KR20130080222A - Washing machine - Google Patents

Abstract

PURPOSE: A washing machine is provided to enable an outer channel performing a balancing function to be prepared at the lower part of a base plate, thereby quickly canceling out unbalanced weight occurring in a rotary tub. CONSTITUTION: A first balancer is mounted at the upper part of a rotary tub and cancels out unbalanced weight of the rotary tub. A second balancer is mounted at the lower part of the rotary tub in order to cancel out the unbalanced weight of the rotary tub by using a part of washing water contained in the rotary tub. An inner channel (210) of the second balancer is formed along the lower circumferential direction of the rotary tub and stores a part of the washing water contained in the rotary tub. An outer channel (220) of the second balancer is formed along the outer circumference of the inner channel and cancels out the unbalanced weight of the rotary tub.

Description

Washing machine {WASHING MACHINE}

The present invention relates to a washing machine having a rotating tub capable of offsetting an unbalanced load.

A washing machine is a machine for washing clothes using electric power, and typically includes a tub for storing wash water, a rotating tub rotatably installed in the tub, a pulsator rotatably installed at the bottom of the tub, and a rotating tub. And a motor and a clutch for rotationally driving the pulsator.

When the rotating tank and the pulsator are rotated while the laundry and the detergent water are put into the rotating tank, the pulsator stirs the laundry introduced into the rotating tank together with the washing water to remove the dirt from the laundry.

If the laundry is not evenly distributed in the rotating tub and is concentrated in a specific part during the rotation of the rotating tub, vibration and noise may occur due to the eccentric rotation of the rotating tub, and in severe cases, parts such as the rotating tub and the motor may be damaged. .

Therefore, the washing machine includes a balancer for stabilizing rotation of the rotating tank by offsetting an unbalanced load generated in the rotating tank.

Conventionally, there was a problem that the balancer is only present in the upper portion of the rotating tub to sufficiently offset the unbalanced load of the washing machine.

One aspect of the present invention discloses a washing machine that improves the performance of the balancer.

Washing machine according to the idea of the present invention; and a tub disposed in the cabinet, the tub accommodates the wash water; and a cylindrical portion forming a side circumference, the rotating tub disposed rotatably inside the tub And a first balancer mounted on an upper portion of the rotary tub to offset an unbalanced load of the rotary tub; and a lower portion of the rotary tub so as to offset an unbalanced load of the rotary tub by using a part of the wash water inside the rotary tub. And a second balancer mounted to the second balancer, an inner channel formed along a lower circumferential direction of the rotary tub to store a portion of the wash water in the rotary tub, and to offset an unbalanced load of the rotary tub. And an outer channel formed along the outer circumference of the inner channel.

The outer surface of the outer channel may be formed to have the same radius as the side of the rotating tub.

The outer channel may include a plurality of boundary plates formed inside the outer channel to divide the outer channel into a plurality of accommodation parts.

Washing water stored in the inner channel may be introduced into at least one of the plurality of receiving portions of the outer channel to offset the unbalanced load of the rotating tub.

The inner channel may be open so that the wash water flows inside the inner channel.

Washing water stored in the inner channel may be characterized in that the initial vibration of the rotating tub to cancel the flow inside the inner channel.

It may further comprise a through-hole for communicating the inner channel and the outer channel.

The wash water stored in the inner channel may be introduced into the outer channel through the through hole when the unbalanced load is generated in the rotating tub to offset the unbalanced load of the rotating tub.

It may further include an inlet configured to allow the washing water to flow into the at least one channel in the cylindrical portion.

The second balancer may further include a plurality of drain holes formed in the lower portion of the at least one channel to discharge the wash water.

In addition, the washing machine according to the spirit of the present invention includes a cabinet; and a tub disposed inside the cabinet to accommodate wash water; and a cylindrical portion forming a side circumference and a base plate supporting a lower portion of the cylindrical portion. And a rotating tub; wherein the base plate is configured to receive wash water and includes at least one channel formed along a lower circumferential direction of the base plate, and the wash water stored in the at least one channel is connected to the rotating tub. It can be characterized by offsetting the generated unbalanced load.

