JP2008036394A - Atomizer and dishwasher therewith - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To stably operate an ultrasonic vibrator and to improve atomizing ability. <P>SOLUTION: In the atomizer, an atomizing ultrasonic vibrator 9 provided at the lower part of a tank 3 so as to make a vibration surface 10 almost in the perpendicular direction carries out atomization by reflecting ultrasonic vibration energy by a reflection part 12 to raise an atomizing liquid level. Long time stable operation may be secured by increasing cooling performance against heat generated by the ultrasonic vibrator 9 in motion. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an atomizing device for atomizing a liquid and a dishwasher equipped with the same.

  Conventionally, this type of atomizing apparatus is provided in a dishwasher as shown in FIG. 13, and in order to remove the dirt adhering to the tableware etc., the sprayed detergent solution is sprayed on the tableware in advance. After swelling, a cleaning method using mechanical force by jetting water or chemical force by detergent has been proposed (for example, see Patent Document 1).

  Hereinafter, the configuration will be described. The dishwasher main body 51 stores a tableware basket 60 for storing tableware in a cleaning tank 53, and a door 54 is provided at the opening 52 of the cleaning tank 53. 55 is a nozzle that jets the cleaning water stored in the cleaning tank 53 toward the tableware, and 56 is an atomizer that atomizes the cleaning water stored in the cleaning tank 53. When the ultrasonic vibrator 57 is directly installed on the bottom surface of the cleaning tank 53, the atomizing device 56 is damaged by the scale or foreign matter accumulated on the surface of the ultrasonic vibrator or by an external impact. The vibrator 57 is covered with a protective container 58, and the cleaning water is atomized through the protective liquid 59.

About the dishwasher comprised as mentioned above, the operation | movement is demonstrated below. First, dirty dishes are set in the tableware basket 60, and the operation is started. When the operation is started, first, the atomizing device 56 atomizes the washing water in which the special detergent stored in the washing tank 53 is dissolved, and sprays the washing water 53 to swell dirt adhering to tableware and the like. Let Next, a main washing step of washing the dishes with the washing liquid ejected from the nozzle 55 is performed. And in order to wash away the stain | pollution | contamination adhering to tableware etc. from tableware, the rinse process which replaces the wash water in the washing tank 53 several times is performed. And the washing | cleaning of tableware is complete | finished by performing the warm water rinse process which heated the replaced wash water to about 70 degreeC. Finally, a drying process for drying water droplets adhering to the tableware is performed and the operation is terminated.
JP 2005-287993 A

  However, the conventional atomization apparatus has a configuration in which heat of the ultrasonic vibrator generated during the atomization operation is transmitted to the cleaning water through the protective liquid 59 and the protective container 58, so that the heat is difficult to escape. For this reason, the cooling performance of the ultrasonic vibrator at the time of operation was poor, and there was a problem that the long-time operation or high output could not be sufficiently performed and the atomization ability was low.

  The present invention solves the above-described conventional problems, and aims to stabilize the operation of an ultrasonic transducer and improve the atomization ability.

  In order to solve the conventional problems, an atomization apparatus according to the present invention includes an atomizing ultrasonic transducer, a reflection unit that reflects ultrasonic vibration energy generated from the atomizing ultrasonic transducer, A tank for storing the atomizing liquid, and a control device for controlling the atomizing ultrasonic vibrator, the atomizing ultrasonic vibrator is disposed so that the vibration surface is in a substantially vertical direction, The ultrasonic vibration energy generated from the atomizing ultrasonic transducer is reflected by the reflecting section configured in the water of the atomizing liquid, and the liquid level of the atomizing liquid is raised to perform the atomization. It is a thing.

  As a result, the cooling performance of the heat generated from the ultrasonic vibrator during operation can be improved to perform stable operation for a long time, and the atomization ability can be improved by increasing the input of the ultrasonic vibrator. . In addition, it is possible to provide an atomizing apparatus with high operational reliability in which the atomizing ultrasonic transducer is not easily damaged by the accumulation of scales, foreign matters, or external impacts.

  The atomization apparatus of the present invention can perform a stable operation for a long time and can improve the atomization capability by increasing the input of the ultrasonic element vibrator.

  The first invention includes an atomizing ultrasonic transducer, a reflecting portion that reflects ultrasonic vibration energy generated from the atomizing ultrasonic transducer, a tank that stores an atomizing liquid, and the atomization. A control device that controls the ultrasonic transducer for the atomization, the ultrasonic transducer for atomization is disposed so that the vibration surface is in a substantially vertical direction, and the ultrasonic transducer generated from the ultrasonic transducer for atomization is disposed. The ultrasonic vibration energy is reflected by the reflecting portion configured in the water of the atomizing liquid, and the liquid level of the atomizing liquid is raised to perform the atomization. Since the liquid can be brought into contact with the crystallization liquid, stable operation for a long time can be performed by improving the cooling performance of the heat generated from the ultrasonic vibrator during operation. In addition, the atomization ability can be improved by increasing the input of the ultrasonic element.

  In the second invention, since the reflecting portion of the first invention is made of a metal material or glass, the reflection efficiency of the ultrasonic vibration energy can be increased, and the atomization ability is increased.

  In the third aspect of the invention, since the reflecting portion of the first and second aspects of the present invention is configured integrally with the tank, the tank can be miniaturized and can be atomized with a small amount of atomizing liquid. .

  According to the fourth aspect of the invention, the tank of the third aspect of the invention can prevent deterioration of the tank due to re-reflection of ultrasonic vibration energy into the tank by forming at least the reflection portion with a metal material or glass.

  According to a fifth aspect of the invention, the reflecting portion of the first aspect of the invention has a substantially concave shape portion formed so as to converge the reflected ultrasonic vibration energy, so that the ultrasonic vibration energy is near the liquid surface of the atomizing liquid. Since it can be made to concentrate on, atomization ability can be improved.

