JP6653363B2 - Electric blower - Google Patents

Description

  The present invention relates to an electric blower.

  As a conventional electric blower for a vacuum cleaner, a blower using a brushless motor has been proposed for downsizing. For example, in a rotor assembly that constitutes an electric blower described in Patent Document 1, a rotor core (magnet) is attached to one end of a shaft, an impeller is attached to the other end of the shaft, and a rotor core and an impeller of the shaft are attached. A bearing is mounted between them.

JP-T-2012-518751

  However, in the invention described in Patent Literature 1, since the bearing is provided at the center of the shaft, it is difficult to balance when the impeller is rotated, so that sound and vibration are easily generated, and the efficiency is reduced. was there.

  As a method of achieving balance without affecting the magnetic circuit, it is conceivable to attach a resin member (non-magnetic) to the end of the shaft on the rotor core side. However, the resin member is too light to make it difficult to balance, and it is necessary to make the resin member larger and heavier in order to make the balance easier.

  An object of the present invention is to solve the above-mentioned conventional problems, and an object of the present invention is to provide an electric blower that can be reduced in size and increased in efficiency.

The present invention provides a rotating shaft rotatably provided, a bearing provided substantially at the center of the rotating shaft in the axial direction, a centrifugal impeller provided at one end of the rotating shaft, A rotor core provided on a side opposite to the centrifugal impeller with a bearing portion interposed therebetween, a stator core arranged to face around the rotor core and a ring member provided at the other end of the rotating shaft, ring member is greater than the specific gravity of the rotor core and formed as Rutotomoni consists of non-magnetic material, the axial length of the ring member made from an end face of the rotor core to an end face of said rotary shaft It is characterized by having been done.

  ADVANTAGE OF THE INVENTION According to this invention, the electric blower which can achieve miniaturization and high efficiency can be provided.

It shows the electric cleaner equipped with the electric blower in this embodiment, (a) is a perspective view when using as a stick type, (b) is a side view when using an electric vacuum cleaner as a handy type. It is a longitudinal cross-sectional view of the cleaner main body equipped with the electric blower in this embodiment. It is an exploded perspective view showing the electric blower in this embodiment. It is an exploded perspective view showing the rotor assembly of the electric blower. It is a side view which shows the electric blower in this embodiment. It is a longitudinal section showing an electric blower in this embodiment. It is a perspective view which shows a centrifugal impeller. 1A is a perspective view, FIG. 2B is a side view, and FIG. 1C is a rear view. It is a perspective view showing the state where the shroud of the centrifugal impeller was removed. It is a longitudinal section of a centrifugal impeller. It is a perspective view when the rotor assembly is seen from the ring member side. It is a schematic diagram which shows the relationship between the blade of a centrifugal impeller and a rotor core. (A) is a perspective view of a guide wing, (b) is a rear view of the guide wing, and (c) is a longitudinal sectional view of the guide wing. It is explanatory drawing which shows the flow of the air in a diffuser. (A) is a perspective view of a fan casing, (b) is a longitudinal sectional view of a fan casing. (A) is a perspective view in which the housing and the bearing cover are integrated, and (b) is a rear view in which the housing and the bearing cover are integrated. It is sectional drawing in the AA of the electric blower of FIG. 16A is a cross-sectional view taken along line BB of FIG. 16A, and FIG. 16B is a cross-sectional view taken along line CC of FIG. It is a perspective view of a bearing cover.

  Hereinafter, embodiments for carrying out the present invention (hereinafter, referred to as “embodiments”) will be described in detail with reference to the drawings as appropriate. In the following, a case in which the present invention is applied to a rechargeable vacuum cleaner 400 that can be used by appropriately switching between a stick type and a handy type will be described as an example. It can be applied to vacuum cleaners.

FIGS. 1A and 1B show a vacuum cleaner equipped with an electric blower according to the present embodiment. FIG. 1A is a perspective view when a stick type is used, and FIG. 1B is a side view when a vacuum type is used as a handy type. is there.
As shown in FIG. 1A, the vacuum cleaner 400 includes a dust collecting chamber 401 for collecting dust and an electric blower 200 (FIG. 2) for generating a suction airflow required for collecting dust. The main body 410, a telescopic pipe 402 provided to be extendable and retractable with respect to the vacuum cleaner main body 410, a grip portion 403 rotatably provided at one end of the telescopic pipe 402, and an electric blower 200 provided to the grip portion 403. And a switch unit 404b (see FIG. 1B) for performing the operations.

  The vacuum cleaner 400 shown in FIG. 1A is in a stick state, in which the telescopic pipe 402 is extended, and the grip portion 403 is turned to the opposite side of the telescopic pipe 402 and locked. Further, a suction body 405 is attached to the other end of the cleaner body 410, and the cleaner body 410 and the suction body 405 are connected to each other by a connection portion 406.

  The vacuum cleaner 400 shown in FIG. 1B is in a handy state, in which the telescopic pipe 402 is stored in the main body 410 of the vacuum cleaner, and the grip portion 403 is rotated toward the telescopic pipe 402. Further, the rotated grip portion 403 is clamped by a clamp member 407 provided on the upper surface of the cleaner body 410. In addition, a suction body (gap nozzle) 408 is attached to the other end of the cleaner body 410, and the cleaner body 410 and the suction body 408 are connected by a connection portion 406.

