JP2011092511A - Washing and drying machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a washing and drying machine equipped with a mist generator which generates the mist which presents bactericidal action using high voltage which easily discharges surplus water in the water supply mechanism while maintaining a fully-high security of the water supply mechanism which supplies water to the mist generator. <P>SOLUTION: The machine is equipped with a water supply tank 76 in the upper part inside of a case. The water supply tank 76 has a lid member 77 having a water supply port 78 and is connected with a water supply pipe 67 through an on-off valve 81 at a connecting port 80 of a bottom. An exhaust port 82 which discharges the surplus water beyond a fixed water level is attached horizontally to the side-wall part of the water supply tank 76. The diameter b of the exhaust port 82 is made larger than the diameter a of the water supply port 78. The exhaust port 82 is connected with a drainage route 83 and an air open hole 84 is formed in the upper end of the drainage route 83. The other end of the drainage route 83 is connected with the downstream-side part of an overflow trap. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a washing and drying machine provided with a mist generator that applies a high voltage to an electrode having water absorption to atomize water, generate mist exhibiting a sterilizing action, and supply the mist to a water tank.

  In the washing / drying machine, the drying process for drying the clothes is performed after the washing process for cleaning the clothes in the washing tub. However, germs attached to clothing may not be able to be removed in the washing process, resulting in poor hygiene, generation of odor, mold, discoloration of clothing, and the like. In particular, in recent years, in order to save water, bath water containing a large amount of various germs and the like may be used as washing water during the washing process, and in this case, the residual amount of germs remaining on the clothing tends to increase. is there. Therefore, conventionally, a washing machine including a mist generating device has been considered (for example, see Patent Document 1).

  In this device, the mist generating device generates mist having at least one of a sterilizing action, a deodorizing action, and a soil decomposing action, and sprays the generated mist onto the laundry in the washing tub. . However, since the mist generator described in Patent Document 1 uses an aqueous solution of hypochlorous acid or a chemical containing a component exhibiting an oxidizing action, metal ions, etc., high corrosion resistance of components is required. In addition, there are problems such as requiring attention to the handling of the user at the time of replenishing the medicine.

  Therefore, as a mist generator for removing germs, malodorous components, harmful substances, etc., Patent Document 2 includes a discharge electrode, a counter electrode facing the discharge electrode, and a Peltier element that generates water in the discharge electrode. Is considered. In this apparatus, by applying a high voltage between the discharge electrode and the counter electrode, a hydroxy radical having a strong oxidizing action is generated. Therefore, if this mist generator is installed in the middle of the circulation air passage of the washing / drying machine, hydroxy radicals can be supplied into the washing tub together with hot air for drying, and the germs remaining in the clothing after the washing process. It will be possible to remove such as.

JP 2005-198860 A JP 2006-26117 A

  By the way, when a mist generator for atomizing water using the high voltage as described above is incorporated in a washing / drying machine, a water supply path from the water supply valve to the mist generator is provided for supplying water to the mist generator. However, since water has electrical conductivity, when the water supply path is filled with water, when a high voltage is applied to the discharge electrode, a conduction state occurs through the water, and the entire water supply path has a high potential. And become. For this reason, it is necessary to ensure sufficient safety for the user.

  In view of this, the present inventors provide a water supply tank for storing water corresponding to, for example, a single water supply amount to the mist generator in the middle of the water supply path from the water supply valve to the mist generator. A configuration for supplying water to the generator was considered. According to this, normally, a portion from the water supply tank to the mist generator in the water supply path is filled with air, which is an insulating gas, so that the conduction state can be interrupted and the safety is improved. be able to.

  However, in such a configuration using a water supply tank, for example, when a larger amount of water than expected is supplied into the water supply tank at a time due to a failure of the water supply valve, the water overflows from the water supply tank and is washed. Occurrence of problems such as spilling in the outer box of the dryer or on the floor where the laundry dryer is installed is expected. Therefore, even when water overflows from the water supply tank, a configuration that can quickly drain excess water from the drainage path to the outside is desired.

  The present invention has been made in view of the above circumstances, and its purpose is to provide a water supply mechanism for supplying water to a mist generator, including a mist generator that generates a mist that exhibits a sterilizing action using a high voltage. An object of the present invention is to provide a washing / drying machine capable of easily discharging excess water in a water supply mechanism outside the apparatus while being sufficiently safe.

