KR100735964B1 - Drier - Google Patents

Abstract

The drying apparatus includes a refrigerant, a compressor for compressing the refrigerant, a radiator for releasing heat of the compressed refrigerant, a throttle portion for depressurizing the compressed refrigerant, a heat absorber capable of dehumidifying by the compressed refrigerant, clothes, and the like. It is provided with the drying chamber which dry | drys a to-be-dried material, and discharges moisture absorption air, an air circulation path, the air outlet provided in the air circulation path, the lint filter provided in the air circulation path, and the air inlet provided in the air circulation path. The air circulation path leads the discharged moisture absorbing air to the heat absorber, dehumidifies the moisture absorbing air in the heat absorber to generate dry air, heats the dry air in the radiator to generate heated air, and introduces the heating air into the drying chamber. The air outlet is provided downstream of the drying chamber and upstream of the heat absorber, and exhausts a part of the moisture absorption air from the air circulation path. The lint filter is installed downstream of the drying chamber and upstream of the heat absorber to capture the lint contained in the hygroscopic air. The air inlet is installed downstream of the lint filter and upstream of the endotherm, and introduces outside air into the air circulation path. This drying apparatus can realize a shortening of drying time and energy saving by operating a heat pump stably.

Description

Drying Device {DRIER}

1 is a cross-sectional view of a drum type laundry dryer as a drying device in an embodiment of the present invention;

2 is a schematic view of a drying apparatus in the embodiment,

3A and 3B are perspective views of the filter unit of the drying apparatus in the embodiment.

Explanation of symbols for the main parts of the drawings

1: laundry dryer 10: water tank unit

15: blower fan 20: heat pump unit

27 compressor 28 heat absorber

29: radiator 46: air outlet

47: air inlet port 48: exhaust valve

60: filter unit 61: lint filter

62 exhaust filter 63 intake filter

74: intake valve 201: air circulation path

The present invention relates to a heat pump type drying apparatus for drying dry items such as clothing.

In the heat pump type clothes drying apparatus, the heating air heated by the heat radiator of the heat pump is supplied to the drying chamber containing the clothes. The heated air desorbs moisture from the clothes and becomes hygroscopic air. The hygroscopic air is returned to the heat absorber of the heat pump to dehumidify to become dry air. The dry air is again heated by the radiator and fed to the drying chamber to form an air circulation path.

When the air in the air circulation path is circulated as it is, as the heat amount of the entire air increases, the heat amount of the refrigerant in the heat pump also increases. If the amount of heat of the coolant increases and the temperature and the pressure increase, the compressor that compresses the coolant is soon overloaded, and the heat pump cannot be stabilized in a safe state.

In the conventional clothes drying apparatus disclosed in Japanese Patent Laid-Open No. 1995-178289, an exhaust port is provided in an air circulation path from a radiator to a rotating drum. A part of the heating air heated by the radiator is discharged from this exhaust port, and heat of air is discharged to the outside of the air circulation path.

In the conventional clothes drying apparatus, a part of the heating air heated by the radiator is discharged from the exhaust port before being used for drying clothes, so the energy loss is large.

Another clothes drying apparatus disclosed in Japanese Patent Laid-Open No. 1995-178289 has a drainage pipe for draining water in a tank containing a rotating drum. A part of the heating air in the air circulation path is discharged to the outside by opening the drain valve when the temperature of the coolant rises above the predetermined temperature in the drying step of the clothes. By opening this drain valve, outside air is introduced into the air circulation path from the intake port, and the temperature of the refrigerant can be reduced by the exhaust and intake air. Therefore, the heat pump is operated in the optimum state by controlling the opening and closing of the drain valve in accordance with the rise of the refrigerant temperature.

In the conventional clothes drying apparatus, since the drainage pipe is useful for the exhaust port of the heating air, a mechanism is required in which the water stored from the exhaust path is not discharged in the washing step.

In addition, the water tank accommodating the rotating drum corresponds to the drying chamber of the clothes drying apparatus, and is exhausted from the drain port provided in the lower part of the water tank, so that part of the heating air used for drying the clothes is discharged, resulting in energy loss. .

