JPH048166B2 - - Google Patents
Info
- Publication number
- JPH048166B2 JPH048166B2 JP60293285A JP29328585A JPH048166B2 JP H048166 B2 JPH048166 B2 JP H048166B2 JP 60293285 A JP60293285 A JP 60293285A JP 29328585 A JP29328585 A JP 29328585A JP H048166 B2 JPH048166 B2 JP H048166B2
- Authority
- JP
- Japan
- Prior art keywords
- machining fluid
- fluid supply
- pressure
- machining
- pressurized air
- 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 - Lifetime
Links
- 238000003754 machining Methods 0.000 claims description 142
- 239000012530 fluid Substances 0.000 claims description 137
- 239000007788 liquid Substances 0.000 claims description 15
- 230000001105 regulatory effect Effects 0.000 description 11
- 238000009760 electrical discharge machining Methods 0.000 description 10
- 238000007789 sealing Methods 0.000 description 5
- 241000282472 Canis lupus familiaris Species 0.000 description 4
- 230000005540 biological transmission Effects 0.000 description 3
- 230000000694 effects Effects 0.000 description 3
- 238000001816 cooling Methods 0.000 description 1
- 230000006866 deterioration Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000005553 drilling Methods 0.000 description 1
- 238000001914 filtration Methods 0.000 description 1
- 238000012423 maintenance Methods 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 230000000149 penetrating effect Effects 0.000 description 1
- 230000000737 periodic effect Effects 0.000 description 1
- 239000002699 waste material Substances 0.000 description 1
Landscapes
- Electrical Discharge Machining, Electrochemical Machining, And Combined Machining (AREA)
Description
【発明の詳細な説明】
〔産業上の利用分野〕
本発明は放電加工機の加工液供給装置に関し、
特に放電加工用の加工液を中空電極の中心孔から
被加工材との放電加工部に供給する形式の放電加
工機に適用して加工液の連続供給を簡単安価に行
い得るように構成した放電加工機の加工液供給装
置に関する。[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a machining fluid supply device for an electric discharge machine,
In particular, this electrical discharge machine is designed to enable continuous supply of machining fluid easily and inexpensively, and is applied to an electrical discharge machine that supplies machining fluid for electrical discharge machining from the center hole of a hollow electrode to the electrical discharge machining part between the workpiece and the workpiece. The present invention relates to a machining fluid supply device for a machining machine.
放電加工機において、棒状等の中空電極を用い
て放電加工を行う場合には電極回転装置を放電加
工機の主軸頭下端に取付け、この電極回路装置の
回転主軸下端に設けられた電極把持装置に中空電
極を着脱自在にさせ、被加工材に対して回転と
縦、横の送りとを与えながら放電加工を推進させ
る。この場合に放電加工部には電極回転装置及び
中空電極の中心孔を介して冷却及び加工屑除去用
の加工液が供給されるために外部から加工液の供
給が行なわれる。この加工液の外部供給手段とし
ては、従来は加工液供給用の電動ポンプを用いて
加工液を放電加工作用時に連続加圧供給する構成
が採られ、放電加工部に供給された加工液は適宜
の濾過手段等を介して回収し、再生利用する構成
が採られていた。
When performing electrical discharge machining using a hollow electrode such as a rod in an electrical discharge machine, an electrode rotating device is attached to the lower end of the main spindle head of the electrical discharge machine, and an electrode gripping device provided at the lower end of the rotating main shaft of this electrode circuit device is The hollow electrode is made removable and rotation is applied to the workpiece, as well as vertical and horizontal feed to promote electrical discharge machining. In this case, machining fluid for cooling and removing machining debris is supplied to the electrical discharge machining section from the outside through the electrode rotation device and the center hole of the hollow electrode. Conventionally, as an external supply means for this machining fluid, a configuration has been adopted in which an electric pump for machining fluid supply is used to continuously supply machining fluid under pressure during electrical discharge machining, and the machining fluid supplied to the electrical discharge machining section is A structure was adopted in which the waste was collected through filtration means, etc., and recycled.
然しながら、従来の加工液の外部供給手段に依
れば、電動ポンプの制御回路等の電気系回路と配
管回路等の混在位置を要し、故障発生が有ると共
に電動ポンプ自体にも故障発生があり、また定期
保守を要する等の煩瑣があること等の問題点を内
在し、しかも比較的に加工液供給手段が高価で放
電加工機のコスト高をもたらすという問題点があ
つた。依つて、本発明はかかる問題点の解消を図
ることを目的とするものである。
However, using conventional external supply means for machining fluid requires a coexistence of electric circuits such as electric pump control circuits and piping circuits, which may cause failures and failures of the electric pump itself. In addition, there are inherent problems such as the need for periodic maintenance, and furthermore, the machining fluid supply means is relatively expensive, resulting in an increase in the cost of the electrical discharge machine. Therefore, it is an object of the present invention to solve these problems.
