JP4834342B2 - Drum type washer / dryer - Google Patents

Description

  The present invention relates to a drum-type laundry dryer having a heat pump for drying laundry.

  2. Description of the Related Art Conventionally, a washing / drying machine having a heat pump for drying laundry has been attracting attention as having good drying performance and being effective in saving energy. In the washing and drying machine equipped with this heat pump, the moisture generated when the laundry is dried is collected by an evaporator (evaporator), and the latent heat collected in the fold is converted into a high-temperature refrigerant state by a compressor (compressor). Then, it is reused as energy for heating air with a condenser. In this way, the energy can be reused without losing almost any energy except for a slight heat loss outside. Therefore, efficient drying can be realized.

  Thus, in a washer / dryer equipped with this heat pump, especially a drum-type washer / dryer, a cylindrical water tank arranged in a horizontal axis divides the hot air inlet and the hot air outlet in the axial direction. A drum is disposed inside the water tank, and a driving device that rotates the drum outside the water tank and a hot air outlet of the water tank and a ventilation path that connects the hot air inlet are provided. An evaporator and a condenser of a heat pump are arranged in the ventilation path, and a compressor is connected to them outside the ventilation path. Further, a blower for circulating the air in the water tank through the ventilation path is also provided outside the water tank.

  With this configuration, when the laundry is dried, the air in the water tank is circulated through the air passage with the blower while the drum is rotated by the driving device, and the compressor of the heat pump is further operated. Then, the circulating air is cooled and dehumidified by exchanging heat with an evaporator, and heated hot air is heated by exchanging heat with a condenser. As a result, dry hot air is repeatedly supplied into the drum, and the laundry Drying is performed.

Thus, in the drum-type washing and drying machine for drying the laundry in this way, the hot air inlet and the hot air outlet of the water tank are provided separately in the axial direction of the water tank, whereas the ventilation path is provided. It is also known that the heat pump compressor is arranged below the water tank in a direction orthogonal to the axial direction of the water tank, and arranged below the water tank so that the compressor of the heat pump is aligned with the ventilation path in the axial direction of the water tank. (For example, refer to Patent Document 1).
JP 2005-52533 A

  In the case of the above conventional one, the route for circulating the air in the aquarium is complicated, and especially the bending from the aquarium to the ventilation passage is large and the air passage resistance is high, so that only a small amount of circulating air can be obtained. Thus, the heat exchange efficiency of the evaporator and condenser of the heat pump is poor, and the drying performance is not high. In addition, a large space is required to arrange the ventilation path and the heat pump compressor with respect to the water tank, and there is a disadvantage that the overall size and weight are increased.

  SUMMARY OF THE INVENTION The present invention has been made in view of the above-described circumstances. Accordingly, an object of the present invention is to provide a drum-type washing / drying machine that can obtain a high drying performance and can be made compact and lightweight as a whole.

In order to achieve the above object, in the drum-type washing and drying machine of the present invention, the outer box and the inner side of the outer box are arranged in a horizontal axis shape in which the axial direction is front and rear and in an upwardly inclined shape , A cylindrical water tank having a hot air inlet at the rear and a hot air outlet at the front, a drum disposed inside the water tank, a driving device for rotating the drum, a hot air outlet of the water tank, A ventilation duct provided by connecting a hot air inlet, an evaporator and a condenser disposed in the ventilation duct, and a compressor connected to the heat pump, and the air in the water tank, the hot air outlet From the hot air inlet through the ventilation duct to the inside of the water tank, and a blower that circulates in a suction manner from the front portion and a blowing manner from the rear portion.ゞArranged in parallel with the axial direction of the tank down the heat pump to the lateral position of the peripheral side portion having a cylindrical curved position and a by and the water tub of the ventilation duct side in the direction perpendicular to the axial direction of the tub The filter case that houses the filter that captures the lint that scatters out of the laundry is arranged in tandem with the evaporator and condenser of the heat pump, and the air duct is on the windward side from the front of the outer box. The side wall of the ventilation duct is provided with an end plate of an evaporator of a heat pump and an end plate of a capacitor .

