JP5978459B2 - Clothes dryer - Google Patents

Description

  The present invention relates to a clothes dryer for drying clothes and the like.

  Conventionally, this type of clothes dryer is provided with a drying filter that captures lint from the clothes during the drying operation. Since lint is gradually trapped and accumulated in the drying filter during the drying process, clogging occurs and the air volume decreases, so it is considered that the lint captured by the drying filter is washed away with water (for example, Patent Documents). 1).

  FIG. 10 shows a conventional washing and drying machine described in Patent Document 1. In FIG. In FIG. 10, a water tank 52 is elastically supported in a casing 51, and a cylindrical rotating tank 53 is rotatably provided in the water tank 52. The rotating tank 53 is rotationally driven by a motor 54 attached to the outside of the rear surface of the water tank 52. A plurality of holes 55 are provided in the peripheral side surface of the rotary tank 53 and communicate with the water tank 52. The rotating tub 53 functions as a laundry room during washing and functions as a drying room during drying. Wash water in the water tank 52 passes through a drain pipe 57 from a drain port 56 provided at the bottom, is discharged through a drain valve 58 and a drain filter 59, and reaches a drain trap 60 outside the machine.

  A blower 61 is disposed in the lower part of the casing 51, and drying air is blown into the rotary tank 53 from the blower opening 63 provided in the front part of the water tank 52 through the circulation air passage 62 during the drying operation. In the circulation air passage 62, an evaporator 64 and a condenser 65 of a heat pump device are arranged, and the drying air that has been wetted by contact with clothes flows out of the rotary tank 53 and enters the circulation air passage 62 to evaporate. After being cooled and dehumidified by the cooler 64, it is heated by the condenser 65, and becomes high-temperature dry drying air that circulates to the rotary tank 53.

  During the drying operation, lint generated from clothes and the like is blown together with the drying air and adheres to and accumulates on the blowing means 61 provided in the circulation air passage 62, causing the function to deteriorate. A drying filter 66 that captures the air is provided in the circulation air passage 62 and is disposed on the windward side of the air blowing means 61.

  As the drying operation proceeds, lint accumulates on the dry filter 66 and the circulating air flow decreases, so water is poured from the water injection pipe 67 along the surface of the dry filter 66 to wash away the captured lint. The washing of the lint is performed after the drying operation is completed, and the washed-off water and lint are discharged from the drain pipe 57 through the drain path 68 and the drain valve 58 to the outside of the machine.

JP 2006-187449 A

However, the conventional configuration has a problem that the lint washed away from the dry filter by pouring water from the water pouring pipe is easily clogged by the drainage path including the drainage pipe and the drainage path. The drainage path is provided with a lint filter included in the laundry drainage and a drainage filter that captures the lint washed away from the dry filter. The lint captured by the drainage filter is discarded by removing the drainage filter from the drainage path. The drainage path is provided with a drainage valve on the upstream side of the drainage filter. The drainage valve opens and closes according to the drainage operation, and prevents water leakage from the drainage path when the drainage filter is removed. The lint flowing through the drainage path is easily clogged by the drainage valve that opens and closes the drainage path, which hinders the operation of the drainage valve and makes the drainage path open and close uncertain.

  In particular, the lint trapped by the dry filter is pressed against the filter surface by the circulating dry air during the drying operation and collects and accumulates in a film form. Lint deposited on the drying filter is generally removed after the drying operation. Since the lint after the drying operation is fixed to the filter surface in a dry state, it is difficult to disperse and flow the lint attached to the filter surface by water injection. It is necessary to pour water vigorously. When lint separated from the filter surface in a lump, the drainage path was clogged with lint. Moreover, in order to prevent clogging of the drainage path by the detached lint, there is a problem that the amount of water when flowing the lint increases.

  SUMMARY OF THE INVENTION The present invention solves the above-described conventional problems, and an object thereof is to provide a clothes dryer capable of preventing clogging of a drainage path due to lint removed from a dry filter device with a simple configuration.

  In order to solve the conventional problems, a clothes dryer of the present invention includes a dry filter device that captures lint contained in drying air, and a lint that removes lint captured by the dry filter device from the dry filter device. A lint storage chamber for storing the lint removed by the lint removal unit; and a lint crushing unit for crushing the lint in the lint storage chamber with a water flow, wherein the lint storage chamber contains a predetermined amount of water. The lint pulverizing means stores water and is provided with a nozzle portion on the submerged inner wall surface of the lint storage chamber.

