CN113226576B - Ultrasonic cleaning device and washing machine - Google Patents

Abstract

An ultrasonic cleaning device (50) is provided, which allows a user to easily set a dirt adhering portion of an object to be cleaned between a distal end surface (112 a) of an ultrasonic generator (110) and a water storage tub (210). An ultrasonic cleaning device (50) is provided with: an ultrasonic wave generator (110) that generates ultrasonic waves; a water storage tank (210) which is arranged below the ultrasonic generator (110) and can store water for soaking the cleaned object; and an outer body (100 a) that houses the ultrasonic generator (110). The outer package (100 a) comprises: a cover body (131) that covers the distal end side of the ultrasound generating body (110) so that the distal end thereof is exposed; and a guide part (132) which is arranged on the front side surface of the cover main body (131) and guides the dirt attaching part of the cleaned object to the space between the top end surface (112 a) of the ultrasonic generator (110) and the water storage barrel (210).

Description

Ultrasonic cleaning device and washing machine

Technical Field

The present invention relates to an ultrasonic cleaning device and a washing machine provided with the ultrasonic cleaning device.

Background

Patent document 1 describes a washing machine in which an ultrasonic cleaning device is disposed around an inlet for laundry in an upper panel, for example, in front of the inlet. The ultrasonic cleaning device is provided with a water storage barrel capable of storing water and an ultrasonic generating unit having an ultrasonic generator positioned right above the water storage barrel.

The ultrasonic wave generating unit includes a housing accommodating the ultrasonic wave generator. The housing has an arm shape which is long in the front-rear direction and whose tip protrudes downward. An opening is formed in the distal end surface of the housing, and the distal end of the ultrasonic generator is exposed to the water storage tub side through the opening.

The dirt adhering portion of the object to be cleaned is provided between the distal end surface of the ultrasonic generator and the water storage tub so as to be immersed in the water stored in the water storage tub, and the cleaning operation is started. Ultrasonic energy generated by the ultrasonic generator acts on the dirt-adhering portion soaked in water, and the dirt is peeled off.

When the ultrasonic cleaning apparatus is provided on the upper panel, the user can easily view the ultrasonic cleaning apparatus from above during use. In this case, it is difficult for the user to confirm the gap between the distal end surface of the ultrasonic generator and the water storage tub. Therefore, in such a situation, it may be problematic how to allow the user to easily dispose the dirt adhesion portion between the distal end surface of the ultrasonic generator and the water storage tub.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2018-68435

Disclosure of Invention

Problems to be solved by the invention

The present invention has been made in view of the above problems, and an object of the present invention is to provide an ultrasonic cleaning apparatus and a washing machine including the ultrasonic cleaning apparatus, in which a user can easily set a dirt adhesion portion of an object to be cleaned between a distal end surface of an ultrasonic generator and a water storage tub.

Means for solving the problems

An ultrasonic cleaning device according to a first aspect of the present invention includes: an ultrasonic generator that generates ultrasonic waves; a water storage tank disposed below the ultrasonic generator and capable of storing water for soaking the object to be cleaned; and an outer package for housing the ultrasonic generator. Here, the exterior body includes: a covering section that covers a distal end side portion of the ultrasonic generator so that a distal end portion thereof is exposed; and a guide part which is arranged on the side surface of the covering part and guides the dirt adhesion part of the cleaned object to the space between the top end surface of the ultrasonic generator and the water storage barrel.

According to the above configuration, the user can easily set the dirt adhering portion of the object to be cleaned between the distal end surface of the ultrasonic generator and the water storage tub by guiding the dirt adhering portion by the guide portion.

In the ultrasonic cleaning apparatus according to the present aspect, the guide portion may be provided with a guide surface that is inclined so as to approach the ultrasonic generator as the guide surface approaches the water storage tub, and the dirt adhesion portion may follow the guide surface.

According to the above configuration, the user can reach between the distal end surface of the ultrasonic generator and the water storage tub only by bringing the dirt adhering portion of the object to be cleaned into contact with the guide surface and following the guide surface.

In the ultrasonic cleaning device according to the present aspect, the outer casing may include a housing that houses a portion of the ultrasonic generator other than the portion on the distal end side, and a cover that includes the covering portion and the guide portion and is detachably attached to the housing.

According to the above configuration, the user can clean the distal end side portion of the ultrasonic generator by removing the cover.

In the ultrasonic cleaning device of this scheme, can adopt following structure: the position of the guide portion coincides with the position of the ultrasonic generator in a direction orthogonal to a direction in which the dirt adhesion portion is guided by the guide portion.

According to the above configuration, the guide portion serves as a mark, and the user can easily confirm the position of the ultrasound generator.

In the ultrasonic cleaning device of this scheme, can adopt following structure: the lower end of the guiding part is positioned below the lower end of the covering part.

According to the above configuration, the distal end portion of the ultrasonic generator exposed from the covering portion can be covered by the lower end portion of the guide portion in the direction in which the dirt adhesion portion is guided by the guide portion. Thus, the dirt adhering portion guided by the guide portion is less likely to be caught by the corner portion of the distal end portion of the ultrasonic generator, and is less likely to be damaged.

A washing machine according to a second aspect of the present invention includes: a washing tub for receiving laundry to wash; an upper panel having an inlet for inputting the washings into the washing barrel; and the ultrasonic cleaning device of the first aspect attached to the upper panel.

With the above configuration, the same effect as the ultrasonic cleaning apparatus according to the first aspect can be obtained.

Effects of the invention

According to the present invention, it is possible to provide an ultrasonic cleaning apparatus and a washing machine including the ultrasonic cleaning apparatus, in which a user can easily set a dirt adhesion portion of an object to be cleaned between a distal end surface of an ultrasonic generator and a water storage tub.

The effects and significance of the present invention will be more apparent from the following description of the embodiments. However, the following embodiment is merely an example of the present invention, and the present invention is not limited to the contents described in the following embodiment.

Drawings

Fig. 1 is a side sectional view of a full automatic washing machine of an embodiment.

Fig. 2 is a perspective view of the ultrasonic cleaning apparatus and the left side surface of the upper panel before the ultrasonic cleaning apparatus according to the embodiment is installed.

Fig. 3 (a) is a perspective view of the ultrasonic cleaning device and the upper panel when the ultrasonic cleaning unit and the water storage unit of the embodiment are located at the standby position, and fig. 3 (b) is a perspective view of the ultrasonic cleaning device and the upper panel when the ultrasonic cleaning unit and the water storage unit of the embodiment are located at the operating position.

Fig. 4 is a front cross-sectional view of the ultrasonic cleaning apparatus, the left side surface portion of the upper panel, and the drain unit of the embodiment, taken along the center position of the body.

Fig. 5 is a side sectional view of the ultrasonic cleaning apparatus of the embodiment, taken along a central position of the main body.

Fig. 6 is a side sectional view of a main part of the ultrasonic cleaning apparatus taken along a central position of the ultrasonic cleaning portion.

Fig. 7 (a) and (b) are front sectional views of the ultrasonic cleaning unit of the embodiment in which the upper member of the housing is omitted.

Fig. 8 (a) is a perspective view of the lid of the embodiment, and fig. 8 (b) is a bottom view of the lid of the embodiment.

