Your search keyword '"Francesco Danzi"' showing total 20 results

1. Nonlinear Dynamics of a Two Members Angle-Shaped Energy Harvester

Author

Francesco Danzi, Hongcheng Tao, Amin Joodaky, and James M. Gibert

Abstract

In this article we propose a theoretical investigation of the nonlinear dynamical response of a class of planar resonators dubbed the V-Shaped resonator. The resonators are intended for energy harvesting purpose and are designed to exhibit two-to-one internal resonance. In particular, we navigate the design space for the generalized V-shaped resonator to investigate the influence of shape parameters on the performance of the Vibration Energy Harvester. Notably, we introduce two metrics that help elucidating the role of the shape parameter in dictating the behavior of the system in terms of peak voltage and operational bandwidth width. For simplicity, we consider that the system is subjected to harmonic excitations near its primary resonances.

Published

2022

2. Characterization of Nonlinear Kirigami Springs Through Transient Response

Author

Francesco Danzi, Joshua Jenkins, Hongcheng Tao, and James M. Gibert

Abstract

Kirigami is defined as the ancient Japanese art of cutting and folding paper to create three-dimensional structures, which is a subset of the larger term. Recent developments in kirigami-based structures have sparked interest in the engineering community for the development of mechanical metastructures with customized behavior such as negative Poisson’s ratio, out-of-plane buckling, and soft robot locomotion. In this manuscript, nonlinear springs based on kirigami are developed; the springs can be used to create customized nonlinear oscillators and vibration suppression systems. A Helmholtz-Duffing oscillator with nonlinear damping is created by attaching a mass to a smooth track with the kirigami springs attached to it. Kirigami springs were made by strategically cutting plastic sheets in predetermined patterns and arranging them in a ring. Identification of the unknown system parameters is accomplished through the use of a two-step procedure. To determine the quasi-static behavior of the spring, it was first subjected to tensile testing. These parameters serve as the foundation for developing a strategy for determining the unknown energy loss parameters in a system. In the second step, the Method of Multiple Scales is used to develop an approximate solution for the transient response, which is then tested. This solution is coupled with an optimization routine that, by modifying the unknown model parameters, seeks to reduce the error between the experimental free oscillations and the developed analytical solution as closely as possible.

Published

2022

3. The role of topology on the response of a V-shaped resonator

Author

Francesco Danzi, James M. Gibert, and Hongcheng Tao

Subjects

Physics, Applied Mathematics, Mechanical Engineering, Aerospace Engineering, Ocean Engineering, Topology, Orientation (vector space), Nonlinear system, Resonator, Modal, Control and Systems Engineering, Excited state, Sensitivity (control systems), Electrical and Electronic Engineering, Topology (chemistry), Multiple-scale analysis

Abstract

The objective of this manuscript is to elucidate the role of topology on the nonlinear response of resonators. The resonators are composed of two beams and designed to exhibit two-to-one internal resonances. The manuscript explores the sensitivity to variations in the topological parameters, i.e., the relative orientation, and the ratio of lengths and heights, on the modal frequencies of the structure. The nonlinear governing equations are solved using the method of multiple scales when the system is excited near the first and second resonances. The occurrence of bifurcations and modal interactions has been shown both numerically and experimentally and related to the topological parameters. The effect of the topology on modal saturation has also been studied.

Published

2020

4. Heterogeneous digital stiffness programming

Author

Hongcheng Tao, Francesco Danzi, Christian E. Silva, and James M. Gibert

Subjects

Mechanics of Materials, Mechanical Engineering, Chemical Engineering (miscellaneous), Bioengineering, Engineering (miscellaneous)

Published

2022

5. Graph-based element removal method for topology synthesis of beam based ground structures

Author

Francesco Danzi, James M. Gibert, Enrico Cestino, and Giacomo Frulla

Subjects

Ground structures, Engineering, Control and Optimization, Resonator, 0211 other engineering and technologies, 02 engineering and technology, Topology, Graph, Planar, 0203 mechanical engineering, Element removal method, Topology optimization, 021106 design practice & management, Topology synthesis, business.industry, Graph based, Compliant mechanism, Control engineering, Computer Graphics and Computer-Aided Design, Computer Science Applications, 020303 mechanical engineering & transports, Control and Systems Engineering, Graph (abstract data type), business, Engineering design process, Software

Abstract

This note proposes a novel element removal method for ground structured based topology optimization that utilizes a double-filtering scheme based on a graph representation of the topology. Two types of systems: planar resonators and compliant mechanisms, are used to illustrate the method.

Published

2017

6. Nonlinear dynamic analysis of 1:2 internal resonant V-shaped harvester

Author

Francesco Danzi, James M. Gibert, and Amin Joodaki

Subjects

Physics, Work (thermodynamics), Nonlinear system, Resonator, Frequency response, Mathematical analysis, Resonance, Folding (DSP implementation), Topology (chemistry), Multiple-scale analysis

Abstract

The objective of the manuscript is to explore the effects of geometry on the dynamics of an internally resonant vibrational energy harvester (VEH). Recently, the authors of this manuscript unveiled the existence of ∞6N solutions to design multi-members resonators which exhibit N commensurate frequencies equal to the number of members of the structure. The generalized topology of this family of resonators which exhibit 1:2 resonance resembles a V -shaped structure, i.e., a structure with two members adjoined at an angle φ, denoted as the folding angle. The classic 1:2 internally resonant L-shaped structure is a subset of solutions in this family. This work investigates the effect of the folding angle on the dynamic response of these oscillators. The nonlinear equations of motion are derived by means of Lagrange’s equation, the beams are inextensible yielding second order nonlinearities. Approximate solutions of the model are obtained using the method of multiple scales. The effect of the folding angle on the nonlinear modal interaction in the power- frequency response curves is investigated.

