JP2003324897A - Cooling device for drive motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a retention area from being formed on the air blasting and exhausting side of a drive motor and thus prevent degradation in cooling efficiency, when air is blown to the cylindrical outer wall of the motor to cool the motor. <P>SOLUTION: A cooling device is for cooling the drive motor 5. The cooling device is provided with an air blasting means 6 for sending air from one side to the other side of the cylindrical outer wall 3a of the drive motor 5. The cooling device is further provided with a retained air removing means 7, which forcedly removes air retained in the air retention area 30 located in proximity to the other end of the cylindrical outer wall 3a. The retained air removing means 7 is, for example, an air vent nozzle. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling device for a drive motor in a built-in spindle of a machine tool, for example.

[0002]

2. Description of the Related Art In a drive motor for a built-in spindle, a heat radiation fin is provided on the outer peripheral portion of the drive motor in order to increase the contact area with air, and heat generated inside is radiated. ing. In order to improve heat dissipation efficiency, air is blown from one direction to the outer circumference of the motor and is discharged to the other. However, when the blown air is blown from one direction, a dead water region or a stagnation point is formed on the exhaust side.
The cooling efficiency at this portion is very poor, and a temperature difference may occur between the motor outer peripheral portion and the air flowing portion, which may cause thermal displacement. This thermal displacement causes contact between the rotor and the stator and generation of vibration, and operating conditions such as motor speed and operating time are limited for safety.

In order to eliminate such an air retention area on the exhaust side, a guide member such as a wind guide fin is provided in a duct accommodating a motor so that the air blown from one direction is the air retention area. Various types have been proposed to facilitate the flow (for example, Japanese Patent Laid-Open No. 8-37760 and Japanese Utility Model Laid-Open No. 4-47369). However, it is difficult to sufficiently spread the cool air in the retention area only by performing such air flow guidance.

An object of the present invention is to prevent the air from staying in the other side of the motor when the air is blown from one of the cylindrical outer walls of the drive motor to cool the motor, thereby making the temperature of the motor uniform and biased. An object of the present invention is to provide a drive motor cooling device capable of preventing thermal displacement.

[0005]

DISCLOSURE OF THE INVENTION A drive motor cooling device according to the present invention comprises a blowing means for blowing air in one direction from one side to the other side of a cylindrical outer wall of a drive motor, and the other side. And a staying air removing unit for forcibly removing the staying air in the air staying region around the outer cylindrical wall of the above. According to this structure, air is blown from one side by the blowing means to cause a retention area of air around the cylindrical outer wall on the other side, but the air trying to stay in this retention area is It is forcibly removed by the removing means. Since forced removal is performed in this manner, new blown air by the blower means flows without staying on the other side of the motor. Therefore, the cooling efficiency does not decrease due to the retention of air, and the uneven thermal displacement due to the temperature difference is prevented. That is, this drive motor cooling device does not attempt to reduce the staying area by enhancing the guide effect of the conventional air blow, but forcibly removes the staying air in the air staying area so that the air blow can easily flow. It is characterized by having done.

In the present invention, the staying air removing means is an air releasing means for releasing air of a predetermined pressure toward the air holding area, and blows the air of the air holding area by the air of the predetermined pressure. It may be. When the air discharging means is provided as the staying air removing means in this way, the blown air can be effectively spread over the entire circumference by blowing off the air in the air staying area. Further, unlike mechanical means for removing the plate by swinging it, it is not necessary to consider interference with the outer peripheral surface of the motor and the fins provided on the outer peripheral surface, and the accumulated air can be simply structured. Can be forcibly removed. As this air discharging means, an air discharging nozzle provided toward a part of the cylindrical outer wall may be adopted. In that case, the configuration can be simpler.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described with reference to FIGS. This embodiment shows an example applied to an air-cooled built-in spindle device of a lathe. The built-in spindle 1 rotatably supports a rotating shaft 11 serving as a main shaft with a bearing 4 in a casing 3 that also serves as a spindle casing and a motor casing.
The rotor 51 and the stator 52 are provided in the casing 3. The casing 3 is installed in the housing 2, which serves as a main shaft housing. The casing 3 includes a tubular outer wall 3a and end walls 3b at both ends thereof. Rotating shaft 1
1 has a casing 12 axially penetrating therethrough, and a chuck 12 for gripping a workpiece is provided at the tip. The rotary shaft 11 is a hollow shaft, and a chuck draw bar (not shown) that penetrates the inside in the axial direction is provided on the base end side of the rotary shaft 11 via a rotary joint (not shown) to the chuck opening / closing cylinder device 13. Are linked together. The rotor 51 of the drive motor 5 is provided on the rotating shaft 11, and the stator 52 is provided on the inner circumference of the cylindrical outer wall 3a. The rotor 51 is made of, for example, a permanent magnet, and the stator 52 has a stator coil.

