JP5819103B2 - Clothes dryer - Google Patents

Description

  The present invention generally relates to a clothes drying apparatus, and more particularly to a clothes drying apparatus using a heat pump as a heat source.

  As a clothes drying apparatus provided with a heat pump, for example, a clothes dryer described in JP-A-2004-215543 (Patent Document 1) and a clothes dryer described in JP-A-2009-61163 (Patent Document 2) Or the dryer described in the patent 4602109 (patent document 3) is conventionally known.

  Generally, in a clothes drying apparatus equipped with a heat pump, the heat pump includes a compressor that compresses the refrigerant, a condenser that discharges the heat of the compressed high-temperature and high-pressure refrigerant to the surroundings, and a decompression unit that depressurizes the high-pressure refrigerant. And an evaporator that removes heat from the surroundings by the decompressed low-pressure refrigerant, and a circulation device. The circulation device is configured by a tubular member in which a compressor, a condenser, a decompression unit, and an evaporator are connected. The refrigerant circulates through the circulation device. Moreover, the clothing drying apparatus using a heat pump includes a drying chamber that stores clothing to be dried and a circulation air passage that circulates drying air. The circulation air path is configured such that dry air circulates between the condenser and the drying chamber, between the drying chamber and the evaporator, and between the evaporator and the condenser.

  In a clothes drying apparatus equipped with a heat pump, the refrigerant gas compressed by the compressor is heated to high pressure and discharged from the compressor. In the condenser, the refrigerant gas discharged from the compressor exchanges heat with the air passing through the condenser. Thereby, the air which passes a condenser is heated. When the heated air is blown into the drying chamber, evaporation of moisture contained in the object to be dried proceeds.

  The drying air heated when passing through the condenser in the circulation air passage is sent to the drying chamber to dry the clothes. The air used for drying the clothes gives the clothes the amount of heat necessary to evaporate the moisture as sensible heat. Therefore, the temperature of the air blown into the drying chamber decreases when passing through the drying chamber. However, when the drying air passes through the drying chamber, it absorbs water vapor from the moisture contained in the garment, thereby obtaining latent heat from the garment having substantially the same amount of heat as that applied to the garment. Thus, the enthalpy of the drying air is maintained before and after the drying air and the clothing come into contact.

  Next, the amount of heat of the air used for drying, i.e., the air flowing from the drying chamber to the evaporator, is absorbed by the evaporator, so that the temperature of the air flowing to the evaporator is lowered below the dew point, and the air The contained water is removed by the evaporator. Then, the drying air is heated again by the condenser, and the drying air circulates in the order of the condenser, the drying chamber, and the evaporator, thereby drying the clothes.

  On the other hand, in terms of the refrigeration cycle, the amount of heat given to the air by the refrigerant in the condenser is the sum of the amount of heat obtained by the refrigerant in the evaporator and the electric power applied from the outside to drive the compressor. Therefore, in a clothes drying apparatus using a heat pump, when the operation of the clothes drying apparatus is continued, the difference between the amount of heat naturally released to the outside of the clothes drying apparatus and the electric power applied to the compressor from the outside. Only the overall energy of the clothes drying device increases. As the energy of the entire clothes drying apparatus increases, the energy of the heat pump refrigerant also increases. That is, the temperature and pressure of the refrigerant increase.

  However, when the refrigerant pressure reaches the upper limit value of the overload of the compressor, it is necessary to stop the operation of the clothing drying device by operating the safety device. Therefore, it is necessary to suppress an increase in energy of the entire clothes drying apparatus during the operation of the clothes drying apparatus.

  For example, in a clothes dryer described in Japanese Patent Application Laid-Open No. 2004-215743 (Patent Document 1), an outlet is formed in a portion between a drying chamber and a heat absorber (that is, an evaporator) in a circulation air passage. Has been. As a part of the drying air is discharged from the outlet to the outside of the clothes dryer, an increase in the energy of the clothes dryer is suppressed.

  On the other hand, the clothes dryer described in Japanese Patent Application Laid-Open No. 2009-61163 (Patent Document 2) reduces the amount of water evaporated from the clothes from the middle to the latter half of the drying operation. The dehumidifying ability of the evaporator is slightly reduced by reducing the flow rate of the refrigerant by the decompression means so as to increase the difference between the outlet temperature and the inlet temperature. Further, in the middle to the latter half of the drying operation, the dehumidifying capacity of the evaporator is slightly lowered and the operating frequency of the compressor is lowered. By such measures, the electric power applied from the outside of the clothes dryer is reduced, so that an increase in the overall energy of the clothes dryer is suppressed. In addition, a clothes dryer described in Japanese Patent Application Laid-Open No. 2009-61163 (Patent Document 2) uses energy to evaporate moisture from the clothes and reduces the amount of energy used for dehumidification, thereby drying the clothes dryer. It is possible to reduce the amount of power consumption without reducing the overall amount of energy used for operation and reducing the drying speed.

  In the dryer described in Japanese Patent No. 4602109 (Patent Document 3), an inlet is formed between the evaporator and the condenser in the circulation air passage, and the dryer is connected to the dryer through the inlet. Air is introduced from the outside, and the temperature of the cooled air is raised by passing through the evaporator. Thereby, it is avoided that the air flowing in from the outside of the dryer is wastedly cooled by the evaporator. On the other hand, in the dryer described in Japanese Patent No. 4602109 (Patent Document 3), the outlet formed in the circulation air passage is between the rotating drum (that is, the drying chamber) in the circulation air passage and the evaporator. Is formed.

JP-A-2004-215543 JP 2009-61163 A Japanese Patent No. 4602109

  As described above, the clothes dryer described in Japanese Patent Application Laid-Open No. 2009-61163 (Patent Document 2) suppresses an increase in energy of the entire clothes dryer by reducing the compression capability of the compressor. However, the clothes dryer described in Japanese Patent Application Laid-Open No. 2009-61163 (Patent Document 2) has not been considered for improving the drying efficiency.

  On the other hand, the clothes dryer described in Japanese Patent Application Laid-Open No. 2004-215543 (Patent Document 1) and the dryer described in Japanese Patent No. 4602109 (Patent Document 3) are configured to remove part of the drying air from the outside. The overall energy rise is suppressed by discharging the water into In the clothes dryer described in Japanese Patent Application Laid-Open No. 2004-215743 (Patent Document 1), an outlet for discharging part of the drying air to the outside includes a drying chamber and a heat sink ( That is, it is formed in the part between the evaporator. Further, in the dryer described in Japanese Patent No. 4602109 (Patent Document 3), the outlet formed in the circulation air passage is between the rotating drum (that is, the drying chamber) in the circulation air passage and the evaporator. Is formed. As described above, the structure in which the outflow port is formed in the portion between the drying chamber and the evaporator in the circulation air path is before the heat quantity of the air after passing through the drying chamber is recovered by the evaporator. Since it is discharged, it does not lead to an improvement in drying efficiency.

