KR101892012B1 - Clothes washer - Google Patents

Abstract

A washing machine according to the present invention includes: a washing shaft for rotating a washing blade; Dehydrating shrinkage for rotating the drum located inside the water tank; An axis coupling unit coupled to the washing shaft and transmitting rotational force of the driving motor; A clutch selectively engaging with the shaft engagement portion by axial movement to selectively transmit the rotational force of the drive motor to the dehydrating shafts; A clutch motor provided around the clutch and generating a force for axially moving the clutch; And a clutch motor provided in the clutch motor for moving between a raised position and a lowered position depending on whether power is applied to the clutch motor, ; A clutch spring provided at one side of the clutch and supporting the clutch in the downward position direction; And a clutch support portion provided between the dehydrating shafts and the clutch to hold the clutch in the raised position.

Description

Washing machine {CLOTHES WASHER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a washing machine, and more particularly to a clutch that connects a washing shaft and a dewatering shaft.

Generally, a washing machine uses a mechanical force to forcibly form a stream of washing water in a drum, thereby promoting the chemical action of the detergent. In addition, the washing machine applies a physical action such as friction or impact to the laundry, Is a device that can be realized.

Such a washing machine rotates a washing blade (pulsator) provided at a lower portion of the drum in the forward and reverse directions to form a water flow for washing. Therefore, such a washing machine requires dehydration shrinkage for rotating the drum and washing shafts for driving the laundry blades. That is, the washing machine is provided with a clutch for selectively driving the two driving shafts (washing shafts, dehydrating shafts). Accordingly, the clutch transmits the rotational force generated from the driving motor to the washing wing during washing, and to the washing wing and the drum when dewatering.

FIG. 1 is a sectional view schematically showing the construction of a general washing machine, and FIG. 2 is a sectional view showing a driving unit according to FIG.

Referring to this, the washing machine has a main body 1 that forms an outer appearance, and a water storage tank 2a is provided in the main body 1. As shown in FIG. Inside the water storage tank 2a, a drum 2b rotated by a drive motor 7 is rotatably provided. The drum 2b is provided at its lower portion with a laundry blade 3 for washing and is rotatable by a driving motor 7.

A driving motor 7 for generating a rotational force for rotating the drum 2b and the laundry blade 3 is provided below the water storage tank 2a and the drum 2b is driven by a driving motor 7 And the washing blade 3 receives the rotational force of the driving motor 7 by means of the washing shaft 6. The dehydrating shafts 5 and the washing shafts 6 are provided concentrically and the washing shafts 6 are located inside the dehydrating shafts 5. [ The dehydrating shafts (5) and the washing shaft (6) are rotatably supported by the bearing housing (4).

On the other hand, the drive motor 7 includes a stator 7a and a rotor 7b. The stator 7a has a coiled coil and a magnet and the rotor 7b covering the outer circumferential surface of the stator 7a is selectively coupled to the washing shaft 6 and the dehydrating shaft 5. In particular, the rotor 7b rotates by electromagnetic interaction with the stator, thereby transferring rotational force to the washing shaft 6 and the dewaxing shaft 5. An optional coupling between the rotor of the drive motor 7 and the dewatering shaft 5 and the washing shaft 6 is achieved by the clutch 8.

The clutch 8 is disclosed in Korean Patent Publication No. 10-2004-0067092. That is, the conventional clutch is provided with a tooth surface (not shown) which is engaged with the washing shaft 6 and is movable up and down and can be engaged with the rotor 7b. The washing shaft 6 is engaged with the rotor 7b by being engaged with the rotor 7b at the time of descending to release the coupling between the washing shaft 6 and the rotor 7b, And transmits the rotational force of the drive motor 7. The clutch 8 is vertically driven by a separate clutch motor 9.

The engaging and driving of the clutch 8 and the rotor 7b must be precisely performed. Otherwise, when the rotational force of the rotor 7b is transmitted while the clutch 8 is not fully engaged with the rotor 7b, the tooth surface of the clutch 8 may be broken.

When the rotor 7b rotates while the clutch 8 is not completely disengaged from the rotor 7b, an impact is transmitted to the clutch motor 9 or the washing shaft 6 and the dewaxing shaft 5 And may be damaged. Which may increase the risk of malfunction and breakage of the washing machine.