  In the sixth aspect of the invention, the substantially concave surface shape part of the fifth aspect of the invention is formed by recessing into a spherical shape, so that the ultrasonic energy reflected by the reflection part can be concentrated at one point near the liquid surface. Atomization ability increases dramatically.

  In a seventh aspect of the invention, the tank of the first aspect of the invention is provided with a water level detection means for detecting the level of the atomizing liquid, thereby preventing damage to the ultrasonic transducer due to a drop in the liquid level due to the atomization operation. can do.

  In an eighth aspect of the invention, the reflection portion of any one of the first to seventh aspects further improves the reflection efficiency of ultrasonic vibration energy by making at least the surface of the portion that reflects ultrasonic waves into a mirror surface. And the atomization ability is dramatically increased.

  In the ninth aspect of the invention, the atomizing liquid of the first aspect of the present invention is a detergent solution, so that the dirt adhering to the tableware surface can be lifted to enhance the cleaning effect.

  A tenth invention includes a main body, a cleaning tank that accommodates an object to be cleaned such as tableware, a cleaning pump that pressurizes cleaning water, a cleaning nozzle that jets cleaning water pressurized by the cleaning pump, and atomization A storage section for storing the liquid to be stored and the atomizing device according to any one of claims 1 to 9, wherein the liquid in the tank is scattered by the atomizing device to be cleaned in the cleaning tank. By making it adhere to, since the stain | pollution | contamination adhering to the tableware surface can be lifted, the dishwasher with high washing | cleaning performance is realizable.

  In an eleventh aspect of the invention, the atomizing device of the tenth aspect of the invention causes the detergent liquid having a higher concentration than the washing water sprayed by the washing nozzle to adhere to the object to be cleaned, so that the dirt adhering to the tableware surface is lifted. The cleaning effect can be enhanced by strengthening the action.

  According to a twelfth aspect of the invention, the cleaning tank of the tenth or eleventh aspect of the invention is provided with a water level detecting means for detecting the level of the cleaning water, and atomizing the tank through a notch provided between the tank and the tank. By detecting the water level of the liquid for atomization, stable atomization performance can be obtained in a state where the ultrasonic transducer for atomization is immersed in the liquid for atomization.

  In a thirteenth aspect of the invention, the control device of the seventh or twelfth aspect of the invention detects the water level of the atomizing liquid by the water level detecting means, and before the atomizing ultrasonic transducer is exposed from the atomizing liquid, By stopping the operation of the atomizing ultrasonic transducer, it is possible to prevent the atomizing ultrasonic transducer from being damaged.

  In a fourteenth aspect, the reflecting portion of the tenth aspect reflects the vibration energy from the atomizing ultrasonic transducer so that the water column rises obliquely upward from the liquid surface at a predetermined inclination angle. By providing a water column recovery unit that collects the raised water column in the tank, it is possible to suppress the discharge of the atomizing liquid containing the high concentration detergent component from the water column to the cleaning tank. Atomization can be maintained longer.

  In the fifteenth aspect of the invention, the water column recovery part of the fourteenth aspect of the present invention is configured integrally with the reflection part, so that ultrasonic waves are transmitted to the water column recovery part through the reflection part, and the surface of the water column recovery part becomes dirty due to contamination during cleaning. Cleaning can be performed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a cross-sectional view of an atomization apparatus according to Embodiment 1 of the present invention. As shown in FIG. 1, the main body 1 of the atomizer has an opening 2 at the top, and the tank 3 for storing the atomizing liquid is configured to be able to be closed by a lid 5 having an ejection port 4. On the side surface of the tank 3, there is provided a blower fan 7 for pumping air sucked from an intake port 6 provided in the main body 1 and ejecting atomized liquid out of the main body 1 from the discharge port 4. . An electrode type water level sensor 8 (water level detecting means) for detecting the water level of the atomizing liquid is provided on the lower side surface of the tank 3.

  The ultrasonic vibrator 9 (atomizing ultrasonic vibrator) is configured to be sealed with the seal member 11 in pressure contact with the side wall surface of the tank 3 so that the vibration surface 10 is in a substantially vertical direction. Similarly, a reflective plate 12 (reflecting portion) made of stainless steel having an inclined surface is provided at a position facing the ultrasonic transducer 9. A control device 13 controls the ultrasonic vibrator 9, the blower fan 7, and the like.

  Regarding the water level detection means, in addition to the electrode type described in the present embodiment, the float type is considered to have the same function. As the material of the reflecting plate 12, it is possible to use a resin that is highly reflective to ultrasonic vibration energy and does not deteriorate even in liquid, a resin with a metal film, glass, or metal.

  The operation and action of the above configuration will be described. First, the atomizing liquid is stored in the tank 3 up to a predetermined water level obtained by the electrode-type water level sensor 8. At this time, the ultrasonic transducer 9 and the reflecting plate 12 are below the liquid level. When a voltage is applied to the ultrasonic vibrator 9 by the control device 13, the ultrasonic vibrator 9 vibrates and ultrasonic vibration energy travels in the liquid in a substantially horizontal direction from the vibration surface 10 toward the reflector 12. Then, it collides with the reflecting plate 12 and is reflected.

  The reflection plate 12 is set so that the ultrasonic vibration energy travels with an inclination from the vertical direction toward the liquid surface, and the reflected ultrasonic vibration energy rises when the liquid level reaches the liquid surface. Thus, a water column W having an inclination from the vertical direction is generated and atomization is performed. The droplets filled in the tank 3 are ejected from the ejection port 4 together with the air by the blower fan 7 to the outside of the apparatus. The amount of atomization increases by tilting the water column W around 10 degrees rather than forming it vertically. Therefore, it is set by the reflection angle by the reflector so that the water column W generated on the liquid surface is inclined.

  The ultrasonic vibrator 9 must be operated in water because the element is destroyed when it is operated in the air (in a burned state). On the other hand, if the distance from the liquid surface is too long, vibration energy is attenuated and atomization does not occur. Therefore, the operation | movement in the state set by the predetermined water level width | variety is needed. The electrode type water level sensor 8 in the present embodiment detects the lower limit water level A, and the control device 13 works to stop the operation when the water level falls below the lower limit water level A.