Fig. 9 (base:Sub>A) isbase:Sub>A perspective view of the water storage unit according to the embodiment, and fig. 9 (b) isbase:Sub>A sectional view taken along linebase:Sub>A-base:Sub>A' of fig. 9 (base:Sub>A).

Fig. 10 (a) and (b) are perspective views of the valve body switching mechanism and the water storage unit of the embodiment.

Fig. 11 is a longitudinal sectional view of a water supply tank of the embodiment.

Fig. 12 is a front sectional view of the peripheral portion of the ultrasonic cleaning apparatus in the case where the ultrasonic cleaning unit and the water storage unit of the embodiment are located at the operation position and the water supply tank is located at the water discharge position.

Fig. 13 (a) to (c) are views for explaining the stain removal of the object to be cleaned by the ultrasonic cleaning apparatus according to the embodiment.

Fig. 14 is a front sectional view of the peripheral portion of the ultrasonic cleaning apparatus in the embodiment in which the ultrasonic cleaning unit and the water storage unit are located at the standby position and the water supply tank is located at the water discharge position.

Description of the reference numerals

1: full automatic washing machines (washing machines); 12: an upper panel; 14: a throwing port; 20: an outer tub (washing tub); 22: a washing and dehydrating tub (washing tub); 50: an ultrasonic cleaning device; 100: an ultrasonic cleaning section; 100a: an exterior body; 110: an ultrasonic wave generator; 120: a housing; 130: a cover; 131: a cover main body (covering portion); 132: a guide section; 135: a guide surface; 210: a water storage barrel.

Detailed Description

Hereinafter, an ultrasonic cleaning apparatus and a washing machine according to an embodiment of the present invention will be described with reference to the drawings.

Fig. 1 is a side sectional view of a fully automatic washing machine 1 of the present embodiment.

The fully automatic washing machine 1 includes a cabinet 10 constituting an external appearance. The casing 10 includes a rectangular tubular body 11 having an open upper and lower surface, an upper panel 12 covering the upper surface of the body 11, and a pedestal 13 supporting the body 11. An inlet 14 for laundry is formed in the upper panel 12. The inlet 14 is covered with an upper cover 15 that can be opened and closed. A control unit 16 is disposed in the front portion of the upper panel 12. The control unit 16 controls the washing operation of the fully automatic washing machine 1 and the cleaning operation of the ultrasonic cleaning device 50 described later.

In the casing 10, an outer tub 20 having an open upper surface is elastically suspended and supported by four suspension rods 21 having a vibration preventing means. A washing and dehydrating tub 22 having an open upper surface is disposed in the outer tub 20. The washing and dewatering tub 22 rotates about a rotation axis extending in the vertical direction. A plurality of dewatering holes 22a are formed in the inner circumferential surface of the washing and dewatering tub 22 over the entire circumference. On the upper part of the washing and dehydrating tub 22, a balance ring 23 is provided. At the bottom of the washing and dehydrating tub 22, a pulsator 24 is disposed. A plurality of blades 24a are radially provided on the surface of the pulsator 24. It should be noted that the washing tub of the present invention includes an outer tub 20 and a washing and dehydrating tub 22.

At the outer bottom of the outer tub 20, a driving unit 30 generating torque to drive the washing and dehydrating tub 22 and the pulsator 24 is disposed. The drive unit 30 includes a drive motor 31 and a transmission mechanism portion 32. The transmission mechanism unit 32 has a clutch mechanism 32a, and by a switching operation performed by the clutch mechanism 32a, the torque of the drive motor 31 is transmitted only to the pulsator 24 to rotate only the pulsator 24 in the washing process and the rinsing process, and the torque of the drive motor 31 is transmitted to the pulsator 24 and the washing and dehydrating tub 22 to rotate the pulsator 24 and the washing and dehydrating tub 22 integrally in the dehydrating process.

A drain port 20a is formed at the outer bottom of the outer tub 20. The drain valve 40 is provided in the drain port portion 20a. The drain valve 40 is connected to a drain hose 41. When the drain valve 40 is opened, the water accumulated in the washing and dehydrating tub 22 and the outer tub 20 is drained to the outside of the machine through the drain hose 41.

An ultrasonic cleaning device 50 is provided on the left side surface 12a of the upper panel 12. The ultrasonic cleaning apparatus 50 is mainly used for performing the following cleaning operation: before the full-automatic washing machine 1 washes the clothes, dirt that is locally attached to the objects to be washed, such as sebum dirt attached to the cuffs and the collar of the shirt, and oil dirt attached to the work clothes, is removed.

A water supply unit 60 for supplying tap water into the washing and dehydrating tub 22 is disposed at the rear of the upper panel 12. The water supply unit 60 has a water supply valve 61. The water inlet 61a of the water supply valve 61 is connected to a faucet. When the water supply valve 61 is opened, tap water from the faucet is supplied into the washing and dehydrating tub 22 through the water supply path 62.

A drain unit 70 is provided on the outer bottom surface of the upper panel 12 at a position corresponding to the ultrasonic cleaning device 50. The drain unit 70 includes a drain receiver 71 that receives drain from the ultrasonic cleaning apparatus 50, and a hose 72 connected to the drain receiver 71. The hose 72 is connected to the drain port portion 20a.

Fig. 2 is a perspective view of the ultrasonic cleaning device 50 and the left side surface portion 12a of the upper panel 12 before the ultrasonic cleaning device 50 is installed. Fig. 3 (a) is a perspective view of the ultrasonic cleaning device 50 and the top panel 12 when the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the standby position, and fig. 3 (b) is a perspective view of the ultrasonic cleaning device 50 and the top panel 12 when the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the operating position.

The ultrasonic cleaning apparatus 50 includes an ultrasonic cleaning unit 100, a water storage unit 200, a main body 300, and a water supply tank 400. The ultrasonic cleaning unit 100 includes an ultrasonic generator 110 that generates ultrasonic waves. The main body 300 holds the ultrasonic cleaning unit 100. The water storage portion 200 is located below the ultrasonic generator 110, has a water storage tub 210 capable of storing water, and is attached to the main body 300. The water storage portion 200 can be pulled out forward by a user's detaching operation and detached from the main body 300. The water supply tank 400 is provided at an upper portion of the main body 300, and accumulates water to be supplied to the tub 210. In the present embodiment, the water stored in the water supply tank 400 and supplied to the water storage tub 210 is water containing detergent. Hereinafter, the water containing the detergent is referred to as "washing water".

An installation part 80 in which the ultrasonic cleaning device 50 is installed is provided on the left side surface part 12a of the upper panel 12. The installation portion 80 includes an attachment portion 81 having a substantially bottomed cylindrical shape and a receiving portion 82 formed in such a manner that the left side face portion 12a is recessed forward of the attachment portion 81. The attachment portion 81 has a receiving portion 83 formed in a shape corresponding to the main body portion 300 of the ultrasonic cleaning apparatus 50. A recess 84 slightly recessed from the periphery is formed in the bottom surface of the receiving portion 83. A circular drain hole 85 is formed in the bottom surface of the recess 84. Further, a laterally long opening 86 connected to the receiving portion 83 is formed at a lower portion of the front side of the attachment portion 81.