The at least one channel comprises an inner channel formed along the lower circumferential direction of the base plate to store a portion of the wash water and an outer channel formed along the outer circumference of the inner channel to offset the unbalanced load of the tumbler It can be characterized.

Washing water stored in the inner channel may be introduced into at least one of the plurality of receiving portions of the outer channel to offset the unbalanced load of the rotating tub.

In addition, a washing machine according to the spirit of the present invention is a cabinet; and a tub disposed inside the cabinet to accommodate wash water; and a rotating tub rotatably disposed in the tub; and a lower portion of the rotating tub. An inner channel formed along the circumferential direction and configured to store a portion of the wash water; and an outer channel formed along the outer circumference of the inner channel at a lower portion of the rotating tub to offset an unbalanced load of the rotating tub; and the inner And a through hole configured to communicate a channel with the outer channel. When the rotary tub rotates to generate centrifugal force such that washing water stored in the inner channel exceeds the wall between the inner channel and the outer channel, Washing water stored in the channel is introduced into the outer channel through the through hole to offset the unbalanced load of the rotating tub It can be made.

The inner channel may be opened to allow the wash water to flow inside the inner channel, thereby offsetting initial vibration of the rotating tub.

And a drain hole formed in the lower portion of the outer channel so that the washing water introduced into the outer channel can be discharged.

In addition, a washing machine according to the spirit of the present invention is a cabinet; and a tub disposed inside the cabinet to accommodate wash water; and a rotating tub rotatably disposed in the tub; and an unbalance generated in the rotating tub. And a balancer mounted on a lower portion of the rotary tub to offset the load, wherein the balancer is formed along a circumferential direction of the balancer, and has an annular inner channel configured to store a portion of the wash water; and the inner channel. It may be characterized in that it comprises an outer channel formed on the outer circumference along the circumferential direction and configured to offset the unbalanced load of the rotating tub.

It may further comprise a through-hole for communicating the inner channel and the outer channel so that the wash water stored in the inner channel can be introduced into the outer channel.

The inner channel may be open so that the wash water flows inside the inner channel to cancel the initial vibration of the rotating tub.

The outer channel may include at least one boundary plate formed inside the outer channel to divide the outer channel into a plurality of accommodation parts.

And a drain hole formed in the lower portion of the outer channel so that the washing water introduced into the outer channel can be discharged.

A balancing channel can be provided under the base plate to quickly cancel the unbalanced load present in the rotating tub.

1 is a view showing the configuration of a washing machine according to an embodiment of the present invention.
Figure 2 is a perspective view showing the configuration of a base plate according to an embodiment of the present invention.
3 is a cross-sectional view of the base plate in FIG.
4 to 7 are cross-sectional views showing the movement of the wash water in the base plate shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the configuration of a washing machine according to an embodiment of the present invention.

As shown in FIG. 1, as shown in FIG. 1, the washing machine 1 includes a cabinet 10 forming an exterior, a tub 20 disposed inside the cabinet 10 to store wash water, and The tub 20 is configured to include a rotating tub 30 rotatably disposed in the tub 20 and a pulsator 35 disposed inside the tub 30 to generate water flow.

In the upper portion of the cabinet 10, an inlet 14 is formed to inject laundry into the rotating tub 30. The inlet 14 is opened and closed by a door 16 installed on the cabinet 10.

The tub 20 is supported in a locked state in the cabinet 10 by a suspension device 21 connecting the lower side of the outer surface of the tub 20 and the inner upper portion of the cabinet 10. By the suspension device 21, vibration generated in the cabinet 10 or the tub 20 during washing or dehydration is attenuated.

