TW200949040A - Washing machine, and washing and drying machine - Google Patents

Abstract

This purpose of the invention is to provide a washing machine for washing in the way to distribute the washing water from the center to the periphery of the inner tank globally and uniformly. The washing machine of this invention comprises: an outer tank receiving the washing water and clean water; an inner tank for accommodating the clothes to be washed, the inner tank being rotatably disposed in the outer tank; a washing opening disposed on the inner tank for spreading the washing water or cleaning water above the clothes to be washed; and a circulation pump for sucking the washing water or cleaning water in the outer tank and supplying the same to the washing opening, wherein the washing water or cleaning water is distributed spirally at the washing opening, and characterized that the increase and decrease of the water amount provided by the circulation pump to the washing opening is continuously repeated.

Description

200949040 VI. Description of the Invention: [Technical Field of the Invention] The present invention relates to a washing machine 'and a washing and drying machine from laundry to drying. [Prior Art] A washing machine, and a washing and drying machine from laundry to drying, are used in a washing operation to wash laundry water from a circulation pump and rinse the laundry in the laundry tank. For example, Japanese Laid-Open Patent Publication No. 2007-282934 (Patent Document 1). [Problem to be Solved by the Invention] In the water saving of the washing water, the washing water is applied to the laundry which is exposed to the surface of the washing water. In the distributed rinsing method (Patent Document 1), the washing water can be widely distributed from the center across the outer circumference in the inner tank. SUMMARY OF THE INVENTION An object of the present invention is to provide a washing machine which uses the rinsing method shown in Patent Document 1 to spread the washing water in a uniform manner from the center and the periphery of the outer tank without any leakage. (Means for Solving the Problem) The present invention relates to a washing machine having an outer tank of -4-200949040 in which washing water and washing water are retained, and a laundry that is rotatably built in the outer tank. a rinsing port provided above the inner tank to disperse washing water or washing water from above the laundry; and washing or supplying the washing water or washing water retained in the outer tank to the rinsing port The circulating pump is configured to disperse the washing water or the washing water by rotating around the flushing port, and is characterized in that the amount of the supplied water supplied to the flushing port by the circulating pump is continuously returned. e [Effects of the Invention] According to the present invention, the amount of supply water supplied to the flushing port by the circulation pump is continuously increased and decreased, so that the washing water can be dispersed in the inner tank from the center and the outer circumference. Do not miss and do it evenly. [Embodiment] For the embodiment of the present invention, a description will be made with reference to Figs. 1 to 60. First, referring to Figure 1, the outline of the washer-dryer is explained. The outer frame 1 of the washing and drying machine is built in the outer tank 2 for storing the washing water. The outer groove 2 is supported by the outer frame 1 by vibration. The laundry dewatering tank (inner tank) 3, which accommodates and washes and dries the laundry, is rotatably supported in the outer tub 2. The stirring blade 4 for washing and washing the laundry is rotatably built in the inner tub 3. During the washing operation and during the drying operation, the stirring blade 4 returns to the forward/reverse rotation. In the dehydration operation, the agitation blade 4 is rotated at a high speed together with the inner tub 3 - 5 - 200949040, so that the moisture of the laundry contained in the inner tub 3 is dehydrated. The washing and drying drive motor 10 is configured to perform rotational driving of the stirring blade 4 and the inner tub 3. The washing and drying drive motor 10 uses a DC brushless motor. This DC brushless motor is vector controlled. The outer cover 5 is openably and closably provided on the top cover 6 located at the upper portion of the outer frame 1. In the upper portion of the outer tub 2, the inner lid 34 is openably and closably provided. The outer cover 5 and the inner cover 34 are opened to allow the laundry to enter and exit in the inner tub 3. The top cover 6 has a water supply box (not shown) on the front side. In the water supply tank, water and bath water are supplied to the outer tank 2. The detergent and finishing agent input device 35 is located on the front side of the top cover 6. The detergent and the finishing agent are injected into the outer tank 2 and the inner tank 3 by the inlet pipe 36. The water supply valve 7 is provided at the rear of the top cover 6. The inflow connection portion 8 of the water supply valve 7 projects upward through the top cover 6. A water pipe (not shown) is connected to the inflow connection portion 8 which is protruded here. The discharge port side of the water supply valve 7 is connected to the previous water supply tank via the connected water supply pipe 30. The drop port of the water supply tank is oriented between the outer tank 2 and the inner tank 3. A bath water pump (not shown) that sucks up the bath water is also built in the rear of the top cover 6. The bathing pump is connected to a suction pipe that extends to the bath. At the front end of the suction pipe, there is provided a bath water removing device for sterilizing bath water to be described later. The drying mechanism 9 performs circulating air blowing and dehumidification of drying air for drying the laundry in the inner tub 3. Most of the drying mechanism 9 is occupied by an air circulation path. -6-200949040 The drying air circulation path has a bottom circulation path 20 connected to the bottom of the outer tank 2, a dehumidification longitudinal passage 21 rising from the bottom circulation passage 20, and a dehumidification longitudinal passage 21. The warm air assembly 22 is connected to the upper side in a connected manner. The heater unit 22 is a blower fan and a heater 24 which will be described later in detail. The suction side of the heater unit 22 is connected to the upper side of the dehumidification longitudinal passage 21, and the discharge side is connected to the return connection circulation path 25. The connection circulation path 25 is provided with an upper bellows tube 23, and is connected to the upper portion of the outer tank 2 via the upper bellows tube 23. The bottom circulation path 20 also has a lower bellows tube 26 that is connected to communicate with the bottom of the outer tank 2 via the lower bellows tube 26. The dehumidification longitudinal passage 21 is built in a dehumidification field to be described later. The dehumidification field extends longitudinally within the longitudinal passage 21 for dehumidification. The bath water and the channel water supplied to the dehumidification area are cooled by the drying air that rises along the dehumidification vertical passage 21, so that the moisture contained in the drying air is taken up by the blower fan 29 of the warm air unit 22. The drying air that has passed through the drying air circulation path is circulated in the inner tank 3, and the laundry in the inner tank 3 is dried. Since the drying air in which the moisture is removed in the dehumidification area is reheated by the heater of the warm air unit 22 and flows toward the inner tank 3, the moisture of the laundry can be removed. This moisture removal is repeated by the circulation of the drying air, so that the laundry is well dried. The lower bellows 26 and the bottom drop portion 31 of the outer tub 2 are connected to the wash water drain passage 42 and the wash water circulation water passage 43 via the lower communication tube 41 200949040. The washing water draining passage 42 communicates with the lower communicating pipe 41 through the drain valve 44, and the washing water circulating water passage 43 communicates with the lower communicating pipe 41 via the circulation pump 45 and the foreign matter removing and deodorizing valve 32" during the washing operation and the drying operation. The drain valve 44 is closed. The drain valve 44 is opened and the washing water and the washing water retained in the outer tub 2 are drained toward the outside of the washer dryer when the laundry water is drained and drained. The suction side of the circulating pump 45 is connected to the foreign matter removing and deodorizing valve 32. The discharge side of the circulation pump 45 is connected to the wash water circulation water passage 43 so as to be connected. The washing water circulating water longitudinal water passage 46 connected to the front side of the washing water circulation water passage 43 rises along the outer side surface of the outer tank 2 and extends up to the upper side of the inner tank 3, and is provided on the upper side of the inner tank 3 and with the washing thread removing device. 33 connected ways are connected. The washing water and the washing water retained in the outer tub 2 are sucked up by the circulation pump 45, and are flowed into the washing water circulating water longitudinal water path 46 to be dispersed from the washing thread removing device 33 to the inner tub 3. Since the washing and rinsing by the circulating water generated by the circulation pump 45 is carried out, the washing and washing can be performed with a small amount of water. The water level sensor 47 detects the water level of the washing water and the washing water retained in the outer tub 2. An air deodorizing valve 50 is provided in the outer tank 2 near the bottom, and an air tube 49 connected in communication with the air deodorizing valve is provided. The upper end of the air tube 49 is connected in a manner to communicate with the water level sensor 47. The water level change in the outer tank 2 is sensed by the water level sensor 47 to detect the water level. -8- 200949040 Next, various features of the present invention will be described with reference to the drawings. First, the drying mechanism, the dehumidification means, and the lint removal will be described with reference to Figs. 4 to 11 . The drying air circulation path occupied by most of the drying mechanism 9 has a vertical passage 21 for dehumidification. This dehumidification longitudinal passage 21 is as shown in Fig. 5, and has a cooling fin 72 included in the dehumidifying means in the dehumidification zone 70. The dehumidification zone 70 is in the range from the middle of the dehumidification longitudinal passage 21 and across the upper portion. The lower end of the dehumidification field is the level at which the washing water is at a high water level (when the amount of laundry is large). The cooling fins 72 of the dehumidifying means are formed of a metal material having good heat conductivity such as stainless steel or aluminum. Further, the cooling fins may be integrally formed of synthetic resin in the same manner as the longitudinal passage 21 for dehumidification. The cooling fins 72 are erected so as to protrude from the inner wall surface of the longitudinal passage 21 for dehumidification. The drying air flowing from the bottom to the top in the longitudinal passage 21 for dehumidification is dehumidified so as to be raised while touching the cooling fins 72. The cooling water supply connection port 80 is provided in the dehumidification vertical passage 21. In this supply port 80, a cooling water pipe for supplying water for the channel and bath water sucked by the bath water pump is connected. The cooling water is lowered along the longitudinal passage 21 for dehumidification by the supply port 80 while contacting the cooling fins 72. Here, the drying air which rises from the lower side along the dehumidification longitudinal passage 21 comes into contact with the cooling water and the cooling fins 72, and is cooled, so that the moisture contained in the drying air is taken. The supply port 8 1 ' of the washing water is a supply port 80 adjacent to the cooling water. In the supply port 81, a washing water supply pipe for supplying water for the bath water which is sucked by the water channel -9-200949040 and the shower water chest is connected. The washing water is supplied to the connection