  Accordingly, an object of the present invention is to provide a clothes drying apparatus provided with a heat pump, which can improve drying efficiency.

  The clothes drying apparatus according to the present invention includes a heat pump, a drying chamber, and an air circulation path. The heat pump includes a compressor, a condenser, a throttle unit, an evaporator, and a refrigerant pipe. The compressor compresses the refrigerant and raises the temperature of the refrigerant. The condenser heats air by exchanging heat between the refrigerant compressed by the compressor and the air. The throttle unit reduces the pressure of the refrigerant that has heated the air. The evaporator cools the air by exchanging heat between the decompressed refrigerant and the air. The refrigerant pipe connects the compressor, the condenser, the throttle unit, and the evaporator so that the refrigerant circulates in the order of the compressor, the condenser, the throttle unit, and the evaporator.

  The drying chamber stores an object to be dried. The drying chamber is supplied with air heated by a condenser. The air circulation path is connected to the heat pump and the drying chamber so that air circulates in the order of the drying chamber, the evaporator, the condenser, and the drying chamber. Moreover, the clothes drying apparatus according to the present invention is configured such that, of the drying air circulating in the air circulation path, a part of the drying air that has passed through the evaporator is circulated to the condenser, and the drying air that has passed through the evaporator. The other part is discharged to the outside of the clothes drying apparatus without passing through the condenser.

  According to the clothes drying apparatus according to the present invention, a part of the drying air is discharged outside the clothes drying apparatus after passing through the evaporator. Thus, before the drying air is discharged to the outside of the clothes drying apparatus, the amount of heat of the drying air is recovered by the evaporator, so that the temperature and pressure of the heat pump refrigerant can be maintained. . Therefore, according to the clothes drying apparatus according to this invention, it is possible to improve drying efficiency.

  The clothes drying apparatus according to the present invention preferably further includes an air outflow path. The air outflow path preferably has an outlet formed in a portion of the air circulation path between the drying chamber and the evaporator. Moreover, it is preferable that an air outflow path is what makes air flow out of an air circulation path | route via an outflow port from an air circulation path | route. In the clothes drying apparatus according to the present invention, the air circulation path preferably has a main flow path. In the main flow path, the drying air passes at least through the condenser. Furthermore, in the clothes drying apparatus according to the present invention, the evaporator preferably includes a first evaporator part and a second evaporator part. The first evaporator portion is preferably disposed in the main channel and cools the air flowing through the main channel. The second evaporator portion is preferably disposed in the air outflow path and cools the air flowing through the air outflow path.

  According to this configuration, a part of the drying air flowing through the air circulation path passes through the condenser after passing through the first evaporator portion arranged in the main flow path. In addition, another part of the drying air flowing through the air circulation path flows out from the air circulation path to the air outflow path through the outlet. The drying air that has flowed out to the air outflow path passes through the second evaporator portion and is then discharged to the outside of the clothing drying apparatus. Thus, according to this configuration, before the drying air is discharged to the outside of the clothing drying apparatus, the amount of heat of the drying air is recovered by the second evaporator portion disposed in the air outflow path. Can do. Thereby, the temperature and pressure of the refrigerant of the heat pump can be maintained.

  The clothes drying device according to the present invention preferably further includes a first blower and a second blower. It is preferable that a 1st air blower blows the air heated with the condenser to a drying chamber. It is preferable that the 2nd air blower is arrange | positioned at the air outflow path. Moreover, it is preferable that a 2nd air blower blows the air cooled by the 2nd evaporator part to the exterior of an air circulation path.

  According to this configuration, the drying air can be stably circulated in the air circulation path by the first blower. In addition, even when the sufficient static pressure difference necessary for causing the drying air to flow out does not occur before and after the second evaporator portion, the necessary amount of drying air is reduced by the operation of the second blower. It can be discharged outside the clothes drying device.

  In the clothes drying apparatus according to the present invention, the compressor, the condenser, the throttle part, the first evaporator part, and the second evaporator part are the compressor, the condenser, the throttle part, and the second evaporator part. And it is preferable that it is connected by refrigerant | coolant piping so that a refrigerant | coolant may circulate in order of a 1st evaporator part.

  Generally, when the refrigerant maintains a gas-liquid two-phase inside the evaporator and all the refrigerant can be evaporated at the outlet of the evaporator, the heat exchange efficiency of the evaporator should be maximized. Can do. However, since it is necessary to prevent the compressor from sucking in the liquid refrigerant, the opening degree of the throttle portion and the like are controlled so as to complete the evaporation of the refrigerant upstream of the outlet of the evaporator. Therefore, the heat exchange performance is reduced in the final stage of the evaporator.

  On the other hand, according to the configuration of the clothes drying apparatus according to the present invention, the first evaporator part including the final stage of the evaporator is connected to the second evaporator part by the refrigerant pipe. Thus, the heat pump can be configured so that the final stage of the evaporator is not included in the second evaporator part. That is, in the normal control range, the second evaporator portion does not include a portion where the heat exchange performance is lowered. For this reason, the air flowing through the air outflow passage is sufficiently recovered by the second evaporator portion after the amount of heat of the air flowing out from the air outflow passage to the outside of the clothing drying device is recovered from the outside of the clothing drying device. To be leaked. That is, according to the structure of the clothes drying apparatus according to the present invention, the air sufficiently heat-exchanged by the second evaporator portion of the evaporator flows out of the clothes drying apparatus. In other words, it is possible to avoid air that has not been sufficiently heat exchanged from flowing out of the clothes drying apparatus. Thus, according to the structure of the clothes drying apparatus according to the present invention, the air is sufficiently heat-exchanged by the second evaporator portion not including the final stage of the evaporator, and the first including the final stage is included. Since the drying air also exchanges heat with the evaporator portion, the heat amount of the drying air can be reliably recovered by the first evaporator portion and the second evaporator portion.

  The clothes drying apparatus according to the present invention preferably further includes an air outflow path. The air outflow path preferably has an outlet formed in a portion of the air circulation path between the evaporator and the condenser. Moreover, it is preferable that an air outflow path is what makes air flow out of an air circulation path | route via an outflow port from an air circulation path | route.

  According to this configuration, a part of the drying air flowing through the air circulation path passes through the condenser after passing through the evaporator. Further, another part of the drying air flowing through the air circulation path flows out to the air outflow path through the outlet after passing through the evaporator. The drying air that has flowed out from the air circulation path to the air outflow path is discharged to the outside of the clothing drying apparatus. Moreover, according to this structure, in the heat pump, the structure which concerns on an evaporator and refrigerant | coolant piping is simplified. Thereby, the structure of the heat pump containing refrigerant | coolant piping, an air inflow path, and an air outflow path is simplified. Therefore, according to the clothes drying apparatus equipped with the heat pump, before the drying air is discharged to the outside of the clothes drying apparatus, the heat quantity of the air after passing through the drying chamber is recovered by the evaporator with a relatively simple configuration. can do.