  In addition, a new water level detection means is provided, and an upper limit water level (not shown) that can achieve the specified atomization performance is set, and when the water level is exceeded, the control device is operated to stop the operation. Atomization performance can be obtained.

  Further, the ultrasonic vibrator 9 performs ultrasonic vibration by applying a voltage, but heat is also generated at the same time. And it has the property that vibration will not occur when the temperature of the ultrasonic vibrator 9 itself exceeds a predetermined temperature. For this reason, cooling of the ultrasonic vibrator 9 is an issue. However, in the configuration of the present invention, since the ultrasonic vibrator 9 is in direct contact with the liquid, the heat generated from the ultrasonic vibrator 9 during operation is reduced. Cooling performance can be enhanced. Therefore, stable operation for a long time can be performed.

  Further, even when the ultrasonic vibrator 9 is used by directly immersing it in the liquid, the ultrasonic vibrator 9 is installed substantially horizontally on the bottom surface of the tank 3 so that the vibration surface 10 faces upward as in the prior art. Unlike the above, the vibration surface 10 of the ultrasonic vibrator 9 is configured to be substantially vertical, so that the ultrasonic vibrator 9 is scratched or damaged by a falling object, and an element due to adhesion or deposition of components in the liquid on the vibration surface 10 It is possible to provide an atomizing device with high operational reliability, such as suppressing the destruction of the liquid.

  Further, since the reflection plate 12 is made of a metal material or glass, the reflectance of the ultrasonic vibration energy at the reflection plate 12 is increased, so that the atomization ability can be greatly improved.

  In addition, according to the present embodiment, since the attenuation of ultrasonic vibration energy is small compared to the conventional atomizer using the protective liquid and the protective container, higher atomization ability can be obtained with the same output. Can do.

(Embodiment 2)
FIG. 2 is a cross-sectional view of the main part showing the configuration of the reflecting part of the atomizing device according to Embodiment 2 of the present invention, and FIGS. FIG.

  As shown in FIG. 2, the entire bottom surface 3a of the tank 3 is made of stainless steel, and a part of the bottom surface 3a of the tank 3 reflects the ultrasonic vibration energy generated from the ultrasonic vibrator 9 toward the liquid surface. An inclined surface 14 in which an angle is set is provided to constitute a reflecting portion.

  In FIG. 3, the tank 3 is made of resin, and an inclined surface 16 is formed by attaching a stainless steel reflector 15 only in the vicinity of a region where the ultrasonic vibration energy is reflected toward the liquid surface. It is set as the structure attached to.

  In FIG. 4, the tank 3 is made of resin, and a part of the bottom surface of the tank 3 is formed with an inclined surface 14 whose angle is set so that the ultrasonic vibration energy generated from the ultrasonic vibrator 9 is reflected toward the liquid surface. A stainless steel reflector 17 is fixed to the inner surface of the inclined surface 14.

  FIG. 5 shows a case in which the tank 3 is made of resin, only the vicinity of the region that reflects ultrasonic vibration energy toward the liquid surface is a stainless steel reflector 18, and the ultrasonic vibration energy is reflected toward the liquid surface. Is provided with a substantially concave surface portion 19. The substantially concave shape portion 19 is formed in a spherically depressed shape, and is formed so as to converge the reflected ultrasonic vibration energy near the liquid surface.

  The basic configuration and operation for realizing the atomization apparatus are the same as those in the first embodiment, and the same reference numerals have the same structure and the description thereof is omitted.

  The operation and action of the above configuration will be described. The atomizing liquid operates with a predetermined water level width. Therefore, among the atomizing liquids stored in the tank 3, the atomizing liquid stored from the lower limit water level A to the tank bottom is not used for atomization. .

  According to the present embodiment, the reflecting portion 12 that reflects ultrasonic vibration energy is formed as a reflecting portion by forming an inclined surface on the tank 3, thereby integrating the parts of the tank 3 and the reflecting portion 12, and the tank. The volume of 3 can be reduced. Therefore, stable atomization performance can be obtained because the inclination angle of the reflecting portion 12 can be configured stably. Moreover, it can be set as the efficient atomization apparatus which can be atomized with a small amount of liquid for atomization.

  Further, most of the ultrasonic vibration energy reflected by the reflecting portion 12 is used for atomization by raising the liquid surface, but part of the ultrasonic vibration energy proceeds again into the tank 3 by reflection on the liquid surface. . Then, it is absorbed in the tank 3 and the atomizing liquid to generate heat. At this time, a specific part of the tank 3 may be exposed to a high temperature by the heat, and there is a problem that the surface of the tank 3 is thermally deteriorated.

  However, according to the configuration of the present embodiment, since the tank 3 is made of a metal material, there is no fear of thermal degradation. As shown in FIGS. 3 to 5, when the tank 3 is made of a resin material and only the vicinity of the reflection portion is made of a metal reflection portion, the portion of the tank 3 that is damaged due to thermal degradation is used. This can be avoided by providing only a metal plate.

  Furthermore, the concave surface portion 19 that enters and reflects the ultrasonic vibration energy of the reflecting portion 12 has a spherical shape so that the reflected ultrasonic vibration energy converges in the vicinity of the liquid surface, so that the liquid surface is raised and atomized. The ultrasonic vibration energy used for the can be increased, and the atomization ability can be improved.

  In any of the embodiments, the reflection efficiency of the ultrasonic vibration energy can be further improved by making the surface of at least the portion of the reflecting portion 12 that reflects ultrasonic waves into a mirror surface, and the atomization ability is dramatically improved. To be high.

