KR20220031329A - dryer - Google Patents

Abstract

The present invention relates to a dryer. The dryer includes: a drum including a drum body providing a space to store clothes, a front cover forming a front side of the drum body, a rear cover forming a rear side of the drum body, and a drum inlet connected to the inside of the drum body through the front cover; a fixing panel provided on a position spaced apart from the rear cover; a motor including a stator fixed to the fixing panel, and a rotor rotated by the stator; a power delivery part including a housing fixed to the fixing panel, and including a first shaft connected to the rotor, a second shaft connected to the rear cover, and an interlocking gear decelerating a rotation force of the first shaft to deliver the rotation force to the second shaft; and a driving part bracket fixed to the fixing panel to limit a position in which the stator is installed, and correcting an installation position of the housing such that the rotation axis of the first shaft can be matched with the center of rotation of the stator when the housing is installed. Therefore, the present invention is capable of minimizing the volume of the driving part and improving the cooling flow path of the motor.

Description

dryer {dryer}

The present invention relates to a dryer, and more particularly, to a dryer in which a power transmission structure of a drum and a motor rotating the drum is improved.

A dryer is a device for drying an object, and may be a device for drying an object by supplying hot air into the object receiving unit.

A drum dryer in which the object accommodating part is formed in a cylindrical drum shape and hot air is supplied into the drum while rotating the drum is widely used. In particular, in household dryers, drum dryers rotating about a horizontal axis are often used.

A motor for rotating the drum is used in such a drum dryer, and the driving force of the motor is transmitted to the drum through a power transmission unit such as a belt to rotate the drum. The rotation shaft of the motor is generally different from the rotation shaft of the drum. This may be referred to as a belt type.

Accordingly, power loss may occur due to a power transmission unit such as a belt, and a separate space is required inside the case for mounting a power transmission unit such as a motor and a belt.

Most of the drum washing machines produced recently are direct-connected (or direct-driven) drum-type washing machines, not belt washing machines. The direct connection type refers to a form in which the rotating shaft of the motor and the rotating shaft of the drum are coaxially formed, and the stator of the motor is generally mounted on the rear or lower wall of the tub). A motor normally used in a washing machine is called a DD (direct drive) motor, and such a washing machine is called a DD washing machine.

The direct connection type has many advantages compared to the belt type. For example, the drum driving RPM and drum torque may be variously changed and controlled in various environments. In addition, the drum rotation direction control, the drum rotation angle control, etc. can be performed very easily. In addition, there is an energy saving advantage by reducing power loss.

Of course, in the case of a washing machine combined with drying, since a motor is provided in the tub, a direct connection structure between the drum and the motor can be easily applied. However, in the case of a pure dryer that does not provide a washing function, since there is no configuration such as a tub for fixing a motor, it is not easy to implement a direct-connected dryer.

Therefore, in the case of the conventional dryer, it is not easy to apply the direct-connection type to the dryer, although it is a direct-connection type having a wide variety of advantages compared to the belt type, and structural necessity has emerged.

The present invention has been devised to solve the above-described problems, and the rotational speed of the rotor is reduced and transferred to the drum, and a driving unit is provided in which the rotational center of the rotor and the rotational center of the drum are located on a concentric shaft. It aims to provide a dryer.

In addition, the present invention has been devised to solve the above-described problems, and an object of the present invention is to provide a dryer capable of minimizing the volume of a driving unit.

In addition, the present invention has been devised in order to solve the above-described problems, and an object of the present invention is to provide a dryer in which a flow path of air supplied to a drum is improved.

In addition, the present invention has been devised to solve the above-described problems, and an object of the present invention is to provide a dryer in which a cooling flow path of a motor driving a drum is improved.

In addition, the present invention has been devised to solve the above-described problems, and an object of the present invention is to provide a dryer having an improved fixing structure for fixing a motor and a power transmission unit.

In addition, the present invention has been devised to solve the above-described problems, and an object of the present invention is to provide a dryer capable of reducing vibrations generated in a power transmission unit that transmits power of a motor.

On the other hand, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

According to the dryer according to the present invention, a drum body providing a space for storing clothes, a front cover forming a front surface of the drum body, a rear cover forming a rear surface of the drum body, and penetrating the front cover a drum provided with a drum inlet communicating with the inside of the drum body; a fixing panel spaced apart from the rear cover and having a through hole formed therein; a motor including a stator installed in the through hole and a rotor rotating by the stator; A first shaft connected to the rotor, a second shaft connected to the rear cover, and an interlocking gear for decelerating the rotational force of the first shaft and transmitting it to the second shaft, and a housing fixed to the fixing panel power transmission unit; and a driving unit bracket mounted on the through hole to limit a position where the stator is installed, and to correct the installation position of the housing so that the rotational center of the stator coincides with the rotational axis of the first shaft when the housing is installed desirable.

The driving unit bracket includes a ring-shaped ring portion overlapping the outer circumferential surface of the through-hole, fixed to the fixing panel, and supporting the stator; It is preferable to include a housing coupling part protruding inside the ring part and supporting the outside of the housing.

It is preferable that the ring portion is formed with a plurality of fastening holes to correspond to the outer circumferential surface of the through hole, and the stator passes through the fixing panel and is fixed to the fastening hole.

Preferably, the ring portion further includes a protrusion through which the through hole protrudes toward the classical panel.

A plurality of fixing protrusions extending in a radial direction with respect to the center of the housing are formed on the outer circumferential surface of the housing, and the housing fastening portion protrudes from the ring portion toward the center of the ring portion at positions corresponding to the plurality of fixing projections. It is preferable that a plurality of housing fastening jaws are formed.

It is preferable that each of the housing fastening jaws has a plurality of fixing holes, and each of the fixing protrusions has a fastening hole through which a fastening member passing through the fixing hole is inserted and fastened.

Preferably, each of the housing fastening jaws is formed with a locking protrusion extending in an insertion direction of the housing, and the housing fixing protrusion is extended in a direction crossing the locking protrusion to be supported by the locking protrusion.

Preferably, the locking protrusion is formed with a locking groove into which the housing fixing protrusion is inserted.

Preferably, the housing fixing protrusion is formed with a fixing groove into which the housing locking jaw is inserted.

Preferably, the locking protrusion has a locking groove into which the housing fixing protrusion is inserted, and the housing fixing protrusion has a fixing groove into which the locking groove is inserted.

It is preferable that at least one of the locking groove and the fixing groove is formed with an inclined surface on which an inlet side is extended.

Preferably, the locking groove and the fixing groove are inserted to cross each other as the housing rotates with respect to the center of the housing.

It is preferable that at least three or more of the fixing protrusion and the housing fastening jaw are provided in a radial direction with respect to the housing.

Preferably, the driving unit bracket supports the stator with the fixing panel interposed therebetween.

The power transmission unit includes a main driving gear formed at the end of the first shaft and transmitting power to the interlocking gear, and a driven gear formed at the end of the second shaft and receiving power from the interlocking gear, the interlocking gear comprising: It is preferable to include a first gear which is rotated by meshing with the main gear, and a second gear which is rotated coaxially with the first gear and meshed with the driven gear with a diameter smaller than that of the first gear.

According to the dryer according to the present invention, it is possible to provide a dryer equipped with a driving unit in which the rotational speed of the rotor is reduced and transmitted to the drum, and the rotational center of the rotor and the rotational center of the drum are located on the concentric shafts. there is.

In addition, according to the dryer according to the present invention, it is possible to provide a dryer capable of minimizing the volume of the driving unit.

In addition, according to the dryer according to the present invention, there is an effect that it is possible to provide a dryer in which the flow path of the air supplied to the drum is improved.

In addition, according to the dryer according to the present invention, there is an effect that it is possible to provide a dryer in which the cooling flow path of the motor driving the drum is improved.

In addition, according to the dryer according to the present invention, it is possible to provide a dryer with an improved fixing structure for fixing the motor and the power transmission unit.

In addition, according to the dryer according to the present invention, there is an effect that it is possible to provide a dryer capable of reducing vibration generated in the power transmission unit that transmits the power of the motor.

