KR101008625B1 - structure of rotor bushing in full automation-type washing machine - Google Patents

Abstract

The present invention effectively prevents wear and noise of both parts due to contact between the switching lever and the rotor bushing during dehydration by preventing the bushing protrusion of the rotor bushing from falling down even when the switching lever for power transmission path switching of the washing machine driving motor is lowered. It is.

To this end, the present invention is a washing tank rotatably installed in the outer tank, a pulsator installed in the washing tank and rotatable independently of the washing tank, a deshrinkage for transmitting the rotational power of the washing machine driving motor to the washing tank, A washing shaft installed inside the contraction and transmitting a rotational power of the washing machine driving motor to a pulsator, a rotor assembly and a stator assembly constituting the washing machine driving motor, a clutch housing coupled to a lower portion of the outer tank, and the clutch Rotor bushing having a stopper fixed to the lower end of the housing and preventing rotation of the sliding coupler during washing, and a bushing protrusion coupled to the lower end of the washing shaft so that the rotational force of the rotor is transmitted to the washing shaft and the lower protrusion of the sliding coupler is fitted. And a clutch motor installed on the lower side of the outer tub, and coupled to a drive shaft of the clutch motor. And a sliding coupler for switching the rotational power transmission path of the washing machine driving motor to the deshrinkment or washing shaft while lifting up and down along the deshrinkage direction, and receiving the power of the clutch motor through a link link assembly. In the automatic washing machine comprising a switching lever for directly moving up and down, the power transmission path of the washing machine driving motor corresponding to the washing shaft or dewatering shaft in response to the washing stroke or dehydration stroke; A stepped portion is formed in a region outside the region where the lower protrusion of the sliding coupler of the bushing protrusion is joined to prevent contact of the switching lever end portion when dewatering.

Washing machine, clutch, changeover, rotor bushing, step

Description

Structure of rotor bushing in full automation-type washing machine

1 is a schematic diagram of a conventional direct-type automatic washing machine

2a and 2b is a longitudinal sectional view showing the structure of the clutch mechanism of the automatic washing machine according to the prior art,

2A is a state diagram at the time of washing

Figure 2b is a state diagram at the time of dehydration

3 is an exploded perspective view of main parts of FIG. 2;

4 is a perspective view of the rotor bushing according to the present invention

* Description of the symbols for the main parts of the drawings *

100 ..... dehydration 200 ..... laundry shaft

300 ..... Clutch housing 535 ..... Rotor bushing

535c ..... Bushing protrusion 630 ..... Link link assembly

630f ..... connecting member 640 ..... switching lever

650 ..... Sliding Coupler 660 ..... Stopper

660d ..... Lever Guide 700 ..... Brake Assembly

k ..... step

The present invention relates to a washing machine, and more particularly, to a structure improvement of a rotor bushing constituting a rotor assembly of a motor direct type washing machine.

In general, a fully automatic washing machine is a product that removes contaminants such as clothing and bedding by using friction and impact of water flow due to emulsification of detergent and rotation of washing blades. Automatically set the water, water to the appropriate level according to the amount and type of laundry, and then wash the microprocessor control.

Hereinafter, a clutch mechanism structure of a conventional direct type washing machine will be described with reference to FIGS. 1 to 3.

1 is a schematic view of a conventional direct-type automatic washing machine, the outer tank (1) for storing the wash water is installed inside the outer case forming the appearance of the washing machine.

2A and 2B are main part longitudinal cross-sectional views showing the configuration of an embodiment of a conventional washing machine driving device, and FIG. 3 is an exploded perspective view of the main part of FIG. 2B, wherein the tub 1 for both washing and dehydration is used inside the outer tub 1. ) Is installed.

On the other hand, the dehydration shaft 100 for rotating the washing tank 2 is directly connected to the washing tank, the dehydration shaft is connected to the upper dehydration shaft 120 for rotating the washing tank, the upper dehydration shaft 120 and on the lower inner peripheral surface It is configured to include a cylindrical drum 160 having a gear and a lower dehydration shaft 140 connected to the lower end of the drum 160 to transmit the rotational force of the motor to the upper dehydration shaft 120.

The upper washing shaft 210 and the lower washing shaft 240 penetrate the inside of the dehydration shaft 100, and the laundry is fixed at the upper end of the upper washing shaft 210 penetrating the bottom surface of the washing tank. , Washing wing 3 for rotating in the reverse direction is installed.

