heat dissipation effect is of course possible. .

The connection unit 160 is positioned below the ultrasonic vibration unit 150 to form flow channel channels 161 and 162 for guiding raw water introduced from the raw water inlet 110 and the inlet opening 115 to the ultrasonic vibration unit 150. do. (See Figure 7)

Below the connecting portion 160, a nozzle seating portion 170 positioned inside the lower housing 190 and fixing the nozzle 200 is positioned. Grooves may be present in the nozzle seating part 170 so that the protrusion 201 of the nozzle 200 may be mounted. Of course, any other coupling method other than the uneven coupling is possible.

The nozzle 200 includes a central hole 210 for discharging raw water to the outside.

5 and 6, the nozzle 200 will be described in more detail.

The nozzle 200 includes a central hole 210 for discharging raw water to the outside. The size of the central hole 210 is determined so that the raw water discharged to the outside through the central hole 210 can be continuously sprayed to a predetermined length without interruption. (See Figure 8b)

Here, the "predetermined length" means the length from the nozzle to the washing position where the washing of the workpiece is made. In the case of washing the wash in the home, the position of the wash is different depending on various variables such as the user, the size of the wash, the washing behavior, the position of the washing machine and the sink.

For example, when the ultrasonic cleaner according to the present invention is used in a general household, the washing position may be different according to the depth of the sink, and if the nominal standard of the sink currently used is changed by several centimeters, the washing is performed. The location can only be changed accordingly.

Therefore, of course, the "predetermined length" cannot be specified as a separate value. However, if the "predetermined length" which cannot be specified in this way is statistically analyzed as follows and described through an embodiment obtained through an experiment, the following is described.

In the home, when washing cleansed objects using raw water discharged to the outside through the nozzle, the washing is performed on an average of about 11 cm from the nozzle. The inventors have verified through experiments that the raw water discharged to the outside should be about 10 mm in diameter in order to continuously spray to the length of about 11 cm downward from the nozzle.

In addition, on the average, the cleaning is performed at a length of about 11 cm downward from the nozzle, but there may be a clearance of several centimeters above and below the washing position due to the movement of the user. The present inventors have confirmed through experiments that the diameter of the central hole 210 may be about 6 to 15 mm in order to continuously discharge the raw water discharged to the outside to the length in consideration of this clearance.

In another embodiment, when the wash is performed at a length longer than about 11 cm from the nozzle, the diameter of the center hole should be greater than 10 mm in order to continuously spray raw water without further breaks.

In short, the longer the predetermined length, i.e., if the wash position of the workpiece is made farther from the nozzle, the larger the diameter of the center hole must be in order to continuously spray raw water without further breaks. In other words, the predetermined length should be proportional to the diameter of the central hole.

Referring to Figures 8a, 8b, 9 will be described the features and effects of the embodiment of the present invention made to continuously spray the stream of raw water discharged to the predetermined length without interruption.

8A, 8B, and 9 are diagrams showing the results of experiments on the ultrasonic delivery degree and the cleaning effect of the ultrasonic cleaner according to the prior art and the ultrasonic cleaner according to the present invention. The ultrasonic cleaner according to the prior art used in the experiment has a plurality of holes, of which the diameter of the center hole is about 3 mm. The ultrasonic cleaner according to the embodiment of the present invention has a central hole 210 having a diameter of about 10 mm. The voltage applied to the ultrasonic vibrator is the same condition as 600 mA.

In this experiment, Figure 8a is a photograph taken at 9000 frames per second of the raw water sprayed from the nozzle of the ultrasonic cleaner according to the prior art, Figure 8b is the raw water sprayed from the nozzle of the ultrasonic cleaner according to an embodiment of the present invention per second The picture was taken at 9000 frames. Raw water injected through the nozzle according to the present invention is discharged to the outside continuously without interruption to a predetermined length, it can be seen that the ultrasonic cleaner according to the prior art does not.

The table below measures the sound pressure of the raw water along the length from the nozzle to the bottom to check whether the ultrasonic wave is transmitted in this experiment.

Measuring distance from nozzle 0 mm 20mm 40 mm 60 mm 80 mm 100 mm 3mm diameter hole 1 MPa Instability Instability Instability Instability Not delivered 10 mm diameter hole 1.54 MPa 1.23 MPa 0.93 MPa 0.93 MPa 0.93 MPa 0.93 MPa

"Unstable" means that the variation in the measured sound pressure is large, making measurement difficult but substantially close to zero. That is, in the prior art having a central hole having a diameter of about 3 mm, it was confirmed that almost no ultrasonic waves were transmitted to the raw water about 20 mm below the nozzle.