  The ultrasonic transducer 9 is provided so that the vibration surface 10 is substantially in the vertical direction a. However, as shown in FIG. 6, the inclination of the upward a1 or the downward a2 does not deviate from its purpose. It is included in the substantially vertical direction of the invention. In this case, the inclination angle of the water column generated from the liquid surface is set to b1 when the vibrating surface 10 is upward a1 and the inclined surface is b1 when the reflecting surface 12 is aligned with the inclination of the ultrasonic transducer 9, and is b2 when the vibration surface 10 is downward a2. Is maintained in the same direction. The inclination angle of the water column may be either an acute angle or an obtuse angle with respect to the liquid surface, and is set to be inclined about 15 degrees with respect to the vertical direction.

(Embodiment 3)
FIG. 7 is a cross-sectional view of the dishwasher according to Embodiment 3 of the present invention. As shown in FIG. 7, the main body 21 of the dishwasher is configured such that a washing tub 23 having an opening 22 on the front side can be closed by a door 24. A cleaning nozzle 27 having an injection port 26 for spraying the cleaning water pressurized by the cleaning pump 25 is provided below the cleaning tank 23.

  Above the cleaning nozzle 27, a tableware basket 28 for storing tableware to be cleaned is provided. Below the cleaning tank 23, a heater 29 for heating the cleaning water is disposed. A guide 30a is disposed on the side wall of the tableware basket 28, and a guide rail 30b is disposed on the inner side wall of the main body 21, and the tableware basket 28 is supported so that it can be pulled out substantially horizontally with respect to the washing tub 23. Has been.

  A control device 31 is provided below the cleaning tank 23 and controls the ultrasonic vibrator 9, the cleaning pump 25, the heater 29, and the like. An electrode-type water level sensor (water level detection means: not shown) for detecting the level of the atomizing liquid (wash water) is provided on the inner wall surface below the front surface of the cleaning tank 23. The ultrasonic vibrator 9 is configured to be sealed with the seal member 11 in pressure contact with the side wall surface of the cleaning tank 23 so that the vibration surface 10 is in a substantially vertical direction. Further, an inclined surface 14 is formed at a position facing the ultrasonic transducer 9 and a stainless steel reflection plate 17 (reflection portion) is provided.

  Reference numeral 32 denotes a storage unit that stores a liquid to be atomized (detergent liquid). Further, the upper part of the storage part 32 is covered with a detergent case cover 33. The reservoir 32 is provided with a detergent inlet 34 at the lower part of the front side wall surface of the cleaning tank 23. The reservoir 32 is formed as a tank independent of the cleaning tank 23, and the cleaning water communicates with the cleaning tank 23 through a notch (not shown) formed by the cleaning tank 23 and the detergent container cover 33. The atomized high-concentration detergent is scattered from the opening of the detergent container cover 33 into the cleaning tank 23.

  In the above configuration, the ultrasonic oscillator 9 is in direct contact with the dirty cleaning water. However, since the vibration surface of the ultrasonic vibrator 9 is provided in a substantially vertical direction with respect to the cleaning tank 23, the solid matter such as food is super There is no accumulation on the surface of the sonic transducer 9. In addition, even when water with very high hardness, such as well water, is used, when washing water is drained, the structure is such that water droplets are unlikely to remain on the surface of the ultrasonic vibrator 9, so that the inorganic matter is deposited and ultrasonic oscillation occurs. It does not adhere to the vibration surface 10 of the child 9, and atomization can be performed stably over a long period of time.

  Next, the operation of the dishwasher of the present invention will be described. First, a predetermined amount of detergent (preferably dedicated detergent) is put into the storage part 32 from the detergent inlet 34. Next, a predetermined amount of cleaning water is supplied to the cleaning tank 23 from a water supply valve (not shown). At this time, the cleaning water is supplied by controlling the water supply valve by the control device 31. At this time, the cleaning water enters the storage portion 32 from the cutout portion as well as the cleaning tank 23, and a part of the detergent starts to dissolve in the cleaning water. At this time, when the ultrasonic oscillator 9 is driven, the oscillation propagates the liquid, is reflected by the reflecting plate 17 and is transmitted toward the cleaning water surface. And a water column generate | occur | produces in a liquid level and atomization of a detergent liquid is performed from the water column.

  The high-concentration detergent liquid is generated by dissolving the detergent liquid and suppressing the diffusion of the high-concentration detergent liquid into the cleaning water in the cleaning tank 23. First, regarding the concentration, for example, when the water storage volume of the storage unit 32 is set to 1/50 of the amount of water supplied to the entire cleaning tank 23 and a predetermined amount of detergent is added, the concentration is theoretically about 50 times. The detergent liquid can be produced. However, since the notch is connected to the inside of the cleaning tank 23, the concentration of the detergent solution is slightly reduced by diffusion into the detergent solution. Therefore, in order to suppress the decrease in the concentration, the high concentration detergent solution is collected in the storage unit 32 along the inner wall of the detergent container cover 33 so that the water column made of the high concentration detergent solution does not flow directly into the washing tank 23. .

  With this configuration, a flow of water of a high-concentration detergent solution is generated in the storage unit 32 to prevent a decrease in the concentration of the detergent solution and accelerate the dissolution of the detergent. Further, when the heater 29 is energized simultaneously with the atomization operation, the washing water is also heated, so that the dissolution of the detergent is promoted and the detergent liquid concentration is further increased. As described above, the concentration of the high-concentration detergent liquid is such that the concentration of the detergent liquid increases as the detergent liquid scatters. For this reason, firstly, the detergent solution with a low concentration is attached to the contamination so that the detergent solution becomes familiar with the stain, and then the detergent solution with a high concentration is attached to the contamination. It increases the permeability of surfactants to contamination and improves cleaning performance.

  The high-concentration detergent liquid flows out from the notch into the cleaning tank 23. However, since the opening area of the notch is minimized, the decrease in the detergent liquid concentration is minimized. Further, when the surface of the ultrasonic vibrator 9 is not immersed in the cleaning water, the generation of atomization stops and the high-concentration detergent liquid does not scatter. Therefore, the ultrasonic oscillator 9 is always driven when the ultrasonic oscillator 9 is driven. The control device 31 detects the water level by the water level detection sensor 9 so that the surface of the ultrasonic vibrator 9 is not immersed in the cleaning water so that the operation of the atomizer 40 is stopped. Take control. In addition, the generation efficiency of fog increases by optimizing the total distance from the vibration surface in water to the reflector, the reflector to the water column, the inclination angle of the water column, and the like.