The ultrasonic cleaning device 50 is attached to the attachment portion 81 so that the main body portion 300 is housed in the housing portion 83, and the water storage portion 200 protrudes to the outside of the attachment portion 81 through the opening portion 86. The main body 300 is attached to the attaching portion 81 in a state where the water storage portion 200 is detached. At the main body portion 300 attached to the attaching portion 81, the water storage portion 200 is attached through the opening portion 86.

As shown in fig. 3 (a), when the ultrasonic cleaning apparatus 50 is not used and the cleaning operation is not performed, the ultrasonic cleaning apparatus 50 is in a state where the ultrasonic cleaning unit 100 and the water reservoir 200, that is, the ultrasonic generator 110 and the water reservoir 210 are stored in the storage unit 82. The ultrasonic cleaning unit 100 and the water storage unit 200 are at the standby position. On the other hand, as shown in fig. 3 (b), when the ultrasonic cleaning device 50 is used for cleaning operation, the ultrasonic cleaning device 50 is switched to a state in which the ultrasonic cleaning portion 100 and the water storage portion 200 protrude toward the inside of the inlet 14 of the upper panel 12. The positions of the ultrasonic cleaning unit 100 and the water storage unit 200 at this time are the operation positions.

Next, the respective configurations of the ultrasonic cleaning apparatus 50 will be described in detail.

Fig. 4 is a front sectional view of the ultrasonic cleaning device 50, the left side surface portion 12a of the top panel 12, and the water discharge unit 70, taken along the center of the body 300. Fig. 5 is a side sectional view of the ultrasonic cleaning apparatus 50 taken along a central position of the main body 300. Fig. 6 is a side sectional view of a main part of the ultrasonic cleaning apparatus 50 taken along a central position of the ultrasonic cleaning unit 100. Fig. 7 (a) and (b) are front sectional views of the ultrasonic cleaning unit 100 with the upper member 150 of the housing 120 omitted. In fig. 7 (a), the ultrasonic cleaning unit 100 is cut along the position of the LED145 provided on the lower member 140, and in fig. 7 (b), the ultrasonic cleaning unit 100 is cut along the fitting portion between the protrusion 147 of the lower member 140 and the recess 134 of the cover 130.

Referring to fig. 5 to 7 (b), the ultrasonic cleaning unit 100 includes: an ultrasonic wave generator 110, a housing 120, and a cover 130. The package 100a includes a case 120 and a lid 130, and the ultrasound generator 110 is housed inside the package 100 a.

The ultrasonic generator 110 includes an ultrasonic transducer 111 and a vibration horn 112 coupled to the ultrasonic transducer 111. The vibration horn 112 is made of a conductive metal material and has a shape that is tapered toward the distal end side. The distal end surface 112a of the vibration horn 112 has an elongated rectangular shape. The ultrasonic wave generator 110 generates an ultrasonic wave from the tip of the vibration horn 112. A flange portion 113 is formed at the upper end portion of the vibration horn 112. The ultrasonic generator 110 is attached with a buffer member 114 so as to cover the flange 113.

The case 120 is made of a resin material and has an arm shape which is long in the front-rear direction and in which a distal end portion 120a is bent downward. An opening 121 is formed in the lower surface of the distal end portion 120 a.

The housing 120 is formed by connecting a lower member 140 whose upper surface is open and an upper member 150 whose lower surface is open. The upper member 150 is integrally formed with the case 500 constituting the main body 300. At the lower member 140 and the upper member 150, a lower mounting boss 141 and an upper mounting boss 151 for connecting them are provided. The lower mounting boss 141 and the upper mounting boss 151 are fixed by screws 161. The top end portion 120a of the housing 120 is formed by the lower member 140.

The lower member 140 is provided with an installation portion 142 above the opening 121, and mounting bosses 143 are provided in front of and behind the installation portion 142. The lower member 140 is provided with a recess 144 in front of the opening 121. The recess 144 is recessed upward so as to have a shape corresponding to the light receiving portion 133 of the cover 130. In the recess 144, the LEDs 145 are arranged on the left and right sides (see fig. 7 (a)). Further, the periphery of the opening 121 of the lower member 140 forms an insertion opening portion 146 into which the cap 130 is inserted, and protrusions 147 are formed on the left and right side surfaces of the insertion opening portion 146 (see fig. 7 (b)).

The flange portion 113 of the ultrasonic generator 110 covered with the buffer member 114 is provided on the installation portion 142 of the housing 120. A frame-shaped fixing plate 170 is attached above the flange portion 113. The fixing plate 170 is fixed to the mounting boss 143 by screws 162. The flange portion 113 is sandwiched between the setting portion 142 and the fixing plate 170, and the ultrasonic generator 110 is fixed in the housing 120. The distal end side portion of the vibration horn 112 protrudes downward from the opening 121 of the housing 120.

The cover 130 is detachably attached to the distal end portion 120a of the housing 120, and covers a portion of the vibration horn 112 of the ultrasonic generator 110 exposed from the housing 120.

Fig. 8 (a) is a perspective view of the cover 130, and fig. 8 (b) is a bottom view of the cover 130. In fig. 8 (b), the tip end surface 112a of the vibration horn 112 is shown by a one-dot chain line for convenience.

Referring to fig. 8 (a) and (b), the cover 130 has a structure in which the cover main body 131, the guide portion 132, and the light receiving portion 133 are integrally formed of a light-transmissive resin material. The cover main body 131 has a tubular shape in which the front, rear, left, and right widths are narrowed in three stages toward the lower side, and includes a substantially racetrack-shaped upper portion 131a, a substantially square intermediate portion 131b, and a lower portion 131c in plan view. A recess 134 having a shape corresponding to the protrusion 147 of the case 120 is formed on the left and right inner surfaces of the upper portion 131a of the cover main body 131. The cap main body 131 covers the distal end portion of the vibration horn 112 of the ultrasonic generator 110 so that the distal end portion thereof is exposed. The cover main body 131 corresponds to a cover portion of the present invention.

The guide 132 is provided at the center of the front surface of the cover main body 131 in the left-right direction so as to protrude forward, and has a flat shape in the left-right direction. The width of the guide portion 132 in the left-right direction is slightly larger than the width of the vibration horn 112 of the ultrasonic generator 110 in the left-right direction. The upper portion of the guide portion 132 has a shape that fits the outer surface of the tip portion 120a of the housing 120. Further, a guide surface 135 inclined in a backward obliquely downward direction and bent to become horizontal at a lower end portion is provided at a lower portion of the guide portion 132. Further, the lower end of the guide portion 132 is located below the lower end of the cover main body 131.

The light receiving part 133 is provided at the upper front end of the cover main body 131. The light receiving portion 133 is long in the left-right direction, and is slightly curved so as to follow the front upper end portion of the cover main body 131. The light receiving unit 133 has circular holes 136 formed on both left and right sides thereof, corresponding to the LEDs 145 of the housing 120.