An air passage 32 having a space portion surrounding the outer periphery of the cylindrical outer wall 3a is provided in the housing 2, and the air passage 32 continues from the lower end opening 33 of the housing 2 to the upper end opening 34. The lower end opening 33 opens on the lower surface of the housing 2, and the upper end opening 34 opens on the upper surface of the housing 2. The housing 2 has spindle fitting holes 2a on both sides of the air passage 32 in the axial direction of the cylindrical outer wall, and the casing 3 is installed in the housing 2 by fitting in the spindle fitting holes 2a. Tubular outer wall 3a of casing 3
Is the cooling fin 3 on the outer circumference of the axial portion in the air passage 32.
1 is provided.

The width of the air passage 32 in the axial direction of the cylindrical outer wall is as shown in FIG.
As shown in, it is almost constant over the entire length. As shown in FIG. 2, the lateral width of the air duct 32 in the direction orthogonal to the axial direction of the tubular outer wall is such that both side portions 32a of the tubular outer wall 3a are widened in the vicinity of the lower end opening 33 and the upper end opening 34. It is said that. The both side portions 32a are formed by the cylindrical outer wall 3a.
The inner surface is a cylindrical surface along the outer periphery of the.

A blowing means 6 for blowing air in one direction from the lower surface side, which is one side of the cylindrical outer wall 3a in the blowing direction, to the upper surface side, which is the other side, is provided for the blowing path 32. . The blowing unit 6 is a blowing fan that is provided near the lower end opening 33 and blows air into the blowing passage 32, or a fan that blows air into the lower end opening 33 through a duct (not shown). May be. Further, the air discharge nozzle 7 is provided as a staying air removing unit for forcibly removing the staying air in the air staying region 30 around the upper surface which is the other side of the cylindrical outer wall 3a from the air staying region 30. . The air discharge nozzle 7 is provided toward a part of the cylindrical outer wall 3a. Specifically, the air discharge nozzle 7 is provided at the center of the cross section of the air passage 32 in the radial direction with respect to the cylindrical outer wall 3a. The air discharge nozzle 7 is composed of a tip portion of a pipe, and is supported by the housing 2 via a supporting means (not shown). A blower fan (not shown) is connected to the nozzle 7, and air adjusted to a predetermined pressure is discharged from the tip of the nozzle 7.

The cooling action of the above configuration will be described. The air blown by the air blower 6 is introduced from the lower end opening 34 of the housing 2 as shown by the arrow, and the introduced air passes through the air passage 32 while touching the cooling fins 31 and is discharged to the outside from the upper end opening 34. . This flow of air promotes the heat radiation effect of the cooling fins 31 and suppresses the heat generation of the drive motor 5. At this time, an air retention region 30 is formed on the exhaust side of the cylindrical outer wall 3a of the drive motor 5. However, the air staying in the air staying region 30 is blown away by the air having a predetermined pressure discharged from the air discharge nozzle 7. Therefore, the large air retention area 30 is prevented from occurring, and the uneven thermal displacement around the motor 5 due to the generation of the air retention area 30 is prevented.

In the above embodiment, one pipe type air discharge nozzle 7 is used as the staying air removing means, but a plurality of air discharge nozzles 7 may be provided, and the air discharge nozzle may be provided. As shown in FIG. 3, the tip 7 may have a tip end outlet which is widened in a slit shape. The spreading direction is the axial direction of the cylindrical outer wall 3a. In addition to these, the staying air removing means may be, for example, the air staying region 3
It may be an air discharge means for discharging air of a predetermined pressure toward substantially the entire zero, or a mechanical means such as a plate which is driven to swing. Further, although the air passage 32 is provided in the vertical direction in the above embodiment, the air passage 32 may be provided in the horizontal direction, for example.

Table 1 shows a test example of each of the above embodiments. In the table, the nozzle type of pipe type is the shape of the air discharge nozzle 7 in the embodiment of FIG. 1, and the wide type is the shape of the air discharge nozzle 7 of the embodiment of FIG. It is a thing.

