JP6718365B2 - Electric blower and vacuum cleaner - Google Patents

Description

Embodiments of the present invention relate to an electric blower having a frame that houses a rotor and a stator, and an electric vacuum cleaner including the electric blower.

Conventionally, for example, an electric blower used for an electric vacuum cleaner includes an electric motor, a fan rotated by the electric motor, and a diffuser which is a rectifying body (rectifying plate) interposed between the electric motor and the fan. There is. The air blown out from the centrifugal fan rotated by the electric motor is rectified by the diffuser and sent into the electric motor, and the air cooled by the electric motor is discharged to the outside of the frame of the electric motor.

In order to ensure the ventilation efficiency of the electric blower, it is necessary to ensure the air passage from the air blown from the centrifugal fan to the inside of the electric motor from the diffuser and the discharge from the electric motor. Therefore, for example, it is conceivable to widen the air passage formed between the rectangular stator core and the inner shape of the frame of the electric motor.

However, if the inner shape of the frame is quadrangular, there is a concern that the frame itself may become large.

Japanese Patent No. 5369557

The problem to be solved by the present invention is to provide an electric blower capable of ensuring an air passage between the air passage portion and the outside of the stator core and the inside of the frame while suppressing an increase in size, and an electric vacuum cleaner provided with the electric blower. ..

The electric blower of the embodiment has a centrifugal fan, an electric motor, and a rectifying body. The electric motor rotates the centrifugal fan. This electric motor includes a rotor, a stator, and a frame. The rotor is connected to the centrifugal fan. The stator rotates the rotor. This stator has a stator core and a coil forming a magnetic pole on the stator core. The frame has an intake opening into which the air rectified by the rectifying body flows, and accommodates the rotor and the stator. The rectifying body is interposed between the centrifugal fan and the electric motor. This rectifying body rectifies the air blown from the centrifugal fan to the electric motor side. The rectifying body also includes an outer frame portion, a body portion, and an air passage portion. The outer frame portion supports the frame and forms an outer shell. The body portion is arranged inside the outer frame portion. The air passage portion is formed between the outer frame portion and the main body portion and rectifies the air blown from the centrifugal fan to the intake opening portion. The air passage portion has an inner diameter larger than the outer diameter of at least a part of the stator core, and the outer diameter is set to be equal to or smaller than the inner diameter of the frame.

It is a sectional view showing an electric blower of one embodiment. It is a top view which shows a part of electric blower same as the above from a centrifugal fan side. It is a perspective view which shows a part of electric blower same as the above from a centrifugal fan side. It is a top view which shows a part of electric blower same as the above from an electric motor side. It is a perspective view which shows some electric blowers from the electric motor side same as the above. It is a top view which shows the stator of an electric blower same as the above. It is a top view which shows a part of frame of an electric blower same as the above. It is an exploded perspective view of an electric blower same as the above. It is a perspective view which notches one part and shows an electric blower same as the above. It is a perspective view showing the electric vacuum cleaner provided with the electric blower same as the above.

Hereinafter, the configuration of one embodiment will be described with reference to the drawings.

8 and 9, 11 indicates an electric blower. The electric blower 11 includes an electric motor 13. The electric blower 11 also includes a centrifugal fan 14. Further, the electric blower 11 includes a diffuser 15 which is a rectifying body (rectifying plate). The electric blower 11 also includes a fan cover 16. The drive of the electric blower 11 (electric motor 13) is controlled by a control circuit (not shown).

The electric motor 13 may be a commutator motor or a brushless motor, but in the present embodiment, it is a single-phase 4-pole brushless motor, for example. The electric motor 13 has a rotor 21. The electric motor 13 also includes a stator 22. Further, the electric motor 13 includes a sensor board 23. The electric motor 13 also includes a frame 24. In the following description, the electric motor 13 side in the axial direction of the electric blower 11 will be described as a rearward direction (arrow RR side shown in FIG. 9 and the like) and the centrifugal fan 14 side as a forward direction (arrow FR side shown in FIG. 9 and the like). Further, unless otherwise specified, the axial direction and the radial direction refer to the axial direction and the radial direction of the electric blower 11.