A lint filter is installed in the air circulation path to capture lint, which increases in amount as the garment is dried. When clogging occurs in the lint filter, the air volume of the air flowing in the air circulation path decreases, and stable operation of the heat pump may be damaged from an overload state of the compressor due to excessive rise of the temperature and pressure of the refrigerant.

The drying apparatus includes a refrigerant, a compressor for compressing the refrigerant, a radiator for releasing the heat of the compressed refrigerant, a throttle portion for pressurizing the compressed refrigerant, an endotherm that can be dehumidified by the reduced pressure refrigerant, clothing and the like. It is provided with the drying chamber which dry | drys a to-be-dried material, and discharges moisture absorption air, an air circulation path, the air outlet provided in the air circulation path, the lint filter provided in the air circulation path, and the air inlet provided in the air circulation path. The air circulation path guides the discharged hygroscopic air to the heat absorber, dehumidifies the hygroscopic air in the heat absorber to generate dry air, heats the dry air in the radiator to generate heated air, and introduces the heated air into the drying chamber. The air outlet is installed downstream of the drying chamber and upstream of the heat absorber, and exhausts a part of the moisture absorption air from the air circulation path. The lint filter is installed downstream of the drying chamber and upstream of the heat absorber to capture the lint contained in the hygroscopic air. The air inlet is installed downstream of the lint filter and upstream of the endotherm, and introduces outside air into the air circulation path.

This drying apparatus can realize a reduction in drying time and energy saving by stably operating the heat pump.

1 is a cross-sectional view of a drum type laundry dryer 1 which is a drying apparatus in an embodiment of the present invention. 2 is a schematic view of the drum type laundry dryer 1. The drum drive motor 4 is attached to the rear surface of the water tank 3 containing the rotary drum 5. The drum drive motor 4 rotationally drives the rotating shaft 17 of the rotating drum 5 axially supported by the bearing 16 provided in the water tank 3. The drum drive motor 4, the water tank 3, the bearing 16, and the rotating drum 5 constitute the water tank unit 10. The water tank unit 10 is supported by the suspension structure in the washing machine housing 2 so that the rotating shaft 17 of the rotating drum 5 may incline upward toward the front side. The water tank 3 and the rotating drum 5 are each opened in the direction toward the front surface. By opening the door 8 provided in the front of the washing machine housing 2, laundry can be taken in and out from the laundry entrance 6 which opens to the front of the rotating drum 5. When the door 8 is closed, bellows 43 provided in the opening of the water tank 3 comes into close contact with the inner surface of the door 8. Thereby, the water tank 3 becomes a watertight and airtight space, and water and air do not leak to the outside at the time of performing each process of washing, rinsing, dehydration, and drying.

The water tank unit 10 is inclined in the washing machine housing 2 so that a space is formed in the lower back side of the washing machine housing 2, and the heat pump unit 20 is accommodated in the space. The volume of the washing machine housing 2 is limited so that the drum type laundry dryer 1 can be installed in an existing installation place where the area such as a waterproof pan is limited. When the large water tank unit 10, the suspension structure supporting it, or the components for water supply, drainage, etc. are accommodated, the excess space of the washing machine housing 2 becomes small. However, by making the heat pump unit 20 small, the washing machine housing 2 is prevented from being enlarged.

The heat pump unit 20 consists of the compressor 27, the heat absorber 28, and the radiator 29, and these are accommodated in the unit case 21. As shown in FIG. The unit case 21 is connected with an intake connecting tube 32 communicating with the heat absorber 28, and an exhaust connecting tube 33 communicating with the radiator 29 is connected. The water storage part 34 which receives the condensation water dripped from the heat absorber 28 is provided in the bottom surface located below the heat absorber 28 of the unit case 21. As shown in FIG. The water stored in the reservoir 34 is drained by a drain pump from the drain through the dust filtration filter 35.

