CN2447131Y - Open-type control platform for industrial robot - Google Patents
Open-type control platform for industrial robot Download PDFInfo
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- CN2447131Y CN2447131Y CN 00254080 CN00254080U CN2447131Y CN 2447131 Y CN2447131 Y CN 2447131Y CN 00254080 CN00254080 CN 00254080 CN 00254080 U CN00254080 U CN 00254080U CN 2447131 Y CN2447131 Y CN 2447131Y
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Abstract
The utility model relates to an open control platform for an industrial robot, and belongs to a universal control system for an industrial robot. The utility model is characterized in that a universal industrial computer is introduced in the traditional robot control system, and a unique open and modularized structure is used. The original controller with a closed structure is extended into a control platform with an open structure. Serving as a control system of a robot, the utility model controls various servos and flexibly controls an industrial robot. The functions are conveniently increased, so that the exiting robot production is made to be further suitable for the requirements of small orders and diversities in the modernized industrial production.
Description
The utility model belongs to the general-purpose industrial robot control system.Its outstanding feature is that the general-purpose industrial computer is introduced in traditional robot control system, and adopts unique open and modular construction, the controller of original structure sealing is expanded to the control platform of structure opening.
Traditional industry robot controller (CONTROLLER) lacks only property, ROBOT CONTROL device and manipulator (MANIPULATOR) are one, Figure 1 shows that the Typical Disposition of traditional robot control system, R1 is an industrial robot, A1 is a controller, the inside is integrated with special-purpose computer and some other electric equipment of servo bag, structure sealing, controller wherein generally can only be suitable for the fixing a kind of servo bag of a certain model, drag a certain specific servomotor, sort controller generally also can only be applicable to a kind of particular machines people.The function of controller depends on required finishing of the task of robot, and the used parameter of servo and planning algorithm of controller is all directly from body: low layer position servo algorithm will customize according to the servomotor of manipulator and the characteristic of servo amplifier, and the upper strata planning procedure will be worked out according to parameters such as the mechanism of manipulator, sizes.
If job task and manipulating object are all fixed, so this closed robot controller has simply, advantage reliably and efficiently.But along with expanding economy, people are more and more higher to the diversified requirement of product.Make already by original task and the operation of the relatively-stationary large-scale pipeline formula of object, to the flexible manufacturing (FM) and computer integrated manufacturing system (CIM) mode development of task and the frequent middle and small scale that changes of object.The task that this industrial robot that just requires to take in the system manufacturing system formerly fresh combatants can be competent at continuous variation, i.e. function flexibilityization.In the purchase stage of robot, the user of robot can not to future production task variation consider comprehensively.In case new task is not included in the existing ROBOT CONTROL function, the controller robot that has enclosed construction so just has no purposes like this.In addition, the configuration of original robot control system as shown in Figure 1, wherein the model of the R1 of robot is fixed.
The purpose of this utility model is as follows: if the function of robot can be expanded, through the function expansion of controller, original robot just can put in the new production task and go.And if the function of controller has expandability, it is open just needing controller.Make robot have flexibility, controller also must be open.In addition, the utility model is controlled polytype servo bag as a kind of control system of robot, controls industrial robot more neatly, increase its function more easily, make existing robots produce the requirement that further adapts to the many kinds of modern industry production small lot.
Technical essential of the present utility model is as shown in Figure 2: I1 is the general-purpose industrial computer, and A2 is a switch board, and servo bag and main frame are installed in wherein, and R2 is an industrial robot.With different be of Fig. 1 in configuration: increased external industrial computer, made the user can be according to own actual needs establishment and modification control program, the model of the R2 of robot among Fig. 2 can be selected for use flexibly.
Technological core of the present utility model is to realize the control of a kind of controller to multiple servo bag by industrial computer and some interface boards.Fig. 3 is concrete connection diagram, C1 is multi-axis motion controller PMAC2-PCR (being called for short PMAC) among the figure, it can be inserted on the slot of the isa bus on the industrial computer, C2 and C3 are YASKAWA absolute encoder converter ACC-8D-OPTION9, C4 is Signal Matching converter ACC-8E, and C5 also is Signal Matching converter ACC-8F; S1 is respectively the different servo bags of two classes with S2, and S1 is the imported servo bag of voltage signal, and input voltage is 0-6V, and S2 is the imported servo bag of PWM, is input as the PWM ripple; M1 and M2 are servomotor, and E1 and E2 are respectively the code-disc signal output unit (ENCODER) of M1 and M2.
