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JPH06126607A - Curved surface polishing device - Google Patents

Curved surface polishing device

Info

Publication number
JPH06126607A
JPH06126607A JP27425792A JP27425792A JPH06126607A JP H06126607 A JPH06126607 A JP H06126607A JP 27425792 A JP27425792 A JP 27425792A JP 27425792 A JP27425792 A JP 27425792A JP H06126607 A JPH06126607 A JP H06126607A
Authority
JP
Japan
Prior art keywords
tool
polishing head
polishing
axis
shaft member
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.)
Pending
Application number
JP27425792A
Other languages
Japanese (ja)
Inventor
Hirofumi Suzuki
浩文 鈴木
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Mitsubishi Electric Corp
Original Assignee
Mitsubishi Electric Corp
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Mitsubishi Electric Corp filed Critical Mitsubishi Electric Corp
Priority to JP27425792A priority Critical patent/JPH06126607A/en
Publication of JPH06126607A publication Critical patent/JPH06126607A/en
Pending legal-status Critical Current

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  • Grinding And Polishing Of Tertiary Curved Surfaces And Surfaces With Complex Shapes (AREA)

Abstract

PURPOSE:To machine a curved-surface work piece' with good accuracy and remarkably improve the working efficiency by connecting an oscillating device for oscillating a polishing head to make the axis of a tool parallel to the tangential line in a working point of a work piece to the polishing head. CONSTITUTION:A curved surface polishing device includes a polishing head 14 for rotatably supporting a disc-like tool 13 round the shaft center and pressing the outer peripheral surface of the tool 13 to a surface 11a to be worked of a workpiece 11 with designated pressing force and a driving device 15 for rotating the tool 13. A NC table 16 as an oscillating device for oscillating the polishing head 14 to make the axis of the tool 13 parallel to the tangential line C in a working point 11b of a work piece 11 is connected to the polishing head 1. Thus, the outer peripheral surface of the tool 13 is pressed to a surface 11a to be worked to uniformalize the relative speed in a contact area between the tool 13 and the surface 11a to be worked. Accordingly, the working amount is equalized extending over the whole area of the contact surface of the tool 13 so that the shaps of single working traces are uniformalized.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、X線用反射ミラーや工
学レンズなどの曲面形状の被加工物を高精度に加工する
曲面研磨装置に関するものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a curved surface polishing apparatus for highly accurately processing a curved surface-shaped workpiece such as a reflection mirror for X-rays or an engineering lens.

【0002】[0002]

【従来の技術】従来のこの種の曲面研磨装置としては、
例えば特公平4−50152号公報に開示された非球面
加工機がある。この公報に示された非球面加工機を図5
に示す。
2. Description of the Related Art As a conventional curved surface polishing apparatus of this type,
For example, there is an aspherical surface processing machine disclosed in Japanese Patent Publication No. 4-50152. The aspherical surface processing machine shown in this publication is shown in FIG.
Shown in.

【0003】図5は従来の非球面加工機の工具部分を拡
大して示す断面図である。同図において1は被加工物
で、この被加工物1の上面には凹曲面からなる加工面1
aが形成されている。また、この被加工物1は不図示の
ロータリテーブルに載置固定され、加工時には中心軸線
aを中心に回転される。
FIG. 5 is an enlarged sectional view showing a tool portion of a conventional aspherical surface processing machine. In the figure, reference numeral 1 denotes a work piece, and a work surface 1 formed of a concave curved surface on the upper surface of the work piece 1.
a is formed. The workpiece 1 is placed and fixed on a rotary table (not shown), and is rotated about the central axis a during machining.

【0004】2は略丸棒状に形成された工具で、この工
具2は軸心部を中心にして回転自在にスピンドル3に支
持されており、不図示の駆動装置に連結されて回転され
る構造になっている。図中一点鎖線bはこの工具2の回
転軸線を示す。前記スピンドル3は支持部材4に圧縮コ
イルばね5を介して支承され、この支持部材4に上下動
自在に装着されている。そして、工具2が加工面1aに
沿って移動するようにこの支持部材4が不図示の回動,
昇降装置によって駆動される構造になっていた。
Reference numeral 2 denotes a tool formed in a substantially round bar shape. The tool 2 is supported by a spindle 3 so as to be rotatable around an axial center thereof, and is connected to a drive device (not shown) to rotate. It has become. In the figure, the alternate long and short dash line b indicates the axis of rotation of the tool 2. The spindle 3 is supported by a support member 4 via a compression coil spring 5, and is mounted on the support member 4 so as to be vertically movable. Then, the support member 4 rotates so as to move the tool 2 along the machining surface 1a,
It was structured to be driven by a lifting device.

