KR20050019351A - Fan motor structure - Google Patents

Abstract

PURPOSE: A fan motor structure is provided to prevent a leakage of lubricating oil by forming a leakage prevention portion at an end of a cooling fan coupling portion. CONSTITUTION: A fan motor structure(160) comprises a base frame(170); a housing(161) coupled to the center of the base frame; a core(163) mounted on an outer wall of the housing; a printed circuit board(162) for applying current to a coil winding portion(164) of the core; a bearing(167) mounted in the housing; a rotary shaft(166) arranged in the bearing; a cooling fan(165) coupled to a top of the rotary shaft; a back yoke(168) arranged on an inner wall of a skirt(165a) of the cooling fan; a magnet(169) arranged on an inner wall of the back yoke; and a leakage prevention portion formed at an end of a cooling fan coupling portion coupled to the top of the rotary shaft so as to prevent a leakage of lubricating oil flowing along the rotary shaft.

Description

Fan motor structure

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fan motor for a computer, and more particularly, to a fan motor structure which prevents leakage of oil to be lubricated by forming a leakage preventing portion at a cooling fan coupling end.

In recent years, small portable computers such as laptops have become increasingly thinner and lighter in performance.

Such miniaturization and thinning of electronic products are inevitable in miniaturization, high speed, and large capacity of a central processing unit (CPU) and peripheral electronic devices used in a computer.

As such, as the capacity of electronic components such as a miniaturized CPU becomes relatively large, the amount of heat generated is extremely increased.

In order to prevent overheating of the electronic parts as heating elements, a faster and more effective cooling means should be provided. However, as electronic products become thinner and thinner, the space inside is inevitably denser, and due to this space limitation, the flow of cooling fluid (air) does not flow smoothly, which leads to difficulty in dissipating heat generated from the electronic chip. .

In particular, since the CPU is relatively high compared to the temperature of other components, the problem caused by the high temperature of the CPU is serious. That is, the high temperature of the CPU results in a decrease in clock speed, malfunction, and a sudden increase in failure rate.

At present, researches are being actively conducted to effectively dissipate a heating element such as a CPU. In the past, a cooling device using a fan motor, a heat dissipation fin, and a heat pipe is attached to a processor to attach a processor or a high heat generation component. It is used to cool.

1 is a perspective view showing an electronic chip cooling apparatus according to the prior art, the conventional electronic chip cooling apparatus, as shown in the figure, the terminal base (10) which directly serves to conduct heat by contacting a heating element such as a CPU ), First and second heat pipes 20 and 30 to be soldered to the upper end of the terminal base 10, and a plurality of heat dissipation fins 41 are soldered at predetermined intervals at ends of the first heat pipe 20. The first heat dissipation block 40 to form a block in the horizontal direction, and the second heat dissipation block to form a block in the vertical direction by soldering a plurality of heat dissipation fins (51) at regular intervals at the end of the second heat pipe ( 50, a fan motor 60 and a fan motor 60 and a terminal base 10 fixed to the center of the first and second heat dissipation blocks 40 and 50 so as to supply a cooling fluid. A base frame 70 and the base To block the fan motor 60, most part except the top center of the installation frame (70) to consist of configurations, including a fan cover 80 that allows cooling fluid to be efficiently introduced and discharged.

Here, since the terminal base 10 is in direct contact with the CPU to conduct heat, the terminal base 10 uses a material having excellent thermal conductivity and is formed in a plate shape which can form an area somewhat wider.

The first and second heat pipes 30 and 40 are soldered to the upper end of the terminal base 10 to transfer heat generated from the CPU to the heat dissipation blocks 40 and 50. The structure and principle will be described with reference to FIG.

Figure 2 is a cross-sectional view showing a conventional heat pipe internal structure, as shown in the structure of the heat pipe (20, 30) is generally formed on the inner wall of the hermetic container wick (Wick) is formed, the inside Is filled by the working fluid.