9 is an experimental result graph for confirming the washing effect under the same conditions. When the fluorescent particles were placed on a glass substrate of 70 mm x 70 mm below 80 mm from the nozzle and a current of 600 mA was applied to the ultrasonic vibrator, it was measured how much the particles were removed. The Y axis represents the particle removal efficiency (PRE) as a percentage, and the X axis represents the radius of the circular range in which the particles to be cleaned are removed in mm. Particle removal efficiency (PRE) refers to the cleaning effect.

As shown in Figure 9, in the prior art ultrasonic cleaner having a central hole of about 3mm in diameter, the range of the PRE of 50% or more is only a circle of about 1.2mm radius, ultrasonic cleaner according to the present invention The range of more than 50% of PRE is larger than the circle of about 25mm radius.

Through the above experimental results, the ultrasonic cleaner of the present invention, which is made so that the stream of raw water discharged to the outside is continuously made to a predetermined length without interruption, the cleaning efficiency is increased by about 400 times or more compared with the ultrasonic cleaner according to the prior art. It can be seen.

Again, a nozzle according to the present invention will be described with reference to FIGS. 5 and 6.

As described above, the central hole 210 of the nozzle of the ultrasonic cleaner according to the present invention has a size for continuously making the stream of raw water discharged to the outside through the central hole without interruption. As described above, the predetermined length and the diameter of the central hole 210 are proportional to each other, and in one preferred embodiment, the diameter of the central hole 210 is about 6 to 15 mm, and in another preferred embodiment, the diameter is about 10 mm. In one preferred embodiment, the diameter is about 10 mm. However, this is only an embodiment of the present invention and the scope of the claims is of course not limited thereto.

In addition, since the diameter of the central hole 210 is increased compared to the prior art, bubbles may be excessively generated on the surface of the ultrasonic vibrator 130, and thus the ultrasonic vibrator 130 may be damaged. In order to prevent this, the length d of the central hole 210 may be adjusted.

When raw water is discharged to the outside a portion of the raw water flows on the inner wall of the nozzle 200. At this time, the friction force is generated between the raw water and the inner wall to reduce a portion of the energy transmitted to the ultrasonic vibrator 130 on the nozzle 200. In this manner, it is possible to prevent excessive generation of bubbles in the ultrasonic vibrator 130, thereby preventing damage to the ultrasonic vibrator 130.

Therefore, the length d of the central hole 210 must reach a certain length so as to transmit sufficient friction force, thereby preventing damage to the ultrasonic vibrator 130. However, the larger the diameter of the central hole 210, the less the influence of the friction force generated on the inner wall of the nozzle 200 on the ultrasonic vibrator 130, the diameter of the central hole 210 and the central hole 210 The length of d should be proportional.

The present inventors confirmed that the length d of the central hole 210 should correspond to 10 to 30 mm when the diameter of the central hole 210 was 6 to 15 mm through experiments.

In addition, in one embodiment of the present invention, the nozzle having a central hole 210 according to the present invention may be adopted, and a plurality of streams of water may be discharged to the outside. That is, apart from the central hole 210 in which the ultrasonically vibrated raw water is discharged to the outside, the raw material may be further provided with a separate outer hole (not shown) so that raw water not ultrasonically vibrated is discharged from the periphery of the central hole 210.

In the case of the ultrasonic cleaner 100 used at home, the overall size may be limited to some extent. Since the diameter of the center hole 210 of the nozzle according to an embodiment of the present invention is about 10 mm larger than that of the nozzle of the prior art, the diameter of the outer hole is reduced within the limited nozzle size, and thus the outer hole. The stream of raw water sprayed through may not be continuously sprayed to a predetermined length without interruption.

That is, since ultrasonic waves may not be transmitted to the raw water injected through the outer hole, the outer hole may be directly connected to the raw water inlet 110 without being passed through the ultrasonic vibration unit 150 and discharged to the outside.

In this case, the ultrasonic water is delivered to the raw water discharged from the center hole 210 to the outside, and thus the washing water is high, and the ultrasonic wave is not transferred to the raw water discharged from the outside hole to the outside, and thus may be raw water for the purpose of rinsing.

