JP2006002751A - Heat-dissipating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat-dissipating device capable of enhancing stability during high speed operation and reducing occurrence of vibrations. <P>SOLUTION: A heat-dissipating device having a two-way motor fixing design comprises a fan frame made up of a first frame and a second frame and a rotor blade mounted in the fan frame. The first frame has a bearing tube and accommodates a first bearing. The second frame has a base and accommodates a second bearing. The first and second frames jointly support and fix a rotary shaft of the rotor blade. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a heat dissipation device, and more particularly to a high-pressure centrifugal fan having a two-way motor fixed design.

  As shown in FIG. 1, the general blower includes an outer frame 10, a motor 11, a fan blade structure 12, and an upper lid 13, and the outer frame 10 includes an opening 101 serving as an air outlet of the blower. 11 is fitted on the base 102 of the outer frame 10 and rolls on the fan blade structure 12. The upper lid 13 has a circular opening 131 that serves as an air inlet of the blower. The fan blade structure 12 further includes a hub 121, an annular plate 122, and a plurality of blades 123 provided on the hub 121.

  In the known blower design, the motor is fixed as shown in FIG. 2 and FIG. 3 by single side fixing, and in FIG. The bearing 14 is installed in the base 102. In FIG. 3, two bearings 141 and 142 are installed in the base 102 to fix and support the rotating shaft 15. However, when applied to a high-pressure centrifugal fan, such a design method is unstable and the vibration becomes more severe.

  The present invention seeks to provide a heat dissipation device that applies a bi-directional fixed motor design.

  It is another object of the present invention to provide a high-pressure centrifugal fan that applies a two-way fixed motor design, to improve the stability during high-speed operation and to reduce the occurrence of vibrations.

  The heat dissipation device of the present invention includes a fan frame including first and second frames and a rotor blade installed in the fan frame. The first frame has a bearing tube and holds the first bearing, and the second frame has a base and holds the second bearing and jointly supports the rotating shaft of the rotor blade. To do.

  Preferably, the rotor blade includes a bottom plate, a ring portion, and a first blade unit. The first blade unit extends from the outer periphery of the ring portion downward to the bottom plate surface. The rotor blade further has a second blade unit and is installed on the bottom plate surface, and the first blade unit and the second blade unit are arranged in an up / down or left / right cross arrangement. The number, shape, or scale of the blades of the first blade unit and the second blade unit may be homologous or heterologous. Both blade outer diameters or heights may be homologous or heterologous. In addition, the first blade unit and the second blade unit are connected to each other, partially connected, and completely disconnected. The first blade unit and the second blade unit are located on the same side of the rotor blade or on the opposite side of the rotor blade.

  Preferably, the ring portion, the bottom plate, the first blade unit, and the second blade unit are generated by an integral injection molding method. Alternatively, the bottom plate and the first blade unit are integrally injection-molded, and the ring portion and the second blade unit are integrally injection-molded and further combined with the rotor blade.

  In addition, the fan frame has at least one wind inlet and is formed on the second frame. The inner edge of the wind inlet has a wall surface, extends inside the fan frame, divides the space in the frame, and defines the air collecting path. One end of the wall has a convex edge and defines the inlet of the air collecting passage. The blade unit of the rotor blade extends in the radial direction near the inlet of the air collecting passage. The height of the airflow path and the height of the flowway passing through the rotor blade are partially or completely overlapped. The cross-sectional area of the air collecting path is substantially equal to the cross-sectional area of the wind outlet.

  In addition, a base and a plurality of flow guide structures are further provided at the wind inlet of the second frame, and the plurality of flow guide structures are installed between the base and the wall surface to improve the wind pressure of the heat dissipation device. The plurality of flow guiding structures are fixed to a base or a wall surface, and have a rectangular, flat plate, curved arc, or airfoil structure. The plurality of flow guiding structures have an inclination angle, and the shape thereof is similar to the blade shape of the rotor blade.

  Preferably, the plurality of current-conducting structures are partially connected between the base and the wall surface, and the remaining portions are connected to the base and the wall surface at both ends, respectively, and the intermediate portion is disconnected and forms a free end. To do.

  More preferably, the plurality of flow guiding structures are partially connected between the base and the wall surface, one part is connected to the wall surface, the other end is a free end, and the other part is connected to the base. The other end is a free end.

  In addition, the fan frame includes at least one air outlet and has a flow guiding structure. Furthermore, an axial compression type air passage is provided in the fan frame.

  The heat dissipating device is a unidirectional air intake type blower, a reverse hook type centrifugal fan, a bidirectional air intake type blower, a centrifugal fan, or an axial flow type fan.

  In addition, the heat dissipating device further includes a driving device, is fitted on the bearing tube, and is coupled to the rotor blade to drive the rotor blade.