On the other hand, the effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a cross-sectional view showing a dryer according to an embodiment of the present invention.
2 is an exploded perspective view showing a dryer according to an embodiment of the present invention.
3 is an exploded perspective view illustrating a driving unit of a dryer according to an embodiment of the present invention.
4 is a cross-sectional view illustrating a driving unit of a dryer according to an embodiment of the present invention.
5 is a perspective view illustrating a gear unit of a driving unit according to an embodiment of the present invention.
6 is a simplified diagram illustrating a gear unit of a driving unit according to an embodiment of the present invention.
7 is an exploded perspective view illustrating a driving unit of a dryer according to another embodiment of the present invention.
8 is a cross-sectional view illustrating a driving unit of a dryer according to another embodiment of the present invention.
9 is a perspective view illustrating a gear unit of a driving unit according to another embodiment of the present invention.
10 is a simplified diagram illustrating a gear unit of a driving unit according to another embodiment of the present invention.
11 is a rear view showing a drive unit bracket according to an embodiment of the present invention.
12 is a perspective view showing a drive unit bracket according to an embodiment of the present invention.
13 is a rear view illustrating a cooling structure of a driving unit according to an embodiment of the present invention.
14 is a perspective view illustrating a cooling structure of a driving unit according to an embodiment of the present invention.
15 is a rear view showing a cooling structure of a driving unit according to another embodiment of the present invention.
16 is a perspective view illustrating a driving unit cooling structure according to another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When it is described that a component is "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to the other component, but another component is between each component. It will be understood that may also be "connected", "coupled" or "connected".

Hereinafter, a dryer according to an embodiment of the present invention will be described in detail.

1 is a cross-sectional view showing a dryer according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view showing the dryer according to an embodiment of the present invention.

As shown in FIG. 1, the dryer 100 includes a cabinet 1, a drum 2 that is rotatably provided inside the cabinet to provide a space for storing clothes (to be washed or dried), and the drum 2 ) by supplying high-temperature dry air (air with a temperature higher than room temperature, air with a degree of drying higher than that of indoor air) to remove moisture from clothes (3), and a driving part (D) for rotating the drum It may be provided to include.

The cabinet 1 includes a front panel 11 forming a front surface of the dryer, and a base panel 17 forming a bottom surface of the dryer. The front panel 11 is provided with an inlet 111 communicating with the drum 2 , and the inlet 111 may be provided to be closed by the door 113 .

A control panel 115 is provided on the front panel 11, and the control panel 115 includes an input unit 116 for receiving a control command from a user, and a display unit 117 for outputting information such as a control command selectable by the user. ) may be provided. The input unit 116 may be provided to include a power supply request unit for requesting power supply to the dryer, a course input unit for allowing a user to select a desired course from among a plurality of courses, and an execution request unit for requesting the start of the course selected by the user. can

The drum 2 may be provided in a cylindrical shape with an empty interior. 1 shows a cylindrical drum body 21 in which the front and rear surfaces of the drum 2 are open, a front cover 22 forming a front surface of the drum body 21, and the drum body 21. A case provided with the rear cover 23 forming the rear surface of the is shown as an example. The front cover 22 may be provided with a drum inlet 221 for communicating the inside of the drum body 21 with the outside.

The drum 2 may be rotatably fixed to at least one of the support panel 12 and the fixed panel 15. In FIG. 1, the rear cover 23 is connected to the fixed panel through the driving unit D. It is rotatably fixed to (15), and the front cover 22 is rotatably connected to the support panel 12 as an example.

The support panel 12 may be fixed to the cabinet 1 and positioned between the front panel 11 and the front cover 22 . 1 illustrates an example in which the support panel 12 is fixed to the base panel 17 and positioned between the front panel 11 and the front cover 22 . In this case, a rear surface (a surface facing the support panel) of the front panel 11 may be fixed to the support panel 12 , and a lower end thereof may be fixed to the base panel 17 .

The support panel 12 includes a support panel through-hole 122, a drum connection body 123 connecting the support panel through-hole 122 and the drum inlet 221, the support panel through-hole 122 and the A panel connecting body 126 for connecting the inlet 111 may be provided.

The support panel through-hole 122 is provided to pass through the support panel 12 and is a means for communicating the inlet 111 and the drum inlet 221 .

The drum connection body 123 may be provided as a pipe fixed to the rear surface of the support panel 12 (a surface facing the drum inlet in the space provided by the support panel). One end of the drum connecting body 123 may be provided to surround the support panel through hole 122 , and a free end of the drum connecting body 123 may be provided to support the front cover 22 . That is, the free end of the drum connection body 123 may be inserted into the drum inlet 221 or may be provided to contact the free end of the front cover 22 forming the drum inlet 221 .

1 illustrates an example in which the free end of the drum connection body 123 comes into contact with the free end of the front cover 22 . In this case, the drum connection body 123 may be provided with a ring-shaped damper 124 (connection damper). The connection damper 124 minimizes the risk of the drum inlet 221 being separated from the drum connection body 123 when the drum 2 rotates or vibrates (the risk of air inside the drum leaking into the cabinet). is a means to

The connection damper 124 may be made of a compressible material (a material whose volume can be increased or decreased by an external force). In this case, the connection damper 124 may be provided to maintain a compressed state between the free end of the drum connection body 123 and the edge of the drum inlet 221 (the free end of the front cover). When the drum 2 vibrates between the support panel 12 and the fixed panel 15 , this is to minimize the separation of the drum inlet 221 from the drum connection body 123 . A felt manufactured by compressing fibers may be an example of the connection damper 124 .

The panel connection body 126 may be provided as a pipe fixed to the front surface of the support panel 12 (a surface facing the front panel in the space provided by the support panel). One end of the panel connecting body 126 may be provided to surround the support panel through hole 122 , and the other end of the panel connecting body 126 may be provided to be connected to the inlet 111 . Accordingly, the clothes supplied to the inlet 111 enter the drum body 21 through the panel connecting body 126 , the support panel through hole 122 , the drum connecting body 123 , and the drum inlet 221 . can move

The fixing panel 15 may be fixed to the cabinet 1 so as to be positioned at a point spaced apart from the rear cover 23 . 1 illustrates an example of a case in which the fixing panel 15 is fixed to the base panel 17 to form the rear surface of the dryer 100 (the rear surface of the cabinet).

As shown in FIG. 2 , the fixing panel 15 may include a driving part mounting groove 153 providing a space for the driving part D to be mounted. The driving part mounting groove 153 is the fixing panel (15) may be provided as a groove bent concavely toward the rear cover 23 of the drum. The fixed panel 15 is provided with a fixed panel through-hole 155 through which the rotating shaft of the drum 2 passes. The fixed panel through-hole 155 may be located inside the driving unit mounting groove 153 . .

The support panel 12 is provided with a drum exhaust port (first exhaust port, 128) penetrating the panel connection body 126, and the fixed panel 15 has a panel exhaust port (second exhaust port, 157) and a supply port ( 158) may be provided.

The supply port 158 may be provided by a plurality of supply holes provided to pass through the fixing panel 15 so as to surround the driving unit mounting groove 153 (the plurality of supply holes surrounding the driving unit mounting groove) may be provided. may be provided to form a ring).

As shown in FIG. 1 , the supply unit 3 supplies the air discharged to the exhaust duct 31 connecting the first exhaust port 128 and the second exhaust port 157 and the second exhaust port 157 to the It may be provided to include a supply duct 32 guiding to the supply port 158 and a heat exchange unit 34 provided in the exhaust duct to sequentially dehumidify and heat air. A filter 129 for filtering air moving from the drum 2 to the exhaust duct 31 may be provided in the first exhaust port 128 .

The exhaust duct 31 includes a first duct 311 connected to the first exhaust port 128 , a second duct 312 connected to the second exhaust port 157 , and the first duct 311 and the second duct It may be provided to include a third duct 313 connecting the 312 . The third duct 313 may be fixed to the base panel 17 .

A fan 315 for moving the air inside the drum 2 to the second exhaust port 157 may be provided in the exhaust duct 31 . In FIG. 1 , the fan 315 is the heat exchange unit 34 ) and the second duct 312 shows a case where it is located.

