JP2018015251A - Washer dryer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a washer dryer capable of effectively removing mites and feces in a blanket and duvets, without enlarging the size of a housing.SOLUTION: In a washer dryer, control means performs a drying step with use of means for overheating air and a blower fan, and control means performs a hot air treatment step for heating dried clothing after a washing step, with use of the means for overheating air and the blower fan.SELECTED DRAWING: Figure 4

Description

  It relates to a washing and drying machine.

  In families with allergic dermatitis and asthma patients, care should be taken not only to clean the room frequently to eliminate allergens, but also to keep clothes, blankets, and futon that are in direct contact with the skin clean. ing. Since blankets and futons are in direct contact with humans for a long time, they are rich in substances that feed on mites, such as dirt and dandruff, and because they are thick, there are places to live in. It has become. Generally, blankets and futons are removed by heating and lowering humidity by drying in the sun and suction with a vacuum cleaner. However, there are more mites in the interior than the surface, and it is difficult to remove mites due to the fact that the internal temperature does not rise sufficiently when drying in the sun, and it is difficult to suck the inside with a vacuum cleaner because it is thick. It's not easy. For this reason, in order to maintain cleanliness, there is a great demand for washing and drying large items such as blankets and futons at home as much as possible. Recent laundry dryers have increased capacity, and an environment in which blankets and futons can be washed and dried at home relatively easily is being prepared.

JP-A-5-123491 Special table 2010-502357

Yoshikawa Kaoru, Studies on the ecology and control of house-dwelling mites (1) to (8), house pests, Vol. 13-Vol. 18, (1991-1995)

  According to the results of investigating the types and composition ratios of mites that live in bedding, tatami mats, carpets, and wooden floors in the house, more than 70% are house dust mites, and others are dust mites, mites, mites In addition, the number of the ceremonial family is about several percent. As damage to the human body due to mites, the development of a rash caused by being bitten by a tick of the claw mite family, the occurrence of asthma and allergic rhinitis due to dead mites and feces are known. In particular, mite faeces of the house dust mite that occupies most have particularly high allergic activity, and it is important to remove not only mites themselves but also feces. However, since feces are also abundant in the interior of the blanket or futon, they can be removed by hitting the surface and sucking with a vacuum cleaner, but sufficient removal is not easy.

  Mites can be killed by raising the temperature, and the results of experiments have been published that, when kept at 50 ° C. for 20 minutes, the most common house dust mites are killed 100% indoors. In addition, more than 99% of mites adhering to thin sheets can be removed by washing water and mechanical action, but in the case of blankets and futons, mites are inside, so washing water flow and mechanical action are not easily affected. Is said to be difficult to remove. However, mite feces as an allergen is water-soluble, and can be removed by passing water through blankets and futons. For this reason, in order to kill mites and remove mite carcasses and feces from the laundry, it is necessary to combine washing with high temperature and washing.

  As a method of washing a futon by a washing machine, there is a drum-type washing machine that suppresses the movement of cotton inside and prevents a loss of shape. In addition, there is a washing and drying machine that promotes drying of the contact surface between the drum and the futon, shortens drying time, and reduces drying unevenness. Furthermore, there is a washing machine having a miticide function that supplies hot water to a washing tub and kills mites adhering to the laundry.

  An example of a flow of operation control when a washing / drying course is set by the washing / drying machine is shown in FIG. When the power switch is turned on, the control device checks the state and executes the initial setting of the washing / drying machine (S101). When the user selects a washing / drying course and presses the start switch (S102), the control device executes a washing process (washing, rinsing, and dewatering sequentially) (S103). When the washing process is completed, a drying process (high-speed dehydration, drying with warm air) is performed (S104), and drying of the clothes is detected, or when a predetermined time has elapsed, the drying process is terminated and the operation is terminated. Thus, washing and drying are executed in order.

  When such a washing / drying machine is used and the washing / drying course is operated, tick droppings are removed by washing, and living ticks are killed by drying, but mite carcasses remain in the laundry after drying. For this reason, if you use laundry (blankets or futons), mite carcasses gradually become crushed and become fine particles, diffuse into the air from the laundry, and inhale it to cause asthma and allergic rhinitis. Can be. That is, there is a problem that allergens that cause allergies cannot be removed only by executing a normal washing and drying course. In addition, many people do not use a washing dryer to dry outside. As described above, outdoor drying does not completely kill the mites that survive the laundry, and subsequent use increases the tick droppings in the laundry.

  In the said patent document 1, the hot water supply apparatus which uses a water absorption heat generating material (synthetic zeolite) is provided, 50-60 degreeC warm water is produced | generated in a short time, and it supplies to a washing tub. However, 10 kg of synthetic zeolite is required to heat 15 L of water from 15 ° C. to 50 ° C. In the invention according to Patent Document 1, about 50 L of water is required to immerse the entire blanket or blanket in warm water in order to remove mites from the blanket or blanket. For this purpose, 30 to 40 kg of synthetic zeolite is required, and if the hot water supply device is built in the washing machine, the size of the casing increases, and there is a problem in terms of ease of installation at home. Moreover, the said patent document 2 describes invention regarding the washing machine and control method which can remove the allergen of the laundry. However, since a steam generator is required separately, the housing size may be increased.

  Accordingly, an object of the present invention is to provide a washing and drying machine that effectively removes ticks and feces such as blankets and futons and that does not increase the size of the housing.

  In order to solve such problems, as an example, the laundry dryer of the present invention is a laundry dryer, in which the control means performs a drying process using an air superheating means and a blower fan, and the control means is a laundry A hot air treatment process for heating the dry clothes after the process is executed using an air superheating means and a blower fan.

  ADVANTAGE OF THE INVENTION According to this invention, while removing mites and feces, such as blankets and futons, effectively, the washing-drying machine which does not enlarge a housing | casing size can be provided.

1 is an external view of a washing / drying machine according to an embodiment of the present invention. It is sectional drawing which shows the internal structure of the washing-drying machine of embodiment which concerns on this invention. It is a block diagram of a control device of a washing dryer of an embodiment concerning the present invention. It is a basic control flow at the time of setting a tick removal course with the washing dryer of the embodiment concerning the present invention. It is an example of the detailed control flow of the hot air heating process of the tick removal course of embodiment which concerns on this invention. It is a bird's-eye view which cut | disconnected a part of housing | casing in order to show the internal structure of the heat pump type washing-drying machine of embodiment which concerns on this invention. It is a basic control flow when a washing / drying course is set by a conventional washing / drying machine. It is a whole process chart at the time of setting a tick removal course with the washing dryer of an embodiment concerning the present invention.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is an external view of a drum-type washing and drying machine, and FIG. 2 is a cross-sectional view showing an internal structure.

