KR101957765B1 - Stator Assembly for Direct Driven Driving Apparatus of Washing Machine - Google Patents

Abstract

A stator assembly of a direct drive type washing machine according to the present invention includes a stator core; The stator core is audited by an insulator; A central space inside the stator core and the insulator; And a lever unit engaging portion formed on the insulator and coupled to the lever unit.

Description

Technical Field [0001] The present invention relates to a stator assembly for a direct drive type washing machine,

The present invention relates to a driving apparatus for a washing machine. More particularly, the present invention relates to a stator assembly of a driving apparatus for a new washing machine, which is configured to be able to be driven by reducing the rotation of a motor in a driving apparatus for a direct coupling type washing machine.

Generally, a washing machine is divided into a pulsator washing machine and a drum washing machine. The pulse washing machine and the drum washing machine are driven differently from each other. For example, a drive device used in a pulse washer is disclosed in Korean Patent No. 10-1603210, Japanese Patent Laid-Open Nos. 10-2004-0071404 and 10-2004-0071417, Are disclosed in Korean Patent Publication Nos. 10-2017-0010031, 10-2015-0009345, and 10-2013-0091589.

The pulsator washing machine has a washing tub fixed thereto, and the laundry is washed or rinsed by making a flow of water in a washing or rinsing mode by rotating a pulsator installed at the center of the washing tub. The pulsator is rotated by the washing shaft, and the operation of the pulsator in the washing and rinsing mode must be rotated at low speed and high torque. In the dehydration mode, the washing tub must be rotated at high speed and low torque. The pulsator washing machine is provided with a speed reducer for adjusting the rotation speed and torque of the motor for such operation, and the operation of the speed reducer is made by the clutch.

In a drum type washing machine, a direct drive type in which a motor is fixed to a tub and a washing tub (drum) installed in the tub is directly connected to the motor and the washing tub is rotated by the rotation of the motor is widely used. In this direct drive type drive device, the rotation speed of the motor is controlled to provide the rotation speed necessary for the washing, rinsing and dewatering modes.

However, since the rotation shaft of the motor directly rotates the washing tub in the direct drive type driving apparatus, the operating efficiency of the motor is inevitably lowered at the time of the low speed operation in the washing or rinsing mode. However, it is difficult to apply the clutch or deceleration mechanism used in the pulsator washing machine because of the structural characteristics and limitations of the drum washing machine and the direct drive type driving device.

In order to solve the above-mentioned problems, the present inventors propose a driving apparatus for a washing machine with a new structure in which a speed reducer is applied to a direct drive type driving apparatus.

An object of the present invention is to provide a driving device for a washing machine of a new structure.

Another object of the present invention is to provide a stator assembly of a driving apparatus for a washing machine of a new structure.

It is still another object of the present invention to provide a driving apparatus for a washing machine having a high driving efficiency by applying a speed reducer structure to a driving apparatus of a drum washing machine.

The above objects and other intrinsic objects of the present invention can be easily achieved by the present invention described below.

The stator assembly of the direct drive type washing machine according to the present invention includes:

Stator core;

The stator core is audited by an insulator;

A central space inside the stator core and the insulator; And

A lever unit engaging portion formed on the insulator and coupled to the lever unit;

And a control unit.

In the present invention, the lever unit may include a lever holder fixed to the lever unit engaging portion, a first lever coupled to the lever holder at a first hinge so as to be rotatable, and a second lever coupled to the lever holder at a second hinge to be rotatable And a second lever which is in contact with the first lever and cooperates with the first lever.

In the present invention, it is preferable that the central space is provided with a reduction coupling unit so as to be movable forward and rearward.

In the present invention, it is preferable that the insulator has a plurality of coupling holes for coupling with the turbine.

The present invention provides a driving device for a washing machine and a stator assembly thereof that can maximize energy efficiency by applying an optimum reduction ratio in a washing or rinsing mode by applying a speed reducer structure to a direct drive type washing machine. .