The surface 28B of the heat absorber 28 opposes the surface 29A of the radiator 29 at a predetermined interval, and a space 21C is formed between them as an air flow path. The surface 28A of the heat absorber 28 faces the wall surface 21B of the unit case 21, and an intake space 28C is formed between them and serves as an air flow path. Similarly, an exhaust space 29C which faces the wall surface 21A of the unit case 21 and serves as an air passage therebetween is formed on the surface 29B of the radiator 29. The intake connecting pipe 32 has an opening 32A that opens in the intake space 28C, and the exhaust connecting pipe 33 has an opening 33A that opens in the exhaust space 29C. The heat absorber 28 and the radiator 29C of the heat absorber 28 and the radiator 29C are formed so that an air flow path through which the air passes through the heat absorber 28 and the space 21C and the radiator 29 is formed in the exhaust space 29C. Both ends are held by a pair of side wall plates 37 and housed in the unit case 21 as a heat absorbing and heat dissipating unit. The heat absorber 28 and the radiator 29 are inclined together so as to be close to each other, and by this arrangement, the air flow path can be effectively ensured, so that the heat pump unit 20 is rearward of the water tank unit 10. It is possible to arrange | position to the limited space formed in the.

The heat pump unit 20 and the water tank unit 10 are connected by the blowing pipe shown in FIG. The inlet port 11 is formed in the back surface of the water tank 3, and the exhaust port 12 is formed in the side peripheral surface of the water tank 3. As shown in FIG. The inlet 11 and the exhaust connection pipe 33 of the heat pump unit 20 are connected by a duct 13. The exhaust port 12 and the intake connecting pipe 32 of the heat pump unit 20 are connected by a duct 14. The blowing fan 15 is arranged in the duct 14. The water tank 3, the heat pump unit 20, the exhaust connection pipe 33, the intake connection pipe 32, and the ducts 13 and 14 provide an air circulation path 201 for drying the clothing 401 which is a dry object. Forming.

A plurality of through holes 9 are formed on the side circumferential surface of the rotary drum 5 so that water and air flow freely between the inside of the water tank 3. At the bottom of the rotary drum 5, a plurality of air introduction holes 26 communicating with the intake port 11 are provided. The heated air supplied from the heat pump unit 20 via the duct 13 is indicated by an arrow in FIG. 1, and the bottom air inlet hole 26 is introduced from the intake port 11 into the rotary drum 5. Is introduced from. The heated air desorbs moisture from the clothes 401 contained in the rotary drum 5 to become hygroscopic air. As shown by the arrow of FIG. 1, the moisture-absorbing air exits from the through hole 9 and the laundry entrance 6 into the water tank 3, passes through the filter unit 60 from the exhaust port 12, and passes through the duct 14. ) Is reached and the intake connecting pipe 32 of the heat pump unit 20 is reached.

The filter unit 60 is detachably attached to the filter container 60A provided in the front part of the washing machine housing 2.

In the drum type laundry dryer 1, instructions such as selection of a driving course, time setting of each step, and the like are input from an operation and display unit provided on the front side of the washing machine housing 2. The instruction is input to the controller 301, and the controller 301 can perform the washing-to-drying as a series of operations in the drum type laundry dryer 1 or perform only a drying process based on the instruction.

When washing is performed, the door 8 is opened, laundry is put into the rotating drum 5, and operation is started by inputting an instruction from the operation / display unit. Water and detergent are supplied into the water tank 3 from a water supply line, the rotating drum 5 is rotationally driven by the drum drive motor 4, and a washing process is started. In the rotary drum 5, the laundry is wash | cleaned by the stirring blade 7 provided in the several places of the inner peripheral surface lifting laundry upward, and tapping washing which falls from the upper side is repeated. After this washing process, a rinsing process and a dehydration process are performed and washing is completed. In the case of inputting a driving course that consistently performs the washing process to the drying process, when washing is completed, the control unit 301 transfers the drum type laundry dryer 1 to the drying process after the washing is completed. In addition, when the wet clothing 401 is dried, the controller 301 may perform only a drying process.

In the drying process, the rotary drum 5 accommodates laundry or wet clothing (hereinafter referred to as clothing 401), which has been dehydrated, which is a dry object. When the drying step is performed, the rotary drum 5 is rotated at a predetermined rotational speed corresponding to the drying step to stir the garment 401. While stirring the garment 401, the control unit 301 drives the heat pump unit 20 and the blowing fan 15 to circulate the drying air. In this drying process, the water tank 3 functions as a drying chamber for accommodating and drying to-be-dried objects, such as the clothing 401. As shown in FIG.