  In each figure, reference numeral 1 is a casing constituting an outer shell, and the casing 1 is mounted on a rectangular base 1h, and includes left and right side plates 1a and 1b (not shown), a front cover 1c, The rear cover 1d, the upper cover 1e, and the lower front cover 1f are configured.

  The left and right side plates 1a and 1b are connected by a U-shaped upper reinforcing material, a front reinforcing material, and a rear reinforcing material (not shown above), and form a box-shaped housing 1 including a base 1h. It has sufficient strength as a housing.

  Reference numeral 9 is a door that closes an insertion port for putting in and out clothes provided in the center of the front cover 1c, and is supported by a hinge provided in the front reinforcing member so as to be opened and closed. By pulling the door opening lever 9a, the lock mechanism (not shown) is released and the door 9 is opened. When the door 9 is pressed against the front cover 1c, it is locked and closed. The front reinforcing member has a circular opening for taking clothes in and out concentrically with the opening of the outer tub described later.

  Reference numeral 2 is an operation panel provided at the upper center of the housing 1 and includes a power switch 3, operation switches 4 and 5, and a display 6, and a control device 33 provided at the lower portion of the operation panel 2 and the housing 1. Is electrically connected.

  Reference numeral 7 is a cylindrical washing / dehydrating tub (rotary drum) supported in a rotatable manner, and has a large number of through holes for water flow and ventilation on its outer peripheral wall and bottom wall, and clothing on the front end face. Is provided with an opening 7a.

  A fluid balancer 7b integrated with the washing and dewatering tub 7 is provided outside the opening 7a. A plurality of lifters 7c extending in the axial direction are provided inside the outer peripheral wall. When the washing and dewatering tub 7 is rotated during washing and drying, the clothes are lifted along the outer peripheral wall by the lifter 7c and centrifugal force, and dropped by gravity. Repeat the movements. The rotation center axis of the washing and dewatering tub 7 is inclined so that the horizontal or opening 7a side becomes higher.

  Reference numeral 8 is a cylindrical outer tub, which encloses the washing and dewatering tub 7 on the same axis, has a front surface opened, and a motor 10 is attached to the outer center of the rear end surface. The rotating shaft of the motor 10 passes through the outer tub 8 and is coupled to the washing and dewatering tub 7.

  An outer tub cover 8a is provided in the opening on the front surface, and water can be stored in the outer tub. In the center of the front side of the outer tub cover 8a, there is an opening 7a for putting clothes in and out. The opening 7a and the opening provided in the front reinforcing member are connected by a rubber bellows 11, and the outer tub 8 is sealed with water by closing the door 9.

  A drainage port 12 is provided at the bottom of the bottom of the outer tub 8 and a drainage hose 13 is connected thereto. A drainage valve 14 is provided in the middle of the drainage hose 13, and water is stored in the outer tub 8 by closing the drainage valve and supplying water, and the drainage valve is opened to discharge the water in the outer tub 8 to the outside of the machine. An overflow port 15 is provided in the outer peripheral portion of the front side of the outer tank cover 8a, and is connected to the drain hose 13 on the downstream side of the drain valve 14 with an overflow hose.

  The outer tub 8 is supported in an anti-vibration manner by a suspension 16 (consisting of a coil spring and a damper) whose lower side is fixed to the base 1h. Further, the upper side of the outer tub 8 is supported by an auxiliary spring (not shown) attached to the upper reinforcing member to prevent the outer tub 8 from falling in the front-rear direction.

  Reference numeral 17 is a detergent container provided on the upper left side in the housing 1, and a drawer-type detergent tray is mounted from the front opening. The detergent container 17 is fixed to the upper reinforcing material of the housing 1.

  On the back side of the detergent container 17, components related to water supply such as a water supply electromagnetic valve 18, a bath water supply pump, and a water level sensor (not shown above) are provided. The top cover 1e is provided with a water supply hose connection port 18a from a water tap and a water absorption hose connection port 18b for remaining hot water in the bath. The water supply electromagnetic valve 18 includes a main water supply electromagnetic valve, a finishing agent water supply electromagnetic valve, a cooling water supply electromagnetic valve, and the like. One of the detergent containers 17 is connected to the main water supply electromagnetic valve and the bath water supply pump, and the other is connected to the outer tub 8, and the detergent container 17 is opened by opening the main water supply electromagnetic valve or operating the bath water supply pump. Washing water is supplied to the outer tub 8 and the washing and dewatering tub 7 together with the detergent put in the inside. Further, by opening the finishing agent water supply electromagnetic valve, washing water is supplied to the outer tub 8 together with the softening finishing agent put in the detergent container 17.

  Reference numeral 19 is a blower passage installed vertically inside the back surface of the housing 1, and a lower portion of the blower passage is connected to an intake port 20 provided below the back surface of the outer tub 8 by a rubber bellows tube 21. A water-cooled dehumidifying mechanism (not shown) is built in the air passage 19, and the cooling water supply electromagnetic valve and the water-cooling dehumidifying mechanism are connected by a cooling water hose, and the cooling water supply electromagnetic valve is opened to open the water-cooling dehumidifying mechanism. Supply cooling water to

  The cooling water flows down along the wall surface of the air passage 19, enters the outer tub 8 from the intake port 20, and is discharged from the drain port 12. In addition to the water-cooled dehumidification, the main water supply electromagnetic valve and the air supply passage 19 are connected by a cleaning hose for cleaning the inside of the air supply passage, and the main water supply electromagnetic valve is opened to supply cleaning water into the air supply passage 19. The washing water travels along the wall surface of the air passage and removes the dust attached to the wall surface.

  The upper portion of the air passage 19 is connected to a filter duct 35 installed in the front-rear direction on the upper right side in the housing 1. An air passage switching valve is provided at the connection portion with the filter duct 35 at the upper portion of the air passage 19. The front surface of the filter duct 35 has an opening, and a drawer-type drying filter 22 is inserted into the opening.

  The air that has entered the filter duct 35 from the blower passage 19 flows into the mesh filter 22a of the drying filter 22 and the lint is removed. The dry filter 22 is cleaned by pulling out the dry filter 22 and taking out the mesh filter 22a. In addition, an opening 23 is provided in the inner surface of the insertion portion of the dry filter 22 of the filter duct 35, and the opening 23 is connected to the intake valve 23 a, and the other end of the intake valve 23 a is the intake air of the blower unit 24. Connected with mouth.