  In the above-described electric vacuum cleaner 400, by operating the switch unit 404 a (see FIG. 1A) or the switch unit 404 b (see FIG. 1B) of the grip unit 403, the electric motor housed in the cleaner main body 410 is operated. The blower 200 (see FIG. 2) operates to generate a suction airflow. Then, dust is sucked in from the mouthpieces 405 and 408 and collected in the dust collecting chamber 401 of the cleaner main body 410 through the connection portion 406.

FIG. 2 is a vertical cross-sectional view of a cleaner main body equipped with the electric blower according to the present embodiment. FIG. 2 shows a handy state in which the suction body 408 (see FIG. 1B) is removed from the cleaner body 410.
As shown in FIG. 2, an electric blower 200 that generates a suction force, a battery unit 420 that supplies power to the electric blower 200, and a driving circuit 430 are provided inside the cleaner body 410.

  The air sucked in from the mouthpieces 405 and 408 (see FIGS. 1A and 1B) passes through a flow path 440 (see FIG. 1A) provided in the cleaner body 410 and is supplied to the electric blower 200. The dust is sent to the dust collection chamber 401 disposed in the front, and is collected in the dust collection chamber 401. The air after the dust is separated in the dust collection chamber 401 passes through the electric blower 200 and the driving circuit 430, and is discharged to the outside from an exhaust port (not shown) formed in the cleaner body 410.

FIG. 3 is an exploded perspective view showing the electric blower according to the present embodiment.
As shown in FIG. 3, the electric blower 200 is a DC brushless motor, and includes a fan casing 204, guide vanes 205, a housing 208, fixing screws 218 and 219, a rotor assembly 230, a stator 240, and the like.

  An air suction port 206 is formed in the fan casing 204. The guide blade 205 includes a plurality of diffuser blades 13, a diffuser 205 a including a substantially triangular flow path 18, and a return guide 205 b including a plurality of return guide blades 14 on the back surface of the diffuser 205 a. The guide wing 205 is fixed to the housing 208 via a fixing screw 218.

  Stator 240 is fixed to housing 208 via fixing screw 219. The rotor assembly 230 is inserted through the guide wing 205 and the housing 208, and the rotor core 209 provided on the rotor assembly 230 is arranged at a position facing the stator 240.

FIG. 4 is an exploded perspective view showing the rotor assembly of the electric blower.
As shown in FIG. 4, the rotor assembly 230 includes the centrifugal impeller 203, the rotating shaft 207, the rotor core 209, the bearings 212 and 212, the ring member 213, the spring 217, and the cover 250. The bearings are formed by the bearings 212 and 212 and the spring 217.

  The centrifugal impeller 203 is made of a thermoplastic resin, and is fixed to one end (end) of the rotating shaft 207. The rotating shaft 207 has an elongated cylindrical shape, and is made of a magnetic material such as iron. In the present embodiment, the centrifugal impeller 203 is press-fitted and fixed to the rotary shaft 207. However, a screw may be provided at an end (tip) of the rotary shaft 207, and the centrifugal impeller 203 may be fixed by a fixing nut.

  Further, bearings 212, 212 are provided at substantially the center of the rotating shaft 207 in the axial direction G (the direction in which the rotating shaft 207 extends) so as to be separated from each other in the axial direction G (see FIG. 3). Further, a centrifugal impeller 203 is fixed to one end of the rotating shaft 207, and a ring member 213 is fixed to the other end of the rotating shaft 207.

  The cover 250 is formed by forming a non-magnetic thin plate into a cylindrical shape, and is attached in a state of being in contact with the peripheral surface of the rotor core 209 (a state of covering the outer periphery of the rotor core 209). The cover 250 is made of, for example, a material containing 12% or more of nickel in a stainless alloy.

  The cover 250 has a flange 250a bent radially inward at one axial end of the cover 250 itself. When the cover 250 is inserted from one end of the rotating shaft 207, the flange 250 a comes into contact with the end face 209 a of the rotor core 209 and is positioned by being hooked. By covering the rotor core 209 with the cover 250 in this way, it is possible to prevent the rotor core 209 from being damaged and scattered when the rotor core 209 is rotated at a high speed.

  By the way, when the cover 250 is magnetic, the magnetic flux of the rotor core 209 returns to the rotor core 209 through the cover 250, so that the force acting on the rotor core 209 is weakened, and the efficiency of the electric blower 200 is reduced. Therefore, by forming the cover 250 with a non-magnetic material, the magnetic flux of the rotor core 209 can be transmitted to the stator core 210 through the cover 250, and a decrease in the efficiency of the electric blower 200 can be prevented.

  The rotating shaft 207 is provided with a spring 217 between the bearings 212. The bearing 212 includes, for example, an outer ring 212a, an inner ring 212b, and a plurality of balls 212c. The outer ring 212a is fixed to the housing 208, and the inner ring 212b is fixed to the rotating shaft 207. The spring 217 is configured by a coil spring, and urges the outer rings 212a of the bearings 212, 212 in a direction away from each other. Thus, the rattling of the bearing 212 is prevented, thereby suppressing the sound and vibration of the electric blower 200.

FIG. 5 is a side view showing the electric blower according to the present embodiment.
As shown in FIG. 5, the electric blower 200 is roughly divided into a blower unit 201 and a motor unit 202. The blower unit 201 includes a centrifugal impeller 203 (see FIG. 3), a fan casing 204 that houses the centrifugal impeller 203, and guide vanes 205 (see FIG. 3).