As shown in FIG. 2, the compressor 27 of the heat pump unit 20 compresses the refrigerant. By the pressure at the time of compression, the refrigerant flows through the refrigerant passage 41 from the compressor 27 and sequentially circulates through the radiator 29, the throttle portion 42, the heat absorber 28, and the compressor 27. The compressed refrigerant flows into the radiator 29 and flows through a portion 41A disposed in the radiator 29 of the refrigerant passage 41. When the coolant flows through the portion 41A, the air in contact with the fin 29D provided on the portion 41A deprives heat of the coolant, and the air is heated to generate heated air. The heated air is supplied from the exhaust space 29C to the rotary drum 5 from the intake port 11 via the exhaust connection pipe 33 and the blower duct 13 to take moisture from the clothes 401 being stirred to absorb moisture. It becomes air and is discharged from the exhaust port 12.

As drying of the garment 401 progresses, lint, such as a seam, is generated from the garment 401 and is contained in hygroscopic air. The filter unit 60 having the lint filter 61 prevents the lint from being deposited on the blower fan 15 or the blower pipe and the blower capacity is lowered. The hygroscopic air discharged from the exhaust port 12 enters the filter unit 60, the lint contained in the hygroscopic air is captured by the lint filter 61, and the hygroscopic air is then sent out to the duct 14. The moisture absorption air sent to the duct 14 enters the intake space 28C of the heat pump unit 20 via the intake connecting pipe 32. Hygroscopic air contacts the fin 28D provided in the heat absorber 28. The refrigerant is depressurized by the throttle portion 42 and passes through the portion 41B disposed in the heat absorber 28 of the refrigerant passage 41. The pin 28D is provided in the portion 41B. When the refrigerant passes through the portion 41B, the coolant takes sensible heat and latent heat from the moisture absorbing air in contact with the fin 28D, and dehumidifies the moisture absorbing air. The dew condensation water generated by dehumidification is dripped into the water storage part 34, and the air dehumidified and dried enters the radiator 29, and is heated again. As mentioned above, the rotary drum 5, the filter unit 60, the blower 15, the heat absorber 28, and the radiator 29 form the air circulation path 201 which circulates air. The water stored in the water storage part 34 is discharged into the water tank 3 by the drain pump which runs every predetermined time, and is drained from the drain port to the outside through the drain pipe 25 by opening the drain valve 19. As shown in FIG.

The heat amount when the radiator 29 heats air is approximately equal to the sum of the electric energy consumed by the compressor 27 and the heat amount that the heat absorber 28 absorbs heat from the moisture absorbing air. Therefore, the radiator 29 may heat the air with a heat amount larger than the electric energy input to the compressor 27. When the circulation of the air in the air circulation path 201 is repeated, the total amount of heat is continuously accumulated in the entire air by subtracting the amount of naturally radiated heat from the energy consumed by the compressor 27. If the heat amount of the refrigerant continues to increase with such accumulation, the temperature and pressure of the refrigerant increase excessively, which may cause an overload of the compressor 27 in the near future. To avoid this, as shown in FIG. 2, the filter unit 60 includes an air outlet 46 for discharging a part of the air circulating in the air circulation path 201 and air for introducing outside air into the air circulation path 201. An introduction port 47 is formed. The filter unit 60 is provided with the exhaust filter 62 which communicates with the air outlet 46, and the intake filter 63 which communicates with the air inlet 47. As shown in FIG.

The controller 301 monitors the temperature of the coolant flowing through the coolant pipe 41, and when the coolant temperature reaches a predetermined temperature or more, opens the intake valve 74 provided in the air inlet 47 to open the air inlet 47. ) Is introduced into the air circulation path 201. The blower fan 15 is provided downstream of the air inlet 47, and outside air flows into the air circulation path 201 from the air inlet 47 by the negative pressure generated by the blower fan 15. As the outside air flows in, some of the moisture absorption air in the air circulation path 201 is exhausted from the air outlet 46. The temperature of the outside air is lower than the moisture absorption air of the air circulation path 201. The temperature of the air circulating in the air circulation path 201 decreases due to the cooling caused by the inflow of outside air and the discharge of the high temperature hygroscopic air. As a result, the temperature of the refrigerant is also lowered, whereby an overload to the compressor 27 due to excessively high temperature of the refrigerant can be prevented. When the temperature of the coolant falls to a predetermined temperature, the control unit 301 closes the intake valve 74 to stop the introduction of outside air from the air inlet 47. As a result, heat is accumulated in the air circulating in the air circulation path 201 without being exhausted from the air outlet 46, and the air having a high drying effect circulates. The air outlet 46 is preferably provided with an exhaust valve 48 capable of adjusting the exhaust amount.

