JPS6214382B2 - - Google Patents
Info
- Publication number
- JPS6214382B2 JPS6214382B2 JP23172082A JP23172082A JPS6214382B2 JP S6214382 B2 JPS6214382 B2 JP S6214382B2 JP 23172082 A JP23172082 A JP 23172082A JP 23172082 A JP23172082 A JP 23172082A JP S6214382 B2 JPS6214382 B2 JP S6214382B2
- Authority
- JP
- Japan
- Prior art keywords
- bearing
- heat
- working liquid
- pipe
- hollow chamber
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23Q—DETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
- B23Q11/00—Accessories fitted to machine tools for keeping tools or parts of the machine in good working condition or for cooling work; Safety devices specially combined with or arranged in, or specially adapted for use in connection with, machine tools
- B23Q11/12—Arrangements for cooling or lubricating parts of the machine
- B23Q11/126—Arrangements for cooling or lubricating parts of the machine for cooling only
- B23Q11/127—Arrangements for cooling or lubricating parts of the machine for cooling only for cooling motors or spindles
Landscapes
- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Auxiliary Devices For Machine Tools (AREA)
- Mounting Of Bearings Or Others (AREA)
Description
【発明の詳細な説明】
この発明は例えば工作機械の複数の主軸等の軸
受部を冷却する多軸冷却装置に関するものであ
る。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a multi-shaft cooling device that cools bearing parts such as a plurality of main shafts of a machine tool, for example.
従来この種の装置としては第1図及び第2図に
示すものがあつた。これら各図において、1,1
1は工作機械の第1、第2の主軸装置であり、ス
パンPの間隔で配置されている。2,21は主
軸、3,31は軸受、4,41は軸受台、5,5
1はプーリ、6はベツドである。 Conventionally, there have been devices of this type as shown in FIGS. 1 and 2. In each of these figures, 1, 1
Reference numeral 1 denotes first and second spindle devices of the machine tool, which are arranged at an interval of span P. 2, 21 are main shafts, 3, 31 are bearings, 4, 41 are bearing stands, 5, 5
1 is a pulley and 6 is a bed.
次に動作について説明する。図示しない駆動用
電動機によりVベルトを介してプーリ5,51に
伝えられた回転力によつて主軸2,21を回転さ
せる。この時、主軸2,21と軸受台4,41と
の間に位置する軸受3,31は主軸2,21が円
滑に回転することを助ける目的をもつているが、
回転とともに軸受3,31は摩擦により発熱し温
度上昇する。軸受3,31に生じた熱量は軸受台
4,41に伝わり、ベツド6および周囲空気へ伝
熱して放熱する。この際に軸受台4,41は温度
上昇し、各部は熱膨脹による種々の熱変形・歪を
生じる。このため主軸2,21の位置が変動し、
被加工物を機械加工するときに加工精度が低下す
るという欠点があつた。さらに、相互間の主軸
2,21の位置の変動に差を生じると同時に複数
の加工を行なう際に相互の加工精度に差を生じる
という欠点があつた。 Next, the operation will be explained. The main shafts 2, 21 are rotated by the rotational force transmitted to the pulleys 5, 51 via the V-belt by a driving electric motor (not shown). At this time, the bearings 3, 31 located between the main shafts 2, 21 and the bearing stands 4, 41 have the purpose of helping the main shafts 2, 21 rotate smoothly.
As the bearings 3 and 31 rotate, they generate heat due to friction and their temperature increases. The amount of heat generated in the bearings 3, 31 is transmitted to the bearing stands 4, 41, and is transferred to the bed 6 and the surrounding air to radiate heat. At this time, the temperature of the bearing stands 4 and 41 increases, and various thermal deformations and strains occur in each part due to thermal expansion. For this reason, the positions of the main shafts 2 and 21 fluctuate,
There was a drawback that the machining accuracy decreased when machining the workpiece. Furthermore, there is a drawback that there is a difference in the fluctuation of the positions of the main shafts 2 and 21 between them, and at the same time, there is a difference in the machining accuracy when performing a plurality of machining operations.