In order to support the rotation of the upper dehydration shaft 120, an oilless bearing 180 is installed between the upper dehydration shaft 120 and the upper washing shaft 210. Here, in the oilless bearing, when the upper washing shaft 210 rotates inside the upper dehydrating shaft 120, if heat is generated by friction, the oil impregnated therein is the upper washing shaft 210 and the upper dehydrating shaft 120. It acts to keep the rotation smoothly out of between.

In addition, a plurality of planetary gears 220, one sun gear 242, and a carrier are provided in the drum 160 to reduce the rotational speed of the motor while transmitting power of the motor to the upper washing shaft 210 during washing. A deceleration means composed of 230 is provided.

On the other hand, the lower washing shaft 240 is coupled to the inside of the lower dehydration shaft 140 for transmitting the power of the motor to the planetary gear 220. In addition, a sun gear 242 is formed at an upper end of the lower washing shaft 240 to mesh with the planetary gear 220 to transmit power of the lower washing shaft 240 to the planetary gear 220.

During washing, the power generated by the motor is transmitted in the order of the sun gear 242, the planetary gear 220, the carrier 230, and the upper washing shaft 210 via the lower washing shaft 240. That is, the planetary gear 220 rotates while being engaged with the sun gear 242 described later between the carriers 230 that support the upper and lower portions of the shaft 222 during washing.

On the other hand, since the planetary gear 220 and the drum 160 rotates at the same time during dehydration, the planetary gear 220 revolves around the sun gear 242.

In addition, a lower portion of the upper dehydration shaft 120, a drum 160, and a clutch housing 300 for surrounding and protecting the upper portion of the lower dehydration shaft 140 are provided.

The clutch housing includes an upper clutch housing 300a and a lower clutch housing 300b, and the upper and lower clutch housings 300a and 300b are fastened to each other by bolts. Upper and lower bearings 330 and 340 supporting the upper and lower desorption shafts 120 and 140 are interposed at the upper end and the lower end of the clutch housing 300, respectively.

Meanwhile, the stopper 660 and the stator assembly 400 which will be described later are fastened to the lower end of the clutch housing 300 by bolts 662.

In addition, a brake assembly 700 for selectively restraining the rotation of the drum 160 is provided for the case where only the washing shaft 200 should be rotated during washing and when the dehydration should be stopped at the moment of dehydration.

At this time, the brake assembly 700 is connected to the brake lever 720 and the upper clutch housing 300a, the brake lever 720, and the lower clutch housing 300b interlocked with the drain valve (not shown). The through shaft 740, which is coupled to the through shaft 740 and connected to the brake spring 760, the brake lever 720 for giving the elasticity of the brake lever 720, for applying the brake of the drum 160 The brake pad 780 is configured to include a brake hinge shaft 790 coupled to an end of the brake pad 780 and hinged when the brake lever 720 is pressed.

The motor for generating the rotational force of the dehydration shaft 100 and the washing shaft 200 includes a rotor assembly 500 which is a rotor directly connected to the lower washing shaft 240, and a lower end of the clutch housing 300. It is configured to include a stator assembly 400 is a stator coupled to generate a rotating magnetic field.

On the other hand, one side of the drive unit is provided with a clutch assembly for switching the power transmitted to the dehydration shaft 100 or the washing shaft 200.

In this case, the clutch assembly includes a clutch motor 600 providing power of a clutch motion, a link link assembly 630 for converting the rotational motion of the clutch motor 600 into a linear motion, and the link link assembly ( A switching lever 640 that rotates about a hinge axis by a linear motion of the shaft 630, and a rotor bushing 535 and a lower washing which are positioned at the top of the coupler support part 640b of the switching lever 640 and positioned at the center of the rotor assembly. Including a sliding coupler 650 for sliding the outer circumferential surface of the shaft 240, and a stopper 660 coupled to the upper protrusion 652 formed on the sliding coupler 650 to prevent rotation of the lower dehydration shaft 140 It is composed.

The link link assembly 630 includes a motor connection part 630a connected to one side of the clutch motor 600, a link body part 630b integrally formed with the motor connection part 630a, and the link body. A link case 630c surrounding the portion 630b, a spring fastening portion 630d formed at one side of the link case 630c and hinged to the switching lever 640, and an outer circumferential surface of the link body portion 630b. It is configured to include a spring (630e) coupled to generate the elasticity. An end of the link body portion 630b is integrally formed with a stepped portion so that the spring 630e does not escape from the link body portion 630b.