In the drum type laundry dryer 1 which is the drying apparatus which concerns on embodiment, the air circulation path 201 guides the moisture absorption air discharged from the water tank 3 which is a drying chamber to the heat absorber 28, and the moisture absorber 28 absorbs moisture. The air is dehumidified to generate dry air, the dry air is heated in the radiator 29 to generate heated air, and the heated air is introduced into the water tank 3. The air outlet 46 is provided downstream of the water tank 3 and upstream of the heat absorber 28 in the air circulation path 201, and exhausts a part of the moisture absorption air from the air circulation path 201. The lint filter 61 is provided downstream of the water tank 3 and upstream of the heat absorber 28 in the air circulation path 201 to capture the lint contained in the hygroscopic air. The air inlet 47 is provided downstream of the lint filter 61 and upstream of the heat absorber 28 in the air circulation path 201, and introduces outside air into the air circulation path 201. In addition, the air outlet 46 is provided upstream of the lint filter 61.

Intermittent operation of the compressor 27 in order to avoid excessive rise of the temperature of the refrigerant lowers the heating capacity and lengthens the drying time. In the drum type laundry dryer 1 according to the embodiment, since the heat pump unit 20 is operated in an optimum state by the control of the intake valve 74, the compressor 27 does not need to be interrupted. In addition, since the air discharge port 46 discharges the moisture absorption air which exited the water tank 3, there is little energy loss. Moreover, since the outside air introduced from the outside is mixed with the air after leaving the water tank 3, the effect of air discharge and the introduction of the outside air on the drying effect is small, and the drying time does not increase.

The exhaust filter 62 is provided in the filter unit 60 which communicates with the air discharge port 46, and the lint contained in the air in the air circulation path 201 is not discharged | emitted outside. In addition, an intake filter 63 is provided in the filter unit 60 that communicates with the air inlet 47 so that dust contained in the outside air does not enter the air circulation path 201. The filter unit 60 is integrally provided with the exhaust filter 62, the intake filter 63, and the lint filter 61.

3A and 3B are perspective views of the filter unit 60. The filter unit 60 is detachably attached to the filter container 60A (FIG. 1) in the washing machine housing 2 so that it can be taken out and taken out from the front. By inserting from the front part, the main part of the filter unit 60 is connected to the opening part of a pipe line so that each main part may communicate with a ventilation pipe line. An exhaust filter 62 is provided on the side surface 66A of the filter housing 66. A blower pipe passage 101 through which air exiting the exhaust port 12 of the water tank 3 flows into the lower surface opening 66B of the filter housing 66 so that the hygroscopic air that leaves the water tank 3 in the filter housing 66 is connected. Inflow. The hygroscopic air flows into the lint filter 61 through the air inlet 65. An air outlet 46 communicating with the exhaust filter 62 is located downstream of the exhaust port 12 opening to the water tank 3 and is located upstream of the lint filter 61. Therefore, even when the lint filter 61 is clogged and the air volume of the air flowing through the air circulation path 201 decreases, the moisture absorption air can be stably discharged from the air outlet 46.

The lint filter 61 has a lower filter 61A and an upper filter 61B positioned above the lower filter 61A. The upper filter 61B is fitted to the lower filter 61A so as to be openable and closeable by the hinge portion 67. The lint filter 61 is formed in the shape of a bag that swells in a direction 61C downstream of the blowing pipe. Hygroscopic air entered from the air inlet 65 is separated into hygroscopic air directed upward and downward. Hygroscopic air toward below permeate | transmits filter sheet 64A adhering to the opening part formed in lower filter 61A. The hygroscopic air directed upward passes through the filter sheet 64B adhering to the opening formed in the upper filter 61B. The filter sheets 64A and 64B trap lint contained in the air as they pass through them. Hygroscopic air which has passed through the filter sheets 64A and 64B, respectively, flows in the direction 61C toward downstream. As shown in FIG. 3A, when the upper filter 64B is closed to the lower filter 64A, the surface 164A of the filter sheet 64A faces the surface 164B of the filter sheet 64B.