According to the above means, the path when circulating the air in the aquarium is simple, especially the bending from the aquarium to the ventilation duct is not large, and the circulation air volume can be increased correspondingly, and in the evaporator and condenser of the heat pump Since the heat exchange efficiency can be increased, the drying performance can be increased. In addition, since the arrangement of the ventilation duct and the heat pump compressor with respect to the water tank can be made space-efficient, the overall compactness and weight reduction can be achieved as desired.
In addition, the flow of air from the fill case through the ventilation duct is also in a straight line and the circulation air volume is not reduced, so that the heat exchange efficiency in the evaporator and condenser of the heat pump can be further improved.
Furthermore, since the filter that captures the lint scattered from the laundry and carried to the circulating air can be easily taken in and out from the front of the machine body, the captured lint can be easily removed, and the circulation air volume is further reduced. You can
In addition, the side wall of the ventilation duct is composed of the end plate of the evaporator of the heat pump and the end plate of the condenser, so that the side wall of the ventilation duct can be made airtight and prevent air leakage from the ventilation duct. Since the circulation air volume is not reduced, the heat exchange efficiency of the evaporator and the condenser of the heat pump can be further improved.
In addition, in that case, the evaporator end plate and the capacitor end plate can be used as they are on the side wall of the ventilation duct, so that the side wall of the ventilation duct can be rationally configured to provide products at low cost. It can be made possible.

Hereinafter, an example (one embodiment) of the present invention will be described with reference to the drawings.
First, FIG. 2 shows an overall configuration of a drum type washing and drying machine, in which a water tank 2 is disposed inside an outer box 1 that is an outer shell. The aquarium 2 has a cylindrical shape, and has a horizontal axis shape in which the axial direction is front and rear (left and right in FIG. 2), and also has an inclined shape that rises forward (upward to the left in FIG. 2). It is supported by a pair of left and right suspensions 3 shown in FIG. The water tank 2 has a water tank cover 4 attached to the front end, and the water tank cover 4 has an annular shape having an opening 5 at the center. On the other hand, as shown in FIG. 2, the outer box 1 has an opening 6 for putting in and out the laundry on the front surface, and the opening 5 of the water tank cover 4 is connected to the opening 6 by a bellows 7. ing. Moreover, the opening 8 of the outer box 1 is provided with a door 8 that can be opened and closed on the front side opposite to the water tank 2 side.

  In addition, in the water tank 2, a hot air outlet 9 is formed at the upper part of the front end part, and a hot air inlet 10 is formed at the upper part of the rear end part. Accordingly, the hot air outlet 9 and the hot air inlet 10 are provided separately in the axial direction of the water tank 2. Further, the water tank 2 has a drain outlet 11 formed at the bottom of the bottom, and a drain pipe 12 is connected to the drain outlet 11.

  A drum 13 is disposed inside the water tank 2. The drum 13 also has a cylindrical shape, and a hole 14 is formed on the circumferential side portion (body portion) of the entire region (only a part is shown). The hole 14 functions as a water passage hole and also functions as a ventilation hole. Further, a hot air inlet 15 made up of a large number of small holes is formed around the center of the inner portion of the drum 13. Further, a reinforcing member 16 is attached to the back surface of the inner portion of the drum 13, and a shaft 17 is attached to the center portion of the rear surface of the inner portion of the drum 13 via the reinforcing member 16.

  On the other hand, a bearing housing 18 is attached to the center of the back (rear end) of the water tank 2, and the shaft 17 is inserted into and supported by the bearing housing 18 via the bearings 19 and 20, The drum 13 is supported in the same manner as the water tank 2 so as to have a horizontal axis shape in which the axial direction is front and rear, and to form an upwardly inclined shape.

  A stator 22 of a motor 21 is attached to the outer periphery of the bearing housing 18, and a rotor 23 attached to the rear end portion of the shaft 17 is opposed to the stator 22 from the outside. Therefore, the motor 21 is an outer rotor type, and in this case, is a brushless DC motor, and functions as a drive device that rotates the drum 13 about the shaft 17.

  A warm air cover 24 is mounted on the inner side of the rear end surface portion of the water tank 2. The warm air cover 24 has an opening 25 in the lower portion, and the shaft 17 is surrounded by the opening 25. The hot air cover 24 faces the hot air inlet 10 at a portion above the opening 25 and covers the hot air inlet 10. Furthermore, as a whole of the warm air cover 24, for example, 1 / of a space between the rear end surface portion of the drum 13 and the rear end surface portion of the water tank 2 between the rear end surface portion of the water tank 2 and the like. A space of about 3 is separated, and the warm air passage 26 communicating from the warm air inlet 10 to the peripheral portion of the shaft 17 is configured by the space. The opening 25 of the hot air cover 24 is sufficiently larger than the shaft 17 and corresponds to the outlet of the hot air passage 26.

