KR20090088844A - Motor unit, method of assembling motor unit, washing machine, and method of assembling washing machine - Google Patents

Abstract

A method of assembling a motor unit (55), the method including mounting of the motor unit (55) on a washing machine body, where the motor unit (55) has a stator holding part (33) to be mounted on the washing machine body, a stator (5a), and a rotor (5b) having a magnet and fitted to a rotating shaft (4a) journalled on the washing machine body. The method has a first step for assembling the stator (5a) and the rotor (5b), the stator (5a) being in a state where it is not yet mounted on the stator holding part (33), the rotor (5b) being in a state where it is not yet mounted on the rotating shaft (4a) and has magnetized magnets, a second step for mounting the rotor (5b) on the rotating shaft (4a), and a third step for mounting the stator (5a) on the stator holding part (33). Assembly of the motor unit (55) to be mounted on the washing machine can be easily made with high workability and without requiring skill. ® KIPO & WIPO 2009

Description

How to assemble a motor unit, a motor unit, a washing machine and a washing machine {MOTOR UNIT, METHOD OF ASSEMBLING MOTOR UNIT, WASHING MACHINE, AND METHOD OF ASSEMBLING WASHING MACHINE}

The present invention relates to a method for assembling a motor unit having a stator attached to a washing machine, a shaft for driving supported by the washing machine, and a rotor having a magnet, a method for assembling a washing machine equipped with the motor unit, and The motor unit of the washing machine used, and the washing machine in which the motor unit is mounted.

A conventional washing machine with a motor of a washing machine has a configuration of a drum type washing machine 100 (hereinafter referred to as washing machine 100) as shown in FIGS. 9 and 10, for example. These washing machines 100 are provided with a water tank 102 and a rotating drum 104 (hereinafter referred to as drum 104) in the washing machine main body 101 (hereinafter referred to as the main body 101). The water tank 102 is elastically supported by the main body 101 by a suspension structure (not shown). The drum 104 is provided in the water tank 102, and many holes 103 are formed. In addition, the drum 104 is rotationally driven by the motor 105. The door 106 is provided in the front side of the main body 101 so that opening and closing is possible. When the door 106 is opened, the laundry (not shown) is put into the drum 104 and taken out through the front opening of the water tank 102 and the front opening of the drum 104.

Moreover, after opening the door 106 and putting laundry into the drum 104, detergent is thrown in and the operation of the washing machine 100 is started. When operation of the washing machine 100 starts, water is supplied from the water supply part 107 in the water tank 102. Water (not shown) supplied to the water tank 102 enters the drum 104 through the plurality of holes 103, and the required amount of water is supplied to the drum 104. When the drum 104 is driven to rotate at a predetermined rotational speed by the motor 105, the laundry contained in the drum 104 is caught by the stirring protrusion 108 provided on the inner circumferential surface of the drum 104 and lifted in the rotational direction. Lose. The laundry lifted in the rotational direction falls from an appropriate height. As a result, a tapping action is applied to the laundry, and the laundry is washed. After this washing stroke, the dirty washing water is drained out of the main body 101 by the drainage portion 109, and a rinsing stroke is performed using the freshly watered water. After the rinsing stroke is finished, the drum 104 is rotated at high speed, so that the dewatering stroke is executed. These washing strokes, rinsing strokes, and dehydration strokes are automatically executed based on a predetermined control procedure.

Such a conventional washing machine is, for example, Japanese Patent Laid-Open No. 10-263271 (hereinafter referred to as Patent Document 1), Japanese Patent Laid-Open No. 2006-43105 (hereinafter referred to as Patent Document 2), and Japanese Patent Laid-Open No. 2005-168116. Patent Documents (hereinafter referred to as Patent Document 3), Japanese Patent Application Laid-Open No. 2004-216166 (hereinafter referred to as Patent Document 4), and the like.

A conventional washing machine has, for example, a first motor capable of forward and reverse rotation for executing a washing stroke and a rinsing stroke, and a second motor continuously rotating in one direction for performing a dehydration stroke. The first motor drives the rotary drum in forward and reverse rotation at a first rotational speed in the washing stroke and the rinsing stroke. The second motor continuously rotates the rotary drum in one direction at the second rotation speed in the dehydration stroke. The first motor and the second motor are attached to the rear surface of the tank, and transmit the rotational force to the rotating drum by the V belt. The driving method of such a rotating drum is disclosed by patent document 1, for example. Moreover, the patent document 2 discloses the drive system which transmits the rotation of the motor attached to the back of the tank directly to the rotating shaft of a rotating drum. In addition, Patent Document 3 discloses an inner rotor type motor in which a rotor is disposed on an inner circumference of a stator of a motor attached to a rear surface of a water tank. Or the outer rotor type motor by which the rotor is arrange | positioned on the outer periphery of a stator is disclosed by patent document 4, for example. As described above, various methods are used for the driving method for driving the rotating drum.

9 shows the conventional drum type washing machine 100 in which the inner rotor type motor 105 was used. Fig. 10 shows a conventional drum type washing machine 100 in which an outer rotor type motor 105 is used. In any drum type washing machine 100, the stator 110 is attached to the outer bottom surface of the back of the water tank 102, and the rotor 111 is attached to the rotating shaft 112.

Moreover, the structure which attaches the stator 110 to the outer bottom surface of the water tank 102 is disclosed by patent document 3, for example. That is, as shown in FIG. 11, the stator 110 and the rotor 111 are molded with the resin material. The attachment leg 113 is formed in the part in which the stator 110 was resin-molded. Using a screw or bolt 114, an attachment leg 113 is attached to the outer bottom surface of the water tank 102. As a result, the motor 105 is attached to the outer bottom surface of the water tank 102.

In addition, it is not limited to the structure shown in FIG. 11, When the motor 105 is used for drive of the washing machine 100, it is not limited to the water tank 102, The stator 110 is fixed to the fixed part of the washing machine 100 somewhere. ) Is attached. In addition, the rotor 111 is connected to and attached to various shafts for driving the drum 104 and the like.

In any case, as shown in FIG. 9 or FIG. 10, the stator 110 is attached to the fixing portion of the washing machine 100 such as the back of the water tank 102. In addition, the rotor 111 is directly attached to the rotating shaft 112 which protrudes from the fixing part of the washing machine 100. With the attachment of the stator 110 and the rotor 111, the motor 105 is assembled with the stator 110 and the rotor 111.

In assembling the motor 105 to the conventional washing machine 100, which is accompanied by the attachment of the stator 110 and the rotor 111, it is necessary to ensure uniform voids between the stator 110 and the rotor 111; It is necessary to attach the fitting portion by stopping the rotation by the serration or the key of the rotor 111 and the rotation shaft 112.

Conventionally, when the motor 105 is assembled to the washing machine 100, first, the stator 110 is attached to the washing machine 100. Thereafter, while the air gap is secured between the magnetized rotor 111 and the stator 110 already attached to the washing machine 100, the position alignment of the rotation stop of the rotor 111 and the rotating shaft 112 is performed. 111 is fitted to the rotating shaft 112 and attached.

However, in the conventional work in which the motor 105 is attached to the washing machine 100, the magnetized rotor 111 is inserted into the stator 110 by securing a gap between the stator 110 and the rotor 111. Fit. In addition, alignment of the rotation stop of the magnetized rotor 111 and the rotating shaft 112 is performed. In this assembling work, when the stator 110 and the rotor 110 are inclined, the stator 110 and the rotor 110 need to be made larger than the force to be self-adsorbed. For this reason, such assembling work is very difficult. However, as with the conventional washing machine 100 described above, the rotor (with the fitting operation of the stator 110 and the rotor 111 and the alignment of the point stop of the rotor 111 and the rotating shaft 112) The fitting work of the 111 and the rotating shaft 112 is performed simultaneously. The assembly of such a washing machine 100 is poor in assembly workability, and requires skill in assembly work. As a result, the assembly cost of the washing machine 100 becomes expensive.

