TW201139779A - Drying machine - Google Patents

Abstract

A drying machine (500) comprising a rotating drum (3) configured to accommodate clothing; a heat pump device (30) configured to dry the clothing; a housing (1) including a wall configured to define an internal space to accommodate the rotating drum (3) and the heat pump device (30); and a support mechanism (560) configured to support, in the housing (1), the heat pump device (30) including a compressor (31) configured to compress refrigerant,wherein the heat pump device (30) is disposed above the rotating drum (3),the wall includes vertically standing side walls (1a, 1b), and the side walls (1a, 1 b) are connected to the support mechanism (560).

Description

201139779 VI. Description of the invention: [Rhyme 'Ming 斤 _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ BACKGROUND OF THE INVENTION Dryers for drying clothes, such as drum type laundry dryers, typically have a heat configuration. The heat pump mechanism can consume less electricity than the device using the heater to dry the clothes. In addition, the hot dish mechanism can use the cooling water instead of the cooling water, and the money used for the clothing (4) is secreted and heat-recovered by the dry gas. Therefore, the 'μ mechanism is advantageous in terms of water saving and saving the source as compared with a device using a heater to dry clothes (refer to Japanese Laid-Open Publication No. _ _ _ _ _ _ _ _ Fig. 12 is a schematic view showing that the former dryer dryer 150 has a drying tank 102 for drying clothes, a frame body for accommodating the internal space of the drying tank 1〇2, and will be fed dry. The drying air of the tank (10) is removed and heated to the hot fruit mechanism 13g. The heat pump mechanism (10) is disposed below the inner space of the casing 100. The heat 130 includes a compressor 131 for compressing a refrigerant, a converter m including an addition (not shown in FIG. 11) and m (not shown in FIG. 12), and a guide for the compressor 131 and the heat exchanger. Circulation between 132: The circulation of the media (not shown in Figure 12) The drying tank 1〇2 of the dryer 150 contains a rotating drum (not shown). The dryer 15G has absorption due to the spin (four) cylinder Vibration 2 201139779 Suspension device (not shown in Fig. 12). Part of the vibration caused by the rotation of the rotary drum is transmitted to the frame 100 via the suspension device supporting the drying tank 102. The vibration system vibrates the heat pump mechanism 13. Therefore, the heat pump mechanism 130 is exposed to the vibration caused by the rotation of the rotary drum in addition to the vibration of the compressor itself. The vibration caused by the rotation of the rotary drum is much larger than that of the compressor itself. The vibration caused by the rotation of the rotary drum generates an excessive load on the circulation piping for guiding the refrigerant, which may cause a malfunction of the heat pump mechanism 130 (for example, breakage of the circulation piping). SUMMARY OF THE INVENTION Summary of the Invention Provided is a dryer using a heat pump device which is effective in reducing vibration of a frame caused by rotation of a rotary drum. The dryer according to one aspect of the present invention is characterized by comprising: a rotary drum for accommodating clothes; a heat pump device for drying clothes; comprising a wall defining an internal space for housing the rotating drum and the heat pump device# < a housing; and a support mechanism for supporting the heat pump device including a compression portion for compressing a refrigerant in the frame; the heat pump device is disposed above the rotary drum, and the wall portion is erected in an up-and-down direction a side wall connected to the aforementioned branching mechanism. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a cross-sectional view showing the schematic configuration of a drum type washing and drying machine according to an embodiment. Fig. 2 is a partial view of the front side of the drum type washer dryer shown in Fig. 1. 201139779 Fig. 3 is a perspective view schematically showing the internal structure of the drum type washing and drying machine shown in Fig. 1. Fig. 4 is a schematic top view of the drum type washer dryer shown in Fig. 1. Fig. 5 is a cross-sectional view taken along line a-A of Fig. 4. Fig. 6 is a perspective view schematically showing the upper portion of the drum type washing and drying machine shown in Fig. 1. Fig. 7 is a perspective view schematically showing the washing and drying machine shown in Fig. 。. Fig. 8 is a perspective view schematically showing a supporting member in the drum type washing and drying machine shown in Fig. 1. Fig. 9 is a perspective view schematically showing the drum type washing and drying machine shown in Fig. 1. Fig. 10 is a perspective view schematically showing another arrangement of the supporting members in the drum type washing and drying machine shown in Fig. 1. Fig. 11 is a perspective view schematically showing the drum type washing and drying machine shown in Fig. 10. Fig. 12 is a perspective view schematically showing a prior laundry dryer using hot chestnut drying clothes. I: Embodiment: j Best Mode for Carrying Out the Invention Hereinafter, a dryer for an embodiment will be described with reference to the drawings. In the present embodiment, a drum type washing and drying machine is exemplified as a dryer. Instead, the dryer can also be other washer dryers. Instead, the dryer can also be a drying device that does not have a laundry function. Therefore, the detailed construction of the following description is not intended to limit the principles of the embodiments. 201139779 (Overall configuration of the drum type washing and drying machine) Fig. 1 is a schematic cross-sectional view of the drum type washing and drying machine. Fig. 2 is a perspective view partially showing the front side of the drum type washing and drying machine. Fig. 3 is a perspective view schematically showing the internal structure of the drum type washing and drying machine. The washing and drying machine 5 includes a casing 1 including a wall portion defining various components for washing and drying the laundry (for example, the rotary drum 3, the water tank 2, and the heat pump device 30, which will be described later). Internal space. The wall portion of the frame body includes a front wall le disposed on the front side, a rear wall Id disposed on the opposite side to the front wall le, a right side wall la disposed between the front wall le and the rear wall id, and a right side wall la The left side wall lb is disposed on the opposite side. The front wall le, the rear wall Id, the right side wall la, and the left side wall lb are erected in the up and down direction. In the present embodiment, at least one of the right side wall 1a and the left side wall 1b is exemplified as a side wall. Further, the right side wall 1a is exemplified as the first side wall. The left side wall lb is exemplified as the second side wall. The wall portion of the frame 1 comprises an upper wall ic surrounded by a front wall le, a rear wall id, a right side wall 1a and an upper edge of the left side wall lb, and a front wall le, a rear wall ld, a right side wall la and a left side wall The bottom wall κ surrounded by the lower edge of lb. An input port for entering and exiting the laundry is formed on the front wall le. The washing and drying machine 500 is further provided with a door body 5 for closing or opening the input port. The door body 5 attached to the front wall is rotated between the open position of the open input port (see the figure) and the closed position of the closed input port (see Fig. 2). The washing and drying machine 500 further includes a substantially cylindrical rotating drum disposed in the casing 3. The rotating drum 3 for washing and drying the laundry includes a peripheral wall that forms an opening that communicates with the inlet of the front wall le. 531 and a bottom wall 532 opposite to the opening formed by the peripheral wall 531. Retracted in the rotating drum 3 6 201139779 The clothes that are put into the input port. The washer-dryer 500 further includes a substantially cylindrical water tank 2 disposed in the casing 1. The water tank 2 includes a peripheral wall 52 surrounding the peripheral wall 531 of the rotary drum 3 and a bottom wall 522 along the bottom wall 532 of the rotary drum 3. The washing water for washing the laundry is stored in the water tank 2. In the present embodiment, the water tank 2 is exemplified as an outer tank. As shown in Fig. 3, the washer-dryer 500 further includes a damper 523 including an upper end portion connected to the peripheral wall 521 of the water tank 2 and a lower end portion connected to the bottom wall If of the casing 1. The rotary drum 3 rotates inside the water tank 2. The damper 523 that supports the water tank 2 in the casing 1 absorbs the vibration caused by the rotation of the