  The blower unit 24 includes a drive motor 25, a fan impeller 26, and a fan case 24a. A heater 27 is built in the fan case 24a and heats air sent from the fan impeller 26.

  The heater 27 can be switched between inputs, and the heater of this embodiment has a strong mode and a weak mode. The air blowing unit 24 is connected to the hot air duct 28. The hot air duct 28 is connected to a front outlet 30 provided in the outer tank cover 8a via a rubber bellows tube 28a and a bellows tube joint 29.

  In the present embodiment, since the blower unit 24 is provided on the upper right side in the housing 1, the front outlet 30 is provided at a position on the upper right side of the outer tank cover 8a, and the distance to the front outlet 30 is set. It is made as short as possible to minimize pressure loss and heat escape.

  A temperature sensor 34 is provided at the outlet of the drain port 12, a temperature sensor 32 is provided at the inlet of the blower unit 24, and a temperature sensor 31 is provided at the outlet of the heater 27.

  The flow of wind during the drying operation is as follows. When the blower unit 24 is operated and the heater 27 is energized, warm air blows into the washing / dehydrating tub 7 from the front blow-out port 30, hits the wet clothing, warms the clothing, and moisture evaporates from the clothing. During the drying operation, since the washing and dewatering tub 7 is rotated forward and backward, the clothes are lifted up by the lifter 7e and repeatedly fall down due to gravity, so that warm air is uniformly distributed over the clothes. The air that has become hot and humid flows from the through hole provided in the washing and dewatering tub 7 to the outer tub 8, is sucked into the air passage 19 from the air inlet 20, and flows from the bottom to the top in the air passage 19. Cooling water from the water cooling and dehumidifying mechanism flows down on the wall surface of the air passage 19, and the hot and humid air is cooled and dehumidified by coming into contact with the cooling water, and enters the drying filter 22 as dry low-temperature air. The lint is removed through the mesh filter 22 a provided in the drying filter 22 and sucked into the blower unit 24. Then, after being pressurized by the blower unit 24, it is heated again by the heater 27 and circulates so as to be blown into the washing and dewatering tub 7. A temperature sensor 32 is provided between the mesh filter 22a and the blower unit 24 to measure the temperature of the circulating air.

  FIG. 3 is a block diagram of the control device 33 of the drum type washer / dryer of this embodiment. A microcomputer 50 is connected to an operation button input circuit 51, a water level sensor, and a temperature sensor connected to the operation buttons 4 and 5, and receives various information signals in the user's button operation, washing process, and drying process. The output from the microcomputer 50 is connected to the drive circuit 54 and connected to the water supply electromagnetic valve 18, the drain valve 14, the motor 10, the blower unit 24, the heater 27, etc., and controls opening / closing, rotation, and energization thereof. Further, it is connected to a 7-segment light emitting diode or a liquid crystal display 6 or a buzzer 57 for notifying the user of the operating state of the washing / drying machine.

  When the power is turned on by pressing the power switch 3, the microcomputer 50 executes a washing and drying control process as shown in FIG. 4. FIG. 4 is an example of an operation flow of a “tick removal course” for removing mites and feces from blankets and futons.

  When the user puts the laundry, in this case, a blanket or futon into the washing and dewatering tub 7, closes the door 9, and presses the power switch 3, the microcomputer 50 checks the state of the washing / drying machine and performs initial settings (S110). The display 6 of the operation panel 2 is turned on, and a tick removal course is set according to an instruction input from the operation button 5 (S111).

  When the start button 4 on the operation panel 2 is pressed, the washing process 1 (S112) is performed. In the washing step 1, washing, rinsing, and rinsing are performed. The washing process 1 is the same as the case of washing ordinary laundry, and details will not be described. However, water and detergent are supplied into the outer tub 8, the washing and dewatering tub 7 is rotated at a low speed, and washing is performed. The washing water is drained, and the washing and dewatering tank 7 is rotated at high speed to perform dehydration. Thereafter, the rinsing water is supplied into the outer tub 8, the washing and dewatering tub 7 is rotated at a low speed to perform rinsing, the rinsing water is drained, and the washing and dewatering tub 7 is rotated at a high speed.

  In the washing step 1, water that is easy to wash enters the inside of the laundry, and tick feces in the inside dissolve in the water and are washed away. Also, some of the dead mites are washed, and legs and hair may be removed by mechanical action during rinsing and dehydration, but the torso will not be crushed. Tick carcasses are removed from the laundry along with water that has entered the laundry. In order to efficiently remove mites carcasses and feces, it is better to increase the amount of water that is easy to wash than when washing ordinary laundry. Since the moisture content of the laundry increases, carcasses and feces are easily washed and rinsed. In addition, some of the live ticks are killed during washing, or are removed from the laundry with the wash water, but many of the live ticks cling to the interior of the laundry such as blankets and futons and are easy to wash. Too much cannot be completely eliminated.

  Then, next, a hot air processing process is implemented (S113). In the hot air treatment process, the air blowing unit 24 is operated to rotate the motor 25 and the fan impeller 26 (S113A). Next, the heater 27 is energized (S113B), and while the washing and dewatering tub 7 is rotated at a predetermined rotation number (S113C), warm air is blown onto the laundry to raise the temperature of the laundry. In the heater in which the output of the heater 27 can be variable, the heater is set in a weak mode so that the temperature of the laundry does not rise too much. In the hot air treatment step, the heater 27 may be set to the strong mode in order to shorten the time in order to increase the temperature of the water-containing laundry after dehydration. However, a temperature sensor 31 is provided between the heater 27 and the front outlet 30 to detect the temperature of the hot air so that the laundry surface temperature becomes too high and damage due to the temperature does not occur. If exceeded, the heater 27 may be set to the weak mode (or OFF mode). The hot air circulates like the wind flow at the time of the drying operation described above. However, in the hot air treatment step S113, dehumidification with cooling water is unnecessary for the purpose of quickly heating the laundry.

  The rotation direction of the washing and dewatering tub 7 may be one direction or may repeat forward and reverse rotation. Further, the rotation speed of the washing and dewatering tub 7 may be varied, for example, about 40 rotations per minute and about 100 rotations per minute. Since blankets and futons are bulky, they are folded and put into the washing and dehydrating tub 7. However, since they occupy most of the volume of the washing and dehydrating tub 7, there is little movement that is lifted and dropped by the lifter 7c. Therefore, if the rotation speed of the washing / dehydrating tub 7 is increased and the centrifugal force is pressed against the wall surface of the washing / dehydrating tub 7, a space is created in the center of the laundry where hot air is difficult to reach. Therefore, the temperature of the entire laundry can be increased efficiently.