The rotor 21 forms a rotating magnetic pole. The rotor 21 is a permanent magnet type rotor in the present embodiment, but may be a wound type rotor when the electric motor 13 is a commutator motor. The rotor 21 includes a shaft 26. The rotor 21 also includes a magnet portion 27. Further, the rotor 21 may include at least one sleeve 28. The rotor 21 is rotatably held by the frame 24 via a pair of bearings 30.

The shaft 26 is a rotating shaft that serves as an output shaft of the electric motor 13. The centrifugal fan 14 is connected to the shaft 26. Specifically, the centrifugal fan 14 is connected to the shaft 26 on the front end side protruding from the frame 24.

The magnet part 27 is formed in a cylindrical shape, and the shaft 26 is fixed to the center part. Magnetic poles (rotating magnetic poles) having polarities different from each other in the rotation direction (circumferential direction) are formed adjacent to the magnet portion 27. Therefore, in the magnet portion 27, north poles and south poles are sequentially arranged alternately in the rotational direction to form pairs.

A pair of sleeves 28 are provided in the present embodiment, and are fixed to the shaft 26 adjacent to the front end portion and the rear end portion of the magnet portion 27. The sleeve 28 is not an essential component.

The bearings 30 are attached to one end side and the other end side of the shaft 26, are fixed to the frame 24, and hold the rotor 21 rotatably with respect to the frame 24.

The stator 22 shown in FIGS. 6, 8 and 9 constitutes a fixed magnetic pole for rotating the rotor 21. The stator 22 includes a stator core 33. The stator 22 also includes a stator insulation 34 that is an insulator. Further, the stator 22 includes a coil 35. The stator 22 also includes terminals 36.

The stator core 33 is formed by laminating thin plate-shaped magnetic bodies such as electromagnetic steel plates into a plate shape having a substantially constant thickness. The stator core 33 includes an annular (cylindrical) back yoke 41. The stator core 33 includes three or more teeth, that is, four teeth 42 in this embodiment. Furthermore, the stator core 33 includes a frame mounting portion 43. Further, in the present embodiment, the stator core 33 is vertically divided into two substantially semi-circular shapes by the dividing portion 44. That is, the stator core 33 is configured by two (one and the other) yoke bodies (core members) 46, 46 punched out by, for example, press molding, being integrally connected at the dividing portion 44.

The back yoke 41 connects the teeth 42 to each other, and forms a magnetic path that magnetically (via magnetic flux) couples the fixed magnetic poles generated by the coils 35, 35 wound around the pair of teeth 42, 42. It is a thing. In this embodiment, the back yoke 41 has first yoke portions 41a and 41a and second yoke portions 41b and 41b. The first yoke portion 41a and the second yoke portion 41b are arranged alternately in the circumferential direction of the stator core 33.

Each of the first yoke portions 41a is formed in an arc shape. The first yoke portion 41a is set to have a substantially constant width dimension, and is formed such that the inner peripheral side gradually becomes wider at a position near the teeth 42 (a position facing the frame mounting portion 43). ing. The terminals 36 are arranged on the stator insulation 34 in the first yoke portion 41a.

The second yoke portions 41b are each formed in an arc shape. In the present embodiment, the second yoke portion 41b is set to have a substantially constant width dimension except for the division portion 44. In the present embodiment, the split portion 44 is set, for example, in the second yoke portion 41b.

The first yoke portion 41a and the second yoke portion 41b have a circumferential length (a dimension in the circumferential direction of the stator core 33) and a width dimension (a radial direction of the stator core 33). Dimensions are different from each other. The circumferential length of the first yoke portion 41a is set shorter than the circumferential length of the second yoke portion 41b, and the width dimension of the first yoke portion 41a is smaller than that of the second yoke portion 41b. Is also set large.