  The washing and drying machine of the present invention includes a mist generator that applies a high voltage to an electrode having water absorption, generates a mist exhibiting a sterilizing action, and supplies the mist to a water tank, and a water supply mechanism that supplies water to the mist generator The water supply mechanism is provided in a water supply tank for storing a certain amount of water, a water supply path for supplying water in the water supply tank to the mist generator, and the water supply tank. The drainage passage is configured to include a drainage port for discharging excess water exceeding the predetermined amount, and a drainage channel connected to the drainage port for discharging the excess water to the outside of the machine. It is characterized in that an air opening hole for opening the drainage path to the atmosphere is provided at a height higher than the height of the drainage port.

  In the above configuration, a required amount of water can be supplied to the mist generator from a water supply tank that stores a certain amount of water by a single water supply operation of the water supply mechanism. In this case, in normal times other than during water supply, the portion of the water supply path from the water supply tank to the mist generator is filled with air, which is an insulating gas, so that the high voltage conduction state of the water supply path can be interrupted. , Can increase safety.

  And when surplus water exceeding a certain amount is supplied into the water supply tank, the surplus water is discharged from the drainage port through the drainage route. Since the air release hole is provided at a higher position, air can be easily introduced into and discharged from the drainage path through the air release hole. As a result, air and water in the drainage channel can easily escape, and surplus water can flow through the drainage channel quickly and smoothly without being interrupted.

  According to the washing / drying machine of the present invention, a water supply mechanism including a water supply tank, a drain outlet, a drainage path, and the like is provided with a mist generator that generates a mist exhibiting a sterilizing action using a high voltage. At the same time, since the air discharge hole is provided in the drainage path, the water supply mechanism for supplying water to the mist generator is sufficiently safe, but the excess water in the water supply mechanism can be easily discharged out of the machine. It has an excellent effect of being able to.

1 shows an embodiment of the present invention, and is a longitudinal rear view schematically showing a configuration of a mist generator The perspective view which shows the state in which the mist generator is attached to the air supply duct An exploded perspective view showing the internal configuration of the mist generator Longitudinal side view schematically showing the configuration of the mist generator Perspective view showing the appearance of the washing and drying machine Longitudinal side view schematically showing the internal configuration of the washing and drying machine Rear view schematically showing the back side of the aquarium Diagram showing the structure of the water tank The figure which shows the overflow route part schematically FIG. 8 equivalent view showing another embodiment of the present invention.

  Hereinafter, an embodiment in which the present invention is applied to a drum-type washing and drying machine will be described with reference to FIGS. First, FIG. 5 is a perspective view showing an overall appearance of the washing / drying machine 1 according to the present embodiment. As shown in FIG. 5, the casing 2 constituting the outer shell of the washing / drying machine 1 has a substantially rectangular box shape whose front surface is smoothly inclined. A handle 3 is provided for use during movement. Further, a tap water supply port 4 and a bath water supply port 5 are provided on the upper surface of the housing 2.

  A substantially circular door 6 is provided at the center of the front surface of the housing 2, and an operation button 7 for opening the door 6 is provided. In addition, an operation panel 8 and a detergent input unit 9 are provided at the upper front of the housing 2. The operation panel 8 is connected to a control device 10 (see FIG. 6) provided on the back side of the housing 2. The operation panel 8 is provided with various switches for selecting, for example, various driving courses and starting driving. One of these switches is a sterilization mode selection switch 8a for the user to select a sterilization mode in the drying operation.

  The control device 10 includes a ROM, a RAM, and the like centered on a microcomputer, and controls the overall operation of the washer / dryer 1 based on various input signals and pre-stored control programs. It is like that. At this time, as will be described later, when the sterilization mode selection switch 8a is turned on by the user, the control device 10 controls the mist generator and the water supply mechanism to execute the drying operation in the sterilization mode. It has become. At the lower part of the housing 2, there is provided a filter housing portion 11 in which a lint filter (not shown) for capturing foreign matter contained in the drainage water or circulating water is detachably disposed.

  Next, FIG. 6 is a longitudinal side view schematically showing the internal configuration of the washing / drying machine 1. As shown in FIG. 6, a water tank 12 is disposed inside the housing 2. Is provided with a drum 13. Both the water tank 12 and the drum 13 have a bottomed cylindrical shape with one end closed, and have openings 14 and 15 at the front end face (left side in FIG. 6).

  The opening 15 of the drum 13 is surrounded by the opening 14 of the water tank 12, and the opening 14 of the water tank 12 is connected to the opening 16 formed in the front part of the housing 2 by the bellows 17. . The above-described door 6 is provided in the opening 16 so as to be openable and closable. With this, the door 6 opens and closes a loading / unloading opening for laundry (clothing, etc.) including the openings 14, 15, and 16. It is like that.