  The reinforcing member 16 is formed with a plurality of relatively large holes 27 around the central portion where the shaft 17 is attached. These holes 25 are the opening 25 of the hot air cover 24 and the hot air inlet port of the drum 13. 15, the hot air introduction path 28 is configured by communicating them.

  The reinforcing member 16 is also provided with a seal member 29 on the outer periphery of the portion constituting the hot air introduction path 28. The seal member 29 is made of an elastic material such as synthetic rubber, and is in contact with a portion around the opening 25 of the warm air cover 24 so as to be in sliding contact therewith. As a result, the seal member 29 seals between the hot air introduction passage 28 and the hot air passage 26 between the drum 13 and the water tank 2.

  On the other hand, the bottom of the outer box 1 is constituted by a base plate 30. As shown in FIG. 3, a ventilation duct 32 is placed on the base plate 30 via a plurality of vibration isolating rubbers 31, and a plurality of bolts 33 penetrating the vibration isolating rubbers 31, The ventilation duct 32 is fixed to the base plate 30 by a plurality of nuts 34 screwed to the projecting tips of the bolts 33. In this way, the ventilation duct 32 is connected to the water tank as shown in FIG. 2 is arranged in parallel with the axial direction of the water tank 2.

  As shown in detail in FIG. 4, the ventilation duct 32 is attached to the bottom plate 35, both left and right side walls 36 and 37 erected on the bottom plate 35, both side walls 36 and 37, and the front end of the bottom plate 35. A front wall 38, both side walls 36, 37, a rear wall 39 attached to the rear end of the bottom plate 35, the front wall 38, the rear wall 39, and an upper cover 40 attached to the upper ends of the side walls 36, 37ゞ It is designed to enclose a square cylindrical air passage.

  In the ventilation duct 32, an evaporator (evaporator) 41 and a condenser (condenser) 42 are disposed between the front wall 38 and the rear wall 39. Specifically, the evaporator 41 is disposed on the front wall 38 side, and the capacitor 42 is disposed on the rear wall 39 side.

  One (left side) side wall 36 of the ventilation duct 32 is formed by a side wall that covers one end plate 43 of the condenser 42 from one end plate 43 of the evaporator 41 with one piece from the outside, and the other side wall 36. The (right side) side wall 37 is constituted by the other end plate 45 of the evaporator 41, the other end plate 46 of the capacitor 42, and the auxiliary side plate 47 connecting these end plates 45, 46.

  For this reason, from the other side wall 37 of the ventilation duct 32, the inlet portion 48a and the outlet portion 48b of the refrigerant pipe 48 projecting from the other end plate 45 of the evaporator 41, and a plurality of bent portions 48c on the way, and the other side of the condenser 42 are provided. The inlet portion 49a and the outlet portion 49b of the refrigerant pipe 49 protruding from the end plate 46 and a large number of bent portions 49c on the way remain protruding.

On the other hand, one side wall 36 of the ventilation duct 32 has a bent portion (not shown) of the refrigerant pipe 48 protruding from one end plate 43 of the evaporator 41, and one of the condensers 42. The bent portion (same as above) of the refrigerant pipe 49 protruding from the end plate 44 is covered and hidden.
Further, between the both end plates 43 and 45 of the evaporator 41 and between the both end plates 44 and 46 of the condenser 42, straight portions (not shown) where the bent portions 48c and 49c of the respective refrigerant pipes 48 and 49 are connected are arranged. In addition, a large number of heat exchanging fins 50 and 51 that are commonly attached to the straight portion are arranged in a row.

  Here, the bottom plate 35 of the ventilation duct 32 has a compressor arrangement portion 52 extending on the side (right side) portion of the other end plate 45 of the evaporator 41, and on the compressor arrangement portion 52, As shown in FIGS. 1 and 2, by arranging a compressor 53, the compressor 53 is arranged at a position on the side of the ventilation duct 32 in a direction orthogonal to the axial direction of the water tank 2.

