KR20200001010A - Washing machine - Google Patents

Abstract

A washing machine of the present invention comprises: an inner tub accommodating the laundry; an outer shaft having a hollow, and rotating the inner tub; an inner shaft rotatably provided in the hollow; a pulsator disposed in the inner tub, and connected to the inner shaft; a clutch screw-coupled to the inner shaft in the hollow of the outer shaft, spline-coupled to the outer shaft, restrained from being raised anymore when the inner shaft is rotated in a forward direction to reach a predetermined raising position so as to rotate the outer shaft in the forward direction, and restrained from being lowered anymore when the inner shaft is rotated in a reverse direction to reach a predetermined lowering position so as to rotate the outer shaft in the reverse direction; an upper sealer interposed between the inner shaft and the outer shaft on an upper side of the clutch; and a lower sealer interposed between the inner shaft and the outer shaft on a lower side of the clutch. The hollow is filled with a fluid in a region between the upper sealer and the lower sealer. A fluid movement path is formed between the clutch and the outer shaft to flow between a lower filling region corresponding to the lower side of the clutch and an upper filling region corresponding to the upper side of the clutch. Therefore, the present invention can provide a washing machine capable of controlling a clutch system through the rotation control of a motor.

Description

Washing machine {WASHING MACHINE}

The present invention relates to a washing machine having a clutch system for connecting or disconnecting a laundry shaft and a dehydration shaft.

In general, the washing machine is provided in the outer tub provided in the casing, the inner tub for accommodating the laundry is rotatable about a vertical axis, and the inner tub is provided with a pulsator for stirring the water flow.

The washing machine includes a motor for driving the inner tank and the pulsator. The motor transmits power through a double shaft structure having an inner shaft and an outer shaft. The inner shaft is a shaft for rotating the pulsator, and is directly connected to the motor, so that the pulsator rotates at all times when the motor is rotated. However, the outer shaft is a shaft for rotating the inner tank, it is configured to be connected or disconnected from the inner shaft by a clutch.

That is, when the outer shaft and the inner shaft are connected by the clutch, the pulsator and the inner tank are rotated together. On the contrary, when the outer shaft is separated from the inner shaft, the pulsator is in the stopped state. Only turns.

Korean Laid-Open Publication No. 2000-0063005 discloses a clutch applied to a washing machine. The clutch is not only complicated in structure by including a plurality of gears and a lever for operating the gears, but also requires a separate motor for operating the gears and the levers.

The problem to be solved by the present invention is to simplify the clutch system for connecting (decoupling) or separating the washing shaft and the dehydration shaft, the clutch system is operated by a motor for rotating the pulsator, not by a separate drive source It is to provide a washing machine. That is, without providing a separate control means for the control of the clutch system, to provide a washing machine that can control the clutch system through the rotation control of the motor for rotating the pulsator.

In addition, to reduce the number of parts of the clutch system, to provide a washing machine that eliminates the separate motor and all the components associated with the conventional motor used in the operation of the clutch system.

In addition, the clutch system is to provide a washing machine that can be prevented from being broken by the impact in the process of connecting the washing shaft and the de-shrink.

The washing machine of the present invention includes an inner tank for accommodating laundry, an outer shaft for forming a hollow, the inner shaft for rotating the inner tank, an inner shaft rotatably provided in the hollow, a pulsator disposed in the inner tank, and connected to the inner shaft; And a clutch screwed with the inner shaft in the hollow of the outer shaft and splined with the outer shaft.

The clutch is further restrained when the inner shaft is rotated in the forward direction to reach a predetermined lift position, and the outer shaft is rotated in the forward direction, and the lower shaft is restrained when the inner shaft is rotated in the reverse direction to reach the predetermined lower position. To rotate the outer shaft in the reverse direction.

The upper side of the clutch is provided with an upper sealer interposed between the inner and outer shafts, and the lower side of the clutch is provided with a lower sealer interposed between the inner and outer shafts.

The hollow is filled with fluid in an area between the upper sealer and the lower sealer, and is formed between the clutch and the outer shaft to form a lower filling area corresponding to the lower side of the clutch and an upper fill corresponding to the upper side of the clutch. A fluid movement path is formed to exchange the fluid between the regions.