  The clothes drying device according to the present invention preferably further includes a first blower and a second blower. It is preferable that a 1st air blower blows the air heated with the condenser to a drying chamber. Moreover, it is preferable that a 2nd air blower is arrange | positioned at an air outflow path, and ventilates the air cooled with the evaporator to the exterior of an air circulation path.

  According to this configuration, the drying air can be stably circulated in the air circulation path by the first blower. In addition, even when there is not enough static pressure difference before and after the evaporator in the air circulation path and the air outflow path, or when the static pressure upstream of the evaporator is not so large with respect to atmospheric pressure, The second blower can discharge a necessary amount of drying air to the outside of the clothing drying apparatus.

  The clothes drying device according to the present invention preferably further includes an air inflow path. The air inflow path has an inlet formed in a portion of the air circulation path between the evaporator and the condenser, and allows air to flow into the air circulation path from the outside of the air circulation path through the inlet. It is preferable.

  According to this structure, the air outside the air circulation path is mixed into the air after passing through the evaporator in the drying air. That is, the air that is used to dry the object to be dried includes air that flows from the outside of the air circulation path to the downstream side of the evaporator in the air circulation path. Therefore, before the drying air is supplied to the drying chamber, it is not wasted by the evaporator. Thereby, the energy required for heating the air in the condenser can be reduced, and the power consumption can be suppressed. Therefore, it is possible to further improve the drying efficiency.

  The clothes drying apparatus according to the present invention preferably further includes an opening / closing part. The opening / closing part is preferably disposed in the air inflow path and adjusts the amount of air flowing into the air circulation path.

  According to this configuration, the amount of air flowing into the air circulation path from the outside of the clothing drying apparatus can be adjusted based on the operation of the opening / closing unit.

  As described above, according to the present invention, it is possible to provide a clothes drying apparatus including a heat pump, which can improve drying efficiency.

It is the schematic which shows the structure of the drum type washing-drying machine which is an example of the clothing drying apparatus according to this invention. It is the schematic which shows an example of a structure of the heat pump of the clothing drying apparatus according to this invention. FIG. 3 is a pressure-enthalpy diagram of a refrigeration cycle according to an example in which an inflow port and an outflow port are closed in an example of a clothes drying apparatus according to the present invention, and shows a transition from the first half to the second half of a drying operation. It is. It is a graph which shows distribution of the static pressure of each part of the air circulation path | route which concerns on the example by which the inflow port and the outflow port were obstruct | occluded among examples of the clothing drying apparatus according to this invention. It is the schematic which shows another example of a structure of the heat pump of the clothing drying apparatus according to this invention.

  As a result of diligent research, the inventor has come up with the idea of exhausting a part of drying air to the outside not for the purpose of suppressing an increase in energy but for the purpose of improving the drying efficiency in the clothes drying apparatus. The inventor can improve the drying efficiency of the clothes drying device by collecting the amount of heat of the drying air with an evaporator before discharging the drying air to the outside of the clothes drying device. I found. The present invention has been made based on the above findings.

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

(First embodiment)
FIG. 1 shows a drum-type washing / drying machine 100 as an example of a clothes drying apparatus according to the present invention. As shown in FIG. 1, the drum type washing and drying machine 100 includes an outer box 1. The outer box 1 forms the outer shape of the main body of the drum type washing and drying machine 100. The outer box 1 has a substantially rectangular parallelepiped shape. The drum type washing and drying machine 100 includes a water tank 2, a rotating drum 3, and a motor 4 as a drive unit.

  The rotating drum 3 rotates around a rotation axis extending in the horizontal direction or in a direction inclined from the horizontal direction. As the material of the rotating drum 3, a stainless steel plate is generally used. A plurality of small holes (not shown) for water supply, drainage and ventilation are formed in the peripheral wall 3a and the bottom 3b of the rotary drum 3. The peripheral wall 3 a is a cylindrical part of the rotary drum 3. In the drum type washing and drying machine 100, the peripheral wall 3a has a substantially cylindrical shape. The peripheral wall 3a extends in a direction parallel to the direction in which the rotation axis extends.

  A plurality of baffles (not shown) are arranged on the peripheral wall 3a. The baffle extends substantially parallel to the rotation axis. Further, the baffle protrudes from the peripheral wall 3a inward in the radial direction of a circle centered on the rotation axis.

  The water tank 2 has a bottomed cylindrical shape. The rotating drum 3 is accommodated in the space inside the water tank 2. A counterweight (not shown) is attached to the lower part of the water tank 2. A plurality of counterweights may be attached to the water tank 2 in order to balance the entire water tank 2. The counterweight may be attached to the upper part of the water tank 2. A liquid balancer (not shown) is attached outside the edge of the opening of the rotary drum 3.

  The rotating drum 3 stores the laundry 5 as an object to be dried. A drive shaft 41 is fixed to the outer surface of the bottom 3 b of the rotary drum 3. The motor 4 is attached to the outer surface of the bottom 3 b of the water tank 2. The motor 4 is connected to the drive shaft 41.

  The drum-type washing / drying machine 100 is a clothes drying apparatus that uses the heat pump 71 as a heat source. As shown in FIG. 2, the heat pump 71 includes a compressor 14, a condenser 15, an evaporator part 171, an evaporator part 172, and a throttle part 16 as an expansion valve. The evaporator part 171 is an example of a first evaporator part. The evaporator part 172 is an example of a second evaporator part. The evaporator part 171 and the evaporator part 172 are examples of the evaporator 17 of the heat pump 71.

  The compressor 14 compresses the refrigerant and raises the temperature of the refrigerant. The condenser 15 heats the air by exchanging heat between the refrigerant compressed by the compressor 14 and the air. The throttle unit 16 reduces the pressure of the refrigerant that heated the air. The evaporator part 171 and the evaporator part 172 cool the air by exchanging heat between the decompressed refrigerant and the air. Further, the heat pump 71 includes a refrigerant pipe 18. The refrigerant pipe 18 evaporates between the compressor 14, the condenser 15, the throttle part 16, and the vaporization so that the refrigerant circulates in the order of the compressor 14, the condenser 15, the throttle part 16, the evaporator part 172, and the evaporator part 171. The evaporator part 171 and the evaporator part 172 are connected. The condenser 15, the evaporator part 171 and the evaporator part 172 are, for example, fin-tube heat exchangers.

  The drum-type washing and drying machine 100 (see FIG. 1) includes an air outflow path 131. The air outflow path 131 has an outflow port 131a, and allows air to flow out of the air circulation path 60 from the air circulation path 60 through the outflow port 131a. The outlet 131 a is formed in a portion of the air circulation path 60 between the drying chamber 32 and the evaporator portion 171.

  As shown in FIG. 1, the drum type washing and drying machine 100 includes a drying chamber 32, a fan 9, an air circulation path 60, and a control unit 20. A space inside the rotating drum 3 functions as a drying chamber 32. In addition, the air heated by the condenser 15 is supplied to the drying chamber 32. As shown in FIGS. 1 and 2, the air circulation path 60 includes a heat pump 71 and a drying chamber such that air circulates in the order of the drying chamber 32, the evaporator portion 171, the condenser 15, and the drying chamber 32. 32.

