KR102011350B1 - Cleaning device for animal including ultrasonic-microbubble system - Google Patents

Abstract

The present invention relates to an animal cleaning apparatus including an ultrasonic microbubble system, and more particularly, to an ultrasonic microbubble system capable of removing fine substances to be removed using ultrasonic waves and microbubbles, and having excellent cleaning power. It relates to a cleaning device comprising.

Description

Cleaning device for animal including ultrasonic-microbubble system

The present invention relates to an animal cleaning apparatus including an ultrasonic microbubble system, and more particularly, to an ultrasonic microbubble system capable of removing fine substances to be removed using ultrasonic waves and microbubbles, and having excellent cleaning power. It relates to a cleaning device comprising.

Ultrasonic wave means a sound having a higher frequency than human audible sound, that is, an audible frequency (20 ~ 20,000 Hz), and mechanical vibration occurs when a piezoelectric material is expanded and contracted by applying voltage. Ultrasonic waves are generated using this generating principle.

This ultrasonic wave is a vibration sound wave that is attenuated in the air but propagates far away in water or oil.In addition, the higher the Hz, the higher the bioabsorption rate, and the lower the frequency (1 MHz) penetrates deeply. It is used for ultrasonic breakdown, washing, etc., and high frequency (3 MHz) is used for skin care due to surface penetration.

In particular, ultrasonic cleaning generates high-frequency ultrasonic waves in water to remove fine dust and residual pesticides from fruits and vegetables by vibrating water molecules, which can be used for kitchenware such as tableware, cutlery, scissors, glasses, toothbrushes, etc. It is easily used for cleaning for skin care because it has an advantage that it can be cleaned in a short time even between the minute gaps that are not deep inside or reach out of the inside.

On the other hand, microbubble (microbubble) is an ultra-fine bubble that can not be identified by the eyes of 10 ~ 50 ㎛ diameter or less and refers to air particles finer than the pores (25 ㎛) of the skin to 1 / 2,000 size of the general bubble.

These microbubbles have a low buoyancy and rise at a very slow rate of 0.1 cm / sec to the surface. Normal bubbles rise in the water and rupture at the surface, but microbubbles generate energy before they reach the surface. Actions such as ultrasonic generation, high sound pressure of 140 db and instantaneous high heat generation of 4,000 ~ 6,000 ℃.

In addition, it has excellent skin regeneration and antiseptic effect and is used for skin cleansing and is currently used in various areas due to physical and chemical properties such as gas dissolution effect, self-pressurizing effect, and charging effect.

Sterilization occurs during the stabilization of the microbubble water, and the high temperature of 4,000 ~ 6,000 ℃ and the shock wave of 500 atm of liquid are generated at the moment of 1 millionth of a second when the bubble bursts by the self-pressurizing effect. In addition, the amount of dissolved oxygen is increased by 40% compared to the existing tap water, forming a pollutant adsorption cleaning effect, vibration wave generation through bubble burst, anion generation and hot spot.

The microbubble generation method includes a pressurized dissolving device, a pressurized melting method, and an upstream swing type. The pressurized melting method is generally used. However, the pressurized melting method has a low flow rate and is used to produce a high concentration of microbubbles, but consumes power. There is a problem that a large and constant size of the bubble is not continuously generated in recent years has been used a lot of pressure swing method.

On the other hand, as a conventional technology related to a cleaning device using ultrasonic waves or microbubbles, Korean Utility Model Publication No. 1998-027960 (1998.08.05.) Discloses a technique related to an ultrasonic dish washer, and the Korean Patent Application Publication 10-2008-0092750 (October 16, 2008) discloses an oxygen microbubble supply device for a bath.

However, in the practical application of the conventional ultrasonic cleaning apparatus, there are problems that various factors such as temperature, dissolved gas, output, frequency, etc. that hinder the characteristics of ultrasonic waves occur, and thus the cleaning effect is deteriorated.

In addition, in the case of the conventional microbubble cleaning device, impurities may easily be released due to the fine bubbles, but there is a problem that it is difficult to clean within a short time to a place between the minute gaps that are not deeply touched or reach inside.

Therefore, there is a continuing need for the development of a cleaning device that can improve the above problems and maximize the cleaning effect.

Korean Utility Model Publication No. 1998-027960 (1998.08.05.) Korean Patent Publication No. 10-2008-0092750 (2008.10.16.)

