JP2008228424A5 - - Google Patents

Description

motor

  The present invention relates to a motor having a stator attached to a fixed portion and a rotor attached to a rotating shaft, which is preferably used in a washing machine or the like.

  The motor 55 having a stator and a rotor is employed in, for example, a drum type washing machine 50 as shown in FIGS. In the drum type washing machine 50, a rotating drum 54 having a large number of holes 53 is disposed in a water tank 52 elastically supported by a suspension structure in a washing machine body 51. The rotating drum 54 is driven by a motor 55. By opening the door 56 that is rotationally driven and is openable and closable on the front side of the washing machine main body 51, the laundry can be taken in and out of the rotary drum 54 through the front opening of the water tank 52 and the front opening of the rotary drum 54. It is configured as follows. Further, when the door 56 is opened, the laundry is put into the rotating drum 54, the detergent is put in, and the operation is started, the water is supplied from the water supply pipe 57 into the water tank 52, and the supplied water is discharged from the hole. A required amount of water is also supplied into the rotary drum 54 through 53. When the rotating drum 54 is driven to rotate at a predetermined rotational speed by the motor 55, the laundry stored in the rotating drum 54 is hooked on the stirring protrusion 58 provided on the inner peripheral surface of the rotating drum 54 and lifted in the rotating direction. When the laundry is dropped from an appropriate height, washing is performed by applying a washing action to the laundry. After this washing process, the dirty washing water is drained from the drain pipe 59, and the rinsing process is performed using newly supplied water. When the rinsing process is completed, the rotating drum 54 is rotated at a high speed to perform the dehydrating process. Is implemented. Each of these steps is automatically executed based on a predetermined control procedure.

  By the way, conventionally, a first motor capable of forward / reverse rotation for executing a washing process and an rinsing process at a first rotational speed by rotating the rotating drum forward / reversely and a dehydration process at a second rotational speed are rotated. A second motor that continuously rotates the drum in one direction at a second speed is attached to the rear surface of the water tank, and a drive system that transmits rotation to the rotating drum by a V-belt (see, for example, Patent Document 1) A motor attached to the back surface is connected to the rotating shaft of the rotating drum, and the motor system that directly transmits the rotation of the motor to the rotating shaft of the rotating drum (for example, see Patent Document 2). An inner rotor type motor in which a rotor is arranged along the inner peripheral surface (see, for example, Patent Document 3), or an outer rotor type motor in which a rotor is arranged along the outer peripheral surface of a stator (for example, As Patent reference 4), there is a system for rotatably driving the rotary drum.

  11 shows an example of a drum type washing machine 50 using a conventional inner rotor type motor 55, and FIGS. 12 and 13 show examples of the drum type washing machine 50 using a conventional outer rotor type motor 55. FIG. Is shown. In any case, the motor 55 has the stator 60 attached to the outer bottom surface that is the back surface of the water tank 52, and the rotor 61 is attached to the rotating shaft 62 of the rotating drum 54.

  A technique for attaching the stator 60 to the outer bottom surface of the water tank 52 is disclosed in, for example, Patent Document 3, and the stator 60 and the rotor 61 are molded as shown in FIG. Are attached by screws or bolts 64.

  However, the present invention is not limited to this. In order to use the motor 55 for driving the rotating drum 54 of the washing machine 50, the stator 60 is not limited to the water tank 52, and the stator 60 is provided at any fixed portion of the washing machine body 51. The attachment and the rotor 61 may be attached so as to be connected to various shafts for driving the rotary drum 54. In any case, in the motor 55 used in such a washing machine 50, as shown in FIGS. 11 and 12, the stator 60 is attached to a fixing part of the washing machine body 51 such as the back surface of the water tank 52, and the fixing part is used. The stator 60 and the rotor 61 are assembled by a method in which the rotor 61 is directly attached to the rotating shaft 62 of the projecting rotating drum 54.

In attaching and assembling the motor 55 to the washing machine 50, a gap between the stator 60 and the rotor 61 is ensured uniformly, and the rotor 61 and the rotary shaft 62 are prevented from rotating by means of serrations, keys, or the like. In the related art, the stator 60 is attached in advance to the washing machine body 51, and the magnetized rotor 61 is provided with a uniform gap between the stator 60 and the attached stator 60. While securing, the rotation preventing means between the rotor 61 and the rotating shaft 62 is aligned, and the rotor 61 is fitted to the rotating shaft 62.
Japanese Patent Laid-Open No. 10-263271 JP 2006-43105 A JP 2005-168116 A JP 2004-216166 A

  However, in the outer rotor type motor 55, the outer side of the stator is covered with a resin mold body of the outer rotor, and the gap between the stator and the outer rotor is difficult to see, and there is a gap between the rotor 61 and the stator 60 after magnetization. In the operation of aligning the stopper means between the rotor 61 and the rotating shaft 62 and fitting the stator 60 on the stator 60 while ensuring such a gap, it is significant to ensure the gap between the rotor 61 and the stator 60 uniformly. It is difficult and requires skilled workers to work carefully.