この発明は上記のような従来のものの欠点を除
去するためになされたものであり、第1、第2の
主軸装置を有効に且つ平均的に冷却することがで
きる多軸冷却装置を提供することを目的としてい
る。 This invention was made in order to eliminate the drawbacks of the conventional ones as described above, and an object of the present invention is to provide a multi-shaft cooling device that can effectively and evenly cool the first and second main shaft devices. It is an object.
以下、この発明の一実施例を第3図及び第4図
に基づいて説明する。第3図は機能系統を示すブ
ロツク図、第4図は断面側面図であり、これら各
図において、7,71は軸受台4,41の内部に
形成された環状の中空室、8は放熱装置であり、
冷却フアン9により冷却されている。10は中空
室7,71でそれぞれ気化する作動液体の蒸気を
放熱装置8に合流させて案内する蒸気管であり、
分流管10a,10b、合流管10cとにより構
成されている。12は放熱装置8で凝縮液化する
作動液体を軸受台4,41の中空室7,71に分
流させて案内する液管であり、合流管12a、分
流管12b,12cにより構成されている。 An embodiment of the present invention will be described below with reference to FIGS. 3 and 4. Fig. 3 is a block diagram showing the functional system, and Fig. 4 is a cross-sectional side view. In these figures, 7 and 71 are annular hollow chambers formed inside the bearing stands 4 and 41, and 8 is a heat dissipation device. and
It is cooled by a cooling fan 9. 10 is a steam pipe that guides the vapor of the working liquid that is vaporized in the hollow chambers 7 and 71, respectively, to join the heat radiating device 8;
It is composed of branch pipes 10a, 10b and a merging pipe 10c. Reference numeral 12 denotes a liquid pipe that separates and guides the working liquid that is condensed and liquefied in the heat dissipation device 8 to the hollow chambers 7 and 71 of the bearing stands 4 and 41, and is composed of a confluence pipe 12a and branch pipes 12b and 12c.
尚、中空室7,71および放熱装置8、蒸気管
10、液管12の内部を真空減圧後、アンモニ
ア、フロン等の作動液体がその内部に所定量封入
される。 After the hollow chambers 7 and 71, the heat radiating device 8, the steam pipe 10, and the liquid pipe 12 are vacuumed, a predetermined amount of a working liquid such as ammonia or chlorofluorocarbon is sealed therein.
次に動作について説明する。軸受台4,41で
受熱した軸受3,31の熱量は中空室7,71内
のフロン等の作動液体を加熱して気化させる際に
蒸発潜熱として奪われ、気化したフロン等の蒸気
は自身の蒸気圧を利用して蒸気管10の分流管1
0a,10b、合流管10cを経て放熱装置8へ
移動し、冷却フアン9により周囲空気により冷や
される。このとき、フロン等の蒸気は凝縮して液
体に戻るが、凝縮潜熱を周囲空気に放出し、軸受
3,31の熱量を周囲空気へ放熱する。凝縮した
作動液体は液管12の合流管12a、分流管12
b,12cを経て重力を利用して軸受台4,41
の中空室7,71へ戻る。このような動作をくり
返し行なうことにより、軸受台4,41の熱量を
放熱装置8に熱輸送して効率よく冷却するように
している。 Next, the operation will be explained. The amount of heat received by the bearings 3, 31 in the bearing stands 4, 41 is taken away as latent heat of vaporization when the working liquid such as fluorocarbons in the hollow chambers 7, 71 is heated and vaporized, and the vapor of the vaporized fluorocarbons is released as its own vapor. The branch pipe 1 of the steam pipe 10 is created using steam pressure.
0a, 10b, and a confluence pipe 10c to the heat dissipation device 8, where it is cooled by the surrounding air by a cooling fan 9. At this time, the vapor of fluorocarbon or the like is condensed and returned to liquid, but the latent heat of condensation is released to the surrounding air, and the amount of heat from the bearings 3 and 31 is radiated to the surrounding air. The condensed working liquid flows through the confluence pipe 12a and branch pipe 12 of the liquid pipe 12.
b, 12c, bearing stands 4, 41 using gravity.
Return to hollow chambers 7 and 71. By repeating such an operation, the amount of heat in the bearing stands 4, 41 is transported to the heat radiating device 8 and efficiently cooled.
