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JPH03166083A - Wrist device for robot and industrial robot - Google Patents

Wrist device for robot and industrial robot

Info

Publication number
JPH03166083A
JPH03166083A JP30216689A JP30216689A JPH03166083A JP H03166083 A JPH03166083 A JP H03166083A JP 30216689 A JP30216689 A JP 30216689A JP 30216689 A JP30216689 A JP 30216689A JP H03166083 A JPH03166083 A JP H03166083A
Authority
JP
Japan
Prior art keywords
wrist
axis
shaft
robot
drive motor
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
JP30216689A
Other languages
Japanese (ja)
Inventor
Toshio Ogiso
敏夫 小木曽
Fujio Tajima
不二夫 田島
Ryoichi Hisatomi
久富 良一
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.)
Hitachi Ltd
Original Assignee
Hitachi Ltd
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 Hitachi Ltd filed Critical Hitachi Ltd
Priority to JP30216689A priority Critical patent/JPH03166083A/en
Publication of JPH03166083A publication Critical patent/JPH03166083A/en
Pending legal-status Critical Current

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Abstract

PURPOSE:To remarkably increase a wrist rotating rigidity, to shorten a positioning time and to improve a wrist axis motion accuracy by arranging a wrist rotating axis speed reducer at a wrist part. CONSTITUTION:A wrist axis 12 is made integral with a ball screw shaft and ball spline shaft, power transmission is performed via a belt 3 from a rotation driving motor 1 to the wrist part and the rotation power decelerated by the rotation speed reducer 6 provided at the wrist part is transmitted to an integral axis 12 via the spline bearing 8 subjected to spline fitting to the integral axis. In this case, a rotation type direction action driving motor is bound with the integral axis 12 coaxially to the rotation speed reducer output shaft, a direction driving motor rotor 9a is bound with the ball nut which screws with the integral axis 12 to drive the integral axis 12 via the ball and a direct action motion is performed.

Description

【発明の詳細な説明】 〔産業上の利用分野〕 本発明はロボットアーム端部に設置される回転・直動2
自由度を有するロボット用手首装置において,高い剛性
を有し,動作指令生成を容易とする簡素な機構を提供し
、併せて該手首機構を有する産業用ロボットを提供する
ことにある.〔従来の技術〕 従来、ロボット用手首装置としては,特開昭62− 5
4693号に記載のように、ボールネジ軸とスプライン
軸を平行配置し、直動・回転駆動モータにより各方向に
駆動し、回転減速機を手首部に設けることにより手首回
転剛性を高めたものが述べられていた. また、特開昭61−173875号に記載のように、手
首軸を1本の軸(タイル)で構成し,直動駆動モータを
クイルと同心状にアームに設置し、タイル外周ネジ部と
ボールを介して螺合する駆動ナットを回動させることに
より直動駆動し、回転駆動モータよりベルトを介して手
首軸と同心配置されているプーりに動力伝達し,タイル
外周に設けられている3列溝にボールを介して回転動力
を伝達する装置が述べられていた. さらに,特開昭64 − 71678号に記載のように
、ボールネジ軸・スプライン軸一体軸を用い、直動・回
転動作の干渉を除去するため,回転形直動駆動モータを
回転駆動モータの回転子上に設ける方法が述べられてい
た. 〔発明が解決しようとする課題〕 上記第lの従来技術は,手首回転剛性は高いものの、ボ
ールネジ軸,スプライン軸の2軸連結機構を用いて回転
・直動動作を行っているため、機構的に複雑となり、各
軸支持ハウジングにより重量が増大し、2軸連結ブラケ
ットの曲げ変形により手首直動方向の絶対位置決め精度
が悪い問題があった。
[Detailed Description of the Invention] [Industrial Application Field] The present invention is directed to a rotary/linear motion 2 installed at the end of a robot arm.
The object of the present invention is to provide a wrist device for a robot having a degree of freedom with a simple mechanism that has high rigidity and facilitates the generation of motion commands, and also to provide an industrial robot having the wrist mechanism. [Prior art] Conventionally, as a wrist device for a robot, Japanese Patent Application Laid-Open No. 62-5
As described in No. 4693, a ball screw shaft and a spline shaft are arranged in parallel, driven in each direction by a direct-acting/rotary drive motor, and a rotary reducer is installed in the wrist to increase wrist rotational rigidity. It was being done. Furthermore, as described in JP-A No. 61-173875, the wrist shaft is composed of one shaft (tile), a direct drive motor is installed on the arm concentrically with the quill, and the tile outer circumferential thread and ball Direct drive is achieved by rotating a drive nut that is threaded through the rotary drive motor, and power is transmitted from the rotary drive motor via a belt to a pulley placed concentrically with the wrist shaft. A device was described that transmitted rotational power to row grooves via balls. Furthermore, as described in Japanese Patent Application Laid-Open No. 64-71678, in order to eliminate interference between linear motion and rotational motion by using an integrated ball screw shaft and spline shaft, a rotary direct motion drive motor is connected to the rotor of the rotary drive motor. The method for installing it above was described. [Problems to be Solved by the Invention] Although the above-mentioned first prior art has high wrist rotational rigidity, it uses a two-axis coupling mechanism of a ball screw shaft and a spline shaft to perform rotational and linear motion, so it has mechanical problems. The problem was that the weight was increased by each axis support housing, and the absolute positioning accuracy in the direction of wrist translation was poor due to bending deformation of the two-axis connection bracket.