Patent Document 1: Japanese Patent Application Laid-Open No. 10-263271

Patent Document 2: Japanese Patent Application Laid-Open No. 2006-43105

Patent Document 3: Japanese Patent Application Laid-Open No. 2005-168116

Patent Document 4: Japanese Patent Application Laid-Open No. 2004-216166

The present invention does not require an assembly of a motor unit attached to a washing machine, and is easy to work with. The method for assembling the washing machine and the motor unit is easily performed, the motor unit used for them, and the washing machine on which the motor unit is mounted. To provide.

A method for assembling a washing machine according to the present invention is a method for assembling a washing machine having a washing machine main body, a water tank, a rotating drum, a rotating shaft, and a motor unit having a stator holder and a stator rotor, wherein the water tank is elastically supported in the washing machine body. The rotating drum has a plurality of holes formed therein and is disposed in the tank, and one end of the rotating shaft is attached to the rear surface of the rotating drum, and the other end of the rotating shaft serration part is installed, and the stator holding part is attached to the rear surface of the tank to support the rotating shaft. The bearing part in which the bearing is press-fitted is integrally formed, the stator has a stator core, a stator resin mold part and an attachment part, the stator core is wound around a tooth extending in the radial direction, and the stator resin mold part is formed of a resin material. The mold is attached to the stator resin mold portion, and the rotor is made of metal boss. It has a magnet and a rotor core, the boss is formed a rotor serration portion that is engaged with the rotating shaft serration portion, the magnet is installed in a position corresponding to the winding, the rotor core corresponds to the magnet, the rotor is also the boss and magnet And the rotor core are integrally molded by the resin material, and the rotor serration portion is engaged with the rotation shaft serration portion and then attached to the rotation shaft. In addition, the assembling method of the washing machine includes a first step in which the stator before being attached to the stator holding part, the rotor before magnets are completed magnetization, and the rotor before being attached to the rotating shaft serration part are combined by magnetic adsorption, and the first step. Later, a second step in which the rotor serration portion is engaged with the rotation shaft serration portion of the rotating shaft supported by the bearing on the stator holding portion, and after the second step, the attachment portion is attached to the stator holding portion by fastening with a bolt. Has 3 steps. According to this method, the washing | cleaning machine which does not require skill of assembly of the motor unit attached to a washing machine, and is easy to workability is provided.

Moreover, the assembly method of the motor unit which concerns on this invention is a assembly method of the motor unit which has a stator holding part, a stator, and a rotor, The stator holding part has one end attached to the back of a rotating drum, and the rotating shaft serration part provided in the other end. The bearing supporting the rotating shaft is integrally formed, and the stator has a stator core, a stator resin mold part and an attachment part, and a stator core is wound around a tooth extending in a radial direction, and the stator resin mold part has a stator core. Molded from a resin material, the attachment portion is provided on the stator resin mold portion, the rotor has a metal boss, a magnet and a rotor core, the boss is formed with a rotor serration portion engaged with the rotating shaft serration portion, and the magnet is wound. Is installed in a position corresponding to the rotor core, the rotor corresponds to the magnet, and the rotor And is molded integrally by the magnet and the rotor core is a resin material, and then walk to the aligned rotor serration portion rotating shaft serration unit, it is attached to the rotating shaft. In addition, the assembling method of the motor unit includes a first step in which the stator before being attached to the stator holding part and the rotor before magnets have been magnetized and the rotor before being attached to the rotating shaft serration part are combined by magnetic adsorption, and the first step. After the second step, the rotor serration portion is engaged with the rotation shaft serration portion of the rotating shaft supported by the bearing on the stator holding portion, and after the second step, the attachment portion is attached to the stator holding portion by fastening with a bolt. Has a third step. According to this method, an assembly of a motor unit attached to a washing machine does not require skill, and provides a motor unit which is easily performed with good workability.

Moreover, the motor unit which concerns on this invention has the stator holding part, the stator, and the rotor, The stator holding part has the bearing part in which the one end is attached to the back surface of a rotating drum, and the bearing which supports the rotating shaft provided with the rotating shaft serration part in the other end was press-fitted. It is formed integrally, the stator has a stator core, a stator resin mold portion and an attachment portion, the stator core is wound around the teeth extending in the radial direction, the stator resin mold portion is molded by the resin material, the attachment portion The rotor is provided in the stator resin mold portion, the rotor has a metal boss, a magnet and a rotor core, and the boss is formed with a rotor serration portion engaged with the rotation shaft serration portion, and the magnet is installed at a position corresponding to the winding, and the rotor The core corresponds to the magnet, and the rotor also has a boss and a magnet and the rotor core The mold is integrally molded, and the rotor serration portion is engaged with the rotation shaft serration portion and then attached to the rotation shaft. Furthermore, the stator is attached to the stator holding part after the stator before attaching to the stator holding part and the rotor are magnetized and the rotor before being attached to the rotating shaft serration part is combined by self-adsorption. And an annular washer-side positioning portion provided in the stator holding portion and having a concave or convex shape, and an annular stator-side positioning portion provided in the stator and having a convex or concave shape. A cross section of the stator holding side of the side positioning unit, a circumferential surface fitted to the washing machine side positioning unit in the stator side positioning unit, a cross section of the stator side of the washing machine side positioning unit, Both parts of the circumferential surface fitted to the stator side positioning unit in the washing machine side positioning unit One side is formed with a tapered surface or an arcuate surface, the difference between the concave positioning portion and the maximum opening diameter of the positioning convex portion at least the distal end having a diameter larger than the diameter of the stator and the rotor diameter difference. According to this structure, the assembly of the motor unit attached to a washing machine does not require skill, and the motor unit which is performed easily with good workability is provided.

Moreover, the washing machine which concerns on this invention has the washing machine main body, the water tank, the rotating drum, the rotating shaft, the motor unit which has the stator holding part, the stator, and the rotor, the water tank is elastically supported in the washing machine main body, and many rotating drums And the stator holding part is attached to the back surface of the water tank, and the bearing supporting the rotating shaft is press-fitted into the bearing, Wherein the stator core is made of a resin material, and the stator core is made of a resin material. The stator core is made of a resin material, The attachment portion is installed in the stator resin mold portion, the rotor has a metal boss, a magnet and a rotor core. The rotor is provided with a rotor serration portion which is engaged with the rotation shaft serration portion, the magnet is installed at a position corresponding to the winding, the rotor core corresponds to the magnet, and the rotor is a boss, the magnet and the rotor core are made of resin material. It is molded integrally, and the rotor serration portion is engaged with the rotation shaft serration portion and then attached to the rotation shaft. In addition, the motor unit is attached to the stator holding part after the stator before attaching to the stator holding part and the rotor are magnetized and the rotor before being attached to the rotating shaft serration part is combined by magnetic attraction. The motor unit is provided in the stator holding part, and the annular washer-side positioning part which has a concave or convex shape, and the annular stator side which is provided in the stator and has a convex or concave shape is provided. It further has a positioning part, the angle part which the cross section of the stator holding part side of the stator side positioning part, the circumferential surface fitted with respect to the washing machine side positioning part in the stator side positioning part, and the stator side of the washing machine side positioning part And a peripheral surface fitted to the stator side positioning portion in the washing machine side positioning portion Is a tapered surface or an arced surface on both sides or one side of each portion, and the difference between the maximum opening diameter of the concave positioning portion and the minimum tip diameter of the convex positioning portion is larger than the difference between the diameter of the stator and the diameter of the rotor. . According to this structure, the washing | cleaning machine which does not require skill of assembly of the motor unit attached to a washing machine, and is easy to workability is provided.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows the structure of the principal part of the washing machine which concerns on embodiment of this invention.

2 is a partial cross-sectional view of the washing machine shown in FIG.

3 is a partial cross-sectional view of the attachment portion of the motor unit used in the washing machine shown in FIG.

4A is a cross-sectional view of the motor unit used for the washing machine shown in FIG.