  Further, since the high-concentration detergent liquid atomized by the ultrasonic oscillator 9 has a fine particle size of about 3 microns, the convection does not flow up to the upper part of the cleaning tank 3 as it is, but only drifts in the vicinity of the liquid surface. .

  However, in the configuration of the present embodiment, since the heater 29 is energized simultaneously with the atomization operation, the cleaning water is heated, and air convection is generated by the heat accompanying the temperature rise. Then, due to the convection effect of the air, the atomized high-concentration detergent liquid fills the entire cleaning tank 23 and adheres uniformly to the surface of the tableware. Further, the chemical effect is further increased by increasing the temperature of the atomized high-concentration detergent solution, so that the cleaning effect is dramatically improved.

  In this way, the detergent solution of high concentration adhering to the contamination of the tableware in the pretreatment process penetrates and swells, and is allowed to stand for a certain period of time so that the effect of the detergent can be obtained more.

  Next, a main washing process is performed in which the washing pump 25 is driven and sprayed from the washing nozzle 27 onto the tableware. In the main washing process, in addition to the amount sprayed on the tableware and the like in the pretreatment process, the detergent liquid remaining in the storage unit 32 is also washed away by the washing water sprayed from the washing nozzle 27 and diffused into the washing tank 23. Therefore, it is usually washed with washing water of detergent concentration.

  And after performing the rinse process of several times by replacing the wash water of the washing tank 23, the heating rinse process is performed with the high temperature wash water heated at the end, and a washing process is complete | finished. Moreover, the drying process which dries the tableware finally wash | cleaned may be performed.

  In order to increase the concentration of this detergent, surfactants, alkali agents, bleaching agents, chelating agents, etc., which are the main components of the detergent, adhere to contamination more than the conventional concentration. The effect of facilitating the entry of the cleaning solution, the cleaning effect by alkali and the bleaching effect by the bleaching component can be drastically exhibited. And in the main cleaning process after the pretreatment process, the dirt after the specific dirt is decomposed with the high concentration detergent solution in the pretreatment process is washed with a cleaning liquid having a normal detergent concentration. Can be washed reliably.

  Thus, in the present embodiment, by including the atomizing device 40, by having a pretreatment process in which a detergent liquid having a higher concentration than the detergent concentration during normal use is allowed to adhere to an object to be washed and left, Cleaning performance can be greatly improved. Moreover, it can wash | clean in a shorter time using this high detergency, and it can wash | clean with a lower washing water temperature. Further, it is possible to clean dirt that could not be removed conventionally.

  Moreover, since the atomizer 40 can produce | generate a detergent liquid, melt | dissolving a detergent in the storage part 32, it can atomize and disperse a high concentration detergent liquid.

  In addition, since the atomizing device 40 atomizes the high-concentration detergent liquid by using the ultrasonic oscillator 9, the high-concentration detergent liquid can sufficiently enter the slight gap between the dishes. it can. Moreover, it can be made to adhere evenly and uniformly to the bottom of the recess on the dirt surface even with dirt attached to the tableware.

  In the present embodiment, air convection is caused by the heater 29 so that a high-concentration detergent solution is uniformly attached to the tableware. However, the air in the cleaning tank 23 is circulated using a blower. A method of causing air flow in the cleaning tank 23 and scattering it uniformly is also conceivable.

  Further, water supplied to the cleaning tank 23 is sprayed by the cleaning nozzle 27, and the detergent liquid adhering to the object to be cleaned is dissolved in the water sprayed by the cleaning nozzle 27. A detergent solution is made and sprayed on the contaminants to promote the decomposition and dissolution of dirt, and after that, the detergent solution is washed to a predetermined concentration by adding water. Therefore, it is possible to realize a drastically high cleaning performance at a low cost, such as making it possible to clean dirt that cannot normally be removed.

  In addition, the cleaning water sprayed from the cleaning nozzle 27 is sprayed with the detergent liquid by dissolving the detergent liquid adhering to the object to be cleaned in a predetermined amount of water supplied to the cleaning tank 23 to obtain a predetermined concentration. Since the detergent solution having the normal washing concentration can be easily made subsequently, the dirt floating in the pretreatment process can be surely washed. Moreover, high cleaning performance can be obtained with a small amount of use due to effective use of the detergent.

(Embodiment 4)
8 is a cross-sectional view of a dishwasher according to Embodiment 4 of the present invention, FIG. 9 is a cross-sectional view of an atomizer provided in the dishwasher, FIG. 10 is a top view of the main part, and FIG. [Fig. 11] is a view as viewed in the direction of arrow B in Fig. 10.

  8 to 11, reference numeral 32 denotes a storage part (tank) for storing cleaning water, and includes a detergent storage part 42 for storing detergent. The upper part of the reservoir 32 is covered with a detergent container cover 33 having a detergent inlet 34, and the detergent inlet 34 is located above the detergent container 42. The storage section 32 is formed as a tank independent of the cleaning tank 23, and the cleaning water communicates with the cleaning tank 23 through a notch 44 formed by the cleaning tank 23 and the detergent container cover 33. A stainless steel reflector having an inclined surface 14 for reflecting the ultrasonic vibration energy emitted from the ultrasonic vibrator 9 toward the liquid surface at a position facing the ultrasonic vibrator 9 in the detergent case cover 33. 17 (reflecting part) is provided. The inclined surface 14 has a substantially concave surface portion 49 that is recessed in a spherical shape (SR = 90) so as to converge the ultrasonic vibration energy, and the reflected ultrasonic vibration energy is converged near the liquid surface. It is formed to do.

