Reliability-Based Topology Optimization of Compliant Mechanisms with Geometrically Nonlinearity

Li, Zhao Kun; Bian, Hua Mei; Shi, Li; Niu, Xiao Tie

doi:10.4028/www.scientific.net/amm.556-562.4422

Cited by 8 publications

(4 citation statements)

References 26 publications

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“…For mechanisms with single pseudo-mobility in the geometrically linear case, in Frecker et al (1999) the ratio of mutual potential energy to strain energy is maximized for one input DoF, where the output displacements are included into a combined mutual potential energy by so-called virtual loads, or a weighted sum of the individual mutual potential energies is used. In Li et al (2014), a multi-objective optimization minimizes the “mean compliance” which, like the strain energy, is a measure of the structural stiffness of the mechanism, while maximizing a weighted sum of the output displacements. Here, transverse loads are included with the help of one load spring applied per output DoF.…”

Section: Overview Of the State Of The Artmentioning

confidence: 99%

Topology-optimization based design of multi-degree-of-freedom compliant mechanisms (mechanisms with multiple pseudo-mobility)

Kirmse

Campanile

Hasse

2022

Journal of Intelligent Material Systems and Structures

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Unlike conventional mechanisms, compliant mechanisms produce the desired deformations by exploiting elastic strain. The mobility of a conventional mechanism is the number of independent coordinates needed to define a configuration of the mechanism. The corresponding concept applicable to compliant mechanisms is the so-called pseudo-mobility defined as the number of scalar parameters needed to identify one single desired deformation of a compliant mechanism. In the case of compliant mechanisms with multiple pseudo-mobility, only synthesis approaches for relatively simple mechanisms exist so far, while systems for more complex tasks like shape adaptation are not covered. In addition, only a limited choice of transverse loads are considered in those approaches. In this paper, a novel optimization algorithm is presented that addresses these two shortcomings. This algorithm is based on a two-step iterative procedure in which the load-case dependency of the deformation is minimized and desired deformations are imposed. The algorithm is tested on mechanisms of different complexity. It could be demonstrated that the new procedure is well suited for the synthesis of different types of compliant mechanisms.

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Section: Overview Of the State Of The Artmentioning

confidence: 99%

Topology-optimization based design of multi-degree-of-freedom compliant mechanisms (mechanisms with multiple pseudo-mobility)

Kirmse

Campanile

Hasse

2022

Journal of Intelligent Material Systems and Structures

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show abstract

“…For mechanisms with single pseudo-mobility in the geometrically linear case, in [15] the ratio of MPE to SE is maximized for one input DoF, where the output displacements are included into a combined MPE by so-called virtual loads, or a weighted sum of the individual MPEs is used. In [16], a multi-objective optimization minimizes the "mean compliance" which, like the SE, is a measure of the structural stiffness of the mechanism, while maximizing a weighted sum of the output displacements. Here, transverse loads are included with the help of one load spring applied per output DoF.…”

Section: Overview Of the State Of The Artmentioning

confidence: 99%

Topology-optimization based design of multi-degree-of-freedom compliant mechanisms (mechanisms with multiple pseudo-mobility)

Kirmse¹,

Campanile²,

Hasse³

2021

Preprint

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Unlike conventional mechanisms, compliant mechanisms produce the desired deformations by exploiting elastic strain and do not need, therefore, moving parts. The number of degrees of freedom of a conventional mechanism, also called mobility, is the number of independent coordinates needed to define a configuration of the mechanism. Due to the different operating principle, such definition of degree of freedom or mobility cannot be directly applied to compliant mechanisms. While those terms are not able to denote a property of a given compliant mechanism, they are meaningful when applied to the design of a compliant mechanism. Compliant mechanisms are, however, mostly seen as elastic structures, for which the term degree of freedom is used in a different meaning. In order to avoid ambiguities, the term pseudo-mobility (already introduced in previous published work) will be used to denote the number of scalar parameters needed to identify one single desired deformation, i.e. one single deformation for which the compliant mechanism is designed. Many synthesis approaches exist for compliant mechanisms with single pseudo-mobility (commonly referred to as "single degree of freedom mechanisms"). In the case of compliant mechanisms with multiple pseudo-mobility (multiple-degree of freedom mechanisms), only synthesis approaches for relatively simple mechanisms exist so far, while systems for more complex tasks like shape adaptation are not covered. In addition, only certain cases of transverse loads are included in the synthesis with these approaches. In this paper, a novel optimization algorithm is presented that addresses these two shortcomings. The algorithm is tested on a simple mechanism with one translation and one rotation kinematic degree of freedom, a compliant parallel mechanism for pure translation and a shape-adaptive structure.

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“…Lazarov et al (2012) introduced the stochastic collocation methods in reliability evaluation of layout design for uncertain mechanical systems. Moreover, the probabilistic RBTO has been also used for accomplishing complex design of engineering systems, mainly including geometrical nonlinear systems (Li et al , 2014), thermal systems (Qian and Dede, 2016) and multidisciplinary coupled systems (Silva et al , 2010).…”

Section: Introductionmentioning

confidence: 99%

A novel approach of reliability-based topology optimization for continuum structures under interval uncertainties

Wang

Xia

Yang

et al. 2019

RPJ

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Purpose The purpose of this paper is to propose a novel non-probabilistic reliability-based topology optimization (NRBTO) method for continuum structural design under interval uncertainties of load and material parameters based on the technology of 3D printing or additive manufacturing. Design/methodology/approach First, the uncertainty quantification analysis is accomplished by interval Taylor extension to determine boundary rules of concerned displacement responses. Based on the interval interference theory, a novel reliability index, named as the optimization feature distance, is then introduced to construct non-probabilistic reliability constraints. To circumvent convergence difficulties in solving large-scale variable optimization problems, the gradient-based method of moving asymptotes is also used, in which the sensitivity expressions of the present reliability measurements with respect to design variables are deduced by combination of the adjoint vector scheme and interval mathematics. Findings The main findings of this paper should lie in that new non-probabilistic reliability index, i.e. the optimization feature distance which is defined and further incorporated in continuum topology optimization issues. Besides, a novel concurrent design strategy under consideration of macro-micro integration is presented by using the developed RBTO methodology. Originality/value Uncertainty propagation analysis based on the interval Taylor extension method is conducted. Novel reliability index of the optimization feature distance is defined. Expressions of the adjoint vectors between interval bounds of displacement responses and the relative density are deduced. New NRBTO method subjected to continuum structures is developed and further solved by MMA algorithms.

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Reliability-Based Topology Optimization of Compliant Mechanisms with Geometrically Nonlinearity

Cited by 8 publications

References 26 publications

Topology-optimization based design of multi-degree-of-freedom compliant mechanisms (mechanisms with multiple pseudo-mobility)

Topology-optimization based design of multi-degree-of-freedom compliant mechanisms (mechanisms with multiple pseudo-mobility)

Topology-optimization based design of multi-degree-of-freedom compliant mechanisms (mechanisms with multiple pseudo-mobility)

A novel approach of reliability-based topology optimization for continuum structures under interval uncertainties

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