Response optimization of underactuated vibration generators through dynamic structural modification and shaping of the excitation forces

Belotti, Roberto; Richiedei, Dario; Tamellin, Iacopo; Trevisani, Alberto

doi:10.1007/s00170-020-06083-2

Cited by 12 publications

(15 citation statements)

References 34 publications

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“…e proposed method relies on the idea of homotopy optimization that has been adopted by the authors and their co-workers, in solving PEA problems similar to equation (7) [28,52], antiresonance assignment [22,52], as well as to the response optimization of underactuated multibody systems [37]. In this paper, the technique is extended to solve equation ( 15), i.e., the PEA problem embedding a robustness condition.…”

Section: Outline Of the Proposed Methodmentioning

confidence: 99%

“…In the third test case, it is required to keep the same natural frequency of the original system, while increasing its robustness with respect to some parameters. is problem could be of interest in resonators (such as feeders [37] or sonotrodes [38]) that are excited by an external tuned harmonic force matching one resonance frequency. Since the system parameters might slightly change during operation, a robust design of these devices is of great importance to ensure that the resonance frequency is robust to parameter variations that could mistune the system and hence downgrade the system performances.…”

Section: Test-case 3: Robustification Of a Natural Frequency In A System With Continuum And Lumped Flexible Elementsmentioning

confidence: 99%

“…is goal is of practical interest in structures and machines in the presence of either wanted or unwanted vibrations. For example, ensuring insensitive natural (or resonance) frequencies is of great importance in the design of resonators (such as feeders [26,37] or sonotrodes [20,38]), where the resonance frequency should match the excitation frequency regardless of the changes in some parameters, to ensure large motion with small actuation effort. In the case of vibration absorption of harmonic excited systems, assigning antiresonances at the excitation frequency is an effective approach ( [39][40][41]), that should be ensured even in the case of changes of some system parameters.…”

Section: Introductionmentioning

confidence: 99%

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Robust Assignment of Natural Frequencies and Antiresonances in Vibrating Systems through Dynamic Structural Modification

Caracciolo

Richiedei

Tamellin

2021

Shock and Vibration

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This paper proposes a novel method for the robust partial assignment of natural frequencies and antiresonances, together with the partial assignment of the related eigenvectors, in lightly damped linear vibrating systems. Dynamic structural modification is exploited to assign the eigenvalues, either of the system or of the adjoint system, together with their sensitivity with respect to some parameters of interest. To handle with constraints on the feasible modifications, the inverse eigenvalue problem is cast as a minimization problem and a solution method is proposed through homotopy optimization. Variables lifting for bilinear and trilinear terms, together with bilinear and double-McCormick’s constraints, are exploited to provide a convexification of the problem and to boost the attainment of the global optimum. The effectiveness of the proposed method is assessed through four numerical examples.

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Section: Outline Of the Proposed Methodmentioning

confidence: 99%

Section: Test-case 3: Robustification Of a Natural Frequency In A System With Continuum And Lumped Flexible Elementsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Robust Assignment of Natural Frequencies and Antiresonances in Vibrating Systems through Dynamic Structural Modification

Caracciolo

Richiedei

Tamellin

2021

Shock and Vibration

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“…Traditionally, structural modification has been widely adopted over the decades to assign natural frequencies [18][19][20], mode shapes [21,22] and antiresonance frequencies [23][24][25]. Recently, DSM has been adopted also to increase the robustness against the system uncertainties in motion planning [26] and to improve the subspace of the allowable motion in linear vibratory feeders excited through harmonic excitation [27]. In addition, a mechanical design approach to convert non-minimum phase systems into minimum phase has been proposed in [4].…”

Section: Motivations and State Of The Artmentioning

confidence: 99%

Integrated Inverse Dynamics and Optimized Mechanical Design in Underactuated Linear Vibratory Feeders Under Periodic Excitation

Bettega

Richiedei

Tamellin

et al. 2023

J. Vib. Eng. Technol.

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Purpose This paper proposes an integrated method for optimizing the response of underactuated linear vibratory feeders operating in open-loop control, under generic periodic excitations. The goal is ensuring a uniform motion of the tray, despite the presence of less actuators than degrees of freedom and of several specifications of the desired motion. Method To cope with the underactuated nature of these systems and with their non-minimum phase behavior, dynamic structural modification and the inverse dynamics approach are properly integrated by exploiting a common definition of the system internal dynamics. In the inverse dynamics problem, the inverse dynamics is stabilized through output redefinition and the resulting ordinary differential equations are integrated to compute causal actuation forces, ensuring almost-exact tracking for as many coordinates as the number of actuators. The tracking of the remaining coordinates of interest is improved through a proper design of the mechanical parameters, based on the modification of the internal dynamics. Results The effectiveness of the proposed method is assessed through numerical simulations performed on the challenging case of a 14-degrees of freedom underactuated non-minimum phase linear vibratory feeder adopted in manufacturing plants to convey products. Conclusion The results evidence the benefits obtained by integrating structural modification together with inverse dynamics. Inverse dynamics is effective, since the tracking error on the imposed coordinates is negligible. On the other hand, the benefits introduced by dynamic structural modification are proved as well, by the reduction of the tracking error also for the non-imposed coordinates.

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“…Since m < n, the system is underactuated. The dynamic model in (1) can be rewritten by partitioning q into the vector of m actuated generalized coordinates, and the vector q u of the n − m unuactuated ones [21]:…”

Section: System Model Formulationmentioning

confidence: 99%

Desensitized motion planning for underactuated multibody systems

Boscariol¹,

Richiedei²

2021

Proceedings of the 10th ECCOMAS Thematic Conference on MULTIBODY DYNAMICS

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Model-plant mismatches can severely limit the effectiveness of conventional model-based motion design methods. To solve this issue, a method for robust trajectory planning that can reduce the effects of parametric uncertainties is presented in this work. The method is based on an indirect variational formulation, which is translated into a Two-Point Boundary Value Problem (TPBVP) and then solved numerically. Robustness is obtained by incorporating into the problem the sensitivity functions of the plant, and imposing some additional constraints on the initial and final points of the trajectory. A formulation aimed at reducing both the residual and the transient oscillations, as well as keeping small the control effort, is also proposed. The work presents a numerical verification of the effectiveness of the method for an underactuated system, such as a double-pendulum crane, by showing its effectiveness and robustness when performing fast rest-to-rest motions.

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Response optimization of underactuated vibration generators through dynamic structural modification and shaping of the excitation forces

Cited by 12 publications

References 34 publications

Robust Assignment of Natural Frequencies and Antiresonances in Vibrating Systems through Dynamic Structural Modification

Robust Assignment of Natural Frequencies and Antiresonances in Vibrating Systems through Dynamic Structural Modification

Integrated Inverse Dynamics and Optimized Mechanical Design in Underactuated Linear Vibratory Feeders Under Periodic Excitation

Desensitized motion planning for underactuated multibody systems

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