The conventional clutch 8 as described above is configured to continuously apply power to the clutch motor 9 to continue the washing mode when the drum 2b and the laundry blade 3 are separated from each other, So that the power consumption is increased accordingly.

Korean Patent Publication No. 10-2004-0067092

SUMMARY OF THE INVENTION It is an object of the present invention to provide a clutch device for a washing machine which can reduce power consumption generated when a drum and a laundry blade are separated to perform a washing mode.

In order to accomplish the object of the present invention, there is provided a washing machine comprising: a washing shaft for rotating a washing blade; Dehydrating shrinkage for rotating the drum located inside the water tank; An axis coupling unit coupled to the washing shaft and transmitting rotational force of the driving motor; A clutch selectively engaging with the shaft engagement portion by axial movement to selectively transmit the rotational force of the drive motor to the dehydrating shafts; A clutch motor provided around the clutch and generating a force for axially moving the clutch; And a clutch motor provided in the clutch motor for moving between a raised position and a lowered position depending on whether power is applied to the clutch motor, ; A clutch spring provided at one side of the clutch and supporting the clutch in the downward position direction; And a clutch support portion provided between the dehydrating shrinkage and the clutch and holding the clutch at an elevated position.

And a clutch rotating part provided between the clutch and the clutch core for rotating the clutch in the up position.

A pressing surface inclined in the circumferential direction is formed on the upper surface of the clutch core, and a guide surface inclined in the circumferential direction corresponding to the pressing surface may be formed on the lower surface of the clutch.

The inclined surface of the pressing surface and the inclined surface of the guide surface may be formed in the same manner.

A first tooth surface is formed on the inner circumferential surface of the clutch, and a second tooth surface is formed on an outer circumferential surface of the dewatering shaft to engage with the first tooth surface. The first tooth surface and the second tooth surface may be formed differently.

A plurality of second tooth surfaces may be formed along the circumferential direction, and the plurality of second tooth surfaces may be spaced apart from each other by a predetermined distance along the circumferential direction to form a sliding groove into which the first tooth surface is inserted.

The first support surface may be formed such that the lower surface of the first tooth surface is inclined at a predetermined inclination angle and the upper surface of the second tooth surface may correspond to the inclination angle of the first support surface.

A plurality of third tooth surfaces, which are engaged with the first tooth surface, are formed along the circumferential direction on the outer circumferential surface of the shaft coupling portion. The plurality of third tooth surfaces are spaced apart from each other in a position axially aligned with the sliding groove, A part of the second tooth surface passing through the one-surface sliding groove can be inserted between the third tooth surfaces.

The washing machine according to the present invention can keep the clutch separated from the shaft coupling portion without continuously applying power to the clutch motor during the washing mode, thereby reducing power consumption accordingly.

1 is a sectional view schematically showing the construction of a general washing machine,
FIG. 2 is a cross-sectional view showing the driving unit according to FIG. 1,
3 is a sectional view schematically showing a washing machine according to the present invention,
FIG. 4 is a cross-sectional view of the driving unit of FIG. 3,
FIG. 5 is a sectional view of the driving unit of the washing machine shown in FIG. 4,
6 is a conceptual diagram for explaining a series of operations in which the clutch according to the present embodiment is moved from a raised position in a washing mode to a lowered position in a dehydrating mode and then maintained in a raised position in a washing mode.
FIG. 7A and FIG. 7B are sectional views showing a switching state of the driving unit in the washing mode and the dehydrating mode in the washing machine according to the present invention. FIG.

Hereinafter, a clutch device for a washing machine according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

FIG. 3 is a cross-sectional view schematically showing a washing machine according to the present invention, FIG. 4 is a cross-sectional view of a driving unit according to the washing machine of FIG. 3, and FIG. 5 is a sectional view of a driving unit of the washing machine according to FIG.

3, the washing machine according to the present embodiment is provided with a water storage tank 12 inside a main body 11 forming an outer appearance and a drum 12 rotated by a driving motor 13 in a water storage tank 12, (14) is rotatably provided. The drum 14 is provided at its lower portion with a washing blade 15 for washing and is rotatable by a driving motor 13. Since this configuration is a general configuration of the washing machine, detailed description is omitted.