It is a main object of the present invention to provide an animal cleaning apparatus including an ultrasonic micro-bubble system capable of removing fine substances to be removed and having excellent cleaning power.

In order to achieve the above object, the present invention provides a cleaning device for generating an ultrasonic wave and a microbubble inside the washing tank filled with the washing water to wash the animals contained in the washing water, the washing tank filled with the washing water; Located in the washing tank, the microbubble generating device for generating a plurality of microbubbles into the washing tank; And an ultrasonic generator positioned in the washing tank and generating ultrasonic waves into the washing tank. The ultrasonic cleaning apparatus for animals includes a ultrasonic micro-bubble system.

According to an embodiment, the washing apparatus may saturate the washing water with a microbubble using a microbubble generating device and then wash the animals contained in the washing water by irradiating ultrasonic waves.

In addition, according to an embodiment, the ultrasonic generator may use a low power high frequency.

In addition, according to one embodiment, the washing water may be any one selected from water, saline or lotion.

According to one embodiment, the low power high frequency may be an intensity of 500W or less.

Animal cleaning apparatus including the ultrasonic micro-bubble system according to the present invention is capable of removing the fine material to be generated by the synergistic effect of the ultrasonic wave and micro bubble, excellent cleaning power, such as pets, farms, etc. There is an effect to maximize the cleaning effect.

In addition, it can be cleaned within a short time to the depth of the water to be cleaned, bacteria and foreign matter can be easily removed, high cleaning power, there is an effect that can be environmentally clean without using a cleaning agent.

1 is a schematic diagram of an animal cleaning device including an ultrasonic-microbubble system according to an embodiment of the present invention.
2 is an explanatory diagram of cavitation generation in ultrasonic waves.
Figure 3 shows the washing process by cavitation.
Figure 4 shows the result of measuring the dissolved oxygen amount of Comparative Examples 1 to 7 in a graph.
Figure 5 shows the result of measuring the dissolved oxygen amount of Example 1 in a graph.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. In general, the nomenclature used herein is well known and commonly used in the art.

Throughout this specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding the other components unless otherwise stated.

The present invention relates to a washing apparatus for generating ultrasonic waves and microbubbles into a washing tank filled with washing water, and washing the animals contained in the washing water. Located in the washing tank, the microbubble generating device for generating a plurality of microbubbles into the washing tank; And an ultrasonic generator positioned in the washing tank and generating ultrasonic waves into the washing tank. The ultrasonic cleaning apparatus for animals includes a ultrasonic micro-bubble system.

Referring to this in more detail with reference to Figure 1, Figure 1 is a schematic diagram of the cleaning device for animals including the ultrasonic-microbubble system according to an embodiment of the present invention, the washing tank 10 that can fill the washing water (11) It is characterized in that the microbubble generator 20 and the ultrasonic generator 30 is included in the inside.

Ultrasonic cleaning is based on the principle that the sound waves vibrate water for tens of thousands of seconds to remove foreign substances adhering to the surface of the object. At this time, the cavitation phenomenon occurs in the ultrasonic waves.

 When a powerful ultrasonic wave is irradiated into the liquid, the ultrasonic wave becomes a pressure wave, and the compressive force (static pressure) and the expansion force (negative pressure) repeatedly appear as shown in FIG. 2, and bubbles are generated around the fine foreign matter in the liquid during the negative pressure cycle. Bubbles will disappear in the next compression cycle.

The process of removing the contamination by cavitation is shown in FIG. 3, and as shown in (a) of FIG. 3, the cavitation bubble explodes to form a gap between contaminants, and as shown in (b), the bubble penetrates into the gap and explodes. Desorbs contaminants.

On the other hand, the microbubble is a magnetic pressurization effect, the magnetic pressurization effect refers to a phenomenon in which the bubbles staying in the water are bursting by themselves when they are compressed and pressurized by the external pressure.

In a short time of one millionth of a second, the chain reaction of compression and rupture is repeated. This is caused by the force of surface tension compressing the gas inside a bubble having a spherical interface. (140 dB of sound wave), when released into the air anionizes the air with the Leonard effect.

In addition, when bubbles burst due to the self-pressing effect, instantaneous high temperatures of about 4,000 to 6,000 ° C. and about 500 atmospheres of shock waves are generated to sterilize harmful microorganisms such as E. coli in water.