Here, in the present embodiment, the first yoke portion 41a is opposite to the central axis side of the stator core 33 (back yoke 41), that is, the inner side (inner peripheral side) and the central axis side, with respect to the second yoke portion 41b. It is formed so as to be wide on each side, that is, on the outer side (outer peripheral side). That is, the outer diameter dimension of the first yoke portion 41a is larger than the outer diameter dimension of the second yoke portion 41b, and the inner diameter dimension of the first yoke portion 41a is smaller than the inner diameter dimension of the second yoke portion 41b. ing. Therefore, the magnetic path of the first yoke portion 41a is set larger than that of the second yoke portion 41b.

The teeth 42 have a fixed magnetic pole formed by the coil 35. These teeth 42 are magnetically paired with each other. Further, these teeth 42 are provided so as to protrude from the inner peripheral portion of the back yoke 41 toward the center, that is, toward the rotor 21 side. That is, the teeth 42 are formed in a longitudinal shape along the radial direction of the back yoke 41 (stator core 33), the base end portion is connected to the back yoke 41, and the tip end portion protrudes in a free end shape. Specifically, the teeth 42, 42 adjacent to each other on the left and right are arranged so as to form an angle of 90° or less with each other in the circumferential direction of the stator core 33 (stator 22). Further, the magnetic action surface facing the outer peripheral surface of the rotor 21 is formed at the tip of each tooth 42. The magnetic action surface causes the fixed magnetic poles formed on the teeth 42 by the coil 35 to act on the rotor 21, and is separated from the outer peripheral surface of the rotor 21 with a slight gap.

The frame attachment portion 43 fixes the stator core 33 (stator 22) to the frame 24. The frame mounting portion 43 is provided in a rectangular shape on the outer side (outer peripheral side) of the back yoke 41, and is arranged in the vicinity of the base end portion of each tooth 42. Therefore, in this embodiment, four frame attachment portions 43 are set apart from each other in the circumferential direction of the back yoke 41 and correspond to the teeth 42. Then, each frame mounting portion 43 is provided with a mounting hole 43a penetrating in the axial direction (front-back direction). A screw 49, which is a mounting member, is inserted into the mounting hole 43a, and the screw 49 is screwed into the frame 24 to fix the stator core 33 (stator 22) to the frame 24.

The stator insulation 34 holds the coil 35 and the terminal 36 in an insulated state with respect to the stator core 33. The stator insulation 34 is made of insulating synthetic resin or the like. The stator insulation 34 includes a terminal holder 52 that is a terminal block that holds the terminals 36. The terminal holding portion 52 is arranged so as to overlap the back yoke 41 of the stator core 33. In the present embodiment, two terminal holding parts 52 are arranged on each first yoke part 41 a of the stator core 33. Further, at least a part of the terminal holding portion 52 is arranged so as to project outward with respect to the stator core 33. In the present embodiment, a part of the terminal holding portion 52 projects outward from the outer peripheral edge of the first yoke portion 41a.

The coil 35 forms a fixed magnetic pole on each tooth 42. In the present embodiment, these coils 35 are arranged so as to alternately generate different poles in the circumferential direction of the stator core 33 (stator 22), for example.

The terminal 36 is for electrically connecting the control circuit and each coil 35. A pair of the terminals 36 is arranged at a position between the teeth 42 located on the left and right of the stator core 33. The terminals 36, 36 located on the left and right are paired.

The sensor substrate 23 detects the rotational position (rotation angle) of the rotor 21 by detecting the polarity of the magnetic poles of the rotor 21 (magnet portion 27), and includes, for example, a Hall IC. The sensor substrate 23 is formed in a C shape, for example, and is arranged along the outer circumference of the magnet portion 27 of the rotor 21. The sensor board 23 is stacked on the rear side of the stator 22, for example, and is fixed to the stator insulation 34 by a board fixing member 59 such as a screw.

The frame 24 is formed of a light and electrically conductive metal member such as aluminum or magnesium. The frame 24 includes, for example, one frame body 61 and another frame body 62. The frame 24 is configured to house the rotor 21, the stator 22 and the sensor substrate 23 by sandwiching them from the front and the rear by fixing the one and the other frame bodies 61 and 62 to each other by the screws 49. ing.