And, the switching lever 640 (640a, 640b) is in the form of "b", including a lever body portion 640a connected to the connecting link 630, and a coupler support portion 640b on which the sliding coupler 650 is placed. Is formed. One end of the lever body portion 640a is hinged rotatably with the spring fastening portion 630d of the link case 630c, and the other end on which the hinge protrusion 660c is formed is a lever guide formed at one side of the stopper 660. It is hinged to the stopper hinge ball of 660d.

The coupler support part 640b extends substantially perpendicular to the lever body part 640a and is formed in a “U” shape. The sliding coupler 650 is stably placed on an upper surface of the coupler support part 640b having a “U” shape. A protrusion 640b-1 for supporting the spring 660e inserted into the spring support 660f of the stopper 660, which will be described later, is formed at one side of the coupler support 640b.

The sliding coupler 650 has a cylindrical shape and a serration in the axial direction is formed on the inner circumferential surface thereof, and is engaged with the serration formed on the outer circumferential surface of the lower dehydration shaft 140 and the rotor bushing 535. In addition, an upper protrusion 652 coupled to the gear coupling hole 660b formed at the lower end of the stopper 660 is formed at the upper end thereof.

In addition, a coupler spring 651 is provided at an upper portion of the sliding coupler 650 to press the sliding coupler 650 downward. A circular groove corresponding to the diameter of the coupler spring 651 is formed on the sliding coupler 650, and a portion of the coupler spring 651 is inserted. Also, the other end of the inserted coupler spring 651 contacts the lower bearing 340.

In addition, the sliding coupler 650 is the first position (lower position, that is, the dehydration position) and the lower dehydration shaft simultaneously engaged with the serration of the bushing protrusion 535c and the lower dehydration shaft 140 of the rotor bushing 535, Up and down sliding to the second position (upper position, that is, the washing position) that is engaged only with the serration of 140 is possible.

The coupler spring 651 is compressed at a second position (upper position) in which the sliding coupler 650 is engaged only with the lower dehydration shaft 140, and the sliding coupler 650 is subjected to a downward pressure. In this case, since the sliding coupler 650 is supported by the coupler support part 640b, the sliding coupler 650 is stopped at the upper position.

However, in the first position, the sliding coupler 650 is pressed down by the elastic restoring force of the coupler spring 651 to stay in the lower position.

The stopper 660 is formed on the side of the stopper fastening hole 660a and the stopper fastening hole 660a for screwing the clutch assembly to the lower clutch housing 300b. A lever guide 660d supporting the gear coupling hole 660b coupled to the protrusion 652 and the lever body portion 640a and having a stopper hinge hole to which the hinge protrusion 660c of the switching lever is rotatably coupled, is provided. And a spring 660e for giving elasticity to the coupler support 640b and a spring support 660f for supporting the spring 660e when the lever 640 rotates to the dewatered position. The stopper 660 is coupled to the lower portion of the lower clutch housing 300b by a bolt 662 and fixed to the clutch housing 300.

In addition, the spring 660e to maintain a constant interval without contact between the sliding coupler 650 and the coupler support portion 640b during dehydration, and when the washing lever of the switching lever 640 by the vibration generated from the drive unit Prevent vibration

On the other hand, when the coupler support portion 640b and the sliding coupler 650 have to maintain a constant interval as described above, looks at the reason that the laundry is dewatered.

As the washing shaft 210 coupled to the rotor bushing 535 rotates at high speed, the lower dehydration shaft 140 coupled by the sliding coupler 650 also rotates at high speed, and thus the lower dehydration shaft 140 is rotated. Combined with the washing tub 20 is also rotated at high speed.

However, since the sliding coupler 650 rotates at a high speed in a state where the sliding coupler 650 is placed on the upper portion of the coupler support 640b, the sliding coupler 650, which is weaker than the coupler support 640b, is easily worn.

As described above, in order to prevent wear of the sliding coupler 650, the sliding coupler 650 and the coupler support part 640b should be prevented during dehydration, and the spring 660e serves to prevent contact as described above. do.

Hereinafter, the operation of the clutch assembly will be described with reference to FIGS. 2A and 2B.