The heat exchange unit 34 may be provided with various devices capable of sequentially dehumidifying and heating the air introduced into the exhaust duct 31. In FIG. 1 , the heat exchange unit 34 is a heat pump. ) is shown as an example.

That is, the heat exchange part 34 of FIG. 1 is provided inside the first heat exchanger (heat absorbing part, 341) for removing moisture from the air introduced into the exhaust duct 31, and the exhaust duct 31 to absorb the heat. It includes a second heat exchanger (heating unit, 343) for heating the air that has passed through the unit (341).

The heat absorbing part 341 and the heat generating part 343 are sequentially arranged along the moving direction of the air, and are connected to each other through a refrigerant pipe 349 forming a circulation path of the refrigerant. The refrigerant moves along the refrigerant pipe 349 by the compressor 345 located outside the exhaust duct 31 , and the refrigerant pipe 349 includes the heat absorbing part 341 from the heat generating part 343 . A pressure regulator 347 for adjusting the pressure of the refrigerant moving to the

The heat absorbing part 341 is a means for cooling the air (evaporating the refrigerant) by transferring heat of the air introduced into the exhaust duct 31 as a refrigerant, and the heat generating part 343 passes through the compressor 345 . It is a means of heating the air (condensing the refrigerant) by transferring the heat of a refrigerant to the air.

As shown in FIG. 2 , the supply duct 32 is fixed to the fixing panel 15 and guides the air discharged through the second exhaust port 157 to the supply port 158 .

When the supply port 158 is provided with a plurality of supply holes arranged in a ring shape, the supply duct 32 is fixed to the fixing panel 15 so that the second exhaust port 157 and the supply port 158 are provided. It may be provided to include a duct body 321 forming a flow path connecting the ducts, and a rotor accommodating part 322 provided to pass through the duct body 321 . The driving part D fixed to the driving part mounting groove 153 is exposed to the outside of the supply duct 32 by the rotor receiving part 322 .

An air inlet ( 233 ), and the fixing panel 15 may be provided with a flow path forming part 159 for guiding the air discharged from the supply port 158 to the air inlet 233 .

The air inlet 233 may be provided by disposing a plurality of holes passing through the rear cover 23 to form a ring surrounding the center of rotation of the drum 2 . The flow path forming part 159 may be provided with a pipe that has one end (one end fixed to the fixed panel) surrounding the supply port 158 and the other end (one end contacting the drum) surrounding the air inlet. In order to minimize the transmission of vibrations generated when the drum 2 is rotated to the fixed panel 15 , the flow path forming part 159 may be made of a material (such as rubber) having high elasticity.

The driving unit D may be provided to include a motor 5 fixed to the driving unit mounting groove 153 , and a power transmission unit 6 transmitting power generated by the motor to the drum 2 . .

In order to minimize deformation of the fixing panel 15 by the weight of the driving unit D and external force generated during operation of the driving unit D, the motor 5 is fixed to the driving unit mounting groove 153 A drive bracket 4 providing space may be provided. The driving unit bracket 4 may be made of a ring-shaped metal (metal having a strength greater than that of the fixing panel) fixed to the driving unit mounting groove 153 .

As shown in FIG. 2 , the motor 5 includes a stator 51 fixed to the driving unit bracket 4 to form a rotating field, and a rotor 52 rotating by the rotating magnetic field. provided to include.

The stator 51 includes a core 511 fixed to the driving unit bracket 4 , a core through hole 512 provided to penetrate the core 511 , and a circumferential surface of the core 511 at equal intervals. It may be provided to include the disposed electromagnet 513 .

The rotor 52 has a disk-shaped rotor body 52a, a pipe-shaped rotor circumferential surface 52b fixed to the rotor body 52a, and a plurality of permanent magnets fixed to the rotor circumferential surface ( 525) is provided. The permanent magnets 525 are fixed to the rotor circumferential surface 52b so that N poles and S poles are alternately exposed.

The power transmission unit 6 is for decelerating or accelerating the rotational force of the motor 5 and transmitting it to the drum 2 . Hereinafter, the power transmission unit 6 of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 3 to 4 , the power transmission unit 6 according to an embodiment of the present invention has a housing 60a fixed to the fixing panel 15, one end of which is provided in a housing shape with an empty interior. is connected to the rotor body 52a and the other end is located inside the housing 60a, the first shaft 63a on which the main driving gear 631a is formed, and the main driving gear 631a of the first shaft 63a. A driven gear 65a including a plurality of interlocking gears 64a meshed and rotatably positioned inside the housing 60a, and a second shaft 652a fitted to the interlocking gear and connected to the rear cover 23 ) can be provided.

The first shaft 63a is for transmitting the rotational force of the rotor 52 to the interlocking gear 64a. The first shaft 63a may be provided with a main driving gear 631a located inside the housing 60a. The first shaft 63a may extend from the main driving gear 631a to the outside of the housing 60a and be connected to the rotor body 52a.

When the first shaft 63a is directly connected to the rotor body 52a, deformation may occur between the first shaft 63a and the rotor body 52a, and in order to prevent deformation of the rotor body 52a, The first shaft 63a may be fixed to the rotor body 52a through a fixing plate 524 . The fixing plate 524 is fixed to the rotor body 52a to reinforce the strength of the rotor body 52a.

A main gear shaft 632a inserted into the first shaft hole 653a of the driven gear 65a is formed at an end of the main driving gear 631a. The main gear shaft 632a and the first shaft hole 653a are formed so that the rotation center of the first shaft 63a and the rotation center of the driven gear 65a coincide with each other. That is, the main driving gear 631a of the first shaft 63a and the second shaft 652a of the driven gear 65a may be positioned on the same rotation shaft and rotated.

The driven gear 65a is formed such that the driven gear body 651a meshed with the interlocking gear 64a and the main driven gear shaft 632a of the first shaft 63a are inserted into the center of the rotation axis of the driven gear body 651a. It may be provided with a first shaft hole (653a) and a first shaft hole bearing (654a) provided in the first shaft hole (653a) to rotatably support the main gear shaft (632a).

The first shaft 63a and the driven gear 65a may be rotatably coupled to each other in a coaxial state by inserting the main driven gear shaft 632a into the first shaft hole 653a. The coaxial coupling of the first shaft 63a and the driven gear 65a can prevent eccentricity when the first shaft 63a and the driven gear 65a rotate.

The second shaft 652a is for transmitting the rotational force of the interlocking gear 64a to the drum 2 . The second shaft 652a may extend from the driven gear 65a provided inside the housing 60a and receiving power from the interlocking gear 64a. That is, the second shaft 652a may extend in the outer direction (ie, the drum 2 direction) of the housing 60a around the rotation axis of the driven gear 65a.

The second shaft 652a may be integrally formed with the driven gear 65a. The second axis 652a is preferably provided to form a concentric axis with the first axis 63a. If the second shaft 652a and the first shaft 63a are provided to form concentric shafts, vibration generated in the power transmission unit 6 when the drum 2 is rotated may be minimized.

Preferably, the housing 60a is fixed to the fixing panel 15 and positioned in the core through-hole 512 . By minimizing the volume of the housing 60a, the volume of the driving unit D may be minimized.

The housing 60a includes a first housing 61a having an open surface facing the fixing panel 15, and a second housing 62a closing the open surface of the first housing of the first housing 61a. ) may be included.

A first shaft support portion 611a and a first shaft through hole 612a penetrating the first shaft support portion 611a may be provided in the first housing 61a. The first shaft 63a is inserted into the first shaft through hole 612a to pass through the first housing 61a, and the first shaft 63a is connected to the first shaft support part 611a. A first shaft bearing 613a rotatably fixed to the first housing 61a may be provided.

The first shaft support part 611a may be provided in the form of a boss protruding from the first housing 61a toward the rotor body 52a, and the second housing 62a in the first housing 61a. It may be provided in the form of a boss protruding toward the

The first shaft support part 611a is a boss that protrudes from the first housing 61a toward the second housing 62a (a form that protrudes from the first housing 61a toward the center of the housing 60a) When provided, there is an effect capable of minimizing the volume of the housing 60a (minimization of the volume of the driving part D, the effect of minimizing the volume of the dryer).