port 81 through the washing water, and is lowered along the longitudinal passage 21 for dehumidification while being in contact with the cooling fins 72. The lint and the cloth dust adhering to the inner wall surface of the cooling fin 72 and the longitudinal passage 21 for dehumidification are removed by the washing water flow. The defoaming nozzle 82 is provided at the upper portion of the longitudinal passage 21 for dehumidification. The front end of the defoaming nozzle 82 is set to be inclined downward. The defoaming water supply pipe 83 is connected to the defoaming nozzle 82. Although not shown, the defoaming water supply pipe 83 is connected to the washing water circulating water longitudinal water passage 46. The defoaming water is dispersed by the defoaming nozzle 82 in the washing operation and the washing operation. By this defoaming water, the lotion bubbles which rise along the dehumidification longitudinal passage 21 during the washing operation and the washing operation are eliminated. The increased lotion bubble is removed while rising along the longitudinal channel 21 for dehumidification. The vertical passage 21 for dehumidification has a rectangular shape in cross section. The reason why the width of the longitudinal direction of the dehumidification longitudinal passage 21 is narrow and the width in the lateral direction is wide is because of the arrangement relationship of the longitudinal passages 21 for dehumidification. The dehumidification longitudinal passage 21' is provided between the outer tub 2 and the outer frame 1 at the rear side of the washer-dryer. Since the rear side of the washer-dryer is narrow only in the space between the outer tub 2 and the outer frame 1, the dehumidification longitudinal passage 21 has the above-described shape. Further, although the outer frame 1 has a square shape, since the hanging bar for hanging the outer groove 2 is provided in the four frames, the vertical passage 21 for dehumidification is disposed on the rear side of the washer-dryer. The longitudinal passage 21 for dehumidification of the above-described shape has an expansion wind 200949040 road portion 84 on the upper side. The expansion air passage portion 84 is formed by expanding the width of the upper portion in the lateral direction toward the outside of the dehumidification longitudinal passage 21 by about 2/3. The width in the lateral direction of the upper end of the longitudinal passage 21 for dehumidification is about twice the width in the lateral direction of the lower end. Further, the expanded air passage portion 84 has an inclined shape that is expanded toward the upper lateral width. The upper end of the longitudinal passage 21 for dehumidification has a drying air outlet 86 for allowing the drying air to flow out in the upper portion of the expansion air passage portion 84, and a lower portion 85 having cooling water in the other portion except the expansion air passage portion 84. . The cooling water supplied from the cooling water supply connection port 80 flows down from the lower portion 85, and descends along the cooling fins 72 along the vertical passage 21 for dehumidification. The drying air flows downward from the lower side along the dehumidification vertical passage 21, and the cooling air passage portion 84 stops contact with the cooling water, and flows toward the warm air module 22 and a drying filter to be described later. By expanding the air passage portion 84, it is possible to suppress the water droplets of the cooling water from flowing into the warm air module 22 and the drying filter. In other words, when the drying air passage portion 86 is not provided, and the drying air outlet 86 is provided in the lower portion 85 of the cooling water, the water droplets of the cooling water flowing down from the lower portion 85 and splashed by the cooling fins 72 have the drying air. The possibility of flowing into the warm air assembly 22 and drying the filter. However, by providing the expansion air passage portion 84, the drying air that rises from the lower side of the dehumidification vertical passage 21 is stopped in contact with the cooling water in the expansion air passage portion 84. Therefore, the drying air is deviated before the cooling water flowing down from the lower portion 85 passes through the splashed portion by the cooling fins 72. Further, the flow path sectional area of the dehumidification longitudinal passage 21 is larger when the expansion air passage portion -11 - 200949040 84 is present than when the lower expansion air passage portion 84 is not present. Therefore, the flow of the drying air becomes gentler, and there is no power (force) for transporting the water droplets of the cooling water. By providing the expansion air passage portion 84, the drying air is transported by the water droplets that do not carry the cooling water, so that the water droplets of the cooling water can be prevented from flowing into the warm air module 22 and the drying filter. In the washing operation and the cleaning operation, even if the defoaming of the defoaming nozzle 82 is insufficient, the detergent bubbles are caused to rise along the dehumidification longitudinal passage 21, and the dehumidification longitudinal passage 21 is expanded in the expansion air passage portion 84. The cross-sectional area of the road, so the rise of the lotion bubble is suppressed here. Thereby, the problem that the lotion bubble flows into the heater element 22 and the drying filter can be prevented in advance. The dehumidification longitudinal passage 21 has a lint removal window 90 as shown in Figs. 5 and 7. This lint removal window 90 is an expansion air path portion 84 provided on the outer frame 1. The window cover 91 is detachably provided in the lint removal window 90. The window cover 91 is screwed and fixed to the outer frame 1 by the fixing bolts 92, as shown in Fig. 8, Fig. 9, Fig. 10, and Fig. 11 'in the face of the lint removal window 90. The location has an outer window 93. The outer cover 94 is detachably provided to the outer window 93. The outer cover 94 is screwed and fixed by the outer fixing bolts 95. The outer periphery of the outer window 93 is larger than the outer periphery of the window cover 91 as shown in Fig. 9. In the drying operation, the drying air is a lint that is circulated in the longitudinal path of the dehumidification passage 21° by the drying air, and the lint is collected by a drying filter to be described later, and is also retained in the flow of the drying air. Expansion of the wind-12- 200949040 Road 84. The lint remaining in the expanded air passage portion 84 is preferably removed. The outer fixing bolt 95 is loosened, and the outer cover 94 is removed. The fixing bolt 92 is loosened, and the window cover 91 is removed. Further, the outer window 93 and the lint removal window 90 are placed in the hand to remove the lint remaining in the expansion air passage portion 84. By attaching the window cover 91, the fixing bolt 92 is tightened, the outer window 93 is attached, and the outer fixing bolt 95 is screwed, and the maintenance of the lint remaining in the expansion air passage portion 84 is completed. In this way, the removal of the lint remaining in the expansion air passage portion 84 can be easily and easily performed from the outside of the outer frame 1 of the washer-dryer by removing the outer cover 94 and the window cover 91. . Further, since the outer periphery of the outer window 93 is larger than the outer periphery of the window cover 91, the window cover 91 can be taken out of the outer frame 1 through the outer window 93. Since the window cover 91 can be completely removed, the removal of the lint can be easily performed. The drying filter (drying filter device) will be described with reference to Figs. 15 to 21 . The drying filter (drying filter device) 100 is located between the drying air circulation paths of the drying mechanism 9. The drying filter (drying filter device) 100 functions as a dry lint removing means for collecting and removing lint transported by the drying air flowing through the drying air circulation path. A drying filter device 100 is provided between the drying air outlet 86 of the wet longitudinal passage 21 and the upstream side (suction side) of the warm air module 22. As shown in Fig. 15, the drying filter device 100 includes a main body casing 101 and a dried filter frame 102 which can be pulled out/pressed into the main body casing 101. The filter housing 102 has a front side frame portion 103 and a filter frame portion 104. The filter frame portion 104 is an inflow port 106 having a flow of drying air in the rear portion, and a filter 107 for collecting the lint pieces on the upper surface. The front operation panel 108 of the front side frame portion 103 is a handle 109 having a notch shape at the lower portion. The handle 109 is gripped, and the drying filter housing 102 is inserted into the main body casing 101. In the filter housing 102, the detachment stopping means 1 1 〇 is provided on both side surfaces of the front side frame portion 103. The drying filter housing 102 that is press-fitted to the main body housing 101 is held by the detachment stopping means 1 1 0 so as not to be detached, and the detachment stopping means 110 is held, as shown in Fig. 16, Fig. 17, and 18 and 20 show a slip preventing member 111 made of rubber, a pressing pin 1 1 2, and a fixing member 1 13 . The anti-slip member 1 1 1 is a head portion 114 having a spherical shape on the front side, a crucible 115 having a peripheral ring shape on the rear side, and a recess 1 16 recessed from the rear side toward the front side. The fixing member 113 has a stopper portion 117 for receiving the rear portion of the pressing pin 112 at the center, and has a pair of locking claws 118 on the outer peripheral side. As shown in FIG. 17 and FIG. 21, the front side frame portion 103 has a through hole 119 for fitting the head portion 114 of the anti-slip member 111 on both side surfaces, and has a locking claw 118 for fixing the fixing member 113. The pair of snap grooves 1 20 . The pair of engaging grooves 1 20 are arranged around the through hole 1 1 9 and have an arc shape. As shown in Fig. 21, the engaging groove 120 has a through groove portion and a non-14-200949040 through groove portion. The through-groove portion is a size that allows the locking claws 118 of the fixing member 113 to be inserted. The locking claws 118 are engaged with the remaining non-through grooves. The groove depth ' of the non-penetrating groove portion is such that the engaged locking claws 118 are not exposed from the engagement groove 120 or are slightly exposed (Fig. 18). The assembly of the detachment stopping means 110 is performed from the inner side of the front side frame portion 103 as shown in Fig. 19. The anti-slip member is inserted from the head portion 114 toward the through hole 119. Next, the mounting of the fixing member 113 is performed after the pressing pin 112 is inserted into the recess 116 of the anti-slip member ill. The fixing member 113 is inserted into the through groove portion of the engagement groove 120 after the locking claw 118 is inserted, and the locking claw 118 is twisted to sit on the non-penetrating groove portion of the engagement groove 120. When the drying filter housing 102 is press-fitted into the main body housing 101, the anti-slip member 111 that protrudes from the side surface of the drying filter housing 102 is pressed against the inner wall surface of the main body housing 101. The anti-slip member 111 is twisted and pressed by the head portion 1 14 by elastic deformation of the rubber. The frictional force of the rubber generated by the elastic deformation causes the anti-slip action to be strongly actuated, and the filter housing 102 is kept dry so as not to come out of the main body casing 101. Further, since the anti-slip member 111 is pressed from the inside by the pressing pin 112, the head portion 114 is strongly pressed against the inner wall surface of the main body casing 101, and the anti-slip effect by the strong friction is maintained. Therefore, even if the operation of the washing and drying machine is vibrated, the installation of the drying filter housing 102 is not released and peeled off. Further, the mounting and holding of the drying filter frame 102 is caused by the anti-slip action of the friction of the member 117-200949040. Therefore, since the drying filter housing 102 is attached and detached by the drawing/pressing operation of the drying filter housing 102, the loading and unloading operation is easy unlike the