また、上記第2の従来技術は、手首機構が同心配置の軸
により構成されており、機構的には単純だが、内側と外
側に逆巻きの螺旋状鋼球転動溝が加工されている(中空
状)*動ナットにより4illlrJi干渉を除去して
いるため、駆動ナットの高精度加工・高精度組立が要求
される問題があった。
In addition, in the second conventional technology, the wrist mechanism is composed of concentrically arranged shafts, and although it is mechanically simple, reverse-wound spiral steel ball rolling grooves are machined on the inside and outside (hollow *Since the 4illlrJi interference was removed by the driving nut, there was a problem that required high-precision machining and high-precision assembly of the drive nut.

また、上記第3の従来技術は,手首機構が同心配置の軸
により構成され機構的に単純であり、特殊機械要素部品
を用いることなく軸間干渉除去を実現しているが、手首
軸までベルトを介して動力伝達をしているため、その低
剛性に起因する伝達誤差により手首軸動作精度に限界が
あるという問題があった. 本発明の目的は、手首回転剛性の高い,機構的に単純で
軽量にでき、手首軸動作精度の高いロボット用手首装置
及び該手首装置の装着された産業用ロボットを提供する
ことにある. 〔課題を解決するための手段〕 上記目的を達成するために、以下に述べる技術的手段を
採用した. (1)手首軸回転剛性を高めるために,手首軸回転減速
機を手首軸と同心配置し、手首軸回転駆動モータより手
首軸回転減速機入力軸までベルトを介してトルク伝動す
ることにより、手首回転軸高剛性化を実現した. (2)手首機構を単純化するために、手首軸として、ボ
ールネジ軸・スプライン軸一体軸を用い,手首軸に減速
機出力軸をスプライン箒合し,減速機出力軸に中空形直
接駆動モータを結合し、直接駆動モータに手首軸と螺合
するボールネジナット部を結合して構成した。
In addition, in the third conventional technology, the wrist mechanism is composed of concentrically arranged shafts and is mechanically simple, and eliminates interference between the shafts without using special mechanical components. Since power is transmitted through the wrist shaft, there is a problem in that there is a limit to the accuracy of wrist axis movement due to transmission errors caused by its low rigidity. An object of the present invention is to provide a wrist device for a robot that has high wrist rotational rigidity, is mechanically simple and lightweight, and has high accuracy in wrist axis movement, and an industrial robot equipped with the wrist device. [Means for solving the problem] In order to achieve the above objective, we adopted the technical means described below. (1) In order to increase wrist shaft rotational rigidity, the wrist shaft rotation reducer is arranged concentrically with the wrist shaft, and torque is transmitted from the wrist shaft rotation drive motor to the wrist shaft rotation reduction gear input shaft via a belt. Achieved high rigidity of the rotating shaft. (2) In order to simplify the wrist mechanism, an integrated ball screw shaft and spline shaft is used as the wrist shaft, the speed reducer output shaft is splined to the wrist shaft, and a hollow direct drive motor is attached to the speed reducer output shaft. A ball screw nut part that screws into the wrist shaft is connected to the direct drive motor.