As described above, the ultrasonic cleaning is mainly performed in the cavitation phenomenon of the ultrasonic wave, and when the energy of the ultrasonic wave propagates in the solution, microbubbles are generated and dissipated by the pressure of the ultrasonic wave. This shock wave has an effect that can be cleaned within a short time to the place where the inside of the object to be washed in the liquid is not visible.

In addition, the microbubble has a small pore size, a large surface area, and maintains a negative charge, which makes it easy to remove bacteria and foreign matters. Due to the synergy of the self-pressing effect of the microbubble and the microbubble has the effect of maximizing the cleaning power, thereby obtaining excellent cleaning effect in pets, farms and the like.

On the other hand, the animal cleaning apparatus including the ultrasonic micro-bubble system of the present invention, the microbubble generating device 20 and the ultrasonic generating device 30 may each include one or more, each microbubble generating device It is preferable to position 20 and the ultrasonic wave generator 30 so that they do not overlap.

In addition, the microbubble generating device 20 and the ultrasonic generating device 30 may be located anywhere in the washing tank 10, but preferably located below the washing tank 10.

In addition, the type of the washing water 11 may include water, saline, lotion, and the like, but is not limited thereto.

In addition, the washing apparatus may saturate the washing water with a microbubble using a microbubble generating device, and then wash the animal, which is the wash water contained in the washing water, by irradiating ultrasonic waves.

In this case, when ultrasonic waves are irradiated after saturating the washing water with microbubbles, bubbles are instantaneously destroyed and high temperature, pressure, and secondary ultrasonic waves are generated to maximize cleaning power, whereas ultrasonic waves are first irradiated or microbubbles and ultrasonic waves are applied. When generated together, the bubble is broken at the discharge hole of the microbubble, which causes a problem that the cleaning power is reduced.

In addition, the ultrasonic generator preferably uses a low power high frequency of 500W or less, and when using a high power high frequency, negative effects not only to the object to be removed but also to the object to be cleaned, may cause problems in application at high cost and low efficiency. Because there is.

On the other hand, when using low-power high-frequency, there is no negative effect on the object to be removed because it does not affect the morphological changes and movements of the object to be cleaned, and it is effective for cleaning because it can cause and destroy the morphological change of the object to be removed.

Hereinafter, the present invention will be described in more detail with reference to Examples. However, the following examples are merely to illustrate the invention, the content of the present invention is not limited by the following examples.

[ Example ]

Example is the result of performing a high pressure washing process after forming the primary ceramic coating layer according to the present invention, performing a surface roughness control process.

Experimental Example  1: Measurement of dissolved oxygen

Dissolved Oxygen refers to the amount of oxygen dissolved in water. Dissolved Oxygen refers to the amount of dissolved oxygen, including water temperature (reduced dissolved oxygen when water temperature rises), barometric pressure, and solute.In addition, dissolved oxygen increases the absorption rate and metabolism in the body when drinking. It is active and has a characteristic of rapidly decreasing with time.

Dissolved oxygen content was measured using a DO6 + Hand Held Dissolved Oxygen Meter (EUTECH), the experiment was carried out using 10 L of tap water at 22 ℃.

<Comparative Examples 1 to 7>

Comparative Examples 1 and 2 measured the dissolved oxygen amount after generating the microbubbles, and the microbubbles were generated for 15 minutes using a microbubble device manufactured by Puritec.

Comparative Examples 3 to 5 measured the amount of dissolved oxygen after generating ultrasonic waves, and generated ultrasonic waves for 3 minutes using JAC-4020 (JINWOO-ALEX) including a total of eight ultrasonic generators at the bottom of the experiment vessel. , Comparative Example 3 is to measure the amount of dissolved oxygen on the left side of the experiment vessel, Comparative Example 4 is to measure the amount of dissolved oxygen on the right side of the experiment vessel, Comparative Example 5 is measured the amount of dissolved oxygen in the middle of the experiment vessel according to the ultrasonic irradiation point The procedure of generating and stopping for 30 seconds was repeated to measure the dissolved oxygen change.

Comparative Examples 6 and 7 measure the dissolved oxygen amounts of distilled water and tap water, respectively, which have not been treated.

The dissolved oxygen amount measurement results of Comparative Examples 1 to 7 are as shown in FIG. 4.