The operation principle of Fig. 3 is as follows:
Send voltage control signal by operating in the control program of working out on the industrial computer, send C4 to by the JMAC2 interface on the C1, send servo bag S1 by C4 to through amplifying again, and then the driving pulse of formation servomotor M1, computer is also controlled PMAC and is produced another road pwm signal in addition, and pass to interface board C5 by JMAC4, and export to the servo bag S2 that needs the PWM input signal by the P5 port of C5 again, the driving signal of servomotor M2 is just from S2.
Robot control system also needs the variation of the position in each joint of definite robot in addition, and this signal is to produce by the code-disc that is installed on the servomotor, because servo bag is inequality, so the pipeline of code-disc signal also is different.The code-disc signal of the M1 that is produced by E1 is given S1 earlier, and EO (ENCODE OUTPUT) port by S1 passes to absolute encoder converter C2 again, and C2 is converted to the increment code wheel signal with the absolute encoder signal, and absolute encoder signal and increment code wheel signal are all passed PMAC back; And the code-disc signal of M2 is to be directly passed to C3 after being produced by E2, and the signal of C3 produces absolute signal and increment signal respectively through C2 and C5 again, and finally is aggregated into PMAC by JMAC1 on the PMAC and JMAC4.Computer has just obtained the code-disc signal of two kinds of servomotors like this, just can understand these code-disc signals by computer program, to determine the position and the motion state in each joint of robot.
By the connection of above circuit, just can realize easily providing control signal, and can understand the code-disc signal of two kinds of different servo motors to two kinds of different servo bags, can control this two classes servomotor very neatly.In like manner also can expand to the control of many servomotors.
The major advantage of the robot controlling platform that the utility model proposes is as follows:,, a cover control system can be controlled many servo bags simultaneously; Owing to adopted complete open structure, the user can carry out secondary development according to technological requirement on the basis of this control system, finish the not available task of some original systems; Because industrial computer has been introduced in the ROBOT CONTROL system, the user is the manipulation robot more neatly, carries out teaching and reproduces, and have very friendly man-machine interface; This cover control system can realize at most the controls of 8 motions are compared with 6 axis controllers that present industrial robot generally uses, and has higher control accuracy and application widely; Because robot body, servo bag, motion controller and industrial computer among the present invention all adopt modularized design, therefore can freely make up according to actual needs, widened the application of robot control system.
Description of drawings:
Fig. 1 is the configuration connection layout of traditional industrial robot control system;
Fig. 2 is the configuration connection layout of this robot controlling platform;
Fig. 3 is the connection layout by two types of servo bags of Industrial Computer Control;
Fig. 4 is the structured flowchart of six axle servo control systems of robot among the embodiment;
Embodiment:
This control platform has been realized control to two kinds of servo bags by circuit as shown in Figure 3, the structured flowchart of the industrial robot control system that utilization the method is formed as shown in Figure 4, industrial computer can adopt ADVANTECH-610 among the figure, also can adopt YASKAWA MOTOMAN SK10 robot body as the control object, two kinds of servo bags adopt four YASKAWA CACR-SR15SZ1SD-Y214 type single shafts to drive servo bag and four servo bags of driving of a DELTA TAU respectively, the Y214 type is the servo bag of voltage-controlled type, the S that is used for the driven machine people, L, four joints of U and R, DELTA TAU is the servo bag of PWM ripple control type, is used for B and two joints of T of driven machine people wrist.
Industrial computer produces control signal by PMAC, passes to four CACR-SR15SZ1SD-Y214 single shafts again after the amplification through two interface board ACC-8ED and drives servo bag, the servomotor in control S, L, U and four joints of R.And the driving signal of the servomotor of two other B and T passes to four servo bag DELTA TAU of driving by ACC-8F after being produced by PMAC.
The code-disc signal of the servomotor in S, L, U and four joints of R all is to be delivered to ACC-8D by servo bag earlier, and the absolute encoder signal is converted to the increment code wheel signal, passes PMAC back by ACC-8E again; And the code-disc signal of the servomotor of B and T is directly to be sent to another piece ACC-8D, divide two-way to pass PMAC back again, can determine the joint angle and the motion state in 6 joints of SK10 robot by the program of on industrial computer, moving very accurately by ACC-8E and ACC-8F.