【0005】このように構成された従来の装置は、工具
2をその下端面を加工面1aの加工点(この加工点を図
中符号6で示す)に押し当てて回転させると共に、被加
工物1を中心線a回りに回転させて加工が行われてい
た。工具2を加工点6に押し当てるときの傾斜角度とし
ては、加工点6での法線方向に工具2の回転軸線bが一
致する角度とされていた。
In the conventional device thus constructed, the lower end surface of the tool 2 is pressed against the machining point of the machining surface 1a (this machining point is indicated by reference numeral 6 in the drawing) to rotate, and at the same time, the workpiece is machined. Processing was performed by rotating 1 around the center line a. The inclination angle when the tool 2 is pressed against the machining point 6 is the angle at which the rotation axis b of the tool 2 coincides with the normal direction at the machining point 6.

【0006】さらに、工具2を押し当てるときの加圧力
は、工具2およびスピンドル3が下がろうとする力から
圧縮コイルばね5の弾発力を差し引いた分の力とされて
いた。すなわち、この装置では支持部材4を下げること
で加工圧が大きくなり、逆に上昇させることで加工圧が
減少する。
Further, the pressing force when the tool 2 is pressed against the tool 2 and the spindle 3 is set to be a force that is obtained by subtracting the elastic force of the compression coil spring 5 from the force of the tool 2 and the spindle 3 being lowered. That is, in this apparatus, the working pressure is increased by lowering the support member 4, and is increased by increasing the working pressure.

【0007】[0007]

【発明が解決しようとする課題】しかるに、上述したよ
うに構成された従来の非球面加工機では、工具2の回転
軸線bを加工点6での法線方向と一致させて加工を行う
ため、工具2の下端面の回転中心が加工面1aに当たっ
てしまう。すなわち、工具2の径方向中心部より外周部
の方が相対的に回転速度が速いため、径方向中心部より
外周部の方が加工量が多くなってしまう。このため、単
一加工痕の形状が不均一であった。また、工具2および
スピンドル3からなる研磨ヘッドを傾けると軸方向への
押圧力(加工圧)が鉛直状態のときに較べて減少するた
め、加工圧を加工面1aの全面にわたって一定とするこ
とができない。言い換えれば図5に示した角度θが大き
くなるにしたがって加工圧が減少してしまう。
However, in the conventional aspherical surface processing machine configured as described above, since the rotation axis b of the tool 2 is made to coincide with the normal direction at the processing point 6, the processing is performed. The center of rotation of the lower end surface of the tool 2 hits the processing surface 1a. That is, since the outer peripheral portion of the tool 2 has a relatively higher rotational speed than the radial central portion, the outer peripheral portion of the tool 2 has a larger amount of machining than the radial central portion. Therefore, the shape of the single processing mark was non-uniform. Further, when the polishing head composed of the tool 2 and the spindle 3 is tilted, the pressing force (processing pressure) in the axial direction is smaller than that in the vertical state, so that the processing pressure can be kept constant over the entire processing surface 1a. Can not. In other words, the processing pressure decreases as the angle θ shown in FIG. 5 increases.

【0008】すなわち、従来の装置では上述した工具2
の接触構造による不具合と加工圧が不均一になるという
不具合との2つが原因となり加工面1aの形状精度が低
くなるという問題があった。
That is, in the conventional device, the above-mentioned tool 2 is used.
There is a problem that the shape accuracy of the machined surface 1a becomes low due to two problems, namely, the contact structure and the problem that the processing pressure becomes non-uniform.

【0009】なお、加工圧を加工面1aの全面にわたっ
て均等にするには支持部材4を傾斜角度に応じて上下さ
せればよいが、そのようにするには、傾斜角度を検出す
るセンサや支持部材昇降用の駆動装置を設けなければな
らず構造が複雑になってしまう。
In order to make the working pressure uniform over the entire working surface 1a, the support member 4 may be moved up and down according to the tilt angle. To do so, a sensor or a support for detecting the tilt angle is used. A drive device for raising and lowering the members must be provided, which complicates the structure.

【0010】さらに、従来の非球面加工機で非球面形状
の加工面を加工するときには、加工圧分布を均一にする
ために工具2としては外径の小さなものを使用しなけれ
ばならない。すなわち、このような場合には工具2と加
工面との相対速度が小さくなって加工能率が極めて低く
なってしまう。
Furthermore, when processing an aspherical surface with a conventional aspherical machine, the tool 2 having a small outer diameter must be used in order to make the processing pressure distribution uniform. That is, in such a case, the relative speed between the tool 2 and the machined surface becomes small and the machining efficiency becomes extremely low.

【0011】本発明は、上述したような不具合を解消す
るためになされたもので、X線用反射ミラーや工学レン
ズなどの曲面形状の被加工物を高精度に加工し、また、
加工能率を大幅に向上させることを目的とする。
The present invention has been made in order to solve the above-mentioned problems, and highly accurately processes a curved workpiece such as a reflection mirror for X-rays or an engineering lens, and
The purpose is to significantly improve processing efficiency.