The heat pipe of this structure forms an evaporation unit, a heat insulation unit, and a condensation unit for each part, and the evaporation unit absorbs heat from an external heat source and causes the working fluid to evaporate in a gaseous state. It moves in the direction of the condenser. On the contrary, in the condensation unit, the working fluid is condensed from the gas state to the liquid state while the heat is taken away from the outside of the low temperature, and is moved to the evaporation unit by the capillary force of the wick. .

That is, the heat pipe is a device that transfers heat by using latent heat to a device that transfers heat between both ends of the vessel through the phase-change process between the gas and the liquid. Compared to phosphorus heat transfer devices, it has a very large heat transfer performance.

The first and second heat dissipation blocks 40 and 50 are formed by soldering a plurality of heat dissipation fins 41 and 51 arranged at regular intervals using separate jigs to the lower ends of the heat pipes 20 and 30. At this time, the installation angle of the heat radiation fins 41 and 51 is selected to match the flow direction of the cooling fluid.

In addition, the fan motor 60 causes forced convection to supply cooling fluid to the first and second heat dissipation blocks. Mostly, axial fan motors are used to transfer the cooling fluid drawn in the vertical direction in the horizontal direction.

The base frame 70 is formed of an integral casting, and a motor mounting portion 71 for mounting the fan motor 60 is formed at one side, and a terminal device portion 73 for mounting the terminal base is formed at one side thereof. do.

In addition, the fan cover 80 is a plate-shaped body shielding the upper portion of the motor mounting portion 71, the suction hole 81 for sucking the cooling fluid is formed in the center.

Referring to the operation of the conventional electronic chip cooling device having the configuration as described above is as follows.

First, high temperature heat is generated in an electronic chip such as a CPU, and the terminal base 10 is in direct contact with the surface of the heating element.

Heat generated in the CPU is conducted to the terminal base 10. The heat conducted to the terminal base 10 is transferred to the heat dissipation blocks 40 and 50 formed at each end of the heat pipes 20 and 30 through the heat pipes 20 and 30.

The heat transferred to the heat dissipation blocks 40 and 50 is partially cooled by natural convection, but this is a very small part, and by driving a fan motor 60 installed inside the heat dissipation blocks 40 and 50, Forced convection causes cooling.

At this time, the fan motor 60 forms a flow path by the motor mounting portion 71 and the fan cover 80 formed on one side of the base frame 70 to transfer the external air to the heat radiation block (40, 50). .

The fan motor 60 plays the most important role in configuring the cooling device, and becomes a decisive factor in determining the thickness of the entire cooling device.

Hereinafter, the fan motor 60 will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing a conventional fan motor internal structure.

As shown in the figure, a conventional fan motor structure 60 includes a base frame 70, a cup-shaped housing 61 coupled to a center of the base frame 70, and an outer wall of the housing 61. A core board 63 mounted to form a plurality of coil windings 64 and a PCB board mounted on an upper surface of the base frame 70 to apply a control current to the coil windings 64 of the core 63. 62, a bearing 67 mounted inside the housing 61, a rotating shaft 66 arranged on the bearing 67 to rotate, and a cooling fan coupled to an upper end of the rotating shaft 66 ( 65, a back yoke 68 installed on an inner wall of the skirt 65a of the cooling fan 65, and a magnet 69 provided on an inner wall of the back yoke 68 to face the core 63. It is composed.

Here, the rotating shaft 66 is arranged on the bearing 67 accommodated in the hollow portion 61a of the housing 61, and the cooling fan 65 is coupled to the upper end of the rotating shaft 66.

At this time, the bearing 67 is injected with lubricating oil, which prevents abrasion and serves to help the rotation shaft 66 to rotate smoothly.

However, the lubricating oil as described above, as the rotary shaft 66 rotates, rides up the rotary shaft 66 by the centrifugal force and leaks to the outside. The oil leaked to the outside not only pollutes the surroundings, The friction is increased due to the reduction of the lubricating oil, and the rotating shaft 66 and the bearing 67 of the motor are worn, causing problems in the rotational performance of the motor.

For this reason, conventionally, by coupling the oil stopper ring 65d before coupling the cooling fan 65 coupling portion 65c to the upper end of the rotation shaft 66, lubrication oil is prevented from leaking to the outside.