mechanical holding mechanism with which the turning operation is performed. Further, since the detachment stopping means 110 is assembled only by inserting the anti-slip member 111 and the pressing pin 112 and inserting the locking claws 118 of the fixing member 113 into the engaging groove 120, the assembly is simple. Further, the locking claws 118 that are engaged with the engaging grooves 120 are not exposed to the engaging grooves 120, or are slightly exposed. Therefore, even if the head portion 114 of the anti-slip member 111 is deformed and crushed, the locking claw 118 does not abut against the inner wall surface of the main body casing 1〇1, and the strong friction generated by the head portion 114 of the anti-slip member is generated. The anti-slip effect is maintained. Further, in the above-described embodiment, the detachment stop means 110 is provided in the dry filter housing 102, and the anti-slip member 111 of the detachment stop means 110 is slidably attached to the inner wall surface of the main body casing 101, but the detachment stop means 110 is replaced. The cost body frame 101 is also possible. In other words, the anti-slip member 111 is a configuration in which one of the opposing surfaces (for example, the inner wall surface of the main body casing 101) that is slidably moved to the opposite side of the main body casing 101 and the drying filter casing 102, and the drying filter can be realized. The frame 102 is stopped. The heater components are described with reference to Fig. 12, Fig. 13, and Fig. 14. The heater unit 22 includes a front side unit case 200, a rear side unit case 201, a blower fan 202, and a heater 24 for heating. The front side component housing 200 and the back side component housing 20 1 are combined to form a module housing. Inside the casing 200949040, a blower fan 202 and a heater 24 for heating are provided. This heater 24 uses a PTC thermistor. The heater 24 of the long PTC thermistor having a rod shape generates heat uniformly across the entire body, and contacts a plurality of fins to heat the air from the blower fan 2〇2. The front side unit case 200 and the rear side unit case 201 have a case portion 204 in which the blower fan 202 is built, and a heater chamber 205 in which the heater 24 is built. The blower fan 202 is a turbine fan that rotates at a high speed in the direction of the P arrow. The wing 212 of the turbofan has a circular arc shape, and the twelve wings 212 are arranged at equal intervals. The blower fan 02 is driven by an electric motor. The blower fan 02 and the motor are collectively referred to as an electric blower. The front side unit case 200 has a suction port 206 and a discharge port 207. The suction port 206 is located at the center of the outer casing portion 204 so as to face the center of the suction side of the blower fan 202. The discharge port 207 is disposed at a position of the heater chamber 205 which is the downstream side of the heater 24. The suction port 205 is connected to the dehumidification longitudinal passage 21 via a drying filter (dry filter device) 100. The discharge port 207 is in communication with the connection circulation path 25 of the drying air circulation path. The outer casing portion 2 04 has a discharge port 208. The discharge port 208 has a rear side end portion 209 which is a rear side and a front side end portion (nose portion) 2 1 0 which is a front side with respect to the rotation direction of the blower fan 202. The rear side end portion 209 is adjacent to the outer circumference of the blower fan 202. The rear end portion 209 is separated from the outer circumference of the blower fan 202. Therefore, the gap between the inner circumference of the outer casing portion 204 and the outer circumference of the blower fan 208 is a shape of an involute that gradually expands from the rear end portion 209 toward the nose portion 210. -17- 200949040 The flow rate distribution from the discharge port 208 by the rotation of the blower fan 202 is a state in which the rear end portion 209 is large and the nose portion 210 is small. Here, in order to make the flow rate distribution uniform, the ridge portion 211 protruding toward the nose portion 210 so as to narrow the discharge port 208 is provided on the rear end portion 209 side. The raised portion 211 is located between the rear end portion 209 and one end portion of the heater 24, and the surface faces the center of the rear end portion 209 to have a high bulge shape. In the discharge port 208, the ridge portion 211 protruding so as to narrow the discharge port 2 0 8 toward the nose portion 2 1 0 is provided at the rear end portion 209 located on the opposite side of the nose portion 210 because Since the air distribution to the heater 24 is uniformly approached to the rear end portion 209 and the nose portion 21, the heating range of the heater 24 is uniform as a whole, and the heating of the dry air is favorably performed. Regarding the static electricity removal, description will be made with reference to Figs. 22 to 28. The outer tank upper cover 300 to which the upper end line portion of the outer tub 2 is supported and supported has an annular cover portion 301 and a semicircular cover portion 312. The annular cover portion 301' covers the upper portion of the front portion of the outer groove 2 and the inner groove 3 except for the rear portion. The semicircular cover portion 302 covers the upper portion of the rear portion of the outer tub 2 and the inner tub 3. The annular lid portion 301 is an inlet/outlet 303 in which a large opening on the inner peripheral side serves as a laundry. The door 303 is opened and closed by the inner lid 34. The annular lid portion 301 and the semicircular lid portion 312 are integrally formed using an SPS (synthetic resin) material. It is conventionally known that the lid portion 301 and the lid portion 3〇2 are formed of a punched product of a stainless steel sheet. Since it is a molded article of SPS (synthetic resin 200949040) material, productivity is further improved, and weight is also reduced. Further, since the SPS (synthetic resin) material is excellent in moldability and excellent in heat resistance, it can withstand high temperatures in the drying operation. The inner lid 34 is such that the outer lid upper cover 300 is supported by the hinge 3〇4 so as to be openable and closable. The inner cover 34 is a cover 306 made of a synthetic resin made of a stainless steel plate, and has a transparent window 307 made of heat-resistant glass. The cover 306 and the reinforcing frame 305 are screwed together by a bolt 308, and the transparent window 307 is held by the cover 306 and the reinforcing frame 305. One end of the reed member 309 for electrostatic discharge made of metal (stainless steel) or an energized material is as shown in Figs. 26 and 28, and the hub portion 310 of the cover 306 is joined by the bolt 317. The reinforcing frame 305 is screwed together. The other end of the reed member 309 is screw-joined by the reed bolt 312 at the reed hub portion 311. The reed bolt 312 is made of metal (stainless steel) or energized material. The conductive rubber member 313 of the thin plate piece is provided in the vicinity of the hinge 304 which is provided with the outer groove upper cover 300. As shown in Figs. 25 and 27, the conductive rubber member 313 and the reed bolt 312 are provided in the vicinity of the rotating shaft 314 of the hinge 306. Therefore, as shown in Figs. 27 and 28, when the inner lid 34 is opened, the reed bolt 312 is separated from the conductive rubber member 313. By closing the inner lid 34, as shown in Figs. 25 and 26, the head of the reed bolt 312 is in contact with and electrically connected to the conductive rubber member 313. One end of the outer reed member 315 made of metal (stainless steel) or an energized material is attached to the conductive rubber member 313' and is fixed to the outer tank upper cover 3 00 together with the conductive rubber member 313-200949040. At the other end of the reed member 315 is provided a connection terminal 316 through which the connection terminal 316 is grounded to the outer frame 1. During the drying operation, the stirring blade 4 is stirred and rotated in the inner tank 3. When the static-charged laundry is in contact with the inner lid 34, the static electricity is via the inner lid 34, the reed member 3 09, and the reed bolt. 312. The conductive rubber member 313 and the reed member 315 are discharged toward the outer frame 1. By such discharge, the static electricity carried by the laundry in the drying operation is neutralized, so that the electric shock when the laundry is taken out after the drying operation can be eliminated. In the above-described neutralization mechanism, the reed bolt 312 for stopping the reed member 309 provided in the inner lid 34 is provided in the vicinity of the rotation shaft 314 of the hinge 304, so that the reed bolt 312 is opened and closed according to the opening and closing of the inner lid 34. The head-coupled conductive rubber member 313 is provided on the outer tank upper cover 300. This configuration is different from the case where the inner cover side and the outer cover upper cover side are connected by wires, and the damage caused by the return bending of the wire which is closed with the opening of the inner cover does not occur. Since the reed bolt 312 and the conductive rubber member 313 are provided in the vicinity of the rotating shaft 314 of the hinge 304, unlike the hinge 300, the outer portion is not exposed. Therefore, the laundry is not damaged by the contact reed bolt 312 and the conductive rubber member 313 when the laundry enters and exits. The bath water sterilization device is described with reference to Figs. 29 to 32. The bath water sterilization device 400' is connected to the front end of the suction pipe extending from the shower water chestnut (not shown). In the washer-dryer, since the bath water is sucked through the bath water sterilization device 400, the laundry can be cleaned by the sterilized bath water. The bath water removing device 400 includes a sterilizing cassette 401, an upstream side foreign matter removing filter 402, a downstream side foreign matter removing filter 403, an intake cap 404, a filter press 405, and a body hammer 406. The body hammer 406 is made of a heavy material that sinks into the water, and a suction pipe is screwed into the rear portion, and a suction cap 404 is screwed into the front side. Further, in the suction cap 404, a sterilization cartridge 401, an upstream foreign matter removal filter 402, a downstream foreign matter removal filter 403, and a filter press 405 are accommodated. The sterilizing cassette 401 has a cylindrical body 407 made of a synthetic resin, a granular sterilizing agent (not shown) that is clogged in the inside of the cylindrical body 407, and a granular sterilizing agent. A cassette cover 408 of synthetic resin. The cylindrical body 407 is a partition portion 409 having a plurality of water-passing holes (water-passing holes smaller than the particle diameter of the granular sterilizing agent) in the center of the inner side. In this partition portion 40, the inside of the cylindrical body 40 7 is divided into two chambers in the axial direction. The partition 409 is formed integrally with the cylindrical body 407. The partition portion 409 has a plurality of water passage holes (water passage holes smaller than the particle size of the granular sterilizing agent). A plurality of pillars 410 extending from the partition portion 409 to the vicinity of the edge portion of the cylindrical body 407 are provided in the two chambers. Further, the plurality of pillars 410 are provided one at the center of the partition portion 409 and four at the periphery. But setting more roots is fine. The cassette cover 408 has a plurality of water-passing holes (the cover 408 having a smaller particle size than the granular sterilizing agent - 21940940) is locked. The sterilizing is made from the outer side to the surface. Next, the inner material is removed by 400, and is held by the upstream lid 408 which is sterilized by the downstream side. Therefore, the downward flow struts 410 of the device 402, because of the generated water-passing holes, the outer circumference is the cylinder 407. The inner side is fitted. When the card is embedded, it is received by the front end of the plurality of struts 410. Further, the cassette is jammed by the snap means 401 which is not easily detached, and when the sterilization is performed, the granular sterilizing agent is partitioned by the cassette cover 408 and the partition 409. The outer side of the upstream side end portion 40 9 of the sterilizing cassette which is the bath water flowing into the sterilizing cassette is the downstream side end surface of the bath sterilizing cassette which is sterilized by the sterilizing cassette. By the water-passing hole of the suction cap 404, the bath water that has entered the bath water sterilizing device is sterilized by the particulate sterilizing agent which is separated from the upstream side foreign matter removing filter 402 by the sterilizing cassette 40 1 . Further, the foreign matter removing filter 403 further removes foreign matter so that the foreign matter-free bath water can be supplied to the washing and drying machine. Since the side foreign matter removing filter 402 is held between the card and the front side of the suction cap 404, this state is secured, and since the position does not deviate, the foreign matter removal by the upstream side foreign matter removal filtering can be favorably removed. get on. The side foreign matter removing filter 403 is held because it is held between the plural and the filter press 405. Since the position does not deviate, the removal of foreign matter by the downstream side foreign matter removing filter 403 can be favorably performed. The downstream side foreign matter removing filter 403 also has a granular fungicide function. When a granular fungicide is discharged from the sterilizing cassette 401,