  The detergent container cover 33 has a stainless steel shielding plate 45 that shields the water column generated by the liquid surface rising by the vibration energy of the ultrasonic vibrator 9, and the water that hits the shielding plate 45 is stored in the storage portion 32 (tank ) And a water column recovery unit 43 including an opening 46 for scattering the liquid atomized by the vibration energy into the cleaning tank 23 is provided. The openings 46 are provided on both sides of the shielding plate 45.

  The reflection plate 17 and the shielding plate 45 are integrally formed of a stainless steel thin plate, and are fixed to the detergent container cover 33 and the storage portion 32, and the ultrasonic energy generated from the ultrasonic vibrator 9 is used. The water column W generated on the liquid surface at a predetermined reflection angle collides with the shielding plate 45, so that stable atomization performance can be exhibited.

  In addition, the lower part of the ultrasonic transducer 9 is such that the seal member 11 and the side wall 32a of the reservoir 32 are inclined downward toward the bottom, so that cleaning water does not easily accumulate on the surface of the ultrasonic transducer 9, Water droplets are less likely to remain on the surface of the acoustic wave vibrator 9.

  Next, the operation according to the above configuration will be described. First, a predetermined amount of detergent (preferably dedicated detergent) is put into the storage part 32 from the detergent inlet 34. Next, the control device 31 controls a water supply valve (not shown) to supply water into the cleaning tank 23. At this time, the cleaning water enters the storage section 32 from the cutout portion 44 communicating with the cleaning tank 23, and a part of the detergent starts to dissolve in the cleaning water. Then, the water is stored in the cleaning tank 23 and the storage unit 32 up to a predetermined water level obtained by the water level sensor 41 (water level detection means). At this time, the ultrasonic transducer 9 and the reflecting plate 17 are below the liquid surface C.

  When a voltage is applied to the ultrasonic vibrator 9 by the control device 31, the ultrasonic vibrator 9 vibrates and ultrasonic vibration energy travels in the liquid in a substantially horizontal direction from the vibration surface 10 toward the reflector 17. Then, it collides with the reflecting plate 17 and is reflected. The reflector 17 is set so that the ultrasonic vibration energy travels at a predetermined inclination angle from the vertical direction toward the liquid surface. When the reflected ultrasonic vibration energy reaches the liquid level of the cleaning water, A water column W having a surface that rises and is inclined from the vertical direction is generated.

  Then, the water column collides with the shielding plate 45, flows downward along the shielding plate 45, passes through the return path 20, and is collected in the storage unit 32 while dissolving the detergent accumulated in the detergent container 42. At this time, the high-concentration detergent atomized from the surface of the water column is scattered into the cleaning tank 23 through the opening 46 provided in the detergent container cover 33.

  In the configuration of the present embodiment, since the heater 29 is energized simultaneously with the atomization operation, the cleaning water is heated, and air convection is generated by the heat accompanying the temperature rise. Then, due to the convection effect of the air, the atomized high-concentration detergent liquid fills the entire cleaning tank 23 and adheres uniformly to the surface of the tableware. Further, the chemical effect is further increased by increasing the temperature of the atomized high-concentration detergent solution, so that the cleaning effect is dramatically improved.

  In this way, the detergent solution of high concentration adhering to the contamination of the tableware permeates and swells, and is left for a certain period of time so that the effect of the detergent can be further obtained. Next, a main washing process is performed in which the washing pump 25 is driven and sprayed from the washing nozzle 27 onto the tableware. In the main washing process, in addition to the amount sprayed on the tableware and the like in the pretreatment process, the detergent liquid remaining in the storage section 32 also diffuses into the washing tank 23, and thus washing is performed with washing water having a normal detergent concentration. .

  And after performing the rinse process of several times by replacing the wash water of the washing tank 23, the heating rinse process is performed with the high temperature wash water heated at the end, and a washing process is complete | finished. Moreover, the drying process which dries the tableware finally wash | cleaned may be performed.

  In order to increase the concentration of this detergent, surfactants, alkali agents, bleaching agents, chelating agents, etc., which are the main components of the detergent, adhere to contamination more than the conventional concentration. The effect of facilitating the entry of the cleaning solution, the cleaning effect by alkali and the bleaching effect by the bleaching component can be drastically exhibited.

  And in the main cleaning process after the pretreatment process, the dirt after the specific dirt is decomposed with the high concentration detergent solution in the pretreatment process is washed with a cleaning liquid having a normal detergent concentration. Can be washed reliably.

  In the present embodiment, air convection is caused by the heater 29 so that a high-concentration detergent solution is uniformly attached to the tableware. However, the air in the cleaning tank 23 is circulated using a blower. A method of causing air flow in the cleaning tank 23 and scattering it uniformly is also conceivable.

  Thus, in the present embodiment, by including the atomizing device 40, by having a pretreatment process in which a detergent liquid having a higher concentration than the detergent concentration during normal use is allowed to adhere to an object to be washed and left, Cleaning performance can be greatly improved. Moreover, it can wash | clean in a shorter time using this high detergency, and it can wash | clean with a lower washing water temperature. Further, it is possible to clean dirt that could not be removed conventionally.

  The high-concentration detergent liquid is generated by dissolving the detergent liquid and suppressing the diffusion of the high-concentration detergent liquid into the cleaning water in the cleaning tank 23. First, regarding the concentration, for example, when the water storage volume of the storage unit 32 is set to 1/50 of the amount of water supplied to the entire cleaning tank 23 and a predetermined amount of detergent is added, the concentration is theoretically about 50 times. The detergent liquid can be produced.

  However, since the notch 44 is connected to the inside of the cleaning tank 23, the concentration of the detergent solution is slightly reduced by diffusion into the detergent solution. Therefore, in order to suppress the decrease in the concentration, the high concentration detergent liquid is transferred through the return passage 20 of the detergent container cover 33 so that the water column made of the high concentration detergent solution does not flow directly into the cleaning tank 23, and the detergent container. The detergent accumulated in 42 is collected in the storage unit 32 while dissolving.

