Abstract
The vibrational behavior of components in mechanical systems like drives and robots can become critical under changes in the system properties or loading in operation. Such undesired vibration can lead to detrimental conditions including excess wear, fatigue, discomfort, and acoustic emissions. Systems are designed to avoid certain frequencies to avoid such problems, but system parameters can change during operation due damage, wear, or change in loading. An example is the change in system properties or operation state that then activates resonance frequencies in our system. Therefore, this work has the goal of modifying the modal behavior of a system to avoid vibrational problems. Methods of design optimization are applied to find a new optimum design for this altered condition. Here, this is limited to the addition of mass in order to move the resonance frequency out of critical ranges. This though requires a new formulation of the optimization problem. We propose a new constraint formulation to avoid frequency ranges. To increase efficiency, a reduced analytical sensitivity analysis is introduced. This methodology is demonstrated on two test cases: a two-mass oscillator followed by a test case of higher complexity which is a gear housing considering over 15,000 design variables. The results show that the optimization solution gives the position and amount of mass added, which is a discrete solution that is practically implementable.
Highlights
In this study, a design methodology is introduced to redesign mechanical systems to account for changes in system parameters or other environmental changes during operation
A reduced analytical sensitivity analysis is introduced. This methodology is demonstrated on two test cases: a two-mass oscillator followed by a test case of higher complexity which is a gear housing considering over 15,000 design variables
An example of changes in system parameters is a changed mesh stiffness of a planetary gear set that causes the vibrational excitation of the housing
Summary
A design methodology is introduced to redesign mechanical systems to account for changes in system parameters or other environmental changes during operation. Optimal design of mechanical systems under dynamic considerations stems from two traditions and seemly separate communities denoted by the terms: structural design optimization ( structural optimization or design optimization, see Ross [1], Baier et al [2], Vanderplaats [3]) and dynamic structural modification ( structural dynamic modification or structural modification, see Bucher and Braun [4], He [5], Avitabile [6], Belotti and Richiedei [7]) The latter includes the assignment of the eigenpair (eigenfrequency or mode shape or both) via an inverse problem formulation. Examples will be shown with both a lumped-parameter model as well as a finite-element model The latter shows the methodology with a large-scale problem, both in terms of the number of design variables and of the number of degrees of freedom
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