  When the rotor 61 is offset with respect to the stator 60, it is necessary to correct the position by overcoming the magnetic attractive force acting in the direction in which the rotor 61 is further offset with respect to the stator 60. This correction work is also very difficult, requiring power and skill. In addition, the work efficiency is poor and time is required, so the assembly cost is high and the assembly accuracy may be inferior. That is, in the conventional mounting and assembling methods, even if it is recognized from the appearance that the rotor 61 is fitted to the stator 60 at the correct position, the gap between the rotor 61 and the stator 60 is uniform with the desired accuracy. There was a problem that it could happen that it was not secured.

  An object of the present invention is to provide a motor capable of ensuring a uniform gap between a rotor and a stator with a desired accuracy when the motor is attached to a washing machine or the like and assembled.

To achieve the above object, a motor according to a first aspect of the present invention includes a substantially annular stator molded with a resin material, and a substantially circle molded with a resin material at a position along the outer peripheral surface of the stator. and an annular outer rotor, the end face of the resin molded body located at least in the axial direction of the outer rotor, the first gap inspection holes for checking the gap dimension between the said stator outer rotor is at least one set vignetting It is characterized by that.

According to such a motor according to claim 1, in the motor having the outer rotor along the outer peripheral surface of the stator, the resin mold body of the outer rotor covers the stator, and the gap dimension between the stator and the outer rotor is difficult to see. even, the first gap inspection hole for inspecting the gap dimension, since at least one set only on the end face of the resin molded body located at least in the axial direction of the outer rotor, the first gap inspection hole Thus, the gap dimension between the stator and the outer rotor can be inspected at at least one place. In addition, for the case where the gap dimension between the stator and the outer rotor is not ensured uniformly with the expected accuracy in the circumferential direction, the rotor positioning operation can be repeated while checking the gap dimension, so the time is also shortened, The gap dimension between the stator and the outer rotor can be ensured uniformly with the desired accuracy. As a method for inspecting the gap size through the first gap inspection hole, a method using a measuring tool such as a gap gauge, a method for automatically detecting the gap accuracy by image recognition, or the like can be used. .

Also, in mounting and assembling the motor, by performing the mounting and assembling work while inspecting the gap dimension through the first gap inspection hole, the uniform gap dimension with the expected accuracy at the end of the work. Can be ensured.

A motor according to a second aspect of the present invention is the motor according to the first aspect, further comprising a substantially annular inner rotor molded with a resin material at a position along the inner peripheral surface of the stator. the end surface of the resin mold body located at least in the axial direction, the second gap inspection holes for checking the gap dimension between the said stator inner rotor is characterized in that it kicked least one set .

According to such a motor according to claim 2, in the motor having the inner rotor along the inner peripheral surface of the stator, the resin mold body of the inner rotor covers the stator, and the gap dimension between the stator and the inner rotor is difficult to see. even, the second gap inspection hole for inspecting the gap dimension, since at least one set only on the end face of the resin molded body located at least in the axial direction of the inner rotor through the gap inspection hole The gap dimension between the stator and the inner rotor can be inspected at at least one place. In addition, for the case where the gap between the stator and the inner rotor is not ensured uniformly with the desired accuracy in the circumferential direction, the rotor positioning operation can be repeated while checking the gap dimension, so the time is shortened, The gap dimension between the stator and the inner rotor can be ensured uniformly.

Also, in mounting and assembling the motor, by performing the mounting and assembling work while inspecting the gap dimension through the second gap inspection hole, the uniform gap size with the expected accuracy at the end of the work. Can be ensured.

A motor according to a third aspect of the present invention is the motor according to the first or second aspect, wherein an opening window for heat dissipation is provided on an end surface of the resin molded body positioned at least in the axial direction of the outer rotor, The first gap inspection hole for inspecting the gap dimension between the stator and the outer rotor is formed by widening the opening window in the radial direction.

According to the motor of the third aspect, the opening window for heat dissipation is provided on the end surface of the resin mold body positioned at least in the axial direction of the outer rotor, and the opening window is widened in the radial direction, so that the stator and the outer rotor Since the first gap inspection hole for inspecting the gap dimension between the first and second gaps is formed, an opening window widened in the radial direction in advance can be used, and a new first gap inspection hole is provided. This is not necessary, and the manufacturing cost can be reduced. In addition, the size of the opening window is usually increased to such an extent that the air can be replaced. Therefore, the gap state can be confirmed by visual inspection, and abnormal conditions such as when the rotor is extremely offset from the stator are easy. Can be determined.

According to the present invention, the first gap inspection holes for checking the gap size between the stator and the rotor, at least one set takes simple structure of the end face of the resin molded body located at least in the axial direction of the rotor In addition, a motor in which the gap between the stator and the inner rotor is ensured uniformly can be obtained. Also, in mounting and assembling the motor, by performing the mounting and assembling work while inspecting the gap dimension through the first gap inspection hole, the uniform gap dimension with the expected accuracy at the end of the work. Can be secured.

DESCRIPTION OF THE PREFERRED EMBODIMENTS The best mode for carrying out the motor of the present invention will be described below with reference to the drawings. It should be understood that the embodiments disclosed below are illustrative in all respects and are not restrictive. The technical scope of the present invention is shown not by the content disclosed in the embodiment but by the description of the scope of claims, and further includes all modifications within the meaning and scope equivalent to the scope of claims. Should be understood.

