JP4613233B2 - Washing machine - Google Patents

Description

  The present invention relates to a washing machine.

  Conventionally, mist-like water (mist) is washed in order to increase the water absorption of clothes and to dissolve detergent sufficiently in water by sprinkling water on the clothes and other laundry. There is a washing machine that supplies things.

  For example, Japanese Patent Laid-Open No. 2001-276472 (Patent Document 1) and Japanese Patent Laid-Open No. 2002-18187 (Patent Document 2) describe washing in which water is supplied to the water level lower than the set water level in the water supply stroke and then mist is supplied. The machine is listed. By such mist water supply in such a water supply process, the laundry becomes familiar with the water, and the detergent adhering to the surface of the laundry is also dissolved. Further, in this washing machine, mist water supply is intermittently performed in the washing process, and when the laundry is lifted, the laundry is beaten from above by the mist water supply to prevent the laundry from being lifted.

  In Japanese Patent Application Laid-Open No. 2005-73836 (Patent Document 3), in order to apply water evenly to the laundry and to quickly apply water and detergent to the laundry, a fog is applied to the laundry from the top in the first stage of the water supply process. A washing machine is described which sprinkles water in the same manner and slowly rotates the washing and dewatering tub with the rotation.

Japanese Patent Laying-Open No. 2006-25901 (Patent Document 4) and Japanese Patent Laying-Open No. 2006-51324 (Patent Document 5) describe a washing machine that performs normal water supply and hot water mist (mist-like hot water) supply. ing.
JP 2001-276472 A Japanese Patent Laid-Open No. 2002-18187 Japanese Patent Laid-Open No. 2005-73836 JP 2006-25901 A JP 2006-51324 A

  However, in a conventional washing machine, a predetermined amount of water is supplied directly from the water supply without being atomized out of the total amount of water supplied to the laundry before reaching the set water level in the water supply process and the washing process. The remaining amount of water is supplied in the form of a mist. Therefore, the time for which the mist-like water is supplied is the time until the water reaches the set water level at the maximum. In this way, in a washing machine that does not supply mist-like water after the water reaches the set water level, even if water is supplied up to the set water level, It may not be possible to fully wet everything. Also, the detergent may remain on the surface of the laundry that has floated from the water. If the entire laundry is not sufficiently wet or the detergent is not dissolved, the laundry may not be sufficiently washed.

  Accordingly, an object of the present invention is to provide a washing machine that can sufficiently absorb a target object to increase its cleaning power.

  The washing machine according to the present invention includes a storage tub for storing an object, a circulation channel for circulating water discharged from the storage tub and returning the water to the storage tub, and water flowing through the circulation channel in a mist form. And a mist water supply device for supplying the water into the storage tank.

  Provided with a circulation water channel that returns water discharged from the storage tank containing the object to the storage tank, and the mist water supply device makes the water flowing through the circulation water channel mist to the set water level in the storage tank Even after the water is stored, the water can be circulated to supply mist-like water into the storage tank. By supplying the water flowing through the circulation channel in the form of a mist into the storage tank, the mist of water can be supplied into the storage tank for an arbitrary time without increasing the water more than the set water level.

  In this way, since mist-like water can be supplied into the storage tank regardless of the set water level and the water supply time, the object floating in the water when the water is stored up to the set water level Can be wet with water.

  By doing in this way, the washing machine which can make a target absorb water enough and can raise washing power can be provided.

  In the washing machine according to the present invention, the mist water supply device has a spray port for discharging the mist water, and the spray port is opened toward the storage tank.

  Since the spray port is opened directly into the storage tank, the mist-like water generated by the mist-like water supply device is combined to become huge, or waste due to adhering to the wall surface of the waterway etc. The mist having an appropriate particle size can be supplied to the object without leaving a limit.

In the washing machine according to the present invention, the mist water supply device includes water containing a detergent that circulates in the circulation channel before the storage tub rotates during a washing process of washing the object with at least the detergent and water. A mist is supplied into the storage tank .

  By doing in this way, the whole target object becomes easy to become familiar with water and detergent, and it can raise cleaning power. Moreover, the detergent can be well dissolved in water by an emulsifying action by making the water containing the detergent mist by ultrasonic waves. Moreover, since the water particles are small in mist-like water, the permeability to the object is good, and by supplying water in which the detergent is well dissolved into the storage tank, the washing power of water used for washing can be increased. it can.

In the washing machine according to the present invention, the mist water supply device supplies the water flowing through the circulation channel in the form of mist in the storage tank in the rinsing process of the object washed in the washing process. .

In the rinsing process, the mist water supply device mists water that does not contain detergent or contains little detergent. By doing in this way, mist water supply device itself can be washed. In addition, by supplying mist-like water into the storage tank in the rinsing process, water particles can be reduced to improve permeability, and the detergent attached to the object and the storage tank can be well removed.

In the washing machine according to the present invention, the mist water supply device supplies the water flowing through the circulation channel in the form of a mist in the storage tank in the final rinsing process when there are a plurality of rinsing processes. Is preferred. Further, in the washing machine according to the present invention, when the water level in the storage tank is lower than a predetermined set water level in the washing process, when water is supplied to the storage tank, the mist water supply device is It is preferable to supply mist-like water into the storage tank.

  As described above, according to the present invention, it is possible to provide a washing machine that can sufficiently absorb water by an object and increase the cleaning power.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a perspective view schematically showing the overall appearance of a washing / drying machine as one embodiment of the present invention. FIG. 2 is a sectional view of the washing / drying machine shown in FIG. It is sectional drawing which shows the cross section seen roughly.

  As shown in FIGS. 1 and 2, the washing / drying machine 1 includes an exterior 101, an upper surface plate 102 that forms an upper surface of the exterior 101, a water tank 130 attached to the interior of the exterior 101, and a fiber as an example of an object. As a storage tank for storing the structure 2, a rotating drum 120 that is rotatably supported inside the water tank 130 and a circulation pump 460 disposed below the exterior 101 are provided. The exterior 101 and the entire interior of the exterior 101 are supported on the floor surface by rubber feet 103.

  The fiber structure 2 only needs to be composed of fibers, such as clothing, cloths, towels, and blankets. In addition to the fiber structure 2, the object may not be composed of fibers as long as the object is washed and dried by the washing / drying machine 1.

  An outer door 111 is attached to the front surface of the exterior 101. An inner door 112 is attached to the inner side of the outer door 111. By opening the outer door 111 and opening the inner door 112, the fiber structure 2 can be input to the rotary drum 120 or taken out from the rotary drum 120 through the input port 113 provided on the front surface side of the exterior 101. The inlet 113 can be closed by closing the inner door 112 and closing the outer door 111. The inner door 112 has a central portion made of transparent glass so that the inside of the rotary drum 120 is visible, and has a concave bowl shape, a so-called basin shape. A door packing 114 made of an elastic material such as rubber is fitted and fixed to the packing cover 115 on the peripheral wall of the water tank 130 on the inlet 113 side. When the inner door 112 is closed, the door packing 114 is brought into close contact with the periphery of the inner door 112 and the water tank 130 is sealed.