  Further, for example, a liquid-sealed rotary balancer 18 is provided around the opening 15 of the drum 13. Furthermore, a plurality of holes 19 are formed in almost the entire region of the peripheral side portion (body portion) of the drum 13 (only a part is shown). These holes 19 function as water holes during the washing process, during the rinsing process, and during the dewatering process, and function as ventilation holes during the drying process. A plurality of baffles 20 project from the inner surface of the peripheral side portion of the drum 13, and a plurality of hot air inlets 21 are arranged on the rear end surface portion of the drum 13 by an annular arrangement concentric with the central axis. Is formed.

  The water tank 12 is provided with a hot air outlet 22 at an upper portion (a portion above the opening portion 14) of the front end surface portion. In addition, a hot air inlet 23 is provided at the upper part of the rear end surface portion of the water tank 12 so as to face the rotation locus of the hot air inlet 21. A water injection case 25 is connected to the inside of the housing 2 via a water supply hose 24 located above the water tank 12. A tap water inlet 4 and a bath water inlet 5 are connected to the water injection case 25 through a water supply valve 26. The water supply valve 26 is controlled by the control device 10.

  Thus, tap water from the tap water supply port 4 or bath water from the bath water supply port 5 is supplied to the inside of the water tank 12 through the water supply valve 26, the water injection case 25, and the water supply hose 24. It is like that. Detergents (detergents, softeners, bleaches, etc.) are introduced into the water injection case 25 through the detergent introduction part 9, and these detergents together with tap water or bath water It is supplied into the water tank 12.

  Although not shown in detail, the water supply valve 26 has two inlet ports to which the tap water supply port 4 and the bath water supply port 5 are connected, and two outlet ports. Among them, the first outlet port is connected to the water injection case 25, and the second outlet port is connected to a water supply tank 76 of a water supply mechanism 75 described later. At this time, the water supply valve 26 is in a state where tap water is supplied to the water injection case 25, a state where bath water is supplied to the water injection case 25, a state where tap water is supplied to the water supply tank 76, and a state where both outlet ports are closed. It is configured to be switchable to four positions.

  On the other hand, a drain outlet 27 is formed at the rear end of the bottom of the water tank 12, and a drain hose 28 is connected to the drain outlet 27. A drain valve 29 is provided in the middle of the drain hose 28. As schematically shown in FIG. 9, a portion of the drain hose 28 downstream of the drain valve 29 is led out of the housing 2. The tip is connected to the drain hole 50 a of the waterproof pan 50. Thus, the water in the water tank 12 can be discharged out of the machine.

  A washing machine motor 30 is attached to the back surface of the water tank 12. A rotating shaft 31 of the washing machine motor 30 protrudes into the water tank 12, and a center portion of the rear end surface portion of the drum 13 is connected to the tip of the rotating shaft 31. Thereby, the drum 13 is coaxially supported by the water tank 12 so that rotation is possible. That is, the drum 13 is directly rotated by the washing machine motor 30, and a direct drive system using the washing machine motor 30 is adopted. In this case, the washing machine motor 30 is composed of an outer rotor type brushless DC motor.

  The water tank 12 is elastically supported by the housing 2 by a plurality of suspensions 32 (only one is shown), and the support form is a horizontal axis in which the axial direction of the water tank 12 is the front-rear direction, and is also lifted forward It is an inclined shape. Therefore, the drum 13 supported in the water tank 12 as described above has the same configuration.

  Furthermore, in this embodiment, as shown in FIG. 7 and FIG. 9, the water overflowed when the water level in the water tank 12 exceeds a predetermined water level is discharged from the overflow port 52 to the rear surface of the water tank 12. An overflow channel for draining water is provided. The overflow path includes an overflow trap 51 attached to the back surface of the water tank 12 and an overflow hose 53. The overflow trap 51 has a slightly vertically long rectangular case shape, and the upper portion of the overflow trap 51 is provided on the rear surface of the water tank 12 (the position at the upper left of the mounting position of the motor 30 (as viewed from the rear in FIG. 7)). It communicates with the mouth 52. On the other hand, a base end portion of the overflow hose 53 is connected to the lower portion of the overflow trap 51, and the distal end of the overflow hose 53 is connected to a portion of the drain hose 28 downstream of the drain valve 29.

  In the overflow trap 51, a first partition plate 54 and a second partition plate 55 are provided to divide the inside of the overflow trap 51 into approximately three equal parts in the left-right direction. The lower end side of the first partition plate 54 and the upper end side of the second partition plate 55 are opened, thereby forming an overflow passage 56 that meanders from the overflow port 52 to the overflow hose 53. With this configuration, water overflowing from the water tank 12 through the overflow port 52 is stored in a space up to the height of the second partition plate 55 in the overflow passage 56, and the water level in the overflow trap 51 is When the height is exceeded, the water in the overflow trap 51 is discharged to the outside through the overflow hose 53.

