JP2009077782A - Drying machine, and washing and drying machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce noise of a blowing means. <P>SOLUTION: In the drying machine having a rotary drum receiving clothes, a motor driving the rotary drum, a casing having the rotary drum therein, and the blowing unit disposed in the casing and blowing air into the rotary drum during drying operation done while rotating the rotary drum, the blowing unit has a fan case having a fan vane wheel therein, a driving motor for rotating the fan vane wheel, a central vibration preventing rubber interposed between the central site of the fan case and the central site of the driving motor, and the outer peripheral rubber interposed between the outer peripheral site of the fan case and the outer peripheral site of the driving motor with the rubber hardness of the central vibration preventing rubber keeping high and the rubber hardness of the outer peripheral vibration preventing rubber low. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a dryer or a washing dryer provided with means for drying clothes.

  Drying clothes with a washing and drying machine that can perform washing to drying continuously creates high-temperature and low-humidity air with a blower fan and a heat source, blows it into the washing tub, raises the temperature of the clothes, and moisture from the clothes By evaporating and evaporating the evaporated water.

  There are two methods for removing the evaporated water: an exhaust system that discharges it to the outside of the washing and drying machine (always supplying new air) and a dehumidification system that cools the evaporated water to condense and removes the water (circulates the same air). is there. For home use, many dehumidification methods are used so that moisture does not come into the room where the washing and drying machine is installed.

  The laundry dryer has (1) short drying time, (2) low power consumption, (3) good drying finish (low wrinkle of clothing), and (4) little damage to clothing. (5) Low operating noise is required.

  Among these, regarding (1) and (2), there is a washing and drying machine that efficiently performs drying by appropriately controlling the flow rate and temperature of air according to the progress of drying. In addition, there is a washing and drying machine that improves the movement of clothes in the washing tub and efficiently evaporates moisture from the clothes. Furthermore, there is a washing / drying machine that uses a water cooling system as a dehumidifying system to increase the efficiency of heat exchange with hot and humid hot air by allowing cooling water to flow uniformly over the wall surface of the air passage.

  Regarding (4), there is a washing and drying machine provided with a low temperature drying course in which the temperature of the warm air is limited so that the temperature of the clothes does not rise too much (the heater input is suppressed). Regarding (3), since wrinkles are generated when clothes are entangled or twisted during drying, there are washing dryers that are less likely to cause tangling or twisting of clothes. With regard to (5), the drum type washing and drying machine generates operational noise due to unbalanced rotation.

  Listed below are patent documents related to washing and drying machines.

JP 62-44299 A JP-A-9-774 JP-A-2005-080946 JP 2002-346272 A

  Even if there is no entanglement or twisting, if the amount of clothing increases with respect to the volume of the dryer, the clothing cannot spread sufficiently, so that the clothing is dried while being folded and wrinkles are generated. As an example, FIG. 13 shows a photograph of clothing (cotton pajamas trousers) when 2 kg of clothing is dried with a commercially available clothing dryer (three types of drum volumes 62L, 77L, and 99L). It can be seen that the wrinkle decreases as the drum volume increases.

  In this way, it has been known that wrinkles can be reduced as the volume increases. However, in home-use washer / dryers, washing / drying is limited due to the size of the installation location and restrictions on the delivery path (corridor and door) to the installation location. There was a limit to the size of the machine, and it was difficult to ensure a sufficient volume.

  For this reason, clothing that cares about the finish of drying is separated from other general clothing, and there is only a method of drying by reducing the amount of clothing. However, it is not realistic to perform time-consuming drying several times, and many people do not use a dryer because such clothes are dried by hanging.

  The time spent for the drying operation is longer than the washing operation time, and noise reduction in the drying operation is required. In the drying operation, the air blowing means for circulating the dry air is moved along with the rotation of the rotating drum. The air blowing means is also a source of noise.

  In view of the above-described problems, an object of the present invention is to provide a dryer or a washing dryer in which noise of a blowing unit (blower unit) is reduced.

  The present invention relates to a rotating drum in which clothing is accommodated, a motor for driving the rotating drum, a casing in which the rotating drum is placed, and a drying operation that is placed in the casing and is performed while rotating the rotating drum. In the dryer having a blower unit that blows air into the rotating drum, the blower unit includes a fan case in which a fan impeller is placed, and a drive motor that rotates the fan impeller. The fan case and the drive motor Is elastically coupled via a central anti-vibration rubber provided in the central portion and an outer peripheral anti-vibration rubber provided on the outer peripheral side.

  According to the present invention, since the fan case and the driving motor are elastically coupled via the central anti-vibration rubber and the outer peripheral anti-vibration rubber, the operation noise of the blower unit can be reduced.

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

  FIG. 1 is an external view of a drum type washing / drying machine according to an embodiment of the present invention. FIG. 2 is a perspective view showing a part of the casing cut off to show the internal structure, FIG. 3 is a rear view with the back cover removed to show the internal structure, and FIG. 4 shows the internal structure. FIG. 5 is a side view, and FIG. 5 is a plan view showing a part of the housing cut away to show the internal structure.

  Reference numeral 1 denotes a housing constituting the outer shell. The housing 1 is mounted on a base 1h, and includes left and right side plates 1a and 1b, a front cover 1c, a back cover 1d, a top cover 1e, and a lower front cover 1f. The left and right side plates 1a and 1b are joined by a U-shaped upper reinforcing material (not shown), a front reinforcing material (not shown), and a rear reinforcing material (not shown). A box-shaped housing 1 is formed and has sufficient strength as a housing.

  9 is a door which closes the insertion port for putting in and taking out the clothes provided in the approximate center of the front cover 1c, and is supported by the hinge provided in the front reinforcement material so that opening and closing is possible. When the door opening button 9d is pressed, the lock mechanism (not shown) is released to open the door, and when the door is pressed against the front cover 1c, the door is locked and closed. The front reinforcing member has a circular opening for putting clothes in and out concentrically with an opening of the outer tub described later.

  Reference numeral 6 denotes an operation panel provided in the upper center of the housing 1 and includes a power switch 39, operation switches 12 and 13, and a display 14. The operation panel 6 is electrically connected to a control device 38 provided at the lower part of the housing 1.

  3 is a cylindrical washing and dewatering tub (rotary drum) supported rotatably, having 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 An opening 3a for taking in and out is provided. A fluid balancer 3c integrated with the washing and dewatering tub 3 is provided outside the opening 3a. A plurality of lifters 3b extending in the axial direction are provided inside the outer peripheral wall. When the washing and dewatering tub 3 is rotated during washing and drying, the clothes are lifted along the outer peripheral wall by the lifter 3b and centrifugal force, and dropped by gravity. Repeat the movements. The rotation center axis of the washing and dewatering tub 3 is inclined so that the horizontal or opening 3a side becomes higher.

  Reference numeral 2 denotes a cylindrical outer tub, which coaxially encloses the washing / dehydrating tub 3, opens on the front surface, and attaches the motor 4 to the outer center of the rear end surface. The rotating shaft of the motor 4 passes through the outer tub 2 and is connected to the washing and dewatering tub 3. An outer tub cover 2d is provided at 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 2d, there is an opening 2c for taking in and out clothing. The opening provided in the main opening 2c and the front reinforcing member 37 is connected by a rubber bellows 10, and the outer tub 2 is sealed with water by closing the door 9. A drain port 2b is provided at the bottom bottom of the outer tub 2 and a drain hose 26 is connected thereto. A drain valve (not shown) is provided in the middle of the drain hose 26. Water is stored in the outer tank 2 by closing the drain valve and supplying water, and the drain valve is opened to drain the water in the outer tank 2 outside the machine. To discharge.

  The outer tub 2 is supported in a vibration-proof manner by a suspension 5 (consisting of a coil spring and a damper) whose lower side is fixed to the base 1h. The upper side of the outer tub 2 is supported by an auxiliary spring (not shown) attached to the upper reinforcing member, and prevents the outer tub 2 from falling in the front-rear direction.

  Reference numeral 19 denotes a detergent container provided on the upper left side in the housing 1, and a drawer-type detergent tray 7 is mounted from the front opening. When putting detergents, the detergent tray 7 is pulled out as shown by a two-dot chain line in FIG. The detergent container 19 is fixed to the upper reinforcing material of the housing 1.