  The motor unit 202 is configured to include a rotor core 209 (see FIG. 4) fixed to a rotating shaft 207 (see FIG. 3) housed in a housing 208, and a stator core 210 fixed to the housing 208.

FIG. 6 is a vertical sectional view of the electric blower according to the present embodiment.
As shown in FIG. 6, the stator 240 has a conductor 211 wound around a stator core 210 and together forms a phase winding. This phase winding is electrically connected to a circuit unit (not shown) provided in the electric blower 200.

  The rotor core 209 is provided at an end of the rotating shaft 207 opposite to the end to which the centrifugal impeller 203 is fixed. The rotor core 209 is made of, for example, a rare-earth bonded magnet. A rare earth-based bonded magnet is made by mixing a rare earth-based magnetic powder and an organic binder. As the rare earth bonded magnet, for example, a samarium iron nitrogen magnet, a neodymium magnet, or the like can be used. The rotor core 209 is formed integrally with the rotating shaft 207.

  As described above, by configuring the rotor core 209 with a bonded magnet, the electric blower 200 can be reduced in weight. Further, by using the bond magnet, the ring member 213 can be reduced in weight, and the electric blower 200 can be reduced in weight.

  In the present embodiment, a permanent magnet is used for the rotor core 209. However, the present invention is not limited to this. For example, the rotor core 209 is a type of non-commutator motor that can rotate at a high speed of 80,000 or more per minute. A reluctance motor or the like may be used.

  Bearings 212, 212 are provided on the rotating shaft 207 between the centrifugal impeller 203 and the rotor core 209. The bearings 212, 212 are arranged apart from each other in the axial direction, and rotatably support the rotating shaft 207.

  The ring member 213 is for balance adjustment, and is provided at an end of the rotating shaft 207 on the rotor core 209 side (the other end of the rotating shaft 207). The ring member 213 has a higher specific gravity than the rotor core 209 and is made of a non-magnetic material. The ring member 213 can be formed by, for example, a sintered product (sintered body) such as a copper material or by machining.

  As described above, by forming the ring member 213 from a non-magnetic material such as copper, a magnetic circuit acting when rotating the rotor assembly 230 (a magnetic circuit acting between the rotor core 209 and the stator core 210) is adversely affected. Giving can be prevented. In addition, by using a sintered product of a copper material, the dimensional accuracy can be increased and the production can be performed at low cost.

  The ring member 213 is not limited to copper as long as it has a higher specific gravity than the rotor core 209 and is a non-magnetic material, and may be a stainless alloy, gold, silver, lead, or the like.

  The rotary shaft 207 is provided with a positioning sleeve 214 for the bearing 212 between the bearing 212 on the rotor core 209 side and the rotor core 209.

  The housing 208 is made of a synthetic resin, and has a support portion 26 for fixing a bearing cover 215 including the bearings 212 and 212. In the bearing cover 215, bearings 212, 212, a sleeve 216, and a spring 217 are provided. The spring 217 is arranged in a compressed state, and abuts against the outer races of the bearings 212 and 212 to apply a preload.

  A plurality of cooling fins 27, which are heat sinks for cooling the bearing 212, are provided on the outer periphery of the bearing cover 215 and are long in the rotation axis direction. The bearing cover 215 is made of a non-magnetic metal material, and is integrated with a resin housing 208 by insert molding.

  The support portion 26 of the housing 208 has a screw hole 28 extending in the axial direction G. A fixing screw 218 can be screwed into the screw hole 28, and the guide wing 205 is fixed to the housing 208 by the screwing of the fixing screw 218.

  The housing 208 has an opening 34 through which air flows into the housing 208 and an exhaust port 35 through which air is discharged to the outside of the electric blower 200. Further, the stator core 210 disposed at the end of the housing 208 in the axial direction G is fixed to the housing 208 by fixing screws 219.

  The magnetic center L1 of the rotor core 209 is arranged so as to be displaced in the axial direction G with respect to the magnetic center L2 of the stator core 210. Note that the magnetic center L1 is the center of the rotor core 209 in the axial direction G, and the magnetic center L2 is the center of the stator core 210 in the axial direction G. As a result, a force (a force in the thrust direction) that pulls the rotor core 209 toward the stator core 210 acts, and it is possible to prevent rattling in the axial direction G of the rotor during high-speed rotation, thereby reducing noise and vibration. Further, when the centrifugal impeller 203 rotates at high speed, a force is generated that pulls the rotor assembly 230 toward the centrifugal impeller 203. Since this force and the force generated by shifting the magnetic center are in opposite directions, mechanical loss during high-speed rotation is reduced, and higher efficiency can be achieved. Further, at the time of assembling, when inserting the rotor assembly 230 into the bearing cover 215, a force directed toward the stator core 210 is generated, so that workability can be improved.

FIG. 7 is a perspective view of a centrifugal impeller, FIG. 8 is an external view of a shroud plate constituting the centrifugal impeller, (a) is a perspective view, (b) is a side view, (c) is a rear view, and FIG. 10 is a perspective view showing a state in which a shroud plate is removed from the centrifugal impeller, FIG. 10 is a longitudinal sectional view of the centrifugal impeller, and FIG. 11 is a perspective view when the rotor assembly is viewed from the ring member side.
It is.

  As shown in FIG. 7, the centrifugal impeller 203 includes a shroud plate 1, a hub plate 2, and a plurality of blades 3. The hub plate 2 and the blades 3 are integrally formed of a thermoplastic resin.