rotary drum 3. The washing and drying machine 500 further includes a drive motor 7 that rotates the rotary drum 3. The drive motor 7 is attached to the outer surface of the bottom wall 522 of the water tank 2. The rotating shaft of the rotary drum 3, which is rotated by the drive motor 7, is inclined upward toward the front. As described above, the door body 5 for opening and closing the input port of the rotary drum 3 is attached to the front wall le of the casing 1. The user can open the door body 5 to enter and exit the clothes of the rotary drum 3. The washing and drying machine 500 further includes a water supply pipe (not shown) for supplying water to the water tank 2. The water supply pipe connected to the water tank 2 contains a water supply valve (not shown). The water supply valve is used to control the water supply to the water tank 2. The washing and drying machine 500 is provided with a drain pipe (not shown) for draining from the water tank 2. The drain pipe connected to the water tank 2 includes a drain valve (not shown). The drain valve is used to control the drainage from the water tank 2. As shown in Fig. 2, the 'washing and drying machine 5' further includes an operation panel 4. The operation panel 4 is disposed along the upper edge of the front wall le of the casing 1. The operation panel 4 includes various operation keys 541 for the operation of the laundry dryer 5G0 of 201139779, and display windows 542 for displaying various operation signals such as the operation mode of the laundry dryer 5GG. Further, the washing and drying machine 500 further includes a lotion input unit 1G for disposing the lotion in the casing i. The lotion input portion 10 disposed under the left end of the operation panel 4 can be pulled forward. The lotion caster is provided in the housing (i) holding the washing container (not shown). The storage container may be divided into, for example, a first housing portion (not shown) for accommodating the powder lotion, a first housing portion (not shown) for storing the liquid detergent, and a third housing for containing the softener. Department (not shown). A discharge port u is formed in an upper portion of the peripheral wall 521 of the water tank 2. The dry air used for drying the laundry contained in the rotary drum 3 rotatably housed in the water tank 2 is efficiently discharged from the discharge port 11. In the present embodiment, the wash water is not discharged from the discharge port 11, and the drain σ n is formed in the water tank 2, and the washing liquid of the rotating drum 3 is above the maximum liquid level. The drying device is used as a dryer. The discharge port u can be formed at any place of the peripheral wall 531 or the bottom wall 532 of the rotary drum 3. The clothing in the rotary drum 3 sometimes produces a weight S imbalance of the rotary drum 3 and/or the water tank 2. As a result, the vibration caused by the rotation of the rotary drum 3 is transmitted to the water tank 2. The damper 523 supporting the water tank 2 attenuates the vibration from the water tank 2. (Heat Pump Device) Fig. 4 is a schematic plan view of the washing and drying machine. Figure 5 is a front view of the A-A line shown in Figure 4. Fig. 6 is a perspective view schematically showing the configuration of the upper portion of the washing and drying machine 500. Figure 7 is a perspective view of the outline of the washing and drying machine. Use the first, third, and seventh and twelfth drawings to illustrate the thermal 8 201139779 pump unit. The laundry dryer 500 is equipped with a hot fruit device for drying the clothes. The washing and drying machine 500 dehumidifies and heats the dry air discharged from the rotary drum 3 using the heat pump device 3''. As described above, the casing 1 forms an internal space in which various devices such as the rotary drum 3, the water tank 2, and the heat pump device 30 are housed. In the following description, the narrow space above the water tank 2 in the inner space of the frame body is referred to as the upper space. Further, a space below the water tank 2 in the internal space of the casing 1 is referred to as a lower space. The heat pump device 30 and the various components of the circulation path of the dry air formed between the heat pump device 3 and the rotary drum 3 are mostly disposed in the upper space. As shown in Fig. 1, the washer-dryer 500 further includes a lavish air duct 8 that connects the water tub 2 and the hot chest device 30. The air passage 8 includes an upstream air passage 58 extending upward from the discharge port 11 and a downstream air passage 582 connected to the bottom wall 522 of the water tank 2. The washer-dryer 500 further includes a filter unit 40 disposed between the upstream air passage 581 and the heat pump device 30. The filter portion connected to the upstream air passage 581 removes the lint in the dry air (referred to as the dry air of the dust component of the thread head, and then flows to the heat 3G.) As described above, the heat pump device 3 () is removed. The washing and drying machine 500 further includes a blowing portion 9 disposed between the heat pump device 3A and the downstream air passage 582. The air blowing portion 9 draws dry air from the discharge port u of the water tank 2, and then passes downstream. The air passage 582 feeds the dry gas into the rotary drum 3 again. Thus, the dry air sent from the blower unit 9 circulates according to the circulation path defined by the circulation air passage 8. 201139779 The heat pump unit 30 is attached to the upper space. The heat pump mechanism 13 is disposed in the lower space of the casing 100 as shown in Fig. 12. The heat pump device 3 of the present embodiment is disposed in the frame. In the upper space, the length of the flow path of the dry air passing through the upstream air passage 581, the filter portion 4, the heat pump device 30, the air blowing portion 9, and the downstream air passage 582 is shortened. This is for connecting the filter portion 4 , hot fruit device and air supply part 9 In the present embodiment, various elements (circumferential portion 40, heat system) of the circulation path of the dry air between the hot pump device and the rotary roller 3 are formed in the present embodiment. The device 30 and the air supply unit 9) are disposed in the upper space in a concentrated manner. As a result, the dry air-free pressure loss can be reduced, and a rapid circulation speed and/or a sufficient air volume can be obtained. As shown in Fig. 5, the heat pump device 30 includes a heat exchanger HEX for compressing the refrigerant, a heat exchanger HEX for drying the laundry in the rotary drum 3, and an expansion valve for containing the pressure for decompressing the high-pressure refrigerant. The decompression unit 33. The heat exchanger HEX includes a heating unit 32 that heats up the refrigerant that is to be cooled by the compression unit 31 to become a high-temperature and high-pressure refrigerant, and a refrigerant that is depressurized and becomes a low-pressure refrigerant to take heat from the surroundings. In the present embodiment, the heating unit 32 is exemplified as a heat radiating portion. The dehumidifying portion 34 is exemplified as a port and a hot portion. As shown in Fig. 3, the heat pump device 30 further includes a connecting unit 31. Heating unit 32 of heat exchanger HEX and The wet portion 34 and the line 20 of the pressure reducing portion 33. The refrigerant flowing in the line 20 is circulated between the compression portion 31, the heating portion 32, the dehumidifying portion 34, and the pressure reducing portion 33. 201139779 In Fig. 3 and In the figure 7, a bus bar G extending from the top 2a of the bottom wall 522 of the water tank 2 (the uppermost point of the circular bottom wall 522) is shown. The bus bar G is a bus bar existing outside the peripheral wall 521 of the Putian drawing water tank 2. The pressing portion 31 is disposed above the peripheral wall 521 of the water tank 2, and is disposed offset from the bus bar g to the right side wall 1a. The compressing portion 31 includes a bottom surface 31p of the water tank 2 located below the bus bar G. Since the upper space above is effectively used in the compression unit 31, the heat pump device 3 including the compression unit 31 can be appropriately housed in the smaller casing 1. Because the position of the compression portion 31 is offset from the right side wall a (or the left side wall lb) relative to the bus bar G at the uppermost position, the degree of twist of the frame 1 is not increased, and the thermal system 30 can be disposed on Upper space. As such, a small laundry dryer 500 can be provided. In the heating unit 32, the refrigerant flowing in the line 2 is thermally exchanged with the ambient air (dry air flowing from the filter unit 40 into the heating unit 32). As a result, the refrigerant is heated and vaporized, and the water component in the dry air is dew condensation. As a result, the water component in