4 and 5, a structure for forming a driving part for driving a drum and a washing blade of the washing machine includes a washing shaft 16 for rotating the washing blade 15, a drum (not shown) A driving motor 13 including a dehydrator shaft 17 for rotating the washing shaft 14 and a rotor 13b coupled to the washing shaft 16 and transmitting a rotating force, And a clutch (20) capable of selectively transmitting the rotational force of the rotor (13b) to the dehydrating shafts (17).

The washing shaft 16 protrudes into the drum 14 through the center of the dew condensation shaft 17, and the washing blade 15 is coupled to the protruding end. The other end of the washing shaft 16 extends downward and is coupled to the rotor 13b of the driving motor.

The dehydrating shafts (17) are installed concentrically through the washing shaft (16). One end of the damping shaft 17 is coupled to the drum 14 to transmit the rotational force to the drum 14 and the other end is coupled to the rotor 13b selectively by the clutch 20 to receive the rotational force. A driven tooth surface 17a for engagement with the clutch 20 is formed at the intermediate portion of the damping shafts 17 so that the clutch 20 is restricted in the circumferential direction to the damping shafts 17, As shown in Fig.

A driven tooth surface 17a is formed on the outer peripheral surface of the damping shafts 17 so as to selectively receive the intermediate tooth surface 21b of the clutch 20 to be described later so as to receive the rotational force of the rotor 13b.

The driven tooth surface 17a is formed to be substantially axially long so as to be engaged with the intermediate tooth surface 21b of the clutch 20 and to be able to slide in the axial direction. However, the length of the driven tooth surface 17a is formed such that the driven tooth surface 17a can be separated from the intermediate tooth surface 21b when the clutch 20 is pushed up by the clutch core 42 to be described later . The specific shape of the driven tooth surface will be described together with the description of the coupling relationship with the intermediate tooth surface.

The washing shaft 16 and the dewatering shaft 17 are supported by the bearing housing 18 and are rotatable by bearings 19a and 19b. The bearing housing 18 can be supported so that a clutch core 42, which will be described later, can be moved in the axial direction.

The driving motor 13 is provided on the lower surface of the water storage tank 12 and forms the driving force of the drum 14 and the washing blade 15 and includes a stator 13a and a rotor 13b. The stator 13a has a ring shape and has a coil wound thereon. The rotor 13b has a container shape surrounding the stator 13a and has a magnet therein to rotate around the stator by interaction with a coil provided on the stator 13a.

At the center of the rotor 13b, there is provided an axial coupling portion 31 for coupling with the washing shaft 16 and the dew condensation shaft 17. The shaft coupling portion 31 and the rotor 13b are integrally rotated so that the washing shaft 16 passing through the shaft coupling portion 31 is fixed to the shaft coupling portion 31 by the nut 32, .

An axial hole 31a through which the washing shaft 16 passes is formed at the central portion of the shaft coupling portion 31. The intermediate tooth surface 21b of the clutch 20, And a drive tooth surface 31b for coupling the rotational force of the rotor 13b to the clutch 20 is formed. The driving tooth surface 31b is formed in a concavo-convex shape along the circumferential direction so as to have a predetermined length in the axial direction. When the shaft coupling portion 31 is engaged with the clutch 20, the rotational force of the rotor 13b is transmitted to both the washing shaft 16 and the dewatering shaft 17 to proceed to the dehydrating mode, Is separated from the clutch 20, the rotational force of the rotor 13b is transmitted only to the washing shaft 16 to proceed to the washing mode.

The clutch 20 may include a bush 21 formed in a cylindrical shape and a flange portion 22 extended to the outer peripheral surface of the bush 21.

A through hole 21a is formed in the center of the bush 21 so that the washing shaft 16 and the dewaxing shaft 17 can pass through. The inner peripheral surface of the through hole 21a is formed with a drive tooth surface 31b of the shaft coupling portion 31 and a middle tooth surface 21b selectively mating with the driven tooth surface 17a of the damping shafts 17 in accordance with the operation mode of the washing machine do. The intermediate tooth surface 21b is elongated in the substantially axial direction so as to correspond to the driving tooth surface 31b and the driven tooth surface 17a, and is formed so as to be irregular along the circumferential direction. Accordingly, the clutch 20 moves in the up-and-down direction (axial direction) along the dew condensation shaft 17 and moves to the raised position where the engagement between the lower position coupled with the rotor 13b and the rotor 13b is released, When the washing machine is in the dewatering mode, the rotational force transmitted through the shaft coupling portion 31 is transmitted to the dewaxing shaft 17 through the clutch 20.