  On the rear side of the detergent container 19, components related to water supply such as a water supply electromagnetic valve 16, a bath water supply pump 17, a water level sensor (not shown) are provided. The top cover 1e is provided with a water supply hose connection port 16a from a water tap and a water absorption hose connection port 17a for remaining hot water in the bath. The detergent container 19 is connected to the outer tub 2 and supplies washing water to the outer tub 2 by opening the water supply electromagnetic valve 16 or operating the bath water supply pump 17.

  Reference numeral 29 denotes a drying duct installed vertically inside the back surface of the housing 1, and a lower portion of the duct is connected to an intake port 2 a provided below the back surface of the outer tub 2 by a rubber bellows tube B 29 a. A water-cooled dehumidifying mechanism (not shown) is built in the drying duct 29, and cooling water is supplied from the water supply electromagnetic valve 16 to the water-cooled dehumidifying mechanism. The cooling water flows down along the wall surface of the drying duct 29, enters the outer tub 2 through the intake port 2a, and is discharged from the drain port 2b.

  The upper part of the drying duct 29 is connected to a filter duct 27 installed in the front-rear direction on the upper right side in the housing 1. The filter duct 27 has an opening on the front surface, and a drawer-type drying filter 8 is inserted into the opening. The air that has entered the filter duct 27 from the drying duct 29 flows into the mesh filter 8a of the drying filter 8, and lint is removed. Cleaning of the dry filter 8 is performed by pulling out the dry filter 8 and taking out the mesh filter 8a. In addition, an opening is provided on the lower surface of the insertion portion of the filter 9 in the filter duct 27, and the opening is connected to the intake duct 33, and the other end of the intake duct 33 is connected to the intake port of the blower unit 28. is doing.

  The blower unit 28 includes a drive motor 28a, a fan impeller (not shown), and a fan case 28b. The fan case 28b incorporates a heater 31 and heats air sent from the fan impeller. The discharge port of the blower unit 28 is connected to the hot air duct 30. The hot air duct 30 is connected to a hot air outlet 32 provided in the outer tank cover 2d through a rubber bellows tube A30a and a bellows tube joint 30b. In the present embodiment, since the blower unit 28 is provided on the upper right side in the housing 1, the hot air outlet 32 is provided at a position diagonally above and to the right of the outer tank cover 2d, and the distance to the hot air outlet 32 is set. I try to keep it as short as possible.

  Temperature sensors (not shown) are provided at the outlet 2b and the inlet and outlet of the blower unit 28.

  “Wrinkle stretching” for stretching the wrinkles of clothes that occur during washing and drying will be described.

  A high-speed wind is applied directly to the clothing, and the wrinkles generated in the clothing are stretched by the wind. For this purpose, a blower unit 28 that generates high-speed wind and a hot air outlet 32 that directly applies the wind to clothing are required. The performance required for the blower unit will be described later. Details of the hot air outlet 32 will be described with reference to FIGS. FIG. 7 is a front view of the outer tub cover 2d of the hot air outlet 28 installation portion, and FIG. 8 is a cross-sectional view of the hot air outlet 32 cut along a two-dot chain line AA in FIG.

  The hot air outlet 32 is provided along the opening 2c from the front side of the outer tub cover 2d, and flow paths 32b and 32c are formed therein. A bellows pipe joint 30b is attached to the inlet of the hot air outlet 32, and a nozzle 32d is formed at the outlet of the flow path 32c. The inner diameter of the opening 2c of the outer tub cover 2d and the inner diameter of the opening 3a of the washing / dehydration tub 3 are set to be substantially the same so that clothing does not enter between the gap between the washing / dehydration tub 3 and the outer tub cover 2d. Yes. For this reason, the outlet 32a of the hot air outlet 32 is formed so as to protrude inward from the inner peripheral surface of the opening 2c, and the nozzle 32d is opened toward the washing and dewatering tub 3. By doing in this way, the warm air which came out of the nozzle 32d can be directly applied to the clothing in the washing and dewatering tank 3.

  If the amount of protrusion of the outlet portion 32a is too large, the movement of clothing is hindered during washing or drying. Therefore, as shown in FIG. 7, the amount of protrusion is reduced by using a flat slit shape, and the opening 2c and the outlet The surface shape of the portion 32a is changed smoothly. Further, the flow path 32b and the flow path 32c are configured so that there is no useless protrusion or a sudden change in the flow direction, and the flow path area gradually decreases toward the nozzle 32d. By doing so, it is possible to reduce the pressure loss and fluid sound that occur when high-speed wind flows through the flow paths 32b and 32c.

  The flow of wind during the drying operation is as follows. When the blower unit 28 is operated and the heater 31 is energized, high-speed warm air blows into the washing and dewatering tub 3 from the nozzle 32d (arrow 41), hits the wet clothing, warms the clothing, and moisture evaporates from the clothing. The air that has become hot and humid flows from the through hole provided in the washing and dewatering tub 3 to the outer tub 2 and is sucked into the drying duct 29 from the air inlet 2a and flows from the bottom to the top in the drying duct 29 (arrow 42). Cooling water from the water cooling and dehumidifying mechanism flows down on the wall surface of the drying duct 29, and the hot and humid air is cooled and dehumidified by contacting with the cooling water, and becomes dry low temperature air and enters the filter duct 27 (arrow 43). . The lint is removed through the mesh filter 8a provided in the filter duct 27, enters the intake duct 33, and is sucked into the blower unit 28 (arrow 44). Then, it is heated again by the heater 31 and circulates so as to blow into the washing and dewatering tub 3.

  FIG. 9 is an example of the results of examining the wind speed ejected from the nozzle 32d and the finish of the clothes after drying when the drying operation as described above is performed. The wind speed and the air volume were adjusted by changing the rotation speed of the motor 28a and the area of the nozzle 32d. The wind speed is a value calculated from the result of measuring the flow pressure characteristic of the blower unit 28. The flow pressure characteristics were measured with the apparatus shown in FIG. An orifice is attached to the suction port of the pressure equalizing box and the discharge port of the blower unit 28, and the flow rate and the pressure of the intake port and the discharge port of the blower unit 28 are measured while varying the diameter of the orifice and the rotation speed of the motor 28a. The characteristics were determined. Then, the pressure of the air inlet and outlet of the air blowing unit 28 when the air blowing unit 28 is mounted on the washing / drying machine is measured, the flow rate is obtained from the above flow rate pressure characteristics, and the value obtained by dividing the flow rate by the nozzle area is the wind speed. It was.

  The experimental conditions are as shown in the figure, and the testing machine is a drum type washing and drying machine having a washing and dewatering tank having a diameter of 600 mm and a volume of 75 L, and the amount of cloth is 2 kg. Finished evaluation was performed on various garments, but the results for thin cotton pajamas trousers with the most wrinkles were shown. Although the evaluation is a five-step sensory evaluation by visual observation, an example of the finished condition with respect to the sensory evaluation value is shown in FIG. The upper nozzle is a case where the nozzle 32d is provided at the above-described position (a position obliquely above and to the right of the outer tub cover 2d), and the lower nozzle is a case where it is provided below the outer tub cover 2d. The blowing direction of the wind from the nozzle 32d was made to face substantially the center of the bottom wall of the washing and dewatering tank 3. The result is an average value of three evaluators.

From the figure, (A)-The finish improves as the wind speed increases. However, if the wind speed is too high, the finish is worsened (from the data of the upper nozzle 1.5 m ³ / min).
(B)-If the wind speed is the same, the higher the flow rate, the better the finish, but the difference between the flow rate of 1.5 m ³ / min and 1.7 m ³ / min is small.
(C)-When compared at the same wind speed and flow rate, the lower nozzle has a better finish than the upper nozzle.
I understand that. Thus, the higher the wind speed, the better the finish, but the higher the flow rate, the better. Therefore, it is desirable not to increase either one but to set the balance in consideration of the balance between the two. Specifically, not only the finish but also the current value (in the case of a commercial power supply for home use, the total of the blower unit 28, the heater 31, the motor 4, and the control device 38 is 15 A or less), the drying performance, and the duct through which the wind circulates. It is necessary to determine the wind speed and flow rate in consideration of the flow path area and the mounting on the washer / dryer.