  As a result, the lint removed from the dry filter device can be pulverized with a water flow, and the drainage path can be prevented from being clogged with lint. Moreover, the problem of the lock | rock by the entanglement of the fiber to the axial part of a rotating body and the water leak from an axial part is solved by grind | pulverizing lint with a water flow, without using a rotating body etc.

  The clothes dryer of the present invention can prevent the drainage path from being clogged by the lint removed from the drying filter device with a simple configuration.

Configuration diagram of a clothes dryer having a washing function in Embodiment 1 of the present invention System diagram of the clothes dryer Partial cutaway rear perspective view of the drying filter device of the clothes dryer Partial cutaway front perspective view of the drying filter device of the clothes dryer Cross section of the main part of the drying filter device of the clothes dryer Sectional drawing of the principal part of the drying filter apparatus of the clothes dryer in Embodiment 2 of this invention Sectional drawing of the principal part of the drying filter apparatus of the clothes dryer in Embodiment 3 of this invention Sectional drawing of the principal part of the drying filter apparatus of the clothes dryer in Embodiment 4 of this invention Sectional drawing of the principal part of the drying filter apparatus of the clothes dryer in Embodiment 5 of this invention Configuration diagram of a conventional washing and drying machine

According to a first aspect of the present invention, there is provided a rotating tub provided rotatably in a housing, a motor for rotationally driving the rotating tub, a circulation air passage for introducing drying air into the rotation tub, and air blowing to the circulation air passage. Air blowing means, dehumidifying means for dehumidifying the drying air from the rotating tank, heating means for heating the drying air dehumidified by the dehumidifying means, and a drying filter device for capturing lint contained in the drying air A lint removing means for removing the lint captured by the dry filter device from the dry filter device, a lint containing chamber for containing the lint removed by the lint removing means, and the lint in the lint containing chamber being crushed with a water flow The lint storage chamber stores a predetermined amount of water, and the lint crushing means is provided with a nozzle portion on a submerged inner wall surface of the lint storage chamber, thereby drying the lint storage chamber. Grinding the lint removed from the filter device to be able to flow, it is possible to prevent the clogging drainage path by lint. In addition, the lint can be pulverized with a simple configuration by pulverizing the lint with a water flow without using a driving unit such as a cutter.

According to a second aspect of the invention, in particular, in the first aspect of the invention, the lint housing chamber is provided with a concave curved surface portion curved in a spherical shape, and the nozzle portion is adapted to cause the water flow to collide with the curved surface portion. Even if the ejection angle of the fluid to be ejected varies, the fluid can be effectively collided with the wall surface, and the vortex flow is stably generated, so that lint can be pulverized stably.

  According to a third aspect of the invention, in particular, in the first or second aspect of the present invention, the plurality of convex portions are provided in the lint storage chamber, and the nozzle portion causes the water flow to collide with the convex portion, so that the water flow becomes the convex portion. The collision can promote the occurrence of overflow in the vicinity of the wall surface, increase the shear force acting on the lint, and reliably and finely grind the lint.

  According to a fourth aspect of the present invention, in particular, in the first or second aspect of the present invention, a plurality of dimple portions are provided in the lint housing chamber, and the nozzle portion causes a water flow to collide with the dimple portion. Since many flows are generated, turbulent flow can be generated with a simple configuration, and lint can be more reliably and finely pulverized.

  In the fifth aspect of the invention, in particular, the nozzle portion of any one of the first to fourth aspects of the present invention is overflowed between passing water streams by arranging a plurality of opposed nozzles in the lint housing chamber so that the jetted water streams pass alternately. Many lint can be generated, and lint can be finely pulverized stably with a simple structure.

  In particular, in a sixth aspect of the invention, in any one of the first to fifth aspects of the invention, a water tub provided with a rotating tub rotatably therein, a washing water supply means for supplying washing water to the tub, and the inside of the water tub The laundry drainage means for discharging the washing water and the control means for controlling the washing and drying operation are provided, and the washing function is provided, so that the clothes are transferred from washing to drying in the same tank without changing clothes. In addition, the lint removed from the drying filter device can be smoothly flowed through the drainage channel for flowing the washing wastewater.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a configuration diagram of a clothes dryer (so-called washing dryer) having a washing function in the first embodiment of the present invention, FIG. 2 is a system diagram of the clothes dryer, and FIG. FIG. 4 is a partially cutaway front perspective view of the drying filter device of the clothes dryer, FIG. 4 is a partially cutaway front perspective view of the drying filter device, and FIG.