(3)手首軸の動作精度向上のために、手首軸と同軸上
における手首軸回転駆動部と手首軸直動駆動部とを直結
し、動力伝達部材を除去することにより、動力伝達部材
の伝達誤差に起因する手首軸動作精度の劣化を小さくし
た. 〔作用〕 前述の目的を達成するための個々の技術的手段の作用に
ついて述べる. (1)手首回転軸用減速機を手首部を配置することによ
り、下記原理で高剛性化がはかられる。第3図に前記第
3の従来技術に述べられている手首回転駆動モータ1の
回転動力をモータと同軸配置されている減速機29に伝
達し、その出力をベルト32,スプライン軸受を含む回
転体31を介して手首軸12に伝達する方式の構或を示
した.また、第4図に手首回転駆動モータ1の回転動力
をベルト3を介して手首部へ伝達し、手首部に配置され
ている減速機6,スプライン軸受を介して手首軸12に
伝達する方式(前記第1の従来技術、本発明で採用)を
示した。ここで、第3図,第4図に示した手首機構の回
転剛性を比較する。ここでプーり速比は1とする。プー
りからみたベルト32,3の回転方向剛性をkθ,kθ
′、減速機回転方向剛性kr、減速機減速比n,手首回
転駆動モータのサーボ剛性無限大とした時の手首軸から
みた各各の回転剛性は下式で示される.減速機モータK
z)通常k r > kθ,kθ′,n″r5oである
ことを考慮すると、K 1 z kθ,Kzχn”kθ
′となり、kθ〉kθ′である点を考慮してもiooo
倍程度の高剛性化をはかることができ,ベルトの伝達誤
差の著しい低減と,固有振動数の向上に伴う位置決め動
作時の静定特性の改善をはかることができる. (2)本手首装置の動作原理について第4図を用いて説
明する.第4図は本発明のロボット用手首装置の動作原
理説明図である.手首回転駆動モータ1よりベルト3を
介して回転駆動される手首部減速機6出力軸は,ボール
ネジ・スプライン一体軸より成る手首軸12(ボールネ
ジ軸,スプライン軸別個に設ける場合と比して軽量化で
きる)にスプライン籍合するスプライン軸受を介して回
転動力を伝達し,手首軸12の回転動作が実現される.
また、減速機6出力軸には回転子に手首軸12と螺合す
るボールネジナット部11が結合されている手首直動駆
動モータ9が結合されており、手首直動動作が実現され
る.前記第3の従来技術の手首装置を第3図に示したが
、直動駆動モータ30が、回転駆動モータ1,減速機2
9出力軸に結合され、ベルト33.32を介して手首軸
l2を直動・回転させる構成である.本発明の手首装置
はこの従来技術と比して,ベルトが1本減って機構が単
純化され,更に、第3図ではベルト32.33の張力調
整を独立に行うためには別にアイドルプーりを設けなけ
ればならなかったが,第4図に示す本発明の手首装置で
は、ベルト3の張力調整を軸間距離の調整のみで行うこ
とができ、機構的に単純化され,軽量化をはかることが
できる. (3)本手首装置は、手首回転駆動モーター,手首直動
駆動モータ9がnθ4,θ8(n:減速機6減速比)回
転時に、手首軸が角度θ番回転し、ボールネジナット部
が(θ8+04)一〇番=03P 軸間干渉は除去される.ここで、ベルト3でΔθ番の角
度伝達誤差が生じた場合は、手首軸n り、ベルトの伝達誤差が,手首軸動作精度に大きい影響
を与えない.一方、第3の従来技術では、ベルト33.
32でΔθ8,Δθ番の角度伝達誤差を生じた場合、手
首軸回転角誤差:P となり、ベルトの角度伝達誤差が軸間干渉して動作精度
の劣化(Δθ8,Δθ番は各軸回転方向により異符号に
なることもある)をまねく問題がある.以上から,本発
明の手首装置は、減速機を手首部に配置した事及びベル
トを1本にしたことにより、ベルトの伝達誤差による手
首軸動作精度の劣化を小さくできる。
(3) In order to improve the movement accuracy of the wrist shaft, the wrist shaft rotation drive unit and wrist shaft direct drive unit on the same axis as the wrist shaft are directly connected, and the power transmission member is removed, thereby transmitting the power transmission member. Reduced deterioration in wrist axis movement accuracy due to errors. [Effects] We will discuss the effects of individual technical means to achieve the above objectives. (1) By arranging the wrist rotating shaft reducer at the wrist, high rigidity can be achieved based on the following principle. In FIG. 3, the rotational power of the wrist rotation drive motor 1 described in the third prior art is transmitted to a reducer 29 coaxially arranged with the motor, and the output is transmitted to a rotating body including a belt 32 and a spline bearing. 31 to the wrist shaft 12. FIG. 4 shows a system in which the rotational power of the wrist rotation drive motor 1 is transmitted to the wrist via the belt 3, and transmitted to the wrist shaft 12 via the reducer 6 and spline bearing disposed in the wrist. The above-mentioned first prior art (adopted in the present invention) is shown. Here, the rotational rigidity of the wrist mechanisms shown in FIGS. 3 and 4 will be compared. Here, the pulley speed ratio is assumed to be 1. The rotational direction rigidity of the belts 32, 3 seen from the pulley is kθ, kθ
', the rotational direction rigidity of the reducer kr, the reduction gear reduction ratio n, and the servo rigidity of the wrist rotation drive motor as infinite, the rotational rigidity of each as seen from the wrist axis is expressed by the following formula. Reducer motor K
z) Considering that normally k r > kθ, kθ′, n″r5o, K 1 z kθ, Kzχn″kθ
′, and considering that kθ〉kθ′, iooo
It is possible to increase the rigidity by about twice as much, significantly reduce belt transmission errors, and improve static stability during positioning operations by increasing the natural frequency. (2) The operating principle of this wrist device will be explained using Fig. 4. FIG. 4 is an explanatory diagram of the operating principle of the robot wrist device of the present invention. The output shaft of the wrist reducer 6 is rotationally driven by the wrist rotation drive motor 1 via the belt 3, and the wrist shaft 12 is composed of a ball screw and spline integrated shaft (lighter than when the ball screw shaft and spline shaft are provided separately). Rotational power is transmitted through a spline bearing connected to the spline (which can be used), and the rotational movement of the wrist shaft 12 is realized.
Further, a wrist direct drive motor 9 whose rotor is coupled to a ball screw nut portion 11 which is threadedly engaged with a wrist shaft 12 is connected to the output shaft of the reducer 6, thereby realizing wrist direct drive motion. The wrist device of the third prior art is shown in FIG.
9 output shaft, and linearly moves and rotates the wrist shaft l2 via belts 33 and 32. Compared to this prior art, the wrist device of the present invention has one less belt and has a simpler mechanism.Furthermore, as shown in FIG. However, in the wrist device of the present invention shown in FIG. 4, the tension of the belt 3 can be adjusted only by adjusting the distance between the axes, which simplifies the mechanism and reduces weight. be able to. (3) In this wrist device, when the wrist rotation drive motor and the wrist direct drive motor 9 rotate by nθ4, θ8 (n: reduction ratio of reducer 6), the wrist shaft rotates by an angle θ, and the ball screw nut part rotates by (θ8+04). ) No. 10 = 03P Inter-axis interference is removed. Here, if an angle transmission error of Δθ occurs in belt 3, the transmission error of the belt will not have a large effect on the wrist axis movement accuracy. On the other hand, in the third prior art, the belt 33.
When an angle transmission error of Δθ8 and Δθ occurs in 32, the wrist axis rotation angle error becomes P, and the belt's angle transmission error interferes between the axes, resulting in deterioration of operational accuracy (Δθ8 and Δθ depend on the rotation direction of each axis. There is a problem that leads to the difference in sign. From the above, in the wrist device of the present invention, by arranging the speed reducer at the wrist and using only one belt, it is possible to reduce deterioration in wrist axis movement accuracy due to belt transmission errors.

