JP2022182591A - Washer dryer - Google Patents

Abstract

To provide a washer dryer capable of preventing condensate water generated in a cooler from adhering to a heater.SOLUTION: A washer dryer has a circulation path connected to an outer tank. The circulation path includes a second duct 113 disposed so that a cooler 130 and a heater 140 are located on downstream side of a position at which an air blower is disposed and the cooler 130 is located on upstream side of the heater 140. A protective wall part 340, which extends in a direction perpendicular to air flow in the second duct 113 along a bottom surface wall 303 of the second duct 113 and is overlapped on a gap between the cooler 130 and the bottom surface wall 303 from downstream side of the cooler 130, is disposed in the second duct 113. A flange part 344 protruding toward the cooler 130 and contacting the cooler 130 is formed on the protective wall part 340.SELECTED DRAWING: Figure 4

Description

The present invention relates to a washer/dryer.

an air circulation path having an outlet and a return port connected to the outer tank, an air blowing unit for circulating air by taking it out from the outlet into the air circulation path from the outer tank and returning it to the outer tank from the return port; A washing/drying machine provided in an air circulation path and including a heat exchanger that exchanges heat between a refrigerant and air in the air circulation path is described in Patent Document 1 below.

In this washing/drying machine, the air circulation path includes a middle portion extending in the front-rear direction at a position higher than the outer tub. Furthermore, the heat exchangers include a first heat exchanger on the heating side arranged downstream of the rotating blades of the air blower in the midway portion, and a first heat exchanger on the cooling side arranged downstream of the first heat exchanger. 2 heat exchangers. A 1st heat exchanger and a 2nd heat exchanger are located in a line with the front-back direction.

High-temperature refrigerant flows through the first heat exchanger. The air passing through the first heat exchanger is heated by heat exchange with the refrigerant to become hot air. Low-temperature refrigerant flows through the second heat exchanger. Air containing moisture evaporated from the laundry is cooled and dehumidified by heat exchange with the refrigerant when passing through the second heat exchanger.

Japanese Patent Application Laid-Open No. 2021-23720

In the washing and drying machine described above, the positions of the first heat exchanger, which is a heater, and the second heat exchanger, which is a cooler, are exchanged, and the second heat exchanger is arranged upstream of the first heat exchanger. Accordingly, it is possible to employ a configuration in which the air that has been dehumidified by the second heat exchanger is heated by the first heat exchanger.

When the above configuration is adopted, since the second heat exchanger and the first heat exchanger are arranged in this order on the downstream side of the air blower, the air with strong momentum sent from the air blower, that is, the hot air is easier to pass through the second heat exchanger. The air from the air blower passes not only between the heat radiating fins, but also between the second heat exchanger and the bottom surface of the air circulation path. Between the second heat exchanger and the bottom surface of the air circulation path, the air path resistance is smaller than between the radiating fins, so the momentum of the passing air is less likely to drop.

Water condensed on the second heat exchanger, that is, on the radiation fins of the second heat exchanger due to heat exchange with the air, travels downward through the radiation fins and falls to the bottom surface of the air circulation path. When the above configuration is adopted, the water present on the bottom surface is blown downstream by the air flowing between the cooler and the bottom surface of the air circulation path, and the blown water adheres to the first heat exchanger. There is a concern that it will interfere with heating.

SUMMARY OF THE INVENTION The present invention has been made in view of such problems, and an object of the present invention is to provide a washing and drying machine that can prevent condensed water generated in a cooler from adhering to a heater.

A washing/drying machine according to a main aspect of the present invention includes an outer tub arranged within a housing, a washing tub arranged within the outer tub to accommodate laundry, and a circulation path connected to the outer tub. a blower disposed in the circulation path for circulating air between the outer tank and the circulation path; a cooler for cooling and dehumidifying the air flowing in the circulation path; a heater for heating the flowing air. Here, the circulation path is a duct arranged such that the cooler and the heater are positioned downstream of the position where the air blower is arranged, and the cooler is positioned upstream of the heater. including. Inside the duct, it extends along the bottom wall of the duct in a direction perpendicular to the flow of air in the duct and overlaps the gap between the cooler and the bottom wall from the downstream side of the cooler. A barrier is provided. The barrier portion is formed with a flange portion that protrudes toward the cooler and comes into contact with the cooler.

According to the above configuration, the water splashed downstream by the air flowing between the cooler and the bottom wall is stopped by the barrier portion. Furthermore, the water blown upward by the air blown up along the barrier is stopped by the brim. As a result, condensed water generated in the cooler can be prevented from entering the area where the heater is arranged and adhering to the heater, thereby preventing the heating of the heater from being hindered.

In the washing/drying machine according to this aspect, the barrier portion may be configured to include a rib projecting from the bottom wall and a cover portion covering the rib from above. In this case, the collar portion may be formed on the cover portion.

According to the above configuration, by covering the rib with the cover portion, the barrier portion having the flange portion can be easily formed in the duct.

In the washing/drying machine according to this aspect, the flange may be made of an elastic material.

According to the above configuration, the collar part is elastically deformed, so that it is likely to come into strong contact with the cooler. As a result, the water blown upward is less likely to leak upward over the flange.