-22- 200949040 The granular bactericide is captured by the downstream side foreign matter removing filter 403. Granular fungicides are of various types. Particles such as metal or glass are formed by adsorption, inclusion, and mixing of silver ions. The sterilizing agent of the hard particles flows out of the sterilizing cassette 401. Since the downstream side foreign matter removing filter 403 is caught, the breakage of the flow tank provided in the bathing water can be avoided. Further, the foreign matter removing pores of the downstream side foreign matter removing filter 40 3 are smaller than the foreign matter removing pores of the upstream side foreign matter removing filter 402. Therefore, it is possible to remove fine foreign matter which cannot be removed by the foreign matter removing filter 402 on the upstream side. When the sterilization effect of the granular bactericide is lowered, the granular bactericide is renewed. The cassette cover 408 of the sterilization cassette 401 is locked by the engagement means. Therefore, the cassette cover 40 8 is not detached by simply pulling out/installing the sterilizing cassette 40 1 from the bath water removing device 400, and the loading and unloading operation is easy. Further, when the cassette cover 40 8 is attached by the renewal of the granular sterilizing agent, the "locked cassette cover 408 is easily engaged by the engagement means at the position where the front end of the plurality of struts 410 is received by the engagement means. . The sterilization performance and flowability of the further bath water sterilization device are described in Fig. 29 and Fig. 60. The sterilizing cassette 401, that is, the diameter of the cylindrical body 407 > 1 is 38 mm. The diameter of the thin flow path connected to the downstream side passage which flows through the sterilized bath water in the sterilizing cassette 401 is about 12 mm. The diameter φ2 of the thin flow path is connected to the suction pipe. The upstream side end surface of the sterilizing cassette 401, that is, the outer surface of the cassette cover 408 and the gap of the opposite side of the upstream side foreign matter removing filter 402, that is, the upstream -23-200949040 side gap length D1 is about 5 mm. The downstream side surface of the sterilizing cartridge 401, that is, the outer surface of the partition portion 409 and the gap of the opposing surface of the downstream side foreign matter removing filter 403, that is, the length D2 of the downstream side gap is about 15 mm. The downstream side passage through which the sterilized bath water flows is gradually thinned from the middle by the sterilizing cassette 40 1 , and is connected to the fine flow path of the diameter < The length D3 from the position where the downstream side passage is tapered to the downstream end surface of the sterilization cartridge 40 1 is about 30 mm. The length D4 from the upstream side end surface of the sterilizing cassette 40 1 (the outer side surface of the cassette cover 408) to the downstream side end surface (the outer side surface of the partition portion 409) is about 15 mm from the downstream side of the sterilizing cassette 401 The length D2 of the end surface (outer side surface of the partition portion 409) up to the upstream end surface of the downstream side foreign matter removing filter 403 is about 15 mm. The length D5 from the position where the downstream side passage becomes thinner to the downstream end surface of the downstream side foreign matter removing filter 403 is about 10 mm. The length D6 of the range in which the downstream side passage is tapered is about 10 mm. The reason why the gap of the width D1 (about 5 mm) is provided on the opposite surface of the upstream side end surface of the sterilizing cassette 401 and the upstream side foreign matter removing filter 402 is to remove the residual water of the bath water removing device 400 and the suction tube. Remove. A gap having a width of D2 (about 15 mm) is provided on the opposing surface of the downstream side end surface of the sterilizing cassette 401 and the downstream side foreign matter removing filter 403, and the residual water of the bath water removing apparatus 400 and the suction tube is removed. The sterilizing cartridge 401 and the upstream and downstream foreign matter removing filter are too close. -24- 200949040   During the formation of the water film, the circulation of the air is blocked and remains in the bath water. The sterilization device 400 becomes unable to drain. Here, the gap between the sterilizing cassette 401 and the upstream-side foreign matter removing filter is not formed by providing the water film, and the circulation of the air is not blocked, and the residual water can be removed. When the residual water is retained in the bath water sterilization device 400, since the sterilizing component is melted from the sterilizing agent in the sterilizing cartridge 401, the sterilization efficiency is lowered early. Further, if the melted high-concentration sterilizing component adheres to the laundry in the laundry, the fabric may be discolored. By draining the remaining water in the bath water sterilization device, it is possible to eliminate the problem of early decline in the efficiency of the bacteria and discoloration of the clothes. Further, the effect of removing the residual water is more effective than the securing of the gap on the side of the filter on the upstream side of the upstream side. Further, as shown in Fig. 32, the cassette cover 408 has an annular ring that rises toward the front side on the outer peripheral edge portion than the outer side surface on which the plurality of water-passing holes are provided. By the annular ring, the upstream side foreign matter removing filter 402 is received to maintain the gap between the outer side surface of the cassette cover 408 (the upstream side end surface of the sterilization cassette 40 1) by such a simple configuration. Achieve the retention of the gap. Figure 60 is a graph showing the liquidity. In the graph, when the length D4 from the upstream end surface to the downstream end surface of the sterilizing cassette 40 1 is 15 mm, the position from the downstream side passage becomes thinner until the downstream end surface of the sterilizing cassette 401. The length D3 is the amount of water flowing per unit of the sterilizing cassette 401 when the range of 〇mm to 30 mm is changed. The flow rate of this 9 L/min is the same as that of the conventional bath water supply device (strainer) which does not have a sterilizing cassette. From this graph, it can be seen that if the length D3 is shortened by -25-200949040 than the length D4 (15 mm), the amount of water flowing through the sterilizing cassette 401 is lowered. Since the bath water is supplied to the washing machine through the bath water removing device 400, the water supply time of the washing and washing is prolonged when the flow rate of the sterilizing cassette 40 1 is lowered. Here, when the relationship between the length D3 and the length D4 is D3 > D4 or D3 = D4, even if the sterilization card 401 for sterilizing the bath water is provided, it is possible to secure a conventional bath water supply device (strainer). The same amount of liquidity. Therefore, it is possible to provide a bath water sterilization device capable of removing the bath water without extending the water supply time of the washing and cleaning. The laundry thread removing device, the foreign matter collecting and deodorizing valve, and the washing and washing are described with reference to Figs. 33 to 43 and Fig. 2 and Fig. 3 . The laundry thread removing device 33 is located on the upper side of the inner tub 3, that is, below the lid portion 302 of the outer tank upper cover 300, as shown in Figs. 1 to 3 and Figs. 3 to 36. The laundry thread removing device 33 has a washing thread collecting casing 500 and a holding casing 501 for holding the laundry chip collecting casing 500 as shown in Figs. 37 to 41. The laundry chip removing device 33 is fixed to the outer tank upper cover 3 00 as shown in Fig. 36 by the holding case 501 being screwed to the lower surface of the covering portion 302. The holding case 501' is a bolt boss portion 502 having a fixing bolt as shown in Fig. 37. The laundry thread collecting casing 500 is detachably mounted to the holding casing 5〇1. The laundry thread collecting casing 500 is slidably moved back and forth in a detachable manner, and is detachably attached to the holding case 501. The laundry thread collecting casing 500' has a peripheral wall 5〇4 rising from the bottom 503 as shown in Figs. 37 and 38. The laundry thread catching cage 505, 200949040 is detachably disposed in the peripheral wall 504. The cage 506 is detachable in the laundry chip catching cage 505. The holding case 501 is a cover pressing rib 507 having a hanging. The lower end of the rib 507 is slidably abutted on the upper surface of the cage cover 506. Since the cage 506 is pressed from the upper side by the rib 507 when the laundry thread collecting casing 500 is attached to the holding casing 501, it does not fall off by the vibration of the washing operation and the inflow of the circulating washing water. The holding case 501 is an injection port 508 having injected circulating laundry water. The circulating washing water injected from the injection inlet 5 08 is injected into the inner tank 3 from the flushing port 509 through the washing thread catching cage 505. The circulating washing water flowing in from the inlet 508 has an inflow port 510 provided in the cage 506. The rinsing port 509 is formed in a circular shape and formed downward. The diameter of the circular flushing port 509 is about 19 mm, preferably 30 mm to 10 mm. The rib 5 07 also becomes a weir that guides the circulating washing water flowing from the inlet port 508 to the inflow port 510. The outflow of the circulating washing water other than the inflow port 510 is blocked by the ribs 507, so that the chips contained in the circulating washing water can be satisfactorily blocked. Since the cage 506 has a fitting groove at the lower end of the rib 507, the dam can be further favorably performed. The holding case 501 is a sealing sleeve 511 (shown in Fig. 27) provided on the lower surface in such a manner as to face the peripheral wall 504. Since the upper end of the peripheral wall 504 is tightly fitted to the sealing sleeve 511 and the flow of water is closed, the circulating washing water injected into the washing thread collecting casing 500 does not leak to other places and can be guided to the flushing port 509. -27- 200949040 The flushing port 509 is provided at the center bottom of the flushing flow chamber 540 surrounded by the circular peripheral wall 504. The flushing inflow chamber 540 has an inflow port 541 at the side. The width of the inflow port 54 is rounded and narrower than the flushing inflow chamber 540, and is about 1/4 of the diameter of the flushing inflow chamber 540. The direction of the inflow port 541 is the eccentricity of the center of the flushing port 509 and the wiring direction of the inner peripheral