the dry air is removed. The refrigerant after vaporization flows into the compression portion 31. The compression unit 31 compresses the refrigerant to have a south temperature and a high pressure. The high temperature and high pressure refrigerant then flows into the heating unit 32. The refrigerant is heat-exchanged with the ambient air (dry air flowing from the dehumidifying portion 34 into the heating portion 32) in the heating portion 32. As a result, the dry air is heated and the refrigerant is cooled and liquefied. The pressure reducing unit 33 depressurizes the liquefied high-pressure refrigerant to have a low temperature and a low pressure. The low temperature and low pressure refrigerant flows into the dehumidifying portion 34 again. As described above, the blower unit 9 sends dry air to the water tank 2 through the downstream air passage 582. After the air is dried, it flows into the rotary drum 3 through the water tank 2. The result is 201139779. The laundry contained in the rotary drum 3 is dried. As a result of the drying of the clothes, the dry air contains more water components. As described above, the air blowing portion 9 sucks the dry air in the rotary drum 3 from the discharge port 11 of the water tank 2. As a result, the dry air reaches the heat pump device 30 via the upstream air passage 581 and the damper portion 4A. As described above, the dehumidifying portion 34 of the heat pump device 30 initially removes and cools the dry air. As a result, the water component in the dry air is dew condensation and separated from the dry air. After the air is dried, it flows into the heating portion 32. The heating unit 32 heats the dry air as described above. As a result, the dry air passing through the heat pump device 30 becomes high temperature and low humidity. The blower unit 9 sends the dry air of high temperature and low humidity to the rotary drum 3 again. As shown in Fig. 4, Fig. 6, and Fig. 7, the air blowing portion 9 that is connected to the heat pump device 30 is disposed close to the compression portion 31. In the present embodiment, the air blowing portion 9 is disposed between the compression portion 31 and the left side wall lb. The busbar G of the peripheral wall 521 of the water tank 2 is disposed on the left side space of the compression portion 31 disposed on the side of the right side wall la, and is effectively used in the arrangement of the air blowing portion 9, so that the air blowing portion 9 is appropriately housed in the smaller frame 1 in. The arrangement of the heat pump device 30 and the air blowing portion 9 arranged between the right side wall 1a and the left side wall 1b hardly causes an increase in the height of the frame body 1. Therefore, a small laundry dryer 500 can be provided. Further, as the refrigerant to be applied to the heat pump device 30, a general refrigerant such as an HFC (hydrofluorocarbon)-based refrigerant, an HFO (hydrofluoroolefin compound)-based refrigerant, or a carbon dioxide refrigerant is preferably used. (Supporting Mechanism) Fig. 8 is a view schematically showing the three-dimensional support member of the washing and drying machine 500. Fig. 9 is a perspective view schematically showing a washing and drying machine 5'. The support mechanism will be described using Figs. 6, 8 and 9. The washing and drying machine 5 further includes a support mechanism 560 that supports the heat pump unit 3 in the frame. The support mechanism 560 includes a support member 61 that supports the heat pump device 30, and a regulation member 62 that inhibits the heat pump device 30 from being displaced upward. As shown in Fig. 8, both ends of the support member 61 of the heat pump device 30 are supported between the compression portion 31 and the regulation member 62, and are respectively engaged with the upper edge of the right side wall 1& and the upper edge of the left side wall lb. Similarly, the two ends of the regulating member 62 are respectively engaged with the upper edge of the right side wall la and the upper side wall than the upper edge. The support member 61 extending between the right side wall 1a and the left side wall 1b of the heating unit 32 and/or the dehumidifying portion 34 disposed upstream of the compressing portion 31 supports the heat pump device 30. The regulating member 62 extending between the right side wall 1a and the left side wall lb at a position farther from the compression portion 31 than the support member 61 regulates the upward displacement of the heat pump device 30. In the present embodiment, the support member 61 is adjacent to the compression portion 31. The regulation member 62 extends above the filter portion 40 disposed above the heat pump device 30. Among the heat pump devices 30, the compression portion 31 has a large weight. The weight of the compression portion 31 is applied to the right side wall 1a and the left side wall 1b via a support member 61' supporting the heat pump device 30 in the vicinity of the compression portion 31. As a result, the weight of the compression unit 31 reduces the vibration of the right side wall la and the upper edge of the left side wall lb due to the vibration factor such as the rotation of the rotary drum 3. The weight of the heat pump device 30 for the load of the right side wall 1 a and the left side wall 1 b indicates an increase in the weight of the vibration element group including the right side wall 1 a and the left side wall 1b. The increase in the weight of the vibration element group including the right side wall ia and the left side wall is such that the vibration vibration 13 201139779 is reduced for the same exciting force. 4 & • The right side wall la and the left side wall lb of the frame 1 are subject to downward gravity, so the right side wall la and the left side wall lb are exposed to the rotation S of the rotary drum 3, and the vibration factor thereof may be appropriately reduced. The vibration of the right side wall la and the left side wall lb. The installation of the gentleman &, ... fruit can suppress the vibration of the frame body as a whole. The support mechanism 560 having the branch member 61 is used to act on the compression unit 31; the "", the gravity of the device 30, the pressure on the right side wall ia and the left side wall lb" is effectively suppressed to cause rotation. The vibration of the right side wall la and the left side wall lb of the frame 1 of the rotation or other vibration factor of the drum 3. Fig. 10 is a perspective view showing another configuration of the support member in the washer dryer 500. Fig. 11 is a washing and drying A schematic perspective view of the dryer 500. The other arrangement of the support members will be described using the first and fourth figures. The weight of the compression portion 31 can also be loaded on the right side wall 1a and the left side wall lb, as shown in Fig. 11, for example. The support mechanism 560 may also be provided with a support structure extending between the right side wall 1a and the rear wall Id instead of the support member 61 described above, and the 'compression unit 31' is disposed as shown in FIG. The corner portion between the right side wall la and the rear wall ld. Since the compression portion 31 is surrounded by the right side wall la, the rear wall Id, and the support member 63, even if the washing and drying machine 500 falls or falls over, the heavier compression portion 31 is also suitably supported by the right side wall la, the rear wall Id, and the support member 63. The support mechanism 56A is further described in Fig. 6 and Fig. 8 to Fig. 5. As shown in Fig. 6, the air blowing portion 9 disposed adjacent to the compression portion 31 is connected to the heat pump device 30. Therefore, the right side wall 1& / or the left side wall, in addition to the weight of the heat pump device 30, also loads the weight of the air supply portion 9. As a result, the right side wall 1& and/or the left side wall of the frame 1 resulting from the rotation or other vibration of the rotating drum 3 The vibration of lb is effectively suppressed. 