JP2009228613A5 - - Google Patents

Description

Blower

The present invention relates to a blower called a sirocco fan, a turbo blower , and a turbo fan .

Conventionally, this type of blower has a case body having an impeller housing chamber in which an air inlet is formed in the upper part and a discharge port is formed in a peripheral wall, and the case body rotatably attached to the impeller housing chamber of the case body An impeller using a closed blade that can suck air from an air inlet and discharge it from the outlet, and a fluid dynamic bearing in which the impeller is fixed to a rotating member attached to the case body are used. The air leaking between the motor, the lower support plate of the impeller and the lower wall of the impeller storage chamber is guided to the coil portion of the motor, and discharged from the case body outside the impeller storage chamber to the outside. And an air introduction passage that can be formed.

Since the air blower configured in this manner cools the motor coil with the air leaked between the lower support plate of the impeller and the lower wall of the impeller storage chamber, the air flow rate is small and sufficient cooling of the coil cannot be performed. In addition to the above-described drawbacks, the air blowing efficiency of the blower deteriorates due to leaking air.
JP2007-154774

    In view of the above-described conventional drawbacks, the present invention sucks a part of an air flow generated by driving an impeller so as to pass through the coil portion, and efficiently An object of the present invention is to provide a blower with good blowing efficiency by cooling the coil well and discharging the air flow generated by driving the impeller only from the discharge port.

The above and other objects and novel features of the present invention will become more fully apparent when the following description is read in conjunction with the accompanying drawings.
However, the drawings are for explanation only and do not limit the technical scope of the present invention.

In order to achieve the above object, the present invention has a case body having an impeller housing chamber in which an air inlet is formed at an upper portion and a discharge port is formed in a peripheral wall, and the case body is rotatable in the impeller housing chamber. An impeller using closed blades that can suck air from the attached air inlet and discharge it from the outlet; and a motor in which the impeller is fixed to a rotating member attached to the case body; A plurality of suction through holes formed on the lower support plate of the impeller positioned above the motor coil so that air can be sucked from the coil portion by rotation of the impeller. And an air introduction passage through which air leaking between the lower support plate of the impeller and the lower wall of the impeller storage chamber can be guided to the lower part of the coil of the motor constitutes a blower.

  As is clear from the above description, the present invention has the following effects.

(1) From a case body having an impeller housing chamber in which an air inlet is formed in the upper portion and a discharge port is formed in the peripheral wall, and the air inlet port rotatably mounted in the impeller housing chamber of the case body In a blower comprising an impeller using a closed blade that can suck air and discharge it from the discharge port, and a motor in which the impeller is fixed to a rotating member attached to the case body, A plurality of suction through holes formed on the lower support plate of the impeller positioned above the coil so that air can be sucked from the coil portion by rotation of the impeller, and a lower support of the impeller Since the air leaking between the plate and the lower wall of the impeller housing chamber can be guided to the lower part of the coil of the motor, when the impeller is driven to rotate, Sky In this case, when the air inlet side becomes negative pressure and the inside of the case and the outlet becomes atmospheric pressure, the impeller thrusts toward the air inlet side and the coil is moved from the air inlet passage. The air is guided to the lower part of the air and the air located at the lower part of the coil from the suction through hole can be sucked into the impeller.
For this reason, the coil of the motor can be cooled by the air passing through the air introduction passage and the suction through hole.

(2) According to the above (1), since the air located in the coil portion is sucked from the suction through-hole by the rotational drive of the impeller, the coil can be efficiently cooled.

(3) According to the above (1), by sucking the intake air into the impeller from the suction through hole, it is possible to suppress the force in the thrust direction of the impeller and optimally drive the impeller.

(4) According to the above (1), the air that cools the motor coil passes through the impeller, the air introduction passage, and the suction through hole and returns to the impeller so that the air can be efficiently blown without being discharged from other than the discharge port. Can be made.

(5) In claim 2, the same effects as in the above (1) to (4) can be obtained, and the suction through-hole can be easily formed.

  Hereinafter, the present invention will be described in detail with reference to the best mode for carrying out the invention shown in the drawings.

