JP2010001839A - Fan motor and electronic apparatus using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve rotation performance by preventing heat generated by a coil for driving a fan provided on a fan motor itself from staying in the fan motor. <P>SOLUTION: This fan motor includes a stator 10, a rotor 20 rotating around a shaft 21 with respect to the stator 10, a fan 3 including a plurality of blade members 4 rotating together with the rotor 20, the coil 13 attached to the stator 10, and a magnet 27 attached to the rotor 20 and generating magnetic field to the coil 13. The rotor 20 includes a cup shape rotor housing 23 comprising a cylinder part 24 having a center on the shaft 21 to surround the coil 13 and the magnet 27 and a ceiling part 25 which is one end surface part provided on an opening part at one end side of the cylinder part 24. A plurality of through-holes 30 enabling flow between an inside and an outside of the cup shape rotor housing 23 are provided on the ceiling part 25. The plurality of through-holes 30 are tapered to make size of hole bigger as it goes from an inside toward an outside. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fan motor that is used in an electronic device or the like and blows air for heat dissipation or the like and an electronic device using the same.

  2. Description of the Related Art Conventionally, electronic devices such as computers and image display devices have been provided with a fan motor for cooling electronic components such as a CPU provided inside the electronic device.

  Such a fan motor includes a stator having a coil and a rotor having a magnet. By energizing the coil, the rotor is rotated about an axis with respect to the stator. The fan motor has a fan attached to the rotor, and rotates the fan integrally with the rotor to blow air inside the electronic device to generate an air flow. The generated heat is discharged to the outside by discharging the generated heat to the outside.

  In such a conventional fan motor, when the rotor is rotated in order to cool the interior of the electronic device, heat is generated in the coil of the fan motor itself by supplying current to the coil.

  The heat generated in such a coil is transferred through the stator housing or the like and dissipated from the case of the fan motor. However, heat proportional to the magnitude of the current supplied to the coil is generated. For this reason, as the magnitude of the supply current increases, the heat generated by the fan motor itself increases, and there is a problem in that the heat dissipation performance for the electronic device is degraded.

  In addition, when the heat generated in the coil is larger than the heat released through the stator housing or the like, heat is accumulated in the stator and the rotor portion where the coil is provided, and the temperature of this portion rises. It is necessary to prevent the operating temperature range from being exceeded. The limitation on the operating temperature range of the coil as described above limits the current value that can be applied to the coil, and it is not possible to flow a large current to obtain a high output as a fan motor. The cooling performance is subject to certain restrictions.

JP 2005-248734 A

  An object of the present invention is to prevent the heat generated in a fan driving coil provided in the fan motor itself from accumulating in the fan motor, thereby improving the rotation performance and an electronic device using the same. To provide equipment.

  A fan motor according to the present invention includes a stator, a rotor that rotates about an axis with respect to the stator, a fan that has a plurality of blade members that rotate together with the rotor, a coil that is attached to the stator, and the rotor. And a magnet for generating a magnetic field with respect to the coil, and the rotor includes a cylindrical portion having a cylindrical shape centered on the shaft so as to surround the coil and the magnet, and one end side of the cylindrical portion. A cup-shaped rotor housing comprising one end surface portion provided in the opening, and the one end surface portion of the rotor housing is provided with a plurality of through holes that circulate inside and outside the cup-shaped rotor housing; The plurality of through holes are tapered so that the size of the holes increases from the inside toward the outside. .

  A fan motor according to the present invention includes a stator, a rotor that rotates about an axis with respect to the stator, a fan that has a plurality of blade members that rotate together with the rotor, a coil that is attached to the stator, and A magnet that is attached to the rotor and generates a magnetic field with respect to the coil, and the rotor includes a cylindrical portion having a cylindrical shape around the shaft so as to surround the coil and the magnet, and one end of the cylindrical portion. A cup-shaped rotor housing having one end surface portion provided in the opening on the side, and the one end surface portion of the rotor housing is provided with a plurality of through-holes that circulate inside and outside the cup-shaped rotor housing. The inner surface of the one end surface portion of the rotor housing is connected to the inner surface from the outer side through the through hole. Distribution gaseous plurality of rising wall to convection within the rotor housing is provided on.

  The electronic device according to the present invention includes a fan motor that generates an air flow inside the housing and dissipates heat generated inside the housing. The fan motor used in the electronic device is as described above. It uses something.

  The present invention can solve the problem that the rotational performance is lowered due to the heat generated in the coil being accumulated because the portion where the coil is provided is conventionally covered by the cup-shaped housing. That is, the present invention prevents the heat generated by the coil from accumulating inside the rotor housing by efficiently circulating air into the rotor housing through a plurality of through holes provided in one end surface portion of the cup-shaped rotor housing. To do. Thereby, this invention implement | achieves that the temperature rise of a coil is prevented and rotational performance is kept high.

  Further, the present invention efficiently circulates air in the rotor housing by the plurality of through holes provided in the one end surface portion of the cup-shaped rotor housing and the plurality of rising walls provided in the inner surface of the one end surface portion. This prevents the heat generated by the coil from accumulating inside the rotor housing. Thereby, this invention implement | achieves that the temperature rise of a coil is prevented and rotational performance is kept high.

  Hereinafter, a fan motor 1 to which the present invention is applied will be described with reference to the drawings.

  As shown in FIGS. 1 and 2, the fan motor 1 to which the present invention is applied includes a fan 3 including a plurality of blade members 4 provided in a main body case 2. Further, as shown in FIG. 3, the fan motor 1 includes a rotor 20 to which the fan 3 is attached and a stator 10 attached to the main body case 2, and serves as a driving unit that rotates the fan 3 relative to the main body case 2. And a motor unit 5.

  The motor unit 5 serving as a driving unit rotates the rotor 20 in a predetermined rotation direction R around the shaft 21 with respect to the stator 10, so that the outer periphery of the rotor 20 with respect to the stator 10 attached to the main body case 2. The fan 3 attached to is rotated.

  The plurality of blade members 4 constituting the fan 3 are arranged side by side on the outer periphery of the rotor 20. The fan 3 is rotated integrally with the rotor 20 by the rotation of the rotor 20, and can blow air that is an internal fluid of the main body case 2 in the axial direction.

  The main body case 2 to which the stator 10 is fixed is provided with an opening 8 serving as an intake port at a position on one side in the axial direction with respect to the rotor 20, that is, for example, on the upper surface portion 6 of the main body case 2. The main body case 2 is provided with an opening 9 serving as an exhaust port at a position on the other side in the axial direction, that is, for example, on the lower surface portion 7 of the main body case 2.

  The fan motor 1 rotates the rotor 20 of the motor unit 5 and the fan 3 fixed thereto with respect to the main body case 2 and the stator 10 fixed thereto. Thereby, as shown in FIG. 1, the fan motor 1 sucks air in the axial direction from the opening 8, sends the sucked air in the axial direction by the fan 3, and discharges it in the axial direction from the opening 9. Become.

  Here, an example in which the fan motor 1 is configured as a so-called axial fan that takes in air from one side in the axial direction and exhausts air toward the other side in the axial direction as described above will be described. It is not limited. That is, the present invention may be applied to a so-called centrifugal fan (sirocco fan) by providing a fan that sucks air from the axial direction and blows and exhausts air in the centrifugal direction.

  Next, the motor unit 5 constituting the fan motor 1 that rotationally drives the above-described fan will be described in detail.

  As shown in FIG. 3, the motor unit 5 includes a stator 10 that is fixed to the main body case 2 and a rotor 20 that is rotated about a shaft 21 that is a rotation shaft with respect to the stator 10. The shaft 21 is integrated with the rotor 20 and is configured as a so-called rotating shaft. The motor unit 5 is provided with a substrate 5a on which various electronic components such as a drive circuit unit are provided.