wall surface of the flushing inflow chamber 540. The inlet water passage 542 that is the upstream of the inflow port 541 has a shape that is narrowed toward the inflow port 541. The washing water flowing into the flushing inflow chamber 540 is rotated in the flushing inflow chamber 540 because the inflow port 541 is in the wiring direction of the inner peripheral wall surface of the flushing inflow chamber 540. Further, since the introduction water passage 542 is narrowed toward the inflow port 541, it becomes a revolving flow with a fast flow. The laundry thread collecting casing 500 has an operating lever 512 on the front side as shown in FIGS. 33 to 37 and 39 to 41. The operating lever 512 is rotatably supported by the laundry thread collecting casing 500. A groove engaging portion 513 is provided at both ends of the operating lever 512. The holding case 501 is on the front side and has a pair of protruding ribs 514 facing each other at both ends of the operating lever 512. The protruding rib 514 is provided with a locking portion 515 for locking the engaging portion 513 of the groove. The operation lever 512 has a center that is rotatably supported on the front side of the laundry chip collecting case 500, but may be provided with a pivot point at a position deviated from the center. The lever engagement means formed by the engagement portion 513 and the locking portion 515 is engaged and disengaged by the twist of the operation lever 512. The engagement is performed by rotating the operating lever 51 to the clockwise direction, and as shown in Fig. 40, the engaging portion 513 and the locking portion 515 are engaged. By engaging the rod 512' in the counterclockwise direction, the engaging portion 5?3 as shown in Fig. 4 is disengaged from the locking portion 5]. In other words, the operation lever 512' is engaged with the horizontal lever engagement means shown in Fig. 33. The operation lever engagement means is disengaged in the state shown in Figs. 34 and 35. The cleaning of the laundry thread collecting casing 500 is performed by engaging the operation lever 512 by the engagement means of the engagement of the engaging portion 513 and the locking portion 515, and the laundry thread collecting casing 500 is removed from 501 is taken off. At the end of the sweeping, the laundry thread collecting casing is attached to the holding case 501. Further, the operation lever 512 is twisted to engage the engagement portion locking portion 515, and the engagement of the laundry thread collecting casing 500 by the operation lever engagement means is performed. The operating lever 512 of the laundry thread collecting casing 500 is in the operation of the washing machine, and is restrained from being twisted so that the laundry casing 500 does not fall off. The inner lid 34 is as described above, and the lid hinges 03 of the outer tank upper lid 300 are openably and closably supported. The operation lever 512 for collecting the laundry thread is provided at a position near the lower side of the rear side of the inner cover 34 so that the front side of the inner cover 34 is raised and lowered as a fulcrum on the free side of the hinge 304 as a fulcrum (see Fig. 33 to Fig. 36). Figure shows). When the inner lid 34 is closed, as shown in Fig. 36, the lower surface of the inner lid 34 is close to the upper surface of the operating lever 512. The proximity of the lower side of the inner cover causes the twisting action of the operating lever 512 to be restrained. Rotating operation [5 out of the state, the tilting of the torsion causes the rod to engage and hold the housing 500 513 and complete the washing and drying of the thread catching 302 from the rear. The engagement of the lever engagement means on the rear side 34 of the casing 500 by the twisting action of the -29-200949040 is not released. Therefore, 'the laundry that is circulated in the inner tub 3 during the operation of the washer-dryer even if it collides with the operating lever 512', the engagement of the operating lever engagement means is not released, and the laundry chip trap casing 500 can be prevented. Natural shedding. By the opening of the inner lid 34, as shown in Figs. 33 to 35, the twisting restriction of the operating lever 512 is released, so that the engagement of the operating lever engaging means is released, and the laundry thread collecting shell can be taken. 500 is removed for sweeping. The torsion restraint of the operating lever 512 is caused by a torsion restraint mechanism (torsion restraining means) constructed in association with the opening and closing operation of the inner lid 34, and is simpler than a complicated mechanical mechanism, and only the inner cover is used. The opening and closing of the 34 can restrain/release the twisting of the operating lever 512, and it is convenient to use. In the washing machine of the above embodiment, the front side is driven upward and downward, and the rear side is rotatably supported on the outer tank cover. 300, the laundry inlet 303 is opened to close the inner lid 34; and under the outer tank upper cover 300, the laundry thread collecting casing 500 is a laundry thread removing device 33 that is detachably held in the holding casing 501. In the washing machine, the laundry thread removing device 33 is rotatably supported by the laundry thread collecting casing 500 with the center as a pivot point, and has a locking and disengaging function for holding the casing 501 by the twisting operation. The operation lever 512 and the position of the operation lever 512 in relation to the inner lid 34 are such that when the inner lid 34 is closed, the inner lid 34 approaches and restrains the twisting operation, and when the inner lid 34 is opened, the restraint is released. When the inner lid 34 is closed, the inner lid 34 approaches and restrains the operation of the twist -30-200949040, and when the inner lid 34 is opened, the restraint is released, and the position of the inner lid 34 is changed. The arrangement position of '33' can appropriately select the position of the fulcrum in which the inner cover 34 is rotatably supported. The foreign matter removal deodorizing valve and the circulation pump ' are as shown in Fig. 42 and Fig. 43. The foreign matter removing deodorizing valve 32 has a deodorizing valve casing 520 and an anti-odor valve inner casing 521. The inflow port 5 22 of the deodorizing valve housing 5 20 is in communication with the lower communication tube 41. The discharge port 523 of the deodorant valve housing 520 is in communication with the circulation pump 45. The deodorizing valve inner casing 521 has a foreign matter removing and deodorizing valve portion 524 inserted into the deodorizing valve casing 520 and a picking portion 525 provided on the front side. The pick portion 525 is gripped, and the deodorizing valve inner casing 52 1 is taken in and out of the deodorizing valve casing 520. The deodorizing valve inner casing 521 is provided with a bayonet type loading and unloading mechanism which can be attached and detached by twisting. The front side inlet and outlet of the deodorizing valve casing 520 is provided with a sealing sleeve to prevent water leakage from the joint portion with the deodorizing valve inner casing 521 to be installed. The foreign matter removing deodorizing valve portion 5 24 of the deodorizing valve inner casing 521 has a cylindrical shape having an introduction port at the rear portion and a small hole 526 at the front side peripheral portion. The foreign matter in the deodorizing valve portion 5 24 is removed from the inlet port, and the foreign matter in the deodorizing valve portion 5 24 is removed, so that the outlet is the small hole 5 26 provided in the peripheral portion of the front side, so that the odor is deodorized. Therefore, the washing water which removes the foreign matter in the circulation pump 45 is supplied with water, and the circulation pump 45 is protected from foreign matter. The circulation pump 45 has a centrifugal pump unit including a pump casing 527 and a pump flow tank 529, and a motor 530 for driving. The suction port 528 of the pump casing 527 is in communication with the foreign matter removing and deodorizing valve 32. The discharge port 53 5 of the chestnut casing 527 is in communication with the washing water circulation water passage 43. -31 - 200949040 The motor 530 is a variable speed motor driven by a DC inverter whose number of revolutions can be changed. The change in the speed of the motor 530 causes the number of revolutions of the chute groove 529 to change, which is a change in the amount of circulating washing water. Fig. 2 and Fig. 3 show the washing and washing. Rinse and wash, while washing and washing the laundry by the stirring blade 4, rinse the washing water from the laundry. The laundry which is exposed to the surface of the washing water by water saving can be cleaned without a spot by washing with a washing water while stirring. Fig. 2 is a view showing flushing washing when the amount of laundry is large, and the amount of washing water is increased by increasing the operating speed of the circulation pump 45, and is flushed from the flushing port 509 (shown in Fig. 37) in the inner tank 3. The breadth of 531 becomes larger. This rinsing 531 is formed such that the film is expanded in a conical shape and the laundry water is dispersed in the laundry existing in the vicinity of the outer periphery of the inner tub 3. The rinsing of the conical shape of the film is as described above, and the rinsing from the rinsing port 509 is generated by a rapid flow of the flow. Therefore, the breadth of the flushing is changed in accordance with the amount of supplied water supplied from the circulation port 45. Therefore, if the operation speed of the circulation pump 45 is lowered to reduce the supply amount of the washing water, the extent of the flushing 5 3 2 as shown in Fig. 3 becomes small. In the small extent produced by the flushing 532, the washing water is dispersed in the laundry present in the central portion of the inner tub 3. The wide-ranging flushing 531 is performed when the motor 530 is operated at 2,800 rpm, and the small-scale flushing 532 is performed by the motor 530 at 1600 rpm. This rinsing washing is performed by changing the supply amount of the washing water 200949040 supplied to the rinsing port 509, so that the washing water can be spread from a central portion of the inner tub 3 and a wide range near the outer periphery of the inner tub 3. Further, since it flows out from the flushing port 509 which becomes a circular shape, unlike the rain dew, the clogging of the lint does not occur. However, because of the conical washing of the film, no washing water is scattered outside the contour of the cone. Here, the rinsing washing performed in the washing operation is carried out without leaking and uniformly dispersing the washing water in the entire laundry which is present in the inner bottom of the inner tank 3. In other words, the dispersion movement of the washing water that traverses the outer circumference from the central portion of the inner tank 3 does not stop, and the distribution of the washing water can be made to the entire laundry which is present in the inner bottom of the inner tank 3 by the returning method. And uniform. Fig. 59 is a view showing an embodiment in which the dispersion of the washing water is carried out uniformly and uniformly, and the operation mode diagram of the waveform shows that the number of revolutions of the circulation pump changes with time. The number of revolutions of the circulation pump is 2800 RPM higher and 1 600 RPM lower. The amount of supply water of the washing water supplied to the flushing port 5 09 is increased at a higher number of rotations (2800 RPM). Conversely, the amount of supply water of the washing water supplied to the flushing port 50 9 in the lower number of rotations (1 600 RPM) is reduced. 