TW201219619A - Laundry drying processor - Google Patents

Abstract

The present invention provides laundry drying processor (100) having: tub (410); removal device (700) for removing lint; dehumidifying heater (630); air supplier (621) and power supply (530), wherein removal device (700) includes: housing (710); filter element (720); adjuster (500) for adjusting flow direction of dry air; and controller (510) for controlling adjuster (500), adjuster (500) includes rotating shaft (740) rotating in housing (710), adjustment plate (765) extending from rotating shaft (740), and drive source (520) for rotating rotary shaft (740), filter element (720) includes first area (753) extending in extension direction of rotating shaft (740), and second area (754) extending along first area (753), and controller (510) controls drive source (520) in response to power to change amounts of dry air passing through first and second areas (753, 754).

Description

201219619 VI. Description of the invention: c. The invention relates to a drying treatment device for drying clothes. C ^tr ϋ BACKGROUND OF THE INVENTION Drying machines for drying clothes or in addition to drying functions A drying device capable of washing a washing machine, typically supplying dry air into a drum containing clothes to dry the clothes. A drying treatment apparatus having an external air introduction system for improving drying efficiency is disclosed in Japanese Laid-Open Patent Publication No. 2007-82586. According to Japanese Laid-Open Patent Publication No. 2007-82586, the drying treatment apparatus has a casing and dehumidifies and heats the air in the casing to provide heating of the dry air. The drying treatment device can suck the outside air into the casing as needed, and heat the fruit in the cold portion. The result is an increase in the efficiency of heat exchange in Canada. The dry handling efficiency of the clothes depends not only on the heat exchange efficiency of the heat pump, but also on the flow of the air in the ring of the casing (10). The typical setting of the county is to have a transitioner that removes the lint separated by the clothes (so-called yarn shavings = angstroms) between the drying steps. The lint causes the blockage of the transitioner to reduce the flow of air. The drying of the ring is generally used to control the dry air in the lean body (four)% of the fan to control the dry space in the flow, to a predetermined extent. The filter described above produces a blockage that causes the blade to rotate at a higher number of revolutions. The result is a reduction in the flow of dry air caused by ^201219619. However, the rotation of the blades with a high number of revolutions increases the power consumption of the blower. SUMMARY OF THE INVENTION An object of the present invention is to provide a drying processing apparatus that can achieve power saving. A drying treatment device according to one aspect of the present invention includes: a drying tank having an air inlet for sucking dry air for drying clothes and an exhaust port for discharging the dry air; and a removing device for exhausting The dry air discharged from the mouth removes cotton dust; the dehumidification heating device dehumidifies and heats the dry air from which the cotton dust is removed by the removing device; and the air supply device dries and dries the drying device by the dehumidifying heating device The air is supplied to the air intake port at a predetermined flow rate; and the power supply source supplies electric power for operating the air supply device, and the removing device includes a casing, and the battery is formed to be introduced into the exhaust port. a drying air introduction port and a discharge port for discharging the drying air to the dehumidification heating device; the filter element is attached to the discharge port to remove the cotton dust by the drying air; and an adjustment mechanism for adjusting the introduction port The flow direction of the aforementioned drying air of the filter element; and a control element for controlling the aforementioned adjustment The adjustment mechanism includes: a rotating shaft that rotates in the casing, an adjusting plate that extends from the rotating shaft, and a driving source that rotates the rotating shaft; and the filter element includes: extending toward the extending direction of the rotating shaft In the first field and the second field extending along the first field, the control element controls the drive source based on the electric power, and passes the flow rate of the dry air in the first 201219619 field and passes through the second field. The flow rate of the aforementioned dry air changes. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic perspective view of a laundry dryer of an embodiment. Fig. 2 is a schematic cross-sectional view showing the laundry dryer shown in Fig. 1. Figure 3 is an enlarged perspective view of the top wall of the laundry dryer shown in Figure 1. Fig. 4 is a view schematically showing an external air introduction mechanism of the laundry dryer shown in Fig. 1. Fig. 5 is a cross-sectional view of the external air introduction mechanism taken along line A - A shown in Fig. 4. Fig. 6 is a plan view schematically showing the cover mechanism of the external air introducing mechanism shown in Fig. 4. Fig. 7 is a schematic bottom plan view of the cap mechanism shown in Fig. 6. Fig. 8 is a schematic plan view showing a filtering device of the external air introducing mechanism shown in Fig. 4. Fig. 9 is a schematic cross-sectional view of the filtering device taken along the line B-B shown in Fig. 8. Fig. 10 is a schematic cross-sectional view of the filtering device taken along line C - C shown in Fig. 9. Fig. 11A is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. Fig. 11B is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. 5 201219619 Figure 12A shows the operation of the adjustment mechanism of the filter device shown in Figure 5. Fig. 12B is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. Fig. 13 is a block diagram showing the outline of the elements for controlling the operation of the adjustment mechanism shown in Figs. 11A to 12B. Fig. 14 is a view showing the range of rotation of the rotating shaft according to the control of the adjusting mechanism shown in Fig. 13. Fig. 15 is a cross-sectional view schematically showing the rotation axis of the filtering device shown in Fig. 9. Fig. 16A is a cross-sectional view schematically showing the switching operation of the casing of the filter device shown in Fig. 9. Fig. 16B is a cross-sectional view schematically showing the switching operation of the casing of the filter device shown in Fig. 9. [Embodiment 3] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, one embodiment of a drying treatment apparatus and a removal apparatus will be described using a drawing. In addition, the terms "upper", "lower", "left", or "right" used in the following descriptions are simply for the purpose of explanation, and the principles of the drying treatment device and the removal device are There are no restrictions. (Composite configuration of the laundry dryer) Fig. 1 is a schematic perspective view showing a washing and drying machine of a drying apparatus of an embodiment. In the present embodiment, a drying treatment device for a washing and drying machine capable of both a washing machine and a drying function is exemplified. Instead, it can also be used as a drying device for the dryer of the washing machine. The garment drying machine 100 has a main casing 200 and a door body 3〇〇. The main housing is formed in a slightly rectangular parallelepiped shape. The main casing 200 includes a front wall 210 that is erected in the vertical direction, a rear wall 220 that is opposite to the front wall 210, and a left side that is placed up and down between the front wall 21〇 and the back wall 22〇. 230 and the right side wall 240, the top wall 25A forming the upper surface of the main casing 2, and the bottom wall 260 forming the lower surface of the main casing 200. The front wall 210 includes a lower wall 211 disposed above, a central wall 212 disposed above the lower wall 211, and an upper wall 213 disposed above the central wall 212. The central wall 212 and the upper wall 213 are curved so as to become closer to the back wall 22A as they go upward. The central wall 212 includes an annular concave surface 214 that forms a concave field, and the concave shaped body forms a shape that is slightly complementary to the slightly disc-shaped door body 300. The concave surface 214 is formed as an input port 215 that penetrates the center of the central wall 212. The inlet 215 is connected to a washing and drying tank (described later) housed inside the main casing 200. The user can take out the laundry (clothing or the like) inside and outside the main casing 200 through the input port 215. The laundry dryer 100 has a hinge structure 330 that allows the door body 300 to be rotatably coupled to the main housing 200. By the hinge structure 330', the door body 300 can be rotated between a closed position for closing the input port 215 and an open position for opening the input port 215. The door body 300 that is rotated in the closed position is housed in a recessed area surrounded by the concave surface 214. Further, the door body 300 shown in Fig. 1 exists in an open position. Fig. 2 is a schematic cross-sectional view of the laundry dryer 201219619 (10) having the door body 300 present in the closed position. The configuration, shape and configuration of the components of the main casing 2 shown in Fig. 2 should not be construed as limiting. The shape and structure of the components of the main M coffee can also be adapted to the design or function of the drying treatment device. Please refer to Fig. 2 for further explanation of the structure of the laundry. As shown in Fig. 2, the main casing is constructed with a processing device for drying. In the present embodiment, the processing apparatus 4 performs a laundry treatment, such as a washing treatment or a dehydration treatment, in addition to the drying treatment, such as washing and drying of the laundry c. Instead, if the dry cleaning device is not used as a drying treatment device, the processing device may be only subjected to a drying process. The processing device 400 has the above-described laundry drying tank 41. The laundry drying tank 41 includes: a bottomed cylindrical water tank 420 which is rotatably supported by one of the inner ends of the main casing 2, and is rotatably supported in the water tank 42〇 and has a bottom end A cylindrical rotating drum 440. The processing device 4 has a suspension device 490 that elastically supports the laundry drying tank 410. The suspending means 490 connected to the bottom wall 260 of the main body 2 can appropriately absorb the vibration generated between the various processes such as the above-described drying treatment, laundry treatment, washing treatment or dehydration treatment. The processing device 400 further includes a motor 430 that rotates the rotary drum 440. The body portion of the motor 430 is attached to the outside of the bottom wall 431 of the water tank 420. Further, the rotating shaft of the motor 430 passes through the bottom wall 431 of the water tank 420 and is connected to the bottom wall 432 of the rotating drum 440. The motor 430 rotates the rotary drum 440 between various processes such as a drying process, a washing process, a washing process, or a spin process. 201219619 The front wall 433 opposite to the bottom wall 431 of the water tank 420 forms an opening 434 which is substantially concentric with the slightly circular door body 300 present in the closed position. Similarly, the front wall 435, which is opposite to the bottom wall 432 of the rotary drum 440, forms an opening 436 which is substantially concentric with the opening 434 formed in the wall 433 of the water tank 420. The user can move the door body 300 to the open position and put the laundry C into the rotating drum 44 through the inlet 215. The processing apparatus 400 further has a bellows 437 disposed between the central wall 212 of the main casing 200 and the front wall 433 of the water tank 420. The water tank 420 is elastically coupled to the main casing 200 via a bellows 437. As shown in Fig. 1, the door body 300 includes a transparent window portion 310 having a substantially trapezoidal rounded shape at one end and a slightly plate-shaped support member 320 for supporting the window portion 31. As shown in Fig. 2, when the door body 300 is placed at the closed position, the window portion 31 is inserted into the insertion port 215 formed in the main casing 200. When the door body 3 is present in the closed position, the user can observe the laundry C in the laundry drying tank 410 through the transparent window portion 31. As shown in Fig. 2, the water tank 420 forms a discharge port 423 for discharging the washing liquid, and a person 424 for washing the secret stream. The washing liquid used for washing is recycled between the discharge port 423 and the inflow port 424. The laundry dryer 1 has a line 425 for defining a circulation path of the silk liquid between the discharge port 423 and the flow port 424. The line 425 includes an upstream line that is connected to the end of the downstream line ❿ upstream line 426 to the discharge port 423. The upstream line is like his end connected to the bottom wall 26 of the main casing 200. One end of the downstream line 427 is connected to the upper time path 426. The downstream f-path is like the other end connected to the inflow port 424. 201219619 'The garment drying machine 100 has: produced between the discharge port 423 and the inflow port 424 The circulation pump 4 8 8 of the washing liquid and the discharge valve 429 for controlling the discharge of the washing liquid to the outside of the main casing 2. The circulation pump 428 and the discharge valve 429 are both installed in the upstream line 426. The pump 428 is disposed further upstream than the connection between the upstream line 426 and the lower 斿g path 427. The discharge valve 429 is disposed downstream of the comparison pump 428. The laundry dryer 100 is required to perform the laundry drying tank 410. During the treatment of the stored water in the bowl (for example, a laundry treatment or a washing treatment), the discharge valve 429 is closed. During this period, the circulation fruit 428 can be actuated as needed to generate a circulation of the washing liquid between the discharge port 423 and the inflow of 0 424. On the other hand, when the laundry is not required to be treated by the Wei (3) towel (for example, dehydration or dry cooking), the discharge _9 will be opened. »Hai. The washing liquid in the laundry drying tank 410 is discharged from the bottom wall 260 to the outside of the main casing 200 through the upstream line 426. The washing and drying machine 1GG has a fine circulation mechanism, and the circulation mechanism 6 is used to circulate the air which is folded in the clothes (10) of the % rotating drum 44Q. The water tank 420 includes a cylindrical peripheral wall 438 extending between the bottom wall 431 and the front wall 433. . The peripheral wall 438 of the water tank 420 forms an exhaust port 60 for discharging dry air from the laundry drying tank 41. Further, the bottom wall 431 of the water tank 420 forms an air inlet (4) for sucking the drying line into the washing and drying tank. . The circulation mechanism 600 circulates dry air between the exhaust port 6〇丨 and the intake port (4). The bottom wall 432 of the tumbling drum 440 forms a bottom hole state, and the bottom hole (4) is used to facilitate the intake of dry air sucked from the suction port 643 into the rotating drum 44. The rotary drum 440 packs 3 a cylindrical peripheral wall 439 extending between the bottom wall 432 and the front wall. The peripheral wall 439 of the rotating drum 44G is formed with a plurality of peripheral holes.