  The fan 9 as an example of the first blower blows the air heated by the condenser 15 to the drying chamber 32. As shown in FIGS. 1 and 2, the drying air flowing through the air circulation path 60 circulates in the order of the drying chamber 32, the evaporator portion 171, the condenser 15, the fan 9, and the drying chamber 32.

  A portion of the air circulation path 60 that is disposed inside the heat pump 71 is a main flow path 61. The air circulation path 60 has a connection path 62 and a supply path 63. The connection path 62 is a part extending between the condenser 15 and the fan 9 in the air circulation path 60. The supply path 63 is a part of the air circulation path 60 that extends between the fan 9 and the drying chamber 32. In the main channel 61, the drying air passes through at least the condenser 15. In the main channel 61, the drying air flows in the order of the evaporator portion 171 and the condenser 15.

  The evaporator portion 171 is disposed in the main channel 61 and cools the air flowing through the main channel 61. The evaporator portion 172 is disposed in the air outflow path 131 and cools the air flowing through the air outflow path 131. The drum type washing and drying machine 100 (see FIG. 1) includes a fan 19. The fan 19 as an example of the second blower is disposed in the air outflow path 131. The fan 19 blows the air cooled by the evaporator portion 172 to the outside of the air circulation path 60.

  Furthermore, the drum type washing / drying machine 100 (see FIG. 1) includes an air inflow path 121. The air inflow path 121 has an inflow port 121a, and allows air to flow into the air circulation path 60 from the outside of the air circulation path 60 through the inflow port 121a. The inflow port 121 a is formed in a portion of the air circulation path 60 between the evaporator portion 171 and the condenser 15. The fan 19 is disposed downstream of the evaporator portion 172 in the air outflow path 131.

  The drum type washing / drying machine 100 (see FIG. 1) includes a temperature / humidity detection unit 22. The temperature / humidity detector 22 detects, for example, the temperature and relative humidity of the air circulating between the evaporator portion 171 and the condenser 15 in the air circulation path 60.

  In addition, arrangement | positioning of the temperature / humidity detection part 22 is not specifically limited. The temperature / humidity detector 22 only needs to be disposed in the air circulation path 60. The temperature / humidity detection unit 22 may be arranged outside the tubular member forming the air circulation path 60 or may be arranged inside. A plurality of temperature / humidity detection units 22 may be arranged in the air circulation path 60.

  Further, as shown in FIG. 1, the control unit 20 includes a determination unit 21. In the drum type washing / drying machine 100, the judgment unit 21 judges the control necessary for the operation of the drum type washing / drying machine 100. The control unit 20 controls the heat pump 71, the fan 19, and the fan 9 based on, for example, the temperature and humidity of the drying air detected by the temperature / humidity detection unit 22 (see FIG. 2). Further, when the motor 4 is controlled by the control unit 20, the rotation, stop, and rotation speed of the rotary drum 3 are adjusted.

  The drum type washing and drying machine 100 includes an opening / closing part 81 (see FIG. 2). As shown in FIG. 2, the opening / closing part 81 is arranged in the air inflow path 121 and adjusts the amount of air that flows into the air circulation path 60. The opening / closing unit 81 is connected to the control unit 20 (see FIG. 1), for example, electromagnetically or electronically. The control unit 20 detects the state including the temperature and humidity of the ambient air outside the drum type washing and drying machine 100, the state of the heat pump 71, and the state of the drying air, and based on the detection results, the control unit 20 Controls the opening / closing part 81.

  By the operation of the opening / closing part 81, the air inflow path 121 is opened and closed, and the amount of air flowing into the air inflow path 121 is adjusted. A sensor (not shown) for detecting a state including the temperature and humidity of the ambient air outside the air circulation path 60 is disposed at a desired position in the drum type washing and drying machine 100. In addition, the opening / closing part 81 has a difference between the static pressure upstream of the opening / closing part 81 in the air inflow path 121 and the static pressure between the evaporator portion 171 and the condenser 15 in the main channel 61. It may operate based on this.

  The operation for drying the laundry 5 by the drum type laundry dryer 100 configured as described above will be described. First, when the motor 4 is driven, the rotary drum 3 is rotated, and driving of the fan 9 and the heat pump 71 is started. The drying air flows through the air circulation path 60 as indicated by the two-dot chain line by the airflow generated by the fan 9. 1 and 2 schematically indicate the direction in which the airflow flows, and do not indicate the speed or scale of the airflow.

  The air flowing into the drying chamber 32 by the air flow generated by the fan 9 obtains moisture from the laundry 5 stirred in the drying chamber 32 and flows through the air circulation path 60 toward the heat pump 71. A part of the air flowing into the heat pump 71 from the air circulation path 60 is dehumidified below the dew point in the evaporator portion 171. The dehumidified air is heated by the condenser 15 to be heated and reduced in humidity, and flows again into the drying chamber 32 as drying air. By repeating such an air flow, the laundry 5 is dried.

  On the other hand, the other part of the air that has flowed into the heat pump 71 from the drying chamber 32 through the air circulation path 60 flows out to the air outflow path 131 through the outlet 131a without passing through the evaporator portion 171. The air flowing out from the air circulation path 60 to the air outflow path 131 passes through the evaporator portion 172. Air passing through the evaporator portion 172 is dehumidified in the evaporator portion 172. Thus, the air discharged to the outside of the drum type washing and drying machine 100 is after being dehumidified by the evaporator portion 172. As described above, the drum type washing / drying machine 100 can recover the amount of heat of the drying air at the evaporator portion 172 before the drying air is discharged to the outside of the drum type washing / drying machine 100. That is, the drum-type washing / drying machine 100 circulates a part of the drying air that has passed through the evaporator 17 among the drying air that circulates in the air circulation path 60, and the drying that has passed through the evaporator 17. The other part of the working air is discharged to the outside of the drum type washing and drying machine 100 without passing through the condenser 15.

  The opening / closing part 81 opens the air inflow path 121 when the drum type washing / drying machine 100 is operated so as to dry the laundry 5. Thereby, atmospheric air flows into the air inflow path 121. The ambient air that has flowed into the air inflow path 121 flows into the main flow path 61 of the air circulation path 60 through the inflow port 121a. As described above, when the opening and closing part 81 opens the air inflow path 121 when the drying operation of the drum type washing and drying machine 100 continues, the air flowing into the main channel 61 from the air inflow path 121 The air flowing out from the main flow path 61 to the air outflow path 131 replaces the air outside the air circulation path 60 and the air flowing through the main flow path 61.

