JP4968627B2 - Cooling system - Google Patents

Description

  The present invention relates to a cooling device mounted on a device for cooling the device.

  Recently, there has been a demand for further downsizing and thinning of devices, and how to effectively cool them in a limited space within the device has become an important issue. Therefore, a cooling device is assembled in the device (Patent Document 1).

  FIG. 9 shows a rotating body provided in a conventional cooling device. The rotating body 101 includes a wing body 103, and the wing body 103 is divided into one 105 and the other 106 by a dividing member 104. .

When a conventional cooling device is incorporated in a device and used, the intake space of the intake portion is limited due to the saving of parts inside the device, and the condition of the intake space varies depending on the intake portion.
Japanese Patent Laid-Open No. 2002-21784

  However, the conventional cooling device has a problem in that it cannot cope with actual machine conditions, and the performance of the cooling device cannot be fully exhibited, and there is a limit.

  An object of the present invention is to solve the above problems and to provide a cooling device whose performance is optimized according to actual machine conditions.

  Another object of the present invention is to provide a cooling device that is quiet.

The cooling device according to claim 1 is a cooling device including an outer member, at least one intake portion, at least one exhaust portion, and a rotating body on the outer member, wherein the rotation member The body includes a wing portion and a dividing member that divides the wing portion, and one and the other of the wing portions divided into the dividing member have different shapes from each other, and Each having a wing, wherein the wings provided on one side of the wing and the wings provided on the other side of the wing are provided in directions different from each other. .

A cooling apparatus of a second invention, in the cooling apparatus according to claim 1, wherein, in the one and the other of said wing portions, between the blade body and Hanetai having on one side of the wing portion, said wing characterized in that a said wing body with the other side of the section.

  According to a third aspect of the present invention, there is provided the cooling device according to the first or second aspect, wherein the wings are provided with wings having substantially the same shape on one side and the other side of the wings, and provided on one side of the wings. The number of the wings provided on the other side of the body and the wings is different from each other.

In the cooling device of the fourth aspect of the present invention, the cooling device according to any one of claims 1 to 3, in one and the other of said wing portions, substantially comprises a blade body having the same shape, one of said wing portions The angle of the wing provided on the side and the angle of the wing provided on the other side of the wing are different from each other with reference to 90 degrees .

In the cooling device according to the invention of claim 5 , in the cooling device according to any one of claims 1 to 4 , the dividing member is provided so as to be biased to one of the wings or the other. Features.

According to the invention of claim 1, according to the condition of the intake section as an actual machine condition in which the cooling device is incorporated in the equipment, one and the other of the wings can be sucked into the intake section with high static pressure and high air flow, and By adopting an optimal shape that reduces noise during intake, the static pressure and air flow performance of the cooling device can be optimized under actual machine conditions by increasing the static pressure and air volume of the cooling device. Further, when the wings are rotated, when the noise of one of the rotating wings and the other is generated, the one and the other of the wings are prevented from resonating with each other, and the cooling device can be made quiet.

  According to the invention of claim 2, during the rotation of the wing, when the noise of one and the other of the rotating wings is generated, one and the other of the wings are prevented from resonating with each other, and the cooling device is made quiet. Can be achieved.

  According to the invention of claim 3, during the rotation of the wing body, when the noise of one and the other of the rotating wing bodies is generated, one and the other of the wing bodies are prevented from resonating with each other, and the cooling device is made silent. Can be achieved.

  According to the invention of claim 4, during the rotation of the wing, it is possible to prevent one of the wings from resonating with the other when the noise of one and the other of the rotating wings is generated, thereby reducing the noise of the cooling device. Can be achieved.

According to the invention of claim 5 , by setting one and the other of the wings to an optimum air volume in the intake portion according to the situation of the intake portion as an actual machine condition in which the cooling device is incorporated in the equipment, High static pressure and high air flow can be achieved, and the static pressure performance and air flow performance of the cooling device under actual machine conditions can be optimized.

  1 and 2 show a first embodiment of the present invention. The cooling device 1 has a flat shape as a whole, and is accommodated in a thin electronic device such as a notebook personal computer. The cooling device 1 includes a fan motor 2 as a blower.

  The fan motor 2 includes a rotor 5 of a centrifugal fan as a rotor provided with a fan 4 around a cup-shaped rotor 3 as well known, and a point at the center of the rotor 5 as shown in FIG. It is comprised by the drive part 6 as a drive source which rotates the rotor 5 by making the chain line X into the rotating shaft X. FIG. On the other hand, the outer member of the cooling device 1 is constituted by a bottomed flat casing 7 and a cover 8 that closes the upper surface opening of the casing 7, and the casing 7 and the cover 8 are the air passage 9 </ b> A in the cooling device 1. , 9B.