  The rotating drum 120 is supported inside the water tank 130 so as to rotate around the shaft portion 141. In this way, the drum-type washing / drying machine 1 has a double structure including the water tank 130 and the rotating drum 120.

  The rotary drum 120 includes a drum body that forms an inner peripheral wall surface in the center in the rotation axis direction, a drum lid that forms an opening at one end, and a drum bottom that forms an inner bottom wall surface at the other end. It is made from stainless steel plate. An uneven surface such as a rib is formed on the drum bottom by pressing to attach a structural component such as the shaft 141 and support a desired load, thereby improving the strength of the bottom wall surface. A number of small holes 121 for water supply, drainage, and ventilation are provided in the peripheral wall and bottom of the rotary drum 120. A fluid balancer 123 is fixed to the outer peripheral edge of the drum lid to prevent vibration during rotation. A baffle 122 is disposed on the inner peripheral wall surface of the drum body.

  The shaft portion 141 includes a shaft of a drum rotation drive motor 140 for rotating the rotary drum 120. The rotation of the drum rotation drive motor 140 is controlled by an inverter circuit of the main circuit 107 disposed in the lower part of the washing / drying machine 1.

  The water tank 130 is elastically supported by a support spring 104 from above and by a support damper 105 from below. A drain valve 432 is provided at the bottom of the water tank 130, and water containing detergent is drained from the water tank 130 through the internal drain hose 430 and the external drain hose 431 when the drain valve 432 is opened and closed.

  A cooling duct 330 is connected to the back side of the water tank 130. When water is not stored in the water tank 130 and the fiber structure 2 is dried in the rotating drum 120, the air in the rotating drum 120 and the water tank 130 is discharged from the water tank 130 through the cooling duct 330, As will be described later, it is cooled (dehumidified), heated, and returned to the water tank 130.

  An operation circuit 106 is disposed above the water tank 130. A main circuit 107 is disposed below the water tank 130. The operation circuit 106 receives a signal from the operation unit when the user operates an operation unit (not shown) disposed on the outer peripheral surface of the exterior 101 in order to operate the washing / drying machine 1, and the water tank 130. A control signal is transmitted to the main circuit 107 arranged below the main circuit 107. The main circuit 107 transmits a control signal to each member of the washing / drying machine 1 such as the drum rotation drive motor 140, the circulation pump 460, the drain valve 432, the water supply valve, and the blower motor, and controls the operation of each member.

  3 is a diagram showing a state when the inside of the exterior of the washing / drying machine shown in FIG. 1 is viewed from above, and FIG. 4 is a view of the inside of the exterior of the washing / drying machine shown in FIG. 5 is a diagram showing a state when the inside of the exterior of the washing / drying machine shown in FIG. 1 is viewed from the left.

  The flow of water and air in the washing / drying machine 1 will be described with reference to FIGS. A dashed-dotted arrow P in the figure indicates the flow of water supplied from the water supply, a solid-line arrow Q indicates the flow of water circulating in the washing / drying machine 1, and a two-dot chain line arrow R indicates air. Shows the flow.

  First, the flow of air in the washing / drying machine 1 will be described with reference to FIGS. 3 and 4.

As shown in FIGS. 3 and 4, a cooling duct 330 is arranged on the back side of the water tank 130 so as to extend in the vertical direction. An exhaust duct 320 is connected to the upper end of the cooling duct 330. A blower fan 312 for sending air, a blower motor 313 for rotating the blower fan 312, and a blown yarn waste filter 314 are disposed in the exhaust duct 320. The exhaust duct 320 is connected to the air supply duct 310. In the air supply duct 310, a PTC (Positive Temperature Coefficient) heater 315 for heating the air in the air supply duct 310 and H ⁺ (H ₂ O) _m () as positive ions in the air in the air supply duct 310. A PCI (plasma cluster ion) unit 316 is arranged as an ion supply device for supplying m (arbitrary natural number) and negative ions O ₂ ⁻ (H ₂ O) _n (n is an arbitrary natural number). The air supply duct 310 is provided with a hot air outlet 311 for blowing out hot air. The hot air outlet 311 is directed to the inside of the water tank 130.

  When the blower motor 313 is driven and the blower fan 312 rotates, the air in the water tank 130 flows into the cooling duct 330 from the lower back of the water tank 130. Water is supplied from the cooling water supply hose 412 into the cooling duct 330, and the air flowing into the cooling duct 330 from the water tank 130 is cooled. When the air in the water tank 130 is moist, the moist air is cooled in the cooling duct 330 and dehumidified. The air in the cooling duct 330 flows upward in the cooling duct 330 and flows into the exhaust duct 320.

  In the exhaust duct 320, air passes through the blown yarn waste filter 314 to remove dust such as yarn waste. The air that has passed through the blown yarn waste filter 314 flows into the air supply duct 310.

  In the air supply duct 310, positive ions and negative ions are supplied from the PCI unit 316 to the air. In addition, the washing / drying machine 1 may not include an ion supply device such as the PCI unit 316 for supplying ions to the air, and also includes a PCI unit 316 as necessary. The unit 316 may be driven, and ions may not be supplied to the air in the air supply duct 310.

  In the air supply duct 310, the air passes through the PTC heater 315 and is heated. The heated air is supplied from the hot air outlet 311 into the water tank 130 and the rotating drum 120 (FIG. 2).

  In the rotating drum 120, the heated air comes into contact with the fiber structure 2 (FIG. 2) to evaporate moisture from the fiber structure 2 and dry it. Air containing moisture evaporated from the fiber structure 2 flows into the water tank 130 through the small hole 121 (FIG. 2) of the rotating drum 120, and flows into the cooling duct 330 again from the lower part of the water tank 130.

  As described above, in the inside of the washing / drying machine 1, the air circulates through the rotating drum 120, the water tank 130, the cooling duct 330, the exhaust duct 320, and the air supply duct 310. The rotating drum 120, the water tank 130, the cooling duct 330, the exhaust duct 320, and the air supply duct 310 are examples of an air flow passage.

  Next, the flow of water in the washing / drying machine 1 will be described with reference to FIGS. 3 and 5.

  As shown in FIGS. 3 and 5, above the water tank 130, a water supply valve 401 for switching between water supply into the washing / drying machine 1 and water supply stop, a water supply unit 410, a detergent case 470, A diversion nozzle 450 and an ultrasonic unit 200 as a mist water supply device are arranged. The water supply unit 410 adjusts the amount of water flowing out of the water supply unit 410.

  A circulation pump 460 is disposed below the water tank 130. An internal drain hose 430 is connected to the lower part of the water tank 130. The internal drain hose 430 is connected to the circulation hose 440 and the external drain hose 431 via the circulation pump 460. The circulation hose 440 is connected to the diversion nozzle 450.