  Next, heat exchange between the refrigeration cycle of the heat pump 71 and the drying air will be described. The refrigerant (R134a) in a gaseous state that has been heated to a high pressure by the compressor 14 is sent to the condenser 15. In the condenser 15, the amount of heat of the refrigerant is radiated to the drying air, so that the liquefaction of the refrigerant proceeds. The refrigerant that has passed through the condenser 15 is decompressed by the throttle unit 16. In the throttle unit 16, the refrigerant whose pressure reduction and flow rate are controlled releases heat and changes to a low-temperature and low-pressure liquid. In the evaporator part 172, the gasification of the refrigerant proceeds as the evaporator part 172 recovers heat from the air flowing through the air outflow path 131 out of the air returned from the drying chamber 32 to the heat pump 71. Further, in the evaporator portion 171, the gasification of the refrigerant proceeds as the evaporator portion 171 recovers the heat amount from the air flowing through the main flow path 61 out of the air returned from the drying chamber 32 to the heat pump 71.

  Depending on the temperature and humidity of the ambient air outside the air circulation path 60, when a part of the air in the air circulation path 60 is replaced with the ambient air, the drying efficiency of the drum type washing and drying machine 100 decreases. End up. Specifically, when the temperature of the ambient air is lower than the temperature of the portion between the evaporator portion 171 and the condenser 15 in the main flow path 61, the air flowing through the main flow path 61 of the air circulation path 60 It is not preferable to replace a part of the atmosphere with the atmosphere air.

  When a part of the air flowing through the air circulation path 60 is not replaced with the atmospheric air, the air inflow path 121 is blocked by the opening / closing part 81, so that air can flow into the main flow path 61 from the air inflow path 121. No. Further, in the air outflow path 131, the air flow in the air outflow path 131 can be blocked by operating the fan 19 to such an extent that atmospheric air does not flow into the main flow path 61 through the air outflow path 131. In addition, when the drum type washing / drying machine 100 is operated so as to dry the laundry 5, the fan 9 is operating. By such operations of the opening / closing portion 81, the fan 19, and the fan 9, the air is changed according to the state of the atmospheric air and the state of the drying air, or according to the state of the atmospheric air or the state of the drying air. Can be adjusted. Thus, the drum-type washing / drying machine 100 is improved in drying efficiency.

  On the other hand, the case where a part of the air flowing through the air circulation path 60 cannot be replaced with the ambient air will be described below. For example, in a standard test environment (air temperature; 20 ° C., 65% RH), the laundry 5 is dried using the drum type laundry dryer 100 (see FIG. 1) in which the inlet 121a and the outlet 131a are closed. Do the journey. In this drying process, the fan 9 is rotated at 2400 rpm using the laundry 5 having a dry weight of 6 kg.

  When the drying operation of the drum type washing and drying machine 100 in which the inlet 121a and the outlet 131a are closed is continued for a long time, the drum type washing and drying machine 100 is applied from the outside to drive the compressor 14. The overall energy of the drum type washing and drying machine 100 increases by the difference between the electric power and the amount of heat naturally released to the outside of the drum type washing and drying machine 100. Therefore, when the drying air is continuously circulated as it is, the amount of heat of the entire drying air increases, and the amount of heat of the refrigerant circulating in the heat pump 71 increases, so that the pressure of the refrigerant increases. As a result, the refrigeration cycle in the second half of the drying operation gradually moves to the high-pressure side as compared with the first half of the drying operation (see FIG. 3).

  If the pressure of the refrigerant reaches the upper limit value of the overload of the compressor 14 by continuing the operation of the drum-type washing / drying machine 100 as it is, the drum-type washing / drying is performed by operating a safety device (not shown) or the like. The operation of the machine 100 needs to be stopped. Therefore, it is necessary to suppress an increase in the overall energy of the drum type washing and drying machine 100 during the operation of the drum type washing and drying machine 100. However, by reducing the rotation speed of the compressor 14 from 2400 rpm to 2150 rpm, for example, during the drying process, the pressure of the discharge section (not shown) of the compressor 14 is prevented from increasing and the pressure of the discharge section is reduced. Transition in a substantially constant state. In the test environment, the temperature of the drying air in the portion between the evaporator portion 171 and the condenser 15 (hereinafter referred to as B) when the pressure of the discharge portion of the compressor 14 is substantially constant. Was about 18 ° C. and the relative humidity was 100% RH.

  FIG. 4 shows a static pressure of a portion (hereinafter referred to as C) of the air circulation path 60 between the fan 9 and the evaporator portion 171 and a portion on the downstream side of the fan 9 (hereinafter referred to as the following) in the test environment. 4 is a graph showing the distribution of the static pressure of D) and the static pressure of the upstream portion of the evaporator portion 171 (hereinafter referred to as A). As shown in FIG. 4, the static pressure of D is the highest compared to the static pressure of other portions, and the drying air flows in the order of the drying chamber 32 (see FIG. 1), A, B, and C, The static pressure decreases in the order of A, B, and C.

  Under the test environment, air flowing through B, that is, air having a temperature of about 18 ° C. and a relative humidity of 100% RH is heated by the condenser 15, and washing is performed using the air heated by the condenser 15. Things are drying. Rather than heating the air having the temperature of about 18 ° C. and the relative humidity of 100% RH with the condenser 15, the atmospheric air having the temperature of 20 ° C. and the relative humidity of 65% RH is condensed in the test environment. Heating at 15 can improve the drying efficiency. However, in a clothes drying apparatus having a so-called open type structure in which all of the drying air is discharged to the outside of the drum-type washing and drying machine 100 after passing through the evaporator 17, When a large amount of high-humidity air is released, problems such as generation of mold occur.

  Therefore, in the drum type washing and drying machine 100, the inlet 121a and the outlet 131a are opened as shown in FIG. In the configuration of the drum-type washing / drying machine 100 in which the inflow port 121a and the outflow port 131a are opened, a part of the drying air can be discharged from the air outflow path 131 as described above. The evaporator portion 172 collects heat from a part of the drying air that flows out from the air circulation path 60 to the air outflow path 131. For example, when the evaporator part 171 and the evaporator part 172 have substantially the same heat exchange performance, a temperature of about 18 ° C. and a relative value of 100% RH are provided outside the drum type washing / drying machine 100. Air having humidity is discharged through the air outflow path 131. In addition, atmospheric air having a higher temperature and lower relative humidity than the exhausted air flows from the air inflow path 121. Thus, in the drum type washing / drying machine 100, the drying efficiency can be improved by replacing a part of the air in the air circulation path 60 and the ambient air.

  As described above, the drum type washing and drying machine 100 according to the first embodiment includes the heat pump 71, the drying chamber 32, and the air circulation path 60. The heat pump 71 includes a compressor 14, a condenser 15, a throttle unit 16, an evaporator 17, and a refrigerant pipe 18. The compressor 14 compresses the refrigerant and raises the temperature of the refrigerant. The condenser 15 heats the air by exchanging heat between the refrigerant compressed by the compressor 14 and the air. The throttle unit 16 reduces the pressure of the refrigerant that heated the air. The evaporator 17 cools the air by exchanging heat between the decompressed refrigerant and the air. The refrigerant pipe 18 connects the compressor 14, the condenser 15, the throttle unit 16, and the evaporator 17 so that the refrigerant circulates in the order of the compressor 14, the condenser 15, the throttle unit 16, and the evaporator 17. .