〇 The increase or decrease in the amount of supplied water is switched by the return interval in 3 seconds. The switching of the number of high and low rotations is performed by the operation control of the motor 530. The shorter the number of rotations (2 800 RPM) and the lower number of rotations (1600 RPM), the shorter the time, the longer the time is less than 1 second. In this way, the amount of supply water supplied to the flushing port 509 continues to increase and decrease, and the dispersion movement of the washing water across the outer periphery from the central portion of the inner tank 3 is not -33-200949040. The dispersion of the laundry in the inner bottom of the inner tank 3 can be omitted and uniformized. Since the operation control of the motor 530 is high and low rotation, it is possible to manufacture a device without requiring complicated operation control and control means. Since the inertia of the motor 53 0 and the pumping groove and the resistance of the water inside are provided, the switching of the change in the number of revolutions of the circulating pump does not immediately respond, but is obliquely changed as shown. Therefore, it is possible to achieve a seamless and uniform laundry water dispersion by simply switching between the high and low rotation numbers. In the embodiment shown in Fig. 59, although the operation is controlled by (2 800 RPM), the lower number of rotations (1 600 RPM), and the switching is performed, but according to the inner groove, the circulation pump, the motor The capacity and the like may be suitably required in order to ensure that the entire bottom of the inner groove is not leaked and uniform, and the supply to the flushing port 509 is continuously increased and decreased, so that the central portion of the inner groove is traversed. The outer dispersion moves back and forth. The control circuit, the operation panel, and the mains of the washer-dryer will be described with reference to Figs. 44 to 46. The control circuit shown in Fig. 44 is provided with a main control circuit 600 having a main brain portion, a load drive control and power supply circuit 602, and an automatic OFF (OFF) relay AC power supply 604. In the whole, the number of the washing water is switched, and the control device that controls the number of revolutions of the circulating pump in the number of rotations of the high and low rotations has a high rotation number of three seconds (the diameter is determined by the diameter). The washing water of the washing water of the washing water of the washing machine is the microphone port making circuit 610, the device 603, the supplier 200949040 in the main control circuit 600, the load drive control circuit 601 and the power supply circuit 602 The power is supplied to the main control circuit 600 by converting the alternating current into a direct current (OFF) relay 603. The load drive control circuit 601 is connected to the water supply valve 7, and is softened. Various devices such as the treatment agent valve 605, the detergent solution valve 606, the cooling water valve 607, the drain valve 44, the washing and drying drive motor 10, the clutch 608, the lid lock mechanism 609, the electric blower 610, the circulation pump 45, and the heater 24 The load drive control circuit 601 controls the energization of various devices in accordance with an instruction from the main control circuit 600. In the main control circuit 600, the connection is: various operations are turned on. 612, water level sensor 47, temperature sensor 6 1 3, cover opening and closing sensor 6 1 4, non-volatile memory means 615, sound generation IC616, display unit of liquid crystal, etc. 6 1 7 , false notification buzzer The main control circuit 600 communicates various operation switches 612, various sensors, and non-volatile memory means 61 and information, and controls the load drive control circuit 601 and the sound generation IC 616. The main control circuit 600 is an instruction to display the various information of the error in the display unit 617 and the buzzer 618 when the error occurs. The various operation switches 612 are for inputting the operation information of the laundry and the drying, and include: The program setting switch 620 of the operation panel 611 shown in FIG. 45 and FIG. 1 and the cleaning switch 621, the cleaning switch 622, the dehydrating switch 623, and the drying switch 624, and the start/stop switch 625, and the sound The sound switch 626, the energy-saving switch 629, and the slightly-35-200949040 power supply (in) switch 627, and the power (cut) switch 62 8 are provided, and the operation panel 611 is provided with the operation panel 611. Start/one-time stop switch 625, yes The error canceling switch that stops the error notification described later. When the error cancel switch is pressed in the error notification, the buzzer 618 that notifies the occurrence of the error and the error display of the display unit 617 are released. In the operated sound generation IC 616, a speaker 630 is connected, and information on the laundry drying operation is provided from the speaker 63 0. The sound generation IC 616 of the sound generation means has the sound ROM 640 and the D/A. Inverter 641 and AMP 642. The content of the speaker 630 is constructed in the sound ROM 640, and the sound generation IC 616 is provided in accordance with the instruction of the main control circuit 600. The operation of the laundry operation shown in Fig. 46 is carried out in the order of the cleaning process 650, the cleaning 1 process 651, the cleaning 2 process 652, and the final dewatering process 65 3 until the end of the laundry operation. Thereafter, although the drying operation is advanced, it is omitted here. The cleaning process 650 is a step 650 1 of measuring the amount of cloth, a step 65 02 of cleaning the water supply, and a step 6503 of washing and stirring. The cleaning 1 process 651 includes a step 6510 of washing 1 drainage, a step 6511 of washing 1 dehydration, a step 6512 of washing 1 water supply, a step 6513 of washing 1 stirring, a step 6510 of dehydration in washing 1 , a rotation by the inner tank 3 If the amount of unbalance generated is more than the specified enthalpy, skip the step of washing 1 stirring -36-200949040 step 6513. The dehydration was interrupted here, and the agitation was changed to water injection. The cleaning 2 process 652 is a step comprising: washing 2 draining steps, washing 2 dehydrating step 6522, washing 2 water supplying step 6523, and stirring step 6524. In the step 2 of the washing 2 dehydration step 65, if the amount of unbalance generated by the rotation exceeds the predetermined enthalpy, the step of washing 2 is stirred 65 24 . The dehydration is interrupted here and the agitation is changed to water. The final dewatering process 653 is a step 653 1 comprising: a final drainage step of final dewatering. In the case where the amount of unbalance generated by the rotation of the final dehydration step 653 1, 3 is more than the prescribed enthalpy, the step 2 of washing 2 is discharged. The dewatering is interrupted here, and the cleaning 652 and the final dewatering process 653 are repeated. The amount of the cleaning process 650 originally performed for the laundry operation will be described with reference to Figs. 50 to 54. According to the amount of cloth measured by the amount of cloth, the amount of cloth is determined (the amount of laundry and the amount of washing water calculated by the laundry are used for washing. This amount of cloth is determined by the dry cloth in which the laundry is dry, so the cloth mixed with the dry cloth is thicker than the cloth of the dry cloth. More, the amount of washing and the amount of washing water will be redundant. Here, even if the wet cloth is stored, the amount of cloth can be determined without any mistake, and the washing and drying machine which does not waste the lotion and washing water. Fig. 51' shows the laundry drying The measurement of the q (vector control) of the drive motor 1値 and the amount of laundry (the amount of cloth). The white circle is the q-axis current for the amount of laundry containing the wet cloth. The black circle is for the wet cloth only. The amount of laundry of the dry cloth is q 6521, and the cleaning inner tank 3 skips the clearing into the 6530 'by the inner groove, skipping the 2 process cloth to measure the amount of material. 'Because it is judged that the shaft current system can be provided. Accumulated 値 Axis current -37- 200949040 Accumulated 値. The laundry is a small variation of the q-axis current product when the dry cloth is only dry, but the variation of the q-axis current product 値 is large when the wet cloth is mixed. Fig. 5 is a graph showing the relationship between the variation range of the measurement enthalpy change and the amount of laundry as shown in Fig. 5 is a comparison of only the dry cloth and the wet cloth. The variation range is 20 or less, and only the dry cloth is mixed with wet cloth at 20 or more. By varying the range, it can be determined that only dry cloth and wet cloth are mixed. The amount of washing water used in accordance with the amount of cloth is set by the cloth amount discriminating list table (a) shown in Fig. 53 and the cloth amount discriminating list table (b)' shown in Fig. 54. And the washing dose is also set. The cloth amount discriminating list table (a) is set so as to correspond to the amount of cloth (the amount of laundry) that is discriminated. The cloth amount discriminating list table (b) is because the wet cloth is mixed, so the laundry amount is decreased from the cloth amount of the circle mark displayed on the corresponding dotted line toward the circle mark of the corresponding point line. In this way, the amount of water (the amount of laundry of the dry cloth) which is reduced by the amount of water contained in the mixed wet cloth is set. Thereby, even if the laundry which is mixed with the wet cloth which has more laundry amount than the dry cloth is measured, since the amount of water which is subtracted from the amount of the multi-measured water due to the moisture content contained therein can be set, the washing water and the lotion can be suppressed. The superfluous use of Fig. 50 is a flow showing the discriminating of the amount of cloth. In step 660 of the start of the discriminating determination, in step 661 of the number of measurements, the number of N times is set, and the drive motor for washing and drying is started (step 662). By: taking in the q-axis current (step 663), washing 200949040 driving of the drying drive motor is stopped (step 664), N = NT1 (step 665), N = 0 (step 666), calculation of the variation width η ( Step 667) moves in the order. When the degree of change 判别 is determined to be 20 or less or more (step 668)' or less, it is determined as the cloth list table a (step 669). The above is judged as the cloth list table b (step 670). According to the individual fabrics

The recording table ' is judged by the cloth amount discriminating process (step 671) until the cloth amount is judged (step 672). In the standard operation of the drying operation, the energy-saving operation will be described with reference to Figs. 55 to 58, 44, and 45. The standard operation of the drying operation is the operation shown in (A) of Fig. 56. The energy-saving operation is the operation shown in (B) of Fig. 56. In the standard operation, the heating (drying) operation of the heater 24 (Fig. 44) is performed at the maximum (strong) heat generation, and after the completion of the drying, the cooling operation after only the air supply is completed. In the energy-saving operation, the heat-drying operation in which the heat generation amount of the heater 24 is large (strong) is first performed. When the drying is performed, the heat-drying operation in which the heat generation amount of the heater 24 is small (weak) is switched, and only the air supply is passed after the drying is completed. After the cooling operation is completed, the "figure 57" is a relationship showing the power consumption and the operation time in the standard operation. Fig. 58 is a view showing the relationship between the power consumption and the operation time during the energy saving operation. The standard operation and the energy-saving operation are almost the same in the operation time. However, when the heat generation amount of the heater 24 is reduced to half of the energy-saving operation during the power consumption, the power-saving effect can be expected. When it is close to drying in the energy-saving operation, even if it is switched to the weak heat-drying-39-200949040 operation, it is considered to be close because it uses the residual heat of the fully heated washer-dryer to perform the drying with the standard operation. Dry at standard operating hours. Figure 55 is a flow chart showing the energy saving operation. In step 680 of following the start of drying, in step 681 where the electric blower 610 is turned "ON" and the heater 24 is strong (ON), the heating and drying operation is performed. In step 682 where the cooling water is turned on (ON), the cooling water flows down from the lower portion 85 (shown in Fig. 5) to dehumidify the drying air. The initial