  One air inlet 10 for sucking air into the cooling device 1 by rotation of the fan motor 2 is provided on the lower surface of the casing 7. In the approximate center of the air inlet 10, an island-shaped motor mounting portion 11 connected to the peripheral portion of the air inlet 10 by a bridge formed in the casing 7 is provided. The motor mounting portion 11 of the casing 7 is mounted with the driving portion 6 of the fan motor 2, and the entire fan motor 2 is provided in the casing 7.

  The cover 8 has a flat plate shape, and the other intake port 12 is provided at a position substantially opposite to the intake port 10. The intake ports 10 and 12 may have the same diameter or may have different diameters. In addition, a plurality of air inlets 10 and 12 may be provided on either the casing 7 or the cover 8. The lower surface portion of the casing 7 and the cover 8 cover a part of the outer periphery of the fan 4. The cover 8 is attached and fixed to the casing 7 by, for example, caulking so as to surround the outer periphery of the rotor 5.

  On the side surface of the cooling device 1, an exhaust port 13 for discharging air to the outside of the cooling device 1 by rotation of the fan motor 2 is provided surrounded by a casing 7 and a cover 8. The exhaust port 13 here is in a direction orthogonal to the intake ports 10 and 12 and is formed in a substantially rectangular shape. Although not illustrated in the present embodiment, for example, a fin-like heat radiating portion is disposed at the exhaust port 13, and heat from a heat-generating component such as an MPU disposed in the thin electronic device D is transferred to a heat pipe or the like. You may guide to a thermal radiation part with a heat transport means. Further, at least one of the casing 7 and the cover 8 is formed of a metal having high rigidity. In addition to metals, resin or the like may be used as the outer material.

  Here, as shown in FIGS. 1 and 2, the fan 4 is arranged in the direction of the rotation axis X by an annular rectifying plate 14 as a divided member formed to protrude in a direction orthogonal to the rotation axis X with respect to the outer periphery of the rotor 3. 1 is divided into a first fan part 15 and a second fan part 16.

  A plurality of first fan portions 15 and second fan portions 16 are arranged along the outer periphery of the rotor 3, are provided integrally with the rectifying plate 14, and have first fan blades 17 and Two fan blades 18 are provided. Here, the number of first fan blades 17 and second fan blades 18 is approximately the same.

  Each of the first fan blade 17 and the second fan blade 18 having substantially the same shape includes a first arc portion 19 and a second arc portion 20 having substantially the same curvature, respectively, and the first arc. The convex side surfaces (hereinafter referred to as the first arc convex surface 21 and the second arc convex surface 22) in the portion 19 and the second arc portion 20 are denoted by reference numerals 21 and 22, respectively.

  Here, as shown in FIG. 2, when the rotation direction R of the fan 4 is clockwise, the first fan blade 17 is formed so that the inlet angle α1 and the outlet angle β1 are obtuse angles larger than 90 degrees, and One arc-shaped convex surface 21 is formed in the forward direction in the rotation direction R. Therefore, the first fan portion 15 is formed as a so-called turbo fan. On the other hand, the second fan blade 18 is formed so that the entrance angle α2 and the exit angle β2 are acute angles smaller than 90 degrees, and the second arcuate convex surface 22 is formed to face backward in the rotation direction R, and is formed backward. Therefore, the second fan portion 16 is formed as a so-called sirocco fan.

  Thus, in the fan 4 of the present embodiment, the arcuate convex surfaces 21 and 22 of either the first fan blade 17 or the second fan blade 18 are disposed forwardly in the rotation direction R of the fan 4. The other arcuate convex surfaces 21 and 22 are disposed rearward in the direction of rotation R of the fan 4. Further, in the first fan part 15 and the second fan part 16 formed by dividing the fan 4 into two parts, the fan part provided with a fan blade facing forward with respect to the rotation direction R of the fan 4 is used for high-pressure air blowing. The turbo fan is a sirocco fan for low-pressure air blowing, and the fan unit having a fan blade facing backward with respect to the rotation direction R of the fan 4 is a coaxial fan of a turbo fan and a sirocco fan whose fan blade directions are different from each other. The structure is provided integrally on the top.