In the case of the above configuration, the brim portion further includes a first brim and a second brim provided on the first brim and protruding shorter than the first brim. can be

According to the above configuration, since the flange has a double structure of the first flange and the second flange in the vertical direction, it is even more difficult for water to leak upward from the flange. Moreover, the second brim has less overhang than the first brim and is less likely to come into strong contact with the cooler than the first brim. It is less likely to become resistance and less likely to interfere with placement.

In the washing/drying machine according to this aspect, the bottom wall may be formed with a drain concave portion having a drain port downstream of the barrier portion and upstream of the heater. In this case, a drainage groove may be formed upstream of the drainage recess, which slopes downward toward the drainage recess and is connected to the drainage recess.

According to the above configuration, the water stopped by the barrier portion can flow into the drainage concave portion through the drainage groove together with other water that has fallen on the bottom wall, and can be discharged from the drainage port.

In the washing/drying machine according to this aspect, the bottom wall may be provided with a drainage part for discharging water that has entered the arrangement area of the heater in the arrangement area.

According to the above configuration, even if water enters the arrangement area and accumulates at the bottom thereof, it is possible to prevent the accumulated water from leaking out of the duct and entering the outer tub.

ADVANTAGE OF THE INVENTION According to this invention, the washing-drying machine which can prevent the condensed water which generate|occur|produced in the cooler from adhering to a heater can be provided.

The effects and significance of the present invention will become clearer from the description of the embodiments shown below. However, the following embodiment is merely an example of carrying out the present invention, and the present invention is not limited to the embodiments described below.

FIG. 1 is a side cross-sectional view schematically showing the configuration of a washing machine/dryer according to the embodiment. FIG. 2(a) is a perspective view of the outer tub to which the drying device is mounted, as viewed from the rear upper side, according to the embodiment. FIG. 2(b) is a perspective view of the main part of the outer tank showing the periphery of the exhaust port according to the embodiment. FIG. 3 is a plan view of a second duct with a cooler and a heater arranged thereon, with the upper case removed, according to the embodiment. FIG. 4 is a cross-sectional view of the second duct in which the cooler and the heater are arranged, cut in the front-rear direction at the position of the drainage recess, according to the embodiment. 5(a) and 5(b) are perspective views of a cooler and a heater, respectively, according to an embodiment. FIG. 6 is a perspective view of the lower case according to the embodiment. FIG. 7 is a perspective cross-sectional view of the lower case from which the packing has been removed, according to the embodiment, cut in front of the arrangement area of the cooler. Fig.8 (a) is the perspective view which looked at the packing from the rear upper part which concerns on embodiment. FIGS. 8(b) and 8(c) are a front cross-sectional view and a side cross-sectional view, respectively, of the packing according to the embodiment. FIG. 9 is a diagram schematically showing the periphery of the barrier section inside the second duct according to the embodiment.

Hereinafter, one embodiment of the washing/drying machine of the present invention will be described with reference to the drawings.

FIG. 1 is a side cross-sectional view schematically showing the configuration of the washing/drying machine 1. As shown in FIG. FIG. 2(a) is a perspective view of the outer tub 20 to which the drying device 100 is mounted, as viewed from the rear upper side. FIG. 2(b) is a perspective view of the main part of the outer tub 20 showing the area around the exhaust port 203. FIG.

The washer/dryer 1 of the present embodiment is a so-called drum-type washer/dryer. The washer/dryer 1 includes a rectangular parallelepiped housing 10 . A circular loading port 11 into which laundry is loaded is formed on the front surface of the housing 10 . The slot 11 is covered with a door 12 that can be opened and closed.

An outer tub 20 is elastically supported in the housing 10 by a plurality of dampers 21 and springs 22 . The outer tub 20 has a cylindrical peripheral wall 201 and a disk-shaped rear wall 202 . A drum 23 is rotatably arranged in the outer tub 20 . The drum 23 rotates around a horizontal axis L. The drum 23 has a circular opening 23a on its front surface. The outer tub 20 has a circular opening 20a in front of the opening 23a of the drum 23 .

A large number of dewatering holes 23b are formed in the peripheral wall of the drum 23 . A baffle 24 for raking up the laundry is provided on the peripheral wall of the drum 23 . The drum 23 corresponds to the washing tub of the present invention.

A drive motor 30 that generates torque for rotating the drum 23 is arranged behind the outer tub 20 . The drive motor 30 is, for example, an outer rotor type DC brushless motor. During the washing process and the rinsing process, the drive motor 30 rotates the drum 23 at a rotational speed at which the laundry in the drum 23 is tumbling because the centrifugal force applied to the laundry in the drum 23 is less than the gravity. On the other hand, the drive motor 30 rotates the drum 23 at a rotation speed at which the centrifugal force applied to the laundry in the drum 23 is far greater than the gravity and the laundry sticks to the peripheral wall of the drum 23 during the dewatering process.