  As shown in FIG. 8A, the shroud plate 1 is formed with an annular suction opening 4 for sucking air in the center. The suction opening 4 is formed with a linear portion 5 extending substantially parallel to the rotating shaft 207 (see FIG. 6). The distal end 5a of the straight portion 5 is formed to have a plate thickness (radial direction) smaller than the base end (see FIG. 10).

  As shown in FIG. 8B, the shroud plate 1 is formed with a curved surface portion 6 that turns the axial flow flowing from the suction opening 4 into a radial flow.

  As shown in FIG. 8C, the shroud plate 1 is configured such that the straight portion 5 and the curved surface portion 6 are smoothly connected, and the shroud plate 1 is directed radially from the curved surface portion 6 toward the outer diameter. On the back surface of the shroud plate 1, a concave groove 7 is formed at a position corresponding to the blade 3 from the curved surface portion 6 toward the outer diameter. The concave groove 7 extends from the inner end to the outer end of the shroud plate 1. Further, a through hole 8 is formed in the concave groove 7 so as to fit with a claw 10 (see FIG. 9) formed on each blade 3.

  As shown in FIG. 9, a convex boss 9 into which the rotating shaft 207 (see FIG. 4) is inserted and fixed is formed in the center of the hub plate 2. The blades 3 integrally formed with the hub plate 2 are installed at equal intervals in the circumferential direction, and have a blade shape that retreats in the rotational direction from the radially inner side to the radially outer side. The boss 9 has a curved surface 9a formed radially outward from the shaft side.

  A protruding claw 10 is formed on the upper surface of the blade 3, and a welding rib 11 is formed on the outer diameter side of the claw 10. On the upper surface of the blade 3, an inclined surface 12 is formed on the pressure surface (convex surface) side of the blade 3 so as to be in close contact with the curved surface portion 6 of the shroud plate 1 on the inner diameter side from the claw 10. The shape (cross-sectional shape) of the welding rib 11 may be a triangle, a semicircle, or a trapezoid.

  The claw 10 of the blade 3 is inserted into the through hole 8 of the shroud plate 1 (see FIG. 8A), and the concave groove 7 of the shroud plate 1 (see FIG. 8C) is engaged with the blade 3, The centrifugal impeller 203 is formed by joining the claws 10 and the ribs 11 to the shroud plate by welding.

  The curved surface portion 6 of the shroud plate 1 and the inclined surface 12 of the blade 3 are not welded. Thereby, since welding can be performed only from the substantially axial direction from the curved surface portion 6 of the shroud plate 1 to the outer diameter, the welding can be simplified. The rib 11 is melted in the concave groove 7, but the volume of the rib 11 is made smaller than the volume of the gap when the blade 3 is inserted into the concave groove 7. Therefore, it is possible to suppress the molten resin material from protruding into the flow path of the centrifugal impeller 203.

  Further, in the centrifugal impeller 203, since the welding rib 11 of the blade 3 is melted and welded to the shroud plate 1 in the flow path where the pressure from the vicinity of the center of the flow path to the outlet increases, the distance between the blades 3 Leakage can be prevented.

  Further, on the front edge side of the claw 10 of the blade 3, which is the front edge side of the centrifugal impeller 203, an inclined surface 12 is formed so as to match the shape of the curved surface portion 6 of the shroud plate 1. In the centrifugal impeller 203, particularly, the inlet flow is important, and the curved surface portion 6 of the shroud plate 1 is not welded, so that no burrs or the like are generated on the inclined surface 12 of the blade 3 by welding. . That is, the air can smoothly flow into the blades 3 without disturbing the flow on the inlet side.

  Further, as shown in FIG. 10, in the centrifugal impeller 203, the suction opening 4 (see FIG. 8A) is formed in the shroud plate 1, and the straight portion 5 and the curved surface portion 6 are formed so as to be smooth. At the same time, a curved surface 9a (see FIG. 9) is formed so that the boss 9 on the flow path surface of the hub plate 2 is directed radially from the axial direction G. Therefore, the air flow in the axial direction G flowing from the suction opening 4 can flow into the blades 3 while smoothly turning to the radial flow, and the bending loss at the entrance of the centrifugal impeller 203 can be reduced. .

  In addition, when the centrifugal impeller 203 is operated, the leading edge side works by the centrifugal force so that the curved surface portion 6 of the shroud plate 1 and the inclined surface 12 of the blade 3 come into close contact with each other, so that the blade 3 and the shroud plate 1 There is no gap, and the efficiency of the electric motor unit 202 (electric blower 200) can be improved.

  Further, the centrifugal impeller 203 is made of a thermoplastic resin. It is desirable to use an engineering plastic material having a pressure of 100 MPa or more. For example, polyether ether ketone (PEEK) or PEEK containing carbon fibers is more preferable. This makes it possible to achieve a resin centrifugal impeller 203 that is lighter than a metal centrifugal impeller, secures strength, and can withstand high-speed rotation.

  When the motor unit 202 is driven to rotate the centrifugal impeller 203, air flows in from the air suction port 206 of the fan casing 204 and flows into the centrifugal impeller 203. The inflowing air is pressurized and accelerated in the centrifugal impeller 203 and discharged from the centrifugal impeller 203. The airflow discharged from the centrifugal impeller 203 is guided to the guide blade 205.