【0012】[0012]

【課題を解決するための手段】第1の発明に係る曲面研
磨装置は、円盤状の工具を軸心回りに回転自在に支持し
かつこの工具の外周面を被加工物の加工面に所定加圧力
をもって押し当てる研磨ヘッドと、前記工具を回転させ
る駆動装置とを備え、前記研磨ヘッドに、この研磨ヘッ
ドを揺動させて工具の軸線を被加工物の加工点における
接線と平行にする揺動装置を連結したものである。
A curved surface polishing apparatus according to a first aspect of the present invention supports a disk-shaped tool rotatably around an axis, and applies an outer peripheral surface of the tool to a machined surface of a workpiece in a predetermined manner. A polishing head that presses with pressure and a drive device that rotates the tool are provided, and the polishing head is oscillated so that the axis of the tool is parallel to the tangent line at the processing point of the workpiece. The device is connected.

【0013】第2の発明に係る曲面研磨装置は、前記第
1の発明の曲面研磨装置において、研磨ヘッドを、工具
支持用軸部材と、この軸部材を加圧方向に沿って移動自
在に支持すると共に加圧力を付与する研磨ヘッド本体と
によって形成し、この研磨ヘッド本体に、工具が装着さ
れた状態の軸部材の重量と同等の重量のバランサを軸部
材の移動方向と平行に移動自在に設け、このバランサで
軸部材を上方から引っ張るものである。
A curved surface polishing apparatus according to a second aspect of the present invention is the curved surface polishing apparatus according to the first aspect of the present invention, in which the polishing head supports a tool supporting shaft member and the shaft member so as to be movable along the pressing direction. And a polishing head body for applying a pressing force to the polishing head body, and a balancer having a weight equivalent to the weight of the shaft member with the tool mounted thereon is movable in parallel with the moving direction of the shaft member. The balancer is provided to pull the shaft member from above.

【0014】[0014]

【作用】第1の発明に係る曲面研磨装置によれば、円盤
状工具の外周面が加工面に押し当てられるから、工具と
加工面との接触部における相対速度が均一になる。
According to the curved surface polishing apparatus of the first aspect of the present invention, since the outer peripheral surface of the disk-shaped tool is pressed against the machining surface, the relative speed at the contact portion between the tool and the machining surface becomes uniform.

【0015】第2の発明に係る曲面研磨装置によれば、
軸部材が略同重量のバランサによって上方から引っ張ら
れるので、軸部材は実質的に無重量になる。このため、
研磨ヘッドを傾斜させても加工点に加わる加工圧は変化
しない。
According to the curved surface polishing apparatus of the second invention,
Since the shaft member is pulled from above by the balancer having substantially the same weight, the shaft member becomes substantially weightless. For this reason,
Even if the polishing head is tilted, the processing pressure applied to the processing point does not change.

【0016】[0016]

【実施例】【Example】

実施例.1 以下、本発明の一実施例を図1および図2によって詳細
に説明する。本実施例では第1の発明と第2の発明の両
方が採用された装置を示す。
Example. 1 Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 1 and 2. In this embodiment, an apparatus adopting both the first invention and the second invention is shown.

【0017】図1は本発明に係る曲面研磨装置の正面
図、図2は同じく側面図である。これらの図において、
11は被加工物で、この被加工物11はX線反射用ミラ
ーであり、凹曲面からなる加工面11aを上方に向けて
支持台(図示せず)に載置固定されている。
FIG. 1 is a front view of a curved surface polishing apparatus according to the present invention, and FIG. 2 is a side view of the same. In these figures,
Reference numeral 11 denotes a workpiece, and this workpiece 11 is an X-ray reflection mirror, and is mounted and fixed on a support (not shown) with a processing surface 11a having a concave curved surface facing upward.

【0018】12は本発明に係る曲面研磨装置で、この
曲面研磨装置12は工具13を前記被加工物11に押し
当てる研磨ヘッド14と、工具13を回転させる駆動装
置15と、これら研磨ヘッド14と駆動装置15を移動
させる第1の発明に係る揺動装置としてのNCテーブル
16とから構成されている。
Reference numeral 12 denotes a curved surface polishing apparatus according to the present invention. The curved surface polishing apparatus 12 has a polishing head 14 for pressing a tool 13 against the workpiece 11, a drive unit 15 for rotating the tool 13, and these polishing heads 14. And an NC table 16 as an oscillating device according to the first invention for moving the drive device 15.

【0019】前記工具13は円盤状に形成され、その軸
心部に工具回転軸17が固着されている。そして、この
工具回転軸17は工具13の円盤面13aが略水平方向
を向くように軸線方向が定められ、軸受18,19を介
して研磨ヘッド14に回転自在に支持されている。ま
た、工具回転軸17の一端には後述する駆動装置15に
よって回転される傘歯車17aが固着されている。
The tool 13 is formed in a disk shape, and a tool rotating shaft 17 is fixed to the shaft center portion thereof. The axis of the tool rotating shaft 17 is determined so that the disk surface 13a of the tool 13 is oriented in a substantially horizontal direction, and is rotatably supported by the polishing head 14 via bearings 18 and 19. Further, a bevel gear 17a rotated by a drive device 15 described later is fixed to one end of the tool rotation shaft 17.