  The drying chamber 32 stores the laundry 5. The drying chamber 32 is supplied with air heated by the condenser 15. The air circulation path 60 is connected to the heat pump 71 and the drying chamber 32 so that air circulates in the order of the drying chamber 32, the evaporator 17, the condenser 15, and the drying chamber 32. The drum-type washing / drying machine 100 circulates a part of the drying air that has passed through the evaporator 17 among the drying air that circulates in the air circulation path 60, and the drying that has passed through the evaporator 17. The other part of the working air is discharged to the outside of the drum type washing and drying machine 100 without passing through the condenser 15.

  According to the drum type laundry dryer 100, a part of the drying air passes through the evaporator 17 and is discharged to the outside of the drum type laundry dryer 100. Thus, before the drying air is discharged to the outside of the drum-type washing / drying machine 100, the heat amount of the drying air is recovered by the evaporator 17, thereby maintaining the temperature and pressure of the refrigerant of the heat pump 71. can do. Therefore, according to the drum type washing / drying machine 100, it is possible to improve drying efficiency.

  The drum type washing and drying machine 100 includes an air outflow path 131. The air outflow path 131 has an outlet 131 a formed in a portion between the drying chamber 32 in the air circulation path 60 and the evaporator portion 171 in the evaporator 17. The air outflow path 131 allows air to flow out from the air circulation path 60 to the outside of the air circulation path 60 via the outflow port 131a. In the drum type washing and drying machine 100, the air circulation path 60 has a main flow path 61. In the main channel 61, the drying air passes through at least the condenser 15. Further, in the drum type washing and drying machine 100, the evaporator 17 has an evaporator part 171 and an evaporator part 172. The evaporator portion 171 cools the air that is disposed in the main flow path 61 and flows through the main flow path 61. The evaporator portion 172 is disposed in the air outflow path 131 and cools the air flowing through the air outflow path 131.

  According to this configuration, a part of the drying air flowing through the air circulation path 60 passes through the condenser 15 after passing through the evaporator portion 171 disposed in the main flow path 61. In addition, another part of the drying air flowing through the air circulation path 60 flows out from the air circulation path 60 to the air outflow path 131 through the outlet 131a. The drying air that has flowed out into the air outflow path 131 passes through the evaporator portion 172 and is then discharged to the outside of the drum type washing and drying machine 100. As described above, according to the drum type washer / dryer 100, before the drying air is discharged to the outside of the drum type washer / dryer 100, the evaporator portion 172 disposed in the air outflow path 131 allows the drying air to flow. The amount of heat can be recovered. Thereby, the temperature and pressure of the refrigerant of the heat pump 71 can be maintained.

  The drum type washing and drying machine 100 includes a fan 9 and a fan 19. The fan 9 blows the air heated by the condenser 15 to the drying chamber 32. The fan 19 is disposed in the air outflow path 131. The fan 19 blows the air cooled by the evaporator portion 172 to the outside of the air circulation path 60.

  According to this configuration, the fan 9 can stably circulate drying air in the air circulation path 60. Further, even when the sufficient static pressure difference necessary for allowing the drying air to flow out does not occur before and after the evaporator portion 172, the operation of the fan 19 causes the necessary amount of drying air to be supplied to the drum type laundry dryer. 100 can be discharged to the outside.

  In the drum-type washing and drying machine 100, the compressor 14, the condenser 15, the throttle part 16, the evaporator part 171, and the evaporator part 172 include the compressor 14, the condenser 15, the throttle part 16, the evaporator part 172, and The refrigerant pipes 18 are connected so that the refrigerant circulates in the order of the evaporator portion 171.

  Generally, when the refrigerant maintains a gas-liquid two-phase inside the evaporator and all the refrigerant can be evaporated at the outlet of the evaporator, the heat exchange efficiency of the evaporator should be maximized. Can do. However, since it is necessary to prevent the compressor from sucking in the liquid refrigerant, the opening degree of the throttle portion and the like are controlled so as to complete the evaporation of the refrigerant upstream of the outlet of the evaporator. Therefore, the heat exchange performance is reduced in the final stage of the evaporator. Note that the direction in which the rotational speed of the compressor is increased, the direction in which the opening of the throttle is increased, or the direction in which the amount of heat exchange between the evaporator and the drying air increases is the gas phase in the refrigerant piping of the evaporator. This is the direction in which the area expands.

  On the other hand, according to the configuration of the drum type washing and drying machine 100, the evaporator part 171 including the final stage of the evaporator 17 is connected to the evaporator part 172 by the refrigerant pipe 18. Thereby, the heat pump 71 can be configured so that the final stage of the evaporator 17 is not included in the evaporator portion 172. That is, in the normal control range, the evaporator portion 172 does not include a portion where the heat exchange performance is degraded. For this reason, the air flowing through the air outflow passage 131 is sufficiently recovered by the evaporator portion 172 after the amount of heat of the air flowing out from the air outflow passage 131 to the outside of the drum type washing / drying machine 100 is drum-type washing / drying. It flows out of the machine 100. In other words, according to the configuration of the drum type laundry dryer 100, the air that has been sufficiently heat-exchanged by the evaporator portion 172 of the evaporator 17 flows out of the drum type laundry dryer 100. In other words, it is possible to avoid air that has not been sufficiently heat-exchanged from flowing out of the drum type washing and drying machine 100. Thus, according to the configuration of the drum type washing and drying machine 100, air is sufficiently heat-exchanged by the evaporator portion 172 that does not include the final stage of the evaporator 17, and also by the evaporator portion 171 that includes the final stage. Since the drying air is heat-exchanged, the heat quantity of the drying air can be reliably recovered by the evaporator portion 171 and the evaporator portion 172. The normal control range here refers to a range in which the opening degree of the throttle portion 16 is controlled so as to complete the evaporation of the refrigerant upstream of the outlet of the evaporator 17. When the control is insufficient, the refrigerant enters a gas phase state in the entire interior of the evaporator portion 171 and a part of the evaporator portion 172.

  The drum type washing and drying machine 100 further includes an air inflow path 121. The air inflow path 121 has an inlet 121a formed in a portion of the air circulation path 60 between the evaporator 17 and the condenser 15, and air from the outside of the air circulation path 60 through the inlet 121a. Air is caused to flow into the circulation path 60.

  According to this configuration, the air outside the air circulation path 60 is mixed in the air after passing through the evaporator 17 in the drying air. That is, the air used for drying the laundry 5 includes air that flows from the outside of the air circulation path 60 to the downstream side of the evaporator 17 in the air circulation path 60. Therefore, before the drying air is supplied to the drying chamber 32, the evaporator 17 does not wastefully cool it. Thereby, the energy required for heating the air in the condenser 15 can be reduced, and the power consumption can be suppressed. Therefore, it is possible to further improve the drying efficiency.