  First, the structure and operation of the drum type washing machine 1 including the motor 5 according to the embodiment of the present invention will be described in detail with reference to FIGS. FIG. 1 is a cross-sectional view showing a main configuration of a drum type washing machine to which a motor according to an embodiment of the present invention is applied, and FIG. 2 is a rear view of the inside of the drum type washing machine.

  The drum type washing machine 1 according to the present embodiment has the basic configuration described above, and has a large number of through holes 4c in a water tank 3 elastically supported by a suspension structure in a washing machine casing 2 as shown in FIG. A rotating drum 4 formed with is provided. The rotating drum 4 is driven to rotate by a motor 5, and the laundry is passed through the front opening of the water tub 3 and the front opening of the rotating drum 4 by opening a door 6 that can be opened and closed on the front side of the washing machine casing 2. The rotary drum 4 can be taken in and out. Further, when the door 6 is opened and the laundry is put into the rotating drum 4 and the operation is started with the addition of the detergent, the water is supplied from the water supply pipe 7 into the water tank 3, and the supplied water is perforated. A required amount of water is also supplied into the rotary drum 4 through 4c. When the rotary drum 4 is driven to rotate at a rotational speed of about 40 rpm, for example, by the motor 5, the laundry stored in the rotary drum 4 is hooked on the stirring protrusion 4d provided on the inner peripheral surface of the rotary drum 4 and rotated. When the laundry is lifted in the direction and dropped from an appropriate height, the laundry is washed by applying the action of tapping. After this washing step, the dirty washing water is drained through the drain pipe 8, and a rinsing step is performed using newly supplied water. When the rinsing process is completed, the spin drum 4 is rotated at a high speed of, for example, about 1000 rpm, and the dehydration process is performed. Each of these steps is automatically executed based on a predetermined control procedure. In the drum type washing machine 1 of the present embodiment, the air in the water tank 3 and the rotating drum 4 is sucked by the blower 14 to perform dehumidification and heating in order, and the water tank 3 and the rotating drum 4 as dry high-temperature air. The drum type washing machine is called a drum type washing and drying machine equipped with a circulation air passage 9 that repeatedly blows air inside, and the drying step is also automatically executed after the dehydration step.

  In order to automatically execute these steps, the motor 5, the water supply line 7, the drainage are performed by the control unit 18 including a control board equipped with a microcomputer in accordance with the mode setting and control program from the operation panel 19. It has a function of automatically controlling the conduit 8 and the circulation air passage 9 to perform a cleaning process, a rinsing process, and a drying process.

  The water supply pipe 7 can supply water in a timely manner as indicated by a solid arrow by opening and closing the electromagnetic valve, and can use the water supply to introduce a detergent in a detergent container (not shown) into the water tank 3 in a timely manner. It is configured. The drainage pipe 8 is configured to allow drainage as indicated by a dashed line arrow when necessary, such as at the end of the washing process or at the end of the rinsing process, by opening and closing the electromagnetic valve.

  The circulation air passage 9 is a circulation passage that circulates the air in the water tank 3 and the rotating drum 4 by the blower 14 as shown by the broken line arrows in FIGS. 1 and 2, and is in the introduced air from the water tank 3 and the rotating drum 4. A filter 17 that collects and removes lint, etc., an evaporator 12 that dehumidifies the introduced air after the dust removal, a condenser 13 that heats the air after the dehumidification to dry the air, It arrange | positions in the downstream of the condenser 13, and makes it difficult to receive the influence of moisture. In the illustrated example, the evaporator 12 and the condenser 13 circulate the refrigerant by the compressor 15 to exchange heat with the circulating air, and constitute the air conditioner 16. However, the heat drying means is not limited to these.

  The rotating drum 4 is directly connected to a rotating shaft 20 with a motor 5 attached to the back surface 3a of the water tank 3, and together with the water tank 3, the rotating shaft direction from the opening side to the bottom side is an angle θ = 20 ± 10 from the horizontal direction. Compared to the case where the rotating drum 4 is installed at the same height as the horizontal drum, the opening is obliquely upward, so that it does not take an unreasonable posture to bend. Laundry can be easily taken in and out. In particular, from the experience of the present inventors, by setting the inclination angle θ to 20 ± 10 °, even if there is a height difference from a child (excluding an infant) to an adult, even a wheelchair user, washing It is possible to obtain a state in which the work of taking in and out the object is most easily performed. Further, there is an advantage that the water supplied into the rotary drum 4 is accumulated on the back side, and a deep water storage state can be obtained even with a small amount of water. In the example shown in FIG. 1, the rotating shaft 20 is directly connected to the back surface of the rotating drum 4 so as to transmit the rotation of the motor 5, but is not limited thereto.

  The washing machine to which the motor 5 of the present invention is applied includes other washing machines such as a drum washing machine without a drying function, a drum washing machine in which a rotating drum is vertically supported, and a washing machine without a rotating drum. It may be. Further, the motor 5 can be applied to any part of the washing machine in any type depending on the washing method or the driving method of the washing machine, and the drive shaft on which the rotor 25 of the motor 5 rotates. However, the support structure of the rotating shaft 20 and the rotation transmission method to the driving target such as the rotating drum 4 are not particularly limited.