4B is a sectional view of a motor unit of another embodiment used in the washing machine shown in FIG. 1.

4C is a partially enlarged cross-sectional view of part A of the motor unit shown in FIG. 4A.

4D is a partially enlarged cross-sectional view of a motor unit of another embodiment used for the washing machine shown in FIG. 1.

5 is an exploded perspective view of the motor unit shown in FIG. 4A.

FIG. 6 is a rear perspective view of the rotor constituting the motor unit shown in FIG. 4A. FIG.

7A is an assembled view of the motor unit shown in FIG. 4A.

FIG. 7B is an assembly view of the motor unit shown in FIG. 4A.

7C is an assembly view of the motor unit shown in FIG. 4A.

FIG. 7D is an assembled view of the motor unit shown in FIG. 4A.

FIG. 7E is an assembled view of the motor unit shown in FIG. 4A.

FIG. 7F is an assembly view of the motor unit shown in FIG. 4A.

7G is an assembly view of the motor unit shown in FIG. 4A.

8A is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

8B is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

8C is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

8D is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

8E is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

8F is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

8G is an explanatory view of the behavior of the laundry of the washing machine shown in FIG. 1.

9 is a sectional view showing a conventional drum type washing machine in which an inner rotor type motor is used.

10 is a cross-sectional view showing a conventional drum type washing machine in which an outer rotor type motor is used.

11 is a rear view of a motor used in a conventional drum type washing machine.

[Description of the code]

1: washing machine body 2: tank

3: hole 4: rotating drum

4a: rotary shaft 4a1: rotary shaft serration

5: motor 5a: stator

5b: rotor 5b1: inner rotor

5b2: outer rotor 6: door

7: water supply unit 9: control board

11: drainage part 13: drying part

20: Stator Core 20a: Teeth

21: laundry 22: magnet

23 rotor core 24 bearing part

30 attachment mechanism 31 stator resin mold portion

32: Attachment part 33: Stator holding part

34, 40: bolt 37: rotor resin mold

37b1: rotor serration part 38: boss

41a, 41b: bearing 43, 43d: stator side positioning unit

43a, 44a: cross section 43b, 44b: circumferential surface

43c, 44c: parts 43e, 44e: end

44, 44d: Washing machine side positioning unit 50: Washing machine

54: winding 55: motor unit

63: circular path

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described, referring FIGS. 1-8G. In addition, the following description is an Example of this invention, and does not limit the content of this invention.

As shown in FIG. 1, the drum type washing machine 50 according to the present embodiment includes a water tank 2 and a rotary drum 4 (hereinafter, referred to as the main body 1). A drum 4) is provided. The water tank 2 is elastically supported by the main body 1 by suspension structure (not shown). The drum 4 is provided in the water tank 2, and many holes 3 are formed. In addition, the drum 4 is rotationally driven by the motor 5. The door 6 is provided in the front side of the main body 1 so that opening and closing is possible. When the door 6 is opened, laundry (not shown) is put in and taken out from inside the drum 4 through the front opening of the water tank 2 and the front opening of the drum 4.

Moreover, after opening the door 6 and putting laundry into the drum 4, detergent (not shown) is thrown in and the operation of the washing machine 50 is started. When operation of the washing machine 50 starts, water is supplied from the water supply unit 7 into the water tank 2. The water (not shown) supplied to the water tank 2 enters the drum 4 through the plurality of holes 3, and the required amount of water is supplied to the drum 4. When the drum 4 is driven to rotate at a predetermined rotational speed, for example, about 40 rpm, by the motor 5, the laundry contained in the drum 4 is stirred by the stirring projection 8 provided on the inner circumferential surface of the drum 4. ) Is caught and lifted in the direction of rotation. The laundry lifted in the rotational direction falls from a suitable height. As a result, a tapping action is applied to the laundry, and the laundry is washed. After this washing process, the dirty washing water is drained out of the main body 1 by the drain 11. After the dirty wash water is drained, the water is newly supplied to the water tank 2, and a rinsing stroke using the water supplied water is executed. After the rinsing stroke is completed, the drum 4 is rotated at a high speed, for example, about 1000 rpm. As a result, the dewatering stroke is executed. These washing strokes, rinsing strokes, and dehydration strokes are automatically executed based on a predetermined control procedure.

In addition, the washing machine 50 of this embodiment is a drum type laundry dryer equipped with the drying part 13. As shown in FIG. That is, the drying unit 13 sucks air in the water tank 2 and the drum 4 by the blower 12. Dehumidification by the dehumidification part 16 and heating by the heating part 17 are performed sequentially with respect to the air drawn in. Thereafter, the dehumidified and heated air becomes dry hot air and is further blown into the water tank 2 and into the drum 4. Thereby, a drying process is performed. In addition, a drying stroke may be performed automatically after a dehydration stroke. Thus, the washing machine 50 of this embodiment comprises the drum type laundry dryer.

In order to automatically execute the above-described steps, the motor 5 and the water supply unit 7 are controlled by a control device such as the control board 9 in accordance with the mode setting by the operation panel 14 or a control program. The drain 11 and the drier 13 are automatically controlled. In this way, the washing machine 50 has a function of automatically executing a washing stroke, a rinsing stroke, a dewatering stroke, and a drying stroke. In addition, a microcomputer is mounted on the control board 9.

In addition, the water supply part 7 supplies water at an appropriate time as indicated by the water supply path 61 by opening and closing the solenoid valve (not shown). Moreover, the washing machine 50 has the mechanism which the detergent of a detergent accommodating part (not shown) is thrown in the water tank 2 at a suitable time using water supply. When drainage is required at the end of the washing stroke, at the end of the rinsing stroke, or the like, the drainage portion 11 drains as indicated by the drainage path 62 by opening and closing the solenoid valve (not shown). The drying unit 13 has a circulation path 63 for circulating air in the water tank 2 and the drum 4 by the blower 12. In addition, the drying unit 13 includes a filter 15, a dehumidifying unit 16, and a heating unit 17. The filter 15 collects and vibrates dust and the like in the introduced air introduced from the water tank 2 and the drum 4. The dehumidifier 16 dehumidifies the air damped by the filter 15. The heating unit 17 heats the air dehumidified by the dehumidifying unit 16 to generate dry hot air. The blower 12 is arrange | positioned downstream of the circulation path 63 with respect to the heating part 17. FIG. As a result, the blower 12 is less likely to be affected by moisture, and the reliability thereof is increased. Moreover, the drying part 13 has the air conditioner 19 comprised by an evaporator and a condenser. The air conditioner 19 circulates the refrigerant through the dehumidifying unit 16 and the heating unit 17 by using the compressor 18, and performs heat exchange with the air circulated by the drying unit 13. In addition, the structure of the drying part 13 is not limited to this.

The drum 4 has a rotating shaft 4a (hereinafter referred to as a shaft 4a) attached to the rear surface of the drum 4. On the outer periphery of the tip of the shaft 4a, a rotation shaft serration section 4a1 (hereinafter referred to as serration section 4a1) is provided. The shaft 4a is supported by the bearing part 24 and is directly connected to the motor 5 attached to the back surface of the water tank 2. The shaft 4a is provided with the drum 4 and the water tank 2 so that the rotation axis direction is inclined from the horizontal direction to the angle θ = 20 ± 10 degrees from the opening side of the washing machine 50 to the bottom side. When the drum 4 is inclined and installed, the opening is obliquely upward even when the drum 4 is installed at the same height as compared with the case where the drum 4 is installed in a direction parallel to the horizontal direction. Thereby, the user of the washing machine 50 can easily put in and take out the laundry without taking an excessively bent posture. In particular, from the experiences of the present inventors, the inclination angle θ is 20 ± 10 degrees, so that even if there is a height difference from a child (except the infant) to an adult, or even a wheelchair user, the operation of putting in and taking out laundry is most The structure of the easy washing machine 50 can be obtained. In addition, the water supplied in the drum 4 is stored on the back side of the drum 4, so that a deep water storage state can be obtained even with a small amount of water. Thereby, the washing | cleaning stroke and the rinsing stroke by a small quantity of water can be performed. In the washing machine 50 shown in FIG. 1, the shaft 4a is directly connected to the motor 5 provided on the rear surface of the drum 4. As a result, the motor 5 directly transmits the rotational force to the drum 4. In addition, the structure of this shaft 4a and the motor 5 is not limited to the structure shown in FIG.

