KR101606663B1 - Clothes dryer - Google Patents

Abstract

The clothes dryer comprises an outer box (11); A drying chamber installed in the outer box (11) and having an outlet (193) and an inlet (194); A circulation air passage 30 installed outside the drying chamber and connecting the outlet 193 and the inlet 194; A fan 42 installed in the circulating air passage 30 for sucking air in the drying chamber from the outlet 193 into the circulating air passage 30 and for supplying the air in the circulating air passage 30 from the inlet 194 to the drying chamber; A fan casing (50) constituting a part of the circulation air passage (30) and having a fan (42) installed therein; A heater 41 installed in the circulating air passage 30 for heating air in the circulating air passage 30; And an exhaust port 57 provided between the fan 42 of the circulation air passage 30 and the heater 41 and discharging the air in the circulation air passage 30 to the outside of the circulation air passage 30.

Description

Clothes Dryer {CLOTHES DRYER}

An embodiment of the present invention relates to a clothes dryer.

A heater-type clothes dryer dries clothes in a drying chamber by supplying air heated by a heater into a drying chamber. Conventionally, there are two types of clothes dryer, namely, an exhaust type and a circulation type. In the exhaust type, the air introduced from the outside is made into a warm air by the heater, and the warm air is brought into contact with the clothes in the drying chamber to perform drying. Then, the air that has taken moisture from the clothes is discharged to the outside of the clothes dryer. According to this, it is not necessary to dehumidify air containing a large amount of moisture, so that a mechanism for dehumidifying is not required, and a relatively simple structure can be obtained. However, the air heated by the heater takes moisture out of the clothes, and eventually exits all to the outside. Therefore, the exhaust heat loss in the conventional exhaust type clothes dryer was large.

On the other hand, the circulation type circulates air between a drying chamber and a heater through a circulating air passage, thereby heating the air after the moisture is taken from the clothes by the heater again. According to this, heat of the air after moisture is taken from the clothes can be reused, so that the arrangement loss can be reduced as compared with the exhaust type. However, since it is necessary to perform dehumidification of the circulating air, a dehumidifying mechanism is required and a complicated configuration is required, which makes it difficult to downsize and reduce the cost.

Further, in the exhaust type clothes dryer, there is provided an exhaust port for discharging the air after taking moisture from the clothes to the outside of the clothes dryer. In this case, the exhaust sound when the circulating air is exhausted from the exhaust port becomes noise. Accordingly, it has been attempted to suppress the rotational speed of the fan, that is, to reduce the circulating air volume to suppress the exhaust sound. However, there is a problem in that a long time is required for drying the clothes, and the efficiency is lowered and the energy saving property is lowered.

Depending on the position of the air outlet, the air containing moisture discharged from the air outlet may enter the inside of the housing of the clothes dryer from the gap of the clothes dryer housing such as the outer box or the cover, and may condense inside the housing of the clothes dryer . In this case, if an electric part or the like is disposed in a place where condensation water is generated, there is a fear that the condensation water adversely affects the electrical parts, such as deterioration of insulation. Further, if the number of condensation is generated in a place where the user can see, there is a fear that the user mistakenly thinks that a leak has occurred.

Further, when water is applied to the housing of the clothes dryer, the water may enter the housing of the clothes dryer from the air outlet. If electrical parts or the like are installed in the place where the water enters, there is a fear that adverse effects such as deterioration of insulation against the electrical parts may be caused as in the case of the above-mentioned dew condensation.

Japanese Patent Application Laid-Open No. 2008-110135

A first object of the present invention is to provide a clothes dryer in which a circulating air passage is provided to reduce the arrangement loss and to eliminate the need for a configuration for performing dehumidification.

A second object of the present invention is to provide a clothes dryer capable of efficiently drying clothes while suppressing the generation of noise.

A third object of the present invention is to provide an air conditioner which can suppress the inflow of the discharged air into the housing of the clothes dryer in discharging air containing moisture generated during the drying operation to the outside of the clothes dryer, In which the water can be prevented from entering the inside of the housing of the clothes dryer from the exhaust port.

A clothes dryer according to an embodiment of the present invention includes an outer box; A drying chamber installed in the outer case and having an outlet and an inlet; A circulation passage installed outside the drying chamber and connecting the outlet to the inlet; A fan installed in the circulating air passage for sucking air in the drying chamber from the outlet into the circulating air passage and for supplying air in the circulating air passage from the inlet to the drying chamber; A fan casing constituting a part of the circulating air passage and having the fan installed therein; A heater installed in the circulating air passage for heating air in the circulating air passage; And an exhaust port provided between the fan and the heater of the circulating air passage for discharging the air in the circulating air passage to the outside of the circulating air passage.

Further, the clothes dryer of the embodiment of the present invention includes a damper for opening and closing the exhaust port, and when the damper is in the open state, the rotational speed of the fan is lowered compared to when the damper is in the closed state.

Further, the clothes dryer of the embodiment of the present invention is characterized in that the clothes dryer comprises: a lid member provided above the outer box and covering the circulating air passage; an opening formed at a position facing the exhaust port in the lid member; And a first seal member provided between the lid member and the circulating air passage constituent member and closely contacting the lid member and the circulating air passage constituent member.

1 is a perspective view showing a clothes dryer according to an embodiment of the present invention in a right front side view.
2 is a longitudinal sectional view showing a schematic structure of the inside of the clothes dryer.
3 is an exploded view of the back cover of Fig.
Fig. 4 is a perspective view showing the configuration of the rear periphery of the top cover as seen from the left rear side. Fig.
Fig. 5 is a view showing the exhaust cover of Fig. 4 separated. Fig.
FIG. 6 is a view showing the back cover of FIG. 4 separated.
7 is a perspective view showing the warm air supply device as viewed from above.
8 is a perspective view showing the warm air supply device as viewed from below.
Fig. 9 is a bottom view showing the hot air supply device by separating the lower part of the fan casing.
10 is a plan view showing the warm air supply device.
11 is a cross-sectional view taken along the line X11-X11 in Fig.
Fig. 12 is a view corresponding to Fig. 11 showing a case in which the damper is in a closed state.
13 is a cross-sectional view taken along the line X13-X13 in Fig.
14 is a cross-sectional view taken along the line X14-X14 in Fig.
15 is a table showing changes in pressure in the fan casing according to the state of the filter device.
16 is a diagram showing the relationship between the open / closed state of the damper, the rotational speed of the fan, and the noise.

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

1, the washing and drying machine 10 as a clothes dryer is provided with an outer box 11, a top cover 12, an operation panel 13, a lid 14 and a back cover 15. In the front-rear direction of the washing and drying machine 10, the operation panel 13 side is set as the front side and the back cover 15 side is set as the rear side. The left and right direction of the washing and drying machine 10 is the right side of the paper on the right side in FIG. 1, and the left side in FIG. 1 is the left side.