1 is a perspective view of a driving apparatus for a washing machine according to the present invention, viewed from the rear side.
2 is a perspective view of a driving apparatus for a washing machine according to the present invention as viewed from the front side.
3 is a perspective view of the driving device for a washing machine according to the present invention when viewed from the rear side of the tub separated from the tub.
4 is a perspective view of the driving device for a washing machine according to the present invention, as viewed from the front side, when the tub is separated.
FIG. 5 is a perspective view of a driving apparatus for a washing machine according to the present invention.
6 is a perspective view of the reduction coupling unit of the driving apparatus for a washing machine according to the present invention as viewed from the front side.
7 is a perspective view of the rear side of the reduction coupling unit of the driving apparatus for a washing machine according to the present invention.
8 is a perspective view showing the decompression coupling unit of the driving apparatus for a washing machine according to the present invention in an exploded manner.
9 is a perspective view illustrating a stator assembly of a driving apparatus for a washing machine according to the present invention.
10 is a side view showing the operation principle of a lever unit of a driving apparatus for a washing machine according to the present invention.
11 is a side view showing the operation of the lever unit and the reduction coupling unit in the washing or rinsing mode of the washing machine driving apparatus according to the present invention.
12 is a side view showing the operation of the lever unit and the reduction coupling unit of the driving apparatus for washing machine according to the present invention in the dehydration mode.
13 is a perspective view illustrating a rotor assembly of a driving apparatus for a washing machine according to the present invention.
14 is a sectional view showing a rotor assembly of a driving apparatus for a washing machine according to the present invention.
15 is a sectional view showing the structure of the driving apparatus for washing machine according to the present invention when it operates in a washing or rinsing mode.
16 is a sectional view showing the structure of the driving apparatus for washing machine according to the present invention when it operates in the dewatering mode.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a driving apparatus 1 for a washing machine according to the present invention viewed from the rear side, FIG. 2 is a perspective view seen from a front side, and FIG. 3 is a front view of the driving apparatus 1 for a washing machine according to the present invention. Fig. 4 is a perspective view from the front side. Fig.

1 to 4, a driving apparatus 1 for a washing machine according to the present invention includes a tub 10, a reduction coupling unit 20, a stator assembly 30, and a rotor assembly 40 .

The tub 10 is fixedly installed in a main body (or a cabinet) of a washing machine (not shown). At the center of the tub (10), the end of the shaft (11) penetrates forward. In the present specification, 'front' and 'rear' refer to 'front' side of the tub 10 and 'rear' side of the rotor assembly 40 with respect to the positions of the tub 10 and the rotor assembly 40, .

The rotation of the shaft 11 is achieved by transmitting the rotational driving force of the motor through the deceleration coupling unit 20. As used herein, the term " motor " is used herein to refer to a stator assembly 30 and a rotor assembly 40 together. 4, the deceleration coupling unit 20 is located inside the stator assembly 30 and the rotation of the rotor assembly 40 rotates the deceleration coupling unit 20 and the deceleration coupling unit 20 The rotation of the shaft 11 causes the rotation of the shaft 11. The deceleration coupling unit 20 is switched to the normal operation mode and the deceleration operation mode for the operation of the lever unit 300. [ In the normal operation mode, since the rotational speed of the rotor assembly 40 is equal to the rotational speed of the shaft 11, a high-speed dehydration mode is applied. In the decelerating operation mode, the rotational speed of the rotor assembly 40 is reduced by operating at a speed lower than the rotational speed of the shaft 11, and thus operates in a low-speed washing or rinsing mode.

A drum (also referred to as a drum) (not shown) is connected to the front end of the tub 10 and coupled to the end of the shaft 11. A tub bearing insertion portion (101) is formed on the front side of the center of the tub (10). The tub bearing 12 coupled to the tub bearing insertion portion 101 supports the rotation of the shaft 11. A lever unit position space 102 formed radially outward from the central portion is formed at the rear of the tub 10, and this space extends to the opening groove 102a on the side surface of the tub. The first lever 320 of the lever unit 300 is located in the lever unit position space 102. The first lever 320 can be connected to a drain valve motor (not shown) installed at one side of the tub by a separate wire (not shown) extending through the lever unit position space 102 and the opening groove 102a have. The drain valve motor can control the operation of the lever unit 300 while controlling the drain valve.