ところで、軸受台4が他方の軸受台41に比べ
温度上昇(熱量)が大きくなると、軸受台4の中
空室7内の作動液体は気化する際に軸受台41の
中空室71内の作動液体に比べより大きな蒸気
量・蒸気圧・蒸気温度となる。従つて、より大き
な蒸気量となる分だけ蒸発潜熱を大きく奪い、よ
り大きく冷却し、軸受台4の温度上昇が軸受台4
1より大きくなるのを抑制するように働く。そし
て、軸受台4の中空室7内にて気化した温度の高
い蒸気は蒸気管10の分流管10a、合流管10
cを経て放熱装置8へ移動して凝縮液化する。一
方、軸受台41は軸受台4に比べ温度上昇が小さ
く、軸受台41の中空室71内の作動液体は軸受
台4の中空室7内の作動液体に比べ気化する際の
蒸気量・蒸気圧・蒸気温度が低い。従つて、軸受
台41の中空室71内にて気化した温度の低い蒸
気は蒸気管10の分流管10b、合流管10cを
経て放熱装置8へ移動して凝縮液化する。 By the way, when the temperature rise (heat amount) of the bearing pedestal 4 is larger than that of the other bearing pedestal 41, the working liquid in the hollow chamber 7 of the bearing pedestal 4 becomes the working liquid in the hollow chamber 71 of the bearing pedestal 41 when vaporized. Compared to this, the amount of steam, pressure, and temperature are greater. Therefore, as the amount of steam becomes larger, the latent heat of vaporization is taken away to a greater extent, and the temperature of the bearing pedestal 4 increases.
It works to prevent it from becoming larger than 1. The high temperature steam vaporized in the hollow chamber 7 of the bearing stand 4 is then transferred to the branch pipe 10a of the steam pipe 10 and the confluence pipe 10.
It moves to the heat dissipation device 8 via c and is condensed and liquefied. On the other hand, the temperature rise of the bearing pedestal 41 is smaller than that of the bearing pedestal 4, and the working liquid in the hollow chamber 71 of the bearing pedestal 41 has a vapor amount and vapor pressure when vaporized compared to the working liquid in the hollow chamber 7 of the bearing pedestal 4.・Steam temperature is low. Therefore, the low-temperature steam vaporized in the hollow chamber 71 of the bearing stand 41 moves to the heat dissipation device 8 via the branch pipe 10b and the confluence pipe 10c of the steam pipe 10, and is condensed and liquefied.
しかるに、温度の高い蒸気は凝縮液化した際の
温度が高く、温度の低い蒸気は凝縮液化した際の
温度が低い。従つて、放熱装置8においては合流
管10cによつて温度の高い蒸気と温度の低い蒸
気とが混合された平均化した温度の蒸気となり、
凝縮液化した作動液体も平均化した温度の作動液
体となる。この平均化された温度の作動液体が液
管12の合流管12a、分流管12b,12cに
よりそれぞれ軸受台4,41の中空室7,71に
戻る。即ち、軸受台4の中空室7には低くなつた
温度の作動液体が戻り、その低くなつた分だけ冷
やされて軸受台4の温度上昇が減少し、軸受台4
1の中空室71には高くなつた温度の作動液体が
戻り、その高くなつた分だけ暖められて軸受台4
1の温度上昇が増大し、両軸受台4,41の温度
上昇差が小さく抑えられる。このような動作をく
り返し行なうことにより、両軸受台4,41の何
れか一方の発熱量・温度上昇が増大しはじめる
と、両軸受台4,41の温度上昇差を小さく抑え
るように働き、両軸受台4,41が平均的に有効
に冷却される。従つて、工作機械においては軸受
部の熱変形・歪を最少限に抑えることができ、加
工精度を向上させることができる。 However, high temperature steam has a high temperature when condensed and liquefied, and low temperature steam has a low temperature when condensed and liquefied. Therefore, in the heat dissipation device 8, high temperature steam and low temperature steam are mixed by the merging pipe 10c to produce steam at an average temperature.