However, the oil stopper ring 65d of the above-described flat shape does not prevent oil leakage properly, and there is a problem in that an assembling process for coupling the oil stopper ring 65d is added.

Therefore, it is urgent to propose a fan motor structure that can maintain the life of the device for a long time without using the expensive oil stopper ring without early wear of the device due to oil leakage.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a fan motor structure to prevent leakage of lubricant oil to the outside by forming a leakage preventing portion at the end of the cooling fan coupling portion.

Another object of the present invention is to provide a fan motor structure in which the leakage preventing part is integrally formed with the cooling fan when the cooling fan is injected, thereby making the formation and assembly process convenient.

The fan motor structure according to the present invention for achieving the above object is a base frame, a housing coupled to the center of the base frame, a core mounted on the outer wall of the housing, a PCB substrate for applying a current to the coil winding of the core, In a fan motor comprising a bearing mounted inside the housing, a rotating shaft built into the bearing, a cooling fan coupled to an upper end of the rotating shaft, and a back yoke and a magnet installed on an inner wall of the skirt of the cooling fan,

It characterized in that to form a leakage preventing portion to prevent the external leakage of the lubricating oil raised on the rotating shaft at the end of the cooling fan coupling portion coupled to the upper end of the rotating shaft.

Here, the leakage preventing portion is characterized in that it is formed to be inclined downward from the inside of the shaft.

Here, the leakage preventing portion is parallel to the predetermined distance from the inside of the shaft, characterized in that forming a jaw at the end thereof.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

4 is a cross-sectional view showing a fan motor structure according to the present invention.

As shown in the figure, the conventional fan motor structure 160 includes a base frame 170, a cup-shaped housing 161 coupled to the center of the base frame 170, and an outer wall of the housing 161. A core board 163 mounted to form a plurality of coil windings 164 and a PCB board mounted on an upper surface of the base frame 170 to apply a control current to the coil windings 164 of the core 163. 162, a bearing 167 mounted inside the housing 161, a rotating shaft 166 arranged and rotated on the bearing 167, and a cooling fan coupled to an upper end of the rotating shaft 166. 165, a back yoke 168 installed on an inner wall of the skirt 165a of the cooling fan 165, and a magnet 169 installed on an inner wall of the back yoke 168 to face the core 163. It is composed.

Here, the base frame 70 is generally manufactured in the form of a mold or aluminum diecasting (Al diecasting), a mounting hole 170a for mounting the housing 161 in the center is formed, the firewood hole 170a ) Is made of a configuration in which a plurality of vent holes (170b) is formed to suck the outside air around.

A circular PCB substrate 162 is mounted around the mounting hole 170a to control a variable current.

In addition, the housing 161 to be mounted in the mounting hole 170a is manufactured in a cup shape, the bearing 167 is accommodated in the inner hollow part 161a, and the core 163 is mounted in the outer wall upper end 161b. Consists of the configuration.

The core 163 is configured to form approximately four divided surfaces, and to form a coil winding 164 for winding a coil on each divided surface.

In addition, a rotating shaft 166 is formed in the bearing 167 accommodated in the hollow portion 161a of the housing 161, and a cooling fan 165 is coupled to the upper end of the rotating shaft 166.

At this time, the bearing 167 is injected with lubricating oil, which prevents abrasion and serves to help the rotation shaft 166 to rotate smoothly.

As the lubricating oil as described above, as the rotating shaft 166 rotates, the lubricating oil rides on the rotating shaft 166 by a centrifugal force and moves upward.

In the present invention to form a leakage preventing portion (165d) to prevent the external leakage of the lubricating oil on the rotating shaft 166 on the end of the cooling fan 165 coupling portion 165c coupled to the upper end of the rotating shaft 166 Consists of the configuration. The leakage preventing part 165d is formed integrally with the cooling fan coupling part 165c, and for this purpose, the material of the cooling fan 165 is formed of a material that can be injected.

At this time, the shape of the leakage preventing portion 165d is preferably formed to be inclined downward from the inside of the shaft.