本発明は上述の発明目的に鑑みて、2つのシリ
ンダ手段を対向連結した加工液供給シリンダを構
成し、圧力空気源からの圧力空気の連続供給に依
つて上記加工液供給シリンダを継続的に作動さ
せ、電極回転装置を介し、また中空電極の中心孔
を経て放電加工部に対し、加工液を放電加工作用
中、継続的に供給するもので、従来は必要とした
電動ポンプを使用しない新規な放電加工機の加工
液供給装置を形成したものである。即ち、本発明
に依れば、放電加工機の主軸頭の下端部に外筺を
介して回転自在に保持されると共に下端に電極把
持装置を有した回転主軸と、前記回転軸の中心部
に貫通形成された加工液管路と、前記外筺内面と
前記回転主軸との間にオイルシールを設けて形成
されると共に前記外筺内の加工液供給路と前記回
転主軸の加工液管路とを相互に連通させる密封管
継手部と、加工液供給タンクに連結されると共に
圧力供給源からの圧力空気によつて加工液の受入
と送出を交互に行い、ピストン桿と対向連結させ
た一対の加工液供給シリンダと、前記一対の加工
液供給シリンダの間の圧力空気経路に前記加工液
供給シリンダのぞれぞれに交互に圧力空気を供給
する圧力空気切換弁と、前記ピストン桿の所定位
置に設けられ、前記ピストン桿の両移動端で前記
ピストンが方向転換するよう前記圧力空気切換弁
の切換桿と係合して前記圧力空気切換弁を切り換
えるドグと、前記加工液供給シリンダから連続的
に加工液が前記加工液管路に供給されるよう前記
加工液供給シリンダから前記外筺内の加工液供給
路に配管された逆止弁を有する加工液供給路とを
具備して構成されたことを特徴とする放電加工機
の加工液供給装置が提供される。
In view of the above-mentioned object of the invention, the present invention constitutes a machining fluid supply cylinder in which two cylinder means are connected oppositely, and the machining fluid supply cylinder is continuously operated by continuous supply of pressurized air from a pressure air source. This system continuously supplies machining fluid to the electrical discharge machining section through the electrode rotation device and the center hole of the hollow electrode during electrical discharge machining, and is a new method that does not use the electric pump that was previously required. This is a machining fluid supply device for an electrical discharge machine. That is, according to the present invention, a rotating spindle is rotatably held at the lower end of the spindle head of an electrical discharge machine via an outer casing and has an electrode gripping device at the lower end, and a rotating spindle is provided at the center of the rotating shaft. A machining fluid pipe passage formed through the outer housing, an oil seal provided between the inner surface of the outer casing and the rotating main shaft, and a machining fluid supply passage in the outer casing and a machining fluid pipe passage of the rotating main shaft. A pair of sealed pipe joints that are connected to a machining fluid supply tank and alternately receive and send machining fluid by means of pressurized air from a pressure supply source, and are connected oppositely to the piston rod. a machining fluid supply cylinder, a pressure air switching valve that alternately supplies pressurized air to each of the machining fluid supply cylinders to a pressure air path between the pair of machining fluid supply cylinders, and a predetermined position of the piston rod. a dog that engages with a switching rod of the pressure air switching valve to switch the pressure air switching valve so that the piston changes direction at both moving ends of the piston rod; and a machining fluid supply path having a check valve that is piped from the machining fluid supply cylinder to the machining fluid supply path in the outer casing so that machining fluid is supplied to the machining fluid conduit. A machining fluid supply device for an electrical discharge machine is provided.
以下、本発明を添付図面に示す実施例に基づい
て詳細に説明する。 Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.
第1図は本発明による放電加工機の加工液供給
装置の機構と電極を把持回転させる電極回転装置
を断面図示したものである。
FIG. 1 is a sectional view showing a mechanism of a machining fluid supply device for an electric discharge machine according to the present invention and an electrode rotation device for gripping and rotating an electrode.
以下においては、本発明の加工液供給装置の説
明に先立つて放電加工機の主軸頭下端に取付けら
れる電極回転装置に就いて先ず説明する。 In the following, prior to explaining the machining fluid supply device of the present invention, the electrode rotating device attached to the lower end of the spindle head of the electric discharge machine will be explained first.