The condensed and liquefied working liquid also becomes a working liquid with an averaged temperature. The working liquid at this averaged temperature returns to the hollow chambers 7, 71 of the bearing stands 4, 41 through the confluence pipe 12a and the branch pipes 12b, 12c of the liquid pipe 12, respectively. That is, the working fluid at a lower temperature returns to the hollow chamber 7 of the bearing pedestal 4, is cooled by the lowered temperature, and the temperature rise of the bearing pedestal 4 is reduced.
The working fluid at a higher temperature returns to the hollow chamber 71 of 1, and the bearing base 4 is heated by the increased temperature.
1 increases, and the difference in temperature rise between both bearing stands 4 and 41 is kept small. By repeating such an operation, when the heat generation amount and temperature rise of either of the bearing stands 4, 41 starts to increase, it works to suppress the difference in temperature rise of both the bearing stands 4, 41 to a small value, The bearing stands 4, 41 are effectively cooled evenly. Therefore, in the machine tool, thermal deformation and distortion of the bearing portion can be minimized, and machining accuracy can be improved.
尚、上記実施例では冷却フアン9を用いた場合
について述べたが、冷却フアン9を用いず自然風
冷してもよく、あるいは冷却源として冷却風以外
の冷却水・油などを用いても同様の効果が得られ
る。 In the above embodiment, the case where the cooling fan 9 is used has been described, but the cooling fan 9 may not be used and natural air cooling may be used, or cooling water or oil other than the cooling air may be used as the cooling source. The effect of this can be obtained.
また、上記実施例では放熱装置8の外側で作動
液体の蒸気の合流、凝縮液化した作動液体の分流
を行う構成とした場合について述べたが、放熱装
置8の内側で作動液体の蒸気の合流、凝縮液化し
た作動液体の分流を行う構成としてもよく、上記
実施例と同様の効果を奏する。 Furthermore, in the above embodiment, a configuration was described in which the vapor of the working liquid is merged outside the heat radiating device 8 and the condensed working liquid is separated, but the vapor of the working liquid is merged inside the heat radiating device 8, A structure may be adopted in which the condensed and liquefied working liquid is divided, and the same effects as in the above embodiment can be achieved.
また、上記実施例では中空室7,71が軸受台
4,41にそれぞれ設けられた場合について述べ
たが、中空室7,71を軸受3,31と軸受台
4,41との間に設けるようにしてもよい。 Further, in the above embodiment, the hollow chambers 7 and 71 are provided in the bearing pedestals 4 and 41, respectively. You can also do this.
ところで、上記説明では主軸装置が2個の場合
について述べたが、3個以上の主軸装置の場合に
ついてもこの発明を適用し得ることができ、上記
実施例と同様な効果を奏する。 Incidentally, in the above description, the case where there are two spindle devices has been described, but the present invention can also be applied to a case where there are three or more spindle devices, and the same effects as in the above embodiment can be obtained.
この発明は以上説明した通り、軸受部内部に形
成され且つ作動液体が封入される環状の中空室を
それぞれ有し、同じ機械に装着される第1、第2
の主軸装置、この第1、第2の主軸装置の熱量を
放熱する放熱装置、第1、第2の主軸装置の中空
室でそれぞれ気化する作動液体の蒸気を放熱装置
に合流させて案内する蒸気管、放熱装置で凝縮液
化する作動液体を第1、第2の主軸装置の中空室
に分流させて案内する液管を設け、軸受部の熱量
を中空室から放熱装置に熱輸送するようにしたこ
とにより、軸受部の熱量を速やかに奪い効率よく
且つ平均的に冷却できるので、軸受部の熱変形・
歪を最少限に抑制し工作機械等の加工精度を向上
できるという実用上極めて大きな効果がある。 As explained above, this invention has annular hollow chambers formed inside the bearing part and filled with working fluid, and the first and second bearings are mounted on the same machine.
a main shaft device, a heat radiating device for dissipating the heat of the first and second main shaft devices, and a steam for guiding the vapor of the working liquid that is vaporized in the hollow chambers of the first and second main shaft devices by merging with the heat radiating device. A liquid pipe is provided to divert and guide the working liquid that is condensed and liquefied in the tube and heat radiating device to the hollow chambers of the first and second main shaft devices, so that the amount of heat in the bearing section is transferred from the hollow chamber to the heat radiating device. By doing so, the amount of heat from the bearing can be quickly removed and cooled efficiently and evenly, thereby preventing thermal deformation and deformation of the bearing.