  As shown in FIG. 6, a base plate 33 is mounted on the bottom surface of the casing 2 below the water tank 12, and a ventilation duct 34 is provided on the base plate 33. The ventilation duct 34 has an air inlet 35 at the upper part of the front end, and the hot air outlet 22 of the water tank 12 is connected to the air inlet 35 via a connection hose 36 and a return air duct 37. Yes. The return air duct 37 is piped so as to bypass the side of the opening 14 of the water tank 12.

  A casing 39 of a circulation fan 38 made of, for example, a centrifugal fan is connected to the rear end portion of the ventilation duct 34. The outlet portion 40 of the casing 39 is connected to the hot air inlet 23 of the water tank 12 through a connection hose 41 and an air supply duct 42. As shown in FIG. 7, the air supply duct 42 is arranged in a form of drawing an arc around the right side of the washing machine motor 30 when viewed from the back side of the water tank 12 (washing and drying machine 1). Here, the return air duct 37, the connection hose 36, the ventilation duct 34, the casing 39 of the circulation fan 38, the connection hose 41, and the air supply duct 42 constitute a circulation air path 43 connected to the water tank 12. .

  The circulation fan 38 has a centrifugal impeller 44 inside the casing 39 and a motor 45 that rotates the centrifugal impeller 44 outside the casing 39. The circulation blower 38 functions as a blower that circulates the air in the water tank 12 (in the drum 13) through the circulation air passage 43.

  An evaporator 46 is disposed in the front portion and a condenser 47 is disposed in the rear portion of the circulation air passage 43 inside the ventilation duct 34. Although neither the evaporator 46 nor the condenser 47 is shown in detail in detail, the evaporator 46 and the condenser 47 are of a finned tube type in which a large number of heat transfer fins are arranged at a fine pitch, and are excellent in heat exchange. A wind flowing through the ventilation duct 34 (see arrows shown by solid lines in FIG. 6) passes between the fins.

  The evaporator 46 and the condenser 47 constitute a heat pump (refrigeration cycle) 49 together with a compressor 48 and a flow rate control valve (for example, an electronic control valve) not shown. The heat pump 49 is configured by connecting a compressor 48, a condenser 47, a flow rate control valve, and an evaporator 46 in this order in a closed loop by a refrigerant circulation pipe, and circulates the refrigerant when the compressor 48 is operated. It is like that. Then, the air flowing in the circulation air passage 43 is cooled and dehumidified by the evaporator 46 and heated by the condenser 47 to warm air.

  Now, in this embodiment, as shown in FIGS. 6 and 7, a mist generator for generating a mist exhibiting a sterilizing action and supplying it to the water tank 12 in the middle of the circulation air passage 43. 60 is provided. As shown in FIG. 7, the mist generator 60 is located downstream of the hot air inlet 23 and beyond the connection hose 41 in the air supply duct 42 constituting the middle portion of the circulation air passage 43. It is provided in the part immediately after.

  Here, the configuration of the mist generator 60 will be described in detail with reference to FIGS. As shown in FIG. 1 and the like, the mist generator 60 includes a plurality of discharge electrodes 62 in a case 61 made of an insulating material that is attached to the back wall portion of the circulation air passage 43 (air supply duct 42). A conductive sheet 63, a water retaining material 64 and the like are provided, and a high voltage power supply device 65 (see FIG. 3) is attached to the back side of the case 61.

  The case 61 is formed in a vertical rectangular box shape that is thin in the front-rear direction from, for example, a synthetic resin such as polypropylene, and a partition wall 66 that divides the internal space in the front-rear direction except for the lower portion is provided inside the case 61. It has been. As shown in FIGS. 3 and 4, an opening 66 a is formed in the partition wall 66. A water supply port 61a is provided in the right end portion (the left end portion in FIG. 4) on the rear side of the upper wall portion of the case 61, and a water supply pipe constituting a water supply path of a water supply mechanism to be described later is provided in the water supply port 61a. 67 is connected.

  Further, a drain port 61b is provided at the right end portion (left end portion in FIG. 4) of the front side of the bottom wall portion of the case 61, and a drain pipe 68 (see FIG. 7) is connected to the drain port 16b. Has been. As shown in FIG. 7, the distal end portion of the drain pipe 68 is connected to a portion of the drain hose 28 downstream of the drain valve 29 together with the overflow hose 53.