If the sensory evaluation value is 4 or more, there is little dissatisfaction even if the clothes after drying are worn as they are. In order to obtain a sensory evaluation value of 4 or more with this experimental machine, the upper nozzle requires a flow rate of 1.5 m ³ / min and a wind speed of 90 m / s or more. However, since the finish tends to deteriorate if the wind speed is too high, it is better to suppress the wind speed to about 130 m / s at the maximum. Further, the finish is best at a wind speed of 100 to 120 m / s. In the case of the lower nozzle, a flow rate of 1.5 m ³ / min and a wind speed of 60 m / s or more are necessary. However, since the finished condition hardly changes at a wind speed of 80 m / s or more, the maximum may be about 80 m / s. The nozzle area for generating the wind speed is 190 to 280 mm ² in the case of the upper nozzle and 310 to 415 mm ² or less in the case of the lower nozzle. Accordingly, the blower unit 28 needs to have a performance that allows the flow rate to flow from the nozzle having the area. In the present embodiment, the nozzle position is the upper nozzle, the nozzle area is 250 mm ² (on the slit having a width of 50 × the height of 5 mm), and the blower unit 28 has a fan impeller diameter of 140 mm and a blade thickness of 7 mm, and the number of revolutions per minute. Driving at 16000 rpm. As a result, the fan discharge pressure is about 7500 Pa (at an air temperature of 30 ° C.), and a wind speed of about 100 m / s is obtained at a flow rate of about 1.5 m ³ / min.

  In the case of clothing that is difficult to wrinkle, a finish with a sensory evaluation value of 4 or more can be obtained even at a value lower than the above wind speed. However, it is common to dry various clothing at the same time. It is better to determine the wind speed.

  The reason why the wrinkle of clothing is reduced by applying high-speed wind to the clothing will be described with reference to FIG. FIG. 12A is a schematic diagram when the high-speed wind 41 from the nozzle 32d hits the clothing. Here, the case where there is other clothing on the back of the clothing is shown. When the wind hits the garment, the garment is forced to spread by the wind (arrow (1)), and after being struck by the garment, the direction of flow is changed and the wind flowing along the garment surface is pulled to the left and right (arrow (2)) ) Acts. The wrinkles of clothes are stretched by the force of (1) and (2). When the amount of clothes in the washing / dehydrating tub 3 is large, wrinkles are stretched mainly by the force of (1) because there are many other clothes that are difficult to move freely around the clothes directly hit by the wind. When the amount of clothing is small, the clothing moves freely, and the clothing hit by the wind looks like a windsock while being pushed in the direction of the wind, and wrinkles are caused by the force of (2) caused by the wind flowing along the surface of the clothing. Stretched. When the amount of clothing is small, the clothing spreads during drying and wrinkles are unlikely to occur, so the force (1) is considered here.

  As shown in FIG. 12B, the force F of (1) is proportional to the product of Q and V, where Q is the flow rate of the wind blown from the nozzle 32d and V is the wind speed. If the distance between the nozzle 32d and the clothing is X, the force F is proportional to V and inversely proportional to X. However, when the distance between the nozzle 32d and the clothing is very close (from the core region of the jet, from the nozzle to a position about 6 times the nozzle diameter in the case of a circular nozzle), F is proportional to V regardless of X. Therefore, in order to increase F, the flow rate Q is increased, the wind speed V is increased, or X is decreased (clothes are brought closer to the nozzle). The finishing result shown in FIG. 8 can be explained with this.

  In order to increase the flow rate Q, it is necessary to increase the rotational speed of the fan of the blower unit 28 or to increase the outer diameter or blade height of the fan. Also, it is better to reduce the pressure loss by increasing the area of the duct through which the hot air passes. In particular, in the case of the water cooling method using water for dehumidification, if the flow velocity of the air flowing through the drying duct 29 is too high, a phenomenon that the cooling water is blown off by the wind occurs. When the cooling water reaches the filter 8a or the heater 31, it leads to a significant decrease in the drying efficiency. Therefore, it is essential to increase the flow path area of the drying duct 29. For this reason, if the flow rate is significantly increased, the size of the duct and the blower unit is increased, which leads to an increase in the size of the housing 1 and makes it difficult to install the washing / drying machine at home.

  On the other hand, in order to increase the wind speed V, the air blowing unit 28 may be a pressure type to reduce the nozzle area. When a general turbofan is used as the blower unit 28, there are a method of increasing the diameter of the fan impeller at a low rotational speed and a method of increasing the rotational speed while keeping the diameter of the fan impeller small. High-speed rotation has the advantage that it can be mounted in the same housing as the conventional one.

  In the finishing test results shown in FIG. 8, when the wind speed was too high, a phenomenon in which the finishing deteriorated was observed. This cannot be explained above. Observing the movement of the clothing during the experiment, it was found that if the wind speed was too high, there was a phenomenon in which the clothing was twisted by the wind. Therefore, this is the cause of deterioration of the finish.

  In order to reduce the distance X between the nozzle 32d and the garment, the nozzle 32d may be provided near the place where the garment always passes during drying. Therefore, the position of the nozzle 32d may be provided at the position where the lifter 3b lifts the clothes, that is, the lower side of the washing and dewatering tub 3 (the lower side of the outer tub cover 2d). By providing the nozzle below, the finish can be improved even when the wind speed is about 60 m / s as shown in FIG. 8, so the pressure and flow rate of the blower unit 28 can be reduced compared to when the nozzle is above. There is an advantage that the rotational speed of the fan impeller can be reduced. Also, if the nozzle is at the bottom, the wind blowing direction and the direction of gravity are reversed. When the wind hits the garment, the garment is difficult to escape due to its own weight, and the force F acting on the garment is not attenuated, so that the finish can be further improved.

  When the nozzle 32d is provided on the lower side, the installation of the drying duct 29 and the air blowing unit 28 on the lower side of the outer tub 2 can be made compact in terms of mounting. However, since washing water at the time of washing enters from the nozzle 32d and flows into the blower unit 28, it is necessary to take measures such as providing a water entry prevention mechanism or a waterproof blower unit.

  In the present embodiment, the nozzle 32d is provided at a position obliquely above and to the right of the outer tub cover 2d, so there is no fear that the washing water will enter. In this case, it is necessary to appropriately control the number of rotations of the washing and dewatering tank 3 so that the clothes are lifted up to the vicinity of the nozzle 32d so that the wind as fast as possible hits the clothes. The clothes are lifted upward by the centrifugal force generated by the rotation of the washing and dewatering tank 3 and the lifter 3b. For this reason, the number of rotations has an optimum value according to the diameter of the washing and dewatering tub 3, and the number of rotations decreases as the diameter increases. However, there are clothes that fall quickly due to gravity, and the average nozzle-to-clothing distance is inevitably longer than when the nozzles are provided on the lower side. Therefore, as shown in FIG. Need to increase.

  Here, the detail of the ventilation unit 28 is demonstrated. FIG. 15 is a cross-sectional view of the blower unit 28. FIG. 16 is a plan view of a state where the impeller is placed with the main fan case removed. FIG. 17 is a plan view with the fan cover removed. FIG. 18 is a cross-sectional view showing the inlet and outlet of the blade 101c of the impeller 101. FIG. FIG. 19 is a sectional view of the impeller. FIG. 20 is a plan view of the impeller. FIG. 21 is a plan view with the side plate removed.

  The blower unit 28 includes a motor case 28a, a main fan case 28d containing the impeller 101, and a fan case 28b including a fan cover 28e. The fan cover 28e is provided with a bell mouth 33a having a circular opening at the center and a section having a curvature and an annular portion. The annular portion 101f of the impeller 101 and the annular shape of the bell mouth 33a are provided. It is comprised so that the part of may overlap. At this time, the annular portion of the bell mouth 33a enters inside.

  The impeller 101 includes a main plate 101b fixed to the rotating shaft 102 of the motor 28a, a blade 101c, and a side plate 101a having an opening at the center. The main plate 101b is sandwiched between the reinforcing plate 101d and the reinforcing plate 101e, and is fixed by the crimping portion 111a and the crimping portion 111b. The caulking portion 111a and the caulking portion 111b are fixed by applying force from the blade side and the opposite blade side and caulking. The side plate 101a is provided with a portion that is substantially parallel to the main plate 101b, and a bent portion 101g and an annular portion 101f that forms a suction port, which are bent in the opposite direction to the main plate 101b.

