KR20100078745A - Bearing cooling apparatus - Google Patents

Abstract

PURPOSE: A bearing cooling device is provided to relatively miniaturize a product in which the bearing cooling device is used by forming a cooling water passage is formed inside the device. CONSTITUTION: A bearing cooling device comprises bearing assemblies(63), isolation rings(66), cooling water passages, and a cooling water source. The bearings rotatably support a rotary shaft(59) extended through a housing(53). The insulation rings are located between bearings(65) and the ends of the housing. The cooling water passages are formed between the insulation rings and the ends of the housing. The cooling water source supplies cooling water to the cooling water passage.

Description

Bearing cooling apparatus

The present invention relates to a bearing cooling device, and more particularly, to a bearing cooling device for releasing heat generated from a bearing rotatably supporting a rotating shaft of a generator or an electric motor.

In the present specification, a bearing cooling apparatus will be described using an electric motor as an example. However, the present invention can be applied to any one provided with a bearing supporting a rotating shaft such as a generator as well as an electric motor.

In general, a motor is provided with a rotor coupled with a magnet and a stator wound with a coil, and uses the power of the rotating shaft as the rotor rotates due to the magnetic flux generated by the current applied to the coil of the stator and the electromagnetic induction of the rotor. Device.

In this case, the rotating shaft is rotatably installed in the electric motor, and generally, both ends of the rotating shaft are rotatably supported by the bearing assembly. 1 is a cross-sectional view showing a main configuration of a motor equipped with a bearing cooling apparatus according to the prior art.

As shown in these drawings, the stator 5 is press-fitted into the housing 3 of the hollow body in the electric motor 1. The housing 3 serves to protect and fix the stator 5. The stator 5 is wound with a coil to which current is applied.

The rotor 7 having magnetic force penetrates inside the stator 5. The rotating shaft 9 is installed by being press-fitted through the center of the rotor 7, and the rotating shaft 9 has a first cover 11 and a second cover having both ends coupled to both end surfaces of the housing 3. Supported by (not shown).

The bearing assembly 13 is installed so that the rotation shaft 9 is rotatably supported by the first cover 11 and the second cover. The bearing assembly 13 has an exterior bearing cap 14 and an outer bearing cap 14 'formed therein, and a bearing 15 is installed in an inner space formed by the bearing caps 14 and 14'. . The bearing 15 substantially rotatably supports the rotating shaft 9.

A ring-shaped insulating ring 16 is installed between the bearing 15 and the first cover 11. The insulating ring 16 serves to block current from flowing from the rotating shaft 9 toward the housing 3. When the insulating ring 16 is sparked in the bearing 15 as the current flows from the rotary shaft 9 through the bearing 15 toward the housing 3, the bearing 15 may be damaged and the durability may be degraded. It is used.

The bearing assembly 13 is installed over the inside and the outside of the housing 3 on the basis of the first cover 11, and the part exposed to the outside of the housing 3 is shielded by the fan cover 17. The fan cover 17 has a gap between the outer circumferential surface of the rotating shaft 9 to form an inlet 17i and a gap between the fan cover 17 and the first cover 11 to form an outlet 17e. .

On the other hand, a blowing fan 19 is formed on the rotating shaft 9 shielded by the fan cover 17 to form airflow toward the bearing assembly 13. The blower fan 19 is rotated by the rotary shaft 9 so that air flows into the fan cover 17 through the inlet 17i and receives heat from the bearing assembly 13 to the outlet 17e. To be discharged to outside.

However, the above-described conventional techniques have the following problems.

When the blower fan 19 rotates, noise is generated. In particular, when the rotary shaft 9 of the motor 1 rotates at a high speed, the noise increases, and the operation noise of the entire motor 1 increases, and the blower fan ( 19) there is a problem that the air flow does not reliably cool the bearing assembly (13).

In addition, since the blowing fan 19 and the fan cover 17 are installed outside the first cover 11, there is a problem that the size of the entire electric motor 1 is increased, and the blowing fan 19 is Since it is rotated by the rotary shaft 9 acts as a load on the rotary shaft 9 to reduce the operating efficiency of the electric motor (1).

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to enable the heat generated from the bearing to be discharged more efficiently using cooling water.

Another object of the present invention is to form a flow path inside the apparatus in which the bearing is used, in which a coolant flows to remove heat generated in the bearing.