  In the first fan unit 15 and the second fan unit 16, the mounting positions of the outer peripheral ends 23, 24 of the first fan blade 17 and the second fan blade 18 with respect to the rectifying plate 14 are determined with respect to the fan 4. The fan portions 15 and 16 are arranged with a half-pitch shift with respect to the rotation direction R, and the respective fan portions 15 and 16 in the rotation axis X direction are adjacent to the respective first fan blades 17 with the current plate 14 interposed therebetween. The outer peripheral end 24 of the second fan blade 18 is disposed between the outer peripheral ends 23, 23.

  Further, the height H2 of the second fan blade 18 in the direction of the rotational axis X is formed to be about 1.5 times larger than the height H1 of the first fan blade 17 in the direction of the rotational axis X.

  Next, the operation of the cooling device 1 configured as described above will be described. FIG. 3 shows a cross-sectional structure in a state in which the cooling device 1 of the present invention is incorporated in a thin electronic device such as a notebook personal computer, and a symbol D indicates the thin electronic device. As the thin electronic device D is activated, the MPU and other electronic components (not shown) in the device D become energized, and the ambient temperature in the thin electronic device D together with these MPU and electronic components. Rises. At this time, when the fan motor 2 is driven by power supply from the outside, the rotor 5 including the fan 4 rotates about the rotation axis X, and the air inlet 10 of the casing 7 and the air inlet 12 of the cover 8 facing each other. Air (see FIG. 3) is supplied from the intake paths F1 and F2 formed in the above. Since these air inlets 10 and 12 are located opposite to each other across the fan motor 2, the air taken in from the air inlet 10 does not hit the cover 8, and the air taken in from the air inlet 12 is the lower surface portion of the casing 7. Without being hit, the air passes through the air passages 9A and 9B and is smoothly sent out to the exhaust port 13 provided in the direction orthogonal to the intake ports 10 and 12, respectively.

  When the cooling device 1 according to the present embodiment is incorporated in the thin electronic device D, in order to guide and supply air from the intake ports 10 and 12 into the cooling device 1, the upstream side of the intake ports 10 and 12 and the thin electronic device. A predetermined gap G1, G2 (gap) is provided between the air intake D and air intake spaces S1, S2 are provided upstream of the air intake ports 10, 12, respectively. , 12 are secured for the respective intake paths F1, F2.

  Then, as an actual machine condition for incorporating the cooling device 1 of the present embodiment into the thin electronic device D, each intake space S1, of each intake port 10, 12 for taking air into the cooling device 1 incorporated in the thin electronic device D, According to S2, the first fan portion 15 and the second fan portion 16 having different shapes provided in the fan 4 are selectively disposed in the intake ports 10 and 12, respectively.

  As shown in FIG. 3, the gap G1 between the upstream side of the air inlet 12 for securing the air intake space S1 and the electronic device D is narrow, and air is sucked in with a predetermined air volume and pressure while suppressing noise during intake. The second fan section 16 side capable of low-pressure air blowing is disposed at the intake port 12 on the side that is difficult to perform (hereinafter referred to as the gap G1 side). Further, the gap G2 between the upstream side of the intake port 10 and the electronic device D is wide, and the side that can suck in air with a predetermined air volume and pressure while suppressing noise during intake (hereinafter referred to as the gap G2 side). The first fan portion 15 side capable of high-pressure air blowing is disposed in the intake port 10 of the name.

  In this case, by arranging the second fan portion 16 side as a sirocco fan capable of low-pressure airflow at the intake port 12 on the gap G1 side, turbulence near the intake port 12 during intake is suppressed and noise is reduced. It can be suppressed and the static pressure can be increased. Further, by arranging the first fan unit 15 side as a turbo fan capable of high-pressure airflow at the intake port 10 on the gap G2 side, high-pressure air is efficiently sent into the cooling device 1, and the air volume of the cooling device 1 Can be improved. As described above, the first fan unit 15 and the second fan unit 16 having different shapes provided on the fan 4 are used as the actual machine conditions in which the cooling device 1 of this embodiment is incorporated in the thin electronic device D. The first fan portion 15 and the second fan portion 16 of the fan 4 are sucked into the intake ports 10 and 12 with a high static pressure and a high air volume according to the conditions of the intake spaces S1 and S2 of the ports 10 and 12, respectively. It is possible to optimize the static pressure performance and air flow performance of the cooling device 1 under actual machine conditions by increasing the static pressure and air flow of the cooling device 1 by adopting an optimal shape that can reduce noise during intake. can do.