  The blade 101c is shaped so as to retreat from the inner diameter side to the outer diameter side with respect to the rotation direction 109 of the impeller 101. Such blades are generally called backward-facing blades, and those using an impeller having such a blade shape are also called turbofans. The shape in which the blade advances in the rotation direction is called a forward-facing blade, and the one using the impeller having such a blade shape is also called a sirocco fan or a multi-blade fan.

  The blade 101c has five protrusions (not shown) on both sides thereof, and is inserted into five rectangular holes (not shown) corresponding to the blades provided on the side plate 101a and the main plate 101b. Apply force from both sides to crush and fix the protrusions. If this method is performed while applying ultrasonic waves, the height when crimped can be reduced. In this embodiment, there are eight blades 101c, and all these are set on the main plate 101b and the side plate 101a before the caulking work is performed. The crimping part 110a with the innermost diameter among the crimping parts is not hung on the bent part 101g of the side plate 101a. Further, the tip of the blade 101c is also not hung on the bent portion of the side plate 101a.

  Of the impeller 101, the side plate 101a, the main plate 101b, and the blade 101c are made of metal, and in particular, aluminum is used. In this case, cemented carbide with high strength is used among aluminum. The reinforcing plate 101d and the reinforcing plate 101e are made of iron, and in this case, stainless steel that does not easily corrode is used. Although the two reinforcing plates 101d and 101e have different outer diameters, stress concentration can be alleviated when various external forces are applied.

  A spiral flow path is formed in an internal space formed by the main fan case 28d and the fan cover 28c. This spiral flow path is a scroll 106, which functions to recover the flow discharged from the impeller 101 as a static pressure while decelerating. There is a nose 107 at the outlet of the scroll 106, a nose 107a is provided on the fan cover 28c side, and a nose 107c, a slit 107d, and a nose 107e are provided on the main fan case 28b side. A heater 31 is provided downstream of the nose 107, and a discharge port 115 is provided downstream thereof.

  The main fan case 28d and the motor 28a are supported at the central portion via a vibration isolating rubber 105, and although not shown, four anti-vibration rubbers are also provided between the motor emblem 28b of the motor 28a and the main fan case. Is supported through. The anti-vibration rubber 105 also has an airtight function so as to prevent the outflow of air from the main fan case 28d.

  Next, the flow of air in the blower unit 28 will be described. When the motor 28a rotates, the impeller 101 rotates, and accordingly, air flows from the bell mouth 33a to the impeller 101 through the filter duct 27 from the intake passage 33b in the intake duct 33 as indicated by the arrow 117. To do. The high-speed air pressurized by the impeller 101 as indicated by the arrow 116 is discharged from the entire circumference of the impeller (arrow 118), collected by the scroll 106 and decelerated, and as indicated by the arrow 119, the nose 107 and the fan case. It flows downstream from the gap with 28 a, is heated by the heater 31, and is then discharged from the blower unit 28 through the discharge port 115.

The outer diameter of the impeller 101 is 140 mm, which is rotated at 16000 r / min. Under these conditions, the peripheral speed of the impeller 101 is about 117 m / s, and the output as the blower unit is about 200 W. . In order to obtain such a large output and pressure increase, it is necessary to ensure strength, and the impeller 101 is made of metal, particularly aluminum. Since aluminum has good thermal conductivity, heat generated by the motor 28a is received by the impeller 101 through the rotating shaft 102 and released from the impeller 101 into the air. As a result, the motor 28a can be cooled, and the waste heat of the motor 28a can be given to the air to increase the temperature without increasing the humidity of the dry system air.

  Further, since the strength can be ensured even if the blades 101c are thinned, the flow path between the blades can be widened even if the number of blades is increased, so that the frictional resistance of the flow in the impeller 101 can be reduced.

  Furthermore, since aluminum is easy to extend, the bent portion 101g and the annular portion 101f can be formed on the side plate 101a, so that it can be parallel to the annular portion of the bell mouth 33a and the distance from the bell mouth 33a can be increased. Since it can be made hard to receive the influence of the leak flow which flows through the clearance gap between two annular parts, it becomes difficult for the turbulent flow to enter between blades, noise can be reduced, and fluid resistance can be reduced. In addition, the gap between the two annular portions is 2 mm, but since the size of the gap can be made constant, the amount of leakage flow hardly changes when the impeller moves relative to the fan case 28b. An effect is obtained.

  Since the intake duct 33 receives the air flowing in from the drying duct 29 from the left side of FIG. 15, the flow when reaching the bell mouth 33a has a bias. Since the tip of the blade 101c of the impeller 101 is located behind the bent portion 101g, it is difficult to be influenced by the drifted flow, prevents an increase in fluid resistance, and suppresses the generation of noise due to the flow disturbance. So noise can be reduced.

  Since the exit of the blade 101c of the impeller 101 is notched in a triangular shape, the timing at which the flow from the impeller 101 flows into the nose 107 can be shifted, and the flow from the impeller 101 periodically fluctuates. Since the timing at which the gas flows into the nose 107 can be shifted, noise having a frequency that is an integral multiple of the product of the number of blades of the impeller and the number of rotations, that is, the so-called blade sound, can be reduced. Further, when the notch on the triangle is provided, it is easy to understand that when the impeller 101 is assembled, it is easy to understand that the notch comes to the outside, so that the assembly becomes easy. Although the triangular cutout is shown here, it may be inclined obliquely.

  The scroll 106 used here has an enlargement angle of 4 degrees, but a larger enlargement angle may be used if there is a margin in size. The tip of the nose 107 is formed in a straight line. The distance between the tip of the nose 107 and the impeller 101 is about 15 mm so as to reduce the increase in blade noise. In order to suppress an increase in blade noise, the nose is provided with a slit 107d to allow air to flow. Since the slit 107d can mitigate pressure fluctuations generated in the nose 107, it is highly effective in suppressing blade noise. In this embodiment, the slit has a width of 3 mm and a depth of 5 mm. Increasing the width of the slit or increasing the depth increases the effect of suppressing the blade noise, but also causes a problem that the pressure increase value decreases. It should be noted that most of the slit 107d is in a position where it does not engage with the side plate 101a of the impeller 101, so that the pressure increase value hardly decreases and the effect of suppressing the blade noise is great.

  When using a turbo fan, the flow discharged from the impeller 101 can be made lower than that of a sirocco fan, so even with a small scroll (a scroll with a small expansion angle), the amount of deceleration can be reduced and the loss can be reduced. Even in a washing and drying machine that cannot afford a large scroll, the performance can be made relatively high. Further, since the width of the impeller can be reduced, space saving can be realized. In addition, since the flow is made to fill the width of the blade 101c (vertical direction in FIG. 18), it is difficult for the air to stagnate due to separation of the flow, etc., so that fiber waste is prevented from staying and adhering to the blade 101c. There is also an advantage of being able to.

  In order to satisfy the fan discharge pressure and the air volume, it is preferable that the rotation speed of the impeller is 10,000 to 20,000 r / min, and the outer diameter of the impeller is about 120 mm to 180 mm.

  FIG. 6 is a block diagram of the control device 38 of the washing / drying machine. A microcomputer 50 is connected to the operation button input circuit 51, the water level sensor 34, and the temperature sensor 52 connected to the switches 12, 13, 13a, and various information signals in the user's button operation, washing process, and drying process. Receive. An output from the microcomputer 50 is connected to a drive circuit 54 and connected to a water supply electromagnetic valve 16, a drain valve 25, a motor 4, a blower fan 28, a heater 31, and the like, and controls opening / closing, rotation, and energization thereof. Further, it is connected to a 7-segment light emitting diode display 14, a light emitting diode 56 and a buzzer 57 for notifying the user of the operating state of the washing machine.

  The microcomputer 50 is activated when the power switch 39 is pressed and the power is turned on, and executes a basic control processing program for washing and drying as shown in FIG.

[Step S101]
Check the status of the washer / dryer and make initial settings.

[Step S102]
The indicator 14 of the operation panel 6 is turned on, and a washing / drying course is set according to an instruction input from the operation button switch 13. When no instruction is input, the standard washing / drying course or the previous washing / drying course is automatically set. For example, when an instruction is input to the operation button switch 13a, a high finishing course for drying is set.