  Next, the attachment structure of the motor according to this embodiment to the drum type washing machine 1 will be described in detail with reference to FIGS. FIG. 3 is a cross-sectional view showing a substantially half part of a motor attachment part to the drum-type washing machine according to the embodiment of the present invention, and is a cross-sectional view showing a state where the motor of FIG. . 5 is an exploded perspective view of the stator and rotor of the motor, FIG. 6 is a plan sectional view of the stator and rotor, FIG. 7 is a plan view of the rotor, and FIG. It is a rear view of a rotor.

  Here, as shown in FIGS. 3 and 4, the motor 5 of the present embodiment is fixed to the back surface 3a of the water tank 3 (specifically, the stator mounting seat 33 fixed to the back surface). A stator 21 attached by a plurality of attachment means 30 arranged in the circumferential direction with respect to the stator attachment seat 33, a rotor 25 connected to the rotary shaft 20 and rotatably supported on the back surface 3a of the water tank 3. have.

  As shown in FIG. 6, the stator 21 includes a stator core 23 including an inner teeth 23 a extending in the radial direction, an outer teeth 23 b, and a substantially annular yoke 23 c that connects the teeth 23 a and 23 b. The winding 24 is wound around the yoke 23c and the whole is molded with a resin material, whereby the resin mold body 22 is formed. FIG. 6 shows a case where a toroidal winding method in which the winding 24 is wound in the radial direction around the yoke 23c is employed.

  As shown in FIGS. 3, 4, and 6, the rotor 25 includes an inner rotor 25 a provided along the inner peripheral surface of the stator 21 (the inner peripheral surface 22 b of the resin mold body 22), and the outer peripheral surface of the stator 21 ( And an outer rotor 25b provided along the outer peripheral surface 22c) of the resin mold body 22. The inner rotor 25a has an inner magnet 27a facing the inner teeth 23a and an inner core 28a corresponding thereto, and the outer rotor 25b has an outer magnet 27b facing the outer teeth 23b and an outer core 28b corresponding thereto. However, the resin mold body 26 is formed by being molded entirely with a resin material.

In the resin molded body 22 for molding the stator 21 has a substantially annular shape, the end face 22a on the opposite side of rotary drum 4 is located in the axial direction, the recess 22 d extending radially a plurality By providing this, a concavo-convex shape is formed. Further, in the resin mold body 26 for molding the rotor 25, the outer edge portion supports the outer rotor 25b, the center portion is fixed to the rotating shaft 20, and the space between the outer edge portion and the center portion is outward on the center portion side. A plurality of convex portions 26b extending in the radial direction are provided on the inner surface of the canopy portion 26a facing the stator 21, and formed in a circumferential direction of the canopy portion 26a. A plurality of opening windows 26c are provided along the same. In the resin mold body 26, the canopy 26a is also an end face that covers the stator 21 and the rotor 25 and is positioned in the axial direction of the inner rotor 25a and the outer rotor 25b.

In the resin mold body 26, as shown in FIGS. 7 and 8, some of the plurality of opening windows 26c provided in the canopy portion 26a are widened in the radial direction, and these widened portions are widened. The opening window 26c functions as a first gap inspection hole 26d for inspecting a gap between the stator 21 and the outer rotor 25b. Further, in the resin mold body 26, a second gap inspection hole 26e for inspecting a gap between the stator 21 and the inner rotor 25a is provided in an end surface portion facing the inner rotor 25a and positioned in the axial direction. The first gap inspection hole 26d and the second gap inspection hole 26e are in positions extending in the axial direction with respect to the gaps formed between the stator 21 and the inner rotor 25a and between the stator 21 and the outer rotor 25b, respectively. Is formed.

With the above configuration, the electromagnetic force generated between one stator 21 and the inner rotor 25a and outer rotor 25b disposed along the inner and outer peripheral surfaces 22b and 22c is distributed winding type motor. Therefore, the rotor is rotated with respect to the stator without generating large noise and vibration. The rotational torque of the motor 5 is increased by disposing the inner rotor 25a by utilizing the dead space between the bearing portion 31 of the rotating shaft 20 formed on the inner peripheral surface 22b side of the stator 21, and thereby Even when the load is high, the rotary drum 4 can be driven to rotate via the rotary shaft 20 in a stable state.

The motor 5 of the present embodiment has an outer rotor 25b as the rotor 25 along at least the outer peripheral surface 22c of the stator 21, and the stator 21 is on the opposite side to the mounting direction to the stator mounting seat 33. Is covered with the rotor 25 from the end surface 22a and the outer peripheral surface 22c located at the center, and heat is likely to flow into the gap between the stator 21 and the rotor 25, but heat dissipation from the end surface 22a of the resin mold body 22 having an uneven shape. Due to the improvement, the heat generation of the motor 5 can be effectively suppressed. Further, the uneven shape and the convex portion 26b formed on the end face 22a disturb the flow almost perpendicularly to the air flow accompanying the rotor 25, and the air can be renewed by the opening window 26c. It is possible to further effectively suppress the heat generation of the rotary drum 21 and to rotate the rotary drum 4 with high rotational torque.