S 10 201219619 The majority of the peripheral holes 646 serve to promote dry air into the exhaust port 601 formed in the peripheral wall 438 of the trough 42. Drying of the laundry C in the rotary drum 440 is promoted by the drying air ' from the bottom hole 645 toward the peripheral hole 646'. In the present embodiment, the laundry drying tank 410 subjected to the drying treatment can be exemplified as a drying tank. The circulation mechanism 6 that circulates the dry air in the main casing 200 has a second conduit 61 that extends from the exhaust port 601 to the top wall 250 of the main casing 200, and is filtered by the first conduit 610. The device 700 and the heat pump 630 adjacent to the filter device 7〇〇. As shown in Fig. 1, the top wall 250 includes a substantially rectangular main wall 252 which forms a majority of the upper surface of the main casing 2, and a slightly rectangular cover mechanism 800 which surrounds the main wall 252. As shown in Fig. 2, the filter unit 7 is adjacent to the lid mechanism 800. During the drying process in the rotary drum 440, lint (so-called cotton dust component) is separated from the laundry c. The lint is introduced into the filtering device 700 through the first line 610 as the dry air flows. The filter unit 7 is formed to remove lint from the dry air. In the present embodiment, the filtration device 7 is exemplified as a removal device. As will be described later, the transition device 700 is coupled to a cover mechanism 80G that is detachably attachable to the main wall 252. When the cover mechanism lion is removed from the main wall 252, the hearing device 7 is removed from the cover housing 800 to the outside of the main housing 200. The user can then remove the lint stored in the filter unit 700. The heat pump 630 can also be a heat exchanger that is generally used. The heat pump 63 is used to cool the leaked air, and the moisture dehumidification 635 of the dry air towel is recorded, and the heating portion 633 for heating the dry air passing through the dehumidifying portion 635. The removal by the dehumidifying unit 635 and the heating by the heating unit 633 are performed by the cold decompression and decompression in the dehumidifying unit 635 and the heating unit 633, and the heat pump 63 is exemplified as dehumidification. The twisting and dehumidifying heating device is also used as a heat pump 630, and is equipped with a dehumidifying portion 635 hot portion 633. Alternatively, the dehumidification heating device may include a heating device for dispensing the dehumidification I dehumidification device and the dehumidification device. Ad: The mechanism 600 has: a dehumidifier by heating the spring 630 and a blower 621 for sending the heated dry air 8 to the air inlet (4), and guiding the dry air that is moved by the blower 621 to the air inlet 643 The second line 62 is 〇. The blower 621 makes itl pressure in the field of the & fan 621 (4), and creates a positive pressure on the side of the radiator 621. As a result, a circulation of dry air at the exhaust port 601 and the intake port 1 is produced. In the present embodiment, the blower 621 is exemplified as a gas supply device. The mechanism 600 has a branch line 650 that is branched by the second line 620, and a switching valve 651 that is disposed at a connection portion between the second line 620 and the branch line 650. The branch line 65A has a front end portion that communicates with the opening portion 436 formed in front of the rotating drum 44'. The switching valve 651 is rotated between a second position for shielding the flow of the dry air from the blower 621 to the air port 643 and a second position along the flow of the dry air from the blower 621 to the intake port 643. When the switching valve 651 is present in the first position, most of the dry air is blown toward the clothes by the opening portion 436 of the rotating drum 44 through the branch line 650. When the t-knife valve 651 is present in the second position, the drying is performed. Most of the air will be directed to the suction port 643. The switching valve 651 is set to, for example, the second position during the pre-twisting period from the start of the drying process. Then, before the end of the drying process, the switching valve η 1 is set to the first position. Moreover, the drying action can match the dryness of the laundry c