14 201139779 The air supply unit 9 includes a blower fan 9b that causes the flow of dry air in the circulation air passage 8, and a blower motor % for the blower fan %鄕. The blower motor 9a rotates the feed motor (4) At this time, the dry air that has been sheathed (4) is sent to the rotary drum 3. The blower motor 9 reads the compression portion 31 in the same manner and has a large weight. As described above, the blower portion 9 is disposed close to the compression portion 31. The lower support member 6 is extended along the compression portion of the wind supply portion 9, and is used not only for the branch compression portion S1 but also for the branch air supply portion 9. Therefore, it can be provided to support the more important members ( The compression unit 31 and the air supply unit % are relatively simple The structure of the cut is a significant contribution to the reduction in the number, weight and cost of the parts of the laundry machine. As mentioned above, above the heat pump unit 3, on the right side wall la and the left side wall lb The regulation member 62 is extended. The regulation member 62 is further away from the compression portion 31 than the support member 61. The regulation member 62 will be described using Figs. 1, 3, and 6. As shown in Figs. 1 and 3, The compression portion 31 and the air blowing portion 9 having a large weight are disposed in the vicinity of the rear wall id. On the other hand, the lighter component (for example, the heat exchanger HEX) is closer to the front than the compression portion 31 and the air blowing portion 9. Wall le. Therefore, the circulation mechanism of the dry air containing the heat pump device 30 acts to bring the torque of the lightweight member close to the front wall 1 e up. The regulation member 62 disposed closer to the front wall le than the support member 61 suppresses the displacement of the lightweight member such as the heat exchanger HEX upward. In the present embodiment, the filter unit 40 is connected to the heat pump device 30. The regulating member 62 is erected above the filter portion 4A between the heat pump device 30 and the front wall le. Thus, the regulating member 62 appropriately regulates the upward displacement of the heat exchanger 15 201139779 HEX of the filter portion 40 and the heat pump device 30. Alternatively, the gauge member 62 can also be erected above the heat exchanger HEX of the heat pump unit 30. The regulating member 62 directly regulates the displacement of the heat exchanger HEX upward. As described above, the peripheral components (the filter portion 40 or the blower portion 9) of the heat pump device 30 and the heat pump device 3 are appropriately supported by the support members 61, 63 which are laid under the heat pump device 30. Further, the regulating member 62 is mounted above the heat pump device 30 and/or the filter portion 40. The regulation member 62 and the support members 61 and 63 disposed above and below the heat pump device 30, respectively, appropriately reduce the vibration amplitude in the vertical direction. Thus, the vibration of the casing 1 caused by the rotation of the rotary drum 3 can be reduced as a whole. (Conclusion of the requirements) The support mechanism 560 described above not only suppresses the vibration of the frame 1 but also the damage or damage of the fixing member such as a screw for concluding various components disposed in the upper space of the frame 1 The supporting mechanism 560 can also continuously maintain the peripheral components of the heat pump device 30 and the heat pump device 30 (filter portion 40 or air supply), for example, when accidental dropping or tipping occurs during the handling and/or setting of the washing and drying machine 500. Department 9). Hereinafter, the influence of the supporting mechanism 560 on the fixing member for the connection between the members will be described. There are also several parts in the upper space of the frame of the general laundry dryer. The parts that are arranged in the upper space are typically connected to the supporting elements called the upper wall of the frame. When the washing and drying machine is overturned or dropped, the fixing member (such as a small screw and/or a threaded bushing for fixing the small dowel) that concludes the upper space part and the supporting element is due to the gravity of the part acting on the upper space. And caused by falling over. The impact of falling, and the greater tensile force. 201139779 Produces a large tensile force on a fixed fixing member for heavy parts. Therefore, the fixing member for fixing the components disposed in the upper space of the general washing machine is more likely to be broken when the washing and drying machine is tipped over or dropped. In the present embodiment, the compression portion 31 and the air blowing portion 9 of the heat pump device 30 have a large weight. The support members 61 and 63 appropriately support the compression portion 31 and/or the air blowing portion 9. Further, the regulating member 62 which is further away from the compressing portion 31 than the supporting members 61, 63 is erected above the heat pump device 30 and/or the filter portion 40. The laundry dryer 500 falls. When it is overturned, the weight of the heat pump device 30 and/or the air supply portion 9 is applied to the support members 61, 63 and the laundry dryer 5 is lowered. The impact of falling over. The weight of the heat pump device 30 and/or the air supply portion 9 and the drop of the washing and drying machine 500. The impact force of the overturn acts as a compressive force to the support members 61, 63. The compressive force acting on the support members 61, 63 also acts on the fixing members such as the screws and the threaded bushings that join the support members 61, 63 and the heat pump device 30/air supply portion 9. However, unlike the tensile force, the fixing member is less susceptible to breakage by the compressive force. In the present embodiment, the support members 61 and 63 are disposed close to the compression portion 31 having a large weight. As a result, the moment around the support members 61, 63 is generated. The moment around the branch members 61, 63 is intended to float the relatively light amount of the elements (filter portion 4 and heat exchanger HEX) present between the support members 61, 63 and the front wall le. The moment around the support members 61, 63 produces a compressive force against the gauge member 62 that is mounted above the heat pump device 30 and/or the filter portion 40. The compressive force applied to the gauge member 62 also acts on the fixed gauge member 61, the heat pump device 30 and/or the screw portion of the filter portion 4, and the threaded bushing. However, unlike the tensile force, the fixing member is less likely to be damaged by the compressive force. The height dimension of the frame of a typical washer dryer is increased according to the height dimension of the building members supporting the parts of the upper space. In the present embodiment, the rotary drum 3 and the water tank 2 are inclined in the casing. As a result, the upper wall rear wall ld is closer to the front wall. Wide near. The larger size (compression portion 31 and/or air blowing portion 9) is disposed in the upper space in the vicinity of the rear wall W. Therefore, it is possible to ensure that the height of the frame 1 is increased, and a sufficient space for arranging the support members 61, 63 is secured. The structure in which the air blowing unit 9 and the heat pump device 3 are connected will be described using Fig. 4 . The washing and drying machine 5 has a structural member 38 for converging the air blowing portion 9 and the heat system device 3''. The air blowing portion 9 that is connected to the heat pump device 3 by the structural member 38 is disposed on the side of the compression portion 31. As a result, as described above, not only the weight of the heat pump device 30 but also the weight of the blower portion 9 is also applied to the right side wall "and/or the left side wall", which can effectively reduce the right side of the rotation or other vibration factor caused by the rotary drum 3. The vibration of the wall la and/or the left side wall 15. The air supply motor 9a has the same weight as the compression portion 31. Since the weight portion 31 and the air blowing portion 9 are disposed close to each other, the support members 61 and 63 can simultaneously The support portion 3 and the air blowing portion 9 are supported. Therefore, a relatively simple structure for supporting a heavy weight (compression portion 31 and air blowing portion 9) can be provided. A relatively simple structure has a relatively large weight (compression portion) The support of the air blower portion 9) contributes significantly to the reduction in the number, weight, and cost of the washer dryer 500. (Configuration of the heat pump device) The dehumidifying portion 34 and the heating portion 32 of the heat pump device 30 are preferably used. A metal such as copper or aluminum having high thermal conductivity is formed. As described above, since the heat treatment device 18 201139779 is provided above the water tank 2, the dehumidifying portion 34 and the heating portion 32 of the heat pump device 30 are hardly exposed to the washing water. Dehumidification The portion 34 and the heating portion 32 are less susceptible to metal corrosion caused by chemical components such as a lotion, a softener, or a bleach contained in the washing water. The dehumidifying portion 34 and the heating portion 32 of the heat exchanger HEX are circulated along the dry air. Since the air passages 9 are linearly arranged, the dry air in the heat exchanger HEX flows substantially linearly. Generally, the fluid flow in the bending causes a bias current and a pressure loss of the fluid, but according to the present embodiment, The arrangement of the straight line of