In addition, the leakage preventing part 165d may be formed to be parallel to a predetermined distance from the inside of the shaft to the outside as shown in FIG. 5 and to have a jaw formed at an end thereof.

In addition, a skirt 165a having a predetermined height is formed at the end of the circumferential surface of the cooling fan 165, and a plurality of fan wings 165b are formed by extending to the outer wall of the skirt 165a.

A back yoke 168 made of a metal plate is attached to an inner wall of the skirt 165a, and a magnet 169 on which an N pole and an S pole are repeatedly magnetized is attached to an inner wall of the back yoke 168 so that the core 164 is attached. And forming a counter electrode corresponding to the variable electrode generated in the second electrode.

Referring to the operation of the conventional fan motor consisting of the above configuration is as follows.

First, when a constant current is applied to the fan motor 160, the current is controlled by the PCB substrate 162 installed on the base frame 170, and coil winding portions formed on divided surfaces of the core 163, respectively. 164 is supplied.

A magnetic field is formed in the coil winding unit 164 as a current flows, and a reaction force is generated between the magnet 169 in which the N pole and the S pole are repeatedly magnetized by the magnetic field.

That is, the cooling fan 165 is rotated by the electromagnetic force caused by the linkage of the magnetic flux of the coil winding unit 164 and the magnet 169.

In this case, as the cooling fan 165 is rotated, the lubricating oil supplied inside the bearing 167 is lifted up along the rotary shaft 166, and the oil moved upward is cooled by the cooling fan 165. By repeating the process of being injected into the bearing 167 again by the leakage preventing part 165d formed at the end of the coupling part 165c, it is possible to effectively prevent leakage of the lubricating oil to the outside.

The present invention has the following effects by forming a leakage preventing portion at the end of the cooling fan coupling portion to prevent the oil to be lubricated to leak to the outside.

First, since the present invention does not have to use an expensive oil stopper ring, the material cost is reduced.

Second, the present invention has the effect of maintaining the life of the device for a long time without the early wear of the device due to oil leakage.

Third, the present invention has the effect of maintaining the clean state of the motor without leaking oil dirty the surroundings.

Fourth, when the cooling fan is injected, by forming integrally with the cooling fan, there is a convenient effect of the forming and assembly process.

1 is a perspective view showing an electronic chip cooling apparatus according to the prior art.

Figure 2 is a cross-sectional view showing a conventional heat pipe internal structure.

Figure 3 is a cross-sectional view showing a conventional fan motor internal structure.

Figure 4 is a cross-sectional view showing a fan motor structure according to an embodiment of the present invention.

5 is a cross-sectional view showing a fan motor structure according to another embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10: terminal base 20: first heat pipe

30: second heat pipe 40: first heat radiation block

41, 51: heat dissipation fin 50: second heat dissipation block

60: axial fan motor 70: base frame

71: motor mounting portion 73: terminal device portion

80: fan cover 160: fan motor

161: housing 162: PCB substrate

163: core 164: coil winding portion

165: cooling fan 165a: skirt

165b: fan blade 165c: coupling

165d: leakage prevention portion 166: rotation axis

167: bearing 168: back yoke

169: magnet 170: base frame

Claims (4)

A base frame, a housing coupled to the center of the base frame, a core mounted on the outer wall of the housing, a PCB substrate for applying current to a coil winding portion of the core, a bearing mounted inside the housing, a rotating shaft installed on the bearing, In the fan motor consisting of a cooling fan coupled to the upper end of the rotating shaft, and a back yoke and a magnet installed on the inner wall of the skirt of the cooling fan, The fan motor structure, characterized in that the leakage preventing portion is formed to prevent the external leakage of the lubricating oil raised on the rotating shaft at the end of the cooling fan coupling portion coupled to the upper end of the rotating shaft. The method of claim 1, The leakage preventing unit is a fan motor structure, characterized in that formed integrally with the cooling fan coupling. The method of claim 1, The leakage preventing unit is formed in the fan motor structure characterized in that the inclined downward to the outside. The method of claim 1, The leakage preventing unit is parallel to a certain distance from the inside to the outside of the shaft, fan motor structure, characterized in that forming a jaw at the end thereof.