In another embodiment of the present invention, by increasing the overall size of the ultrasonic cleaner 100 so that the ultrasonic wave is transmitted to both the raw water passing through the central hole 210 and the outer hole, and all of the raw water discharged through it is continuously and a predetermined length You can also get to.

7 is a longitudinal cross-sectional view of an embodiment of an ultrasonic cleaner 100 according to the present invention as viewed along line BB ′ of FIG. 4.

The raw water introduced through the raw water inlet 110 flows through the raw water opening 115 through the plurality of flow channel channels 161 and 162 formed by the shape of the connection unit 160 to the ultrasonic vibration unit 150. The flow channel channels 161 and 162 allow the raw water entering the ultrasonic vibration unit 150 to enter at a higher speed to form a vortex.

When the raw water is introduced into the ultrasonic cleaner 100, the flow direction is changed in the vicinity of the ultrasonic vibrator 150 to form an air layer inside the ultrasonic cleaner. When the raw water in which the air layer is formed is ultrasonically vibrated and discharged to the outside, the ultrasonic wave may not be sufficiently transmitted to all the raw water due to the air layer, thereby reducing the washing efficiency.

By forming a unique flow channel (161, 162) to prevent this, the raw water can enter at a high speed to form a vortex to reduce the probability of generating an air layer inside the ultrasonic cleaner.

In the embodiment shown in FIG. 7, there are two flow channels 161 and 162, and the inflow direction is shown by the arrow. One flow channel 162 is a straight line, the other flow channel 161 forms an angle α in the direction in which the raw water flows.

In experiments to determine the optimal reduction of air layer formation, the present inventors confirmed that the effect is excellent when the angle (α) is 30 degrees or more, and particularly the effect is excellent when the angle (α) is 60 degrees.

As the flow channel 161 is at a predetermined angle, as the raw water flows into the ultrasonic cleaner 100, the flow path becomes smaller and gradually increases in velocity of the incoming water. Accordingly, the raw water introduced in both directions of the channel channels 161 and 162 forms a vortex at the center, thereby reducing the probability of generating an air layer.

In addition, when the area of the channel channels 161 and 162 is 7 to 11 mm ² , respectively, the vortex generation effect is most excellent.

7 is only one embodiment of the present invention, the number of flow channel can be different, and of course, different shapes of the flow channel to speed up the incoming raw water is possible.

10 and 11, the magnitude of the sound pressure of the current applied to the ultrasonic vibration unit 150 and thereby ultrasonically vibrated raw water will be described.

10 is a graph illustrating an experimental result of measuring sound pressure of raw water by changing a current applied to the ultrasonic vibration unit 150.

When washing the object using the ultrasonically vibrated raw water by the ultrasonic vibrator 150 at home, the ultrasonically vibrated raw water may be in contact with a body part such as a user's hand.

The size of the ultrasonic wave transmitted to the raw water can be known by measuring the sound pressure of the raw water, and can be adjusted by a method such as controlling the magnitude of the current applied to the ultrasonic vibration unit 15.

In general, the greater the ultrasonic waves delivered, the greater the cleaning effect. However, when a part of the human body comes in contact with the raw water to which excessive ultrasonic waves are delivered, there is a risk of damaging human tissue by heat, mechanical force and bubbles.

With regard to heat, there is a risk of burns due to absorption of ultrasound, which is related to thermal inertia by the time-averaged intensity (I _SPTA ) of ultrasound.

With regard to mechanical force, there is a risk of expansion and contraction of cellular tissue during ultrasound delivery, which is related to the instantaneous intensity of ultrasound.

There is a risk of damage to cellular tissues due to the generation of air bubbles in the liquid inside the body tissue to which ultrasound is delivered, which is related to the instantaneous intensity and the time average intensity of the ultrasound.

In the ultrasonic cleaner according to the prior art, since there was little sound pressure at the washing position spaced from the nozzle by a predetermined length, there was almost no need to limit the current applied to the ultrasonic vibrator, but in the ultrasonic cleaner according to the present invention, more ultrasonic waves were applied. The safety of the user should be considered further.

Therefore, in consideration of the above matters, it is preferable to increase the cleaning effect by maximizing ultrasonic waves within a range that does not affect the human body. To this end, the present invention controls the current applied to the ultrasonic vibration unit 150 to adjust the sound pressure intensity of the raw water at a predetermined length in which the wash of the object is made.