Referring to FIG. 3, a motor coupling portion 103 protruded to engage the stator assembly 30 is formed at the center of the rear side of the tub 10. A plurality of alignment protrusions 103a and a coupling hole 103b are formed in the motor coupling portion 103. [ The alignment protrusion 103a is engaged with the alignment hole 34 formed in the stator assembly 30 so that the stator assembly 30 is positioned in the tub 10 in the correct position. The coupling hole 103b communicates with a separate coupling hole 35 formed in the stator assembly 30 so that the stator assembly 30 is coupled to the tub 10 by a separate fastening means such as a bolt.

At the center of the tub (10), a shaft penetration portion (104) through which the shaft passes is formed. Around the rear side inlet of the shaft penetration portion 104 of the tub 10, there is provided a tub tooth 105 formed radially. The tub teeth 105 are engaged with the reduction coupling unit 20 in the washing and rinsing mode to cause the reduction coupling unit 20 to cause a reduced rotation of the shaft 11, as described below. On the inside of the shaft penetration portion 104, a spring support portion 106 is formed in a stepped shape to support one end of the spring 24.

Fig. 5 is a perspective view of the driving apparatus 1 for a washing machine according to the present invention.

5, a driving apparatus 1 for a washing machine according to the present invention comprises a tub 10, a reduction coupling unit 20, a stator assembly 30, and a rotor assembly 40. As shown in FIG. A shaft (11) is passed through the tub (10) and the rotation of the shaft (11) is supported. The deceleration coupling unit 20 moves forward and backward by the lever unit 300 while being positioned in the central space 33 of the stator assembly 30. [ The stator assembly (30) is fixedly coupled to the tub (10). The lever unit 300 is coupled to the stator assembly 30 to move the deceleration coupling unit 20 forward and backward. The rotor assembly 40 rotates at a position surrounding the stator assembly 30. The rear portion of the shaft 11 passes through the rotor assembly 40. The rotor assembly 40 is not fixedly coupled to the shaft 11 but is mounted on the center portion of the rotor assembly 40, And is supported by an end bearing 44 provided at the end portion. The fastening means 45 is coupled to the rear end of the shaft 11 to prevent the rotor assembly 40 from moving backward.

The front end of the shaft 11 is connected to the washing tub coupling portion 111, and a washing tub (not shown) is fixed to the tub 11, so that the shaft 11 and the washing tub rotate together. The rear end of the shaft 11 is coupled with a fastening means 45 such as a nut to the fastening portion 112. A shaft spline 113 formed in an axial direction is formed at an intermediate portion of the shaft 11 and a coupling stopper portion 114 is formed in a stepped shape in front of the shaft spline 113. [ In the shaft spline 113, the reduction coupling unit 20 is movably coupled in the axial direction within a limited distance. The coupling stopper portion 114 can limit the forward movement of the front end portion of the deceleration coupling unit 20. The front portion of the shaft 11 is rotatably supported by the tub bearing 12 and the rear portion of the shaft 11 is rotatably supported by the end bearing 44 of the rotor assembly 40. [

The reduction coupling unit 20 is splined to the shaft 11 so that axial backward movement is possible within a limited range. This reduction coupling unit 20 is made in the central space 33 inside the stator assembly 30. The spring 24 is located between the front surface of the reduction coupling unit 20 and the spring support portion 106 which is formed to be stepped inside the shaft penetration portion 104 of the tub 10 so that the reduction coupling unit 20 ) To the rear side. Therefore, when the deceleration coupling unit 20 is positioned on the side of the tub 10, the spring 24 is compressed. The detailed configuration of the deceleration coupling unit 20, the stator assembly 30, and the rotor assembly 40 will be described below with reference to the respective drawings.

