KR20200066169A - dryer - Google Patents

Abstract

The present invention relates to a dryer, and more particularly, to a dryer for drying an object inside a rotating drum.
According to an embodiment of the present invention, the case forming the appearance; A drum provided inside the case and accommodating a drying object; And it is provided to drive the drum, the dryer having a drive unit including a motor having a stator and a rotor, wherein the case includes a rear case forming a rear appearance of the dryer, the rotor is outside the rear case In relation to the rear case, the drum is rotatably supported in an axis and an axis, and the stator may be provided with a dryer fixed to the rear case outside the rear case.

Description

Dryer

The present invention relates to a dryer, and more particularly, to a dryer for drying an object inside a rotating drum.

The dryer is a device for drying the object, and may be referred to as a device for drying the object by supplying hot air into the object receiving portion.

A drum dryer that forms an object receiving portion in a cylindrical drum shape and supplies hot air into the drum while rotating the drum is often used. Particularly, a drum dryer that rotates about a horizontal axis is generally used for a household dryer.

In this drum dryer, a motor for rotating the drum is used, 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 axis of the motor is generally different from the rotation axis of the drum. This can be called a belt type.

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

Most drum washing machines produced in recent years can be referred to as direct-type (or direct-acting) drum-type washing machines, not belt type. The direct connection type means that the rotation axis of the motor and the rotation axis of the drum are formed coaxially, and the stator of the motor is generally mounted on the rear wall or the lower wall of the tub). A motor used in a washing machine is called a direct drive (DD) motor, and such a washing machine is called a DD washing machine.

The direct connection type has a wide variety of advantages over the belt type. For example, the drum driving RPM and the drum torque can be controlled by variously changing in various environments. In addition, drum rotation direction control, drum rotation angle control, and the like can be performed very easily. In addition, there is an energy saving advantage by reducing power loss.

Of course, in the case of a laundry and dryer (aka "combo"), a tub is provided, so a direct connection type may be applied. However, in the case of a pure dryer that does not provide a washing function, since there is no configuration corresponding to a tub, it is not easy to implement a direct dryer. That is, it is not easy to apply the direct type to the dryer, although it is a direct type with a wide variety of advantages over a belt type.

Meanwhile, JP1982-124674 or KR291966 discloses a dryer in which a rotor is directly connected to a rotating shaft that drives a drum. However, all of these prior patents disclose that a fan casing is provided so that the motor is supported in the fan casing or the motor is supported through a separate configuration. Therefore, the structure of the driving unit is complicated and it is not easy to stably support the motor.

It is intended to provide a direct-type dryer (DD dryer) through the present invention.

Through one embodiment of the present invention, to provide a dryer capable of stably supporting the motor by mounting the motor to the rear case forming and supporting the rear shape of the dryer. That is, the motor is mounted on the rear case, which is one of the structural frames that form and support the external shape of the dryer, and thus, it is intended to minimize additional configuration and provide a stable dryer.

Through one embodiment of the present invention, it is intended to provide a direct-type dryer that can apply a circulation path of air for drying.

Through one embodiment of the present invention, the fan motor for circulating the air and the motor for driving the drum are separated, and the RPM of the drum and the RPM of the fan can be individually controlled to provide a large air volume and a variable air volume area. It is intended to provide a dryer that can be effectively widened.

Through one embodiment of the present invention, to provide a dryer that can reduce the air flow resistance by preventing the flow resistance is generated by the motor by isolating the circulation path of the air for drying and the motor.

Through one embodiment of the present invention, it is intended to provide a direct-type dryer capable of applying a flow path structure in which dry air is introduced from the rear of the drum and air is discharged from the front of the drum.

Through an embodiment of the present invention, to provide a direct-type dryer that can secure the space inside the case and increase the degree of freedom in the flow path design by arranging the motor in the space outside the case, not the space inside the case where the drum is provided.

Through an embodiment of the present invention, despite the difference between the drum rotation band of the dryer and the optimum efficiency band of the motor, it is intended to provide a direct-type dryer capable of driving a motor at an optimum motor efficiency in an optimal motor efficiency band. .

Through one embodiment of the present invention, it is intended to provide a direct-type dryer capable of improving the drying performance by increasing the area where air is introduced into the drum.

Through one embodiment of the present invention, the hot air is introduced into the drum through a donut-shaped region excluding the center portion and the outer shell of the drum rear wall, thereby providing a dryer capable of introducing hot air into the drum in three dimensions. That is, the present invention is to provide a dryer capable of increasing the heat transfer area of the hot air and the object to be dried by supplying a cylindrical hot air having an empty center.

Through one embodiment of the present invention, by providing a compact size of the power transmission portion between the drum and the motor to provide a direct-type dryer that can prevent the front and rear width of the dryer is increased or the drum volume is reduced.

Through one embodiment of the present invention, through the connector coupled to overlap in the front-rear direction of the stator and dryer on one side and overlapped in the front-rear direction of the reducer and dryer on the other side, the increase in the front-rear length of the driving unit is minimized and the stator is stably And to reducer to a rear case.

Through one embodiment of the present invention, to provide a direct-type dryer that can protect the rear case by transmitting the repelling force generated by the stator and the reducer to the connector rather than directly to the rear case. In particular, it is intended to provide a direct-type dryer capable of facilitating and mating the stator and the reducer by forming the connector through injection molding, and offsetting the repulsive force transmitted from the stator and the reducer by itself.

Through one embodiment of the present invention, it is intended to provide a direct-type dryer that is easy to manufacture. In particular, the process of coupling the reducer and the stator to the rear case by omitting the connector to the rear case is omitted to provide a direct-type dryer that is easy to manufacture.

Through one embodiment of the present invention, by directly driving the drum through the motor, it is easy to control the exact position and rotation speed of the drum, and reduce inaccuracy and abrasion caused by slip of the belt, so that various drum motions can be realized and the optimum drum It is intended to provide a direct-type dryer that can reduce power loss by implementing RPM.

Through one embodiment of the present invention, to increase the gear strength of the reducer by applying an increase in outer diameter, not an increase in thickness, to provide a direct-type dryer capable of preventing a reduction in drum capacity due to an increase in the thickness of the reducer.

Through an embodiment of the present invention, while having a front supporter rotatably supporting the front of the drum in contact with the front of the drum, while eliminating the rear supporter rotatably supporting the rear of the drum in contact with the rear of the drum Therefore, to provide a dryer that can reduce power loss due to the rotational support of the drum.

In order to achieve the above object, according to an embodiment of the present invention, the case forming the appearance; A drum provided inside the case and accommodating a drying object; And it is provided to drive the drum, the dryer having a drive unit including a motor having a stator and a rotor, wherein the case includes a rear case forming a rear appearance of the dryer, the rotor is outside the rear case In relation to the rear case, the drum is rotatably supported in an axis and an axis, and the stator may be provided with a dryer fixed to the rear case outside the rear case.

The driving unit includes a power transmission unit that transmits the rotational force of the rotor to the drum, and the power transmission unit may be provided between the rotor and the drum. It is preferable that the power transmission unit transmits power so that the rotor and the drum have a coaxial shape.

It is preferable that the motor is an outer rotor type motor provided to rotate the rotor in the radially outer side of the stator. The outer rotor type motor may be capable of directly using a motor used in a conventional washing machine.

It is preferable that the stator has a hollow portion inside the radial direction and is fixed to the outside of the rear case. It is possible to prevent an increase in the front-rear distance of the power transmission unit or the driving unit by allowing at least a portion of the power transmission unit to be inserted into the hollow portion.

It may be provided between the stator and the rear case is provided to secure the stator to the rear case, and may include a connector that forms a front-rear gap between the stator and the rear case. Through the connector, the stator can be securely fixed to the rear case, and the rotor can be rotated without interfering with the rear case.

Part of the connector may be inserted into the hollow portion of the stator. Therefore, the stator can be fixed more firmly to the connector by the matching.

It is preferable that the connector has a hollow portion inside the radial direction. A portion of the power transmission portion is inserted into the hollow portion, and thus it is possible to prevent the front and rear lengths of the power transmission portion and the driving portion from increasing.

The power transmission unit may include a reducer that converts high RPM low torque of the rotor to low RPM high torque of the drum. Preferably, at least a portion of the reducer is inserted into the hollow portion of the connector and positioned.

The power transmission unit, a drum shaft connected to the rear of the drum; A rotor shaft connected to the rotor; And it may include a reduction gear provided between the drum shaft and the rotor shaft.

A shaft through hole through which the drum shaft passes may be formed in the rear case.

The reducer, the housing; And it may be provided inside the housing may include a converter for converting the high RPM low torque of the rotor to a low RPM high torque of the drum. The conversion device may include a plurality of gears.

The housing of the speed reducer may be provided to be fixed to the outside of the rear case. The reducer housing can be fixed directly to the rear case.

The reducer housing may be first fixed to the connector. Thereafter, a connector can be directly fixed to the rear case. The connector may be provided to surround the reducer housing. In this case, the connector can be fixed to the rear case at a point having a larger radius in the shaft through-hole. Therefore, it is more preferable that the reducer housing is not directly coupled to the rear case and the reducer housing is fixed to the rear case through the connector.

The housing of the speed reducer, the drum shaft through-hole protruding a predetermined length in the front so that the drum shaft is penetrated, a drum shaft through-hole through which a bearing for rotatably supporting the drum shaft is mounted; And it may include a rotor shaft through-hole protruding a predetermined length in the rear so that the rotor shaft penetrates, and a bearing for rotatably supporting the rotor shaft is mounted therein.

Preferably, the drum shaft through hole is inserted into the shaft through hole of the rear case, and the rotor shaft through hole is inserted into the hollow portion formed in the radially inner side of the stator.

The bearing support points of the shafts rotating through the through holes are secured, and sufficient support can be performed. In addition, the positions of the through holes may be substantially the space between the drum rear wall and the rear case and the inner space of the stator. Therefore, it is possible to prevent the front and rear lengths of the power transmission unit or the driving unit from being increased. That is, a compact power transmission unit or a driving unit can be implemented.

The reducer rotates a first sun gear, a ring gear, a plurality of first planetary gears provided between the ring gear and the first sun gear, and the plurality of first planetary gears integrally rotating with the rotor shaft. It may include a first carrier capable of supporting.

Power of the rotor shaft may be converted from the first carrier to the first stage.

The first sun gear is located in front of the rotor shaft and may be integrally formed with the rotor shaft.

The reducer may include a second sun gear, a ring gear, a plurality of second planetary gears provided between the ring gear and the second sun gear, and the plurality of second planetary gears integrally rotating with the first carrier. It may include a second carrier that is rotatably supported and rotates integrally with the drum shaft.

The power of the rotor shaft can be converted from the second carrier to two stages.

The second carrier is located behind the drum shaft and may be integrally formed with the drum shaft.

The first carrier may be integrally formed with the second sun gear.

The reducer may include an intermediate shaft extending rearward from the first carrier and forwardly extending from the second sun gear, forming a coaxial relationship between the drum shaft and the rotor shaft.

The first carrier, the second sun gear, and the intermediate shaft may be integrally formed.

One end of the intermediate shaft is supported to enable independent rotation coaxially with the rotor shaft in the interior of the rotor shaft through a bearing, and the other end of the intermediate shaft is through the bearing inside the drum shaft. It is desirable to be supported coaxially with independent rotation.

It is preferable that the ring gear for the first stage conversion and the ring gear for the second stage transformation are single ring gears.

It is preferable that the first stage conversion ratio and the second stage conversion ratio are the same. Therefore, it is possible to implement a very compact reducer. A two-speed planetary gear reducer can be implemented.

The plurality of gears, a single ring gear; A first sun gear rotating integrally with the rotor shaft at an inner rear of the ring gear; A plurality of first planetary gears provided between the ring gear and the first sun gear; A first carrier rotatably supporting the plurality of first planetary gears; A second sun gear rotating integrally with the first carrier; A plurality of second planetary gears provided between the ring gear and the second sun gear; It is preferable that the plurality of second planetary gears includes a second carrier rotatably supporting and rotating integrally with the drum shaft at an inner front of the ring gear, and the plurality of gears are helical gears.