  Further, in this case, as shown in detail in FIG. 5, the compressor 53 is arranged on the bottom plate 35 (compressor arrangement portion 52), which is the bottom surface of the ventilation duct 32, via a metal reinforcing plate 54 such as a steel plate. is doing. The bottom plate 35 of the ventilation duct 32 is made of plastic. 5, FIG. 1 and FIG. 2 show the compressor 53 with the soundproof cover 55 shown in FIG. 7 removed. Further, in FIG. 5, 56 indicates a reserve tank for liquid refrigerant attached to the compressor 53.

  The compressor 53 constitutes the heat pump (refrigeration cycle) 57 shown in FIG. 6 together with the evaporator 41 and the condenser 42. In the heat pump 57, the compressor 53, the condenser 42, the capillary tube 59, and the evaporator are connected by a connection pipe 58. These are cycle-connected in the order of 41. With this configuration, when the compressor 53 operates, the refrigerant sealed in the cycle is circulated.

  As shown in FIG. 4, a rectangular opening 60 is formed as an inlet portion in the front wall 38 of the ventilation duct 32, and a circular opening 61 is formed as an outlet portion in the rear wall 39. The openings 60 and 61 are aligned at the center when viewed from the front, and the evaporator 41 and the condenser 42 of the heat pump 57 located between them are also aligned with the openings 60 and 61 when viewed from the front. Arranged.

  Further, the upper cover 40 of the ventilation duct 32 is divided into an evaporator-side upper cover 62 and a capacitor-side upper cover 63 in detail, and the evaporator-side upper cover 62 is provided in the ventilation duct 32. Removably attached to the front part of the both side walls 36 and 37 (on the evaporator 41 side) and the upper end part of the front wall 38, the condenser side upper cover 63 is attached to the rear part of the side ducts 36 and 37 of the ventilation duct 32 (condenser). 42 side) and the rear wall 39 are detachably mounted. Thus, maintenance of the evaporator 41 and the capacitor 42 can be performed individually by removing the evaporator-side upper cover 62 and the capacitor-side upper cover 63 individually.

A filter case 64 is attached to the opening 60 that is the inlet of the ventilation duct 32 as shown in FIGS. Therefore, the filter case 64, the arrangement arranged in tandem and the evaporator 41 and the condenser 42 of the heat pump 57, as will become apparent later, are provided on the windward side of the ventilation duct 32.

  Specifically, the filter case 64 has a rectangular opening at the rear end portion and the front end portion (only the opening 65 at the front end portion is shown in FIG. 7), and the connection port 66 protrudes upward at the upper portion on the front side. Among them, the opening at the rear end portion (not shown) has the same size as the opening 60 of the ventilation duct 32 and is coupled to the opening 60. On the other hand, the opening 65 at the front end of the filter case 64 is smaller in the vertical direction than the opening at the rear end and is positioned closer to the top.

  A filter 67 is housed in the filter case 64 so as to be able to be put in and taken out from the opening 65 at the front end portion. The filter 67 captures lint (waste thread) that scatters when the laundry is dried. Specifically, as shown in FIG. 8, a plurality of filter bodies 68 having different mesh sizes are laminated on the filter frame 69. The mesh size of the filter main body 68 is coarser as the upper side, which will become apparent later, and becomes finer as the lower side, which is the leeward side.

  FIG. 9 shows a drain receiving portion 70 provided immediately below the evaporator 41. The drain receiving portion 70 is inclined downward on the right side in the drawing, and has a drain discharge port 71 at its extension. . A connection port 74 of a drain tank 73 is connected to the drain discharge port 71 via a connection pipe 72. The drainage tank 73 is formed on the bottom plate 35 of the ventilation duct 32 by integral molding of plastic, for example, and is located below the drain receiving portion 70.

  The drainage tank 73 has a flat container shape, and its bottom 73a is inclined downward to the right in the figure, and has the connection port 74 directly above its lowest part. Further, FIG. 9 shows a drainage pump 75 disposed on the base plate 30 behind the connection port 74, and the suction port thereof corresponds to the lowest part of the bottom 73 a of the drainage tank 73, and the portion It is designed to absorb water.

  In addition, FIG. 10 shows a drain valve 76, which is disposed on the base plate 30 on the left side of the ventilation duct 32, and the drain pipe 12 is connected to the inlet portion 76 a via a drain filter case 77. Connected. The drainage filter case 77 houses a drainage filter (not shown) that captures lint from the wastewater discharged from the water tank 2 through the drainage pipe 12.