The outer box 11 has a rectangular parallelepiped shape and forms an outer shell of the washer / dryer 10. The top cover 12 is provided on the upper part of the outer box 11. The top cover 12 is formed in a rectangular frame shape as a whole, and has laundry openings not shown at the center thereof. As shown in Fig. 5, the top cover 12 also has a housing chamber 121 which becomes a space inside the rear side. The outer box 11 and the top cover 12 constitute the housing of the washer / dryer 10.

The operation panel 13 is provided at a front side portion of the top cover 12. The operation panel 13 is connected to a control device (not shown). The setting contents are input from the user, and the contents of the setting and the current operation status are displayed. The lid 14 is provided on the top of the top cover 12 and is configured to be openable and closable in two folds with the rear edge of the top cover 12 as a fulcrum. The lid 14 opens and closes the laundry doorway of the top cover 12 (not shown). 3, the back cover 15 is provided on the rear portion of the top cover 12 and covers the containing chamber 121 in the rear portion of the top cover 12. In this case, the back cover 15 functions as a lid member.

As shown in Figs. 4 and 5, the back cover 15 has a concave portion 151 that dents a portion of the upper rear portion of the back cover 15. The back cover 15 is provided with a decorative panel 16 and an exhaust cover 17. The decorative panel 16 is provided on the upper surface of the back cover 15 and on the front side of the concave portion 151. The exhaust cover 17 covers the upper portion of the concave portion 151 as shown in Fig. As shown in Fig. 1, the exhaust cover 17 is provided with a plurality of exhaust ports 171 connecting the inside and the outside of the exhaust cover 17. The space formed by the concave portion 151 of the back cover 15 and the exhaust cover 17 is connected to the outside through a plurality of outlets 171.

2, the washing and drying machine 10 includes a rotary tub 18, a water tub 19, a stirring body 20, a driving unit 21, an elastic supporting unit 22, a water supply unit 23, And a device (24). The rotary tub 18 is rotatable in a tubular shape having a bottom and opened on the upper side. The axial direction of the rotation center axis of the rotary tub 18 is parallel to the gravity direction. That is, the washing and drying machine 10 is a so-called vertical washing machine.

The rotary tub 18 is provided inside the water tub 19. [ The rotary tub 18 has a plurality of holes 181 and a plurality of projections 182. The hole 181 is formed so as to penetrate the peripheral wall portion forming the tubular shape of the rotary tub 18 in the plate thickness direction. When the laundry is dewatered, the water separated from the laundry is discharged to the outside of the rotary tub 18 via the hole 181. The protruding portion 182 is formed by projecting inward the peripheral wall portion forming the tubular shape of the rotary tub 18. The protruding portion 182 removes the laundry from the inner surface of the rotary tub 18 and prevents the laundry from sticking to the inner surface of the rotary tub 18. A rotary balancer 183 is provided on the upper portion of the rotary tub 18. The rotation balancer 183 is filled with liquid to stabilize the rotary tub 18.

The water tank 19 has a water receiving section 191 and a water tank cover 192. The water receiving portion 191 is formed in a cylindrical shape having a bottom and opened at the top. The water tank cover 192 is provided on the upper portion of the water receiving portion 191. An opening (not shown) is formed in the center of the water tank cover 192. The laundry is put into the rotary tub 18 through an opening (not shown) formed in the water tub cover 192. The opening is opened and closed by an inner cover (not shown) provided on the water tub cover 192.

The agitator 20 is located at the bottom of the inside of the rotary tub 18 and is rotatably installed relative to the rotary tub 18. [ The rotating shaft of the stirring body 20 and the rotating shaft of the rotating tank 18 coincide with each other. The driving device 21 has a motor 211, a clutch 212, and the like. The motor 211 is provided on the back side of the bottom of the water receiving portion 191. The motor 211 is a so-called direct drive motor of an outer rotor type. The clutch 212 is provided between the motor 211 and the rotary tub 18 and connects the motor 211, the rotary tub 18 and the stirrer 20. The clutch 212 selectively switches between a form in which only the agitator 20 is rotated and a form in which the agitator 20 and the rotating tub 18 are integrally rotated.

The elastic supporting device 22 is composed of a plurality of sets, for example, four sets of a suspension bar 221, a supporting portion 222 and an elastic member 223. The upper end of each hanging bar 221 is attached to the four corners of the upper part of the outer box 11. The hanging bar 221 rocks at the attachment portion with the outer box 11 as a supporting point. The supporting portion 222 is provided in the receiving portion 191 of the water tub 19. [ The lower ends of the respective suspension rods 221 are passed through the support portions 222 and supported by the support portions 222 through elastic members 223 such as coil springs. As described above, the elastic supporting device 22 elastically supports the water tub 19 so as to be swingable. Thereby, the elastic supporting device 22 reduces the transmission of the vibration generated in the water tub 19 to the outer box 11 while keeping the water tub 19 in the attitude of the vertical axis.

As shown in Fig. 6, the water supply device 23 is installed in a containing chamber 121 formed at the rear portion of the top cover 12. [ 2, the water supply device 23 includes a main case 231, a main hose 232, an electronically controlled water supply valve 233, a water supply hose connecting portion 234, a bath hose connecting portion 235, A bath water pump 236, and the like. As shown in Fig. 2, the juice hose 232 connects the main juice hose 231 to the water tub 19. As shown in Fig. The water supply hose connecting portion 234 is exposed to the outside of the back cover 15 through the back cover 15, as shown in Figs. 1 and 4. The water supply hose connection portion 234 is connected to an external water source such as a faucet through a water supply hose (not shown).

The tub hose connecting portion 235 is exposed to the outside of the decorative panel 16 as shown in Fig. The tub hose connecting portion 235 is connected to an external water source such as a bathtub through a bath water hose (not shown). Then, the water in the water source is sucked up by the bath water pump (not shown) and supplied to the tub hose connecting portion 235. The water supplied from the external water source to the water supply hose connection portion 234 or the tub hose connection portion 235 is supplied to the main case 231 by opening and closing the water supply valve 233. The water supplied to the water main case 231 melts the detergent disposed in the water main case 231 and is then injected into the water tub 19 through the main water hose 232.

The drainage device 24 has an electronically controlled drain valve 241 and a drainage hose 242 and the like. The drain valve 241 is connected to the drain port 195 provided on the bottom of the water receiving section 191 on the water inlet side and connected to the drain hose 242 on the water outlet side. When the drain valve 241 is closed, the water storage tank 19 becomes water-saving. On the other hand, when the drain valve 241 is opened, the water stored in the water tank 19 is discharged to the outside of the washing and drying machine 10 via the drain valve 195 and the drain hose 242 through the drain hole 195.

2, the washing and drying machine 10 is provided with a circulating air passage 30. The circulation air passage 30 connects the outlet 193 provided in the water tub cover 192 and the inlet 194 from the outside of the water tub 19. During the drying operation, the air in the water tank 19 is discharged from the outlet 193 into the circulating air passage 30, is warmed in the circulating air passage 30, and returned from the inlet 194 into the water tub 19. Specifically, the circulating air passage 30 is mainly provided with a hot air supply device 40 for generating and supplying warm air during a drying operation, and is provided with an intake duct 31, a filter device 32 and a supply duct 33 .