S 12 201219619 Change. (External air introduction means) The external air introduction means for cooling the heat pump 63A will be described with reference to Figs. 1 and 2 . In the present embodiment, in order to maintain the heat-replacement efficiency of the heat pump 63, the outside air outside the main casing 200 is introduced into the main casing 200 as cooling air. As shown in Fig. 2, the external air introduction mechanism 15 includes the above-described transition device 700 and a cover mechanism 8 disposed above the filter device 7 ( (as described above) the cover mechanism 800 is attached to the main housing 2 The top wall of the crucible is 25 〇. Fig. 3 is an enlarged perspective view of the top wall 250. The external air introduction mechanism 15A is further explained using Figs. 1 to 3. The top wall 250 is formed as an exit 251 having a slightly rectangular opening. The outlet 251 is formed for taking out the filter device 7 inside and outside the main casing 200. As will be described later, the cover mechanism 800 is connected to the filter device 7. Therefore, the user removes the cover mechanism 800 from the outlet 251, Therefore, the filter device 70 can be taken out from the outside of the main casing 200 via the take-out port 251. Further, the user can attach the cover mechanism 800 to the take-out port 251 by connecting the cover mechanism 8 to the filter device 700. The filter device 700 is disposed at a suitable place in the main housing 200 for accommodating the garment c. As shown in Fig. 1, the cover mechanism 800 includes a cover 810 having a complementary outer surface 813 with the outlet 251, and is rotatable. Mounted to the lever plate 820 of the cover plate 810. The cover plate 810 can be properly closed The outlet 251 is closed. Therefore, mechanical noise or flow occurring from various components housed in the main casing 200 (for example, the laundry drying tank 41, the filtering device 700, the heat pump 630, or the blower 621) can be appropriately suppressed. As will be described later, the 'cover_bar plate breakage is formed to introduce the attraction σ into the fineness of the main casing, and the 700-shaped eve air introduction port is formed, and the external air introduction port is formed. In order to communicate with the attraction air through the outside air of the transition device, the air is sucked into the body of the main body. The air is used for cooling the heat pump (4). In the present embodiment, the capping machine is illustrated as a cover member. χ, the outer surface 813 of the cover plate 81 is exemplified as the first outer surface. Fig. 4 is a front view of the external air introduction mechanism 15A. Fig. 5 is a view of the outer air of the Α. A cross-sectional view of the introduction mechanism 15A. Fig. 6 is a plan view of the cover plate 810. The suction port formed between the cover plate 810 and the lever plate 820 will be described using the first @] and the fourth to fourth caps. And shown in FIG. 5, the cover 81 of the cover mechanism 800 is mounted on the filter device 700. As shown in Fig. 6, the cover plate 81 includes a mounting edge 812 which forms a mounting opening 811 complementary to the lever plate 820. In the present embodiment, the mounting edge 812 is a closed ring shape which is slightly rectangular. As shown in Fig. 1, the lever plate 820 is installed to close the mounting opening 811. As shown in Fig. 5, the lever plate 820 includes: a base end edge 821 on the back side of the washer dryer 100, on the opposite side of the base end edge 821 ( That is, the front side edge 822 and the outer surface 823 extend between the base end edge 821 and the front end edge 822. The base end edge 821 is along the swivel axis of the stem plate 820. In the present embodiment, the outer surface 823 of the rod plate 820 is exemplified as the second outer surface. The lever plate 820 is rotated up and down about a rotation axis near the base end edge 821. Therefore, the user can press the lever plate 820 to grasp the cover 810. The leading edge 822 is located below the mounting edge 812 (i.e., inside the main housing 200). 201219619 The outer surface 823 of the rod plate 820 includes a base surface 824 extending from the base end edge 821 along the outer surface 813 of the cover plate 81 and extending in the front direction, and an inclined surface 825 bent obliquely from the front end edge 822 toward the base surface 824. . A space formed between the inclined surface 825 and the mounting edge 812 is used as a suction port 830 for attracting outside air. The suction port 830 is open in the opposite direction to the front wall 210 (i.e., toward the back wall 220). The suction port 830 which is opened obliquely upward is mainly used to regulate the direction in which the sound generated in the main casing 200 in the back surface direction is transmitted. Therefore, the sound of the user working in the vicinity of the front wall 210 can be appropriately suppressed. As shown in Figures 5 and 6, the mounting edge 812 includes a raised edge 814 that bulges upward. The raised edge 814 is located above the front edge 822 of the stem plate 820. The ridge 814 can appropriately suppress, for example, the water dripping from the laundry placed on the top wall 25 of the user to the suction port 830. Figure 7 is a bottom plan view of the capping mechanism 800. The rotation of the lever plate 820 will be described using Figs. 5 and 7. The lever plate 820 has a first shaft piece 826 and a second shaft piece 827 disposed in the vicinity of the base end edge 821. The first shaft piece 826 and the second shaft piece 827 protrude downward from the bottom surface of the rod plate 820. The first shaft piece 826 includes a first column 828 that is slightly columnar. The second shaft piece 827 includes a second shaft 829 which is shorter than the first shaft 828 and has a substantially columnar shape. The first shaft 828 and the second shaft 829 extend along the base end edge 821. The cover plate 810 has a mounting wall 815 that extends along a slightly rectangular loop. The mounting wall 815 protrudes downward from the bottom surface of the cover 810. The mounting wall 815 includes a first bearing piece 816 that rotatably supports the first shaft 828 and a second bearing piece 817 that rotatably supports the second shaft 829. The first bearing piece 816 and the second bearing piece 817 protrude from the inner surface of the mounting wall 815 adjacent to the base end edge 821 of the rod plate 820 toward the front direction of 15 201219619. Further, the lever plate 82G is rotatably attached to the cover plate 81. Along with the base end edge 821 of the stem plate, the first and the second of the (4) are used to define the rotation of the stem plate 820. The cover mechanism 800 has a winding number! The auger of the shaft 828 is 84 inches. The spiral spring 84 knows. The crucible is connected to the bottom surface of the cover 81. The end of the spiral magazine _ is connected to the bottom surface of the rod 82. Moreover, the coil spring is given the potential energy of the lever plate (4), and the front end edge 822 of the lever plate 820 is pushed upward. In the present embodiment, the coil spring 840 is exemplified as a potential energy element. The lever plate 820 includes a slightly U-shaped positioning piece 891. The positioning piece 891 forms a front end edge 822 and a side edge of the rod plate 82. The partial land piece 891 is partially overlapped with the cover plate 81. Moreover, the positioning tab 891 suitably limits the potential of the coil spring 84 to cause rotation above the stem 820. Figure 8 is a plan view of the filter device 7GG. The connection of the cover mechanism 8A to the transition device 700 will be described using Fig. 2, Fig. 4, Fig. 5, Fig. 7, and Fig. 8'. As shown in Figs. 4, 5, and 8 , the transition device 7 has a child's body. The casing 710 is formed with an introduction port 712 for introducing dry air discharged from the exhaust port and an external air introduction port 725 for introducing external air outside the main body 2 (9). The discharge port 713 is formed in the casing 71'' and the introduction port opening. The σ713 position is supported by the sub-support portions 714. The filter 720 is attached along the support portion μ (refer to Fig. 5). The dry air guided to the filtering device 700 by the first port_ through the first port_ is introduced into the casing 71 through the inlet port 712. Thereafter, the dry air is dried by the discharge claws formed by the opposite side of the introduction u712.

