An hierarchical motion-control design strategy is presented to integrate various intelligent machining modules to CNC systems. There are two independent buses in the CNC system. Modular and independent processor boards reside in the primary bus which is global for manufacturing process monitoring, control and machine tool position commands. A digital signal processing board provides a secondary CNC bus, which has one imbedded microprocessor for the position control of each axis. The system is open to integration of new hardware and software modules. Any process control and monitoring task in the system can manipulate the feed, acceleration, control law parameters and position commands in real time. New process control, monitoring and position control algorithms can be integrated to the system by using globally available CNC parameters. The process control and monitoring functions are executed in the real-time multi-tasking environment within 1 ms time intervals without disturbing the position control system. The proposed design provides an open development platform for parallel testing of intelligent manufacturing algorithms on machine tools and robots.

Issue Section:
Research Papers
Topics:
Computer numerical control machine tools, Design, Machining, Motion control, Position control, Process control, Algorithms, Machine tools, Manufacturing, Buses, Computer software, Hardware, Lumber, Robots, Signal processing, Testing
1.
Duffie, N. A., and Bollinger, J. G., 1980, “Distributed Computing Systems for Multiple-Processor Industrial Control,” Annals of CIRP, pp. 358–361.
2.
Bollinger, J. G., and Duffie, N. A., 1988, Computer Control of Machines and Processes, Addison-Wesley.
3.
Stute
G.
, and
Klemm
P.
,
1981
, “
The Application of a Modular Multiprocessor N.C. System
,”
Int. J. Machine Tool Design and Research
, Vol.
22
, pp.
215
222
.
4.
Koren, Y., 1983, Computer Control of Manufacturing System, McGraw-Hill Inc.
5.
Weck, M., 1984, Handbook of Machine Tools, Vol. 3, Automation and Controls, Wiley Heyden Ltd.
6.
Koren
Y.
,
1992
, “
Advanced Controllers for Feed Drives
,”
Annals of CIRP
, Vol.
41
, No.
2
, pp.
689
698
.
7.
Altintas
Y.
,
1992
, “
Prediction of Cutting Forces and Tool Breakage in Milling from Feed Drive Current Measurements
,”
ASME Journal of Engineering for Industry
, Vol.
114
, No.
4
, pp.
386
392
.
8.
Wright, P. K., 1990, “Open Architecture Manufacturing. The Impact of Open-System Computers on Self-sustaining Machinery and the Machine Tool Industry,” Proceedings of Manufacturing International ‘90. Part 2: Advances in Manufacturing Systems, Mar. 25–28, 1990, Atlanta, GA, pp. 41–47.
9.
Greenfeld
I.
,
1989
, “
Open-System Machine Controllers—The MOSAIC Concept and Implementation
,”
Trans. ACM
, Vol.
18
, pp.
91
97
.
10.
Altintas
Y.
, and
Peng
J.
,
1990
, “
Design and Analysis of a Modular CNC System
,”
J. of Computers in Industry
, Vol.
13
, No.
4
, pp.
305
316
.
11.
Pritschow
G.
,
Daniel
Ch.
,
Junghans
G.
,
Sperling
W.
,
1993
, “
Open System Controllers—A Challenge for the Future of Machine Tool Industry
,”
CIRP Annals
, Vol.
42
, No.
1
, pp.
449
452
.
12.
Yellowley
I.
, and
Pottier
P. R.
,
1994
, “
Integration of Process and Geometry within an Open Architecture Machine Tool Controller
,”
Int. J. Mach. Tools & Manufac.
, Vol.
34
, No.
2
, pp.
277
293
.
13.
Altintas
Y.
, and
Munasinghe
W. K.
,
1996
, “
Modular CNC Design for Intelligent Machining, Part 2: Modular Integration of Sensor Based Milling Process Monitoring and Control Tasks
,”
ASME JOURNAL OF MANUFACTURING SCIENCE AND ENGINEERING
, Vol.
118
, No.
4
, November, pp.
514
521
.
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