  Tick has the habit of clinging to the laundry fibers when external force is applied. For this reason, by rotating the washing and dewatering tank 7, the mites are clinged to the fibers. However, as described above, blankets and futons are bulky and have little movement to fall, so if the temperature of the laundry rises, it moves to a low temperature place such as the shadow of the outer tub 8 where hot air is difficult to go and survives. There is a possibility. Therefore, the blower unit 24 is a high-pressure type (the fan impeller is rotated at a high speed), and the area of the front blowout port 30 is reduced so that high-speed warm air from the front blowout port 30 enters the washing and dewatering tub 7. Blow out. In this way, high-speed wind hits the laundry, and mites cling to the laundry so that it is not blown away. Furthermore, high-speed hot air tends to enter the folded gap of the laundry, and the temperature rise inside the laundry rises quickly and substantially uniformly, so that mites clinging to the laundry can be efficiently killed. Dead mite carcasses lose their ability to cling to the laundry and can be efficiently removed from the laundry. Further, a large amount of warm air may be blown onto the laundry. Also in this case, warm air easily spreads to each part of the laundry, the temperature of the laundry rises substantially uniformly, and mites can be killed efficiently. After the mites have been killed, the speed of the warm air may be increased to remove the mites' dead bodies from the laundry. For this purpose, a variable mechanism for the area of the front outlet 30 is provided. That is, when the air volume is large, the area of the front air outlet 30 is increased, and when the wind speed is increased, the area of the front air outlet 30 is reduced. Moreover, you may change the rotation speed of the ventilation unit 24. FIG. In this case, the temperature of the laundry is raised and the rotational speed of the blower unit 24 is decreased until the mites are killed, and after the mites are killed, the rotational speed is increased to increase the wind speed.

  The hot air treatment process is carried out until the mites lurking in the blanket or futon are killed. Specifically, as described in Non-Patent Document 1, mites that live in the house die 100% when left at 50 ° C for 20 minutes, so the temperature of the lowest part of the laundry reaches 50 ° C. At least 20 minutes is required. The temperature of the laundry rises later than the surface directly hit by hot air, but it is difficult to detect the temperature inside. Therefore, the relationship between the warm air blowing time for the laundry (the thickest possible thing) and the internal (the slowest temperature rise) temperature is examined in advance, and the internal temperature reaches 50 ° C. after the heater 27 is energized. The time T is obtained experimentally. Then, 20 minutes may be added to the time, and 30 minutes or more may be added to make room for the hot air treatment process. Since the time T depends on the capacity of the heater 27 and the air volume of the blower unit 24, it is of course set according to the specifications of the washer / dryer.

  When the elapsed time from energization of the heater 27 becomes, for example, T + 30 minutes or more (S113D), the energization to the heater 27 and the rotation of the blower unit 24 and the washing and dewatering tub 7 are stopped, the hot air treatment process is terminated, and the washing process 2 is executed (S114). In the washing step 2, the continuation of the washing step 1 is performed. Rinsing water is supplied into the outer tub 8, the washing and dewatering tub 7 is rotated at a low speed to perform rinsing, the rinsing water is drained, and dewatering is performed to rotate the washing and dewatering tub 7 at a high speed. Carcasses of mites that have been killed in the hot air treatment process are crushed by mechanical action during rinsing and dehydration, and are removed from the laundry together with water that has entered the laundry. In addition, tick droppings remaining in the washing step 1 are also removed. This rinsing and dehydration may be performed once, but in order to remove more mite carcasses, it is better to perform it twice or more.

  A method for efficiently removing mite carcasses remaining in the laundry in the washing step 2 will be described. The first method is to increase the amount of rinse water compared to the washing step 1. As the moisture content of the laundry increases, the tick carcasses move easily into the rinse water. Further, the washing / drying machine having a washing water circulation pump mechanism in which the washing water accumulated in the bottom of the outer tub 8 is sprayed from the front side of the outer tub cover 8a onto the laundry in the washing / dehydrating tub 7 in a shower shape. Then, the water content of the laundry can be increased also by increasing the amount of water in the circulation pump of the laundry water. In this case, the mite carcasses can be efficiently moved into the rinse water without increasing the amount of rinse water. Next, the rinsing time may be lengthened. This method can also remove mite carcasses remaining in the laundry. Moreover, the rotation speed of the washing and dewatering tub 7 is set so that the fall height of the laundry is maximized (maximum mechanical force). By doing so, the tapping effect acting on the laundry is maximized, and the tick carcasses are easily removed from the laundry. The above methods may be performed alone, but performing all can maximize tick carcass removal.

  In the present embodiment, an example in which the rinsing in the washing process 2 is performed twice is described, but the above operation is performed at least once. Preferably, it should be done at the last rinse. This is because it is effective to increase the amount of water or increase the mechanical force at the last rinse to remove mite carcasses remaining in the laundry before the final rinse. Of course, it may be performed with every rinse. Note that this operation is effective not only for the removal of mite carcasses but also for removal of mite feces.

  The final dehydration may be completed in a short time when the washing / drying course is set. In the hot air treatment step (S113), not only the laundry but also parts such as the washing and dewatering tub 7 and the outer tub 8 are warmed, so that the rinse water supplied by the rinsing in the washing step 2 (S114) Water temperature rises with parts. Sebum stains adhere to the surface of the laundry (futon and blanket) as well as dirt and dandruff, but sebum stains that could not be removed in the washing process 1 are softened and removed during rinsing due to the rise in water temperature. There is also an advantage that the washing effect of the laundry is enhanced.

  When the washing process 2 is completed, a drying process is executed (S115). In the drying process, first, high-speed dewatering is performed for a predetermined time. After the dehydration is completed, the blower unit 24 is operated, the heater 27 is energized, and hot air is blown onto the laundry while rotating the washing and dehydrating tub 7. In the drying process, since the laundry contains moisture, the laundry is warmed by warm air to evaporate the moisture, resulting in hot and humid air. In order to dehumidify the water, cooling water is passed through the water-cooled dehumidifying mechanism. When the completion of drying is detected, the drying process is terminated and the operation is terminated.