さて、第1図を参照すると、放電加工機の主軸
頭10の下端に電極回転装置20がボルト結合等
によつて取付けられ、この電極回転装置20の下
端に具備されたコレツト型等の電極把持装置22
には中空棒状等の電極Elが挿脱自在に装着される
ようになつている。放電加工作用に当つては、こ
の中空棒状等の電極Elが図示されていない下方の
被加工材(ワーク載台に定着されている)まで主
軸頭10の下降に従つて降下する。さて、電極回
転装置20は取付フランジ24とこの取付フラン
ジ24に固定、一体化された筒形のハウジング2
6とから成る外筺28を具備し、このハウジング
26の中空孔26a内に装着、保持された回転軸
受30,30によつて回転自在に主軸32が軸承
されている。そして、この主軸32は内方中心部
に液管路34を有すると共に下端に適宜の押え板
36等を介して前述の電極把持装置22がねじ固
定等によつて取付けられるようになつている。こ
のとき、主軸32の液管路34と電極把持装置2
2に装着される電極Elの中心孔とは軸方向に整合
するように予め電極把持装置22が位置決めされ
ていることは言うまでもない。電極回転装置20
は更に主軸32を回転駆動するために回転駆動源
を形成するモータ38及びこのモータ38の出力
軸に取付けた駆動プーリ40と、主軸32の軸方
向に沿う適当位置に取付けられた被動用の主軸プ
ーリ42と、上記駆動及び主軸の両プーリ40,
42間に張設された伝動ベルト44とからなる伝
動機構を具備し、主軸32の回転によつて中空棒
状等の電極Elに回転を付与するようになつてい
る。なお、伝動機構は上述のベルト・プーリ機構
に代えてピニオン、ギヤホイールの歯車列からな
る歯車機構によつて形成することも可能である。 Now, referring to FIG. 1, an electrode rotating device 20 is attached to the lower end of the spindle head 10 of the electrical discharge machine by bolt connection or the like, and an electrode gripping device such as a collet type is provided at the lower end of the electrode rotating device 20. device 22
An electrode El in the form of a hollow rod or the like is removably attached to the holder. During the electrical discharge machining operation, this hollow rod-shaped electrode El descends to a lower workpiece (not shown) (fixed on a workpiece mounting table) as the spindle head 10 descends. Now, the electrode rotation device 20 includes a mounting flange 24 and a cylindrical housing 2 fixed and integrated with the mounting flange 24.
The main shaft 32 is rotatably supported by rotary bearings 30, 30, which are mounted and held in the hollow hole 26a of the housing 26. The main shaft 32 has a liquid conduit 34 at its inner center, and the electrode gripping device 22 described above is attached to the lower end of the main shaft 32 by screwing or the like via a suitable holding plate 36 or the like. At this time, the liquid pipe line 34 of the main shaft 32 and the electrode gripping device 2
Needless to say, the electrode gripping device 22 is positioned in advance so as to be aligned in the axial direction with the center hole of the electrode El attached to the electrode El. Electrode rotation device 20
Furthermore, a motor 38 forming a rotational drive source for rotationally driving the main shaft 32, a drive pulley 40 attached to the output shaft of this motor 38, and a driven main shaft attached at an appropriate position along the axial direction of the main shaft 32. a pulley 42, and both drive and main shaft pulleys 40,
It is equipped with a transmission mechanism consisting of a transmission belt 44 stretched between 42, and rotation of the main shaft 32 imparts rotation to the hollow bar-shaped electrode El. The transmission mechanism can also be formed by a gear mechanism consisting of a gear train of pinions and gear wheels instead of the belt/pulley mechanism described above.
電極回転装置20は更に外部から供給される加
工液を外筺28の取付フランジ24に形成した加
工液供給路46から受入し、主軸32の加工液管
路34に供給すべく、加工液の管継手部50を具
備している。この管継手部50は上記取付フラン
ジ24に形成された加工液供給路46の内端が開
口した加工液溜め室48と、この加工液溜め室4
8からの加工液の漏洩を防止するように取付フラ
ンジ24の内壁と主軸32の上端部分の外周との
間に設けられた第1のオイルシール52とによつ
て形成され、主軸32の液管路34は主軸32の
上端において上記加工液溜め室48に開口してい
る。こゝで上記管継手部50を形成している第1
のオイルシール52の下方、つまり該第1のオイ
ルシール52の液封止部分に対して外側、ないし
背面域には主軸32の軸線方向に適宜の間隙を距
てて第2のオイルシール54が同じく取付フラン
ジ24の内壁と主軸32の外周との間に介挿、装
着された配置で設けられており、この第2のオイ
ルシール54と上記第1のオイルシール52との
間に形成された環状間隙は圧力空気による加圧室
56として主軸32の周囲に確保されている。即
ち、この加圧室56には外筺28の取付フランジ
24及びハウジング26の両者を貫通、穿設して
形成された圧力空気通路58が連通し、この圧力
空気通路58を介して外部から供給される圧力空
気が供給され得るように、構成されている。この
ように第1オイルシール52の液封止部分の外側
に圧力空気が供給されると、この圧力空気は加工
液溜め室48へ加工液供給路46を経て外部から
供給される加工液から該第1のオイルシール52
に掛る液圧に抗する空気圧を当該第1のオイルシ
ール52に対して及ぼし、従つて、液圧及び空気
圧が平衡化されると、第1オイルシール52の液
封止部からは漏洩れの発生が充分に防止されるだ
けでなく、第1オイルシール52の圧力負荷によ
る疲労劣化も防止される。この結果、加工液が回
転軸受30等を水漏れ劣化させる不具合の発生も
未然に防止し、しかも管継手部50を形成する第
1オイルシール52の耐用寿命をも充分に増加さ
せ得るのである。 The electrode rotating device 20 further receives machining fluid supplied from the outside from a machining fluid supply path 46 formed in the mounting flange 24 of the outer casing 28, and connects the machining fluid pipe to the machining fluid conduit 34 of the main shaft 32. A joint portion 50 is provided. The pipe joint portion 50 includes a machining fluid reservoir chamber 48 in which the inner end of a machining fluid supply path 46 formed in the mounting flange 24 is open, and a machining fluid reservoir chamber 48 formed in the mounting flange 24 .