Step S103
The process branches after monitoring the instruction input from the start switch 12 of the operation panel 6.

[Step S104]
Perform the laundry. Laundry is performed in the order of washing, intermediate dehydration, rinsing, and final dehydration. Since this is the same as a normal drum-type washing and drying machine, a detailed description thereof is omitted.

[Step S105]
The process branches after confirming whether the washing / drying course is set. When only the washing course is set, the driving is ended.

[Step S106]
When a washing / drying course is set, hot air dehydration is performed. In the hot air dehydration, the blower unit 28 is operated at a low speed, and the heater 31 is energized (strong mode) to blow warm air into the washing and dewatering tub 3 to increase the temperature of the clothes. At the same time, the washing and dewatering tub 3 is rotated at a high speed to effectively dehydrate moisture from the warmed clothes (the viscosity of the water decreases as the temperature rises so that it can be efficiently dehydrated). In the present embodiment, the rotation speed of the blower unit 28 is set to 11000 rotations per minute. This is to prevent the allowable current value (15 A) from being exceeded.

[Step S107]
Dry operation 1 is executed. The blower unit 28 operates at a low speed, the heater 31 operates in a strong mode, repeats forward / reverse rotation of the washing / dehydrating tub 3, and blows hot hot air onto the garment while changing the position of the clothing in the washing / dehydrating tub 3. . The temperature of the entire clothing rises and moisture evaporates from the clothing.

[Step S108]
Check if the high finishing course is set and branch the process. In the case of the different course of the high finish course, step S107 is performed until the drying is completed.

[Step S109]
The process branches after confirming whether the elapsed time from the start of drying has reached a predetermined time. The specified time is set before the dryness of the garment (= dry weight / wet weight) reaches 0.9.

  Drying proceeds as follows. It is important to give the garment as much heat as possible in order to raise the garment temperature quickly in the early stage of drying. During the preheating period, there is little evaporation of moisture from the clothing.

  As the temperature of the clothing rises, the evaporation of moisture from the clothing increases, so the temperature rise of the clothing becomes dull due to the heat of vaporization, and eventually the heat and the heat of vaporization balance, and the temperature of the clothing becomes almost constant (constant rate) Dry). When the moisture content of the garment decreases, the heat of vaporization decreases, and the temperature of the garment begins to rise again. When the moisture of the garment runs out, the temperature becomes almost the same as that of the warm air, and drying ends (decreasing drying). The temperature of the clothing begins to rise when the dryness reaches around 0.9.

  When the clothes contain a lot of moisture, even if the clothes are wrinkled, they can be easily repaired (it can also be seen from the fact that the wrinkled clothes can be wrinkled by spraying or steaming). However, wrinkles are fixed when drying proceeds to a dryness of 0.9 or more with wrinkles remaining. Once fixed, wrinkles can hardly be taken in subsequent processes. Therefore, it is important to stretch the wrinkles before the dryness reaches 0.9.

  At the time of actual drying, clothes of different materials and thicknesses are dried at the same time, so the time when the dryness is 0.9 varies depending on the clothes. Therefore, in this embodiment, the dryness of the thin cotton clothing that is most likely to be wrinkled is set to a time when the dryness is about 0.8 to 0.85. Moreover, since the time for the dryness to be 0.9 differs depending on the amount of cloth, it is needless to say that the time needs to be set according to the amount of cloth.

[Step S110]
Dry operation 2 is executed. While the forward / reverse rotation of the washing / dehydrating tub 3 is continued, the blower unit 28 is rotated at a high speed, the heater 31 is set in a weak mode, high-speed air is blown to the clothes in the washing / dehydrating tub 3, and drying is performed while stretching wrinkles. Do. The reason why the heater 31 is set to the weak mode when the blower unit 28 is rotated at high speed is to prevent the allowable current value from being exceeded. In the present embodiment, the rotation speed of the blower unit 28 is set to 16000 rotations per minute. The input current of the blower unit 28 at 16000 revolutions per minute is about 7 A, the heater 31 is about 6 A, and the motor 4 and the control device 38 are about 1 A.

  In this step, since the heater 31 is in the weak mode, it is lower than that in step S107. Especially when the dryness exceeds 0.9, the temperature of the clothing rises and approaches the warm air temperature, but since the warm air temperature is low, the temperature of the clothing can be kept low and damage to the clothing can be reduced. There are also benefits.

  Drying is performed while monitoring the temperature of the warm air or the cooling water drainage using a temperature sensor, and is finished when the rate of temperature change reaches a predetermined value.

  Note that the drying operation 2 of step S110 may be performed from the beginning without performing the drying operation 1 of step S107. As the amount of cloth increases, the rear and front clothing in the washing and dewatering tub 3 is less likely to be replaced, and the front clothing to which the warm air is blown dries quickly. Therefore, by operating the blower unit 38 at a high speed from the beginning, it is possible to prevent wrinkles from being quickly dried even if the drying speed varies greatly.

  As described above, according to the above-described embodiment, high-speed wind is blown directly on the clothes during the drying operation, so that the clothes are spread by the wind, and the wrinkles of the clothes are stretched, thereby realizing a dry finish with less wrinkles.

  Further, when the nozzle for blowing out the high-speed wind is provided on the upper side of the rotating drum, the wrinkle of the clothes can be efficiently stretched by setting the air volume to about 1.5 cubic meters per minute and the wind speed from 90 to 130 meters per second. Can do.

  Further, when the nozzle for blowing out the high-speed wind is provided on the lower side of the rotating drum, the wrinkle of the clothes is efficiently stretched by setting the air volume to about 1.5 cubic meters per minute and the wind speed from 60 to 100 meters per second. be able to. By blowing wind from the underside of the clothing, the force acting on the clothing increases due to the falling weight of the clothing, and wrinkles can be sufficiently stretched even at low wind speeds. Further, since the wind is blown from the lower side to the falling clothing, the clothing spreads like a parachute, so that the effect of stretching wrinkles becomes larger.

  In addition, an impeller is used as a part of the air blowing means, a front plate having a suction port and a rear plate are provided, and a blade is provided between the front plate and the rear plate, and the blade goes from the center side to the outer diameter side. Accordingly, the impeller that moves backward in the direction opposite to the rotation direction is made of metal, so that high-speed wind can be generated, and it can be realized in a small space, and noise can be reduced.

  Next, the noise reduction of the blower unit as a means for blowing air will be described with reference to FIGS.

  The blower unit shown in FIGS. 22 to 31 elastically couples a fan case and a drive motor via a central anti-vibration rubber and an outer peripheral anti-vibration rubber.

  More specifically, a central anti-vibration rubber interposed between the central part of the fan case and the central part of the driving motor, and an intermediate part between the outer peripheral side part of the fan case and the outer peripheral side part of the driving motor. A peripheral anti-vibration rubber was provided, and the rubber hardness of the peripheral anti-vibration rubber was made lower than that of the central anti-vibration rubber.

  The operation noise of the blower unit can be reduced by elastic coupling with the central anti-vibration rubber and the outer peripheral anti-vibration rubber.

  In the embodiment of the blower unit that achieves this noise reduction, differences from the previous embodiment will be mainly described in detail. The parts common to the previous embodiment are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIGS. 23 and 24, the blower unit 200 includes a fan case 202 in which a fan impeller 201 is placed, a drive motor 204 that rotates the fan impeller 203, a central portion of the fan case 202, and a drive motor 204. A central anti-vibration rubber 205 interposed between the central portion and an outer peripheral anti-vibration rubber 206 interposed between the outer peripheral portion of the fan case 202 and the outer peripheral portion of the driving motor 204.

  The central anti-vibration rubber 205 has a high rubber hardness, and the outer anti-vibration rubber 206 has a low rubber hardness. The central anti-vibration rubber 205 is made of NBR and has a rubber hardness of about 30 to 50 degrees. The outer peripheral anti-vibration rubber 206 is made of silicon rubber and has a rubber hardness of about 10 to 30 degrees.

  Whereas one central anti-vibration rubber 205 is provided, plural (four) outer anti-vibration rubbers 206 are provided at equal intervals as shown in FIG. The central anti-vibration rubber 205 and the outer peripheral anti-vibration rubber 206 are made of heat-resistant rubber that can withstand the high temperatures that rise during the drying operation.

