JPH10244233A - Ultrasonic washing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inexpensive washing apparatus removing the contaminant of an article to be washed, harmless to a human body and capable of performing lasting sterilization. SOLUTION: A ceramic part 15 emitting far infrared rays and a copper metal part 20 capable of eluting copper ions are provided in a washing tank 10. A washing soln. 11 is activated by far infrared red rays emitted from the ceramic part 15 and copper ions harmless to a human body are eluted from the copper metal part 20 and an article to be washed is sterilized by copper ions during ultrasonic washing. Further, since a very small amt. of copper metal is bonded to the article to be washed, sterilizing capacity can be kept even after drying. This ultrasonic washing apparatus 1 dispenses with a complicated mechanism like an ozone generator and, since it is unnecessary to add a sterilizing agent such as chlorine to the washing soln., the inexpensive ultrasonic washing apparatus capable of being lightly used even in a home can be inexpensively provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic cleaning apparatus widely used for cleaning eyeglasses, dentures, and the like.

[0002]

2. Description of the Related Art As one type of cleaning apparatus, ultrasonic waves are radiated into a cleaning liquid in which an object to be cleaned is immersed, and the cleaning liquid is stirred to remove contaminants on the surface of the cleaning object very quickly and very efficiently. A possible ultrasonic cleaning device is known. In recent years, there has been developed an ultrasonic cleaning device capable of disinfecting by providing an ozone sterilizing device at the same time as removing surface dirt. On the other hand, as small and inexpensive ultrasonic cleaning devices have been developed, the number of cases where ultrasonic cleaning devices are used at home has been increasing.For example, they are used for cleaning eyeglasses and contact lenses, and also for dentures. It is also used for cleaning.

[0003]

When an ultrasonic cleaning device equipped with an ozone sterilizing device is used to directly wear an article such as eyeglasses or dentures on a user's body or to put the article in a mouth, the stain is generated. At the same time, it can be sterilized, so it is considered to be excellent. However, ozone is harmful to the human body and has no sustained bactericidal effect. This is the same when sterilizing with chlorine.For example, it is possible to obtain a sterilizing effect by washing with a chlorine-based disinfectant such as chlorchloride in a washing tank, but chlorine itself is not harmful to the human body. It is toxic and has no persistent bactericidal effect. Furthermore, when sterilizing using ozone,
The addition of an ozone sterilizer to the ultrasonic cleaning device makes the cleaning device large and expensive. For this reason, it becomes difficult for general users to easily obtain it. Further, when a chlorine-based disinfectant or the like is added to the cleaning liquid and sterilization is performed at the same time as the cleaning, it is troublesome to purchase and manage the disinfectant, and there is a risk that a child may accidentally drink at home.

Therefore, an object of the present invention is to provide an ultrasonic cleaning apparatus which is a sterilization method which is harmless to the human body and which has a sterilizing means which is persistent. further,
It is another object of the present invention to provide an ultrasonic cleaning device having a sterilizing function that does not require a special device for sterilization and that can be easily purchased at low cost without increasing power consumption. It is another object of the present invention to provide an ultrasonic cleaning apparatus having a sterilizing function which is easy to maintain and manage and has no danger even when used at home.

[0005]

For this reason, in the ultrasonic cleaning device of the present invention, the cleaning tank is sterilized using copper ions. The safety of copper ions has already been recognized by academic societies and the like. For example, the concentration in tap water has been recognized up to 1 ppm. Similarly, in the United States,
ppm, and 1.5 ppm in the UK, the safety of copper is recognized worldwide. If a trace amount of copper ions is present in the solution, it acts on the cells of the organism, lowers the metabolic function, inhibits the growth of microorganisms, and provides a very powerful bactericidal effect. Further, even after the cleaning, a very small amount of copper metal adheres to the object to be cleaned, so that the sterilizing effect is continued. As described above, by using copper ions, sterilization can be performed safely and efficiently in the cleaning tank, and a continuous sterilization effect can be obtained.

[0006] Such copper ions may be obtained by adding a water-soluble copper compound such as chloride to the cleaning solution, but the management and maintenance of the copper compound are troublesome. further,
When an aqueous solution of a copper compound is used, only the copper compound remains when dried, and metallic copper having a high sterilizing effect does not remain. For this reason, it is desirable to dissolve minute metallic copper in the cleaning solution, but simply immersing the metallic copper in the cleaning solution does not provide a concentration of copper ions having a certain sterilizing effect.