2, the intake duct 31 is formed of, for example, a bellows-shaped hose, and connects the outlet 193 of the water tub 19 and the filter device 32. [ The filter device 32 is installed above the water tub 19 and is connected to the lower side of the hot air supply device 40. The filter device 32 collects the lint from the clothes in the water tank 19 during the drying operation. Although not shown in detail in the filter device 32, an outside air intake port connected to the outside of the circulation air passage 30 is formed. From the outside air intake port, outside air, in this case, the air inside the outer box 11, enters into the circulation air passage 30. The supply duct 33 is constituted by a hose of a bellows shape, for example, and connects the inlet 194 of the water tub 19 and the hot air supply device 40.

As shown in Figs. 2, 3 and 6, the hot air supply device 40 is installed in the containing chamber 121 formed at the rear portion of the top cover 12. [ 2, 7 and 8, the warm air supply device 40 includes a heater 41, a fan 42, a fan motor 43, a damper 45, a damper motor 46, (50). Among them, the heater 41, the fan 42 and the damper 45 are installed inside the fan casing 50, and the fan motor 43 and the damper motor 46 are installed outside the fan casing 50 have. In this case, the fan casing 50 functions as a circulating air passage constituting member constituting a part of the circulating air passage 30.

7, 8, 11, and 12, the fan casing 50 has a space therein by combining the fan casing upper portion 501 and the lower portion 502 of the fan casing. 11 and 12, a seal member 51 for a case is provided between the fan casing upper portion 501 and the lower portion 502 of the fan casing. The case sealing member 51 secures the airtightness of the joint portion between the upper portion 501 of the fan casing and the lower portion 502 of the fan casing.

9, the space in the fan casing 50 is divided into a fan accommodating portion 52, an enlarged air passage 53, and a heater accommodating portion 54. As shown in Fig. A fan (42) is provided in the fan storage portion (52). The fan 42 circulates air in the circulating air passage 30 and is composed of, for example, a centrifugal multi-blade fan, a so-called sirocco fan. The fan motor 43 is, for example, a stepping motor, and is installed on the outer surface of the fan casing upper portion 501. The fan shaft 431 of the fan motor 43 is connected to the fan 42 in the fan casing 50 through the fan casing upper portion 501 as shown in Fig. When the fan 42 is rotated by the driving of the fan motor 43, the fan 42 sucks the air in the axial direction of the fan shaft portion 431, Direction to the outside.

The enlarged air passage 53 is provided along the outer periphery of the fan 42, that is, the fan 42. The width of the enlarged air passage 53 is enlarged in a logarithmic spiral shape from the starting point portion 531 to the end point portion 532. A tongue wall 503 is provided between the fan accommodating portion 52 and the enlarged air passage 53 and the heater accommodating portion 54. The bottom wall 503 is formed integrally with the upper portion 501 of the fan casing. In this case, the end of the sidewall 503 is defined as the starting point 531. The reference point 533 is a position at an angle? = 30 to 45 degrees from the end of the bottom wall 503, that is, the starting point 531, about the rotation center axis of the fan 42, To an end point portion 532 is set to an angle? = 270 degrees.

As shown in Fig. 9, the heater accommodating portion 54 is formed into a substantially rectangular space in plan view. One corner of the fan housing portion 52 and the enlarged air passage 53 of the four corner portions of the substantially rectangular heater accommodating portion 54 is provided on the side of the end point portion 532 of the enlarged air passage 53 And the end portion 532 side of the installed enlarged air passage 53 is connected.

The fan casing 50 has a suction port 55, a blowing port 56, and an exhaust port 57, as shown in Figs. 8 to 10 and the like. The suction port 55 is located radially inward of the fan 42 provided in the fan accommodating portion 52 and is formed so as to penetrate the bottom of the fan casing 50, that is, the fan casing lower portion 502 in a circular manner. The suction port 55 is connected to the outlet 193 of the water tub 19 through the filter device 32 and the intake duct 31 as shown in Fig.

The air outlet 56 is located in the heater accommodating portion 54 and on the diagonal side with respect to the end point portion 532 of the enlarged air passage 53. The air outlet 56 is formed by penetrating the bottom of the fan casing 50, that is, the lower portion of the fan casing 50 in a circular manner. As shown in Figs. 8, 11 and 12, the air outlet 56 is connected to the inside of the air blowing cylinder 561 formed in a cylindrical shape. The air blowing tube portion 561 is integrally provided with the lower portion 502 of the fan casing and protrudes downward from the bottom portion of the lower portion 502 of the fan casing. As shown in Fig. 2, a supply duct 33 is connected to the air blowing tube portion 561. As shown in Fig. Thereby, the air outlet 56 is connected to the inlet 194 of the water tub 19 through the supply duct 33.

9, the exhaust port 57 is located in the vicinity of the end point portion 532 of the enlarged air passage 53, that is, on the downstream side of the fan 42 in the circulating air passage 30, And is disposed on the upstream side. The exhaust port 57 is formed to penetrate the fan casing upper portion 501 in a circular shape and is connected to the inside of the exhaust chamber 571 formed in a cylindrical shape. The exhaust chamber portion 571 is integrally provided with the fan casing upper portion 501 and protrudes upward from the upper surface of the fan casing upper portion 501. A part of the air circulating in the circulating air passage 30 is exhausted from the air outlet 57 outside the circulating air passage 30. In this case, the exhaust chamber portion 571 functions as the second tubular portion.

The heater 41 serving as a heat source is disposed in the heater accommodating portion 54 and between the end point portion 532 of the enlarged air passage 53 and the air outlet 56 as shown in Fig. The heater 41 is, for example, a PTC heater, and is generally formed in the shape of a rectangular plate. The heater 41 is disposed in the heater accommodating portion 54 along the diagonals of two corner portions different from the end portion 532 side of the enlarged air passage 53 and the air outlet 56 side. In this case, the inside of the heater accommodating portion 54 is partitioned by the heater 41 into a space on the side of the end point portion 532 of the enlarged air passage 53 and a space on the side of the air outlet 56 side. The heater 41 passes air in the thickness direction of the plate-shaped phase and heats the air.

The damper motor 46 is, for example, a stepping motor or the like, and is provided outside the side wall of the fan casing upper portion 501. The damper shaft portion 461 of the damper motor 46 protrudes into the fan casing 50 through the side wall of the fan casing upper portion 501. The damper shaft portion 461 is located on the side of the heater accommodating portion 54 with respect to the exhaust port 57, that is, on the downstream side. The axial direction of the damper shaft portion 461 is orthogonal to the direction of the wind flowing through the enlarged air passage 53.

As shown in Figs. 11 and 12, the damper 45 is provided inside the fan casing 50 and below the exhaust port 57. As shown in Fig. The damper 45 is composed of a damper main body portion 451 and a seal portion 452. The damper main body portion 451 is substantially rectangular in shape near the end point portion 532 of the enlarged air passage 53 and has a shape covering the exhaust port 57. [ The side of the damper main body portion 451 on the side of the heater 41 is connected to the damper shaft portion 461 of the damper motor 46. Thus, the damper 45 rotates about the damper shaft portion 461 of the damper motor 46 as a fulcrum.

