JP4789075B2 - Fan motor - Google Patents

Description

  The present invention relates to a fan motor which is mounted on a thin electronic device such as a notebook personal computer and has fan blades extending in the outer peripheral direction of a rotor.

  In recent years, in the field of electronic devices, the processing speed of electronic parts that process various information such as characters, sounds, and images, for example, MPU (microprocessor unit) has been increased, and multifunctional functions have been promoted. . Such electronic devices tend to increase the power consumption of the MPU and thus the amount of heat generated with higher integration and higher performance.

  On the other hand, for thin electronic devices such as notebook computers, further downsizing and thinning are required, and heat from the electronic components mounted on the printed circuit board is limited in a limited space within the thin electronic device. It has become an important issue how to cool effectively. Therefore, in order to thermally control electronic parts such as MPUs in the thin electronic device, a fan motor for blowing provided with fan blades as impellers in the outer peripheral direction of the rotor is assembled.

  In a conventional centrifugal fan motor, for example, as shown in Patent Document 1, a casing that serves as a base for mounting a blower and a cover that covers the upper surface of the frame constitute an outer shell that forms an air passage. In addition, the casing includes a double-sided intake type fan including a rotor in which fan blades are arranged radially with respect to the rotation shaft, and a motor as a drive source for applying a rotational driving force to the rotor.

  More specifically, as shown in FIG. 10, the outer shape of the flat fan motor 101 is constituted by a casing 102 and a cover 103, and the rotating cup-shaped rotor portion 104 and the outer periphery of the rotor portion 104 are configured. A fan 107 including a plurality of fan blades 105 extending from the side surface and a motor 106 that applies a rotational driving force to the rotor unit 104 is accommodated in the outer periphery of the fan motor 101. Further, on both sides of the rotor portion 104 in the direction of the rotation shaft 104A, the casing 102 and the cover 103 are respectively provided with intake holes 108 and 109 for sending air to the fan 107 which is a blower. Further, an exhaust hole 110 that exhausts air to the outside of the fan motor 101 is provided in the blowing direction orthogonal to the intake holes 108 and 109.

When the fan blade 105 is rotated together with the rotor unit 104 by energizing the motor 106, the air F is taken in from the two intake holes 108 and 109 provided on the upper side and the lower side of the fan 107, respectively. The air F is sent out in the outer peripheral direction of the fan blade 105 and is discharged from the exhaust hole 110 on the side surface of the fan motor 101 to the outside of the housing 111 of the thin electronic device.
JP 2004-140061 A

  When the conventional fan motor 101 is assembled in the casing 111 of the electronic device, since the walls are formed outside the upper and lower outer surfaces of the fan motor 101, The ratio of the intake air amount from the vertical direction of the fan motor 101 is different, and the intake air amount is unbalanced. When the inflow amount of air from one intake hole 108 is extremely larger than the inflow amount of air from the other intake hole 109, the air F sucked into the fan motor 101 is indicated by an arrow in FIG. As indicated by the line, it collided with the casing 102 and the cover 103 to prevent smooth exhaustion, resulting in increased noise.

  The present invention solves the above-described problems and adjusts the balance of the intake air amount from the intake holes when the fan motor is incorporated into the housing, thereby smoothly exhausting the air sucked into the fan motor. An object of the present invention is to provide a fan motor that reduces air flow loss and achieves low noise.

In the fan motor according to the first aspect of the present invention, even when the air intake amount taken into the fan motor is unbalanced when the fan motor is incorporated in the housing, the air volume adjusting plate provided in the rotor is Adjusts the balance of the air intake amount, and smoothly exhausts the air drawn into the fan motor. This reduces flow loss in the fan motor and achieves low noise. Further, since air is taken in from the respective end faces of the fan blades, the intake air amount can be increased and the air volume as a fan motor can be increased. Furthermore, since the curved surface is formed on the rotor side of the fan blade, the curved surface can be used to promote the intake of air to the rotor side of the fan blade more effectively and the air is sucked into the rotor side of the fan blade. The air is smoothly sent out to the outer peripheral side of the fan blade by the rotational centrifugal force of the fan blade, and more ideal air flow characteristics can be obtained.

In the fan motor according to the second aspect of the present invention, the air guided along the flat portion of the air volume adjusting plate is structured such that the air volume adjusting plate rotates together with the fan blades by the rotation of the rotor. A part of the air colliding with the surface of the inflow restricting portion of the flat surface portion by the rotation is drawn into the air of the ventilation path to be guided to the internal space, and the flow of air sent from the surface of the flat surface portion to the inclined portion Is formed. Therefore, the air volume adjusting plate can realize smooth intake while appropriately blocking the flow of the air F that is about to be sucked from the intake hole.

In the fan motor according to the third aspect of the present invention, since a surface having a plurality of curvatures is formed on the rotor side of the fan blade, the intake air is effectively promoted toward the rotor side of the fan blade by this surface. can do. Further, the air sucked into the rotor side of the fan blade is smoothly sent out to the outer peripheral side of the fan blade by the rotational centrifugal force of the fan blade, and more ideal air flow characteristics can be obtained.

In the fan motor of the invention of claim 4 , by forming the fan blade integrally with the rotor, even the fan blade having a complicated shape can be manufactured at a time including the rotor.

In the fan motor according to the fifth aspect of the present invention, since the thickness of the fan blade is 1.5 mm or less, it is possible to prevent the intake air from being obstructed by this thickness as much as possible, and while reducing the weight of the fan blade, it is high. Airflow characteristics can be obtained.

In the fan motor according to the sixth aspect of the present invention, particularly in a structure in which air can be taken into the intake portion of the fan blade from both sides in the rotation axis direction of the fan blade, from one side of the rotation axis direction, Fan blades of two shapes that promote intake from the other side are alternately extended around the rotor so that air can be evenly introduced from both sides of the fan blade in the rotational axis direction. Is possible.