  The water supply unit 410 is connected to a dry mist water supply hose 411, a cooling water supply hose 412, a water supply duct 420, and a diversion nozzle 450. The dry mist water supply hose 411 is connected to the water supply unit 410 via the dry mist water supply valve 413. A wet mist water supply hose 451 and a foam extinguishing water supply hose 452 are connected to the diversion nozzle 450. The dry mist water supply hose 411 and the wet mist water supply hose 451 are connected to the ultrasonic unit 200.

  Water supplied from the water supply into the washing / drying machine 1 is supplied to the water supply unit 410 through the water supply valve 401. At this time, whether the water is supplied to the water supply unit 410 through the detergent case 470 or not supplied to the water supply unit 410 without passing through the detergent case 470 is controlled according to the washing / drying process of the washing / drying machine 1. The The water that has passed through the detergent case 470 contains detergent.

  Water that does not pass through the detergent case 470 and does not contain detergent is supplied from the water supply unit 410 to the dry mist water supply hose 411 and the cooling water supply hose 412. When the ultrasonic unit 200 is driven, the water supplied to the dry mist water supply hose 411 is atomized by the ultrasonic unit 200 and supplied into the rotary drum 120 (FIG. 2). It flows into the water tank 130 through the hole 121 (FIG. 2). The water supplied to the cooling water supply hose 412 flows into the cooling duct 330. The water supplied to the water supply duct 420 is supplied into the water tank 130.

  The water containing the detergent passing through the detergent case 470 passes from the water supply unit 410 to the water supply duct 420 or the wet mist water supply hose 451 connected to the diversion nozzle 450 and the foam-erasing water supply hose 452, and then into the rotary drum 120. To be supplied. When the ultrasonic unit 200 is driven, the water supplied to the wet mist water supply hose 451 is atomized by the ultrasonic unit 200 and supplied into the rotary drum 120 and passes through the small hole 121 of the rotary drum 120. Into the water tank 130. The water supplied to the foam-extinguishing water supply hose 452 flows into the cooling duct 330 through the cooling duct 330, and the bubbles generated by the stirring of the detergent components in the cooling duct 330 disappear. The water supplied from the diversion nozzle 450 directly through the shower outlet hole of the packing cover 115 (FIG. 2) into the rotating drum 120 flows into the water tank 130 through the small hole 121 of the rotating drum 120.

  When the circulation pump 460 is driven, the water in the water tank 130 is returned from the internal drain hose 430 to the diversion nozzle 450 through the circulation hose 440. Further, when the drain valve 432 (FIG. 2) is opened, the water in the water tank 130 is drained from the internal drain hose 430 through the external drain hose 431 to the outside of the washing dryer 1.

  The water returned to the diversion nozzle 450 through the circulation hose 440 is supplied into the wet mist water supply hose 451, the foam-extinguishing water supply hose 452, and the rotary drum 120. When the ultrasonic unit 200 is driven, the water supplied to the wet mist water supply hose 451 is atomized by the ultrasonic unit 200 and supplied into the rotary drum 120 and passes through the small hole 121 of the rotary drum 120. Into the water tank 130. The water supplied to the foam extinguishing water supply hose 452 flows into the cooling duct 330, extinguishes bubbles generated by stirring of the detergent components in the cooling duct 330, and flows into the water tank 130 at the lower part of the cooling duct 330. The water supplied into the rotating drum 120 directly from the diversion nozzle 450 through the shower outlet hole of the packing cover 115 flows into the water tank 130 through the small hole 121 of the rotating drum 120.

  Thus, the water in the washing and drying machine 1 circulates in the washing and drying machine 1 through the rotating drum 120 and the water tank 130, the internal drainage hose 430, the circulation hose 440, and the diversion nozzle 450. In this way, the water circulating inside the washing / drying machine 1 is referred to as circulating water. The rotating drum 120, the water tank 130, the internal drain hose 430, the circulation hose 440, and the diversion nozzle 450 are examples of the circulation water channel. The ultrasonic unit 200 supplies the water supplied from the diversion nozzle 450 in the form of a mist into the rotary drum 120. Further, the path for supplying water from the water supply unit 410 to the rotary drum 120 and the water tank 130 through the ultrasonic unit 200 and the path for supplying water to the rotary drum 120 and the water tank 130 through the diversion nozzle 450 are examples of the water supply path. . The ultrasonic unit 200 supplies the water supplied from the water supply unit 410 and the water supplied from the diversion nozzle 450 in the form of a mist into the rotary drum 120.

  As described above, the water supplied to the ultrasonic unit 200 through the dry mist water supply hose 411 is not the circulating water circulating inside the washing / drying machine 1 but only the tap water supplied from the water supply. On the other hand, the water supplied to the ultrasonic unit 200 through the wet mist water supply hose 451 is tap water supplied from the water supply unit 410 through the diversion nozzle 450 to the wet mist water supply hose 451, and the circulation hose 440. In some cases, the circulating water is supplied to the wet mist water supply hose 451 through the diversion nozzle 450. Whether the circulating water is supplied to the ultrasonic unit 200 through the wet mist water supply hose 451, tap water, or circulating water is supplied as necessary in the washing or drying process of the washing / drying machine 1. Selected.

  FIG. 6 is a front view showing a state when the inside of the exterior of the washing / drying machine shown in FIG. 1 is viewed from the front.

  As shown in FIG. 6, the ultrasonic unit 200 and the hot air outlet 311 of the air supply duct 310 are disposed above the rotating drum 120 in the upper part of the water tank 130. Below the spray port 250 of the ultrasonic unit 200, guide vanes 116 are disposed as guide members in the frame of the packing cover 115 (FIG. 2). The guide vane 116 is located outside the opening of the rotating drum 120 and inside the inner peripheral surface of the water tank 130. The guide vane 116 may be formed as a part of the shape of the packing cover 115.

  Hot air is supplied from the hot air outlet 311 of the air supply duct 310 into the rotary drum 120 as indicated by a two-dot chain line arrow R1. As shown by the broken line M, the water in the form of mist is supplied from the spray port 250 of the ultrasonic unit 200 into the rotary drum 120. Further, from the spray port 250 of the ultrasonic unit 200, non-mist water that has not been atomized falls as indicated by an arrow W. The non-misty water travels along the guide vane 116 and falls between the outer peripheral surface of the rotating drum 120 and the inner peripheral surface of the water tank 130 and flows into the water tank 130.

  In the rotary drum 120, the air in the air supply duct 310 blows out from the front side of the washing / drying machine 1 through the hot air outlet 311. The hot air outlet 311 is disposed at the upper right of the rotating drum 120 when viewed from the front side of the washing / drying machine 1. On the other hand, the ultrasonic unit 200 is disposed at the upper left of the rotary drum 120 when viewed from the front side of the washing / drying machine 1. As described above, the hot air outlet 311 and the ultrasonic unit 200 are spaced apart from each other.