FIG. 6 is a perspective view of the reduction coupling unit 20 of the driving apparatus 1 for a washing machine according to the present invention as seen from the front side, FIG. 7 is a perspective view seen from the rear side, Fig.

6 to 8, the reduction coupling unit 20 of the present invention includes a cup-shaped coupling housing 21, a coupling cap 22 coupled to the front of the coupling housing 21, And a carrier 23 accommodated in the housing 21. A sun gear through hole 211 is formed in the center of the bottom surface of the rear side of the coupling housing 21. The sun gear portion 432 of the rotor assembly 40 penetrates the sun gear through hole 211.

A flange portion (212) is formed in a radially protruding shape in a circumferential portion on the front end side of the coupling housing (21). The deceleration coupling unit 20 can be moved forward by applying a forward force to the rear portion of the flange portion 212 by the lever unit 300. [ The rearward movement of the reduction coupling unit 20 is effected by the compression force of the spring 24. A coupling cap 22 is coupled to the front of the coupling housing 21. A center hole 221 is formed at the center of the coupling cap 22 to allow the shaft receiving portion 232a of the carrier 23 to pass therethrough. A flange coupling portion 222 corresponding to the flange portion 212 is formed around the coupling cap 22 and a first tooth 223 is formed in the shaft direction from the periphery of the flange coupling portion 222. [ The teeth 223 have a shape engaging with the shape of the tub teeth 105. Therefore, when the deceleration coupling unit 20 is positioned on the side of the tub 10 and the first teeth 223 and the tub teeth 105 are engaged with each other, the coupling housing 21 can not rotate.

An inner gear portion 213 is formed around the inner wall of the coupling housing 21. The inner gear portion 213 preferably has an axial spline shape. When the coupling housing 21 and the carrier 23 are rotated together with the inner gear portion 213 engaged with the planetary gear 233 of the carrier 23 or the coupling housing 21 can not rotate Only the carrier 23 rotates in the inner gear portion 213 to make the shaft 11 decelerate.

To this end, the carrier 23 has a ring-shaped first carrier body 231 located on the rear side, a second carrier body 232 coupled to the front of the first carrier body 231, a first carrier body 231, And a planetary gear shaft 234 fixed to the first carrier main body 231 for rotatably supporting the planetary gear 233.

A sun gear through hole 231a is formed at the center of the first carrier main body 231. [ At the center of the second carrier main body 232, a shaft receiving portion 232a is formed protruding forward. Preferably, the shaft receiving portion 232a is formed to be exposed in front of the center hole 221 of the coupling cap 22. [ A plurality of support portions 232b extending rearward are formed around the second carrier body 232 so as to be engaged with the first carrier body 231 and to allow the planetary gear 233 to be exposed to the periphery of the carrier 23 do. Of course, the support portion 232b may be partially or entirely formed on the second carrier body 232 side.

On the inner circumferential surface of the shaft receiving portion 232a, a carrier spline 232c formed in the shaft direction is formed. The carrier spline 232c is positioned to mate with the shaft spline 113 to allow the reduction coupling unit 20 to move a limited distance forward and backward. The sun gear portion 432 of the rotor assembly 40 penetrates the sun gear through hole 211 of the coupling housing 21 and the sun gear through hole 231a of the first carrier main body 231 to form a plurality of planetary gears 233, As shown in Fig. The rotation of the sun gear portion 432 causes the rotation of the carrier 23 by the planetary gear 233 and when the coupling housing 21 is fixed, the planetary gear 233 of the carrier 23 is inwardly The rotation of the carrier 23 is reduced as compared with the rotation of the sun gear portion 432 while the rotation of the carrier 23 is engaged with the gear portion 213 and the reduced rotation is transmitted through the shaft spline 113 engaged with the carrier spline 232c ). When the coupling housing 21 is rotatable, the rotation of the planetary gear portion 432 drives the planetary gear 232 and the internal gear portion 213 to rotate together. Therefore, the shaft spline 232c engaged with the carrier spline 232c, The rotation speed of the shaft 11 through the rotation shaft 113 is the same as the rotation speed of the sun gear portion 432.