〔実施例〕〔Example〕

本発明の実施例を第1図及び第2図を用いて説明する.
第1図は本発明のロボット用手首装置の縦断面図であり
、第2図は、第1図のロボット用手首装置を具備する水
平多関節形直接駆動ロボットの構或図を示している。ま
ず第2図を用いて本発明で対象とする手首装置を具備す
る産業用ロボットの構成とその動作について説明する.
本ロボットは水平面内で高速動作が可能で、水平方向の
剛性を可変とできる組立作業に適するタイプのロボット
である.ベースに設けられた1軸用直接駆動モータ21
は第1アーム22を矢印25に示すように回転駆動し、
第1アーム22先端に設けられた2軸用直接駆動モータ
23は第2アーム24を矢印26に示すように回転駆動
し,第2アーム24先端には、下端に作業用工具20の
取り付けられた手首軸l2が設けられており、上下方向
移動(矢印27)と回転動作(矢印28)を行う。
An embodiment of the present invention will be explained using FIGS. 1 and 2.
FIG. 1 is a longitudinal sectional view of the robot wrist device of the present invention, and FIG. 2 is a diagram showing the structure of a horizontal multi-joint direct drive robot equipped with the robot wrist device of FIG. First, the configuration and operation of an industrial robot equipped with a wrist device, which is the object of the present invention, will be explained using Fig. 2.
This robot is a type of robot that can operate at high speed in the horizontal plane and has variable horizontal rigidity, making it suitable for assembly work. Single-axis direct drive motor 21 installed on the base
rotates the first arm 22 as shown by the arrow 25,
A two-axis direct drive motor 23 provided at the tip of the first arm 22 rotates the second arm 24 as shown by an arrow 26, and a working tool 20 is attached to the bottom end of the second arm 24. A wrist shaft l2 is provided, and performs vertical movement (arrow 27) and rotational movement (arrow 28).