the wet portion 34 and the heating portion 32 hardly causes a bias current and a pressure loss of the fluid. As a result, an efficient circulation of dry air can be achieved. Therefore, it is possible to reduce the flow of dry air in the circulation air passage 8 The power consumption of the air blowing portion 9 is suppressed. The drift of the dry air is suppressed, and as a result, the high-speed flow of the dry air passing through the dehumidifying portion 34 can be suppressed. As described above, the dehumidifying portion 34 dews the water component in the dry air. When the high-speed flow of air is locally generated in the dehumidifying portion 34, the dew condensation water component is again transported to the rotary drum 3 via the blower portion 9 by the dry air. As a result, the rotary drum 3 is rotated. In the present embodiment, the arrangement of the straight line of the fishing unit 34 and the heating unit 32 suppresses the high-speed flow of the dry air as described above. Therefore, the water caused by the condensation is hardly generated. The drying efficiency of the component cycle is reduced. In general, when the flow rate of the fluid passing through the heat pump device is lowered, the heat absorption amount from the heat absorbing portion of the fluid heat absorbing portion is reduced. As a result, the vaporization of the refrigerant passing through the heat absorbing portion becomes incomplete. The refrigerant that has not completely vaporized reaches the compression device. The compression device compresses the liquid refrigerant, and as a result, it is potentially malfunctioning. 201139779 In the present embodiment, the arrangement of the straight line except the weir portion 34 and the heating portion 32 is maintained by the heat exchanger. The proper flow rate of the dry air in the HEX is such that complete vaporization of the refrigerant in the dehumidifying section 34 is easily achieved. Since it is difficult for the liquid refrigerant to flow to the compression portion 31, the failure of the compression portion 31 is hard to occur. Therefore, the reliability of the washing and drying machine 500 having the heat pump device 30 is improved. As a result of the increase in reliability, continuous deburring can be performed without stopping the compression unit 31. Therefore, the drying operation time can be shortened. (Arrangement of Air Supply Portion) The arrangement of the air blowing unit 9 will be described with reference to Fig. 1 . As described above, the blower unit 9 includes the blower motor 9a and the blower fan 9b. The blower motor 9a is provided on the side of the blower fan 9b. As a result, the rotation axis of the blower unit 9 is inclined downward toward the upstream. As a result, even if the water component dewed by the dehumidifying portion 34 is scattered to the air blowing portion 9, the water component adhering to the air blowing fan 9b is dropped in the opposite direction of the air blowing motor 9a by gravity and the thrust from the air blowing fan 9b. Thus, the water component adhering to the blower fan 9b hardly reaches the blower motor 9a located above the blower fan 9b. (Arrangement of Control Substrate) The arrangement of the control substrate will be described using FIG. The washing and drying machine 500 includes a control board 50 disposed in the housing 1 . Electronic components (various circuits) for controlling the washing and drying machine 5 are mounted on the control board 50. The control board 5 is positioned above the lotion input unit 10 housed in the housing 1. The wire for connecting the control substrate 50 of the present embodiment to the drive motor 7 or the blower motor 9a and the like is shortened as compared with the control substrate disposed in the lower space of the casing. The control board 50 is disposed in the upper space of the casing 1 (preferably in the vicinity of the front wall le). Therefore, the operator can perform the repair of the control substrate 50 while standing in the vicinity of the front wall le of the casing. In this way, the washing and drying machine 5〇〇 can provide efficient maintenance work. (Filter Unit) The filter unit 40 will be described with reference to Figs. 1, 2, and 4 to 6 . The lint (referred to as the dust component of the thread) is produced by the dry laundry in the rotary drum 3. The adhesion and accumulation of the lint to the heat exchanger HEX causes a decrease in the circulation efficiency of the dry air and the heat exchange rate of the heat exchanger HEX. The washer-dryer 500 includes a filter unit 40 disposed upstream of the heat exchanger HEX. The filter unit 40 collects and recovers foreign matters (lint) such as thread, dust, and pollen from the dry air before passing the dry air through the heat exchanger HEX, thereby suppressing entry of the lint toward the heat exchanger HEX. The upper space of the casing 1 is attached to the filter portion 40 of the circulation air passage 8, and is close to the front wall IE. Therefore, the user or the operator who wants to remove the lint accumulated in the filter unit 40 can perform the maintenance work while standing near the front wall le of the casing 1. As such, the washer dryer 500 can provide highly efficient maintenance operations. As shown in Fig. 5, the filter unit 40 includes a first filter 40A and a second filter 40B disposed downstream of the first filter 40A. The mesh of the first filter 40A is thicker than the second filter 40B. Therefore, the second filter 40B collects and recovers fine lint and other foreign matter that has passed through the first filter 40A. As a result, it is possible to suppress a decrease in heat exchange efficiency of the heat pump device 30 due to adhesion of lint and other foreign matter, and a decrease in cycle efficiency of the blower portion 9. Further, the transition unit 40 suppresses the scattering of lint and other foreign matter toward the outside of the casing 1. Therefore, it is possible to suppress the contamination around the washing machine # 201139779 clothes dryer 500. As shown in Fig. 2, an opening 4c is formed in the upper wall lc of the casing. The first filter 40A attaches and detaches the circulation air passage 8 via the opening portion 4〇c formed near the front edge of the upper wall lc. Therefore, the user or the operator can attach and detach the third filter 4A to the frame while standing near the wall le of the casing 1. As such, the washer dryer 500 can provide high efficiency maintenance operations. Unlike the first filter 40A, the second filter 40B is fixed to the circulation air passage 8. Since the first filter 40A removes lint and other foreign matter in the dry air before the second filter 40B, the frequency of clogging of the second filter 4B is small. Further, the user or the operator can clean the second filter 40B via the opening portion 40c formed in the upper wall lc of the casing. Therefore, the clogging of the second damper 40B fixed to the circulation air passage 8 does not require excessive labor. After the second filter 40B, a heat exchanger ΗΕχ is disposed. As described above, the heat exchanger HEX flows through the refrigerant which is heated by the compression unit 31. The second filter 40B fixed to the 4-shield air passage 8 prevents the user who is unskilled from the maintenance work from easily contacting the heat exchanger HEX. Further, unlike the second filter 4A, since the second filter 40B is fixed to the circulation air passage 8, the second filter 40B hardly generates positional change. Therefore, the entry of the lint caused by the improper setting of the second filter 40B toward the heat exchanger hex can be appropriately suppressed. The filter portion 40 generates a pressure loss of dry air. As a result of the pressure loss, the velocity distribution of the dry air is smoothed (i.e., the flow of the dry air is rectified). As shown in Figs. 4 and 5, the filter unit 4 is disposed in the heat exchanger HEX. Therefore, the rectified dry air flows into the heat exchanger hex. 22 201139779 When the road, slaves and §, in order to reduce the size of the washing and drying machine, it is necessary to shorten the circulation of the wind. It is difficult to set up a rectifying mechanism (such as a straight pipe) in the wind path, but in the dry ^ form, because of the filtration The unit 4G rectifies the dry air, so that the flow interval required for the rectification of the dry gas is shortened. Drying after rectification The two milks are looking for a large change in the efficiency of the HHEX flow suppression. As a result, the heat exchange efficiency of the heat exchanger HEX can be improved. In the transition portion 4A upstream of the heat exchanger HEX as described above, the money mechanism _ is not required to be provided. Straight f), that is, dry air is achieved. Thus, the circulation air passage 8 can be appropriately shortened. As shown in Figs. 1 and 5, the dehumidifying portion 34 of the heat exchanger 包含 includes a lead-in surface 534 into which