  When the washing process 2 is completed, the mite feces in the laundry is almost removed, but the mite carcasses may remain. Therefore, it is better to consider so that tick carcasses can be removed even in the drying process. Increasing the speed of warm air is the most effective way to remove mite carcasses. The mite carcasses remaining in the washing process 2 are in a state where the tick legs and the fibers of the laundry are entangled. The dead body of mites can be peeled off from the laundry by the force of the wind by applying high-speed wind to the clothes. Also, as drying progresses, moisture is removed from the mite carcass, but when it dries, legs and hair can be easily removed from the mite carcass, but it becomes easier to remove by applying high-speed wind. For this reason, the body part which occupies most of the mite carcasses is easily removed from the laundry.

  It is also effective to lengthen the drying time. However, if hot air is continuously applied while the laundry is dry, the temperature of the laundry becomes too high, and thus the heater 27 may be energized intermittently in the drying process.

  The mite carcasses that have separated from the laundry in the drying process circulate with the warm air as in the wind flow during the drying operation described above. For this reason, if the size of the mesh filter 22a of the dry filter 22 is not set smaller than the size of the mite, the dead mite circulates and adheres to the laundry again. The size of the house dust mite that causes allergies is about 0.1 to 0.4 mm. For this reason, what is necessary is just to make the mesh size of a mesh filter 0.1 mm or less. However, if the aperture size is too small, there is a problem that pressure loss increases. Even considering the leg taken from the tick carcass, a minimum mesh opening size of 0.05 mm is sufficient. In addition, when using a water-cooled dehumidification method as a dehumidification method, the water filter effect of cooling water from the water-cooling dehumidification mechanism flowing through the air passage 19 removes dead mites from the flow of hot air, along with the cooling water, It can be discharged out of the machine.

  Note that the laundry may be dried outdoors or indoors without performing the drying step. Even in this case, at the end of the second washing step, the mites are killed, and many of the mite carcasses and mite feces have been removed from the laundry, thus eliminating allergens.

  Further, in the washing process 1, it is possible to kill mites even if the hot air treatment process is performed without rinsing after washing and dehydration. However, since the laundry is heated to 50 ° C. or more while containing the detergent component, there is a possibility that the detergent component may adversely affect the laundry. For this reason, as described above, it is better to execute the hot air treatment step after rinsing at least once after washing to dilute the detergent components.

  An example of the drying end detection method will be described below. Since the amount of heat exchanged with the cooling water is large when the moisture from the laundry is much evaporated, the temperature of the cooling water after the heat exchange is higher than the supply temperature. As the drying progresses, the water that evaporates decreases and the amount of heat exchange with the cooling water decreases, so the temperature of the cooling water decreases. On the other hand, the temperature of the warm air after passing through the air passage 19 is substantially constant while the evaporation of moisture is large, but becomes higher as the drying proceeds and the amount of evaporated water decreases. By detecting the temperature of the cooling water after heat exchange with the temperature sensor 34 and detecting the temperature of the warm air after passing through the air passage 19 with the temperature sensor 32, the end of drying can be detected from the temperature difference detected between the two. Alternatively, it is also possible to detect the end of drying by providing a humidity sensor between the drying filter 22 and the blower unit 24 and detecting the humidity of the circulating hot air.

  At the end of the drying process, the temperature of the laundry is close to the temperature of the warm air from the front outlet 30. As described above, since the maximum temperature of the warm air is set to 70 ° C., the temperature of the laundry also rises to near 70 ° C. For this reason, it also has the effect of disinfecting laundry.

  As described above, according to the present embodiment, washing and rinsing are first performed to remove a part of mite dung and mite carcasses, and then a hot air treatment process such as blankets and futons. Tick can be killed by heating the thick laundry to the inner depth. Thereafter, rinsing can be performed to wash away mite carcasses inside the laundry. In this way, it is possible to provide a washing / drying machine having a dedicated washing / drying course that not only cleans the surface of blankets, futons, etc., but also allows removal and sterilization of mites and feces in the interior.

In the operation flow of FIG. 4, the end of the hot air treatment process is determined by the elapsed time after the heater 27 is energized. The elapsed time is set based on the time T when the thick laundry, which is considered to have the slowest temperature rise, reaches 50 ° C. However, when the laundry is thin, the temperature of the laundry is too high, which may damage the laundry. An example of the operation flow of the hot air treatment step (S120) using the temperature sensor is shown in FIG. 5 so that the temperature of the laundry does not rise too much. The same reference numerals as those in FIG. 4 are the same operations and will not be described. Processing is branched depending on whether or not a predetermined time (for example, 20 minutes) has elapsed since the energization of the heater 27 was first stopped (S123). When the elapsed time exceeds 20 minutes, an end process is executed (S130), and the hot air processing step is ended. In the end process S <b> 130, the energization to the heater 27 is stopped, and the rotation of the blower unit 24 and the washing and dewatering tub 7 is stopped. If the elapsed time is within 20 minutes, the process proceeds to the next S124.

  The process branches depending on whether the temperature detected by the temperature sensor 31 is, for example, a threshold value of 78 ° C. or higher (S124). In the case of 78 ° C. or higher, the energization of the heater 27 is stopped while the air blowing unit 24 is operated (S131), and when a predetermined time (for example, 5 minutes) has elapsed after the energization stop (S132), the process returns to S113C and the heater is energized. The threshold value of 78 ° C. is set to prevent the laundry from being damaged by high temperature hot air. By stopping energization of the heater 27 and operating the blower unit 24, the temperature of the circulating air decreases.

  The process branches depending on whether or not the temperature detected by the temperature sensor 32 exceeds a threshold value of 55 ° C., for example (S125). When the temperature is lower than 55 ° C., the process returns to S113C and the heater 27 is energized. If it is 55 ° C. or higher, the process proceeds to S126.

  The process branches depending on whether or not a time (for example, 90 minutes) has elapsed since the start of the hot air treatment process (S126). If 90 minutes have passed, the end process is executed (S130), and the hot air process step is ended. The operation flow of FIG. 5 determines the end of the hot air treatment process based on the temperature. However, in some cases, there is a possibility that the hot air treatment process cannot be completed due to an infinite loop. Therefore, the maximum time of the hot air treatment process is set to 90 minutes in this embodiment, and when this threshold is exceeded, the hot air treatment process is forcibly terminated. The longest time may be set so that the laundry has a temperature of 50 ° C. or more and 20 minutes or more even in the worst conditions (when the laundry is clogged and the drying filter is clogged and the air volume is reduced). .

  When the elapsed time is 90 minutes or less, the energization to the heater 27 is stopped while the air blowing unit 24 is operated (S127).