The second housing 62a may include a second shaft support portion 621a and a second shaft through-hole 622a penetrating the second shaft support portion 621a. The second shaft 652a passes through the second housing 62a through the second shaft through hole 622a, and the second shaft 652a is connected to the second shaft support part 621a. A second shaft bearing 623a rotatably fixed to the housing 62a may be provided. As the second shaft 652a is rotatably supported by the second shaft bearing 623a, the driven gear 65a may be rotatably supported inside the housing 60a.

The second shaft support portion 621a may be provided as a boss (protruding toward the rear cover 23 of the drum 2) from the second housing 62a to the fixing panel through-hole 155. can

The first shaft bearing 613a may be provided as a pair arranged in parallel in the longitudinal direction of the first shaft 63a in the first shaft support part 611a. The second shaft bearing 623a may be provided as a pair in the second shaft support portion 621a in parallel in the longitudinal direction of the second shaft 652a.

When the first shaft bearing 613a and the second shaft bearing 623a are provided with two or more bearings, respectively, when the rotor 52 rotates, the first shaft 63a and the second shaft 652a are There is an effect that can minimize the eccentricity. That is, when the first shaft bearing 613a and the second shaft bearing 623a are provided in plurality, when the first shaft 63a and the second shaft 652a rotate, the first shaft 63a and the second shaft ( 652a) can minimize the occurrence of eccentricity during rotation.

If the volume of the driving part D is large, it is difficult to increase the number of bearings. The dryer 100 has a structure in which the housing 60a is located in the core through hole 512 of the stator 51, and the first shaft Since the volume of the driving part can be minimized through the boss structure in which the support part 611a protrudes toward the center of the housing 60a, the number of the first shaft bearing 613a and the second shaft bearing 623a can be increased. can

In order to minimize the volume of the housing 60a, the diameter of the first housing 61a and the diameter of the second housing 62a may be set differently. That is, the diameter of the first housing 61a may be set to be smaller than the diameter of the second housing 62a, or may be set to be longer than the diameter of the second housing 62a. In order to minimize the volume of the housing 60a, the first and second housings 61a and 62a may have a cylindrical shape corresponding to the core through hole 512 .

Alternatively, the outer shape of the first housing 61a and the second housing 62a may be formed to correspond to the outer shape of the interlocking gear 64a according to the number of interlocking gears 64a provided in the housing 60a. there is.

Specifically, a plurality of interlocking gears 64a may be provided around a first shaft 63a and a second shaft 652a coaxially provided to the first shaft 63a. When three or more interlocking gears 64a are provided in plurality, the outer surface formed by the interlocking gears 64a may be formed in a polygonal shape. Therefore, the housing 60a formed of the first housing 61a and the second housing 62a may be formed in a triangular shape when three interlocking gears 64a are configured according to the number of interlocking gears 64a, When the interlocking gear 64a consists of four, it may be formed in a rectangular shape.

The housing 60a may be fixed by the driving unit bracket 4 fastened to the driving unit mounting hole 153 of the fixing panel 15 . The driving unit bracket 4 may have an outer peripheral surface formed to correspond to the driving unit mounting hole 153 , and an inner peripheral surface formed to correspond to the outer shape of the housing 60a.

The interlocking gear 64a is rotatably provided by a connecting shaft 625a positioned between the first housing 61a and the second housing 62a. The connecting shafts 625a may be provided to correspond to the number of interlocking gears 64a.

In the power transmission unit according to an embodiment of the present invention, a case in which the interlocking gear 64a and the connecting shaft 625a are provided with three gears and shafts spaced apart by 120 degrees will be described as an example.

Each of the interlocking gears 64a is provided on a circumferential surface of a first body 641a rotatably fastened to the connection shaft 625a through the connection shaft 625a, and the first body 641a, A first gear 642a meshed with the main driving gear 631a of the first shaft 63a, a second body fixed to the first body 641a and having a diameter smaller than the diameter of the first body 641a ( 643a), and a second gear 644a provided on the circumferential surface of the second body 643a and coupled to the driven gear 65a provided with the second shaft 652a.

Inside the first housing 61a and the second housing 62a, a first connection shaft hole (not shown) for fixing the connection shaft 625a and a second connection shaft hole 624a are to be formed at opposite positions. can A bearing (not shown) for rotatably supporting the connecting shaft 625a may be provided in the first connecting shaft hole and the second connecting shaft hole 624a.

A second shaft 652a provided in the driven gear 65a may be inserted into the fixing panel through-hole 155 to connect the rear cover 23 of the drum 2 . In order to prevent damage to the rear cover 23 due to the rotation of the second shaft 652a, a separate shaft bracket (not shown) to which one end of the second shaft 652a is fixed to the rear cover 23 . ) may be provided.

4 , the main driving gear 631a of the first shaft 63a may be provided to be positioned in a space formed between the first gears 642a. In addition, the free end of the first shaft support part 611a may be inserted into the first shaft through hole 612a formed in the center of the first housing 61a to pass through the housing 60a. Such a structure (the structure of the first shaft support part 611a and the first housing 61a) can minimize the volume of the housing 60a.

In order to seal the fixing panel through-hole 155 (to prevent the air supplied to the drum 2 from leaking to the outside of the cabinet 1), the driving unit bracket 4 or the fixing panel 15 The sealing part 41 may be further provided. The driving unit bracket 4 is provided in a ring shape surrounding the fixing panel through-hole 155 , the ring-shaped core 511 is fixed to the driving unit bracket 4 , and the housing 60a is the core When positioned in the through hole 512 , the sealing part 41 may be provided to seal a space formed between the driving part bracket 4 and the second housing 62a.

The operation process of the driving unit D having the above-described structure is as follows. 6, when the rotor 52 rotates clockwise, the first shaft 63a and the main driving gear 631a will also rotate clockwise.

When the main driving gear 631a rotates clockwise, the interlocking gears 64a will rotate counterclockwise by the first gear 642a. When the first gear 642a rotates counterclockwise, the second gear 644a also rotates counterclockwise.

Here, since the interlocking gear 64a is rotatably supported inside the housing 60a, when the second gear 644a rotates counterclockwise, the driven gear 65a rotates clockwise. will be.

Since the drum 2 and the driven gear 65a are connected through the second shaft 652a, the drum 2 will rotate in the same direction as the rotor 52 .

As shown in the drawing, the diameter of the first gear 642a is set to be larger than the diameter of the main gear 631a, and the diameter of the second gear 644a is larger than the diameter of the first gear 642a. It can be set small.

When the first gear 642a, the second gear 644a, and the main gear 631a are provided as described above, the driving unit D operates at a lower rotation speed than that of the rotor 52 and the drum ( 2) can be rotated. That is, the driving unit D may also serve as a speed reducer.

The interlocking gear 64a provided with the first gear 642a and the second gear 644a as described above, and the main driving gear 631a and the second gear 644a meshed with the first gear 642a are meshed with each other. The driven gear 65a being the first gear 642a and the second gear 644a of the interlocking gear 64a are respectively arranged in parallel to the main driven gear 631a inside the housing 60a, the interlocking gear 64a, It is possible to minimize the installation volume of the driven gear (65a).

In addition, the first gear 642a and the second gear 644a of the interlocking gear 64a are respectively meshed with the driven gear 65a of the first shaft 631a and the second shaft 652a. When the rotation of the first shaft 63a is transmitted from the interlocking gear 64a to the driven gear 65a by coupling the first shaft 63a and the second shaft 652a in a coaxial state, the first shaft 63a It is possible to prevent the occurrence of eccentricity between and the driven gear (65a).

Hereinafter, a power transmission unit according to another embodiment of the present invention will be described in detail with reference to the accompanying drawings.