S 16 201219619 When the outlet 713 is passed, the filter 720 is filtered. As a result, the screen 720 can properly capture the lint contained in the dry air. The heating fruit 630 is disposed after the discharge port 713. Therefore, the dry air which has been removed by the lint is discharged from the discharge port 713 to the heat pump 630. In the present embodiment, the screen 72 is exemplified as a filter element. In the following description, the flow direction of the dry air from the introduction port 712 to the discharge port 713 (i.e., the direction from the front wall 21 to the back wall 220) is referred to as a first direction. The lug body 710 includes a first housing wall 715 having an introduction port 7丨2 and an external air introduction port 725, and a second housing wall 716 having a discharge port 713 formed therein. The first housing wall 715 includes a connecting wall 717 for connection to the cover mechanism 8 and having a substantially u-shaped cross section. As shown in Fig. 5, a space r 1 for the rotation of the lever plate 820 is formed between the connecting wall 717 which is bent downward and the flat plate cover 810. As shown in Fig. 5, the connecting wall 717 includes a protrusion 718 that bulges upward. The ridge 718 is formed along the edge of the back side of the connecting wall 717. A mounting wall 815 disposed to cover the cover 810 of the connecting wall 717 is adjacent to the ridge 718. Mounting wall 815 and rib 718 are joined using a suitable fixture of screws or bolts. In the present embodiment, the mounting wall 815 is a coupling portion. Fig. 9 is a cross-sectional view of the filter unit 7'' along the line B-B shown in Fig. 8. The introduction of the outside air into the casing 710 will be described using Figs. 1, 5, 8 and 9. As will be described with reference to Fig. 5, a space is formed between the substantially flat plate-shaped cover 81 and the connecting wall 717 which is bent downward. As shown in Figs. 8 and 9, the first casing wall 715 has a partition wall 719 extending in the first direction. The partition wall 719 is partially divided into a space R for the rod plate 820 between the cover plate 810 and the connecting wall 717, and a space R2 for the outside air to flow into. The space R2 communicates with the suction port 83A via a gap between the upper edge of the partition wall 719 and the cover plate 810. The connecting wall 7A for defining the space R2 forms an external air introduction port 725 having a substantially rectangular opening. The space between the suction port 830 and the outside air introduction port 725 (i.e., the space between the cover plate and the connecting wall 717) is partially partitioned by the partition wall 719 which protrudes upward from the upper surface of the connecting wall 717. The partition wall 719 appropriately suppresses the inflow of the liquid flowing from the suction port 830 to the connecting wall 717 to the outside air introducing port 725. As shown in Figs. 8 and 9, the filter unit 7A includes a switch mechanism 730 for opening and closing the external jade gas introduction port 725. Switching mechanism 730 includes a valve plate 735. The valve piece 73 5 includes a base portion 731 that is fitted into the opening portion formed adjacent to the external air introduction port, and is displaced between a closed position for closing the external air introduction port 725 and an open position for opening the external air introduction port 725. The valve plug portion 732 and the thinner portion 733 formed between the base portion 731 and the valve plug portion 732. In the present embodiment, the valve piece 735 is exemplified as a valve element. Further, in the Fig. 9, the valve plug portion 732 existing in the open position is drawn by a broken line. The base portion 731 formed in a substantially rectangular parallelepiped shape is fixedly attached to the connecting wall 717. The plug portion 732 formed in a substantially rectangular parallelepiped shape partially protrudes toward the internal space of the casing 710 through the external air introduction port 725. The valve plug portion 732 is rotated about the rudder thin portion 733 between the open position and the closed position. While the valve plug portion 732 is present in the open position, the outside air flows into the casing 710 through the external air introduction port 725 that communicates with the outside of the main casing 200 via the suction port 830. In the present embodiment, the thinner portion 733 is exemplified as a hinge portion. Fig. 10 is a cross-sectional view of the filter device 700 taken along line C-C shown in Fig. 9 in the 201219619. The switching mechanism 730 will be described using FIG. 5, FIG. 9, and FIG. As shown in Fig. 10, the housing 710 includes an inner wall surface 726 which forms an inner space having a substantially rounded shape. The inner space formed by the inner wall surface 726 extends in the second direction which is substantially orthogonal to the first direction. The casing 710 has an annular partitioning plate 729 that partitions the inner space extending in the second direction into the first chamber 727 and the second chamber 728. The first chamber 727 is in communication with the inlet port 712. Therefore, the dry air flows in the first chamber 727. As shown in Fig. 9, the second chamber 728 is in communication with the outside air introduction port 725. Therefore, the valve plug portion 732 exists in the open position, and the outside air flows in the second chamber 728. The filter device 700 includes a rotating shaft 740 that rotates within the housing 710. The first housing wall 715 includes a first side wall 736 and a second side wall 737 extending between the introduction port 712 and the discharge port 713. A gear 738 is mounted on the outer surface of the first side wall 736. The gear wheel 738 has a gear shaft 739 that is inserted through a through hole formed in the first side wall 736. The gear shaft 739 is inserted into a recess formed at one end of the rotating shaft 740. A suitable fixture of a screw or bolt is screwed along the long axis of the gear shaft 739 and the rotating shaft 740. Further, the gear 738 and the rotating shaft 740 are appropriately connected. Gear 738 is coupled to a motor or other suitable drive source. The rotation shaft 74 is appropriately rotated in the casing 710 by the transmission of the driving force to the tooth transmission 738. The second side wall 737 includes a boss 741 that is inserted into a recess formed at the other end of the rotating shaft 740. The sleeve 741 supports a rotatable rotary shaft 740. The switch mechanism 730 includes a & wheel 745 that protrudes from the circumferential surface of the rotating shaft 740 in the second chamber 728. The cam piece 745 that rotates with the rotating shaft 740 is formed in contact with the valve plug portion 732 existing in the closed position. The plug portion 732 that is in contact with the cam piece 745 is pushed up. Moreover, the valve plug portion 732 is rotated upward about the thinner portion 733 19 201219619 and is displaced to the open position. Then, the valve plug portion 732 which is released from contact with the cam piece 745 is rotated downward about the thin portion 733 due to its own weight, and is displaced toward the closed position. Further, the switch mechanism 73A can be interlocked with the rotation of the rotary shaft 740 to close the external air introduction port 725. The partition plate 729 includes an outer edge 746 that is connected to the inner wall surface 726 of the casing 710, and an opening portion that forms an inner edge 74 of the inner edge 74 of the opening through which the rotary shaft 74 is inserted. An annular gap portion for connecting the first chamber 727 and the second chamber 728 is formed between the inner edge 747 and the rotating shaft 74A. The flow of the dry air flowing from the introduction port 712 to the discharge port 713 causes the second chamber 728 to be a negative pressure. As a result, when the valve plug portion 732 is pushed up by the cam piece 745, the outside air flows into the second chamber 728 from the suction port 830. As shown in Fig. 10, the discharge port 7A includes a third discharge port 748 for discharging the dry air flowing into the first chamber 727 from the introduction port 727 to the heat pump 63, and an external flow into the second chamber 728. The air is discharged to the second discharge port 749 of the heat pump 63. Further, the filter screen includes a first filter portion 751 (see Fig. 5) for covering the first discharge port 748 and a second filter portion 752 (see Fig. 9) for covering the second discharge port 749. The second filter unit 751 filters the dry air introduced into the inlet 712" and removes the cotton field contained in the dry air. After the lint is removed, the dry (four) gas will be directly supplied (i.e., not in the air blower 621) by the heat pump 63 0. The second filter portion 75 2 is for filtering the outside air flowing from the outside air inlet 725 and removing foreign matter (e.g., 'Angstrom') contained in the outside air. After the foreign matter is removed, the outside air is directly supplied (i.e., not sandwiched between the blowers 621) by the heat pump 630. (adjustment mechanism)