For this reason, in the present invention, a ceramic portion capable of emitting far-infrared rays is further provided in the cleaning tank, and a cleaning solution such as tap water is activated to elute copper ions of sufficient concentration for sterilization from metallic copper. Like that. That is, in the present invention, in an ultrasonic cleaning apparatus having a cleaning tank capable of performing cleaning by radiating ultrasonic waves into a cleaning liquid immersed in an object to be cleaned, in the cleaning tank, a ceramic part radiating far-infrared rays,
A copper metal part capable of eluting copper ions.

As the ceramic part, a ceramic solid capable of radiating far-infrared rays installed in the washing tank so that the washing liquid can be circulated can be used, and the sterilizing effect can be obtained without greatly changing the structure of the washing tank. A highly safe and inexpensive ultrasonic cleaning apparatus can be provided. It is also possible to employ a ceramic layer formed on at least a part of the inner wall of the cleaning tank and capable of emitting far-infrared rays as the ceramic part. Such a ceramic layer can be formed by painting or vapor deposition. By radiating far-infrared rays from the inner wall of the cleaning tank, the cleaning tank can be widely used, and the cleaning liquid is easily activated. Further, at least a part of the inner wall of the cleaning tank may be constituted by a plastic material containing a ceramic capable of emitting far-infrared rays.

On the other hand, as the copper metal part, a copper metal layer in which at least a part of the inner wall of the cleaning tank is formed of copper metal can be used. Further, a basket provided inside the cleaning tank so as to hold the object to be cleaned may be made of copper. Furthermore, by adopting a group of ultrafine fiber coppers installed in the cleaning tank so that the cleaning liquid can be circulated as the copper metal part, the copper ions are more easily eluted.

The ceramic part has ceramic particles capable of emitting far-infrared rays, the copper metal part has pure copper particles or fibers, and the ceramic particles and pure copper particles or fibers are mixed in a part of the cleaning tank. The cleaning solution activated by far-infrared rays immediately comes into contact with the copper metal part, and copper ions are efficiently eluted.

As described above, by providing a ceramic portion that emits far-infrared rays in addition to the copper metal portion, it is possible to greatly increase the amount of copper ions in the cleaning liquid. When the cleaning liquid is irradiated with ultrasonic waves, the cleaning liquid is removed.
Copper ions having a concentration sufficient for sterilization of about 1 to 0.2 ppm or more can be obtained. Furthermore, by providing a ceramic portion, copper ions can be eluted directly from metallic copper, so that a sterilizing effect due to copper ions can be obtained without using a water-soluble copper compound which is cumbersome to maintain and manage. . Therefore, it is possible to provide an ultrasonic cleaning apparatus having a high sterilizing effect that can be easily used at home. Furthermore, this ultrasonic cleaning device does not require an electric mechanism dedicated to sterilization such as an ozone generator, has a simple structure, has no fear of failure, etc., and is easy to handle and inexpensive in this regard. Can be. In addition, by performing sterilization using copper ions eluted from metallic copper, a continuous sterilization effect can be obtained, and contamination and infection of the object to be cleaned after cleaning can be prevented.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows the appearance of an ultrasonic cleaning apparatus according to the present invention, and FIG. 2 shows an example of the configuration using a cross section. In the ultrasonic cleaning apparatus 10 of the present embodiment, a cleaning tank 10 is housed in an upper part of a substantially box-shaped housing 2,
The lid 3 provided above the housing 2 is opened, and the cleaning tank 1 is opened.
The object to be cleaned such as eyeglasses and dentures can be put into the inside of the housing. Further, an operation unit 30 that can set a cleaning time and the like is provided at a lower portion of the housing 2 so that various functions provided on a substrate 31 housed at a lower portion of the housing 2 can be used. . A plug 32 for connecting a power cable is further provided at a lower portion of the housing 2. The plug 32 is connected to a household power outlet via a cable 4 to obtain electric power and to come into contact with the bottom of the cleaning tank 10. The vibrator 35 can be driven.

The cleaning tank 10 of the ultrasonic cleaning apparatus 1 of the present embodiment is made of stainless steel, and is filled with a cleaning liquid 11 (usually tap water is generally used). An object to be cleaned is put in the cleaning tank 10 and the cleaning liquid 1
The basket 12 can be stored so as to be held in the washing machine 1, so that the periphery of the object to be washed uniformly contacts the washing liquid 11. After holding the handle 12a of the basket 12 containing the objects to be cleaned, such as eyeglasses and dentures, immersing the basket 12 in the cleaning tank 10 and then supplying power to the vibrator 35 provided on the bottom surface of the cleaning tank 10, the vibrator 35 receives ultrasonic waves. Vibration is started. The ultrasonic vibration is transmitted to the cleaning liquid through the bottom surface, and the cleaning liquid 11 is stirred around the object to be cleaned, so that cleaning is performed very efficiently.