  In the present embodiment, the metal stator mounting seat 33 is fixed to the back surface 3a of the water tank 3 by bolting or the like, and the rotating shaft 20 of the rotating drum 4 is connected to the stator mounting seat 33. The shaft is rotatably supported by a bearing portion 31 formed so as to penetrate the central portion. A plurality of attachment means 30 for attaching the stator 21 to the stator attachment seat body 33 includes, as shown in FIGS. 4 and 5, attachment feet 32 formed outwardly extending on the outer peripheral surface 22c of the resin mold body 22. The mounting foot 32 is composed of fasteners such as a bolt 34 for screwing the mounting foot 32 to the stator mounting seat 33. An attachment hole 32a is formed in the attachment foot 32. As shown in FIG. 4, a screw hole 33a of the stator attachment seat 33 is passed through the attachment hole 32a from the opposite side of the water tank 3 with a bolt 34. The stator 21 is firmly attached to the back surface 3a (stator attachment seat 33) of the water tank 3 by screwing together.

Further, as shown in FIGS. 4 to 5 and 8, the rotor 25 has a central portion of a canopy portion 26 a that covers an end surface 22 a that is positioned in the axial direction opposite to the water tank 3 of the stator 21 in the resin mold body 26. Further, a mounting hole 26f formed by inserting a metal boss 36 is formed. The mounting hole 26f is provided at the rear end portion of the rotary shaft 20 supported by the bearing portion 31 with serration portions 26g and 20a of both the canopy portion 26a and the rotary shaft 20, or a detent means comprising a key and a key groove. After the engagement and fitting, the presser washer 37 is applied and fastened to the rotary shaft 20 with fasteners such as bolts 38 so that the rotor 25 is securely attached to the rotary shaft 20. In addition, the procedure of the assembly accompanying attachment to the washing machine housing | casing 2 of the motor 5 can be selected variously. Also, various methods can be employed for the rotation preventing means and the positioning means for the gap between the stator 21 and the rotor 25.

As described above, in the present embodiment, among the plurality of opening windows 26c provided in the canopy portion 26a of the resin mold body 26, the first gap inspection hole 26d widened in the radial direction is interposed. The gap dimension between the stator 21 and the outer rotor 25b can be inspected in at least one place by inserting a gap measuring tool such as a gap cage inwardly. Further, similarly, by inserting a gap measuring tool such as a gap cage inwardly through the second gap inspection hole 26e provided in the canopy 26a, the gap dimension between the stator 21 and the inner rotor 25a. Can be inspected in at least one place. As a result, for the case where the gap dimension between the stator 21 and the outer rotor 25b or the inner rotor 25a is not uniformly ensured in the circumferential direction with the desired accuracy, the mounting and assembling operations of the motor 5 are repeated, and the stator 21 and the outer rotor 25b or the inner rotor 25a can be uniformly secured. Further, in the mounting and assembling operations of the motor, by performing the mounting and assembling operations while inspecting the gap dimensions through the first gap inspection hole 26d and the second gap inspection hole 26e, the operation is completed. It is assumed that a uniform gap dimension is ensured with the desired accuracy.

The first gap inspection hole 26d may be provided separately from the opening window 26c without using the opening window 26c. However, the first gap inspection hole 26d expands the opening window 26c in the radial direction. If formed, it is not necessary to newly provide the first gap inspection hole by using the opening window 26c widened in the radial direction in advance, and the manufacturing cost can be reduced. In general, the opening window 26c is enlarged to such an extent that the air can be exchanged. Therefore, the state of the gap can be visually confirmed, and abnormalities such as when the rotor 25 is extremely offset from the stator 21 are observed. The state can be easily determined. In addition, the number of the first gap inspection holes 26d and the second gap inspection holes 26e may be one or more. If the number is large, the gap dimension is inspected with higher accuracy. Although it can be ensured uniformly, the time required for the inspection becomes longer, and the manufacturing cost also increases. In order to ensure the initial accuracy, the first gap inspection hole 26d and the second gap inspection hole 26e may be provided only once in each of the first gap inspection hole 26d and the second gap inspection hole 26e. When both are provided at one place, in order to reduce the radial moment that causes unbalance of the rotor 25, it is preferable to provide them on the opposite side with the central portion of the resin mold body 26 therebetween. In order to prevent the rotor 25 from being unbalanced, it is desirable that the first gap inspection hole 26d and the second gap inspection hole 26e are provided at two or more locations so as to be equally spaced in the circumferential direction.

  As the gap measuring tool used for the gap inspection, a measuring tool such as a gap gauge or a measuring instrument that automatically detects the accuracy of the gap by image recognition is preferably used. A measuring tool such as a metal gap cage is made of a paramagnetic material such as copper or stainless steel, and is preferably made of a material having high strength.

Next, an assembly method for attaching the motor 5 according to the embodiment to the washing machine body will be described in detail with reference to FIG. FIG. 9 is an assembly process diagram when the motor according to the embodiment of the present invention is attached to the washing machine body.