  The process branches depending on whether or not 20 minutes have passed since the energization of the heater 27 was first stopped (S128). If the elapsed time exceeds 20 minutes, an end process is executed (S130), and the hot air processing step is ended. If the elapsed time is within 20 minutes, the process proceeds to S129.

  The process branches depending on whether the temperature detected by the temperature sensor 32 is lower than, for example, a threshold value of 45 ° C. (S129). If the temperature is 45 ° C. or higher, the process returns to S128, and the air blowing is continued without energizing the heater 27. If the temperature is lower than 45 ° C., the process returns to step S113C and the heater 27 is energized.

  The basic concept of this operation flow will be described. In this embodiment, when the detected temperature of the temperature sensor 32 is 50 ° C. or higher in S125, the temperature of the laundry is 55 to 60 ° C. even at the lowest place, which is enough to kill mites. Temperature. Therefore, in S127, the energization to the heater 27 is stopped, and the air blowing unit 24 is operated to circulate the warm air. For this reason, although the temperature of the circulating hot air gradually decreases, the temperature of the laundry does not rapidly decrease due to the sensible heat of the laundry, the washing / dehydrating tub 7 and the outer tub 8, and the heater 27 Even if it does not supply with electricity, 50 degreeC or more can be maintained for 20 minutes or more. Accordingly, when 20 minutes have elapsed since the energization of the heater 27 was first stopped (S128), the hot air treatment process is terminated. That is, at the time of S127, the temperature of the laundry is 50 ° C. or higher, and when the hot air treatment step S120 is completed after 20 minutes have passed, the laundry maintains a temperature of 50 ° C. or higher for 20 minutes or longer. Can kill mites completely. Thus, by stopping energization of the heater 27 during the hot air treatment process, the temperature of the laundry can be maintained at 50 ° C. or higher without using extra power. Moreover, since the temperature of the laundry does not rise more than necessary, the laundry is not damaged.

  In normal operation, the temperature detected by the temperature sensor 32 is not detected below 45 ° C. in S129. However, when the temperature of the circulating air decreases for some reason, the heater 27 is energized again to prevent the temperature of the laundry from becoming less than 50 ° C.

  The temperature threshold value described above is an example, and may be set appropriately depending on the installation position of the temperature sensor, the structure of the washing / drying machine, and the like.

  In the present embodiment, the drum type washing / drying machine has been described as an example, but a vertical washing / drying machine in which the rotation axis of the washing / dehydrating tub is substantially vertical may be used. In the case of a vertical washer / dryer, the structure is different from that of a drum-type washer / dryer. The clothes slot is opened at the top of the washing / dehydrating tub, and the washing / dehydrating tub is installed vertically and rotates around the vertical axis. . A stirring blade is provided at the bottom of the washing and dewatering tank. Usually, when it is easy to wash, the rotation from the drive motor is transmitted to the stirring blade via the planetary gear reduction mechanism, and the stirring blade is rotated. At the time of dehydration, the rotation from the drive motor is directly transmitted to the washing / dehydrating tank, and the washing / dehydrating tank and the stirring blade are rotated together. For this reason, the clutch mechanism which switches the power transmission path | route of a drive motor at the time of washing, a rinse, and dehydration is provided.

  In the case of a tick removal course, the laundry is a large item such as a blanket or a futon, and if the stirring blade is rotated when it is too easy to wash, the portion in contact with the rotating blade is damaged. For this reason, the washing and dewatering tank and the stirring blade are rotated together in the washing process, the hot air treatment process, and the drying process. The operation flow of the tick removal course is the same as that of the drum-type washing and drying machine, and the description thereof is omitted, but the same effect can be obtained.

  Moreover, although the water-cooled dehumidification method has been described as an example of the dehumidification method, an air-cooled dehumidification method or an exhaust dehumidification method may be used. The operation flow in the case of the air cooling dehumidification method is the same as that in FIG. 4 or FIG.

  In the case of the exhaust dehumidification method, the outside air is sucked by the blower unit, the laundry is warmed by the warm air heated by the heater, and the warm air that warms the laundry is exhausted outside the apparatus. For this reason, it is necessary to always heat the outside air, and the temperature of the laundry is unlikely to rise as compared with a circulation method such as a water-cooled dehumidification method. Also, if the heater is de-energized when the temperature of the laundry reaches 50 ° C. or higher, the outside air is blown onto the laundry, and the temperature of the laundry decreases at a stretch. Therefore, in the exhaust dehumidification method, until the temperature of the laundry reaches approximately 50 ° C., the heater is operated in the strong mode to increase the temperature of the laundry, and then the heater is switched to the weak mode, thereby It is good to maintain 50 degreeC or more. By carrying out like this, the allergen removal effect similar to a warm air circulation system like a water cooling dehumidification system is realizable.

  As mentioned above, although the example which used the heater as a heat source of drying was shown, what uses a heat pump type may be used.

  FIG. 6 is an external view showing an embodiment of a drum type washing and drying machine equipped with a heat pump type heat source. A part of the housing is cut so that the internal structure can be understood. The same reference numerals as those in FIG. 1 and FIG.

  A blower duct 19 is installed vertically inside the back surface of the housing 1, and a lower portion of the blower duct is connected to an intake port provided below the back surface of the outer tub 8 with a rubber bellows tube. The upper part of the air duct 19 is connected to a filter duct 35 installed in the vertical direction on the upper rear side in the housing 1. A pull-out drying filter is inserted into the filter duct 35. An evaporator 62 is installed on the downstream side of the filter duct 35, and an intake duct 38 is connected on the downstream side thereof. The other end of the intake duct 38 is connected to the intake port of the blower unit 24.

  The blower unit 27 includes a drive motor 25, a fan impeller, and a fan case 24a. The fan case 24a has a built-in condenser 63 to heat the air sent from the fan impeller. The air blowing unit 24 is connected to the hot air duct 28. The warm air duct 28 is connected to a front outlet 30 provided in the outer tank cover 8a through a rubber bellows tube 28a and a bellows tube joint 29.

  The compressor 61 is installed at the corner at the lower back of the housing 1. The refrigerant pipe exiting from the compressor 61 is connected so as to return from the condenser 63 to the compressor 61 via the evaporator 62. An expansion mechanism 64 is provided in the refrigerant pipe between the condenser 63 and the evaporator 62.

  The flow of the refrigerant in the heat pump cycle is as follows. The high-temperature and high-pressure gas compressed by the compressor 61 is heat-exchanged with air by the condenser 63. Thereafter, the refrigerant decompressed by the expansion mechanism 64 is evaporated by the evaporator 62, and the low-pressure gas is returned to the compressor 61. Here, when the refrigerant evaporates in the evaporator 62, the humid air that has passed through the filter duct 35 is cooled and dehumidified and reheated in the condenser 63.