  On the other hand, a drainage hose 79 is connected to the outlet part 76b of the drainage valve 76 via a drainage joint 78, and the leading end of the drainage hose 79 is led out of the machine (not shown). The drainage joint 78 is equipped with a check valve 80, and the connection hose 81 connected to the discharge port of the drainage pump 75 is connected to the drainage joint 78 via the check valve 80. That is, the discharge port of the drainage pump 75 is connected to the downstream side of the drainage valve 76 in the drainage channel from the water tank 2.

  The check valve 80 allows the flow of water from the connection hose 81 to the drain hose 79 and blocks the flow of water opposite to that (from the drain valve 76 to the connection hose 81). Waste water from the water tank 2 is prevented from reaching the ventilation duct 32 through the drainage pump 75 with lint that cannot be completely captured by the drainage filter, and clogging in the ventilation duct 32 by the lint, particularly the evaporator 41. The clogging between the fins 50 and between the fins 51 of the capacitor 42 is prevented.

  As shown in FIGS. 2, 3, and 7, a lower end portion of a bellows-like connection hose 82 is connected to the connection port 66 of the filter case 64. On the other hand, the water tank cover 4 is formed with a return air duct 83 connected to the hot air outlet 9 by making the left half circumference, the right half circumference or the whole circumference hollow. That is, the return air duct 83 is formed using the wall surface of the water tank cover 4. In addition, a connection port 84 is provided in the lower portion of the return air duct 83, and the upper end portion of the connection hose 82 is connected to the connection port 84.

  On the other hand, a blower 85, in particular, an inlet portion (not shown) of the casing 86 is connected to the opening 61 which is an outlet portion of the ventilation duct 32. The blower 85 accommodates a blower blade (not shown) inside the casing 86 and rotates the blower blade by a motor (not shown). The blower blade sucks air from the inlet portion of the casing 86 by the rotation. Exhalation is made from the outlet 87.

  The outlet portion 87 of the casing 86 of the blower 85 is connected to the hot air inlet 10 of the water tank 2 through a bellows-like connection hose 88 and an air supply duct 89 shown in FIG. The air supply duct 89 is piped so as to bypass the periphery of the motor 21.

  As a result, the ventilation duct 32 has an inlet portion (opening 60) connected to the hot air outlet 9 of the water tank 2 via the filter case 64, the connection hose 82, and the return air duct 83, and the outlet portion (opening 61). Is connected to the hot air inlet 10 of the water tank 2 through the blower 85, the connection hose 88, and the air supply duct 89. Moreover, the ventilation path 90 which connects the warm air outlet 9 and the warm air inlet 10 of the said water tank 2 simultaneously is provided by them.

Next, the operation of the above configuration will be described.
In the above configuration, when a standard driving course is started, a washing (washing and rinsing) process is first started. In this washing process, an operation of supplying water into the water tub 2 by a water supply device (not shown) is performed, and then the motor 21 is operated, whereby the drum 13 is alternately rotated in both forward and reverse directions at a low speed.

  When the washing process is completed, the dehydration process is then started. In this dehydration process, after the water in the water tank 2 is discharged, an operation of rotating the drum 13 in one direction at a high speed is performed. Thereby, the laundry in the drum 13 is centrifugally dehydrated.

  When the dehydration process is completed, a drying process is then performed. In this drying process, the air in the water tank 2 is blown from the hot air outlet 9 through the return air duct 83 by the blowing action of the blower blades by rotating the drum 13 in both forward and reverse directions at low speed. It flows into the ventilation duct 32 through the connection hose 82 and the filter case 64.

  At this time, the operation of the compressor 53 of the heat pump 57 is started. As a result, the refrigerant sealed in the heat pump 57 is compressed to become a high-temperature and high-pressure refrigerant, and the high-temperature and high-pressure refrigerant flows into the condenser 42 and exchanges heat with the air in the ventilation duct 32. As a result, the air in the ventilation duct 32 is heated, and conversely, the temperature of the refrigerant is lowered and liquefied. Next, the liquefied refrigerant passes through the capillary tube 59 and is decompressed, and then flows into the evaporator 41 and vaporizes. Thereby, the evaporator 41 cools (heat exchanges) the air in the ventilation duct 32. The evaporator 41 cools the air in the ventilation duct 32 and cools the refrigerant to return to the compressor 53.