  1 to 5, a water tank 1 is elastically supported by a plurality of suspension mechanisms 3 inside a housing 2 of a washing / drying machine. The rotating tub 4 has a loading port 6 for taking in and out the laundry 5 on the front side, is configured in a bottomed cylindrical shape, and is disposed in the water tub 1. The rotating tub 4 is rotatably provided on the rotating shaft 4a and accommodates laundry 5 such as clothes.

The peripheral wall 7 of the rotating tub 4 is provided with a large number of holes 8 over the entire circumference, and the stirring baffle for lifting the laundry 5 in the rotating direction of the rotating tub 4 is provided inside the peripheral side wall 7 of the rotating tub 4. 9 is provided. The water tank 1, the rotating tank 4, and the rotating shaft 4 a are provided to be tilted forward and upward at an angle θ (for example, 10 to 20 °) with respect to the horizontal.

  A motor 10 that rotationally drives the rotating tub 4 is provided outside the rear surface side of the water tub 1 so as to rotate the rotating tub 4 forward and backward. The motor 10 is constituted by a brushless DC motor or the like, and the rotation speed can be freely changed by inverter control. A door body 11 that opens and closes the insertion port 6 is provided on the front surface of the housing 2. The opening 1 a of the water tank 1 facing the inlet 6 is airtightly connected to the housing 2 by a flexible packing 12 that can be expanded and contracted.

  When the door body 11 is closed, the packing 12 provided in the opening 1a of the water tank 1 is in close contact with the inner surface of the door body 11, and the water tank 1 becomes a watertight and airtight space, and each of washing, rinsing, dehydration and drying is performed. When carrying out the process, water and air are prevented from leaking outside.

  A washing water supply valve (washing water supply means) 13 is provided in the housing 2, and a washing water supply path 14 communicating with the water tank 1 is connected to the washing water supply valve 13 through a detergent case (not shown). Yes. By opening and closing the washing water supply valve 13, tap water can be supplied to the water tank 1 and stopped.

  In addition, a washing drainage path 16 is connected to a drainage hole 15 provided at the bottom of the water tank 1, and a washing drainage valve (washing drainage means) 17 is provided. By opening and closing the washing drain valve 17, the washing water in the water tank 1 can be drained and stopped. In the washing drainage path 16, a drainage filter 18 is provided on the downstream side of the washing drainage valve 17.

  A discharge port 19 is provided in the peripheral side wall 7 in the upper front portion of the water tank 1, and a blower port 20 is provided in the back surface portion of the water tank 1. The discharge port 19 and the air blowing port 20 are connected to each other by a circulation air passage 21 extending from the front upper side of the water tank 1 toward the rear side.

  The circulation air passage 21 includes a drying filter device 25 that captures lint L that passes through the circulation air passage 21 together with the drying air, a blower unit 26 that supplies the drying air to the rotating tank 4, and dehumidification of the drying air. A heat radiator (heating means) 29 and a heat absorber (dehumidifying means) 31 of the heat pump device 27 that performs heating are provided.

  The blower means 26 includes a fan 26a having a blade shape and a fan motor 26b that rotationally drives the fan 26a. The drying air blown by the blower 26 is blown into the rotary tank 4 from the blower port 20.

  Drying air discharged into the water tank 1 from the hole 8 of the rotating tank 4 flows into the circulation air passage 21 from the discharge port 19 as indicated by an arrow A, and the heat absorber 31 of the drying filter device 25 and the heat pump device 27. The radiator 29, the air blowing means 26, and the air blowing port 20 are circulated to the rotary tank 4.

  The heat pump device 27 includes a compressor 28 that compresses a refrigerant, a radiator (heating means) 29 that radiates heat of the compressed high-temperature and high-pressure refrigerant, and a capillary tube that reduces the pressure of the high-pressure refrigerant. The pipe 30 is connected to the means 30 so that the refrigerant circulates through a heat absorber (dehumidifying means) 31 in which the refrigerant whose pressure has been reduced to a low pressure takes heat from the surroundings.