  In addition, by providing the first fan unit 15 and the second fan unit 16 in different shapes, a unique frequency at which the noise of the rotating fan units 15 and 16 reaches a peak during the rotation of the fan 4 is dispersed. Thus, when the noise peaks of the fan portions 15 and 16 occur, the fan portions 15 and 16 can be prevented from resonating with each other, and the cooling device 1 can be made silent.

  An equal number of first fan blades 17 and second fan blades 18 are provided, and the outer peripheral ends 23 and 24 of the first fan blade 17 and the second fan blade 18 are attached to the current plate 14. The positions of the first fan blade 17 and the second fan blade 18 are arranged so as to be shifted by a half pitch with respect to the rotation direction R of the fan 4. In this state, the outer peripheral end 24 of the second fan blade 18 is disposed between the outer peripheral end 23 and the outer peripheral end 23 of the first fan blade 17.

  In this case, the mounting positions of the outer peripheral ends 23 and 24 of the fan blades 17 and 18 in the fan parts 15 and 16 are shifted by a half pitch, and the shapes of the fan parts 15 and 16 are made different. The frequency (natural frequency) inherent to each of the fan units 15 and 16 where noise peaks are generated during rotation of the fan units 15 and 16 is dispersed, and when the noise peaks of the fan units 15 and 16 are generated, the fan units 15 and 16 are distributed. Can be prevented from resonating with each other, and the cooling device 1 can be further silenced.

  In addition, in the second fan portion 16 for low-pressure ventilation disposed in the intake port 12 on the smaller side of the intake space S1, the height H2 of the second fan blade 18 in the rotation axis X direction is set to the other fan. The first fan blade 15, which is the first fan blade 17, is provided to be larger than the height H 1 of the first fan blade 17 in the rotation axis X direction.

  In this case, even when the gap G1 with the electronic device D is narrow and a turbo fan for high-pressure ventilation cannot be arranged to suppress noise during intake, the second fan section 16 that is a sirocco fan for low-pressure ventilation is used. By increasing the height H2 of the second fan blade 18 and increasing the air volume of the second fan section 16, it is possible to reduce the noise of the cooling device 1 and increase the air volume.

  Further, the fan 4 is provided between the first fan part 15 and the second fan part 16 in the direction of the rotation axis X so as to be divided into two parts, the first fan part 15 and the second fan part 16. A rectifying plate 14 is provided.

  In this case, the air taken into the outer members 7 and 8 from the air inlets 10 and 12 by rotating the fan 4 is caused by the surface perpendicular to the rotation axis X provided on the current plate 14, and the outer members 7 and 8. Since the air is guided to the exhaust port 13 in a rectified state without flowing back in the air 8, the air in the outer shell members 7, 8 is efficiently circulated and the reverse flow of the air in the outer shell members 7, 8 is reduced. This makes it possible to reduce the noise of the cooling device 1.

  As described above, in this embodiment, the casing 7 and the cover 8 that are the outer members, the intake ports 10 and 2 that are at least one intake portion in the casing 7 and the cover 8, and the exhaust ports that are at least one exhaust portion. The cooling device 1 includes a rotor 13 that is a rotating body, and the rotor 5 includes a fan 4 that is a wing portion and a current plate 14 that is a dividing member that divides the fan 4. The first fan portion 15 that is one of the fans 4 divided into 14 and the second fan portion 16 that is the other of the fans 4 have different shapes.

  In this case, the actual fan condition in which the cooling device 1 of this embodiment is incorporated in the thin electronic device D depends on the state of the intake spaces S1 and S2 of the intake ports 10 and 12, and the first fan unit 15 of the fan 4 and The second fan unit 16 has an optimum shape that can be sucked into each of the air inlets 10 and 12 with high static pressure and high air volume, and that reduces noise during intake, so that the high static pressure and It is possible to increase the air volume and optimize the static pressure performance and air volume performance of the cooling device 1 under actual machine conditions.

  Further, in the present embodiment, the first fan blade 17 and the second fan blade 18 that are blades are respectively attached to the first fan portion 15 and the second fan portion 16 of the fan 4 divided into the current plate 14. The first fan blade 17 provided in the first fan part 15 and the arcuate convex surfaces 21 and 22 facing the second fan blade 18 provided in the second fan part 16 are the rotational direction R of the fan 4. Are provided in different directions.

  In this case, when the fan 4 rotates, a unique frequency at which the noise of the rotating fan units 15 and 16 reaches a peak is dispersed, and when the noise peaks of the fan units 15 and 16 occur, each fan unit 15 16 can be prevented from resonating with each other, and the cooling device 1 can be silenced.