7 to 10, the power transmission unit 6 according to another embodiment of the present invention is provided in a housing shape with an empty interior and is fixed to the fixing panel 15 by a housing 60b, One end is connected to the rotor body 52a and the other end is located inside the housing 60b, the first shaft 63b on which the main driving gear 631b is formed, the main driving gear 631b of the first shaft 63b) A driven gear including a plurality of interlocking gears 64b meshed with and rotatably positioned inside the housing 60b, and a second shaft 652b fitted to the interlocking gear and connected to the rear cover 23 ( 65b) and a carrier 67b fixed to the housing 60b by rotatably supporting the first shaft 63b, the interlocking gear 64b, and the driven gear 65b.

Preferably, the housing 60b is fixed to the fixing panel 15 and positioned in the core through-hole 512 . By minimizing the volume of the housing 60b, the volume of the driving unit D may be minimized.

The housing 60b includes a first housing 61b having an open surface facing the fixing panel 15, and a second housing 62b for closing the open surface of the first housing of the first housing 61b. ) may be included.

A first shaft through hole 612b through which the first shaft 63b is exposed may be provided in the first housing 61b. The first shaft 63b is inserted into the first shaft through hole 612b to pass through the first housing 61b, and may be connected to the rotor body 52a.

A second shaft through hole 622b through which the second shaft 652b is exposed may be provided in the second housing 62b. The second shaft 652b passes through the second housing 62b by inserting the second shaft through hole 622b, and may be connected to the rear cover 23 of the drum.

The housing 60b may be fixed by the driving unit bracket 4 fastened to the driving unit mounting hole 155 of the fixing panel 15 . It may be formed to correspond to the driving unit mounting hole 155 of the outer peripheral surface of the driving unit bracket 4, and the inner peripheral surface may be formed to correspond to the outer shape of the housing 60b.

The outer shape of the first housing 61b and the second housing 62b may be formed to correspond to the outer shape of the interlocking gear 64b according to the number of interlocking gears 64b provided in the housing 60b. there is.

Specifically, a plurality of interlocking gears 64b may be provided around a first shaft 63b and a second shaft 652b coaxially provided to the first shaft 63b. When three or more interlocking gears 64b are provided in plurality, the outer surface formed by the interlocking gears 64b may be formed in a polygonal shape. Therefore, the housing 60b formed of the first housing 61b and the second housing 62b may be formed in a triangular shape when three interlocking gears 64b are configured according to the number of interlocking gears 64b, When the interlocking gear 64b is composed of four, it may be formed in a rectangular shape.

Between the first housing 61b and the carrier 67b and between the second housing 62b and the carrier 67b, a first shaft 63b inside the carrier 67b, an interlocking gear 64b, A first carrier damper 613b formed in a ring shape to prevent vibration and noise generated during driving of the driven gear 65b from being transmitted to the first and second housings 61b and 62b; A carrier damper 623b may be provided.

The carrier 67b is to rotatably support the first shaft 63b, the interlocking gear 64b, and the driven gear 65b, respectively, and to be fastened to the housing 60b.

The carrier 67b is a driven gear having a first shaft 63b and a second shaft 652b by separately fastening the first shaft 63b, the interlocking gear 64b, and the driven gear 65b. 65b) to prevent eccentricity between them and to be fixed to the housing 60b. The carrier 67b can improve the assembly of the power transmission unit 6 and prevent eccentricity between the first shaft 63b, the interlocking gear 64b, and the driven gear 65b.

The carrier 67b is positioned toward the inner surface of the first housing 61b and includes a carrier cover 671b on which the first shaft 63b is rotatably supported, and the inner surface of the second housing 62b. and a carrier base 676b positioned toward the second shaft 652b to rotatably support the second shaft 652b.

An interlocking gear 64b may be rotatably provided between the carrier cover 671b and the carrier base 676b. The carrier cover 671b is provided with a plurality of connecting shafts 675b into which the interlocking gear 64b is rotatably inserted. A plurality of connecting shaft grooves 675b into which the connecting shaft 675b is inserted are formed in the carrier base 676b.

The carrier cover 671b may include a first shaft support part 673b and a first shaft support hole 672b penetrating the first shaft support part 673b. The first shaft 63b passes through the carrier cover 671b by being inserted into the first shaft through-hole 612b, and the first shaft 63b is connected to the first shaft support part 673b with the carrier. A first shaft bearing 674b rotatably fixed to the cover 671b may be provided.

The first shaft support part 673b may be provided in the form of a boss that protrudes from the carrier cover 671b toward the carrier cover 671b, and protrudes from the carrier cover 671b toward the carrier base 676b. It may be provided in the form of a boss.

When the first shaft support portion 673b is provided as a boss protruding from the carrier cover 671b toward the carrier base 676b, the volume of the carrier 67b can be minimized.

The carrier base 676b may include a second shaft support portion 677b and a second shaft support hole 678b penetrating the second shaft support portion 677b. The second shaft 652b passes through the carrier base 676b through the second shaft support hole 678b, and the second shaft 652b is connected to the carrier base in the second shaft support part 677b. A second shaft bearing 679b rotatably fixed to the 676b may be provided.

The second shaft support part 677b may be provided as a boss protruding from the carrier base 676b toward the second housing 62b, and a boss protruding from the carrier base toward the carrier cover 671b. It may be provided in the form.

The first shaft bearing 674b may be provided as a pair arranged in parallel in the longitudinal direction of the first shaft 63b in the first shaft support part 673b. The second shaft bearings 679b may be provided as a pair arranged in parallel in the longitudinal direction of the second shaft 652b in the second shaft support part 677b.

When the first shaft bearing 674b and the second shaft bearing 679b are provided with two or more bearings, respectively, when the rotor 52 rotates, the first shaft 63b and the second shaft 652b There is an effect that can minimize the eccentricity. That is, when the first shaft bearing 674b and the second shaft bearing 679b are provided in plurality, the first shaft 63b and the second shaft 652b are rotated when the first shaft 63b and the second shaft 652b are rotated. 652b) can minimize the occurrence of eccentricity during rotation.

The first shaft 63b is for transmitting the rotational force of the rotor 52 to the interlocking gear 64b. The first shaft 63b may be provided with a main driving gear 631b located inside the carrier 67b. The first shaft 63b extends from the main driving gear 631b located inside the carrier 67b and is rotatably supported by the first shaft support part 673b of the carrier cover 671b, It may extend to the outside of the housing 60b through the uniaxial through-hole 612b and be connected to the rotor body 52a.

When the first shaft 63b is directly connected to the rotor body 52a, deformation may occur between the first shaft 63b and the rotor body 52a, and in order to prevent deformation of the rotor body 52a, the The first shaft 63b may be fixed to the rotor body 52a through a fixing plate 524 . The fixing plate 524 may be fixed to the rotor body 52a to reinforce the strength of the rotor body 52a.

A main gear shaft 632b inserted into the first shaft hole 653b of the driven gear 65b is formed at an end of the main driving gear 631b. The main gear shaft 632b and the first shaft hole 653b are formed so that the rotation center of the first shaft 63b and the rotation center of the driven gear 65b coincide with each other. That is, the main driving gear 631b of the first shaft 63b and the second shaft 652b of the driven gear 65b may be positioned on the same rotation shaft and rotated.

The driven gear 65b is formed such that the driven gear body 651b meshed with the interlocking gear 64b and the main driven gear shaft 632b of the first shaft 63b are inserted into the center of the rotation axis of the driven gear body 651b. It may be provided with a first shaft hole (653b) and a first shaft hole bearing (654b) provided in the first shaft hole (653b) to rotatably support the main gear shaft (632b).

The first shaft 63b and the driven gear 65b may be rotatably coupled to each other in a coaxial state by the main driven gear shaft 632b being inserted into the first shaft hole 653b. The coaxial coupling between the first shaft 63b and the driven gear 65b can prevent eccentricity when the first shaft 63b and the driven gear 65b rotate.

The second shaft 652b is for transmitting the rotational force of the interlocking gear 64b to the drum 2 . The second shaft 652b may extend from the driven gear 65b provided inside the carrier 67b to receive power from the interlocking gear 64b. That is, the second shaft 652b is rotatably supported by the second shaft support portion 677b of the carrier base 676b and extends to the outside of the housing 60b through the second shaft through hole 622b. can be

Preferably, the second axis 652b is provided to form a concentric axis with the first axis 63b. If the second shaft 652b and the first shaft 63b are provided to form concentric shafts, vibration generated in the power transmission unit 6 when the drum 2 is rotated may be minimized.