  The drying air blown by the blowing means 26 is cooled and dehumidified by the heat absorber 31 provided in the circulation air passage 21, heated by the radiator 29, supplied from the blower opening 20 to the rotating tub 4, and the circulation air is discharged from the discharge outlet 19. It flows into the passage 21 and circulates.

  The circulation air passage 21 has an exhaust port 33 through which a part of the drying air flowing out from the rotary tank 4 can be discharged out of the circulation air passage 21, and is configured to be opened and closed by an exhaust valve 33a. Between the exhaust port 33 and the heat absorber 31, it has the inlet port 34 which can introduce external air into the circulation air path 21, and it can be opened and closed by the intake valve 34a. The dry filter device 25 is disposed in the circulation air passage 21 between the exhaust port 33 and the intake port 34.

  As shown in FIGS. 3 and 4, the drying filter device 25 includes an introduction unit 35 that introduces drying air, an exhaust unit 36 that exhausts the introduced drying air, and drying air introduced from the introduction unit 35. And a lint removing means 38 for removing the lint L captured by the filter unit 37 from the filter unit 37 and configured to be removable from the housing 2.

  The filter unit 37 is configured in a substantially semi-cylindrical shape, and a part thereof is configured with a mesh or the like. The lint removing means 38 is formed in a spiral shape so as to be inscribed along the filter portion 37 and is rotationally driven by a lint removing means driving motor 39 provided on the housing 2 side. The rotational drive of the lint removal means drive motor 39 is transmitted to the lint removal means 38 at a reduced speed via a slave gear 39b meshing with the drive gear 39a, and scrapes and removes the lint L adhering to the filter portion 37.

  The lint L scraped off from the filter unit 37 by the rotational drive of the lint removing means 38 and removed from the dry filter device 25 is separated from the lint removing means 38 by its own weight and accommodated in the lint accommodation chamber 41. The lint accommodated in the lint accommodation chamber 41 is finely crushed by the lint crushing means 40.

  The lint storage chamber 41 is provided adjacent to the outlet side from which the lint L is removed from the dry filter device 25, and is configured to fall from the outlet 37 a of the filter unit 37 and accumulate at the bottom in the lint storage chamber 41. ing.

  Further, a water sealing part 41 b is provided in the drainage part 41 a of the lint storage chamber 41, and a water storage part 41 c that stores a predetermined amount of water in the lint storage room 41 is configured. The drainage part 41 a is formed in a substantially U shape, and after rising from the bottom of the lint storage chamber 41 by a height h 1, is bent downward and extends downward, and is connected to the discharge path 43.

  The lint crushing means 40 includes a nozzle portion 40a disposed on the submerged inner wall surface of the lint storage chamber 41, a water supply passage 40b for supplying water to the nozzle portion 40a, and a water supply valve 40c provided in the water supply passage 40b. Water is jetted from the portion 40 a toward the inner wall surface of the lint storage chamber 41, and a water flow is generated in the lint storage chamber 41.

  The water flow generated by jetting water from the nozzle portion 40a collides with the inner wall surface of the lint storage chamber 41, and changes the course vertically to form a plurality of overflows. Since the shear force acts on the lint L where the water flow is divided, the lint L is finely pulverized. The water supply path 40 b branches off from the washing water supply path 14.

  In order to discharge the pulverized lint L, the controller 44 first opens the water supply valve 40c to supply water from the nozzle portion 40a to the lint storage chamber 41 and store the water in the water storage portion 41c. Water whose water level W in the water storage part 41c exceeds the height h1 of the water sealing part 41b is discharged from the drainage part 41a and flows into the discharge path 43.

The lint L removed from the filter unit 37 is finely pulverized by the water flow generated in the lint storage chamber 41 as indicated by an arrow B, and together with the water discharged from the nozzle unit 40a, the lint L passes through the discharge path 43. It flows through the washing drainage path 16 and is discharged out of the machine.

  The discharge part 42 is pulverized by a water flow in the lint storage chamber 41, and the lint pulverized smaller than a set size passes through and is discharged from the lint storage chamber 41.