The seal portion 452 is provided on the surface of the damper main body portion 451 on the side of the exhaust port 57 side. The seal portion 452 is made of, for example, resin or metal, and is configured to cover the exhaust port 57. The seal portion 452 is sandwiched between the damper main body portion 451 and the inner surface of the fan casing 50 around the exhaust port 57 when the damper 45 is in the closed state for closing the exhaust port 57 . Thus, when the damper 45 is in the closed state, the damper 45 comes into close contact with the inner surface of the fan casing 50 around the exhaust port 57 to seal the exhaust port 57.

The damper 45 is rotated by driving the damper motor 46 to open and close the exhaust port 57. That is, the damper 45 rotates in a direction away from the exhaust port 57, with the damper shaft portion 461 as a fulcrum, thereby to open the exhaust port 57 as shown in Fig. In this opened state, the damper 45 opens toward the fan 42 side, that is, toward the upstream side with respect to the flow of air in the circulating air passage 30. [ Further, the damper 45 is rotated in the direction approaching the exhaust port 57, so that the damper 45 is in a closed state for closing the exhaust port 57 as shown in Fig. In this case, the damper 45 is provided inside the fan casing 50, that is, inside the circulating air passage 30. Compared to the case where the damper 45 is provided outside the fan casing 50, the damper 45 It is not necessary to secure a space for opening and closing the door. Further, when the damper 45 is in the closed state, the damper 45 receives a force in the direction in which the damper 45 is closed by the pressure of the air flowing in the fan casing 50. As a result, the exhaust port 57 can be more reliably closed.

The damper 45 is configured so that the rotation angle when it is in the open state is 90 degrees or less at maximum. 11, the angle? Formed by the inner surface of the fan casing 50 and the surface of the damper 45 on the seal portion 452 side is set such that the damper 45 is opened Is set to be 90 DEG or less in the open state. Hereinafter, the angle? Formed by the inner surface of the fan casing 50 and the surface of the damper 45 on the seal portion 452 side is referred to as an opening angle?. In the case of the present embodiment, the opening angle [theta] of the damper 45 is set at 45 [deg.]. In this case, the opening angle [theta] may be set by, for example, controlling the damper motor 46, or by providing a regulating portion for regulating the rotation of the damper 45. [ In this case, when the damper 45 is in an open state, the damper 45 forms an inclined surface inclined downward toward the upstream side, so that the air flowing in the fan casing 50 flows along the slope of the damper 45 57). Thereby, the air flowing in the fan casing 50 can be exhausted more reliably.

The fan casing (50) has a damper receiving portion (58). The damper accommodating portion 58 is located at the connecting portion between the fan casing upper portion 501 and the exhaust port 57 and the fan casing upper portion 501 is formed to be recessed toward the outer side of the fan casing upper portion 501, have. The amount of depression of the damper accommodating portion (58) is set to be equal to or larger than the thickness dimension of the damper (45). In the closed state of the damper 45, the damper 45 is accommodated in the damper accommodating portion 58. Therefore, when the damper 45 is in the closed state, the surface of the damper 45 on the side of the fan casing 50, that is, the surface opposite to the seal portion 452 is flush with the inner surface of the fan casing 50 Or is located on the outer side of the inner surface of the fan casing 50, that is, on the upper side. In this case, when the damper 45 is in the closed state, the damper 45 is not projected inwardly from the inner surface of the fan casing 50, so that the damper 45 is prevented from impeding the flow of air in the fan casing 50 .

As shown in FIGS. 2 and 4, the washing and drying machine 10 is provided with a silencing device 60. The silencer 60 is installed in the recess 151 of the back cover 15 as shown in Fig. An upper portion of the silencer (60) is covered by an exhaust cover (17). The silencer 60 is generally formed in a rectangular box shape that is long in the lateral direction. As shown in Figs. 13 and 14, the silencer 60 has a space therein by combining an upper case 601 and a lower case 602 as box-like members.

As shown in Fig. 13, the silencer 60 has an inlet 61 and an outlet 62. The inlet 61 is located on the lower right side of the silencer 60, that is, on the side of the hot air supply device 40, and is formed by passing through the lower case 602 circularly. The inner diameter of the inlet 61 is larger than the outer diameter of the exhaust chamber 571 provided in the fan casing 50. [ The outlet mechanism 62 is located at the upper left of the silencer 60 and is formed by passing through the upper case 601 in a rectangular shape as shown in FIG. The inlet 61 and the outlet 62 connect the inside and the outside of the silencer 60. The inlet 61 is connected to an exhaust port 57 provided in the circulating air passage 30, that is, an exhaust port 57 provided in the fan casing 50 of the hot air supply device 40. The outlet mechanism 62 is connected to the space formed by the concave portion 151 of the back cover 15 and the exhaust cover 17 and is connected through the outlet 171 of the exhaust cover 17 to the inside of the washing / It is connected to the outside.

The space inside the silencer 60 is divided into a take-in path 63, a silencer chamber 64 and a low-water chamber 65. The dressing path 63 is a path connecting the inlet 61 and the noise chamber 64 and is inclined in the front-rear direction with respect to the horizontal direction as shown in Fig. The noise chamber (64) is formed wider than the entrance hall (63). The volume of the noise chamber 64 is larger than the volume of the dressing passage 63. The low water chamber (65) is provided below the noise chamber (64). The low water chamber 65, for example, stores the water when the water enters from the discharge mechanism 62. This prevents water infiltrating from the outlet mechanism 62 into the silencer 60 from entering the circulation air passage 30 from the inlet 61.

A plurality of concave-convex portions 641, which are concavo-convex shapes, are provided on the upper wall of the noise chamber 64, that is, the ceiling wall portion of the upper casing 601. The concavo-convex portion 641 extends in the short side direction of the silencer 60, that is, in the front-rear direction, that is, in the direction orthogonal to the air flow direction flowing in the silencer chamber 64. [ In this case, the concave-convex portion 641 extends parallel to the outlet mechanism 62. Therefore, when water is applied to the silencer 60, the water can escape in parallel with the outlet mechanism 62, and invasion of water from the outlet mechanism 62 can be avoided.

The silencer 60 is provided with a connection cylinder 66 at a portion of the inlet 61 of the lower casing 602. The connection cylinder 66 is integrally formed with the lower case 602 and is formed in a cylindrical shape and protrudes downward from the lower case 602. The inlet 61 is connected to the inside of the connection cylinder 66. The inner diameter of the connection cylinder 66 is larger than the outer diameter of the exhaust chamber 571 provided in the fan casing 50. A stepped portion 661 is formed in the inside of the connection cylinder portion 66. The stepped portion 661 is formed such that the inner diameter of the lower portion of the stepped portion 661 is larger than the inner diameter of the upper portion, thereby forming a stepped shape.