In the fan motor according to the seventh aspect of the present invention, the generation of noise due to the provision of the ring can be prevented, and the intake efficiency can be improved to increase the air volume. In addition, the air taken in by the fan blades flows along the inner surface of the ring without flowing out from the end face perpendicular to the blowing direction, so that the air is exhausted in a low noise state without interfering with the outer wall surrounding the fan blades. it can.

In the fan motor according to the eighth aspect of the present invention, it is possible to prevent the generation of noise due to the provision of the ring, further improve the intake efficiency and increase the air volume. In addition, the air taken in by the fan blades flows along the inner surface of the ring without flowing out from the end face perpendicular to the blowing direction, so that the air is exhausted in a low noise state without interfering with the outer wall surrounding the fan blades. it can.

In the fan motor according to the ninth aspect of the invention, the inner peripheral side of the ring is flush with the outer shell or protrudes more than the outer shell so that the air can be easily taken into the fan blade, and as a result, the air flow characteristic as the fan motor is obtained. Can be improved.

In the fan motor according to the tenth aspect of the present invention, the flow of air flowing from the inner peripheral side of the fan blade to the outer peripheral side is not hindered midway by forming the air passage side of the ring in a smooth straight line or curved shape. Can be.

According to the invention of claim 1, by providing the rotor with the air volume adjusting plate that rotates together with the fan blade, the unbalance of the inflow amount of air from the intake hole when the fan motor is incorporated inside the housing of the electronic device or the like. The noise can be reduced by improving the efficiency and improving the exhaust efficiency. Further, the amount of air as a fan motor can be increased by increasing the amount of intake air. Furthermore, the intake of air to the rotor side of the fan blade can be promoted more effectively, and more ideal air flow characteristics can be obtained.

According to the invention of claim 2, with respect to the air guided along the flat portion of the air volume adjusting plate, the air volume adjusting plate is structured to rotate together with the fan blade by the rotation of the rotor. As a result, a part of the air colliding with the surface of the inflow restricting portion of the flat portion is drawn into the air of the ventilation path that is to be guided to the internal space, and the flow of air sent from the surface of the flat portion to the inclined portion is It is formed. Therefore, the air volume adjusting plate can realize smooth intake while appropriately blocking the flow of the air F that is about to be sucked from the intake hole.

According to the third aspect of the present invention, intake air can be promoted very effectively toward the rotor side of the fan blade, and more ideal air flow characteristics can be obtained.

According to the invention of claim 4 , even if the fan blade has a complicated shape, the rotor and the fan blade can be manufactured at a time.

According to the invention of claim 5 , it is possible to obtain a desirable air flow characteristic while reducing the weight of the fan blade that prevents the intake air from being hindered by the thickness of the fan blade as much as possible.

According to the sixth aspect of the present invention, air can be evenly taken in from both sides of the fan blade in the rotational axis direction without being biased.

According to the seventh aspect of the present invention, it is possible to provide a fan motor capable of increasing the amount of intake air to the fan blades to achieve high air flow characteristics and low noise.

According to the eighth aspect of the present invention, it is possible to provide a fan motor that can increase the amount of intake air to the fan blades to achieve high air flow characteristics and achieve low noise.

According to the ninth aspect of the present invention, air can be easily taken into the fan blade, and the air flow characteristic as a fan motor can be improved.

According to the tenth aspect of the present invention, it is possible to prevent the flow of air flowing from the inner peripheral side to the outer peripheral side of the fan blade from being interrupted.

  Hereinafter, preferred embodiments of a fan motor according to the present invention will be described with reference to the accompanying drawings. FIG. 1 and FIG. 2 show a first embodiment of the present invention. A fan motor 1 as a blower has a flat outer shape as a whole and is accommodated in a thin electronic device such as a notebook computer. . The fan motor 1 includes a fan 7 as a blower. The outer shell of the fan motor 1 is composed of a bottomed casing 2 made of a member having excellent heat conductivity, for example, and a cover 3 that covers the upper opening of the casing 2.

  The fan 7 includes a rotor portion 4 which is a cylindrical cup-shaped rotor, a plurality of fan blades 5 extending radially from the outer peripheral side surface of the rotor portion 4, and a magnet attached to the inner peripheral surface of the rotor portion 4 (see FIG. And a motor 6 that rotates the rotor portion 4 and the fan blade 5 about the rotation shaft 4A by an electromagnetic action with the motor. In addition, on the both sides of the rotor portion 4 in the direction of the rotation axis 4A, the casing 2 and the cover 3 are respectively provided with intake holes 8 and 9 for sending air to the fan 7 so as to face each other. Further, an exhaust hole 10 for discharging air to the outside of the fan motor 1 is provided in the blowing direction orthogonal to the intake holes 8 and 9.

  11 is an air volume adjusting plate provided on the outer periphery of the rotor portion 4 and includes a disk-shaped flat portion 12 formed in parallel to the radial direction of the rotating shaft 4A. The outer diameter D1 of the flat surface portion 12 is formed substantially equal to the outer diameter D2 of the intake hole 8 of the casing 2, and the inner diameter D3 of the flat surface portion 12 is formed approximately equal to the inner diameter D4 of the intake hole 8 of the casing 2. That is, the area of the plane portion 12 is formed to be substantially the same as the area of the opening portion of the intake hole 8 of the casing 2. Further, the flat surface portion 12 of the air volume adjusting plate 11 does not need to be a circle, and may have an irregular shape.

  Further, in the flat surface portion 12, the outer peripheral end 17A of the adjustment surface 17 is formed of the casing 2 and the cover 3 with respect to the outer periphery of the adjustment surface 17 facing the intake hole 8 on the side where the intake amount is adjusted. An inclined portion 18 serving as an air guide portion is formed so as to be directed to a virtual plane K (indicated by a two-dot chain line in the figure) that divides the inner space N of one outer shell into approximately two equal parts in the direction of the rotation axis 4A. In other words, the outer peripheral end 17A of the adjustment surface 17 is formed toward the substantially middle portion of the outer peripheral end surface 5A of the fan blade 5, so that the inclination of the inclined portion 18 is substantially the same as that of the outer peripheral end surface 5A of the fan blade. It is formed toward the middle part. Further, a plane portion other than the inclined portion 18 of the adjustment surface 17 is formed as the inflow restricting portion 19.