Moreover, the washing machine 50 comprises the drum type laundry dryer which has a drying function. However, other washing machines 50, such as a drum type washing machine 50 having no drying function, a drum type washing machine 50 in which the drum 4 is vertical, and no drum 4 may be used. Moreover, even if the motor 5 is attached to any part of the washing machine 50 according to the washing | cleaning method of the washing machine 50, or the difference of a drive system, etc., application of this invention is possible. Moreover, also about the drive shaft 4a which rotates the rotor 5b, the support structure of the shaft 4a, or the rotation transmission system with respect to the drive object, such as the drum 4, is also irrespective.

The motor 5 also has a stator 5a and a rotor 5b. Moreover, the stator 5a is attached to the stator holding part 33 (henceforth the holding part 33) by the some attachment mechanism 30 arrange | positioned in the circumferential direction of the stator 5a. The holding | maintenance part 33 is comprised from the sheet body with a stator made of metal fixed to the back surface of the water tank 2 by bolt fixing (not shown). The motor unit 55 is comprised by the motor 5 and the holding part 33. As shown in FIG. Moreover, the shaft 4a which transmits rotational force to the drum 4 is fastened to the rotor 5b. The rotor 5b rotates by the electromagnetic action by three-phase alternating current which acts between the stator 5a and the rotor 5b. Thereby, the drum 4 is rotationally driven, and each stroke, such as a washing stroke, a rinsing stroke, a dewatering stroke, and a drying stroke, is executed. In addition, the holding part 33 may be comprised with the resin molded article.

The stator 5a is connected to the stator core 20, the stator resin mold portion 31 (hereinafter referred to as the mold portion 31), the attachment portion 32, the rotation position detector 26, and the winding 54. Connector 27 is provided. The stator core 20 has a tooth 20a extending in the radial direction of the stator 5a. The stator core 20 is configured by winding the winding 54 around the tooth 20a. Moreover, the rotor 5b has the magnet 22 which opposes the tooth 20a, and the rotor core 23 corresponding to the magnet 22. As shown in FIG. Thereby, an electromagnetic action acts between the stator 5a and the rotor 5b, and the motor 5 rotates. The mold part 31 is molded so that the stator core 20 may be covered using resin material.

The attachment mechanism 30 is comprised by the fasteners, such as the some attachment part 32 and the bolt 34. The attachment part 32 is comprised with the several attachment leg provided so that it extended outward with respect to the outer periphery of the axial cross section of the side by which the mold part 31 is affixed to the holding part 33. As shown in FIG. Fasteners, such as the bolt 34, screw-tighten the attachment part 32 and the holding part 33. As shown in FIG. Moreover, the holding part 33 and the bearing part 24 are formed integrally. In the bearing portion 24, bearings 41a and 41b supporting the shaft 4a are press-fitted. In addition, one side of the holding part 33 is attached to the water tank 2, and the stator 5a is attached to the back side of the surface to which the water tank 2 was attached.

An attachment hole 32a is provided in each attachment portion 32, and a screw hole 33a is provided in the retention portion 33. The bolt 34 is passed through the attachment hole 32a from the opposite side of the holding portion 33, thereby being screwed into the screw hole 33a and fastened. Thereby, the attachment part 32 and the holding | maintenance part 33 are fastened. As a result, the stator 5a is firmly attached to the back surface of the water tank 2.

In addition, the rotor 5b has a boss 38, a magnet 22, and a rotor core 23 corresponding to the magnet 22. Moreover, the rotor 5b has the rotor resin mold part 37 (henceforth a mold part 37) molded with the resin material. The mold part 37 is molded so that the magnet 22 and the rotor core 23 may be covered using a resin material. The mold part 37 has the ceiling part 37a provided in the opposite side to the water tank 2. A metal boss 38 is formed by an insert in the center of the ceiling portion 37a. When the boss 38 is inserted, the attachment hole 37b is formed in the center of the ceiling portion 37a. The rotor serration part 37b1 (henceforth a serration part 37b1) is provided in the inner periphery of the attachment hole 37b. The attachment hole 37b and the shaft 4a are secured and fitted in the rotation stop state in the rotational direction so that both serration portions 37b1 and 4a1 are engaged with each other on the opposite side of the holding portion 33. In addition, the presser washer 39 is used for the rotor 5b and is fastened to the shaft 4a with the fasteners, such as the bolt 40, with respect to the boss 38. As shown in FIG. As a result, the rotor 5b is firmly attached to the shaft 4a.

In this way, when the motor 5 or the motor unit 55 is attached to the main body 1, the assembly is performed with good assembly. In addition, the washing machine 50 of the present embodiment and the motor unit 55 mounted on the washing machine 50 are particularly assembled in the order of the steps shown in FIGS. 7A to 7G. Hereinafter, the assembly method of the motor unit 55 mounted in the washing machine 50 and the washing machine 50 is demonstrated in detail using FIG. 7A to FIG. 7G.

First, as shown in FIG. 7A, in the first pretreatment step, the bearing 41a and the oil seal 42 are attached to the bearing portion 24 from the side of the surface on which the holding portion 33 is attached to the water tank 2. Is press-fitted.

Next, as shown in FIG. 7B, in the second pretreatment step, the bearing 41b is press-fitted into the bearing portion 24 from the opposite side to the surface on which the holding portion 33 is attached to the water tank 2. In addition, the shaft 4a is inserted into the bearing portion 24 from the side opposite to the side on which the bearing 41b is press-fitted. Thereby, the structure which supports the shaft 4a by the bearing part 24 is assembled. In addition, although not shown in FIG. 7B, the holding part 33 may be attached to the plane of the water tank 2. As shown in FIG.

In addition, in the first pretreatment step and the second pretreatment step, when the assembling work is performed with the bearing 41a or the side in which the bearing 41b is pushed into the bearing part 24 faces vertically upward, high efficiency assembling is performed. The work is done. Therefore, it is suitable that the up-and-down of the holding part 33 is inverted between the 1st pretreatment step and the 2nd pretreatment step. Further, after the second pretreatment step, the side on which the stator 5a is attached to the holding portion 33 faces vertically upward improves subsequent workability. For this reason, in a 1st preprocessing step, a press-in operation is performed in the state which the side to which the stator 5a is attached to the holding | maintenance part 33 faces vertically downward. Thereafter, the holding portion 33 is inverted by 180 degrees so that the side to which the stator 5a is attached to the holding portion 33 faces vertically upward. As a result, after the operation of the second pretreatment step, the need for reversal of the holding part 33 is eliminated.

Next, as shown in Fig. 7C, in the magnetization step which is the third pretreatment step, the magnet 22 constituting the rotor 5b is magnetized. In addition, in the magnetization step, the magnetization state of the rotor 5b is inspected. Also, not necessarily the magnetizing step. Magnetization of the rotor 5b may be performed at another opportunity, and the magnetized rotor 5b may be used in the steps described below. That is, the magnetization state should just be managed. In addition, the magnetization step is actually the final opportunity to manage the magnetization or the magnetization state of the rotor 5b. At this time, the rotor 5b is magnetized and the magnet 5 is not attached to the shaft 4a.

Next, as shown in Fig. 7D, in the first step, the rotor 5b and the stator 5a are combined by magnetic adsorption. In the rotor 5b used for assembly in the first step, the magnet 22 is magnetized and is not fixed to the shaft 4a. In addition, the stator 5a was not attached to the holding part 33. That is, the stator 5a is not attached to the main body 1.