Returning to fig. 5 to 7 (b), the cover 130 is attached to the insertion mouth portion 146 of the housing 120 from below. As shown in fig. 7 (b), the left and right protrusions 147 of the housing 120 are fitted in the left and right recesses 134 of the cover 130. At this time, the protrusion 147 slightly protrudes outward from the inner surface of the upper portion 131a of the cap body 131, and when attached, the upper portion 131a of the cap body 131 is expanded in the left-right direction by contacting the protrusion 147, and is fitted into the fitting opening portion 146. As shown in fig. 7 (a), the light receiving portion 133 of the cover 130 is fitted into the recess 144 of the housing 120, and the right and left LEDs 145 of the recess 144 are fitted into the right and left holes 136 of the light receiving portion 133. Thereby, the two LEDs 145 are connected to the light receiving portion 133, i.e., the cover 130. When the right and left LEDs 145 emit light, the light is guided into the cover 130 through the light receiving unit 133, and the entire cover 130 emits light.

As shown in fig. 6, in a state where the cap 130 is attached to the housing 120, the tip end portion of the vibration horn 112 of the ultrasonic generator 110 is slightly exposed from the cap body 131. Further, the lower end of the guide portion 132 of the cap 130 is almost flush with the tip end surface 112a of the vibration horn 112. Further, the guide surface 135 of the guide portion 132 is inclined so as to approach the vibration horn 112 as approaching the water storage tub 210. Further, as shown in fig. 8 (b), the position of the guide portion 132 coincides with the position of the distal end portion of the vibration horn 112 in the left-right direction, that is, in the direction orthogonal to the front direction of the ultrasonic cleaning portion 100.

As shown in fig. 7 (a) and (b), the left and right side surfaces of the distal end portion 120a of the housing 120 are inclined such that the width of the distal end portion 120a becomes narrower toward the lower side. Further, the cover 130 also has a tapered shape in which the right and left widths become narrower as approaching downward. Accordingly, the user can always see the ultrasonic cleaning apparatus 50 provided on the upper panel 12 from obliquely above, and at this time, the position of the distal end portion of the vibration horn 112 of the ultrasonic generator 110 can be easily confirmed.

As shown in fig. 6, the distal end surface 112a of the vibration horn 112 of the ultrasonic generator 110 is positioned slightly lower than the upper surface of the water storage tub 210, and the distal end portion of the vibration horn 112 is in a state of slightly entering the water storage tub 210.

Fig. 9 (base:Sub>A) isbase:Sub>A perspective view of the water storage unit 200, and fig. 9 (b) isbase:Sub>A sectional view taken along linebase:Sub>A-base:Sub>A' of fig. 9 (base:Sub>A).

Referring to fig. 9 (a) and (b), the water storage portion 200 is made of a resin material, is long in the front-rear direction, and has a shape in which the rear portion is curved to the right. The front end and the rear end of the water storage unit 200 have arc shapes. A front part of the water storage part 200 is formed with a water storage tub 210 long in the front-rear direction. The water storage tub 210 has a mortar shape, and its inner circumferential surface is gently inclined. A circular water supply tub 220 is formed at the rear of the water storage part 200. The water supply tub 220 is connected to the water storage tub 210 through a water supply tank 230. The bottom surfaces of the water storage tub 210 and the water supply tank 230 are gently inclined toward the water supply tub 220.

A drain port 221 is formed in the center of the bottom surface of the water supply tub 220. A projection 222 having a hole 222a is provided in the center of the drain port 221. Both sides of the projection 222 are coupled to the inner peripheral edge of the drain opening 221 by two ribs 223. A cylindrical rib 201 surrounding the drain port 221 is formed on the outer bottom surface of the water storage portion 200 so as to protrude downward.

The water supply tub 220 is provided with a drainage mechanism 240 for draining water through a drainage port 221. The drain mechanism 240 includes a valve body 241, an operating member 242, and a coil spring 243.

The valve body 241 is made of an elastic material such as rubber, and closes the drain opening 221 from below. The operating member 242 is made of a resin material, and includes a cylindrical boss portion 244 whose top surface portion is closed, a columnar protrusion portion 245 which protrudes upward from the center of the surface of the top surface portion of the boss portion 244, a shaft portion 246 which extends downward from the center of the back surface of the top surface portion of the boss portion 244, and four arm portions 247 which extend in four directions from the peripheral surface portion of the boss portion 244. The shaft portion 246 is movably passed through the hole portion 222a of the boss 222 up and down. A valve body 241 is attached to the lower end of the shaft portion 246. Each arm portion 247 extends substantially horizontally outward from the peripheral surface of the boss portion 244, then bends substantially vertically and extends upward, and further bends substantially vertically and extends substantially horizontally outward. The coil spring 243 is disposed between the boss portion 244 of the operating member 242 and the two ribs 223. The coil spring 243 is in a compressed state, and applies a force to the operating member 242 in a direction to close the water discharge opening 221 by the valve body 241.

Referring to fig. 4 and 5, the main body 300 includes a tank 500, a valve body switching mechanism 600, and a tank switching mechanism 700. The main body 300 is accommodated in the accommodating portion 83 of the attachment portion 81 provided on the top panel 12.

The case 500 is made of a resin material and has a cylindrical shape with a closed bottom surface and an open top surface. An insertion port 501 is formed in the lower portion of the tank 500 on the ultrasonic cleaning unit 100 side. The insertion port 501 matches the opening portion 86 of the attachment section 81. Inside the box 500, a housing chamber 502 is provided in the depth of the insertion port 501. The housing chamber 502 includes a circumferential wall 503 rising from a bottom surface portion of the box 500 and a fixing plate 510 covering an upper surface of the circumferential wall 503. The fixing plate 510 is fastened to a plurality of mounting bosses 504 provided on the peripheral wall 503 by screws, not shown. The fixed plate 510 has a circular opening 511 at the center. Two ribs 512 extending in the circumferential direction are provided at the peripheral edge of the opening 511 at positions facing each other.

An opening 505 is formed in the storage chamber 502 in the bottom surface of the box 500. The water supply tub 220 of the water storage unit 200 is accommodated in the accommodating chamber 502 through the insertion opening 501. When the water supply tub 220 is accommodated in the accommodating chamber 502, the rib 201 on the outer bottom surface of the water storage part 200 is fitted into the opening 505. A U-shaped slit 506 is formed around the opening 505 in the bottom surface of the tank 500, and when the water storage portion 200 enters and exits the storage chamber 502, the inner portion of the slit 506 including the opening 505 can be pushed by the rib 201 and bent downward. The deflected portion enters the recess 84 of the receiving portion 83.

The drain hole 85 of the storage part 83 is located directly below the drain port 221 of the water storage part 200 and the opening 505 of the tank 500. The inlet 73 provided in the drain receiving portion 71 of the drain unit 70 is connected to the drain hole 85.

The valve body switching mechanism 600 is disposed inside the tank 500, and switches the position of the valve body 241 as follows: the valve 241 of the water discharge mechanism 240 is closed when the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the operating position, and the valve 241 is opened when the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the standby position.

Fig. 10 (a) and (b) are perspective views of the valve body switching mechanism 600 and the water storage unit 200. Fig. 10 (a) shows a state in which the water storage unit 200 is located at the standby position, and fig. 10 (b) shows a state in which the water storage unit 200 is located at the operating position.

Referring to fig. 4, 5, and 10 (a) and (b), the valve body switching mechanism 600 includes a cam member 610 and a holding member 620 that holds and lifts the cam member 610. The cam member 610 and the holding member 620 contain a resin material.