A first oil seal 52 is provided between the inner wall of the mounting flange 24 and the outer periphery of the upper end portion of the main shaft 32 to prevent leakage of machining fluid from the liquid pipe of the main shaft 32. The passage 34 opens into the machining liquid reservoir 48 at the upper end of the main shaft 32. Here, the first pipe forming the pipe joint part 50 is
A second oil seal 54 is disposed below the oil seal 52, that is, on the outside or in the back area of the liquid sealing portion of the first oil seal 52, with an appropriate gap in the axial direction of the main shaft 32. Similarly, it is inserted and installed between the inner wall of the mounting flange 24 and the outer periphery of the main shaft 32, and is formed between the second oil seal 54 and the first oil seal 52. An annular gap is secured around the main shaft 32 as a pressurizing chamber 56 using pressurized air. That is, a pressurized air passage 58 formed by penetrating and drilling both the mounting flange 24 of the outer casing 28 and the housing 26 communicates with this pressurizing chamber 56, and air is supplied from the outside through this pressurized air passage 58. It is configured such that the pressurized air can be supplied. When pressurized air is supplied to the outside of the liquid sealing portion of the first oil seal 52 in this way, this pressurized air is extracted from the machining fluid supplied from the outside to the machining fluid reservoir chamber 48 via the machining fluid supply path 46. First oil seal 52
Applying air pressure against the hydraulic pressure applied to the first oil seal 52, and therefore, when the hydraulic pressure and air pressure are balanced, no leakage will occur from the liquid sealing part of the first oil seal 52. Not only is this occurrence sufficiently prevented, but also fatigue deterioration due to pressure load on the first oil seal 52 is also prevented. As a result, it is possible to prevent the occurrence of problems in which machining fluid leaks and degrades the rotary bearing 30, etc., and also to sufficiently increase the service life of the first oil seal 52 forming the pipe joint portion 50.
上述の空気圧による管継手部50に対するバツ
クアツプ作用に当つては、加工液の液圧に対して
略等価の空気圧を作用させ、圧力平衡を得るよう
にすることがオイルシール、特に第1オイルシー
ル52の耐用性を長期化させる上で望ましいこと
は言うまでもなく、このためには加工液の液圧に
見合つた空気圧を加圧室56に供給すればよいこ
とは言うまでもない。従つて、加工液と圧力空気
とを夫々独立的に供給しても両者の圧力関係にお
いて、上述のような圧力平衡を保持できれば良
く、故に加工液と圧力空気の供給系に夫々液圧及
び空気圧を適宜調節する圧力調節弁等の調節手段
を設けた構成とすれば良いが、以下に説明する本
発明の加工液供給装置によれば、先ず加工液の継
続的な供給と同時に上述した圧力空気による背圧
力を液圧に均衡させ得るのである。 When the above-mentioned backup action is performed on the pipe joint part 50 by air pressure, it is necessary to apply air pressure approximately equivalent to the hydraulic pressure of the machining fluid to obtain pressure equilibrium between the oil seals, especially the first oil seal 52. Needless to say, it is desirable to prolong the durability of the machining fluid, and it goes without saying that for this purpose, it is sufficient to supply the pressurizing chamber 56 with an air pressure commensurate with the hydraulic pressure of the machining fluid. Therefore, even if machining fluid and pressurized air are supplied independently, it is sufficient to maintain the pressure equilibrium as described above in the pressure relationship between the two. However, according to the machining fluid supply device of the present invention described below, firstly, the above-mentioned pressurized air is continuously supplied at the same time as the machining fluid is continuously supplied. This makes it possible to balance the back pressure caused by the hydraulic pressure with the hydraulic pressure.
即ち、加工液は適宜の加工液タンク60内に予
め貯溜されてこの加工液タンク60から電極回転
装置20に向けて供給されるが、供給路には1対
の加工液供給シリンダ62a,62bが配設され
る。この加工液供給シリンダ62a,62bの
夫々は加工液室64a,64bと圧力空気室66
a,66bとを有し、各加工液供給シリンダ62
a及び62bの上記加工液室64a,64bと圧
力空気室66a,66bとはピストン68aと6
8bとによつて隔離された構成を有し、しかも両
ピストン68aと68bとはそれぞれのピストン
桿70a,70bが連結フランジ72で結合、一
体化されることにより一体に往復動作する対設構
造で配置されている。こゝで、両加工液供給シリ
ンダ62a,62bの各加工液室64aと64b
は夫々逆止弁74a,74bを介して加工液タン
ク60に結合され、上記逆止弁74a,74bは
加工液タンク60側から加工液供給シリンダ62
a,62bの各加工液室64a,64bへ加工液
を供給するとき開弁し得るように配置され、その
逆方向には加工液は阻止されるようになつてい
る。また、各加工液室64a,64bは夫々他の
逆止弁76a,76bを介して前述した電極回転
位置20の取付フランジ24に形成された加工液
供給路46に接続、結合されている。 That is, the machining fluid is stored in advance in a suitable machining fluid tank 60 and is supplied from this machining fluid tank 60 toward the electrode rotating device 20, but a pair of machining fluid supply cylinders 62a and 62b are provided in the supply path. will be placed. The machining fluid supply cylinders 62a, 62b have machining fluid chambers 64a, 64b and a pressure air chamber 66, respectively.