A water supply pipe 50 for supplying wash water to the tub 20 is installed at an upper portion of the tub 20. One side of the water supply pipe 50 is connected to an external water source (not shown), and the other side of the water supply pipe 50 is connected to the detergent supply device 60. Water supplied through the water supply pipe 50 is supplied into the tub 20 together with the detergent via the detergent supply device 60. The water supply pipe 50 is provided with a water supply valve 53 to control the supply of water.

The pulsator 35 rotates forward or reverse to generate water flow, and the laundry in the rotary tub 30 is stirred with the wash water by the water flow.

A drain hole 81 is formed at the bottom of the tub 20 to discharge the wash water stored in the tub 20, and a drain pipe 82 is connected to the drain hole 81. A drain valve (not shown) may be installed in the drain pipe 82 to control the drainage.

The driving device for the washing machine 90 receives power and selectively transmits the rotational force generated by the motor 92 to the rotating tub 30 and the pulsator 35 to generate a pulsator ( 35 and clutch 91 which allow the rotating tub 30 to rotate simultaneously or selectively.

The rotating tub 30 is formed of a cylindrical cylindrical portion 31, the upper portion of which is open to form the side of the rotating tub, and a base plate 40 supporting the lower portion of the cylindrical portion 31. The cylindrical portion 31 is provided with a plurality of dehydration holes 32 along the circumference thereof so that the inner space of the rotating tub 30 and the inner space of the tub 20 communicate with each other.

The first balancer 33 is mounted on the upper side of the rotating tub 30 to offset the unbalanced load generated in the rotating tub 30 at the high speed of the rotating tub 30 so that the rotating tub 30 can be stably rotated. Can be.

The filling liquid for balancing can be accommodated in the inside of the first balancer 33, and this filling liquid cancels out the unbalanced load of the rotating tank 30. In general, saline may be used as the fill solution. The brine contained in the first balancer 33 has a specific gravity higher than that of ordinary water and is suitable for performing balancing. Furthermore, the freezing point can be lowered to compensate for the unbalanced load of the rotating tub 30 without freezing even in winter.

Since the first balancer 33 of the rotary tub 30 is biased upward, it is difficult to offset the unbalanced load on the lower side of the rotary tub 30, so that the base plate 40 located below the rotary tub 30 is located. The second balancer is formed to offset the unbalanced load of the rotating tub 30. In general, the base plate 40 forms a lower portion of the rotating tub 30 and is configured to penetrate a driving shaft connected to the pulsator 35. Further, it is connected to the drive shaft for rotating the rotating tub 30 performs a function of receiving the power generated by the motor 92 to rotate. Base plate 40 according to the present invention may include a balancer function to offset the unbalanced load of the rotating tub 30 in addition to the above general function. This will be described with reference to FIG. 2.

2 is a perspective view showing the configuration of a base plate according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the base plate in FIG.

As shown in Figure 2 and 3, the base plate 40 is formed by the combination of the upper plate 100 and the lower plate 200.

By combining the upper plate 100 and the lower plate 200, a predetermined space is formed below the base plate 40, and the space forms the inner channel 210 and the outer channel 220. The inner channel 210 and the outer channel 220 formed in the lower portion of the rotating tub 30 form a second balancer.

The outer surface of the outer channel 220 may be formed to have the same radius as the outer surface of the rotating tub (30). That is, the second balancer may be formed so as not to protrude outward from the circumference of the rotary tub 30.

As a result, since the outer channel 220 and the inner channel 210 forming the second balancer are formed inside the base plate 40 of the rotating tub 30, a separate space for the second balancer may not be secured. Can be.

 The upper plate 100 is formed in a ring shape in which the first opening 150 is formed at the center thereof. Protruding radially inward along the circumference of the first opening 150 to form a first fastening protrusion 160 for coupling with the lower plate 200.

The upper plate 100 is provided with a plurality of steps to form the inner channel 210 and the outer channel 220.

An inner channel ceiling 121 is formed on the radially outer circumference of the first opening 150 of the upper plate 100 to form a top plate of the inner channel 210. A second fastening hole 170 for coupling with the lower plate 200 is formed in the inner channel ceiling 121.