A plurality of engagement grooves may be arranged along the circumferential direction on the inner circumferential surface of the outer shaft. The clutch includes a tubular clutch body having threads threaded to the inner shaft on an inner circumferential surface thereof, and a plurality of engagement grooves formed on the inner circumferential surface of the outer shaft to be engaged with the engaging grooves formed on the inner circumferential surface of the outer shaft. May include a device.

The fluid movement path may be formed between a section other than the engagement section on the outer circumferential surface of the clutch body and an inner circumferential surface of the outer shaft.

The upper sealer may form an upper buffer groove having an inlet open downwardly between the inner shaft and the inner sealer. The clutch may have an upper end in the upper buffer groove at the raised position.

The lower sealer may form a lower buffer groove having an inlet open upwardly between the inner shaft and the lower sealer. The clutch may have a lower end in the lower buffer groove at the lowered position.

The upper sealer has an outer circumferential surface in contact with an upper region of an inner circumferential surface of the outer shaft in which an engagement groove for splined engagement with the clutch is unformed, and an inner circumferential surface defines a hollow through which the inner shaft passes, the inner shaft and the upper side It may include an upper o-ring that seals between the caps.

The lower sealer has an outer circumferential surface in contact with an upper region of an inner circumferential surface of the outer shaft, in which an engagement groove for splined engagement with the clutch is unformed, and an inner circumferential surface defining a hollow through which the inner shaft passes, and the inner shaft and the lower side. It may include a lower o-ring that seals between the caps.

The washing machine of the present invention has the effect of simplifying the clutch system for connecting or disconnecting the washing shaft (or the inner shaft) and the dehydrating shaft (or the outer shaft), as compared with the related art. In particular, since the operation of the clutch system is made by a motor that provides power to rotate the pulsator, no separate power source or drive source is required for the operation of the clutch.

In particular, since the connection and disconnection between the washing shaft and the dehydration shaft are made by controlling the rotational direction of the motor, there is an effect that the control of the clutch system is very simple.

1 is a longitudinal sectional view of a washing machine according to an embodiment of the present invention.
2 is an enlarged view of a portion of FIG. 1.
FIG. 3 (a) schematically shows the planetary gear train when the pulsator rotates relative to the inner tank, and FIG. 3 (b) shows the planetary gear train when the inner tank and the pulsator rotate together. The operation is schematically illustrated.
4 is a view showing a configuration in which the outer axis is cut off and located inside.
5 is a cross-sectional view taken along the VV of FIG. 2.
(A) of FIG. 6 shows a state where the clutch is in an up position, (b) is a state where the clutch is located between an up and down position, and (c) is a state where the clutch is in a down position. It is shown.

1 is a longitudinal sectional view of a washing machine according to an embodiment of the present invention. 2 is an enlarged view of a portion of FIG. 1. FIG. 3 (a) schematically illustrates the operation of the planetary gear train when the pulsator rotates relative to the inner tank, and FIG. 3 (b) shows the planetary gear train when the inner tank and the pulsator rotate together. The operation is schematically illustrated. 4 is a view showing a configuration in which the outer axis is cut off and located inside. FIG. 5 is a cross-sectional view taken along the line V-V of FIG. 2. (A) of FIG. 6 shows a state where the clutch is in an up position, (b) is a state where the clutch is located between an up and down position, and (c) is a state where the clutch is in a down position. It is shown.

1 to 6, a washing machine according to an embodiment of the present invention includes an outer tub 1 containing water and a laundry disposed in the outer tub 1 to accommodate laundry, and center a vertical axis. The inner tank 2 rotated, the pulsator 3 disposed in the inner tank 2, and the motor 10 for providing a rotational force. A plurality of through holes (not shown) may be formed in the inner tank 2 so that water may be exchanged between the outer tank 1 and the inner tank 2.

Although not shown, a water supply unit (eg, a water supply valve) for supplying water to the outer tank 1 or the inner tank 2 may be provided, and a drainage unit (eg, to drain the outer tank 1) may be provided. Drain valve, drain pump) may be further provided.