5 and 8, the number of the planetary gears 233 is four, but the number of the planetary gears 233 is not necessarily limited to four, but may be three, five or six, .

9 is a perspective view showing a stator assembly 30 of a driving apparatus 1 for a washing machine according to the present invention.

5 and 9, the stator assembly 30 of the present invention includes an insulator 31 surrounding a stator core (not shown). A lever unit engaging portion 32 is formed at the center of the insulator 31. The central space 33 refers to the empty space in the central portion of the stator assembly 30, and the decoupling coupling unit 20 is located in this space. The lever unit 300 coupled to the lever unit engaging portion 32 is operated to push the deceleration coupling unit 20 toward the front side. The aligning protrusion 103a of the tub 10 is fitted into the alignment hole 34 and the engaging hole 35 is positioned to correspond to the engaging hole 103b of the tub 10 so that the bolt and the like can be engaged.

The lever unit 300 includes a lever holder 310, a first lever 320, and a second lever 330. The lever holder 310 is fixed to the lever unit engaging portion 32 formed in the insulator 31 of the stator assembly 30. [ The first lever 320 and the second lever 330 are hinged to the lever holder 310 so as to be rotatable, respectively, and rotate within a predetermined range, and are interlocked with each other as described later.

10 is a side view showing the operation principle of the lever unit 300 of the driving apparatus 1 for a washing machine according to the present invention.

10, the lever unit 300 of the present invention includes a lever holder 310 fixed to the lever unit engaging portion 32 of the insulator 31, a lever unit 310 fixed to the front side of the lever holder 310, 1 lever 320, and a second lever 330 hinged to the rear side of the lever holder 310.

The first lever 320 is hinged to the lever holder 310 by the first hinge 321. Similarly, the second lever 330 is hinged to the lever holder 310 by the second hinge 331. When the lever operating portion 323 of the first lever 320 is operated from the A position to the B position, the first lever 320 is rotated by the first hinge 321, The contact portion 322 of the contact portion 322 also rotates. The second lever 330 rotates about the second hinge 331 and the lift of the second lever 330 is stopped by the rotation of the second hinge 331. When the contact portion 322 rotates and the contact surface 333 of the second lever 330 is pushed, 332 move from position A 'to position B'. By the operation of the first lever 320 and the second lever 330, the deceleration coupling unit 20 moves from the front to the rear and is positioned. The shape of the lift 332 is preferably U-shaped when viewed from the front.

11 is a side view showing the operation of the lever unit 300 and the reduction coupling unit 20 in the washing or rinsing mode of the washing machine driving apparatus 1 according to the present invention, Fig.

FIG. 11 shows a state in which the first lever 320 and the second lever 330 are at the positions A and A ', respectively, in FIG. 11, the lift 332 of the second lever 330 pushes the flange portion 212 of the reduction coupling unit 20 and pushes the reduction coupling unit 20 toward the front. In this state, the spring 24 is compressed between the spring support 106 of the tub 10 and the coupling cap 22 of the reduction coupling unit 20. Fig. 11 shows an operation in the washing or rinsing mode. In the case of switching to the dehydrating mode, the state is changed to the state shown in Fig.

12 shows a state in which the first lever 320 and the second lever 330 are positioned at positions B and B ', respectively, by the operation of the lever unit 300. As shown in FIG. 12, the lift 332 of the second lever 330 moves backward from the flange portion 212 of the deceleration coupling unit 20 and moves to the rear of the compression force of the spring 24 which was compressed in the washing or rinsing mode The deceleration coupling unit 20 moves backward. Fig. 12 shows a state in the dehydration mode.

FIG. 13 is a perspective view showing a rotor assembly 40 of a driving apparatus 1 for a washing machine according to the present invention, and FIG. 14 is a sectional view.

