TWM484244U - Dynamic pressure bearing structure for carrying heat dissipation fan - Google Patents

Description

Dynamic pressure bearing structure for carrying a cooling fan

The present invention is a dynamic pressure bearing structure for carrying a cooling fan, and particularly relates to a dynamic pressure bearing structure for carrying a cooling fan used in a heat dissipation module.

Press, the cooling fan is one of the main components in the cooling module. In recent years, in order to cope with the trend of miniaturization, thinning, and increasing processor operating power for information products such as notebook computers and tablet computers, the heat dissipation module must also be miniaturized, thinned, and simultaneously Taking into account the direction of heat efficiency improvement. Therefore, the fan used in the heat dissipation module must also reduce the volume, reduce the thickness, and at the same time increase the fan speed. In order to meet the demand for miniaturization, thinning and high speed of fans, a considerable number of cooling fans have been replaced by conventional dynamic bearings.

As shown in FIG. 8 and FIG. 9 , it is a conventional heat dissipation fan structure using a dynamic pressure bearing, which comprises: a heat sink housing 1; a bearing device 2 is disposed on the bottom plate of the heat sink housing 1; A fan blade 3 is disposed at an upper end of the rotating shaft 6 of a bearing device 2. A fan 4 is further disposed on the fan blade 3, and a stator 5 is disposed on the bottom plate of the heat sink casing 1. The rotor 4 and the stator 5 cooperate to generate a mutually exclusive magnetic field to drive the fan blade 3 to generate the shaft 6 Centered rotation. As shown in FIG. 9, the bearing device 2 of the prior art includes: a casing 7, a dynamic pressure bearing 8 disposed in the casing 7, and a pressure ring for fixing the dynamic pressure bearing 8 to the inside of the casing 7. 7a and a rotating shaft 6 disposed through the dynamic pressure bearing 8.

The inside of the outer casing 7 has a cylindrical accommodating space, and the dynamic pressure shaft The bearing is disposed in the accommodating space. The bottom of the outer casing 7 has an integrally formed bottom plate 7b such that a closed space is formed between the inner receiving space of the outer casing 7 and the bottom surface of the dynamic pressure bearing 8, and the space is filled with lubricating oil. The bottom surface of the bottom plate 7b is provided with a wear pad 9, and the bottom end of the rotating shaft 6 is in contact with the surface of the wear pad 9, so that the bottom end of the rotating shaft 6 is supported by the bottom plate 7b. The surface of the inner hole of the dynamic pressure bearing 8 shown in FIG. 9A is provided with a herringbone groove 8a. The function of the herringbone groove 8a is to guide the lubricating oil to flow and generate pressure when the rotating shaft 6 rotates, so that the rotating shaft 6 moves. A pressure oil layer is formed between the rotating shaft holes of the pressure bearing 8, so that the rotating shaft 6 does not contact the surface of the dynamic pressure bearing 8 when the fan is running, so as to reduce the frictional force of the rotating shaft 6, and reduce the dynamic pressure bearing 8 Wear with the rotating shaft 6 when the fan is running at high speed.

The main problem of the dynamic pressure bearing structure for the conventional heat dissipating fan is that the diameter of the fan blade 3 is relatively large, and the rotor 4 is provided on the blade, so that when the fan blade 3 is operated, the yaw yaw is relatively easy to occur. In addition to increasing the vibration and noise of the operation, it also causes the shaft 6 and the dynamic pressure bearing 8 to wear.

However, the bearing device 2 has only radial support between the rotating shaft 6 and the dynamic pressure bearing 8 used, and lacks axial support, and the rotating shaft 6 and the dynamic pressure bearing 8 are added due to the flattening of the fan design. The axial length of the joint is very small compared to the diameter of the heat dissipating fan, so that the support between the rotating shaft 6 and the dynamic pressure bearing 8 is insufficient, and the yaw of the fan during operation cannot be solved.

Further, the outer casing 7 of the bearing device 2 is integrally formed with the bottom plate 7b of the bottom, so that the shaft 6 must be inserted from the upper end of the dynamic pressure bearing 8 into the interior of the dynamic pressure bearing 8 when the bearing device 2 is assembled, so that no shaft can be placed on any of the shafts 6 The additional positioning structure cannot overcome the problem of insufficient support and positioning of the rotating shaft 6 and the dynamic pressure bearing 8.