手首軸12の上下方向,回転方向動作を行う手首軸駆動
機構34がロボットアーム中に設けられている.工具2
0の3次元空間内における位置決めは、l軸,2軸用直
接駆動モータ21,23及び手首軸12上下方向駆動モ
ータにより行われ,姿勢決めは、手首軸12の軸まわり
回転姿勢のみ手首軸12回転方向駆動モータにより行わ
れる.アーム駆動用に直接駆動モータを用いたロボット
は低剛性な減速機を介さず直接アームに動力を伝達する
ため、軸の回転剛性を高くとることができ,かつ直接駆
動モータ制御回路の定数変更により剛性可変とできる利
点がある.このようなロボットにおいて手首装置に望ま
れることは、軽量であり,高剛性であることである.こ
れは各々アームの加減速時間の短縮、ロボット全体とし
ての動作精度の向上につながる技術項目である. これらの要求を満たすロボット用手首装置の機構を第1
図を用いて説明する.本手首装置は、(作用)の項にお
いても述べたように軽量化のためにボールネジ軸・スプ
ライン軸一体軸を用い、高剛性化のために減速機手首部
配置方式と、手首直動駆動モータの手首部設置減速機出
力軸直結方式を用いた.手首直動駆動モータの手首部設
置減速機出力軸直結方式は従来用いられていない新規な
方式である. 第1図において、手首回転駆動系は以下のように構成さ
れている.ロボットアーム5と連結されている支え板1
9に設置された手首回転駆動モータ1の回転が、プーり
2,ベルト3,プーり4を介して減速機6の入力軸に伝
達され、その出力軸から取り出された回転動力が手首軸
12(ボールネジ軸・スプライン軸一体軸)にスプライ
ン符合しているスプライン軸受8とスプライン軸受とキ
ー結合されているスプライン軸受付部材7を介して伝達
され,手首軸12が回転する.ここで、プーり2,4の
速比が1であれば減速比は減速機6の減速比で決まり、
プーリ速比lでない場合は減速機6の減速比とプーり速
比の積でモータからの減速比が定まる. 次に、手首上下駆動系について述べる.本発明では、手
首回転駆動系との干渉を避けるたる,減速機出力軸後段
に手首上下駆動系を設ける構或にした.スプライン軸受
取付部材7と結合された直動NljJモータハウジング
35には内筒回転子形直接駆動モータ9が設置されてい
る.モータ9は例えばモータ固定子9bにはコイルが巻
回されており,モータ固定子9bに軸受を介して支持さ
れているモータ回転子9aには永久磁石が設けられてお
り,コイルに通電することにより磁気作用により、モー
タ回転子9aがモータ固定子9bに対して相対的に回転
する.モータ回転子9aは中空構造となっており、手首
軸12と内面が螺合するプーり11と結合されており,
直動駆動モータ9の回転により,手首軸12は上下方向
に直動動作を行う.直動駆動モータ9は通常最高300
Orpm程度まで回転する高速回転形直接駆動モータで
あリ,手首軸12のネジリードP=20(am)の場合
、手首軸は最高1−で直動動作を行う。
A wrist shaft drive mechanism 34 that moves the wrist shaft 12 in the vertical and rotational directions is provided in the robot arm. Tool 2
0 in the three-dimensional space is performed by the direct drive motors 21 and 23 for the l-axis and 2-axis and the vertical drive motor for the wrist shaft 12, and the posture is determined only by rotating the wrist shaft 12 around the axis. This is done by a rotational direction drive motor. Robots that use a direct drive motor to drive the arm transmit power directly to the arm without going through a low-rigidity reducer, so the rotational rigidity of the axis can be increased, and by changing the constants of the direct drive motor control circuit. It has the advantage of being able to have variable rigidity. What is desired for the wrist device in such a robot is that it be lightweight and have high rigidity. This is a technical item that reduces the acceleration/deceleration time of each arm and improves the movement accuracy of the robot as a whole. The first mechanism for a robot wrist device that meets these requirements is
Explain using a diagram. As mentioned in the (Function) section, this wrist device uses an integrated ball screw shaft and spline shaft to reduce weight, and uses a reduction gear wrist arrangement method and wrist direct drive motor to increase rigidity. The wrist-mounted reducer is directly connected to the output shaft. The wrist direct drive motor's wrist-mounted reducer output shaft direct connection method is a new method that has not been used previously. In Figure 1, the wrist rotation drive system is configured as follows. Support plate 1 connected to robot arm 5
The rotation of the wrist rotation drive motor 1 installed at the wrist shaft 12 is transmitted to the input shaft of the reducer 6 via the pulley 2, belt 3, and pulley 4, and the rotational power taken out from the output shaft is transmitted to the wrist shaft 12. The rotation of the wrist shaft 12 is transmitted through the spline bearing 8 whose splines are aligned with the ball screw shaft/spline shaft (integrated shaft of the spline shaft) and the spline bearing member 7 which is key-coupled to the spline bearing. Here, if the speed ratio of pulleys 2 and 4 is 1, the reduction ratio is determined by the reduction ratio of reducer 6,
If the pulley speed ratio is not l, the reduction ratio from the motor is determined by the product of the reduction ratio of the reducer 6 and the pulley speed ratio. Next, we will discuss the wrist vertical drive system. In the present invention, in order to avoid interference with the wrist rotation drive system, a wrist vertical drive system is provided after the output shaft of the reducer. An internal cylinder rotor type direct drive motor 9 is installed in the direct drive NljJ motor housing 35 which is connected to the spline bearing mounting member 7. In the motor 9, for example, a coil is wound around a motor stator 9b, and a permanent magnet is provided on a motor rotor 9a supported by the motor stator 9b via a bearing, and the coil cannot be energized. Due to the magnetic effect, the motor rotor 9a rotates relative to the motor stator 9b. The motor rotor 9a has a hollow structure, and is connected to a pulley 11 whose inner surface is threadedly engaged with the wrist shaft 12.
The rotation of the direct drive motor 9 causes the wrist shaft 12 to perform direct motion in the vertical direction. Direct drive motor 9 usually has a maximum of 300
It is a high-speed rotation type direct drive motor that rotates up to about 100 rpm, and when the screw lead P of the wrist shaft 12 is 20 (am), the wrist shaft performs direct motion at a maximum of 1-.