Since the lint filter 61 is formed in the shape of a bag composed of the lower filter 61A and the upper filter 61B fitted together, the lint filter 61 has a high trapping effect of lint. In addition, since the area of the filter sheets 64A and 64B can be widened, the lint filter 61 can maintain the effect of capturing lint over a long period of time. When the upper filter 61B is closed on the lower filter 61A, the opening projection 68 opened upward of the lower filter 61A is fitted into the fitting groove 69 formed in the upper filter 61B. Maintain high confidentiality. Since the lint gradually accumulates in the lint filter 61, it is necessary to remove the lint accumulated regularly. When the filter unit 60 is taken out from the washing machine housing 2 and the upper filter 61B is opened, the inside of the bag shape, that is, on the surface 164B of the filter sheet 64B and the surface 164A of the filter sheet 64A The lint deposited on the) phase can be easily removed. When the upper filter 61B is closed and fitted on the lower filter 61A, the fitting concave portion 72 formed above the air inlet 65 has a fitting protrusion 71 provided at the distal end of the upper filter 61B. Locks into position. Therefore, it is possible to prevent the upper filter 61B from being opened due to the vibration or shock when the filter unit 60 is taken out to the outside, and the lint accumulated therein can be prevented from scattering to the outside.

When removing the accumulated lint, a finger is pulled up from the open concave portion 73 formed in the filter housing 66 and the fitting protrusion 71 and the fitting concave portion 72 are pulled up. The fitting of is separated and the upper filter 61B can be opened from the lower filter 61A as shown in FIG. 3B.

The exhaust filter 62 formed on the side surface 66A of the filter housing 66 is provided to be open in the lateral direction of the flow of the hygroscopic air, that is, parallel to the flow. Therefore, when the air outlet 46 communicating with the exhaust filter 62 is opened by the exhaust valve 48, the air circulating in the air circulation path 201 is not discharged at once, but the opening of the air outlet 46 is opened. By appropriately adjusting the diameter and the ventilation cross-sectional area of the exhaust valve 48, part of the air can be discharged to the outside. When this air is discharged, the lint contained in the air is captured by the exhaust filter 62, and the lint is not discharged to the outside.

The intake filter 63 is provided in the lateral direction of the flow of air passing through the lint filter 61, that is, in parallel with the flow. Therefore, when a part of hygroscopic air is discharged from the air outlet 46, outside air flows in from the air inlet 47 so as to replenish the discharged part, and the outside air passes through the intake filter 63 to allow the air circulation path 201. Flows into). A partition plate 70 is provided between the intake filter 63 and the lint filter 61 in order to suppress the flow of the air passing through the lint filter 61 from interfering with the introduction of outside air introduced into the air circulation path 201. It is installed. As shown in FIG. 2, the air inlet 47 is located upstream immediately before the blowing fan 15, that is, the air inlet 47 is connected to the blowing fan 15. In this position, since the negative pressure by the blowing fan 15 is large, a sufficient amount of outside air can be introduced into the air circulation path 201 from the air inlet 47.

In the air outlet 46, an exhaust valve 48 is preferably provided. By controlling the intake valve 74 and the exhaust valve 48 together, the controller 301 can control the air in the air circulation path 201 in response to the outside air temperature. Since the temperature of the place where the drum type laundry dryer 1 is installed also changes according to the season or the environment, the control corresponding to the ambient temperature is necessary. When the ambient temperature is low and the amount of natural heat dissipation from the air circulation path 201 is large, the controller 301 controls the opening of the intake valve 74 to control the amount of low temperature outdoor air introduced from the air inlet 47. In addition, the amount of heat dissipation is reduced by suppressing the opening of the exhaust valve 48 to reduce the amount of high temperature hygroscopic air discharged from the air outlet 46. On the other hand, when the ambient temperature is high and the amount of natural heat dissipation from the air circulation path 201 is small, the control unit 301 increases the opening frequency of the intake valve 74 to increase the introduction amount of outside air, and also opens the exhaust valve 48. Increase the amount of hygroscopic air discharged from the air circulation path 201. The air inlet 47 is preferably provided with an intake duct 75 which is opened to the outside of the washing machine housing 2, and introduces a low temperature outside air into the air circulation path 201 by the intake duct 75, Excessive temperature rise can be suppressed.