The one frame body 61 is located on the front side of the rotor 21, the stator 22 and the sensor substrate 23. As shown in FIG. 8, the one frame body 61 includes an annular outer shell 64. Further, one frame body 61 includes one bearing portion 65. Furthermore, the one frame body 61 includes one leg portion 66 as a plurality of one connecting portions. Further, the one frame body 61 includes a plurality of restriction portions 67. Further, the one frame body 61 includes a plurality of threaded portions 68 as attached portions. Further, one frame body 61 includes a frame intake opening 69 which is an intake opening.

The outer shell 64 sets the maximum outer diameter of the frame 24 (one frame body 61). As shown in FIGS. 3 and 5, the outer shell portion 64 has an outer diameter dimension substantially equal to that of the diffuser 15.

As shown in FIGS. 8 and 9, one bearing portion 65 is one bearing holding portion that rotatably supports the rotor 21 by receiving one (front side) bearing 30. In addition, one bearing portion 65 is provided with a round hole-shaped screwing hole 65a into which a fixing body 71 such as a screw for fixing the electric motor 13 and the diffuser 15 in the front-rear direction is screwed.

As shown in FIGS. 4 and 7, the one leg portion 66 connects the one bearing portion 65 and the outer shell portion 64. These one leg portions 66 are provided so as to radially project from the one bearing portion 65. A plurality of these one leg portions 66 are provided corresponding to the number of teeth 42 of the stator core 33. That is, the four leg portions 66 are provided in this embodiment. Further, the one leg portion 66 is substantially evenly distributed in the circumferential direction of the frame 24 (the one frame body 61). That is, a plurality of these one leg portions 66 are arranged around the electric blower 11 (the rotor 21). Furthermore, the tip side of each of these one leg portions 66 is bent toward the rear side, that is, toward the other frame body 62 side.

The restricting portion 67 positions the frame 24 (one frame body 61) in the circumferential direction with respect to the stator 22 by stopping the stator core 33 from rotating. These restricting portions 67 are provided at the connecting positions of the outer shell portion 64 and the one leg portion 66. Then, the frame attachment portions 43 are fitted into the restriction portions 67, respectively, so that the stator core 33 (stator 22) is prevented from rotating in the circumferential direction.

As shown in FIG. 7 and FIG. 9, the screwing portion 68 is located on the regulating portion 67 and provided on the one leg portion 66, respectively. The screw portion 68 is provided in a boss shape into which the screw 49 inserted into the mounting hole 43a of each frame mounting portion 43 of the stator core 33 is screwed.

The frame intake opening 69 is partitioned between the outer shell 64, one bearing 65, and one adjacent leg 66, 66. The frame intake opening 69 is opened so as to face the diffuser 15.

As shown in FIGS. 8 and 9, the other frame body 62 is located on the rear side with respect to the rotor 21, the stator 22 and the sensor substrate 23. The other frame body 62 includes another bearing portion 73. Further, the other frame body 62 includes another leg portion 74 as another connecting portion.

The other bearing portion 73 is another bearing holding portion that rotatably supports the rotor 21 by receiving the other (rear side) bearing 30.

The other leg portion 74 is a contact portion with the stator core 33, and is a portion that connects the other frame body 62 and the one frame body 61. The other leg portions 74 are provided so as to radially project from the other bearing portion 73. A plurality of these other leg portions 74 are provided corresponding to the number of teeth 42 of the stator core 33, in other words, the number of frame attachment portions 43. That is, four of these other leg portions 74 are provided in this embodiment. Further, the other leg portions 74 are substantially evenly distributed in the circumferential direction of the frame 24 (the other frame body 62). That is, a plurality of these other leg portions 74 are arranged around the electric blower 11 (rotor 21). Furthermore, the tip end side of these other leg portions 74 is bent toward the front side, that is, toward the one frame body 61 side. In addition, insertion holes 74a through which the screws 49 are inserted are provided at the tip ends of the other leg portions 74, respectively. Then, the screw 49 inserted into the insertion holes 74a of the other leg portions 74 stacked on the stator core 33 is inserted into the attachment hole 43a of the frame attachment portion 43 of the stator core 33, and the screwed portion 68 of the one frame body 61. The one and the other frame bodies 61 and 62 are fixed to each other by being screwed into. Therefore, in a state in which the other frame body 62 is fixed to the one frame body 61, the outer shell portion 64 of the one frame body 61, the other bearing portion 73 of the other frame body 62, and the other adjacent leg portion 74. , 74, a frame exhaust opening 75, which is an exhaust opening, is defined. These frame exhaust openings 75 exhaust the air that has flowed into the electric motor 13 to the outside. The terminals 36 are located so as to be exposed at a pair of frame exhaust openings 75 facing each other among the frame exhaust openings 75.