a, 66b, and each machining fluid supply cylinder 62
The machining liquid chambers 64a, 64b and pressure air chambers 66a, 66b of pistons 68a and 62b are
8b, and both pistons 68a and 68b have opposing structures in which their respective piston rods 70a and 70b are connected and integrated by a connecting flange 72, so that they reciprocate as one. It is located. Here, each machining fluid chamber 64a and 64b of both machining fluid supply cylinders 62a and 62b
are connected to the machining fluid tank 60 via check valves 74a and 74b, respectively, and the check valves 74a and 74b are connected to the machining fluid supply cylinder 62 from the machining fluid tank 60 side.
The valve is arranged so that it can be opened when supplying machining fluid to the machining fluid chambers 64a and 64b of a and 62b, and the machining fluid is blocked in the opposite direction. Further, each machining liquid chamber 64a, 64b is connected and coupled to a machining liquid supply path 46 formed in the mounting flange 24 of the electrode rotation position 20 described above through other check valves 76a, 76b, respectively.
他方、上述した加工液供給シリンダ62a,6
2bの各圧力空気室66a,66bは4ポート2
位置切換弁からなる圧力空気切換弁78及びフイ
ルタ82、リリーフ弁84、ルブリケータ86を
具備した圧力調整弁80を経由して圧力空気供給
源88に接続され、上記圧力空気切換弁78の切
換に従つて、圧力空気供給源88から供給される
圧力空気が圧力調整弁80で所望の圧力レベルに
調節、設定されてから各圧力空気室66a,66
bに交互に供給され、この圧力空気によつて両加
工液供給シリンダ62a,62bのピストン68
a,68bが往復動されるようになつている。つ
まり、両ピストン68a,68bが往復動する
と、一方の、加工液供給シリンダ62a又は62
bからは電極回転装置20に向けて逆止弁76a
又は76bを開動させて加工液の供給が成され、
他方の加工液供給シリンダ62b又は62aには
その間に加工液タンク60から逆止弁74a又は
74bを介して加工液の受入が成されるようにな
つている。そして圧力空気の供給が継続される限
り、加工液の供給は両加工液供給シリンダ62
a,62bから交互に行なわれるので、電極回転
装置20には継続的に加工液の供給が成されるの
である。なお、両ピストン桿70a,70bの連
結フランジ72の位置に設けられたドグ90が圧
力空気切換弁78の切換桿92a,92bに対
し、ピストン往復動に従つて交互に係合し、圧力
空気切換弁78を自動的に切換える構成が具備さ
れているから圧力空気の供給が継続される限り、
圧力空気切換弁78の切換が上述のように、自動
的に繰り返される。 On the other hand, the machining fluid supply cylinders 62a, 6 mentioned above
Each pressure air chamber 66a, 66b of 2b has 4 ports 2
It is connected to a pressure air supply source 88 via a pressure air switching valve 78 consisting of a position switching valve, and a pressure regulating valve 80 equipped with a filter 82, a relief valve 84, and a lubricator 86. After the pressure air supplied from the pressure air supply source 88 is adjusted and set to a desired pressure level by the pressure regulating valve 80, each pressure air chamber 66a, 66
This pressurized air causes the pistons 68 of both machining fluid supply cylinders 62a and 62b to
a and 68b are designed to be reciprocated. In other words, when both pistons 68a and 68b reciprocate, one machining fluid supply cylinder 62a or 62
A check valve 76a is connected from b to the electrode rotating device 20.
Or the machining fluid is supplied by opening 76b,
The other machining fluid supply cylinder 62b or 62a receives machining fluid from the machining fluid tank 60 via a check valve 74a or 74b. As long as the supply of pressurized air continues, the machining fluid is supplied to both machining fluid supply cylinders 62.
Since the machining is performed alternately from a and 62b, the machining fluid is continuously supplied to the electrode rotating device 20. In addition, the dogs 90 provided at the positions of the connecting flanges 72 of both piston rods 70a, 70b engage alternately with the switching rods 92a, 92b of the pressure air switching valve 78 as the pistons reciprocate, thereby switching the pressure air. Since the valve 78 is equipped with a structure that automatically switches the valve 78, as long as the supply of pressurized air is continued,
The switching of the pressure air switching valve 78 is automatically repeated as described above.