  Apply to high-pressure centrifugal fans to improve stability during high-speed operation and reduce the occurrence of vibration.

  4-6 is a figure which shows the 1st Example of the heat dissipation apparatus of this plan. In the embodiments, the centrifugal fan is taken as an example, but it may be applied to an axial fan. The centrifugal fan is a single-direction inlet type blower, and mainly includes a first frame 21, a second frame 22, a driving device 23, an iron housing 24, and a rotor blade 25. The first frame 21 has a bearing tube 211 and is coupled to the rotor blade 25, on which the drive device 23 rests, and drives the rotor blade. The second frame 22 includes a wind inlet 221 and a wall surface 222 extending downward from the inner edge of the wind inlet. After the second frame 22 and the first frame 21 are combined, the second frame 22 and the second frame 22 are separated by the wall surface 222. A space formed after the combination of one frame 21 is divided to define a space in which the air collecting path 26 and the rotor blade 25 are placed, and at the same time, an air outlet 212 is formed. The bottom end of the wall surface has a convex edge 223 that extends outward in the radial direction, and defines an inlet 261 of the air collecting passage.

  The rotor blade 25 includes an annular portion 251, a bottom plate 252, a first blade unit 253, and a second blade unit 254. Both the first blade unit 253 and the second blade unit 254 are composed of a plurality of blades, and the first blade unit 253 extends downward from the outer periphery of the ring portion 251 to the surface of the bottom plate 252. The arrangement method of the first blade unit 253 and the second blade unit 254 is an alternating arrangement as shown in FIG.

  Of course, the scale size, shape, and arrangement method of the first blade unit 253 and the second blade unit 254 are not limited to the design shown in FIG. 4. For example, the fan blade design of the rotor blade includes at least two types of blade units. A composite fan blade design consisting of The number, shape and scale of the blades of the various blade units may be homologous or heterogeneous. The outer diameter and height of each blade may be homologous or heterologous. In the arrangement, the blade units are connected to each other, partially connected to each other, and completely disconnected, and each blade unit is on the same side or opposite side of the rotor blade. The ring portion, the bottom plate, the first blade unit, and the second blade unit are generated by an integral injection molding method. Alternatively, the bottom plate and the first blade unit are integrally injection-molded, and the ring portion and the second blade unit are integrally injection-molded and further combined with the rotor blade.

  A base 224 is further installed at the wind inlet of the second frame 22 and a plurality of flow guide structures 225 are installed between the base 224 and the wall surface 222 to increase the wind pressure of the centrifugal fan.

  When the centrifugal fan is operated, the air flow is sucked from the wind inlet 221, passes through the first blade unit 253 and the second blade unit 254 of the rotor blade, and further passes through the inlet 261 located in the air collecting passage 26. The air is introduced into the air collecting passage 26, and pressurization and gas holding are performed to prevent a rapid change in the wind pressure. Further, a high-pressure air flow is discharged from the air outlet 212.

  In this embodiment, the wall extending downward at the air inlet edge of the centrifugal fan leaves only the small air outlet leaving the air collecting passage 26 and the rotor blade 25, leaving only a small air outlet, and the rotor. The air pressure flow through the blade is lengthened to prevent rapid pressure changes. The height of the air collecting path and the flow height passing through the rotor blade and the guide flow partially or completely overlap with each other on the rotor blade in the axial direction, thereby achieving the purpose of reducing the thickness of the centrifugal fan. The cross-sectional area of the air collecting path 26 is substantially equal to the cross-sectional area of the air outlet 212. Thereby, it can avoid that work efficiency falls by the change of an area of airflow.

  In addition, as shown in FIG. 5, the present invention provides a second bearing 232 provided inside the base 224 of the second frame 22 in addition to disposing the first bearing 231 in the bearing tube 211. The rotation shaft 27 of the blade 25 is jointly supported to improve the stability at which the fan operates at high speed and reduce the occurrence of vibration. The bearing used is a ball bearing or a sleeve bearing. In addition, the present invention may employ an axial compression type airway 29 design as shown in FIG.

  In addition to the above-mentioned method in which the flow guide structure is disposed at the wind inlet, a similar flow guide structure is further installed at the wind outlet of the heat dissipation device. Different selections and changes are possible. In addition, when the concept of the present plan is applied to a reverse hook type centrifugal fan, a bidirectional air intake type blower, a centrifugal fan, or an axial flow type fan, the flow guide structure is installed at the wind inlet in the fan. Or at the same time installed at each wind inlet.

  As described above, the present invention provides a heat dissipation device that applies a two-way fixed motor design, and in particular, is applied to a high-pressure centrifugal fan to improve stability during high-speed operation and reduce the occurrence of vibration.