Next, after the first step, as shown in Fig. 7E, in the second step, the rotor 5b combined with the stator 5a is inserted into the shaft 4a. The rotor 5b is inserted into the shaft 4a so that the serration portion 37b1 is engaged with the serration portion 4a1 of the shaft 4a supported by the holding portion 33 via the bearings 41a and 41b. Lose.

Next, after the second step, as shown in FIG. 7F, in the third step, the attachment part 32 is attached to the holding part 33 by fastening with the bolt 34. As a result, the motor 5 is attached to the water tank 2. That is, the motor unit 55 is attached to the back surface of the water tank 2.

Next, as shown in FIG. 7G, in the inspection step which is a post-processing step, an inspection regarding the electronic characteristics of the motor 5 and the motor unit 55 after assembly is completed is performed. Specifically, inspection such as displacement of the induced voltage into the effective value, sensor pulse width, pulse deviation during the motor 5 round, such as sensor shift time of the signal detected by the rotation position detecting unit 26, etc. Is done.

The second pretreatment step and the third pretreatment step are the final chances of checking whether the mold part 31 or the mold part 37 falls. In addition, the fitting operation of the rotor 5b and the shaft 4a in a 2nd step is accompanied with the positioning operation between both serration parts 37b1 and 4a1 as already demonstrated. In the third step, the attaching operation of the holding part 33 and the stator 5a using the bolt 34 involves managing the tightening torque of the bolt 34. The fastening operation of the rotor 5b and the shaft 4a using the bolt 40 may be immediately after the rotor 5b is fitted to the shaft 4a, and the stator 5a is attached to the holding part 33. You may be later.

According to such a method of assembling the motor unit 55 or the washing machine 50, a step in which the combination work of the stator 5a and the magnetized rotor 5b and the attachment work of the rotor 5b and the shaft 4a are different from each other. It is done independently. That is, the attachment work of the rotor 5b and the shaft 4a is a fitting work which involves positioning work of both the serration parts 37b1 and 4a1 which are rotation stop mechanisms. As a result, the combined operation of the stator 5a and the rotor 5b and the attachment operation of the rotor 5b and the shaft 4a do not interfere with each other. Therefore, the fitting operation of the stator 5a and the rotor 5b is performed in the free state in which the members which interfere with each other are not attached. In addition, in the first step, securing of a predetermined gap between both the stator 5a and the rotor 5b is not required. Therefore, the fitting operation of the stator 5a and the rotor 5b is a simple operation.

Moreover, the fitting operation for attaching the rotor 5b to the shaft 4a is also performed in a stable assembling state by magnetic adsorption inclined to one of the stator 5a and the rotor 5b. In addition, this fitting work is performed in the free state in which the member which obstructs a work is not attached. Therefore, the positioning operation of rotation stop mechanisms, such as the serration parts 37b1 and 4a1, is a simple operation. In addition, at the stage where the positioning operation of the rotation stop mechanism is completed, the attachment work of the rotor 5b and the shaft 4a using the bolt 40 may be completed. In addition, in the stage where the positioning operation of the rotation stop mechanism is completed, the attachment work of the rotor 5b and the shaft 4a using the bolt 40 may not be completed.

In addition, the stator 5a is attached to the holding part 33 alone. That is, the stator 5a is attached to the main body 1 alone. In the attachment operation to the holding part 33 of the stator 5a, a predetermined gap is secured between the stator 5a and the rotor 5b to be greater than the magnetic attraction force between the stator 5a and the rotor 5b. The attachment work is performed in a state. However, the predetermined gap between the stator 5a and the rotor 5b is determined from the unique positional relationship between the shaft 4a and the main body 1, that is, the shaft 4a and the holding portion 33. . Therefore, when the stator 5a is fixed to the holding part 33, it is pushed in by using mechanical force etc., and the stator 5a is positioned with respect to the predetermined position of the holding part 33. FIG.

As a result, the positioning operation of the stator 5a and the rotor 5b are both free of uninterrupted conditions from other members, and a predetermined gap is secured and executed as a simple operation. In addition, the fitting operation for attachment to the shaft 4a of the rotor 5b is also performed in the self-adsorbed state without fear of separation or rattling of the stator 5a and the rotor 5b, and from other members. It is done in an uninterrupted free state. For this reason, even if the alignment operation | work of serration parts 37b1 and 4a1 which are rotation stop mechanisms is accompanied, the fitting operation is a simple operation. As a result, the stator 5a is attached to the main body 1 side alone. The assembling work of the motor unit 55 involves a positioning work in which a predetermined gap is secured between the stator 5a and the rotor 5b. However, the positional relationship between the stator 5a and the rotor 5b is uniquely positioned at a predetermined position determined from the positional relationship between the shaft 4a and the main body 1.

As described above, the assembly of the motor unit 55 with the attachment to the main body 1 is performed by an inexperienced worker or in a short time with high precision and without individual differences. As a result, the assembly cost of the motor unit 55 and the washing machine 50 can be easily reduced.

Here, the assembling work of the motor unit 55 and the washing machine 50 that accompany the attachment to the main body 1 side fixing portion of the motor 5 to the motor unit 55 as described above is performed by the holding portion 33. ) Is treated alone. As the holding part 33 is performed as shown in FIGS. 7A to 7B in the state of the main body 1 side, specifically, before the attachment to the water tank 2, the necessary work is conveniently performed in each. However, the assembling method of the motor unit 55 and the washing machine 50 is not limited to this, and may be an assembling method involving the attachment of the holder 33 to the side of the main body 1 or to the equipped equipment. .

In addition, in this embodiment, as shown to FIG. 4A, the stator 5a is called the substantially annular stator side positioning part 43 (henceforth positioning part 43) which has a convex shape. ) Is installed. The holding | maintenance part 33 is provided with the substantially annular washing machine side positioning part 44 (henceforth called the positioning part 44) which has a concave shape. The positioning unit 43 and the positioning unit 44 are configured to fit with each other. As shown in Fig. 4B, the stator 5a may be provided with a substantially annular stator side positioning portion 43d (hereinafter referred to as positioning portion 43d) having a concave shape. . In addition, the holding part 33 may be provided with a substantially annular washing machine-side positioning part 44d (hereinafter referred to as positioning part 44d) having a convex shape. The positioning portion 43d and the positioning portion 44d are configured to fit with each other. That is, the stator 5a is provided with positioning parts 43 and 43d having a convex or concave shape, and the holding part 33 has positioning parts 44 and 44d having a concave or convex shape. Is installed. Moreover, the positioning parts 43 and 43d and the positioning parts 44 and 44d are comprised so that they may mutually fit. Further, the first engagement lengths X of the serration portions 4a1 and 37b1 of the shaft 4a and the rotor 5b are formed by the positioning portions 43 and 43d and the positioning portions 44 and 44d. It is preferable that it is longer than 2nd engagement length Y. That is, it is preferable to have a relationship of X> Y. In this way, when the serration portions 4a1 and 37b1 are engaged in the second step by the first engagement length X being longer than the second engagement length Y, the positioning unit 43 is engaged. , 43d) and the positioning portions 44 and 44d do not interfere.

By providing the positioning portions 43 and 43d and the positioning portions 44 and 44d, in the third step, as shown in the partial enlarged sectional view of FIG. 4C, the positioning portion 43 is the positioning portion 44. FIG. ) Is fitted. 4C is a partially enlarged sectional view of part A of the motor unit 55 shown in FIG. 4A. That is, in the second step, the rotor 5b is fitted to the shaft 4a by the positioning mechanism of the rotation stop mechanism such as the serration portions 37b1 and 4a1. In this fitting operation, from the beginning of the fitting with respect to the shaft 4a of the rotor 5b, the stator 5a and the rotor 5b, together with the rotor 5b, regulate the position in the rotation stop state based on the shaft 4a reference. Receive. Further, in the third step, the stator 5a is close to the holding part 33, that is, close to the attachment position is used, and the positioning part 43 is fitted to the positioning part 44. . For this reason, the stator 5a is mechanically positioned at the predetermined position determined from the unique positional relationship between the shaft 4a and the holding part 33. As a result, the stator 5a is automatically secured to the holding portion 33 with appropriate voids with respect to the rotor 5b positioned by the shaft 4a. For this reason, the positioning part 43 and the positioning part 44 should just be corrected as much as the inclination amount which both sides incline in the appropriate space | gap between the stator 5a and the rotor 5b, and a necessary correction amount Is very little. Specifically, the gap L between the stator 5a and the rotor 5b is about 0.65 mm. For this reason, the amount of inclination of the magnetic adsorption of the stator 5a and the rotor 5b from one side is no different from the appropriate dimension L of the air gap, and the degree of inclination of the stator 5a can be corrected. What is necessary is just to determine each dimension of an inner diameter and the outer diameter of the rotor 5b. In addition, the dimension 2L twice the gap L is the difference between the diameter of the stator 5a and the diameter of the rotor 5b.