また、圧力空気供給源88からは圧力調整弁8
0を介して前述した電極回転装置20の圧力空気
通路58へ調圧された圧力空気を供給する管路が
配設されており、この圧力空気が既述のように当
該電極回転装置20の管継手部50における第1
オイルシール52に対して加圧室56から背圧力
をおよぼすようになつている。こゝで圧力空気は
電極回転装置20に対して供給されるものも2つ
の加工液供給シリンダ62a,62bに交互に供
給されるものも共に圧力調整弁80で所望の一定
圧に調圧されており、しかも加工液供給シリンダ
62a,62bにおいては、この一定調圧された
圧力空気の作用で圧力付与された加工液が逆止弁
76a又は76bを経由して電極回転装置20の
加工液供給路46を経て管継手部50の加工液溜
め室48へ供給されているから、この加工液の圧
力は空気圧と略等圧を呈し、故に上記管継手部5
0の第1オイルシール52に作用する加工液の圧
力と該第1オイルシール52の外側の加圧室56
から第1オイルシール52の液封部に作用する圧
力とが平衡し得るようになつている。 In addition, a pressure regulating valve 8 is connected to a pressure air supply source 88.
A pipe line is provided for supplying regulated pressure air to the pressure air passage 58 of the electrode rotation device 20 described above through the tube 0, and this pressure air is supplied to the pipe of the electrode rotation device 20 as described above. The first part in the joint part 50
Back pressure is applied to the oil seal 52 from the pressurizing chamber 56. Here, both the pressure air supplied to the electrode rotating device 20 and the pressure air supplied alternately to the two machining fluid supply cylinders 62a and 62b are regulated to a desired constant pressure by the pressure regulating valve 80. In addition, in the machining fluid supply cylinders 62a and 62b, the machining fluid that is pressurized by the action of the pressure air whose pressure is regulated at a constant level is supplied to the machining fluid supply path of the electrode rotating device 20 via the check valve 76a or 76b. 46 to the machining fluid storage chamber 48 of the pipe joint 50, the pressure of this machining fluid is approximately equal to the air pressure, and therefore the pressure of the machining fluid is approximately equal to the air pressure.
The pressure of the machining fluid acting on the first oil seal 52 and the pressurizing chamber 56 outside the first oil seal 52
The pressure acting on the liquid sealing portion of the first oil seal 52 can be balanced with the pressure acting on the liquid sealing portion of the first oil seal 52.
上述のように加工液を加工液タンク60から一
旦加工液供給シリンダ62a,62bに供給し、
次いで圧力空気の作用下で電極回転装置に向けて
加圧、供給されることによつて上述のような圧力
空気との圧力平衡が得られるばかりでなく、加工
液をポンプ供給する場合に比較してポンプ振動の
影響を回避し、またポンプ作動による騒音を回避
することもできる。 As described above, the machining fluid is once supplied from the machining fluid tank 60 to the machining fluid supply cylinders 62a and 62b,
Then, by pressurizing and supplying the fluid to the electrode rotating device under the action of pressurized air, not only can pressure equilibrium with the pressure air as described above be obtained, but compared to when machining fluid is supplied by a pump. It is possible to avoid the effects of pump vibration and also avoid the noise caused by pump operation.
こゝで第1図において、加工液供給装置におけ
る1対の加工液供給シリンダ62a,62bの作
用を説明すると、図示の如く、圧力空気切換弁7
8が切換えられた状態では圧力空気供給源88の
圧力空気は、圧力調整弁80で調圧されてから、
右側の加工液供給シリンダ62bにおける圧力空
気室66bに供給される。従つて、この圧力空気
の空気圧がピストン68bに作用し、ピストン桿
70a,70bを一体に矢印方向に左動させる。
故に加工液供給シリンダ62bの加工液室64b
に受入されている加工液が逆止弁76bを開弁さ
せて電極回転装置20の加工液供給路46へ連続
的に供給される。上記ピストン桿70a,70b
の左動に応じて、やがてドグ90が切換桿92b
から解離し、次に切換桿92aに係合すると圧力
空気切換弁78の切換えが行なわれる。なお、ピ
ストン桿70a,70bの左動中に左側の加工液
供給シリンダ62aにおいては、圧力空気室66
aからは圧力空気が押し出されて上記切換弁78
の空気出口から外部に放出され、この間に加工液
室64aには室容積の増加に従つて加工液の受入
作用が生じ逆止弁74aを開弁させて加工液タン
ク60から加工液の受入が継続的に行なわれてい
る。 Now, in FIG. 1, to explain the operation of the pair of machining fluid supply cylinders 62a and 62b in the machining fluid supply device, as shown in the figure, the pressure air switching valve 7
8 is switched, the pressure air from the pressure air supply source 88 is regulated by the pressure regulating valve 80, and then
It is supplied to the pressurized air chamber 66b in the right machining fluid supply cylinder 62b. Therefore, the air pressure of this pressurized air acts on the piston 68b, causing the piston rods 70a, 70b to move together to the left in the direction of the arrow.