  The control means 44 is disposed at the lower front part in the housing 2, and includes the motor 10, the washing water supply valve 13, the washing drain valve 17, the air blowing means 26, the heat pump device 27, the lint removal means driving motor 39, the water supply valve 40c, and the like. And control each step of washing, rinsing, dehydration and drying sequentially.

  The pressure in the water tank 1 and the output of pressure detection means (not shown) for detecting the water level of the washing water, the motor rotation speed detection means 45 for detecting the rotation speed of the motor 10, and the temperature of the refrigerant flowing through the radiator 29 are as follows. The output of the refrigerant temperature detecting means 46 to be detected is input.

  The operation and action of the washing / drying machine configured as described above will be described below. A series of operations from washing to drying is performed by the control means 44 based on the set contents by inputting the selection of the driving course and the time of each process from the operation display unit 47 provided on the upper front of the housing 2. It is possible to carry out, and it is also optionally possible to carry out only the drying step.

  When washing is performed, the door body 11 is opened, the laundry 5 is put into the rotating tub 4, and an operation course or the like is input from the operation display unit 47 to start the operation. Water and detergent are supplied inside, and the rotating tub 4 is driven to rotate by the motor 10 to start the washing process.

  When the rotating tub 4 rotates at a predetermined speed, the laundry 5 is lifted in the rotating direction by the stirring baffles 9 provided at a plurality of locations on the inner peripheral surface, and is tapped by dropping from above in the rotating tub 4. Washing is performed by repeating the washing for a predetermined time.

  After the washing process, the rinsing process and the dehydrating process are executed to complete the washing. When an operation course that consistently executes from the washing process to the drying process is selected and input, when the washing process is completed, the control unit 44 executes the drying process following the washing process. Moreover, when drying wet clothes etc., only a drying process can be performed.

  In the drying process, when the laundry 5 or wet clothing (hereinafter referred to as clothing) that has been dehydrated is stored in the rotating tub 4 and the drying process is executed, the rotating tub 4 is rotated at the rotation speed set in the drying process. , The air blowing means 26 and the heat pump device 27 are driven, and the air circulation of the drying air into the rotating tub 4 is started. In this drying process, the water tank 1 plays the same role as a drying chamber in a clothes dryer.

  In the heat pump device 27, the refrigerant is compressed by the operation of the compressor 28, and by this pressure, the refrigerant flows through the pipe line 32 from the compressor 28 and circulates through the radiator 29, the throttle means 30, the heat absorber 31, and the compressor 28. Since the heat of the compressed refrigerant flows into the radiator 29, it is radiated to the air in contact with the fins provided in the pipe line 32 provided in the radiator 29, so that the drying refrigerant flowing in the circulation air passage 21 is used. Air is heated.

The heated drying air is supplied to the rotating tub 4 from the air blowing port 20, takes moisture from the laundry 5 or clothes, becomes moist air, and is discharged from the discharge port 19 to the circulation air passage 21. Lint L such as lint is generated from clothes as the clothes are dried. The drying air discharged from the discharge port 19 is introduced from the introduction unit 35 into the drying filter device 25, and the mesh of the filter unit 37 captures the lint L.

  The drying air from which the lint L has been removed by the drying filter device 25 is dehumidified when sensible heat and latent heat are taken away when passing through the heat absorber 31 through which the refrigerant that has been depressurized by the throttling means 30 flows to a low pressure. Condensed water generated by dehumidification is dropped into a water storage unit (not shown), and the dehumidified and dried drying air passes through the radiator 29 and is heated. The dehumidified condensed water is drained outside the machine through the washing drainage path 16.

  The amount of heat by which the drying air is heated by the radiator 29 is substantially equal to the sum of the power consumption of the compressor 28 and the amount of heat absorbed from the drying air by the heat absorber 31. It is possible to heat the drying air by obtaining an output that is equal to or higher than the power input to. However, if the drying air in the circulation air passage 21 is repeatedly circulated, the amount of heat of the entire drying air will continue to be accumulated by subtracting the amount of heat radiated naturally from the amount corresponding to the power consumption of the compressor 28. Become.

  At the same time, the amount of heat of the refrigerant in the heat pump device 27 continues to increase, the temperature and pressure of the refrigerant rise, and there is a possibility that an overload will be applied to the compressor 28 before long. In order to avoid this, an exhaust port 33 for exhausting a part of the drying air flowing through the circulation air passage 21 to the outside of the circulation air passage 21 and an intake port 34 for introducing outside air into the circulation air passage 21 are provided. Yes.