【0020】前記研磨ヘッド14は前記工具回転軸17
を支持する軸部材20と、この軸部材20を工具回転軸
17の軸線方向とは直交する略鉛直方向にスライドベア
リング21,22を介して移動自在に支持する研磨ヘッ
ド本体23とから形成されており、後述するNCテーブ
ル16に支持されている。前記軸部材20は下端部がフ
ォーク状に形成され、このフォーク状部分に工具13を
臨ませてフォーク下端に工具回転軸17が支持されてい
る。また、この軸部材20の上部は後述する加圧機構2
4およびバランサ25に連結されている。なお、軸部材
20の上下方向略中央部に設けられた符号20aで示す
ものは抜け止め用ストッパーである。図示の状態はスト
ッパー20aが研磨ヘッド本体23の受け部23aに当
接している状態であるが、研磨を行うときにはストッパ
ー20aは図示の状態より上側に位置づけられて受け部
23aから離間される。
The polishing head 14 has the tool rotating shaft 17
And a polishing head main body 23 for movably supporting the shaft member 20 through slide bearings 21 and 22 in a substantially vertical direction orthogonal to the axial direction of the tool rotation shaft 17. And is supported by an NC table 16 described later. A lower end portion of the shaft member 20 is formed in a fork shape, and the tool 13 is faced to the fork-shaped portion, and the tool rotating shaft 17 is supported on the lower end of the fork. The upper part of the shaft member 20 has a pressing mechanism 2 which will be described later.
4 and the balancer 25. In addition, a stopper 20a provided at a substantially central portion of the shaft member 20 in the up-down direction is a stopper for retaining. In the illustrated state, the stopper 20a is in contact with the receiving portion 23a of the polishing head main body 23, but when performing polishing, the stopper 20a is positioned above the illustrated state and is separated from the receiving portion 23a.

【0021】前記研磨ヘッド本体23は、工具13に加
圧力を付与するための加圧機構24が上部に設けられる
と共に、軸部材支持部分の側方にバランサ25が装着さ
れている。加圧機構24は、研磨ヘッド本体23に螺合
する圧力設定ねじ24aと、この圧力設定ねじ24aの
下端に対接する圧力センサ24bと、この圧力センサ2
4bと軸部材20の上端ばね受け20bとの間に介装さ
れた圧縮コイルばね24cとから構成されている。この
加圧機構24を使用して加圧力を所望の値にするには、
圧力センサによって検出された値が予め定めた値となる
ように圧力設定ねじ24aを締め込んだり緩めたりして
行う。
The polishing head main body 23 is provided with a pressing mechanism 24 for applying a pressing force to the tool 13, and a balancer 25 is mounted on the side of the shaft member supporting portion. The pressure mechanism 24 includes a pressure setting screw 24a screwed into the polishing head main body 23, a pressure sensor 24b contacting the lower end of the pressure setting screw 24a, and the pressure sensor 2
4b and the compression coil spring 24c interposed between the upper end spring bearing 20b of the shaft member 20. To use the pressurizing mechanism 24 to set the pressing force to a desired value,
This is performed by tightening or loosening the pressure setting screw 24a so that the value detected by the pressure sensor becomes a predetermined value.

【0022】前記バランサ25は本実施例では円柱状に
形成されており、工具13が取付けられた状態の軸部材
20の重量と同等の重量とされている。そして、このバ
ランサ25は長手方向の軸線が前記軸部材20の移動軸
線と平行になるように研磨ヘッド本体23にスライドベ
アリング26を介して移動自在に装着されており、上端
部に結合されたワイヤ27を介して軸部材20の上部に
連結されている。前記ワイヤ27は、研磨ヘッド本体2
3の上部に枢支されたワイヤ支持具28,29に案内さ
れて軸部材20の上端部に導かれ、バランサ25の重量
が略上方に向けて軸部材20に加えられる構造になって
いる。すなわち、バランサ25が軸部材20を実質的に
上方へ引っ張る構造になっている。
The balancer 25 is formed in a cylindrical shape in this embodiment, and has a weight equivalent to the weight of the shaft member 20 to which the tool 13 is attached. The balancer 25 is movably mounted on the polishing head main body 23 via a slide bearing 26 so that the longitudinal axis of the balancer 25 is parallel to the moving axis of the shaft member 20. It is connected to the upper part of the shaft member 20 via 27. The wire 27 is used for the polishing head body 2
The structure is such that the weight of the balancer 25 is applied to the shaft member 20 in a substantially upward direction by being guided to the upper end portion of the shaft member 20 by being guided by the wire supporting members 28 and 29 pivotally supported on the upper part of the shaft 3. That is, the balancer 25 has a structure in which the shaft member 20 is pulled substantially upward.