13 and 14, the rotor assembly 40 of the present invention includes a cup-shaped rotor housing 41, a plurality of magnets 42 attached to the inner wall of the rotor housing 41, And a sun gear unit 43 formed at the center of the rotor housing 41.

The sun gear unit 43 is shown as a separate member from the rotor housing 41 in FIG. 5, but is not necessarily limited to this type. The rotor housing 41 may be disposed in the insert mold, It may be manufactured as an injection molding.

The sun gear unit 43 includes a main body portion 431, a sun gear portion 432 and a shaft penetrating portion 433. The main body portion 431 is fixed to the central portion of the rotor housing 41 and rotates integrally with the rotor housing 41. An end bearing 44 is inserted into the rear inner side of the body portion 431. A shaft penetrating portion 433 is formed at the center of the sun gear portion 432. The shaft 11 is supported so as to be rotatable by the end bearing 44 through the shaft penetrating portion 433. With this structure, even if the rotor housing 41 rotates, its rotational force is not directly transmitted to the shaft 11. [ That is, the rotor housing 41 and the shaft 11 are coupled to rotate independently of each other. The rotation of the rotor housing 41 causes the rotation of the propeller unit 432 and the rotation of the propeller unit 432 causes the rotation of the carrier 23 so that the shaft 11 splined to the carrier 23 And is rotated by the rotation of the carrier 23. The rotational speed of the shaft 11 can be reduced with respect to the rotational speed of the rotor housing 41 by the independent engagement between the rotor housing 41 and the shaft 11. [

The outer side of the sun gear portion 432 has a gear shape engaged with the inside of a plurality of planetary gears 233 provided on the carrier 23 of the reduction coupling unit 20. [ The fastening means 45 is a part such as a washer or a nut and is coupled to the rear end of the shaft 11 to prevent the end bearing 44 from being pushed back or the shaft 11 from moving forward.

Rotor teeth 46 are formed around the center of the rotor housing 41 and around the gear unit 432. The rotor teeth 46 have a shape engaging with the second teeth 214 of the reduction coupling unit 20 when the reduction coupling unit 20 is moved rearward. When the rotor housing 41 rotates with the rotor teeth 46 and the second teeth 214 engaged with each other, the reduction coupling unit 20 also rotates together.

15 is a cross-sectional view showing the structure of the driving apparatus for washing machine 1 according to the present invention when it operates in a washing or rinsing mode.

15, in the washing or rinsing mode, the washing machine driving apparatus 1 of the present invention operates the first lever 320 of the lever unit 300 so that the second lever 330 is operated in the speed reducing coupling unit 20 are moved forward. At this time, the spring 24 is compressed and the first tooth 223 formed on the coupling cap 22 of the deceleration coupling unit 20 is engaged with the tub teeth 105 formed on the tub 10.

In this state, when the rotor housing 41 of the rotor assembly 40 is rotated by applying power to the stator assembly 30, the sun gear unit 432 of the sun gear unit 43 rotates together and the sun gear unit 432 rotates, Since the coupling housing 21 coupled to the coupling cap 22 is constrained so as not to rotate, the carrier 23 is located inside the coupling housing 21 And rotates. Since the carrier spline 232c formed inside the shaft accommodating portion 232a of the carrier 23 meshes with the shaft spline 113, the reduced rotation of the carrier 23 is transmitted as it is by the rotation of the shaft 11. [ The reduced rotation of the shaft 11 causes a reduced rotation of the washing tub (not shown) coupled to the front of the shaft 11, so that the washing and rinsing mode is performed at a low speed operation.

16 is a sectional view showing the structure of the driving apparatus for washing machine 1 according to the present invention when it operates in the dewatering mode.