temperature detection (step 683), the temperature detection (step 684), and the dryness calculation (step 685) are performed one by one, and the temperature and the dryness are changed to the near-drying discrimination 値D1 or more (step 686), and then switched to heating. The device 24 is weak (step 687). Next, the temperature detection (step 68 8) and the dryness calculation (step 68 9) are performed one by one, and the temperature and the dryness are determined to be the completion of the drying 値D2 or more (step 690), and the heater 24 is switched off (step 690). In step 691 of OFF), step 692 is entered in which the electric blower 610 is turned off (OFF) and the cooling water is turned off (OFF) until the end of drying (step 693). The above-described energy-saving drying operation is set by the energy-saving switch 629 provided on the operation panel 611 shown in Fig. 45. Since the energy-saving drying operation and the standard drying operation can be selected by various switches including the energy-saving switch 629, the type of laundry can be appropriately selected depending on the amount of laundry. The sound guidance, display, and the notification of the occurrence of errors caused by the sound of the operation of the washer-dryer are described with reference to Fig. 47 to Fig. 49, Fig. 40-200949040, Fig. 45, and Fig. 45. . Fig. 47 shows the flow of the operation start processing. The various operation switches 612 (shown in FIG. 45) are pressed, and the initial setting of the operation contents including the laundry drying program and the operation operation is performed (step 7〇〇), and the start/one-time stop switch 625 is pressed to start the operation (step) 701). When the operation is started, the sound switch 626 is pressed to the sound permitting state (step 702), and the sound generation IC 616 is activated, and the sound guidance of the start operation is heard from the speaker 63 0 (Fig. 44) (step 703). The operation is advanced (step 704). At the start of such operation, since the sound is started by the sound of the notification operation, it is easy for the user who is not used to perform the washing operation. In step 70, the input of the setting content change is performed at the time of the standby that has not started (step 705), and when the utterance permission state is obtained (step 706), the changed setting content is guided by the sound (step 70). 7). Since the setting contents of the laundry drying operation are guided by the sound, the contents of the laundry drying which cannot be operated from here can be confirmed by listening. Even if the surroundings are dark, the display information of the display unit 617 (shown in Fig. 45) is unsightly, and the setting contents can be surely grasped by the guidance of the sound. Fig. 49 is a flow chart showing the error processing in the laundry drying operation. In the error processing, first, it is determined whether or not the error notification state is present (step 720). In step 720, if the state of the error notification is no, the error cancellation process (step 721) is performed and the process returns. -41 - 200949040 In step 7200, when the error notification state is yes but the buzzer is not sounding (step 722), the presence or absence of the utterance permission state is determined (step 723). Thus, in step 7 22, the pronunciation permission status is sometimes the error content and the coping method is notified by the sound (step 724)' and returns after the aforementioned step 721. When the buzzer sounds in step 722 and the error cancel button is pressed by the operation of the start/time stop switch 625 (step 725), the buzzer sound is stopped (step 726), and the step 723 is performed. )go ahead. When the error cancel button is not executed in step 725, if the voice button (step 727) is input by the operation of the voice switch 626, the process proceeds to step 726 (buzzer stop is stopped). If the voice sound button is not input in step 727, if the predetermined time elapses and the buzzer sounding time is reached (step 728), the process proceeds to step 726 (buzzer sounds stop). Further, if the pronunciation permission status is none in step 723, if an error occurs, the error content and the coping method are always notified by the sound in accordance with step 724. That is, when the buzzer is sounded by the occurrence of an error, and the start/temporarily stop switch 625 is pressed, the buzzer is stopped, and then the error content and the coping method can be heard by the pronunciation of the step 724. Even if the start/stop switch 625 is not pressed, the buzzer sounds for a predetermined period of time, the buzzer is stopped, and the error content and the coping method are notified by the sound. Further, after the buzzer of the error notification is stopped, it is easy to hear the error content by the sound, and the grasp of the error content can be quickly performed. Further, when the sound is generated by the sound generating means to notify the error content, the buzzer sounds to stop -42 - 200949040, but the error display shown in the display unit 617 may be continued or stopped. The content of the sound guidance when the error occurs is as follows. (1) . (1) -1 Description of "cause", description of (1) -2 "state". (2). Description of the method of coping. (3) · The operation will be reopened even if the power is not turned off.

❹ * By processing, the operation can be reopened. (4). Description of the subsequent process (can/cannot continue). According to the above, the specifics of the sound guidance are as follows. "[ ( 1 ) -1] Because the laundry has been biased, [(1) -2], the dehydration operation is interrupted. [(3)] After pressing the stop button for a while, [(2)] will cover/inside When the cover is opened, please correct the deviation of the laundry. [(4)] Press the start button and start the operation." In addition to the sound generated by the buzzer and the notification from the display unit, the error is generated. The sound is informed of the error content and the method of coping, and the correspondence to the error resolution can be quickly performed. In particular, even if the sound sound switch 626 that requires the sound guidance is forgotten, the notification of the sound sound that has occurred in response to the error is added to the sound of the buzzer and the notification of the display unit, so the use of the washer-dryer Convenience is further improved. Further, in the case where the utterance permission state is NO in step 723, the sound guidance is not performed at all. This is because the sound guidance is set to be invalid to prevent the sound guidance from being performed. If the sound guide is set to be invalid, in the ringing and error notification of the buzzer of -43-200949040, even if the start/temporary stop switch 62 5 or the sound switch 626 is turned on (ON), the sound guide is still It is not carried out. Figure 48 is a flow of operation start processing including error information reading. In this flow, after the step 70 of the second half, since it is the same as the flow of the operation start processing described with reference to Fig. 47, the explanation of the common symbol is omitted. Next, the error information is first read in by the non-volatile memory means 615 (shown in Fig. 44) (step 73 0). Next, it is judged whether or not the error is present (step 731), and if there is no error, the process proceeds to step 700. When there is an error in step 73 1, it is judged whether or not the pronunciation permission state is present (step 732). In step 732, the pronunciation permission status is sometimes, and the error content and the coping method are notified by the sound sound (step 73 3). When the error cancel button reception (step 734) is performed, the error display and the voice sound is stopped (step 73 5), and the process proceeds to step 700. When the error cancel button reception (step 734) is not performed, the broadcast of the error content and the coping method is repeatedly notified by the sound. After the broadcast is repeated several times, the process proceeds to step 700. When the pronunciation permission status is no in step 73 2, an error is displayed on the display unit (7 3 6 ). And the buzzer is also added as needed. And, proceed to step 73 4 . BRIEF DESCRIPTION OF THE DRAWINGS - 44- 200949040 [Fig. 1] A schematic longitudinal cross-sectional view showing a washing and drying machine in accordance with an embodiment of the present invention. [Fig. 2] A diagram showing the washing and washing of a large amount of laundry when there is an embodiment of the present invention. [Fig. 3] A diagram showing the rinsing washing when the amount of laundry is small, according to an embodiment of the present invention. [Fig. 4] An external perspective view of a dehumidifying means (longitudinal path for dehumidification) of a drying mechanism according to an embodiment of the present invention. [Fig. 5] A dehumidifying means for displaying a drying mechanism is provided for an embodiment of the present invention. A perspective view of the inside of the longitudinal passage for dehumidification. [Fig. 6] A LL figure which is seen from the opposite side of Fig. 4 of the dehumidifying means (longitudinal path for dehumidification) of the drying mechanism in the embodiment of the present invention. [Fig. 7] A perspective view similar to Fig. 6 shows a view in which the window cover is removed from the lint removal window 90, in the same manner as in the sixth embodiment. [Fig. 8] A view showing an outer frame from the rear side with respect to an embodiment of the present invention. [Fig. 9] A cross-sectional view taken along line A-A of Fig. 8 showing an embodiment of the present invention. [Fig. 10] A perspective view of an embodiment of the present invention in which the outer cover is removed from the outer window and the window cover is viewed. [Fig. 11] A perspective view showing a state in which the outer window is closed by the outer cover and a correspondence relationship between the window covers, according to an embodiment of the present invention. [Fig. 12] A perspective view of the heater assembly #-45-200949040, relating to an embodiment of the present invention. [Fig. 1 3] A person having an embodiment of the present invention removes the inside of the front side assembly case from the inside of the display heater assembly. [Fig. 14] Fig. 14 is a view similar to Fig. 13 showing a view in which the fan cover is removed. [Fig. 15] An external perspective view of a drying filter (dry filter device) relating to an embodiment of the present invention. [Fig. 16] In the embodiment of the present invention, the detachment stop means is shown by a cross-sectional view of the front side frame portion of the drying filter casing. [Fig. 17] In the embodiment of the present invention, the appearance of the drying filter casing is exploded and displayed. [Embodiment 18] A cross-sectional view of the embodiment of the present invention in which a detachment stopping means is attached to a front side frame portion of a drying filter casing. [Fig. 19] In the embodiment of the present invention, the front side frame portion of the drying filter housing is shown with a detachment stop means. [Fig. 20] An exploded perspective view of the detachment stopping means of the embodiment of the present invention. [21] Fig. 21 shows a pair of engaging grooves and through holes provided in the front side frame portion of the dry filter housing, according to an embodiment of the present invention. [Fig. 22] A view of the outer tank upper cover seen from the top in the state in which the inner cover is opened, in the embodiment of the present invention. [Fig. 23] A view of the outer tank upper cover as seen from the above, in the state in which the inner cover is further opened, in the embodiment of the present invention. [Fig. 24] An embodiment of the present invention is shown with an enlarged view of the reeds around the plugs of the reeds 200949040. [Fig. 25] A perspective view showing a relationship between a conductive rubber member, an outer tank upper cover, a hinge rotating shaft, and a reed member in a state in which the inner lid is closed, according to an embodiment of the present invention. [Fig. 26] In relation to the embodiment of the present invention, the relationship between the bolt, the reinforcing frame, the conductive rubber member, the reed bolt, the outer tank upper cover, the hinge rotating shaft, and the reed member is displayed in a state where the inner cover is closed. Sectional view. [Embodiment 27] A perspective