  In order to reduce the amount of heat possessed by the refrigerant, the control means 44 opens the intake valve 34 a provided at the intake port 34 based on the output of the refrigerant temperature detection means 46 to introduce outside air into the circulation air passage 21, and the exhaust port 33. A part of the drying air flowing through the circulation air passage 21 is exhausted to the outside of the circulation air passage 21 by opening the exhaust valve 33 a provided in the air.

  Circulation air is introduced by the introduction of the outside air into the circulation air passage 21, the cooling of the outside air flowing into the circulation air passage 21 by the partial exhaust of the drying air flowing through the circulation air passage 21, and the exhaust of the high-temperature drying air. Since the temperature of the drying air flowing through the passage 21 is lowered, the temperature of the refrigerant is also lowered, and the compressor 28 is prevented from being overloaded due to the excessive rise in the refrigerant temperature.

  When the refrigerant temperature is lowered to a predetermined temperature, the intake valve 34a and the exhaust valve 33a are closed, the introduction of outside air from the intake port 34 and the exhaust from the exhaust port 33 are eliminated, and the air blown into the circulation air passage 21 is dried. The amount of heat is accumulated in the working air, and drying air with a high drying effect circulates.

  The amount of lint L generated from the laundry 5 such as clothes increases from the start of drying when the clothes are wet, and the amount of lint L generated increases as the drying of the clothes progresses. Will increase.

  When the drying process is performed in a state where the lint L is accumulated on the drying filter device 25, the drying air circulating in the circulation air passage 21 is less likely to flow from the drying filter device 25 to the downstream side, and the drying performance is reduced. The control means 44 removes the lint L deposited on the dry filter device 25 after the drying operation, for example.

  Specifically, the lint removing unit 38 includes a spiral-shaped portion that is inscribed along the filter unit 37, and the control unit 44 drives the lint removing unit drive motor 39 to rotate the lint removing unit 38. .

When the spiral-shaped portion of the lint removing means 38 scrapes the lint L, it applies forces in the radial direction and the thrust direction of the mesh to the lint L on the mesh. Because of these forces, the lint L moves in the direction Z along the rotation axis of the lint removing means 38 while being scraped off, so that even if the lint L scraped off is fine, it is transferred to the lint crushing means 40. And can be transported.

  The control means 44 opens the water supply valve 40c while the lint removal means 38 is being driven or after the drive of the lint removal means 38 is completed and a predetermined time has elapsed, and supplies water from the nozzle portion 40a to the lint storage chamber 41. Then, the water is accumulated up to the water level W. The lint L transferred to the end of the lint removal means 38, that is, the outlet 37a of the filter unit 37 falls into the lint storage chamber 41 by gravity, and is immersed in water stored in the water storage unit 41c to absorb water.

  The lint crushing means 40 injects water from a nozzle portion 40a provided at a position submerged in the water storage section 41c, and generates a water flow in the water storage section 41c. The water sprayed from the nozzle part 40a collides with the inner wall surface of the lint storage chamber 41, and changes the course to generate a plurality of water streams. The lint L in the water storage part 41c of the lint storage chamber 41 is finely pulverized by the water flow generated by the water jetted from the nozzle part 40a.

  The pulverized lint L is discharged from the machine through the washing drainage path 16 through the discharge path 43 from the discharge section 42 by the water jetted from the nozzle section 40a. The discharge part 42 provided in the lower part of the lint storage chamber 41 is configured to allow the lint L finely pulverized to a predetermined size to pass therethrough.

  In the present embodiment, since the lint L can be removed from the filter unit 37 without spraying water onto the filter unit 37, the lint can be used even during the driving of the blowing unit 26, for example, during the drying operation. L can be transferred to the lint crushing means 40 by the lint removing means 38, and the drying air can be passed smoothly without the lint L being deposited in a large amount on the filter unit 37.

  Further, by crushing the lint L by a water flow without using a driving means such as a rotary cutter, it is possible to prevent the lint crushing means 40 from being locked due to the entanglement of the lint to the rotation shaft of the driving means and the tooth of the cutter. Deterioration can be prevented, the durability is excellent, and the lint L can be reliably pulverized.