The inclined portion 123 is formed to be inclined upward from the outer circumference of the inner channel ceiling 121. The outer channel ceiling 111 forming the top plate of the outer channel 220 is formed radially outward from the inclined portion 123. The outer channel ceiling 111 is formed at a higher position than the inner channel ceiling 121. The inclined portion 123 connects the outer channel ceiling 111 and the inner channel ceiling 121 having different heights.

The outer channel ceiling 111 and the inner channel ceiling 121 form a step.

Like the upper plate 100, the lower plate 200 is formed in a ring shape having a second opening 250 formed at the center thereof. A protruding wall 251 is formed by protruding upward along the circumference of the second opening 250. A first fastening hole 260 is formed along the outer circumference of the protruding wall 251 to engage with the first fastening protrusion 160 of the upper plate 100.

The first opening 150 is wider than the second opening 250. Thus, as shown in FIG. 3, the inlet 151 is formed by the inner channel ceiling 121 formed around the first opening 150 and the protruding wall 251 formed around the second opening 250. do. The inlet 151 serves as an inlet for communicating the cylindrical portion 31 of the rotating tub 30 and the inner channel 210.

An inner channel bottom 221 is formed along the periphery of the protruding wall 251 to form the bottom of the lower plate 200 in the radial direction and to form the bottom of the inner channel 210. The inner channel bottom part 221 is formed lower than the protruding wall 251 which protrudes.

A second fastening protrusion 261 for fastening with the second fastening hole 170 is formed at a position corresponding to the second fastening hole 170 of the upper plate 100 at the inner channel bottom 221. The second fastening protrusion 261 is formed to protrude upward from the inner channel bottom 221.

The fastening member (not shown) is inserted into and fastened to the first fastening protrusion 160 and the first fastening hole 260, and is inserted into and fastened to the second fastening hole 170 and the second fastening protrusion 261. 100 and the lower plate 200 are combined.

The inner wall 231 is formed by protruding upward from the radially outer side of the inner channel bottom 221. The inner wall 231 is arranged such that the first inner wall 232 and the second inner wall 233 having different heights are repeated one by one along the radial circumference of the inner channel bottom 221.

The first inner wall 232 extends from the inner channel bottom 221 to the inner channel ceiling 121 to block the inner channel 210 and the outer channel 220. On the other hand, the second inner wall 233 is formed at a height lower than the first inner wall 232 to form a through hole 230 to allow the inner channel 210 and the outer channel 220 to communicate with each other.

The inner channel 210 is formed by the inner wall 231, the inner channel bottom 221, the inner channel ceiling 121, and the protruding wall 251.

The outer channel bottom 211 is formed radially outward from the outer circumference of the inner channel bottom 221. The outer channel bottom 211 is formed to be inclined upwardly outward in the radial direction of the lower plate 200 to form the outer channel 220 without a separate outer wall. However, unlike the present embodiment shown in the drawings, the outer channel bottom 211 is not formed, it may be included in the embodiment of the present invention formed on the outer wall along the outer periphery of the outer channel bottom 211.

However, the inner channel bottom portion 221 is formed to have a predetermined slope so that the washing water stored in the inner channel 210 may be smoothly drained to the drain hole 240 formed in the inner channel bottom portion 221 after the rotation is completed. It is preferable to be.

The outer channel 220 is formed by the inner wall 231, the outer channel bottom 211, and the outer channel ceiling 111.

A boundary plate 212 protrudes upward from the outer channel bottom 211 of the lower plate 200 to divide the outer channel 220 into a plurality of accommodation portions. The boundary plate 212 does not extend to the outer channel ceiling 111, but has a height such that each receiving portion is hardly communicated. Depending on the embodiment, the boundary plate 212 may be formed by completely dividing each receiving portion so as not to communicate.