The second shaft 652b may extend in the outward direction of the carrier 67b (ie, the drum 2 direction) around the rotation axis of the driven gear 65b. The second shaft 652b may be integrally formed with the driven gear 65b.

The second shaft 652b is extended from the driven gear 65b located inside the carrier 67b and is rotatably supported by the second shaft support portion 677b of the carrier base 676b, It may extend to the outside of the housing through the two-axis through-hole 622b and be connected to the rear cover 23 .

The interlocking gear 64b may be rotatably provided between the carrier cover 671b and the carrier base 676b by a connecting shaft 675b provided in the carrier 67b. The connecting shafts 675b may be provided to correspond to the number of interlocking gears 64b.

In the power transmission unit according to another embodiment of the present invention, a case in which the interlocking gear 64b and the connecting shaft 675b are provided with three gears and shafts spaced apart by 120 degrees will be described as an example.

A plurality of connecting shafts 675b extending toward the carrier base 676b may be provided on the carrier cover 671b. A connection shaft groove 675b into which the connection shaft 675b is inserted is formed in the carrier base 676b. A bearing (not shown) for rotatably supporting the interlocking gear 64b may be provided between the connecting shaft 675b and the interlocking gear 64b.

Each of the interlocking gears 64b is provided on the circumferential surface of the first body 641b and the first body 641b that are rotatably fastened to the connecting shaft 675b through the connecting shaft 675b. A first gear 642b meshed with the main driving gear 631b of the first shaft 63b, a second body fixed to the first body 641b and having a smaller diameter than the diameter of the first body 641b ( 643b), and a second gear 644b provided on the circumferential surface of the second body 643b and coupled to the driven gear 65b provided with the second shaft 652b.

A second shaft 652b provided in the driven gear 65b may be inserted into the fixing panel through-hole 155 to connect the rear cover 23 of the drum 2 . In order to prevent damage to the rear cover 23 due to the rotation of the second shaft 652b, the rear cover 23 includes a shaft bracket (not shown) to which one end of the second shaft 652b is fixed. can be provided.

9 to 10 , the main driving gear 631b of the first shaft 63b may be provided to be positioned in a space formed between the first gears 642b. In addition, the free end of the first shaft support part 673b is inserted into the first shaft support hole 672b formed in the center of the carrier cover 671b to form the first shaft through hole 612b of the housing 60b. It may be provided to penetrate. This structure can minimize the volume of the carrier 67b and the housing 60b.

In order to seal the fixing panel through-hole 155 (to prevent the air supplied to the drum 2 from leaking to the outside of the cabinet 1), the driving unit bracket 4 or the fixing panel 15 The sealing part 41 may be further provided. The driving unit bracket 4 is provided in a ring shape surrounding the fixing panel through-hole 155 , the ring-shaped core 511 is fixed to the driving unit bracket 4 , and the housing 60b is the core When positioned in the through hole 512 , the sealing part 41 may be provided to seal the space formed between the driving part bracket 4 and the second housing 62b.

The operation process of the driving unit D having the above-described structure is as follows. 10, when the rotor 52 rotates clockwise, the first shaft 63b and the main driving gear 631b will also rotate clockwise.

When the main driving gear 631b rotates clockwise, the interlocking gears 64b will rotate counterclockwise by the first gear 642b. When the first gear 642b rotates counterclockwise, the second gear 644b also rotates counterclockwise.

Here, since the interlocking gear 64b is rotatably supported inside the housing 60b, when the second gear 644b rotates counterclockwise, the driven gear 65b rotates clockwise. will be.

Since the drum 2 and the driven gear 65b are connected through the second shaft 652b, the drum 2 will rotate in the same direction as the rotor 52 .

As shown in the drawing, the diameter of the first gear 642b is set to be larger than the diameter of the main gear 631b, and the diameter of the second gear 644b is larger than the diameter of the first gear 642b. It can be set small.

When the first gear 642b, the second gear 644b, and the main gear 631b are provided as described above, the driving unit D operates the drum ( 2) can be rotated. That is, the driving unit D may also serve as a speed reducer.

As described above, the power transmission unit 6 according to another embodiment of the present invention meshes with the interlocking gear 64b provided with the first gear 642b and the second gear 644b, and the first gear 642b. The driven gear 65b meshed with the main driving gear 631b and the second gear 644b is disposed in parallel to the first gear 642b and the second gear 644b of the interlocking gear 64b, respectively, and the housing 60b ) It is possible to minimize the installation volume of the internal main driven gear (631b), the interlocking gear (64b), and the driven gear (65b).

In addition, the first gear 642b and the second gear 644b of the interlocking gear 64b are meshed with the driven gear 65b in which the first shaft main driven gear 631b and the second shaft 652b are formed, respectively. In the first shaft (63b) and the second shaft (652b) are coupled to the inside of the carrier (67b) in a coaxial state, the rotation of the first shaft (63b) is transmitted from the interlocking gear (64b) to the driven gear (65b) It is possible to prevent the occurrence of eccentricity between the first shaft (63b) and the driven gear (65b).

In addition, the first shaft 63b provided with the main driven gear 631b, the interlocking gear 64b, and the driven gear 65b provided with the second shaft 652b are assembled in the carrier 67b. It is fastened to the inside of the housing 60b, and the housing 60b is fixed to the fixing panel 15 by the driving unit bracket 4, thereby simplifying the assembly process of the driving unit D.

As shown in FIGS. 11 to 12, the driving unit bracket 4 is configured to minimize deformation of the fixing panel 15 by the weight of the driving unit D and external force generated during operation of the driving unit D. , is fastened to the driving unit mounting groove 153 .

The motor 5 fixed to the driving unit bracket 4 and the power transmission unit 4 may be coupled to each other by the driving unit D to have a coaxial rotation axis. That is, the power transmission unit 6 is fastened to the central portion of the driving unit bracket 4, and the outer portion of the stator 51 is fastened to the outer portion of the driving unit bracket 4 by a separate fastening member (not shown). can

The driving unit bracket 4 has a motor fastening hole 421 fastened to the stator 51 with the fixing panel 15 interposed therebetween and a ring forming an installation space for the housings 60a and 60b in the central portion. A ring-shaped ring portion 42 and a housing coupling portion 43 protruding from an inner circumferential surface of the ring portion 42 to receive and fix the housings 60a and 60b may be formed.

The motor fastening hole 421 may further include a protrusion 422 protruding toward the stator 51 from the rear of the fixing panel 15 to form a fastening tolerance with the stator 51 . The motor fastening hole 421 may be formed in the protrusion 422 . Accordingly, the driving unit bracket 4 and the stator 51 may be fastened to the fixing panel 15 in the order of the protrusion 422 , the driving unit mounting groove 155 , and the stator 51 .

A housing fixing protrusion 68a corresponding to the housing coupling part 43 may protrude from an outer surface of the housing 60a and 60b of the power transmission part 6 . The housing fixing protrusion 68a is formed with the same radius around the rotation axis of the second shafts 652a and 652b of the housings 60a and 60b. A housing fixing hole 69a into which a separate fastening member (not shown) is inserted is formed in the housing fixing protrusion 68a.

The housing fastening part 43 and the housing fixing protrusion 68a may be provided in plurality to correspond to each other. The housing fastening part 43 and the housing fixing protrusion 68a may be provided in at least three pairs, respectively.

Both the motor fastening hole 421 and the housing fastening part 43 may be disposed to have the same radius around the second axis of rotation of the housings 60a and 60b. Accordingly, the stator 51 of the motor 5 fastened to the motor fastening hole 421 and the second shafts 652a and 652b of the housings 60a and 60b fastened to the housing fastening part 43 have the same center. It may be fastened to the drive unit bracket 4 to have a shaft.

The housing coupling part 43 includes a housing coupling jaw 431 protruding from the inner circumferential surface of the ring part 42 and a locking protrusion bent in the opposite direction into which the housings 60a and 60b are inserted from the housing coupling jaw 431 . (433) is provided.