  The air volume adjusting plate 11 is formed by extending the planar portion 12 in the radial direction of the rotating shaft 4A from the connecting portion 4B of the rotor portion 4 to which the base end of the fan blade 5 is connected. The plane portion 12 is formed to be substantially flush with the end face 24A facing the intake hole 8 in the direction of the rotation axis 4A of the fan blade 5.

  In this embodiment, the air volume adjustment plate is used when the intake air amount sucked from the intake hole 8 is larger than the intake air amount sucked from the intake hole 9 and the intake air amount on the intake hole 8 side is adjusted. 11 is provided on the intake hole 8 side. That is, when air is sucked from the intake holes 8 and 9, the air volume adjusting plate 11 is provided close to the intake hole (intake hole 8) on the side where the intake air is larger than the rotor portion 4. Therefore, regarding the distance from each intake hole 8, 9 to the first air volume adjusting plate 11, the distance T 1 from the intake hole 8 having the larger intake air volume to the air volume adjusting plate 11 is set to the intake hole 9 having the smaller air intake volume. Is smaller than the distance T2 from the airflow adjustment plate 11 to the airflow adjustment plate 11.

  In the present embodiment, the first air volume adjusting plate 11 is provided close to the intake hole (for example, the intake hole 8) on the side where the intake air is large, assuming that the intake air amount of the intake holes 8 and 9 is different. The air volume adjusting plate 11 may be provided only on the intake hole 9 side. Further, as shown in FIGS. 3 and 4 as another modified example, when a plurality of air volume adjusting plates 11 and 51 are provided, the air volume adjusting plates 11 and 51 are brought close to the intake holes 8 and 9 and the rotor. It is preferable to provide from part 4. Here, it is preferable that the plane portion 12 of the air volume adjusting plate 11 shown in FIG. 3 is formed in an area substantially the same as the opening area of the corresponding intake hole 8 as shown in FIG. Further, when the ring 41 is provided on the end face 25B of the fan blade 5 on the intake hole 9 side, the flat portion 52 of another air volume adjusting plate 51 is provided with an outer diameter D6 that is substantially the same as the inner diameter D5 of the ring 41. It is preferable to form. As a result, the air sucked from the intake holes 8 and 9 is prevented from passing without contacting the flat portions 12 and 52 of the first and second air volume adjusting plates 11 and 51. The air volume restriction of the air sucked into the outer shell is surely performed. The air volume adjusting plate 51 has the same structure as that of the air volume adjusting plate 11, and includes a flat surface portion 12, an adjusting surface 17, an outer peripheral end 17A, an inclined portion 18 and an inflow restricting portion 19 formed on the air volume adjusting plate 11. Are provided with a flat portion 52, an adjustment surface 57, an outer peripheral end 57A, an inclined portion 58 and an inflow restricting portion 59, and the flat portion 52 of the second air volume adjusting plate 51 is in the direction of the rotational axis 4A of the fan blade 5. Is formed to be substantially flush with the end face 25A facing the intake hole 9.

  In FIG. 2, reference numeral 16 denotes a lead wire for electrical connection with the motor 6. In particular, in this embodiment, the intake hole 9 on the side where the ring 41 described later is disposed is wide open to reach the outer peripheral portion 14 of the fan blade 5. Further, the thickness t of the fan blade 5 is preferably set to 1.5 mm or less in order to reduce the air resistance sucked from the intake holes 8 and 9 as much as possible.

  The number of fan blades 5 is not limited as long as it is plural. Further, the exhaust hole 10 of the fan motor 1 is not limited to one direction, and may be provided, for example, on the entire circumference of the fan 7 in the radial direction. Each fan blade 5 may be configured to be attached to the outer peripheral side surface of the rotor portion 4, but in consideration of manufacturability and the like, it is preferable that the rotor portion 4 and each fan blade 5 are formed as a single member. .

  Further, in FIGS. 1 and 2, reference numeral 41 denotes an annular ring formed on the end face 25 </ b> B in the vertical direction orthogonal to the blowing direction (lateral direction) of the fan blade 5. The ring 41 blocks the flow of the air F from the end face 25B toward the inner surface of the cover 3, and prevents the air F from flowing from the intake hole 9 toward the inner peripheral portion 13 of the fan blade 5. It arrange | positions so that it may mount on the end surface 25B of the outer peripheral part 14 of the braid | blade 5. FIG.

  In this embodiment, a ring 41 is provided on one end face 25B of the fan blade 5. However, as shown in FIG. 4, which is another modified example, each end face 24B, 25B on both sides of the fan blade 5 is provided respectively. Rings 41 and 42 having the same shape may be provided. In this case, each of the rings 41 and 42 may have an arbitrary diameter and area, and the shapes thereof may be different. For example, when the opening areas of the intake holes 8 and 9 are different, the intake air amount toward the fan blade 5 is naturally different at the end faces 24B and 25B. In that case, on the one end face 24B side where the intake air amount is large. If a ring 41 with a large area is arranged and a ring 42 with a smaller area is arranged on the other end face 25B side with a small intake amount, the air flow from each end face 24B, 25B toward the inner surface of the casing 2 or the cover 3 Can be effectively blocked. Further, the inner peripheral edge and the outer peripheral edge of the ring 41 do not have to be circular, and may have a different shape. Further, in FIG. 4, only the ring 42 facing the intake hole 8 may be formed on the fan blade 5 as a matter of course.

  The end face 25B of the outer peripheral portion 14 of the fan blade 5 provided with the ring 41 is inclined so that its inner peripheral side protrudes most toward the intake hole 9 and away from the intake hole 9 from there toward the outer peripheral side. A ring 41 is formed in an overall shape along the same line. The inner surface 41A of the ring 41 facing the outer peripheral portion 14 of the fan blade 5 is formed in a smooth flat or curved shape without local irregularities along the flow of the air F in the blowing direction. That is, the ventilation path side of the ring 41 through which the air F flows toward the exhaust hole 10 is formed in a smooth straight line or curved line so as not to obstruct the flow of the air F on the way.