【0023】前記駆動装置15は、前記研磨ヘッド14
と共に後述するNCテーブル16に支持された工具回転
駆動用モータ31と、このモータ31の出力軸31aに
連結されて下方へ延びるシャフト32と、このシャフト
32の下端部に連結された歯車組立体33とから構成さ
れている。
The driving device 15 is provided with the polishing head 14.
A tool rotation driving motor 31 supported by an NC table 16, which will be described later, a shaft 32 connected to an output shaft 31a of the motor 31 and extending downward, and a gear assembly 33 connected to a lower end of the shaft 32. It consists of and.

【0024】前記シャフト32は柔軟性が高い構造とさ
れ、容易に撓んだり軸方向の寸法が伸びたりできる構造
になっている。前記歯車組立体33は、前記軸部材20
の支持ブロック34に軸受35,36を介して回転自在
に支持された回転軸37を有し、この回転軸37の上端
に前記シャフト32の下端を結合させると共に、前記傘
歯車17aに噛合する傘歯車38を下端に固着させた構
造になっている。
The shaft 32 has a structure with high flexibility, and can be easily bent or expanded in the axial direction. The gear assembly 33 includes the shaft member 20.
Has a rotating shaft 37 rotatably supported by bearing blocks 35 and 36 on a support block 34 of the umbrella, and the lower end of the shaft 32 is coupled to the upper end of the rotating shaft 37, and an umbrella that meshes with the bevel gear 17a. The structure is such that the gear 38 is fixed to the lower end.

【0025】前記NCテーブル16は、研磨ヘッド14
および駆動装置15を走査し、加工面11aの全体が研
磨されるように工具13と被加工物11との接触点を加
工面11a上で相対移動させる構造になっている。この
NCテーブル16の走査軌跡は、被加工物11の前加工
形状を予め測定しておき、その前加工形状と目標形状と
の差から加工面11a上の各座標(図中X軸,Y軸,Z
軸および回転A軸)における必要研磨量を求め、この必
要研磨量が工具13によって研磨されるような軌跡とさ
れる。すなわち、必要研磨量だけ研磨されるのに要する
時間だけ工具13が滞留するような走査速度をもって走
査される。
The NC table 16 includes the polishing head 14
The driving device 15 is scanned to relatively move the contact point between the tool 13 and the workpiece 11 on the machining surface 11a so that the machining surface 11a is entirely polished. The scanning locus of the NC table 16 is obtained by measuring the pre-machined shape of the workpiece 11 in advance and determining the coordinates (X-axis and Y-axis in the drawing) on the machined surface 11a from the difference between the pre-machined shape and the target shape. , Z
The required amount of polishing in the axis and the rotation A axis) is obtained, and the required amount of polishing is set as a locus for polishing by the tool 13. That is, scanning is performed at a scanning speed such that the tool 13 stays for the time required to polish the required polishing amount.

【0026】次に、上述したように構成された本発明に
係る曲面研磨装置12の動作について説明する。先ず、
NCテーブル16によって研磨ヘッド14および駆動装
置15を下降させて下端部の工具13の外周面13bを
被加工物11の加工面11aに対接させる。このとき、
工具回転軸17の軸線が加工面11aの加工点(図1中
に符号11bで示す)における接線(図1中に二点鎖線
Cで示す)と平行になるように研磨ヘッド14および駆
動装置15を揺動させる。また、このときには、研磨ヘ
ッド14の軸部材23にバランサ25の重量が作用する
関係から工具13から被加工物11に加えられる加工圧
は0である。
Next, the operation of the curved surface polishing apparatus 12 according to the present invention configured as described above will be described. First,
The NC head 16 lowers the polishing head 14 and the drive unit 15 to bring the outer peripheral surface 13b of the tool 13 at the lower end into contact with the machined surface 11a of the workpiece 11. At this time,
The polishing head 14 and the drive unit 15 are arranged such that the axis of the tool rotating shaft 17 is parallel to the tangent line (indicated by the chain double-dashed line C in FIG. 1) at the processing point (indicated by reference numeral 11b in FIG. 1) on the processing surface 11a. Rock. Further, at this time, the processing pressure applied from the tool 13 to the workpiece 11 is zero because the weight of the balancer 25 acts on the shaft member 23 of the polishing head 14.

【0027】次に、加圧機構24の圧力設定ねじ24a
を締め込んで圧縮コイルばね24cにより所定の加工圧
を付与する。この加工圧は前記加工点11bでの法線方
向から付与されることになる。なお、加工圧を付与する
ときには軸部材20は研磨ヘッド本体23に対して上下
に移動するが、このときには駆動装置15のシャフト3
2が伸びるようにして撓む。
Next, the pressure setting screw 24a of the pressurizing mechanism 24
And a predetermined processing pressure is applied by the compression coil spring 24c. This processing pressure is applied from the normal direction at the processing point 11b. When applying the processing pressure, the shaft member 20 moves up and down with respect to the polishing head main body 23. At this time, the shaft 3 of the drive unit 15 is moved.
2 flexes as it extends.