  The stator 10 is attached and fixed so that the stator housing 11 is integrated with the lower surface portion 7 of the main body case 2. The stator 10 includes a bearing unit 12 that supports a shaft 21 that is a rotating shaft provided on the rotor 20 side, a coil 13 to which a drive current is supplied, and an iron core 14 around which the coil is wound. The bearing unit 12 is fixed by press-fitting or adhering, or press-fitting and adhering into a holder 15 that is formed in a cylindrical shape protruding from the center of the stator housing 11.

  An iron core 14 around which a coil 13 is wound is attached to the outside of a holder 15 that is an outer peripheral portion of the bearing unit 12 that is integrally fixed to the stator housing 11.

  The bearing unit 12 is capable of rotating a radial bearing 16 that supports the shaft 21 that is a rotating shaft in the circumferential direction, and a bearing support portion 22 that is provided at one end portion in the thrust direction of the shaft 21 that is supported by the radial bearing 16. And a thrust bearing 17 to be supported.

  The radial bearing 16 is a sliding bearing that supports the shaft 21 in the circumferential direction. Here, the radial bearing 16 is a sliding bearing, but is not limited to this, and may be, for example, a sintered oil-impregnated bearing or a hydrodynamic bearing. The thrust bearing 17 is formed as a pivot bearing that supports a bearing support portion of a rotating shaft formed in an arc shape or a tapered shape with a point.

  The bearing unit 12 uses a radial bearing 16 and a thrust bearing 17 to support the shaft 21 in a circumferential direction and a thrust direction so as to be rotatable.

  The rotor 20 that constitutes the motor unit 5 together with the stator 10 is attached to a shaft 21 that is rotatably supported by the bearing unit 12, and rotates integrally with the shaft 21 that is the rotating shaft.

  The rotor 20 includes a cup-shaped rotor housing 23 including a cylindrical portion 24 formed in a cylindrical shape with a shaft 21 as a center, and a top plate portion 25 as an end surface portion provided in an opening on one end side of the cylindrical portion 24. And have. The rotor 20 includes a magnetic yoke 26 provided on the inner peripheral surface of the rotor housing 23 and a rotor magnet 27 provided on the inner peripheral surface of the magnetic yoke 26. As described above, the fan housing 3 having a plurality of blade members 4 that rotate integrally with the rotor housing 23 is attached to the outer peripheral surface of the rotor housing 23, or is integrally formed by being molded integrally. Is done. The plurality of blade members 4 are integrally formed by outsert molding on the outer peripheral surface of the rotor housing 23. Further, when the plurality of blade members 4 are provided separately, the plurality of blade members 4 are formed on the outer peripheral surface of the cylindrical boss portion, and the rotor housing 23 is press-fitted into the through hole of the boss portion. Thus, the plurality of blade members are formed integrally with the rotor housing 23.

  A ring-shaped rotor magnet 27 provided on the inner peripheral surface of a magnetic yoke 26 attached to the rotor housing 23 is a magnet in which S and N poles are alternately magnetized in the circumferential direction of the shaft 21. . The rotor magnet 27 is fixed to the inner peripheral surface of the magnetic yoke 26 with an adhesive or the like, for example, and is integrated with the rotor magnet 27. Further, the iron core 14 around which the coil 13 is wound is opposed to the rotor magnet 27 in the radial direction of the rotating shaft.

  In the motor unit 5 having the above-described configuration, a drive current is supplied to the coil 13 on the stator 10 side from the drive circuit unit provided on the substrate 5a of the motor unit 5 with a predetermined energization pattern. Thereby, in the motor unit 5, the rotor 20 rotates integrally with the shaft 21 by the action of the magnetic field generated in the coil 13 and the magnetic field from the rotor magnet 27 on the rotor 20 side. As the rotor 20 rotates, the fan 3 including the plurality of blade members 4 attached to the rotor 20 also rotates together with the rotor 20.

  When the fan 3 is rotated, the fan motor 1 sucks air inside the main body case 2 from the opening 8 and discharges it from the opening 9, thereby causing an air flow in the electronic apparatus in which the fan motor 1 is provided. generate. As a result, the fan motor 1 circulates through a heat sink provided in the housing of the electronic device and exhausts it to the outside of the housing as will be described later, thereby generating heat generated from the heat-generating parts of the electronic device. The heat is dissipated outside to cool the electronic equipment.

  Specifically, the fan motor 1 is provided in an electronic device 100 such as a computer or an image display device as shown in FIG. The electronic device 100 includes a housing 103 having an intake port 101 for allowing air to flow into the inside from the outside of the electronic device 100 and an exhaust port 102 for discharging the air flowing from the intake port 101 to the outside of the electronic device 100. Prepare. The electronic device 100 includes a heat generating component 104 such as a processor or a video memory and the fan motor 1 described above inside the housing 103.

  The fan motor 1 provided in the electronic device 100 rotates the fan 3 in the arrow R direction. The rotated fan 3 sucks air into the fan motor 1 in the axial direction from the opening 8 and discharges air in the axial direction from the opening 9, whereby air flows into the housing 103 of the electronic device 100. Is generated. In other words, the fan motor 1 can blow air in one direction by rotating the fan 3.

  The electronic device 100 including the fan motor 1 can cause air outside the electronic device 100 to flow into the inside from the air inlet 101 as indicated by an arrow D in FIG. 4 due to the air flow generated by the fan motor 1. it can. At the same time, the electronic device 100 can cause the air inside the electronic device 100 to flow out from the exhaust port 102 to the outside by the generated air flow. As described above, the electronic device 100 generates air flow from the intake port 101 to the exhaust port 102 by blowing air in one direction by the fan motor 1. The electronic device 100 can cool the inside of the electronic device 100 by dissipating the heat generated from the heat generating component 104 to the outside of the electronic device 100. That is, the electronic device 100 includes the fan motor 1 that generates an air flow inside the housing 103 to dissipate heat generated inside the housing 103, so that various components inside the electronic device 100 generate heat from the heat generating component 104. Prevents the temperature from rising. And the electronic device 100 can implement | achieve always the performance as the electronic device 100 by keeping the inside of the electronic device 100 at appropriate temperature by the cooling performance of the fan motor 1.

  By the way, as shown in FIG.2 and FIG.3, the top plate part 25 which is the one end surface part of the rotor housing 23 mentioned above so that air can distribute | circulate the inner side and the outer side of the rotor housing 23 formed in the cup shape. A plurality of through holes 30 to be formed are provided. Although not shown here, the top plate portion 25 may be provided with a plurality of concave portions functioning as a balancer for ensuring a balance during rotation of the rotor housing 23 as necessary.

  The through hole 30 provided so as to penetrate the top plate portion 25 has a cross section in the axial direction of the shaft 21 of the hole formed in a substantially circular shape, and each cross section from the inside to the outside of the rotor housing 23. The hole is tapered so that the size of the hole in the shape is increased. When the through-hole 30 is not provided, the air generated in the rotor housing 23 is accumulated in the rotor housing 23 because the air inside the rotor housing 23 does not circulate and the coil 13 provided in the rotor housing 23 is energized. There's a problem. On the other hand, since the through hole 30 is provided so as to be able to flow inside and outside the rotor housing 23, the air inside the rotor housing 23 is allowed to flow between the through hole 30 and the other end side of the cylindrical portion 24. It is possible to circulate through the opening. Thus, the through hole 30 functions as an air circulation hole that takes in a part of the air sucked into the fan motor 1 from the opening 8 into the rotor housing 23. That is, the through hole 30 has a function of preventing heat from accumulating in the rotor housing 23 and preventing heat from accumulating in the fan motor 1 itself by accumulating heat in the rotor housing 23.