the air can flow. The filter unit 4 is disposed near the introduction surface. Therefore, the dry air rectified by the filter unit 4 is directly sent to the dehumidifying portion 34 disposed after the filter unit 40. As described above, the filter portion 40 rectifies the dry air. The rectification of the dry air by the filter reduces the flow rate of the dry air. Since the circulation air passage 8 hardly bends the flow direction of the dry air between the filter portion 40 and the introduction surface 534, the dry air flows in a straight line toward the dehumidification 34 after the flow rate is reduced. As a result, the dry air passing through the dehumidifying unit 34 does not locally become a high flow rate, and the scattering of the water component dew condensation in the dehumidifying unit 34 can be suppressed. (Recycling Structure) The recycling structure for recovering the water component dew condensation in the dehumidifying portion 34 will be described using Fig. 5 . As shown in Fig. 5, the washer-dryer 500 further includes a recovery structure 35 for recovering the water component dew condensation in the dehumidifying portion 34. The recovery structure 35 is disposed below 23 201139779. As described above, since the filter portion 4 is prevented from scattering due to the dew condensation of the water component of the dehumidifying portion 34, the water component can be sufficiently recovered by using the small plastic recovery structure. Therefore, a small laundry dryer 5 可 can be provided. A recess (not shown) is formed in the recovery structure 35. The water dew condensation in the dehumidifying portion 34 is transmitted to the surface of the dehumidifying portion 34 and is dropped in the concave portion. The recess is formed to accept a range of water components that are scattered downstream by dry air. As described above, the filter portion 4 of the rectifying and drying air suppresses the scattering of the water component dew condensation in the dehumidifying portion 34. Therefore, the area of the recess required to receive the water component dropped from the dehumidifying portion % is small. Therefore, the water component can be sufficiently recovered using the small recovery structure 35. As described above, the water component which is scattered by the filter unit 4 is appropriately recovered by the recovery structure 35. The recovered water component is preferably discharged from the recess of the recovery structure 35 to the outside of the laundry dryer 500. For example, the water component can be drained together with the washing water to the drain opening provided below the frame 1. The recovery structure 35 is disposed in the upper space of the tow body 1 in the same manner as the heat exchanger HEX. Therefore, the water component recovered by the recovery structure 35 is properly drained by utilizing the potential energy. Since the discharge of the water component of the recovery structure 35 does not require a dedicated discharge device such as a pump. Therefore, a small washing and drying machine can be provided. (Maintenance of heat exchanger) The maintenance of the heat exchanger HEX will be described using Figs. 2 and 5. As described above, the filter unit 4 disposed before the heat exchanger HEX effectively suppresses the inflow of lint or other foreign matter toward the heat exchanger HEX. However, as a result of the use of the washer-dryer 500 for a long period of time, there are also cases where the heat exchanger hex adheres and/or accumulates lint or other foreign matter. 24 201139779 As described above, the heat exchanger HEX is provided on the upper portion of the casing 1. The operator can remove the first actuator 40A through the opening 40c formed in the upper wall lc of the casing 1. Then, the operator can remove the second filter 40B from the circulation air path 8 using a dedicated tool. As a result, the operator can approach the heat exchanger HEX and remove lint or other foreign matter from the heat exchanger HEX. The operator can perform the first position while standing near the wall le of the frame 1! A series of operations such as removal of the filter 4A, removal of the second filter 40B, and removal of lint or other foreign matter from the heat exchanger HEX. As a result, the Laundry Dryer 5〇〇 provides efficient maintenance. (Structure of Filter Portion) The structure of the filter portion 4A will be described using Fig. 5 . The first cylindrical filter 40A having a substantially cylindrical shape of the filter portion 40 includes a filter mesh having a filter mesh which is thicker than that of the second filter 40B. The i-th filter 40A includes a circumferential surface on which an opening portion is formed. The opening formed in the circumferential surface of the first filter 40A serves as an inflow portion 41 into which dry air flows. The dry air discharged from the spin roller 3 flows into the first filter 40A via the inflow portion 41. The second filter 40B fixed downstream of the first filter 40A includes a flat filter mesh. The filter unit 40 includes a lid portion 42 disposed on the upper portion of the first filter 40A. When the first filter 40A is attached to the washing and drying machine 500, the lid portion 42 is fitted to the opening 40c formed in the upper wall lc of the casing 1. The cover portion 42 is preferably formed to be grippable by a user. When the user mounts the first filter 40A, the lid portion 42 can be used as a handle member. 25 201139779 The first cylindrical filter 40A having a substantially cylindrical shape includes a region L1 which generates a large pressure loss and a region Ls which generates a small pressure loss. The substantially central region Ls generated in the second filter 4A faces the inflow portion 41 and directly collides with the dry air flowing in from the inflow portion 41. The region U is generated above and below the region Ls. The dry air of the cylindrical first filter 40A which generates the pressure loss distribution described above flows into the heat exchanger hex. The result of the pressure loss described above is a velocity distribution of dry air obtained at a relatively high flow velocity in the upper portion of the dehumidifying portion 34 and a small flow velocity in the lower portion of the dehumidifying portion 34. The cylindrical second filter 4A is preferably disposed in the vicinity of the introduction surface 534 of the dehumidifying portion 34. As a result, it is possible to effectively suppress the scattering of the water component which is dew condensation in the dehumidifying portion 34. The droplets of the water component which is dew condensation in the portion 34 are smaller than the upper portion of the dehumidifying portion 34. The drops of water are combined with drops of other water components during the run down. As a result, the drop of the water component gradually increases as it flows down. Therefore, a large amount of water component is attached to the lower portion of the dehumidifying weir 34, and a smaller amount of water component is attached to the upper portion of the dehumidifying portion 34. The speed of the dry air in the lower portion of the dehumidifying portion 34 is smaller than the speed of the dry air in the dehumidifying portion 34_L portion. Therefore, the droplets of the large water component are difficult to scatter. As a result, the scattering range of the water component which is dew condensation in the dehumidifying portion 34 is narrowed. Therefore, the water component dew condensation in the dehumidifying portion 34 can be appropriately recovered using the smaller recovery structure 35. (Compared with the previous washing and drying machine) According to the washing and drying machine 500 of the present embodiment, the heat pump device 30 and the filter unit 40 which is connected to the heat pump device 30 are provided as described above. The heat exchanger HEX of the filter unit 40 and the heat & 褒 30 is disposed in the upper space of the casing 1 (water 26 201139779 above the tank 2). Therefore, the filter unit 40 is disposed close to the heat exchanger HEX. The filter unit 40, the heat exchange SHEX, and the blower unit 9 are sequentially disposed along the flow direction of the dry air. The filter unit 40 rectifies the dry air. The rectified dry air flows into the heat exchanger HEX. The heat exchanger HEX will dehumidify and heat without drying. The blower 9 then sends the dry air toward the rotary drum 3. The prior art washing and drying machine includes a heat pump device disposed in a lower space of the casing (a space lower than the water tank), and a filter portion disposed in a space above the casing (a space above the water tank). The filter unit, the air supply unit, and the heat exchanger are arranged in sequence along the flow direction of the dry air. As described above, in the present embodiment, since the filter portion 4 is disposed close to the hot parent converter HEX, the circulation air passage 8 which is shorter than the