The centrifugal fan 14 is connected to the shaft 26 and rotated by the electric motor 13 to push out (blow out) air from the center side to the outer peripheral side. The centrifugal fan 14 has a shaft insertion hole 77 at the center thereof, into which the shaft 26 is inserted. Further, the centrifugal fan 14 includes a plurality of fan blades 78. Then, a nut 79 as a fixing member is screwed into the front end portion of the shaft 26 of the electric motor 13 inserted into the shaft insertion hole 77, whereby the centrifugal fan 14 is integrally fixed to the shaft 26.

As shown in FIG. 1 to FIG. 5, FIG. 8, FIG. 9, etc., the diffuser 15 rectifies the air pushed out by the centrifugal fan 14 and flows it into the electric motor 13. The diffuser 15 includes an outer frame portion 80. Moreover, the diffuser 15 includes a main body 81. Further, the diffuser 15 includes an air passage portion 82 which is a ventilation opening. The diffuser 15 also has a mounting opening 83. Further, the diffuser 15 includes a through hole 84 which is a fixed hole portion. Further, the diffuser 15 includes a plurality of flow straightening vanes 85. Further, the diffuser 15 includes a frame positioning portion 86. A fan cover 16 is attached to the front side of the diffuser 15. The diffuser 15 is formed of, for example, synthetic resin, glass fiber (GF) reinforced PET in this embodiment.

The outer frame portion 80 supports the frame 24. The outer frame portion 80 forms the outer shell of the diffuser 15. The outer frame portion 80 is formed, for example, in an annular shape having substantially the same diameter as the frame 24. That is, the outer frame portion 80 is set to have an outer diameter dimension substantially equal to that of the outer shell portion 64. Further, the outer frame portion 80 is superposed on the outer shell portion 64 in the axial direction (front side) while supporting the frame 24. Further, the outer frame portion 80 is set to have a larger dimension in the axial direction (front-back direction) than the main body portion 81. Therefore, the outer frame portion 80 extends so as to project in the front-rear direction with respect to the main body portion 81.

The main body 81 is a portion on which the frame 24 is overlapped. The main body portion 81 is arranged inside the outer frame portion 80. The main body 81 has an outer diameter larger than the centrifugal fan 14 and smaller than the inner diameter of the outer frame 80. Therefore, the outer edge portion of the main body portion 81 is separated from the inner edge portion of the outer frame portion 80 inward (center side) and is connected by the flow straightening blades 85. Further, the main body 81 may be provided with a circular recess 81a in which the rear side of the centrifugal fan 14 is disposed in the central portion. Further, the main body portion 81 is located, for example, on the front side in the outer frame portion 80.

The air passage portion 82 rectifies the air blown out from the centrifugal fan 14 to the frame intake opening 69. The air passage portion 82 is formed between the outer frame portion 80 and the main body portion 81 so as to penetrate the diffuser 15 in the front-rear direction. A straightening vane 85 is arranged in the air passage section 82. In other words, the air passage portion 82 is defined between the outer frame portion 80, the main body portion 81, and the flow straightening vanes 85, 85.