FIG. 7 is a perspective view (A) showing the overall appearance of the ultrasonic unit provided in the washing / drying machine, and a perspective view (B) showing through the inside of the ultrasonic unit shown in FIG. 7 (A). . FIGS. 8A and 8B are views of the ultrasonic unit as seen from the direction of the arrow VIII shown in FIGS. 7A and 7B, respectively.

  As shown in FIG. 7A and FIG. 8A, the ultrasonic unit 200 includes a nozzle 201 and a case 202. The nozzle 201 includes a pipe line 220, a wet mist water supply path 230, and a dry mist water supply path 240. The wet mist water supply path 230 is connected to a wet mist water supply hose 451 (FIG. 6), and the dry mist water supply path 240 is connected to a dry mist water supply hose 411 (FIG. 6). The inside of the pipe line 220, the inside of the wet mist water supply path 230, and the inside of the dry mist water supply path 240 communicate with each other. A spray port 250 is opened in the conduit 220 as a discharge port. The ultrasonic unit 200 is disposed in the washing / drying machine 1 (FIG. 6) so that the spray port 250 is inclined downward from the horizontal plane. The spray port 250 is directed into the rotary drum 120 of the washing / drying machine 1.

  As shown in FIG. 7B and FIG. 8B, inside the ultrasonic unit 200, a horn 210 as an atomizing portion and bonded to one end of the horn 210 are superposed on the horn 210. A vibrator 213 for sonic vibration is disposed. In the horn 210, an end 211 opposite to the side to which the vibrator 213 is bonded is formed in a plate shape. The horn 210 is disposed in the nozzle 201 so that the end portion 211 of the horn 210 is positioned at the spray port 250 of the nozzle 201. The end 211 of the horn 210 is composed of a short side end surface 212 and a long side end surface 216. An electrode 215 and a backing plate 214 are connected to the vibrator 213.

  When a voltage is applied to the vibrator 213 through the two electrodes 215, the vibrator 213 vibrates ultrasonically. When the vibrator 213 vibrates ultrasonically, the vibration is transmitted to the horn 210 bonded to the vibrator 213, and the end portion 211 of the horn 210 vibrates at the frequency of the ultrasonic wave that vibrates the vibrator 213.

  FIG. 9 is a diagram when the ultrasonic unit is viewed from the direction indicated by the arrow IX in FIG. 7.

  As shown in FIG. 9, the spray port 250 of the ultrasonic unit 200 has an end surface (tip surface) 212 on the short side of the end portion 211 (FIGS. 7 and 8) of the horn 210 (FIGS. 7 and 8). Has been placed. The end surface 212 extends substantially in the vertical direction, and is spaced a predetermined distance (about 1 mm in this embodiment) from the inner peripheral wall surface of the pipe line 220 in the vertical direction. A rib 222 protrudes from the inner peripheral wall surface of the pipe line 220 in the pipe line 220 in a direction perpendicular to the direction in which the end face 212 extends, that is, in a substantially horizontal direction.

  FIG. 10 is a cross-sectional view of the ultrasonic unit when viewed from the direction of line XX shown in FIG.

  As shown in FIG. 10, when the water flowing into the wet mist water supply channel 230 flows into the pipeline 220 from above the wet mist water supply channel 230, the wet mist water supply channel 230 has an inner circumference of the pipeline 220. The nozzle 201 is formed so as to flow in the tangential direction of the inner peripheral surface 221 along the surface 221. Similarly to the wet mist water supply path 230, when the water flowing into the dry mist water supply path 240 flows into the pipe 220 from the upper side of the dry mist water supply path 240, the dry mist water supply path 240 is The nozzle 201 is formed so as to flow in the tangential direction of the inner peripheral surface 221 along the inner peripheral surface 221.

  A process in which the ultrasonic unit 200 sprays water from the spraying port 250 by using ultrasonic waves will be described with reference to FIGS. 7 to 10.

  The water that has flowed into the wet mist water supply passage 230 from above flows downward from the wet mist water supply passage 230 into the pipeline 220 in the tangential direction of the inner peripheral surface 221 of the pipeline 220. The water that has flowed into the pipe line 220 flows along the inner peripheral surface 221 in the pipe line 220 in the counterclockwise direction as viewed from the spray port 250 toward the lowermost part of the pipe line 220. If the momentum of the water flowing into the pipe line 220 is strong, the water flows upward along the inner peripheral surface 221 after passing through the lowermost part of the pipe line 220, but when it reaches the position of the rib 222, the water hits the rib 222 and gets momentum. It weakens and falls downward in a clockwise direction when viewed from the spray port 250.

  On the other hand, the water that has flowed into the dry mist water supply channel 240 from above flows downward from the dry mist water supply channel 240 into the pipeline 220 in the tangential direction of the inner peripheral surface 221 of the pipeline 220. The water that has flowed into the pipeline 220 from the water supply channel 240 for dry mist, along the inner peripheral surface 221 and the rib 222 of the pipeline 220, clockwise from the direction of the spray port 250, It flows toward. The water flowing into the pipeline 220 is not circulating water but tap water supplied from the water supply, and the amount of water is controlled by controlling the water supply valve for dry mist (FIG. 3) so that the momentum does not become too strong. It has been adjusted.

  In this way, the water flowing into the pipeline 220 from the wet mist water supply channel 230 and the dry mist water supply channel 240 flows along the inner peripheral surface 221 of the pipeline 220, and thus is disposed in the pipeline 220. It is difficult to hit the side surface of the horn 210.

  In the lowermost part of the pipe line 220, the water surface flowing through the pipe line 220 is in contact with the lower end of the end portion 211 of the horn 210. When the horn 210 vibrates ultrasonically, a part of water in the pipe line 220 is sucked up by the horn 210 due to the pumping effect. The water sucked up by the horn 210 is atomized by the ultrasonic vibration of the horn 210.

  The atomized water is sprayed from the spray port 250 to the outside of the ultrasonic unit 200 as indicated by a broken line M in FIG. Since the spray port 250 is disposed so as to face the inside of the rotary drum 120 of the washing / drying machine 1, the atomized water is supplied to the inside of the rotary drum 120.

  In the lowermost part of the pipe line 220, non-mist water that has not been atomized flows out of the ultrasonic unit 200 from the spray port 250 as indicated by an arrow W in FIG. Non-misty water falls down from the spray nozzle 250 by gravity.

  As shown in FIG. 6, the water that falls down from the spray port 250 hits the guide blades 116 disposed in the frame of the inner door 112 of the washing / drying machine 1 below the spray port 250, along the guide blades 116. It falls between the outer peripheral surface of the rotating drum 120 and the inner peripheral surface of the water tank 130.

  Hereinafter, the washing process, the rinsing process, the dehydrating process and the drying process performed using the washing / drying machine 1 configured as described above will be described in the order of the processes.