S このような構造とすることにより、軸間干渉の除去がは
かられ,軽量・高剛性の手首装置が実現できる。以下述
べた駆動系の駆動制御に当ってはモータ1,9に直結さ
れた位置検出器18.10検出データと回転・上下方向
の移動量データθ番,? π ■ΔZ(=08)(ΔZ:上下方向移動距離)のP 偏差をもとにモータ1,9のトルク指令が生或・出力さ
れる.また、上下軸は、重負荷時には直動駆動モータ9
のパワーオフ時に滑落し、位置ずれを起こすため、メカ
ニカルブレーキ(例えば無励磁作動形)を装着する必要
がある,しかるに、直動駆動モータ9と同軸上に設ける
と、ロボットエ,2軸駆動モータの負荷イナーシャが増
大するため、図示のようにボールネジナット部(プーリ
)11,ベルト13,プーり14を介して回転ディスク
17,静止ディスク16,アクチュエータ・バネ15よ
りなるメカニカルブレーキで位置保持を行うことにより
ロボット1.2軸駆動モータの負荷イナーシャの増大を
防ぐことができる.このメカニカルブレーキはバワーオ
フ時はバネ力で静止ディスク16と回転ディスク17が
接触し,摩擦により制動トルクを発生し,バワーオン時
には静止ディスクl6が下方に移動し、回転ディスク1
7がフリー状態となり回転可能となるという作動原理で
ある。また、プーり11・プーり14間で増速比3程度
とすることによりベルトの巻き角も十分とれ、モータ9
発生トルクの1/3の制動トルクで手首軸12の滑落を
抑止することが可能になり、メカニカルブレーキの小容
量・軽量化がはかれる。また、本構成の制動装置は特願
昭63−87729号中において本出願人よりその効果
を詳述した.メカニカルブレーキ及び手首回転駆動モー
タ1は第2アーム26中で2軸用直接駆動モータ25近
傍もしくは2軸用直接駆動モータ25に対して手首部l
2と反対側に設けることにより、1軸用直接駆動モータ
の負荷イナーシャを軽減でき、ロボットの加減速時間を
短縮できる利点がある。
S By adopting such a structure, interference between axes can be eliminated, and a lightweight and highly rigid wrist device can be realized. In the drive control of the drive system described below, the position detectors 18 and 10 directly connected to the motors 1 and 9 detect data and rotational/vertical movement amount data θ, ? Torque commands for motors 1 and 9 are generated/output based on the P deviation of π ■ΔZ (=08) (ΔZ: vertical movement distance). In addition, when the vertical axis is under heavy load, the direct drive motor 9
Because the robot slides down when the power is turned off, causing positional deviation, it is necessary to install a mechanical brake (for example, a non-excitation type). However, if it is installed coaxially with the direct drive motor 9, the robot As the load inertia increases, the position is maintained by a mechanical brake consisting of a rotating disc 17, a stationary disc 16, and an actuator spring 15 via a ball screw nut (pulley) 11, belt 13, and pulley 14 as shown in the figure. This can prevent the load inertia of the robot's 1.2-axis drive motor from increasing. In this mechanical brake, when the power is off, the stationary disk 16 and the rotating disk 17 come into contact with each other due to the spring force, and braking torque is generated by friction, and when the power is on, the stationary disk 16 moves downward and the rotating disk 1
7 is in a free state and can rotate. In addition, by setting the speed increasing ratio to about 3 between pulley 11 and pulley 14, the belt wrap angle can be set sufficiently, and the motor 9
It becomes possible to prevent the wrist shaft 12 from slipping off with a braking torque that is 1/3 of the generated torque, and the capacity and weight of the mechanical brake can be reduced. Furthermore, the effect of the braking device having this configuration was detailed in Japanese Patent Application No. 87729/1983 by the present applicant. The mechanical brake and wrist rotation drive motor 1 is located near the two-axis direct drive motor 25 in the second arm 26 or at the wrist l with respect to the two-axis direct drive motor 25.
By providing it on the side opposite to 2, the load inertia of the single-axis direct drive motor can be reduced, and there is an advantage that the acceleration/deceleration time of the robot can be shortened.