The back cover 15 has an introduction cylinder 152 as a first cylinder. The introduction cylinder 152 is formed in a cylindrical shape and extends in the vertical direction through the back cover 15. The introduction cylinder 152 is provided at a position opposite to the exhaust port 57 of the fan casing 50. The introduction tube 152 has an introduction port 153 inside the introduction tube 152. That is, the introduction port 153 is formed by passing through the back cover 15 circularly, and connects the inside of the back cover 15, that is, the space on the side of the concave portion 151 and the outside. In this case, the introduction port 153 functions as an opening formed through the back cover 15 in a circular shape.

The inner diameter of the introduction port 153 is equal to the inner diameter of the connection tube 66. That is, the inner diameter of the inlet 153 is larger than the outer diameter of the exhaust chamber 571. The introduction cylinder 152 has a step portion 154 on the outer side of the back cover 15, that is, toward the silencer 60 side. The stepped portion 154 is formed such that the outer diameter of the lower portion of the stepped portion 154 is larger than the upper outer diameter, thereby forming a stepped shape.

5, 13 and 14, the exhaust chamber 571 of the fan casing 50 is passed to the inside of the introducing cylinder 152 of the back cover 15, and the outside of the back cover 15 That is, toward the concave portion 151 side. The silencer 60 is disposed in the concave portion 151 through the introduction cylinder 152 of the back cover 15 to the inside of the connection cylinder 66. [

A plate-like seal member 67 serving as a first seal member is provided between the end portion on the side of the fan casing 50, that is, between the lower end portion and the fan casing 50 in the introduction cylinder 152 of the back cover 15. The plate-shaped seal member 67 is, for example, a rubber-like member formed in a disc shape. At the center of the plate-shaped sealing member 67, there is formed a hole 671 passing through the plate-shaped sealing member 67 in a circular shape. An exhaust chamber 571 of the fan casing 50 is passed through the hole 671. The plate-shaped sealing member 67 closely contacts the lower end of the inlet cylinder 152 of the back cover 15 and the outer surface of the fan casing 50 around the airflow cylinder 561. Thus, the fan casing 50 and the back cover 15 are hermetically and watertightly connected. The plate-shaped sealing member 67 is configured such that the air discharged from the air outlet 57 or the water that has entered from the air outlet 62 and overflows the low water chamber 65 flows into the space between the air outlet 571 and the inlet cylinder 152 And is prevented from leaking into the accommodating chamber 121. [

As shown in Figs. 13 and 14, an annular sealing member 68 serving as a second sealing member is provided between the introducing cylinder 152 and the connecting cylinder 66. As shown in Fig. The annular seal member 68 is made of, for example, a rubber member and has a circular ring shape along the outer circumferential surface of the introduction tube 152 and the inner circumferential surface of the step 661 portion of the connection tube 66. The annular seal member 68 is provided between the stepped portion 154 of the introduction tube 152 and the stepped portion 661 of the connection tube 66, And the connection cylinder 66 of the device 60 is brought into close contact with each other. Thereby, the back cover 15 and the silencer 60 are hermetically and watertightly connected. The annular seal member 68 prevents water that has entered the recess 151 of the back cover 15 from penetrating into the side of the fan casing 50 through the gap between the connection cylinder 66 and the inlet cylinder 152 .

The washing and drying machine 10 performs washing operation, dehydration operation and drying operation by user's operation or automatically. In the washing operation, first, the washing water in which the detergent is dissolved by the water supply device 23 is introduced into the water tub 19. Then, the driving device 21 alternately rotates the stirring body 20 in the forward and reverse directions at low speed. Thereby, the clothes accommodated in the rotary tub 18 are agitated and washed together with the washing water. In the dewatering operation, the water in the water tank 19 is drained by the water drainage device 24 first. Then, the rotary device 18 and the agitator 20 are integrally rotated at a high speed in one direction by the driving device 21. [ Thereby, the clothes in the rotating tub 18 are dewatered by the centrifugal force.

In the drying operation, the hot air supply device 40 is operated to advance drying of the clothes. In the drying operation, the rotary tub 18 and the water tub 19 which accommodate clothes function as a drying chamber. Specifically, when the drying operation is started, the washing and drying machine 10 sequentially executes the heating stroke, the dehumidifying stroke, and the cooling stroke.

When the washing and drying machine 10 executes the heating stroke, the damper 45 is driven to close the exhaust port 57 as shown in Fig. Then, the heater 41 of the hot air supply device 40 is energized to heat the heater 41 and drive the fan motor 43. The air in the rotary tub 18 and the water tub 19 is sucked into the circulation air passage 30 from the outlet 193 of the water tub 19 by the blowing action of the fan 42, Into the fan casing 50 through the suction port 55. [ 12, the air is heated by the heater 41 in the fan casing 50 to be hot air, and then the air is supplied from the air outlet 56 to the supply duct 33 and the inlet 194, And is supplied into the water tub 19.

The warm air supplied into the water tub 19 heats the clothes in the rotary tub 18 and is sucked into the circulation air passage 30 from the outlet 193 of the water tub 19 again. Thus, the warm air supply device 40 heats the air in the rotating tub 18 and the water tub 19 while circulating it. Therefore, by the execution of the heating stroke, the air in the circulating air passage 30 and the temperature of the clothes in the rotary tub 18 gradually rise.

When the temperature of the air circulating through the circulating air passage 30 in the heating stroke rises sufficiently to advance the drying of clothes in the rotary tub 18, the washing and drying machine 10 executes the dehumidification stroke. In the dehumidifying operation, the dehumidifying operation and the reheating operation are alternately performed. In the dehumidifying operation, the washing and drying machine 10 drives the fan 42 and also drives the damper 45 as shown in Fig. 11 to open the exhaust port 57 in the state of heating the heater 41 . In this case, the air heated by the warm air supply device 40 and supplied into the rotary tub 18 takes moisture from the clothes in the rotary tub 18 and becomes air containing a large amount of moisture. When a part of the air containing a large amount of the moisture passes through the circulating air passage 30, the air is discharged from the air outlet 57 to the outside of the circulating air passage 30 as shown by an arrow in Fig.

At this time, the inside of the filter device 32 located on the upstream side of the fan 42 in the circulating air passage 30 becomes a negative pressure, so that the air is sucked into the filter device 32 from the outside air intake port of the filter device 32 Lt; / RTI > Therefore, a part of the air containing a large amount of moisture taken from the clothes and the outside air having little moisture are exchanged to dehumidify the air in the circulation air passage 30, thereby drying the clothes.

Here, the pressure in the fan casing 50 during the dehumidification operation is changed according to the clogging state of the filter of the filter device 32. [ The change in the pressure in the fan casing 50 will be described with reference to Figs. 9 and 15. Fig. The pressure in the fan casing 50 changes around the vicinity of the end point portion 532. In this case, the region from the starting point portion 531 of the enlarged air passage 53 to the vicinity of the end point portion 532 is defined as the region A, and the region A is located in the vicinity of the end point portion 532 in the heater accommodating portion 54 The area up to reaching the air outlet 56 is defined as area B.