  The fan case 202 has a main fan case 202d and a fan cover 202e. The fan case 202 is configured by fitting the outer periphery of the main fan case 202d and the fan cover 202e. The main fan case 202d and the fan cover 202e are made of heat resistant synthetic resin.

  The fan cover 202e located on the opposite side of the drive motor 204 has a suction opening 202j at the central portion. The fan impeller 201 is a turbo fan, and sucks air in the direction of the rotation axis from the opening 202j of the fan cover 202e and discharges it in the outer peripheral direction by the high-speed rotation described above.

  The drive motor 204 has a rotating shaft 204a that extends through the center of the main fan case 202d and extends into the fan case 202, and fixes and supports the fan impeller 201. The rotating shaft 204a is rotatably supported by bearings (not shown) provided on both ends of the housing case 204b of the driving motor 204.

  At both ends of the housing case 204b, annular recesses 204c formed concentrically outside the rotating shaft 204a are provided. A bearing (not shown) placed at the center of both ends in the housing case 204b is fixedly supported on the inner side of the housing case 204b in the recess 204c.

  As shown in FIGS. 23 and 24, the central anti-vibration rubber 205 is fitted and held in the recess 204c. As shown in FIGS. 25 to 27, the central anti-vibration rubber 205 includes an annular base portion 205a, a plurality of support ridges 205b arranged radially on the base portion 205a, and a plurality of support ridges 205b. It has annular rings 205c and 205d to be connected.

  Since the center of the support ridge 205b rises high, the center annular ring 205c stands higher than the outer annular ring 205d. The central anti-vibration rubber 205 is reliably held stably by fitting a plurality of high central ridges 205b connected by the annular rings 205c and 205d into the recess 204c.

  The central anti-vibration rubber 205 includes an annular base portion 205a, a plurality of ridges 205b arranged radially on the base portion 205a, and annular rings 205c and 205d that connect the plurality of ridges 205b. For this reason, the central anti-vibration rubber 205 is rich in elasticity and excellent in the anti-vibration function as compared with a lump of anti-vibration rubber packed inside, although the central anti-vibration rubber 205 is formed of rubber having high rubber hardness.

  The central anti-vibration rubber 205 is provided at a central through hole 205e through which the rotation shaft 204a passes in the center, and a peripheral edge of the central through hole 205e (periphery facing the driving motor 204), and a motor that contacts the driving motor 204 A side annular airtight projection 205f is provided. The motor-side annular airtight projection 205f abuts on the driving motor 204, and the airtightness with the driving motor 204 is maintained.

  Further, the central anti-vibration rubber 205 is provided on the annular base portion 205a and has a plurality (three) of fan case side annular airtight protrusions 205g that abut against the main fan case 202d of the fan case 202. The plurality (three) of fan case side annular airtight projections 205g are provided concentrically with the central through hole 205e, and abut against the main fan case 202d to keep the fan case 202 airtight.

  Thus, airtightness is maintained by the fan case side annular airtight projection 205g and the motor side annular airtight projection 205f. For this reason, air leakage from a gap passing through the main fan case 202d and around the rotating shaft 204a is prevented despite a large pressure with the atmospheric pressure (large in the case of a turbofan). .

  Further, due to the suction action of the fan impeller 201, the central anti-vibration rubber 205 is subjected to a compressive force in the axial direction of the rotating shaft 204a. For this reason, the airtightness of the fan case side annular airtight protrusion 205g and the motor side annular airtight protrusion 205f is further promoted, and the airtightness performance is improved.

  The central anti-vibration rubber 205 has an engagement foot 205h that engages with the main fan case 202d in an annular base portion 205a. The engagement foot 205h of the central anti-vibration rubber 205 engages with the main fan case 202d, and the plurality of raised ridges 205b of the central anti-vibration rubber 205 are engaged with the recess 204c, so that the fan case 202 and the drive motor 204 Constrain the positional relationship.

  The state in which the center positions of the fan case 202 and the driving motor 204 are aligned is maintained by the restraint by the central anti-vibration rubber 205.

  As shown in FIGS. 23, 24, and 28, the drive motor 204 has a support rod 207 on the outer periphery. The outer peripheral anti-vibration rubber 206 is attached to and supported by the support rod 207. The outer peripheral anti-vibration rubber 206 has a ring groove 206a on the outer periphery. A ring groove 206 a is fitted into a support hole 207 a provided in the support rod 207, and the outer peripheral antivibration rubber 206 is attached to and supported by the support rod 207.

  The interposed member 206b is placed so as to be interposed between the ring groove 206a and the support hole 207a. The interposition member 206b has a cylinder part and a collar part provided at the upper end of the cylinder part. The interposition member 206b prevents deformation of the outer peripheral antivibration rubber 206 made of soft silicon rubber and prevents cutting at the edge of the support hole 207a.

  The outer peripheral anti-vibration rubber 206 has a through hole 206c penetrating the center in the axial direction (direction facing the fan case 202). The set screw 208 is threaded into the screw boss 202i provided in the main fan case 202d through the through hole 206c. By tightening the set screw 208, the driving motor 204 is fastened to the fan case 202, and the blower unit is assembled.

  The heat insulating sheet 209 is interposed between the screw boss 202 i and the outer peripheral vibration isolating rubber 206. This heat insulating sheet 209 suppresses heat transmitted from the fan case 202 to the drive motor 204.

  The operation and effect of the central anti-vibration rubber 205 and the outer peripheral anti-vibration rubber 206 will be described.

  The blower unit elastically joins the central portion of the fan case 202 and the central portion of the driving motor 204 with a central rubber vibration isolator 205 having a high rubber hardness, and the outer peripheral side portion of the fan case 202 and the outer periphery of the driving motor 204. It is characterized by a combined configuration of a fan case and a driving motor in which the side portions are elastically joined by the outer peripheral vibration-proof rubber 206 having a low rubber hardness.

  Since the central part of the fan case 202 and the central part of the driving motor 204 are elastically joined by the central rubber vibration isolator 205 having a high rubber hardness, even if an impact load due to the weight of the driving motor 204 acts during transportation. The central positions of the fan case 202 and the driving motor 204 are securely supported without being displaced.

  Further, even if the strong suction action of the fan impeller 201 in the drying operation acts in the axial direction of the rotating shaft 204a, it is elastically supported by the central vibration-proof rubber 205 having a high rubber hardness, so that the movement in the axial direction is suppressed. It is done. For this reason, the fan impeller 201 is prevented from contacting the fan case 202.

  The driving motor 204 is vibrated by a residual unbalanced centrifugal force including the fan impeller 201, but the movement in the radial direction is restricted by a plurality of outer peripheral vibration isolating rubbers 206 arranged on the outer peripheral side portion. For this reason, the vibration due to the residual unbalanced centrifugal force changes to butterfly vibration with the central anti-vibration rubber 205 as a fulcrum as shown by the dotted line in FIG. Since this butterfly vibration has a large amplitude on the outer peripheral side, vibration transmission is suppressed by gently supporting the butterfly vibration with the outer peripheral anti-vibration rubber 206 having a low rubber hardness.

  That is, the outer periphery anti-vibration 206 is supported on the outer peripheral portion of the driving motor 204 to the extent that it is not bent. As a result, a large displacement is restrained by a force proportional to the displacement, but almost no force is generated for the slight vibration. Therefore, no vibration is transmitted to the fan case 202, and noise reduction of the air blowing means (air blowing unit) is achieved.

  FIG. 30 and FIG. 31 are graphs showing the frequency of noise of the blowing means (fan unit) and the measured values of the noise level.

  FIG. 31 shows measured values when both the central anti-vibration rubber and the outer peripheral anti-vibration rubber have a rubber hardness of 40. FIG. 30 shows measured values when the central anti-vibration rubber has a rubber hardness of 40 degrees and the outer anti-vibration rubber has a rubber hardness of 10 degrees. By reducing the rubber hardness of the outer peripheral anti-vibration rubber, the noise of the 250 Hz component was reduced from 55 dB to 39 dB, making it easy to hear.

  Next, an embodiment relating to a silencer will be described with reference to FIGS.

  Note that portions common to the first embodiment described above are denoted by the same reference numerals and description thereof is omitted, and portions relating to the silencer are mainly described.