  On the other hand, like the inner surface 41A, the outer surface 41B of the ring 41 is inclined from the inner peripheral side of the ring 41 toward the outer peripheral side so that the inner peripheral side protrudes to the intake hole 9 side from the outer peripheral side. In order to prevent air from entering through the gap between the intake hole 9 and the outer surface 41B of the ring 41 with certainty, a rib 41C is formed on the outer surface 41B of the ring 41 so as to close the outer peripheral side of the intake hole 9. The rib 41C may protrude outward from the cover 3. Further, in this embodiment, in order to increase the intake of the air F into the fan blade 5, the inner peripheral edge of the ring 41 is provided at the same position as the cover 3 which is the outer shell of the fan motor 1, but the intake force is further increased. For this reason, the cover 3 may protrude outward.

  Similarly, in FIG. 4, the end surface 24B of the outer peripheral portion 14 of the fan blade 5 provided with the ring 42 is inclined so that the inner peripheral side protrudes most toward the intake hole 8 and away from the intake hole 8 from there to the outer peripheral side. Thus, the ring 42 is formed in an overall shape along this inclination. The inner surface 42A of the ring 42 is formed in a smooth flat surface or curved surface without local unevenness along the flow of the air F in the blowing direction. That is, the ventilation path side of the ring 42 through which the air F flows toward the exhaust hole 10 is also formed in a smooth straight line or curved line so as not to obstruct the flow of the air F on the way.

  On the other hand, like the inner surface 42A, the outer surface 42B of the ring 42 is inclined from the inner peripheral side of the ring 42 to the outer peripheral side so that the inner peripheral side protrudes toward the intake hole 8 side from the outer peripheral side. In order to surely prevent air from entering through the gap between the intake hole 9 and the outer surface 42B of the ring 42, a rib 42C is formed on the outer surface 42B of the ring 42 so as to close the outer peripheral side of the intake hole 8. The rib 42C may protrude outward from the casing 2. Further, in this embodiment, in order to increase the intake of the air F to the fan blade 5, the inner peripheral edge of the ring 42 is provided at the same position as the casing 2 which is the outer shell of the fan motor 1, but the intake force is further increased. For this purpose, the casing 2 may protrude outward.

  In addition, as a modification of the rings 41 and 42, the outer periphery of the rings 41 and 42 may be protruded from the outermost diameter of the fan blade 5, and when viewed from the vertical direction of the fan motor 1 as shown in FIG. Rings 41 and 42 may be formed at different positions (the areas may not overlap).

  Next, the operation of the above configuration will be described. When electric power is supplied to the motor 6 through the lead wire 16 and a rotational driving force is applied to the magnet attached to the inner peripheral surface of the rotor portion 4, the fan blade 5 integrated with the rotor portion 4 rotates together.

  At this time, the air F sucked through the other intake hole 9 flows downward toward one end face 24A as shown in FIG. Similarly, the air F sucked through the one intake hole 8 also flows upward. The air scraped by the fan blade 5 flows downward or upward as described above, and gradually flows from the inner peripheral portion 13 side to the outer peripheral portion 14 side by the rotation of the fan blade 5 (FIG. 2). (See broken line F). Since one end face 24B and the other end face 25B of the fan blade 5 are surrounded by the casing 2 and the cover 3, respectively, the air F reaching the outer periphery 14 escapes from the intake holes 8 and 9. Without being pushed further toward the outer circumferential direction. Then, the air F that has reached the outer peripheral end surface 5A of the fan blade 5 is discharged to the outside at a high pressure from the exhaust hole 10 that is orthogonal to the intake holes 8 and 9.

  In the example shown in FIG. 1, if the flow of the air F sucked from the intake hole 8 of the casing 2 in the direction of the rotation axis 4A is a ventilation path F1, in this ventilation path F1, from the intake hole 8 to the rotation axis 4A direction. The sucked air F is guided to the internal space N along the surface direction of the flat portion 12 of the air volume adjusting plate 11.

  Further, if the air flow sucked in the direction of the rotation axis 6A from the intake hole 9 of the cover 3 is defined as a ventilation path F2, the air F sucked in the direction of the rotation axis 4A from the intake hole 9 in the ventilation path F2. Then, it is guided to the internal space N as it is.

  As described above, the air F guided from the intake hole 8 along the plane direction of the flat portion 12 of the air volume adjusting plate 11 is smoothly sent out to the internal space N along the inclination of the inclined portion 18. Since the inclination of the inclined portion 18 is formed toward the virtual plane K, that is, the substantially middle portion of the outer peripheral end surface 5A of the fan blade 5, the air sucked from the intake hole 8 is rotated by the rotating fan blade 5 In this case, the air F is sent out toward the substantially middle stage of the outer peripheral end surface 5A of the fan blade 5 to which the centrifugal force is most applied, and the air F does not directly hit the inner surfaces of the casing 2 and the cover 3. Therefore, it is possible to discharge the air F with lower noise while maintaining high air volume characteristics.

  Further, with respect to the air F guided along the plane portion 12 of the air volume adjusting plate 11, the air volume adjusting plate 11 rotates with the fan blade 5 by the rotation of the rotor portion 4. , A part of the air F colliding with the surface of the inflow restricting portion 19 of the plane portion 12 is drawn into the air F of the ventilation path F1 that is about to be guided to the internal space N, and the air from the surface of the plane portion 12 An air flow F3 sent to the inclined portion 18 is formed. Therefore, the air volume adjusting plate 11 can realize smooth intake while appropriately blocking the flow of the air F that is about to be sucked from the intake hole 8.