15 shows the results of measuring the pressures of the areas A and B in the case where no clogging occurs in the filter of the filter device 32 and in the case where clogging occurs up to a range of 87.5% Respectively. In the case where no clogging occurs in the filter, the regions A and B are all at a constant pressure. On the other hand, when clogging occurs in the filter, a positive pressure is generated in the region B compared with a negative pressure in the region A. Here, the exhaust port 57 is provided between the fan 42 and the heater 41, that is, in the region B. Therefore, the periphery of the exhaust port 57 becomes a constant pressure irrespective of the state of the filter device 32. Therefore, when the exhaust port 57 is opened, the periphery of the exhaust port 57 becomes negative pressure, thereby preventing the outside air from flowing backward from the exhaust port 57 into the fan casing 50. That is, since the pressure around the exhaust port 57 in the fan casing 50 is high with respect to the outside, air in the circulating air passage 30 containing a large amount of moisture can be smoothly discharged from the exhaust port 57 .

The air discharged from the exhaust port 57 to the outside of the fan casing 50 passes through the exhaust port 571 and passes through the inlet 61 to the silencer 60, Lt; / RTI > The air introduced into the silencer 60 first reaches the silencer chamber 64 through the entrance hall 63, as indicated by the arrow in Fig. In this case, since the width of the noise chamber 64 is larger than the width of the entrance hall 63, the air that has entered the noise chamber 64 from the entrance hall 63 is expanded in the noise chamber 64, .

A part of the air which enters the noise chamber 64 and whose speed and pressure are reduced flows out of the silencer 60 from the outlet mechanism 62. At this time, there is a difference in acoustic impedance between the entrance hall 63 and the noise chamber 64, and between the noise chamber 64 and the silencer 60. Sound waves are reflected where the difference in acoustic impedance is large. Therefore, the sound waves generated by the air entering the noise chamber 64 can be transmitted to a portion where the difference in acoustic impedance is large, for example, a boundary portion between the noise chamber 64 and the dressing passage 63, 61 and the wall portion around the noise chamber 64, particularly the portion of the concave-convex portion 641, and the like. Then, the reflected sound waves interfere with each other, whereby sound energy is consumed and noise is produced. The air that has been muffled by the muffler 60 flows out of the muffler 60 from the outflow mechanism 62. The air that has flowed out of the silencer 60 passes through the gap between the silencer 60 and the back cover 15 as indicated by the arrow in Fig. 14 and flows from the outlet 171 to the outside of the washer dryer 10 And is discharged forward.

When the dehumidifying operation is performed, the outside air is blown into the circulating air passage 30, and the temperature of the air in the circulating air passage 30 is gradually lowered. Therefore, the washing and drying machine 10 performs the reheating operation after the dehumidifying operation is performed for a predetermined period of time. When the washing and drying operation is executed, the washing and drying machine 10 continues to drive the fan 42 and heat the heater 41 and also drives the damper 45 to close the air outlet 57. As a result, the air passing through the circulation air passage 30 is not discharged to the outside from the exhaust port 57, and the air in the circulation air passage 30 and the clothes in the rotary tub 18 are heated again.

In this dehumidification stroke, the rotational speed of the fan 42 is set so that the rotational speed of the fan 42 is lower when the damper 45 is in the open state than when the damper 45 is in the closed state. That is, during the reheating operation in the dehumidifying step, since the damper 45 is in the closed state, the rotation speed of the fan 42 is increased. On the other hand, during the dehumidification operation, since the damper 45 is in an open state, the rotation speed of the fan 42 is lowered compared to during the reheating operation.

Fig. 16 shows the relationship between the opening and closing of the damper 45 and the noise generated by the rotation of the fan 42. Fig. When the damper 45 is in the closed state, the noise value is 45 [dB], whereas when the damper 45 is in the open state, the noise value is 50 [dB] when the rotation speed of the fan 42 is 4500 [rpm] do. Further, when the damper 45 is in the open state, the rotational speed of the fan 42 is 45 [rpm], the noise value is 50 [dB], while the noise value is 47 [dB ], And the noise value becomes 45 [dB] at a rotation speed of 3500 [rpm].

Based on the results shown in Fig. 16, it is preferable to lower the damper 45 to 3500 [rpm] when the damper 45 is in the open state. Thus, when the damper 45 is in the open state, the air including the moisture taken from the clothes is discharged from the air outlet 57 to the outside, so that the clothes can be efficiently dried. In this case, since the rotation speed of the fan 42 is low, the noise generated by the exhaust can be reduced. Further, when the damper 45 is in the closed state, since the rotation speed of the fan 42 is high, the drying time of the clothes can be shortened. As a result, the washing and drying machine 10 achieves high energy saving with respect to the drying operation.

The washing and drying machine 10 repeats the dehumidifying operation and the reheating operation a plurality of times in the dehumidifying step and judges the completion of the clothes drying, and then shifts to the cooling stroke. The judgment of the completion of drying of the clothes is performed, for example, by judging whether a predetermined time has elapsed or by detecting a predetermined temperature by a drying temperature sensor (not shown). The washing and drying machine 10 continues driving the fan 42 in a state where the heating operation of the heater 41 is stopped and the damper 45 is operated to open the exhaust port 57. [ Thereby, the hot air in the circulating air passage 30 is discharged from the air outlet 57 to the outside of the circulating air passage 30 and the relatively outside air is blown into the circulating air passage 30 to cool the clothes in the rotating tub 18 do. Then, the washing and drying machine 10 stops the fan 42 after the clothes have sufficiently cooled, and ends the drying cycle. Further, in the drying cycle, the washing and drying machine 10 suitably stirs the clothes in the rotary tub 18 by appropriately driving the motor 211 and rotating the rotary tub 18.

The exhaust port 57 is provided between the fan 42 and the heater 41 in the fan casing 50 constituting the circulation air passage 30. Therefore, even if the filter device 32 is clogged and the pressure balance in the circulating air passage 30 is broken, the vicinity of the exhaust port 57 can be kept at the maximum static pressure. Therefore, air containing moisture generated by the drying of the clothes can be efficiently discharged from the air outlet 57 to the outside of the circulating air passage 30. Thus, the washing and drying machine 10 is provided with the circulating air passage 30 so as to reduce the arrangement loss during the drying operation and to perform the dehumidifying operation, thereby reducing the size and the cost.

The exhaust port 57 is provided on the upstream side of the heater 41. That is, since the heater 41 is provided on the downstream side of the exhaust port 57, it is possible to prevent the air heated by the heater 41 from being discharged to the outside before contributing to the drying of the clothes. That is, most of the air heated by the heater 41 can contribute to the drying of clothes. Therefore, the washing and drying machine 10 can further reduce the arrangement loss of the heater 41, and as a result, can exhibit higher drying performance.

An enlarged air passage 53 is provided in the fan casing 50 along the outer periphery of the fan 42 and extends from the starting point portion 531 to the end point portion 532 in a logarithmic spiral shape. The exhaust port 57 is provided in the vicinity of the end point portion 532 of the expanded air passage 53 of the end point portion 532 in the fan casing 50. According to this, the blowing performance of the centrifugal multi-blade fan (42) can be more effectively exhibited, and as a result, the exhaust performance from the exhaust port (57) can be improved.