A drain port 20b is formed at the bottom of the outer tub 20 . A drainage channel 40 configured by a drainage hose or the like is connected to the drainage port 20b. A drainage valve 41 and a drainage filter 42 are provided in the drainage channel 40 . The drain valve 41 includes, for example, a valve and a torque motor for opening and closing the valve. When the drain valve 41 is opened, the water stored in the outer tank 20 is drained out of the machine through the drain path 40. - 特許庁Foreign matter such as lint contained in the waste water is captured by the waste water filter 42 .

A water supply unit 50 is arranged in the upper part of the housing 10 . The water supply unit 50 includes a first water supply valve 51 , a second water supply valve 52 , a first water supply hose 53 and a second water supply hose 54 . The first water supply valve 51 and the second water supply valve 52 are composed of double electromagnetic valves. The first water supply hose 53 has one end connected to the first water supply valve 51 and the other end connected to the water inlet 20 c provided in the rear wall 202 of the outer tub 20 . The second water supply hose 54 has one end connected to the second water supply valve 52 and the other end connected to the water supply path 160 .

When the first water supply valve 51 is opened, tap water from the faucet flows through the first water supply hose 53 and is supplied into the outer tub 20 from the water inlet 20c. When the second water supply valve 52 is opened, tap water flows through the second water supply hose 54 and is supplied to the water supply path 160 .

A drying device 100 for drying the laundry in the drum 23 is arranged in the upper part of the housing 10 . The drying device 100 includes a circulation path 110 , a blower 120 , a cooler 130 , a heater 140 , a drying filter 150 , a water supply path 160 and a wiper mechanism 170 .

The circulation path 110 is an air path through which air flows and is connected to the outer tub 20 . Circulation path 110 includes first duct 111 , fan casing 112 , second duct 113 , and introduction pipe 114 .

As shown in FIG. 2( b ), the peripheral wall 201 of the outer tub 20 is provided with an exhaust port 203 in the rear part and above the center of the outer tub 20 . The exhaust port 203 has a rectangular shape elongated in the front-rear direction, that is, in the axial direction of the outer tank 20 and with rounded corners.

As shown in FIG. 2( a ), the first duct 111 is arranged on the peripheral wall 201 at the rear of the outer tank 20 and connected to the exhaust port 203 . extends to the top of the The fan casing 112 is arranged in the rear part of the outer tub 20 above the peripheral wall 201 and above the first duct 111 on the right side of the top of the peripheral wall 201 .

The fan casing 112 is formed in a flat, hollow columnar shape, has a suction port on its lower surface, and has a discharge port on its peripheral surface. The first duct 111 is connected to the suction port of the fan casing 112 via a flexible connection hose 115 .

The second duct 113 has a substantially rectangular parallelepiped box shape elongated in the front-rear direction, and is arranged above the peripheral wall 201 and in front of the fan casing 112 . The second duct 113 is connected at its rear end to the outlet of the fan casing 112 . The introduction pipe 114 extends from the front end of the second duct 113 and is connected to an intake port 204 formed in the upper front portion of the outer tub 20 . The introduction pipe 114 is composed of a first pipe 114 a integrally formed with the second duct 113 and a second pipe 114 b connecting the first pipe 114 a and the intake port 204 . A drain hose 116 through which water condensed from the air by the cooler 130 is discharged is connected to the bottom of the second duct 113 . The drain hose 116 is connected to the outer tub 20 via a connection hose (not shown). In addition, the second duct 113 corresponds to the duct of the present invention.

Blower 120 is, for example, a centrifugal fan, and includes fan 121 housed in fan casing 112 and fan motor 122 for rotating fan 121 . Air blower 120 circulates air between outer tub 20 and circulation path 110 . The air discharged from inside the outer tank 20 through the air outlet 203 flows through the first duct 111, the fan casing 112, the second duct 113, and the introduction pipe 114 in this order within the circulation path 110, and enters the outer tank 20 through the air inlet 204. return. A blower unit is configured by the blower 120 and the fan casing 112 .

Cooler 130 and heater 140 are arranged upstream and downstream in second duct 113, respectively. Cooler 130 and heater 140 are respectively composed of an evaporator and a condenser included in the heat pump device. A heat pump device includes a compressor, an expansion valve, and the like that form a cooling circuit together with an evaporator and a condenser.

A low-temperature coolant flows inside the cooler 130 . The cooler 130 cools the air flowing through the second duct 113, that is, the circulation path 110, by exchanging heat with the low-temperature refrigerant to dehumidify the air. A high-temperature refrigerant flows inside the heater 140 . The heater 140 heats the dehumidified air flowing through the second duct 113, that is, the circulation path 110, by heat exchange with the high-temperature refrigerant.

Dry filter 150 , water supply channel 160 and wiper mechanism 170 are arranged in first duct 111 . The dry filter 150 is arranged in the first duct 111 so as to block the air passage. Dry filter 150 is positioned upstream of air flow in circuit 110 from blower 120 , cooler 130 and heater 140 . The dry filter 150 captures foreign matter such as lint contained in the air discharged from the outer tub 20 .

The water supply channel 160 and wiper mechanism 170 are for cleaning the dry filter 150 . The water supply path 160 allows the water supplied from the water supply unit 50 to flow to the dry filter 150 and allows the foreign matter adhering to the capture surface of the dry filter 150 to flow. The wiper mechanism 170 includes a wiper 171 that moves on the catching surface, and the wiper 171 wipes off foreign matter adhering to the catching surface.