  First, the user opens the outer door 111 and the inner door 112, inputs the fiber structure 2 from the insertion port 113, and then closes the inner door 112 and the outer door 111. The user puts the detergent in the detergent case 470 and, if necessary, the finishing agent in a finishing agent case (not shown). The finish may be added during the washing process or the rinsing process.

  Next, the user operates the operation panel to select washing and drying conditions. When the user operates the operation panel, the operation circuit 106 transmits a control signal to the main circuit 107, and the main circuit 107 controls each member of the washing / drying machine 1. The main circuit 107 performs a washing process, a rinsing process, a dehydrating process, and a drying process according to the washing and drying conditions selected by the user. Depending on the washing and drying conditions selected by the user, some of the steps may not be performed. Here, the case where all the processes of a washing process, a rinse process, a dehydration process, and a drying process are performed is demonstrated.

  When the user presses the start button on the operation panel, the main circuit 107 controls the outer door 111 and the inner door 112 to be locked, and controls the water supply valve 401 to be opened, so that tap water is supplied. The water is supplied from the water supply duct 420 into the water tank 130 through the water supply unit 410 and the detergent case 470. The water tank 130 is supplied with water mixed with the detergent contained in the detergent case 470. In this way, the washing process is started.

  When a water level sensor (not shown) detects that the water level in the water tank 130 has reached a predetermined value, the water supply valve 401 is closed. Subsequently, the circulation pump 460 is controlled to be driven. Further, the voltage is controlled to be applied to the electrode 215 of the ultrasonic unit 200.

  The main circuit 107 supplies the tap water to the ultrasonic unit through the diversion nozzle 450 so that the water level in the water tank 130 reaches a predetermined value and generates tap water instead of circulating water. The water supply unit 410 may be controlled so as to be supplied to 200.

  The water supplied into the water tank 130 is supplied to the diversion nozzle 450 by the circulation pump 460 through the internal drain hose 430 and the circulation hose 440. A part of the water supplied to the diversion nozzle 450 is supplied directly from the diversion nozzle 450 into the rotary drum 120. The remaining part of the water supplied to the diversion nozzle 450 is supplied from the diversion nozzle 450 to the ultrasonic unit 200 through the wet mist water supply hose 451.

  In the ultrasonic unit 200, water containing a detergent is atomized and supplied into the rotary drum 120. When the water containing the detergent is atomized by ultrasonic waves, the detergent is well dissolved in the water, and the water containing the detergent penetrates the fiber structure 2 well.

  The water supplied into the rotating drum 120 flows out into the water tank 130 through the small hole 121 and is circulated again by the circulation pump 460.

  Circulation pump 460 is driven for a predetermined time. In this way, even after the tap water is supplied to the predetermined level in the water tank 130, the water flows out from the rotary drum 120 through the small hole 121 into the water tank 130, and the internal drain hose 430 and the diversion nozzle are discharged from the water tank 130. Using the circulating water supplied again to the ultrasonic unit 200 through 450, mist-like water is supplied into the rotary drum 120. When a predetermined time elapses, the main circuit 107 controls to stop the circulation pump 460 and the ultrasonic unit 200 and close the drain valve 432.

  Next, the rotating drum 120 is rotated by the drum rotation driving motor 140 in accordance with the rotation chart for the washing process.

  In addition, regarding the rotation chart of the rotating drum 120, the rotation speed, the rotation cycle, and the reversal of the washing process, the rinsing process, the dehydration process, the drying process, or the type of the fiber structure 2 and the washing and drying course A plurality of rotation charts having different periods and the like are set in advance. The rotation chart is selected by the user or programmed to be selected automatically.

  When the drum rotation drive motor 140 rotates forward and backward, the rotary drum 120 also rotates forward and backward in the same manner. When the rotating drum 120 rotates, the baffle 122 fixed to the inner peripheral wall surface of the rotating drum 120 lifts the fiber structure 2 and drops it downward. In this way, the washing process is performed using a so-called tapping effect. Further, the circulation pump 460 may be driven in the washing process. The ultrasonic unit 200 may be driven while the circulation pump 460 is being driven, and mist water may be supplied into the rotary drum 120. When the ultrasonic unit 200 is driven in accordance with the movement of the rotating drum 120, more effective cleaning can be performed due to a decrease in the amount of detergent remaining undissolved and an improvement in the penetration of the detergent into the fiber structure 2.

  In the washing process, the water level may be detected midway, and makeup water may be supplied if the water level is lower than the set water level. Further, when replenishing water is performed, the circulation pump 460 may be driven to supply mist-like water from the ultrasonic unit 200 into the rotary drum 120. In the washing process, the mist water is supplied into the rotating drum 120 for a total of 5 minutes, for example.

  When the washing process ends, the drain valve 432 is opened, and water is discharged from the external drain hose 431 to the outside of the exterior 101. When the drainage is completed, the rotary drum 120 is subjected to an intermediate dehydration process in which the rotary drum 120 is rotated at a high speed on the rotation chart for the intermediate dehydration process. In the intermediate dehydration process, the water contained in the fiber structure 2 is discharged to the inner wall surface of the water tank 130 through the small holes 121 provided in the peripheral wall of the rotating drum 120 by centrifugal force due to the high-speed rotation of the rotating drum 120. The water flows down along the inner wall surface of the water tank 130 and is discharged from the external drain hose 431 to the outside of the exterior 101 via the drain valve 432.

  When the intermediate dehydration process is completed, the program proceeds to the rinsing process. After the drain valve 432 is closed, the water supply valve 401 is opened, and tap water is supplied to the water tank 130 through the water supply unit 410. When a water level sensor (not shown) detects that the water level in the water tank 130 has reached a predetermined value, the water supply valve 401 is closed.

  After the water supply valve 401 is closed, the main circuit 107 controls to drive the circulation pump 460 for a predetermined time. At this time, the ultrasonic unit 200 may also be driven for a predetermined time.

  When the circulation pump 460 and the ultrasonic unit 200 are driven, the water in the water tank 130 circulates through the circulation channel, and is supplied from the diversion nozzle 450 to the ultrasonic unit 200 through the wet mist water supply hose 451. In the ultrasonic unit 200, the circulating water is atomized and supplied into the rotary drum 120.

  In the rinsing process, tap water is newly supplied after being dehydrated once after the washing process, so that the detergent and dirt components contained in the circulating water are relatively small. By supplying this circulating water to the ultrasonic unit 200 and generating mist-like water, detergent and dirt components adhere to the wet mist water supply path 230, the pipe line 220, and the horn 210 of the ultrasonic unit 200 during the washing process. You can wash it off. As described above, the process of washing away the dirt component and the detergent attached to the horn 210 may be performed in each rinse process when there are a plurality of rinse processes, but the final rinse process in which the rinse water is clean is used. It is more effective to be implemented in

  In the rinsing process, the circulating water is not made to be mist, but tap water may be supplied from the water supply unit 410 to the ultrasonic unit 200 through the diversion nozzle 450 to generate mist water.