Here, both the positioning part 43 and the positioning part 44 should just be an annular shape concentric with respect to the axis | shaft 4a. However, the positioning part 43 and the positioning part 44 may not be a full ring, but may be divided into equal numbers or divided into appropriate numbers. That is, when the positioning section 43 and the positioning section 44 are positioned, the effective effect of positioning can be obtained unless both of them are displaced in the axial perpendicular direction or a deformation causing the displacement occurs. Lose. As the motor unit 55 employing the above-described assembling method, the positioning unit 43 fitted with the positioning unit 44 provided in the holding unit 33 may be provided in the stator 5a.

In addition, as shown in FIG. 4C, the corner portion 43c, which is a tapered surface, is provided at the junction between the end face 43a and the circumferential surface 43b. The corner part 44c which is a tapered surface is provided in the junction part of the end surface 44a and the circumferential surface 44b. In addition, the cross section 43a is a cross section at the holding part 33 side of the positioning part 43, and the circumferential surface 43b is fitted with respect to the positioning part 44 in the positioning part 43. Circumference. Moreover, the end surface 44a is a cross section by the side of the stator 5a of the positioning part 44, and the circumferential surface 44b is the circumference which fits with respect to the positioning part 43 in the positioning part 44. Moreover, as shown in FIG. Cotton. That is, the circumferential surface 43b and the circumferential surface 44b are fitted. By this structure, the assembly of the motor unit 55 which is further characteristic as follows is possible.

In assembling the motor unit 55, the rotor 5b is positioned by the shaft 4a reference while the rotor 5b is fitted to the shaft 4a. Then, the stator 5a approaches the holding part 33, and the positioning part 43 is fitted to the positioning part 44. As shown in FIG. As a result, the stator 5a and the rotor 5b are positioned with a predetermined gap. Moreover, the edge part 43e is provided in the junction part of end surface 43a and each part 43c, and the edge part 44e is provided in the junction part of end surface 44a and each part 44c. The difference between the bore of the end 43e and the bore of the end 44e is larger than the difference between the diameter of the stator 5a and the diameter of the rotor 5b. That is, the diameter of the end portion 43e is the minimum tip diameter of the positioning portion 43 having a convex shape, and the diameter of the end 44e is the maximum opening of the positioning portion 44 having a concave shape. Diameter. As a result, the difference between the bore of the end 43e and the bore of the end 44e becomes larger than the amount of inclination caused by inclination in an appropriate gap between the stator 5a and the rotor 5b positioned on the shaft 4a. In short, the difference between the bore of the end 43e and the bore of the end 44e is the size including the inclination area of the stator 5a and the rotor 5b. Thereby, in the situation where it is not influenced by the inclination of the stator 5a and the rotor 5b, the positioning part 43 reliably enters into the positioning part 44, and it starts to fit. In addition, as the fitting progresses, the fitting positions of the corner portions 43c and the corner portions 44c gradually open to the outside, so that the positioning portion 43 is appropriate to the rotor 5b by the positioning portion 44. Guided to the proper position to secure the voids. After the fitting position where the tapered surfaces of the corner portions 43c and 44c end, the stator 5a is held by the holding portion 33 by fitting to the positioning portion 44 of the positioning portion 43. It is positioned at the proper position with respect to and attached to the holding part 33. Therefore, the stator 5a is pressed against the holding part 33 side larger than the magnetic attraction force between the stator 5a and the rotor 5b in accordance with the fitting of the rotor 4b to the shaft 4a. 55 is appropriately assembled. In addition, when the motor unit 55 is properly assembled, the circumferential surface 43c and the circumferential surface 44c are fitted.

In addition, as shown in Fig. 4B, when the positioning portion 43d has a concave shape, and the positioning portion 44d has a convex shape, the diameter of the end 43e is a concave shape. It becomes the largest opening diameter of the positioning part 43 which has, and the diameter of the edge part 44e becomes the minimum tip diameter of the positioning part 44 which has a convex shape. Moreover, even if it is the structure of the positioning parts 43d and 44d as shown in FIG. 4B, the effect and effect similar to the above are acquired.

4A to 4C are each provided with a corner portion 43c that is a tapered surface and a corner portion 44c that is a tapered surface. However, even if both of the corner portion 43c and the corner portion 44c are not necessarily provided, the above-described action and effect can be obtained by providing one of the corner portion 43c or the corner portion 44c. For example, although not shown, when only one side of the corner portion 43c is provided, the end portion 43e is formed at the junction between the end surface 43a and the corner portion 43c, and the end portion 44e is formed from the end surface 44a. It is formed in the junction of the circumferential surface 43b. On the contrary, when only one side of the corner part 44c is provided, the end part 43e is formed in the junction part of the end surface 43a and the circumferential surface 43b, and the end part 44e is formed of the end surface 44a and the corner part 43c. It is formed at the junction.

As shown in FIG. 4D, the arc portions 43c and the arc portions 44c of the arcuate face may be provided. Also in the case where the corner portion 43c and the corner portion 44c have an arcuate surface, an end portion 43e is provided at the junction between the end face 43a and the corner portion 43c in the same manner, and the junction portion between the end face 44a and the corner portion 44c is provided. The end 44e is provided in this. Moreover, although not shown in figure, the same effect and effect are acquired by providing one of each part 43c or each part 44c similarly. In addition, the corner portion 43c may be a tapered surface, and the corner portion 44c may be an arcuate surface. Conversely, the corner portion 43c may be an arcuate surface, and the corner portion 44c may be a tapered surface.

In addition, when the motor 5 which has the outer rotor 5b2 is employ | adopted for the rotor 5b on the outer periphery of the stator 5a, the outer rotor 5b2 is covered by the outer side of the stator 5a. Thereby, when the assembly operation of the motor unit 55 is performed, the space | gap between the stator 5a and the rotor 5b is interrupted | blocked by the outer rotor 5b2, and it is a state which is hard to confirm visually. Therefore, in assembling of the motor unit 55 having such an outer rotor 5b2, in the assembling method by visual confirmation as in the prior art, it is very difficult to secure an appropriate gap and to position the rotation stop mechanism at the same time. Do. However, according to the method of assembling the motor unit 55 according to the present invention as described above, an appropriate gap between the stator 5a and the rotor 5b is automatically secured.

Moreover, also when the motor 5 which has the inner rotor 5b1 in the inner periphery of the stator 5a, and the outer rotor 5b2 is employ | adopted on the outer periphery of the stator 5a, the outer rotor 5b2 is similarly It is covered on the outer side of the stator 5a. Thereby, when the assembly operation of the motor unit 55 is performed, the space | gap between the stator 5a and the rotor 5b is interrupted | blocked by the outer rotor 5b2, and it is a state which is hard to confirm visually. Therefore, also in the assembling of the motor unit 55 having the inner rotor 5b1 and the outer rotor 5b2, in the assembling method by visual confirmation as in the prior art, ensuring proper air gap and positioning of the rotation stop mechanism is difficult. It is very difficult to be done at the same time. However, according to the method for assembling the motor unit 55 according to the present invention as described above, an appropriate gap between the stator 5a and the rotor 5b is automatically secured.