FIG. 3 is a plan view of the second duct 113 with the cooler 130 and the heater 140 arranged, with the upper case 302 removed. FIG. 4 is a cross-sectional view of the second duct 113 in which the cooler 130 and the heater 140 are arranged, cut in the longitudinal direction at the position of the drainage recess 313 . 5(a) and (b) are perspective views of cooler 130 and heater 140, respectively. 6 is a perspective view of the lower case 301. FIG. FIG. 7 is a perspective cross-sectional view of lower case 301 with packing 341 removed, taken in front of arrangement region 320 of cooler 130 . FIG. 8(a) is a perspective view of the packing 341 as seen from the rear upper side. 8B and 8C are a front cross-sectional view and a side cross-sectional view of the packing 341, respectively. FIG. 9 is a diagram schematically showing the periphery of the barrier section 340 inside the second duct 113. As shown in FIG.

The configurations of second duct 113, cooler 130 and heater 140 will be described in detail with reference to FIGS. 3 to 9. FIG.

The second duct 113 is configured by connecting a lower case 301 with an open upper surface and an upper case 302 with an open lower surface. The second duct 113 is made of a resin material and includes a bottom wall 303 , a top wall 304 , a front side wall 305 , a rear side wall 306 , a right side wall 307 and a left side wall 308 .

The bottom wall 303 has a substantially horizontal right end portion, and a portion on the left side of the right end portion that slopes upward toward the left end. A rectangular inlet 309 elongated in the left-right direction is formed in the rear side wall 306 . A discharge port of the fan casing 112 is connected to the inlet port 309 . The front side wall 305 is formed with an outlet 310 elongated in the left-right direction. A first pipe 114 a of an introduction pipe 114 integrally formed with the second duct 113 is connected to the outflow port 310 . The air sent out from the fan casing 112 flows through the second duct 113 from the rear to the front.

Inside the second duct 113 , the cooler 130 is arranged in the rear arrangement area 320 on the upstream side, and the heater 140 is arranged in the front arrangement area 330 on the downstream side. The cooler 130 and the heater 140 are arranged linearly in the front-rear direction while being close to each other.

As shown in FIG. 5(a), the cooler 130 is an evaporator and includes three heat exchangers 131 arranged in the front-rear direction and two connecting pipes 132 for connecting the heat exchangers 131. . Each heat exchanger 131 is configured by vertically meandering a flat pipe through which a refrigerant flows, and has a large number of radiation fins 131a in the meandering portion. The cooler 130 is provided with a coolant inlet 133 at the front of the upper connecting pipe 132 and with a coolant outlet 134 at the rear of the lower connecting pipe 132 .

As shown in FIG. 5B, the heater 140 is a condenser, and includes four heat exchangers 141 arranged in the front-rear direction and two connecting pipes 142 for connecting these heat exchangers 141. . Each heat exchanger 141 is configured by making a flat pipe through which a refrigerant flows meander in the left-right direction, and has a large number of radiation fins 141a in the meandering portion. The heater 140 is provided with a coolant inlet 143 and an outlet 144 at the front and rear of the upper connecting pipe 142, respectively.

The cooler 130 and the heater 14 have front shapes corresponding to the front cross-sectional shape of the second duct 113 .

As shown in FIG. 3 , inside the second duct 113 , a housing portion 312 partitioned by a partition wall 311 extending in the front-rear direction is provided on the right side of the two arrangement areas 320 and 330 . The partition wall 311 has a lower portion formed in the lower case 301 and an upper portion formed in the upper case 302 .

A feed pipe 181 and a return pipe 182 extending respectively from a discharge port and a suction port of a compressor (not shown) are introduced into the housing portion 312 . Feed tube 181 is connected to inlet 143 of heater 140 . A return pipe 182 is connected to the outlet 134 of the cooler 130 .

A connection tube 184 having a capillary tube 183 that is an expansion valve is arranged in the housing portion 312 . The inlet of the connecting tube 184 is connected to the outlet 144 of the heater 140 and the outlet of the connecting tube 184 is connected to the inlet 133 of the cooler 130 .

Refrigerant compressed by the compressor and having a high temperature is supplied to the heater 140 through the feed pipe 181 and flows through the three heat exchangers 141 of the heater 140 . As a result, the heater 140 becomes hot. The refrigerant exiting the heater 140 is decompressed and becomes low temperature when passing through the capillary tube 183 in the connecting pipe 184 . Cold refrigerant is supplied to the cooler 130 and flows through the three heat exchangers 131 of the cooler 130 . Thereby, the cooler 130 becomes low temperature. Refrigerant exiting cooler 130 returns to the compressor through return line 182 .

As shown in FIGS. 6 and 7, inside the second duct 113, a rectangular parallelepiped projecting from the lower part of the partition wall 311 so as to be close to the left end of the cooler 130 is provided in the arrangement area 320 of the cooler 130. A shaped overhang 321 is provided. Also, in the arrangement area 320 , a drainage groove 322 is formed in the horizontal portion of the bottom wall 303 so as to traverse the arrangement area 320 in the front-rear direction. The drainage ditch 322 slopes down forward.