  The drum type washing and drying machine 100 includes an opening / closing part 81. The opening / closing part 81 is disposed in the air inflow path 121 and adjusts the amount of air that flows into the air circulation path 60.

  According to this configuration, the amount of air flowing into the air circulation path 60 from the outside of the drum type washing and drying machine 100 can be adjusted based on the operation of the opening / closing part 81.

  In addition, the position where the control part 20 is arrange | positioned in the drum type washing-drying machine 100 is not specifically limited. The control unit 20 shown in FIG. 1 is schematically shown as long as it has a desired function as described above.

  In the drum type washing / drying machine 100, the driving amount of the fan 9 and the driving amount of the fan 19 can be adjusted. By adjusting at least the driving amount of the fan 19, the amount of high-humidity air flowing out from the air circulation path 60 to the air outflow path 131 can be adjusted. Further, during the period from the start to the end of the operation of the drum type washing and drying machine 100, for example, the drive amount of the fan 19 is adjusted so that the fan 19 is driven with a different drive amount every predetermined time. An amount of air corresponding to each predetermined time can be discharged from the air circulation path 60.

(Second Embodiment)
Below, the heat pump 72 as another example of the heat pump of the clothing drying apparatus according to this invention is demonstrated using FIG. In addition, below, the same code | symbol is attached | subjected to the thing of the same structure as the drum type washing-drying machine 100 which concerns on 1st Embodiment, and the description is abbreviate | omitted.

  The heat pump 72 is disposed in the drum type washing and drying machine 100 at, for example, substantially the same position as the heat pump 71 (see FIG. 1). As shown in FIG. 5, the heat pump 72 includes a compressor 24, a condenser 25, an evaporator 27, and a throttle unit 26 as an expansion valve. The evaporator 27 is an example of an evaporator of the heat pump 72.

  The compressor 24 compresses the refrigerant and raises the temperature of the refrigerant. The condenser 25 heats the air by causing heat exchange between the refrigerant compressed by the compressor 24 and the air. The throttle unit 26 reduces the pressure of the refrigerant that heated the air. The evaporator 27 cools the air by exchanging heat between the decompressed refrigerant and the air. The refrigerant pipe 28 connects the compressor 24, the condenser 25, the throttle unit 26, and the evaporator 27 so that the refrigerant circulates in the order of the compressor 24, the condenser 25, the throttle unit 26, and the evaporator 27. Link. The condenser 25 and the evaporator 27 are, for example, fin-tube heat exchangers. The evaporator 27 is disposed in the main channel 61 and cools the air flowing through the main channel 61.

  The air circulation path 60 is connected to the heat pump 72 and the drying chamber 32 so that air circulates in the order of the drying chamber 32 (see FIG. 1), the evaporator 27, the condenser 25, and the drying chamber 32. The fan 9 blows air heated by the condenser 25 to the drying chamber 32. The drying air flowing through the air circulation path 60 circulates in the order of the drying chamber 32, the evaporator 27, the condenser 25, the fan 9, and the drying chamber 32. In the main channel 61, the drying air flows in the order of the evaporator 27 and the condenser 15.

  The drum type washing and drying machine 100 provided with the heat pump 72 is further provided with an air outflow path 132. The air outflow path 132 has an outflow port 132a, and allows air to flow out of the air circulation path 60 from the air circulation path 60 through the outflow port 132a. The outlet 132 a is formed in a portion of the air circulation path 60 between the evaporator 27 and the condenser 25.

  The drum type washing and drying machine 100 provided with the heat pump 72 further includes a fan 29. The fan 29 as an example of the second blower is disposed in the air outflow path 132. Further, the air cooled by the evaporator 27 is blown out of the air circulation path 60 by the operation of the fan 29.

Further, the drum type washing and drying machine 100 including the heat pump 72 further includes an air inflow path 122. The air inflow path 122 has an inflow port 122a, and allows air to flow into the air circulation path 60 from the outside of the air circulation path 60 through the inflow port 122a. The inflow port 122 a is formed in a portion of the air circulation path 60 between the evaporator 27 and the condenser 15. The atmospheric air that has flowed into the main flow path 61 via the air inflow path 122 moves in the direction D ₁ near the inflow port 122a, thereby moving in the main flow path 61 toward the condenser 25. On the other hand, a portion of the drying air passing through the evaporator 27, by flowing in the direction D ₂ in the vicinity of the outlet 132a, flows out from the main flow path 61 in the air outlet channel 132.

  The drum type washing and drying machine 100 including the heat pump 72 further includes an opening / closing part 82. The configuration and operating principle of the opening / closing unit 82 are the same as those of the opening / closing unit 81 of the drum type washer / dryer 100 including the heat pump 71.

  In addition, when the static pressure of the part between the evaporator 27 and the condenser 25 in the main flow path 61 is a negative pressure compared with the static pressure outside the drum type washing dryer 100 (that is, atmospheric pressure). The fan 29 needs to be always operated. In this case, when the fan 29 is not operating, a part of the drying air that has passed through the evaporator 27 is unlikely to flow out of the drum type laundry dryer 100 through the air outflow path 132. Therefore, in the drum type washing and drying machine 100 provided with the heat pump 72, it is preferable that the fan 29 is always operated.

  However, in the drum type washing and drying machine 100 including the heat pump 72, the air inflow path 122 and the air outflow path 132 are connected to a portion of the main flow path 61 between the evaporator 27 and the condenser 25. . Therefore, a situation occurs in which a part of the atmospheric air flowing in from the air inflow path 122 flows out from the air outflow path 132 without moving toward the condenser 25. In order to avoid such a situation, the inflow port 122a and the outflow port 132a are preferably formed at positions as far apart as possible in the main channel 61. For example, the inlet 122a and the outlet 132a are formed in the main flow path 61 so that the interval between the inlet 122a and the condenser 25 is narrower than the interval between the outlet 132a and the evaporator 27. Such a situation can be avoided.

  As described above, the heat pump 72 of the drum type washer / dryer 100 according to the second embodiment includes the compressor 24, the condenser 25, the throttle unit 26, the evaporator 27, and the refrigerant pipe 28. The compressor 24 compresses the refrigerant and raises the temperature of the refrigerant. The condenser 25 heats the air by causing heat exchange between the refrigerant compressed by the compressor 24 and the air. The throttle unit 26 reduces the pressure of the refrigerant that heated the air. The evaporator 27 cools the air by exchanging heat between the decompressed refrigerant and the air. The refrigerant pipe 28 connects the compressor 24, the condenser 25, the throttle unit 26, and the evaporator 27 so that the refrigerant circulates in the order of the compressor 24, the condenser 25, the throttle unit 26, and the evaporator 27. .