The first lever 320 of the lever unit 300 operates in the direction of the arrow and the lift 332 of the second lever 330 rotates toward the rear side as shown in FIG. . At this time, the compressed spring 24 pushes the deceleration coupling unit 20 backward. The coupling cap 22 which has engaged with the tub teeth 105 of the tub 10 is separated. The coupling housing 21 moves rearward and the second teeth 214 formed on the coupling housing 21 are engaged with the rotor teeth 46 formed in the center of the rotor housing 41. [ Of course, it is also conceivable that the lift 332 of the second lever 330 is moved in a coupled state with the coupling housing 21 without the spring 24.

In this state, when the rotor housing 41 of the rotor assembly 40 is rotated by applying power to the stator assembly 30, the sun gear unit 432 of the sun gear unit 43 rotates together and the sun gear unit 432 rotates, Since the second teeth 214 of the coupling housing 21 and the rotor teeth 46 of the rotor housing 41 mesh with each other, the plurality of planetary gears 233 engaged with the rotor housing 41 The rotation causes rotation of the coupling housing 21 immediately.

Therefore, the carrier 23, the coupling housing 21, and the rotor housing 41 rotate together at the same speed. The carrier spline 232c formed inside the shaft receiving portion 232a of the carrier 23 meshes with the shaft spline 113 so that the rotation of the carrier 23 is directly transmitted to the rotation of the shaft 11. [ Therefore, the rotational speed of the rotor housing 41 and the rotational speed of the shaft 11 are the same. (Not shown) coupled to the front of the shaft 11 also rotates at the same speed as the rotor housing 41, so that the dehydration mode is performed at high speed.

It should be noted that the above description of the present invention has been made by way of example only for the understanding of the present invention, and is not intended to limit the scope of the present invention. It is to be understood that the scope of protection of the present invention is defined by the appended claims, and all such modifications and changes are intended to fall within the scope of the present invention.

1: Drive device for washing machine 10:
11: shaft 12: tub bearing
20: Deceleration coupling unit 21: Coupling housing
22: coupling cap 23: carrier
24: spring 30: stator assembly
31: insulator 32: lever unit engaging portion
33: central space 34: alignment hole
35: coupling hole 40: rotor assembly
41: rotor housing 42: magnet
43: sun gear unit 44: end bearing
45: fastening means 46: rotor teeth
101: Tub bearing insertion portion 102: Lever unit position space
102a: Opening groove 103: Motor coupling portion
103a: Alignment protrusion 103b: Coupling hole
104: shaft penetration part 105: tub saw tooth
106: spring supporting portion 111: washing tub coupling portion
112: fastening portion 113: shaft spline
114: coupling stopper section 211, 231a: sun gear through hole
212: flange portion 213: inner gear portion
214: second tooth 221: center hole
222: flange engaging portion 223: first toothed portion
231: first carrier body 232: second carrier body
232a: shaft receiving portion 232b:
232c: Carrier spline 233: Planetary gear
234: Planetary gear shaft 300: Lever unit
310: lever holder 320: first lever
321: first hinge 322:
323: lever operating portion 330: second lever
331: second hinge 332: lift
333: contact surface 431:
432: a striker 433: a shaft penetrating part

Claims (4)

delete A stator assembly constituting a motor of a driving device for a washing machine, wherein the stator assembly
Stator core;
The stator core is audited by an insulator;
A central space inside the stator core and the insulator; And
A lever unit engaging portion formed on the insulator and coupled to the lever unit;
, ≪ / RTI >
The lever unit includes a lever holder fixed to the lever unit engaging portion, a first lever coupled to the lever holder at a first hinge so as to be rotatable, and a second lever coupled at a second hinge to be rotatable with the lever holder, And a second lever operatively associated with the first lever,
And a deceleration coupling unit positioned in the central space and movable in an axial direction. A stator assembly constituting a motor of a driving device for a washing machine, wherein the stator assembly
Stator core;
The stator core is audited by an insulator;
A central space inside the stator core and the insulator; And
A lever unit engaging portion formed on the insulator and coupled to the lever unit;
Wherein the central space is provided with a reduction coupling unit to be movable forward and rearward. The stator assembly according to claim 2 or 3, wherein the insulator has a plurality of coupling holes for coupling with the turbine.

Images