  In the present embodiment, the fan 4 is a turbo with the rectifying plate 14 sandwiched and the arcuate convex surface 21 facing forward with respect to the rotation direction R of the fan 4 and the outlet angle β1 being an obtuse angle greater than 90 degrees. The first fan portion 15 as a fan and the second sirocco fan which is formed rearward with the direction of the arc convex surface 22 facing away from the rotation direction R of the fan 4 and the exit angle β2 is an acute angle smaller than 90 degrees. The fan section 16 is divided into the first fan section 15 and the second fan section 16 except for the turbo fan and the sirocco fan. A fan is added, and one of these turbo fan, sirocco fan, and radial fan is used as the first fan part, and the turbo fan, sirocco fan, and Depending on the intake spaces S1 and S2 of the intake ports 10 and 12 as actual machine conditions for incorporating the cooling device 1 of this embodiment into the thin electronic device D by using either one of the dial fans as the second fan portion. The cooling device of the present embodiment is selected by selecting an optimum fan shape from among centrifugal fans having different arc convex surface orientations and outlet angles of turbo fans, sirocco fans, and radial fans for each intake port. 1 is incorporated into the thin electronic device D, and the first fan unit 15 and the second fan unit 16 of the fan 4 are set in accordance with the status of the intake spaces S1 and S2 of the intake ports 10 and 12, respectively. By adopting an optimal shape that allows intake to the intake ports 10 and 12 with high static pressure and high airflow and that reduces noise during intake, the cooling device 1 is designed to have high static pressure and high airflow, and under actual machine conditions. Cooling It is possible to optimize the static pressure performance and air flow performance of the location 1.

  FIG. 4 shows a second embodiment of the present invention, and the same components as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

  In the cooling device 1 of the present embodiment, the first fan unit 15 and the second fan unit 16 are the first arc unit 19 and the second arc unit with respect to the first fan blade 17 and the second fan blade 18. The shape of the portion 20, the orientation of the first arc convex surface 21 and the second arc convex surface 22 with respect to the rotation direction R of the fan 4, the number of the first fan blades 17 and the second fan blades 18, the first inlet angle α1 And the second inlet angle α2, the first outlet angle β1, and the second outlet angle β2 have the same shape.

  As a feature of the cooling device 1 of this embodiment, the mounting positions of the first fan blade 17 and the second fan blade 18 with respect to the rectifying plate 14 are shifted by a half pitch with respect to the rotation direction R of the fan 4. The second fan blade 18 is disposed between the adjacent first fan blades 17 with the rectifying plate 14 sandwiched in the rotation axis X direction. It is said.

  In this case, the mounting positions of the first fan blade 17 and the second fan blade 18 with respect to the rectifying plate 14 are shifted by a half pitch with respect to the rotation direction R of the fan 4. And the second fan part 16 is formed in a different shape, and when the fan 4 rotates, the unique frequency at which the noise of each of the rotating fan parts 15 and 16 reaches a peak is distributed to each fan part 15, When 16 noise peaks occur, the fan portions 15 and 16 are prevented from resonating with each other, and the cooling device 1 can be silenced.

  As described above, in this embodiment, the first fan unit 15 and the second fan unit 16 of the fan 4 divided into the rectifying plate 14 are provided in the first fan unit in the direction of the rotation axis X of the fan 4. A second fan blade 18, which is a wing provided in the second fan unit 16, is disposed between the first fan blade 17, which is a wing, and the first fan blade 17.

  In this case, when the fan 4 rotates, a unique frequency at which the noise of the rotating fan units 15 and 16 reaches a peak is dispersed, and when the noise peaks of the fan units 15 and 16 occur, each fan unit 15 16 can be prevented from resonating with each other, and the cooling device 1 can be silenced.

  FIG. 5 shows a third embodiment of the present invention, and the same components as those in the first and second embodiments are denoted by the same reference numerals and the description thereof is omitted.

  The first fan part 15 and the second fan part 16 in the cooling device 1 of the present embodiment are the first arc part 19 and the second arc part with respect to the first fan blade 17 and the second fan blade 18. 20, the orientation of the first arc convex surface 21 and the second arc convex surface 22 with respect to the rotation direction R of the fan 4, the first inlet angle α1 and the second inlet angle α2, the first outlet angle β1 and the second Have the same shape in which the outlet angles β2 of each are equally configured.