The outer tub 1 is disposed in a casing (not shown) forming the exterior of the washing machine. The outer tub 1 may be suspended in the casing by a support rod (not shown). The support rod may be provided in plurality. When vibration is caused by the rotation of the inner tub 2, the outer tub 1 is lifted along the support rod, a suspension (not shown) or a damper (not shown) for buffering the lifting movement of the outer tub 1 It may be provided.

The motor 10 can be rotated forward and backward, and the pulsator 3 and the inner tank 2 are rotated by the motor 10. The motor 10 can control the rotation direction and the rotation speed. The motor 10 is preferably a brushless direct current electric motor (BLDC), but is not necessarily limited thereto.

The motor 10 is an outer rotor type in which a stator (not shown) in which an induction coil is wound at a center thereof, and the rotor 11 is rotated around the stator. The rotor 11 may include a bottom portion 13 and a ring-shaped side portion 12 extending upwardly from the bottom portion 13. The drive shaft 7 is rotated by the motor 10.

By the rotor bush 14, the drive shaft 7 can be connected to the rotor hub 15 fixed to the bottom 13. The inner circumferential surface of the side portion 12 of the motor 10 is provided with a plurality of magnets (not shown) along the circumferential direction, so that the rotor 11 is rotated by a magnetic field acting between the stator and the magnet.

The inner shaft 4 is connected with the pulsator 3. A fastening hole is formed in the center of the pulsator 3, and a screw 23 passing through the fastening hole from above may be fastened to the inner shaft 4.

The outer shaft 9 is connected to the inner tank 2, and has a tubular shape in which a hollow 9h through which the inner shaft 4 passes is formed. Below the inner tub 2, a hub base 18 coupled with the bottom of the inner tub 2 may be provided. An opening is formed at the center of the bottom of the inner tub 2, and fastening members such as screws and bolts are fastened to the bottom of the inner tub 2 by passing through the fastening members such as screws and bolts.

The hub base 18 is rotated together when the outer shaft 9 is rotated. The outer shaft 9 and the hub base 18 are splined together. At least one tooth constituting the spline may be formed on the outer surface of the outer shaft 9. The hub base 18 may be formed in a disk shape as a whole, and a boss through which the outer shaft 9 passes may be formed in the center. The inner circumferential surface of the boss may be provided with the engaging groove to be engaged with the teeth formed on the outer shaft (9). Unevenness (or spline) such as a tooth or a key formed on the outer shaft 9 is engaged with the engaging groove formed on the inner circumferential surface of the boss, thereby torqueing to the hub base 18 when the outer shaft 9 is rotated. Is passed. The outer shaft 9 may protrude upward after passing through the boss of the hub base 18, and this protruding portion may be engaged with the nut 19.

The bearing housing 16 may be disposed below the outer tub 1. The bearing housing 16 may be coupled to the bottom of the outer tub 1. The bearing housing 16 may be provided with a bearing 26 for supporting the outer shaft 9. In the bearing housing 16, the gear housing 17 mentioned later is arrange | positioned.

When the motor 10 is rotated, the inner shaft 4 is always rotated. In contrast, in order for the inner tub 2 to rotate, the torque provided by the motor 10 must be transmitted from the inner shaft 4 to the outer shaft 9, and this function is achieved by the lifting operation of the clutch 6.

The outer circumferential surface of the clutch 6 and the inner circumferential surface of the outer shaft 9 defining the hollow 9h are splined so that the clutch 6 can be elevated relative to the outer shaft 9. Here, the spline coupling means that one of the clutch 6 and the outer shaft 9 is formed with a spline such as a tooth or a key extending in the axial direction, and the other is formed with a groove engaged with the spline. Even when the clutch 6 is rotated together when the outer shaft 9 is rotated by the engagement between the grooves, the axial movement of the clutch 6 with respect to the outer shaft 9 is caused by the movement of the spline along the groove. To allow.