  As described above, in the present embodiment, the rotating tank 4 that is rotatably provided in the housing 2, the motor 10 that rotationally drives the rotating tank 4, and the circulation that introduces drying air into the rotating tank 4. An air passage 21, an air blowing means 26 for blowing air to the circulation air passage 21, a dehumidifying means 31 for dehumidifying drying air that has come out of the rotating tank 4, and a heating means 29 for heating the drying air dehumidified by the dehumidifying means 31; The dry filter device 25 that captures lint contained in the drying air, the lint remover 38 that removes the lint captured by the dry filter device 25 from the dry filter device 25, and the lint removed by the lint remover 38 is accommodated. A lint storage chamber 41, and a lint crushing means 40 for crushing lint in the lint storage chamber 41 with a water flow. The lint storage chamber 41 stores a predetermined amount of water. Are those in which a nozzle portion 40a to the submerged inner wall surface of the chamber 41, drying the filter device can be made to flow by grinding lint removed from 25, it is possible to prevent the clogging drainage path by lint. In addition, by pulverizing the lint, water flowing through the lint can be reduced.

(Embodiment 2)
A drying filter device for a clothes dryer according to a second embodiment of the present invention will be described . The feature of the present embodiment is that in FIG. 5, a curved surface portion (not shown) is provided on the inner wall surface of the lint storage chamber 41 facing the nozzle portion 40a, and water is jetted from the nozzle portion 40a toward the curved surface portion . The water flow collides with the curved surface portion . Other configurations are the same as those of the first embodiment, the same reference numerals are given to the same configurations, and the detailed description of the first embodiment is used.

The curved surface portion is provided on the inner wall surface of the lint storage chamber 41 facing the nozzle portion 40a, and is formed in a concave shape curved in a spherical shape.

With the above configuration, even when the spray angle of water sprayed from the nozzle portion 40a varies, the water flow collides substantially perpendicularly with the curved surface portion formed on the inner wall surface, so that the water flow effectively collides with the curved surface portion . In addition, since the vortex flow is stably generated, the lint L can be pulverized stably.

(Embodiment 3)
FIG. 7: is principal part sectional drawing of the drying filter apparatus of the clothes dryer in the 3rd Embodiment of this invention. A feature of the present embodiment is that a plurality of convex portions 41e are provided on the inner wall surface of the lint storage chamber 41, water is jetted from the nozzle portion 40a toward the convex portion 41e, and the water flow collides with the convex portions 41e. Is. Other configurations are the same as those of the first embodiment, the same reference numerals are given to the same configurations, and the detailed description of the first embodiment is used.

  The convex portion 41e is provided on the inner wall surface of the lint storage chamber 41 facing the nozzle portion 40a, and is formed so that the tip protrudes toward the nozzle portion 40a.

  With the above configuration, even when the spray angle of the water sprayed from the nozzle portion 40a varies, the water flow can be effectively collided with the convex portion 41e, and the overflow near the inner wall surface of the lint storage chamber 41 can be achieved. The shear force acting on the lint L can be increased, and the lint L can be pulverized reliably and finely.

(Embodiment 4)
FIG. 8: is principal part sectional drawing of the drying filter apparatus of the clothes dryer in the 4th Embodiment of this invention. A feature of the present embodiment is that a plurality of dimple portions 41f are provided on the inner wall surface of the lint storage chamber 41, and water is sprayed from the nozzle portion 40a toward the dimple portion 41f so that the water flow collides with the dimple portion 41f. Is. Other configurations are the same as those of the first embodiment, the same reference numerals are given to the same configurations, and the detailed description of the first embodiment is used.

  The dimple portion 41f is provided on the inner wall surface of the lint storage chamber 41 facing the nozzle portion 40a, and is formed so as to be recessed in the nozzle portion 40a.

  With the above configuration, many small overflows can be generated in the dimple portion 41f other than the collision point between the water flow and the inner wall surface, so that turbulent flow can be generated with a simple configuration, and the lint L can be more reliably obtained. And it can be finely pulverized.

(Embodiment 5)
FIG. 9: is principal part sectional drawing of the drying filter apparatus of the clothes dryer in the 5th Embodiment of this invention. A feature of the present embodiment is that a plurality of nozzle portions 40a are arranged opposite to each other in the lint storage chamber 41 so that the water flows ejected from the nozzle portions 40a pass alternately. Other configurations are the same as those of the first embodiment, the same reference numerals are given to the same configurations, and the detailed description of the first embodiment is used.