According to a feature of the present invention for achieving the above object, the present invention is a bearing assembly for rotatably supporting a rotating shaft extending through the end of the housing constituting the appearance, and a bearing constituting the bearing assembly; An insulating ring positioned between the end of the housing, and a cooling water flow path formed between the insulating ring and the end of the housing, one end of which is connected to the inlet tube side, and the other end of which is connected to the outlet tube side, to which the coolant flowed from the outside flows. And a cooling water supply source for supplying cooling water to the cooling water channel.

The insulating ring is an insulating material is installed between the inner ring and the outer ring, the cooling water flow path is formed on the outer surface of the outer ring.

The plurality of cooling water flow paths are formed side by side, and adjacent cooling water flow paths communicate with each other by a connection path.

The connection path is connected to an adjacent flow path with a predetermined slope.

The cooling water flow path, the inlet pipe and the outlet pipe communicate with each other through an inlet port and an outlet port formed in a cover constituting an end of the housing.

In the bearing cooling apparatus according to the present invention having such a configuration, the following effects can be obtained.

First, in the present invention, since the coolant flowing through the coolant flow path formed in the insulation ring or the cover of the housing directly contacting the bearing is absorbed and released, the heat radiation effect is more reliably released without noise. have.

Further, in the present invention, since the cooling water flow path through which the cooling water flows is formed in the insulating ring or the housing, it is not necessary to install a separate part around the bearing for cooling the bearing, so that the product using the bearing cooling device is relatively small. There is also an effect that can be done.

Hereinafter, a preferred embodiment of a bearing cooling apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view showing the configuration of a motor employing a preferred embodiment of a bearing cooling apparatus according to the present invention, Figure 3 is an enlarged cross-sectional view of the configuration of the embodiment of the present invention, Figure 4 is an embodiment of the present invention The configuration of the insulating ring constituting is shown in schematic perspective.

As shown in these figures, the stator 55 is press-fitted into the cylindrical housing 53 of the electric motor 51. The housing 53 serves to protect and fix the stator 55. The outer surface of the housing 53 is formed with a cooling passage 54 through which a coolant for dissipating heat generated from the electric motor 51 to the outside.

The stator 55 is wound with a coil to which a current is applied. Inside the stator 55, a rotor 57 having magnetic force penetrates and is installed. The rotating shaft 59 is installed by being press-fitted through the center of the rotor 57, and the rotating shaft 59 has a first cover 61 and a second cover having both ends coupled to both end surfaces of the housing 53. Supported by 61 '. The first cover 61 and the second cover 61 ′ are integral with the housing 53 or fixed to the housing 53. Thus, the cover 61, 61 ′ may be regarded as the housing 53.

The bearing assembly 63 is installed so that the rotation shaft 59 is rotatably supported by the first cover 61 and the second cover 61 '. The bearing assembly 63 has an exterior bearing cap 64 and an outer bearing cap 64 'formed therein, and a bearing 65 is installed in an inner space formed by the bearing caps 64 and 64'. . The bearing 65 substantially rotatably supports the rotating shaft 59.

A ring-shaped insulating ring 66 is provided between the bearing 65 and the covers 61 and 61 '. The insulating ring 66 serves to block current from flowing from the rotation shaft 59 toward the housing 53. When the insulating ring 66 is sparked in the bearing 65 as a current flows from the rotating shaft 59 through the bearing 65 toward the housing 53, the bearing 65 may be damaged and its durability may be degraded. Because it is used.

 The insulating ring 66 is formed by the insulation 68 is installed between the inner ring 67 and the outer ring 67 ', these inner ring 67, the outer ring 67' and the insulator 68 ) Are all configured in a ring shape.

In this embodiment, the cooling water flow path 70 is formed on the outer circumferential surface of the outer ring 67 ′ of the insulating ring 66. The cooling water channel 70 serves to absorb heat generated from the bearing assembly 63 while the cooling water flows. However, the cooling water flow path 70 may be formed in the covers 61 and 61 'and / or the outer ring 67'. That is, the cover 61 and 61 ′ may be formed around the surface in contact with the outer ring 67 ′. The flow path 70 is preferably formed on the outer circumferential surface of the insulating ring 66 in terms of the machining operation.

The flow path 70 may be formed in various ways. That is, a plurality of flow paths 70 may be formed side by side, adjacent flow paths 70 may be formed to be connected through the connection path 71, or one flow path 70 may be formed in a spiral shape. The connection paths 71 are formed to be orthogonal to the adjacent flow paths 70, and the connection paths 71 may also be connected to the adjacent flow paths 70 at predetermined angles.