For example, at least one tooth 62 constituting a spline is formed on an outer circumferential surface of the clutch 6, and at least one engagement groove corresponding to at least one tooth 62 is formed on an inner circumferential surface of the outer shaft 9. 9r is formed. The engagement grooves 9r are engaged with the teeth 6a, respectively. The teeth formed on the outer shaft 9 may be formed in one body with the outer shaft 9, or may be formed as separate components and may be keyed to the outer shaft 9.

Preferably, the serrations of the teeth constituting the spline are triangular and interlocked with each other (the concept included in the spline coupling defined above). They are formed on the outer circumferential surface of the clutch 6 and the inner circumferential surface of the outer shaft 9, respectively. Can be.

Since the teeth 62 formed on the outer circumferential surface of the clutch 6 are engaged with the engagement grooves 9r formed on the inner circumferential surface of the outer shaft 9, the clutch 6 is in a raised position and cannot be raised any further. When it reaches the lowered position and cannot be lowered anymore, torque is transmitted to the outer shaft 9 through the clutch 6, and the clutch 6 and the outer shaft 9 rotate together. This will be described later in more detail.

The clutch 6 is screwed with the inner shaft 4 in the hollow 9h. On the outer circumferential surface of the inner shaft 4 a spiral thread 41 is formed along the axial direction, and on the inner circumferential surface of the clutch 6 a thread 6r, which engages with the thread 41, FIG. 2. Is formed. That is, in the relationship between the inner shaft 4 and the clutch 6, the inner shaft 4 corresponds to an external thread, and the clutch 6 corresponds to an internal thread.

Since the outer circumferential surface of the clutch 6 is splined with the inner circumferential surface of the outer shaft 9, and the inner shaft 4 and the clutch 6 are screwed together, the inner shaft ( When 4) is rotated, the clutch 6 is raised or lowered in accordance with the rotational direction of the inner shaft 4 while rotating relative to the thread 41. Hereinafter, the rotation direction of the inner shaft 4 which causes the clutch 6 to rise is called a positive direction, and the opposite direction is defined as a reverse direction.

The clutch 6 is further restrained when the inner shaft 4 is rotated in the forward direction to reach a predetermined lift position (see Fig. 6A). If the inner shaft 4 continues to rotate in the forward direction while the clutch 6 is lifted up, the outer shaft 9 also rotates in the forward direction.

In contrast, the clutch 6 is further restrained when the inner shaft 4 is rotated in the reverse direction to reach a predetermined lowered position (see FIG. 6C). When the lowering of the clutch 6 is restrained and the inner shaft 4 continues to rotate in the reverse direction, the outer shaft 9 also rotates in the reverse direction.

At least one of the raised position and the lowered position of the clutch 6 may be defined by the thread 41. That is, when the clutch 6 is rotated relative to the inner shaft 4 in the reverse direction, and reaches the upper end of the thread 41, the upward movement is restrained because the clutch 6 can no longer be rotated, and the clutch at this time The position of (6) becomes the rising position.

On the contrary, when the clutch 6 is rotated relative to the inner shaft 4 in the forward direction, and reaches the lower end of the thread 41, the lowering motion is restrained because the clutch 6 can no longer be rotated. The position of (6) becomes the lowered position.

On the other hand, alternatively, it is also possible to further include an upper stopper for restraining the rise of the clutch 6 and / or a lower stopper for restraining the lowering. For example, the bearing 27 interposed between the inner shaft 4 and the outer shaft 9 may be the upper stopper. It is also possible to further include a bearing for the lower stopper.

As another example, a bush or a ring may be fitted to the inner shaft 4, or a protrusion may protrude from the outer circumferential surface of the inner shaft 4 to constitute the upper stopper or the lower stopper.

On the other hand, the region in which the clutch 6 is moved in the first hollow formed in the outer shaft 9 may be provided outside the inner tub 2. Furthermore, the region in which the clutch 6 is moved may be provided below the outer tub 1. Since the region in which the clutch 6 is moved (or a space for installing or operating the clutch 6) is not provided inside the inner tub 2, the pulsator 3 is similar to a conventional washing machine, so that the inner tub ( 2) can be placed on the floor.