〔発明の効果〕〔Effect of the invention〕

本発明は、以上説明したように構威されているので以下
に記載されるような効果を奏する。
Since the present invention is structured as described above, it produces the effects described below.

(1)手首回転軸用減速機を手首部に配置したため、手
首回転剛性を著しく高めることができ、位置決め時間の
短縮、手首軸動作精度の向上をはかることができる。
(1) Since the reduction gear for the wrist rotation axis is placed in the wrist, the rotational rigidity of the wrist can be significantly increased, the positioning time can be shortened, and the accuracy of wrist axis movement can be improved.

(2)手首軸としてボールネジ軸・゛スプライン軸一体
軸を用いて手首装置を構成することにより、手首機構を
単純にすることができ、軽量化をはかることができるの
で、ロボットアーム駆動モータの負荷イナーシャを低減
でき、加減速時間を短縮できる. (3)手首部回転減速機出力軸と手首直動駆動モータを
直結することにより,ベルトの低剛性に起因する位置伝
達誤差が低減され、手首軸の動作精度を向上させること
ができる。
(2) By configuring the wrist device using an integrated ball screw shaft and spline shaft as the wrist shaft, the wrist mechanism can be simplified and the weight can be reduced, so the load on the robot arm drive motor can be reduced. Inertia can be reduced and acceleration/deceleration time can be shortened. (3) By directly connecting the wrist rotary reducer output shaft to the wrist direct drive motor, position transmission errors caused by low belt rigidity can be reduced and the operational accuracy of the wrist shaft can be improved.

【図面の簡単な説明】[Brief explanation of the drawing]

第1図は本発明のロボット用手首装置の縦断面図,第2
図は第l図のロボット用手首装置を具備する水平多関節
形直接駆動ロボットの構或図、第3図は従来技術のロボ
ット用手首装置の動作原理説明図,第4図は本発明のロ
ボット用手首装置の動作原理説明図である。 l・・・手首回転邸動モータ、2,4,14.31・・
・プーリ、3,13,32.33・・・ベルト、5・・
・ロボットアーム、6,29・・・減速機,7・・・ス
プライン軸受取付部材、8・・・スプライン軸受、9,
30・・・手首直動駆動モータ、10,18・・・位置
検出器,1工・・・ボールネジナット部,12・・・手
首軸(ボールネジ・スプライン一体軸)、工5・・・ア
クチュエータ・バネ、16・・・静止ディスク.17・
・・回転ディスク,19・・・支え板.20・・・工具
、21・・・1軸用直接駆動モータ、22・・・第1ア
ーム、23・・・2軸用直接駆動モータ、24・・・第
2アーム、25,26,27,28・・・各軸動作方向
,34・・・手首軸案 図
Fig. 1 is a longitudinal sectional view of the robot wrist device of the present invention, Fig.
The figure shows the structure of a horizontal multi-joint direct drive robot equipped with the robot wrist device shown in FIG. 1, FIG. It is an explanatory diagram of the operating principle of the wrist device. l...Wrist rotation motor, 2, 4, 14.31...
・Pulley, 3, 13, 32. 33...Belt, 5...
・Robot arm, 6, 29...Reducer, 7...Spline bearing mounting member, 8...Spline bearing, 9,
30... Wrist direct drive motor, 10, 18... Position detector, 1 work... Ball screw nut section, 12... Wrist shaft (ball screw/spline integral shaft), Work 5... Actuator. Spring, 16...stationary disk. 17・
... Rotating disk, 19... Support plate. 20... Tool, 21... 1-axis direct drive motor, 22... 1st arm, 23... 2-axis direct drive motor, 24... 2nd arm, 25, 26, 27, 28...Each axis movement direction, 34...Wrist axis plan

