KR100976490B1 - shock-absorbing structure for bearing for supporting drive shaft of washer - Google Patents

Abstract

The present invention relates to a buffer structure of a bearing for supporting a driving shaft of a washing machine, and when a strong impact load is applied from the lower side of the washing machine during the packing strength test, it prevents damage to the ball in the ball bearing by reducing the impact transmitted to the lower ball bearing through the washing shaft. I would have to.

To this end, the present invention, the rotor assembly and the stator assembly constituting the dewatering contraction for transmitting the rotational power of the washing machine driving motor to the washing tank, the washing shaft installed inside the dewatering shaft, the washing machine driving motor, and the rotor assembly Rotor bushing connecting the central portion of the washing shaft and the lower end of the washing shaft, a ball bearing rotatably supporting the lower portion of the washing shaft relative to the lower end of the dewatering shaft immediately above the rotor bushing, and the ball bearing at the upper end of the central portion of the rotor bushing In a washing machine having a washer installed to form a gap of the rotor, it is provided in the space formed between the upper end of the rotor bushing and the lower end of the de-shrinkage, the gap between the upper end and the lower end of the de-shrinkage is the ball bearing and the washer Configured with a buffer washer, the thickness of which is formed to have a size smaller than the void of the liver. It provides a buffer structure of the drive shaft support bearing of the washing machine.

Washing machines, bearings, laundry shafts, buffer washers

Description

Shock-absorbing structure for bearing for supporting drive shaft of washer}

1 is a sectional view showing main parts of a general washing machine configuration

2 is a cross-sectional view of main parts showing the structure of a driving apparatus of a conventional washing machine.

3 is a sectional view showing the main parts of a structure of a driving device of a washing machine according to the present invention;

4 is an enlarged view of an essential part of FIG. 3 showing a bearing buffer structure according to the present invention;

Explanation of symbols on the main parts of the drawings

140: lower dewatering contraction 195: lower ball bearing

240: lower washing shaft 530: rotor bushing

535: washer 540: space part

950: Shock Washer

The present invention relates to a buffer structure of a bearing for supporting a drive shaft of a washing machine. In particular, the bearing supporting the washing shaft, which is a driving shaft of the washing machine, is prevented from being damaged by the impact load applied to the driving device of the washing machine when testing the packing strength after the manufacturing of the washing machine. It relates to a buffer structure of the drive shaft support bearing of the washing machine.

In general, a washing machine is a household appliance that removes contaminants such as clothes and bedding by using friction and impact of water flow due to the emulsification of detergent and the rotation of a washing blade. It consists of the class and drainage administration.

Such a washing machine can be generally classified into a pulsator washing machine and a drum washing machine according to a washing method, and the pulsator washing machine has a washing tub and a pulsator installed in a lower portion of the washing tub. When the washing tank is stopped, only the pulsator rotates to generate a flow of water and the pulsator and the washing tank rotate together in the dehydration process.

Figure 1 schematically shows an example of the configuration of a conventional pulsator washing machine as described above, Figure 2 is a view showing the configuration of the drive device of the washing machine of Figure 1, the pulsator washing machine is an outer case forming the appearance of the washing machine An outer tub 1 for storing the wash water is installed inside the tub 1, and a washing tub 2 for both washing and dehydration is rotatably installed in the tub 1, and a pulse is installed at the bottom of the tub 2. The eater 3 is configured to be rotatably installed.

In addition, the washing tank 2 and the pulsator 3 are connected to the motor 500 and the clutch 800 installed at the lower portion of the outer tank 1 to selectively receive power to rotate and perform washing and dehydration strokes. .

2, 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 a lower drum 100 having a gear formed on the lower inner circumferential surface thereof, and a lower drum dehydration shaft 140 connected to the lower end of the drum 160 to transmit a rotational force of the motor to the upper drum dehydration shaft 120. .

The upper washing shaft 210 and the lower washing shaft 240 are installed in the dehydration shaft 100 and the upper end of the upper washing shaft 210 penetrates the bottom of the washing tub. It is combined with the center of (3) to rotate the laundry in the forward and reverse directions.

In addition, 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.

In addition, upper and lower ball bearings 190 and lower ball bearings 195 are installed at upper and lower portions between the lower dehydrating shaft 140 and the lower washing shaft 240 to support rotation of the lower dehydrating shaft 140. .

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, power generated by the motor 500 is transmitted to 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 in engagement with a sun gear 242 to be described later between 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 housing 300, and a clutch housing 300 for surrounding and protecting the upper portion of the lower dehydration shaft 140 are provided, and the upper and lower portions of the clutch housing 300 are provided. Upper and lower bearings 330 and 340 rotatably supporting the upper and lower dehydration shafts 120 and 140 are respectively installed.

The motor 500 for generating the rotational force of the dehydration shaft 100 and the washing shaft 200 includes a rotor assembly 510 which is a rotor directly connected to the lower washing shaft 240, and the clutch housing 300. It is configured to include a stator assembly 520, which is a stator coupled to the bottom of the) to generate a rotating magnetic field. The rotor assembly 510 is fixedly coupled to the lower washing shaft 140 by the rotor bushing 530 of the central portion.