  Furthermore, the through hole 30 formed in a tapered shape as described above has a function of facilitating the flow of air existing outside the rotor housing 23 toward the inside of the rotor housing 23 from the characteristics of the fluid. ing. Such a through hole 30 is configured to take in air from the opening 8 provided in the upper surface portion 6 of the main body case 2 and exhaust from the opening 9 provided in the lower surface portion 7 by the fan 3. By being provided in the fan motor 1, the function is further exhibited. That is, in the configuration in which the air flow in the direction of arrow A in FIGS. 1 and 3 is generated in the through hole 30 in the axially lower side from the first opening 8 and toward the rotor housing 23 side, An air flow (in the direction of arrow B) can be generated. As described above, the through hole 30 efficiently directs air existing outside the rotor housing 23 inward and guides the air in the direction of arrow B in the figure to flow in efficiently, thereby efficiently circulating air in the rotor housing 23. Make it possible to do.

  The function of the through hole 30 will be further described. In a cup-shaped rotor housing such as the rotor housing 23, it is considered that by increasing the size and number of through holes, the circulation function inside and outside the rotor housing can be increased and the heat radiation effect can be increased. However, in consideration of the fact that the rotor housing holds a fan composed of a plurality of blade members and is rotated at a high speed, the increase in the hole diameter and the increase in the number of holes are limited in view of the decrease in mechanical strength. In addition, if the thickness of the rotor housing is increased in order to solve this problem, the entire apparatus as a fan motor is prevented from being reduced in size and weight, leading to problems such as an increase in the size and weight of an electronic device equipped with the fan motor. There is a risk.

  The through hole 30 formed in the tapered shape as described above is compared with the same predetermined hole diameter and number of holes from the viewpoint that the rotor housing 23 is a strength member and it is difficult to increase the number of holes and the hole diameter so much. Sometimes, it is possible to perform air blowing and air circulation more efficiently. In addition, the through hole 30 formed in a tapered shape eliminates the problems described here and efficiently prevents the temperature inside the rotor housing 23 and the fan motor 1 itself with a simple configuration as a fan motor. can do.

In addition, the top plate portion 25 of the rotor housing 23 provided with such a through-hole 30 is provided with air that flows from the outside of the rotor housing 23 through the through-hole 30 to the inside surface 25a. A plurality of rising walls 32 are provided for guiding them toward the 21 side.
For example, as shown in FIGS. 3, 5, and 6, the rising wall 32 is formed along the edge 30 a of each through hole 30 formed in a substantially circular shape on the inner surface 25 a of the top plate portion 25. Is formed.

  As shown in FIGS. 5 and 6, the rising wall 32 is formed to rise in a direction orthogonal to the top plate portion 25, that is, in the axial direction, but has a cross-sectional shape orthogonal to the forming direction that is the rising direction. It is formed so as to have a substantially arc shape having a predetermined width. That is, the rising wall 32 cuts the substantially cylindrical shape along the edge 30a of each through-hole 30 by two cutting planes C1 and C2 including the substantially radial direction of this cylindrical shape and the forming direction (rising direction) of the rising wall. (See FIG. 7A). In this case, the substantially cylindrical shape is cut by the flat cut surfaces indicated by C1 and C2, and both end portions thereof are formed in a flat shape, but the end portions are formed in a curved surface shape. You may comprise.

  The rising wall 32 effectively guides air (gas) circulated from the outside to the inside of the rotor housing 23 through the through hole 30 toward the shaft 21 when the rotor 20 is rotated. In order to obtain, it has the characteristic in the formed part. Then, by convection of the air so as to be directed toward the shaft 21 by the rising wall 32, the air is also induced in the coil 13 portion which is a heat generating portion, and a higher cooling effect can be exhibited.

  That is, the rising wall 32 is formed as shown in FIGS. 7A and 7B, for example. The rising wall 32 is a part LPS of the semicircular arc on the side located behind the rotor 20 in the rotation direction of the semicircle divided by the radial line of the shaft 21 in the edge 30 a of the through hole 30. It is formed along. That is, such a rising wall 32 has an inner portion 32a provided on the inner surface side of the circular arc shape facing the rotation direction R in the opposite direction. 7B is a conceptual diagram for explaining the positions of the rising wall 32 shown in FIG. 7A and the positions of both end portions of the rising wall, which will be described later. In FIG. It shows a semicircular arc along the edge 30a.

  The rising wall 32 formed along the above-described portion LPS of the edge 30 a of the through hole 30 has a function of circulating the air that has flowed in from the outside of the rotor housing 23 to the inside. The rising wall 32 can effectively send out air in substantially the same direction as the rotation direction R of the rotor 20 by an inner portion 32 a provided on the arcuate inner surface side of the rising wall 32. The function to circulate can be exhibited more.

  Further, here, the advantage in the case where the rising wall is formed so as to follow the above-described semicircular arc portion LPS has been described, but the rising wall constituting the fan motor 1 to which the present invention is applied is not limited thereto. It is not something that can be done. That is, the rising wall that constitutes the fan motor 1 is configured to circulate the air that has flowed in through the through-hole 30 and to guide it toward the axial center, that is, for example, FIG. You may comprise as shown to 7 (e).

  That is, the rising wall that has substantially the same configuration as the rising wall 32 and can be guided to direct the air that has flowed into the rotor housing 23 through the through hole 30 toward the shaft 21 side is, for example, FIG. You may comprise as the standing wall 33 as shown to c). The rising wall 33 shown in FIG. 7C has the above-described semicircular arc portion LPS as shown in FIG. 7B as a reference arc, and both ends E10 and E20 of the reference arc LPS. It is formed so as to follow an arc whose position at one end is changed. The rising wall 33 is formed so that the end E10 on the side close to the shaft 21 of the both ends E10 and E20 is located at the end E11 located on the rear side in the rotation direction R. That is, the rising wall 33 is formed along the arc portion L1 having the end E11 and the end E20 described above.

  Further, a rising wall that has substantially the same configuration as that of the rising wall 32 and can be guided to direct the air that has flowed in through the through hole 30 toward the shaft 21 is, for example, as shown in FIG. The rising wall 34 may be configured. The rising wall 34 shown in FIG. 7 (d) changes the position of the other end of both ends E10, E20 of the reference arc LPS with respect to the reference arc LPS as shown in FIG. 7 (b). It is formed along the circular arc. The rising wall 34 is formed so that the end portion E20 on the side away from the shaft 21 of the both end portions E10 and E20 is located at the end portion E21 located on the front side in the rotation direction R. That is, the rising wall 34 is formed along the arc portion L2 having the end E21 and the end E10 described above.

  Furthermore, a rising wall that has substantially the same configuration as the rising wall 32 and can be guided to direct the air that has flowed in through the through hole 30 toward the shaft 21 side is, for example, as shown in FIG. The rising wall 35 may be configured. The rising wall 35 shown in FIG. 7E is along an arc in which the positions of both ends E10, E20 of the reference arc LPS are changed with respect to the reference arc LPS as shown in FIG. 7B. Formed as follows. The rising wall 35 is formed along the arc portion L3 having the end portions E11 and E21 described above.

  Like the rising wall 32, the rising walls 33, 34, and 35 of the modified example described above have a function of further circulating the air that has flowed in from the outside of the rotor housing 23 through the through holes 30. Furthermore, the rising walls 33, 34, and 35 can effectively send out air toward the shaft side with respect to the rotational direction R of the rotor 20 by the inner portion provided on the arcuate inner surface side, and the rotor housing The function of circulating the air inside 23 can be exhibited more.