  As shown in FIGS. 1 and 4, a rising wall 61c that rises upward in the case 61 is provided on the bottom wall portion of the case 61 so as to surround the periphery of the drain port 16b. As a result, a water reservoir 69 is provided at the bottom of the case 61, located outside the drainage port 16b delimited by the rising wall 61c, and stores water supplied into the case 61 through the water supply port 61a. Is provided. When the water level stored in the water storage part 69 exceeds the upper end of the rising wall 61c, it overflows to the drain outlet 16b side and drains. Therefore, the water storage part 69 has a predetermined amount. (For example, 10 cc) of water is collected.

  As shown in FIG. 1, the discharge electrode 62 is formed in a rod shape from a porous material (for example, a felt material made of fibrous polyester) having water absorption, water retention, and suction properties, and its tip. It has a pin shape with a sharp point. The plurality of discharge electrodes 62 are held in a state where the base end side penetrates a plate-like pin collar 70 made of an insulating material (for example, a resin such as polypropylene). 3 and 4A, the pin collar 70 is fixed so as to block the opening 66a portion of the partition wall 66 with the discharge electrode 62 extending horizontally in the front-rear direction. As a result, the distal end portion of each discharge electrode 62 passes through the front wall portion of the case 61 and is disposed so as to protrude into the air supply duct 42.

  The conductive sheet 63 is formed by mixing a porous material (for example, urethane sponge) with a conductive substance (for example, graphite) and molding it into a relatively hard thin plate having water retention and conductivity. As shown also, it has a rectangular plate shape with a convex portion 63a at the lower end. As shown in FIG. 1, the conductive sheet 63 has a plate surface (front surface) in contact with the rear end portion of each discharge electrode 62 in a state where the convex portion 63 a at the lower end is immersed in the water in the water storage portion 69 ( Are electrically connected).

  The water-retaining material 64 is also formed in a thin plate shape from a porous material (for example, urethane sponge) having water retention properties, and as shown in FIG. 3, it is configured in a substantially rectangular plate shape having a rectangular opening 64a in the upper portion. Has been. The water retaining material 64 has a lower end immersed in water in the water storage unit 69, and the discharge electrode 62 is disposed in the rectangular opening 64a. It arrange | positions so that it may be pinched | interposed between the partition walls 66 (pin collar 70). At this time, as shown in FIG. 4, two ribs 61 d for positioning and holding the conductive sheet 63 and the water retaining material 64 are provided at the bottom of the case 61.

  Thus, the water supplied into the water storage part 69 of the case 61 is sucked up and sucked up by the water retaining material 64 and the conductive sheet 63 and supplied to each discharge electrode 62. As shown in FIGS. 1 to 3, an eave-like duct cover 71 is provided at the front portion of each discharge electrode 62 and is inclined downward toward the front, as shown in FIGS. 1 to 3. . 1, a part of the air (warm air) flowing through the circulation air passage 43 (air supply duct 42) is guided to the distal end side of each discharge electrode 62 by the duct cover 71. Then, after passing through the discharge electrode 62 portion, it joins the circulation air passage 43.

  As shown in FIGS. 1 and 3, the conductive sheet 63 is electrically connected to a discharge pin 72, and the discharge pin 72 passes through the back wall portion of the case 61 to output the high-voltage power supply device 65. Connected to the terminal (negative side). As is well known, the high-voltage power supply device 65 is configured by molding a rectifier circuit, a booster circuit, or the like that converts a high-frequency power supply (AC power supply) into direct current with an insulating material, and generates a negative high voltage (for example, −6 kV) Generated and output to the output terminal. As shown in FIGS. 2 and 3, the high-voltage power supply device 65 is attached to the back side of the case 61 while being housed in a power supply case 73 for waterproofing and insulation.

  Thereby, a negative high voltage from the high voltage power supply 65 is applied to the discharge electrode 62 through the discharge pin 72 and the conductive sheet 63, and each discharge electrode 62 is negatively charged. In this case, the housing 2 of the washing / drying machine 1 is grounded via a ground wire (not shown) or the like, and the housing 2 grounded in this way (opposite the discharge electrode 62). And a member provided at a position far away from the discharge electrode 62) functions as a counter electrode corresponding to the negatively charged discharge electrode 62.

  In the mist generator 60 configured as described above, the water in the water storage section 69 is sucked up by the water retaining material 64 and the conductive sheet 63 and supplied to each discharge electrode 62. A negative high voltage from the power supply device 65 is applied. At this time, electric charges concentrate on the tip of the discharge electrode 62, and energy exceeding the surface tension is given to the water contained in the tip. As a result, water at the tip of the discharge electrode 62 is split (Rayleigh split) and discharged from the tip of the discharge electrode 62 in a mist form (electrostatic atomization phenomenon). Here, the water particles released in the form of mist are negatively charged and contain hydroxy radicals generated by the energy.