<Example 1>

Example 1 generated both microbubbles and ultrasonic waves, and stabilized by generating microbubbles for 5 minutes, and then repeating the process of operating ultrasonic waves for 60 seconds at 1 minute intervals twice, and then reducing the amount of dissolved oxygen in a 1L container. Was measured, and the result is as shown in FIG.

First, in the graph of FIG. 4, the dissolved oxygen amounts of Comparative Example 6 and Comparative Example 7 which were not treated with anything were about 8 ppm, and among the Comparative Examples 3 to 5, the left side (Comparative Example 3) and the right side ( The dissolved oxygen amount of Comparative Example 4 was about 15 ppm, which was higher than that of Comparative Example 6. On the other hand, Comparative Example 5 measured the dissolved oxygen amount in the middle portion of the ultrasonic generating device, in Comparative Example 5 can be seen that increases with the ultrasonic generation exceeds the 20ppm to the range that can not be measured by this measuring equipment, In addition, it can be seen that the dissolved oxygen decreases rapidly when the ultrasonic wave is stopped.

In addition, in FIG. 5, the amount of dissolved oxygen was measured at 17 to 18 ppm when the first ultrasonic wave was generated after generating the microbubble, and since the second ultrasonic wave was generated at 20 ppm or more, the measurement was not possible. Subsequently, it took 8 seconds to stop the microbubble and the ultrasonic wave and to reduce it to 12 ppm. Afterwards, it was found that it used 38 minutes to reduce the existing tap water to 8.3 ppm. In view of these results, it is judged that the amount of dissolved oxygen in the washing water can be maintained high when ultrasonic waves are generated after generating the microbubbles during washing.

Experimental Example  2: Determination of cleaning power

Washing was performed in four ways: tap water, microbubbles, ultrasonic waves, microbubbles + ultrasonic waves, and the cleaning power of each was as follows: skin gauge (GENIE SKIN, AM Corporation), USB microscope (Dino-Lite Edge Digital Microscope AM7115MZTL) , Narae Plus Co., Ltd. measured the surface by measuring the color conversion.

The number of pixels through Photoshop was used to measure the cleaning rate for each variable through the area removed relative to the total area, and in order to proceed with uniform coating, the barcota was used under the same conditions.

<Experimental Example 2-1 to Experimental Example 2-4> Orange surface cleaning power experiment

Orange surface cleaning power experiments of Experimental Examples 2-1 to 2-4 were each washed for 30sec, and in the case of microbubbles (Experimental Example 2-3), washing was performed after stabilization, and microbubble + ultrasonic waves (Experimental Example 2- In the case of 4), after the microbubble stabilization, the ultrasonic waves were operated at 60-second intervals for 1 minute and then washed.

The orange surface was measured by a skin meter, and the number of pixels was analyzed. The results are shown in Table 1 below.

As shown in Table 1, the washing rate of tap water (Experimental Example 2-1) is 5.19%, the washing rate of ultrasonic waves (Experimental Example 2-2) is 25.38%, the washing rate of microbubbles (Experimental Example 2-3) ) Is 6.91%, the microbubble + ultrasonic wave (Experimental Example 2-4) is 57.48%, when using the microbubble and ultrasonic waves, it can be seen that the cleaning rate is more than twice that of the current ultrasonic waves.

<Experimental Example 2-5 to Experimental Example 2-8> Apple surface cleaning power experiment

Apple surface cleaning power experiments of Experimental Examples 2-5 to 2-8 were each washed for 30sec, the microbubble (Experimental Example 2-7) was washed after stabilization, microbubble + ultrasound (Experimental Example 2- In the case of 8), after the microbubble stabilization, the ultrasonic waves were operated at an interval of 1 minute for 60 seconds and then washed.

The apple surface was measured by a skin measurer to analyze the number of pixels, and the results are shown in Table 2 below.

As shown in Table 2, the tap water washing rate (Experimental Example 2-5) is 0.91%, the ultrasonic washing rate (Experimental Example 2-6) is 3.29%, the microbubble washing rate (Experimental Example 2-7 ) Is 2.14%, the microbubble + ultrasonic wave (Experimental Example 2-8) is 21.05% wash rate when using a microbubble and ultrasonic waves can be seen that more than six times better than the ultrasonic waves currently used.

Moisture Paste Detergent Test

Moisture paste is coated with 1 g of paste on the artificial pad (skin pad) with bakota, and the paste was prepared by mixing 9 g of water grass and 1 g of ink, wherein the moisture paste is a total pad of 13 cm in total length and 3 cm in width. Only 10 cm in length will be subjected to the bakota coating with the paste.