  FIG. 32 is a plan view when a silencer is attached to the fan cover 28e. 33 is a cross-sectional view taken along line EE in FIG. 32 when the fan cover 28e and the fan case 28b are attached. FIG. 34 is a cross-sectional view of the silencer 301a.

  A heater 33 is attached to the fan cover 28e of the blower unit 28 as a means for blowing air, and silencers 301a and 301b are attached near the discharge port 115 thereof. The silencers 301a and 302b have the same size, a circular cross-sectional shape, a tube diameter of 13 mm, and a center length of 46 mm. One end of the pipes of the silencers 301a and 301b has an open end 306 and is connected to the outside of the silencer. Further, the other end is closed, and a slope portion 307 having an inclination of 45 degrees is formed. The two silencers are integrally formed and are screwed to the fan cover 28e.

  The flow that flows out of the impeller 101 is collected by the scroll 106, flows between the nose 107 a, the fan cover 28 e, and the fan case 28 b, then is heated when passing through the heater 33, flows downstream, and discharge outlet 115 It flows further downstream. The silencers 301a and 301b are placed in this flow path, and their open ends face toward the discharge port 115, in other words, in the downstream direction of the flow. The two silencers are arranged substantially parallel and the length of the tube is larger than the cross-sectional dimension of the tube.

  Although the fan case 28b is not greatly bent on the downstream side of the heater 33, the fan cover 28e is bent in a direction away from the fan case 28b on the downstream side of the heater 33. The silencers 301a and 301b are arranged so as to be housed in the bent portions.

  This silencer has a standing wave inside, and the sound pressure distribution is a standing wave having a mode in which the sound pressure is maximum at the closed end face and the sound pressure is minimum near the open end 306. Since this is exactly ¼ of the wavelength, it is a resonance type silencer also called a ¼ wavelength tube. Therefore, when the frequency at which the sound is to be silenced is determined, the tube length is determined from the sound speed. Since this type of silencer has a narrow frequency range in which noise is extinguished, it needs to be set according to the usage conditions and the usage conditions. In this embodiment, the length of the tube is set to 46 mm, and the above-described blade noise is set to be extinguished under the operating conditions during drying.

  Since the open ends of the silencers 301a and 301b are directed to the downstream side of the flow, the whistling sound due to the airflow is hardly generated. Further, since the silencer main body is placed in the flow path, it is not necessary to make holes for mounting on the wall surfaces of the fan cover 28e and the fan case 28b, so that air leakage does not occur. Furthermore, since the silencer main body is housed in the flow path having a large area and the open end thereof is located near the discharge port 115 having a small area, the silencing effect can be increased.

  Although the cross-sectional shape of the silencer is circular, it may be composed of an ellipse or a rectangle. Furthermore, the inclined portion 307 is provided and the closed end is inclined. This is because the frequency range in which the effect is obtained experimentally is larger, and the silencing effect at the resonant frequency is obtained. However, this is to make it easier to obtain an effect when the resonance frequency (frequency at which the effect is obtained) changes due to a change in sound speed due to a temperature change during drying. Of course, the closed end face may be vertical.

  The silencer is composed of two parts 301a and 302b. This is to prevent the increase in flow resistance by placing the silencer on the peripheral edge of the flow path by constructing the two silencers. It is effective to make the sound wave in the silencer operate as a plane wave by reducing the cross-sectional area. Moreover, installation is facilitated by providing a screwing portion between the two. The number of silencers can be one or more. In this embodiment, the two have the same shape, but the length may be changed with the two so that the effect can be obtained at different frequencies.

The main features of the embodiment described above are listed below.
(1). A rotating drum for storing clothing, a motor for driving the rotating drum, a housing for placing the rotating drum, and a rotating drum that is placed in the housing and is rotated while the rotating drum is being rotated. In the dryer having a blower unit that blows air, the blower unit includes a fan case in which a fan impeller is placed, a drive motor that rotates the fan impeller, a central part of the fan case, and a central part of the drive motor A central anti-vibration rubber interposed between the outer peripheral side portion of the fan case and an outer peripheral side portion of the driving motor, and the rubber hardness of the central anti-vibration rubber And the rubber hardness of the outer peripheral antivibration rubber is lowered.
(2). The fan case has a suction opening in a central portion on the opposite side of the drive motor, and the fan impeller is a turbo fan that sucks in a rotation axis direction and discharges in an outer peripheral direction. .
(3). One central anti-vibration rubber is provided, and a plurality of the outer peripheral anti-vibration rubbers are provided at equal intervals.
(4). The driving motor has a rotating shaft that passes through the fan case and fixes and supports the fan impeller, and the central vibration-proof rubber includes a central through hole through which the rotating shaft passes and a central through hole. A motor-side annular hermetic protrusion is provided on the periphery and keeps airtight with the driving motor by contacting the driving motor.
(5). The drive motor has a rotating shaft that passes through the fan case and fixes and supports the fan impeller, and the central vibration-proof rubber includes a central through hole through which the rotating shaft passes, and the central through hole A plurality of fan case-side annular airtight protrusions are provided concentrically and are in contact with the fan case to maintain airtightness with the fan case.
(6). The drive motor has a rotating shaft that passes through the fan case to fix and support the fan impeller, and an annular recess formed concentrically on the outer side of the rotating shaft. A plurality of support ridges arranged radially and fitted in the recess, and an annular ring connecting the support ridges.
(7). The outer periphery anti-vibration rubber has a through-hole penetrating the center toward the fan case,
It has a set screw inserted into the through hole, screwed to the fan case, and fastened to the fan case by the drive motor.
(8). The driving motor has a support rod provided on the outer periphery and a support hole provided in the support rod, and the outer peripheral vibration isolating rubber is provided on the outer periphery, and has a ring groove into which the support hole fits, An interposition member is provided between the ring groove and the support hole.
(9). The outer periphery anti-vibration rubber is formed of silicon rubber.
(10). The central anti-vibration rubber has a rubber hardness of about 30 to 50 degrees, and the outer anti-vibration rubber has a rubber hardness of about 10 to 30 degrees.
(11). A rotating drum for storing clothing, a motor for driving the rotating drum, a housing for placing the rotating drum, and a rotating drum that is placed in the housing and is rotated while the rotating drum is being rotated. In the washer / dryer having a blower unit that blows air, the blower unit includes a fan case in which a fan impeller is installed, a drive motor that rotates the fan impeller, a central portion of the fan case, and a center of the drive motor A central anti-vibration rubber interposed between the outer peripheral side portion of the fan case and an outer peripheral side portion of the driving motor; The hardness is high, and the rubber hardness of the outer peripheral anti-vibration rubber is low.
(12). The fan case has a suction opening in a central portion on the opposite side of the drive motor, and the fan impeller is a turbo fan that sucks in a rotation axis direction and discharges in an outer peripheral direction. .
(13). One central anti-vibration rubber is provided, and a plurality of the outer peripheral anti-vibration rubbers are provided at equal intervals.
(14). The driving motor has a rotating shaft that passes through the fan case and fixes and supports the fan impeller, and the central vibration-proof rubber includes a central through hole through which the rotating shaft passes and a central through hole. A motor-side annular hermetic protrusion is provided on the periphery and keeps airtight with the driving motor by contacting the driving motor.
(15). The drive motor has a rotating shaft that passes through the fan case and fixes and supports the fan impeller, and the central vibration-proof rubber includes a central through hole through which the rotating shaft passes, and the central through hole A plurality of fan case-side annular airtight protrusions are provided concentrically and are in contact with the fan case to maintain airtightness with the fan case.
(16). The drive motor has a rotating shaft that passes through the fan case to fix and support the fan impeller, and an annular recess formed concentrically on the outer side of the rotating shaft. A plurality of support ridges arranged radially and fitted in the recess, and an annular ring connecting the support ridges.
(17). The outer periphery anti-vibration rubber has a through hole penetrating through the center toward the fan case, inserted into the through hole, screwed to the fan case, and a set screw for fastening the driving motor to the fan case It is characterized by having.
(18) The drive motor has a support rod provided on an outer periphery and a support hole provided on the support rod, and the outer peripheral vibration isolating rubber is provided on the outer periphery and has a ring groove into which the support hole fits. And an interposition member is provided between the ring groove and the support hole.
(19). The outer periphery anti-vibration rubber is formed of silicon rubber.
(20) The central anti-vibration rubber has a rubber hardness of about 30 to 50 degrees, and the outer anti-vibration rubber has a rubber hardness of about 10 to 30 degrees.
(21). In a dryer having a rotating drum for storing clothes, a motor for driving the rotating drum, and a casing for supporting the rotating drum, and performing a drying operation, air is blown into the rotating drum during the drying operation. And a silencer is provided near the discharge port of the means.
(22). A washing / drying machine having a rotating drum for storing clothes, a motor for driving the rotating drum, and a casing for supporting the rotating drum, and having a drying operation. A means for blowing air is provided, and a silencer is provided near the discharge port of the means.