S 20 201219619 An adjustment mechanism for adjusting the flow direction of the dry air from the inlet 712 to the discharge port 713 will be described using Figs. 5 and 10. The filter device 700 has an adjustment mechanism for adjusting the flow direction of the dry air from the introduction port 712 to the discharge port 713. The adjustment mechanism 5 includes the above-described rotation shaft 740 and an adjustment piece 765 extending from the rotation shaft 740. The tab 765 rotates as the rotating shaft 740 rotates within the housing 71. The adjustment piece 765 is a slightly rectangular plate. In the present embodiment, the adjustment piece 765 is exemplified as the adjustment plate " The housing 710 includes the upper side stopper pin 773 and the lower side stopper pin 774 protruding from the inner wall surface 726 toward the discharge port 713. The upper stopper pin 773 is formed on the upper side of the introduction port 712. The lower side stopper pin 774 is formed on the lower side of the introduction port 712. The adjustment piece 765 includes a front end portion 766 between the upper side stopper pin 773 and the lower side stopper pin 774. When the tab 765 is moved above the movement, the front end portion 766 abuts against the upper side stopper pin 773. As a result, the movement of the tab 765 upward is restricted. When the tab 765 is moved downward, the front end portion 766 abuts against the lower stopper pin 774. As a result, the movement of the tab 765 downward is restricted. In the present embodiment, the upper stopper pin 773 and/or the lower stopper pin 774 are exemplified as the restriction member. Figs. 11A to 12B schematically show the operation of the adjustment mechanism 5〇〇. 11A and 12A are schematic cross-sectional views of the filter device 7'. The first filter unit 751 is shown in FIGS. 11B and 12B. The operation of the adjustment mechanism 500 will be described using Figs. 1 to 12B. The tab 765 shown in Fig. 11 is protruded downward by the rotating shaft 74, and the front end portion 766 abuts against the lower stopper pin 774. The tab 765 21 201219619 shown in Fig. 12A maintains a more horizontal posture than the tab 765 shown in Fig. 11A. The red shaft 740 extends in the second direction. The second filter unit 751 extends in the second direction similarly to the rotary shaft 740. In Fig. 11B and Fig. 12β, it is shown that the f first filter unit 751 is divided into upper and lower imaginary lines FL. The imaginary line FL defines an upper side field 753 extending in the extending direction of the rotating shaft 740, and a lower side field 754 extending along the upper side field 753. In the present embodiment, the upper field 753 is exemplified as the first field. In addition, the lower field is shown as the second field. As shown in Figs. 11A and 11B, the entire three-week 765 projecting downward from the rotating shaft 740 interferes with the dry air to be flowed under the relatively rotating shaft 740. The result is that 'most of the dry air is pushed up. As a result, the flow rate of the dry air passing through the lower side field 754 is decreased, and on the other hand, the flow rate of the dry air passing through the upper side field 753 is increased. The tab 765 shown in Figs. 12A and 12B allows the smooth flow of dry air as compared with the tab 765 shown in Figs. 11A and 118. As a result, when the tab 765 is moved from the position shown in FIGS. 11A and 11B to the positions shown in FIGS. 12A and 12B, the flow rate of the dry air passing through the lower side field 754 is increased, and the other is In terms of the flow of dry air through the upper field 753, the flow rate is reduced. Thus, the tab 765 can vary the flow of dry air through the upper field 753 and the flow of dry air through the lower field 754 as the axis of rotation 740 rotates. Figure 13 is a block diagram of the components responsible for controlling the filtering device 700. The control of the filter unit 7 is explained using Fig. 2, Fig. 11A to Fig. 13.