【0028】そして、この状態でモータ31を作動させ
る。モータ31の出力軸31aの回転はシャフト32か
ら歯車組立体33に伝わり、この歯車組立体33の傘歯
車28から傘歯車17aに伝わることで回転方向が変え
られて工具回転軸17を介して工具13に伝わる。これ
によって工具13がその軸心を中心として回転駆動され
ることになる。
Then, the motor 31 is operated in this state. The rotation of the output shaft 31a of the motor 31 is transmitted from the shaft 32 to the gear assembly 33, and is transmitted from the bevel gear 28 of the gear assembly 33 to the bevel gear 17a so that the rotation direction is changed and the tool is rotated via the tool rotation shaft 17. It is transmitted to 13. As a result, the tool 13 is driven to rotate about its axis.

【0029】このように工具13を回転させた状態で工
具13と被加工物11との接触面に加工液である研磨材
を供給しながら研磨が行われる。この研磨はNCテーブ
ル16が上述したように研磨ヘッド14および駆動装置
15を走査して行われる。すなわち、工具回転軸17の
軸線が加工面11aの加工点での接線と平行になるよう
に研磨ヘッド14および駆動装置15が図中回転A軸方
向に揺動されると共に、それらがX軸,Y軸およびZ軸
方向に走査される。
In this manner, while the tool 13 is rotated, the polishing is performed while supplying the abrasive, which is the working liquid, to the contact surface between the tool 13 and the workpiece 11. This polishing is performed by scanning the NC head 16 with the polishing head 14 and the driving device 15 as described above. That is, the polishing head 14 and the driving device 15 are swung in the rotational A-axis direction in the drawing so that the axis line of the tool rotation shaft 17 is parallel to the tangent line at the processing point of the processing surface 11a, and at the same time the X-axis, Scanning is performed in the Y-axis and Z-axis directions.

【0030】したがって、このように構成された曲面研
磨装置12では、円盤状に形成された工具13の外周面
13bが加工面11aに押し当てられるから、工具13
と加工面11aとの接触部における相対速度が均一にな
る。
Therefore, in the curved surface polishing apparatus 12 thus constructed, the outer peripheral surface 13b of the disk-shaped tool 13 is pressed against the processing surface 11a, so that the tool 13
And the relative speed at the contact portion between the processed surface 11a becomes uniform.

【0031】また、研磨ヘッド14の軸部材20が略同
重量のバランサ25によって上方から引っ張られるの
で、軸部材20は実質的に無重量になる。このため、研
磨ヘッド14を傾斜させても加工点に加わる加工圧は変
化することがなくなる。
Further, since the shaft member 20 of the polishing head 14 is pulled from above by the balancer 25 having substantially the same weight, the shaft member 20 becomes substantially weightless. Therefore, even if the polishing head 14 is tilted, the processing pressure applied to the processing point does not change.

【0032】なお、本実施例では工具13を回転させる
に当たってモータ出力軸31aと共に回転するシャフト
31に一対の傘歯車38,17aを連結して動力伝達方
向を変える構造としたが、動力伝達方向を変える部材は
回転速度等によって決定されるべきものであり、本実施
例で示したような傘歯車38,17aに限定されるもの
ではない。
In this embodiment, when the tool 13 is rotated, the shaft 31 that rotates together with the motor output shaft 31a is connected to the pair of bevel gears 38 and 17a to change the power transmission direction. The member to be changed should be determined by the rotation speed and the like, and is not limited to the bevel gears 38 and 17a as shown in this embodiment.

【0033】実施例2.また、駆動装置15としては本
実施例に示したようなシャフトドライブ式のものに限定
されず、例えば図3および図4に示すようにモータの出
力軸と工具回転軸とを平行にすることもできる。
Example 2. Further, the drive device 15 is not limited to the shaft drive type as shown in this embodiment, and the output shaft of the motor and the tool rotation shaft may be parallel to each other as shown in FIGS. 3 and 4, for example. it can.

【0034】図3は曲面研磨装置の他の実施例を示す正
面図、図4は同じく側面図で、これらの図においては研
磨ヘッドと駆動装置のみを示した。また、これらの図に
おいて前記図1および図2で説明したものと同一もしく
は同等部材については、同一符号を付し詳細な説明は省
略する。図3および図4で示した曲面研磨装置は前記実
施例の曲面研磨装置12と駆動装置の構造が異なる以外
は同等の構造になっている。
FIG. 3 is a front view showing another embodiment of the curved surface polishing apparatus, and FIG. 4 is a side view of the same, in which only the polishing head and the driving apparatus are shown. Further, in these figures, the same or equivalent members as those described in FIG. 1 and FIG. 2 are designated by the same reference numerals and detailed description thereof will be omitted. The curved surface polishing apparatus shown in FIGS. 3 and 4 has the same structure as that of the curved surface polishing apparatus 12 of the above-mentioned embodiment except that the structure of the driving device is different.