  Accordingly, hydroxy radicals having a strong oxidizing action are released together with mist from the discharge electrode 62, and sterilization and deodorization are enabled by the action of the hydroxy radicals. In this case, a counter electrode corresponding to the negatively charged discharge electrode 62 is not provided in the vicinity of the discharge electrode 62. Therefore, the discharge itself from the discharge electrode 62 becomes very gentle, and unlike the conventional configuration in which corona discharge is generated between the discharge electrode and the counter electrode, harmful gas (ozone or the ozone is nitrogen in the air). Generation of nitrogen oxides, nitrous acid, nitric acid, and the like, which are generated by oxidizing the oxidant.

  Next, a water supply mechanism 75 for supplying water to the mist generator 60 having the above configuration will be described. As shown in FIGS. 6 and 7, a water supply mechanism 75 for supplying water into the case 61 (water storage part 69) of the mist generator 60 is provided at the rear part of the housing 2 (on the back side of the water tank 12) as follows. It is provided as follows. That is, as shown in FIGS. 6 and 7, the water supply mechanism 75 includes a water supply tank 76 located at the upper part in the housing 2.

  FIG. 8 shows the details of the water supply tank 76. Here, the water supply tank 76 has a cylindrical container shape with an upper surface opened, and a lid member 77 for closing the upper surface opening is provided. At this time, the gap between the water supply tank 76 and the lid member 77 is not sealed, and there is a gap that allows air to flow. The lid member 77 is provided with a water supply port 78 extending vertically. As shown in FIGS. 6 and 7, the water supply port 78 is connected to a second outlet port of the water supply valve 26 via a connection hose 79.

  On the other hand, as shown in FIG. 8, a connection port 80 is provided at the bottom of the water supply tank 76 so as to extend downward, and a water supply pipe 67 serving as a water supply path is connected to the connection port 80 via an on-off valve 81. It is connected. The on-off valve 81 is controlled to be opened and closed by the control device 10, and is normally closed. When the on-off valve 81 is opened, water stored in a fixed amount (for example, 20 cc) in the water supply tank 76 is supplied to the case 61 (water storage unit 69) of the mist generator 60 through the water supply pipe 67. It is.

  The side wall of the water supply tank 76 is provided with a drain port 82 extending in the horizontal direction for discharging excess water when the inside of the water supply tank 76 exceeds a certain water level. That is, a certain amount of water is stored from the bottom in the water supply tank 76 to the height position of the lower end of the drain port 82. At this time, in this embodiment, as shown in FIG. 8, the diameter (inner diameter) dimension b of the drain port 82 is configured to be larger than the diameter (inner diameter) dimension a of the water supply port 78.

  The drain port 82 is connected to the outside of the water supply tank 76 and in the vicinity of the upper end portion of the drainage path 83 formed of a pipe line extending in the vertical direction. The drainage channel 83 extends further upward from the connection portion of the drainage port 82, and its tip (upper end) is open to the atmosphere. Therefore, an air opening hole 84 is provided at the upper end of the drainage path 83 at a height equal to or higher than the drainage port 82.

  As shown in FIGS. 7 and 9, the other end side of the drainage path 83 is connected to the downstream side portion (near the connection portion of the overflow hose 53) with respect to the overflow portion of the overflow passage 56 of the overflow trap 51. Has been. As a result, surplus water that exceeds the height of the drainage port 82 in the water supply tank 76 passes through the drainage passage 83, passes through the overflow hose 53, and is discharged outside the apparatus. In the present embodiment, as shown only in FIG. 9, a check valve 85 is provided in the middle of the drainage path 83 to prevent the backflow of water or air from the bottom to the top. Of course, the drain 82 is provided at a position higher than the overflow path (the overflow trap 51).

  Next, the operation of the above configuration will be described. When the user wants to perform a drying operation in the sterilization mode in the washing / drying machine 1, the sterilization mode selection switch 8 a is turned on on the operation panel 8. Then, the control apparatus 10 performs the drying operation in the sterilization mode as follows. That is, before starting the drying operation, first, water (tap water) is supplied to the water supply tank 76 of the water supply mechanism 75 under the control of the water supply valve 26. At this time, the on-off valve 81 of the water supply tank 76 is closed.

  The supply of water into the water supply tank 76 is performed by time control of the water supply valve 26. For example, about three times (for example, 50 to 60 cc) of water stored in the water supply tank 76 is supplied through the connection hose 7. It is supplied into the water supply tank 76 from the port 78. As a result, a certain amount (for example, 20 cc) of water is stored in the water supply tank 76, but the amount of supplied water is sufficiently larger than the amount of water to be stored. It is discharged through the drainage path 83.