On the other hand, the clutch coupler 650 for switching the power transmitted to the dehydration shaft 100 or the washing shaft 200 is installed in the lower portion of the clutch housing 300, although not shown in the figure the clutch coupler 650 Is connected to the clutch motor and the interlocking device installed on one side of the clutch housing 300 and sliding up and down selectively the rotor bushing 535 and the lower dewatering shaft 140 located in the center of the rotor assembly 510 selectively Coupling and serves to transfer the power of the rotor assembly 510 to the lower dehydration shaft (140).

By the way, the conventional drive device configured as described above when the lower ball bearing 195 rotatably supporting the lower dewatering shaft 140 with respect to the lower laundry shaft 240 when a strong impact load is applied from the bottom. In this case, the ball bearing 195 is not rotated smoothly, the noise is increased and the life is shortened.

In more detail, the washing machine undergoes a packing strength test that applies a shock load by performing a free fall at a predetermined height in a state of packaging after completion of the product in the manufacturing process, and the impact load is a lower washing shaft of the driving device ( 240 and the rotor bushing 530 is delivered to the lower washing shaft 240 and the rotor bushing 530 is pushed upward.

At this time, the lower ball bearing 195 is the upper end of the outer ring is supported by the stepped inside the lower dehydration shaft 140, the force applied to the lower washing shaft 240 and the rotor bushing 530 is the lower ball bearing ( The lower ball bearing 195 is damaged by being transferred toward the lower end of the inner ring of the lower ball bearing 195 by the washer 535 between the 195 and the rotor bushing 530.

Accordingly, the present invention has been made in order to solve the above problems, to prevent the damage of the ball bearing by reducing the impact transmitted to the lower ball bearing through the washing shaft when a strong impact load is applied from the lower side of the washing machine as in the packaging strength test An object of the present invention is to provide a buffer structure of a bearing for supporting a drive shaft of a washing machine.

The present invention for achieving the above object, the cabinet, the outer tank is installed inside the cabinet to store the wash water, the washing tank rotatably installed inside the outer tank, and a pulsator rotatably installed in the washing tank; Dehydration shaft for transmitting the rotational power of the washing machine driving motor to the washing tank, and is installed so as to be rotatable independently of the dehydration inside the dewatering shaft and washing shaft for transmitting the rotational power of the washing machine driving motor to the pulsator; And a rotor assembly and a stator assembly constituting the washing machine driving motor, a rotor bushing connecting the central portion of the rotor assembly and the lower end of the washing shaft, and a groove formed in the lower portion of the dewatering shaft. A ball bearing rotatably supporting a lower portion of the washing shaft with respect to a lower end of the dewatering shaft; A washing machine having a washer installed at a central upper end of a bushing to form a predetermined gap with the ball bearing, wherein the washing machine is installed in a space formed between the upper end of the rotor bushing and the lower end of the dehydration shaft, and the upper end portion and the dehydration shaft. It provides a shock absorbing structure of the drive shaft support bearing of the washing machine, characterized in that it comprises a buffer washer formed in thickness so that the gap between the lower end is smaller than the gap between the ball bearing and the washer.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the buffer structure of the drive shaft support bearing of the washing machine according to the present invention will be described in detail.                     

For clarity, the same or similar components as those of the conventional washing machine and the driving device will be described with the same reference numerals as those of the prior art described with reference to FIGS. 1 and 2.

3 and 4 are views of the driving device of the washing machine showing the bearing buffer structure according to the present invention, the dewatering shaft 100 for rotating the washing tank 2 (see Fig. 1) is directly connected to the washing tank, the dewatering shaft is An upper dehydration shaft 120 for rotating the washing tank, a cylindrical drum 160 connected to the upper dehydration shaft 120 and a gear formed on a lower inner circumferential surface thereof, and a lower end portion of the drum 160 to rotate the motor. Consists of the lower dehydration shaft 140 to transfer to the upper dehydration shaft 120.

In addition, an upper washing shaft 210 and a lower washing shaft 240 are installed in a state in which the upper washing shaft 210 and the lower washing shaft 240 penetrate coaxially, and an upper end portion of the upper washing shaft 210 penetrating the bottom surface of the washing tank. Combined with the center of the washing blade (3) is to rotate the laundry in the forward, reverse direction.

In addition, 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.

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 the power of the lower washing shaft 240 to the planetary gear 220.

During washing, power generated by the motor 500 is transmitted to 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 in engagement with a sun gear 242 to be described later between 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 housing 300, and a clutch housing 300 for surrounding and protecting the upper portion of the lower dehydration shaft 140 are provided, and the upper and lower portions of the clutch housing 300 are provided. Upper and lower bearings 330 and 340 rotatably supporting the upper and lower dehydration shafts 120 and 140 are respectively installed.

The motor 500 for generating the rotational force of the dehydration shaft 100 and the washing shaft 200 includes a rotor assembly 510 which is a rotor directly connected to the lower washing shaft 240, and the clutch housing 300. It is configured to include a stator assembly 520, which is a stator coupled to the bottom of the) to generate a rotating magnetic field. The rotor assembly 510 is fixedly coupled to the lower washing shaft 140 by the rotor bushing 530 of the central portion.