The fan casing (50) is installed inside the rear of the top cover (12). The exhaust port 57 is provided on the upper portion of the fan casing 50, that is, the fan casing upper portion 501. This makes it easier to discharge the air discharged from the air outlet 57 from the top surface of the top cover 12 to the outside of the washer / drier 10.

The fan casing 50 is installed in the housing of the washing and drying machine 10, that is, in the housing chamber 121 formed above the top cover 12. A back cover 15 for covering the fan casing 50, that is, the circulation air passage 30, is provided above the fan casing 50. The exhaust port 57 is connected to an exhaust chamber 571 formed in a cylindrical shape and the tip end of the exhaust chamber 571 protrudes to the outside of the back cover 15 as shown in Fig. According to this, air containing moisture in the circulation air passage 30 can be discharged from the outside of the top cover 12, that is, outside the back cover 15. Therefore, the temperature rise in the top cover 12 and the occurrence of condensation can be effectively prevented. In this case, it is more effective when the fan motor 43, the damper motor 46, and electric components (not shown) are installed in the storage chamber 121.

The exhaust port 57 is connected to the silencer 60 through the exhaust port 571. According to this, it is possible to reduce noise such as resonance noise generated when the air is discharged from the exhaust port 57 during the drying operation.

The washing and drying machine (10) is provided with a damper (45) for opening and closing the exhaust port (57). According to this, since the exhaust port 57 can be freely opened and closed in accordance with the state of the drying operation, the exhaust from the exhaust port 57 can be actively controlled. Therefore, the humidity, the temperature, and the like in the circulating air passage 30 during the drying operation can be more finely controlled.

The damper 45 is installed inside the fan casing 50 and rotatable about a damper shaft portion 461 of the damper motor 46 as a supporting point. The damper 45 is opened in the direction of opening the exhaust port 57 by rotating in the direction away from the exhaust port 57 and in the closed state of closing the exhaust port 57 by rotating in the direction approaching the exhaust port 57 . That is, the damper 45 rotates to the inside of the fan casing 50 to open and close the exhaust port 57. Accordingly, the damper 45 is located inside the fan casing 50 even when the exhaust port 57 is opened. Therefore, unlike the case where the damper 45 is provided outside the fan casing 50, it is not necessary to secure a space for opening and closing the damper 45 on the outer side of the fan casing 50. Therefore, by providing the damper 45, the fan casing 50, i.e., the hot wind supply device 40 can be prevented from becoming large.

According to this, in the state in which the damper 45 closes the exhaust port 57, a force for suppressing the damper 45 against the wall portion of the fan casing 50 acts by the positive pressure around the exhaust port 57. [ Therefore, the inner surface of the fan casing 50 around the damper 45 and the exhaust port 57 is tightly adhered to each other, whereby the airtightness of the exhaust port 57 by the damper 45 can be enhanced.

The damper motor 46 for driving the damper 45 has its damper shaft portion 461 provided on the downstream side of the circulation air passage 30 with respect to the exhaust port 57. The angle? Between the inner surface of the fan casing 50 and the damper 45 is 90 degrees or less, that is, an acute angle, when the air outlet 57 is opened. That is, the damper 45 is inclined downward from the downstream side toward the upstream side when the exhaust port 57 is opened. A part of the air flowing in the circulating air passage 30 is guided to the air outlet 57 along the slope of the damper 45 so that the air in the circulating air passage 30 can be efficiently discharged.

The damper 45 is accommodated in the damper accommodating portion 58 in the closed state of the exhaust port 57. That is, in the closed state of the exhaust port 57, the lower surface of the damper 45 is on the same plane as the inner surface of the fan casing 50 or is located outside the inner surface of the fan casing 50, Is not protruded to the inside of the fan casing (50) than the inner surface of the fan casing (50). This prevents the damper 45 from obstructing the flow of the air in the circulation air passage 30 even in the closed state of the exhaust port 57. [ As a result, it is possible to reduce the pressure loss in the circulating air passage 30 by providing the damper 45 in the fan casing 50, that is, inside the circulating air passage 30, It is possible to suppress the noise generated due to the collision of the flowing air with the damper 45.

The damper 45 has a seal portion 452 provided on a surface of the damper main body portion 451 on the side of the exhaust port 57 side. The seal portion 452 closely contacts the damper 45 with the inner surface of the fan casing 50 in the closed state of the exhaust port 57. According to this, the damper 45 can more reliably close the exhaust port 57, and therefore, the communication between the circulation air passage 30 and the outside through the exhaust port 57 can be more reliably prevented. Therefore, when the heating operation of the drying operation is performed, the leakage of the heated air from the exhaust port 57 can be suppressed, the air in the circulation air passage 30 can be efficiently raised, and as a result, the drying efficiency can be improved can do.

The back cover 15 as the lid member has an inlet 153 as an opening. The introduction port 153 is provided at a position opposed to the exhaust port 57 formed in the fan casing 50 which is the circulating air passage constituting member constituting the circulation air passage 30. The plate-like seal member 67 as the first seal member is provided around the inlet 153 and around the outlet 57 and between the back cover 15 and the fan casing 50. The plate-shaped seal member 67 closely contacts the fan casing 50 and the back cover 15 in a watertight and airtight manner.

Thus, when the air including the moisture generated by the drying operation is discharged from the exhaust port 57 to the outside of the back cover 15, that is, to the outside of the casing of the washing and drying machine 10, Can be suppressed from flowing into the housing chamber 121 below the back cover 15, that is, into the housing of the washing and drying machine 10, through the gap between the fan casing 50 and the back cover 15 . Therefore, air containing a large amount of moisture can be prevented from entering the housing chamber 121, and condensation in the housing chamber 121 can be suppressed. Even if water is applied to the upper part of the back cover 15, the water penetrates into the storage chamber 121 below the back cover 15 through the gap between the fan casing 50 and the back cover 15 Can be suppressed. As a result, it is possible to safely dispose the electric parts and the like in the storage room 121 above the top cover 12, and to prevent the user from mistakenly assuming that leakage of water has occurred, .

The washer / dryer (10) is provided with a silencer (60) as a box-like member. The annular sealing member 68 as the second sealing member is provided around the inlet 153 of the back cover 15 and around the inlet 61 of the silencer 60, And the silencer (60). The annular seal member 68 closely contacts the back cover 15 and the silencer 60 in an airtight and watertight manner. Therefore, even when water enters the inside of the exhaust cover 17, that is, the recess 151 of the back cover 15, the water is discharged from the gap between the silencer 60 and the back cover 15, It is possible to prevent intrusion into the inside of the device 60.