S 22 201219619 The laundry dryer 100 is provided with a control element 51 for controlling the adjustment mechanism 500. The adjustment mechanism 500 includes a stepping motor 52A for rotating the rotary shaft 740. The control element 510 adjusts the flow of dry air in the filter unit 700 through the control of the stepper motor 520 engaged with the gear 738 described in connection with Fig. 10. In the present embodiment, the stepping motor 520 is exemplified as a drive source. Alternatively, the drive source can use other drive components that can rotate the rotary shaft 740. The blower 621 includes a blade 622 and a motor 623 for rotating the blade 622. Motor 623 rotates blade 622 to maintain the amount of dry air in the laundry dryer 100 at a predetermined level. The washing and drying machine 1 is stocked to supply electric power to the power supply source 530 of the motor 623. The control element 510 controls the stepping motor 52 based on the power supplied from the power supply source 530 to the motor 623. As a result, the adjustment of the flow of the dry air in the filtering device 700 according to the description of Figs. 18 to 12B is appropriately performed. In the present embodiment, the control element 510 controls the stepper motor 520 to read or receive the current 流动 flowing from the power supply source 530 to the motor 623 and to reduce the current 値 (i.e., reduce the power). For example, in the upper field 753 of the second filter unit 751, when more cotton velvets are attached to the lower side field 754, more dry air passes through the upper side field 753 than the position of the setting adjustment piece 765, and the adjustment piece is provided. The position of 765 is such that more dry air passes through the underside field 754 'the lower amount of current can be used to circulate the same amount of dry air. Therefore, in this case, the control member 51 adjusts the position of the tab 765 to allow more dry air to pass through the lower side field 754. The heating system 630 includes a temperature sensor 631 for detecting the temperature of the refrigerant of 23 201219619 exchanged with dry air, and a compressor 632 for compressing the refrigerant. The control element 510 controls the stepping motor 520 based on the temperature of the refrigerant detected by the temperature sensor 631 and the number of rotations of the compressor 632, and moves the valve plug portion 732 to the open position or the closed position. The control element 510 includes an acquisition unit 511 for reading or receiving a current 値 flowing from the power supply source 530 to the motor 623. The acquisition unit 511 further receives an output signal from the temperature sensor 631. In addition to this, the acquisition unit 511 reads or receives the number of rotations of the compressor 632. In the present embodiment, the current flowing from the power supply source 530 to the motor 623 is exemplified as electric power information. Further, the output signal from the temperature sensor 631 and/or the number of revolutions of the compressor 632 are exemplified as temperature information. The control element 510 includes an output unit 512 that outputs an operation signal for causing the stepping motor 52 to operate. The action signal includes a second action signal, and the second action signal causes the rotary shaft 740 to rotate to include a predetermined range of rotation defined by the upper stop pin 773 and/or the lower stop pin 774. The rotation axis 74A monitors the current 供给 supplied to the blower 621 during the rotation including the predetermined rotation range in accordance with the second rotation operation signal. The level of the semi-position is set to, for example, the position at which the tab 765 abuts against the upper stopper pin 773, and/or the position at which the tab %5 abuts against the lower stopper pin 774. The stepping motor 52A rotates the rotating shaft 74G in a predetermined rotation range based on the i-th operation signal. Obtain the current 期间 during the rotation of the rotating shaft, and find out the self-rotation (4) buckled two turns and then the (4) Μ minimum power. The information of the period in which the present embodiment (1) is obtained by the acquisition of the department is exemplified as the positional information on the position of the adjustment core 765 24 201219619. The control element 51G includes the period for which the acquisition unit η is found: The material has been concealed 513. The operation signal includes the second operation signal. The second operation 5 causes the adjustment piece 765 to move to the position where the force of the rotation axis 740 is the most reduced during the rotation of the rotation axis 740 according to the first operation signal. Based on the data of the period, the position of the tab 765 when the power drop is low during the rotation of the rotary shaft 7 is found. Output. Ρ 512 in accordance with the first! When the rotation of the rotation axis 74A of the operation signal is completed, the second operation signal is output to the stepping motor 520. As a result, the tab 765 is moved to the position where the power supplied to the blower is cut to the lowest. Fig. 14 is a schematic cross-sectional view showing the external air guiding mechanism 15G. The control of the control unit will be described using the U and FIG. In the present embodiment, the rotation range of the 'rotational axis 740' includes the upper side rotation range UR and the lower side rotation range gjLR. The upper rotation range gripping system is defined as, for example, the adjustment &ample 765 abutting the upper side stopper pin and moving downward by about 6 inches. The scope. The lower rotation range LR is defined such that, for example, the adjustment piece 765 abuts against the lower stopper pin 774 and then moves upward by about 卯. The scope. While the rotating shaft 74 is rotated in the upper side rotation range UR, the valve plug portion 732 is held in the open position. While the rotary shaft 740 is rotating within the lower rotation range 1^, the spool portion 2 is held in the closed position. In the present embodiment, the lower side rotation range 1^11 is exemplified as the first circumference. Further, the upper side rotation range UR is exemplified as the second range. The first operation signal includes a second mode signal that rotates the rotary shaft 740 in the lower rotation range LR, and a second mode signal that rotates the rotary shaft 74 in the upper rotation range UR. The acquisition unit 511 determines whether or not the cooling of the heat pump 630 is required by the 2012 201219 19 based on the output signal from the temperature sensor 631 and/or the number of rotations of the compressor 632. When the cooling of the heat pump 63 is not necessary, the acquisition unit 511 selects the first mode in which the rotary shaft 740 rotates in the lower rotation range LR. When the cooling of the heat pump 630 is necessary, the second mode in which the rotation shaft 74 is rotated in the upper rotation range UR is selected. As a result, the valve plug portion 732 is moved to the open position, and the outside air is supplied to the heat pump 63. The output unit 512 selectively outputs the first mode k and the second mode signal based on the determination by the acquisition unit 511. The result is that the rotation axis is said to encompass the upper side rotation vane 1SUR or the lower reversal range LR_. During this period, the acquisition unit 511 monitors the current 期间 during the rotation of the rotary shaft 740, and finds that the rotation of the rotary shaft 74 开始 starts to observe the minimum current 値 (4). The memory unit $丨3 memory is observed as the period of the minimum current 后 after the rotation of the rotary shaft 740 is started. Then, the output unit 512 outputs the second operation (fourth). As a result, the tab 765 moves to the position where the power supplied to the blower 621 is the lowest. Figure 15 is a cross-sectional view of the filter device 700 along the long axis of the axis of rotation 7 4 Q. The rotating shaft 740 will be described using FIG. As described above, the inner edge w of the partition plate 729 forms an opening that allows the i-th chamber w to communicate with the second chamber 728. The rotating shaft 74q includes a one-portion (four)-shaped projecting portion 775 which is defined by the inner edge of the river. The ring shape is formed to be slightly larger than the opening portion. The P775 package 3 / α is on the periphery π of the inner edge 747 of the partition plate 729. The lint flowing through the drying in the second direction is suppressed from entering the second chamber 728 by the first chamber 727. In addition, 'the lungs between the 729 and the ring record _75." The communication with the (8) is maintained by the gap between (4) and the annular projection 775.

B 26 201219619 Fig. 16A and Fig. 16B are schematic cross-sectional views showing the housing 71 of the filter unit 7〇〇. Fig. 16A shows the housing 71〇 when in use. The MB map shows the housing 710 at the time of decomposition. The housing 710 will be described using Figs. 16A and 16B. The second housing wall 716 is rotatably attached to the second housing wall 715. A connecting portion 780 between the first housing wall 715 and the second housing wall 716 is provided below the connecting wall 717 of the i-th housing wall 715. The second housing wall 716 includes, for example, a connecting plate 78 disposed directly below the connecting wall 717 and a pin 782 protruding from the connecting plate 781. The connecting wall 717 is formed to keep the pin 782 rotated. The user can appropriately remove the lint accumulated in the casing 710 by rotating the second casing wall 716. (The following is a repeat request range area.) In the above embodiment, a drying processing apparatus having the following configuration is mainly included. A dry processing apparatus having the following configuration can achieve power saving. The drying processing apparatus according to one aspect of the embodiment includes a drying tank having an air inlet for sucking dry air for drying clothes and an exhaust port for discharging the dry air, and a removing device is provided by the row The dry air discharged from the air outlet removes cotton dust; the dehumidification heating device dehumidifies and heats the dry air from which the cotton dust is removed by the removing device; and the air supply device is configured to dehumidify and heat the dehumidifying heating device Dry air is sent to the air intake port at a predetermined flow rate; and the power supply source 'supplies electric power for operating the air supply device, and the removing device includes a casing body formed with a discharge for introducing the exhaust port a drying air introduction port and a discharge port for discharging the drying air to the dehumidification heating device; and a filter element attached to the discharge port to remove the cotton dust by the drying air of the above-mentioned 27 201219619; and an adjustment mechanism for adjusting the aforementioned a flow direction of the aforementioned drying air passing through the inlet to the filter element; and a control element, The adjusting mechanism includes: a rotating shaft that rotates in the casing, an adjusting plate that extends from the rotating shaft, and a driving source that rotates the rotating shaft; and the filter element includes: toward the rotating shaft The first field extending in the extending direction and the second field extending along the first field, the control element controls the driving source based on the electric power, and the flow rate of the dry air passing through the first field and the second The flow rate of the aforementioned dry air in the field. According to the above configuration, the dry air flows into the drying tank through the intake port. Then, it is discharged through the drying port through the exhaust port. As a result, the laundry in the drying tank is dried. The removing device removes the dry air discharged from the drying tank to remove the cotton chips. After the cotton swab removal treatment, the dehumidification heating device dehumidifies and heats the dry air. The power supply source supplies electric power to the air supply means which supplies the dehumidified and heated dry air to the suction port of the drying tank at a predetermined flow rate. As a result, dry air is supplied to the inflow port and is again used to dry the clothes in the drying tank. The casing of the removing device is formed with an introduction port for introducing dry air discharged from the exhaust port and a discharge port for discharging dry air to the dehumidifying heater. The filter element mounted to the discharge port removes cotton dust from the dry air. The adjustment mechanism for adjusting the flow direction of the dry air from the inlet to the filter element includes a rotating shaft that rotates in the casing, and an adjusting plate that extends from the rotating shaft. The filter element includes a first field extending in a direction in which the rotation axis extends, and a second field extending along the first field. The control element controls the driving source according to the electric power to make the flow rate of the dry air passing through the first field and

