Robust Optimal Influence-Coefficient Control of Multiple-Plane Active Rotor Balancing Systems

Stephen W.  Dyer; Jianjun  Shi; Jun  Ni; Kwang-Keun  Shin

Source: Journal of Dynamic Systems, Measurement, and Control:;2002:;volume( 124 ):;issue: 001::page 41

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DOI: 10.1115/1.1435622

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: Rotating mass imbalance causes harmful vibration of high-speed machine tools, turbomachinery, etc. Constant speed, steady-state influence coefficient control allows active balancing systems to suppress this vibration if the influence matrix is estimated accurately. An optimal strategy for multiple-plane active balancing control is presented here that improves control robustness to modeling and estimation errors. The vibration controller objectively trades off residual vibration, control effort, and control rate of change. Penalizing control effort and rate of change is shown to enhance control stability margin, with certain performance trade-offs. Experimental results illustrate the improvement in control robustness compared with traditional weighted least squares optimal control.

keyword(s): Stability , Rotors , Vibration , Errors , Robustness , Steady state , Optimal control , Rotor balancing , Sensors , Machinery AND Control equipment ,

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Robust Optimal Influence-Coefficient Control of Multiple-Plane Active Rotor Balancing Systems

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Journal of Dynamic Systems, Measurement, and Control

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contributor author	Stephen W. Dyer
contributor author	Jianjun Shi
contributor author	Jun Ni
contributor author	Kwang-Keun Shin
date accessioned	2017-05-09T00:07:06Z
date available	2017-05-09T00:07:06Z
date copyright	March, 2002
date issued	2002
identifier issn	0022-0434
identifier other	JDSMAA-26296#41_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/126537
description abstract	Rotating mass imbalance causes harmful vibration of high-speed machine tools, turbomachinery, etc. Constant speed, steady-state influence coefficient control allows active balancing systems to suppress this vibration if the influence matrix is estimated accurately. An optimal strategy for multiple-plane active balancing control is presented here that improves control robustness to modeling and estimation errors. The vibration controller objectively trades off residual vibration, control effort, and control rate of change. Penalizing control effort and rate of change is shown to enhance control stability margin, with certain performance trade-offs. Experimental results illustrate the improvement in control robustness compared with traditional weighted least squares optimal control.
publisher	The American Society of Mechanical Engineers (ASME)
title	Robust Optimal Influence-Coefficient Control of Multiple-Plane Active Rotor Balancing Systems
type	Journal Paper
journal volume	124
journal issue	1
journal title	Journal of Dynamic Systems, Measurement, and Control
identifier doi	10.1115/1.1435622
journal fristpage	41
journal lastpage	46
identifier eissn	1528-9028
keywords	Stability
keywords	Rotors
keywords	Vibration
keywords	Errors
keywords	Robustness
keywords	Steady state
keywords	Optimal control
keywords	Rotor balancing
keywords	Sensors
keywords	Machinery AND Control equipment
tree	Journal of Dynamic Systems, Measurement, and Control:;2002:;volume( 124 ):;issue: 001
contenttype	Fulltext

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