Therefore, the machining fluid chamber 64b of the machining fluid supply cylinder 62b
The machining fluid received in the electrode rotating device 20 is continuously supplied to the machining fluid supply path 46 of the electrode rotating device 20 by opening the check valve 76b. The above piston rods 70a, 70b
In response to the left movement of the dog 90, the switching rod 92b
When the pressure air switching valve 78 is disengaged and then engaged with the switching rod 92a, the pressure air switching valve 78 is switched. Note that during leftward movement of the piston rods 70a and 70b, the pressure air chamber 66 in the left machining fluid supply cylinder 62a
Pressure air is pushed out from a, and the switching valve 78
During this time, as the volume of the machining fluid chamber 64a increases, a machining fluid receiving action occurs in the machining fluid chamber 64a, opening the check valve 74a and allowing machining fluid to be received from the machining fluid tank 60. This is done continuously.
圧力空気切換弁78の切換えが行なわれると、
圧力空気は今度は、左側の加工液供給シリンダ6
2aにおける圧力空気室66aに圧力空気の供給
が行われるから、この圧力空気の空気圧を受けて
ピストン68a,68b及びピストン桿70a,
70bは今度は矢印とは逆向きに右動する。この
ため、左側の加工液供給シリンダ62aにおける
加工液室64aから加工液が押し出され、加工液
は逆止弁76aを開弁させて電極回転装置に向け
て供給される。そして、この間に右側の加工液供
給シリンダ62bでは加工液室64bに加工液タ
ンク60から逆止弁74bを開弁させて加工液受
入を行う。このように、左右1対の対設配置によ
る加工液供給シリンダ62a,62bが交互に加
工液の受入と供給を行い、電極回転装置20に対
しては加工液を継続的に供給するのである。 When the pressure air switching valve 78 is switched,
The pressurized air is now supplied to the machining fluid supply cylinder 6 on the left side.
Since pressurized air is supplied to the pressurized air chamber 66a in 2a, the pistons 68a, 68b and the piston rods 70a, receive the air pressure of this pressurized air.
70b now moves to the right in the opposite direction of the arrow. Therefore, the machining fluid is pushed out from the machining fluid chamber 64a in the left machining fluid supply cylinder 62a, and the machining fluid is supplied toward the electrode rotating device by opening the check valve 76a. During this time, in the machining fluid supply cylinder 62b on the right side, the check valve 74b is opened from the machining fluid tank 60 into the machining fluid chamber 64b to receive the machining fluid. In this way, the pair of left and right machining fluid supply cylinders 62a and 62b arranged opposite each other alternately receive and supply machining fluid, and continuously supply machining fluid to the electrode rotating device 20.
以上の説明から明らかなように、本発明によれ
ば、従来の加工液供給装置のように電動ポンプを
用いることが無く、一対のシリンダ装置から加工
液を供給し得るようにしたから、ポンプ制御回路
等の煩瑣な構成を必要とすること無く、しかもポ
ンプによる振動、騒音等の問題の無い静粛な加工
液供給が可能となり、また、1対のシリンダと圧
力空気の切換弁、圧力空気の圧力調整弁等の低コ
スト要素によつて加工液供給装置が構成されるか
ら、加工液供給装置の低コスト化も可能となる効
果がある。更に、管継手部を形成するオイルシー
ルには加工液圧とその加工液圧に抗する圧力に調
圧された空気圧とが付与される圧力平衡がとられ
るから、オイルシールの負担が軽減される。
As is clear from the above description, according to the present invention, the machining fluid can be supplied from a pair of cylinder devices without using an electric pump unlike the conventional machining fluid supply device, so that pump control is possible. It is possible to supply machining fluid quietly without the need for complicated configurations such as circuits, and without problems such as vibration and noise caused by pumps. Since the machining fluid supply device is constructed of low-cost elements such as regulating valves, there is an effect that the cost of the machining fluid supply device can be reduced. Furthermore, the pressure on the oil seal forming the pipe joint is balanced by the processing fluid pressure and the air pressure regulated to the pressure that resists the processing fluid pressure, which reduces the burden on the oil seal. .
第1図は本発明による放電加工機の加工液供給
装置の機構と電極回転装置との接続を示した断面
図を含む機構図である。
10……主軸頭、20……電極回転装置、22
……電極把持装置、32……主軸、El……電極、
34……液管路、50……管継手部、52……第
1オイルシール、60……加工液タンク、62
a,62b……加工液供給シリンダ、74a,7
4b,76a,76b……逆止弁、78……圧力
空気切換弁、80……圧力調整弁、88……圧力
空気供給源、90……ドグ、92a,92b……
切換桿。
FIG. 1 is a mechanical diagram including a sectional view showing the connection between the mechanism of the machining fluid supply device of the electrical discharge machine according to the present invention and the electrode rotation device. 10... Spindle head, 20... Electrode rotating device, 22
... Electrode gripping device, 32 ... Main shaft, El ... Electrode,
34...Liquid pipe line, 50...Pipe joint part, 52...First oil seal, 60...Processing liquid tank, 62
a, 62b... machining fluid supply cylinder, 74a, 7
4b, 76a, 76b... Check valve, 78... Pressure air switching valve, 80... Pressure adjustment valve, 88... Pressure air supply source, 90... Dog, 92a, 92b...