It is preferable that the first planetary gear and the second planetary gear have the same radius, and the height (thickness) of the second planetary gear is larger than the height (thickness) of the first planetary gear.

It is preferable that the front and rear widths of the gears for the second stage conversion are larger than the front and rear widths of the gears for the first stage transformation.

In the rear case, a shaft through hole through which a drum shaft is connected to the drum to transmit power of the rotor to the drum is formed, and in the rear case, the driving part is radially outward around the shaft through hole. A mounting area for mounting of may be formed.

An air supply area for supplying air into the drum is formed in the rear case, and the air supply area may be formed radially outside the mounting area around the mounting area.

An air intake area for sucking air from the drum is formed in the rear case, and the air intake area may be formed outside the air supply area in a radial direction.

The inflow region of the air may be formed on the rear wall of the drum except for the radially central portion and the outermost portion. Therefore, hot air can be uniformly supplied to the entire drum. In particular, by increasing the air supply area, it is possible to significantly reduce the variation in the flow rate of air as it goes forward from the rear wall of the drum. Therefore, uniform drying is enabled.

It is preferably provided to be coupled to the rear case from the outside of the rear case, and a flow path duct covering the air intake area and the air supply area to form an air flow space between the rear case is provided. That is, it is preferable that some sections for supplying air into the drum are provided outside the rear case, that is, outside the case through the flow path duct.

The flow path duct includes: an inner coupling portion coupled to the rear case between the mounting area of the rear case and the air supply area; An outer coupling portion that is combined with the rear case while surrounding the air supply region and the air intake region of the rear case; In addition, it is preferable to include an extension portion extending between the inner coupling portion and the outer coupling portion to the rear of the rear case to form an air flow space.

Accordingly, air introduced into the flow path duct from one lower portion of the rear case may flow through the flow path duct into the drum with a very large area except for the center and rim portions of the drum.

In order to cover the driving part exposed to the outside of the dryer from the radially inner side of the inner coupling part, a driving part cover coupled to the flow channel duct from the rear side of the flow channel duct may be included to cover the inner coupling part.

It is preferable that a plurality of openings through which air may flow in and out into a space accommodating the power transmission unit is formed in the driving unit cover. The relatively low temperature air may be introduced into the power transmission unit to cool the power transmission unit and discharge relatively high temperature air. That is, it is possible to cool through natural convection caused by a temperature difference. In particular, when the rotor is provided in the power transmission unit, forced air flow may be generated by rotation of the rotor. The flow of air may include inflow of air through an opening in the driving part cover, and may include exhaust of air through another opening in the driving part cover.

In the upper portion of the rear case, an electric wire extraction hole through which electric wires are drawn out from the inside of the dryer case is formed, and the electric wire extends to the mounting area of the rear case through the outside of the flow path duct and can be connected to the stator. .

A wire cover may be provided outside the rear case to cover the wire.

The flow path duct is recessed forward to form a seating portion on which the electric wire cover is seated, and both ends of the electric wire cover may be combined with the rear case, respectively.

An electric wire cover coupling region for one end of the electric wire cover to be coupled may be formed between the mounting region of the rear case and the air supply region.

It is preferable that the rear wall of the drum is formed with a mounting area opposite the mounting area of the rear case and an air intake area opposite the air supply area of the rear case. Gong dryer.

It may include a gasket provided between the rear case and the rear wall of the drum so that the air supplied from the air supply region of the rear case flows into the air intake region of the drum.

The gasket includes: an inner gasket provided to prevent air from leaking radially inside the air intake region of the drum between the rear case and the rear wall of the drum; And it may include an outer gasket provided between the rear case and the rear wall of the drum to prevent air from leaking radially outward than the air intake region of the drum.

The inner gasket may include an extension extending radially inward and toward the rear wall of the drum, and the outer gasket may include an extension extending radially outward and inclined toward the rear wall of the drum.

The gasket is preferably provided to be fixed to the inside of the rear case and then extended toward the drum. That is, it is preferable that the gasket is mounted on a fixed rear case rather than a rotating drum.

It is preferable that a blowing fan for introducing air into the flow path duct and a heating portion for heating air flowing into the flow path duct is provided in the space inside the case. The heating unit may be implemented through a heat pump. Through the heat pump, it is possible to heat the air and condense the moisture in the air.

The air heated by the blower fan is guided inside the flow path duct, which is outside of drying. The heated air is introduced into the drum from the rear of the drum through the flow path duct. The heat exchanged inside the drum is discharged from the front of the drum. The discharged wet air is cooled in the evaporator of the heat pump, and moisture is condensed and converted to dry air, and the dry air is heated in the condenser of the heat pump. The heated air is introduced into the drum again, whereby a circulating structure of air can be formed.

In order to achieve the above object, according to an embodiment of the present invention, the rear case forming the rear appearance of the dryer; A drum provided in front of the rear case and accommodating a drying object; It is provided to drive the drum, the stator fixed to the rear case from the rear outside of the rear case, and rotatably supported relative to the rear case from the rear outside of the rear case and provided to rotate outside the radial direction of the stator A motor including a rotor; A dryer including a flow path duct positioned at the periphery of the motor at the rear outside of the rear case and fixed to the rear case and provided to guide hot air introduced from the front of the rear case into the drum. .

In order to achieve the above object, according to an embodiment of the present invention, the rear case forming the rear appearance of the dryer; A drum provided in front of the rear case and accommodating a drying object; A power transmission unit provided to drive the drum and rotatably fixed with respect to the rear case from a rear outside of the rear case; A dryer including a flow path duct positioned around the driving unit at the rear outside of the rear case and fixed to the rear case and provided to guide hot air flowing in from the front of the rear case into the drum may be provided. .

The power transmission portion is positioned corresponding to the rotating center of the drum, and thus, hot air may be supplied to the radially outer side of the rotating center of the drum through the flow path duct. That is, hot air may be supplied into the drum in the form of a donut. Through this, a three-dimensional and large air volume can be supplied into the drum.

The rear case and the flow path duct may be combined with each other to form an air flow space therein. Therefore, a part of the rear case can also form a part of the duct. That is, the flow path duct may form an air flow space between the rear case. Therefore, the duct can be easily formed by closely coupling the flow path duct with the front opening to the rear case.

The flow path duct, the inner coupling portion coupled to the rear case; An outer coupling portion coupled to the rear case from the outside of the inner coupling portion; And it may include an expansion portion extending between the inner coupling portion and the outer coupling portion to the rear of the rear case to form an air flow space.

In the rear of the rear case, it is preferable that the space provided with the motor and the air flow space are partitioned by the flow path duct. In other words, it can be said that the space in which the motor is provided is divided by a space inside the flow path duct and the flow path duct and the rear case. Therefore, the flow resistance of the air by the motor is not generated.

The inner coupling portion may be coupled to the rear case from the radially outer side of the stator or rotor.

Therefore, the flow path duct may have a donut shape surrounding the mounting space of the motor. Of course, a portion of the donut shape may be deformed.

In order to cover the driving part exposed to the outside of the dryer from the inner side in the radial direction of the inner coupling part, it is preferable to include a driving part cover coupled to the flow channel duct from the rear side of the flow channel duct. That is, it is preferable to cover the central portion of the donut shape through the driving part cover. Therefore, it is possible to prevent the stator to which the rotating rotor and the electric wire are connected from being exposed outside the dryer.

In the rear case, an air supply area for supplying air into the drum; In addition, it is preferable that an air intake area is formed to intake air from inside the drum. That is, air passes through the regions from front to rear or rear to front of the rear case. Here, it can be said that the inner space of the dryer surrounded by the case is referred to as the front of the rear case.

The air intake area may be formed outside the radial direction of the air supply area. Speaking of the substantially upper, lower, left, and center portions of the rear case of the air supply region, the air intake region may be formed in the lower left portion of the rear case.

That is, the air discharged through the lower left portion of the rear case from the inside of the dryer may flow to the upper right along the inside of the flow path duct and be supplied to the drum interior.

The flow path duct may be provided to cover both the air intake area and the air supply area. Therefore, the donut-shaped flow path duct may have a shape in which a portion extends to the lower left portion of the rear case.

It includes a blowing fan for generating air flow and a heating unit for heating air, and the blowing fan and the heating unit may be located in front of the rear case, that is, inside the case. Therefore, a configuration for heating and flowing air is not provided at the rear of the rear case. Therefore, it is possible to increase the degree of freedom in the design of the flow path and realize a simple structure.

Air may pass from the front to the rear of the air intake region of the rear case to flow into the flow path duct, and air may flow from the rear to the front of the air supply region of the rear case to allow air to flow into the drum. .

In the rear case, a shaft through hole through which a drum shaft is connected to the drum to transmit power of the rotor to the drum is formed, and mounting for mounting the motor radially outside the shaft through hole It is preferred that a region is formed.

It is preferable that the flow path duct is coupled to the rear case at a radially outer side of the mounting region, so that the air flow space inside the flow path duct is partitioned from the mounting region and the motor.

An air supply area for supplying air into the drum may be formed on the rear case by the flow path duct, and an air intake area opposite to the air supply area of the rear case may be formed on the rear wall of the drum. .

The air supply region of the rear case may have a donut shape, and the air intake region of the drum opposite thereto may also have a donut shape.

The donut-shaped air intake area may supply a three-dimensional hot air inside the drum. That is, a cylindrical hot air with an empty center can be supplied inside the drum. Preferably, the air intake region is not formed on the outer shell of the drum rear wall. Through the cylindrical three-dimensional hot air, it is possible to effectively enhance the heat exchange area with the drying object inside the drum.

It is preferable to include a gasket provided between the rear case and the rear wall of the drum so that air supplied from the air supply area of the rear case flows into the air intake area of the drum.

The gasket includes: an inner gasket provided to prevent air from leaking radially inside the air intake region of the drum between the rear case and the rear wall of the drum; And it may include an outer gasket provided between the rear case and the rear wall of the drum to prevent air from leaking radially outward than the air intake region of the drum.

Therefore, hot air can be prevented from leaking out between the drum and the rear case, and it can also be prevented from entering the reducer or the motor.

Preferably, the inner gasket includes an extension extending radially inward and towards the rear wall of the drum, and the outer gasket includes an extension extending radially outward and inclined toward the rear wall of the drum.

Through this extension, sealing efficiency can be increased, and friction and damage of the gasket can be minimized.

It is preferable that a wire lead-out hole through which wires are drawn from the front to the rear is formed in the upper portion of the rear case, and the wires extend through the outside of the flow path duct to the mounting area of the rear case and are connected to the motor.

After the motor and the flow path are mounted on the rear case, wiring can be easily performed and the wire can be protected by a wire cover. In addition, after the electric wire cover is mounted, the driving unit cover may be finally coupled to the flow path duct or the rear case.

In order to achieve the above object, according to an embodiment of the present invention, the case forming the appearance of the dryer; A drum provided inside the case and accommodating a drying object; A driving unit provided to drive the drum and including a motor having a stator and a rotor; And in the dryer including a flow path duct for introducing the air sucked from the inside of the drum into the drum, the case forms a rear appearance of the dryer, the power transmission unit mounting area for transmitting the driving force to the drum, air suction And a rear case having an area and an air supply area, wherein the power transmission unit is mounted to the mounting area at the rear of the rear case, and the flow path ducts are configured to connect the air intake area and the air supply area except for the mounting area. A dryer may be provided, which covers and is coupled to the rear case to form an air flow space between the flow path duct and the rear case.

In order to achieve the above object, according to an embodiment of the present invention, the case forming the appearance; A drum provided inside the case and accommodating a drying object; And it is provided to drive the drum, the dryer having a drive unit including a motor having a stator and a rotor, wherein the case includes a rear case forming a rear appearance of the dryer, the rotor is outside the rear case In relation to the rear case, the drum is rotatably supported in an axis and an axis, and the stator may be provided with a dryer fixed to the rear case outside the rear case.