  At this time, since the air release hole 84 is provided in the drainage path 83 at a position higher than the drainage port 82, air can be easily introduced or discharged into the drainage path 83 through the atmosphere release hole 84. As a result, air and water in the drainage path 83 can be easily removed, and surplus water can be flowed through the drainage path 83 quickly and smoothly without hindering the flow. Further, in this embodiment, since the diameter dimension b of the drain port 82 is configured to be larger than the diameter dimension a of the water supply port 78, the amount of excess water discharged from the drain port 82 is set to the water supply port. The amount of water supplied from 78 can be increased, and the inside of the water supply tank 76 can be effectively prevented from being filled with water and overflowing.

  The surplus water that has passed through the drainage path 83 is discharged from the downstream portion of the overflow passage 56 of the overflow trap 51 through the overflow hose 53 to the outside of the apparatus. In this case, since the existing overflow route is used for discharging the surplus water, there is no need to newly provide it, and the configuration can be simplified correspondingly. Since the check valve 85 is provided in the middle of the drainage path 83, it is possible to prevent the odor from the drainage hole 50a of the waterproof pan 50 from flowing back to the water supply tank 76 side.

  After a certain amount of water is stored in the water supply tank 76, the open / close valve 81 is now opened with the water supply valve 26 closed. At this time, the on-off valve 81 is closed after being opened for a time sufficient to discharge all the water in the water supply tank 76 (water is supplied to the case 61). Thus, a certain amount of water in the water supply tank 76 is all supplied from the water supply pipe 67 to the case 61 of the mist generator 60 and stored in the water storage unit 69. Water that exceeds a predetermined water level (rising wall 61c) of the water storage section 69 overflows to the drain outlet 16b side and is drained out of the machine from the drain pipe 68.

  Thereafter, when the drying operation is started, as described above, the mist containing hydroxy radicals generated from the mist generator 60 is supplied into the drum 13 from the air supply duct 42 to disinfect and deodorize clothes. It works. In this case, during operation of the mist generator 60, a high voltage is applied to the discharge electrode 62, but the portion from the water supply tank 76 to the case 61 in the water supply path to the mist generator 60 (water supply pipe 67). Moreover, since the insulating gas is filled with air, the high voltage conduction state of the water supply path can be cut off, and the safety can be improved.

  As described above, according to the present embodiment, in the washing / drying machine 1 including the mist generator 60 that generates the mist exhibiting the sterilization action using the high voltage, the water supply mechanism 75 that supplies water to the mist generator 60 is provided with surplus. Since the water supply tank 76 having the drain outlet 82 for discharging water and the drain passage 83 are provided, and the atmosphere opening hole 84 is provided in the drain passage 83 at a position higher than the drain outlet 82, the safety is sufficiently high. Although it is high, the outstanding effect that the excess water in the water supply mechanism 75 can be easily discharged | emitted outside the apparatus can be acquired.

  In particular, in the present embodiment, the drainage path 83 is configured to drain using the overflow trap 51 and the overflow hose 53 for overflowing the water tank 12, so that the drainage path 83 can be shortened accordingly. Can be simplified. Moreover, since the check valve 85 is provided in the middle of the drainage path 83, it is possible to prevent backflow such as odor from the drainage hole 50a of the waterproof pan 50 in advance. Furthermore, since the diameter dimension b of the drain port 82 in the water supply tank 76 is configured to be larger than the diameter dimension a of the water supply port 78, the water tank 76 can be effectively prevented from overflowing with water. Etc. can also be obtained.

  FIG. 10 shows another embodiment of the present invention, and shows the structure of a water supply tank 91 portion constituting the water supply mechanism. The water supply tank 91 is different from the water supply tank 76 of the above embodiment in the following points. That is, the water supply tank 91 is also formed in a cylindrical container shape, and a lid member 77 having a water supply port 78 is provided on the upper surface thereof with a gap through which air can flow. In addition, a connection port 80 is provided at the bottom of the water supply tank 91, and a water supply pipe 67 is connected via an on-off valve 81.

  The side wall of the water supply tank 91 is provided with a drain outlet 92 extending in the horizontal direction for discharging excess water when the inside of the water supply tank 91 exceeds a certain water level. A communication port 93 extending in the horizontal direction is provided at the upper part of the drain port 92. The drainage port 92 and the communication port 93 are respectively connected in a state in which the drainage port 92 and the communication port 93 are kept parallel to a vertically extending drainage path 94. At this time, the upper end of the drainage path 94 is not open to the atmosphere but is closed. In addition, the diameter (inner diameter) dimension b of the drain port 92 is configured to be larger than the diameter (inner diameter) dimension a of the water supply port 78.