In order to perform assembly with attachment of the motor 5 to the washing machine main body with high work efficiency, the present embodiment particularly adopts the steps (a) to (g) as shown in FIG. . Basically, a first step in which the rotor 25 magnetized with the magnets 27 (magnets 27 a , 27 b) shown in (c) is combined with the stator 21 as shown in (d), After this first step, as shown in (e), the rotor 25 fitted to the stator 21 is attached to the rotary shaft 20, and as shown in (f), the second positioning and fitting is finally performed. After the step and the second step, as shown in (g), the motor 5 in which the stator 21 and the rotor 25 are fitted and the rotary shaft 20 is attached is attached to the back surface 3a of the water tub 3 of the washing machine body. It consists of the 3rd process attached to the stator attachment seat 33 fixed. This assembling method is an example, and may be appropriately changed depending on the structure of the motor 5 and the like.

For this purpose, as shown in (a), a pre-process for press-fitting the bearing 39 and the oil seal 40 into the bearing portion 31 of the stator mounting seat 33, and as shown in (b), the stator mounting seat 33. A pre-process for press-fitting the bearing 41 into the bearing portion 31, loading the rotary shaft 20 from the opposite side, and bearing the rotary shaft 20 is necessary. In these operations, since it is convenient for the operation that the surface to be press-fitted into the bearing portion 31 faces upward, the stator mounting seat 33 is between the press-fitting operation (a) and the press-fitting operation (b). Is preferably turned upside down, and after the operation of (b), the surface on the side where the motor 5 is attached to the stator mounting seat 33 should be directed upward, so in (a) the attachment of the motor 5 is preferred. The press-fitting operation is performed with the surface facing downward, and when moving to (b) thereafter, it is reversed so that the mounting surface of the motor 5 faces upward, and thereafter it is not necessary to reverse.

In addition to the above work, the magnet 27 is magnetized and the magnetization management is performed in (c), and the resin mold bodies 22 and 26 of the stator 21 and the rotor 25 are peeled off in (c) and (d). Check. Further, when the rotor 25 and the rotary shaft 20 are fitted together in (e), the alignment work between both the serration portions 26g and 20a is performed, and when the rotary shaft 20 is attached to the rotor 25 in (f), the fitting is performed. The assembled assembly of the stator 21 and the rotor 25 after the inspection is inspected for the gap dimension between the stator 21 and the rotor 25, and the tightening torque of the bolt 38 that fixes the rotor 25 to the rotating shaft 20 is managed. The work of fastening and fixing the rotor 25 to the rotary shaft 20 with the bolts 38 may be performed after the rotor 25 is fitted to the rotary shaft 20 or after the stator 21 is attached to the stator mounting seat 33 in (g). In (g), the motor 5 after assembly is inspected for electromagnetic characteristics. Specifically, the inspection items related to the electromagnetic characteristics include replacement of the induced voltage with the effective value, sensor pulse width, sensor deviation time of the signal detected by the rotation position detecting means 29 (see FIG. 5) with respect to the rotor 25, that is, For example, variations in pulses during one rotation of the rotor 25.

According to such an assembling method, serration portions 26g and 20a, which are means for engaging the rotor 25 that has been magnetized with the stator 21 (the first step described above), and a means for preventing rotation between the rotor 25 and the rotary shaft 20, are provided. Since the work of fitting the rotor 25 to the rotary shaft 20 (the second process described above) can be carried out independently in separate processes while aligning both, the work is distracted by the work of each other. It won't be difficult. Therefore, the mating operation of the stator 21 and the rotor 25 can be performed in a relatively easy state where no other members are attached to each other, and the rotor 25 is mated with the stator 21 in the first step. Then, it is not always necessary to ensure a uniform gap between the stator 21 and the rotor 25 in the circumferential direction. When the rotor 25 is fixed to the rotary shaft 20 with the bolt 38 in the second step, the rotor 25 The fitting position can be adjusted by forcibly applying a force from the outside.

  Further, an engaging means for improving positioning accuracy when fitting the rotor 25 to the stator 21, that is, for ensuring a uniform gap between the stator 21 and the rotor 25, is provided on the stator 21 and / or rotor 25 side. If it is provided, the operation | work which fits the rotor 25 to the stator 21 at a 1st process can be performed more easily.

Therefore, as a timing for inspecting the gap dimension between the stator 21 and the rotor 25 with respect to the assembled assembly of the stator 21 and the rotor 25 after the fitting, the rotor 25 is attached to the rotating shaft 20 and the bolt 38 in the second step. If an assembly is detected in which the gap dimension is not ensured uniformly with the desired accuracy, the fitting position of the rotor 25 is forcibly set at that time. The fitting of the rotor 25 can be adjusted by applying a force from the outside. In addition, since the position adjustment operation of the rotor 25 can be performed while checking the gap size, the time can be shortened, and the motor 5 in which the gap size between the stator 21 and the rotor 25 is ensured uniformly can be obtained. The timing for inspecting the gap dimension may be after the rotor 25 is fitted to the stator 21 in the first step.

  However, in the second step, the rotor 25 is fitted to the rotary shaft 20 while aligning both the serration portions 26g and 20a, which are means for preventing the rotation of the rotor 25 and the rotary shaft 20, so that the stator 21 and the rotor 25 are fitted. Is regulated by the rotary shaft 20 (including the anti-rotation means) and the stator mounting seat 33, and the fitting state is corrected at a more accurate position. Further, the inspection of the gap dimension reveals that the gap dimension between the stator 21 and the rotor 25 is not ensured uniformly, and even if the fitting position needs to be corrected, the stator mounting seat Using the mounting holes 33 and other members, the fitting position can be finely adjusted relatively easily, and the gap size can be uniformly ensured with higher accuracy.