  Further, the ventilation path F1 guided from the intake hole 8 through the air volume adjusting plate 11 to the substantially middle portion of the outer peripheral end surface 5A of the fan blade 5 is connected to the fan motor 1 from the intake holes 8 and 9 of the casing 2 and the cover 3. In the case of the present embodiment in which both-side intake is performed, the air flow path F2 of air sucked from the intake hole 9 of the cover 3 is hardly affected, and is directed to the substantially middle portion of the outer peripheral end surface 5A of the fan blade 5. Yes. The air passages F1 and F2 until the air sucked from the intake holes 8 and 9 is sent to the outer peripheral end surface 5A of the fan blade 5 by the rotating fan blade 5 are interposed with the air volume adjusting plate 11 therebetween. Therefore, even when the intake air amount sucked from the intake holes 8 and 9 of the casing 2 and the cover 3 is different, the air directly flows in the internal space N of the fan motor due to the difference in the intake air amount. Further, the air F sucked from the side with the large intake air amount does not push the air sucked from the side with the small air intake amount and directly hits the inner surface of the casing 2 or the cover 3. Therefore, it is possible to discharge the air F with lower noise while maintaining high air volume characteristics.

  Further, regarding the distance from each intake hole 8, 9 to the first air volume adjusting plate 11, the distance T 1 from the intake hole 8 on the side where the intake air is large to the first air volume adjusting plate 11 is the side where the intake air is small. By making it smaller than the distance T2 from the intake hole 9 to the first air volume adjusting plate 11, the distance from the outer periphery of the opening portion of each intake hole 8, 9 to the outer periphery of the flat portion 12 in the first air volume adjusting plate 11, That is, the width of each of the ventilation paths F1 and F2 is adjusted to adjust the amount of air sucked from each of the intake holes 8 and 9.

  The air volume adjustment of the air passages F1 and F2 through which the air F is guided from the intake holes 8 and 9 to the fan blade 5 is performed by adjusting the distance between the air volume adjusting plate 11 and the intake holes 8 and 9. For example, when the air volume is increased, the distance between the air volume adjusting plate 11 and the intake holes 8 and 9 is increased. Conversely, when the air volume is decreased, the distance between the air volume adjusting plate 11 and the intake holes 8 and 9 is decreased. It is preferable to do. In particular, in the intake hole 9 that does not require adjustment of the intake air amount, the distance T2 is sufficiently large, so that air is guided to the internal space N without being restricted by the intake air amount. On the contrary, in the intake hole 8 on the side where the adjustment of the intake hole is necessary, the distance T1 is formed small, and the ventilation path F1 is narrowed accordingly, so that the inflow amount of air that can pass through the ventilation path F1 Is also limited. In other words, not all the air sucked from the intake hole 8 can pass through the narrowed ventilation path F1, but the inflow amount of the air sucked from the intake hole 8 can pass through the ventilation path F1. If the air intake exceeds the intake air amount, the excessively sucked air, which is obtained by subtracting the inflow amount that can be passed through, is restricted by the air volume adjusting plate 11 from entering the inner space N of the outer shell. The air volume of the ventilation path F1 guided from 8 to the fan blade 5 is adjusted. Then, by adjusting the air volume of the ventilation path F1 of the intake hole 8 located on the side where the intake air is large, air flows from each intake hole 8 and 9 in a well-balanced manner and is smoothly exhausted with a small loss.

  Further, in the example shown in FIG. 1, when the air F flows from the inner peripheral portion 13 to the outer peripheral portion 14 of the fan blade 5, especially the air that is about to flow out from the longitudinal end face 25 </ b> B orthogonal to the blowing direction Since the air flows toward the exhaust port 10 while being guided along the inner surface 41A of 41, the air F does not directly hit the inner surface of the cover 3 facing the end surface 25B of the fan blade 5. Therefore, it is possible to discharge the air F with low noise while maintaining the high air volume characteristics as described above. Moreover, the inner surface 41A of the ring 41 is formed into a smooth flat surface or curved surface, and the air F flowing from the outer peripheral portion 14 of the fan blade 5 toward the exhaust hole 10 is smoothly moved along the inner surface 41A of the ring 41. Can be sent out.

  At the same time, the outer surface 41B side of the ring 41 is flush with the cover 3 by the rib 41C on the inner peripheral side of the ring 41, and is inclined so as to sink into the cover 3 on the outer peripheral side of the ring 41. Therefore, the air F to be taken in from the intake hole 9 cannot enter from the gap between the intake hole 9 and the outer surface 41B of the ring 41, and the generation of noise due to the provision of the ring 41 can be reduced. The air F can be efficiently taken into the fan blade 5 from the inner peripheral edge of the ring 41 that protrudes most toward the intake hole 9.

  Further, in the embodiment shown in FIG. 4, since another similar ring 42 is provided on the end face 24 </ b> B of the outer peripheral portion 14 of the fan blade 5, the above-described operational effects become more remarkable. That is, when the air F flows from the inner peripheral portion 13 to the outer peripheral portion 14 of the fan blade 5, not only the inner surface 41A of the ring 41 but also the air that is about to flow out from the end surface 24B of the fan blade 5 is different. Since the air flows toward the exhaust port 10 while being guided along the inner surface 42A of the ring 42, the air F does not directly collide with the inner surfaces of the casing 2 and the cover 3 facing the end surfaces 24B and 25B of the fan blade 5. Therefore, it is possible to discharge the air F with lower noise while maintaining high air volume characteristics. Moreover, the inner surfaces 41A, 42A of the rings 41, 42 are formed in a smooth flat surface or curved surface, and the air F flowing from the outer peripheral portion 14 of the fan blade 5 toward the exhaust hole 10 is supplied to the rings 41, 42. Can be smoothly fed along the inner surfaces 41A and 42A.

  At the same time, the outer surface 42B side of the ring 42 is flush with the casing 2 by the rib 42C on the inner peripheral side of the ring 42, and is inclined so as to sink into the casing 2 on the outer peripheral side of the ring 42. Therefore, the air F to be taken in from the intake hole 8 cannot enter from the gap between the intake hole 8 and the outer surface 42B of the ring 42, and the generation of noise due to the provision of the ring 42 can be reduced. The air F can be efficiently taken into the fan blade 5 from the inner peripheral edge of the ring 42 that protrudes most toward the intake hole 8.