  The air flow during the drying operation is as follows. By operating the blower unit 24 and operating the compressor 61 of the heat pump, the condenser 63 generates heat, and hot air blows into the washing and dewatering tank 7 from the front outlet 30 to hit the wet clothing and warm the clothing. Water evaporates from the clothing. The air that has become hot and humid flows from the through hole provided in the washing and dewatering tub 7 to the outer tub 8, is sucked into the air duct 19 from the air inlet, flows from the bottom to the top, and enters the filter duct 35. . The lint is removed through the mesh filter provided in the filter duct 35 and enters the evaporator 62. The hot and humid air is cooled and dehumidified by coming into contact with the low-temperature evaporator 62, becomes dry low-temperature air, enters the intake duct 38, and is sucked into the blower unit 24. Then, it is heated again by the high-temperature condenser 63 and circulates so as to blow into the washing and dewatering tub 7.

  The basic operation flow of the heat pump type is the same as that shown in FIG. Compared to the heater type, the heat pump type requires time to establish a heat pump cycle, and the temperature rise of the hot air is slow. Therefore, during the washing process 1, the compressor 61 and the air blowing unit 24 are operated at a low speed to establish a heat pump cycle and perform preheating. In the hot air treatment step, the rotation of the compressor 61 is kept high until the temperature of the hot air reaches a predetermined temperature, for example, 60 to 70 ° C. By doing so, the temperature of the laundry can be raised to 50 ° C. or higher in a relatively short time. Thereafter, the compressor 61 is rotated at a low speed to adjust the heat generation amount. This is because if the heat pump cycle stops the compressor 61, hot air cannot be immediately produced even if the compressor is started again. After the hot air reaches a predetermined temperature, the compressor 61 is turned off. It is better to keep the compressor running at low speed.

  Even in the heat pump system, the temperature of the laundry can be kept at 50 ° C. or higher for 20 minutes or more, so that mites can be killed in the same manner as the heater type, and then the washing process 2 and drying are performed, Allergens such as tick feces can be removed. In addition, since the heat pump type has a high heating capacity with a low input as compared with the heater type, it is of course excellent in energy saving.

  Next, with reference to FIG. 8, an overall process chart when a tick removal course is set in the washing / drying machine according to the embodiment of the present invention will be described.

  The washing process 1 (S112) in FIG. 4 is a washing process (S112-1) and a rinsing process 1 (S112-2). Moreover, the washing process 2 (S114) of FIG. 4 is made into the rinse process 2 (S114-2) and the final dehydration process (S114-2), and the hot air treatment process of S11 and S12 corresponds to S113 of FIG. .

  First, when a tick removal course is set, this process is executed. When the standard course is selected, the hot air processing step (S113) is not executed.

  In the detergent melt water supply step (S2), the control device 33 opens the detergent water supply electromagnetic valve (not shown) and supplies tap water to the detergent charging chamber (not shown). The tap water poured into the tray is poured into the outer tub 8 through a bellows hose (not shown) and an outer tub water supply joint while dissolving the detergent.

  In the rotation water supply step (S3), the control device 33 drives the circulation pump P while rotating the washing and dewatering tub 7 while maintaining the opening of the detergent water supply electromagnetic valve, and the wash water (high concentration water) Supply detergent while spraying washing water on clothes by circulating a detergent solution. Here, the washing and dewatering tub 7 is rotated at a predetermined rotational speed. In the pre-washing step (S4), the control device 33 washes the clothes with a high concentration detergent solution.

  In the makeup water process (S5), the control device 33 supplies water to the inside of the outer tub 8. For example, if it is a thing with high water absorption, such as towel cloth, wash water is replenished in a replenishment water process. In the main washing step (S6), the control device 33 wash the clothes while rotating the washing and dewatering tub 7 in both forward and reverse directions.

  In the draining step (S7) of the rinsing step 1 (S112-1), the control device 33 opens the drain valve and drains the washing water in the outer tub 8. In the dewatering step 1 (S8), after the drainage is completed, the control device 33 rotates the washing and dewatering tank 7 at a high speed to dehydrate the washing water contained in the clothes. In addition, the rotational speed of the inner tank 10 at the time of dehydration is set to 1000 rpm, for example.

  In the rotary shower step (S9), the control device 33 closes the drain valve V, opens the outer tank water supply electromagnetic valve, and supplies rinse water to the outer tank 8. Further, while the washing / dehydrating tub 7 is rotated, the circulation pump P is driven to spray the rinse water on the clothes in the washing / dehydrating tub 7.

  In the dehydration step 2 (S10), the control device 33 stops the circulation pump P while rotating the washing and dewatering tub 7 at a high speed to dehydrate the rinse water from the clothes.

  After the dehydration step 2 (S10), the controller 33 turns on the heater 27 and executes the hot air treatment step (S113). Then, the rinse process 2 (S114-1) is performed.

  Thus, a hot air treatment process (S113) is performed between the rinsing process 1 (S112-1) and the rinsing process 2 (S114-1). At the stage where the rinsing process 1 (S112-1) is completed, the mites are washed away from the clothing to some extent and removed. In this state, mites hidden in the back of the clothing are killed by hot air treatment and washed away in the rinsing step 2 (S114-1), so that mites can be removed more efficiently. Also, if high-speed wind is blown on the clothes while the clothes contain a lot of washing liquid, the washing liquid may flow into the tub, but since the hot air treatment process is performed after the rinsing process 1, such a risk is Absent.

  Next, the rinsing process 2 (S114-1) will be described. In the water supply step (S13), the control device 33 closes the drain valve V and opens the tank cleaning water supply electromagnetic valve to supply rinse water to the outer tank 8.

  In the finishing agent water supply step (S14), the control device 33 opens the finishing agent water supply electromagnetic valve and supplies the outer tub 8 with rinse water containing the finishing agent. The control device 33 closes the finishing agent water supply solenoid valve after finishing the finishing agent water supply.

  In the rotary water supply / replenishment water step (S15), the control device 33 opens the outer tank water supply electromagnetic valve to supply rinse water into the outer tank 8. In addition, when clothes with high water absorption are thrown in and water supply amount is insufficient, rinse water is replenished. In the rinsing and agitation step (S16), the control device 33 rotates the washing and dewatering tub 7 while rinsing water is accumulated in the outer tub 8, and rinses the clothes while agitating the clothes.