On the other hand, the upper sealer 50 interposed between the inner shaft and the outer shaft at the upper side of the clutch 6, and the lower sealer 70 interposed between the inner shaft 4 and the outer shaft at the lower side of the clutch 6 is further provided. do.

The upper sealer 50 and the lower sealer 70 each have a tubular shape, and the inner circumferential surface defines a hollow through which the inner shaft 4 passes, and the outer circumferential surface is in contact with the inner circumferential surface of the outer shaft 9.

The hollow 9h of the outer shaft 9 is filled with a fluid having a predetermined viscosity in the region between the upper sealer 50 and the lower sealer 70. Further, between the clutch 6 and the outer shaft 9, the fluid is exchanged between the lower filling region L corresponding to the lower side of the clutch 6 and the upper filling region H corresponding to the upper side of the clutch 6. 6S of fluid movement paths are formed.

That is, when the inner shaft 4 is rotated in the forward direction and the clutch 6 is moved upward, the volume of the upper filling region H is reduced, so that the fluid in the upper filling region H is fluid flow path 6S. It passes through and moves to the lower filling region (L). When the clutch 6 is moved upward, compression of the fluid in the upper filling region H, viscous frictional force during the movement of the fluid, resistance in the process of passing through the fluid movement path 6S, etc. are generated. The impact acting from the upper stopper is reduced in the process of reaching the clutch 6 in the ascending position. At this time, the upper stopper is not limited to the above, it may be composed of an upper sealer (50).

On the other hand, when the inner shaft 4 is rotated in the reverse direction and the clutch 6 is moved downward, the volume of the lower filling region L is reduced, so that the fluid in the lower filling region L is fluid flow path 6S. It passes through and moves to the upper filling region (H). At this time, since the compression of the fluid in the lower filling region L, the viscous frictional force during the movement of the fluid, the resistance in the process of passing through the fluid movement path 6S, etc. are generated during the lowering of the clutch 6, the clutch is generated. The impact from the lower stopper is reduced in the process of reaching (6) in the lowered position. At this time, the lower stopper is not limited to the above, it may be composed of a lower sealer (70).

A plurality of engagement grooves 9r are arranged along the circumferential direction on the inner circumferential surface of the outer shaft 9. The clutch 6 is formed in a tubular shape, and is formed on a clutch main body 61 having a thread (not shown) screwed to the inner shaft 4 on an inner circumferential surface thereof, and formed on an outer circumferential surface of the clutch main body 61 of the outer shaft 9. It may include a plurality of teeth (62) formed on the inner circumferential surface and engaged with the engaging groove (9r).

Here, the teeth 62 may not be formed between the whole sections along the circumferential direction on the outer circumferential surface of the clutch body 61, but may be formed only in predetermined engagement sections P1 and P2 corresponding to a part of the circumference. The fluid movement path 6S is formed between the inner circumferential surface of the outer shaft 9 in a section other than the engagement sections P1 and P2 on the outer circumferential surface of the clutch body 61 (that is, the section in which the teeth 62 are not generated). It can be intervals that become. Preferably, the pair of engagement sections (P1, P2) may be formed so that two fluid movement path (6S) is formed.

On the other hand, it is not limited to this, but the engaging groove 9r on the inner circumferential surface of the outer shaft 9 is also not to be formed in the entire area along the circumference, and corresponds to the engaging sections P1 and P2 of the clutch body 61. It may be formed only in the section. In FIG. 5, 9S indicates a section in which the engagement groove 9r is not formed on the inner circumferential surface of the outer shaft 9. Preferably, the section 9S forms the fluid movement path 6S between the clutch 6 and the clutch 6. do.

On the other hand, the upper sealer 50 forms an upper buffer groove 51h having an inlet opened downwardly between the inner shaft 4, and the clutch 6 has an upper buffer groove 51h having an upper end at the raised position. It can be located within. When the clutch 6 enters the upper shock absorbing groove 51h while the clutch 6 reaches the raised position, the fluid filled in the upper shock absorbing groove 51h acts as a buffer.