It is an external view which concerns on the Example of this invention and shows a drum type washing-drying machine. FIG. 4 is a perspective view showing an internal structure by cutting a part of the casing of the drum type washing machine according to the embodiment of the present invention. It is a back view which removes the back cover of a drum type washing machine and shows an internal structure concerning the Example of this invention. It is a side view which concerns on the Example of this invention and shows the internal structure of a drum type washing machine. FIG. 5 is a top view showing an internal structure of the drum type washing machine according to the embodiment of the present invention by cutting an upper part of the housing. FIG. 3 is a block diagram of a control system of the washing / drying machine shown in FIG. 2 according to the embodiment of the present invention. It is a front view of the outer tank cover which concerns on the Example of this invention and provided the warm air blowing outlet. FIG. 8 is an AA cross-sectional view of the hot air outlet in FIG. 7 according to the embodiment of the present invention. It is based on the Example of this invention, and is an experimental result of the sensory evaluation value of the finish of the clothing after a wind speed and drying. It concerns on the Example of this invention, and is an apparatus which measures the flow volume pressure characteristic of a ventilation unit. It is a photograph which relates to the example of the present invention and relates to the example of the present invention, and shows the sensory evaluation value and the finish of clothing. FIG. 4 is a schematic diagram when a high-speed wind blown from a nozzle hits clothing according to the embodiment of the present invention. It is a photograph which concerns on the Example of this invention, and shows an example of the drum volume of a clothes dryer, and the clothing finishing state after drying. FIG. 7 is a flowchart according to the embodiment of the present invention and showing a part of control processing executed by a microcomputer in the controller of the control system shown in FIG. 6. FIG. 4 is a cross-sectional view of the blower unit 28 according to the embodiment of the present invention. It is a top view of the state which concerns on the Example of this invention and put the impeller in the state which removed the main fan case. It is a top view of the state which concerns on the Example of this invention and removed the fan cover. FIG. 4 is a cross-sectional view illustrating an inlet / outlet of a blade 101c of an impeller 101 according to an embodiment of the present invention. It concerns on the Example of this invention, and is sectional drawing of an impeller. It concerns on the Example of this invention, and is a top view of an impeller. It is a top view of the impeller which concerns on the Example of this invention and removed the side plate. It concerns on the other Example of this invention, and is the top view which looked at the ventilation unit from the drive motor. It concerns on the other Example of this invention, and is AA sectional drawing of FIG. FIG. 23 is a partially enlarged view of FIG. 22 according to another embodiment of the present invention. FIG. 6 is a front view of a central anti-vibration rubber according to another embodiment of the present invention. FIG. 6 is a side view of a central anti-vibration rubber according to another embodiment of the present invention. It concerns on the other Example of this invention, and is AA sectional drawing of FIG. FIG. 25 relates to another embodiment of the present invention and is an enlarged view of a part (peripheral vibration isolating rubber) of FIG. It is a figure which concerns on the other Example of this invention, and shows the vibration mode of a ventilation unit. FIG. 5 is a graph showing the noise of the air blowing means (air blowing unit) and the measured value of the noise level (the central anti-vibration rubber and the outer anti-vibration rubber both have a rubber hardness of 40) according to another embodiment of the present invention. is there. According to another embodiment of the present invention, the noise of the air blowing means (air blowing unit) is measured for the frequency and noise level (the rubber hardness of the central anti-vibration rubber is 40 degrees, and the rubber hardness of the outer anti-vibration rubber is 10). It is the graph which showed degree. FIG. 10 is a plan view when a silencer is attached to a fan cover according to another embodiment of the present invention. It concerns on the other Example of this invention, and is EE sectional drawing of FIG. It concerns on the other Example of this invention, and is sectional drawing of a silencer.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Housing | casing, 2 ... Outer tank, 2d ... Outer tank cover, 3 ... Washing and dewatering tank, 4,28a ... Motor, 6 ... Operation panel, 8 ... Drying filter, 9 ... Door, 16 ... Water supply solenoid valve, 27 ... Filter duct, 28 ... Air blow unit, 28b ... Fan case, 28d ... Main fan case, 28e ... Fan cover, 29 ... Drying duct, 31 ... Heater, 32 ... Hot air outlet, 32d ... Nozzle, 33 ... Intake duct, 33a ... Bell mouth, 38 ... Control device, 101 ... Impeller, 105 ... Anti-vibration rubber, 106 ... Scroll, 107 ... Nose, 200 ... Blower unit, 201 ... Fan impeller, 202 ... Fan case, 204 ... Drive motor 205 ... Central anti-vibration rubber, 206 ... Outer peripheral anti-vibration rubber, 115 ... Discharge port, 301a, 301b ... Silencer.

Claims (6)

A rotating drum for storing clothes, a motor for driving the rotating drum, a casing for placing the rotating drum, and a rotating drum that is placed in the casing and rotates while rotating the rotating drum. In a dryer having a blower unit for blowing air to
The blower unit has a fan case in which the fan impeller is placed, and a driving motor that rotates the fan impeller.
The dryer, wherein the fan case and the drive motor are elastically coupled via a central anti-vibration rubber provided at a central portion and an outer anti-vibration rubber provided on an outer peripheral side. A rotating drum for storing clothes, a motor for driving the rotating drum, a casing for placing the rotating drum, and a rotating drum that is placed in the casing and rotates while rotating the rotating drum. In a dryer having a blower unit for blowing air to
The blower unit includes a fan case in which a fan impeller is placed, a driving motor that rotates the fan impeller, and a central anti-vibration rubber interposed between a central part of the fan case and a central part of the driving motor. The outer vibration isolating rubber interposed between the outer peripheral portion of the fan case and the outer peripheral portion of the drive motor;
A dryer characterized in that the rubber hardness of the outer peripheral anti-vibration rubber is lower than that of the central anti-vibration rubber. A rotating drum for storing clothing, a motor for driving the rotating drum, a housing for placing the rotating drum, and a rotating drum that is placed in the housing and is rotated while the rotating drum is being rotated. In the washing and drying machine having a blower unit for blowing air,
The blower unit has a fan case in which the fan impeller is placed, and a driving motor that rotates the fan impeller.
The washing machine according to claim 1, wherein the fan case and the driving motor are elastically coupled to each other through a central anti-vibration rubber provided at a central portion and an outer anti-vibration rubber provided on an outer peripheral side. A rotating drum for storing clothes, a motor for driving the rotating drum, a casing for placing the rotating drum, and a rotating drum that is placed in the casing and rotates while rotating the rotating drum. In the washing and drying machine having a blower unit for blowing air,
The blower unit includes a fan case in which a fan impeller is placed, a driving motor that rotates the fan impeller, and a central anti-vibration rubber interposed between a central part of the fan case and a central part of the driving motor. The outer vibration isolating rubber interposed between the outer peripheral portion of the fan case and the outer peripheral portion of the drive motor;
A washer-dryer characterized in that the rubber hardness of the outer peripheral anti-vibration rubber is lower than that of the central anti-vibration rubber. In a dryer having a rotary drum for storing clothes, a motor for driving the rotary drum, and a casing for supporting the rotary drum, and performing a drying operation.
A drier having a means for blowing air in the rotating drum during the drying operation and a silencer provided near the discharge port of the means. In a washing / drying machine having a rotating drum for storing clothes, a motor for driving the rotating drum, and a casing for supporting the rotating drum, and having a drying operation.
A washing / drying machine characterized in that means for blowing air is provided in the rotating drum during the drying operation, and a silencer is provided near the discharge port of the means.

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