  In the final dehydration step (S114-2), the control device 33 drains (S17). After the drainage is completed, the washing and dewatering tank 7 is rotated at a high speed to dehydrate the washing water contained in the clothes (S17). In addition, the rotational speed of the inner tank 10 at the time of dehydration is set to 1000 rpm, for example.

  And a drying process (S19) is performed.

  Note that the hot air treatment step (S113) may be performed after the pre-washing step (S4) and before the main washing step (S6) (replenishing water step (S5)). Further, the hot air treatment step (S113) may be executed after the main washing step (S6) (after the dehydration step (S8) of the rinsing step 1 and before the rotary shower step (S9). Heating and activating the high-concentration detergent contained in the clothes increases the detergency and enables removal of ticks from the laundry.

  Further, the hot air treatment step (S113) may be performed after the drainage step (S7 or S17) and before the dehydration step (S8 or S18). Thereby, mites killed by the centrifugal force in the dehydration process can be effectively removed from the clothing.

  In addition, if the mechanical force applied to the clothing is effective in removing ticks, when the tick removal course is selected, the circulation flow rate of the circulation pump in the washing process and rinsing process can be increased or the tank compared to the standard course. The rotational speed may be increased (for example, 50 rpm).

  Moreover, although FIG. 8 shows an example in which the rinsing process is roughly divided into the rinsing process 1 (S112-2) and the rinsing process 2 (S114-1), and the rinsing process is performed twice in total, the present invention is not limited to this. For example, the rinsing process 1, the rinsing process 2, and the rinsing process 3 may be performed three times in total, and the hot air treatment process may be performed between the rinsing process 3 after the dehydrating process of the rinsing process 2. With this, more mites can be removed more efficiently by rinsing the mites hidden in the back of the clothes by hot air treatment and washing away in the rinsing process 3 while the mites are washed away and removed from the clothes. It becomes.

  As described above, according to the present embodiment, mites in the laundry can be killed, and further, mite carcasses and feces that cause allergies can be removed. By the way, tick feces are dissolved in washing water and ovulated outside the machine. However, there is a possibility that the dead bodies of ticks adhere to the washing / dehydrating tub or the outer tub as well as being collected by the drying filter after the drying process. If the next washing is performed as it is, the dead bodies of ticks adhere to the laundry, which is not preferable. Therefore, a step of cleaning the washing tub may be performed after the drying step. This cleaning process may be the same operation as the tank washing course mounted on the conventional washing and drying machine. However, the purpose is not to remove dirt from the washing tub, but to discharge dead mites from the machine. After washing water is stored in the washing and dehydrating tub (outer tub), the washing and dehydrating tub Rotating and washing the inner surface of the outer tub with washing water will easily move the dead mite bodies in the washing water, so a short time is sufficient.

  DESCRIPTION OF SYMBOLS 1 ... Housing, 2 ... Operation panel, 3 ... Power switch, 4, 5 ... Operation switch, 6 ... Display, 7 ... Washing and dewatering tub, 8 ... Outer tub, 9 ... Door, 10 ... Motor, 11 ... Bellows , 12 ... Drain port, 13 ... Drain hose, 14 ... Drain valve, 15 ... Overflow port, 16 ... Suspension, 17 ... Detergent container, 18 ... Water supply hose connection port, 19 ... Air passage, 20 ... Air intake port, 21 ... Bellows Pipe, 22 ... Drying filter, 23 ... Opening, 24 ... Blower unit, 25 ... Motor for driving, 26 ... Fan impeller, 27 ... Heater, 28 ... Warm air duct, 29 ... Bellows pipe joint, 30 ... Front blowout Mouth, 31 ... temperature sensor, 32 ... clothing, 33 ... control device, 50 ... microcomputer, 51 ... operation button input circuit, 57 ... buzzer, 61 ... compressor, 62 ... evaporator, 63 ... condenser, 64 ... expansion mechanism

Claims (9)

An outer tub, a washing and dewatering tub that is rotatably disposed in the outer tub and accommodates laundry, a driving means including an electric motor that drives the washing and dewatering tub, and supports the outer tub and constitutes an exterior A housing, an air passage having an outlet opening toward the washing and dewatering tub for blowing air for drying to the washing and dewatering tub, and an inlet opening toward the outer tub; and An air heating means for heating air provided in the middle, and a blower fan provided in the middle of the blower passage,
In the washing and drying machine comprising the driving means, the air heating means and the control means for controlling the blower fan, the washing step, the rinsing step, the final dehydration step,
The control means performs a drying process using the air superheating means and the blower fan,
The said control means performs the hot-air process process which heats dry clothing after the said washing process using the said air superheating means and the said ventilation fan, The washing-drying machine characterized by the above-mentioned. In the washing and drying machine according to claim 1,
The washing step has a pre-washing step and a main washing step,
The said control means performs the said hot-air process process after the said pre-washing process, and before the said main-washing process, The washing-drying machine characterized by the above-mentioned. In the washing and drying machine according to claim 1,
The rinsing step has at least a first rinsing step and a second rinsing step,
The control means executes the hot air treatment step after the dehydration step of the first rinsing step and before the second rinsing step. The washing / drying machine according to any one of claims 1 to 3,
Temperature detecting means for detecting the temperature in the housing;
The said control means controls the said air heating means and the said ventilation fan according to the temperature detection result of the said temperature detection means, The washing-drying machine characterized by the above-mentioned. In the washer / dryer according to any one of claims 1 to 4,
The air heating means comprises a heater, and the heater has a strong mode and a weak mode,
The said air heating means operates the said heater in the said strong mode in the said hot air process process, The washing-drying machine characterized by the above-mentioned. In the washer / dryer according to any one of claims 1 to 4,
In the hot air treatment process, the control means executes the hot air treatment process so that the lowest temperature in the laundry is maintained at 50 ° C. or higher for a minimum of 20 minutes. In the washing and drying machine according to claim 2,
When the temperature detection means detects that the temperature detection means is higher than a predetermined threshold, the control means turns off the air heating means or weakens the heating function. In the washing and drying machine according to claim 4,
When the control means detects that the temperature detection means is higher than a predetermined threshold, the control means turns off the air heating means,
The said control means ends the said hot-air process process when predetermined time passes, after turning off the said air heating means, The washing-drying machine characterized by the above-mentioned. In the washing and drying machine according to any one of claims 1 to 8,
In the hot air treatment process, the control means controls the driving means so as to rotate the washing and dewatering tub at a rotation speed higher than the rotation speed in the drying process.

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