Here, as shown in FIGS. 1, 2 and 4, the air passage portion 82 has an inner diameter D1 and an outer diameter D2 set to be substantially constant, and the inner diameter D1 is an outer diameter of at least a part of the stator core 33. It is larger than D3 (D1>D3), and the outer diameter D2 is less than or equal to the inner diameter D4 of the frame 24 (D2≦D4). The inner diameter D1 of the air passage portion 82 is defined by the outer diameter dimension of the main body portion 81. Further, the outer diameter D2 of the air passage portion 82 is defined by the inner diameter dimension of the outer frame portion 80. Further, the outer diameter D3 of the stator core 33 is defined by the outer diameter dimension of the position excluding the frame mounting portion 43, that is, the outer diameter dimension of the back yoke 41. In the present embodiment, the back yoke 41 is provided with a first yoke portion 41a having a relatively large outer diameter dimension and a second yoke portion 41b having a relatively small outer diameter dimension. The outer diameter D2 is defined as the outer diameter dimension at the position of the second yoke portion 41b. The inner diameter D4 of the frame 24 is defined by the inner diameter dimension of the outer shell portion 64 (the inner diameter dimension of the outer shell portion 64 at the position excluding the restricting portion 67 and the screwing portion 68). At this time, in the present embodiment, the diffuser 15 is made of a synthetic resin, and the shape of the diffuser 15 opens the molding die for injection molding along the axial direction to release it. Therefore, the diffuser 15 may be provided with a fine draft (taper) along the axial direction. For example, in the present embodiment, the diffuser 15 may be provided with a draft so that the diameter thereof gradually increases from the front side (centrifugal fan 14 side) to the rear side (electric motor 13 side). In this case, the outer diameter D2 of the air passage portion 82 defined by the inner diameter of the outer frame portion 80 is the maximum inner diameter of the outer frame portion 80, in this embodiment, the inner diameter of the rear end portion of the outer frame portion 80, in other words, It is defined by the inner diameter of the end portion on the electric motor 13 (frame 24) side, that is, the inner diameter of the alignment position (partition position) P between the diffuser 15 (outer frame portion 80) and the frame 24 (outer shell portion 64). In the present embodiment, the outer diameter D2 of the air passage portion 82 substantially coincides with the inner diameter D4 of the frame 24 at the position P where the diffuser 15 and the frame 24 are aligned (D2≈D4). Therefore, no step is formed at the alignment position P between the diffuser 15 and the frame 24.

As shown in FIG. 3, the mounting opening 83 is for fitting a part of the frame 24. In the present embodiment, the bearing opening 65 of the frame body 61 is fitted into the mounting opening 83. Therefore, the mounting opening 83 has a circular shape. The mounting opening 83 is provided in the center of the main body 81. In the present embodiment, the mounting opening 83 penetrates the recess 81a of the main body 81 in the front-rear direction.

The through holes 84 are provided on both sides of the attachment opening 83 in the main body 81, for example. In the present embodiment, each of these through holes 84 penetrates the recess 81a of the main body 81 in the front-rear direction.

The flow straightening vanes 85 connect the outer frame portion 80 and the main body portion 81 to partition the air passage portion 82. These flow straightening vanes 85 are provided so as to be inclined from the front side to the rear side along the rotation direction of the centrifugal fan 14 (FIG. 9). Further, as shown in FIG. 1, a part of the flow straightening vanes 85 faces the frame 24 (one frame body 61) while the frame 24 (electric motor 13) is supported by the diffuser 15. ing. In the present embodiment, some of the flow control vanes 85 face the one leg portion 66 of the frame 24 (one frame body 61) while the frame 24 (electric motor 13) is supported by the diffuser 15. Further, these flow straightening vanes 85 are provided at substantially equal intervals in the circumferential direction. In the present embodiment, the rectifying blades 85 are provided in a larger number than the one leg portion 66 of the frame 24 and the fan blades 78 of the centrifugal fan 14.

As shown in FIG. 8, the frame positioning portion 86 is, for example, a portion to which one leg portion 66 of one frame body 61 is fitted. Therefore, a plurality of frame positioning portions 86, four in this embodiment, are provided corresponding to one leg portion 66. The frame positioning portion 86 is provided, for example, in a groove shape along the front-rear direction on the inner edge portion on the rear end side (electric motor 13 side) of the outer frame portion 80.

The fan cover 16 covers a part of the centrifugal fan 14 and is attached to the diffuser 15. An intake port 90 that exposes the central portion of the centrifugal fan 14 is opened in the fan cover 16.