  The main circuit 107 controls the drum rotation driving motor 140 after the predetermined time has elapsed since the circulation pump 460 and the ultrasonic unit 200 are started to be driven, and the rotating drum 120 is used for the rinsing process by the drum rotation driving motor 140. It is rotated according to the rotation chart. After the intermediate dehydration process and the rinsing process are repeated a plurality of times, the process proceeds to the final rinsing process. In the final rinsing step, the water supply valve 401 is opened, and the soft finish contained in the detergent case 470 is supplied from the water supply duct 420 to the water tank 130 as water containing the soft finish.

  When the final rinsing process is completed, the drain valve 432 is opened and the rinse liquid is discharged from the external drain hose 431 to the outside of the exterior 101. When the drainage is completed, the rotary drum 120 is rotated at a high speed according to the rotation chart for the final dewatering process, and the final dewatering process is performed. In the final dewatering process, the rinsing liquid contained in the fiber structure 2 due to the centrifugal force generated by the high-speed rotation of the rotating drum 120 is passed through the small holes 121 provided in the peripheral wall of the rotating drum 120 to enter the water tank 130. It is discharged on the wall.

  When the final dehydration process is completed, the process proceeds to the drying process. In the drying process, the rotary drum 120 is rotated and the PTC heater 315 and the blower motor 313 are driven. Note that when the washing and drying processes are continuously performed, the PTC heater 315 may be driven from the final dehydration process. By doing in this way, the temperature in the rotating drum 120 rises, it dehydrates better, and it becomes possible to implement drying efficiently.

  By driving the PTC heater 315 and the blower motor 313, the air heated by the PTC heater 315 flows as shown by the two-dot chain line arrows in FIGS. 3 and 4, and from the hot air outlet 311 to the water tank 130. It blows into the rotating drum 120. After the hot air comes into contact with the fiber structure 2 in the rotating drum 120, the hot air flows out of the rotating drum 120 through the small holes 121, and passes through the exhaust port formed in the lower part of the water tank 130 to form the cooling duct. 330 is exhausted. The gas exhausted to the cooling duct 330 has high humidity due to moisture contained in the fiber structure 2 in the rotary drum 120. The air containing moisture is cooled by the cooling duct 330 and dehumidified. The moisture removed from the gas returns into the water tank 130 from below the cooling duct 330 and is discharged from the exterior 101 through the internal drain hose 430, the drain valve 432, and the external drain hose 431.

  The air dehumidified in the cooling duct 330 returns to the air supply duct 310 through the exhaust duct 320. The air supply duct 310 is heated by the PTC heater 315. The drying process is performed by repeating this cycle.

  In the drying process, the control is performed so that the water supply valve 401 is opened and the ultrasonic unit 200 is driven when a predetermined time has elapsed since the start of driving of the PTC heater 315. At this time, the main circuit 107 preferably stops driving the PTC heater 315 in order to prevent the ultrasonic unit 200 from being driven at a high temperature and the operation becoming unstable due to a change in temperature characteristics.

  When the water supply valve 401 is opened, tap water is supplied from the water supply unit 410 to the ultrasonic unit 200 through the dry mist water supply hose 411. In the ultrasonic unit 200, tap water is atomized and supplied into the rotating drum 120.

  At this time, the water supply unit 410 adjusts the amount of water by the dry mist water supply valve 413 so that a relatively small amount of water is supplied to the ultrasonic unit 200. In addition, the main circuit 107 is connected to the water supply unit 410, the dry mist water supply valve 413, and the ultrasonic wave so that the water supply to the ultrasonic unit 200 and the ultrasonic vibration of the horn 210 of the ultrasonic unit 200 are intermittently performed. The sound wave unit 200 is controlled. In this way, a small amount of mist-like water is intermittently supplied into the rotating drum 120 during the drying process. The mist-like water in the drying process is supplied into the rotating drum 120 for 10 minutes, for example.

  Humidity detection means may be provided in the water tank 130, and the driving of the ultrasonic unit 200 may be controlled so that the humidity is adjusted. For example, the ultrasonic unit 200 may be driven when the humidity in the water tank 130 detected by the humidity detector is equal to or lower than a predetermined humidity.

  The ultrasonic unit 200 does not pass water through a small hole, but makes the water mist by ultrasonic vibration of the horn 210. Therefore, even if the amount of supplied water is small and the water pressure is low, mist water is generated. And can be supplied into the rotating drum 120. That is, even if the amount of water is increased or decreased to adjust the humidity in the water tank 130, mist-like water can be generated stably.

  Since the mist-like water generated by the ultrasonic vibration in the horn 210 of the ultrasonic unit 200 is not highly straight, only a specific part is not wetted in the rotary drum 120.

  Further, the non-mist water that has not been atomized in the ultrasonic unit 200 falls down from the spray port 250 of the ultrasonic unit 200 due to gravity. Non-fog-like water falling downward from the spray port 250 hits the guide vane 116 and is guided to the guide vane 116, and does not enter the rotary drum 120, but the outer peripheral surface of the rotary drum 120 and the inner periphery of the water tank 130. Fall between the faces. Therefore, non-misty water does not wet the fiber structure 2 in the rotating drum 120.

  Thus, in the drying process, a small amount of mist-like water is intermittently supplied into the rotary drum 120, whereby the humidity in the rotary drum 120 is adjusted moderately, and the fiber structure 2 is wrinkled by overdrying. Can be prevented.

  After driving the ultrasonic unit 200 for a predetermined time, the main circuit 107 controls to stop driving the ultrasonic unit 200 and drive the PTC heater 315. When the predetermined time has passed, the main circuit 107 stops driving the PTC heater 315, performs only the air blowing by the blower fan 312 for a predetermined time, cools the fiber structure 2, and after the drying process is finished, Make it available.

  In the drying process, mist water may be supplied into the rotating drum 120 a plurality of times.

  When the air blow by the blower fan 312 is performed for a predetermined time, the main circuit 107 stops driving the blower motor 313. In this way, the drying process is completed. When the drying process is completed, all the washing and drying processes are completed.

  As described above, the washing / drying machine 1 includes the rotating drum 120 for housing the fiber structure 2 and the ultrasonic unit 200 for supplying water into the rotating drum 120 in the form of mist by ultrasonic waves. .

  When making water mist by ultrasonic waves, adjusting the amount of mist water, the particle size of mist water, and the timing to generate mist water by adjusting the frequency of the ultrasonic waves Can do. Since water pressure above a certain level is not required to make the water mist, the water can be made mist regardless of the environment in which the washing / drying machine 1 is installed. Since there is no need to increase the water pressure, mist-like water can be generated even using circulating water that is difficult to increase because the water is circulated by a small pump or the like.