In the arrangement region 320 , the bottom wall 303 is provided with four bottom ribs 323 extending in the left-right direction between the projecting portion 321 and the right side wall 307 at intervals in the front-rear direction. Further, the right side wall 307 is provided with four side ribs 324 that extend vertically and whose lower ends are connected to the bottom ribs 323 . Furthermore, the projecting portion 321 is provided with four support ribs 325 extending from the side surface to the upper surface of the projecting portion 321 and having lower ends connected to the bottom ribs 323 .

The rear three bottom ribs 323 have stepped portions corresponding to the inclined portions of the bottom wall 303 . The frontmost and rearmost bottom ribs 323 are interrupted at the drainage groove 322 . The middle two bottom ribs 323 are interrupted in many areas of the horizontal portion of the bottom wall 303 , including portions of the drains 322 . The four support ribs 325 are recessed in a half-U shape on the right side.

In the arrangement area 320 , low mounting ribs 326 extending in the left-right direction are provided on the right and left sides of the drainage groove 322 in the horizontal portion of the bottom wall 303 between the two front and rear bottom ribs 323 . It is formed.

The cooler 130 has each heat exchanger 131 sandwiched between two front and rear bottom ribs 323 , side ribs 324 and support ribs 325 . Thereby, the movement of the cooler 130 in the front-rear direction is restricted. In the cooler 130 , each heat exchanger 131 is mounted on the mounting ribs 326 and the two connecting pipes 132 are supported by the supporting ribs 325 . This creates a gap between cooler 130 and bottom wall 303 .

Inside the second duct 113 , a barrier part 340 is provided in front of the cooler 130 , that is, downstream, so as to be close to the cooler 130 . The barrier part 340 extends in the left-right direction along the bottom wall 303 of the second duct 113, that is, in the direction orthogonal to the air flow in the second duct 113, and extends from the downstream side of the cooler 130 to the bottom wall 303. overlaps the gap between

The barrier portion 340 is composed of a front bottom rib 323 and a packing 341 covering the bottom rib 323 from above. The packing 341 is made of an elastic material such as rubber and formed in a shape corresponding to the bottom rib 323 and has the same length as the bottom rib 323 in the left-right direction. The front bottom rib 323 corresponds to the rib of the present invention, and the packing 341 corresponds to the cover portion of the present invention.

As shown in FIGS. 8A to 8C, a fitting groove 342 extending in the left-right direction is formed in the lower surface of the packing 341 . The left and right ends of the packing 341 protrude upward, and the fitting grooves 342 extend upward at the left and right ends. Four holes 343 connected to the fitting grooves 342 are formed in the upper surface of the packing 341 .

A flange portion 344 is formed at the upper end portion of the packing 341 so as to protrude rearward, that is, toward the cooler 130 side. The flange portion 344 has the same length as the packing 341 in the left-right direction. The flange portion 344 is provided on the first flange 344a that projects obliquely so as to approach the bottom wall 303 and extends parallel to the upper surface of the packing 341, that is, the bottom wall 303 of the second duct 113. and a second collar 344b that protrudes. The second collar 344b protrudes shorter than the first collar 344a.

When the packing 341 is placed over the front bottom rib 323 , the fitting groove 342 of the packing 341 fits into the top of the bottom rib 323 , the bottom end of the side rib 324 , and the bottom end of the support rib 325 . Four protrusions 327 provided on the upper ends of the bottom ribs 323 are inserted into the four holes 343 of the packing 341 . Furthermore, the discontinuous portion of the bottom rib 323 above the drainage groove 322 is covered with the packing 341 .

As shown in FIG. 9 , the barrier 340 has a collar 344 that contacts the cooler 130 located in the placement area 320 . When the cooler 130 is arranged in the arrangement area 320 from above, the first flange 344a of the flange portion 344 strongly contacts the cooler 130 while being elastically deformed forward and downward, and the second flange 344b is brought into contact with the first flange. Above 344a, it contacts the cooler 130 weaker than the first collar 344a. In this manner, the collar portion 344 is easily brought into close contact with the cooler 130 by elastically deforming.

The packing 341 has an inclined surface by chamfering substantially the front half of the upper surface thereof. As a result, the water adhering to the upper surface of the packing 341 can easily flow to the bottom wall 303 due to the inclined surface, so that the water remaining on the upper surface can be prevented from being blown to the heater 140 side by the hot air. The front side of the upper surface of the packing 341 may be formed as an arcuate inclined surface by forming a large R.

Inside the second duct 113 , a drainage recess 313 is provided in front of the drainage groove 322 by recessing the bottom wall 303 . The drainage concave portion 313 is located downstream of the barrier portion 340 and upstream of the arrangement region 330 of the heater 140 . A drain groove 322 is connected to the drain recess 313 . The drainage recess 313 has a cylindrical drainage port 314 formed in the lower portion of the rear wall thereof. A drain hose 116 is connected to the drain port 314 . Further, a cylindrical inlet 315 is formed in the lower portion of the front wall of the drainage recess 313 (see FIG. 4).