Further, in the cleaning tank 10 of this embodiment, a ceramic portion 15 and a copper metal portion 20 are arranged on the inner bottom surface 10a so as to be always immersed in the cleaning liquid during cleaning. Ceramic part 15 and copper metal part 20
It can be circulated around. As the ceramic portion 15 of the present embodiment, a solid filter type in which ceramic capable of emitting far-infrared rays is formed in a honeycomb shape is employed. Cordierite (2MgO.2Al ₂ O ₃ .5SiO) is a ceramic capable of emitting far-infrared rays.
₂ ), spinel (MgO.Al ₂ O ₃ ), ZrO ₃
It is possible to use a zircon-based material in which MnO is mixed into SiO ₂ or a material in which these are mixed. For example, in this example, 13.8% of MgO and ₃ % of Al ₂ O ₃ are used.
4.8% and 51.4% SiO ₂ to 1400
A ceramic filter sintered in a honeycomb shape at ℃ can be employed. Of course, the composition of each component is not limited to the above. For example, MgO is 2.6 to 13.
Even when a ceramic filter having a mixing ratio of about 8%, Al ₂ O ₃ of 25.5 to 38.8% and SiO ₂ of about 51.4 to 64.9% is used, a sufficient effect is recognized. I have.

The copper metal part 20 of this embodiment is formed by a plurality of copper fibers arranged in a filter.
As the copper fiber, it is possible to use electrolytic copper having a purity of about 99.9% produced by ultra-high-level refining and formed into a fibrous shape having a diameter of about 20 to 30 μm. By using such ultra-fine fibrous pure copper, the surface area of the copper metal portion 20 in contact with the cleaning liquid 11 can be made very large, so that the copper metal portion 2 from which copper ions can be easily eluted.
0 can be configured. For example, a copper metal part 20 provided with about 3 grams of ultra-fine fibrous pure copper is applied to the cleaning tank 1 of this embodiment.
When the ultrasonic cleaning is performed at 0 ° C., about 0.1 to 0.2 ppm or more of copper ions are eluted into the cleaning liquid 11 after about 3 minutes have passed. I have. On the other hand, when the ceramic portion 15 was not provided inside the cleaning tank 10, the elution of copper ions was hardly measured.

As described above, copper ions have already been recognized as safe metal ions that are harmless to the human body.
About 1 to 3 ppm is contained in tap water as a substance contained in tap water in all over the world. On the other hand, it is also recognized that a trace amount of copper ions exerts a strong bactericidal property. It is thought that the bactericidal performance of copper ions is similar to the general bactericidal performance of metal ions, because it acts on bacterial cell membranes and degrades metabolic functions. Strong bactericidal performance can be obtained by using silver or copper ions having a large particle size. For example, sufficient bactericidal activity is exerted by allowing about 0.03 to 0.07 ppm of silver ions or copper ions to act on water containing 100 to 1500 cells / ml of Escherichia coli, Shigella, S. typhi and the like. Can be. Thousands / m of these bacteria
Even in a very contaminated state such as those present on the order of 1, a sufficient bactericidal effect can be obtained with about 0.1 ppm of silver or copper ions. However, silver ions can cause silver poisoning, and drinking water standards (US standards) place a limit of 0.05 ppm or less. For this reason, it is desirable not to take in any form as much as possible. Therefore, the sterilization method using silver ions is not suitable for cleaning eyeglasses directly attached to a human body or dentures in a mouth.

On the other hand, as a method of using copper ions for sterilization, it is of course possible to employ copper salts, that is, water-soluble copper compounds such as copper oxide, copper sulfate, copper chloride and basic copper carbonate. . However, aqueous solutions of these copper compounds dissociate with bases such as O ₂ , SO ₃ , Cl _2, or CO ₂ to form copper ions, but antagonize them by chemical equivalents, so that their activity as copper ions is low. It is limited and cannot exhibit sufficient bactericidal properties. Further, when the object to be washed is dried after washing, it precipitates as a copper compound, so that it is difficult to maintain the sterilizing performance as copper ions with a trace amount of moisture such as moisture in the air. Therefore, it is most desirable to elute copper ions from metallic copper in order to exhibit strong sterilizing performance in the cleaning solution and maintain an appropriate sterilizing power even after cleaning.
In addition, if sufficient copper ions can be eluted from metallic copper, it is not necessary to maintain and control a copper compound as a germicide, so that the handling of the ultrasonic cleaning apparatus becomes very simple.