  In addition, since it is not necessary to pass water through small holes in order to make the water mist, the holes are blocked even if the washing water contains solid matter or solid matter such as fibers, dust, or detergent. There is no worry that mist-like water cannot be generated, and mist-like water can be generated stably. Therefore, for example, in the washing / drying machine 1 that circulates the water in the rotary drum 120, even when the circulating water is used, mist-like water can be stably generated. Further, even when water containing dirt such as dirt remaining in the bath or hair such as hair is used, mist-like water can be stably generated.

  Further, since the water atomized by the ultrasonic waves has low linearity, only a specific portion of the fiber structure 2 is wetted when supplied into the rotating drum 120 in which the fiber structure 2 is accommodated. The entire fiber structure 2 can be wetted.

  By doing in this way, the laundry dryer 1 which can generate the stable mist-like water can be provided, without being influenced by the environment where the laundry dryer 1 is installed.

  In the washing / drying machine 1, the ultrasonic unit 200 supplies water into the rotary drum 120 in the form of a mist in a washing process in which at least the fiber structure 2 is washed with water and a detergent.

  By doing in this way, the fiber structure 2 whole can be made to become familiar with water and a detergent, and a cleaning power can be improved. Moreover, the detergent can be well dissolved in water by an emulsifying action by making the water containing the detergent mist by ultrasonic waves. Moreover, since the water particles are small in the mist-like water, the permeability to the fiber structure 2 is good. By supplying water in which the detergent is well dissolved into the rotating drum 120, the detergency of water used for washing is increased. Can be increased. In addition, since there is little undissolved residue of the detergent, good rinsing performance can be stably secured, dirt due to mold and bacteria is hardly generated in the rotating drum 120, and the inside of the rotating drum 120 can be secured cleanly.

  In the washing / drying machine 1, the ultrasonic unit 200 supplies water into the rotating drum 120 in the form of water mist in the rinsing process of the fiber structure 2 washed in the washing process.

  In the rinsing process, the ultrasonic unit 200 mists water that does not contain detergent or contains little detergent. By doing so, the ultrasonic unit 200 itself can be cleaned.

  Further, by supplying mist-like water into the rotating drum 120 in the rinsing process, the water particles are reduced to improve the permeability, and the detergent adhering to the fiber structure 2 and the rotating drum 120 is well removed. be able to.

  In addition, as described above, the washing / drying machine 1 includes the rotating drum 120 for housing the fiber structure 2, the circulation channel for circulating the water discharged from the rotating drum 120 and returning the water to the rotating drum 120, And an ultrasonic unit 200 for supplying water flowing through the circulation channel into the rotating drum 120 in the form of a mist.

  A circulating water path for returning the water discharged from the rotating drum 120 containing the fiber structure 2 to the rotating drum 120 is provided, and the ultrasonic unit 200 mists the water flowing through the circulating water path to thereby form the inside of the rotating drum 120. Even after the water has been stored up to the set water level, the water can be circulated to supply the mist water into the rotary drum 120. By supplying the water flowing through the circulation channel in the form of a mist into the rotating drum 120, the mist-like water can be supplied into the rotating drum 120 for an arbitrary time without increasing the water more than the set water level. it can.

  In this way, since the mist-like water can be supplied into the rotating drum 120 regardless of the set water level and the water supply time, the fiber structure 2 floating in the water when the water is stored up to the set water level. Can also be wetted with mist-like water.

  By doing in this way, the washing-drying machine 1 which can fully absorb the water to the fiber structure 2 and can improve a cleaning power can be provided.

  In the washing / drying machine 1, the ultrasonic unit 200 has a spray port 250 that discharges mist-like water, and the spray port 250 is opened toward the inside of the rotary drum 120.

  Since the spray port 250 is opened directly into the rotary drum 120, the mist-like water generated by the ultrasonic unit 200 is combined to become huge, or is wasted due to adhering to the wall surface of the water channel. And the mist having an appropriate particle size can be supplied to the fiber structure 2 without leaving any mist.

  In the washing / drying machine 1, the ultrasonic unit 200 supplies water into the rotary drum 120 in the form of a mist in a washing process in which at least the fiber structure 2 is washed with water and a detergent.

  By doing in this way, the fiber structure 2 whole can be made to become familiar with water and a detergent, and a cleaning power can be improved. Moreover, the detergent can be well dissolved in water by an emulsifying action by making the water containing the detergent mist by ultrasonic waves. Moreover, since the water particles are small in the mist-like water, the permeability to the fiber structure 2 is good. By supplying water in which the detergent is well dissolved into the rotating drum 120, the detergency of water used for washing is increased. Can be increased.

  In the washing / drying machine 1, the ultrasonic unit 200 supplies water into the rotating drum 120 in the form of water mist in the rinsing process of the fiber structure 2 washed in the washing process.

  In the rinsing process, the ultrasonic unit 200 mists water that does not contain detergent or contains little detergent. By doing so, the ultrasonic unit 200 itself can be cleaned.

  Further, by supplying mist-like water into the rotating drum 120 in the rinsing process, the water particles are reduced to improve the permeability, and the detergent adhering to the fiber structure 2 and the rotating drum 120 is well removed. be able to.

  Further, as described above, the ultrasonic unit 200 is wet for supplying water into the pipeline 220 along the tangential direction of the pipeline 220 for circulating water and the inner peripheral surface 221 of the pipeline 220. The water supply path 230 for mist, the water supply path 240 for dry mist, and the horn 210 which are arrange | positioned inside the pipe line 220 and make water into a mist form with an ultrasonic wave are provided.

  When water is supplied from the wet mist water supply path 230 and the dry mist water supply path 240 into the pipe line 220 along the tangential direction of the inner peripheral surface 221 of the pipe line 220, the water is arranged in the pipe line 220. It becomes difficult to directly hit the horn 210. Since water does not directly hit the horn 210, a water film that covers the surface of the horn 210 is hardly formed.

  By doing in this way, the ultrasonic unit 200 which can generate the stable mist-like water can be provided.

  Further, in the ultrasonic unit 200, the horn 210 has an end 211 formed in a plate shape, the end 211 has an end surface 216 on the long side and an end surface 212 on the short side, The horn 210 is arranged in the pipe line 220 so that the end surface 212 on the short side of the end part 211 extends along the direction in which water is stored in the pipe line 220.

  Mist-like water is generated at the end 211 of the horn 210 formed in a plate shape. The end portion 211 of the horn 210 is disposed so that the end surface 212 on the short side extends along the direction in which water is stored in the pipe line 220, so that the horn 210 can pump a predetermined amount of water by a pumping effect. Suck up and atomize.

  If the horn 210 is arranged so that the end surface 212 on the short side of the end portion 211 of the horn 210 extends along the horizontal plane, the amount of mist generated depending on the amount of water stored in the conduit 220. Will change drastically.

