Modeling and controlling variation in mechanical assemblies using state transition models

Author

Mantripragada, R. ; Whitney, D.E.

Author_Institution

Dept. of Mech. Eng., MIT, Cambridge, MA, USA

Volume

1

fYear

1998

fDate

16-20 May 1998

Firstpage

219

Abstract

Presents a state transition model of assembly and concepts from control theory to model variation propagation and control during assembly. The assembly process is modeled as a multi-stage linear dynamic system. Two types of assemblies are addressed: Type-1 where the assembly puts together parts at their pre-fabricated mating features, and Type-2 where the assembly process can incorporate in-process adjustments to redistribute variation. The model builds on the concept of the datum flow chain. Algorithms are developed to determine and control variation in final assembly propagated through the combined effect of individual part variations and choice of assembly methods. An optimal control problem is formulated to develop a scientific approach to designing assembly features

Keywords

assembling; controllability; discrete systems; linear systems; matrix algebra; optimal control; stochastic systems; datum flow chain; mechanical assemblies; multi-stage linear dynamic system; optimal control problem; state transition models; variation propagation; Assembly systems; Digital-to-frequency converters; Discrete event systems; Fixtures; Gaussian approximation; Logic; Manufacturing systems; Robotic assembly; Robots; Tolerance analysis;

fLanguage

English

Publisher

ieee

Conference_Titel

Robotics and Automation, 1998. Proceedings. 1998 IEEE International Conference on

Conference_Location

Leuven

ISSN

1050-4729

Print_ISBN

0-7803-4300-X

Type

conf

DOI

10.1109/ROBOT.1998.676376

Filename

676376