In the ultrasonic cleaning apparatus 1 of this embodiment, the cleaning liquid 11 is activated by bringing the cleaning liquid 11 into contact with a ceramic part 15 which emits far-infrared rays to increase the dissolving power. By contacting the ultrafine fiber having a large surface area of 20 with pure copper, a sufficient concentration of copper ions for sterilization can be eluted from metallic copper. Therefore, the activity of the copper ions in the cleaning solution is high, and it exhibits an extremely strong bactericidal activity. Of course, unlike sterilization with ozone or Cl ₂ , instead of killing bacteria directly, copper ions act to degrade metabolic performance, lose fertility, and eventually kill bacteria, so that sufficient sterilization is achieved. In order to carry out the above, it is desirable to soak in the cleaning solution for an appropriate time. Normally, sufficient sterilization is possible in the time period of performing ultrasonic cleaning, but if it is desired to perform more powerful sterilization, the object to be cleaned is washed for a certain time, for example, overnight, in the cleaning solution after ultrasonic cleaning. Processing such as continuous immersion is also possible.

When copper ions eluted from metallic copper are used for sterilization, a very small amount of metallic copper adheres to the surface of the object to be cleaned which has been dried after cleaning. Therefore, even if bacteria adhere to the object to be washed during use or storage, if there is a small amount of water such as sweat or moisture in the air, metallic copper is ionized and has a sterilizing effect. For this reason, it is possible to add sustained sterilization performance. As described above, by cleaning with the ultrasonic cleaning device 1 of the present example, it is possible to add antibacterial ability to the object to be cleaned.

As described above, by providing the ceramic portion 15 radiating far-infrared rays and the copper metal portion 20 capable of eluting copper ions inside the cleaning tank 10, the surface dirt can be efficiently removed by ultrasonic cleaning. At the same time, the copper ions can be efficiently eluted into the cleaning solution stirred by the ultrasonic waves, and powerful sterilization can be performed. And
Copper ions used in the ultrasonic cleaning apparatus 1 of the present example are:
It is harmless to the human body and has the advantage of maintaining sterilization performance. In contrast, sterilization using silver ions is highly effective but harmful to the human body as described above. Sterilization using ozone or chlorine is also possible, but ozone or chlorine is not harmless to the human body and is not a recommended sterilization method. Furthermore, it is not possible to have antibacterial properties since the bactericidal effect does not last. On the other hand, there is a sterilization method using alcohol or the like, but it is impossible to use it in an ultrasonic cleaning device because it is diluted by a cleaning liquid.

Further, the ultrasonic cleaning apparatus 1 of this embodiment can obtain the above-mentioned sterilizing function only by adding a static part such as the ceramic part 15 and the copper metal part 20 to the inside of the cleaning tank 10. . And the cleaning liquid stirred by the ultrasonic vibration cleans all corners of the object to be cleaned and at the same time is sterilized by copper ions. Dirt such as corners of an object to be cleaned can be removed, and at the same time, sterilization can be performed. Therefore, it is possible to wash in a very good condition in terms of hygiene. Therefore, by employing the ultrasonic cleaning apparatus of this example, it is not necessary to sterilize by adding a device having a complicated function such as an ozone generator, and it can be realized with a very simple configuration, and provided with a sterilizing function at very low cost. And an ultrasonic cleaning device. In addition, the running cost is low because the power consumption does not increase and maintenance is almost unnecessary. Furthermore, compared to the method of adding chlorine or other disinfectants, there are no labor and safety issues such as maintaining the disinfectants at home. It is a very convenient and highly useful ultrasonic cleaning device that can perform safe and harmless sterilization without performing cleaning.

In the above example, the filter-like ceramic portion 15 and the copper metal portion 20 are shown separated from each other and installed inside the cleaning tank 10. Pure copper particles or fibers may be installed in a mixed state, and the cleaning solution activated by far-infrared rays immediately comes into contact with the copper metal part, thereby improving the copper ion elution efficiency.

Further, in the above, the ceramic portion is
Although an example is described in which a filter-like ceramic solid capable of radiating far-infrared light installed in the cleaning tank so that the cleaning liquid can be circulated is used, as shown in FIG. Of course, a ceramic layer 16 capable of emitting far-infrared rays may be partially formed. Such a ceramic layer 16 can be formed by applying the above-described ceramic to the inner wall by at least one of painting and vapor deposition, and of course, it can be used together with the above-mentioned filter-like ceramic solid. It is. By providing a ceramic layer on the inner wall of the cleaning tank 10, the contact area with the cleaning liquid can be easily widened, so that the cleaning liquid can be easily activated and copper ions can be eluted. Further, the inner wall of the cleaning tank 10 or the cleaning tank 10 itself can be made of a plastic material containing a ceramic capable of emitting far-infrared rays. By employing the cleaning tank 10 that radiates far-infrared rays from the inner wall as described above, a larger basket 12 can be installed in the cleaning tank 10, so that the inner volume of the cleaning tank 10 is more effectively used as a cleaning area. It is possible to do.