The upper sealer 50 may include an upper cap 51 and an upper o-ring 52. When distinguishing the upper region and the lower region on the inner circumferential surface of the outer shaft 9 with respect to the engaging groove (i.e., the portion splined with the clutch 6), the upper region is in contact with the outer circumferential surface of the upper cap 51, and the lower The area is in contact with the outer circumferential surface of the lower cap 71 described later.

More specifically, the upper cap 51 is formed in a tubular outer circumferential surface is in contact with the upper region of the inner circumferential surface of the outer shaft (9) is an unformed region, the inner circumferential surface is a hollow through which the inner shaft 4 passes To regulate.

The upper o-ring 52 seals between the inner shaft 4 and the upper cap 51. A groove is formed along the circumferential direction on the inner circumferential surface of the upper cap 51, and the upper o-ring 52 may be inserted into the groove.

Similarly, the lower sealer 70 can form a lower buffer groove 71h having an inlet open upwardly between the inner shaft 4. The lower sealer 70 may be substantially the same configuration as the upper sealer 50. In this case, the upper sealer 50 is turned upside down and the lower sealer 70 is inserted into the inner shaft 4.

The clutch 6 may be located at the lower end of the lower buffer groove 71h in the lowered position. When the clutch 6 enters the lower buffer groove 71h while reaching the lowered position, the fluid filled in the lower buffer groove 71h acts as a buffer.

The lower sealer 70 may include a lower cap 71 and a lower o-ring 72. More specifically, the lower cap 71 is formed in a tubular outer circumferential surface is in contact with the lower region of the inner circumferential surface of the outer shaft (9) is an unformed region, and the inner circumferential surface is a hollow through which the inner shaft 4 passes. To regulate.

The lower o-ring 72 tightly seals between the inner shaft 4 and the lower cap 71. A groove is formed along the circumferential direction on the inner circumferential surface of the lower cap 71, and the lower o-ring 72 may be inserted into the groove.

The planetary gear train 8 is disposed in the gear housing 17 engaged with (or shaft coupled to) the outer shaft 9. The gear housing 17 is shafted with the outer shaft 9 so that it rotates together when the outer shaft 9 is rotated.

The gear housing 17 may include an upper housing 17a and a lower housing 17b. The lower housing 17b and the upper housing 17a are coupled to each other by fastening members such as screws or bolts. A space is formed between the upper housing 17a and the lower housing 17b to accommodate the planetary gear train 8.

The planetary gear train 8 includes a sun gear 81, a pinion gear 82, a carrier 83, and a ring gear 84. The sun gear 81 is connected to the drive shaft 7 and rotates integrally with the drive shaft 7.

The ring gear 84 may be fixed inside the gear housing 17. That is, the ring gear 84 is rotated integrally with the gear housing 17. The ring gear 84 is an internal gear, and teeth engaging with the pinion gear 82 are formed on an inner circumferential surface defining a ring-shaped opening.

The pinion gear 82 is interposed between the sun gear 81 and the ring gear 84 to mesh with the sun gear 81 and the ring gear 84. A plurality of pinion gears 82 may be arranged along the circumference of the sun gear 81, and each pinion gear 82 is rotatably supported by the carrier 83.

The carrier 83 is engaged with the washing shaft 4 (axes). The carrier 83 is a kind of link connecting the pinion gear 82 and the washing shaft 4. That is, as the pinion gear 82 revolves around the sun gear 81, the carrier 83 is rotated, so that the washing shaft 4 is rotated.

Hereinafter, the operation of the clutch 6 will be described with reference to FIG. 6.

Fig. 6A shows a state where the clutch 6 has reached the raised position. At this time, the upper end portion of the clutch 6 in the raised position is located in the upper buffer groove (51h) of the upper sealer (50).

In this state, when the inner shaft 4 rotates in the forward direction, since the clutch 6 can no longer be raised, the outer shaft 9 rotates in the forward direction. This is a case where the pulsator 3 and the inner tank 2 are rotated together in the forward direction.