Further, in the configuration of the conventional bearing device 2, the wear pad 9 provided at the bottom of the outer casing 7 is a sheet-like body separated from the bottom plate 7b, and since the thickness thereof is relatively thin, bending deformation is likely to occur for a long time.

Due to the above factors, there are quite a few disadvantages in the dynamic pressure bearing structure for the conventional cooling fan. Therefore, how to improve the cooling fan by improving the structural design The dynamic stability of the dynamic bearing structure to overcome the above-mentioned shortcomings has become one of the important issues to be solved by this business.

The main purpose of this creation is to provide a dynamic pressure bearing structure for carrying a cooling fan that can improve operational stability and reduce the yaw state of the cooling fan rotor.

The present invention mainly includes: a casing, a dynamic pressure bearing, a rotating shaft, a thrust member and a bottom plate. Wherein the outer casing has a cylindrical receiving space, the upper end of the outer casing has an upper end opening communicating with the receiving space; the bottom plate is made of a wear-resistant material, and is disposed on the outer casing The bottom portion is such that the bottom of the bottom plate is in a closed state; the dynamic pressure bearing is disposed in the accommodating space, and the center of the dynamic pressure bearing has a shaft hole that consistently passes through the top surface and the bottom surface of the bearing; a rotating shaft is disposed in the rotating shaft hole of the dynamic pressure bearing, an upper end of the rotating shaft protrudes from a top surface of the dynamic pressure bearing, and a bottom end of the rotating shaft protrudes from a bottom surface of the dynamic pressure bearing and is in contact with a top surface of the bottom plate; and a thrust member fixedly coupled to a bottom end of the rotating shaft, the thrust member being received between a bottom surface of the dynamic pressure bearing and the bottom plate.

Wherein the accommodating space is filled with lubricating oil in a space between a bottom surface of the dynamic pressure bearing and a top surface of the bottom plate, wherein the thrust member is a circular plate body and a plurality of top or bottom surfaces thereof are disposed Guide grooves arranged in a radial direction. When the thrust member rotates, the guide groove provided on the top surface of the thrust member interacts with the bottom surface of the dynamic pressure bearing, or the guide groove provided by the bottom surface of the thrust member and the top surface of the bottom plate The guide groove provided on the top surface or the bottom surface of the guiding thrust member guides the lubricating oil to flow, and applies pressure to the lubricating oil to form a pressure oil layer on the surface of the thrust member and is maintained by the oil layer pressure. The stability of the push member rotation.

In this embodiment, a fan blade is further disposed at a top end of the rotating shaft, and a fan is disposed on the fan blade, and the rotor cooperates with a stator to generate a mutual repulsion thrust, thereby driving the fan blade and the rotating shaft to rotate.

The beneficial effect of the present invention may be that when the rotating shaft rotates, the thrust structure The piece is rotated together by the rotating shaft, and when the thrust member rotates, the lubricating oil is pressed by the groove of the surface of the thrust member to generate pressure on the lubricating oil on the surface of the thrust member, thereby maintaining the rotation of the rotating shaft stably. Sexuality, while reducing the yaw of the rotor on the fan blades.

In order to further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings are only for reference and description, and are not intended to limit the creation.

1‧‧‧ radiator housing

2‧‧‧ bearing device

3‧‧‧ a fan blade

4‧‧‧Rotor

5‧‧‧ Stator

6‧‧‧ shaft

7‧‧‧Shell

7a‧‧‧ Pressure ring

7b‧‧‧floor

8‧‧‧Dynamic bearing

8a‧‧‧ Herringbone groove

9‧‧‧ wear pad

10‧‧‧Dynamic bearing structure

20‧‧‧ Shell

21‧‧‧ accommodating space

22‧‧‧Upper opening

23‧‧‧Bottom opening

24‧‧‧floor

25‧‧‧ Pressure ring

26‧‧‧ Sealing members

27‧‧‧Depression

30‧‧‧Dynamic bearing

31‧‧‧ shaft hole

32‧‧‧ Herringbone groove

40‧‧‧ shaft

41‧‧‧End part

42‧‧‧Arc Department

50‧‧‧ thrust member

51‧‧‧ Guide groove

52‧‧‧ holes

Figure 1 is a schematic cross-sectional view of the dynamic pressure bearing structure of the present invention mounted on a cooling fan.