  In the best mode for carrying out the present invention shown in FIGS. 1 to 12, reference numeral 1 denotes a blower according to the present invention. The blower 1 has an air inlet 2 formed in an upper central portion and a discharge port on a peripheral wall. A case body 5 having an impeller housing chamber 4 formed with 3, a cover body 8 formed with an air suction port 7 fixed by a plurality of screws 6 so as to cover an upper portion of the case body 5, A long closed vane plate 9a capable of sucking air from the air introduction port 2 rotatably mounted in the impeller housing chamber 4 of the case body 5 and discharging it from the discharge port 3, and this long closed vane plate The impeller 9 using a plurality of short closed vane plates 9b in the present embodiment, and a fluid dynamic pressure bearing attached to the case body 5 so that the impeller 9 can be rotated are used. Motor 10 and the motor 10 A plurality of suction transparent holes formed so that air can be sucked from the coil 11 portion by the rotational drive of the impeller 9 to the hub 12 positioned at the top of the cylinder 11 and the lower support plate 13 of the impeller 9. An air introduction passage 16 capable of guiding air leaking between the hole 14 and the lower support plate 13 of the impeller 9 and the lower wall 15 of the impeller housing chamber 4 to the lower portion of the coil 11 of the motor 10; It consists of

  The case body 5 includes a base plate 17, a motor outer wall 19 covering the outer periphery of the motor 10 fixed to the base plate 17 with a plurality of screws 18, a case outer wall 20 positioned on the outer periphery of the base plate 17, and A lower case 21 that covers the lower part of the impeller 9 and constitutes the lower part of the impeller storage chamber 4, and an air inlet 2 is formed in the center part fixed to the upper part of the lower case 21 with a plurality of screws 22. The upper case 23 covers the upper part of the impeller 9 and the cover 8 is attached to the upper part of the upper part of the impeller storage chamber 4.

As shown in FIG. 5, the motor 10 includes a base plate 25 provided with a motor drive circuit (not shown) fixed on the upper surface of the base plate 17 of the case body 5 with a plurality of screws 24, and the base plate. A ring-shaped out magnet 29, an in magnet 30 provided through collars 28 and 28 on a cylindrical magnet holder 27 fitted and fixed in a concave portion 26 formed in the substantially central portion of 17 and the in magnet 30, a rotatable shaft 31, a sleeve 33 fixed to the magnet holder 27 via a fluid dynamic pressure bearing 32 on the outer periphery of the shaft 31, and an upper portion of the shaft 31. The hub 12 is fixed and fixed to the center of the impeller 9 by a bolt 34 at the center, and the back is fixed to the hub 12 at the outer periphery of the sleeve 33. A yoke 35, a coil 11 fixed to the substrate 25 at the outer peripheral portion of the back yoke 35, a yoke 36 fixed to the hub 12 at the outer peripheral portion of the coil 11, and the yoke 36 and the coil 11 The rotor magnet 37 is fixed to the yoke 36 so as to be positioned therebetween.
The hub 12 positioned above the coil 11 has twelve through holes 14a formed at equal intervals constituting one of the suction through holes 14.

  As shown in FIGS. 6 to 9, the impeller 9 includes a boss 39 including a plurality of radial support plates 39a fitted and fixed to a shaft portion 38 of the hub 12 as a rotating member of the motor 10. A lower support plate 13 whose upper surface integrally formed with the boss 39 inclines outward and downward sequentially, and the lower surface is flat in a substantially horizontal direction, and an arc shape is formed so that the height dimension integrally formed with the lower support plate 13 decreases sequentially. A plurality of closed blade plates 9a, an upper cover plate 40 integrally formed so as to cover the upper portions of the multiple closed blade plates 9a, and a lower support plate 13 corresponding to the through hole 14a. The suction through holes 14 formed between the support plates 39a are formed with five through holes 14b at regular intervals.

In the blower 1 configured as described above, when the motor 10 is driven, the impeller 9 rotates at high speed, and air is introduced into the impeller storage chamber 4 from the air suction port 7 of the cover 8 and the air introduction port 2 of the case body 5, and the pressure is increased. Even if it is small and smaller than the discharge port 3, it is discharged with a large air volume and high pressure.
At this time, air leaks between the upper cover plate 40 and the lower support plate 13 of the upper and lower impellers 9 of the impeller storage chamber 4, but the pressure difference of the air leaking from the upper and lower portions is reduced from the suction through hole 14 to the vane. As shown in FIG. 12, the impeller 9 moves up and down so that the air sucked into the car 9 is even, and the inner walls of the upper and lower cases 23 and 21 and the impeller 9 come into contact with each other. The air in the upper part of the coil 11 part is impeller 9 through a plurality of suction through holes 14 comprising a plurality of through holes 14 a of hub 12 and a plurality of through holes 14 b formed in lower support plate 13 of impeller 9. , And a part of the air is guided from the impeller 9 through the air introduction passage 16 between the lower support plate 13 of the impeller 9 and the lower wall of the impeller storage chamber 4. .
For this reason, the coil 11 can be efficiently cooled by the air flowing to the impeller 9, the air introduction passage 16, the suction through hole 14 and the impeller 9, and the air used for cooling the coil 11 is exhausted. Since it is discharged | emitted from the exit 3, it can prevent that air is discharged | emitted wastefully and can aim at the improvement of ventilation efficiency.
In addition, since the air which flows through the coil 11 part increases by raising the rotation speed of the motor 10, the efficient cooling according to the increase in the emitted-heat amount of the coil 11 can be performed.
[Different forms for carrying out the invention]