In the housing fastening part 43, the front surfaces of the second housings 60a and 60b are seated, and a housing fastening hole 432 corresponding to the housing fixing hole 69a of the housing fixing protrusion 68a is formed. . The housing fastening hole 432 and the housing fixing hole 69a may be fixed by inserting a separate fastening member.

The locking protrusion 433 is formed with a locking groove 434 into which the housing fixing protrusion 68a is inserted. The locking groove 434 is formed in the lateral direction of the locking protrusion 433, and after the housings 60a and 60b are seated on the driving unit bracket 4, the center of the housings 60a and 60b is a reference. As it rotates, the housing fixing protrusion 68a may be formed to be inserted into the locking groove 434 .

A housing fixing groove 69b may be formed in the housing fixing protrusion 68a at a position corresponding to the locking groove 434 . As the housing fixing groove 69b is inserted in a direction crossing the locking groove 434 , the housings 60a and 60b may be fixed to the driving unit bracket 4 .

The housing fixing groove 69b may be formed in the form of an inclined surface in which an inlet side is extended. As the housing fixing groove 69b is cross-inserted into the locking groove 434, the more the housing fixing groove 69b moves from the inlet side of the housing fixing groove 69b to the inside of the housing fixing groove 69b, the The position may be fixed while being moved to the center of the driving unit bracket (4).

The strength of the fixing panel 15 can be reinforced by being fastened to the driving unit mounting hole 155 of the driving unit bracket 4 . At the same time, when the housings 60a and 60b are fastened to the driving unit bracket 4 , the installation position of the housings 60a and 60b may be corrected to the center of the driving unit bracket 4 . In addition, by fastening the stator 51 of the motor 5 and the housings 60a and 60b of the power transmission unit 6 to the driving unit bracket 4, the motor 5 and the power transmission unit ( 6) can be coaxially aligned with the axis of rotation.

A plurality of supply holes 158a and 158b arranged in a ring shape may be provided in the rear cover 23 of the drum 2 . 2 and 13, the dryer 100 further includes a flow path guide 324 for evenly supplying the air discharged from the second exhaust port 157 to the supply holes 158a and 158b. can be

Since air moves to a side with a small flow resistance, in the case of the dryer 100 without the flow guide 324 , the air introduced into the duct body 321 through the second exhaust port 157 moves in a clockwise direction. Accordingly, the amount of moving the inside of the duct body 321 and the amount of moving the inside of the duct body 321 in the counterclockwise direction tend to be different from each other.

For example, if the amount of air moving inside the duct body 321 along the clockwise direction is greater than the amount of air moving inside the duct body 321 along the counterclockwise direction, the supply located on the left side of the reference line L A large amount of air is supplied to the holes 158a, but a small amount of air is supplied to the supply holes 158b located on the right side of the reference line L.

The above-described imbalance in the air supply amount may cause an imbalance in the amount of air supplied to the clothes in the drum 2 . That is, a phenomenon in which the amount of supplied air varies depending on the location of the clothes may cause a problem in that the drying time increases, and some clothes become overdried and some clothes become undried.

The flow guide 324 solves the above-mentioned problem by maintaining the same or similar amount of air moving inside the duct body 321 along the clockwise direction and the amount of air moving inside the duct body along the counterclockwise direction. can be solved That is, some of the air introduced into the duct body 321 by the flow guide 324 moves to the supply holes 158a located on the left side with respect to the flow guide 324, and the rest of the air moves to the flow path. This is because the guide 324 will move to the supply holes 158b located on the right side.

Since the dryer 100 having the above structure has a structure in which the duct body 321 surrounds the motor 5 (since the motor is located inside the rotor receiving part), there is a possibility that the motor 5 is overheated. there is.

For effective cooling of the motor 5 (specifically, cooling of the stator 51 ), the dryer 100 may further include a cooling passage 35 .

13 to 14 show a cooling passage 35 according to an embodiment of the present invention. As shown, the cooling passage 35 according to an embodiment is for cooling the motor 5 by circulating the air inside the cabinet 1 with the motor 5 .

The cooling passage 35 includes a first cooling hole 236 formed to penetrate the inside of the cabinet 1 at the lower portion of the rear cover 23 , and the cabinet 1 at the upper portion of the rear cover 23 . A second cooling hole 237 formed to penetrate through the inside, and the first cooling hole 236 , the second cooling hole 237 and the rotor accommodating part 322 fixed to the outside of the duct body 321 . ) may be provided with a duct cover 36 connected to communicate.

The first cooling hole 236 and the second cooling hole 237 penetrate the rear cover 23 to circulate the air in the rotor accommodating part 322 and the air inside the cabinet 1 to circulate the air inside the rotor. The motor 5 of the accommodating part 322 may be cooled.

The duct cover 36 includes a cover plate 361a covering the rotor accommodating part 322 and a first cooling duct 362a extending from the lower portion of the cover plate 361a to the first cooling hole 236; , a second cooling duct 363a extending from an upper portion of the cover plate 361a to the second cooling hole 237 may be provided.

That is, the duct cover 36 is fastened to the outside of the duct body 321 , so that the air inside the cabinet 1 is cooled through the first cooling hole 236 , the rotor accommodating part 322 , and the first cooling. A flow path that can be moved to the hole 236 may be formed.

The air inside the cabinet 1 uses the heat exchange unit 34 and the supply duct 32 to form a relatively lower temperature than the air for drying clothes inside the drum 2, and the cabinet 1 ) as the internal air moves to the rotor accommodating part 322 through the cooling passage 35 , it is possible to cool the motor 5 .

Additionally, the base panel 17 has a separate exhaust fan (not shown) capable of discharging the air inside the cabinet 1 to the outside of the cabinet 1 in order to cool the heat generated by the compressor 345 . may be provided, and since the heated high-temperature air inside the cabinet 1 is discharged to the outside of the cabinet 1 by the exhaust fan, the air inside the cabinet 1 is transferred to the heat exchange unit 34, the The supply duct 32 may be formed relatively lower than the air inside the drum (2).

In order to make it easier for the air introduced from the first cooling duct 362a to be discharged through the second cooling duct 363a and at the same time to effectively cool the motor 5, the rotor 52 has a plurality of A vane 523 (vane) may be further provided.

The vane 523 may be provided as a board protruding from the rotor body 52a toward the duct cover 36 . The vane 523 may be provided as a single plate or as a plurality of plates. In either case, the vanes 523 are preferably provided parallel to the radial direction of the rotor body 52a.

When the vane 523 is provided as a plate parallel to the radial direction of the rotor body 52a, the function of the impeller for forcibly moving the air in the rotor accommodating part 322 when the rotor 52 rotates. can

The rotor 52 further includes a rotor through-hole 521 provided to pass through the rotor body 52a so that heat generated from the stator 51 can be more effectively discharged to the rotor accommodating part 322 . can do. The rotor through-hole 521 may be provided by disposing a plurality of holes to form a ring surrounding the first shafts 63a and 63b.

The rotor through-hole 521 may be provided as a slit in which a length in a radial direction of the rotor body 52a is set longer than a length in a circumferential direction of the rotor body 52a. In this case, the vane 523 may be fixed to the edge of the rotor through-hole 521 parallel to the radial direction of the rotor body 52a.

In order to more effectively cool the motor 5, the first cooling duct 362a, the center of rotation of the rotor 52, and the second cooling duct 353 are arranged in a direction extending on a single straight line. can be placed

Accordingly, when the rotor 52 rotates, the outside air is introduced into the rotor accommodating part 322 through the first cooling hole 236 and the first cooling duct 362a, and the rotor accommodating part 322 . After cooling the motor 5 , the air introduced into the motor 5 will be discharged to the outside of the rotor accommodating part 322 through the second cooling duct 363a and the second outlet ring hole 237 .

15 to 16 show a cooling passage 35 according to another embodiment of the present invention. As shown, the cooling flow path 35 according to another embodiment is for cooling the motor 5 by forming a predetermined part of the classical panel as the cooling flow path 35 .