In particular, in the motor 5 having the inner rotor 5b1 and the outer rotor 5b2 on both the inner and outer circumferences of the stator 5a, the winding 54 is circumferentially with respect to the stator core 20. By applying the toroidal winding to be wound, the circumferential length of the winding 54 is shortened. For this reason, miniaturization and high efficiency of the motor 5 are possible. When the number of poles of the motor 5 is 2P and the number of slots is S and N are natural numbers, a combination of P: S = 5N: 6N may be used. Thereby, the motor 5 of a distribution range is comprised and the noise reduction of the motor 5 is aimed at, and it is preferable.

In the washing machine 50 according to the present invention, the drum 4 is inclined from the horizontal direction. Thereby, compared with the washing machine in which the drum 4 was installed in the horizontal direction, the laundry tends to collect in a low position with respect to the rotation axis direction of the drum 4. In addition, the generation of entanglement and kinks in the laundry are greatly improved, and it is intended to make wrinkles less likely to occur while increasing the function of the mechanical force. That is, the washing machine 50 of this embodiment has the forward and reverse rotation drive mode and the forward and reverse continuous rotation drive mode regarding drive control of the drum 4 using the control board 9. In the forward and reverse rotation drive mode, rotations in which the rapid arc rotation and the rapid reverse rotation are alternately repeated under the condition that the rotation angle of the drum 4 exceeds 90 degrees and are less than 180 degrees. Drive mode. In addition, in the forward and reverse continuous rotation drive mode, the drum 4 is rotated at a rotational speed at which the laundry lifted by the rotation of the drum 4 realizes a behavior in which the weight of the laundry falls from a higher height. It is a rotation drive mode in which the continuous rotation of 4) is repeated alternately in forward and reverse. In addition, these two drive modes are combined and executed as needed.

8A to 8F show the drive mode of the drum 4 when the pseudo laundry 21 is housed in the drum 4. From the stopped state of the drum 4, as shown in FIG. 8A, as shown in FIG. 8B, the drum 4 rotates more than 90 degrees and less than 180 degrees. As a result, the laundry 21 is lifted to as much as 90 degrees and less than 180 degrees. In addition, since this arc-rotating drive is performed alternately in the reverse direction, in the vicinity of the last point to the last point where the laundry 21 is lifted up, the drum 4 has a deceleration or braking state for reversing the rotation. As a result, as shown in FIG. 8C, the laundry 21 is reliably instantaneously from the inner surface of the drum 4 due to the forced peeling force due to the rotational inertia applied to the laundry 21 and the weight of the laundry 21. It is detached. In addition, the operation | movement shown to FIG. 8F from FIG. 8C is performed repeatedly. That is, as shown in FIG. 8C to FIG. 8F, by the forward rotation drive of the drum 4, the position where the laundry 21 is lifted, and the fall position are alternately changed left and right in every rotation drive. do. By rotationally driving the drum 4 in such a drive mode, the loosening action of the laundry 21 is increased. In addition, the mechanical force is exerted on the laundry 21 and is effectively washed. 8G is a schematic diagram schematically showing the forward / reverse rotation drive mode in the case where the forward / reverse rotation of each 90 degrees is repeatedly performed.

In addition, in the forward and reverse rotation drive mode as shown in Figs. 8A to 8F, tangling, kinks, wrinkles, and the like of the laundry 21 are alleviated, and the position of the laundry 21 in the up and down direction is hard to be replaced, It is easy to cause washing dirt. Therefore, the positive / lower continuous rotation drive mode is used in combination, so that the positional change of the laundry 21 in the vertical direction is easily realized. That is, the entanglement, twisting, and wrinkles of the laundry 21 are alleviated by the forward and reverse rotation drive mode, and the imbalance of mechanical force imparting to the laundry 21 is alleviated by the forward and reverse continuous rotation drive mode. Thus, by using both modes of forward and backward rotation drive mode and forward and reverse continuous rotation drive mode together, two different behaviors arise in the laundry 21 in a washing stroke and a rinsing stroke. Specifically, the forward and reverse rotational drive mode reduces the entanglement, the kink, and the wrinkles of the laundry 21, and realizes the steady hand washing behavior. In addition, by the forward and reverse continuous rotation drive mode, the laundry 21 moves largely continuously and is washed while the stain is reduced, and a uniform sucking behavior is provided. In addition, in the forward / reverse rotation drive mode, since the operation in which the rapid forward rotation and the rapid reverse rotation are alternately performed is performed, the driving load applied to the motor 5 is large. However, the drive load applied to the motor 5 is reduced by using the forward / reverse continuous rotation drive mode in which the drive load applied to the motor 5 is comparatively smaller.

As described above, the arc rotation of the drum 4 is alternately repeated. Thereby, the operation | movement which lifts the laundry 21 to the upper left and right one side of the drum 4 is performed by the reverse rotation. In addition, the drum 4 is decelerated or braked at or near the end point at which the laundry 21 is lifted. As a result, the forced peeling force due to the inertia of the rotational motion and the gravity due to the weight of the laundry 21 act on the laundry 21 to reliably remove the laundry 21 from the inner surface of the drum 4 reliably. It falls to the left and right opposite sides of the drum 4. By repeatedly performing this operation, the position in which the laundry 21 is lifted and the dropping position are alternately changed left and right at each rotation, thereby increasing the loosening action of the laundry 21. This prevents entanglement and twisting of the laundry 21 and adhesion to the inner surface of the drum 4, thereby making it easier to take out the laundry 21 from the washing machine 50, and the occurrence of wrinkles on the laundry 21 is prevented. It is greatly eased. Moreover, the mechanical force exerts on the laundry 21, and the tapping sucking effect, the tapping rinsing effect, and the wrinkle spreading effect by the tapping action are applied to the laundry 21. The number of drops of the laundry 21 is also greatly increased. Thus, the function in each stroke of the washing machine 50 including the washing effect is effectively increased. For example, the laundry 21 is squeezed strongly on the inner surface of the drum 4 in the form of entanglement, kinks, and folds at the end of the washing and rinsing strokes, and the laundry 21 adheres strongly to the dehydration stroke. It may occur. However, by performing the forward and reverse rotational driving mode in the drying stroke, the left and right rotations of the position where the laundry 21 is lifted up and the dropping position are replaced. Moreover, by this operation | movement, the high loosening action and the action of a mechanical force which accompany the left-right rotation of the laundry 21 mutually act on the laundry 21. In addition, while the laundry 21 is smoothly released in this manner, the forward and backward continuous rotation drive mode is used in combination. Thereby, the up-and-down replacement | exchange of the laundry 21 is performed, the air permeability to each of the laundry 21 becomes high, and dry high temperature air reaches every corner of the laundry 21 inside. As a result, the laundry 21 is dried in a short time without staining. Moreover, the wrinkle spreading action by the tapping action at the time of the fall of the laundry 21 in the absence of water is accompanied, and the spreading of the fiber and the regeneration of the fiber by the unwinding of the twists of the respective laundry 21 are achieved. As a result, the finishing state of the laundry 21 after washing, rinsing, dehydration and drying is greatly improved.

In order to realize the forward and reverse rotational driving mode of the drum 4, the driving load on the motor 5 is very large. However, the inner rotor 5b1 and the outer rotor 5b2 are arranged on the inner and outer circumferences of the stator 5a as described above, and the motor 5 which is torqueed up is employed. Thereby, even the small motor 5, both the forward and reverse rotation drive mode which has the operation | movement of rapid reverse, and the forward and reverse rotation drive mode which have the rapid braking of the rapid forward rotation and rapid reverse rotation are easily implement | achieved. Accordingly, the ideal behavior of the laundry 21 as shown in Figs. 8A to 8G can be realized. In this way, the motor 5 can be easily rotated even under severe conditions. Moreover, the mechanical load applied to the motor 5 is reduced by performing a combination of the forward and reverse rotation drive mode and the forward and reverse continuous rotation drive mode alternately.