  As shown in FIG. 11, the centrifugal impeller 203 has a convex portion 2a formed along the circumferential direction on the outer periphery of the rear surface side of the blade 3 of the hub plate 2 (see FIG. 10). In other words, the outer peripheral portion 203a of the centrifugal impeller 203 is formed to be thicker in the axial direction G than the inner peripheral side. The balance adjustment is performed on each of the manufactured rotor assemblies 230. At this time, the convex portion 2a of the hub plate 2 and the end surface 213a of the balance adjustment ring member 213 attached to the shaft end of the rotary shaft 207 are adjusted. Are corrected in the axial direction G (see holes P1 and P2) to correct the balance.

  Thus, by shaving the outer peripheral edge portion 203a (outer peripheral side) of the centrifugal impeller 203, it is possible to correct the balance with a smaller shaving amount than shaving the inner peripheral side. Further, by forming the ring member 213 with a material having a higher specific gravity than the rotor core 209, the shape of the ring member 213 can be made smaller than in a case where the ring member 213 is made of a resin, and the electric blower 200 can be downsized. Therefore, by providing the ring member 213 at the end of the rotating shaft 207, the amount of unbalance during rotation of the rotating body (rotor assembly 230) can be suppressed, and vibration and noise can be reduced. High efficiency of the electric blower 200 can be achieved. Further, since the balance can be adjusted at both ends (the ring member 213 and the centrifugal impeller 203) of the rotating shaft 207, the balance adjustment becomes easy. As described above, the unbalance amount of the rotating body (the rotor assembly 230) including the centrifugal impeller 203 can be reduced, vibration and noise can be reduced, and high-speed rotation of 80,000 rotations or more per minute can be achieved. The electric blower 200 can be realized.

FIG. 12 is a schematic diagram showing the relationship between the blades of the centrifugal impeller and the rotor core. FIG. 12 shows a state where the shroud plate 1 of the rotor assembly 230 is removed, and also shows a simplified central portion of the centrifugal impeller 203.
As shown in FIG. 12, in the rotor assembly 230, the number of the blades 3 of the centrifugal impeller 203 is eight, and the number of poles of the rotor core 209 is two poles of an N pole and an S pole. As described above, the number of the blades 3 is n times (n is an integer of 1 or more) times the number of poles of the rotor core 209. With this configuration, no matter where the pole position of the rotor core 209 and the radial position of the blade 3 of the centrifugal impeller 203 are assembled, the pole position and the position of the blade 3 rotate for each pole. Because of the symmetry, the force generated by the rotor core 209 is uniformly applied to the blades 3 of the centrifugal impeller 203, so that sound and vibration can be reduced. Note that the number of the blades 3 is n times the number of poles of the rotor core 209, and is not limited to the present embodiment, and can be changed as appropriate.

  Further, a weld 209 b at the boundary between the N pole and the S pole of the rotor core 209 is configured to pass through the axis O of the rotation shaft 207. This makes it possible to reduce the amount of unbalance between the magnetic flux densities of the N pole and the S pole in the rotor core 209, thereby reducing sound and vibration and increasing the efficiency of the electric blower 200.

  Next, the guide wing 205 of this embodiment will be described with reference to FIGS. 13A is a perspective view of the guide vane, FIG. 13B is a rear view of the guide vane, FIG. 13C is a longitudinal sectional view of the guide vane, and FIG. 14 is an explanatory diagram showing a flow in the diffuser.

  As shown in FIG. 13A, the guide blade 205 is made of resin, and has a plurality of diffuser blades 13, a plurality of return guide blades 14 formed downstream of the diffuser blades 13, and a diffuser blade. A partition plate 15 for partitioning between the return guide blade 13 and the return guide blade 14 is integrally formed.

  A rib 13a is formed on an upper surface of the diffuser blade 13, and the rib 13a is in contact with an inner surface 25a (see FIG. 6) of the fan casing 204 (see FIG. 6). On the diffuser 205a side, the fan casing 204, the diffuser blades 13, and the partition plate 15 constitute a diffuser flow path R1 (see FIG. 6).

  In the center of the partition plate 15, a through hole 16a through which the rotor assembly 230 is inserted is formed. In the partition plate 15, a plurality of through holes 16b are formed around the through hole 16a. The guide wing 205 is fixed to the housing 208 by inserting a fixing screw 218 (see FIG. 3) into the through hole 16b and screwing it into the screw hole 28 of the housing 208.

  As shown in FIG. 13B, on the return guide 205b side, the partition plate 15 and the return guide blades 14 constitute a return guide channel R2 (see FIG. 6). A cylindrical projection 17 is formed on the outer periphery of the through hole 16b on the return guide 205b side. The projection 17 and the concave portion 29 (see FIG. 3) of the housing 208 are fitted to each other to prevent leakage to the blower unit 201 (see FIG. 6).

  As shown in FIG. 13 (c), the outer diameter side of the diffuser blade 13 is gradually inclined in the axial direction to form a diffuser flow path R3 inclined in the axial direction (downward in the figure).

  As shown in FIG. 14, the guide vane 205 causes the air flowing out of the gap between the diffuser blade 13 and the diffuser blade 13 to the outer peripheral end side of the diffuser blade 13 to flow toward the return guide blade 14 (see FIG. 13B). A substantially triangular flow path (communication path) 18 is formed. The inflow flow 19 to the diffuser blade 13 is decelerated in a diffuser flow path R1 (see FIG. 3) surrounded by the adjacent diffuser blade 13, the partition plate 15, and the fan casing 204, and hits the inner surface 204b of the fan casing 204. The outflow flow 20 turns in the axial direction G through the flow path 18 having a substantially triangular shape. The outflow flow 20 has a flow component in the swirling direction, and turns the swirl flow into a radially inward flow by the return guide blade 14 (see FIG. 13B).