The back cover 15 has an introduction cylinder 152 as a first cylinder. The introduction cylinder 152 is formed in a cylindrical shape, and the inside of the cylinder is an introduction opening 153. The introduction cylinder 152 protrudes toward the exhaust port 57 of the fan casing 50. [ The position of the inlet port 153 and the outlet port 57 can be easily aligned by fitting the end of the introduction cylinder 152 on the side of the outlet port 57 to the outlet port 57. [ Therefore, it is possible to avoid the situation where the assembling property is improved and the positional relationship between the introduction port 153 and the exhaust port 57 is shifted and the exhausting is not carried out properly.

The fan casing 50 as a circulating air passage constituting member has an exhaust passage 571 as a second tubular portion. The exhaust port 571 is formed in the shape of a cylinder, and the inside of the cylinder is an exhaust port 57. The exhaust tube 571 protrudes toward the inlet 153 of the back cover 15 and is directed to the outside of the back cover 15 through the inlet 153. According to this, air in the circulation air passage 30 can be more reliably discharged upward of the back cover 15. Therefore, it is possible to more effectively suppress the intrusion of the discharged air from the gap between the fan casing 50 and the back cover 15 into the containing chamber 121.

Further, although the clothes dryer of the above embodiment has a washing and drying function, it may be a clothes dryer having no washing function. Further, the present invention is not limited to the longitudinal axis type washing and drying machine, and may be, for example, a drum type washing and drying machine having a horizontal axis or an oblique axis. The heater 41 is not limited to the PTC heater, and various heaters can be employed. The air outlet 57 may be provided between the fan 42 and the heater 41 in the middle of the circulating air passage 30 and is not necessarily provided in the fan casing 50. [

According to the embodiment described above, the air outlet for discharging the air in the circulating air passage to the outside of the circulating air passage is provided between the fan and the heater in the middle of the circulating air passage. Therefore, it is possible to maintain the vicinity of the exhaust port at the maximum static pressure, so that air containing a large amount of moisture taken from the clothes during the drying operation can be efficiently discharged from the exhaust port to the outside of the circulating air passage. Thus, the clothes dryer is provided with the circulating air passage, so that the arrangement loss during the drying operation can be reduced and a configuration for performing dehumidification is not required. Further, since the air outlet is provided on the upstream side of the heater, it is possible to prevent the air heated by the heater from being discharged to the outside before contributing to the drying of the clothes. Therefore, the clothes dryer can further reduce the arrangement loss of the heater, and as a result, can exhibit higher drying performance.

Although one embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. This new embodiment can be implemented in various other forms, and various omissions, substitutions, and alterations can be made without departing from the gist of the invention. This embodiment and its modifications fall within the scope and spirit of the invention and are included in the scope of the invention described in the claims and their equivalents.

Claims (15)

Outer box;
A top cover installed on an upper portion of the outer box;
A drying chamber installed in the outer box and having an outlet and an inlet;
A circulation path provided outside the drying chamber and connecting the outlet to the inlet;
A fan installed in the circulating air passage for sucking air in the drying chamber from the outlet into the circulating air passage and for supplying air in the circulating air passage from the inlet to the drying chamber;
A fan casing which constitutes a part of the circulating air passage and in which the fan is installed, and which is installed inside the rear of the top cover;
A back cover covering an upper portion of the fan casing;
A heater installed in the circulating air passage for heating air in the circulating air passage; And
And an exhaust port provided on the upper portion of the fan casing between the fan and the heater of the circulating air passage for discharging air in the circulating air passage to the outside of the circulating air passage,
Wherein the exhaust port is connected to an exhaust section formed in a cylindrical shape,
And a front end of the exhaust tube protrudes outside the back cover. The method according to claim 1,
The fan is a centrifugal multi-blade fan,
Wherein the fan casing is provided along an outer periphery of the fan and has an enlarged air passage extending in a logarithmic spiral shape from a start point portion to an end point portion,
And the exhaust port is provided in the fan casing in the vicinity of the end point portion. delete delete 3. The method according to claim 1 or 2,
And the exhaust port is connected to the silencer through the exhaust pipe. Outer box;
A drying chamber installed in the outer box and having an outlet and an inlet;
A circulation path provided outside the drying chamber and connecting the outlet to the inlet;
A fan installed in the circulating air passage for sucking air in the drying chamber from the outlet into the circulating air passage and for supplying air in the circulating air passage from the inlet to the drying chamber;
A fan casing constituting a part of the circulating air passage and having the fan installed therein;
A heater installed in the circulating air passage for heating air in the circulating air passage;
An exhaust port provided between the fan and the heater of the circulating air passage for discharging air in the circulating air passage to the outside of the circulating air passage;
A damper installed inside the fan casing for opening and closing the exhaust port; And
Wherein the fan casing is formed by recessing the damper to a thickness greater than the thickness of the damper and has a damper accommodating portion for accommodating the damper in a closed state. The method according to claim 6,
Wherein the damper is configured to be rotatable about a shaft as a fulcrum and rotates in a direction away from the exhaust port to open the exhaust port and rotate in a direction approaching the exhaust port to close the exhaust port , Clothes dryer. 8. The method of claim 7,
The shaft portion is provided on the downstream side of the circulating air passage with respect to the exhaust port,
Wherein an angle between the inner surface of the fan casing and the damper is 90 degrees or less in the open state. delete The method according to claim 6,
Wherein the damper is provided on the exhaust port side and includes a seal portion that closely contacts the inner surface of the fan casing with the damper in a closed state. The method according to any one of claims 6 to 8 and 10,
And the rotational speed of the fan is lower when the damper is in the open state than when the damper is in the closed state. Outer box;
A drying chamber installed in the outer box and having an outlet and an inlet;
A circulation path provided outside the drying chamber and connecting the outlet to the inlet;
A fan installed in the circulating air passage for sucking air in the drying chamber from the outlet into the circulating air passage and for supplying air in the circulating air passage from the inlet to the drying chamber;
A fan casing constituting a part of the circulating air passage and having the fan installed therein;
A heater installed in the circulating air passage for heating air in the circulating air passage;
An exhaust port provided between the fan and the heater of the circulating air passage for discharging air in the circulating air passage to the outside of the circulating air passage;
A cover member installed above the outer box and covering the circulation air passage;
An opening formed in the cover member at a position facing the exhaust port; And
And a first sealing member provided between the lid member and the circulating air passage constituent member at the periphery of the exhaust port and closely contacting the lid member and the circulating air passage constituent member. 13. The method of claim 12,
A box-like member provided on the outside of the cover member and having a space therein, an outlet mechanism connected to the space, and a mouthpiece communicating with the space and provided opposite to the opening; And
Further comprising a second sealing member provided between the lid member and the box-shaped member at the periphery of the opening and at the periphery of the mouthpiece, the lid member being in close contact with the box-shaped member. 13. The method of claim 12,
Wherein the cover member has a tubular shape protruding toward the exhaust port side and has a first tubular portion having the inside of the tubular shape as the opening portion. 15. The method according to any one of claims 12 to 14,
Wherein the circulation air passage constituting member has a tubular shape protruding toward the opening and having an inner side of the tubular shape as the exhaust port and a second tubular portion passing through the opening and facing the outside of the lid member.

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