  Thus, the air that has flowed into the ventilation duct 32 from the water tank 2 is cooled by the evaporator 41 and dehumidified, and then heated by the condenser 42 to be warmed. Then, the warm air is supplied back to the water tank 2 from the warm air inlet 10 through the connection hose 88 and the air supply duct 89.

The hot air supplied back into the drum 13 deprives the laundry of moisture, and then flows again into the ventilation duct 32 from the hot air outlet 9 through the return air duct 83 and the connection hose 82.
Thus, air circulates between the ventilation duct 32 having the evaporator 41 and the condenser 42 and the drum 13 so that the laundry in the drum 13 is dried.

  Then, during this drying process, the lint spattered from the laundry in the drum 13 is carried from the warm air outlet 9 to the air passing through the return air duct 83 and the connection hose 82, and reaches the filter case 64. Captured by the filter 67 in the filter case 64. The captured lint can be removed from the filter 67 by removing the filter 67 from the filter case 64 after the operation is completed. Further, the filter 67 from which the lint has been removed is then returned to the filter case 64, so that the lint spattered from the laundry is captured again.

  During this drying process, in the evaporator 41, condensation is generated on the surface as the air passing through the ventilation duct 32 is cooled and dew (water) is dripped from the evaporator 41 and immediately below. It flows down the inclined surface of the drain receiving portion 70 and falls into the drainage tank 73 from the drain discharge port 71 through the connection pipe 72.

The water that has fallen into the drainage tank 73 is stored from the lowest part according to the inclination of the bottom 73a of the drainage tank 73. On the other hand, the suction port of the drainage pump 75 corresponds to the lowest part thereof. Therefore, during this drying process, when the drainage pump 75 is operated, the water reaching the drainage tank 73 is It is efficiently sucked into the drainage pump 75 from the lowest part. Accordingly, the water sucked into the drain tank 73 is discharged from the connection hose 81 through the drain joint 78 and the drain hose 79 to the outside of the machine.
After this, the drying process is finished and the standard driving course is finished.

  As described above, in this configuration, the evaporator 41 and the condenser 42 of the heat pump 57 are arranged in the ventilation duct 32 that connects the warm air outlet 9 and the warm air inlet 10 of the water tank 2, and the ventilation duct 32 contains the inside of the water tank 2. The laundry is dried through air, and the hot air inlet 10 and the hot air outlet 9 are provided separately in the axial direction of the cylindrical water tank 2 arranged in a horizontal axis. The ventilation duct 32 is arranged in parallel with the axial direction of the water tank 2 just below.

  Thereby, the path | route when circulating the air in the water tank 2 is simpler than what the conventional ventilation path was arrange | positioned in the direction orthogonal to the axial direction of a water tank under the water tank, and it is especially ventilated from the water tank 2. Since the bending to the duct 32 is not large, a large amount of circulating air can be obtained, and the heat exchange efficiency in the evaporator 41 and the condenser 42 of the heat pump 57 can be increased, so that the drying performance can be improved.

Further, in this configuration, in addition to the ventilation duct 32 being arranged in parallel with the axial direction of the water tank 2 just below the water tank 2, the side of the ventilation duct 32 in the direction orthogonal to the axial direction of the water tank 2 is provided. The compressor 53 of the heat pump 57 is arranged at the position.
Thereby, the compressor 53 of the heat pump 57 can be arranged in a wide space between the corner in the outer box 1 and the circumferential lower part forming the cylindrical curved surface shape of the water tank 2, and an extra wide space is not required. The arrangement of the ventilation duct 32 with respect to the water tank 2 and the compressor 53 of the heat pump 57 can be made space efficient, so that the overall compactness and weight reduction can be achieved as desired.

  In addition, in this configuration, the ventilation duct 32 has an inlet portion (opening 60) and an outlet portion (opening 61) facing each other, and the evaporator 41 and the condenser 42 of the heat pump 57 are interposed between them. And centered. As a result, the air that has flowed out of the water tank 2 passes through the evaporator 41 and the condenser 42 of the heat pump 57 in a straight line and in contact with each other without waste while the escape duct 32 eliminates escape to the outside. The heat exchange efficiency in the evaporator 41 and the condenser 42 can be further improved.