Applied to the assembly of a motor unit having a stator and a rotor with an attachment to a washing machine, the assemblability and the assembly accuracy are improved.

Claims (16)

With the washing machine body, A water tank elastically supported in the washing machine body; A plurality of holes are formed, the rotating drum disposed in the tank, A rotating shaft having one end attached to the rear surface of the rotating drum and having a rotating shaft serration provided at the other end thereof; A stator holding part which is attached to the rear surface of the water tank and has a bearing part in which a bearing supporting the rotating shaft is press-fitted; A stator resin part having a tooth extending in the radial direction, the winding of which is wound around the tooth, a stator resin mold part which molds the stator core on which the winding is wound by a resin material, and an attachment portion provided on the stator resin mold part Having a stator, The boss having a rotor serration formed on the rotating shaft serration portion, the magnet is provided at a position corresponding to the winding, and the rotor core corresponding to the magnet, wherein the boss, the magnet and the rotor core Integrally molded with a resin material, and having the rotor attached to the rotating shaft after the rotor serration portion is engaged with the rotating shaft serration portion, As a method of assembling a washing machine with a motor unit, A first step in which the stator before being attached to the stator holder and the magnet are magnetized and the rotor before being attached to the rotary shaft serration part is combined by magnetic attraction; After the first step, the rotor serration portion is engaged with the rotation shaft serration portion of the rotation shaft supported by the stator holding portion through the bearing; And a third step of attaching the attachment part to the stator holding part by fastening with a bolt after the second step. The method according to claim 1, The motor unit, An annular stator side positioning portion provided in the stator and having a convex or concave shape; It is provided in the said stator holding part, It has a concave or convex shape, and further has an annular washing machine side positioning part fitted with the said stator side positioning part, The method of assembling the washing machine, wherein in the third step, the stator side positioning portion is fitted to the washing machine side positioning portion. The method according to claim 1 or 2, The rotor is an assembly method of the washing machine provided on the outer periphery of the stator. The method according to claim 1 or 2, The rotor is an assembly method of the washing machine provided in both the inner circumference and the outer circumference of the stator. A stator holding part having one end attached to the rear surface of the rotating drum and having a bearing part in which a bearing supporting the rotating shaft provided with the rotating shaft serration part is press-fitted integrally; A stator resin part having a tooth extending in the radial direction, the winding of which is wound around the tooth, a stator resin mold part which molds the stator core on which the winding is wound by a resin material, and an attachment portion provided on the stator resin mold part Having a stator, The boss having a rotor serration formed on the rotating shaft serration portion, the magnet is provided at a position corresponding to the winding, and the rotor core corresponding to the magnet, wherein the boss, the magnet and the rotor core Integrally molded with a resin material and provided with a rotor attached to the rotation shaft after the rotor serration portion is engaged with the rotation shaft serration portion, As a method of assembling the motor unit, A first step in which the stator before being attached to the stator holder and the magnet are magnetized and the rotor before being attached to the rotary shaft serration part is combined by magnetic attraction; After the first step, the rotor serration portion is engaged with the rotation shaft serration portion of the rotation shaft supported by the stator holding portion through the bearing; And a third step of attaching the attachment part to the stator holding part by fastening with a bolt after the second step. The method according to claim 5, The motor unit, An annular stator side positioning portion provided in the stator and having a convex or concave shape; It is provided in the said stator holding part, It has a concave or convex shape, and further has an annular washing machine side positioning part fitted with the said stator side positioning part, In the third step, the stator side positioning unit is fitted to the washing machine side positioning unit. The method according to claim 5 or 6, The rotor is an assembly method of the motor unit provided on the outer periphery of the stator. The method according to claim 5 or 6, The rotor is an assembly method of the motor unit provided in both the inner circumference and the outer circumference of the stator. A stator holding part having one end attached to the rear surface of the rotating drum and having a bearing part in which a bearing supporting the rotating shaft provided with the rotating shaft serration part is press-fitted integrally; A stator resin part having a tooth extending in the radial direction, the winding of which is wound around the tooth, a stator resin mold part which molds the stator core on which the winding is wound by a resin material, and an attachment portion provided on the stator resin mold part Having a stator, The boss having a rotor serration formed on the rotating shaft serration portion, the magnet is provided at a position corresponding to the winding, and the rotor core corresponding to the magnet, wherein the boss, the magnet and the rotor core A rotor integrally molded with a resin material, the rotor serration portion engaged with the rotation shaft serration portion, and then attached to the rotation shaft, The stator is attached to the stator holding part after the stator before attaching to the stator holding part and the rotor are magnetized and the rotor before being attached to the rotary shaft serration part is combined by magnetic attraction. Has a configuration, An annular washer-side positioning unit provided in the stator holding unit and having a concave or convex shape; An annular stator side positioning portion provided on the stator and having a convex or concave shape and fitted to the washing machine side positioning portion, A corner portion formed by a cross section of the stator holding portion side of the stator side positioning portion, a circumferential surface fitted to the washing machine side positioning portion of the stator side positioning portion, Both or one side of each part which a cross section of the said stator side of the said washing machine side positioning part, and the circumferential surface fitted with respect to the said stator side positioning part in the said washing machine side positioning part make a tapered surface or an arc surface Formed into, And a difference between a maximum opening diameter of the concave positioning portion and a minimum tip diameter of the convex positioning portion is larger than a difference between the diameter of the stator and the diameter of the rotor.  The method according to claim 9, The rotor is a motor unit provided on the outer periphery of the stator. The method according to claim 9, The rotor is provided in both the inner circumference and the outer circumference of the stator. The method according to claim 10 or 11, The motor unit, wherein the attachment portion is provided outward in the radial direction from the rotor located on the outer periphery of the stator. With the washing machine body, A water tank elastically supported in the washing machine body; A plurality of holes are formed, the rotating drum disposed in the tank, A rotating shaft having one end attached to the rear surface of the rotating drum and having a rotating shaft serration provided at the other end thereof; A stator holding part which is attached to the rear surface of the water tank and has a bearing part in which a bearing supporting the rotating shaft is press-fitted; A stator resin part having a tooth extending in the radial direction, the winding of which is wound around the tooth, a stator resin mold part which molds the stator core on which the winding is wound by a resin material, and an attachment portion provided on the stator resin mold part Having a stator, The boss having a rotor serration formed on the rotating shaft serration portion, the magnet is provided at a position corresponding to the winding, and the rotor core corresponding to the magnet, wherein the boss, the magnet and the rotor core Integrally molded with a resin material, and having the rotor attached to the rotating shaft after the rotor serration portion is engaged with the rotating shaft serration portion, Equipped with a motor unit, The motor unit, The stator is attached to the stator holding part after the stator before attaching to the stator holding part and the rotor are magnetized and the rotor before being attached to the rotary shaft serration part is combined by magnetic attraction. Has a configuration, The motor unit, An annular washer-side positioning unit provided in the stator holding unit and having a concave or convex shape; It is provided in the said stator and has a convex or concave shape, and further has the annular stator side positioning part fitted to the said washing machine side positioning part, A corner portion formed by a cross section of the stator holding portion side of the stator side positioning portion, and a circumferential surface fitted to the washing machine side positioning portion of the stator side positioning portion; Both or one side of each part which a cross section of the said stator side of the said washing machine side positioning part, and the circumferential surface fitted with respect to the said stator side positioning part in the said washing machine side positioning part make a tapered surface or an arc surface Formed into, And a difference between a maximum opening diameter of the concave positioning portion and a minimum tip diameter of the convex positioning portion is larger than a difference between the diameter of the stator and the diameter of the rotor. The method according to claim 13, The rotor is installed on the outer periphery of the stator. The method according to claim 13, The rotor is provided in both the inner and outer circumference of the stator. The method according to claim 14 or 15, A washing machine, wherein said attachment portion is provided in a radially outer side than said rotor located on the outer periphery of said stator.

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