Figure 2 is a combined sectional view of the dynamic pressure bearing structure of the present invention.

Figure 2A is a cross-sectional view of the dynamic pressure bearing used in the present creation.

Fig. 3 is a side view showing the combination of the rotating shaft and the thrust member used in the dynamic pressure bearing of the present invention.

3A is a combined side view of another embodiment of the present invention for providing a guide groove on the bottom surface of the thrust member.

4A is a top plan view of the thrust member used in the creation.

4B is a top plan view of another embodiment of a thrust member used in the art.

Fig. 5 is an exploded cross-sectional view showing the outer casing and the bottom plate used in the dynamic pressure bearing structure of the present invention.

Fig. 6 is a cross-sectional view showing another modified embodiment of the bottom plate used in the dynamic pressure bearing structure of the present invention.

Fig. 7 is a flow chart showing the assembly of the dynamic pressure bearing structure of the present invention.

Fig. 8 is a schematic cross-sectional view showing a conventional dynamic pressure bearing structure for a heat dissipation fan mounted on a heat dissipation fan.

Figure 9 is a combined cross-sectional view of a conventional dynamic pressure bearing structure.

Fig. 9A is a cross-sectional view showing a dynamic pressure bearing used in a conventional dynamic pressure bearing structure.

Please refer to FIG. 1 and FIG. 2 . FIG. 1 is a schematic structural view of the dynamic pressure bearing structure 10 of the present invention mounted on a cooling fan, and FIG. 2 is a dynamic pressure bearing of the present invention. A combined cross-sectional view of structure 10.

As shown in FIG. 1, the dynamic pressure bearing structure 10 of the present invention is mounted on the surface of a bottom plate of a heat sink casing 1. The dynamic pressure bearing structure 10 has a rotating shaft 40, and a fan blade 3 is disposed at the top end of the rotating shaft 40. A fan 4 is disposed on the fan blade 3, and the rotor 4 and a stator 5 disposed on the bottom plate of the radiator casing 1 cooperate to generate a mutually exclusive magnetic field, thereby propelling the fan blade 3 to rotate.

As shown in FIG. 2, the dynamic pressure bearing structure 10 of the present invention comprises: a casing 20, a dynamic pressure bearing 30, a rotating shaft 40, a thrust member 50 and a bottom plate 24. The outer casing 20 has a cylindrical accommodating space 21 therein, and the upper end of the outer casing 20 has an upper end opening 22 communicating with the accommodating space 21.

The dynamic pressure bearing 30 is disposed in the accommodating space 21 of the outer casing 20. The center of the dynamic pressure bearing 30 has a shaft hole 31 that consistently passes through the top and bottom surfaces of the dynamic pressure bearing 30. The rotating shaft 40 is disposed in the rotating shaft hole 31. The upper end of the rotating shaft 40 protrudes from the top surface of the dynamic pressure bearing 30, and the bottom end protrudes from the bottom surface of the dynamic pressure bearing 30. A pressing ring 25 is further disposed on the top surface of the outer casing 20, and the dynamic pressure bearing 30 is fixed in the accommodating space by the pressure ring 25.

As shown in Figs. 2 and 3, the bottom of the rotary shaft 40 has an end portion 41 having a diameter slightly smaller than the diameter of the rotary shaft 40 to form a step portion. The bottom portion of the end portion 41 of the rotary shaft 40 forms a circular arc portion 42 which is in contact with the top surface of the bottom plate 24 by the circular arc portion 42 to reduce the contact area between the rotary shaft and the bottom plate 24.

As shown in FIG. 5, the bottom of the outer casing 20 in this embodiment has a lower end opening 23 which is formed at the lower end opening 23 of the outer casing 20. A sealing member 26 that is tightly coupled between the bottom plate 24 and the outer casing 20 is provided at a position where the bottom plate 24 is engaged with the bottom of the outer casing 20 to tightly bond the bottom plate 24 and the outer casing 20 to prevent leakage.