  A plurality of nozzle portions 40a are arranged opposite to each other under the water surface of the water storage portion 41c, one nozzle portion 40a injects water supplied from the water supply passage 40b, and the other nozzle portion 40a is branched water supply branched from the water supply valve 40c. The water supplied from the passage 40g is jetted so that the water flow jetted from the nozzle portions 40a alternately passes. The direction in which the water flows pass may be either the upper or lower direction, the left or right direction, or both.

  With the above configuration, a large number of overflows can be generated between passing water streams, and the lint L can be finely pulverized stably with a simple configuration.

  In each of the above-described embodiments, a plurality of nozzle portions 40a may be provided when the nozzle portion 40a is configured as one. In that case, it is preferable to arrange the nozzle portions 40a to face each other so that the water flow ejected from the nozzle portions 40a alternately passes as in the fifth embodiment. Since a plurality of overflows occur between the passing water streams, the lint L is pulverized even outside the vicinity of the inner wall surface of the lint storage chamber 41, and the lint L can be pulverized more finely.

  Moreover, in each said embodiment, although water is injected from the nozzle part 40a and a water flow is generated in the water storage part 41c of the lint accommodation chamber 41, you may make it inject air from the nozzle part 40a. . In this case, air can be blown to the nozzle portion 40a with an air pump, and the water in the water storage portion 41c can be agitated to generate a water flow.

  In each of the above embodiments, the radiator 29 of the heat pump device 27 is used as a heating unit, and the heat absorber 31 is used as a dehumidifying unit, so that a predetermined drying performance can be obtained at a low temperature and with a small amount of power consumption. be able to. In addition, a heating means may be comprised with a heater and a dehumidification means may be comprised with a water-cooling type heat exchanger.

  Further, in each of the above embodiments, the washing / drying machine having a washing function is configured. However, even in a clothes drying machine having no washing function, the performance of pulverizing and discharging lint and the performance of the heat pump device A similar effect can be obtained.

  As described above, the clothes dryer according to the present invention is useful as a clothes dryer because it can prevent the drainage path from being clogged by the lint removed from the drying filter device with a simple configuration.

2 Housing 4 Rotating tank 10 Motor 21 Circulating air passage 25 Drying filter device 26 Blower means 29 Radiator (heating means)
31 Heat absorber (dehumidifying means)
38 lint removing means 40 lint grinding means 40a nozzle part 41 lint storage chamber

Claims (6)

A rotating tank provided rotatably in the housing;
A motor for rotationally driving the rotating tub,
A circulation air passage for introducing drying air into the rotary tank;
A blowing means for blowing air to the circulation air passage;
Dehumidifying means for dehumidifying the drying air that has come out of the rotating tank;
Heating means for heating the drying air dehumidified by the dehumidifying means;
A drying filter device for capturing lint contained in drying air;
Lint removing means for removing lint captured by the dry filter device from the dry filter device;
A lint storage chamber for storing the lint removed by the lint removal means;
Lint crushing means for crushing lint in the lint storage chamber with a water flow,
The lint storage chamber stores a predetermined amount of water,
The lint crushing means is a clothes dryer in which a nozzle portion is provided at a position where the inner wall surface of the lint storage chamber is submerged. The clothes dryer according to claim 1, wherein a concave curved surface portion curved in a spherical shape is provided in the lint storage chamber, and the nozzle portion causes a water flow to collide with the curved surface portion. The clothes dryer according to claim 1 or 2, wherein a plurality of convex portions are provided in the lint storage chamber, and the nozzle portion causes a water flow to collide with the convex portions. The clothes dryer according to claim 1 or 2, wherein a plurality of dimple portions are provided in the lint storage chamber, and the nozzle portion causes a water flow to collide with the dimple portion. The clothes dryer according to any one of claims 1 to 4, wherein a plurality of nozzle portions are arranged to face each other in the lint storage chamber so that the jetted water flows alternately. A water tank rotatably provided inside, and
Washing water supply means for supplying washing water to the water tank;
Washing drainage means for discharging the washing water in the water tank;
Having control means for controlling washing and drying operation;
The clothes dryer of any one of Claims 1-5 provided with the washing function.