  Next, the rotational drive mode when the motor 5 of the present embodiment is applied to a drum-type washing / drying machine and the behavior of the laundry at that time will be described with reference to FIG. FIG. 10 is a schematic diagram for explaining (a) the driving procedure and (b) the behavior of the laundry at that time in the forward / reverse continuous rotation driving mode in the drum type washing machine according to the embodiment of the present invention.

  By the way, in the drum type washing machine 1 which concerns on this Embodiment, when installing in the horizontal direction from the relationship which inclines the rotational-axis direction of the rotating drum 4 to the angle (theta) = 20 ± 10 degrees from a horizontal direction. Compared to the above, the laundry 70 tends to gather at a low position in the rotation axis direction. The drum type washing machine 1 of the present embodiment has an inner rotor 25a and an outer rotor 25b, and relates to drive control by the control unit 18 for the rotating drum 4 by utilizing the characteristics of the motor 5 with enhanced rotational torque. A forward / reverse arc rotation drive mode in which sudden forward arc rotation and sudden reverse arc rotation of 90 ° to less than 180 ° are alternately repeated at a rotational speed of about 40 rpm to 60 rpm is lifted by normal rotation of the rotating drum 4. The laundry 70 can be used in combination with the forward / reverse continuous rotation drive mode in which the continuous rotation of the rotating drum 4 is repeated forward and backward alternately at a rotational speed at which the laundry 70 falls from the height at which its own weight wins. As will be described later in detail, the forward / reverse arc rotation drive mode greatly reduces the occurrence of entanglement and twisting of the laundry 70 by utilizing the tendency of the laundry 70 to easily gather at a low position, and enhances the function of mechanical force. However, this drive mode is intended to make it difficult for wrinkles to occur. Both of these drive modes can be executed at any stage of the washing, rinsing and drying steps as required.

First, the case where the forward / reverse arc rotation drive mode is executed in the washing and rinsing process will be described. The washing and rinsing process in the forward / reverse arc rotation drive mode is particularly severe and requires a large driving load. However, with the motor 5 of the present embodiment, the rotary drum 4 is driven to rotate stably with sufficient torque. The arc rotation drive of more than 90 ° and less than 180 ° allows the laundry 70 to be moved up to 90 ° from the broken line position illustrated by the circled symbols 2, 4, and 6 in FIG. It can be lifted up to less than 180 °. Further, by performing this arc rotation drive in the order of the circled symbols 2, 4, 6, 4, 6,... Shown in FIG. 10 (a), the circled symbol 3 shown in FIG. As shown in FIG. 5, a decelerating state or a braking state for reversal occurs at or near the final point of lifting of the laundry 70, and the forced peeling force due to the rotational inertia applied to the laundry 70 and the laundry 70. The laundry 70 can be reliably and instantaneously peeled off from the inner surface of the rotating drum 4 by its own weight. Furthermore, the lifting position and the falling position of the laundry 70 can be switched alternately left and right as shown in FIG. 10B by forward and reverse alternating arc rotation driving, as shown in FIG. And the mechanical force can be applied evenly to the laundry 70.

  In addition, although the forward / reverse arc rotation drive mode has a large drive load, by using the forward / reverse continuous rotation drive mode with a low drive load in combination, the laundry 70 generated in the forward / reverse continuous rotation drive mode is reduced while reducing the mechanical load. The imbalance of mechanical force application to the laundry 70 such as entanglement, twisting, and wrinkles can be corrected by adjusting the execution ratio of the forward / reverse arc rotation drive mode. In addition, two different behaviors of the laundry 70 in both driving modes and the laundry being rinsed, specifically, the behavior of washing hands firmly by the forward / reverse arc rotational drive mode, by the forward / reverse continuous rotational drive mode Executes a washing and rinsing process that synergistically combines the characteristic behavior in both drive modes by moving the laundry 70 continuously and performing a uniform washing behavior to wash evenly and using them together Can do. Furthermore, in the forward / reverse arc rotation drive mode alone, a large rotational torque is obtained, so that the power consumption increases. However, the combined use of the forward / reverse continuous rotation drive mode can save power.

  Next, the case where the forward / reverse arc rotation drive mode is executed in the drying process will be described. The driving procedure in the drying process and the behavior of the laundry 70 are basically the same as in the case where the forward / reverse arc rotation driving mode is executed in the washing and rinsing process described above, and the description thereof is omitted here. Executing the forward / reverse arc rotation driving mode in the drying process is somewhat reduced in driving load compared to the case of executing in the washing / rinsing process, but the driving load is larger than that in the forward / reverse continuous rotation driving mode. Become.