Also, the filter case 64 for housing the filter 67 for trapping lint to Chide from the laundry, in the arrangement arranged in tandem and the evaporator 41 and the condenser 42 of the heat pump 57 is provided on the windward side of the ventilation duct 32. Thus, even flow of air through the ventilation duct 32 from the filter case 64 becomes a straight line, since there is no lowering of the amount of circulating air, to further improve the heat exchange efficiency of the evaporator 41 and the condenser 42 of the heat pump 57 be able to.

  Further, the compressor 53 of the heat pump 57 is disposed on the bottom surface of the ventilation duct 32 via a reinforcing plate 54. As a result, the compressor 53 can be reinforced by the reinforcing plate 54 on the bottom surface of the ventilation duct 32 and the ventilation duct 32 can be disposed without deformation, so that leakage of air from the ventilation duct 32 due to deformation of the ventilation duct 32 is prevented. it can. Therefore, this also does not reduce the circulating air volume, and the heat exchange efficiency in the evaporator 41 and the condenser 42 of the heat pump 57 can be further improved. Further, in this case, damage to the ventilation duct 32 at the time of a fall during handling can be reduced by the reinforcing plate 54.

  Further, in this case, since the compressor 53 can be firmly fixed to the bottom surface of the ventilation duct 32 via the reinforcing plate 54, vibration during operation can be suppressed from being transmitted to the ventilation duct 32 and the compressor 53. In addition, vibrations can be prevented from being transmitted to the pipe connecting the condenser 42 and the evaporator 41, and damage to the pipe can be suppressed. Therefore, the life of the pipe and thus the heat pump 57 can be extended. In addition, transmission of vibration from the compressor 53 to the outer box 1 can be suppressed, and vibration and vibration noise of the outer box 1 can be reduced.

  A drainage tank 73 is formed in the bottom plate 35 of the ventilation duct 32 to store water generated when the air passing through the ventilation duct 32 is dehumidified by the evaporator 41 of the heat pump 57. As a result, the bottom plate 35 of the ventilation duct 32 can be strengthened by the drainage tank 73, and this also prevents the ventilation duct 32 from being deformed. Therefore, the ventilation duct 32 is caused by the deformation of the ventilation duct 32. Therefore, the heat exchange efficiency of the evaporator 41 and the condenser 42 of the heat pump 57 can be further improved.

  Further, in this case, the water generated when the air passing through the ventilation duct 32 is dehumidified by the evaporator 41 of the heat pump 57 can be stored below the bottom plate 35 of the ventilation duct 32 by the drainage tank 73, so that the evaporator of the heat pump 57. 41 and the condenser 42 are not soaked in the stored water. Therefore, clogging in the ventilation duct 32 due to lint mixed in the stored water, particularly between the fins 50 of the evaporator 41 and between the fins 51 of the condenser 42. Therefore, it is possible to prevent the circulation air volume from decreasing.

  Further, the side wall 37 of the ventilation duct 32 is constituted by an end plate 45 of the evaporator 41 of the heat pump 57, an end plate 46 of the condenser 42, and an auxiliary side plate 47 that connects these end plates 45, 46. Thereby, the side wall 37 of the ventilation duct 32 can be hermetically sealed, air leakage from the ventilation duct 32 can be prevented, and the amount of circulating air can be prevented from being reduced. Therefore, the evaporator 41 and the condenser 42 of the heat pump 57 are also reduced. The heat exchange efficiency can be further improved.

  In addition, in this case, the end plate 45 of the evaporator 41 and the end plate 46 of the condenser 42 are used as they are on the side wall 37 of the ventilation duct 32, and an auxiliary side plate 47 that just connects the end plates 45, 46 is added thereto. Therefore, the side wall 37 of the ventilation duct 32 can be rationally configured, and the product can be provided at a low cost.

In addition, the ventilation duct 32 and the compressor 53 are connected to the base plate 30 constituting the bottom of the outer box 1.
As described above, vibration during operation can be prevented from being transmitted to the ventilation duct 32 and the compressor 53, and vibration transmission to the piping in the heat pump 57 can be prevented. Can also be prevented and damage to the piping can be suppressed, so that the service life of the heat pump 57 can be extended. Further, the vibration transmission from the compressor 53 to the outer box 1 can also be prevented by the anti-vibration rubber 31, and the vibration and vibration noise of the outer box 1 can be reduced.