The cam member 610 is formed in a substantially cylindrical shape. The cam member 610 has a stepped portion 611 at an intermediate portion, and the outer diameter of the lower side is made smaller by the stepped portion 611. The cam member 610 has two notches 612 formed at positions facing each other below the step 611. These two notches 612 are engaged with the corresponding ribs 512 of the fixed plate 510, and the cam member 610 is coupled to the fixed plate 510 so as to be immovable in the circumferential direction and movable in the vertical direction with respect to the fixed plate 510. Four shafts 613 protruding outward are formed at equal intervals on the outer peripheral surface of the upper portion of the cam member 610. In a state where the water supply tub 220 of the water storage part 200 is accommodated in the accommodating chamber 502 of the tank 500, the lower end of the cam member 610 contacts the four arm parts 247 of the operation member 242 disposed at the water supply tub 220.

The holding member 620 has a substantially cylindrical frame portion 621, and a disc-shaped holding portion 622 is integrally formed in an upper portion of the inside of the frame portion 621. A part of the lower portion of the frame portion 621 through which the water storage portion 200 passes is opened. Mounting bosses 623 are provided at three locations on the lower surface of the holding portion 622. The mounting boss 623 extends downward along the inner surface of the frame portion 621 and slightly protrudes from the lower end portion of the frame portion 621.

A circular opening 624 is formed in the center of the holding portion 622. Four elevating portions 625 are provided on the upper surface of the holding portion 622 at the periphery of the opening 624. When the cam member 610 is inserted into the opening 624, the shafts 613 of the cam member 610 are arranged in the elevating portion 625. The upper surface of the elevating portion 625 has a ramp shape in which the shaft 613 can move upward and downward after the cam member 610 moves in the circumferential direction. Further, on the upper surface of the holding portion 622, cylindrical guide portions 626 extending upward are provided at four places, and claw portions 627 protruding upward are provided on the rear side. Further, the holding portion 622 is provided with a detection hole 628 on the front side.

At three positions, oval openings 507 curved in the circumferential direction are formed in the bottom surface of the case 500. The three mounting bosses 623 of the holding member 620 are fixed to the bottom surface of the receiving portion 83 through the corresponding openings 507. Accordingly, the holding member 620 is not rotatable with respect to the attachment portion 81, and the ultrasonic cleaning portion 100, the water storage portion 200, and the tank 500 are rotatable between the standby position and the operating position with respect to the attachment portion 81 and the holding member 620. Further, the cam member 610 is coupled to the fixing plate 510 of the case 500, and thus rotates together with the fixing plate 510.

The range of rotation of the ultrasonic cleaning unit 100, the water reservoir 200, and the tank 500 is determined by the length of the opening 507 of the tank 500 in the circumferential direction. When the ultrasonic cleaning unit 100, the water storage unit 200, and the tank 500 are located at the standby position, one end of the opening 507 contacts the mounting boss 623. When the ultrasonic cleaning unit 100, the water storage unit 200, and the tank 500 are moved to the operating position, the other end of the opening 507 contacts the mounting boss 623, and further rotation is prevented.

Inside the tank 500, the tank switching mechanism 700 is disposed above the valve body switching mechanism 600. The tank switching mechanism 700 switches the position of the water supply tank 400 between a water stop position where water is not discharged from the water supply tank 400 and a water discharge position where water is discharged from the water supply tank 400. In the tank 500, the water stop position is located above the water discharge position. The tank switching mechanism 700 does not rotate with respect to the attachment portion 81, as in the case of the valve body switching mechanism 600.

Referring to fig. 4 and 5, the tank switching mechanism 700 includes an upper receiving member 710, a lower receiving member 720, a coil spring 730, and a locking device 740. The upper receiving member 710 has a cylindrical shape corresponding to the shape of the water supply tank 400, and upper and lower surfaces thereof are opened. The lower receiving member 720 has a circular upside down dish shape with an open center, and is fitted to the outer bottom surface of the upper receiving member 710. The lower receiving member 720 is provided with guide holes 721 into which the four guide portions 626 of the holding member 620 are inserted. The lower receiving member 720 is guided by the guide portion 626 when moving up and down.

The coil spring 730 is disposed between the lower receiving member 720 and the step 611 of the cam member 610. The coil spring 730 pushes up the upper receiving member 710 and the lower receiving member 720 to the water stopping position by its elastic force.

The locking device 740 is fitted to the rear side of the lower receiving member 720 in a downward manner. The pawl 627 of the retaining member 620 is located directly below the locking device 740. The lock device 740 includes: a rod 741 having holding pieces on both sides of a distal end portion, a housing 742 for allowing the rod 741 to enter and exit, and an alternative mechanism not shown.

When the upper receiving member 710 and the lower receiving member 720 are pushed down to the water discharge position against the elastic force of the coil spring 730, the holding piece of the lever 741 of the lock device 740 abuts the claw 627 of the holding member 620 from above, and the lever 741 is pushed into the inside of the housing 742 by the claw 627. The pawl 627 is grasped from both sides by the retaining tabs of the rod 741, and the rod 741 is retained inside the housing 742 by the action of the alternating mechanism. Thereby, the pawl 627 is not disengaged from the locking device 740, and the upper receiving member 710 and the lower receiving member 720 are locked at the water discharge position.

When the lever 741 is pushed in again by the pawl 627 from this state, the holding is released by the action of the alternate mechanism, and when the pushing-in force is released, the distal end portion of the lever 741 protrudes from the housing 742, and the holding piece of the lever 741 is released. Thereby, the pawl portion 627 is disengaged from the lock 740. The upper receiving member 710 and the lower receiving member 720 are pushed up to the water stopping position by the elastic force of the coil spring 730.

A sensor mounting portion 722 extending downward is provided on the front side of the lower receiving member 720 at a position corresponding to the detection hole 628 of the holding member 620. A reed switch 801 is attached to the tip of the sensor attachment portion 722. On the other hand, a magnet 802 is attached to the fixing plate 510 of the case 500. The detection unit 800 includes a reed switch 801 and a magnet 802.

The magnet 802 of the fixing plate 510 is located at a position shifted from the detection hole 628 of the holding member 620 when the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the standby position, and moves to a position directly below the detection hole 628 when the ultrasonic cleaning unit 100 and the water storage unit 200 are moved to the operating position. When the upper and lower receiving members 710 and 720, i.e., the water supply tank 400, are lowered to the water discharge position, the reed switch 801 is inserted into the detection hole 628. At this time, when the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the operation position, the reed switch 801 approaches the magnet 802. Thus, an on signal is output from reed switch 801 to control unit 16, and control unit 16 can detect that ultrasonic cleaning unit 100 and water storage unit 200 are in the operating position and that water supply tank 400 is in the water discharge position.

Fig. 11 is a longitudinal sectional view of the water supply tank 400.

Referring to fig. 11, the water supply tank 400 includes a tank body 410 and a cover 420. The tank main body 410 and the cover 420 contain a resin material. The lid 420 includes an opening/closing valve mechanism 430.