2A illustrates a washing state in which the sliding coupler 650 is engaged only with the lower dehydration shaft 140, and the link link assembly 630, the switching lever 640, the sliding coupler 650, and the stopper 660 in the second position. Indicates the state.

2B illustrates a dehydration state in which the sliding coupler 650 is simultaneously engaged with the lower dehydration shaft 140 and the rotor bushing 535, and the link link assembly 630 and the switching lever 640 in the first position are slid. The coupler 650 and the stopper 660 are shown.

2B to 2A, that is, a process of moving the sliding coupler 650 to an upper portion will be described.

First, the clutch motor 600 is rotated under control by a microprocessor. The link link 630 is pulled toward the clutch motor 600 by the rotational movement of the clutch motor 600. In addition, by the movement of the connecting link 630, the switching lever 640 is inclined toward the clutch motor 600, the upper end of the lever body portion 640a around the stopper hinge ball.

And by the inclination of the lever body portion 640a, the coupler support portion 640b is inclined so that the end portion thereof faces the lower end of the stopper 660.

At this time, the sliding coupler 650 lying on the upper end of the coupler support part 640b slides upward on the serration formed on the lower outer circumferential surface of the lower dehydration shaft 140 to be positioned at the second position. The upper protrusion 652 formed in the sliding coupler 650 by the sliding is engaged with the gear coupling hole 660b of the stopper 650.

On the other hand, looks at the action of the spring (630e) formed in the connection link (630). The spring 630e is inserted between one side wall of the link body portion 630b and the projection of the spring fastening portion 630c to form elasticity in the switching lever 640 to maintain a smooth operation of the sliding coupler 650. It is for. When sliding the sliding coupler 650 up and down, it is difficult for the gear coupling hole 660b of the stopper 660 coupled with the upper protrusion 652 of the sliding coupler 650 to meet each other and to be coupled accurately. So, in consideration of this in the design of the washing machine is designed to rotate the motor finely to the left and right when the sliding coupler 650 vertical operation.

As described above, the gear coupling hole 660b of the stopper 660 coupled with the upper protrusion 652 of the sliding coupler 650 may be momentarily engaged when the motor rotates left and right. And at this time, if the sliding coupler 650 is receiving the force to be slid upward with elasticity, the engagement can be made even more smoothly. The spring 630e is fastened inside the connection link 630 in order to maintain elasticity when sliding the upper coupler 650 as described above.

On the other hand, with reference to Figures 1 to 3 will be described the operation during washing and dehydration of the drive device.

As shown in Figure 2a during the washing by the operation of the clutch motor 600, the switching lever 640 is rotated in the counterclockwise direction on the drawing about the hinge point. In addition, the coupler support part 640b is moved by the switching lever 640 in the rotational position so that the sliding coupler 650 is engaged with only the lower dehydration shaft 240 so as to move upward.

Then, when power is applied to the washing machine driving motor, the rotor assembly 500 rotates around the stator assembly 400 around the lower washing shaft 240.

Looking at the rotational force transmission process in this case, the rotational force by the rotation of the rotor assembly 500, the rotor bushing 535 of the rotor frame 530, the lower washing shaft 240 coupled to the rotor bushing 535, planetary It is transmitted to the gear 220, the carrier 230, the upper washing shaft 210.                         

At this time, the dehydration shaft 100 is constrained by the sliding coupler 600 that the lower dehydration shaft 240 is engaged with the stopper 660, it can not rotate.

On the other hand, since the planetary gear 220 is constrained by the brake assembly 700 when the drum 160 of the dehydration shaft 100 is washed, the planetary gear 220 is disposed in the opposite direction to the sun gear 242 formed at the upper end of the lower washing shaft 240. At the same time, the rotation around the drum 160 in the same direction as the sun gear 242. As the planetary gear 242 revolves as described above, the upper washing shaft 210 connected to the carrier 230 rotates inside the upper dehydration shaft 120.

As shown in FIG. 2B, the lever body 640a of the switching lever 640 is vertical by driving the clutch motor 600, and the coupler support 640b lowers the sliding coupler 650. It is moved downward to engage (first position) with the bushing protrusion 535c of the dehydration shaft 240 and the rotor bushing 535 at the same time. That is, the upper protrusion 652 of the sliding coupler 650 is separated from the gear coupling hole 660b of the stopper 660 and the sliding coupler 650 is lowered by the self-weight and the pushing force of the coupler spring 651.