This has an extremely large practical effect in that distortion can be suppressed to a minimum and the machining accuracy of machine tools can be improved.
第1図及び第2図は従来の多軸冷却装置を示す
断面側面図及び正面図、第3図及び第4図はこの
発明の一実施例による多軸冷却装置を示すブロツ
ク図及び断面側面図である。
図において、1,11は第1、第2の主軸装
置、4,41は軸受台、7,71は中空室、8は
放熱装置、10は蒸気管、10a,10bは分流
管、10cは合流管、12は液管、12aは合流
管、12b,12cは分流管である。尚、図中同
一符号は同一又は相当部分を示す。
1 and 2 are a cross-sectional side view and a front view showing a conventional multi-shaft cooling device, and FIG. 3 and FIG. 4 are a block diagram and a cross-sectional side view showing a multi-shaft cooling device according to an embodiment of the present invention. It is. In the figure, 1 and 11 are the first and second spindle devices, 4 and 41 are bearing stands, 7 and 71 are hollow chambers, 8 is a heat dissipation device, 10 is a steam pipe, 10a and 10b are branch pipes, and 10c is a confluence pipe. 12 is a liquid pipe, 12a is a confluence pipe, and 12b and 12c are branch pipes. Note that the same reference numerals in the figures indicate the same or corresponding parts.
Claims (1)
れる環状の中空室をそれぞれ有し、同じ機械に装
着される第1、第2の主軸装置、上記第1の主軸
装置の熱量を放熱する放熱装置、上記第1、第2
の主軸装置の中空室でそれぞれ気化する作動液体
の蒸気を上記放熱装置に合流させて案内する蒸気
管、上記放熱装置で凝縮液化する作動液体を上記
第1、第2の主軸装置の中空室に分流させて案内
する液管を備え、上記作動液体の蒸発、凝縮作用
により、上記軸受部の熱を上記中空室から上記放
熱装置に輸送するようにしたことを特徴とする多
軸冷却装置。 2 中空室は軸受台に形成されたことを特徴とす
る特許請求の範囲第1項記載の多軸冷却装置。 3 中空室は軸受台と軸受との間にに形成された
ことを特徴とする特許請求の範囲第1項記載の多
軸冷却装置。[Scope of Claims] 1. First and second spindle devices each having an annular hollow chamber formed inside a bearing portion and filled with a working liquid, and mounted on the same machine, and the first spindle device described above. a heat dissipation device that dissipates a heat amount of
a steam pipe for guiding the vapor of the working liquid that is vaporized in the hollow chambers of the first and second main shaft devices to join the heat radiating device and guiding the working liquid that is condensed and liquefied in the heat radiating device to the hollow chambers of the first and second main shaft devices; A multi-shaft cooling device comprising a liquid pipe that divides and guides the flow, and the heat of the bearing portion is transported from the hollow chamber to the heat radiating device by the evaporation and condensation action of the working liquid. 2. The multi-axis cooling device according to claim 1, wherein the hollow chamber is formed in a bearing stand. 3. The multi-shaft cooling device according to claim 1, wherein the hollow chamber is formed between the bearing stand and the bearing.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP23172082A JPS59118340A (en) | 1982-12-24 | 1982-12-24 | Multi-spindle cooling device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP23172082A JPS59118340A (en) | 1982-12-24 | 1982-12-24 | Multi-spindle cooling device |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| JPS59118340A JPS59118340A (en) | 1984-07-09 |
| JPS6214382B2 true JPS6214382B2 (en) | 1987-04-02 |
Family
ID=16927960
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP23172082A Granted JPS59118340A (en) | 1982-12-24 | 1982-12-24 | Multi-spindle cooling device |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPS59118340A (en) |
-
1982
- 1982-12-24 JP JP23172082A patent/JPS59118340A/en active Granted
Also Published As
| Publication number | Publication date |
|---|---|
| JPS59118340A (en) | 1984-07-09 |