By control program, can control the motion of SK10 robot under joint coordinates, Cartesian coordinate, tool coordinates and User Defined coordinate, can finish the motion of straight line, circular arc and various SPLs.This cover robot controlling platform not only can be controlled robot and finish the various work that present general-purpose industrial robot is possessed, but also can further develop on its basis, realizes new function.
The utility model has replaced computer special-purpose in conventional machines people's controller with general opened industrial computer, make the user not only can control robot according to the conventional method, and can adjust and change the job task of robot neatly, even can on open computer platform, construct the new adaptation upper strata control software of different production requirements separately by computer.Therefore can improve the user to the ROBOT CONTROL ability easily for robot increases the function that does not possess when some dispatch from the factory.This creation improves its control accuracy for the function that increases industrial robot, expands the application of robot in industrial production and has important effect.
Claims (2)
1. opened industrial robot controlling platform that constitutes by general-purpose industrial computer, controller, converter, servo bag, servomotor, it is characterized in that: multi-axis controller C1 can be inserted on the slot of the isa bus on the industrial computer, multi-axis controller C1 interface is connected with Signal Matching converter C4, Signal Matching converter C4 is connected with servo bag S1 through amplifying, and servo bag S1 is connected to form driving pulse with servomotor M1 again; Servomotor M1 is connected with servo bag S1 by code-disc signal conversion unit E1 again; Servo bag S1 is connected with absolute encoder converter C2 by the EO port; Absolute encoder converter C2 also respectively with multi-axis controller C1, another absolute encoder converter C3, Signal Matching converter C4 connects; Absolute encoder converter C3 connecting interface plate C5, interface board C5 connects servo bag S2, and servo bag S2 connects servomotor M2, and servomotor M2 is connected with absolute encoder converter C3 by code-disc signal output unit E2; Interface board C5 also is connected with multi-axis controller C1.
2. according to the described opened industrial robot controlling platform of claim, it is characterized in that: industrial computer is connected with multi-axis controller with slot by isa bus, multi-axis controller is connected with a plurality of interface boards again, corresponding with the absolute encoder converter respectively again connection of interface board; Each interface board can connect a pair of servo bag, realizes the control of a kind of controller to multiple servo bag; Servo Bao Yiyu absolute encoder converter connects, and servo bag is connected with servomotor, and servomotor also can be connected the back with the absolute encoder converter and be connected with multi-axis controller.
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CN 00254080 CN2447131Y (en) | 2000-09-30 | 2000-09-30 | Open-type control platform for industrial robot |
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CN 00254080 CN2447131Y (en) | 2000-09-30 | 2000-09-30 | Open-type control platform for industrial robot |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102520665A (en) * | 2011-12-23 | 2012-06-27 | 中国科学院自动化研究所 | Open robot demonstration device and robot control system |
CN103025491A (en) * | 2010-05-14 | 2013-04-03 | 史陶比尔法万举 | Method for controlling an automated work cell |
WO2013131457A1 (en) * | 2012-03-08 | 2013-09-12 | 南京埃斯顿机器人工程有限公司 | Dual-system assembly type industrial robot controller |
CN103429399A (en) * | 2011-01-21 | 2013-12-04 | Abb股份公司 | System for commanding a robot |
-
2000
- 2000-09-30 CN CN 00254080 patent/CN2447131Y/en not_active Expired - Lifetime
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103025491A (en) * | 2010-05-14 | 2013-04-03 | 史陶比尔法万举 | Method for controlling an automated work cell |
US8965574B2 (en) | 2010-05-14 | 2015-02-24 | Staubli Faverges | Method for controlling an automated work cell |
CN103025491B (en) * | 2010-05-14 | 2016-02-24 | 史陶比尔法万举 | The method of auto-control working cell |
CN103429399A (en) * | 2011-01-21 | 2013-12-04 | Abb股份公司 | System for commanding a robot |
CN102520665A (en) * | 2011-12-23 | 2012-06-27 | 中国科学院自动化研究所 | Open robot demonstration device and robot control system |
WO2013131457A1 (en) * | 2012-03-08 | 2013-09-12 | 南京埃斯顿机器人工程有限公司 | Dual-system assembly type industrial robot controller |
US9114529B2 (en) | 2012-03-08 | 2015-08-25 | Nanjing Estun Robotics Co. Ltd | Dual-system component-based industrial robot controller |
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Expiration termination date: 20100930 Granted publication date: 20010912 |