circulation air passage used in the above-described prior art washing and drying machine can be used. , circulate dry air. The pressure loss of the dry air flowing through the % wind path 8 can be reduced. The reduction in the pressure loss of the dry air reduces the power consumption of the squadron 9 of the air flow. The decrease in the pressure loss of the drying line also increases the flow rate of the dry air flowing through the circulation air path 8. . The filter portion 4 disposed in the short circulation air passage 8 is provided with a rectifying dry air. The rectification system of miL enhances the heat exchange rate of the missing lock. As a result, the amount of heat exchange per unit time, the amount of money, and the short drying time can be significantly increased as compared with the previous laundry dryer. (The temperature of the dry air is checked.) Use Figure 5 to describe the temperature detection of the dry air. 27 201139779 The laundry dryer 500 further includes a first temperature sensor 36 and a second temperature sensor 37. Both the first temperature sensor 36 and the second temperature sensor 37 are used to detect the temperature of the dry air in the circulation air path 8. The first temperature sensor 36 detects the temperature of the dry air flowing between the rotary drum 3 and the heat exchanger HEX. The second temperature sensor % is disposed between the filter portion 40 and the dehumidifying portion 34. The second temperature sensor 37 detects the temperature of the dry air between the heat exchanger HE X and the rotary drum 3. The second temperature sensor 37 is disposed after the blower unit 9. The first temperature sensor 36 detects that it is dehumidified by the heat exchanger HEX. The temperature of the dry air before heating. The second temperature sensor 37 detects the temperature of the dry air after dehumidification and heating by the heat exchanger HEX. The output signal of the first temperature sensor 36 and the output signal of the second temperature sensor 37 are used for control of the heat pump device 30. The first temperature sensor 36 between the filter unit 40 and the heat exchanger HEX is disposed in a region L1 in which the pressure loss of the first filter 40A having a substantially cylindrical shape is large (the upper portion of the first filter 4A) Or lower) nearby. Compared with the region Ls where the pressure loss of the first filter 4a is small, it is difficult to cause clogging due to lint or other foreign matter in the region 11 where the pressure loss is large. Therefore, the first temperature sensor 36 provided in the vicinity of the region L1 can accurately detect the temperature of the dry air for a long period of time. When the filter unit 40 is clogged with lint or other foreign matter, since the temperature detected by the first temperature sensor 36 changes, the output signal of the first temperature sensor 36 is utilized. The filter unit 4 is detected for clogging. Therefore, the first temperature sensor 36 disposed in the vicinity of the region L1 can be accurately detected for a long period of time, and the presence or absence of clogging is detected. The first temperature sensor 36 between the second unit 40 and the heat exchanger HEX: the air supply. The second temperature sensor 37 downstream of the Ρ9 is disposed inside the shorter 'Li Road 8'. The interval between the first temperature sensor 36 and the gate of the second temperature sensor 37 is changed (four). The first temperature sensor 36 and the second degree sensor 37 in the shorter interval are less likely to cause an error factor of the temperature detection error (e.g., (4) of dry air). So, the first! The temperature sensor 36 and the second 'degree sensing n 137 are hardly affected by the error factors such as the external force of the dry air. The temperature of the dry air can be accurately detected. (Alternative configuration) In the present embodiment, the filter unit 40 includes the first filter 40A and the second transition device to perform the two-stage shouting process, and instead, the dryer can also be used with the single-filament requirement. A filter device that performs m treatment. Alternatively, the dryer may be provided with a filter device that uses a filter element of greater than 2 to perform a filtration process of greater than two. In the present embodiment, the filter unit 4A includes a ith filter 20A having a substantially cylindrical shape. Instead, the dryer can also be provided with flat filter elements or other shapes of filter elements. In the present embodiment, the washing and drying machine 5 has a washing function and a drying function. Instead, the dryer can also be used without a laundry function. For example, if the laundry function is removed from the above-described washing and drying machine 500, a dryer having only a drying function can be obtained. The dryer having only the drying function does not need to be connected to the water supply pipe or the drain pipe of the water tank 2 of the above-described washing and drying machine 500. The element corresponding to the above-described water tank 2 is used as a groove for covering the rotating drum 3. 29 201139779 Other requirements may be the same as the various requirements of the laundry dryer 500 described above. In the present embodiment, the washing and drying machine 500 is a drum type washing and drying machine. Instead, the dryer can also be a dry laundry dryer for dry hanging garments. Even in the case of the 洗衣 type washing and drying machine, according to the principle of the above-described embodiment, the reliability of the heat pump device can be improved, the drying time can be shortened, and the power consumption can be reduced. In the above embodiment, a dryer having the following configuration is mainly included. A dryer according to one aspect of the present invention includes: a rotary drum for accommodating clothes; a heat pump device for drying the clothes; and a frame for defining a wall portion for accommodating the rotating drum and the internal space of the heat pump device And a support mechanism for supporting the heat pump device including a compression portion for compressing the refrigerant in the frame; the heat pump device is disposed above the rotary drum, and the wall portion includes a side wall that is erected in the vertical direction. The side wall is connected to the aforementioned support mechanism. According to the above configuration, the heat pump device includes a compression portion that compresses the refrigerant. The compression portion has a large weight. The support mechanism supports the heat pump device in the frame. The side wall of the frame is connected to the support mechanism. Therefore, the larger weight of the compression portion is applied to the side wall, reducing the vibration amplitude of the side wall. By connecting the side walls of the branching structure to the heat pump unit, a large number of vibration element groups including the side walls and the heat pump unit can be formed. Therefore, the vibration amplitude for the same exciting force can be reduced. Since the weight of the heat pump device including the compression portion is applied to the side wall, the side wall vibration of the frame caused by the rotation of the rotary drum can be effectively suppressed. Since the heat pump device is disposed above the rotary drum, the operator can easily access the heat pump device. Therefore, maintenance of the heat pump device becomes easy. In the above configuration, the dryer further includes a groove including a peripheral wall of a cylindrical shape that covers the rotary drum, and the side wall includes a first side wall and a second side wall opposite to the first side wall. The compressed portion disposed on the side wall of the first peripheral wall and the second side wall offset from the side wall of the first side wall and the second side wall, and the compressed portion disposed above the peripheral wall includes a bottom surface located below the bus bar. According to the above configuration, the dryer further includes a groove including a peripheral wall of a cylindrical shape that covers the rotary drum. Since the compression portion is disposed above the peripheral wall toward the side wall side of the first side wall and the second side wall, the compression portion is provided so that the bottom surface of the compression portion is located below the bus bar of the uppermost peripheral wall. . Since the space inside the casing above the rotary drum is effectively used as a place where the compression portion is provided, the height of the casing can be increased. Therefore, a small dryer can be provided. In the above configuration, the dryer further includes a blower that includes a blower fan that blows dry air and a blower motor, and a circulation duct that connects the outer tub and the heat pump device to form a circulation path of the dry air from the blower. The air blowing portion that is connected