As shown in FIG. 6, in the arrangement area 330 of the heater 140, the inclined portion of the bottom wall 303 has a stepped shape. In the arrangement region 330 , the bottom wall 303 is provided with five bottom ribs 331 extending in the left-right direction between the partition wall 311 and the right side wall 307 at intervals in the front-rear direction. Further, the right side wall 307 is provided with five side ribs 332 that extend vertically and whose lower ends are connected to the bottom ribs 331 . Each bottom rib 331 has a stepped portion corresponding to the inclined portion of the bottom wall 303 .

The heater 140 has each heat exchanger 141 sandwiched between two front and rear bottom ribs 331 and side ribs 332 . Thereby, the movement of the heater 140 in the front-rear direction is restricted. Also, the heater 140 has each heat exchanger 141 mounted on the bottom wall 303 and two connecting pipes 142 supported by four bottom ribs 331 on the rear side.

A recess 333 having a predetermined shape is formed in the horizontal portion of the bottom wall 303 in the placement area 330 . The three intermediate bottom ribs 331 are interrupted at the portions where the recesses 333 are formed. A drainage part 334 is provided at the foremost part of the recess 333 . The drainage portion 334 includes a drainage recess 335 formed by recessing the bottom wall 303 and a cylindrical drainage port 336 formed in the lower portion of the rear wall of the drainage recess 335 .

As shown in FIG. 4 , the drain port 336 and the inlet port 315 are connected by a connecting pipe 350 . Thereby, the drain port 336 , that is, the drain recess 335 is connected to the drain hose 116 via the connection pipe 350 and the drain recess 313 . Thereby, the drainage part 334 can share the drain hose 116 with the drainage concave part 313 .

Note that the drainage part 334 may be configured only by a drainage port provided in the bottom surface of the recess 333 and passing through the bottom wall 303 .

Now, in the washing/drying machine 1, washing/drying operation of various operation courses, washing operation or drying operation is performed. In the washing/drying operation, a washing process, an intermediate dehydration process, a rinsing process, a final dehydration process and a drying process are performed in order. In the washing operation, the washing process to the final dehydration process are performed, and the drying process is not performed. In the drying operation, only the drying process is performed. Depending on the operation course, the rinsing process and the intermediate dehydration process may be performed twice or more.

In the washing process, water containing detergent is accumulated in the outer tub 20 up to a predetermined water level corresponding to the load of the laundry accommodated in the drum 23, and the laundry soaked in the water is washed into the drum 23. The tumbling is performed by repeating the forward and reverse rotations of the . The water containing the detergent permeates into the inside of the laundry, and dirt adhering to the surface and inside of the laundry is removed by the force of the detergent and the mechanical force of tumbling.

In the rinsing process, the drum 23 rotates forward and backward while the outer tub 20 is filled with water up to a predetermined water level to tumble the laundry. As a result, the detergent contained in the laundry is discharged together with the water, and the laundry is rinsed.

In the intermediate dehydration process and the final dehydration process, the drive motor 30 rotates in one direction at a high speed, and the drum 23 rotates in one direction at a speed at which the centrifugal force acting on the laundry in the drum 23 is far greater than the gravity. . Centrifugal force causes the laundry to be pressed against the peripheral wall surface of the drum 23 and dewatered. In the final dewatering process, the drum 23 rotates at a higher rotational speed than in the intermediate dewatering process.

In the drying process, air is circulated between the outer tub 20 and the circulation path 110 by the operation of the blower 120, and the air introduced into the outer tub 20 is heated by the operation of the heater 140 to become hot air. Further, the drum 23 rotates forward and backward to tumble the laundry.

The hot air introduced into the outer tub 20 from the air inlet 204 hits the tumbling laundry and dries the laundry. The hot air that has dehydrated the laundry returns from the air outlet 203 to the circulation path 110. - 特許庁Foreign matter such as lint from the laundry is taken into the circulation path 110 together with the hot air. Foreign matter is trapped on the trapping surface of dry filter 150 as hot air passes through dry filter 150 . Foreign matter is less likely to flow through the circulation path 110 downstream of the dry filter 150, and adheres to the blower 120, the cooler 130, and the heater 140 downstream.

Within the circulation path 110 , the hot air passes through the cooler 130 before being heated by the heater 140 and is dehumidified by the cooler 130 . At this time, water condensed from the air condenses on the radiator fins 131 a of the cooler 130 , and the condensed water moves downward along the radiator fins 131 a and falls onto the bottom wall 303 below the cooler 130 . As indicated by the arrows in FIG. 7, the water that has fallen on the bottom wall 303 flows through the gap between the cooler 130 and the bottom wall 303 into the drain groove 322 and flows through the drain groove 322 into the drain recess 313 . The water that has flowed into the drainage recess 313 is discharged from the drainage port 314 and discharged into the outer tub 20 through the drain hose 116 .

In the washing/drying operation and the drying operation, a filter cleaning operation for removing foreign matter from the drying filter 150 is performed after the drying process is completed. In the filter cleaning operation, a water supply process and a wiper operation process are performed in order.