【0035】51はベルトドライブ式駆動装置で、この
ベルトドライブ式駆動装置51は、軸線方向が工具回転
軸17と平行とされたモータ52と、このモータ52の
出力軸52aに固着されたドライブプーリ53と、工具
回転軸17に固着されたドリブンプーリ54と、これら
のプーリ53,54に巻掛けられたベルト55と、この
ベルト55の張力を調整するためのテンションプーリ5
6等とから構成されている。
Reference numeral 51 denotes a belt drive type drive device. The belt drive type drive device 51 has a motor 52 whose axial direction is parallel to the tool rotating shaft 17 and a drive pulley fixed to an output shaft 52a of the motor 52. 53, a driven pulley 54 fixed to the tool rotating shaft 17, a belt 55 wound around these pulleys 53, 54, and a tension pulley 5 for adjusting the tension of the belt 55.
It is composed of 6 mag.

【0036】このように構成されたベルトドライブ式駆
動装置51を使用すると、軸部材20が研磨ヘッド本体
23に対して上下するときにはドライブプーリ53とド
リブンプーリ54との軸間距離が変化することになる。
When the belt drive type drive device 51 thus constructed is used, the axial distance between the drive pulley 53 and the driven pulley 54 changes when the shaft member 20 moves up and down with respect to the polishing head body 23. Become.

【0037】なお、モータ52の出力軸52aと工具回
転軸17を平行にする場合の動力伝達部材としては、図
3および図4に示したようなベルト55に限定されるも
のではなく、回転速度に応じてベルト以外のものをも使
用することができる。
The power transmission member for parallelizing the output shaft 52a of the motor 52 and the tool rotation shaft 17 is not limited to the belt 55 as shown in FIGS. Other than belts can be used depending on the requirements.

【0038】さらに、上述した各実施例では研磨ヘッド
14および駆動装置15,51を4軸駆動(X軸,Y
軸,Z軸および回転A軸)させたが、軸の種類や軸数の
選択は被加工物の形状や要求精度などにより決定される
べきものであり、本実施例に限定されるものではない。
Further, in each of the above-mentioned embodiments, the polishing head 14 and the driving devices 15 and 51 are driven by four axes (X axis, Y axis).
Axis, Z axis, and rotation A axis), the selection of the type of axis and the number of axes should be determined by the shape of the workpiece, the required accuracy, etc., and is not limited to this embodiment. .

【0039】[0039]

【発明の効果】以上説明したように第1の発明に係る曲
面研磨装置は、円盤状の工具を軸心回りに回転自在に支
持しかつこの工具の外周面を被加工物の加工面に所定加
圧力をもって押し当てる研磨ヘッドと、前記工具を回転
させる駆動装置とを備え、前記研磨ヘッドに、この研磨
ヘッドを揺動させて工具の軸線を被加工物の加工点にお
ける接線と平行にする揺動装置を連結したため、円盤状
工具の外周面が加工面に押し当てられるから、工具と加
工面との接触部における相対速度が均一になる。このた
め、工具の接触面の全域にわたって加工量が等しくなる
から、単一加工痕の形状が均一になる。
As described above, the curved surface polishing apparatus according to the first aspect of the present invention supports a disk-shaped tool rotatably around its axis and sets the outer peripheral surface of the tool as a predetermined machining surface of a workpiece. A polishing head that presses with a pressing force and a drive device that rotates the tool are provided, and the swinging head causes the polishing head to swing so that the axis of the tool is parallel to the tangent line at the processing point of the workpiece. Since the moving device is connected, the outer peripheral surface of the disk-shaped tool is pressed against the machining surface, so that the relative speed at the contact portion between the tool and the machining surface becomes uniform. For this reason, since the machining amount becomes equal over the entire contact surface of the tool, the shape of the single machining mark becomes uniform.

【0040】第2の発明に係る曲面研磨装置は、前記第
1の発明の曲面研磨装置において、研磨ヘッドを、工具
支持用軸部材と、この軸部材を加圧方向に沿って移動自
在に支持すると共に加圧力を付与する研磨ヘッド本体と
によって形成し、この研磨ヘッド本体に、工具が装着さ
れた状態の軸部材の重量と同等の重量のバランサを軸部
材の移動方向と平行に移動自在に設け、このバランサで
軸部材を上方から引っ張るため、軸部材が略同重量のバ
ランサによって上方から引っ張られるので、軸部材は実
質的に無重量になる。このため、研磨ヘッドを傾斜させ
ても加工点に加わる加工圧は変化しないから、加工圧の
研磨位置による誤差が生じることがなく、加工面の全面
にわたり均等な加工圧をもって研磨を行うことができ
る。
A curved surface polishing apparatus according to a second aspect of the present invention is the curved surface polishing apparatus of the first aspect, wherein the polishing head supports a tool supporting shaft member and the shaft member so as to be movable along a pressing direction. And a polishing head body for applying a pressing force to the polishing head body, and a balancer having a weight equivalent to the weight of the shaft member with the tool mounted thereon is movable in parallel with the moving direction of the shaft member. Since the balancer is provided and the shaft member is pulled from above by the balancer, the shaft member is pulled from above by the balancer having substantially the same weight, so that the shaft member becomes substantially weightless. For this reason, since the processing pressure applied to the processing point does not change even if the polishing head is tilted, an error due to the polishing position of the processing pressure does not occur, and polishing can be performed with uniform processing pressure over the entire processing surface. .