  With this configuration, a flow of water of a high-concentration detergent solution is generated in the storage unit 32 to prevent a decrease in the concentration of the detergent solution and accelerate the dissolution of the detergent. Further, when the heater 29 is energized simultaneously with the atomization operation, the washing water is also heated, so that the dissolution of the detergent is promoted and the detergent liquid concentration is further increased.

  As described above, the concentration of the high-concentration detergent liquid is such that the concentration of the detergent liquid increases as the detergent liquid scatters. For this reason, firstly, the detergent solution with a low concentration is attached to the contamination so that the detergent solution becomes familiar with the stain, and then the detergent solution with a high concentration is attached to the contamination. It increases the permeability of surfactants to contamination and improves cleaning performance.

  Note that the high-concentration detergent liquid flows out from the notch 44 into the cleaning tank 23. However, since the opening area of the notch 44 is minimized, the decrease in the detergent liquid concentration is minimized. Further, when the surface of the ultrasonic vibrator 9 is not immersed in the cleaning water, the generation of atomization stops and the high-concentration detergent liquid does not scatter. Therefore, the ultrasonic oscillator 9 is always driven when the ultrasonic oscillator 9 is driven. The water level sensor 41 detects the water level so that the ultrasonic vibrator 9 is immersed in the cleaning water, and the control device 31 detects the ultrasonic vibrator 9 before the ultrasonic vibrator 9 is exposed from the atomizing liquid by the water level detecting means 41. The operation is stopped and damage to the ultrasonic transducer is prevented.

  Thus, although the ultrasonic oscillator 9 is in direct contact with the dirty cleaning water, since the vibration surface 10 of the ultrasonic vibrator 9 is provided in a substantially vertical direction with respect to the cleaning tank 23, There is no accumulation on the surface of the ultrasonic transducer 9.

  Even in the case where water with very high hardness such as well water is used, the lower portion of the ultrasonic vibrator 9 is inclined with the seal member 11 and the side wall portion 32a of the storage portion 32 inclined downward toward the bottom, and cleaning is performed. When draining water, water droplets hardly remain on the surface of the ultrasonic vibrator 9. Therefore, the inorganic component of hard water does not precipitate and adhere to the vibration surface 10 of the ultrasonic oscillator 9, and the atomization can be performed stably over a long period of time.

  Further, the ultrasonic vibrator 9 performs ultrasonic vibration by applying a voltage, but heat is also generated at the same time. And it has the property that vibration will not occur when the temperature of the ultrasonic vibrator 9 itself exceeds a predetermined temperature. For this reason, cooling of the ultrasonic vibrator 9 becomes a problem, but in the configuration of the present invention, since the ultrasonic vibrator 9 is in direct contact with the liquid, the heat generated from the ultrasonic vibrator 9 during operation is reduced. While being cooled, the water column recovery unit 43 allows the detergent liquid in the storage unit 32 to flow and enhance the cooling performance.

  Therefore, stable operation for a long time can be performed. In addition, high cleaning performance can be obtained by directly atomizing the cleaning water without using a protective container and uniformly diffusing the water to float dirt adhering to the tableware surface.

  In addition, by providing the detergent container 42 for containing the detergent and the water column collecting part 43 for collecting the water column generated by the rising of the liquid level in the storage unit 32, the atomization containing the high concentration detergent component by the water column. Since the discharge of the cleaning liquid into the cleaning tank 23 can be suppressed, the atomization of the high-concentration detergent liquid can be maintained for a longer time.

  In addition, since the detergent liquid having a higher concentration than the washing water sprayed by the washing nozzle 27 is scattered, the ability to lift dirt adhering to the tableware surface can be enhanced, so that higher washing performance can be obtained. .

  Further, a water level detecting means 41 for detecting the water level of the washing water is provided, and the water level of the atomizing liquid in the storage part 32 is detected via a notch part 44 provided between the storage part 32 and a predetermined mist. By setting the upper limit water level (not shown) at which the conversion performance can be obtained and operating the control device 31 to stop the operation when the water level is exceeded, stable atomization performance can be obtained, and The ultrasonic transducer 9 can be stably atomized while being immersed in the atomizing liquid.

  Further, water supplied to the cleaning tank 23 is sprayed by the cleaning nozzle 27, and the detergent liquid adhering to the object to be cleaned is dissolved in the water sprayed by the cleaning nozzle 27. A detergent solution is made and sprayed on the contaminants to promote the decomposition and dissolution of dirt, and after that, the detergent solution is washed to a predetermined concentration by adding water. Therefore, it is possible to realize a drastically high cleaning performance at a low cost, such as making it possible to clean dirt that cannot normally be removed.

  Moreover, by having the substantially concave shape portion formed so as to converge the reflected ultrasonic vibration energy, the ultrasonic vibration energy can be converged at a shorter distance. For this reason, the distance between the liquid surface and the ultrasonic transducer can be shortened, and a more compact atomizing device can be obtained. Moreover, the liquid level can be raised, the ultrasonic vibration energy used for atomization can be increased, and the atomization ability can be improved.

  In addition, since the substantially concave surface portion is formed in a spherical shape, the ultrasonic energy reflected by the reflecting portion can be concentrated at a single point in the vicinity of the liquid surface, so that the atomization ability is dramatically increased. .

  In addition, the reflection plate (reflecting portion) has at least a portion that reflects ultrasonic waves as a mirror surface, so that the reflection efficiency of ultrasonic vibration energy can be further increased, and the atomization ability is dramatically increased. The mirror surface can be obtained by subjecting the surface of a stainless steel reflecting plate to electrolytic polishing or mirror polishing, or by plating or coating a metal surface. In any case, the reflection efficiency of the ultrasonic energy can be dramatically improved by smoothing the reflection surface of the reflection plate.

  In addition, the shielding plate (water column recovery unit) touches the cleaning water contaminated with ingredients during cleaning. For this reason, dirt accumulates in gaps and surfaces of the shielding plate and the return passage communicating therewith. However, since it is configured integrally with the reflecting portion, ultrasonic waves are transmitted to the shielding plate through the reflecting portion, and the surface of the water column collecting portion that becomes dirty due to contamination during cleaning can be cleaned. Moreover, cost reduction can be realized by integration with the reflector.