In order to achieve the above object, according to an embodiment of the present invention, the rear case forming the rear appearance of the dryer; A drum provided in front of the rear case and accommodating a drying object; It is provided to drive the drum, the stator fixed to the rear case from the rear outside of the rear case, and rotatably supported relative to the rear case from the rear outside of the rear case and provided to rotate outside the radial direction of the stator A motor including a rotor; A rotor shaft that rotates integrally with the rotor and penetrates the rear case from the rear wall of the drum and extends to the rear of the rear case; A drum shaft rotating integrally with the drum; In addition, a dryer including a reduction gear that performs power conversion between the rotor shaft and the drum shaft and includes an intermediate shaft coaxially connecting the rotor shaft and the drum shaft may be provided.

The intermediate shaft may be inserted into the hollow portion of the drum shaft and the hollow portion of the rotor shaft, and three shafts may be formed coaxially. Since the three shafts are connected by simple insertion, the manufacturing process can be very easy.

The drum shaft, reducer and rotor shaft can be manufactured and handled in one assembly. The drum shaft may be coupled to the drum inside the drum, and the rotor shaft may be coupled to the rotor from the rear outside of the rotor. Therefore, the engagement of the drum, drum shaft, speed reducer, rotor shaft and rotor can be performed very easily.

The rotor shaft, drum shaft and intermediate shaft are individually formed and can be sequentially connected for power transmission. Preferably, this coupling position is inside the housing of the reducer. Therefore, disconnection between the shafts can be prevented through the housing of the reducer.

The rotor shaft and the intermediate shaft may be connected to rotate independently of each other through a bearing, and the drum shaft and the intermediate shaft may also be connected to rotate independently of each other through a bearing.

The stator may have a hollow portion inside the radial direction and be fixed at the rear outside of the rear case.

It is preferred to include a connector provided between the stator and the rear case to fix the stator to the rear case, and forming a front-rear gap between the stator and the rear case.

Part of the connector may be inserted into the hollow portion of the stator. That is, the stator and the connector can be coupled to each other so as to overlap in the front-rear direction of the dryer. Through this, it is possible to minimize an increase in the length of the front and rear of the driving unit. In addition, the bonding strength of the two can be further increased through conformation bonding.

The connector may have a hollow portion inside the radial direction.

The speed reducer includes the housing and the intermediate shaft, and is provided inside the housing, and may include a converter that converts high RPM low torque of the rotor to low RPM high torque of the drum.

At least a portion of the reducer may be inserted into the hollow portion of the connector and positioned. That is, at least a portion of the reducer housing may be inserted into the hollow portion of the connector. Therefore, the reducer and the connector can be combined with each other so as to overlap in the front-rear direction of the dryer. Through this, it is possible to minimize an increase in the length of the front and rear of the driving unit. In addition, the bonding strength of the two can be further increased through conformation bonding.

The housing of the speed reducer may be provided to be fixed to the outside of the rear case.

The connector may be fixedly coupled to the rear of the rear case. The reducer housing and the stator may be fixedly coupled to the connector. Therefore, the reduction gear housing and the stator may be fixed to the rear case indirectly through the connector. That is, the reduction gear housing and the stator are first fixedly coupled to the connector, and then the connector can be fixedly coupled to the rear housing. Therefore, the process of coupling the reducer housing and the stator to the rear case and the coupling components (eg, stud, bolt or screw) can be omitted.

Therefore, the repulsive force generated by the reducer and the stator can be transmitted to the connector without being directly transmitted to the rear case. Through this, the rear case can be protected.

The connector can be formed through injection molding. It can be made of plastics, especially engineering plastics. Due to the nature of the material, the repulsive force can be offset by itself. In addition, since the shape is easy to form, it is possible to form a stator and a reducer and a matching structure very precisely.

The converter includes a first sun gear, a ring gear, a plurality of first planet gears provided between the ring gear and the first sun gear, and the plurality of first planet gears rotating integrally with the rotor shaft. It includes a first carrier rotatably supported, the power of the rotor shaft can be converted from the first carrier to the first stage.

Preferably, the first sun gear is located in front of the rotor shaft and is integrally formed with the rotor shaft.

The converter includes a second sun gear, a ring gear, a plurality of second planetary gears provided between the ring gear and the second sun gear integrally rotating with the first carrier, and the plurality of second planetary gears And a second carrier rotatably supporting and rotating integrally with the drum shaft, and power of the rotor shaft may be converted to two stages in the second carrier.

Preferably, the second carrier is located behind the drum shaft and is integrally formed with the drum shaft.

The first carrier is preferably formed integrally with the second sun gear.

The intermediate shaft may be formed by extending rearward from the first carrier and extending forwardly from the second sun gear.

Preferably, the first carrier, the second sun gear and the intermediate shaft are integrally formed.

One end of the intermediate shaft is supported to enable independent rotation coaxially with the rotor shaft in the interior of the rotor shaft through a bearing, and the other end of the intermediate shaft is through the bearing inside the drum shaft. And coaxially independent rotation can be supported.

The reducer is a two-stage planetary gear reducer, and the first stage conversion ratio and the second stage conversion ratio are the same dryer.

The reducer includes a single ring gear; A first sun gear rotating integrally with the rotor shaft at an inner rear of the ring gear; A plurality of first planetary gears provided between the ring gear and the first sun gear; A first carrier rotatably supporting the plurality of first planetary gears; A second sun gear rotating integrally with the first carrier; A plurality of second planetary gears provided between the ring gear and the second sun gear; And it may include a second carrier that rotatably supports the plurality of second planetary gears and rotates integrally with the drum shaft at an inner front of the ring gear.

It is preferable that the first planetary gear and the second planetary gear have the same radius, and the height (thickness) of the second planetary gear is larger than the height (thickness) of the first planetary gear.

In order to achieve the above object, according to an embodiment of the present invention, the rear case forming and supporting the rear appearance of the dryer; A drum provided in front of the rear case and accommodating a drying object; A motor provided to drive the drum and including a stator having a hollow portion and a rotor provided to rotate in a radially outer side of the stator; One side is inserted into the hollow portion of the stator and coupled with the stator, the other side is coupled to the rear case from the rear of the rear case, a connector having a hollow portion; In addition, a dryer may be provided, which is inserted into the hollow portion of the connector and coupled with the connector, and includes a reducer provided to convert the power of the rotor and transmit it to the drum.

In order to achieve the above object, according to an embodiment of the present invention, the case forming the appearance; A drum provided inside the case and accommodating a drying object; And it is provided to drive the drum, the dryer having a drive unit including a motor having a stator and a rotor, wherein the case includes a rear case forming a rear appearance of the dryer, the rotor is outside the rear case In relation to the rear case, the drum is rotatably supported in an axis and an axis, and the stator may be provided with a dryer fixed to the rear case outside the rear case.

The driving unit includes a power transmission unit that transmits the rotational force of the rotor to the drum, and the power transmission unit may be provided between the rotor and the drum. It is preferable that the power transmission unit transmits power so that the rotor and the drum have a coaxial shape.

It is preferable that the motor is an outer rotor type motor provided to rotate the rotor in the radially outer side of the stator. The outer rotor type motor may be capable of directly using a motor used in a conventional washing machine.

It is preferable that the stator has a hollow portion inside the radial direction and is fixed to the outside of the rear case. It is possible to prevent an increase in the front-rear distance of the power transmission unit or the driving unit by allowing at least a portion of the power transmission unit to be inserted into the hollow portion.

It may be provided between the stator and the rear case is provided to secure the stator to the rear case, and may include a connector that forms a front-rear gap between the stator and the rear case. Through the connector, the stator can be securely fixed to the rear case, and the rotor can be rotated without interfering with the rear case.

Part of the connector may be inserted into the hollow portion of the stator. Therefore, the stator can be fixed more firmly to the connector by the matching.

It is preferable that the connector has a hollow portion inside the radial direction. A portion of the power transmission portion is inserted into the hollow portion, and thus it is possible to prevent the front and rear lengths of the power transmission portion and the driving portion from increasing.

The power transmission unit may include a reducer that converts high RPM low torque of the rotor to low RPM high torque of the drum. Preferably, at least a portion of the reducer is inserted into the hollow portion of the connector and positioned.

The power transmission unit, a drum shaft connected to the rear of the drum; A rotor shaft connected to the rotor; And it may include a reduction gear provided between the drum shaft and the rotor shaft.

A shaft through hole through which the drum shaft passes may be formed in the rear case.

The reducer, the housing; And it may be provided inside the housing may include a converter for converting the high RPM low torque of the rotor to a low RPM high torque of the drum. The conversion device may include a plurality of gears.

The housing of the speed reducer may be provided to be fixed to the outside of the rear case. The reducer housing can be fixed directly to the rear case.

The reducer housing may be first fixed to the connector. Thereafter, a connector can be directly fixed to the rear case. The connector may be provided to surround the reducer housing. In this case, the connector can be fixed to the rear case at a point having a larger radius in the shaft through-hole. Therefore, it is more preferable that the reducer housing is not directly coupled to the rear case and the reducer housing is fixed to the rear case through the connector.

The housing of the speed reducer, the drum shaft through-hole protruding a predetermined length in the front so that the drum shaft is penetrated, a drum shaft through-hole through which a bearing for rotatably supporting the drum shaft is mounted; And it may include a rotor shaft through-hole protruding a predetermined length in the rear so that the rotor shaft penetrates, and a bearing for rotatably supporting the rotor shaft is mounted therein.

Preferably, the drum shaft through hole is inserted into the shaft through hole of the rear case, and the rotor shaft through hole is inserted into the hollow portion formed in the radially inner side of the stator.

The bearing support points of the shafts rotating through the through holes are secured, and sufficient support can be performed. In addition, the positions of the through holes may be substantially the space between the drum rear wall and the rear case and the inner space of the stator. Therefore, it is possible to prevent the front and rear lengths of the power transmission unit or the driving unit from being increased. That is, a compact power transmission unit or a driving unit can be implemented.

The reducer rotates a first sun gear, a ring gear, a plurality of first planetary gears provided between the ring gear and the first sun gear, and the plurality of first planetary gears integrally rotating with the rotor shaft. It may include a first carrier capable of supporting.

Power of the rotor shaft may be converted from the first carrier to the first stage.

The first sun gear is located in front of the rotor shaft and may be integrally formed with the rotor shaft.

The reducer may include a second sun gear, a ring gear, a plurality of second planetary gears provided between the ring gear and the second sun gear, and the plurality of second planetary gears integrally rotating with the first carrier. It may include a second carrier that is rotatably supported and rotates integrally with the drum shaft.

The power of the rotor shaft can be converted from the second carrier to two stages.

The second carrier is located behind the drum shaft and may be integrally formed with the drum shaft.

The first carrier may be integrally formed with the second sun gear.

The reducer may include an intermediate shaft extending rearward from the first carrier and forwardly extending from the second sun gear, forming a coaxial relationship between the drum shaft and the rotor shaft.

The first carrier, the second sun gear, and the intermediate shaft may be integrally formed.

One end of the intermediate shaft is supported to enable independent rotation coaxially with the rotor shaft in the interior of the rotor shaft through a bearing, and the other end of the intermediate shaft is through the bearing inside the drum shaft. It is desirable to be supported coaxially with independent rotation.

It is preferable that the ring gear for the first stage conversion and the ring gear for the second stage transformation are single ring gears.

It is preferable that the first stage conversion ratio and the second stage conversion ratio are the same. Therefore, it is possible to implement a very compact reducer. A two-speed planetary gear reducer can be implemented.