Looking at the rotational force transmission process at this time, the rotational force of the rotor assembly 500, the rotor bushing 535, the lower washing shaft 240, the planetary gear 220, the upper washing shaft 210 of the rotor frame 530 Is passed to.

That is, during dehydration, since the sliding coupler 650 is engaged with the rotor bushing 535 and the lower dehydration shaft 140 at the same time, the rotational force transmitted to the lower washing shaft 240 is the lower dehydration shaft 140 and the drum 160. It is delivered to the upper dehydration shaft 120 through, so that the washing shaft 200 and the dehydration shaft 100 is rotated at the same speed at the same time.                         

On the other hand, the planetary gear 220 does not rotate because the drum 160 of the dehydration shaft 100 rotates at the same speed as the lower washing shaft 240, but the drum 160 is in the same direction as the sun gear 242. Revolve together.

However, such a conventional washing machine has the following problems in the structure of the rotor bushing in the clutch mechanism.

First, as shown in FIG. 2B, when dewatering, the switching lever 640 and the sliding coupler 650 descend by the driving of the clutch motor 600, thereby simultaneously engaging the lower dehydration shaft 240 and the rotor bushing 535. (First position).

At this time, the lower protrusion 653 of the sliding coupler 650 is fitted to the bushing protrusion 535c of the rotor bushing 535, the end of the coupler support portion 640b of the switching lever 640 is a spring 660e. By means of the force comes down to the position placed on the outer end of the bushing projection (535c).

Therefore, when the rotational force of the rotor assembly 500 is transmitted to the rotor bushing 535 of the rotor frame 530 during dehydration, the coupler support part 640b of the switching lever 640 and the rotor bushing 535 in contact with the end thereof. The bushing protrusion 535c may cause wear, and at the same time, there is a problem in that the friction noise is generated by the high speed rotation.

The present invention is to solve the above problems, by the contact between the switching lever and the rotor bushing during dehydration by preventing the bushing projection of the rotor bushing even if the switching lever for the power transmission path switching of the washing machine driving motor is lowered. The aim is to effectively prevent the occurrence of wear and noise.

The present invention for achieving the above object is a washing tank rotatably installed in the outer tub, a pulsator installed in the washing tub and rotatable independently of the washing tub, and a demounting unit for transmitting the rotational power of the washing machine driving motor to the washing tub. A contraction shaft, a washing shaft installed inside the deshrinkable shaft and transmitting a rotational power of the washing machine driving motor to a pulsator, a rotor assembly and a stator assembly constituting the washing machine driving motor, and a clutch coupled to the lower portion of the outer tank A stopper fixed to a lower end of the housing, the clutch housing and preventing rotation of the sliding coupler during washing, and a bushing protrusion coupled to the lower end of the washing shaft so that the rotational force of the rotor is transmitted to the washing shaft and the lower protrusion of the sliding coupler is combined. Rotor bushing having a, a clutch motor installed on the lower side of the outer tank, and the clutch hat Cam coupled to the drive shaft of the rotor, a sliding coupler for switching the rotational power transmission path of the washing machine driving motor to the dehydration shaft or the washing shaft while moving up and down along the de-shrinkage direction, and the power of the clutch motor through a link link assembly In the automatic washing machine is configured to include a switching lever for directly receiving the sliding coupler to move up and down, and to switch the power transmission path of the washing machine driving motor to the washing shaft or dewatering shaft in response to the washing stroke or dehydration stroke; A stepped portion is formed in a region outside the region where the lower protrusion of the sliding coupler of the bushing protrusion is joined to prevent contact of the switching lever end portion when dewatering.

Hereinafter, an embodiment of a fully automatic washing machine driving apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

4 is a perspective view of the rotor bushing according to the present invention.