On the contrary, when the inner shaft 4 is rotated in the reverse direction while the clutch 6 reaches the lift position, the outer shaft 9 remains stopped due to the inertia or load of the outer tub 1, and the clutch ( 6) will descend. At this time, only the pulsator 3 is rotated while the inner tank 2 is stopped. FIG. 6B shows the position of the clutch 6 when the clutch 6 is rotated in this manner only the pulsator 3.

On the other hand, the pulsator 3 can be continuously rotated in the state in which the inner tank 2 is stopped according to the maximum angle (or rotational speed) which the clutch 6 can rotate continuously between a lowered position and an elevated position. The maximum angle (or rotational speed) can be determined. In the section in which the clutch 6 is lifted, the pulsator 3 may be rotated in the forward or reverse direction according to the rotation direction of the motor 10.

In particular, when the clutch 6 does not reach the rising position or the falling position and is between these positions, the rotation direction of the pulsator 3 is also determined according to the rotation direction of the inner shaft 4, so that the motor 10 By controlling the rotational direction of, the stirring rotation of the pulsator 3 can be induced.

FIG. 6C shows a state where the clutch 6 has reached the lowered position. In this state, when the inner shaft 4 rotates in the reverse direction, since the clutch 6 can no longer lower, the outer shaft 9 rotates in the reverse direction. This is a case where the pulsator 3 and the inner tank 2 rotate together in the reverse direction. When the clutch 6 is in the lowered position, the lower end of the clutch 6 is located in the lower buffer groove 71h of the lower sealer 70.

Claims (6)

An inner tank to house laundry;
An outer shaft having a hollow and rotating the inner tank;
An inner shaft rotatably provided in the hollow;
A pulsator disposed in the inner tank and connected to the inner shaft;
In the hollow of the outer shaft is screwed with the inner shaft and splined with the outer shaft, when the inner shaft is rotated in a forward direction to reach a predetermined lift position further restrained to rotate the outer shaft in the forward direction, the inner shaft A clutch that rotates in the reverse direction and stops further lowering when the predetermined lowering position is reached to rotate the outer shaft in the reverse direction;
An upper sealer interposed between the inner shaft and the outer shaft at an upper side of the clutch; And
A lower sealer interposed between the inner shaft and the outer shaft at a lower side of the clutch,
The hollow is,
Fluid is filled in the area between the upper sealer and the lower sealer,
And a fluid movement path formed between the clutch and the outer shaft to exchange the fluid between a lower filling region corresponding to a lower side of the clutch and an upper filling region corresponding to an upper side of the clutch. The method of claim 1,
The inner peripheral surface of the outer shaft is arranged a plurality of engagement grooves along the circumferential direction,
The clutch is,
A tubular clutch body having a thread formed on the inner circumferential surface and screwed to the inner shaft; And
And a plurality of teeth arranged along the circumferential direction in the engagement section on the outer circumferential surface of the clutch body and engaged with the engaging grooves formed on the inner circumferential surface of the outer shaft,
The fluid movement path,
Washing machine formed on the outer peripheral surface of the clutch body between the section other than the engagement section and the inner peripheral surface of the outer shaft. The method of claim 1,
The upper sealer,
An upper buffer groove having an inlet opened downwardly with the inner shaft is formed,
The clutch is,
Washing machine having an upper end in the upper buffer groove in the raised position. The method of claim 1,
The lower sealer,
A lower buffer groove is formed between the inner shaft and the inlet opened upward,
The clutch is,
Washing machine having a lower end in the lower buffer groove in the lowered position. The method of claim 1,
The upper sealer,
An outer circumferential surface is in contact with an upper region of an inner circumferential surface of the outer shaft in which an engagement groove coupled to the clutch is splined, and an inner circumferential surface defines a hollow through which the inner shaft passes;
Washing machine comprising an upper O-ring which is airtight between the inner shaft and the upper cap. The method of claim 1,
The lower sealer,
An outer circumferential surface is in contact with an upper region of an inner circumferential surface of the outer shaft in which a mating groove splined to the clutch is unformed, and an inner circumferential surface defines a hollow through which the inner shaft passes; And
Washing machine including a lower O-ring airtight between the inner shaft and the lower cap.

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