The control circuit includes, for example, a driver including an inverter circuit and a control unit that performs PWM control of the driver, and is electrically connected to each terminal 36 and the sensor substrate 23. Then, the control circuit switches the magnetic poles generated in the teeth 42 of the stator core 33 of the stator 22 via the coils 35 by controlling the direction of the current flowing in the coils 35 and the energization time by the driver. Is configured.

The electric blower 11 and the control circuit described above are included in the electric vacuum cleaner 91 shown in FIG. 10 in the present embodiment. The electric vacuum cleaner 91 includes a vacuum cleaner body 92 and a dust collecting portion 93. In the present embodiment, the electric vacuum cleaner 91 is, for example, a long stick-type (handy-type) electric vacuum cleaner including an air passage body 94 that can be attached to and detached from a longitudinal cleaner body 92. For example, a canister type or the like, or a self-propelled electric vacuum cleaner capable of autonomous traveling can be preferably used.

The vacuum cleaner body 92 houses the electric blower 11 and a control circuit. Further, a dust collecting portion 93 is attachable to and detachable from the cleaner body 92.

The dust collecting portion 93 is a portion that collects the dust sucked together with the air from the air by using the negative pressure generated by the driving of the electric blower 11. In the present embodiment, for example, a cyclone dust collecting unit that centrifuges dust is used as the dust collecting unit 93, but, for example, one that filters and collects dust with a filter, one that collects dust using inertia, etc. , And can have any configuration.

The air duct body 94 applies a negative pressure generated by the drive of the electric blower 11 to the floor surface or the like. The air duct body 94 is not an essential component.

Next, the operation of the electric blower 11 of the above embodiment will be described.

The electric blower 11 detects the rotational position of the rotor 21 by the sensor substrate 23, and controls the direction of the current flowing through each coil 35 and the energization time by the control circuit in accordance with the rotational position, so that each tooth 42 is controlled. The magnetic poles are sequentially formed, and the rotor 21 is rotated by the repulsion and attraction between these magnetic poles and the magnetic poles of the rotor 21. Therefore, the negative pressure generated by the rotation of the centrifugal fan 14 of the electric blower 11 causes the air to be sucked into the electric blower 11 from the intake port 90.

Then, the sucked air is rectified by the fan blades 78 of the centrifugal fan 14 through the gap between the centrifugal fan 14 and the fan cover 16 and around the centrifugal fan 14, and then passes through the front side of the diffuser 15. It flows to the surrounding air passage section 82. Subsequently, this air is flowed into the electric motor 13 through the frame intake opening 69 while being rectified by the rectifying blades 85 of the diffuser 15, and the stator 22 (stator core 33) and the frame 24 (one frame body 61 (outer shell portion). 64)) and the inside of the stator 22 (between the teeth 42, 42 of the stator core 33) to cool the stator 22 and the rotor 21, and pass through the inside of the frame 24 of the electric motor 13. Air is exhausted from the frame exhaust opening 75 while cooling the terminal 36.

At this time, according to the embodiment described above, the inner diameter D1 of the air passage portion 82 is larger than the outer diameter D3 of at least a part of the stator core 33, and the outer diameter D2 of the air passage portion 82 is equal to or less than the inner diameter D4 of the frame 24. By being set, the air blown out from the centrifugal fan 14 and flowing along the air passage portion 82 is exhausted without being disturbed by the outside of the stator core 33 or the inside of the frame 24. Therefore, for example, as compared with the case where the inner shape of the frame 24 is rectangular, the air passage between the air passage portion 82 and the outside of the stator core 33 and the inside of the frame 24, that is, the air passage portion is suppressed while suppressing an increase in size. The air passage from 82 to the exhaust can be secured, and the blowing efficiency of the electric blower 11 can be improved.

In particular, since the inner diameter D1 of the air passage portion 82 is larger than the outer diameter D3 of the stator core 33 at the position of the second yoke portion 41b, in the air passage portion 82, the stator core in which the terminal 36 (terminal holding portion 52) is arranged. Air can be made to flow more easily at the position corresponding to the second yoke portion 41b than at the position corresponding to the first yoke portion 41a of 33.