The tank body 410 is a substantially cylindrical transparent container, and is formed by screwing an upper container 411 having an open lower surface and a lower container 412 having an open upper surface, with a gasket 441 for water sealing interposed therebetween. The upper portion of the tank body 410 has a step, and the outer diameter becomes smaller at the lower side of the step. A water inlet/outlet 413 is formed in the center of the bottom surface of tank main body 410, and a cylindrical connection port 414 is provided around inlet/outlet 413 so as to protrude downward.

A cap 420 is screwed to the connection port 414 to cover the inlet/outlet 413. A gasket 442 for water sealing is interposed between the cap 420 and the connection port 414. An outflow port 421 is formed on the bottom surface of the cap 420. A projection 422 having a hole portion 422a is provided at a central portion of the outflow port 421. Both sides of the projection 422 are connected to the peripheral edge of the outflow port 421 by two ribs 423.

The opening and closing valve mechanism 430 includes a valve body 431, a pin 432, and a coil spring 433. The valve body 431 includes an elastic material such as rubber. The pin 432 is made of a metal material or a resin material and is inserted through the hole 422a of the protrusion 422 so as to be movable up and down. A valve body 431 is fitted to an upper end portion of the pin 432. The outer diameter of the lower end of the pin 432 is larger than the other portions to form a flange portion 432a, and a coil spring 433 is disposed between the flange portion 432a and the boss 422. The coil spring 433 is in a compressed state, the pin 432 is pressed downward by the coil spring 433, and the valve body 431 closes the outlet 421.

A cylindrical vent hole 424 is formed in the outer bottom surface of the cover 420 so as to surround the pin 432. The outlet of the drain part 424 is a drain port 401 through which the last water in the water tank 400 is supplied.

As shown in fig. 4, the water supply tank 400 is provided to the upper receiving member 710 of the tank switching mechanism 700 from above. The outlet 424 of the cover 420 is exposed downward from the lower surface opening of the upper receiving member 710 and enters the inside of the cam member 610.

The full automatic washing machine 1 performs washing operations in various operation modes. In the washing operation, a washing process, an intermediate dehydration process, a rinsing process, and a final dehydration process are sequentially performed.

In the washing process and the rinsing process, the pulsator 24 rotates in the right and left directions in a state that water is stored in the washing and dehydrating tub 22. By the rotation of the pulsator 24, a water current is generated in the washing and dehydrating tub 22. In the washing process, the laundry is washed by the generated water flow and the detergent contained in the water. In the rinsing process, the laundry is rinsed by the generated water current.

In the intermediate dehydration process and the final dehydration process, the washing dehydration tub 22 and the pulsator 24 are integrally rotated at a high speed. The laundry is dehydrated by the centrifugal force generated in the washing and dehydrating tub 22.

Further, the full-automatic washing machine 1 performs a washing operation of the ultrasonic washing device 50. When a user washes an object to be washed such as a shirt, if the object to be washed partially contains stubborn dirt, the object to be washed is partially washed using the ultrasonic washing apparatus 50 before washing.

When the cleaning operation is not performed, as shown in fig. 3 (a), the ultrasonic cleaning apparatus 50 is in a state where the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the standby position. At this time, as shown in fig. 4, the water supply tank 400 is held at the water stopping position by the tank switching mechanism 700. The valve body 431 is closed and the washing water is not discharged from the water supply tank 400. As shown in fig. 10 (a), the cam member 610 of the valve body switching mechanism 600 moves to the lowermost position by positioning the four shafts 613 at the lowermost point of the corresponding elevating unit 625. As shown in fig. 4, in the reservoir portion 200, the operating member 242 of the drain mechanism 240 is pushed downward by the cam member 610, the valve body 241 is separated from the drain port 221, and the drain port 221 is opened.

When the washing operation is performed and there is no washing water in water supply tank 400, the user takes water supply tank 400 out to the outside, turns it upside down, and opens lower container 412. The user adds water and liquid detergent to the water supply tank 400, closes the lower container 412, and then gently shakes the water supply tank 400 to mix the liquid detergent with the water. Thereby, washing water is generated in the water supply tank 400. Thereafter, the user puts the water supply tank 400 into the main body 300 again.

Further, the user rotates ultrasonic cleaning unit 100 and water storage unit 200 toward inlet 14, and moves ultrasonic cleaning unit 100 and water storage unit 200 to the operating position, as shown in fig. 3 (b). Then, the user pushes the water supply tank 400 downward. The water supply tank 400 descends to a water discharge position. The water supply tank 400 is maintained at the water discharge position by the tank switching mechanism 700.

Fig. 12 is a front sectional view of the peripheral portion of the ultrasonic cleaning apparatus 50 when the ultrasonic cleaning unit 100 and the water storage unit 200 are at the operating position and the water supply tank 400 is at the water discharge position.

As shown in fig. 12, when the water supply tank 400 is lowered to the water discharge position, the pin 432 of the water supply tank 400 abuts against the projection 245 of the operating member 242 and is pushed up against the urging force of the coil spring 433. Thereby, the valve body 431 is separated from the outlet 421, the outlet 421 is opened, and the washing water in the water supply tank 400 is discharged from the discharge port 401. At this time, as shown in fig. 10 (b), the cam member 610 of the valve body switching mechanism 600 moves to the uppermost position by positioning the four shafts 613 at the uppermost point of the corresponding elevating portion 625. Therefore, in the water storage unit 200, the operating member 242 of the drainage mechanism 240 is released from the pressing of the cam member 610 and pushed up by the elastic force of the coil spring 243. Thereby, the valve body 241 closes the drain port 221, and the drain port 221 is closed.

The washing water discharged from the water supply tank 400 is received by the water supply tub 220 and is supplied to the water storage tub 210 through the water supply tank 230. When the washing water is stored in the water storage tub 210, the water level in the water supply tub 220 rises together with the water level in the water storage tub 210. As shown by the one-dot chain line of fig. 12, when the water level in the water supply tub 220 rises to the height of the drain port 401 of the water supply tank 400 and the drain port 401 is blocked by the washing water, the valve body 431 is maintained in an open state by the balance between the air pressure in the water supply tank 400 and the external air pressure, and the water supply from the water supply tank 400 is stopped.

When the washing water is stored in the tub 210, the user places a dirt-attached portion of the object to be washed, for example, a collar portion of a shirt, on the tub 210 from the front direction of the ultrasonic cleaning unit 100, i.e., between the tub 210 and the vibration horn 112 of the ultrasonic generator 110.

At this time, in the ultrasonic cleaning unit 100, the position of the guide portion 132 of the cover 130 coincides with the position of the distal end portion of the vibration horn 112 of the ultrasonic generator 110 in the front-rear direction, and therefore, the guide portion 132 serves as a mark, and the user can easily grasp the position of the distal end portion of the vibration horn 112. On the other hand, since the user usually views the ultrasonic cleaning apparatus 50 provided on the top panel 12 from obliquely above, it is difficult to check the gap between the ultrasonic generator 110 and the water storage tub 210.