(Embodiment 5)
FIG. 12 is a cross-sectional view of a main part of the atomizing device according to Embodiment 5 of the present invention. As shown in FIG. 12, the substantially concave surface portion 47 is made of glass and is formed into a spherically recessed shape, and is fixed to the metal or resin reflector 17 to reflect the reflected ultrasonic vibration energy. It is formed so as to converge near the liquid surface. The reflection plate 17 and the shielding plate 45 are separate bodies, and are fixed to the water storage section 32 and the detergent container cover 33, respectively.

  The operation and action of the above configuration will be described. When a voltage is applied to the ultrasonic vibrator 9, the ultrasonic vibrator 9 vibrates and ultrasonic vibration energy travels in the liquid in a substantially horizontal direction from the vibrating surface 10 toward the reflecting plate 17. Reflect and collide. The ultrasonic vibration energy travels toward the liquid surface with an inclination from the vertical direction. When the reflected ultrasonic vibration energy reaches the liquid surface of the washing water, the liquid surface rises and a water column with an inclination from the vertical direction is generated. To do.

  At this time, when the reflecting surface is not smooth, the convergence of the ultrasonic energy near the water surface is hindered and the atomization ability is reduced. However, by making the reflecting plate 17 made of smooth glass, Since the reflectance of ultrasonic vibration energy is increased, the atomization ability can be greatly improved.

  As described above, the dishwasher equipped with the atomization apparatus according to the present invention can perform stable operation for a long time and can improve the atomization ability by increasing the input of the ultrasonic element. Therefore, it is useful as a dishwasher or the like that can obtain high cleaning performance.

Sectional drawing of the atomization apparatus of Embodiment 1 of this invention Sectional drawing which shows the principal part which shows the structure of the reflection part of the atomization apparatus in Embodiment 2 of this invention. Sectional drawing of the principal part which shows the other structure of the reflection part of the atomization apparatus Sectional drawing of the principal part which shows the other structure of the reflection part of the atomization apparatus Sectional drawing of the principal part which shows the other structure of the reflection part of the atomization apparatus Illustration of the ultrasonic vibrator of the atomizer Sectional drawing of the principal part of the dishwasher in Embodiment 3 of this invention Sectional drawing of the principal part of the dishwasher in Embodiment 4 of this invention Cross section of the main part of the atomizer of the dishwasher Top view of the main parts of the dishwasher View of arrow B in Fig. 10 of the dishwasher Sectional drawing of the principal part of the atomization apparatus of the dishwasher in Embodiment 5 of this invention Cross-sectional view of a conventional dishwasher

Explanation of symbols

1 Body 3 Tank 8 Electrode water level sensor (water level detection means)
9 Ultrasonic vibrator for atomization 10 Vibration surface 12 Reflector (reflector)
DESCRIPTION OF SYMBOLS 13 Control apparatus 17 Substantially concave shape part 23 Cleaning tank 25 Cleaning pump 27 Cleaning nozzle 40 Atomization apparatus

Claims (15)

An atomizing ultrasonic transducer, a reflecting portion for reflecting ultrasonic vibration energy generated from the atomizing ultrasonic transducer, a tank for storing an atomizing liquid, and the atomizing ultrasonic transducer The atomizing ultrasonic transducer is disposed so that the vibration surface is in a substantially vertical direction, and the ultrasonic vibration energy generated from the atomizing ultrasonic transducer is An atomization apparatus which is reflected by the reflecting portion configured in the water for atomizing liquid and raises the liquid surface of the atomizing liquid to perform atomization. The atomizing device according to claim 1, wherein the reflecting portion is made of a metal material or glass. The atomizing device according to claim 1, wherein the reflecting portion is configured integrally with the tank. The atomizing device according to claim 3, wherein the tank has at least a reflecting portion made of a metal material or glass. The atomizing device according to claim 1, wherein the reflecting portion has a substantially concave shape portion formed so as to converge the reflected ultrasonic vibration energy. The atomizing device according to claim 5, wherein the substantially concave surface-shaped portion is formed in a spherical shape. The atomization apparatus according to claim 1, wherein the tank is provided with a water level detection means for detecting the water level of the atomizing liquid. The atomizing device according to any one of claims 1 to 7, wherein the reflecting portion has at least a surface of a portion that reflects ultrasonic waves as a mirror surface. The atomizing device according to claim 1, wherein the atomizing liquid is a detergent solution. A main body, a cleaning tank for storing objects to be cleaned such as tableware, a cleaning pump for pressurizing cleaning water, a cleaning nozzle for injecting cleaning water pressurized by the cleaning pump, and a reservoir for storing liquid to be atomized And the atomizing device according to any one of claims 1 to 9, wherein the atomizing device scatters the liquid in the tank and adheres to the object to be cleaned in the cleaning tank. dishwasher. The dishwasher according to claim 10, wherein the atomizing device attaches a detergent solution having a concentration higher than that of the washing water sprayed by the washing nozzle to the object to be washed. The cleaning tank is provided with a water level detecting means for detecting the level of the cleaning water, and detects the water level of the atomizing liquid in the tank through a notch provided between the tank and the tank. 11. The dishwasher according to 11. The control device detects the water level of the atomizing liquid by the water level detecting means, and stops the operation of the atomizing ultrasonic vibrator before the atomizing ultrasonic vibrator is exposed from the atomizing liquid. The atomizing device according to claim 7 or the dishwasher according to claim 12. The reflection part reflects the vibration energy from the ultrasonic transducer for atomization so that the water column rises obliquely upward from the liquid surface at a predetermined inclination angle, and collects the water column raised from the liquid surface in the tank. The dishwasher of Claim 10 which provided the part. The dishwasher according to claim 14, wherein the water column recovery unit is configured integrally with the reflection unit.