  The diffuser 205a of the guide vane 205 includes a plurality of diffuser blades 13, and the kinetic energy of the air flow is converted to pressure energy by increasing the speed of the air flow between the blades of the diffuser blade 13 to increase the pressure. The airflow discharged from the diffuser 205a flows into the return guide 205b from the flow path 18 (see FIG. 14) formed between the inner surface of the fan casing 204 and the rear edge of the diffuser 205a. In this embodiment, a diffuser with blades is used, but a diffuser without blades may be used. In that case, a plurality of columns are provided on the outer diameter side of the guide vane to support the fan casing 204.

  The air that has passed through the return guide blades 14 of the return guide 205 b flows into the housing 208 through the opening 34 of the housing 208, cools the cooling fins 27 of the bearing cover 215, and cools the bearing 212 via the bearing cover 215. (See FIG. 6). The air cools the rotor core 209, the stator core 210, and the conductor 211 and is discharged to the outside. Thereby, each part in the housing 208 is cooled. Part of the airflow that has passed through the return guide blades 14 is discharged to the outside through the exhaust port 35 of the housing 208.

  The return guide blade 14 is provided so as to be located at the opening 34 of the housing 208 (see FIG. 6). The flow turned inward in the radial direction by the return guide blades 14 hits the cooling fins 27 of the bearing cover 215 from the opening 34 of the housing 208, and the bearing 212 is effectively cooled. Thereby, the electric blower 200 with high reliability of the bearing 212 can be realized.

  Since the diffuser flow path R1 (see FIG. 6) formed by the fan casing 204, the diffuser blades 13, and the partition plate 15 is gently inclined (see FIG. 13C), it has a substantially triangular shape in plan view. The flow can smoothly flow from the flow path 18 (see FIG. 14) to the return guide blade 14, and the bending loss can be reduced. Thereby, the efficiency of the motor unit 202 can be improved. Further, since the cylindrical projection 17 of the return guide 205b (see FIG. 13C) and the recess 29 of the housing 208 (see FIG. 3) provide sufficient airtightness, the efficiency of the motor 202 can be further improved. Can be.

FIG. 15A is a perspective view of a fan casing, and FIG. 15B is a longitudinal sectional view of the fan casing.
As shown in FIG. 15A, the fan casing 204 has a substantially umbrella shape that covers the centrifugal impeller 203 (see FIG. 3) and the guide blade 205 (see FIG. 3) from the outside. A plate 21 and an annular side plate 22 that extends in the axial direction continuously from the peripheral portion of the upper plate 21 are provided.

  On the side plate 22 of the fan casing 204, a plurality of protrusions 23 are formed at an edge portion on the opposite side to the upper plate 21 side. The protrusions 23 are formed at intervals in the circumferential direction. The projection 23 has a fixing hole 24 for fixing the fan casing 204 to the housing 208. In the present embodiment, three projections 23 are formed, but the number is not limited to three, and four or more projections 23 may be provided.

  As shown in FIG. 15B, an air inlet 206 is formed in the center of the upper plate 21 in the fan casing 204. A concave portion 204a is formed on the inner surface of the edge of the air suction port 206, and the linear portion 5 of the centrifugal impeller 203 is arranged in the concave portion 204a (see FIG. 6). The centrifugal impeller 203 is arranged so as to have a small gap between the fan casing 204 and the tip of the linear portion 5, and reduces the amount of air in which the air pressurized by the centrifugal impeller 203 leaks to the suction opening 4 side of the centrifugal impeller 203. It has a structure. Thereby, the sealing effect can be enhanced, and the efficiency of the electric motor unit 202 can be further improved.

  An airtight holding member 25 using an elastic body is arranged on the inner surface of the upper plate 21 of the fan casing 204. The airtight holding member 25 is made of an elastic material such as rubber or elastomer, and is formed integrally with the fan casing 204. In the present embodiment, the airtight holding member (elastic member) 25 and the fan casing 204 are integrally formed by insert molding. In addition, the gate direction is opposite (outside) to the surface on which the centrifugal impeller 203 is disposed, so that no gate mark remains inside, so that the flow of air is not disturbed. Further, the ribs 13a (see FIG. 13A) provided on the diffuser blades 13 bite into the airtight holding member 25, so that the airtightness between the fan casing 204 and the guide vanes 205 is maintained. Thus, leakage of the guide wing 205 between the diffuser blades 13 can be prevented, and the efficiency of the electric blower 200 can be improved.

  16A is a perspective view in which the housing and the bearing cover are integrated, FIG. 16B is a rear view in which the housing and the bearing cover are integrated, FIG. 17 is a cross-sectional view of the electric blower in FIG. 18A is a cross-sectional view taken along line BB of FIG. 16A, FIG. 18B is a cross-sectional view taken along line CC of FIG. 16A, and FIG. 19 is a perspective view of a bearing cover. .

  As shown in FIG. 16A, the housing 208 is made of a synthetic resin and has a support portion 26 for fixing a bearing cover 215 including the bearings 212, 212 (see FIG. 6). The support portion 26 has a substantially double cylindrical shape, and is located inside a front portion (upper portion in the drawing) of the housing 208.