Moisture Paste cleaning power experiments of Experimental Examples 2-9 to 2-12 were performed with two variables of 30 sec and 60 sec, respectively. In the case of microbubbles (Experimental Example 2-11), washing was performed after stabilization. In the case of (Experimental Example 2-12), after the microbubble stabilization, the ultrasonic wave was operated for 60 seconds at an interval of 1 minute, and then the washing was performed.

The moisture paste surface was measured by a USB microscope and the number of pixels was analyzed. The results are shown in Table 3 below.

As shown in Table 3, the tap water washing rate (Experimental Example 2-9) was 2.09% (30 seconds), 3.69% (60 seconds), and the ultrasonic washing rate (Experimental Example 2-10) was 64.79% ( 30 seconds), 66.28% (60 seconds), microbubble cleaning rate (Experimental Example 2-11) is 3.85% (30 seconds), 5.24% (60seconds), microbubble + ultrasonic cleaning rate (Experimental Example 2- 12) is 77.32% (30 seconds), 81.04% (60 seconds), when using the microbubble and ultrasonic waves, it can be seen that the cleaning rate is 13-15% or more superior to the current ultrasonic waves.

<Oil paste cleaning power test>

The oil paste is coated with 1g of artificial paste (skin pad) with bakota, and the paste is an oily layer (sesame oil (7g), macadamia oil (3g), flaxseed oil (0.5g), room temperature emulsifier (0.5g) ), Color mix (3g)) and aqueous layer (makgeolli fermentation solution (10g), purified water (22.5g), niacinamide (1g), aqua adenosine (1g)) and additives (glycerine (1g), ecofree (1g)) To prepare a room temperature emulsifier BB cream, olive emulsification wax (3g) was used to increase the viscosity of the oil paste. Sesame oil can be used in place of jojoba oil and the added weight is the same as 7g. Here, the oil paste is a barcota coating with the paste only 10 cm in length from an artificial pad having a total length of 13 cm and a width of 3 cm.

Oil Paste cleaning power experiments of Experimental Examples 2-13 to 2-16 were performed with two variables of 30 sec and 60 sec, respectively. In the case of microbubbles (Experimental Examples 2-15), washing was performed after stabilization, and microbubbles + ultrasonic waves. In the case of (Experimental Example 2-16), after the microbubble stabilization, the ultrasonic wave was operated for 60 seconds at an interval of 1 minute, and then the washing was performed.

The oil paste surface was measured by a USB microscope and the number of pixels was analyzed. The results are shown in Table 4 below.

As shown in Table 4, the washing rate of the tap water (Experimental Example 2-9) is 5.34% (30 seconds), 22.37% (60 seconds), the ultrasonic washing rate (Experimental Example 2-10) is 42.68% ( 30 seconds), 50.35% (60 seconds), microbubble cleaning rate (Experimental Example 2-11) is 1.21% (30 seconds), 47.21% (60seconds), microbubble + ultrasonic cleaning rate (Experimental Example 2- 12) is 59.17% (30 seconds), 72.11% (60 seconds) when using a microbubble and ultrasonic waves can be seen that the cleaning rate is 17-22% or more than the current ultrasonic waves.

The specific parts of the present invention have been described in detail above, but are not limited to those illustrated in the drawings. For those skilled in the art, these specific descriptions are merely preferred embodiments, and thus, It will be clear that the scope is not limited. Thus, the substantial scope of the present invention will be defined by the appended claims and their equivalents.

10: washing tank
11: washing water
20: microbubble generating device
30: ultrasonic generator

Claims (5)

In the cleaning device for washing the animals contained in the washing water by generating ultrasonic waves and microbubbles in the washing tank filled with the washing water,
A washing tank filled with washing water;
Located in the washing tank, the microbubble generating device for generating a plurality of microbubbles into the washing tank; And
Located in the washing tank, the ultrasonic generator for generating a low-power high-frequency ultrasonic wave of less than 500W into the washing tank; includes,
Ultrasonic-microbubble system, characterized in that for washing the animal contained in the wash water by irradiating ultrasonic waves after saturating the wash water with a microbubble using the microbubble generating device. delete delete The method of claim 1,
The washing water is an animal cleaning device comprising an ultrasonic micro-bubble system selected from any one or more of water, saline or lotion. delete

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