In the water supply process, water is supplied from the water supply path 160 to the dry filter 150 for a predetermined water supply time. Water flows on the trapping surface of the dry filter 150, and the foreign matter adhering to the trapping surface is washed away by the water. In the wiper operation process, the wiper 171 operates for a predetermined wiper operation time. The brush of the wiper 171 moves while rubbing the catching surface of the dry filter 150, thereby scraping off the foreign matter adhering to the catching surface.

Foreign matter discharged into the outer tank 20 in the water supply process and the wiper operation process flows into the drainage channel 40 together with the water discharged into the outer tank 20, and is collected by the drainage filter 42 disposed in the drainage channel 40. .

In the drying apparatus 100, the cooler 130 and the heater 140 are arranged in this order on the downstream side of the air blower 120 in the circulation path 110. As shown in FIG. For this reason, the air with strong force sent out from the blower 120 , that is, the hot air, easily passes through the cooler 130 . The hot air not only passes between the radiating fins 131 a, but also passes between the cooler 130 and the bottom wall 303 . Between the cooler 130 and the bottom wall 303, airflow resistance is smaller than between the radiating fins 131a, so the momentum of the passing hot air is less likely to drop. Therefore, as shown in FIG. 9, the water falling from the cooler 130 and existing on the bottom wall 303 is easily blown downstream by the hot air flowing between the cooler 130 and the bottom wall 303 .

In the present embodiment, a barrier portion 340 is provided downstream of the cooler 130 inside the second duct 113 . Therefore, as shown in FIG. 9, the water blown downstream by the hot air is stopped by the barrier 340 . Furthermore, when hot air blows up along the barrier 340 and water is blown upward, the water blown upward is stopped by a collar 344 formed on the barrier 340 . The flange portion 344 has a double structure consisting of a first flange 344a and a second flange 344b in the vertical direction. Hateful. The water stopped by the barrier part 340 flows through the drain groove 322 to the drain recess 313 .

In this way, even if the water falling from the cooler 130 onto the bottom wall 303 is blown downstream by the hot air, the barrier part 340 prevents the blown water from entering the arrangement area 330 of the heater 140. be done. Therefore, it is possible to prevent the condensed water generated in the cooler 130 from adhering to the heater 140 and prevent the heating of the heater 140 from being hindered.

Furthermore, in the present embodiment, a drainage section 334 is provided in the arrangement area 330 of the heater 140 . Therefore, even if water enters the arrangement area 330 and accumulates at the bottom thereof, the accumulated water is discharged by the drainage section 334 . The discharged water flows to the drain hose 116 through the connection pipe 350 and the drainage recess 313 and is discarded outside the machine. As a result, it is possible to prevent the water accumulated in the arrangement area 330 from leaking out of the second duct 113 through the outflow port 310 , flowing through the introduction pipe 114 and entering the outer tub 20 .

<Effect of Embodiment>
According to the present embodiment, circulation path 110 is arranged such that cooler 130 and heater 140 are positioned downstream of the position where blower 120 is arranged, and cooler 130 is positioned upstream of heater 140. including a second duct 113 arranged in the . Inside the second duct 113 , along the bottom wall 303 of the second duct 113 , the cooler 130 and the bottom wall 303 extend in the direction perpendicular to the air flow in the second duct 113 , and the cooler 130 and the bottom wall 303 extend from the downstream side of the cooler 130 . A barrier portion 340 is provided that overlaps the gap between. The barrier portion 340 is formed with a flange portion 344 that protrudes toward the cooler 130 and contacts the cooler 130 .

According to this configuration, the water splashed downstream by the air flowing between the cooler 130 and the bottom wall 303 is stopped by the barrier portion 340 . Furthermore, the brim portion 344 stops the water blown upward by the air blown up along the barrier portion 340 . As a result, condensed water generated in the cooler 130 can be prevented from entering the placement region 330 of the heater 140 and adhering to the heater 140 , thereby preventing the heating of the heater 140 from being hindered.

Furthermore, according to the present embodiment, the barrier portion 340 includes the bottom rib 323 projecting from the bottom wall 303 and the packing 341 covering the bottom rib 323 from above. be.

According to this configuration, by covering the bottom rib 323 with the packing 341 , the barrier portion 340 having the flange portion 344 can be easily formed inside the second duct 113 .

Furthermore, according to the present embodiment, since collar portion 344 is made of an elastic material, it is likely to come into strong contact with cooler 130 by elastically deforming. As a result, the water blown upward is less likely to leak upward over the collar portion 344 .

Furthermore, according to the present embodiment, the flange portion 344 made of an elastic material includes a first flange 344a and a second flange 344b which is provided on the first flange 344a and protrudes shorter than the first flange 344a. and including.

According to this configuration, the flange portion 344 has a double structure of the first flange portion 344a and the second flange portion 344b in the vertical direction, so that it is even more difficult for water to leak upward from the flange portion 344. Moreover, the second flange 344b protrudes less than the first flange 344a and does not come into strong contact with the cooler 130 compared to the first flange 344a. It is less likely to be a resistance to the cooler 130 when it is arranged, and it is less likely to interfere with the arrangement.