S 28 201219619 The flow rate of dry air passing through the second field. The adjustment plate can be adjusted. The flow of dry air is hardly affected by the lint in the filter unit. = It must be supplied by the machine. The dry control unit can control the above-mentioned drive source to reduce the power. According to the above configuration, (4) the component control source is used to reduce the aforementioned electric power. Moreover, the power saving of the drying treatment device is achieved. In the above configuration, the casing preferably includes a restriction section that contacts the adjustment plate and the range of the rotation axis. According to the above configuration, the _ element contact adjustment plate 1 limits the rotation range of the rotation axis. The adjustment plate is adjusted in such a manner that the rotation of the restriction element is adjusted so that the flow of the dry air is hardly affected by the cotton dust in the filter unit, and unnecessary supply of power to the air supply device can be prevented. Moreover, the power saving of the drying treatment device can be achieved. . In the above configuration, the control element preferably includes an output unit that outputs an operation signal for operating the drive source, an acquisition unit that acquires power clearing of the power, and a memory that reduces power in the rotation range. The position information storage unit of the position of the adjustment plate, the operation 3 includes: operating the front rotation _ rotation including the rotation range; and rotating the rotation shaft to move the adjustment plate to the rotation portion The second operation signal at the position when the time is minimized, the output unit transitions/escapes the first operation signal, and the acquisition unit acquires the power information of the rotation axis, and the memory unit moves according to the power information record; The information output unit outputs the chirp signal based on the position information, and the drive source rotates the screw 29 201219619 according to the second operation signal to shift the adjustment plate according to the position information. According to the above configuration, the control element includes an output unit that outputs an operation signal for operating the drive source, an acquisition unit that acquires power information about the power, and a fourth position of the adjustment plate when the power is lowest in the rotation range. The memory department of intelligence. The operation signal includes a first operation signal for rotating the rotation axis and a rotation range, and a second operation signal for rotating the rotation axis to move the adjustment plate to a position where the electric power in the rotation range is the lowest. When the output unit outputs the first operation signal, the acquisition unit acquires the power information during the rotation of the rotation axis, and the δ memory unit stores the position information based on the power information. The output unit rotates the second operation signal according to the position report. The drive source rotates according to the second operation signal to move the adjustment plate to the position based on the position information. Therefore, the adjustment plate is adjusted so that the flow of the dry air is hardly affected by the cotton shoulder in the filter device, and the power necessary for supplying the air supply device can be prevented. Moreover, the power saving of the drying treatment device is achieved. In the above configuration, it is preferable to further include a main casing for accommodating the drying tank, the removing device 'the dehumidifying heating device and the air supplying device, and the impingement body is formed with an external air introduction port for introducing outside air from the outside of the main casing. The removing device includes a valve element having a valve plug portion and a cam piece that are displaced between a closed position in which the outside air guiding population is closed and a opening position in which the external air introducing port is opened, and is connected to the valve piece. In the rotating shaft, the cam piece is displaced between the closed position and the open position in accordance with the rotation of the rotating shaft. According to the above configuration, the external air introduction port formed in the casing is introduced to receive the drying tank, the removing device, the dehumidifying heating device, and the air supply device.

S 30 201219619 The outside air outside the main basket. The valve plug portion of the valve member is displaced between the closed position of the closed external air introduction port and the open position of the open outer introduction port by being coupled to the rotary piece. When the cold portion of the heating device is required to be dehumidified, the external air introduction port is opened. Therefore, the dehumidifying heating device can be appropriately cooled. Moreover, the dry energy can be suitably __ long period. In the above configuration, it is preferable that the rotation range of the rotation axis includes a first mode in which the p is held in a closed position, and a rear circumference in which the valve plug portion holds the open position, and the acquisition unit is switched to the dehumidification heating device. The temperature information of the dish, the first operation signal includes: a first mode signal that rotates in the first range, and a second mode signal that rotates the second range in the rotation The output unit selectively outputs the first mode signal and the second wedge signal based on the temperature information. According to the above configuration, the rotation range of the rotating shaft includes the first range in which the plug portion is held in the closed position and the second range in which the plug portion is kept in the open position. The acquisition unit acquires temperature information about the temperature of the dehumidification heating device. The i-th operation signal includes an ith mode signal for rotating the rotation axis in the ith rotation range and a second mode signal for rotating the rotation axis in the second rotation range. The output unit selectively outputs the ith mode signal and the second mode signal based on the temperature information. Therefore, the adjustment of the position of the plug portion and the adjustment of the flow direction of the dry air in the removing device can be appropriately performed. In the above configuration, the valve element includes a base portion that is attached to the casing, and a hinge portion that is formed between the base portion and the valve plug portion, and the valve plug portion that contacts the cam piece faces upward toward the hinge portion Rotation, 31 201219619 When the position is changed to the open position, the valve plug portion that has been released from contact with the cam piece is rotated downward about the hinge portion by its own weight, and is displaced to the closed position. According to the above configuration, the valve element preferably includes a base attached to the casing and a hinge portion formed between the base and the plug portion. The plug portion that contacts the cam piece is swung upwardly about the hinge and is displaced to the open position. The valve plug which is released from contact with the cam piece is rotated about the lower side of the hinge by its own weight and is displaced to the closed position. Moreover, the opening and closing of the external air introduction port is achieved by a relatively simple structure. Industrial Applicability The principle of this embodiment is suitable for use in dryers and laundry dryers. I: BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic perspective view of a laundry dryer of an embodiment. Fig. 2 is a schematic cross-sectional view showing the laundry dryer shown in Fig. 1. Figure 3 is an enlarged perspective view of the top wall of the laundry dryer shown in Figure 1. Fig. 4 is a view schematically showing an external air introduction mechanism of the laundry dryer shown in Fig. 1. Fig. 5 is a cross-sectional view of the external air introduction mechanism taken along line A-A shown in Fig. 4. Fig. 6 is a plan view schematically showing the cover mechanism of the external air introducing mechanism shown in Fig. 4. Fig. 7 is a schematic bottom plan view of the cap mechanism shown in Fig. 6. Figure 8 is a filter device of the external air introduction mechanism shown in Figure 4

S 32 201219619 A rough plan view. Fig. 9 is a schematic cross-sectional view of the filtering device taken along the line B-B shown in Fig. 8. Fig. 10 is a schematic cross-sectional view of the filtering device taken along line C - C shown in Fig. 9. Fig. 11A is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. Fig. 11B is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. Fig. 12A is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. Fig. 12B is a view showing the operation of the adjusting mechanism of the filtering device shown in Fig. 5. Fig. 13 is a block diagram showing the outline of the elements for controlling the operation of the adjustment mechanism shown in Figs. 11A to 12B. Fig. 14 is a view showing the range of rotation of the rotating shaft according to the control of the adjusting mechanism shown in Fig. 13. Fig. 15 is a cross-sectional view schematically showing the rotation axis of the filtering device shown in Fig. 9. Fig. 16A is a cross-sectional view schematically showing the switching operation of the casing of the filter device shown in Fig. 9. Fig. 16B is a cross-sectional view schematically showing the switching operation of the casing of the filter device shown in Fig. 9. 33 201219619