The plurality of gears, a single ring gear; A first sun gear rotating integrally with the rotor shaft at an inner rear of the ring gear; A plurality of first planetary gears provided between the ring gear and the first sun gear; A first carrier rotatably supporting the plurality of first planetary gears; A second sun gear rotating integrally with the first carrier; A plurality of second planetary gears provided between the ring gear and the second sun gear; It is preferable that the plurality of second planetary gears includes a second carrier rotatably supporting and rotating integrally with the drum shaft at an inner front of the ring gear, and the plurality of gears are helical gears.

It is preferable that the first planetary gear and the second planetary gear have the same radius, and the height (thickness) of the second planetary gear is larger than the height (thickness) of the first planetary gear.

It is preferable that the front and rear widths of the gears for the second stage conversion are larger than the front and rear widths of the gears for the first stage transformation.

In the rear case, a shaft through hole through which a drum shaft is connected to the drum to transmit power of the rotor to the drum is formed, and in the rear case, the driving part is radially outward around the shaft through hole. A mounting area for mounting of may be formed.

An air supply area for supplying air into the drum is formed in the rear case, and the air supply area may be formed radially outside the mounting area around the mounting area.

An air intake area for sucking air from the drum is formed in the rear case, and the air intake area may be formed outside the air supply area in a radial direction.

The inflow region of the air may be formed on the rear wall of the drum except for the radially central portion and the outermost portion. Therefore, hot air can be uniformly supplied to the entire drum. In particular, by increasing the air supply area, it is possible to significantly reduce the variation in the flow rate of air as it goes forward from the rear wall of the drum. Therefore, uniform drying is enabled.

It is preferably provided to be coupled to the rear case from the outside of the rear case, and a flow path duct covering the air intake area and the air supply area to form an air flow space between the rear case is provided. That is, it is preferable that some sections for supplying air into the drum are provided outside the rear case, that is, outside the case through the flow path duct.

The flow path duct includes: an inner coupling portion coupled to the rear case between the mounting area of the rear case and the air supply area; An outer coupling portion that is combined with the rear case while surrounding the air supply region and the air intake region of the rear case; In addition, it is preferable to include an extension portion extending between the inner coupling portion and the outer coupling portion to the rear of the rear case to form an air flow space.

Accordingly, air introduced into the flow path duct from one lower portion of the rear case may flow through the flow path duct into the drum with a very large area except for the center and rim portions of the drum.

In order to cover the driving part exposed to the outside of the dryer from the radially inner side of the inner coupling part, a driving part cover coupled to the flow channel duct from the rear side of the flow channel duct may be included to cover the inner coupling part.

In the upper portion of the rear case, an electric wire extraction hole through which electric wires are drawn out from the inside of the dryer case is formed, and the electric wire extends to the mounting area of the rear case through the outside of the flow path duct and can be connected to the stator. .

A wire cover may be provided outside the rear case to cover the wire.

The flow path duct is recessed forward to form a seating portion on which the electric wire cover is seated, and both ends of the electric wire cover may be combined with the rear case, respectively.

An electric wire cover coupling region for one end of the electric wire cover to be coupled may be formed between the mounting region of the rear case and the air supply region.

It is preferable that the rear wall of the drum is formed with a mounting area opposite the mounting area of the rear case and an air intake area opposite the air supply area of the rear case. Gong dryer.

It may include a gasket provided between the rear case and the rear wall of the drum so that the air supplied from the air supply region of the rear case flows into the air intake region of the drum.

The gasket includes: an inner gasket provided to prevent air from leaking radially inside the air intake region of the drum between the rear case and the rear wall of the drum; And it may include an outer gasket provided between the rear case and the rear wall of the drum to prevent air from leaking radially outward than the air intake region of the drum.

The inner gasket may include an extension extending radially inward and toward the rear wall of the drum, and the outer gasket may include an extension extending radially outward and inclined toward the rear wall of the drum.

The gasket is preferably provided to be fixed to the inside of the rear case and then extended toward the drum. That is, it is preferable that the gasket is mounted on a fixed rear case rather than a rotating drum.

It is preferable that a blowing fan for introducing air into the flow path duct and a heating portion for heating air flowing into the flow path duct is provided in the space inside the case. The heating unit may be implemented through a heat pump. Through the heat pump, it is possible to heat the air and condense the moisture in the air.

The air heated by the blower fan is guided inside the flow path duct, which is outside of drying. The heated air is introduced into the drum from the rear of the drum through the flow path duct. The heat exchanged inside the drum is discharged from the front of the drum. The discharged wet air is cooled in the evaporator of the heat pump, and moisture is condensed and converted to dry air, and the dry air is heated in the condenser of the heat pump. The heated air is introduced into the drum again, whereby a circulating structure of air can be formed.

Through the present invention, a direct dryer can be provided. In particular, it is possible to provide a direct-type dryer that can use a direct-type motor used in a conventional washing machine.

Through one embodiment of the present invention, it is possible to provide a direct dryer that can apply a circulation path of air for drying.

Through one embodiment of the present invention, it is possible to provide a direct dryer that can apply a flow path structure in which dry air is introduced from the rear of the drum and air is discharged from the front of the drum.

Through one embodiment of the present invention, by arranging the motor in the outer space of the case, not the inner space of the case where the drum is provided, it is possible to provide a direct dryer that can secure space inside the case and increase freedom of flow path design.

Through one embodiment of the present invention, despite the difference between the drum rotation band of the dryer and the optimum efficiency band of the motor, it is possible to provide a direct-type dryer capable of driving the motor at the optimum motor efficiency in the optimal motor efficiency band. have.

Through one embodiment of the present invention, it is possible to provide a direct-type dryer capable of improving the drying performance by increasing the area where air is introduced into the drum. In particular, the standard deviation of the air flow velocity at a position along the longitudinal direction of the drum can be significantly reduced, and a direct-type dryer capable of performing uniform drying can be provided.

Through one embodiment of the present invention, it is possible to provide a direct-type dryer capable of preventing the width of the front and rear of the dryer from being enlarged or reducing the volume of the drum by compactly forming the size of the power transmission unit between the drum and the motor.

Through one embodiment of the present invention, it is possible to provide a direct-type dryer that is easy to manufacture.

Through one embodiment of the present invention, by directly driving the drum through the motor, it is easy to control the exact position and rotation speed of the drum, and reduce inaccuracy and abrasion caused by slip of the belt, so that various drum motions can be realized and the optimum drum By implementing RPM, it is possible to provide a direct-type dryer that can reduce power loss.

1 is a cross-sectional view of a dryer according to an embodiment of the present invention,
Figure 2 shows a rear view of the dryer according to an embodiment of the present invention,
3 is an enlarged view showing a driving part of a dryer according to an embodiment of the present invention,
Figure 4 shows the drum, rear case and the drive unit configuration of the dryer according to an embodiment of the present invention is disassembled,
5 shows a front view of the drum according to an embodiment of the present invention,
Figure 6 shows the rear view of the drum according to an embodiment of the present invention,
Figure 7 shows the air inlet structure in the driving part of the dryer according to an embodiment of the present invention,
8 is a view of the rear case portion viewed from the outside of the dryer according to an embodiment of the present invention,
9 is a view of the rear case portion viewed from the inside of the dryer according to an embodiment of the present invention,
10 is a graph showing the necessity and reduction ratio of a reducer in a dryer according to an embodiment of the present invention,
11 shows an exploded configuration of the reducer components of the dryer according to an embodiment of the present invention,
12 shows a combined state of the components for the first stage conversion of the reducer,
13 shows a combination of configurations for two-stage conversion of the reducer,
114 is a graph comparing the speed standard deviation according to the position of the drum in the dryer and the conventional dryer according to an embodiment of the present invention.

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

First, the main configuration of the dryer will be described with reference to FIGS. 1 and 2. In the present specification, for convenience of description, the direction of the door 140 of the dryer shown in FIG. 1 is referred to as a front and the direction of the driving unit 200 is a rear.

The dryer 10 includes a case 100 forming an external shape and a drum 20 provided inside the case 100. A drying object may be provided inside the drum 20. In the case of a clothes dryer, clothes may be introduced into the drum 20 and dried.

The case 100 may include an upper case 100 forming a top surface of the dryer, a front case 120 forming a front surface, a rear case 130 forming a rear surface, and a side case 150 forming a side surface. have. In addition, the case 100 may include a dryer base 155 forming a bottom portion of the dryer. The cabinet 100 forms an interior space, and various configurations including the drum 20 are accommodated in the interior space.

And the upper case 100, the front case 120, the rear case 130, the side case 150 and the base 155 are structurally coupled to each other. Therefore, each of the cases and the base not only forms an external appearance in one direction of the dryer, but also forms a support structure supporting the external shape of the dryer.

A door 140 is provided in the front case, and the door 140 is opened to allow clothing to be introduced into the drum.

The drum 20 may be rotatably provided with respect to a horizontal axis horizontal to the ground.

The drum 20 is formed in a cylindrical shape, and the front of the drum is opened to allow clothing to be introduced.

A plurality of lifters 30 may be provided on the inner wall of the drum 20. The lifter 30 may be provided to extend in the front-rear direction. The lifter 30 may be provided to rotate integrally with the drum. As the drum 20 rotates, the lifter 30 lifts the garment, and when the drum rotates further, the garment leaves the lifter 30 and falls by gravity. As the drum 20 rotates, the fluctuation of clothes in the drum 20 may be more smooth and active by the lifter 30. Therefore, clothing can be evenly exposed to the hot air.

In this embodiment, the driving unit 200 for driving the drum 20 is positioned behind the drum 20. The driving unit 200 includes a motor 260, and the motor 260 includes a rotor 270 and a stator 280. The axis of rotation of the rotor 270 and the axis of rotation of the drum may be formed coaxially. That is, the drum 20 and the rotor 270 rotate with the same center of rotation. Therefore, the dryer according to the present embodiment may be referred to as a direct dryer.

In order to transmit the power of the rotor 270 to the drum 20, the drum 20 is provided with a drum shaft 210. The drum shaft 210 is connected to the center of the rear wall 22 of the drum 20. Therefore, as the drum shaft 210 rotates, the drum 20 rotates integrally with the drum shaft 210.

A front supporter 160 may be provided to support the front of the drum 20. The front support 160 may be coupled to the rear of the front case 120 or may be formed as part of the front case 120.

In the conventional belt-type dryer, an opening is formed not only in front of the drum but also in the rear of the drum, and substantially the drum is formed only with a cylindrical side wall with front and rear openings. And a rear supporter is provided in the rear opening of the drum. That is, it is supported by the rear supporter in a state where the rear opening of the drum is blocked. Since the rear supporter has a fixed configuration, only the side wall of the drum is rotated by a belt.

However, in this embodiment, the drum 20 is made of a cylindrical side wall 21 as well as a rear wall 22, and the side wall 21 and the rear wall 22 rotate integrally. Therefore, the drum rear support structure in this embodiment is different from the conventional belt type dryer.

The drum in this embodiment, unlike the drum of the conventional dryer, the side wall 21 and the rear wall 22 of the drum 20 rotate integrally. The drum in this embodiment may be similar to the drum of the washing machine. However, since the washing is not performed on the drum, a through hole for entering or exiting air or water is not formed on the side wall of the drum in this embodiment. However, air communication is allowed on the rear wall 22 and a plurality of through-holes or through-holes for excluding entry and exit of clothing will be formed. This will be described later.

The rear of the drum 20 may be rotatably supported by the drum shaft 210. More specifically, it can be said that the drum shaft 210 is rotatably supported by the rear case 130, and consequently, the rear of the drum is rotatably supported by the rear case 130. The rear case 130 is configured to form a support structure for the entire dryer. Therefore, the rear of the drum 20 may be firmly and rotatably supported through the rear case 130 which is a support structure of the dryer.

The drum shaft 210 extends rearward from the center of the rear wall 22 of the drum 20. In addition, the driving unit 200 and the power transmission units 210, 220, and 230 are provided behind the drum rear wall 22. The power transmission units 210, 220, and 230 include the drum shaft 210, and the driving unit 200 includes the motor 260 and the power transmission units 210, 220, and 230.