Therefore, as shown in fig. 6, the user brings the dirt adhering portion such as the collar or cuff into contact with the guide surface 135 of the guide section 132, moves downward and rearward along the guide surface 135, and reaches the position of the distal end surface 112a of the vibration horn 112. At this time, the lower end of the guide portion 132 extends below the lower end of the cover body 131, and covers the front surface of the distal end portion of the vibration horn 112 exposed from the cover body 131. Therefore, the dirt-adhering portion guided by the guide portion 132 is less likely to be caught by the corner portion of the distal end portion of the vibration horn 112, and is less likely to be damaged. Further, by the guidance of the guide portion 132, the dirt adhesion portion is positioned to an appropriate height position almost in contact with the tip end face 112a of the vibration horn 112, not too far away from the tip end face 112a of the vibration horn 112.

The dirt adhering portion of the object to be cleaned is soaked in the cleaning water stored in the water storage tub 210, and the cleaning water soaked in the object to be cleaned is leached out to the surface. The following states are presented: a thin water layer is formed on the surface of the object to be cleaned, and the vibration horn 112 is in contact with the water layer. When the water level in the storage tub 210 is lowered by the water absorbed into the object to be washed, and the water level in the water supply tub 220 is lowered, and the drain port 401 of the water supply tank 400 is not blocked by the washing water, the washing water is supplied from the water supply tank 400 to the water supply tub 220, that is, the storage tub 210, until the drain port 401 is blocked by the washing water again. Thus, the water level, i.e., the amount of water, in the water storage tub 210 is maintained in an appropriate state.

The user performs a prescribed start operation to start the washing operation.

When ultrasonic cleaning unit 100 and water storage unit 200 are at the operating position and water supply tank 400 is at the water discharge position, this state is detected by detection unit 800, and an on signal is output from reed switch 801 of detection unit 800 to control unit 16. In this case, the control unit 16 energizes the ultrasonic transducer 111 to operate the ultrasonic generator 110. Thereby, the cleaning operation is started.

Note that, when at least water supply tank 400 is in the rest position or ultrasonic cleaning unit 100 and water storage unit 200 are in the standby position, that is, when at least washing water is not supplied from water supply tank 400 or even washing water is supplied, the washing water is discharged from water discharge port 221, no on signal is output from reed switch 801. Therefore, the control unit 16 does not energize the ultrasonic transducer 111 and does not operate the ultrasonic generator 110. Therefore, the washing operation is not started in a state where the preparation for the washing operation is not completed.

When the cleaning operation is started and the ultrasonic generator 110 is operated, the two LEDs 145 of the ultrasonic cleaning unit 100 are turned on by the control unit 16. Thereby, the cover 130 emits light as a whole. This allows the user to easily recognize that the ultrasonic generator 110 is operating, that is, the cleaning operation is being performed.

Fig. 13 (a) to (c) are views for explaining the decontamination of the object to be cleaned by the ultrasonic cleaning device 50.

When the ultrasonic generator 110 is operated, ultrasonic waves are generated from the distal end of the vibration horn 112, and the ultrasonic vibrations are transmitted to the washing water inside the object to be washed via the washing water around the vibration horn 112. As shown in fig. 13 (a), inside the object to be cleaned, pressure reduction and pressurization are alternately generated by the action of ultrasonic vibration, and a vacuum cavity is generated in a portion where the pressure is reduced. That is, a large number of cavities are present in the contaminated portion of the object to be cleaned. Next, as shown in fig. 13 (b), when the pressure of the cavity portion becomes high and the cavity is crushed and broken by the pressure, a shock wave is generated in the contaminated portion of the object to be cleaned. By this shock wave, dirt is separated from the object to be cleaned. As shown in fig. 13 (c), the ultrasonic vibration from the vibration horn 112 generates a water flow heading from the inside of the object to be cleaned into the water storage tub 210, and the water flow discharges dirt separated from the object to be cleaned into the water storage tub 210. In the water storage tub 210, the above-described water flow causes convection, and therefore, dirt is easily removed from the object to be cleaned. Further, the dirt is easily peeled off from the object to be cleaned by the action of the detergent contained in the washing water, and the dirt is not easily reattached to the object to be cleaned. In this way, the dirt is removed from the object to be cleaned.

When the cleaning of the object to be cleaned is completed, the user performs a predetermined end operation to end the cleaning operation. The control unit 16 stops the operation of the ultrasonic generator 110, and the cleaning operation is ended.

As described in fig. 6, the dirt-adhering portion of the object to be cleaned is not placed too far from the distal end surface 112a of the vibration horn 112 of the ultrasonic generator 110, and thus the ultrasonic vibration from the vibration horn 112 is effectively applied to the dirt-adhering portion, and the dirt is easily removed.

The user presses the water supply tank 400 slightly downward with the finger without continuing a new washing operation. When the finger is removed from the water supply tank 400, the locking means 740 is disengaged from the claw 627, and the water supply tank 400 is moved to the water stopping position together with the upper receiving member 710. The pin 432 moves downward, and the outlet 421 is closed by the valve body 431, and thus, water cannot be supplied from the water supply tank 400.

Then, the user turns ultrasonic cleaning unit 100 and water storage unit 200 toward installation unit 80, and moves ultrasonic cleaning unit 100 and water storage unit 200 to the standby position, as shown in fig. 3 (a). As described above, the drain port 221 of the water storage unit 200 is opened at the standby position (see fig. 4). Thereby, the washing water stored in the water storage tub 210 and the water supply tub 220 is discharged through the drain port 221. The water discharged from the drain port 221 is discharged to the drain port portion 20a of the outer tub 20 through the drain receiving portion 71 of the drain unit 70 and the hose 72.

The user may want to discard the washing water remaining in the water supply tank 400 after the washing operation is finished. In this case, the user can take the water supply tank 400 out of the main body 300 to a place to be discarded such as a sink and remove the cover 420 to discharge the washing water in the water supply tank 400 to the place to be discarded, but such an operation is troublesome.

In the present embodiment, the user can discard the washing water in the water supply tank 400 without taking the water supply tank 400 out of the main body 300. Therefore, the user pushes down the water supply tank 400 located at the water stop position to the water discharge position in a state where the ultrasonic cleaning unit 100 and the water storage unit 200 are located at the standby position.

Fig. 14 is a front sectional view of the peripheral portion of the ultrasonic cleaning apparatus 50 when the ultrasonic cleaning unit 100 and the water storage unit 200 are at the standby position and the water supply tank 400 is at the water discharge position.

As shown in fig. 14, when the water supply tank 400 is lowered to the water discharge position, the pin 432 of the water supply tank 400 abuts against the projection 245 of the operating member 242 and is pushed up against the urging force of the coil spring 433. Thereby, the valve body 431 is separated from the outlet 421, the outlet 421 is opened, and the washing water in the water supply tank 400 is discharged from the discharge port 401. When ultrasonic cleaning unit 100 and water storage unit 200 are located at the standby position, operation member 242 is pushed down by cam member 610, and therefore, projection 245 is located lower than when ultrasonic cleaning unit 100 and water storage unit 200 are located at the operating position. Therefore, the amount of movement of the pin 432 is smaller than when water is supplied to the reservoir tank 210, and therefore, the gap between the valve body 431 and the outlet 421 is smaller, and the flow rate discharged from the discharge port 401 is smaller. The washing water discharged from the water supply tank 400 is received by the water supply tub 220 and discharged from the drain port 221 to flow toward the drain unit 70.