  The cooling device 1 of the present embodiment uses different numbers of first fan blades 17 and second fan blades 18, and the number of second fan blades 18 is the same as that of the first fan blade 17 as shown in FIG. 5. Half the number of sheets. Furthermore, the mounting positions of the first fan blade 17 and the second fan blade 18 with respect to the rectifying plate 14 are shifted by a half pitch with respect to the rotation direction R of the fan 4, and the rectifying plate 14 is arranged in the rotation axis X direction. The second fan blades 18 are arranged between the adjacent first fan blades 17 in a state of being sandwiched between them.

  In this case, the first fan blade 17 and the second fan blade 18 have different numbers, so that the first fan portion 15 and the second fan portion 16 have different shapes and rotate when the fan 4 rotates. The unique frequency at which the noise of the fan units 15 and 16 reaches the peak is dispersed to prevent the fan units 15 and 16 from resonating with each other when the noise peaks of the fan units 15 and 16 occur. It is possible to reduce the noise of the device 1. Further, the air volume of the first fan unit 15 and the second fan unit 16 is arbitrarily adjusted, and the intake air of each of the intake ports 10 and 12 is set as an actual machine condition in which the cooling device 1 of this embodiment is incorporated in the thin electronic device D. By setting the first fan unit 15 and the second fan unit 16 of the fan 4 to an optimum air volume for each of the air inlets 10 and 12 according to the situation of the spaces S1 and S2, the cooling device 1 can be kept quiet. It is possible to optimize the static pressure performance and air flow performance of the cooling device 1 under actual machine conditions by increasing the pressure and air flow.

  Further, the positions of the fan blades 17 and 18 of the first fan unit 15 and the second fan unit 16 are shifted by a half pitch from each other, so that the shapes of the fan units 15 and 16 are different. The frequency unique to each fan unit 15 and 16 (natural frequency) where noise peaks occur when the units 15 and 16 rotate is dispersed to prevent resonance from occurring when the noise peaks of the fan units 15 and 16 occur. Further, it is possible to further reduce the noise of the cooling device 1.

  As described above, in this embodiment, the first fan blade 17 and the second fan portion 16 of the fan 4 divided into the current plate 14 are respectively provided with the first fan blade 17 and the first fan blade 17 having substantially the same shape. Two fan blades 18 are provided, and the numbers of the first fan blades 17 and the second fan blades 18 are different from each other.

  In this case, the first fan blade 17 and the second fan blade 18 have different numbers, so that the first fan portion 15 and the second fan portion 16 have different shapes and rotate when the fan 4 rotates. The unique frequency at which the noise of the fan units 15 and 16 reaches the peak is dispersed to prevent the fan units 15 and 16 from resonating with each other when the noise peaks of the fan units 15 and 16 occur. It is possible to reduce the noise of the device 1. Further, the air volume of the first fan unit 15 and the second fan unit 16 is arbitrarily adjusted, and the intake air of each of the intake ports 10 and 12 is set as an actual machine condition in which the cooling device 1 of this embodiment is incorporated in the thin electronic device D. By setting the first fan unit 15 and the second fan unit 16 of the fan 4 to an optimum air volume for each of the air inlets 10 and 12 according to the situation of the spaces S1 and S2, the cooling device 1 can be kept quiet. It is possible to optimize the static pressure performance and air flow performance of the cooling device 1 under actual machine conditions by increasing the pressure and air flow.

  FIG. 6 shows a fourth embodiment of the present invention. The same components as those in the first to third embodiments are denoted by the same reference numerals and the description thereof is omitted.

  The first fan part 15 and the second fan part 16 in the cooling device 1 of the present embodiment are the first arc part 19 and the second arc part with respect to the first fan blade 17 and the second fan blade 18. 20 and the same shape in which the directions of the first arc convex surface 21 and the second arc convex surface 22 with respect to the rotation direction R of the fan 4 are configured to be equal to each other.

  The cooling device 1 of the present embodiment rotates the first fan blade 17 and the second fan blade 18 having the same shape by forming the first arc portion 19 and the second arc portion 20 with the same curvature. A plurality of first fan blades 17 and second fan blades 18 are arranged on the outer periphery of the rotor 3 with a predetermined gap in the direction of the axis X with a predetermined interval between them. While the pitches of the outer peripheral ends 23 and 24 in the rotational direction R are aligned, the inner peripheral ends 25 of the first fan blades 17 are moved in the rotational direction R of the fan 4 from the inner peripheral ends 26 of the second fan blades 18. Are arranged with a delay angle γ backward. In this way, the first fan blade 17 and the second fan blade 18 are different from each other in the first inlet angle α1 and the second inlet angle α2, the first outlet angle β1 and the second outlet angle β2. It is characterized by being arranged as described above.