  As shown in FIG. 16B, a bearing cover 215 made of a non-magnetic metal material is fixed to the substantially cylindrical portion 26a inside the support portion 26. A plurality of cooling fins 27, which are heat sinks for cooling the bearing 212, are provided in the substantially cylindrical portion 26 b on the outer peripheral side of the bearing cover 215, and are formed integrally with the support portion 26 of the housing 208. Since the bearing cover 215 has a complicated shape in which the cooling fins 27 are provided on the outer periphery, the production cost can be suppressed and high dimensional accuracy can be obtained by manufacturing the bearing cover 215 by die casting. As a material to be used for the bearing cover 215 and the cooling fins 27, an aluminum alloy which is a nonmagnetic metal and has a high thermal conductivity is desirable.

  In the present embodiment, the housing 208 is formed by insert molding using the bearing cover 215 as an insert product. A screw hole 28 (see FIG. 16A) extending in the rotation axis direction is formed at an end of the support portion 26 of the resin housing 208. A fixing screw 218 can be screwed into the screw hole 28, and the guide wing 205 is fixedly installed on the housing 208 by screwing the fixing screw 218.

  An annular concave portion 29 is provided on the outer diameter side of the screw hole 28. By fitting the concave portion 29 and the cylindrical convex portion 17 (see FIG. 13B) on the return guide 205b side, it is possible to prevent air leakage from the motor portion 202 side to the blower portion 201 side.

  The outer peripheral portion of the support portion 26 is connected to a substantially cylindrical frame 31 by a bridge 30 (see FIG. 16A). At the end of the frame 31 where the bridge 30 is located, a screw hole 32 for fixing the stator core 210 (see FIG. 6) is provided. A fixing screw 219 can be screwed into the screw hole 32, and the stator core 210 is fixed to the housing 208 by the screwing of the fixing screw 219.

  A claw-shaped projection 33 is provided at an end of the frame 31 on the side of the blower unit 201, and is fitted and connected to the fixing hole 24 of the fan casing 204. By the connection by fitting, not by the adhesive, the positioning accuracy of the fan casing 204 in the axial direction can be secured, whereby the airtightness between the fan casing 204 and the guide blade 205 can be secured. In addition, it is possible to reduce the variation in the gap between the front end of the concave portion 204a of the fan casing 204 (see FIG. 6) and the straight portion 5 of the centrifugal impeller 203 (see FIG. 6), thereby improving the performance of the electric blower 200. , Performance variations can be reduced.

  The housing 208 has openings 34 (see FIG. 16A) formed between the bridges 30 so that air flows into the housing 208, and directs air to the outside without cooling the rotor core 209, the stator core 210, and the conductor 211. An exhaust port 35 (see FIG. 16 (b)) for discharging air is formed at a plurality of locations.

  Inside the frame 31, a plurality of inclined portions 36 (see FIG. 16A) are provided. The air that flows out of the substantially triangular flow path 18 (see FIG. 14) of the guide wing 205 easily flows into the opening 34 by the return guide blade 14 (see FIG. 13B) and the inclined portion 36. ing. The air that has flowed in from the opening 34 flows on a plurality of cooling fins 27 that are heat sinks provided on the bearing cover 215 and that are long in the rotation axis direction. The cooling fin 27 has a rectangular plate shape. The heat generated in the bearing 212 is transmitted through a bearing cover 215 made of a non-magnetic metal material by heat conduction, is radiated by the cooling fins 27, and the bearing 212 is effectively cooled.

  By the way, in the motor section 202, the mechanical loss generated in the bearing 212 is larger than the copper loss generated in the conductor 211 wound around the stator core 210, and it is important to effectively cool the bearing 212. . Even if the housing 208 is made of resin, the bearing 212 can be effectively cooled by dissipating the heat generated by the bearing 212 with a heat sink (cooling fin 27) provided on the bearing cover 215, and a highly reliable electric motor can be provided. A blower 200 can be provided.

  Further, since the housing 208 is made of resin, the weight of the housing 208 can be reduced, and the weight of the electric blower 200 can be reduced. In the present embodiment, the bearing cover 215 and the resin housing 208 are integrated by insert molding, but the bearing cover 215 may be press-fitted into the resin housing 208.

  As shown in FIG. 17, in the bearing cover 215, the cooling fins 27 are arranged at the positions of the openings 34 of the housing 208, but the cooling fins 27 are not arranged on the bridge 30 of the housing 208. The bridge 30 is provided with a rib 26c (see FIG. 16B) instead of the cooling fin 27. The rib 26c connects the substantially cylindrical portions 26a and 26b of the substantially double cylindrical shape of the housing 208 and the bridge 30, and has an effect of increasing the rigidity of the housing 208.

  The air having the swirling flow component flowing out of the flow path 18 (see FIG. 14) having a substantially triangular shape is turned by the return guide blades 14 into a radially inward flow, and the cooling fins of the heat sink are formed. 27, a sufficient cooling effect can be obtained. Accordingly, a sufficient cooling effect can be obtained without providing the cooling fins 27 on the bridge 30, and the number of cooling fins can be reduced as compared with the case where the number of cooling fins is evenly provided in the circumferential direction. The effect of weight reduction can also be achieved.

  As shown in FIGS. 18A and 18B, the housing 208 and the bearing cover 215 are integrated by insert molding. The support portion 26 of the housing 208 has a substantially double cylindrical shape. The axial length of the substantially cylindrical portion 26a on the inner diameter side is substantially the same as the axial length of the cooling fin 27, The axial length of the substantially cylindrical portion 26b on the side is about half the axial length of the cooling fin 27.