  Further, in the modification shown in FIG. 3, since the first and second air volume adjusting plates 11 and 51 are provided in the intake holes 8 and 9, respectively, the above-described operational effects become more remarkable. In other words, the fan motor prevents the air sucked from the intake holes 8 and 9 from passing without contacting the flat portions 12 and 52 of the first and second air volume adjusting plates 11 and 51. Since the air volume restriction of the air sucked into the outer shell of 1 is surely performed, the air flows from each of the intake holes 8 and 9 in a well-balanced manner and is smoothly exhausted with a small loss.

  FIG. 5 shows the air volume-noise characteristics in the present example and the conventional example, and the broken line plotted with ● (black circle) in the figure represents the air volume-noise characteristic line in this example. A broken line plotted with a medium ◆ (black diamond) represents a comparison result at a predetermined static pressure, which represents an air volume-noise characteristic line of a conventional example. As is apparent from this figure, at the same air volume level, the fan motor 1 in the present embodiment averages about 4 [dBA] less noise than the fan motor 101 in the conventional example. .

  As described above, in the present embodiment, in the fan motor 1 in which the fan blades 5 are extended in the outer circumferential direction of the rotor portion 4 that is a rotor, the rotor portion 4 is provided with the air volume adjusting plate 11, thereby Even when the air intake amount from the intake holes 8 and 9 is unbalanced when the fan motor 1 is installed inside the housing, the air volume adjusting plate 11 provided in the rotor portion 4 is used for air intake. The amount of imbalance is improved, and the air sucked into the fan motor 1 is exhausted smoothly. Thereby, the loss of the flow in the fan motor 1 can be reduced, and the noise can be reduced by improving the exhaust efficiency.

  Further, if the fan blade 5 and the rotor portion 4 are formed integrally instead of separately, even the fan blade 5 having a complicated shape can be manufactured at once including the rotor portion 4. .

  In addition, when the thickness t of the fan blade 5 is formed to be 1.5 mm or less, it is possible to prevent the air intake to the fan blade 5 from being obstructed by the thickness t as much as possible, and to reduce the weight of the fan blade 5 and to achieve desirable air flow characteristics. Can be obtained.

  Further, in this embodiment, in the fan motor 1 in which the fan blade 5 is extended in the outer peripheral direction of the rotor, that is, the rotor portion 4, and the ring 41 is formed on the end face 25B in the longitudinal direction of the fan blade 5, the ring 41 is The inner peripheral side is inclined so as to protrude from the outer peripheral side toward the outer peripheral side from the inner peripheral side.

  In this case, the ring 41 is inclined with respect to the cover 3 which is the outer shell of the fan motor 1 so as to close the gap between the cover 3 and the outer surface 41B of the ring 41. The problem that occurs can be avoided. Further, since the inner peripheral side of the ring 41 protrudes from the outer peripheral side, the air F can be efficiently taken into the fan blade 5 from the inner peripheral edge of the ring 41. As a result, it is possible to prevent the generation of noise due to the provision of the ring 41, further improve the intake efficiency and increase the air volume. In addition, the air F taken into the fan blade 5 flows along the inner surface 41A of the ring 41 without flowing out from the end face 25B orthogonal to the blowing direction, so that it does not interfere with the members surrounding the fan blade 5, It can exhaust in a low noise state.

  As shown in FIG. 4, in the fan motor 1 in which the rings 41 and 42 are formed on the end faces 24B and 25B in the longitudinal direction of the fan blade 5, at least one of the rings 41 Even when the inner peripheral side is inclined from the inner peripheral side toward the outer peripheral side so as to protrude from the outer peripheral side, the same effect can be obtained.

  Furthermore, in the present embodiment, the air to the fan blade 5 is projected by causing the inner peripheral side of the rings 41 and 42 to be flush with the casing 2 and the cover 3 that are the outer shell, or to protrude outward from the casing 2 and the cover 3. As a result, the air flow characteristics of the fan motor 1 can be improved.

  In this embodiment, the inner surfaces 41A and 42A, which are the ventilation paths of the rings 41 and 42, are formed in a smooth straight line or curved line, whereby the flow of the air F flowing from the inner peripheral side of the fan blade 5 to the outer peripheral side. Can be prevented in the middle.

  Next, a second embodiment of the fan motor 1 of the present invention will be described with reference to FIGS. Note that portions corresponding to those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  Here, the shape of the fan blade 5 that contributes to intake air to the fan 7 will be described in more detail with reference to cross-sectional views shown in FIGS. 8 and 9. An inner peripheral portion 13 serving as an intake portion, which is a portion opposite to the holes 8 and 9 and into which air F is sucked from the intake holes 8 and 9, and on the outer peripheral side of the inner peripheral portion 13. , The outer peripheral portion 14 surrounded by the casing 2 and the cover 3, and in the inner peripheral portion 13 of the fan blade 5, a front surface 21 </ b> A facing the rotation direction of the fan blade 5 and a rear surface 22 </ b> A on the rear side thereof are 8 or the intake hole 9 is formed in a curved shape instead of a flat shape (see FIG. 8A). On the other hand, in the outer peripheral portion 14 of the fan blade 5, the front surface 21B facing the rotation direction of the fan blade 5 and the rear surface 22B on the rear side are both formed in a flat shape without irregularities, and are taken from the intake holes 8 and 9 respectively. It is arranged perpendicular to the intake surface of the air F (see FIG. 8B). That is, in this embodiment, when focusing on the shapes of the front faces 21A and 21B of the fan blade 5, the curvature of the front face 21A on the inner peripheral portion 13 side (≠ 0) and the curvature of the front face 21A on the outer peripheral portion 14 side (= 0) is different, and in particular, the air F from the intake holes 8 and 9 is swept into the front side of the fan blade 5 by the front surface 21A on the inner peripheral portion 13 side formed in a curved shape.