Further, in the ultrasonic cleaning apparatus 1 shown in FIG. 3, the basket 12 is formed of pure copper and used as the copper metal part 20. Therefore, the activated cleaning liquid 11 circulates while being in contact with the basket 12, whereby copper ions are eluted, and the object to be cleaned in the basket 12 can be sterilized and a sufficient sterilizing ability can be obtained. Further, the cleaning tank 10
It is also possible to form the copper metal part 20 by forming at least a part of the inner surface of the inner wall with pure copper. These copper metal parts 2
0 can of course be used with a fibrous or similar copper filter as shown in the above example.

[0025]

As described above, in the ultrasonic cleaning apparatus of the present invention, by providing the ceramic portion and the copper metal portion in the cleaning tank, copper ions having a high sterilizing ability can be eluted into the cleaning solution. . Therefore, it is possible to sterilize by performing ultrasonic cleaning using this cleaning liquid,
It is possible to efficiently remove dirt from spectacles, dentures, and other objects to be cleaned, and to sterilize efficiently using a method harmless to the human body. Furthermore, sterilization using copper ions can maintain the sterilizing effect even after washing. Therefore, it is very suitable for cleaning what is directly worn on the human body or what is put into the mouth, and can be used for cleaning not only eyeglasses and dentures but also various other articles such as tableware and infant toys. In addition, the ultrasonic cleaning device of the present invention does not need to add a complicated mechanism such as an ozone generator, can be provided at very low cost, and can prevent an increase in power consumption. Furthermore, since there is no need to add a disinfectant, maintenance is easy, and an ultrasonic cleaning apparatus that can be used easily and safely at home can be provided.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an appearance of an ultrasonic cleaning apparatus according to an embodiment of the present invention.

FIG. 2 is a sectional view of the ultrasonic cleaning apparatus shown in FIG.

FIG. 3 is a cross-sectional view illustrating an example of an ultrasonic cleaning apparatus different from FIG.

[Explanation of symbols]

 1. Ultrasonic cleaning device 2. Housing 3. Lid 4. Power cord 10. Cleaning tank 11. Cleaning liquid 12. Basket 15. Ceramic part 16. Ceramic layer 20. Copper metal part 35 ..Vibrators

Claims (9)

[Claims] 1. A cleaning tank capable of radiating ultrasonic waves into a cleaning liquid immersed in an object to be cleaned for cleaning, a ceramic part radiating far-infrared rays, and a copper ion capable of being eluted therein. An ultrasonic cleaning device comprising a copper metal part. 2. The ultrasonic wave according to claim 1, wherein the ceramic portion includes a ceramic solid capable of radiating far-infrared rays installed in the cleaning tank so that the cleaning liquid can circulate. Cleaning equipment. 3. The ultrasonic cleaning apparatus according to claim 1, wherein the ceramic portion includes a ceramic layer formed on at least a part of an inner wall of the cleaning tank and capable of emitting far-infrared rays. 4. The ultrasonic cleaning apparatus according to claim 3, wherein the ceramic layer is formed by at least one of painting and vapor deposition. 5. The ultrasonic cleaning apparatus according to claim 3, wherein the ceramic layer is a plastic material containing a ceramic capable of emitting far-infrared rays. 6. The ultrasonic cleaning apparatus according to claim 1, wherein the copper metal part includes a copper metal layer formed on at least a part of an inner wall of the cleaning tank. 7. The ultrasonic cleaning apparatus according to claim 1, wherein the copper metal part includes a copper basket installed inside the cleaning tank so as to hold the object to be cleaned. . 8. The ultrasonic cleaning apparatus according to claim 1, wherein the copper metal part includes a group of ultrafine fiber copper disposed in the cleaning tank so that the cleaning liquid can circulate. . 9. The cleaning device according to claim 1, wherein the ceramic portion includes ceramic particles capable of emitting far-infrared rays, the copper metal portion includes pure copper particles or fibers, and a part of the cleaning tank includes the ceramic particles. An ultrasonic cleaning apparatus characterized in that particles and pure copper particles or fibers are mixed and installed.