Further, since the outer diameter D2 of the air passage portion 82 substantially matches the inner diameter D4 of the frame 24 at the position P where the diffuser 15 and the frame 24 are aligned, the air is blown out from the centrifugal fan 14 and follows the air passage portion 82. The air flowing therethrough can be more reliably prevented from being disturbed by the inside of the frame 24, and the turbulent flow due to the step between the diffuser 15 and the inner periphery of the frame 24 can be suppressed, so that the blowing efficiency of the electric blower 11 can be further improved. Can be improved.

In particular, in the present embodiment, the coil 35 forms four or more magnetic poles on the stator core 33, so that switching of magnetic flux is smoothed and torque of the electric motor 13 is improved as compared with the case of three or less magnetic poles. The efficiency of the electric blower 11 is further improved.

Further, since the stator core 33 is divided into two or more yoke bodies 46, even if the stator core 33 has a substantially circular shape (substantially annular shape), for example, winding is performed for each semicircular (semi-arcuate) yoke body 46. Therefore, the coil 35 can be easily configured and the manufacturability can be improved. Further, the circular stator 22 can be easily configured by connecting the yoke bodies 46 that respectively configure the coils 35 at the split portions 44.

Further, by providing the electric vacuum cleaner 91 with the electric blower 11 having good ventilation efficiency, it is possible to provide the electric vacuum cleaner 91 which is energy-saving and has good cleaning performance.

In the above-described embodiment, the stator core 33 includes a back yoke 41 having a first yoke portion 41a having a relatively large outer diameter dimension and a second yoke portion 41b having a relatively small outer diameter dimension. However, it is also possible to form it with a substantially constant outer diameter.

Further, not only the outer diameter D3 of a part of the stator core 33 but also the entire outer diameter D3 can be made smaller than the inner diameter D1 of the air passage portion 82.

Furthermore, although the electric blower 11 has been described as being applied to the suction of the electric vacuum cleaner 91, it may be applied to the exhaust of a blower, for example.

The electric blower 11 can be used for any electric device other than the electric vacuum cleaner 91.

Although one embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the scope equivalent thereto.

11 electric blower
13 electric motor
14 Centrifugal fan
15 Diffuser that is a rectifier
21 rotor
22 Stator
24 frames
33 Stator core
35 coils
46 York body
69 Frame intake opening that is the intake opening
80 outer frame
81 Main body
82 Wind path
91 vacuum cleaner
92 Vacuum cleaner body
D1 inner diameter
D2 outer diameter
D3 outer diameter
D4 Inner diameter P Matching position

Claims (5)

Centrifugal fan,
An electric motor that rotates this centrifugal fan,
A rectifying body interposed between the centrifugal fan and the electric motor, for rectifying the air blown from the centrifugal fan to the electric motor side,
The electric motor is
A rotor connected to the centrifugal fan, and a stator for rotating the rotor,
An intake opening into which the air rectified by the rectifying body flows, and a frame accommodating the rotor and the stator,
The stator is
A stator core,
This stator core has a coil forming a magnetic pole,
The rectifying body is
An outer frame portion that supports the frame and forms an outer shell,
A main body portion arranged inside the outer frame portion,
An air passage portion formed between the outer frame portion and the main body portion for rectifying the air blown out from the centrifugal fan to the intake opening portion,
The air blower has an inner diameter larger than an outer diameter of at least a part of the stator core, and an outer diameter set to be equal to or smaller than an inner diameter of the frame. The electric blower according to claim 1, wherein an outer diameter of the air passage portion is substantially equal to an inner diameter of the frame at a position where the rectifying body and the frame are aligned with each other. The electric blower according to claim 1 or 2, wherein the coil has four or more magnetic poles formed on a stator core. The electric blower according to any one of claims 1 to 3, wherein the stator core is divided into two or more yoke bodies. With the vacuum cleaner body,
An electric blower according to any one of claims 1 to 4, comprising: an electric blower.

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