[Description of main component symbols] 100... Laundry dryer 423... Discharge port 150... External air introduction mechanism 424... Inflow port 200... Main casing 425... Pipe 210... Front wall 426...upstream line 211...lower wall 427...downstream line 212... center wall 428...circulation pump 213...upper wall 429...discharge valve 214...recess 430. .. motor 215... input port 431... sink bottom wall 220... back wall 432... rotating drum bottom wall '230... left side wall 433... sink front wall 240... right side wall 434...opening portion 250...top wall 435...rotating drum front wall 251...take outlet 436...opening portion 252...main wall 437...retractable hose 300...door Body 438...sink peripheral wall 310...window 439...rotary drum peripheral wall 320...support frame 440...rotary drum 330...hinge structure 490...suspension device 400...processing device 500...adjustment mechanism 410...Washing drying tank 510...Control element 420...Sink 511...Acquisition unit 34 S 201219619 512.. Output unit 513.. Memory unit 520...Stepper motor 530.. Power supply Power supply 600.. .Circulation mechanism 601...Exhaust port 610.. .1st pipe 620.. .2nd pipe 621.. . blower 622.. .blade 623.. motor 630.. heat pump 631.. temperature sensor 632.. compressor 633.. heating section 635.. dehumidification section 643.. Suction port 645.. . Bottom hole 646... Peripheral hole 650.. . Branch line 651.. Switching valve 700.. Filter device 710.. . Housing 712.··Inlet port 713.. Outlet 714.. Supporting section 715.. . 1st housing wall 716.. 2nd housing wall 717.. Connecting wall 718.. . protruding strip 719.. . partition wall 720.. Net 725.. External air inlet 726.. Inner wall surface 727.. 1st chamber 728... 2nd room 729.. Separator 730.. Switching mechanism 731.. Base 732.. Valve Plug 733... Thinner part 735.. Valve 736.. .1st side wall 737.. 2nd side wall 738.. Gear 739.. Gear shaft 740.. . Rotary shaft 741.. shaft Set 35 201219619 745.. .Cam piece 746.. . outer edge 747.. . inner edge 748.. . 1st row exit 749.. . 2nd row exit 751.. . 1st filter part 752... 2nd filter Department 753... Upper side field 754... Lower side field 765.. Adjusting piece 766.. Front end part 773.. Upper side stop pin 774.. Lower side stop pin 775.. Projection 776.. .Circumference 780.. .Connection 781.. .Connection Plate 782... retaining pin 800.. cover mechanism 810.. cover 811.. mounting port 812.. mounting edge 813.. outside 814.. ridge edge 815.. mounting wall 816.. The first bearing piece 817.. 2nd bearing piece 820.. rod plate 821.. base end edge 822.. . front end edge 823.. outside 824... base surface 825... inclined surface 826. . 1st shaft 827.. 2nd shaft 828... 1st shaft 829.. 2nd shaft 830.. suction port 840... coil spring 891.. positioning piece 900... filtering device 910. .. Laundry Dryer 911.. .Shell 912... Pipeline 260, 431,913.··Bottom wall 914...Sub-pipe 920.. Filter cartridge 921..

S 36 201219619 922.. .coil member 923.. motor 924.. bottom 925.. ring cylinder 926.. sub filter 931.. outer cylinder C...clothing FL...hypothetical line L... cotton thief UR... upper side rotation range LR... lower side rotation range R1, R2... space 37

Claims (1)

201219619 VII. Patent application scope: 1. A drying treatment device, comprising: a drying tank for forming an air inlet for sucking dry air for drying clothes and an exhaust port for discharging the dry air; The removing device removes the cotton dust by the drying air discharged from the exhaust port; the dehumidifying heating device dehumidifies and heats the dry air from which the cotton scrap is removed by the removing device; and the air supplying device is configured to perform the dehumidification The drying air that is dehumidified and heated by the heating device is sent to the intake port at a predetermined flow rate; and the power supply source supplies electric power for operating the air supply device, and the removing device includes: a casing, which is formed to be introduced into the row a port for introducing the dry air discharged from the port, and a discharge port for discharging the dry air to the dehumidifying heater; the filter element is attached to the discharge port to remove the cotton scrap by the dry air; Adjusting the aforementioned dry air from the inlet to the filter element a flow direction; and a control element for controlling the adjustment mechanism, the adjustment mechanism comprising: a rotation shaft rotating in the housing, an adjustment plate extending from the rotation shaft, and a drive source for rotating the rotation shaft; The transition element includes: a first field extending in a direction in which the rotation axis extends in S 38 201219619, and a second field extending along the first field, wherein the control element controls the drive source based on the electric power to pass the The flow rate of the "air" before the third field and the flow rate of the dry air by the aforementioned first field. 2. The drying treatment device of claim 1, wherein the control element controls the driving source to reduce the power 3. The processing device according to the fourth aspect of the invention, wherein the front body comprises a restriction member that contacts the adjustment plate and limits a rotation range of the rotating shaft. 4. Drying treatment according to item 3 of the patent application. The device, wherein the control component package 3 is used for outputting an operation signal of the axis source operation when the wheel is rotated, and obtaining The power information acquisition unit for the electric power and the memory unit for storing the position information of the position of the adjustment plate when the electric power is reduced to the minimum in the rotation range, wherein the operation signal includes rotating the rotation axis to include the rotation I The first movement signal of the circumference and the second operation signal for rotating the rotation shaft to move the adjustment plate to a position where the electric power is minimized in the rotation range, and when the output unit outputs the first operation signal, The acquisition unit acquires the electric power information that the rotation axis rotates, and the memory unit stores the position information based on the electric power information, and the output “the position information outputs the second operation signal, and the driving source is based on the second operation signal. The thief money rotation axis 39 201219619 turns, the aforementioned adjustment plate is moved to the position according to the aforementioned position information. 5. The drying treatment apparatus according to claim 4, further comprising a main casing for accommodating the drying tank, the removing device, the dehumidifying heating device, and the air supplying device, wherein the casing is formed with the introduction from the main basket The external air introduction port of the external air outside the body, the removal device includes: a valve element having a valve plug portion that is displaced between a closed position that closes the external air introduction port and an open position that opens the external air introduction port, And the cam piece is coupled to the rotating shaft, and the cam piece is displaced between the closed position and the open position according to the rotation of the rotating shaft. 6. The drying processing device according to claim 5, wherein the rotation range of the rotating shaft includes a first range in which the valve plug portion holds the closed position, and a second range in which the valve plug portion holds the open position. The acquisition unit acquires temperature information on the temperature of the dehumidification heating device, and the first operation signal includes a first mode signal for rotating the rotation axis in the first range and a rotation of the rotation axis in the second range. In the second mode signal, the output unit selectively outputs the first mode signal and the second mode signal based on the temperature information. 7. The drying apparatus according to claim 5 or 6, wherein the valve element S 40 201219619 comprises: a base portion attached to the casing, and a rim portion formed between the base portion and the valve plug portion, The valve plug portion that is in contact with the cam piece is rotated upward about the hinge portion, and is changed to the open position, and the valve plug portion that releases the contact with the cam piece is wound around the hinge portion by its own weight. Rotate below and shift to the aforementioned closed position. 41