Although the regulation on the size of the ultrasonic cleaner for the ultrasonic cleaner in consideration of the effect on the human body is not separately defined, for the safety of the user using the ultrasonic cleaner according to the present invention, the electronic medical device standard of the Korea Food and Drug Administration, the Canadian Health Department regulation and the ultrasonic wave International regulations on medical equipment used are referred to.

In the case of the Korea Food and Drug Administration, the limit of ultrasound size is 0.1W / cm ² when using the neurosurgery imaging mode, and the limit is 0.04W / cm ² when using the gynecological imaging mode. Limited to 3 W / cm ² (0.3 MPa).

Through these criteria, the inventors confirmed that it is safe for the human body that the sound pressure in the washing position is 0.3 MPa or less.

The table below shows an experiment in which the current applied to the ultrasonic vibration unit 150 is adjusted in one embodiment of the present invention having a diameter of about 10 mm, and the washing position spaced apart by a predetermined distance below the nozzle. Some of the results of measuring the sound pressure at, which are shown graphically in FIG. 10.

Measuring distance from nozzle 0 mm 20mm 40 mm 60 mm 80 mm 100 mm 600 mA 1.54 MPa 1.23 MPa 0.93 MPa 0.93 MPa 0.93 MPa 0.93 MPa 300 mA 0.43 MPa 0.31 MPa 0.31 MPa 0.25 MPa 0.25 MPa 0.21 MPa

In this result, it was confirmed that a current of 300 mA or less is preferably transmitted to the ultrasonic vibration unit 150 in order to deliver a sound pressure of 0.3 MPa or less in the washing position spaced by a predetermined distance.

FIG. 11 is a graph showing experimental results deriving a washing effect according to an applied current.

In this experiment, fluorescent particles were placed on a glass substrate of 70 mm x 70 mm below 80 mm from the nozzle. According to the present invention, when a hole having a diameter of about 3 mm is provided and a current of 600 mA is applied to the ultrasonic vibrator, the center hole having a diameter of about 10 mm is provided according to the present invention, and a current of 600 mA is applied to the ultrasonic vibrator. Accordingly, when a central hole having a diameter of about 10 mm was provided and a current of 300 mA was applied to the ultrasonic vibrator, the particle removal efficiency PRE was measured and compared. The Y axis is the percentage of particle removal efficiency (PRE), and the X axis is the radius of the circular range in which the object is washed, in mm.

As shown in FIG. 11, in the prior art ultrasonic cleaner adopting a hole having a diameter of about 3 mm, the range of the PRE of 50% or more is only a circle of about 1.2 mm radius, and the ultrasonic cleaner according to the present invention is about 600 mA. When the current is applied, the range of the PRE is 50% or more is greater than the circle of about 25mm radius, and when the current of about 300mA is applied to the ultrasonic cleaner according to the present invention, the range of the PRE is 50% or more is the circle of about 20mm radius.

Although the cleaning effect of applying a current of about 600 mA to the ultrasonic vibration unit of the ultrasonic cleaner according to the present invention is 1.5 times or more, there is a risk of damage to the human body as described above. Therefore, in consideration of this, the current applied to the ultrasonic vibrator is preferably 600 mA or less in one embodiment considering the cleaning effect even more, and the current applied to the ultrasonic vibrator is preferably 300 mA or less in an embodiment considering the human risk. Do.

The smaller the current applied, the lower the risk of human injury, but the lower the cleaning effect. Conversely, as the applied current increases, the cleaning effect increases, but the risk of human damage increases.

Therefore, the ultrasonic cleaner according to the present invention is preferably made such that the sound pressure at the washing position spaced a predetermined distance from the nozzle is lower than 0.3 MPa.

In another embodiment, a current of about 600 mA or less is preferably applied to the ultrasonic vibration unit in view of the cleaning effect, and when a current exceeding about 700 mA is applied, the risk to the human body may be excessively high.

In another embodiment, a current of about 300 mA or less is preferably applied to the ultrasonic vibration unit in terms of reducing the risk of human injury, and when a current lower than about 200 mA is applied, the cleaning effect may be excessively reduced.

In one embodiment of the present invention in consideration of this, it is preferable that a current of 200 to 700mA is applied.

While the invention has been shown and described with respect to specific embodiments thereof, those skilled in the art can variously modify the invention without departing from the spirit and scope of the invention as set forth in the claims below. And that it can be changed. Nevertheless, it will be clearly understood that all such modifications and variations are included in the scope of the present invention.