Switching rod.
Claims (1)
転自在に保持されると共に下端に電極把持装置を
有した回転主軸と、前記回転主軸の中心部に貫通
形成された加工液管路と、前記外筐内面と前記回
転主軸との間にオイルシールを設けて形成される
と共に前記外筐内の加工液供給路と前記回転主軸
の加工液管路とを相互に連通させる密封管継手部
と、加工液供給タンクに連結されると共に圧力供
給源からの圧力空気によつて加工液の受入と送出
を交互に行う一対のピストンを有し、それぞれの
ピストン桿を対向連結させた一対の加工液供給シ
リンダと、前記一対の加工液供給シリンダの間の
圧力空気経路に前記加工液供給シリンダのそれぞ
れに交互に圧力空気を供給する圧力空気切換弁
と、前記ピストン桿の所定位置に設けられ、前記
ピストン桿の両移動端で前記ピストンが方向転換
するよう前記圧力空気切換弁の切換桿と係合して
該圧力空気切換弁を切り換えるドグと、前記加工
液供給シリンダから連続的に加工液が前記加工液
管路に供給されるよう前記加工液供給シリンダか
ら前記外筐内の加工液供給路に配管された逆止弁
を有する加工液供給路とを具備して構成されたこ
とを特徴とする放電加工機の加工液供給装置。 2 前記圧力空気供給源から前記密封管継手部に
前記加工液の液圧に抗する背圧付与を行う圧力空
気を供給するようにした特許請求の範囲第1項に
記載の放電加工機の加工液供給装置。[Scope of Claims] 1. A rotating spindle rotatably held at the lower end of the spindle head of an electrical discharge machine via an outer casing and having an electrode gripping device at the lower end, and a rotating spindle formed through the center of the rotating spindle. A machining fluid pipe line formed by providing an oil seal between the inner surface of the outer casing and the rotary main shaft, and a machining fluid supply passage in the outer casing and the machining fluid pipe line of the rotating main shaft are connected to each other. It has a sealed pipe joint for communication, and a pair of pistons that are connected to a machining fluid supply tank and alternately receive and send out machining fluid using pressurized air from a pressure supply source, with their respective piston rods facing each other. a pair of connected machining fluid supply cylinders; a pressure air switching valve that alternately supplies pressurized air to each of the machining fluid supply cylinders in a pressure air path between the pair of machining fluid supply cylinders; a dog provided at a predetermined position and engaged with a switching rod of the pressure air switching valve to switch the pressure air switching valve so that the piston changes direction at both moving ends of the piston rod; and a dog from the machining fluid supply cylinder. and a machining fluid supply path having a check valve piped from the machining fluid supply cylinder to the machining fluid supply path in the outer casing so that machining fluid is continuously supplied to the machining fluid conduit. A machining fluid supply device for an electric discharge machine, characterized in that: 2. Machining in an electric discharge machine according to claim 1, wherein pressurized air is supplied from the pressurized air supply source to the sealed pipe joint portion for applying back pressure against the hydraulic pressure of the machining fluid. Liquid supply device.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP29328585A JPS62157721A (en) | 1985-12-27 | 1985-12-27 | Machining liquid feeding device of electric discharge machine |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP29328585A JPS62157721A (en) | 1985-12-27 | 1985-12-27 | Machining liquid feeding device of electric discharge machine |
Publications (2)
Publication Number | Publication Date |
---|---|
JPS62157721A JPS62157721A (en) | 1987-07-13 |
JPH048166B2 true JPH048166B2 (en) | 1992-02-14 |
Family
ID=17792851
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP29328585A Granted JPS62157721A (en) | 1985-12-27 | 1985-12-27 | Machining liquid feeding device of electric discharge machine |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPS62157721A (en) |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5420388A (en) * | 1989-03-29 | 1995-05-30 | Charmilles Technologies | Tool-holder and rapid rotary spindle |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS56107978A (en) * | 1979-06-11 | 1981-08-27 | Holzer Walter | Circulation pump for carrying liquefied or gaseous medium |
JPS5771728A (en) * | 1980-10-21 | 1982-05-04 | Japax Inc | Fine hole perforator |
-
1985
- 1985-12-27 JP JP29328585A patent/JPS62157721A/en active Granted
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS56107978A (en) * | 1979-06-11 | 1981-08-27 | Holzer Walter | Circulation pump for carrying liquefied or gaseous medium |
JPS5771728A (en) * | 1980-10-21 | 1982-05-04 | Japax Inc | Fine hole perforator |
Also Published As
Publication number | Publication date |
---|---|
JPS62157721A (en) | 1987-07-13 |
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