  In the drying step, the laundry 70 is lifted up to the upper left and right sides of the rotating drum 4 by the arc rotation driving of the rotating drum 4 alternately and forwardly and reversely. In a braking state, the laundry 70 is reliably and instantaneously peeled off from the inner surface of the rotating drum 4 by the forced peeling force due to its inertia and the weight of the laundry 70, and dropped to the left and right sides of the rotating drum 4 to repeat the arc. For each rotational drive, the lifting position and the falling position of the laundry 70 are alternately switched to the left and right to increase the unwinding action of the laundry 70, preventing entanglement, twisting and sticking to the inner surface of the rotating drum 4, The laundry 70 can be easily taken out, and the wrinkle of the laundry 70 can be greatly reduced.

  Further, by executing such a forward / reverse arc rotation drive mode in the drying process, the laundry 70 is entangled, twisted, and wrinkled in the dehydration step after the washing process and the rinsing process, and is strongly applied to the inner surface of the rotating drum 4. Even when the pressed and stuck ridges are attached, it is solved smoothly by the high unwinding action and the mechanical force action due to the alternating left and right of the laundry 70 lifting position and dropping position. Since the dry high-temperature air can reach the inside of the laundry 70, the laundry 70 can be dried evenly. In addition, the hitting action when the laundry 70 is dropped allows the laundry 70 to unfold and regenerate the fibers accompanying the unfolding effect, so that the feel at the dry finish can be greatly enhanced.

Furthermore, when the forward / reverse continuous rotation drive mode is executed in the drying process, the contact efficiency with the dry air in the laundry 70 can be increased, and the drying efficiency can be generally improved. Therefore, by using the forward / reverse arc rotation drive mode and the forward / reverse continuous rotation drive mode in combination, the drying time can be further shortened, and further, the laundry 70 can be entangled, twisted, and stuck to the inner surface of the rotary drum 4. It is possible to prevent the laundry 70 from being taken out easily and to greatly reduce the wrinkle of the laundry 70. In this way, it is possible to execute a drying process that synergistically combines the advantages of both drive modes. In addition, in the forward / reverse arc rotation drive mode alone, a large rotational torque is obtained, so that the power consumption increases. However, the combined use of the forward / reverse continuous rotation drive mode can save power.

  Thus, in the drum-type washing machine 1 using the motor 5 of the present embodiment, mechanical force can be exerted on the laundry 70 by using both the forward / reverse arc rotation drive mode and the forward / reverse continuous rotation drive mode. In addition to the scouring effect and the rinsing effect by the slamming action, it has the effect of preventing entanglement / twisting and heel stretching, that is, washing, rinsing, and drying that combine the features and advantages of both drive modes These steps can be executed.

  It can be applied to the assembly of a motor having a stator and a rotor with attachment to a washing machine, and the assemblability and assembly accuracy can be improved.

It is sectional drawing which shows the principal part structure of the drum type washing machine to which the motor which concerns on embodiment of this invention is applied. It is the rear view which looked at the inside of the drum type washing machine concerning an embodiment of the invention. It is sectional drawing which shows the substantially half part of the motor attachment part of the drum type washing machine which concerns on embodiment of this invention. It is sectional drawing which shows the attachment state to the water tank back surface of the motor of the drum type washing machine which concerns on embodiment of this invention. It is the perspective view which decomposed | disassembled the stator and rotor of the motor which concern on embodiment of this invention. It is a plane sectional view of a stator and a rotor in a motor concerning an embodiment of the invention. It is a top view of the rotor in the motor concerning an embodiment of the invention. It is the perspective view seen from the back of the rotor in the motor concerning an embodiment of the invention. It is an assembly process figure when attaching the motor which concerns on embodiment of this invention to a washing machine main body. It is a schematic diagram explaining the behavior of the (a) drive procedure in the normal / reverse continuous rotation drive mode in the drum type washing machine which concerns on embodiment of this invention, and (b) the laundry at that time. It is sectional drawing which shows the conventional drum type washing machine which employ | adopted the inner rotor type motor. It is sectional drawing which shows the conventional drum type washing machine which employ | adopted the outer rotor type motor. It is a rear view of an outer rotor type motor.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Drum type washing machine 2 Washing machine housing 3 Water tank 4 Rotating drum 5 Motor 20 Rotating shaft 21 Stator 22 Resin mold body 22a End surface 23 Stator core 23a Inner teeth 23b Outer teeth 23c Yoke 24 Winding 25 Rotor 25a Inner rotor 25b Outer rotor 26 Resin mold Body 26a Canopy (end face)
26b Convex part 26c Open window
26d first gap inspection hole
26e second gap inspection hole

Claims (3)

A substantially annular stator molded with a resin material;
A substantially annular outer rotor molded with a resin material at a position along the outer peripheral surface of the stator;
The end surface of the resin mold body located at least in the axial direction of the outer rotor, the first gap inspection holes for checking the gap dimension between the said stator outer rotor is characterized by being kicked at least one set motor. A substantially annular inner rotor molded with a resin material at a position along the inner peripheral surface of the stator;
The end surface of the resin mold body located at least in the axial direction of said inner rotor, second gap inspection holes for checking the gap dimension between the said stator inner rotor is characterized by being kicked at least one set The motor according to claim 1. An opening window for heat dissipation is provided on the end surface of the resin mold body positioned at least in the axial direction of the outer rotor,
The motor according to claim 1 or 2 before Symbol first gap inspection hole is characterized in that it is formed by widening the opening window in the radial direction.