The boundary plate 212 is formed at a portion where the first inner wall 232 blocking the inner channel 210 and the outer channel 220 is located. That is, the boundary plate 212 and the first inner wall 232 are formed to cross each other. Thus, the receiving portion is isolated from the adjacent receiving portion and the inner channel 210 by the first inner wall 232 and the boundary plate 212.

A drain hole 240 is formed in the outer channel bottom 211 of the outer channel 220 so that the washing water introduced into the outer channel 220 can be drained. Since the drain hole 240 is formed to drain the wash water, the drain hole 240 is preferably biased downward in the outer channel bottom 211 formed to be inclined. As shown in the figure, the drain hole 240 is formed adjacent to the inner wall 231 to be located at the bottom of the outer channel bottom 211.

The drain hole 240 is formed in each accommodation portion formed by dividing the external channel 220. This is because each receiving portion is formed so as not to communicate with each other, so that drain holes 240 must be formed in the respective receiving portions in order to drain the wash water.

The outer channel 220 is used to offset the unbalanced load when the rotation of the rotary tub 30 (see FIG. 1) reaches a normal state. ) Is divided into unreceiving portions.

On the other hand, the inner channel 210 receives a portion of the wash water accommodated in the tub 20 (see FIG. 1). The introduced wash water cancels the initial vibration at the beginning of rotation of the rotating tub 30 (see FIG. 1) while flowing inside the inner channel 210, and when the rotation of the rotating tub 30 reaches a normal state, the rotating tub 30 is rotated. ) Flows into the receiving part where it can offset the unbalanced load inside. Therefore, the wash water W needs to flow freely through the inside of the inner channel 210 so that the inside is open and not blocked.

However, since the washing water flowing inside the inner channel 210 needs to flow inside the inner channel 210 with a predetermined frictional force in order to control the initial vibration, a bottom rib having a low height on the inner channel bottom 221. 222 is formed. The height of the bottom ribs 222 is significantly lower than the height of the inner channel 210, but may not slow the flow of the washing water flowing inside the inner channel 210, but does not block the flow itself.

The inclined rib 223 is formed to be inclined upward from the radially outer edge of the inner channel bottom 221 to the inner wall 231. Inclined rib 223 also plays a role similar to bottom rib 222.

4 to 6 are cross-sectional views showing the movement of the wash water in the base plate shown in FIG. That is, the operation of the second balancer is shown.

In particular, FIG. 4 is a view showing a state in which the rotation of the rotating tub 30 has just started before the rotating tub 30 is rotated.

The laundry is accommodated in the rotating tub 30 (see FIG. 1), and the washing water is accommodated in the tub 20 (see FIG. 1) and the rotating tub 30. Washing water (W) accommodated inside the rotating tub 30 of the wash water is introduced into the inner channel 210 through the inlet 151.

Since the inner channel 210 is open inside, the washing water W introduced into the inner channel 210 is stored in the inner channel 210 in a state capable of flowing in the inner channel 210.

As will be described later wash water (W) is introduced into the outer channel 220 to offset the unbalanced load of the rotating tub 30 (see FIG. 1), for this purpose, a portion of the wash water (W) is the inner channel 210 Are stored in.

At the same time, the wash water (W) stored in the inner channel 210 serves to offset the initial vibration caused by the rotation of the rotating tub 30 (see FIG. 1).

When the wash water W is stored in the inner channel 210, the weight of the entire rotating tub 30 (see FIG. 1) including the base plate 40 is increased, whereby the vibration of the rotating tub 30 is reduced. Occurs. Furthermore, since the wash water W may flow inside the inner channel 210, even when the rotating tank 30 is eccentrically rotated at the initial rotation of the rotating tank 30, the washing water W may rotate. Flow in the opposite direction to the eccentric direction of the stabilization of the rotation of the rotating tub 30 can be reduced accordingly the vibration of the rotating tub (30).