The duct cover 36 is formed in the form of an enclosure in which the surface facing the supply duct 32 is opened so as to cover the entire supply duct 32 . In the case of the supply duct 32, it is formed in a ring shape along the arrangement of the supply port 158 of the fixed panel 15, and the duct cover 36 covers the outer portion of the supply duct 32. formed in a rectangular shape.

When the duct cover 36 covers the supply duct 32 , a space is formed between the outer peripheral surface of the supply duct 32 and the inner edge of the duct cover 36 , and the inner edge of the duct cover 36 . A first cooling hole 236 and a second cooling hole 237 are formed in the fixed panel 15 corresponding to the position.

The duct cover 36 includes a cover plate 361b having an area larger than an area formed by the supply duct 32 , the first cooling hole 236 and the second cooling hole 237 and the cover plate. A cover side wall 362b fixed to the fixing panel 15 at a height higher than the supply duct 32 on the outer peripheral surface of the 361b may be provided.

The first cooling hole 236 and the second cooling hole 237 may communicate with each other by the cover plate 361b and the cover sidewall 362b, and the motor ( 5) may be cooled by air passing through the first cooling hole 236 and the second cooling hole 237 .

The first cooling hole 236 and the second cooling hole 237 serve as passages through which air inside the cabinet 1 moves. The first cooling hole 236 may be formed on the lower side of the fixed panel 15 , and the second cooling hole 237 may be formed on the upper side of the fixed panel 15 . The first cooling hole 236 and the second cooling hole 237 allow air in the cabinet 1 to move into the duct cover 36 . The first cooling hole 236 and the second cooling hole 237 may be formed on opposite corners with respect to the center of the supply duct 32 .

In order to make it easier for the air introduced from the first cooling hole 236 to be discharged through the second cooling hole 237 and at the same time to effectively cool the motor 5, the rotor 52 is attached to the rotor. It may further include a plurality of vanes 523 (vanes) serving as impellers during rotation of 52, and a rotor through-hole 521 provided to pass through the rotor body 52a. Since the description of the vane 523 and the rotor through-hole 521 has been described in an exemplary embodiment, a detailed description thereof will be omitted.

A circulation fan (not shown) has one of the first cooling hole 236 and the second cooling hole 237 so that the air inside the cabinet 1 can forcibly circulate through the inside of the duct cover 36 . may be further provided. If the circulation fan is provided, the cooling of the motor 5 may be performed more effectively.

Although the above-described dryer 100 has been described with reference to a case in which a circulating drying system is provided, the dryer 100 may also be applied to an exhaust-type drying system. The circulation drying system refers to a drying method in which dehumidification and heating of the air discharged from the drum 2 are sequentially performed, and then high temperature and dry air is re-supplied to the drum. The exhaust type drying system refers to a drying method in which outdoor air is heated and supplied to the drum 2 , and the air discharged from the drum 2 after heat exchange is completed is exhausted to the outside of the cabinet 1 .

When the dryer 100 is provided with the exhaust drying system, the supply unit 3 includes an exhaust duct connecting the first exhaust port 128 and the second exhaust port 157, and outside air (air or air inside the cabinet). It may be provided to include a supply duct for supplying air from outside the cabinet) to the drum 2 , and a heat exchange unit for heating the air introduced into the supply duct.

The above description is merely illustrative of the technical idea of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1: Cabinet 11: Front panel 111: Inlet
113: door 115: control panel 123: drum connection body
124: connection damper 126: panel connection body 128: first exhaust port
129: filter 15: fixed panel 157: second exhaust port
158: supply port 159: flow path forming part 17: base panel
2: drum 21: drum body 22: front cover
221: drum inlet 23: rear cover 233: air inlet
236: first cooling hole 237: second cooling hole 3: supply unit
31: exhaust duct 32: supply duct 321: duct body
322: rotor receiving part 324: flow guide 34: heat exchange part
341: heat absorbing part 343: heating part 345: compressor
35: cooling passage 351: supply passage 353: exhaust passage
357: guide passage 36: duct cover 4: drive unit bracket
42: ring part 421: motor fastening hole 43: housing fastening part
431: housing fastening jaw 432: housing fastening hole 433: locking projection
434: locking groove 5: motor 51: stator
52: rotor 52a: rotor body 521: rotor through hole
523: vane 6: power transmission unit
60a, 60b: housing 68a: housing fixing protrusion 69a: housing fixing hole
69b: housing fixing groove 61a, 61b: first housing 62a, 62b: second housing
63a, 63b: first shaft 631a, 631b: main gear 632a, 632b: main gear shaft
64a, 64v: interlocking gear 642a, 642b: first gear 644a, 644b: second gear
65a, 65b: driven gear 652a, 652b: second shaft

Claims (15)

A drum body providing a space for storing clothes, a front cover forming a front surface of the drum body, a rear cover forming a rear surface of the drum body, and a drum passing through the front cover and communicating with the inside of the drum body a drum equipped with an inlet;
a fixing panel spaced apart from the rear cover and having a through hole formed therein;
a motor including a stator installed in the through hole and a rotor rotating by the stator;
A first shaft connected to the rotor, a second shaft connected to the rear cover, and an interlocking gear for decelerating the rotational force of the first shaft and transmitting it to the second shaft, and a housing fixed to the fixing panel power transmission unit; and
and a driving unit bracket mounted on the through hole to limit a position where the stator is installed, and to correct the installation position of the housing so that the rotational center of the stator coincides with the rotational axis of the first shaft when the housing is installed. dryer with According to claim 1, wherein the drive bracket is
a ring-shaped ring portion overlapping the outer circumferential surface of the through hole, fixed to the fixing panel, and supporting the stator;
and a housing coupling part protruding inside the ring part and supporting the outside of the housing. 3. The method of claim 2,
The ring portion has a plurality of fastening holes corresponding to the outer peripheral surface of the through hole, and the stator passes through the fixing panel and is fixed to the fastening hole. 4. The method of claim 3,
The dryer, characterized in that the ring portion is further formed with a protrusion through which the through hole protrudes toward the classical panel. 3. The method of claim 2,
A plurality of fixing protrusions extending in a radial direction with respect to the center of the housing are formed on the outer circumferential surface of the housing,
The drying machine according to claim 1, wherein the housing fastening portion has a plurality of housing fastening jaws protruding from the ring portion toward the center of the ring portion at positions corresponding to the plurality of fixing protrusions. 6. The method of claim 5,
A plurality of fixing holes are formed in each of the housing fastening jaws, and each of the fixing protrusions has a fastening hole through which a fastening member passing through the fixing hole is inserted and fastened. 7. The method of claim 6,
Each of the housing fastening jaws is formed with a locking projection extending in an insertion direction of the housing, and the housing fixing projection extends in a direction crossing the locking projection and is formed to be supported by the locking projection. The dryer according to claim 7, wherein the locking protrusion has a locking groove into which the housing fixing protrusion is inserted. The dryer according to claim 7, wherein the housing fixing protrusion has a fixing groove into which the housing fixing jaw is inserted. 8. The method of claim 7,
The locking protrusion has a locking groove into which the housing fixing protrusion is inserted, and the housing fixing protrusion has a fixing groove into which the locking groove is inserted. 11. The method of claim 10,
The dryer, characterized in that at least one of the locking groove and the fixing groove is formed with an inclined surface extending the inlet side. The dryer according to claim 10, wherein the locking groove and the fixing groove are inserted to cross each other as the housing rotates with respect to the center of the housing. The dryer according to claim 5, wherein at least three of the fixing protrusion and the housing fastening jaw are provided in a radial direction with respect to the housing. The dryer according to claim 1, wherein the driving unit bracket supports the stator with the fixing panel interposed therebetween. According to claim 1, wherein the power transmission unit
a main gear formed at the end of the single shaft and transmitting power to the interlocking gear;
It is formed at the end of the second shaft and includes a driven gear receiving power from the interlocking gear,
The interlocking gear comprises a first gear which is rotated by meshing with the main gear, and a second gear which is rotated coaxially with the first gear and meshed with the driven gear with a diameter smaller than that of the first gear. dryer to do.

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