Figure 1 is a schematic diagram schematically showing the configuration of one embodiment of a conventional water-type ultrasonic cleaner.

Figure 2 is a schematic diagram schematically showing the configuration of another embodiment of a conventional water-type ultrasonic cleaner.

3 is a perspective view of the ultrasonic cleaner according to an embodiment of the present invention.

4 is a cross-sectional view of the ultrasonic cleaner according to one embodiment of the present invention, as seen from A-A 'of FIG.

5 is a sectional view of a nozzle according to an embodiment of the present invention.

6 is a bottom view of the nozzle according to the embodiment of the present invention.

FIG. 7 is a cross-sectional view of the ultrasonic cleaner according to one embodiment of the present invention, as seen from BB ′ of FIG. 4.

8A and 8B are photographs comparing raw water discharged to the outside through the ultrasonic cleaner according to the prior art and raw water discharged to the outside through the ultrasonic cleaner according to the present invention.

Figure 9 is a graph of the experimental results comparing the cleaning effect of the ultrasonic cleaner according to the prior art and the ultrasonic cleaner according to the present invention.

10 is a graph measuring the sound pressure of the raw water discharged to the outside through the ultrasonic cleaner according to the present invention.

11 is a graph of an experimental result comparing the cleaning effect of the ultrasonic cleaner according to the prior art and the ultrasonic cleaner according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: ultrasonic cleaner 110: raw water inlet

120: oscillation circuit portion 130: ultrasonic oscillator

140: heat sink 150: ultrasonic vibration unit

160 connection part 170 nozzle mounting part

180: upper housing 190: lower housing

200: nozzle 210: central hole

Claims (23)

An ultrasonic vibrator having an ultrasonic vibrator, A flow channel for guiding the introduced raw water to the ultrasonic vibration unit; In the ultrasonic cleaner comprising a nozzle provided in the lower portion of the ultrasonic vibration unit for spraying raw water, The nozzle includes a central hole for continuously spraying a stream of raw water ultrasonically vibrated by the ultrasonic vibrator and discharged to the outside to a predetermined length, The channel is at least two, and Any one of the two or more flow channel is characterized in that the angle (α) in the direction in which the raw water flows, Ultrasonic cleaner. The method of claim 1, The predetermined length is characterized in that the length from the nozzle to the washing position where the cleaning of the object is made, Ultrasonic cleaner. The method according to claim 1 or 2, Characterized in that the diameter of the central hole is made to be proportional to the predetermined length, Ultrasonic cleaner. The method according to claim 1 or 2, Characterized in that the diameter of the central hole is 6 to 15mm, Ultrasonic cleaner. The method according to claim 1 or 2, Characterized in that the diameter of the central hole is 10mm or more, Ultrasonic cleaner. The method according to claim 1 or 2, The length of the central hole is characterized in that it is made to be proportional to the diameter of the predetermined central hole, Ultrasonic cleaner. The method of claim 4, wherein The length of the central hole is characterized in that 10 to 30mm, Ultrasonic cleaner. The method according to claim 1 or 2, The ultrasonic cleaner further comprises a plurality of outer holes for discharging the raw water to the outside, Ultrasonic cleaner. delete The method according to claim 1 or 2, Characterized in that the other of the two or more flow channel is formed in a straight line, Ultrasonic cleaner. The method according to claim 1 or 2, The angle (α) formed by any one of the flow channel is characterized in that more than 30 degrees, Ultrasonic cleaner. The method according to claim 1 or 2, The area of the flow channel is characterized in that each of 7 to 11mm ² , Ultrasonic cleaner. The method according to claim 1 or 2, Characterized in that the current applied to the ultrasonic vibration unit is controlled to adjust the sound pressure intensity of the raw water at the predetermined length, Ultrasonic cleaner. The method of claim 13, The current applied to the ultrasonic vibration unit is characterized in that 200 to 700mA, Ultrasonic cleaner. The method of claim 13, The sound pressure intensity of the raw water at the predetermined length is 0.3 MPa or less, Ultrasonic cleaner. The method of claim 13, The current applied to the ultrasonic vibration unit is characterized in that less than 600mA, Ultrasonic cleaner. The method of claim 13, The current applied to the ultrasonic vibration unit is characterized in that less than 300mA, Ultrasonic cleaner. delete delete delete delete delete delete

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