As shown in FIG. 5, a central portion of the top surface of the bottom plate 24 may be provided with a recessed portion 27 corresponding to the circular arc portion 42 of the rotating shaft, or as shown in FIG. 6, the top surface of the bottom plate 24 may be formed into a completely flat structure. .

As shown in FIG. 2, the recessed portion 27 provided on the top surface of the bottom plate 24 can accommodate the bottom of the rotating shaft 40. The arc portion 42 of the portion. The function of the recessed portion 27 can be changed in addition to the end of the rotating shaft 40, and the depth of the recessed portion 27 can be changed such that the tip end portion 41 of the rotating shaft 40 sinks into the depth of the recessed portion 27 to cause a thrust member. There is a proper gap between the bottom surface of the bottom surface 50 and the top surface of the bottom plate 24, so that when the thrust member 50 is rotated, a pressure oil layer can be formed between the bottom surface of the thrust member 50 and the top surface of the bottom plate 24 to improve the pressure. The stability of the push member 50 when it is rotated.

As shown in FIGS. 2 and 3, the thrust member 50 is sleeved on the outer side of the end portion 41 of the rotary shaft 40. As shown in FIG. 3 and FIG. 4A and FIG. 4B, the thrust member 50 is a circular plate body having a hole 42 at the center thereof and sleeved on the end portion 41 of the bottom of the rotating shaft 40, and is tightly fitted or dispensed. The thrust member 50 is fixedly coupled to the end portion 41 of the rotary shaft 40. As shown in FIG. 2, the thrust member 50 is received in the gap between the bottom surface of the dynamic pressure bearing 30 and the bottom plate 24, and the top surface of the thrust member 50 is close to the bottom surface of the dynamic pressure bearing 30, or the bottom surface thereof can be Adjacent to the top surface of the bottom plate 24.

The dynamic pressure bearing structure 10 of the present invention is filled with lubricating oil in the space between the bottom surface of the dynamic pressure bearing 30 and the top surface of the bottom plate 24 in the accommodating space 21, so that the rotating shaft 40 and the thrust member 50 are both immersed in lubrication. In the oil. As shown in FIG. 2, the surface of the shaft hole 31 of the dynamic pressure bearing 30 may further be provided with a herringbone groove 32. When the rotating shaft 40 rotates, the lubricating oil flows and generates pressure by the herringbone groove 32 to form a medium. The oil layer between the surface of the rotating shaft 40 and the rotating shaft hole 31 is such that the rotating shaft 40 does not come into contact with the rotating shaft hole 31 when it is operated. However, the structural shape of the herringbone groove 32 on the surface of the shaft hole 31 of the dynamic pressure bearing 30 is not the technical feature of the present invention, so the detailed structure thereof will not be described.

As shown in FIG. 3 and FIG. 3A, the top surface or the bottom surface of the thrust member 50 of the present invention is provided with a plurality of guiding grooves 51 which are arranged in a radial direction at the top of the thrust member 50. The surface (as shown in FIG. 3) is disposed on the bottom surface of the thrust member 50 (as shown in FIG. 3A), and the shape of the guiding groove 51 may be a linear groove as shown in FIG. 4A. An arcuate groove is shown in Fig. 4B. It must be emphasized here that the shape of the guiding groove 51 is not limited to the shape disclosed in the above embodiment, which may be based on actual conditions. The change in requirements is designed to fit any shape.

The guide groove 51 functions to guide the flow of the lubricating oil and generate pressure to form an oil layer having pressure on the surface of the thrust member 50, and maintain the stability of the thrust member 50 and the rotary shaft 40 by the pressure of the oil layer. .

For the assembly method of the dynamic pressure bearing structure of the present invention, please refer to the assembly flow chart shown in FIG. 7 and explain as follows:

1. A housing 20 is first provided.

2. The dynamic pressure bearing 30 is placed into the accommodating space 21 from the upper end opening 22 at the top end of the outer casing 20.

3. The pressure ring 25 is placed at the top end of the outer casing 20 to fix the position of the dynamic pressure bearing 30.

4. After the rotating shaft 40 is combined with the fan blade 3, the rotating shaft 40 is inserted into the rotating shaft hole 31 of the dynamic pressure bearing 30 together with the fan blade 3.