to the heat pump device is disposed between the compression portion and the other of the first side wall and the second side wall. According to the above configuration, since the weight of the heat pump device and the weight of the air blowing portion are also applied to the side walls, the side wall vibration of the frame body caused by the rotation of the rotary drum can be effectively suppressed. Similarly to the compression portion, the air supply portion having a large weight is disposed between the compression portion and the other of the first side wall and the second side wall. Since the air blowing portion and the compression portion are arranged between the first side wall and the second side wall, 31 201139779, the support mechanism easily supports the air blowing portion and the compression portion. Since the number of components is reduced by four, the number of components and the weight of the mechanism can be reduced. In the above configuration, the heat system should preferably include the cost. The heat absorbing portion for drying the dry air and the heat absorbing portion using the refrigerant air are arranged linearly with respect to the air blowing portion along the winding path. According to the above configuration, the heat absorbing portion and the heat radiating portion are linearly arranged along the circulating air portion, so that the dry air is not bent (four), and the pressure loss of the gas is small, so that the dry air flows in the circulating air path: : The power consumption of the ministry is getting smaller. The high-speed flow due to the bending of the dry air is hardly generated due to the bias current due to the bending of the dry air. Therefore, in the dry air of the dew condensation in the heat absorbing portion, the shirts are returned to the material by the air supply portion. If you have money, you can get it. In the above configuration, the air blowing motor is preferably disposed above the air blowing fan. The air blowing portion is preferably formed to send the dry air to the lower side. According to the above configuration, since the blower motor is above the blower fan and the blower sends the dry air to the lower side, the water component of the dew condensation in the fishing unit is scattered to the blower portion, and the water component is dripped downward, so that the water can be suppressed. Into the wounded up to the wind motor into the people. Therefore, the failure rate of the blower motor can be reduced and the reliability of the blower motor can be improved. In the above configuration, the support structure includes a support member extending from the lower side of the heat system, and a support member disposed on the support member and extending over the front of the ', , and The upper regulatory member β 32 201139779 Therefore, according to the above configuration, the branch member extending below the ageing device is a stable cutting device. Further, the regulating member extending above the hot plate set regulates the hot spring device to be displaced upward. The heat pump device vibrates up and down. In the above configuration, the aforementioned regulating member is preferably further away from the compressing portion than the supporting member. According to the above configuration, since the regulating member is further away from the compressing portion than the supporting member, it is possible to appropriately arbitrarily adjust (4) the heat pump device which is caused by the moment of the weight of the compressing portion to be displaced upward. Industrial Applicability The principle of the above embodiment is preferably used in various drying devices such as a drum type or a hanging type. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a cross-sectional view showing the schematic configuration of a drum type washing and drying machine according to an embodiment. Fig. 2 is a partial view of the front side of the drum type washer dryer shown in Fig. 1. Fig. 3 is a perspective view schematically showing the internal structure of the drum type washing and drying machine shown in Fig. 1. Fig. 4 is a schematic top view of the drum type washer dryer shown in Fig. 1. Fig. 5 is a cross-sectional view taken along line A-A of Fig. 4; Fig. 6 is a perspective view schematically showing the upper portion of the drum type washing and drying machine shown in Fig. 1. Fig. 7 is a perspective view schematically showing the washing and drying machine shown in Fig. 1. 33 201139779 Fig. 8 is a perspective view schematically showing a branch member in the drum type washing and drying machine shown in Fig. 1. Fig. 9 is a perspective view schematically showing the drum type washing and drying machine shown in Fig. 1. Fig. 10 is a perspective view schematically showing another arrangement of the supporting members in the drum type washing and drying machine shown in Fig. 1. Fig. 11 is a perspective view schematically showing the drum type washing and drying machine shown in Fig. 10. Figure 12 is a perspective view schematically showing a prior laundry dryer using a heat pump to dry laundry. [Main component symbol description] 1. . . Frame 8. . . Circulating wind road . . Right side wall 9. . . Air supply unit lb. . . Left side wall 9a. . . Air supply motor lc. . . Upper wall 9b. . . Air supply fan Id. . . Back wall 10... lotion input unit le. . . Front wall 11. . . Discharge port If. . . Bottom wall 20...pipeline 2. . . Sink 30. . . Heat pump unit 2a. . . Top 31. . . Compression unit 3. . . Rotating drum 31a. . . Bottom surface 4. . . Operation panel 32. . . Heating section 5. . . Door body 33. . . Decompression department 7. . . Drive motor 34. . . Dehumidification unit 34 201139779 35. .  . Recycling structure 36. .  . The first temperature sensor 37. .  . The second temperature sensor 38. .  . Structure of the structure 40. .  . Filter section 40A. . . 1st filter 40B. . . 2nd filter 40c. . . Opening portion 41...flow portion 42. .  . Cover 50. .  . Control substrate 61. .  . Support member 62. .  . Regulatory component 63. .  . Support member 100. .  . Frame 102. .  . Drying tank 130. .  . Heat pump mechanism 131. .  . Compressor 132. .  . Heat exchanger 150. .  . Dryer 500. .  . Washing and drying machine 521. .  . The wall 522. .  . Bottom wall 523. .  . Damper 531. .  . The wall of the week 532. .  . Bottom wall 534·. ·Import surface 541. .  . Operation key 542. .  . Display window 560. .  . Support mechanism 581. .  . Upstream wind road 582. .  . Downstream wind road . . Busbar HEX. . . Heat exchanger Ll. . . region

Lg...area 35

Claims (1)

201139779 VII. Patent application scope: 1. A dryer characterized by: a rotary drum for accommodating clothes; a heat pump device for drying the clothes; and a wall for arranging the inner space of the rotating drum and the heat pump device And a support mechanism for supporting the heat pump device including a compression portion for compressing the refrigerant in the frame; the heat pump device is disposed above the rotary drum; and the wall portion is erected in the vertical direction a side wall; the side wall is coupled to the support mechanism. 2. The dryer according to claim 1, further comprising a groove including a peripheral wall of a cylindrical shape that covers the rotary drum; the side wall includes a first side wall and a side opposite to the first side wall a second side wall; the compressed portion disposed on the side wall of the first side wall and the second side wall offset from the side wall of the first side wall and the second side wall; The bottom surface below the aforementioned bus bar. 3. The dryer according to claim 2, further comprising: a blower including a blower fan that blows dry air and a blower motor; and the outer tank and the heat pump device are connected to form the air blower from the air blower a circulating air passage for a circulation path of dry air; 36 201139779 The air blowing portion associated with the heat pump device is disposed between the compression portion and the other of the first side wall and the second side wall. 4. The dryer according to claim 3, wherein the heat pump device includes a heat absorbing portion that uses heat from the drying air using the refrigerant, and a heat releasing portion that heats the drying air using the refrigerant; the heat absorbing portion and the heat radiating portion The air blowing portions are linearly arranged along the circulating air passage. 5. The dryer according to claim 3, wherein the air blowing motor is disposed above the air blowing fan, and the air blowing portion is configured to send the dry air to the lower side. 6. The dryer according to claim 1, wherein the support mechanism comprises: a support member extending from below the heat pump device to support the heat pump device; and extending above the heat pump device to regulate the heat pump A regulatory member that is displaced upwards. 7. The dryer of claim 6 wherein said regulatory member is further from said compression portion than said support member. 37