The power transmission units 210, 220, and 230 are provided between the drum 20 and the rotor 270 of the motor 200 to transmit the driving force of the rotor to the drum. Therefore, the driving unit 200 including the power transmission units 210, 220, and 230 may be located at the rear rear of the drum 200.

The motor 260 may include a stator 280 and a rotor 270 rotatably provided outside the stator 280 in a radial direction. Therefore, the motor 260 may be an outer rotor type motor. Such outer rotor type motors are frequently used in direct-type washing machines. However, in the conventional dryer, as described above, it is difficult to implement an outer rotor type motor because it is difficult to implement a direct-type dryer.

In this embodiment, the stator 280 is preferably provided on the outside of the rear case 130. In particular, it is preferably provided to be fixed to the outside of the rear case 130. The rear case 130 is configured to form the outer shape of the dryer at the rear of the dryer 10 and form the inner space of the dryer. Therefore, the rear case 130 is a fixed configuration. Therefore, the stator 280 may be securely fixed by fixing the stator 280 to the outside of the rear case 130.

Since the motor 260 is provided on the outside of the rear case 130, the distance between the inside of the rear case 130 and the drum rear wall 22 can be provided only to the extent that it is possible to avoid rotational interference of the drum. In addition, since the motor 260 is provided outside the rear case 130, manufacturing is very easy.

The stator 280 may be provided to be spaced apart from the rear surface of the rear case 130. That is, it is preferable that the stator 280 is not directly coupled to the rear case 130. A connector 250 is provided between the rear case 130 and the stator 280. The stator 280 may be said to be coupled to the rear case 130 through the connector 250.

The reducer 230 may be located inside the connector 250, specifically, in the hollow portion 250a positioned inside the connector in the radial direction. That is, the speed reducer 230 may be inserted into the connector 250. Therefore, it is possible to minimize the increase in the front-rear spacing of the driving unit 200 or the power transmission units 210, 220, and 230 by the reduction gear 230.

The speed reducer 230 may be located between the rotor 270 and the drum 20. It may be provided to convert the driving force of the rotor 270 to be transmitted to the drum (20). Specifically, the reducer 240 may be provided to convert high RPM low torque of the rotor 270 to low RPM high torque of the drum 20.

The drum shaft 210 coupled with the drum 20 is located at the front of the reducer 230 and the rotor shaft 220 coupled with the rotor 270 is located at the rear of the reducer 230. The rotor shaft 220 rotates integrally with the rotor 270, and the drum shaft 210 rotates integrally with the drum 20. Therefore, the reduction gear 230 may be said to constitute a power transmission unit that converts power of the rotor shaft and transmits it to the drum shaft. In order to secure efficiency and ease of power transmission, it is desirable that the drum shaft 210 and the rotor shaft 220 form a coaxial shaft.

The reducer 230 may be mounted on the rear case 130. The speed reducer 230 may be mounted to directly contact the rear surface of the rear case 130. In addition, a connector 230 is provided radially outward of the reduction gear 230, and the stator 280 may be mounted to the rear case 130 through the connector 230.

The rotor 270 rotates on the radially outer side of the stator 280, and substantially the rotor 270 is formed to extend further forward toward the rear case than the stator 280 on the radially outer side of the stator. Therefore, it can be said that securing the front-to-back separation distance between the rear case 130 and the stator 280 through the connector 230 is to secure a rotation space of the rotor 270.

In addition, the speed reducer 230 is positioned in the form inserted into the connector 250. Therefore, the front-rear width of the driving unit 200 by the reduction gear 230 and the motor 260 can be formed very compactly. Thereby, the width expansion to the outside of the rear case 130 can be minimized.

On the other hand, it can be said that the driving unit 200 including the power transmission unit 230 is supported by a rear case forming an outer shape of the dryer and forming a support structure of the dryer.

In this embodiment, since the motor 260 and the reducer 230 are located at the rear of the rear case 130, there is a fear that these components are exposed to the outside. Therefore, protection of these configurations is necessary. To this end, a driving unit cover 180 covering the driving unit from the rear of the dryer 10 may be provided.

Among the components constituting the driving unit 200, a configuration that is formed to be largest in the radial direction may be referred to as a rotor 260. Therefore, the components constituting the driving unit 200 except for the rotor 260 are all located in the radially inner side of the rotor 260. Therefore, it is sufficient that the driving part cover 180 is formed to completely cover the rotor 260. That is, the driving unit cover 180 may be formed in a circular dish shape having an outer diameter slightly larger than the outer diameter of the rotor 26.

The driving unit cover 180 may be combined with the rear case 130 from the rear of the rear case 130. Alternatively, the driving part cover 180 may be combined with a flow path duct 170 to be described later. The driving unit cover 180 and the flow path duct 170, which will be described later, are located at the rear of the rear case 130 and may not be configured to form a support structure of the dryer. Therefore, even if the driving unit cover 180 and the flow path duct 170 are removed, there will be no change in the support structure of the dryer. However, in this embodiment, by extending a portion of the driving unit 200 and the air passage to the rear outside of the rear case 130 instead of inside the case 10, it can be said that the driving unit cover 180 and the flow path duct 170 are provided. You can.

In this embodiment, the air may be provided at the outside of the rear case 130 to have a rear air inflow structure provided to the drum 20. Specifically, the flow path duct 170 is mounted on the rear case 130 to allow air to be supplied into the drum 20 through the flow path duct 170.

The flow path duct 170 may be mounted on the rear surface of the rear case 130 to form a space 171 through which air flows. In addition, the flow path duct 170 may be formed outside the radial direction of the driving unit 200. That is, the flow path duct 170 may be formed to surround the driving unit 200.

Therefore, the air flow space 171 inside the flow path duct 170 and the motor 260 and the reducer 230 may be structurally separated or separated from the outside of the rear case 130. Therefore, air flow can be smoothly performed, and hot air or humid air flowing into the motor 260 and the reducer 230 can be prevented.

Details of the air communication structure between the flow path duct 170, the rear case 130 and the drum 20 will be described later.

The motor 260 is located at the rear outside of the rear case 130. And the motor 260 is surrounded by the flow path duct 170 from the rear outside of the rear case 130. Therefore, it is not easy to connect the motor 260 by extending an electric wire or a signal wire inside the case 100.

In this embodiment, the wire or signal line passing through the rear case 130 extends from the radially outer side of the flow path duct 170 to the radially inner side, and may be connected to the motor 260. At this time, the wire or signal line may be exposed to the outside. In order to prevent such exposure, the electric wire cover 190 may be provided.

Hereinafter, a connection and a positional relationship between the drum rear wall 22, the rear case 130, and the driving unit 200 will be described in detail with reference to FIGS. 3 and 4. 3 is an enlarged cross-sectional view of the rear portion of the dryer shown in FIG. 1, and FIG. 4 is an exploded perspective view of the drum, the rear case, and the driving unit.

The rear case 130 is positioned behind the drum rear wall 22. Since the drum rear wall 22 is configured to rotate, it is spaced apart from the rear case 130.

A motor 260 is provided outside the rear case 130. The stator 280 of the motor is positioned to be spaced from the rear of the rear case to the rear by the connector 250 and is fixed to the rear case 130.

In order to transmit the driving force of the rotor 270 of the motor to the drum 20, power transmission units 210, 220, and 230 are provided. The power transmission unit 210 includes a drum shaft 210, a reduction gear 230, and a rotor shaft 220.

In order to transmit the driving force of the rotor 270, the rotor 270 is coupled to the rotor shaft 220. The rotor shaft 220 forms a coaxial axis with the rotation axis of the rotor and rotates integrally with the rotor. Accordingly, a coupler 296 may be provided to secure the rigidity of the fastening and the reliability of power transmission. The coupler 296 may be referred to as a rotor coupler 296.

The rotor coupler 296 may be coupled to the inner surface of the rotor through a plurality of bolts. And the rotor shaft 220 may penetrate the rotor coupler 296 and be coupled to the rotor 270 by a stud 294. A washer 295 may be interposed between the stud 294 and the rotor 270 to secure the coupling by the stud.

The stud 294 may be formed with a female screw at the center of the rotor shaft 220 so that the stud can be fastened.

In addition, the rotor shaft 220 may be serrated with the rotor coupler 296. A serration may be formed on the outer circumferential surface of the rotor shaft 220 and a serration may be formed in the rotor coupler through which the rotor shaft passes. Therefore, the driving force of the rotor can be firmly transmitted to the rotor shaft 220.

The driving force of the rotor shaft 220 is converted through the reduction gear 230 and transmitted to the drum shaft 210. The drum shaft 210 has the same or similar fastening structure to the rotor shaft 220 and may be combined with the drum rear wall 22.

That is, a stud 291, a washer 292, and a drum coupler 293 may be provided. Their shape and structure may be the same or similar to the stud 294, washer 295 and rotor coupler 296 for fastening the rotor shaft 220.

The stud 291 will penetrate through the stud through hole 29a from the inside of the drum to the outside (front to rear) and be coupled to the drum shaft 210. And the stud 294 will be coupled to the rotor shaft 220 through the stud through hole from the outside to the inside of the rotor (back to front).

The rotor shaft 220 rotates integrally with the rotor 270 and the drum shaft 210 rotates integrally with the drum 20. Therefore, the reduction gear 230 may be said to be a device for performing power conversion between the rotor shaft 220 and the drum shaft 210.

The reducer 230 includes a housing 231 and a converter 240 provided inside the housing. The conversion device may include various gears. The rotor shaft 220 and the drum shaft 210 may extend into the housing 231 and be connected to the converter. The rotor shaft 220 and the drum shaft 210 may be part of the reduction gear 230 or may be a part of the converter.

A drum shaft through-hole 232 through which the drum shaft 210 penetrates is formed in front of the housing 231. The drum shaft through-hole 232 may be formed to extend forward. That is, it may be provided to form a predetermined forward straight line distance. The drum shaft through hole 232 may penetrate the shaft through hole 130a formed in the rear case 130.

The shaft through hole 130a is formed so that the drum shaft 210 extends from the rear wall 22 of the drum 20 through the rear case 130 to the reducer 230. Here, it is not preferable that the drum shaft 210 is rotatably supported through the shaft through-hole 130a. This is because the rear case 130 is formed through a plate such as a thin steel plate, and it is not easy or desirable to form a bearing support structure in a through hole formed in the plate.

Therefore, the diameter of the shaft through-hole 130a is preferably formed so that the drum shaft through-hole 232 of the reducer housing 231 as well as the drum shaft 210 can penetrate.

The reducer housing 231 may be fixedly coupled at the rear of the rear case 130. In addition, the drum shaft through-hole 232 of the reducer housing 231 may extend further forward through the shaft through-hole 130a.

A bearing 234 may be provided inside the drum shaft through-hole 232. The drum shaft 210 may be inserted into the bearing 234. Therefore, the drum shaft 210 may be rotatably supported relative to the housing 231 through the bearing 234. Since the housing 231 is fixed to the rear case 130, it can be said that the drum shaft 210 is rotatably provided with respect to the rear case 130 through the housing 231.

In addition, the reduction gear housing 231 may be fixedly coupled to the connector 250. The reducer housing 231 may be coupled to be fixed by being molded inside the connector 250. The connector 250 may be fixed to the rear case from the rear of the rear case 130 while surrounding the reducer housing 231.

Accordingly, the speed reducer 230 may be securely fixed to the rear case 130 through the connector 250. This is because the radius of the portion where the connector 250 is engaged with the rear case 130 (eg, a coupling portion through a bolt or stud) is larger than the radius of the reducer housing 231.

As described above, the motor 260 may be an outer rotor type motor. Therefore, the rotor 260 rotates in the radially outer side of the stator 280. With this structure, the hollow portion 280a may be formed inside the stator 280 in the radial direction.

