Lobing Behavior in Centerless Grinding—Part I: Stability Estimation-Reference-Cited by-同舟云学术

Lobing Behavior in Centerless Grinding—Part I: Stability Estimation

Published:1997-06-01 Issue:2 Volume:119 Page:153-159
ISSN:0022-0434
Container-title:Journal of Dynamic Systems, Measurement, and Control
language:en
Short-container-title:

Author:

Zhou S. S.¹,Gartner J. R.¹,Howes T. D.¹

Affiliation:

1. Center for Grinding Research and Development, University of Connecticut, Storrs, CT 06269-5119

Abstract

This two-part paper addresses the lobing behavior associated with centerless grinding. Part I establishes a system model (the lobing loop) for lobing analysis and develops methodologies for lobing stability analysis, and Part II investigates lobing characteristics and proposes remedies for lobing suppression. The lobing loop shows that lobing behavior is of kinematic nature, caused by the interaction between the geometric rounding mechanism and regenerative cutting mechanism. A bidiagram-matical method is subsequently developed for lobing stability estimation. It was found that lobing is inherently unstable, and the characteristic roots of the lobing loop are limited within their respective root neighborhoods in the u-plane. This leads to: (1) a method of lobing stability estimation using the growth rate boundaries, and (2) an efficient way of solving for the characteristic roots using a Taylor’s series approximation. The availability of growth rate boundaries and characteristic root distribution provides an effective tool for the control of lobing in centerless grinding.

Publisher

ASME International

Subject

Computer Science Applications,Mechanical Engineering,Instrumentation,Information Systems,Control and Systems Engineering

Link

http://asmedigitalcollection.asme.org/dynamicsystems/article-pdf/119/2/153/5778913/153_1.pdf

Reference18 articles.

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2. Dall, A. H., 1946, “Rounding Effect in Centerless Grinding,” Mech. Eng., Apr. pp. 325–329.

3. Frost, M., and Fursdon, P. M. T., 1985, “Towards Optimum Centerless Grinding,” ASME M.C. Shaw Grinding Symposium, pp. 313–328.

4. Furukawa Y. , MiyashitaM., and ShiozakiS., 1971, “Vibration Analysis and Work-rounding Effect in Centerless Grinding,” Int. Jnl. Mach. Toot Des. Res., Vol. 11, pp. 145–175.

5. Goodall, C., 1990, “A Study of the Through-feed Centerless Grinding Process with Particular Reference to the Size Accuracy,” Ph.D. thesis, Liverpool Polytechnic, U.K.

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