  In the above description, the advantages of the rising walls 32, 33, 34, and 35 formed along the arc portions LPS, L1, L2, and L3 have been described. However, the rising walls constituting the fan motor 1 to which the present invention is applied. Is not limited to this. That is, the rising wall constituting the fan motor 1 is configured to circulate the air that has flowed in through the through-hole 30 and to guide it toward the axial center, for example, as shown in FIGS. 8 and 9. Alternatively, a curved shape may be formed.

  The rising wall 36 shown in FIGS. 8 and 9 is provided for each through hole 30, and in the cross-sectional shape orthogonal to the axis, of the edge part of each through hole 30, the portion located at the rearmost in the rotational direction of the rotor Is formed in a curved shape from the base end portion formed along the front side toward the front side in the rotation direction. Specifically, the rising wall 36 has a curvature larger than the radius of the hole shape of the through hole 30 from the base end portion 36a to the tip end portion 36b positioned on the front side in the rotation direction with respect to the base end portion 36a. And is formed in a curved shape toward the front side in the rotation direction. Here, the curvature is larger than the radius of the hole shape, but when the hole shape of the through hole 30 is not circular, the curvature is larger than the radius of the circle larger than the hole shape of the through hole 30. It is made to have.

  The rising wall 36 is formed such that, in a cross-sectional shape perpendicular to the axis, the distal end portion 36b passes through the base end portion 36a and is located on the inner side of a circle centering on the axis. That is, the distance between the distal end portion 36b and the axial center is formed to be smaller than the distance between the proximal end portion 36a and the axial center. With this configuration, the rising wall 36 can send air from the base end portion 36a side toward the tip end portion 36b, that is, toward the shaft side with respect to the rotation direction R. 8 and 9, the numbers of the through holes 30 and the rising walls 36 are not limited to this.

  Like the rising walls 32, 33, 34, and 35, the rising wall 36 of the modified example described above has a function of further circulating the air that has flowed in from the outside of the rotor housing 23 through the through hole 30. Have. Furthermore, the rising wall 36 can send out air toward the shaft more with respect to the rotation direction R of the rotor 20, and can further exhibit the function of circulating the air inside the rotor housing 23.

  As described above, the fan motor 1 to which the present invention is applied includes the stator 10, the rotor 20, the fan 3, the coil 13, and the rotor magnet 27, and a through hole having a taper in the top plate portion 25 of the rotor housing 23 of the rotor 20. It is characterized in that 30 is provided. This fan motor 1 solves the problem that the rotational performance is deteriorated due to the heat generated in the coil being accumulated because the portion provided with the coil is conventionally covered by the cup-shaped housing by the through hole 30. it can. That is, the fan motor 1 has an arrow B that is guided into the rotor housing through the through hole 30 from the air flow that flows into the fan motor 1 in the direction of arrow A due to the rotation of the fan 3 by the through hole 30 having a taper. The amount of air in the direction can be generated. The fan motor 1 can prevent the heat generated by the coils from accumulating inside the rotor housing 23 by efficiently circulating air into the rotor housing 23 through the through hole 30. As described above, the fan motor 1 prevents the heat generated by the coil from accumulating inside the rotor housing 23, thereby preventing the coil temperature from rising and maintaining a high rotational performance. Therefore, the fan motor 1 realizes a high cooling performance as a fan motor.

  In addition to the through hole 30, the fan motor 1 to which the present invention is applied is configured such that the air that has flowed inward through the through hole 30 into the inner surface 25 a of the top plate portion 25 of the rotor housing 23 is transferred to the rotor housing 23. It has a feature in that it has a rising wall for convection inside. The fan motor 1 having the through hole 30 and the rising walls 32, 33, 34, 35, and 36 described above can further circulate the air inside the rotor housing 23. That is, the fan motor 1 is configured such that the air that has flowed into the rotor housing 23 through the through hole 30 is rotated around the rotation direction of the rotor 20 by the rising wall 32 or the like. 13 side. Thereby, the fan motor 1 can circulate air efficiently in the rotor housing 23, and can prevent heat from being accumulated in the rotor housing 23. Therefore, the fan motor 1 more effectively prevents heat from accumulating inside the rotor housing 23, and prevents the temperature of the coil from rising and maintains high rotation performance and cooling performance.

  The fan motor to which the present invention is applied is not limited to the above. For example, the fan motor may be configured to have a plurality of grooves instead of the above-described rising wall 32 or in addition to the above-described rising wall 32 or the like. Good.

  Next, an example in which the rotor housing 23 is provided with a groove portion 38 having a V-shaped cross section, for example, will be described with reference to FIG. In the example described with reference to FIG. 10, the rising wall is not provided. However, in addition to the groove portion 38, any of the above-described rising walls 32, 33, 34, 35, 36 is provided. May be.

  As shown in FIGS. 10A and 10B, the inner surface of the rotor housing 23 is provided with a plurality of grooves 38 formed along a circular shape so as to surround each through hole 30. ing. As shown in FIG. 10C, the groove 38 is formed such that the cross-sectional shape in the formation direction of each groove is substantially V-shaped.

  This groove portion 38 prevents turbulent flow from occurring in the airflow that flows into the rotor housing 23 through the through hole 30. That is, the groove part 38 can prevent air from flowing by suppressing the air separation in the groove part 38 and the generation of vortices. Thus, by preventing the generation of vortices, that is, the generation of turbulent flow, noise due to the turbulent flow can be reduced. In addition, the groove part provided in the rotor housing 23 which comprises this fan motor 1 is not restricted to V shape, You may comprise so that it may be formed in curved shape including a substantially rectangular cross section, a semicircle, etc. . The groove formed so as to surround each of the through holes 30 can be configured to resonate and absorb sound by, for example, resonating sound generated by turbulent flow or the like with air in the groove. is there.

  As described above, the fan motor 1 to which the present invention is applied has a plurality of groove portions formed on the inner surface 25a of the top plate portion 25 of the rotor housing 23 so as to surround the through holes 30 in addition to the through holes 30. It is characterized by having 38. And the fan motor 1 which has the through-hole 30 and the groove part 38 can prevent the noise by the air which flowed in through the through-hole 30, in order to exhibit the above heat dissipation effects. In other words, the fan motor 1 prevents the vortex and turbulent flow from being generated in the air flow that has flowed in through the through hole 30 by the groove portion 38 and reduces noise due to the turbulent flow. Therefore, the fan motor 1 prevents heat from being accumulated in the rotor housing 23 by the through hole 30, maintains high rotation performance and cooling performance, and prevents generation of noise and the like.

  As described above, the fan motor having the groove portion 38 may also be configured to provide any of the above-described rising walls 32 to 36. In this case, in addition to the noise reduction effect by having the groove portion 38, the effect of preventing the coil temperature from rising can be obtained by increasing the air circulation function by the rising wall. When the groove 38 and the rising wall are provided, the rising wall may be formed outside the groove 38, or the groove may be formed outside the rising walls 32 to 36. For example, in the case of providing the groove 38 and a rising wall having the same shape as the rising wall 32, for example, as shown in FIGS. 11A and 11B, the groove formed so as to surround the through hole 30. 38 is configured to form a rising wall along the outer edge 38a.

  Further, the fan motor to which the present invention is applied is not limited to the above, and for example, the top plate portion of the rotor housing 23 may be provided with a tapered shape.

  Next, the example which provided the top plate part 40 which has the cyclic | annular recessed part 41 formed in the rotor housing 23, for example with a taper is demonstrated using FIGS. In the example described with reference to FIGS. 12 to 15, the configuration is the same as described above except that the top plate portion 40 is provided instead of the top plate portion 25 shown in FIG. 3 described above. Constituent parts are denoted by common reference numerals and detailed description thereof is omitted. FIG. 13 shows the X1-X2 cross section shown in FIG.