The present invention provides a washing tank (2) rotatably installed in the outer tank (1), a pulsator (3) rotatably installed in the washing tank (2), and a demounting unit for transmitting the rotational power of the washing machine driving motor to the washing tank. Shrinkage 100, the washing shaft 200 is installed inside the deshrinkable shaft and transmits the rotational power of the washing machine driving motor to the pulsator, and the rotor assembly 500 and the stator assembly constituting the washing machine driving motor. In the fully automatic washing machine provided with a clutch mechanism 400 and the clutch mechanism capable of switching the power transmission path of the washing machine driving motor to the washing shaft or dewatering shaft in response to the washing stroke or the dehydrating stroke; The clutch mechanism is fixed to the clutch housing 300 coupled to the lower portion of the outer tub 1, and the clutch housing 300 is fixed to the lower end of the clutch housing 300, thereby preventing rotation of the sliding coupler 650 during washing to rotate the dewatering shaft 100. The stopper 660 to be prevented, the rotor bushing 535 is coupled to the lower end of the washing shaft 200 to transmit the rotational force of the rotor to the washing shaft, the clutch motor 600 is installed on the lower side of the outer tank, and A cam 620 coupled to the drive shaft of the clutch motor, a sliding coupler 650 for switching the rotational power transmission path of the washing machine driving motor to the dehydration shaft or the washing shaft while moving up and down along the dehydration direction, and the clutch motor ( Switching lever 640 for moving the sliding coupler 650 directly up and down while being rotated by the power of the 600, and a rolling member provided in the part in contact with the sliding coupler 650 of the switching lever 640 , It is configured to include the connecting link assembly 630 is provided between the clutch motor 600 and the switching lever 640 so as to transmit the driving force of the clutch motor 600, the sliding coupler through the switch lever.

At this time, the rotor bushing 535 is formed with a bushing protrusion (535c) to form the lower projection 653 of the sliding coupler 650 when dewatering, the lower projection of the sliding coupler 650 of the bushing protrusion (535c). Outside the region where the 653 is joined, a step k is formed to prevent contact of the end of the switching lever 640 when dewatering.

In addition, the switching lever 640 is in the form of "b", the lever body portion 640a and the sliding coupler 650 connected to the connecting member 630f of the connecting link assembly 630, which will be described later, is placed on the top. The ground includes a coupler support 640b.

A protrusion (not shown) coupled to the hinge hole 660c formed at the end of the stopper 610 is formed at the lower end of the lever body 640a, and the coupler support 640b is the lever body portion ( At the lower end of the 640a, the lever body portion 640a extends in a direction substantially perpendicular to the lever body portion 640a, and is formed in a branched form to form a “U” shape, and the sliding coupler 650 is placed on the upper end thereof.

Hereinafter, the operation of the washing machine according to the present invention.

When the dehydration stroke is performed after the completion of washing, the lever body 640a of the switching lever 640 becomes vertical by driving the clutch motor 600 (see FIG. 2B), and the coupler support part 640b is a sliding coupler ( The 650 is moved downward to be engaged (first position) with the lower dehydration shaft 240 and the rotor bushing 535 simultaneously.

That is, the upper protrusion 652 of the sliding coupler 650 is separated from the gear coupling hole 660b of the stopper 660 and the sliding coupler 650 is lowered by its own weight downward.

Looking at the rotational force transmission process at this time, the rotational force of the rotor assembly 500, the rotor bushing 535, the lower washing shaft 240, the planetary gear 220, the upper washing shaft 210 of the rotor frame 530 Is passed to.

And the rotational force transmitted to the upper washing shaft 210 is a state in which the sliding coupler 650 is engaged with the rotor bushing 535 and the lower dehydration shaft 140 at the same time through the lower dehydration shaft 140 and the drum 160 It is delivered to the upper dehydration shaft (120).

In this case, each of the bushing protrusions 535c protruding from the upper surface of the rotor bushing 535 has a step portion k outside the region where the lower protrusion 653 of the sliding coupler 650 is joined. That is, each bushing protrusion 535c forms a "b '" shape, thereby having a stepped portion in the outer region.

Therefore, even when the switching lever 640 reaches the dehydration stroke performing position as shown in FIG. 2B by the driving of the clutch motor 600, the coupler support part 640b of the switching lever 640 is located in the stepped area k. Therefore, the bushing protrusion 535c cannot be reached.

That is, in the related art, although there is no step portion k, the end of the coupler support portion 640b of the switching lever 640 and the bushing protrusion 535c are in contact with each other at the dehydration position. The bushing protrusion 535c is not in contact with the end of the coupler support part 640b of the switching lever 640 supporting the lower end of the sliding coupler 650.

On the other hand, the width and depth of the stepped portion (k) should be designed in consideration of the position when dewatering the switching lever 640.                     