In this way, the user can discard the washing water remaining in the supply water tank 400 without detaching the supply water tank 400 from the main body 300.

In the ultrasonic cleaning unit 100, dirt may enter the cap 130 from the opening of the cap 130 and adhere to the vibration horn 112 of the ultrasonic generator 110 inside the cap 130 during repeated cleaning operations. In the present embodiment, since the cover 130 is detachable from the housing 120, the user can remove the cover 130 from the housing 120 and clean the vibration horn 112.

In addition, the water storage tub 210 and the water supply tub 220 may be soiled during the repeated washing operations. In the present embodiment, the water storage portion 200 is detachable from the main body 300, and therefore, the user can detach the water storage portion 200 from the main body 300 and wash the water storage tub 210 and the water supply tub 220. Since the water storage portion 200 is stored in the storage portion 82 when it is located at the standby position, the water storage portion 200 cannot be detached from the main body 300. Therefore, when the user detaches the water storage portion 200 from the main body 300, the user moves the water storage portion 200 to a position away from the housing portion 82, for example, an operation position.

< effects of the embodiment >

As described above, according to the present embodiment, since the guide portion 132 is provided in the cap 130 covering the distal end side of the vibration horn 112 of the ultrasonic wave generator 110, the user can easily set the dirt adhesion portion of the object to be cleaned between the distal end surface 112a of the vibration horn 112 and the water storage tub 210 by being guided by the guide portion 132.

Further, according to the present embodiment, since the guide surface 135 inclined so as to approach the ultrasonic generator 110 as approaching the reservoir tank 210 can be provided in the guide portion 132, the user can reach between the distal end surface 112a of the vibration horn 112 and the reservoir tank 210 only by bringing the dirt adhesion portion of the object to be cleaned into contact with the guide surface 135 and following the guide surface 135.

Further, according to the present embodiment, since the cap 130 is detachably attached to the housing 120, the user can clean the portion of the ultrasonic generator 110 on the distal end side of the vibration horn 112 by removing the cap 130.

Further, according to the present embodiment, since the position of the guide portion 132 coincides with the position of the ultrasonic generator 110 in the direction orthogonal to the direction in which the dirt adhering portion is guided by the guide portion 132, the guide portion 132 serves as a mark, and the user can easily confirm the position of the ultrasonic generator 110.

Further, according to the present embodiment, since the lower end of the guide portion 132 is located below the lower end of the cover main body 131, the distal end portion of the vibration horn 112 exposed from the cover main body 131 can be covered in the direction in which the dirt adhering portion is guided by the guide portion 132 through the lower end portion of the guide portion 132. Thus, the dirt-adhering portion guided by the guide portion 132 is less likely to be caught by the corner portion of the distal end portion of the vibration horn 112, and is less likely to be damaged.

The embodiments of the present invention have been described above, but the present invention is not limited to the above embodiments, and various modifications other than the above may be made to the embodiments of the present invention.

For example, in the above embodiment, the cover 130 is detachably attached to the housing 120. However, the cover 130 may be formed integrally with the housing 120.

In the above embodiment, the position of the lower end of the guide portion 132 is substantially flush with the position of the distal end surface 112a of the vibration horn 112. However, the position of the lower end of the guide portion 132 may be slightly lower or higher than the position of the distal end surface 112a of the vibration horn 112.

Further, in the above embodiment, the hole 136 is provided in the light receiving portion 133 of the cover 130, and when the light receiving portion 133 is fitted into the recess 144 of the housing 120, the LED145 is fitted into the hole 136. However, the hole 136 may not be formed in the light receiving portion 133, and the ledd 145 may be in contact with or close to the upper surface of the light receiving portion 133.

Further, in the above embodiment, the ultrasonic cleaning device 50 is provided in the fully automatic washing machine 1. However, the ultrasonic cleaning device 50 may be provided in a washing machine other than the fully automatic washing machine 1, for example, a drum-type washing machine. The ultrasonic cleaning device 50 may be provided in, for example, a full-automatic washing and drying machine or a drum-type washing and drying machine having a drying function. In a drum type washing machine and a drum type washing and drying all-in-one machine, a washing tub includes an outer tub and a drum disposed in the outer tub.

The embodiments of the present invention can be modified in various ways as appropriate within the scope of the technical idea shown in the claims.

Claims (6)

1. An ultrasonic cleaning device is characterized by comprising:

an ultrasonic cleaning unit having an ultrasonic generator and generating ultrasonic waves;

a water storage unit having a water storage tank capable of storing water, disposed below the ultrasonic generator, and capable of storing water to be soaked in the object to be cleaned; and

an outer casing for housing the ultrasonic generator,

the exterior body includes:

a covering section that covers a distal end side portion of the ultrasonic generator so that a distal end portion thereof is exposed; and

a guide part which is arranged on the side surface of the covering part and guides the dirt adhesion part of the cleaned object to the space between the top end surface of the ultrasonic generator and the water storage barrel;

a circular water supply barrel is formed at the rear part of the water storage part and is connected with the water storage barrel through a water supply groove;

a water discharge opening is formed in the central portion of the bottom surface of the water supply barrel, a water discharge mechanism for discharging water through the water discharge opening is arranged on the water supply barrel, and the water discharge mechanism comprises a valve body for closing the water discharge opening;

a valve body switching mechanism that closes a valve body of the drainage mechanism when the ultrasonic cleaning unit and the water storage unit are located at an operating position, and opens the valve body when the ultrasonic cleaning unit and the water storage unit are located at a standby position;

the valve body switching mechanism includes a cam member and a holding member that holds and raises and lowers the cam member, the holding member being capable of moving the valve body between a closed position that closes the drain opening and an open position that opens the drain opening by reciprocating the cam member;

four shafts protruding outward are formed at equal intervals on the outer peripheral surface of the upper portion of the cam member;

the holding member has a cylindrical frame portion, a disc-shaped holding portion is integrally formed at an upper portion inside the frame portion, a circular opening portion is formed at a central portion of the holding portion, four elevating portions are provided at an upper surface of the holding portion at a periphery of the opening portion, and an upper surface of the elevating portion has a ramp shape in which a shaft can move up and down after the cam member moves in the circumferential direction.

2. An ultrasonic cleaning device according to claim 1,

the guide portion is provided with a guide surface that is inclined so as to approach the ultrasonic generator as it approaches the water storage tub, and along which the dirt adhesion portion follows.

3. An ultrasonic cleaning device according to claim 1,

the exterior body includes:

a housing that houses a portion of the ultrasonic generator other than the portion on the distal end side; and

a cover including the covering portion and the guide portion, detachably attached to the housing.

4. An ultrasonic cleaning device according to any one of claims 1 to 3,

the position of the guide portion coincides with the position of the ultrasonic generator in a direction orthogonal to a direction in which the dirt adhesion portion is guided by the guide portion.

5. An ultrasonic cleaning device according to any one of claims 1 to 3,

the lower end of the guide portion is located below the lower end of the covering portion.

6. A washing machine is characterized by comprising:

a washing tub for receiving laundry to wash;

an upper panel having an inlet for inputting the washings into the washing barrel; and

the ultrasonic cleaning device of claim 1 attached to the top panel.

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