  As shown in FIGS. 12 to 14, taper portions 41 a and 41 b are provided on the outer surface 40 b of the top plate portion 40 as one end surface portion provided in the opening on one end side of the cylindrical portion 24 of the rotor housing 23. The recessed part 41 formed in this way is formed. The recess 41 has a substantially annular shape (ring shape) in a plane perpendicular to the axis.

  As shown in FIGS. 13 and 14, the top plate portion 40 is formed in a plurality of positions that are located in the recess 41 so that air can flow through the inside and outside of the rotor housing 23 described above. A through hole 30 is provided. Further, the top plate portion 40 is formed with a recess 41 on the outer surface 40b, so that a protrusion 42 is formed on the inner surface 40a at a position corresponding to the recess 41. As shown in FIGS. 14 and 15, the top plate portion 40 is air circulated from the outer side to the inner side of the rotor housing 23 through the through hole at a position corresponding to the concave portion 41 on the inner surface 40 a. Are provided with a plurality of rising walls 32 that guide the shaft toward the shaft 21 side. Here, the protrusions 42 are provided on the inner surface 40a so that the thickness of the top plate portion 40 is substantially uniform. However, the inner surface is not limited to this, and is substantially flat. You may form in a shape. Here, the rising wall 32 is provided on the protrusion 42 of the inner surface 40a. However, when the inner surface 40a is formed in a flat shape, the rising wall 32 corresponds to the recess 41 of the inner surface 40a. This rising wall 32 is formed at the position. Also, the rising wall provided here is not limited to this, and may be configured to form the above-described rising walls 33 to 36 or other shapes of rising walls.

  Further, the taper portions 41 a and 41 b provided on the outer surface 40 b of the top plate portion 40 of the rotor housing 23 are formed in the same direction although the angles are different from those of the taper formed in the through hole 30. Thereby, the taper portions 41 a and 41 b of the rotor housing 23 have a function of facilitating the flow of air existing outside the rotor housing 23 toward the inside of the rotor housing 23 from the characteristics of the fluid. And this taper part 41a, 41b formed by providing the recessed part 41 has an effect which reinforces the function which makes the air of the through-hole 30 flow easily into an inside. As a result, the taper portions 41a and 41b and the through-hole 30 can more efficiently blow air from the outside to the inside of the rotor housing 23, that is, perform efficient air circulation in the rotor housing 23. That is, the taper portions 41a and 41b and the through hole 30 have a simple configuration as a fan motor, and can efficiently prevent the temperature inside the rotor housing 23 and the fan motor 1 itself. Furthermore, by providing the through hole 30 in the region where the concave portion 41 is provided, it is possible to make the distance between the through hole 30 and the coil 13 as the heat generating portion closer. In other words, the recess 41 and the through hole 30 can blow air that is guided into the rotor housing 23 through the through hole 30 toward the coil 13, thereby efficiently preventing a temperature rise in the rotor housing 23. be able to.

  As described above, in the fan motor 1 to which the present invention is applied, the through hole 30 is within the range in which the annular recess 41 formed with the tapered portions 41a and 41b on the top plate portion 40 of the rotor housing 23 is provided. By being positioned, the following effects are obtained. That is, the fan motor 1 has air that is guided into the rotor housing 23 through the through hole 30 from the air flow that flows into the fan motor 1 by the rotation of the fan 3 by the through hole 30 and the tapered portions 41a and 41b. The amount can be generated more effectively. The fan motor 1 can prevent the heat generated by the coils from accumulating in the rotor housing 23 by efficiently circulating air into the rotor housing 23 through the through holes 30 and the like. Further, the fan motor 1 can efficiently blow air through the heat generation part such as the coil 13 by the recess 41 and the through hole 30, and can effectively prevent the temperature of the rotor housing 23 from rising. As described above, the fan motor 1 prevents the heat generated by the coil from accumulating inside the rotor housing 23, thereby preventing the temperature of the coil from rising and maintaining high rotation performance and cooling performance.

  Further, the fan motor 1 has the rising wall 32 in addition to the tapered portions 41a and 41b and the through hole 30, so that the air inside the rotor housing 23 can be circulated more. That is, the fan motor 1 can efficiently circulate air in the rotor housing 23, thereby realizing further reduction in coil temperature rise and high rotation performance / cooling performance.

  Note that the fan motor of the example described with reference to FIGS. 12 to 15 may be configured to provide the rising walls 33 to 36 instead of the rising wall 32, and may be configured to provide the groove 38. May be. In such a case, in addition to the effects of the tapered portions 41a and 41b described here, the above-described effects of the rising walls 33 to 36 and / or the groove portion 38 are obtained.

  Moreover, the taper shape provided in a top-plate part in the fan motor to which this invention is applied is not restricted above, For example, you may comprise as follows.

  Next, the example which provided the top-plate part 45 which has the some recessed part 46 formed in the rotor housing 23, for example with a taper is demonstrated using FIGS. 16-18. In the example described with reference to FIGS. 16 to 18, the configuration other than the top plate portion 45 is the same as described above, and thus detailed description thereof is omitted. Moreover, since the cross-sectional view in the example in which the top plate portion 45 is provided is the same as FIG. 12 showing the cross-sectional view in the case where the top plate portion 40 is provided, the description is omitted here. FIG. 16 shows an X3-X4 cross section shown in FIG.

  As shown in FIGS. 16 to 18, the outer surface 45 b of the top plate portion 45 as one end surface portion provided in the opening on one end side of the cylindrical portion 24 of the rotor housing 23 is provided for each through-hole 30 described later. A plurality of concave portions 46 formed with tapered portions 46a are formed. Each of the recesses 46 has a substantially circular shape in a plane orthogonal to the axis.

  As shown in FIGS. 16 to 18, the top plate portion 45 is positioned in the plurality of recesses 46 so that air can flow inside and outside the rotor housing 23 described above. A plurality of through holes 30 to be formed are provided. Further, the top plate portion 45 is formed with a concave portion 46 on the outer surface 45 b, and a projection 47 is formed on the inner surface 45 a at a position corresponding to the concave portion 46. In addition, although the top plate part 45 demonstrated here demonstrates the example which does not provide a rising wall, it is comprised so that the rising walls 32-36 and the groove part 38 may be provided similarly to the top plate parts 25 and 40 mentioned above. The above-described effects can be obtained by adopting such a configuration.

  The taper portion 46 a provided on the outer surface 45 b of the top plate portion 45 of the rotor housing 23 is formed in the same direction as the taper formed in the through hole 30. The angle of the tapered portion 46a may be the same as or different from the angle of the taper formed in the through hole 30. In other words, the taper portion 46a of the rotor housing 23 has a function of facilitating the flow of air existing outside the rotor housing 23 toward the inside of the rotor housing 23 from the characteristics of the fluid. . And this taper part 46a formed by providing the recessed part 46 has the effect which reinforces the function which makes the air of the through-hole 30 flow easily into an inside. As a result, the tapered portion 46a and the through hole 30 can more effectively blow air from the outside to the inside of the rotor housing 23, that is, perform efficient air circulation in the rotor housing 23. That is, the taper portion 46a and the through hole 30 have a simple configuration as a fan motor, and can efficiently prevent the temperature inside the rotor housing 23 and the fan motor 1 itself. Furthermore, by providing the through hole 30 in the region where the recess 46 is provided, the distance between the through hole 30 and the coil 13 that is the heat generating portion can be made closer. In other words, the recess 46 and the through hole 30 can blow air directed to the rotor housing 23 through the through hole 30 toward the coil 13, and efficiently prevent a temperature rise in the rotor housing 23. be able to.