  Accordingly, the horn 210 has an end portion 211 formed in a plate shape, and the horn 210 is a tube so that the end surface 212 on the short side of the end portion 211 extends along the direction in which water is stored in the conduit 220. By being arranged in the passage 220, even if the amount of water in the conduit 220 changes, mist-like water can be stably generated.

  Further, the ultrasonic unit 200 includes a rib 222 that protrudes from the inner peripheral surface 221 of the conduit 220 toward the inside of the conduit 220.

  By doing so, the water supplied along the tangential direction of the inner peripheral surface 221 of the conduit 220 and flowing along the inner peripheral surface 221 of the conduit 220 collides with the rib 222. It is possible to reduce the momentum, prevent the water level from becoming too high, and prevent the water level from becoming too high, causing the oscillation of the ultrasonic waves to become abnormal and preventing the water from being atomized. Further, when there is a momentum in the water flow, it is possible to prevent water from directly hitting the horn 210 away from the inner peripheral surface 221 of the pipe line 220.

  The washing / drying machine 1 also includes a rotating drum 120 that houses the fiber structure 2 and any one of the ultrasonic units 200 described above, and the ultrasonic unit 200 supplies mist-like water into the rotating drum 120. To do.

  By doing in this way, the laundry dryer 1 which can generate the stable mist-like water can be provided, without being influenced by the environment where the laundry dryer 1 is installed.

  In addition, as described above, the washing / drying machine 1 includes the rotary drum 120 for housing the fiber structure 2, the water supply channel for supplying water for supplying water into the rotary drum 120, and the water supply channel And an ultrasonic unit 200 for supplying water into the rotary drum 120 by atomizing the water therein.

  When water is atomized by ultrasound, the amount of atomized water, the particle size of atomized water, and the timing for generating atomized water can be adjusted by adjusting the frequency of water supply and ultrasound. Can be adjusted. Since water pressure above a certain level is not required to make the water mist, the water can be made mist regardless of the environment in which the washing / drying machine 1 is installed.

  Further, since the water atomized by the ultrasonic waves has low linearity, only a specific portion of the fiber structure 2 is wetted when supplied into the rotating drum 120 in which the fiber structure 2 is accommodated. The humidity in the rotating drum 120 can be increased without any problems.

  In addition, by making the running water in the water supply flow path mist, water that does not contain bacteria or the like can be made mist and supplied into the rotating drum 120.

  By doing in this way, it is possible to generate the stable mist-like water without being influenced by the environment in which the washing / drying machine 1 is installed, and to give appropriate moisture to the fiber structure 2. A possible laundry dryer 1 can be provided.

  In the washing / drying machine 1, the ultrasonic unit 200 has a spray port 250 that discharges mist-like water and non-mist-like water, and the non-mist-like water flows from the spray port 250 to the rotary drum 120. A guide vane 116 for guiding non-mist water is provided so as to be discharged to the outside.

  By doing so, the non-mist-like water is guided to the guide vane 116 and does not flow into the rotating drum 120, but only the mist-like water is supplied into the rotating drum 120. The humidity in the rotating drum 120 can be increased without getting the structure 2 wet.

  The washing / drying machine 1 includes a hot air outlet 311 for blowing out hot air into the rotary drum 120, and the ultrasonic unit 200 is disposed at a position away from the hot air outlet 311.

  The ultrasonic unit 200 that mists water with ultrasonic waves may change the temperature characteristics of the horn 210 at a high temperature, and may not perform a stable operation.

  Therefore, the ultrasonic unit 200 can be made difficult to increase the temperature of the ultrasonic unit 200 by being arranged at a position away from the hot air outlet 311 that blows out the hot air.

  Further, as described above, the washing / drying machine 1 rotates around the rotation axis extending in the horizontal direction or the rotation axis inclined with respect to the horizontal direction in the water tank 130 and the fiber inside. A rotating drum 120 that performs washing, rinsing, and dewatering of the structure 2 and an ultrasonic unit 200 that supplies water into the rotating drum 120 in a mist form are provided.

  Even if the fiber structures 2 overlap each other by rotating the rotating drum 120 around a rotation axis extending in the horizontal direction or a rotation axis inclined with respect to the horizontal direction in the water tank 130, the ultrasonic unit The mist-like water supplied from 200 to the rotating drum 120 is likely to wet the entire fiber structure 2. Further, when the detergent is supplied into the rotating drum 120, the detergent and water penetrate the fiber structure 2 quickly and uniformly.

  By doing in this way, the washing / drying machine 1 which can raise a cleaning power can be provided.

  The embodiment disclosed above should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above embodiments but by the scope of claims, and includes all modifications and variations within the meaning and scope equivalent to the scope of claims.

1 is a perspective view schematically showing an overall appearance of a washing / drying machine as one embodiment of the present invention. FIG. It is sectional drawing which shows schematically the cross section which looked at the washing-drying machine shown in FIG. 1 from the direction of II-II line. It is a figure which shows a state when the inside of the exterior of the washing-drying machine shown in FIG. 1 is seen from an upper direction. It is a figure which shows a state when the inside of the exterior of the washing / drying machine shown in FIG. 1 is seen from the right direction. It is a figure which shows a state when the inside of the exterior of the washing / drying machine shown in FIG. 1 is seen from the left direction. It is a front view which shows a state when the inside of the exterior of the washing / drying machine shown in FIG. 1 is seen from the front. It is the perspective view (A) which shows the external appearance of the whole ultrasonic unit with which a washing-drying machine is provided, and the perspective view (B) which sees through the inside of the ultrasonic unit shown to (A) of FIG. It is the figure which looked at the ultrasonic unit from the direction of arrow VIII shown in FIG. It is a figure when an ultrasonic unit is seen from the direction shown by arrow IX in FIG. It is sectional drawing when an ultrasonic unit is seen from the direction of the XX line shown in FIG.

Explanation of symbols

  1: Washing and drying machine, 120: rotating drum, 130: water tank, 2: fiber structure, 200: ultrasonic unit, 430: internal drain hose, 440: circulation hose.

Claims (3)

A storage tank capable of rotating around a predetermined axis and storing an object;
A circulation channel for returning water discharged from the storage tank to the storage tank;
A mist water supply device having a spray port for opening the water into the storage tank and discharging the water in the form of mist , supplying the water flowing through the circulation channel into the storage tank.
The spray water supply device
Before the storage tank rotates out of the washing process of washing the object with at least the detergent and water, water containing the detergent flowing through the circulation channel is supplied into the storage tank as a mist,
Further, in the rinsing process of the object washed in the washing process, the water flowing through the circulation channel is made into a mist and supplied into the containing tank.
Washing machine. In the final rinsing process when there are a plurality of rinsing processes, the mist water supply device supplies the water flowing through the circulation channel in the form of mist to the inside of the storage tank.
The washing machine according to claim 1. In the washing step, when water is supplied to the storage tank when the water level in the storage tank becomes lower than a predetermined set water level, the mist water supply device supplies the mist water to the storage tank. Supply in,
The washing machine according to claim 1.

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