  The air circulation path 60 is connected to the heat pump 72 and the drying chamber 32 so that air circulates in the order of the drying chamber 32, the evaporator 27, the condenser 25, and the drying chamber 32. Also, the drum-type washing and drying machine 100 circulates a part of the drying air that has passed through the evaporator 27 among the drying air that circulates in the air circulation path 60 to the condenser 25, and the drying air that has passed through the evaporator 27. The other part of the working air is discharged to the outside of the drum type washing and drying machine 100 without passing through the condenser 25.

  According to the drum type laundry dryer 100, a part of the drying air passes through the evaporator 27 and is discharged to the outside of the drum type laundry dryer 100. Thus, before the drying air is discharged to the outside of the drum type washing and drying machine 100, the amount of heat of the drying air is recovered by the evaporator 27, thereby maintaining the temperature and pressure of the refrigerant of the heat pump 72. can do. Therefore, according to the drum type washing / drying machine 100, it is possible to improve drying efficiency.

  The drum type washing and drying machine 100 including the heat pump 72 includes an air outflow path 132. The air outflow path 132 has an outlet 132 a formed in a portion of the air circulation path 60 between the evaporator 27 and the condenser 25. The air outflow path 132 allows air to flow out from the air circulation path 60 to the outside of the air circulation path 60 via the outflow port 132a.

  According to this configuration, part of the drying air flowing through the air circulation path 60 passes through the condenser 25 after passing through the evaporator 27. Further, another part of the drying air flowing through the air circulation path 60 flows out to the air outflow path 132 through the outlet 132 a after passing through the evaporator 27. The drying air that has flowed out from the air circulation path 60 to the air outflow path 132 is discharged to the outside of the drum type washing and drying machine 100.

  Moreover, according to this structure, the heat pump 72 is not provided with other evaporators other than the evaporator 27 as an example of an evaporator, and the structure concerning the evaporator 27 and the refrigerant | coolant piping 28 is simplified. . Thereby, the structure of the heat pump 72 including the refrigerant pipe 28, the air inflow path 122, and the air outflow path 132 is simplified. Therefore, according to the drum type washing and drying machine 100 provided with the heat pump 72, the heat quantity of the air after passing through the drying chamber 32 is relatively simple before the drying air is discharged to the outside of the drum type washing and drying machine 100. It can collect | recover with the evaporator 27 by simple structure.

  The drum type washing and drying machine 100 provided with the heat pump 72 includes a fan 9 and a fan 29. The fan 9 blows the air heated by the condenser 25 to the drying chamber 32. The fan 29 is disposed in the air outflow path 132 and blows the air cooled by the evaporator 27 to the outside of the air circulation path 60.

  According to this configuration, the fan 9 can stably circulate drying air in the air circulation path 60. Further, when there is no sufficient static pressure difference between the air circulation path 60 and the air outflow path 132 before and after the evaporator 27, or between the evaporator 27 and the condenser 25 in the main flow path 61. Even when the static pressure of the portion is not so large with respect to the atmospheric pressure, a necessary amount of drying air can be discharged to the outside of the drum type washing and drying machine 100 by the second blower.

  The drum type washing and drying machine 100 provided with the heat pump 72 includes an air inflow path 122. The air inflow path 122 has an inlet 122a formed in a portion of the air circulation path 60 between the evaporator 27 and the condenser 25, and air from the outside of the air circulation path 60 through the inlet 122a. Air is caused to flow into the circulation path 60.

  According to this configuration, the air outside the air circulation path 60 is mixed in the air after passing through the evaporator 27 in the drying air. That is, the air used for drying the laundry 5 includes air that flows from the outside of the air circulation path 60 to the downstream side of the evaporator 27 in the air circulation path 60. Therefore, before the drying air is supplied to the drying chamber 32, the evaporator 27 does not wastefully cool the drying air. Thereby, the energy required for heating the air in the condenser 25 can be reduced, and the power consumption can be suppressed. Therefore, it is possible to further improve the drying efficiency.

  The embodiment disclosed above should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above embodiments but by the scope of claims, and includes all modifications and variations within the meaning and scope equivalent to the scope of claims.

5: Laundry, 9: Fan, 14, 24: Compressor, 15, 25: Condenser, 16, 26: Throttle part, 17, 27: Evaporator, 18, 28: Refrigerant piping, 19, 29: Fan, 32: Drying chamber, 60: Air circulation path, 61: Main flow path, 71, 72: Heat pump, 81, 82: Opening / closing section, 100: Drum-type washing and drying machine, 121a, 122a: Inlet, 121, 122: Inflow of air Road, 131a, 132a: Outlet, 131, 132: Air outflow path, 171: Evaporator part, 172: Evaporator part

Claims (5)

A compressor that compresses the refrigerant to raise the temperature of the refrigerant, a condenser that heats the air by exchanging heat between the refrigerant compressed by the compressor and air, and a pressure reduction of the refrigerant that heated the air The refrigerant that circulates in the order of the throttle section, the evaporator that cools the air by exchanging heat between the decompressed refrigerant and the air, the compressor, the condenser, the throttle section, and the evaporator. And a refrigerant pump connecting the compressor, the condenser, the throttle unit, and the evaporator, and a heat pump,
A drying chamber for storing an object to be dried and supplied with air heated by the condenser;
The drying chamber, the evaporator, the condenser, and the order of the drying chamber so that air is circulated, Bei example and a connection air circulation path into said drying chamber and said heat pump,
Of the drying air circulating in the air circulation path, a part of the drying air that has passed through the evaporator is circulated to the condenser, and the other part of the drying air that has passed through the evaporator is condensed. without flowing into a vessel is discharged to the outside of the clothes drying apparatus,
An outlet formed in a portion of the air circulation path between the drying chamber and the evaporator;
And air flows out of the air circulation path from the air circulation path through the outlet.
An air outflow passage
The air circulation path has a main flow path;
In the main flow path, the drying air passes at least through the condenser,
The evaporator is disposed in the main flow path and cools the air flowing through the main flow path.
The evaporator portion and the air disposed in the air outflow path and flowing through the air outflow path are cooled.
A clothes drying device having a second evaporator portion . A first blower for blowing air heated by the condenser to the drying chamber;
Air arranged in the air outflow path and cooled by the second evaporator portion is passed through the air circulation path.
The clothes drying apparatus according to claim 1, further comprising a second blower for blowing air to the outside of the road . The compressor, the condenser, the throttle, the first evaporator part, and the second evaporator part
Are the compressor, the condenser, the throttle, the second evaporator part, and the first
Are connected by the refrigerant pipe so that the refrigerant circulates in the order of the evaporator part,
The clothing drying apparatus according to claim 1 or 2. An inlet formed in a portion of the air circulation path between the evaporator and the condenser;
And air flows into the air circulation path from the outside of the air circulation path through the inlet.
An air inflow passage
The clothes drying apparatus according to any one of claims 1 to 3 . An opening / closing part that is arranged in the air inflow path and adjusts the amount of air that flows into the air circulation path
The clothes drying apparatus according to claim 4, further comprising:

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