In other words, if the step portion k is not formed in the bushing protrusion 535c, when the rotor bushing 535 is rotated by the rotation of the rotor assembly 500 during dehydration, the coupler support part 640b and the rotor bushing are rotated. Since the bushing protrusion 535c of 535 is in contact with each other, the bushing protrusion 535c and the coupler support part 640b are worn out.

However, in the present invention, the stepped portion (k) is formed in the bushing protrusion (535c), so that the coupler support portion (640c) of the coupler support portion (640c) of the switching lever (640) is not allowed to contact the bushing protrusion (535c) during dehydration. 640b and the bushing protrusion 535c of the rotor bushing 535 are prevented from being worn.

In short, according to the present invention, the bushing protrusion 535c of the rotor bushing 535 is in contact with the switching lever 640 during dehydration, thereby preventing a phenomenon in which both parts are worn and noise at the contact portion.

On the other hand, forming the bushing plate 535a with a resin material is disadvantageous in terms of strength as compared with the rotor bushing 535 formed with an integral metal material as described above. However, it is preferable that the bushing plate 535a and the washing shaft support bushing 535b are formed using different materials due to the advantages described below.

Looking at the advantages of forming the bushing plate (535a) with a resin material as follows.

First, it is possible to reduce the vibration generated in the motor of the washing machine. The vibration generated by the rotation of the rotor assembly 500 is transmitted through the bushing plate 535a, the washing shaft support bushing 535b, the washing shaft 200, and the washing tank.

However, since the rotor frame 530 and the bushing plate 535a are formed of different materials, vibration modes are different from each other. Therefore, the vibration of the rotor frame 530 is attenuated to some extent while passing through the bushing plate 535a and transmitted to the washing shaft 200.

And, it looks at blocking the flow of current that can be generated from the motor of the washing machine to be delivered to the wash water.

Power applied to the stator assembly 400 is induced current to the rotor frame 530, the current is delivered to the washing shaft 200, the washing tank, and the washing water. If current is delivered to the wash water, it may cause a safety accident such as an electric shock. To avoid this risk, insulation must be in place during the transfer to the wash water.

The bushing plate 535a is where the insulation can be most easily formed. That is, the current transmitted to the rotor frame 530 by the bushing plate 535a formed of an insulating material may be prevented from being transferred to the washing shaft 200.

On the other hand, the present invention is within the scope of the basic technical idea, many modifications are possible to those skilled in the art of course.

According to the present invention as described above it is possible to effectively prevent the wear of the rotor bushing provided on the power transmission path of the washing machine driving motor.

That is, the present invention prevents the switching lever for switching the power transmission path of the washing machine driving motor does not come into contact with the bushing protrusion of the rotor bushing, thereby effectively preventing wear and noise of the rotor bushing and the switching lever during dehydration, thereby improving product life and reliability. Can be improved.

Claims (2)

A washing tank rotatably installed in the outer tank, A pulsator installed in the washing tank and rotatable independently of the washing tank, De-shrinkage to transfer the rotational power of the washing machine driving motor to the washing tank; A washing shaft installed inside the dewatering shaft and transmitting a rotational power of the washing machine driving motor to a pulsator; A rotor assembly and a stator assembly constituting the washing machine driving motor; A clutch housing coupled to the outer tub lower portion; A stopper fixed to the lower end of the clutch housing and preventing rotation of the sliding coupler during washing; A rotor bushing having a bushing protrusion coupled to a lower end of the washing shaft so that the rotational force of the rotor is transmitted to the washing shaft, and the lower protrusion of the sliding coupler is combined; Clutch motor is installed on the lower side of the outer tank, A cam coupled to the drive shaft of the clutch motor; Sliding coupler for switching the rotational power transmission path of the washing machine driving motor to the deshrinkment or washing shaft while moving up and down along the deshrinkage direction, It comprises a switching lever for receiving the power of the clutch motor through a link link assembly to move the sliding coupler directly up and down, washing shaft power transmission path of the washing machine driving motor corresponding to the washing stroke or dehydration stroke Or in an automatic washing machine switchable to deshrinkable; Fully automatic washing machine characterized in that the step portion is formed in the area outside the region of the lower projection of the sliding coupler of the bushing protrusion to prevent the contact of the end of the switching lever when dewatering. The method of claim 1, Fully automatic washing machine, characterized in that the step portion formed in the bushing protrusion to form a "b" shape.

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