A part of the connector 250 may be inserted into the hollow portion 280a. Through this, an increase in the length of the front and rear of the driving unit 200 may be prevented, and the stator 280 may be firmly coupled to the connector 250.

The length of the front and rear for connecting the rotating shaft (which is a rotating shaft including a drum shaft, an intermediate shaft, and a rotor shaft described later) between the rotor 270 and the drum 20 may be increased by the reduction gear 230. Therefore, it is important to secure a rotatable support point of the rotating shaft. However, in order to secure such a support point, it is not desirable to increase the total length of the rotating shaft.

The rear portion of the reducer housing 231 is preferably inserted into the hollow portion 280a of the stator 280.

A rotor shaft through-hole 233 through which the rotor shaft 220 penetrates is formed at a rear side of the reducer housing 231. The rotor shaft through-hole 233 may be formed to extend rearward. That is, it may be provided to form a predetermined rear straight line distance. The rotor shaft through-hole 233 is preferably inserted into the hollow portion 280a of the stator 280.

A bearing 236 may be provided inside the rotor shaft through-hole 233. The rotor shaft 220 may be inserted into the bearing 236. Therefore, the rotor shaft 220 may be rotatably supported relative to the housing 231 through the bearing 236. Since the housing 231 is fixed to the rear case 130 and can be fixed in particular through a connector, it can be said that the rotor shaft 220 is also rotatably provided with respect to the rear case 130.

As described above, the bearing support point of the drum shaft 210 is substantially located in the space between the drum rear wall 22 and the front surface of the rear case 130. In addition, the bearing support point of the rotor shaft 220 is substantially located in the interior of the stator 280, that is, the hollow portion 280a. Therefore, it is possible to smoothly secure the bearing support point of the entire rotation shaft, and thereby, the entire length of the rotation shaft. It is possible to prevent the increase.

In addition, since the bearings 234 and 236 can be mounted in advance on the reduction gear housing 231, manufacturing is greatly facilitated.

The reducer 230 may include an intermediate shaft 241. The reduction gear converter 240 may include the intermediate shaft 241. The intermediate shaft 241 is a shaft 241 for coaxially connecting the rotor shaft 220 and the drum shaft 210, and is configured to rotate independently of the drum shaft 210 and the rotor shaft 220.

The intermediate shaft 241 is inserted into the center of the rotor shaft 220 and the drum shaft 210, respectively, and these shafts are coaxial. A bearing 235 is provided outside the intermediate shaft 241 and inside the drum shaft 210. The intermediate shaft and the drum shaft may be rotated independently through the bearing 235. A bearing 237 is provided outside the intermediate shaft 241 and inside the rotor shaft 220. The intermediate shaft and the rotor shaft can be independently rotated through the bearing 237.

Assembling may be very easy by the structures of the drum 20, the rear case 130, the power transmission unit, and the driving unit.

First, the reducer 230 and the connector 250 are coupled. The connector 250 is coupled to the rear case 130. After the stator 280 is coupled to the connector 250, the connector 250 may be coupled to the rear case 130. Then, the stator is temporarily coupled to the connector 250. The rotor shaft 220 is inserted into the center of the rotor 260 to be temporarily coupled, and similarly, the drum shaft 210 is inserted into the center of the drum rear wall 22 to be said to be temporarily coupled.

The drum rear wall and the drum shaft 210 are coupled through the stud 291 inside the drum. Then, the rotor 270 and the rotor shaft 220 are coupled through the stud 294 from the outer rear side of the rotor 270.

Through this order, the drum 20, the rear case 130, the power transmission unit 210, 220, 230 and the motor 260 can be easily combined. Thereafter, the flow path duct 170 is coupled to the rear case 130 from the rear of the rear case, and the driving part cover 180 is coupled to the flow path duct 170 to protect the driving part 200. In addition, the wire or signal line exposed after the wire or signal line is connected to the motor 260 may be protected by the wire cover 190. One end of the electric wire cover 190 may be coupled to the rear case 130 from the radially outer side of the flow path duct, and the other end may be coupled to the flow path duct or the rear case 130 from the radially inner side of the flow path duct 170. After the electric wire cover 190 is first coupled, the driver cover 180 may be combined.

Hereinafter, the drum 20 that can be applied to the present embodiment will be described in detail with reference to FIGS. 5 and 6.

5 is a front perspective view of the drum, and FIG. 6 is a rear front view of the drum.

The drum 20 may include a side wall 21 and a rear wall 22 in a form in which the front is opened. In addition, the drum may be formed in a cylindrical structure in which the rear side is blocked by the rear wall 22. Here, being clogged means that clothing is not allowed in and out, and air communication is possible.

A mounting region 23 is formed in the center of the rear wall 22. The mounting area 23 is an area where the drum shaft 210 is mounted and may be referred to as an area opposite to the speed reducer 230. An air intake region 24 may be formed outside the mounting region 23 in the radial direction. In addition, a rear wall border area 25 is formed outside the air intake area 24 in the radial direction, and the rear wall border area 25 may be connected to the side wall 21.

When the rear wall 22 is circular, the mounting area 23 is formed so that air communication is excluded for mounting the central drum shaft, and the radially outer side of the mounting area 23 is provided with an air intake area 24 to allow air to pass through. ) Can be said to be formed.

A plurality of holes 26 are formed in the air intake area 24 to allow air to communicate. Specifically, the air intake region 24 is formed in the form of a mesh. The wider the air intake area 24, the more evenly the air is supplied into the drum to increase drying efficiency. The diameter of the hole 29 is very small. This is because clothing is inserted into the hole 26 to prevent damage. Therefore, the number of the holes 26 is inevitably large so that air is smoothly supplied into the drum.

However, the rigidity of the rear wall 22 may be weakened by the hole 26. Accordingly, a plurality of radius bridges 27 and circumferential bridges 28 may be included to reinforce the rigidity of the rear wall 22 from the air intake region 24. The radial bridge 27 is provided to divide the air intake region 24 along the circumferential direction, and the circumferential bridge 28 can be provided to divide the air intake region 24 radially inside and out.

The radius bridge 27 may extend from the mounting area 23 to the air intake area 24 to the rear wall edge area 25. In addition, the radius bridge 27 may be connected to the circumferential bridge 28.

It is preferable that no holes 26 are formed in the radius bridge 27 and the circumferential bridge 28. Therefore, it can be said that the radius bridge 27 and the circumferential bridge 28 are formed as a support structure for supporting the air intake region 24 of the mesh structure by the plurality of holes 26. The radius bridge 27 and the circumferential bridge 28 are preferably formed convex in the front or convex in the rear in order to reinforce their rigidity.

It is preferable that no hole 26 is formed in the rear wall border area 25. Since the rear wall edge region 25 is connected to the side wall 21, it is to prevent the rigidity of the rear wall edge region 25 from becoming weak. In addition, when air flows into the rear wall edge region 25, it can be said that air is supplied to the clothes in close contact with the drum inner wall or air is supplied to the place where the clothes do not exist. Therefore, it is preferable to concentrate the air supply from the air intake region 24 rather than the rear wall edge region 25 in order to increase drying efficiency.

A stud hole 29a may be formed in the center of the mounting region 29 in the center of the drum rear wall 22. In addition, a washer seating portion 29c may be formed outside the radial direction surrounding the stud hole 29. A plurality of bolt fastening portions 29b may be formed on the radially outer side of the washer seating portion 29. Here, in this embodiment, the stud, bolt, or screw can be said to be named for convenience according to the relative size of the fastening means. Therefore, the fastening means will not be limited by the specific name.

The mounting area 29 may be referred to as an area engaged with the drum shaft 210. A coupler is provided to firmly fasten the drum shaft 210 to the drum 20 and secure reliability of power transmission. This may be referred to as a drum coupler 293 (see FIG. 3).

It is practically not desirable for hot air to enter the interior of the drum to the central portion of the rear wall of the drum. Therefore, it is preferable that the mounting region 29 extends further outward in the radial direction of the drum coupler.

6, the gaskets 40 and 50 projected onto the drum rear wall 22 are shown. The gaskets 40 and 50 may be provided for air sealing between the drum rear wall 22 and the rear case 130. That is, the air flowing into the interior from the outside of the rear case 130 passes through the air intake region 24 by sealing by a gasket between the drum rear wall 22 and the rear case 130 and flows into the drum.

Referring to FIG. 7, the position, structure, and function of the gaskets 40 and 50 will be described in detail. 7 is a cross-sectional view of the drum, the drive portion and the flow path duct portion in the gasket portion.

The gaskets 40 and 50 may include a radially inner medial gasket 40 and a radially outer gasket 50. The inner gasket 40 partitions the mounting area 29 and the air intake area 24 of the drum. Therefore, hot air can be prevented from leaking from the outside of the drum in the direction of the mounting area of the drum (inward in the radial direction). The outer gasket 50 partitions the air intake region 24 and the rear wall edge region 25 of the drum. Therefore, it can be prevented that hot air leaks from the outside of the drum to the rear wall edge region 25 of the drum.

The inner gasket 40 includes a fixing portion 41 and an extension portion 42, and a fastening portion 43 may be formed in the fixing portion 41. The inner gasket 40 may be mounted to the inner surface of the rear case through the fixing portion 41 and the fastening portion 43, and the extension portion 42 may be a drum rear wall 22 in the fixing portion 41. It may be formed extending in the direction. The extension portion 42 may be provided to abut against the drum rear wall to perform sealing. The extension portion 42 may extend obliquely from the radially outer side to the inner side. That is, the extension portion 42 may be located inside the fixing portion 41 in the radial direction.

Likewise, the outer gasket 40 includes a fixing part 51 and an extension part 52, and a fastening part 53 may be formed in the fixing part 51. The inner gasket 50 may be mounted on the inner surface of the rear case through the fixing portion 51 and the fastening portion 53, and the extension portion 52 is the drum rear wall 22 in the fixing portion 51 It may be formed extending in the direction. The extension portion 52 is provided to abut against the rear wall of the drum to perform sealing. The extension part 52 may extend obliquely from inside to outside in the radial direction. That is, the extension part 52 may be located outside the fixing part 21 in the radial direction.

Both the inner gasket 40 and the extending portions 42 and 52 of the outer gasket 50 may extend obliquely from the fixing portions 41 and 52 toward the drum rear wall. Through this, it is possible to perform sealing of the air while minimizing friction between the rotating drum and the ends of the extension portions 42 and 52.

Of course, unlike the above, it may be possible to mount the gaskets 40 and 50 to the drum 20 rather than the rear case 130. However, it would be desirable to mount the gasket on a fixed rear case 130 rather than the rotating drum 20. Through this, in addition to the ease of manufacture, the sealing point can be formed in the downstream side of the air passage (upstream), so it is more advantageous in terms of sealing.

On the other hand, as shown in Figure 7, the power transmission unit may be placed in a closed space. For example, the motor and the reducer including the stator 280 and the rotor 260 may be located inside the space surrounded by the rear case 130, the flow path duct 170, and the driving unit cover 180.

The reducer and the motor, especially the stator, generate heat as the drum is driven, and it is very advantageous to secure performance by resolving the heat. Therefore, it is desirable that a configuration for heat dissipation or cooling is added.

Rather than adding a configuration such as a separate cooling fan, it is possible to secure cooling performance using natural convection or convection through rotation of the rotor.

A plurality of openings 260a may be formed in the rotor 260, and air may flow from the outside of the rotor into the rotor as the rotor rotates. The introduced air may be flowed toward the stator 280.

Meanwhile, it is preferable that the air flowing into the rotor 260 is external air. To this end, the driving unit cover 180 may be provided with an opening 180a, and a plurality of openings 180a may be provided.

The air introduced from the opening 180a of the driving unit cover 180 cools the stator inside the rotor through the opening 260a of the rotor. Here, when the air cooled with the rotor is discharged to the outside, effective air circulation or flow may occur. Therefore, it is preferable that the driving unit cover 180 is provided with an emission unit 180b for discharging air to the outside.