  Next, different modes for carrying out the present invention shown in FIGS. 13 to 19 will be described. In the description of these different modes for carrying out the present invention, the same components as those in the best mode for carrying out the present invention are designated by the same reference numerals and redundant description is omitted. To do.

The second embodiment for carrying out the present invention shown in FIG. 13 to FIG. 16 is mainly different from the best first embodiment for carrying out the present invention in that the lower support plate 13 of the impeller 9 and This is because the air introduction passage 16A in which a large number of arc-shaped shallow groove concave portions 41 are formed in the rotation direction is formed in the lower wall 15 of the corresponding impeller storage chamber 4 so that air can easily flow to the lower portion of the coil 11. Even with the blower 1A configured using the air introduction passage 16A, the same effects as those of the best first embodiment for carrying out the present invention can be obtained.
The cooling efficiency can be further improved by providing the shallow groove recess 41 on the lower support plate 13 of the impeller 9 or on the side surfaces of the hub 12 and the yoke 36.

  The third embodiment for carrying out the present invention shown in FIGS. 17 to 19 is mainly different from the best first embodiment for carrying out the present invention in that the shaft 31 is fixed to the base plate 17. In addition, the motor 10A in which the hub 12A is fixed to the upper end portion of the sleeve 33 provided via the fluid dynamic pressure bearing 32 is used. The same effects as the first preferred embodiment for carrying out the invention can be obtained.

  The present invention is utilized in an industry for manufacturing a blower used at high speed rotation.

The top view of the best 1st form for implementing this invention. 1 is a front view of the best first embodiment for carrying out the present invention. The left view of the best 1st form for implementing this invention. Sectional drawing in alignment with line 4-4 in FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view of a motor according to a first embodiment for carrying out the present invention. The top view of the impeller of the best 1st form for implementing this invention. The front view of the impeller of the best 1st form for implementing this invention. Sectional drawing which follows the 8-8 line of FIG. The bottom view of the impeller of the 1st best form for implementing this invention. The top view of the hub of the best 1st form for implementing this invention. Sectional drawing which follows the 11-11 line of FIG. Explanatory drawing of the state which cools the coil part of the best 1st form for implementing this invention. The front view of the 2nd form for carrying out the present invention. Sectional drawing which follows the 14-14 line | wire of FIG. The top view of the lower case of the 2nd form for carrying out the present invention. FIG. 16 is a cross-sectional view taken along line 16-16 in FIG. 15; The top view of the 3rd form for carrying out the present invention. FIG. 18 is a sectional view taken along line 18-18 in FIG. 17; Sectional drawing of the motor of the 3rd form for implementing this invention.

1, 1A, 1B: blower, 2: air inlet,
3: discharge port, 4: impeller storage room,
5: Case body, 6: Screw,
7: Air suction port, 8: Cover,
9a: long closed blade, 9: impeller,
10, 10A: Motor, 11: Coil,
12, 12A: Hub, 13: Lower support plate,
14: suction through hole, 15: lower wall,
16, 16A: air introduction passage, 17: base plate,
18: screw, 19: outer wall of motor,
20: Case outer wall 21, 21A: Lower case,
22: Screw, 23: Upper case,
24: Screw, 25: Substrate,
26: recess, 27: magnet holder,
28: Color, 29: Out magnet,
30: Inner magnet, 31: Shaft,
32: Fluid dynamic pressure bearing, 33: Sleeve,
34: Bolt, 35: Back yoke,
36: York, 37: Rotor magnet,
38: Shaft, 39: Boss
40: Upper cover plate, 41: Arc-shaped shallow groove recess.

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