  As described above, in the fan motor 1 to which the present invention is applied, the through holes 30 are provided so as to be positioned in the plurality of concave portions 46 formed on the top plate portion 45 of the rotor housing 23 with the tapered portions 46a. Having the following effects. The fan motor 1 has a more effective amount of air introduced into the rotor housing 23 through the through hole 30 from the air flow introduced into the fan motor 1 by the rotation of the fan 3 by the through hole 30 and the tapered portion 46a. Can be generated automatically. The fan motor 1 can prevent the heat generated by the coils from accumulating in the rotor housing 23 by efficiently circulating air into the rotor housing 23 through the through holes 30 and the like. Further, the fan motor 1 can efficiently blow air through the heat generation part such as the coil 13 by the recess 46 and the through hole 30, and can effectively prevent the temperature of the rotor housing 23 from rising. As described above, the fan motor 1 prevents the heat generated by the coil from accumulating inside the rotor housing 23, thereby preventing the temperature of the coil from rising and maintaining high rotation performance and cooling performance.

  Furthermore, the taper shape provided in the top plate part in the fan motor to which the present invention is applied is not limited to the above, and may be configured as follows.

  Next, an example in which the top plate portion 50 having a circular protrusion 51 formed with a taper, for example, is provided on the rotor housing 23 will be described with reference to FIG. In the example described with reference to FIG. 19, the configuration other than the top plate portion 50 is the same as described above, and thus detailed description thereof is omitted.

  As shown in FIG. 19, a circle 50a having a tapered portion 51a is formed on the outer surface 50b of the top plate portion 50 as one end surface portion provided in the opening on one end side of the cylindrical portion 24 of the rotor housing 23. A protruding portion (convex portion) 51 having a shape is formed. The protrusion 51 has a substantially circular shape in a plane perpendicular to the axis, and a circular shape centered on the axis center.

  The top plate portion 50 is located at a position close to the outside of the region where the tapered portion 51a of the protrusion 51 is provided so that air can flow through the inside and outside of the rotor housing 23 described above. A plurality of through holes 30 are provided. In addition, the top plate portion 50 is a surface 50a on the inner side, and the air circulated from the outer side of the rotor housing 23 through the through hole 30 to the position where the through hole 30 is provided on the shaft 21 side. A plurality of rising walls 32 are provided to guide the head toward the surface. The rising wall provided here is not limited to this, and may be configured to form the above-described rising walls 33 to 36 or other shapes of rising walls. Furthermore, you may comprise so that the groove part 38 mentioned above may be provided. By providing these, the above-described effects can be obtained.

  A tapered portion 51 a provided on the outer surface 50 b of the top plate portion 50 of the rotor housing 23 is formed in the same direction as the taper formed in the through hole 30. The angle of the taper portion 51 a may be the same as or different from the taper angle formed in the through hole 30. In other words, the tapered portion 51a of the rotor housing 23 thus has a function of facilitating the flow of air existing outside the rotor housing 23 toward the inside of the rotor housing 23 from the characteristics of the fluid. . And this taper part 51a formed by providing the protrusion 51 has the effect which reinforces the function which makes the air of the through-hole 30 flow easily into an inside. Thereby, the taper part 51a and the through-hole 30 enable air to be blown from the outside to the inside of the rotor housing 23 more effectively, that is, efficient air circulation in the rotor housing 23 can be performed. That is, the taper part 51a and the through-hole 30 have a simple configuration as a fan motor, and can efficiently prevent the temperature inside the rotor housing 23 and the fan motor 1 itself.

  As described above, in the fan motor 1 to which the present invention is applied, the through holes 30 are provided so as to be positioned in the protrusions 51 formed on the top plate portion 50 of the rotor housing 23 with the tapered portions 51a. Thus, the following effects are obtained. The fan motor 1 has a more effective amount of air introduced into the rotor housing 23 through the through-hole 30 from the air flow introduced into the fan motor 1 by the rotation of the fan 3 due to the through-hole 30 and the tapered portion 51a. Can be generated automatically. The fan motor 1 can prevent the heat generated by the coils from accumulating in the rotor housing 23 by efficiently circulating air into the rotor housing 23 through the through holes 30 and the like. As described above, the fan motor 1 prevents the heat generated by the coil from accumulating inside the rotor housing 23, thereby preventing the temperature of the coil from rising and maintaining high rotation performance and cooling performance.

  Further, the fan motor 1 has the rising wall 32 in addition to the tapered portion 51 a and the through hole 30, whereby the air inside the rotor housing 23 can be circulated more. That is, the fan motor 1 can efficiently circulate air in the rotor housing 23, thereby realizing further reduction in coil temperature rise and high rotation performance / cooling performance.

  Although the fan motor described with reference to FIGS. 1 to 19 has been described as having a through hole 30 formed in a tapered shape, the fan motor to which the present invention is applied is not limited thereto. . That is, the fan motor to which the present invention is applied may be configured to have a through hole and a rising wall that are formed in a substantially cylindrical shape instead of a tapered shape.

  Next, the example which provided the cylindrical through-hole 60 in the top-plate part 25 of the rotor housing 23 is demonstrated using FIG.20 and FIG.21. 20 and 21 is the same as that described above except that a through hole 60 is provided instead of the through hole 30 in the fan motor described with reference to FIGS. 1 to 19 described above. Therefore, the same components are denoted by common reference numerals and detailed description thereof is omitted.

  As shown in FIGS. 20 and 21, the top plate portion 25, which is one end surface portion of the rotor housing 23, is formed so that air can flow inside and outside the rotor housing 23 formed in a cup shape. A plurality of through holes 60 are provided.

  The through hole 60 provided so as to penetrate the top plate portion 25 has a cross section in the axial direction of the shaft 21 of the hole formed in a substantially circular shape, and each cross sectional shape from the inside to the outside of the rotor housing 23. The holes are formed in a cylindrical shape so that the sizes of the holes are substantially equal. When the through hole 60 is not provided, the air generated in the rotor housing 23 is accumulated in the rotor housing 23 because the air inside the rotor housing 23 does not circulate, and the coil 13 provided in the rotor housing 23 is energized. There's a problem. On the other hand, since the through hole 60 is provided so as to be able to circulate inside and outside the rotor housing 23, air inside the rotor housing 23 is allowed to pass through the through hole 60 and the other end side of the cylindrical portion 24. It is possible to circulate through the opening. Thus, the through hole 60 functions as an air circulation hole that takes in a part of the air sucked into the fan motor 1 from the opening 8 into the rotor housing 23. That is, the through hole 60 has a function of preventing heat from accumulating in the rotor housing 23 and preventing heat from accumulating in the fan motor 1 itself by accumulating heat in the rotor housing 23.

  In addition, the top plate portion 25 of the rotor housing 23 provided with such a through hole 60 is provided with air that flows from the outside to the inside of the rotor housing 23 through the through hole 60 on the inner surface 25a. A plurality of rising walls 32 are provided for guiding them toward the 21 side. As shown in FIGS. 20 and 21, the rising wall 32 is formed along the edge portion 60 a of each through hole 60 formed in a substantially circular shape on the inner surface 25 a of the top plate portion 25.

  As shown in FIG. 21, the rising wall 32 is formed so as to rise in a direction orthogonal to the top plate portion 25, that is, in the axial direction, but the cross-sectional shape orthogonal to the forming direction that is the rising direction has a predetermined width. It is formed so that it may become the substantially circular arc shape which has. The rising wall 32 has the same configuration as that described with reference to FIG.

  The rising wall 32 can effectively guide the air circulated from the outside to the inside of the rotor housing 23 through the through hole 60 toward the shaft 21 side when the rotor 20 is rotated. , Has a characteristic in the portion to be formed. Then, by convection of the air so as to be directed toward the shaft 21 by the rising wall 32, the air is also induced in the coil 13 portion which is a heat generating portion, and a higher cooling effect can be exhibited.