[0014]

[Table 1]

In the table, the built-in spindle device is operated under each condition for 8 hours, and the difference between the outside temperature of the lower surface and the upper surface (in the air retention area 30) of the cylindrical outer wall 3a is measured. This is the highest value. The cylindrical outer wall 3
The temperature of a is the outside air temperature (15-1
8 ° C). Experiment No. 1 shows a comparative example in which air is not released to the air retention area 30. Experiment Nos. 2 and 3 are examples in which pipe type nozzles 7 as shown in FIGS. 1 and 2 are used, and air is discharged to the air retention region 30 at different air pressures, and Experiment No. 4 is as shown in FIG. An example in which air is discharged to the air retention area 30 using the wide type nozzle 7 is shown. The purge pressure indicates the air pressure released from the tip of the nozzle 7. In addition,
The blowing speed of the cooling blown air by the blowing means 6 including a blowing fan was set to about 12 m / sec.

As can be seen from Table 1, when the air is not discharged to the region 30 as in Experiment No. 1, the temperature rise in the upper surface portion (air retention region 30) of the cylindrical outer wall 3a is large, and the air is blown. The cooling effect of air is small. On the other hand, Experiment No
When air is discharged to the air retention area 30 as in 2, 3, and 4, the temperature difference between the upper surface portion and the lower surface portion of the cylindrical outer wall 3a is reduced. This is because the air staying in the air staying area 30 is blown away by the air discharged from the nozzle 7 and the blown air introduced from the lower end opening 33 comes into contact with the entire circumference of the cylindrical outer wall 3a, so that the cooling effect of the blown air is increased. It is thought that it is fully exerted. Also, Experiment Nos. 2, 3
In the result of No. 4, the difference from the outside air temperature at the upper surface of the cylindrical outer wall is smaller than that at the lower surface of the cylindrical outer wall. This is because the cooling effect of the air discharged from the nozzle 7 is synergistic. It is thought to be due to.

According to the results of Table 1, the shape of the nozzle 7 is
There is no great difference in effectiveness between the pipe type and the wide type. The pressure of the air discharged from the nozzle 7 is 0.05 MPa when the velocity of the blown air is 12 m / sec.
It is also understood that the degree is appropriate, and if it is larger than this, it tends to be too cold, and if it is smaller than this, the effect of cooling cannot be expected.

The above embodiment has been described for the case of being applied to the built-in spindle 1 in the main shaft of a lathe, but the present invention can also be applied to a built-in spindle for driving a tool in a machine tool other than that. The invention can be applied not only to machines but also to drive motor cooling devices for general industrial machines.

[0019]

Since the drive motor cooling device of the present invention is provided with the staying air removing means to forcibly remove the staying air in the air staying region around the outer cylindrical wall, the cooling blown from one direction is performed. The air is easily distributed all around the motor outer periphery, the cooling efficiency is not reduced due to the retention, and the uneven thermal displacement due to the temperature difference is effectively prevented. As the staying air removing means, an air releasing means for releasing air of a predetermined pressure toward the air staying area is provided, and when the air in the air staying area is blown off, the blown air can be effectively spread all around. Further, unlike the case where a mechanical staying air removing means is provided, it is not necessary to consider interference with the outer peripheral surface of the motor and fins, and the staying air can be forcibly removed with a simple configuration. When the air discharge means is an air discharge nozzle provided so as to face a part of the cylindrical outer wall, the structure becomes even simpler.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional view of a drive motor including a cooling device of the present invention.

FIG. 2 is a sectional view taken along line II-II in FIG.

FIG. 3 is a vertical sectional view of a drive motor cooling device according to another embodiment of the present invention.

[Explanation of symbols]

1 ... Built-in spindle 2 ... Housing 3 ... Casing 3a ... Cylindrical outer wall 5 ... Drive motor 7 ... Air discharge nozzle (retained air removing means) 11 ... Rotation axis 30 ... Air retention area 31 ... Cooling fin 32 ... Blower 33 ... Lower end opening 34 ... Top opening

   ─────────────────────────────────────────────────── ─── Continued front page    F term (reference) 3C011 FF02                 3C048 BB14 EE02                 5H605 AA01 BB05 CC01 DD03 DD11                 5H609 BB12 BB19 BB24 PP01 PP05                       PP17 QQ02 QQ20 QQ23 RR46                       RR48 RR63 RR68 RR73

Claims (3)

[Claims] 1. A cooling device for cooling a drive motor, comprising: a blower means for blowing air in one direction from one side to the other side of a cylindrical outer wall of the drive motor; and the other side cylinder. And a staying air removing means for forcibly removing the staying air in the air staying area around the outer wall of the outer shape of the drive motor. 2. The staying air removing means is an air releasing means for releasing air of a predetermined pressure toward an air staying area,
2. The drive motor cooling device according to claim 1, wherein the air in the air retention area is blown off by the air having the predetermined pressure. 3. The drive motor cooling device according to claim 2, wherein the air discharge means is an air discharge nozzle provided toward a part of the cylindrical outer wall.