The clutch coupler 650 for switching the power transmitted to the dehydration shaft 100 or the washing shaft 200 is installed at the lower portion of the clutch housing 300. Although not shown in the drawing, the clutch coupler 650 is a clutch. It is connected to a clutch motor and an interlock device installed outside one side of the housing 300 and selectively couples the rotor bushing 535 and the lower dehydration shaft 140 positioned at the center of the rotor assembly 510 while sliding up and down. It serves to transfer the power of the rotor assembly 510 to the lower dehydration shaft (140).

On the other hand, in order to support the rotation of the lower dehydration shaft 140, the upper ball bearing 190 and the lower ball bearing 195 are respectively installed between the lower dehydration shaft 140 and the lower washing shaft 240, respectively. Here, the lower ball bearing 195 is pressed into the groove 145 formed at the lower end of the lower dehydration shaft 140.

The lower side of the lower ball bearing 195 is supported while eliminating the play between the lower washing shaft 240 and the upper end of the rotor bushing 530 to prevent the rotor bushing 530 from vibrating up and down when the rotor assembly 510 is rotated. The washer 535 is provided.

Between the washer 535 and the lower ball bearing 195, a predetermined void C _U (hereinafter referred to as 'upper void') must be formed, which means that the lower washing shaft 240 and the rotor bushing 530 rotate. This is because when the washer 535 coupled to the top of the rotor rotor 530 comes into contact with the lower ball bearing 195, rotation is constrained or acts as a resistance.

In addition, a space portion 540 is formed at an upper end of the rotor bushing 530 corresponding to the outer peripheral portion of the lower dehydration shaft 140 to maintain a predetermined distance from the lower end of the lower dehydration shaft 140. A buffer washer 950 of a type is installed, wherein the buffer washer 950 has a predetermined pore C having a smaller size than the upper gap C _U between the lower dehydration shaft 140 and the lower end. _L ) (hereinafter referred to as 'lower void') is formed to a thickness that can be formed.

The buffer washer 950 is preferably made of a material that is elastically deformed by a heavy pressure and can absorb a load. For example, a polyslider washer as the buffer washer or Nylon washers and the like can be used.

Referring to the operation of the buffer washer 950 as described above are as follows.

When the washing machine is manufactured, the packing strength test is performed to apply a shock load by performing a free fall at a predetermined height while packing before shipment. When a strong impact load is applied from the lower part of the washing machine as in this packing strength test, The rotor bushing 530, the washer 535, and the lower washing shaft 240 slide upward by a predetermined amount.

At this time, since the lower pore C _L is smaller than the upper pore C _U , the washer 535 lower ball bearing (B) in the process of moving the rotor bushing 530 and the lower washing shaft 240 upward. The buffer washer 950 is deformed by a strong pressure before it reaches the lower end portion of the lower dehydration shaft 140 before it reaches 195, and by this deformation the buffer washer 950 absorbs the shock.

Therefore, the impact is hardly transmitted to the lower ball bearing 195 so that the balls therein are not damaged.

 As described above, according to the present invention, when a strong impact is applied in the lower part of the washing machine as in the case of the packing strength test, the shock absorbing washer is deformed while touching the lower end of the lower dehydration shaft before the washer of the rotor bushing touches the lower ball bearing. Since it is absorbed, the impact is not transmitted to the lower ball bearing, and thus, the ball in the lower ball bearing is prevented from being damaged, thereby preventing vibration and noise caused by bearing damage.

Claims (3)

Rotating power of a cabinet, an outer tub installed inside the cabinet to store wash water, a washing tub rotatably installed inside the outer tub, a pulsator rotatably installed in the washing tub, and a washing machine driving motor in the washing tub. A rotor shaft constituting the dehydration shaft to be transmitted, a washing shaft which is installed to be rotatable independently of the dehydration shaft, and which transmits the rotational power of the washing machine driving motor to a pulsator, and the washing machine driving motor. A stator assembly, a rotor bushing connecting the center of the rotor assembly to the lower end of the laundry shaft, and a groove formed in the groove formed in the lower end of the dewatering shaft to rotate the lower portion of the washing shaft relative to the lower end of the dewatering shaft from the upper portion of the rotor bushing. A ball bearing that can be supported, and a predetermined portion of the ball bearing at a central upper end of the rotor bushing. In a washing machine having a washer installed to fulfill the air gap, A buffer washer is formed in the space formed between the upper end of the rotor bushing and the lower end of the de-shrinkage, the thickness of the buffer washer so that the gap between the upper end and the lower end of the de-shrinkage has a size smaller than the gap between the ball bearing and the washer. The buffer structure of the drive shaft support bearing of the washing machine characterized in that it comprises a. The shock absorbing structure of claim 1, wherein the shock absorbing washer is made of synthetic resin. 3. The shock absorbing structure of claim 2, wherein the shock absorbing washer is a poly slider washer.

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