  In the present invention, preferred embodiments have been disclosed as described above. However, the present invention is not limited to the present invention, and any person who is familiar with the technology can use various methods within the spirit and scope of the present invention. Therefore, the protection scope of the present invention is based on the content specified in the claims.

It is a three-dimensional exploded view of a known blower. It is sectional drawing of a well-known air blower. It is another sectional drawing of a well-known air blower. It is a three-dimensional exploded view of a preferred embodiment of the heat dissipation device of the present invention. It is sectional drawing of the heat dissipation apparatus of FIG. FIG. 5 is a combined three-dimensional view of the heat dissipation device of FIG. 4.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Outer frame 11 ... Motor 12 ... Fan blade structure 13 ... Upper cover 101 ... Opening 102 ... Base 131 ... Circular opening 121 ... Hub 122 ... Ring-shaped plate 123 ... Blade 14, 141, 142 ... Bearing 15 ... Rotating shaft 21 ... First Fan frame 22 ... second fan frame 23 ... drive device 24 ... iron housing 25 ... rotor blade 211 ... bearing tubes 231 and 232 ... bearing 27 ... rotary shaft 221 ... air inlet 222 ... wall 26 ... air collecting passage 212 ... air outlet 223 ... convex edge 261 ... inlet 251 ... ring portion 252 ... bottom plate 253 ... first blade unit 254 ... second blade unit 224 ... base 225 ... convection structure 29 ... axial compression type air passage

Claims (18)

A heat dissipation device,
A fan frame consisting of a first frame and a second frame;
Installed in the fan frame, the first frame has a sleeve base and holds a first bearing; the second frame has a base and holds a second bearing; A rotor blade for supporting the rotating shaft;
A heat dissipator characterized by comprising: The heat dissipation device according to claim 1, wherein the rotor blade includes a bottom plate, an annulus, and a first blade unit. The heat dissipation device according to claim 2, wherein the first blade unit extends downward from the ring portion to the bottom plate surface. The heat dissipation device according to claim 2, wherein the rotor blade has a second blade unit and is installed on a surface of the bottom plate. The heat dissipation device according to claim 4, wherein the number, shape, scale, outer diameter, or altitude of the first and second blade units are homologous or heterologous. The heat dissipating apparatus according to claim 4, wherein the first and second blade units are connected to each other, partially connected, or completely disconnected. 5. The heat dissipation device according to claim 4, wherein the first and second blade units are located on the same side or different sides of the rotor blade. The ring portion, the bottom plate, the first blade unit, and the second blade unit are generated by integral injection molding, or the bottom plate and the first blade unit are integrally injection molded, and the ring portion and the first blade unit 5. A heat dissipation device according to claim 4, wherein the two-blade unit is integral injection molding and is combined with a complete rotor blade. The fan frame has at least one air inlet, is formed on the second frame, has a wall surface at an inner edge of the air inlet, extends toward the inside of the frame, and divides the space in the fan frame Then, a heat collecting device is defined. One end of the wall surface has a convex edge to define an inlet of the air collecting passage, and the rotor blade has a blade unit and extends radially toward the vicinity of the inlet of the air collecting passage. The heat dissipation device according to claim 9, wherein the heat dissipation device is a heat dissipation device. The altitude of the air collecting passage and the altitude passing through the rotor blade partially or completely overlap, and the cross sectional area of the air collecting passage is substantially equal to the cross sectional area of the air outlet of the fan frame. The heat dissipation device according to claim 9. The wind inlet of the second frame further includes a base, and a plurality of flow guide structures are installed between the base and the wall surface to increase the wind pressure of the heat dissipation device. The heat dissipation device described. The heat dissipation structure according to claim 12, wherein the plurality of flow guiding structures are fixed to the base or the wall surface, and the shape thereof is a rectangle, a flat plate, a curved arc, or an airfoil. apparatus. The plurality of flow guiding structures are partially connected between the base portion and the wall surface, and the other portion is connected to the base and the wall surface at both ends, the intermediate portion is discontinuous, and the free end is It forms, The heat dissipation apparatus of Claim 12 characterized by the above-mentioned. The plurality of flow guiding structures are partially connected between the base and the wall surface, one end is connected to the wall surface, the other end is a free end, and the other portion is connected to the base at the other end. The heat dissipating device according to claim 12, wherein is a free end. The heat dissipating apparatus according to claim 1, wherein the fan frame has at least one air outlet and is provided with a flow guide structure. The heat dissipation device according to claim 1, further comprising an axial compression type air passage in the fan frame. The heat dissipating apparatus according to claim 1, further comprising a driving device, fitted on the bearing tube, and coupled to the rotor blade to drive the rotor blade.

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