As described above, since the bottom rib 222 and the inclined rib 223 are formed in the inner channel bottom 221, the washing water W does not rotate with the rotation of the rotating tub 30 (see FIG. 1). The flow rate is lowered by the friction between the bottom rib 222 and the inclined rib 223. Therefore, during the initial rotation of the rotating tub 30, the function of stabilizing the rotation of the rotating tub 30 while remaining opposite to the eccentric direction of the rotating tub 30.

5 is a view illustrating a state in which the rotation of the rotating tub 30 begins to wash water flows into the external channel.

As shown in FIG. 5, the washing water W is pressed radially outward of the base plate 40 by the centrifugal force generated by the rotation of the rotating tub 30 (see FIG. 1). Pressurized washing water (W) is pressurized by the inner wall (231) when the centrifugal force is stronger and rises along the inner wall (231) is introduced into the outer channel 220 through the through-hole (230).

When the wash water W is introduced into the outer channel 220 through the through hole 23, the washing water W is dropped into the outer channel bottom 211 by a centrifugal force greater than gravity and is not discharged to the drain hole 240. 220 is pressed directly to the outer surface.

6 is a view showing a state in which the rotation of the rotating tub 30 has reached a steady state.

When the rotation of the rotating tub 30 (refer to FIG. 1) reaches a normal state, the laundry inside the rotating tub 30 may be collected and biased toward one side in the rotating tub 30, thereby unbalanced load on the rotating tub 30. This can happen. When an unbalanced load is generated in the rotating tub 30, the washing water W flows intensively into the receiving portion of the outer channel 220 located in the opposite direction to the laundry.

Since the accommodation portion is partitioned by the boundary plate 212 as described above, the washing water W introduced into the specific accommodation portion is received only in the specific accommodation portion without flowing while flowing to another adjacent accommodation portion.

The laundry that is biased to one side of the rotating tub 30 (see FIG. 1) and the washing water W accommodated in a specific accommodation portion balance the mass with each other, thereby canceling the unbalanced load of the rotating tub 30. When the unbalanced load of 30 is canceled, the vibration can be significantly reduced even if the rotating tub 30 rotates at high speed.

7 is a view illustrating a state in which the rotation of the rotating tub 30 is finished.

As shown in FIG. 7, the rotation of the rotating tub 30 (see FIG. 1) is terminated to remove the centrifugal force and the force applied to the wash water W. Thus, wash water W stays on the radially outer wall of outer channel 220 and falls to outer channel bottom 211 due to gravity.

The washing water W dropped to the outer channel bottom 211 flows to the drain hole 240 by the inclination of the outer channel bottom 211 and is drained.

When the rotation of the rotating tub 30 is stopped in the middle of the dehydration process, the washing water W is drained to the drain hole 240 formed in the receiving portion as described above. At the same time, the washing water W discharged from the laundry during the dehydration process is again stored in the internal channel 210 through the inlet 151, which is in the same state as shown in FIG. Therefore, when the rotating tub 30 rotates again for dehydration, the unbalanced load of the rotating tub 30 is canceled while going through the process of FIGS. 4 to 7.

1: washing machine 20: tub
30: rotating tank 40: base plate
100: upper plate 200: lower plate
151: inlet 210: internal channel
220: external channel 230: through hole
240: drain hole W: wash water
113, 143, 153: mass 120: restraint unit
130: control unit 131, 133, 134, 135, 136: electromagnet
86, 86b: control unit

Claims (21)