  The curvature of the front surface 21A on the inner peripheral portion 13 side may not be uniform over the entire front surface 21A. For example, the front surface 21A shown in FIG. 8A is formed in an arc curved surface having a substantially uniform curvature as a whole. For example, the other end surface 25A (or the other surface) facing the intake hole 9 (or the intake hole 8) is formed. The front surface 21A having a constant curvature is formed in an arc curved surface from the other end surface 24A) to the middle of the one end surface 24A from the other end surface 25A), and as it approaches the one end surface 24A, In this case, the front surface 21A may be formed in a substantially flat shape so that the curvature is substantially zero. Thus, if the front surface 21A of the fan blade 5 is formed in a shape in which a plurality of curvatures are combined, the fan blade can be used against the air F entering from the other end surface 25A of the fan blade 5 toward the one end surface 24A. The force stirred by 5 acts strongly first, and it becomes possible to promote inhalation very effectively. Although the center of the radius of curvature of the front surface 21A shown in FIGS. 8 and 9 is located downward as viewed from the front surface 21A, it may be located upward.

  As shown in FIG. 7, each fan blade 5 of the present embodiment is located on the inner peripheral portion 13, and has a first tongue piece 31 that extends forward from one end face 24 </ b> A that faces the intake hole 8, Any one of the second tongue pieces 32 extending forward from the other end face 25 </ b> A facing the intake hole 9 is provided alternately. That is, here, two types of fan blades 5 having different shapes are provided, and by rotating the fan blade 5, the air F from the intake hole 8 is scraped by the first tongue piece 31, The air F is scraped by the second tongue piece 32. The fan blades 5 may all have different shapes. Conversely, in the case where the air intake hole 9 is provided only on one side of the fan blade 5, the fan blade having the same shape with the second tongue piece 32 is provided. 5 may be all disposed on the outer periphery of the rotor portion 4.

  In FIG. 7, the base end of the connecting portion between the rotor portion 4 and the fan blade 5 is located on the outer periphery of the cylindrical rotor portion 4, and the outer periphery of the rotor portion 4 passes through the base end P. Assuming that the upper normal line is X0, the angle θ1 between the normal line X0 and the line X1 extending from the base end P to the outer end of the inner peripheral part 13 of the fan blade 5 is outside the outer peripheral part 14 of the fan blade 5. It is smaller than the angle θ2 formed by the line X2 reaching the end and the normal line X0. In other words, the mounting angle (90 ° −θ1) of the inner peripheral portion 13 of the fan blade 5 with respect to the rotor portion 4 is larger than the mounting angle (90 ° −θ2) of the outer peripheral portion 14 of the fan blade 5 with respect to the rotor portion 4; The fan blade 5 extends from the outer peripheral side surface of the rotor portion 4 to the tip while curving in an arch shape in the rotational direction instead of linearly. More preferably, if the fan blade 5 is formed so that the shape of the fan blade 5 is in the direction of the resultant force of the rotational force and the centrifugal force received by the air F taken in by the fan 7, it is directed toward the outer peripheral end surface 5A of the fan blade 5. Thus, the air F can be sent out efficiently without receiving resistance as much as possible.

  Next, the operation of the above configuration will be described. When electric power is supplied to the motor 6 through the lead wire 16 and a rotational driving force is applied to the magnet attached to the inner peripheral surface of the rotor portion 4, the fan blade 5 integrated with the rotor portion 4 rotates together.

  At this time, the air F passing through the other intake hole 9 and sucked into the fan blade 5 from the other end face 25A of the fan blade 5 is on the rotor part 4 side (inner peripheral part 13 side) facing the intake hole 9. In particular, the fan blade 5 provided with the second tongue piece 32 on the other end face 25A flows in such a manner as to be scraped by the front face 21A having a predetermined curvature. As shown in FIG. 8, this is a downward flow toward one end face 24A. Similarly, the air F that passes through one intake hole 8 and is sucked into the fan blade 5 from one end face 24A of the fan blade 5 is also particularly at one of the portions on the rotor portion 4 side facing the intake hole 8. The fan blade 5 provided with the first tongue piece 31 on the end face 24A flows upward toward the other end face 25A so as to be scraped by the front face 21A having a predetermined curvature. The scraping of the air F by the front surface 21A of each fan blade 5 causes an increase in the amount of suction from the respective intake holes 8 and 9 toward the fan blade 5.

  The air swept by the front surface 21A of the fan blade 5 flows downward or upward as described above, and gradually flows from the inner peripheral portion 13 side to the outer peripheral portion 14 side by the rotation of the fan blade 5. (See broken line arrow F in FIG. 7). The outer peripheral portion 14 of the fan blade 5 has one end surface 24B and the other end surface 25B surrounded by the casing 2 and the cover 3, respectively. The reached air F is not pushed away from the intake holes 8 and 9 and is pushed out further toward the outer peripheral direction. Then, the air F that has reached the outer peripheral end surface 5A of the fan blade 5 is discharged to the outside at a high pressure from the exhaust hole 10 that is orthogonal to the intake holes 8 and 9.

  Further, in the present embodiment, the inner peripheral portion 13 of the fan blade 5 is arranged on the inner peripheral portion 13 side of the fan blade 5 at an attachment angle (90 ° −θ1) so that the air F can be scraped efficiently by the front surface 21A. Furthermore, by arranging the outer peripheral portion 14 of the fan blade 5 at the mounting angle (90 ° −θ2) at which the air F is sent out at an angle toward the exhaust hole 10 on the outer peripheral portion 14 side of the fan blade 5, Combined with the shape of the front surface 21A, the intake efficiency can be further improved, and the smooth delivery of the air F can be realized.

  As described above, in this embodiment, a configuration is adopted in which intake is performed from the respective end faces 24A and 25A of the fan blade 5 facing each other. If it carries out like this, since the air F is taken in from each end surface 24A, 25A of the fan blade 5, the amount of intake air can be increased and the air volume as the fan motor 1 can be increased.