Furthermore, according to the present embodiment, the bottom wall 303 is formed with a drainage recess 313 having a drainage port 314 downstream of the barrier section 340 and upstream of the heater 140 . A drainage groove 322 that slopes downward toward the drainage recess 313 and is connected to the drainage recess 313 is formed on the upstream side.

According to this configuration, the water stopped by the barrier part 340 can flow into the drainage concave part 313 through the drainage groove 322 together with other water that has fallen on the bottom wall 303 , and can be discharged from the drainage port 314 .

Furthermore, according to the present embodiment, the bottom wall 303 is provided with a drainage portion 334 for draining water that has entered the arrangement area 330 of the heater 140 .

According to this configuration, even if water enters the arrangement area 330 and accumulates at the bottom thereof, the accumulated water leaks from the second duct 113 and enters the outer tub 20 . can be prevented.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments and the like, and the embodiments of the present invention can be modified in various ways other than those described above. be.

For example, in the above-described embodiment, the second duct 113 is formed in a rectangular parallelepiped box shape in which a part of the bottom wall 303 is inclined corresponding to the peripheral wall 201 of the outer tub 20 . However, the second duct 113 may have any shape as long as it has a structure in which the cooler 130 and the heater 140 are arranged on the upstream and downstream sides thereof, respectively.

Furthermore, in the above-described embodiment, the barrier portion 340 is configured by the bottom rib 323 projecting from the bottom wall 303 and the packing 341 having the flange portion 344 formed of an elastic member. However, the configuration of the barrier section 340 is not limited to the above. For example, the barrier part 340 may be configured such that a collar part made of an elastic material is attached to the upper part of the rib protruding from the bottom wall 303 .

Furthermore, in the above-described embodiment, cooler 130 and heater 140 are configured by the evaporator and condenser, respectively, included in the heat pump device. However, the cooler 130 may be configured by a water-cooled heat exchanger or the like, and the heater 140 may be configured by a semiconductor heater or the like.

Furthermore, in the above-described embodiment, the protective wall portion 340 is configured such that the flange portion 344 is made of an elastic material and has two flanges, the first flange 344a and the second flange 344b. However, the collar portion 344 may be made of, for example, a resin material other than the elastic material. Also, the flange portion 344 may be configured to have one flange, or three or more flanges.

Furthermore, in the above embodiment, drain port 336 of drain portion 334 is connected to drain hose 116 via connecting pipe 350 and drain recess 313 . However, the drain port 336 may be connected to the drain hose 116 via the connecting pipe 350 , or the drain port 336 may be connected to another drain hose connected to the drain channel 40 .

Furthermore, in the above embodiment, the washer/dryer 1 is a drum-type washer/dryer provided with the drum 23 of horizontal shaft type. However, the present invention can also be applied to a so-called vertical washing/drying machine having a vertical axis type washing/drying tub with a pulsator inside.

In addition, the embodiments of the present invention can be appropriately modified in various ways within the scope of the technical idea indicated in the scope of claims.

10 housing
20 outer tank
23 drum (washing tub)
110 circuit
113 second duct (duct)
120 blower
130 cooler
140 heater
313 drainage recess
314 Drain
322 Drain
323 bottom rib (rib)
330 placement area
334 Drain
340 Barrier
341 packing (cover part)
344 flange portion 344a first flange 344b second flange

Claims (6)

an outer tank disposed within the housing;
a washing tub arranged in the outer tub and containing laundry;
a circulation path connected to the outer tank;
an air blower disposed in the circulation path for circulating air between the outer tank and the circulation path;
a cooler that cools and dehumidifies the air flowing through the circulation path;
a heater that heats the air flowing in the circulation path,
The circulation path includes a duct arranged such that the cooler and the heater are positioned downstream of the position where the blower is arranged, and the cooler is positioned upstream of the heater,
Inside the duct, it extends along the bottom wall of the duct in a direction perpendicular to the flow of air in the duct and overlaps the gap between the cooler and the bottom wall from the downstream side of the cooler. A barrier is provided,
The barrier portion is formed with a flange portion that protrudes toward the cooler and contacts the cooler.
A washing and drying machine characterized by: In the washing and drying machine according to claim 1,
The barrier portion includes a rib projecting from the bottom wall and a cover portion covering the rib from above,
The collar portion is formed on the cover portion,
A washing and drying machine characterized by: In the washing and drying machine according to claim 1 or 2,
The collar is made of an elastic material,
A washing and drying machine characterized by: In the washing and drying machine according to claim 3,
The brim portion includes a first brim, and a second brim provided on the first brim and protruding shorter than the first brim,
A washing and drying machine characterized by: In the washing and drying machine according to any one of claims 1 to 4,
The bottom wall includes
A drainage recess having a drainage port is formed downstream of the barrier and upstream of the heater,
A drainage groove is formed on the upstream side of the drainage recess and is inclined downward toward the drainage recess and connected to the drainage recess.
A washing and drying machine characterized by: In the washing and drying machine according to any one of claims 1 to 5,
The bottom wall is provided with a drain for draining water that has entered the arrangement area of the heater in the arrangement area.
A washing and drying machine characterized by:

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