view showing a relationship between a conductive rubber member, a reed bolt, an outer tank upper cover, a hinge rotating shaft, and a reed member in a state in which the inner lid is opened. [Fig. 28] In relation to the embodiment of the present invention, the relationship between the bolt, the reinforcing frame, the conductive rubber member, the reed bolt, the outer tank upper cover, the hinge rotating shaft, and the reed member is displayed in a state where the inner cover is opened. Sectional view. [Fig. 29] A cross-sectional view of a bath water sterilization apparatus relating to an embodiment of the present invention. [Fig. 30] A cross-sectional perspective view of a bath water sterilization apparatus relating to an embodiment of the present invention. [31] An exploded perspective view of a bath water removing device in accordance with an embodiment of the present invention. [Fig. 32] An exploded perspective view of the sterilized cassette in the embodiment of the present invention. [Fig. 33] In the embodiment of the present invention, the inner lid is opened, and the positional relationship between the operation lever and the inner lid of the laundry thread removing device provided on the lower surface of the outer tank upper cover is displayed. - 47- 200949040 [Fig. 34] In the embodiment of the present invention, the inner cover is opened, and the operation lever for rotating the thread removing device is rotated in the counterclockwise direction and the engagement of the operating lever is released. [Fig. 35] With regard to an embodiment of the present invention, the inner cover is opened, showing that the operating lever of the laundry thread removing device is rotated counterclockwise and the engagement of the operating lever is released and the laundry thread is captured. The figure pulled out by the shell. [Fig. 36] A perspective view of an outer tank upper cover provided with a laundry chip removing device, as seen from below, with respect to an embodiment of the present invention. [Fig. 37] A plan view of a laundry chip removing device relating to an embodiment of the present invention. [Fig. 38] A longitudinal sectional view of a laundry chip removing device in accordance with an embodiment of the present invention. [Fig. 39] A plan view showing an operating lever of the laundry thread removing device and an operating lever engaging means in the embodiment of the present invention. [Fig. 40] A view showing a state in which the operating lever engagement means of the laundry thread removing device is engaged by a longitudinal section in the embodiment of the present invention [Fig. 41], relating to an embodiment of the present invention The state in which the operating lever engagement means of the laundry thread removing device is disengaged is shown by a longitudinal section [Fig. 42]. For the embodiment of the present invention, the foreign matter removing deodorizing valve and the longitudinal section of the circulating pump are disclosed. Figure. [Fig. 43] A longitudinal sectional view of the deodorizing valve and the circulation pump for removing foreign matter from the embodiment of the present invention shows the state in which the casing of the deodorizing valve is removed from the deodorizing valve casing. [Fig. 44] A control circuit for a washing and drying machine, relating to an embodiment of the present invention. [Fig. 45] A view showing an operation panel in which various switches and display units are arranged, according to an embodiment of the present invention. [Fig. 46] A diagram showing a process from the washing of the washer-dryer to the final dehydration, with respect to an embodiment of the present invention. [Fig. 47] A flowchart relating to the operation start processing is shown in the embodiment of the present invention. [Fig. 48] A flowchart showing an operation start process including error information reading, in the embodiment of the present invention. [Fig. 49] A flowchart showing an error processing is shown in the embodiment of the present invention. [Fig. 50] A flowchart showing the discriminating amount of the first performed laundry operation in the embodiment of the present invention. [Fig. 51] A diagram showing the relationship between the q-axis current and the amount of laundry (the amount of laundry) of the drive motor for washing and drying, according to an embodiment of the present invention. [Fig. 52] A diagram showing the relationship between the fluctuation range of the q-axis current and the amount of laundry (the amount of cloth) in the embodiment of the present invention. [Fig. 53] A diagram showing an example of the present invention, showing only the cloth amount discriminating list (dry cloth amount and set water level) of the dry cloth. [Fig. 54] A diagram showing a cloth discriminating list table (amount of laundry cloth and a set water level) in which a wet cloth is present, according to an embodiment of the present invention. [Fig. 55] A flow of the energy-saving operation in the dry operation -49-200949040 is shown in the embodiment of the present invention. [Fig. 56] A diagram showing an example of the present invention, in which the standard operation and the energy-saving operation in the drying operation are performed by energization of the heater. [Fig. 57] A diagram showing a relationship between power consumption and operation time in a standard operation in a drying operation according to an embodiment of the present invention. [Embodiment 58] A person who is an embodiment of the present invention displays a relationship between power consumption and operation time in an energy-saving operation during a drying operation. [Fig. 59] A diagram showing the relationship between the elapsed time of operation and the number of rotations of the circulation pump in the embodiment of the present invention. [Fig. 60] A graph showing the flowability of a bath water sterilization apparatus in the embodiment of the present invention. [Main component symbol description] 1 : Frame 2 : Outer groove 3 : Inner groove 4 : Stirring blade 5 : Cover 6 : Top cover 7 : Water supply valve 8 : Inflow connection 9 : Drying mechanism 1 : Washing and drying drive Motor 2〇: bottom circulation path 21: dehumidification longitudinal passage 22: warm air assembly 23: upper bellows tube 24: heater 25: connection circulation path 26: lower bellows tube 29: air supply fan 3 0: water supply pipe 31: bottom drop Inlet 32: foreign matter removal deodorizing valve 33: laundry thread removing device 200949040

34 : Inner cover 35 : 36 : Input pipe 41 : 42 : Washing water drain 43 : 44 : Drain valve 45 : 46 : Wash water circulating water longitudinal water 47 : 49 : Air pipe 50 : 70 : Dehumidification area 72 : 80 : Cooling Water supply connection port 81 : 82 : Defoaming nozzle 83 : 84 : Expansion air passage portion 85 : 86 : Drying air outlet 90 : 91 : Window cover 92 : 9 3 : Outer window 94 : 95 : External fixing bolt 100 101 Main body frame 102 103 : front side frame portion 104 106 : inflow port 107 108 : front operation panel 109 110 : detachment stop means 111 112 : press pin 113 114 = head 115 116 : recess 117 118 : locking claw 119 120 : Kapgou 200 input device lower communication pipe laundry water circulation water circulation pump water level sensor air deodorant valve cooling fin cleaning water supply connection port defoaming water supply pipe flow lower lint removal window fixing bolt external cover: drying filter device :Dry filter frame: Filter frame: Filter: Handle: Anti-slip member: Fixing member: 锷: Stop: Through hole: front side component shell -51 - 200949040 2〇1 : Side component housing 2〇4: outer casing portion 206: suction port 208: discharge port 21〇: nose portion 212: wing 3〇1: cover portion 303: inlet and outlet 3〇5: reinforcing frame 307: window 309: reed member 3Π: Reed hub 3 1 3 : Conductive rubber member 3 1 5 : Reed member 317 : Bolt 401 : Sterilization cassette 4〇3 : Downstream side foreign matter removal filter 4〇5 : Filter press 4〇7 : Round The cylinder 409: the partition 500: the laundry thread collecting casing 502: the bolt hub 504: the peripheral wall 202: the blower fan 205: the heater chamber 207: the discharge port 209: the rear side end 211: the ridge portion 300: the outer tank upper cover 302: cover portion 304: hinge 306: cover 308: bolt 310: hub portion 312: reed bolt 314: rotation shaft 3 1 6 : connection terminal 400: bath water sterilization device 402: upstream side foreign matter removal filter 404 : suction cap 406 : body hammer 408 : cassette cover 410 : pillar 501 : holding case 503 : bottom 505 : laundry thread catching cage 506 : cage cover 507 : cover pressing rib 200949040

508 : Injection port 509 510 : Inlet port 511 512 : Operating lever 513 514 : Projecting rib 515 520 : Deodorizing valve housing 521 522 : Inflow port 523 524 : Foreign matter removing deodorizing valve portion 525 526 : Small hole 527 528 : Suction port 529 530 : Motor 531 532 : Flush 535 540 : Flushing inflow chamber 541 542 : Inlet water path 600 601 : Load drive control circuit 602 603 : Automatic OFF (OFF) relay 604 605 : Soft post-treatment valve 606 607 : Cooling water valve 608 609 : Cover Locking Mechanism 610 611 : : Operating Panel 612 613 : : Temperature Sensor 614 615 : : Non-volatile Memory Means 616 617 : : Display Section 618 620 : Program Setting Switch 621 622 : Cleaning Switch 623 Flushing Port Sealing Enclosure Part of the card deodorant valve inner casing discharge port extracting pump casing pumping trough flushing spout outlet inlet main control circuit power supply circuit commercial AC power supply dissolving valve clutch electric blower operation switch cover opening and closing sensor sound sound generation 1C bee Sounder cleaning switch = dehydration switch -53- 200949040 624 : 627 : 629 : 640 : 6 42 : 65 1 : 653 : Drying switch 626 : Sound switch 628 : Switch energy saving switch 630 : Speaker sound ROM 641 : D/A converter AMP 650 : Cleaning process cleaning 1 Process 652 : Cleaning 2 process Final dehydration process -54-

Claims (1)

200949040 VII. Patent application scope: 1. A washing machine is provided with: an outer tank in which washing water and washing water are retained; and a storage tank, a vertically disposed inner tank which is rotatably built in the outer tank; and a flushing port disposed above the inner tank to disperse washing water or washing water from above the laundry; and a circulating pump for sucking up the washing water or the washing water retained in the outer tank and supplying the washing water to the flushing port And the washing water or the washing water is dispersed by rotating around the flushing port, and the amount of the supplied water supplied to the flushing port by the circulation pump is continuously returned. 2. The washing machine according to claim 1, wherein the circulation pump has a centrifugal pump unit and a motor that drives the centrifugal pump unit, and the amount of the supplied water is changed by a change in the number of rotations of the motor. 3. The washing machine of claim 2, wherein the control for changing the number of rotations of the motor is to switch between a higher number of rotations and a lower number of rotations. A washing and drying machine comprising: an outer tank in which washing water and washing water are retained; and an inner tank in which the laundry is accommodated and rotatably built in the outer tank; and the inner tank is provided in the inner tank Above, the washing water or the washing water is sprayed from the washing mouth above the laundry-55-200949040, and the washing water or the washing water retained in the outer tank is sucked up to the circulation pump supplied to the flushing port; The outer tank and the inner tank, the drying air circulation path through which the laundry in the inner tank is dried to allow drying air flowing out from the outer tank, and the drying air circulation path to be provided from the outer tank a dehumidification means for extracting moisture from the drying air; and a longitudinal passage for dehumidification provided in the drying air circulation passage; and a passage through the airflow provided at a lower end of the longitudinal passage for dehumidification and communicating with a bottom portion of the outer tank; Further, the dehumidification means is provided inside the longitudinal passage for dehumidification, and the washing water or the washing water is dispersed by rotating around the flushing port, and is characterized by The amount of water supplied to the rinse cycle of Li supplying port constantly increase or decrease in back cover. -56-