By this structure, as shown in Fig. 7, air flow is generated, so that effective cooling can be performed.

Here, it is preferable that the positions of the openings 260a of the rotor and the openings 180a of the driving part cover 180 are opposed to each other. Through this, the flow resistance of air can be minimized. On the other hand, when air is introduced from the outside, it is not preferable that the inlet pressure is excessively high. Accordingly, it is preferable that the number of openings 180a and the total area of the openings are larger than the number of openings of the rotor and the total area of the openings.

In addition, the position of the inlet portion of the air and the location of the outlet portion of the air are preferably different from each other so that the inflow and outflow of air are smoothly performed. That is, it is preferable that the position of the discharge part is located radially outside from the position of the inlet part.

Accordingly, openings for air inflow and outflow from the driving unit cover 180 are easily formed, thereby enabling effective cooling of the motor and the reducer.

8 and 9, an air flow path of a dryer according to an embodiment of the present invention will be described in detail.

The rear case 130 may have an outlet 131 through which air is discharged from the inside of the dryer. In addition, the rear case 130 may have an inlet 135 through which air discharged through the outlet 131 flows into the dryer. The outlet 131 is a single outlet, and a plurality of inlets 135 may be formed.

The inlet 135 may be formed in the air supply region 134 of the rear case 130, and the air supply region 134 may be formed outside the mounting region 136 in the radial direction. The air supply region 134 may be formed to surround the mounting region 136.

The outlet 131 may be formed in the air intake area of the rear case 130. The air intake area may be provided outside the air supply area 134 in the radial direction. Since the outlet 131 may be formed as a single outlet, the outlet may be referred to as an air intake area.

Air introduced into the flow path duct 170 through the outlet 135 flows into the dryer through the inlet 135. Specifically, the flow path passing through the inlet 135 may be introduced into the drum by passing between the drum rear wall 22 sealed by the gaskets 40 and 50 and the rear case front.

The inlet 135 is preferably larger than the size of the hole 26 through which the air is introduced into the drum in order to reduce the resistance of air flow flowing through the inlet 135. As illustrated, the number of holes 26 of the drum projected on one inlet 135 may be 10 or more.

The region in which the hole 26 of the drum is formed is continuously formed except for the radius rib 27 along the circumferential direction. On the other hand, the inlet 135 and the inlet 135 may be provided to be spaced from each other along the circumferential direction. The area of the portion where the inlet 135 is formed in the air inlet region 134 may be similar to that of the portion where the inlet is not formed.

In addition, the radial width of the inlet 135 is preferably smaller than the radial width of the air intake region 24 of the drum. That is, it is preferable that the area for sucking air from the drum for supplying air from the rear case to the drum is larger. Through this, air inflow can be performed more smoothly, and air can be evenly introduced into the drum.

The flow path duct 170 may be provided to cover both the air intake area 131 and the air supply area 134 of the rear case, except for the mounting area of the rear case. Accordingly, the air introduced into the flow path duct 170 through the air intake region 131 may be discharged from the flow path duct through the inlet 134 while being branched to both sides of the mounting region and flowing along the periphery of the mounting region.

The air discharged through the inlet 134 flows into the drum through a plurality of holes 29 formed in the air intake region 24 formed in the drum rear wall 22. The air introduced into the drum is discharged to the front of the drum and is discharged to the outside of the dryer rear case 130 through the heat pump 300 and the fan 179 through the outlet 131 of the rear case.

Meanwhile, although not shown, the heat pump 300 may be replaced with a heating unit. That is, the configuration of condensing moisture in the air may be omitted. That is, the air outside the dryer is introduced into the dryer and heated,

Through this structure, in the dryer according to the present embodiment, drying may be performed while air is circulating. Includes a fan 179 that generates a circulating flow of air, a heat pump 300 that is an example for heating and condensing air, and a flow path duct 170 and a connection duct 179 that form an air flow path. can do.

On the other hand, the rear case 130 may be provided with a fan mounting portion 132 protruding rearward. The outlet 131 may be formed in the fan mounting portion 132. In addition, a wire lead-out hole 133 may be formed at an upper portion of the rear case 130.

The flow path duct 170 may include an inner coupling portion 172 and an outer coupling portion 171. The inner coupling portion 172 may be coupled to the rear case between the mounting area of the rear case and the air supply area. The outer coupling portion 171 may be combined with the rear case while surrounding the entire air supply area and the air intake area of the rear case. An expansion portion 173 is formed between the outer coupling portion 171 and the inner coupling portion 172 to form an air flow space 171.

The extension 173 may be formed to be convex from the rear case 130 to the rear. Therefore, the electric wire extending outward from the rear case through the electric wire taking-out hole 133 is connected to the motor located in the radially inner side of the inner coupling portion 172 of the flow path duct 170 across the extension portion 173. Should be. Therefore, the electric wire cover 133 for protecting the electric wire crossing also crosses the extension portion 173. The front and rear width of the dryer may be increased due to the wire cover 133. Therefore, it is preferable that a part of the extension part 173 is recessed forward and a seating part 173 on which the electric wire cover is seated is formed.

Between the air supply area 134 and the mounting area 136 of the rear case 130, a wire coupling area or a wire cover coupling area 137 may be formed. The wire coupling region 137 may be a region in which a portion of the mounting region 136 extends radially outward. Therefore, the radial width of the inlet 135 formed on the radially outer side of the wire coupling region may be narrowed due to the wire coupling region 137.

Wire connection regions may be formed in the flow path ducts corresponding to the wire connection regions of the rear case. One end of the wire cover 190 may be fixedly coupled through the wire coupling region.

As described above, the dryer according to an embodiment of the present invention preferably includes a reducer 230. Hereinafter, with reference to FIG. 10, the reason for the need for the speed reducer and the optimum speed reduction ratio in one embodiment of the present invention will be described.

In order to facilitate the control of the torque and RPM of the motor, the outer rotor type motor in which the permanent magnet is provided in the rotor is frequently used in the DD washing machine. In order to apply this outer rotor type motor to the present embodiment, it is necessary to examine the efficiency of the motor. FIG. 10 shows the efficiency of the motor according to the current phase angle when 269 W of power consumption is used in the motor.

As shown, it can be seen that the efficiency of the outer rotor type motor is high in a high-speed driving area, for example, 600 to 750 RPM. However, in the low-speed operation around 50 RPM, which is the normal driving RPM of the dryer drum, the efficiency is significantly reduced or the drum itself does not rotate due to insufficient torque. That is, a case in which drum driving is impossible may occur. For this reason, it can be said that a reduction gear capable of driving the drum at approximately 50 RPM while driving the motor at the RPM having the optimum efficiency is required. Therefore, in this embodiment, for example, a reduction gear having a reduction ratio of 15:1 may be provided. The optimum reduction ratio may be changed due to the difference between the motor itself and the drum drive RPM, but will be approximately 15:1.

In general, a reducer using a planetary gear is manufactured for the purpose of deceleration such as a servo motor and is fastened to the front of the motor. Therefore, it is common to increase the thickness (the axial length of the gear) of the planetary gear by limiting the outer diameter of the reduction gear by the motor to secure the safety factor.

However, the reducer of the dryer according to an embodiment of the present invention may be said to require a compact design for height (axial length) rather than the outer diameter of the reducer. This is because the motor in this embodiment is an outer rotor type motor, so that the outer diameter of the reduction gear can be made to approach the outer diameter of the rotor at the maximum.

In order to realize a high reduction ratio (eg 15:1), a two-speed planetary gear reducer may be applied. The 1-speed planetary gear reducer is usually used at a reduction ratio of about 9:1, and the 15:1 reduction ratio in the 1-speed planetary gear reducer is based on the geometric feature of the number of planetary gears implementing the reduction mechanism. It becomes two by. Therefore, stability is very poor. Therefore, in this embodiment, a two-speed planetary gear reducer that implements a high-speed reduction ratio and decelerates through four planetary gears from one-speed deceleration to consequently performs two-speed deceleration can be applied.

On the other hand, when using a second gear, the thickness by the gears (the axial length of the reducer) increases, so it can be said that a compact and lightweight design is very required. In this embodiment, it is possible to provide a reduction gear that converts a high RPM low torque to a low RPM high torque in two stages between a rotor and a drum. In addition, it is possible to provide a reduction gear capable of realizing a compact and light weight in consideration of the power conversion characteristics in the dryer.

In the first-stage power conversion, the thickness of the gear can be reduced in consideration of the characteristic that the torque of the input shaft (the rotor shaft in this embodiment) is low. And, as an example of engineering plastics, not steel-based materials, gears can be formed through POM (Poly Oxy Methylene)-based materials. Accordingly, a compact and lightweight design is possible by lowering the thickness and weight of the gear in proportion to the strength of the gear.

However, in the two-stage power conversion, it can be said that a higher gear strength is required because the torque of the output shaft (the drum shaft in this embodiment) is increased through the first-stage power conversion. Therefore, in the two-stage power conversion, it can be considered that it is preferable to increase the height of the gear relatively and to form the gear from a steel material.

In this regard, it may be difficult to implement a compact reducer due to the thickness of the gear for power conversion, especially in two-speed power conversion.

In an embodiment of the present invention, attention was paid to improving gear strength through an increase in the outer diameter of the gear, not an improvement in gear strength by increasing the thickness of the gear.

By using the same reduction ratio and the same speed components, it is possible to improve the gear strength by increasing the overall outer diameter of the planetary gear. This is because when the outer diameter increases in a gear having the same number of gear teeth, the area of the support portion of the gear teeth increases. In other words, it is possible to increase the support area of the gear teeth by increasing the size of the gear teeth rather than increasing the thickness of the gear to increase the area of the support area of the gear teeth.

Securing the strength of the gear can be equally applied to the first-stage power conversion as well as the second-stage power conversion. Therefore, it is possible to implement a very compact reducer back and forth in the entire first gear and second gear having the same outer diameter. In particular, since the reducer in this embodiment converts the power of the outer rotor type motor, an increase in the outer diameter of the reducer can be tolerated sufficiently. In particular, it is possible to increase the outer diameter of the reducer according to the inner diameter of the hollow portion 250a of the connector that fixes the stator to the rear case.

Hereinafter, a reduction gear and a reduction principle according to an embodiment of the present invention will be described in detail with reference to FIGS. 11 to 13. FIG. 11 is an exploded perspective view of the reducer, FIG. 12 shows the connection structure of the reducer components for the first stage conversion of power, and FIG. 13 shows the connection structure of the reducer components for the two stage transformation of power.

The reducer 230 includes a housing 231, and the housing 231 may include a front housing 231a and a rear housing 231b. Components for various converters may be accommodated in the housing 231. A fastening part 231c may be provided in the housing 231. The rear housing 231b substantially accommodates the components for the converter, and the front housing 231a can perform a cover function covering the rear housing. Of course, this could be the opposite.

When the rear housing 231b substantially accommodates the components for the converter, the fastening portion 231c may be provided in the rear housing 231b. The rear housing 231b is inserted into the hollow portion 250a of the connector 250 described above and fixedly coupled to the connector 250 through the fastening portion 231c.

A rotor shaft 220 through hole 233 is formed in a central portion of the rear housing 231b, and a bearing 236 is provided inside the through hole 233 to rotatably support the rotor shaft 220. .

A drum shaft 210 through hole 232 is formed in a central portion of the front housing 231a, and a bearing 234 is provided inside the through hole 232 to rotatably support the drum shaft 210. .

It can be said that the input RPM at the first stage power conversion is high RPM. Therefore, the bearing 336 supporting the rotor shaft 220 is preferably a ball bearing. In addition, two ball bearings are preferably provided along the rotor shaft 220. The output RPM in the two-stage power conversion can be said to be low RPM. Therefore, it is preferable to use an oilless bearing as the bearing supporting the drum shaft 210. That is, it is to ensure reliability and reduce manufacturing costs.