  As described above, since the cooling fins 27 are provided on the bearing cover 215, the rigidity is high, and the cooling fins 27 are included by the substantially cylindrical portion 26a inside and the substantially cylindrical portion 26b outside the substantially double cylindrical support portion 26. (In such a manner that the cooling fins 27 cross the inner substantially cylindrical portion 26a and the outer substantially cylindrical portion 26b). Therefore, the rigidity of the bearing cover 215 and the housing 208 can be increased, and high-speed rotation of 80,000 or more per minute can be achieved.

  In the present embodiment, the outer diameter side substantially cylindrical portion 26b is about half the length of the cooling fins 27. However, when the rigidity of the housing 208 is sufficiently high, the outer diameter side is increased in order to enhance the cooling effect. May be shortened, and the length of the cooling fin 27 to which the cooling air is applied may be increased.

  As shown in FIG. 19, a cylindrical reference surface 37 on which the cooling fins 27 are not provided is provided at an axial end of the bearing cover 215. The reference surface 37 is a reference surface when the bearing cover 215 and the resin housing 208 are insert-molded, and serves as a reference when cutting the inner diameter of the outer ring 212a (see FIG. 4) of the bearing 212 (see FIG. 6). . By making the reference surface 37 have a cylindrical shape, it is possible to easily configure the reference surface when the inner diameter is cut by a lathe or the like. In addition, the number of machining points using a lathe or the like can be reduced. As a result, the dimensional accuracy is improved, the center axis of the stator core 210 attached to the housing 208 and the center axis of the rotor core 209 attached to the rotating shaft 207 coincide, and the efficiency of the electric motor unit 202 is improved, and vibration and noise are further improved. It is possible to obtain the electric blower 200 capable of reducing the power consumption.

  In the present embodiment, the reference surface 37 has a cylindrical shape. However, the present invention is not limited to this. The reference surface 37 may have a polyhedral shape, provided that the reference for cutting the inner diameter and the reference for insert molding the housing 208 can be used. Any shape may be used.

  Here, the rotor core 209 is assembled into the housing 208 after being magnetized. However, since the bearing cover 215 is made of a non-magnetic metal, the bearing cover 215 is not affected by the attractive force of the magnet and has excellent assemblability. .

  In the present embodiment, a plurality of cooling fins 27 that are long in the rotation axis direction are provided as heat sinks, and the cooling fins 27 have a rectangular plate shape. However, a large number of pin shapes such as a cylinder, a cone, and a prism are used. It may be. That is, any shape may be used as long as the cooling fins 27 protrude in the circumferential direction so that the cooling fin 27 crosses the inner substantially cylindrical portion 26a and the outer substantially cylindrical portion 26b in order to radiate heat from the bearing. By forming the cooling fins 27 in a pin shape, the volume can be reduced to obtain the same surface area, and the weight can be reduced.

  By mounting the electric blower 200 configured as described above on the electric vacuum cleaner 400, the output of the electric vacuum cleaner 400 can be improved. In addition, when the same output is obtained by improving the efficiency of the motor unit 202, the input of the electric blower 200 can be reduced, and the operation time of the rechargeable vacuum cleaner that uses the battery unit 420 as a drive source can be increased. Can be.

REFERENCE SIGNS LIST 1 shroud plate 2 hub plate 2 a convex portion 3 blade 4 suction opening 5 linear portion 6 curved surface portion 7 concave groove 8 through hole 9 boss 10 protruding claw 11 rib 12 inclined surface 13 diffuser blade 14 return guide blade 15 partition plate 16 penetration Hole 17 Convex part 18 Substantially triangular flow path 19 Inflow to diffuser blade 20 Outflow from diffuser blade 21 Upper plate 22 Side plate 23 Projection 24 Fixing hole 25 Airtight holding member 26 Support 27 Cooling fin 28 Screw hole 29 Concave REFERENCE SIGNS LIST 30 bridge 31 frame 32 screw hole 33 claw-shaped projection 34 opening 35 exhaust port 36 inclined part 37 reference plane 200 electric blower 201 blower part 202 electric motor part 203 centrifugal impeller 203a outer peripheral edge part 204 fan casing 205 guide vane 205a diffuser 205b return Guide 2 06 Suction port 207 Rotating shaft 208 Housing 209 Rotor core 210 Stator core 211 Conductor 212 Bearing 213 Ring member 214 Positioning sleeve 215 Bearing cover 216 Sleeve 217 Spring 218 Fixing screw 219 Fixing screw 230 Rotor assembly 240 Stator 250 cover 400 Vacuum cleaner 410 Cleaning Machine body G Axial direction R1 Diffuser flow path R2 Return guide flow path

Claims (1)

A rotating shaft provided rotatably,
A bearing portion provided substantially at the center in the axial direction of the rotating shaft,
A centrifugal impeller provided at one end of the rotating shaft,
A rotor core provided on the opposite side of the centrifugal impeller across the bearing portion of the rotating shaft,
A stator core disposed to face around the rotor core;
A ring member provided at the other end of the rotating shaft,
Said ring member is greater than the specific gravity of the rotor core, and is composed of a non-magnetic material Rutotomoni, as the axial length of the ring member is the end surface of the rotor core to an end face of said rotary shaft An electric blower characterized by being formed .

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