  In this case, the first fan blade 17 and the second fan blade 18 are set such that the first inlet angle α1 and the second inlet angle α2, the first outlet angle β1 and the second outlet angle β2 are different from each other. By providing the first fan unit 15 and the second fan unit 16 in different shapes, a unique frequency at which the noise of each of the rotating fan units 15 and 16 reaches a peak when the fan 4 rotates. Are distributed to prevent the fan portions 15 and 16 from resonating with each other at the time of noise peaks of the fan portions 15 and 16, thereby reducing the noise of the fan 4 and the first fan portion 15 and the first fan portion 15. The air volume and static pressure of the second fan unit 16 can be adjusted to optimize the static pressure performance and air volume performance of the cooling device 1 under actual machine conditions.

  As described above, in the present embodiment, the first fan blade 17 which is a substantially identical wing is provided on the first fan portion 15 and / or the second fan portion 16 of the fan 4 divided into the current plate 14. And the second fan blade 18, and the inlet angles α 1 and α 2 and the outlet angles β 1 and β 2 that are the mounting angles of the first fan blade 17 and the second fan blade 18 are different from each other.

  In this case, when the fan 4 rotates, a unique frequency at which the noise of the rotating fan units 15 and 16 reaches a peak is dispersed, and when the noise peaks of the fan units 15 and 16 occur, each fan unit 15 , 16 can be prevented from resonating with each other, and the noise of the fan 4 can be reduced, and the intake space of each of the intake ports 10, 12 as an actual machine condition in which the cooling device 1 of this embodiment is incorporated in the thin electronic device D. Depending on the situation of S1 and S2, the first fan part 15 and the second fan part 16 of the fan 4 can be sucked into the intake ports 10 and 12 with high static pressure and high air volume, and noise during intake By optimizing the shape, it is possible to increase the static pressure and the air volume of the cooling device 1 and to optimize the static pressure performance and the air volume performance of the cooling device 1 under actual machine conditions.

  7 to 8 show a fifth embodiment of the present invention, and the same components as those in the first to fourth embodiments are denoted by the same reference numerals and the description thereof is omitted.

  The first fan part 15 and the second fan part 16 in the cooling device 1 of the present embodiment are the first arc part 19 and the second arc part with respect to the first fan blade 17 and the second fan blade 18. 20, the orientation of the first arc convex surface 21 and the second arc convex surface 22 with respect to the rotation direction R of the fan 4, the number of the first fan blades 17 and the second fan blades 18, the first inlet angle α1, and The second inlet angle α2, the first outlet angle β1, and the second outlet angle β2 are configured to be equal to each other, and have the same shape with the same pitch with respect to the rotation direction R.

  The fan 4 according to the present embodiment is provided in the first fan unit 15 in a rectifying plate 14 that divides the fan 4 into a first fan unit 15 and a second fan unit 16 in the rotation axis X direction. Further, when the position where the heights of the second fan blades 18 provided in the first fan blade 17 and the second fan unit 16 are equal to each other in the rotation axis X direction is the central portion of the rectifying plate 14. The rectifying plate 14 of the present embodiment is characterized in that it is disposed at a position arbitrarily deviated in the direction of the rotation axis X from the central portion of the rotation axis X.

  Therefore, the fan 4 is divided into two in the direction of the rotation axis X by the current plate 14 by arranging the current plate 14 at a position arbitrarily deviated in the direction of the rotation axis X from the central portion. In the first fan unit 15 and the second fan unit 16, the heights H1 and H2 in the rotation axis X direction of the first fan blade 17 and the second fan blade 18 are formed to be different from each other. .

  In this case, by arranging the rectifying plate 14 at a position arbitrarily displaced in the direction of the rotation axis X from the central portion of the rotation axis X, the rotation axis X direction of the first fan blade 17 and the second fan blade 18 is arranged. The heights H1 and H2 can be formed at different arbitrary heights, and the fan portions 15 and 16 can be set at an arbitrary air volume. By doing so, it is possible to increase the static pressure and the air volume of the cooling device 1 and to optimize the static pressure performance and the air volume performance of the cooling device 1 under actual machine conditions.