In the filter unit 60, the lint filter 61, the exhaust filter 62, and the intake filter 63 are integrated. Therefore, when the filter unit 60 is pulled out from the front part of the washing machine housing 2, three filters 61, 62, and 63 can be taken out simultaneously, and three filters can be collectively cleaned. Thus, the filter unit 60 can be easily maintained. Although the lint filter 61 has a bag shape having high performance of capturing lint, the lint filter 61 can be divided into two parts by the upper filter 61B and the lower filter 61A to open the inside, and thus, the accumulated lint can be easily removed.

The filter unit 60 is connected to the air circulation path 201 and the air outlet port 46 by being inserted into the filter container 60A, so that the filter unit 60 is connected to the air inlet port 47. It can be arrange | positioned easily in each flow path.

The drum type laundry dryer 1 according to the embodiment includes both the intake valve 74 of the air inlet port and the exhaust valve 48 of the air outlet port 46, or includes only the intake valve 74 to provide the exhaust valve ( The same effect can be obtained without providing 48 or providing only the exhaust valve 48 to provide the intake valve 74.

Although the drum type laundry dryer 1 was demonstrated as a drying apparatus by embodiment, the technique of the drying apparatus which concerns on embodiment can be similarly applied also to a vertical type | mold laundry dryer and a single type drying apparatus.

In the drying apparatus (drum type washing machine 1) which concerns on embodiment, air which dries the to-be-dried goods, such as clothing, can be produced stably, and shortening of drying time and energy saving can be realized.

Claims (11)

With refrigerant, A compressor for compressing the refrigerant; A radiator for dissipating heat of the compressed refrigerant; A throttle unit for reducing the compressed refrigerant; A heat absorber capable of dehumidifying by the reduced pressure refrigerant; A drying chamber capable of accommodating a dry matter and drying the dry matter with heated air to discharge moisture absorption air; The discharged moisture absorbing air is led to the heat absorber, the moisture absorbing air is dehumidified in the heat absorber to generate dry air, the dry air is heated in the radiator to generate the heating air, and the heated air is An air circulation path introduced into the drying chamber, An air outlet installed in the air circulation path downstream of the drying chamber and upstream of the heat absorber, for exhausting a part of the moisture absorption air from the air circulation path; A lint filter installed in the air circulation path downstream of the drying chamber and upstream of the heat absorber, for catching lint contained in the moisture absorption air; It is installed downstream of the lint filter in the air circulation path and upstream of the endotherm, and has an air inlet for introducing outside air into the air circulation path. Drying device. The method of claim 1, The air outlet is installed upstream of the lint filter Drying device. The method of claim 1, Further provided with an intake filter for trapping dust in the outside air introduced into the air circulation passage from the air inlet Drying device. The method of claim 3, wherein And an exhaust filter for capturing lint from the portion of the moisture absorbing air exhausted from the air outlet. Drying device. The method of claim 4, wherein The lint filter, the intake filter, and the exhaust filter are integrally provided, and a filter unit detachable from the air circulation path is further provided. Drying device. The method of claim 1, And an exhaust filter for capturing lint from the portion of the moisture absorbing air exhausted from the air outlet. Drying device. The method of claim 1, And a partition plate for dividing the flow of air passing through the lint filter and the flow of outside air introduced from the air inlet. Drying device. The method of claim 1, And a blowing fan installed downstream of the air inlet in the air circulation passage and upstream of the heat absorber. Drying device. The method of claim 1, Further provided with an intake duct for guiding the outside air to the air inlet Drying device. The method of claim 1, Further provided with an intake valve for adjusting the amount of the outside air introduced from the air inlet Drying device. The method of claim 1, And an exhaust valve for adjusting an amount of the portion of the moisture absorbing air exhausted from the air outlet port. Drying device.

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