Claims (1)

【特許請求の範囲】 1、ロボットアームの端部に取り付けられた工具の直動
及び回転動作を自在とするロボット用手首装置において
、手首軸をボールネジ軸・ボールスプライン軸一体軸に
より構成し、回転駆動モータより手首部までベルトを介
して動力伝達を行い、手首部に設けられた回転減速機に
より減速した回転動力が前記一体軸とスプライン符合す
るスプライン軸受を介して前記一体軸に伝達され、前記
回転減速機出力軸に前記一体軸と同心に回転形直動駆動
モータが結合され、直動駆動モータ回転子を前記一体軸
と螺合するボールナットに結合し、ボールを介して前記
一体軸を駆動し、直動動作を行うことを特徴とするロボ
ット用手首装置。 2、特許請求範囲第1項記載のロボット用手首装置にお
いて、直動駆動モータロータと直結されたボールネジナ
ット部より他の回転軸へベルトを介して増速動力伝達を
行い、前記他の回転軸と同軸上にその回転を制動可能な
メカニカルブレーキを設けたことを特徴とするロボット
用手首装置。 3、ベースに垂直な軸まわりに回転駆動される第1アー
ムと、第1アーム先端の軸まわりに回転駆動される第2
アームとからなる産業用ロボットにおいて、特許請求範
囲第1項または第2項記載の手首軸を前記第2アーム先
端に設け、その駆動機構をその周辺部に設けたことを特
徴とする産業用ロボット。
[Claims] 1. In a wrist device for a robot that allows free translational and rotational movement of a tool attached to the end of a robot arm, the wrist axis is composed of an integrated ball screw axis and ball spline axis, and the rotation Power is transmitted from the drive motor to the wrist via a belt, and the rotational power reduced by a rotary reducer provided at the wrist is transmitted to the integral shaft via a spline bearing that is aligned with the spline of the integral shaft. A rotary direct drive motor is coupled to the output shaft of the rotary reducer concentrically with the integral shaft, and the direct drive motor rotor is coupled to a ball nut that is threaded onto the integral shaft, and the integral shaft is connected to the rotary reducer through a ball. A wrist device for a robot that is driven and performs linear motion. 2. In the wrist device for a robot according to claim 1, speed-up power is transmitted from a ball screw nut directly connected to the direct drive motor rotor to another rotating shaft via a belt, and A wrist device for a robot characterized by having a mechanical brake coaxially provided that can brake its rotation. 3. A first arm that is rotationally driven around an axis perpendicular to the base, and a second arm that is rotationally driven around an axis at the tip of the first arm.
An industrial robot comprising an arm, characterized in that the wrist shaft according to claim 1 or 2 is provided at the tip of the second arm, and a drive mechanism thereof is provided in the periphery thereof. .
JP30216689A 1989-11-22 1989-11-22 Wrist device for robot and industrial robot Pending JPH03166083A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP30216689A JPH03166083A (en) 1989-11-22 1989-11-22 Wrist device for robot and industrial robot

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP30216689A JPH03166083A (en) 1989-11-22 1989-11-22 Wrist device for robot and industrial robot

Publications (1)

Publication Number Publication Date
JPH03166083A true JPH03166083A (en) 1991-07-18

Family

ID=17905719

Family Applications (1)

Application Number Title Priority Date Filing Date
JP30216689A Pending JPH03166083A (en) 1989-11-22 1989-11-22 Wrist device for robot and industrial robot

Country Status (1)

Country Link
JP (1) JPH03166083A (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103624794A (en) * 2013-04-27 2014-03-12 张家港诺信自动化设备有限公司 Scara robot
CN103934825A (en) * 2014-02-18 2014-07-23 威海正棋机电技术有限公司 Horizontal joint robot
CN106391635A (en) * 2016-12-09 2017-02-15 无锡银联齿轮传动机械有限公司 Rotation driving mechanism of small-piece cleaning machine
CN110103211A (en) * 2019-06-06 2019-08-09 深圳市秘银科技有限公司 A kind of manipulator

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103624794A (en) * 2013-04-27 2014-03-12 张家港诺信自动化设备有限公司 Scara robot
CN103934825A (en) * 2014-02-18 2014-07-23 威海正棋机电技术有限公司 Horizontal joint robot
CN106391635A (en) * 2016-12-09 2017-02-15 无锡银联齿轮传动机械有限公司 Rotation driving mechanism of small-piece cleaning machine
CN110103211A (en) * 2019-06-06 2019-08-09 深圳市秘银科技有限公司 A kind of manipulator

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