  In addition, since the lint scattered from the laundry and carried to the circulating air can be captured by the filter 67, the lint can prevent clogging between the fins 50 of the evaporator 41 and the fins 51 of the condenser 42. Can be prevented from lowering. In addition, the filter 67 is provided in a filter case 64 provided at the front of the machine body so that the filter 67 can be easily taken in and out from the front of the machine body, so that the captured lint can be easily removed. Thus, it is possible to further reduce the circulating air volume.

  Furthermore, the filter 67 is formed by providing a plurality of filter main bodies 68 having different mesh sizes in a stacked state, so that a large lint to a fine lint can be captured, and between the fins 50 of the evaporator 41 and It is possible to prevent further clogging between the fins 51 of the capacitor 42. In this case, in particular, by making each of the plurality of filter bodies 68 detachable from the filter frame 69, it becomes possible to remove the captured lint more than once and to keep the drying performance long and good. In addition, the product life can be extended.

Further, the return air duct 83 is formed by using the wall surface of the water tank cover 4, so that the number of parts can be reduced and the product can be provided at low cost.
Further, the drainage tank 73 has a bottom portion 73a inclined downward toward the suction port of the drainage pump 75, so that the drainage pump 75 efficiently removes the water dripped from the evaporator 41 and reaching the drainage tank 73 during the drying process. Can be inhaled well and discharged in a short time.
In addition, this invention is not limited only to the Example shown above and shown in drawing, In the range which does not deviate from a summary, it can change suitably and can implement.

The front view of the internal structure which shows one Example of this invention Full side view Longitudinal side view of ventilation duct and surrounding area Exploded perspective view of ventilation duct Front view of the compressor section Schematic configuration diagram of heat pump Perspective view of the ventilation duct and its surroundings Broken perspective view of filter Longitudinal front view of ventilation duct Perspective view of drain valve and surrounding area

Explanation of symbols

  In the drawing, 2 is a water tank, 9 is a hot air outlet, 10 is a hot air inlet, 13 is a drum, 21 is a motor (drive device), 32 is a ventilation duct, 35 is a bottom plate of the ventilation duct, 37 is a side wall of the ventilation duct, 41 is an evaporator, 42 is a condenser, 45 is an end plate of the evaporator, 46 is an end plate of the capacitor, 47 is an auxiliary side plate, 53 is a compressor, 54 is a reinforcing plate, 57 is a heat pump, 60 is an opening (inlet part of the ventilation duct) , 61 is an opening (exit part of the ventilation duct), 64 is a filter case, 67 is a filter, and 73 is a drainage tank.

Claims (3)

An outer box,
A cylindrical aquarium having a horizontal axis with the axial direction in the front and rear and an upwardly rising slope inside the outer box, a hot air inlet at the rear, and a hot air outlet at the front,
A drum disposed inside the aquarium;
A driving device for rotating the drum;
A ventilation duct provided by connecting a hot air outlet and a hot air inlet of the water tank;
A heat pump configured by arranging an evaporator and a condenser in this ventilation duct and connecting them to a compressor;
A blower that circulates the air in the water tank by suction from the front and blowing from the rear by supplying the air from the hot air outlet through the ventilation duct and returning from the hot air inlet to the water tank. Equipped,
The ventilation duct is arranged in parallel with the axial direction of the water tank just below the water tank,
While disposing the compressor of the heat pump at a position on the side of the ventilation duct in the direction orthogonal to the axial direction of the water tank and on the side position of the circumferential side portion forming the cylindrical curved surface shape of the water tank ,
A filter case that houses a filter that captures lint that scatters from the laundry is arranged in tandem with the evaporator and condenser of the heat pump, and is provided on the windward side of the ventilation duct so that it can be taken in and out from the front of the outer box ,
A drum type washing and drying machine, wherein the side wall of the ventilation duct is composed of an end plate of an evaporator of a heat pump and an end plate of a condenser .   The drum type washing and drying machine according to claim 1, wherein the compressor of the heat pump is arranged on the bottom surface of the ventilation duct via a reinforcing plate.   2. The drum type washing and drying machine according to claim 1, wherein a drainage tank for storing water generated when air passing through the ventilation duct is dehumidified by an evaporator of a heat pump is formed on a bottom plate of the ventilation duct.

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