5. The thrust member 51 is placed from the lower end opening 23 at the bottom of the outer casing 20 and assembled on the end portion 41 of the bottom of the rotary shaft 40.

6. Then, lubricating oil is injected into the accommodating space from the lower end opening 23 at the bottom of the outer casing 20.

7. After the lubricating oil is injected, the bottom plate 24 and the sealing member 26 are assembled at the lower end opening 23 of the bottom of the casing to close the bottom of the accommodating space 21.

[Possible effects of the examples]

The present invention cooperates with the bottom surface of the dynamic pressure bearing 30 or the top surface of the bottom plate 24 by the thrust member 50, and the guide groove 51 on the surface of the thrust member 50 and the bottom surface of the dynamic pressure bearing 30 or the top of the bottom plate 24 The surface is matched with the top surface or the bottom surface of the guiding member 51 to form a lubricating oil layer with pressure, which can generate an axial positioning effect, and maintains stability when the thrust member 50 and the rotating shaft 40 are rotated by the pressure of the oil layer, so that the fan blade 3 When turning, it is less likely to cause yaw.

The above description is only a preferred and feasible embodiment of the present invention, and thus does not limit the scope of the patent of the creation, so the equivalent technique of using the creation specification and the schema content is used. Changes are included in the scope of this creation.

10‧‧‧Dynamic bearing structure

20‧‧‧ Shell

21‧‧‧ accommodating space

22‧‧‧Upper opening

23‧‧‧Bottom opening

24‧‧‧floor

25‧‧‧ Pressure ring

26‧‧‧ Sealing members

27‧‧‧Depression

30‧‧‧Dynamic bearing

31‧‧‧ shaft hole

32‧‧‧ Herringbone groove

40‧‧‧ shaft

41‧‧‧End part

42‧‧‧Arc Department

50‧‧‧ thrust member

51‧‧‧ Guide groove

Claims (8)

A dynamic pressure bearing structure for carrying a heat dissipating fan, comprising: a casing having a cylindrical receiving space, the upper end of the casing having an upper end opening communicating with the accommodating space; a bottom plate The bottom plate is disposed at a bottom of the outer casing, and the bottom plate and the bottom of the outer casing are closely adhered to each other; a dynamic pressure bearing, the dynamic pressure bearing is disposed in the accommodating space, and the center of the dynamic pressure bearing a shaft hole having a top surface and a bottom surface of the dynamic pressure bearing; a rotating shaft disposed in the shaft hole of the dynamic pressure bearing, the upper end of the rotating shaft protruding from the dynamic pressure bearing a top surface of the rotating shaft protruding from a bottom surface of the dynamic pressure bearing and contacting a top surface of the bottom plate; and a thrust member fixedly coupled to a bottom end of the rotating shaft The thrust member is disposed between the bottom surface of the dynamic pressure bearing and the bottom plate; wherein the accommodating space is filled in a space between the bottom surface of the dynamic pressure bearing and the top surface of the bottom plate lubricating oil. The dynamic pressure bearing structure for carrying a heat dissipation fan according to claim 1, wherein the thrust member is a circular plate body, and a top surface or a bottom surface of the thrust member surface is provided with a plurality of radially arranged Guide the groove. The dynamic pressure bearing structure for carrying a heat dissipation fan according to claim 2, wherein the plurality of the guide grooves are linear grooves. The dynamic pressure bearing structure for carrying a heat dissipation fan according to claim 2, wherein the plurality of the guide grooves are arc-shaped grooves. The dynamic pressure bearing structure for carrying a heat dissipation fan according to claim 3 or claim 4, wherein a position at which the bottom plate is engaged with the outer casing is provided with a seal tightly coupled between the bottom plate and the outer casing member. The dynamic pressure bearing structure for carrying a cooling fan according to claim 5, wherein The bottom plate is a wear plate body. The dynamic pressure bearing structure for carrying a heat dissipation fan according to claim 6, wherein the bottom plate of the bottom plate has a recessed portion, and the bottom of the rotating shaft has a circular arc portion, and the circular arc portion abuts against the recessed portion Ministry. The dynamic pressure bearing structure for carrying a heat dissipation fan according to claim 7, wherein the lower end of the outer casing has a lower end opening communicating with the accommodating space, and the lower end opening is closed by the bottom plate.