Inlet ports 61i and outlet ports 61e formed through the covers 61 and 61 'are connected to both ends of the flow path 70, respectively. The inlet pipe 72 and the outlet pipe 74 are connected to the inlet port 61i and the outlet port 61e, respectively. The inlet pipe 72 is connected to a coolant supply source to supply coolant to the flow path 70, and the outlet pipe 74 serves to discharge the coolant flowing through the flow path 70. The outlet pipe 74 extends from the inside of the housing 53 to the outside through the covers 61 and 61 '.

Hereinafter, the operation of the bearing cooling apparatus according to the present invention having the configuration as described above in detail.

The electric motor 51 is driven by electromagnetic interaction between the stator 55 and the rotor 57. When power is applied to the coil of the stator 55, the rotor 57 rotates, and the rotation shaft 59 rotates together.

Both ends of the rotation shaft 59 are installed through the covers 61 and 61 ′ and are supported and rotated by the bearing assembly 63. The bearing 65 of the bearing assembly 63 rotatably supports the rotation shaft 63 directly.

Therefore, heat is generated between the bearings 65 during the rotation of the rotary shaft 63, and the process of discharging thereof will be described.

Cooling water is supplied through the inlet pipe 72, and the coolant is delivered to the flow path 70 through the inlet pipe 72 and the inlet port 61i. Cooling water flows along the flow path 70 to absorb heat transferred from the bearing 65 to the insulating ring 66.

Cooling water that absorbs heat while flowing along the flow path 70 is transferred to the outside through the outlet port 61e and the outlet pipe 74 to discharge the heat generated from the bearing assembly 63 to the outside.

For reference, as the coolant flows through the cooling flow path 54 formed on the outer surface of the housing 53, heat generated from the electric motor 51 is discharged to the outside. As such, the cooling water for cooling the housing 53 and the cooling water for cooling the bearing assembly 63 may be supplied by one cooling water supply source.

On the other hand, the flow path 70 is provided with a plurality of side by side and the adjacent flow path 70 may be communicated through the connection path 71, in this case adjacent by the pressure of the cooling water supplied through the inlet pipe (72) Cooling water may be sequentially delivered to the flow path 70 to flow. When the flow path 70 is spiraled as one, the flow path 70 may flow within the flow path 70 relatively easily by the pressure of the cooling water itself.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self-evident.

1 is a cross-sectional view showing the configuration of an electric motor provided with a bearing cooling device according to the prior art.

2 is a cross-sectional view showing the configuration of an electric motor employing a preferred embodiment of a bearing cooling apparatus according to the present invention.

Figure 3 is an enlarged cross-sectional view showing the main portion of the embodiment of the present invention.

Figure 4 is a schematic perspective view showing an outer ring constituting an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

51: electric motor 53: housing

54; Cooling flow path 55: stator

57: rotor 59: axis of rotation

61: first cover 61: first cover

61i: inlet port 61e: outlet port

63: bearing assembly 64: inner bearing cover

64 ': outer bearing cover 65: bearing

66: insulation ring 67: inner ring

67 ': outer ring 68: insulator

70: cooling water flow path 72: inlet pipe

74: outlet pipe

Claims (5)

A bearing assembly rotatably supporting a rotating shaft extending through an end portion of the housing constituting the exterior; An insulating ring located between the bearing constituting the bearing assembly and an end of the housing; A cooling water flow path formed between the insulating ring and an end of the housing, one end of which is connected to an inlet tube side, and the other end of which is connected to an outlet tube side; And a cooling water supply source for supplying cooling water to the cooling water channel. The bearing cooling apparatus of claim 1, wherein an insulation is installed between the inner ring and the outer ring, and a cooling water flow path is formed on an outer surface of the outer ring. The bearing cooling apparatus according to claim 1 or 2, wherein a plurality of the cooling water flow paths are formed in parallel, and adjacent cooling water flow paths communicate with each other by a connection path. The bearing cooling apparatus according to claim 3, wherein the connection path is connected to an adjacent flow path with a predetermined slope. The bearing cooling apparatus according to claim 4, wherein the cooling water flow path, the inlet pipe, and the outlet pipe communicate with each other through an inlet port and an outlet port formed in a cover constituting an end of the housing.

Images