The outer peripheral surface of the flange portion 22 is slidably engaged with the pressing surface 42a of the clutch core 42 to be described later so that the clutch 20 can rotate in one direction when the clutch core 42 moves in the axial direction The guide surface 22a is formed.

The guide surface 2a may be formed in a sawtooth shape that is inclined at approximately 45 degrees to correspond to the pressing surface 42a of the clutch core 42. [ Here, the inclination of the guide surface 22a is formed to be substantially equal to the inclination of the pressing surface 42a.

A clutch motor 41 is provided as a drive means for moving the clutch 20 up and down in the vicinity of the outer circumferential surface of the clutch 20. An electromagnetic force generated by the clutch motor 41 is applied to the inside of the clutch motor 41 There is provided a clutch core 42 that moves in the axial direction.

The clutch motor 41 is provided with an AC motor constituting a kind of solenoid, and is formed in an annular shape and fixedly coupled to the bearing housing 18 or the like.

The clutch core 42 is made of a magnetic material and is provided in a free state with respect to the clutch motor 41 so as to be able to move in the axial direction from the inside of the clutch motor 41. [ However, the clutch core 42 can be slidably engaged with a guide rod (not shown) provided in the bearing housing 18 or the like so as to move in the same locus in the axial direction.

A pressing surface 42a may be formed on the upper surface of the clutch core 42, that is, the surface facing the flange portion 22 of the clutch 20. The pressing surface 42a may be formed as a 45-degree inclined surface corresponding to the guiding surface 22a of the clutch 20, or may be formed in a saw-tooth shape in which both surfaces are inclined at 45 degrees.

The clutch core 42 is moved in the axial direction to approach or disengage the clutch motor 41 so that the clutch 20 is switched to the washing mode or the dehydration mode depending on whether or not the power is applied to the clutch motor 41 .

A clutch spring 51 for supporting the clutch 20 in the axial direction may be provided on the upper side of the clutch 20. The clutch spring 51 is composed of a compression coil spring. As a result, the clutch 20 is elastically supported in the upward direction by the clutch spring 51.

On the other hand, in order to maintain the state in which the clutch 20 is separated from the rotor 13b in the washing mode, that is, in a state in which the clutch 20 is separated from the shaft coupling portion 31, the intermediate tooth surface 21b of the clutch 20 is inserted into the through hole 21a , While the driven tooth surface 17a of the dew condensation shaft 17 can be formed only in the lower half.

Conversely, in order to switch the state in which the clutch 20 is engaged with the rotor 13b in the dewatering mode, that is, the state in which the clutch 20 is engaged with the shaft coupling portion 31, the intermediate tooth surface 21b has a large interval along the circumferential direction While the driven tooth surface 17a may be formed to have a narrow interval along the circumferential direction as compared with the intermediate tooth surface 21b.

A first supporting surface 21c is formed so that the lower surface of the intermediate tooth surface 21b is inclined in one direction and a second supporting surface 17b is formed on the upper surface of the driven tooth surface 17a so as to correspond to the first supporting surface 21c. Is formed. The second support surface 17b is formed as a pair of two, and each second support surface 17b is formed longer than the length of the first support surface 21c.

The driven tooth surface 17a is spaced apart by a circumferential width of the intermediate tooth surface 21b along the circumferential direction to form a sliding groove 17c. The intermediate tooth surface 21b can be supported on the second support surface 17b of the driven tooth surface 17a or moved axially along the sliding groove 17c between the driven tooth surfaces 17a according to the rotational position thereof.

6 is a conceptual diagram for explaining a series of operations in which the clutch according to the present embodiment is moved from a raised position in a washing mode to a lowered position in a dehydrating mode and then maintained in a raised position in a washing mode.