  As described above, in this embodiment, the rectifying plate 14 is provided to be biased to either the first fan portion 15 or the second fan portion 16 in the direction of the rotation axis X of the fan 4. During rotation, the unique frequency at which the noise of the rotating fan units 15 and 16 reaches a peak is dispersed, and the fan units 15 and 16 resonate with each other when the noise peaks of the fan units 15 and 16 occur. This makes it possible to reduce the noise of the fan 4 and to arbitrarily set the position of the rectifying plate 14 in the direction of the rotation axis X, so that the first fan unit 15 and the second fan unit 16 By arbitrarily changing the ratio of the rotation axis X direction and arbitrarily setting the heights H1 and H2 of the first fan unit 15 and the second fan unit 16 in the rotation axis X direction, the first fan unit 15 And the air flow of the second fan section 16 Can be set as desired. Here, as the actual machine conditions in which the cooling device 1 of the present embodiment is incorporated in the thin electronic device D, the first fan unit 15 of the fan 4 and the fan 4 according to the state of the intake spaces S1 and S2 of the intake ports 10 and 12 and By setting the second fan unit 16 to an optimum air volume for each of the air inlets 10 and 12, the static pressure of the cooling apparatus 1 under actual machine conditions can be increased. Air flow performance can be optimized.

  In addition, this invention is not limited to the said Example, A various deformation | transformation implementation is possible within the range of the summary of this invention. For example, you may comprise combining the characteristic part in each said Example, respectively. Moreover, in the said 1st-5th Example, although the rotation direction R of the fan 4 was demonstrated as clockwise as shown in FIGS. 1-8, about the rotation direction R of this fan 4, FIGS. In FIG. 4, it may be counterclockwise. Therefore, the first fan part 15 and the second fan part 16 are both turbo fins with the arcuate convex surfaces 21 and 22 facing the rotation direction R, or the arcuate convex surfaces 21 and 22 facing away from the rotation direction R and facing backward. It is also possible to use a sirocco fan provided in the above, or a radial fan whose exit angles β1, β2 are 90 degrees, that is, a right angle. With respect to this radial fan, the fan blades 17 and 18 may be curved or arcuate with arc portions. Further, the heights H1, H2, the number and shape of the fan blades 17 and 18 can be appropriately changed. Further, the position of the annular plate 14 can be changed as appropriate. Furthermore, the number of intake ports and exhaust ports can be changed as appropriate.

It is sectional drawing of the cooling device which shows 1st Example of this invention. It is a perspective view of the rotor provided in the cooling device same as the above. It is sectional drawing which showed the state which incorporated the cooling device of the present Example in the thin electronic device same as the above. It is a perspective view of the rotor with which the cooling device which shows 2nd Example of this invention was equipped. It is a perspective view of the rotor with which the cooling device which shows 3rd Example of this invention was equipped. It is a top view of the rotor with which the cooling device which shows 4th Example of this invention was equipped. It is a perspective view of the rotor with which the cooling device which shows 5th Example of this invention was equipped. It is sectional drawing which showed the state which incorporated the cooling device of the present Example in the thin electronic device same as the above. It is a perspective view of the rotary body with which the conventional cooling device was equipped.

1 Cooling device 4 Fan (wings)
5 Rotor (Rotating body)
7 Casing (outer member)
8 Cover (outer member)
10,12 Air intake (intake part)
13 Exhaust port (exhaust part)
14 Current plate (divided member)
15 First fan part (one of the wings)
16 Second fan part (the other of the wings)
17 First fan blade (blade)
18 Second fan blade (blade)
α1, α2 Entrance angle (mounting angle)
β1, β2 outlet angle (mounting angle)

Claims (5)

A cooling device comprising an outer member, at least one intake portion, at least one exhaust portion, and a rotating body on the outer member,
The rotating body includes a wing portion and a dividing member that divides the wing portion,
One and the other of the wings divided into the divided members have different shapes ,
One and the other of the wings are each provided with wings,
The cooling apparatus according to claim 1, wherein the wing body provided on one side of the wing portion and the wing body provided on the other side of the wing portion are provided in directions different from each other . Claimed in one and the other of said wing portions, which between the blades body and Hanetai having on one side of the wing portion, characterized in that a said wing body having on the other side of the wing portions Item 2. The cooling device according to Item 1. One and the other of the wings are provided with wings of substantially the same shape,
The cooling device according to claim 1 or 2, wherein the number of the wings provided on one side of the wings and the number of the wings provided on the other side of the wings are different from each other. One and the other of the wings are provided with wings of substantially the same shape,
The angle of the wing provided on one side of the wing and the angle of the wing provided on the other side of the wing are different from each other on the basis of 90 degrees. The cooling apparatus of any one of -3 . The dividing member, the cooling device according to any one of claims 1 to 4, characterized in that provided deviated to either one or the other of said wing portions.

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