  That is, the rising wall 32 is, for example, a semicircle on the side located behind the rotational direction of the rotor 20 in the semicircle divided by the radial line of the shaft 21 in the edge portion 60 a of the through hole 60. It is formed along the arc portion LPS (see FIGS. 7A and 7B). That is, such a rising wall 32 has an inner portion 32a provided on the inner surface side of the circular arc shape facing the rotation direction R in the opposite direction.

  The rising wall 32 formed along the above-described portion LPS of the edge 60 a of the through hole 60 has a function of circulating the air that has flowed in from the outside to the inside of the rotor housing 23. The rising wall 32 can effectively send out air in substantially the same direction as the rotation direction R of the rotor 20 by an inner portion 32 a provided on the arcuate inner surface side of the rising wall 32. The function to circulate can be exhibited more.

  Further, here, the advantage in the case where the rising wall is formed so as to follow the above-described semicircular arc portion LPS has been described, but the rising wall constituting the fan motor 1 to which the present invention is applied is not limited thereto. It is not something that can be done. That is, the rising wall constituting the fan motor 1 may be configured to guide the air flowing in through the through hole 60 to circulate more and be directed toward the axial center. Instead of the rising wall 32, for example, any of the rising walls 33 to 36 described with reference to FIGS. 7B to 7E, 8 and 9 may be provided.

  As described above, the fan motor 1 to which the present invention is applied includes the stator 10, the rotor 20, the fan 3, the coil 13, and the rotor magnet 27. A cylindrical through hole is formed in the top plate portion 25 of the rotor housing 23 of the rotor 20. It is characterized in that 60 is provided. This fan motor 1 solves the problem that the rotational performance is lowered due to the heat generated in the coil being accumulated because the through-hole 60 previously covered the portion where the coil was provided by the cup-shaped housing. it can. The fan motor 1 can prevent the heat generated by the coils from accumulating inside the rotor housing 23 by circulating air into the rotor housing 23 through the through hole 60. As described above, the fan motor 1 prevents the heat generated by the coil from accumulating inside the rotor housing 23, thereby preventing the coil temperature from rising and maintaining a high rotational performance. Therefore, the fan motor 1 realizes a high cooling performance as a fan motor.

  In addition to the through hole 60, the fan motor 1 to which the present invention is applied has the air that flows inward through the through hole 60 into the inner surface 25 a of the top plate portion 25 of the rotor housing 23. It has a feature in that it has a rising wall for convection inside. The fan motor 1 having the above-described through hole 60 and rising walls 32, 33, 34, 35, 36 can circulate the air inside the rotor housing 23 more. In other words, the fan motor 1 has the air in the direction of arrow B guided into the rotor housing through the through hole 60 from the air flow that flows into the fan motor 1 in the direction of arrow A due to the rotation of the fan 3 by the rising wall 32 or the like. Amount can be generated. And this fan motor 1 is a coil which is the rotation center side with respect to the rotation direction or rotation direction of the rotor 20 with respect to the rotation direction or rotation direction of the rotor 20 by the rising wall 32 or the like. 13 side. Thereby, the fan motor 1 can circulate air efficiently in the rotor housing 23, and can prevent heat from being accumulated in the rotor housing 23. Therefore, the fan motor 1 more effectively prevents heat from accumulating inside the rotor housing 23, and prevents the temperature of the coil from rising and maintains high rotation performance and cooling performance.

  Note that the fan motor having the through hole 60 described with reference to FIGS. 20 and 21 may also be configured to have a plurality of groove portions 38 as described with reference to FIG. Further, the fan motor having the through hole 60 may be configured to have a tapered shape on the top plate portion of the rotor housing 23 as described with reference to FIGS.

  The electronic device 100 to which the present invention is applied includes a fan motor that generates an air flow in the housing 103 and dissipates heat generated in the housing 103. The fan motor 1 described above is used as the fan motor. It is what is used. Therefore, the electronic device 100 prevents the heat from accumulating in the rotor housing 23 of the fan motor 1 and keeps the rotation performance and cooling performance of the fan motor 1 high, so that the temperature inside the apparatus is always properly set. Realize to keep.

It is a perspective view of the fan motor to which the present invention is applied. It is a disassembled perspective view which shows the main body case and fan which comprise the fan motor to which this invention is applied. It is sectional drawing of the fan motor to which this invention is applied. It is a perspective view which shows the structure of the electronic device using the fan motor to which this invention is applied. It is a perspective view from the direction opposite to FIG. 2 of the fan and rotor housing which comprise the fan motor to which this invention is applied. It is a figure which shows the structure of the rotor housing and rising wall which comprise the fan motor to which this invention is applied, (a) is sectional drawing of a rotor housing, (b) is a bottom view of a rotor housing. It is a figure explaining the structure of the standing wall provided in the inner surface of a rotor housing, (a) is an enlarged plan view which expands and shows the standing wall shown in FIG. 6, (b) is (a) and ( It is a figure for demonstrating the position of the both ends of the standing wall shown to c)-(e). (C) is a plan view showing another example of the rising wall, (d) is a plan view showing still another example of the rising wall, and (e) is still another example of the rising wall. It is a top view which shows an example. It is a figure which shows the structure of the other example of the rotor housing which comprises the fan motor to which this invention is applied, and a rising wall, and is a perspective view toward the inner surface side of the rotor housing of the fan and the rotor housing. FIG. 9 is a view for further explaining the rotor housing and the rising wall shown in FIG. 8, and is a bottom view of the rotor housing. It is a figure which shows the structure of the example which provided the groove part in the inner surface of the rotor housing which comprises the fan motor to which this invention is applied, (a) is sectional drawing of a rotor housing, (b) is a bottom face of a rotor housing. It is a figure and (c) is an expanded sectional view which shows a through-hole and a groove part in detail. It is a figure which shows the case where it comprises so that the standing wall demonstrated in FIG. 6 and the groove part demonstrated in FIG. 10 may be provided simultaneously, (a) is a bottom view of a rotor housing, (b) is a through-hole, It is an expanded sectional view showing a slot and a standing wall in detail. It is a figure which shows the example which provided the taper in the rotor housing outer surface of the fan motor to which this invention is applied, and is sectional drawing of a fan motor. It is a figure which shows the structure of the rotor housing and rising wall which comprise the fan motor shown in FIG. 12, and is sectional drawing of a rotor housing. It is a figure which shows the structure of the rotor housing and rising wall which comprise the fan motor shown in FIG. 12, and is a bottom view of a rotor housing. FIG. 13 is a perspective view showing a state of the inner surface side of the rotor housing shown in FIG. 12. It is a figure for demonstrating the other example which provided the taper in the rotor housing outer surface of the fan motor to which this invention is applied, and is sectional drawing of a rotor housing. It is a figure for demonstrating the other example which provided the taper in the rotor housing outer surface of the fan motor to which this invention is applied, and is a bottom view of the rotor housing shown in FIG. FIG. 17 is a perspective view showing a state of the inner surface side of the rotor housing shown in FIG. 16. It is a figure which shows the further another example which provided the taper in the outer surface of the rotor housing of the fan motor to which this invention is applied, and is sectional drawing of a rotor housing. It is sectional drawing which shows the example which provided the cylindrical through-hole of the fan motor to which this invention is applied. It is a figure which shows the structure of the rotor housing and rising wall which comprise the fan motor shown in FIG. 20, (a) is sectional drawing of a rotor housing, (b) is a bottom view of a rotor housing.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Fan motor, 2 Main body case, 3 Fan, 4 Blade member, 5 Motor part, 5a Board | substrate, 6 Upper surface part, 7 Lower surface part, 8 Opening part, 9 Opening part, 10 Stator, 11 Stator housing, 12 Bearing unit, 13 Coil, 14 Iron core, 15 Holder, 16 Radial bearing, 17 Thrust bearing, 20 Rotor, 21 Shaft, 22 Bearing support part, 23 Rotor housing, 24 Cylindrical part, 25 Top plate part, 26 Magnetic yoke, 27 Rotor magnet, 30 Through Hole, 30a Edge, 32-36 Standing Wall, 36a Base End, 36b Tip, 38 Groove, 41 Recess, 41a, 41b Taper, 46 Recess, 51 Protrusion, 51a Taper, 100 Electronic Device