Cabinet;
A tub disposed inside the cabinet to accommodate wash water;
A rotating tub including a cylindrical portion forming a circumferential side and rotatably disposed in the tub;
A first balancer mounted on an upper portion of the rotating tub to cancel an unbalanced load of the rotating tub; And
And a second balancer mounted to the lower portion of the rotating tub so as to cancel an unbalanced load of the rotating tub by using a part of the washing water inside the rotating tub.
The second balancer
An inner channel formed along a lower circumferential direction of the rotating tub to store a portion of the washing water inside the rotating tub;
And an outer channel formed along an outer circumference of the inner channel to cancel an unbalanced load of the rotating tub. The method of claim 1,
Washing machine, characterized in that the outer surface of the outer channel is formed to have the same radius as the side of the rotating tub. The method of claim 1,
And said outer channel comprises a plurality of boundary plates formed inside said outer channel to divide said outer channel into a plurality of receiving portions. The method of claim 3,
Washing water stored in the inner channel is introduced into at least one of the plurality of receiving portions of the outer channel washing machine characterized in that to offset the unbalanced load of the rotating tub. The method of claim 1,
And the inner channel is open to allow wash water to flow inside the inner channel. The method of claim 5,
Washing water stored in the inner channel is washing machine, characterized in that to cancel the initial vibration of the rotating tub while flowing inside the inner channel. The method of claim 1,
And a through hole configured to communicate the inner channel and the outer channel. The method of claim 7, wherein
The washing water stored in the inner channel is introduced into the outer channel through the through-hole when the unbalanced load occurs in the rotating tub to offset the unbalanced load of the rotating tub. The method of claim 1,
And an inlet configured to allow washing water to flow into the at least one channel inside the cylinder. The method of claim 1,
The second balancer
And a plurality of drain holes formed in the lower portion of the at least one channel to allow the washing water to be discharged. Cabinet;
A tub disposed inside the cabinet to accommodate wash water;
And a rotating tub including a cylindrical portion forming a side circumference and a base plate supporting a lower portion of the cylindrical portion.
The base plate
At least one channel configured to receive wash water and formed along a lower circumferential direction of the base plate;
Washing machine stored in the at least one channel, characterized in that to offset the unbalanced load generated in the rotating tub. The method of claim 11,
The at least one channel comprises an inner channel formed along the lower circumferential direction of the base plate to store a portion of the wash water and an outer channel formed along the outer circumference of the inner channel to offset the unbalanced load of the tumbler The washing machine characterized by. The method of claim 11,
Washing water stored in the inner channel is introduced into at least one of the plurality of receiving portions of the outer channel washing machine characterized in that to offset the unbalanced load of the rotating tub. Cabinet;
A tub disposed inside the cabinet to accommodate wash water;
A rotating tank rotatably disposed in the tub;
An inner channel formed in the circumferential direction at the bottom of the rotating tub and configured to store a portion of the wash water;
An outer channel formed at a lower portion of the rotating tub along an outer circumference of the inner channel to offset an unbalanced load of the rotating tub;
And a through hole configured to communicate the inner channel and the outer channel.
When the rotating tub rotates to generate centrifugal force such that the wash water stored in the inner channel can cross the wall between the inner channel and the outer channel, the wash water stored in the inner channel is introduced into the outer channel through the through hole. Washing machine, characterized in that to cancel the unbalanced load of the rotating tub. 15. The method of claim 14,
And the inner channel is opened to allow the wash water to flow inside the inner channel, thereby canceling initial vibration of the rotating tub. 15. The method of claim 14,
And a drain hole formed in the lower portion of the outer channel to discharge the wash water introduced into the outer channel. Cabinet;
A tub disposed inside the cabinet to accommodate wash water;
A rotating tank rotatably disposed in the tub;
And a balancer mounted on the lower portion of the rotating tank to cancel an unbalanced load generated in the rotating tank.
The balancer
An inner channel formed along a circumferential direction of the balancer and formed in an annular shape to store a portion of the wash water;
And an outer channel formed on the outer circumference of the inner channel and configured to offset an unbalanced load of the rotating tub. 18. The method of claim 17,
And a through hole configured to communicate the inner channel with the outer channel so that the washing water stored in the inner channel can flow into the outer channel. 18. The method of claim 17,
And the inner channel is open so that the wash water flows inside the inner channel to cancel the initial vibration of the rotating tub. 18. The method of claim 17,
And the outer channel includes at least one boundary plate formed inside the outer channel to divide the outer channel into a plurality of accommodation portions. 18. The method of claim 17,
And a drain hole formed in the lower portion of the outer channel to discharge the wash water introduced into the outer channel.

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