  In such a configuration, the upper portion of the drainage path 94 is located between the water supply tank 91 and the lid member 77 through the upper space where the water in the communication port 93 and the water supply tank 91 does not accumulate at a position higher than the drainage port 92. Open to the atmosphere through the gap. Thereby, the communication port 93 functions as an air release hole.

  Accordingly, in this embodiment as well, as in the above embodiment, surplus water supplied into the water supply tank 91 is discharged through the drainage passage 94 from the drainage port 92. Since a communication port 93 that is open to the atmosphere is provided at a position higher than 92, air is easily introduced into the drainage path 94 through a gap between the air communication port 93, the water supply tank 91, and the lid member 77. Alternatively, it can be discharged. Thereby, surplus water can be discharged | emitted quickly and smoothly from the drainage channel | path 94, without a flow being interrupted.

In addition, this invention is not limited only to each Example mentioned above, The following modifications or expansions are possible.
That is, various modifications can be made to the configuration of the mist generator 60. For example, as the porous material forming the discharge electrode 62, a porous ceramic material, a porous metal material, or the like may be used. The discharge electrode 62 is not limited to a shape having a pointed tip, and may be, for example, a shape in which the tip is rounded into a smooth hemisphere. The discharge electrode 62 may carry platinum nanocolloid. You may comprise so that the base end part of the discharge electrode 62 may be extended in the water storage part 69, and the function as a water supply means may also be performed.

  Specific numerical values of the amount of water stored in the water supply tanks 76 and 91, the amount of water stored in the water storage unit 69 of the case 61, and the amount of water supplied by one water supply operation of the water supply valve 26 Of course, only an example is shown, and various changes can be made. In addition, the present invention can be applied not only to the washing / drying machine 1 having the heat pump 49 in the circulation air passage 43 but also to the heater type washing / drying machine having a heater and a water-cooled heat exchanger in the circulation air passage. The present invention can be implemented with appropriate modifications without departing from the scope of the invention.

  In the drawings, 1 is a washing / drying machine, 2 is a housing, 8a is a sterilization mode selection switch, 12 is a water tank, 13 is a drum, 26 is a water supply valve, 28 is a drain hose, 29 is a drain valve, and 42 is an air supply duct. , 43 is a circulation air passage, 49 is a heat pump, 50a is a drain hole, 51 is an overflow trap, 52 is an overflow port, 53 is an overflow hose, 56 is an overflow passage, 60 is a mist generator, 61 is a case, 62 is a discharge electrode , 63 is a conductive sheet, 64 is a water retaining material, 65 is a high-voltage power supply device, 67 is a water supply pipe (water supply path), 68 is a drain pipe, 69 is a water storage unit, 75 is a water supply mechanism, 76 and 91 are water supply tanks, and 77 is A lid member, 78 is a water supply port, 81 is an on-off valve, 82 and 92 are drain ports, 83 and 94 are drain passages, 84 is an air release hole, 85 is a check valve, and 93 is a communication port (atmosphere open hole). Show.

Claims (4)

A mist generator that applies a high voltage to an electrode having water absorbency, generates a mist exhibiting a sterilizing action, and supplies the mist to the water tank;
In the washing and drying machine provided with a water supply mechanism for supplying water to the mist generator,
The water supply mechanism includes a water supply tank that stores a certain amount of water, a water supply path for supplying water in the water supply tank to the mist generator, and excess water that is provided in the water supply tank and exceeds the certain amount. A drainage outlet to be discharged and a drainage path connected to the drainage outlet for discharging the excess water to the outside of the machine,
The washing / drying machine, wherein the drainage passage is provided with an air opening hole that is located at a height higher than the drainage outlet and opens the drainage passage to the atmosphere. An overflow path for draining the overflowed water to the outside when the water level in the water tank exceeds a predetermined water level;
The drain outlet is provided at a position higher than the overflow path,
The washing / drying machine according to claim 1, wherein the drainage path is connected to the overflow path, and a check valve for preventing a backflow is provided in the drainage path.   A water supply port for supplying water into the water supply tank is provided at an upper portion of the water supply tank, and the diameter of the drainage port is configured to be larger than the diameter of the water supply port. The washing / drying machine according to claim 1 or 2, characterized in that: An overflow path for draining the overflowed water to the outside when the water level in the water tank exceeds a predetermined water level;
The overflow path is provided with an overflow trap,
The washing / drying machine according to any one of claims 1 to 3, wherein the drainage path is connected to a downstream side of the overflow trap in the overflow path.

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