Claims (16)

A stator,
A rotor that rotates about an axis relative to the stator;
A fan having a plurality of blade members rotating together with the rotor;
A coil attached to the stator;
A magnet attached to the rotor and generating a magnetic field for the coil;
The rotor has a cup-shaped rotor housing that includes a cylindrical portion having a cylindrical shape centering on the shaft so as to surround the coil and the magnet, and an end surface portion provided at an opening on one end side of the cylindrical portion. And
The one end surface portion of the rotor housing is provided with a plurality of through holes that circulate inside and outside of the cup-shaped rotor housing,
The fan motor, wherein the plurality of through holes are tapered so that the size of the holes increases from the inside toward the outside.   The inner surface of the one end surface portion of the rotor housing is provided with a plurality of rising walls for convection of the gas circulated from the outer side to the inner side through the through hole in the rotor housing. The fan motor according to 1. Each of the through holes is formed in a substantially circular shape at the edge thereof,
The rising wall is formed to rise in the axial direction on the inner surface of the one end surface portion, and has a shape obtained by cutting a cylindrical shape along the edge of each through hole, and The fan motor according to claim 2, wherein a cross-sectional shape perpendicular to the forming direction is formed into a substantially arc shape having a predetermined width in the radial direction.   The rising wall is provided for each of the through holes, and is formed along a portion of the edge of each through hole that is located at the rearmost position in the rotational direction of the rotor in a cross-sectional shape perpendicular to the axis. From the proximal end portion to the distal end portion positioned on the front side in the rotational direction with respect to the proximal end portion, and having a curvature larger than the circular radius larger than the hole shape of the edge portion of the through hole. The fan motor according to claim 2, wherein the fan motor is formed so as to be curved toward the front side in the rotation direction. The inner surface of the one end surface portion of the rotor housing is provided with a plurality of groove portions formed so as to surround the through holes, respectively.
5. The fan motor according to claim 3, wherein each of the plurality of grooves is provided outside the rising wall or between the rising wall and the through hole. An annular recess formed with a taper is provided on the outer surface of the one end surface portion of the rotor housing,
5. The fan motor according to claim 1, wherein the through hole is provided within a range in which the annular recess is provided. The outer surface of the one end surface portion of the rotor housing is provided with a plurality of concave portions formed with a taper,
5. The fan motor according to claim 1, wherein the through-hole is provided in each of the plurality of recesses. The outer surface of the one end surface portion of the rotor housing is provided with a circular convex portion formed with a taper,
5. The fan motor according to claim 1, wherein the through hole is provided at a position close to an outside of a region where the taper of the circular convex portion is provided.   The rising wall is a semicircular arc portion on the side located behind the rotor in the rotation direction of the semicircle divided by the radial line of the shaft among the edges of the through holes, or Of the both ends of the reference arc with respect to the reference arc, the end of the arc adjacent to the axis is located on the rear side in the rotation direction, or the reference arc Of both end portions of the reference arc, the end portion on the side away from the axis is the arc portion located on the front side in the rotational direction, or both end portions of the reference arc with respect to the reference arc Of which the end close to the shaft is located on the rear side in the rotational direction and the end on the side away from the shaft among the both ends of the reference arc is located on the front side in the rotational direction Formed along the arc part And it has claim 3 wherein the fan motor. The inner surface of the one end surface portion of the rotor housing is provided with a plurality of groove portions formed so as to surround the through holes, respectively.
The fan motor according to claim 1, wherein the groove is formed so that a cross-sectional shape in a forming direction of each groove is substantially V-shaped. A stator,
A rotor that rotates about an axis relative to the stator;
A fan having a plurality of blade members rotating together with the rotor;
A coil attached to the stator;
A magnet attached to the rotor and generating a magnetic field for the coil;
The rotor has a cup-shaped rotor housing that includes a cylindrical portion having a cylindrical shape centering on the shaft so as to surround the coil and the magnet, and an end surface portion provided at an opening on one end side of the cylindrical portion. And
The one end surface portion of the rotor housing is provided with a plurality of through holes that circulate inside and outside of the cup-shaped rotor housing,
A fan motor provided with a plurality of rising walls on the inner surface of the one end surface portion of the rotor housing for convection of the gas circulated from the outer side to the inner side through the through hole in the rotor housing. . Each of the through holes is formed in a substantially circular shape at the edge thereof,
The rising wall is formed to rise in the axial direction on the inner surface of the one end surface portion, and has a shape obtained by cutting a cylindrical shape along the edge of each through hole, and 12. The fan motor according to claim 11, wherein a cross-sectional shape perpendicular to the forming direction is formed to be a substantially arc shape having a predetermined width in the radial direction.   The rising wall is provided for each of the through holes, and is formed along a portion of the edge of each through hole that is located at the rearmost position in the rotational direction of the rotor in a cross-sectional shape perpendicular to the axis. From the proximal end portion to the distal end portion positioned on the front side in the rotational direction with respect to the proximal end portion, and having a curvature larger than the circular radius larger than the hole shape of the edge portion of the through hole. The fan motor according to claim 11, wherein the fan motor is formed so as to be curved toward the front side in the rotation direction.   The rising wall is a semicircular arc portion on the side located behind the rotor in the rotation direction of the semicircle divided by the radial line of the shaft among the edges of the through holes, or Of the both ends of the reference arc with respect to the reference arc, the end of the arc adjacent to the axis is located on the rear side in the rotation direction, or the reference arc Of both end portions of the reference arc, the end portion on the side away from the axis is the arc portion located on the front side in the rotational direction, or both end portions of the reference arc with respect to the reference arc Of which the end close to the shaft is located on the rear side in the rotational direction and the end on the side away from the shaft among the both ends of the reference arc is located on the front side in the rotational direction Formed along the arc part And it has claim 12 wherein the fan motor. Equipped with a fan motor that radiates heat generated inside the housing by generating an air flow inside the housing,
The fan motor is
A stator,
A rotor that rotates about an axis relative to the stator;
A fan having a plurality of blade members rotating together with the rotor;
A coil attached to the stator;
A magnet attached to the rotor and generating a magnetic field for the coil;
The rotor has a cup-shaped rotor housing that includes a cylindrical portion having a cylindrical shape centering on the shaft so as to surround the coil and the magnet, and an end surface portion provided at an opening on one end side of the cylindrical portion. And
The one end surface portion of the rotor housing is provided with a plurality of through holes that circulate inside and outside of the cup-shaped rotor housing,
The electronic device in which the plurality of through holes are tapered so that the size of the holes increases from the inside toward the outside. Equipped with a fan motor that radiates heat generated inside the housing by generating an air flow inside the housing,
The fan motor is
A stator,
A rotor that rotates about an axis relative to the stator;
A fan having a plurality of blade members rotating together with the rotor;
A coil attached to the stator;
A magnet attached to the rotor and generating a magnetic field for the coil;
The rotor has a cup-shaped rotor housing that includes a cylindrical portion having a cylindrical shape centered on the shaft so as to surround the coil and the magnet, and an end surface portion provided at an opening on one end side of the cylindrical portion. And
The one end surface portion of the rotor housing is provided with a plurality of through holes that circulate inside and outside of the cup-shaped rotor housing,
An electronic device in which the inner surface of the one end surface portion of the rotor housing is provided with a plurality of rising walls that convect the gas circulated from the outer side to the inner side through the through hole in the rotor housing. .

Images