【0041】したがって、本発明に係る曲面研磨装置に
よれば加工面の形状精度が向上するという効果がある。
Therefore, the curved surface polishing apparatus according to the present invention has the effect of improving the shape accuracy of the machined surface.

【0042】また、非球面形状の加工面を研磨する場
合、加工圧分布を均一にするために外径の小さな工具を
用いる必要が全く無く、工具外径を大きく設定すること
ができ、工具と加工面との相対速度も大きくなるから、
能率よく研磨を行うことができる。
Further, when polishing an aspherical machined surface, it is not necessary to use a tool having a small outer diameter in order to make the machining pressure distribution uniform, and the tool outer diameter can be set to a large value. Since the relative speed with the machined surface also increases,
The polishing can be performed efficiently.

【図面の簡単な説明】[Brief description of drawings]

【図1】本発明に係る曲面研磨装置の正面図である。FIG. 1 is a front view of a curved surface polishing apparatus according to the present invention.

【図2】本発明に係る曲面研磨装置の側面図である。FIG. 2 is a side view of the curved surface polishing apparatus according to the present invention.

【図3】曲面研磨装置の他の実施例を示す正面図であ
る。
FIG. 3 is a front view showing another embodiment of the curved surface polishing apparatus.

【図4】曲面研磨装置の他の実施例を示す側面図であ
る。
FIG. 4 is a side view showing another embodiment of the curved surface polishing apparatus.

【図5】従来の非球面加工機の工具部分を拡大して示す
断面図である。
FIG. 5 is an enlarged sectional view showing a tool portion of a conventional aspherical surface processing machine.

【符号の説明】[Explanation of symbols]

13 工具 14 研磨ヘッド 15 駆動装置 16 NCテーブル 20 軸部材 23 研磨ヘッド本体 24 加圧機構 25 バランサ 27 ワイヤ 13 Tool 14 Polishing Head 15 Drive Device 16 NC Table 20 Shaft Member 23 Polishing Head Main Body 24 Pressurizing Mechanism 25 Balancer 27 Wire

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 円盤状に形成された工具を軸心回りに回
転自在に支持しかつこの工具の外周面を被加工物の曲面
からなる加工面に予め定めた加圧力をもって押し当てる
研磨ヘッドと、前記工具を回転させる駆動装置とを備
え、前記研磨ヘッドに、この研磨ヘッドを揺動させて工
具の軸線を被加工物の加工点における接線と平行にする
揺動装置を連結したことを特徴とする曲面研磨装置。
1. A polishing head, which rotatably supports a disk-shaped tool around an axis and presses the outer peripheral surface of the tool against a machining surface formed of a curved surface of a workpiece with a predetermined pressing force. A drive device for rotating the tool, and a swinging device connected to the polishing head for swinging the polishing head to make the axis of the tool parallel to the tangent line at the processing point of the workpiece. Curved surface polishing equipment.
【請求項2】 請求項1記載の曲面研磨装置において、
研磨ヘッドを、工具を支持する軸部材と、この軸部材を
加圧方向に沿って移動自在に支持すると共に加圧力を付
与する研磨ヘッド本体とによって形成し、この研磨ヘッ
ド本体に、工具が装着された状態の軸部材の重量と同等
の重量のバランサを軸部材の移動軸線と平行な軸線をも
って移動自在に設け、このバランサで軸部材を上方から
引っ張ることを特徴とする曲面研磨装置。
2. The curved surface polishing apparatus according to claim 1,
The polishing head is formed by a shaft member that supports the tool, and a polishing head body that movably supports the shaft member along the pressing direction and applies a pressing force, and the tool is mounted on the polishing head body. A curved surface polishing apparatus characterized in that a balancer having a weight equivalent to the weight of the shaft member in the opened state is movably provided along an axis parallel to the moving axis of the shaft member, and the shaft member is pulled from above by the balancer.
JP27425792A 1992-10-13 1992-10-13 Curved surface polishing device Pending JPH06126607A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP27425792A JPH06126607A (en) 1992-10-13 1992-10-13 Curved surface polishing device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP27425792A JPH06126607A (en) 1992-10-13 1992-10-13 Curved surface polishing device

Publications (1)

Publication Number Publication Date
JPH06126607A true JPH06126607A (en) 1994-05-10

Family

ID=17539174

Family Applications (1)

Application Number Title Priority Date Filing Date
JP27425792A Pending JPH06126607A (en) 1992-10-13 1992-10-13 Curved surface polishing device

Country Status (1)

Country Link
JP (1) JPH06126607A (en)

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