  In particular, the fan blade 5 of this embodiment has a front surface 21A that is a curved surface on the inner peripheral portion 13 on the rotor portion 4 side. In this case, it is possible to more effectively promote intake of the fan blade 5 toward the rotor portion 4 using the front face 21A, and the air F sucked into the rotor portion 4 of the fan blade 5 The centrifugal force is smoothly sent to the outer peripheral portion 14 side of the fan blade 5, and more ideal air flow characteristics can be obtained.

  Furthermore, the fan blade 5 preferably has a shape in which a plurality of curvatures are combined at the inner peripheral portion 13 on the rotor portion 4 side. In this case, since the front surface 21A having a combination of a plurality of curvatures is formed on the rotor portion 4 side of the fan blade 5, the intake air is extremely effectively directed toward the rotor portion 4 side of the fan blade 5 by this front surface 21A. Can be promoted. Also, the air sucked into the rotor part 4 side of the fan blade 5 is smoothly sent out to the outer peripheral part 14 side of the fan blade 5 by the rotational centrifugal force of the fan blade 5, and a more ideal air flow characteristic can be obtained. .

  Further, when the shape of the plurality of fan blades 5 is different every other, especially in the structure in which the air F can be taken into the inner peripheral portion 13 of the fan blade 5 from both sides of the fan blade 5 in the direction of the rotation axis 4A. Has advantages. That is, by alternately extending the fan blades 5 having two shapes around the rotor portion 4 so as to promote intake from one side of the rotating shaft 4A direction and from the other side of the rotating shaft 4A direction, The air F can be evenly taken in from both sides of the fan blade 5 in the direction of the rotation axis 4A without being biased.

  In addition, the fan blade 5 here is different in the mounting angle (90 ° −θ1) on the inner peripheral portion 13 side and the mounting angle (90 ° −θ2) on the outer peripheral portion 14 side with respect to the rotor portion 4. 5 can be directed at a desired angle (for example, the exhaust hole 10).

  In the fan motor 1 of the present embodiment, the fan blade 5 has front surfaces 21A and 21B having different curvatures on the inner peripheral side of the inner peripheral portion 13 and the outer peripheral portion 14 on the outer peripheral side of the inner peripheral portion 13. .

  In this case, these front surfaces 21A and 21B can not only push out the air F in the outer peripheral direction of the fan blade 5, but can also promote the intake of air toward the inner peripheral portion 13 of the fan blade 5. Therefore, the amount of intake air to the fan blade 5 is increased, and a desirable air volume characteristic can be obtained.

  In addition, this invention is not limited to said each Example, A various deformation | transformation implementation is possible. For example, in FIG. 7, the fan blade 5 is mounted at angles + θ1 and + θ2 in the right direction as viewed from the normal line X1, but is at angles −θ1 and −in the left direction (−side) as viewed from the normal line X1. You may attach to (theta) 2. In each of the above embodiments, as shown in FIGS. 2 and 7, the exhaust direction of the fan motor 1 is described as only one direction. However, this can be exhausted in the entire circumferential direction of the fan motor 1. But it does n’t matter.

1 is an overall cross-sectional view of a fan motor in a first embodiment of the present invention. It is a top view of a fan motor same as the above. It is whole sectional drawing of the fan motor in another modification. It is the whole fan motor sectional view in another modification. It is a graph which shows the correlation with the fan air volume and noise in a prior art example and a present Example. It is whole sectional drawing of the fan motor in 2nd Example of this invention. It is a top view of a fan motor same as the above. FIG. 7A is a cross-sectional view taken along line A-A ′ in FIG. 6, and FIG. 6B is a cross-sectional view taken along line B-B ′ in FIG. 6. In this example, it is a principal part sectional view of a fan blade which showed a flow of air. It is a whole sectional view of a centrifugal fan motor in a conventional example.

1 Fan motor 2 Casing (outer)
3 Cover (outside)
4 Rotor (Rotor part)
4A Rotating shaft (axis)
5 Fan blade
11,51 Airflow adjustment plate
12,52 Plane section
17,57 Adjustment surface
17A, 57A Outer edge
18,58 Inclined part
19,59 Inflow restriction
41, 42 ring

Claims (10)

In a fan motor having fan blades extending in the outer peripheral direction of the rotor and provided with a shaft serving as the center of rotation of the rotor, intake air is provided from the intake holes facing the respective end faces in the longitudinal direction of the fan blade. The fan blade has a curved surface on the rotor side, and includes an air volume adjusting plate on the outer periphery of the rotor , and the air volume adjusting plate includes a flat portion formed in parallel to the radial direction of the shaft , The fan motor , wherein the flat portion is formed with an inclined portion at an outer peripheral end of the adjustment surface facing the intake hole toward a substantially middle portion of the fan blade . The fan motor according to claim 1, wherein a planar portion other than the inclined portion of the adjustment surface is an inflow restricting portion . The fan motor according to claim 1 or 2 , wherein the fan blade has a shape in which a plurality of curvatures are combined on the rotor side. The fan motor according to any one of claims 1 to 3 , wherein the fan blade and the rotor are integrally formed. Fan motor according to any one of claims 1-4, characterized in that the formation of the thickness of the fan blades to 1.5mm or less. Fan motor according to any one of claims 1 to 5 in which the shape of the plurality of fan blades, characterized in that different from the one every. Fan motor according to any one of claims 1-6, characterized in that the formation of the ring on the end face in the longitudinal direction of the fan blades. The fan motor according to any one of claims 1 to 6 , wherein a ring is formed on each of the end faces in the longitudinal direction of the fan blade. Wherein the inner periphery of the ring, the fan motor according to claim 7 or 8, wherein the allowed also protrude from the outer surface flush or the outer covering of the fan blades. The fan motor according to any one of claims 7 to 9 , wherein a ventilation path side of the ring is formed in a smooth straight line or a curved line.

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