The power of the rotor 260 is transmitted directly to the rotor shaft 220. The rotor shaft 220 is firmly coupled to the rotor 260 through a rotor coupler 296, a washer 295, and a stud 194. One side of the rotor shaft 220 may be coupled to the rotor, and the other side may form the first sun gear 221. Accordingly, the rotor shaft 220 and the first sun gear 221 may be referred to as one component or configuration. It can be said to be a structure formed of a single material.

The same first planetary gear 223 is positioned on the radially outer side of the first sun gear 221, and the first sun gear and the first planetary gear are gear-engaged. If the first planetary gear is provided to have the same distance along the circumferential direction of the first sun gear, for example, four first planetary gears may be provided.

The first planetary gear 223 is rotatably provided based on the roller shaft 222, and the roller shaft 222 may be fixed to the first carrier 243. A first carrier supporter 224 may be provided for fixing the front and rear positions of the first planetary gear and fixing the roller shaft. Accordingly, the first planetary gear 223 may be rotatably provided on the first carrier 243, and as the first planetary gear 223 orbits the first sun gear 221, the first carrier ( 243) will rotate.

The first planetary gears 223 may all be geared in a form inscribed to the ring gear 244.

When the reduction ratio in each step is called a and the ring gear 244 is provided to be fixed inside the reduction gear housing 231, a is 1 obtained by dividing the number of gear teeth of the ring gear 244 by the number of teeth of the sun gear. Has the value added.

When the motor power is input to the rotor shaft 220 with N RPM and T torque, the first sun gear 221 has the same N RPM and T torque.

As the rotor shaft 220 rotates, the first planetary gear 223 and the first carrier 243 rotate. At this time, the first carrier 243 has a reduction ratio a, N/a RPM, and T*a torque values. Therefore, it can be said that the power of the rotor shaft 220 is converted to one stage through the first carrier 243.

A first planetary gear 223 is rotatably provided on one side (the rotor shaft side) of the first carrier 243. In addition, a second sun gear 242 may be provided on the other side (drum shaft side) of the second carrier 243. The second carrier 243 and the second sun gear 242 may be integrally formed in a single configuration. Therefore, the second carrier 243 and the second sun gear 242 rotate integrally. Therefore, the second sun gear 242 has a reduction ratio a, N/a RPM, and T*a torque values.

As the second sun gear rotates, the second planetary gear 213 and the second carrier 211 rotate. The second planetary gear 213 may be rotatably provided on the second carrier 211 through the roller shaft 212. A second carrier supporter 214 may be provided to fix the front and rear positions of the second planetary gear 213 and the roller shaft 212.

The second carrier 211 rotates as the second planetary gear 213 orbits the second sun gear 242.

At this time, the second carrier 211 has a reduction ratio a, N/a/a RPM, and T*a*a torque values.

The second carrier 211 may be combined with the drum shaft 210. Preferably, the second carrier 211 and the drum shaft 210 may be provided in a single component or configuration. Therefore, the drum shaft 210 has N/a/a RPM and T*a*a torque values.

As described above, the reduction ratio of the reduction gear in this embodiment is 15:1. Accordingly, when both the first gear ratio and the second gear ratio have the same value a, the value a may have a square root of 15, that is, a value of 3.871.

Here, it is very effective to have the deceleration ratio of the final a-squared value with the first-stage reduction ratio a and the second-stage reduction ratio a. This is because the ring gear used for the first and second stage deceleration can be implemented as a single ring gear. That is, the rear of the fixed single ring gear may be geared with the first planetary gears and the front of the single ring gear may be geared with the second planetary gears. Therefore, the reduction gear implementation can be very easy.

In addition, there is an effect capable of making the radius sizes of the planetary gears and the carriers the same. Therefore, it is possible to implement a reducer having a cylindrical shape and having the same front and rear diameter. Of course, the structure of the fastener for the fixed coupling of the reducer is out of the question.

The drum shaft 210 may be securely fixed to the drum rear wall through a drum shaft coupler 293, a washer 292, and a stud 291.

After all, according to this embodiment, the reducer 230 is provided between the drum rear wall and the inner wall of the rotor to convert the high RPM low torque of the rotor to the low RPM high torque of the drum.

Meanwhile, the rotor shaft 220 and the drum shaft 210 are spaced apart from each other back and forth. It is necessary to form the rotor shaft 220 and the drum shaft 210 coaxially and to keep the coaxial firmly.

To this end, an intermediate shaft 241 may be provided. One side of the intermediate shaft may be connected to the rotor shaft 220 to form a coaxial, and the other side may be connected to the drum shaft 210 to form a coaxial.

The intermediate shaft 241 may be integrally configured with the first carrier 243 and the second sun gear 242. That is, it may consist of a single component or parts. Therefore, the intermediate shaft 241 may rotate integrally with the first carrier 243. This means that the rotation speed of the first carrier is different from the rotation speed of the rotor shaft and the drum shaft, respectively.

Accordingly, there is a need for a structure that supports the intermediate shaft 241, the drum shaft 210, and the rotor shaft 220 to be rotatable with different rotation speeds or rotatable independently of each other. Of course, this support structure can be said to be a structure for forming and maintaining a coaxial.

The intermediate shaft 241 is positioned to be inserted into the center of the drum shaft 210 and the center of the rotor shaft 220. An intermediate shaft may be inserted by forming a hollow in a part of the drum shaft and the rotor shaft. A bearing 235 is provided between the drum shaft and the intermediate shaft, and likewise a bearing 237 may be provided between the rotor shaft and the intermediate shaft.

The thrust generated between the rotor 260 and the drum rear wall 22 may be supported through the bearings 236 and 234 described above. In one example, the stepped jaw formed around the lateral drum shaft of the oilless bearing 234 and the annular ring (not shown in FIG. 10) fastened to the sides and shafts of the ball bearing 236 may be supported to contact. have. Therefore, it is possible to minimize frictional force due to thrust in the driving unit or the power transmission unit.

On the other hand, it may be possible to apply a reducer of a different type from the planetary gear reducer in the above-described embodiment of the present invention to the dryer according to the embodiment of the present invention. As an example, a cyclo reducer can be applied.

The cyclo reducer is a reducer using a reduction device having a cyclo tooth. It is a gear reducer in which the shape of the gear teeth is formed by a continuous curve of a cyclo tooth and is in rolling contact. Since the input shaft and the output shaft can be coaxial, it can also be applied in this embodiment.

According to the dryer according to an embodiment of the present invention, uniform drying may be performed. As shown in Figure 14, it can be seen that the dryer according to the embodiment of the present invention has a uniform air flow rate regardless of the front-rear position of the drum.

The standard deviation of the speed means the deviation of the air flow velocity across the entire section at the drum section position. The small speed standard deviation means that there is not much difference in speed in all areas of a specific section.

Therefore, according to the present embodiment, it can be seen that the standard deviation of speed at seven cross-sectional positions between the front and rear of the drum is about 0.7 or less and about 0.6 or less except for the rear of the drum. Since the inflow of air from the rear of the drum is performed only in a certain region, this result can be predicted.

However, it can be seen that in the conventional dryer having a structure in which air is introduced into the rear of the drum, the speed standard deviation is significantly increased according to the position of the drum section. In particular, it can be seen that it is greater than the standard speed deviation in the present invention at all positions. In addition, it can be seen that the speed standard deviation is remarkably high near the rear of the drum. This paradoxically shows that in one embodiment of the present invention, the speed standard deviation at the rear of the drum is significantly lower.

The speed standard deviation characteristic of the dryer according to the exemplary embodiment of the present invention can be assumed to be due to the annular air supply area of the rear case and the annular air intake area of the drum rear wall. That is, since the position where air is introduced into the drum is the same regardless of whether the drum is rotated and whether the drum is rotated, it can be assumed that it has these characteristics. In addition, it can be assumed that as compared to the conventional dryer, the area where air is introduced into the drum and the area that supplies air toward the drum increase.

In particular, according to this embodiment, it can be seen that air may be introduced through the entire 360-degree inside the drum. Therefore, it can be seen that a larger air volume can be supplied into the drum, and air can be uniformly supplied.

Therefore, according to the dryer according to the present embodiment, drying efficiency may be increased and uniform drying may be performed.

10: dryer 20: drum
130: rear case 170: flow path
180: driving unit cover 190: electric wire cover
200: driving unit 210: drum shaft
220: rotor shaft 230: reducer

Claims (20)

A case provided to form and support the appearance of the dryer;
A drum provided inside the case and accommodating a drying object; And
In the dryer is provided to drive the drum, and having a drive unit including a motor having a stator and a rotor,
The case includes a rear case forming and supporting the rear appearance of the dryer,
The rotor is rotatably supported on the outside of the rear case with respect to the rear case in an axis and an axis of rotation of the drum,
The stator is a dryer fixed to the rear case outside the rear case. According to claim 1,
The drive unit includes a power transmission unit for transmitting the rotational force of the rotor to the drum,
The power transmission unit is a dryer, characterized in that provided between the rotor and the drum. According to claim 2,
The motor is a dryer characterized in that the rotor is an outer rotor type motor provided to rotate in the radially outer side of the stator. According to claim 2,
The stator has a hollow in the radially inner side and is fixed to the outside of the rear case. The method of claim 4,
A dryer including a connector provided between the stator and the rear case to fix the stator to the rear case, and forming a front-rear gap between the stator and the rear case. The method of claim 5,
Dryer characterized in that a part of the connector is inserted into the hollow portion of the stator. The method of claim 5,
The connector is a dryer characterized in that it has a hollow portion in the radially inner side. The method of claim 7,
The power transmission unit includes a reducer for converting high RPM low torque of the rotor to low RPM high torque of the drum,
Dryer characterized in that at least a part of the reducer is inserted into the hollow portion of the connector. According to claim 2,
The power transmission unit,
A drum shaft connected to the rear of the drum;
A rotor shaft connected to the rotor; And
And a reduction gear provided between the drum shaft and the rotor shaft. The method of claim 9,
The rear case has a dryer, characterized in that a shaft through-hole through which the drum shaft passes. The method of claim 10,
The reducer,
housing; And
And a converter provided inside the housing to convert a high RPM low torque of the rotor to a low RPM high torque of the drum. The method of claim 11,
Dryer, characterized in that the housing of the reducer is provided to be fixed to the outside of the rear case. The method of claim 12,
The housing of the reducer,
A drum shaft through-hole protruding a predetermined length forward so that the drum shaft penetrates, and a bearing for rotatably supporting the drum shaft is mounted therein; And
A dryer including a rotor shaft through-hole protruding a predetermined length rearward so that the rotor shaft penetrates therethrough and a bearing for rotatably supporting the rotor shaft is mounted therein. The method of claim 13,
The drum shaft through-hole is positioned to be inserted into the shaft through-hole of the rear case,
The rotor shaft through-hole is characterized in that the dryer is inserted into the hollow portion formed in the radially inner side of the stator. The method according to any one of claims 1 to 14,
In the rear case, a shaft through-hole formed through a drum shaft connected to the drum and transmitting power of the rotor to the drum is formed,
In the rear case, a dryer characterized in that a mounting area for mounting the driving unit is formed radially outside about the shaft through-hole. The method of claim 15,
An air supply region for supplying air into the drum is formed in the rear case,
The air supply area is a dryer, characterized in that formed in the radially outer side of the mounting area around the mounting area. The method of claim 16,
In the rear case, an air intake area for intake air from the drum is formed,
The air intake region is characterized in that the dryer is formed on the radially outer side of the air supply region. The method of claim 17,
It is provided to be coupled to the rear case from the outside of the rear case,
And a flow path duct covering the air intake area and the air supply area and forming an air flow space between the rear case. The method of claim 15,
A dryer, characterized in that a donut-shaped air intake region facing the air supply region of the rear case is formed on the rear wall of the drum. The method of claim 19,
And a gasket provided between the rear case and the rear wall of the drum so that air supplied from the air supply area of the rear case flows into the air intake area of the drum.

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