6 (a), when the clutch core 42 rises, the clutch 20 is pushed up, and the clutch 20 is moved in the circumferential direction ) While moving slightly.

When the clutch core 42 is lowered as shown in Fig. 6C, the clutch 20 slides along the damping shafts 17 and moves in the circumferential direction while the intermediate tooth surface 21b is inserted into the sliding groove 17c, .

The clutch 20 further descends and the intermediate tooth surface 21b of the clutch 20 is engaged with the drive tooth surface 31b of the shaft coupling portion 31 as shown in FIG.

When the clutch core 42 rises again as shown in FIG. 6E, the clutch 20 is pushed up by the clutch core 42 and the intermediate tooth surface 21b is separated from the driven tooth surface 31b and the driven tooth surface 17a The clutch 20 slides in the circumferential direction as shown in FIG. 6F so that the first support surface 21c of the intermediate tooth surface 21b rests on the second support surface 17b of the driven tooth surface 17a Thereby maintaining the raised position of the clutch 20.

In the drawing, reference numeral 52 denotes a core spring that elastically supports the clutch core.

In the washing machine according to the present embodiment, the washing mode and the dehydrating mode are operated as follows.

That is, the clutch 20 transmits the driving force of the driving motor 13 only to the washing shaft 16 while moving up and down according to the mode of the washing machine, or proceeds the washing mode or the washing shaft 16 and the dehydrating shaft 17, So that the dehydration mode proceeds.

This will be described in more detail as follows.

As shown in FIG. 7A, when the user selects the washing mode, the primary power is applied to the clutch motor 41, and the primary electromagnetic force is generated in the clutch motor 41.

Then, the clutch core 42 is attracted by the primary electromagnetic force of the clutch motor 41 and ascended and sucked in the direction close to the clutch motor 41. [

The vicinity of the attachment surface of the pressing surface 42a provided on the upper surface of the clutch core 42 is brought into contact with the vicinity of the attachment of the guide surface 22a provided on the flange portion 22 of the clutch 20. [ When the clutch core 42 further ascends, the pressing surface 42a pushes the guide surface 22a, and the clutch 20 is lifted along the axial direction.

At this time, the intermediate tooth surface 21b provided on the bush 21 of the clutch 20 is guided along the driven tooth surface 17a provided on the outer peripheral surface of the damping shaft 17, Thereby moving along the axial direction. However, as soon as the intermediate tooth surface 21b moves away from the driven tooth surface 17a, the guide surface 22a of the clutch 20 slides in the circumferential direction while being pushed by the pressing surface 42a of the clutch core 42 to rotate . In this state, when the primary power applied to the clutch motor 41 is removed, the clutch core 42 is lowered again to move to the original lowered position.

The clutch 20 is then pushed by the restoring force of the clutch spring 51 to engage the clutch core 42 with the restoring force of the clutch spring 51 as the clutch core 42 is lowered by the core spring 52 and the force for supporting the clutch 20 is removed. A force to descend is generated. At this time, in this embodiment, the first support surface 21c provided on the intermediate tooth surface 21b of the clutch 20 is placed on the second support surface 17b provided on the driven tooth surface 17a of the damping shaft 17 So that the clutch 20 is kept separated from the shaft coupling portion 31 without descending along the clutch core 42 even if the clutch core 42 moves to the lowered position.

This allows the clutch 20 to maintain the raised position, i.e., the position separated from the dehydrating shrink 17 even when power is not applied to the clutch motor 41. [

On the other hand, as shown in FIG. 7B, when the user finishes the washing mode and selects the dehydration mode, the secondary power is applied to the clutch motor 41, and the secondary electromagnetic force is generated in the clutch motor 41.

Then, the clutch core 42 is attracted and attracted by the secondary electromagnetic force of the clutch motor 41 and is attracted in the direction close to the clutch motor 41.

The clutch 20 is caused to rise along the axial direction in a state in which the pressing surface 42a of the clutch core 42 is in contact with the guide surface 22a of the clutch 20. [

At this time, the intermediate tooth surface 21b of the clutch 20 is guided along the driven tooth surface 17a of the damping shafts 17 so that the clutch 20 is moved along the axial direction to a predetermined height, and the intermediate tooth surface 21b The guide surface 22a of the clutch 20 slides in the circumferential direction while being pushed by the pressing surface 42a of the clutch core 42 to rotate. In this state, when the secondary power source applied to the clutch motor 41 is removed, the clutch core 42 is lowered again by the core spring 52 and moved to the original lowered position.

The clutch 20 is pushed by the restoring force of the clutch spring 51 to generate a force to descend along the clutch core 42 as the clutch core 42 supporting the clutch 20 is removed. At this time, the driven tooth surface 17a is provided with the sliding groove 17c cut axially in the middle in the circumferential direction, so that the intermediate tooth surface 21b moves along the sliding groove 17c.

The intermediate tooth surface 21b of the clutch 20 then moves away from the driven tooth surface 17a of the dewaxing shaft 17 and a part thereof is engaged with the drive tooth surface 31b of the shaft coupling portion 31. [ The rotational force of the rotor 13b is transmitted through the shaft coupling portion 31 and the clutch 20 to the dehydrating shafts 17 ).

In this way, the clutch can be kept separated from the shaft coupling portion while power is not continuously applied to the clutch motor during the washing mode, thereby reducing power consumption accordingly.

Further, when the mode of the washing machine is switched, the clutch is quickly moved to the ascending position and the descending position, the time for switching from the washing mode to the dehydrating mode or from the dehydrating mode to the washing mode can be shortened, .

13: drive motor 13b: rotor
16: washing shaft 17: dehydrating shrinkage
17a: driven tooth surface 17b: second supporting surface
17c: Sliding groove 20: Clutch
21: Bush portion 21b: intermediate tooth surface
21c: second supporting surface 22: flange portion
22a: guide surface 31:
31b: drive tooth surface 41: clutch motor
42: clutch core 42a: pressing face

Claims (8)

A washing shaft for rotating the laundry blade;
Dehydrating shrinkage for rotating the drum located inside the water tank;
An axis coupling unit coupled to the washing shaft and transmitting rotational force of the driving motor;
A clutch selectively engaging with the shaft engagement portion by axial movement to selectively transmit the rotational force of the drive motor to the dehydrating shafts;
A clutch motor provided around the clutch and generating a force for axially moving the clutch;
The clutch motor is provided inside the clutch motor and moves between a rising position and a falling position depending on whether power is applied to the clutch motor or not when the clutch motor is moved to the up position, Clutch core;
A clutch spring provided at one side of the clutch and supporting the clutch in the downward position direction; And
And a clutch support portion provided between the dehydrating shrinkage and the clutch and holding the clutch at an elevated position. The method according to claim 1,
Further comprising a clutch rotating portion provided between the clutch and the clutch core, wherein the clutch core rotates the clutch at the raised position. 3. The method of claim 2,
Wherein a pressing surface inclined in a circumferential direction is formed on an upper surface of the clutch core and a guide surface inclined in a circumferential direction is formed on a lower surface of the clutch so as to correspond to the pressing surface. The method of claim 3,
Wherein the inclined surface of the pressing surface and the inclined surface of the guide surface are formed identically. The method of claim 3,
A first tooth surface is formed on an inner circumferential surface of the clutch and a second tooth surface formed on an outer circumferential surface of the dewatering shaft to be engaged with the first tooth surface,
Wherein the first tooth surface and the second tooth surface are formed differently from each other. 6. The method of claim 5,
Wherein a plurality of second tooth surfaces are formed along the circumferential direction and the plurality of second tooth surfaces are spaced apart from each other by a predetermined distance along the circumferential direction to form a sliding groove into which the first tooth surface is inserted. The method according to claim 6,
Wherein the first tooth surface has a first supporting surface formed so that a lower surface thereof is inclined at a predetermined inclination angle,
And a second support surface is formed on the second tooth surface so that an upper surface thereof corresponds to an inclination angle of the first support surface. 8. The method of claim 7,
A plurality of third tooth surfaces, which are engaged with the first tooth surface, are formed along the circumferential direction on the outer peripheral surface of the shaft coupling portion,
And the plurality of third tooth surfaces are spaced apart from each other in a position axially aligned with the sliding groove so that a part of a second tooth surface passing through the sliding groove of the first tooth surface is inserted between the third tooth surfaces washer.

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