Published

2019

7. Numerical/experimental evaluation of buckling behaviour and residual tensile strength of composite aerospace structures after low velocity impact

Author

Enrico Cestino, Francesco Danzi, Giulio Romeo, and Paolo Piana

Subjects

Materials science, business.industry, Composite number, Aerospace Engineering, 02 engineering and technology, Structural engineering, 021001 nanoscience & nanotechnology, Residual, Composite structure, Low-velocity impact, Residual strength, Finite element method, Characterization (materials science), 020303 mechanical engineering & transports, 0203 mechanical engineering, Buckling, Ultimate tensile strength, 0210 nano-technology, business, Tensile testing

Abstract

A procedure for the characterization of low velocity impact damage and its effect on residual tensile and buckling behaviour of composite structures is presented. A simplified analytical method is used to enhance the damage simulation and a degradation model is introduced in the subsequent finite element analysis. Different degradation coefficients are defined for three impact energy stages. Two different types of analysis are performed using MD.Nastran software: the non-linear progressive failure analysis to estimate the residual tensile strength and the linear analysis to predict the critical uniaxial and shear buckling loads after impact. Tensile and buckling experiments are used to validate the present methodology. A good correlation is obtained for all the cases under investigation.

Published

2016

8. Exact dynamics of an angle-shaped resonator for energy scavenging applications

Author

Francesco Danzi and James M. Gibert

Subjects

Physics, Resonator, Exact Dynamics, Dynamics (mechanics), 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, Analytical Model, Energy Harvesting, 0103 physical sciences, Resonator, Exact Dynamics, Energy Harvesting, Analytical Model, 0210 nano-technology, 010301 acoustics, Energy harvesting

Published

2018

9. An Invariant-based Performance-Oriented Procedure for Preliminary Design of Composite Structures

Author

Francesco Danzi, Giacomo Frulla, and Giulio Romeo

Subjects

preliminary structural design, composite structures, Trace invariant, Scaling approach, business.industry, Composite number, Scaling approach, Aerospace Engineering, Stiffness, preliminary structural design, Functional requirement, 02 engineering and technology, 021001 nanoscience & nanotechnology, Reliability engineering, 020303 mechanical engineering & transports, High fidelity, 0203 mechanical engineering, Material selection, medicine, medicine.symptom, Invariant (mathematics), 0210 nano-technology, Aerospace, business, Scaling, composite structures, Trace invariant

Abstract

Purpose This paper aims to present a systematic performance-oriented procedure to predict structural responses of composite layered structures. The procedure has a direct application in the preliminary design of aerospace composite structures evaluating the right and most effective material. Design/methodology/approach The aforementioned procedure is based upon the definition of stiffness invariants. In the paper, the authors briefly recall the definition and the physical explanation of the invariants, i.e. the trace; then they present the scaling procedure for the selection of the best material for a fixed geometrical shape. Findings The authors report the basic principles of the scaling procedure and several examples pertaining typical responses sought in the preliminary design of aeronautic structures Research limitations/implications Typically, during early stages, engineers had to perform the daunting task of balancing among functional requirements and constraints and give the optimum solution in terms of structural concept and material selection. Moreover, preliminary design activities require evaluating different responses as a function of as less as possible parameters, ensuring medium to high fidelity. The importance of incorporating as much physics and understanding of the problem as early as possible in the preliminary design stages is therefore fundamental. A robust and systematic procedure is necessary. Practical implications The time/effort reduction in the preliminary design of composite structures can increase the overall quality of the configuration chosen. Social implications Reduction in design costs and time. Originality/value In spite of the well-known invariant properties of composites, the application and extension to the preliminary design of composite structures by means of a scaling rule is new and original.

Published

2018

10. Generalized topology for resonators having N commensurate harmonics

Author

James M. Gibert, Francesco Danzi, Giacomo Frulla, and Enrico Cestino

Subjects

Rayleigh–Ritz method, Physics, energy harvesting, Acoustics and Ultrasonics, Mechanical Engineering, Degrees of freedom (statistics), 02 engineering and technology, resonator, commensurate frequency, MEMS, energy harvesting, Condensed Matter Physics, Topology, 01 natural sciences, commensurate frequency, Orientation (vector space), Nonlinear system, Resonator, MEMS, 020303 mechanical engineering & transports, Planar, Modal, 0203 mechanical engineering, Mechanics of Materials, Harmonics, 0103 physical sciences, resonator, 010301 acoustics

Abstract

Despite the ubiquity of both linear and nonlinear multimember resonators in MEMS and kinetic energy harvesting devices very few research efforts examine the orientation of members in the resonator on its dynamic behavior. Previous efforts to design this type of resonator constrains the members to have relative orientations that are 0 ○ or 90○ to each other, i.e., the elements are connected inline with adjoining members or are perpendicular to adjoining members. The work expands upon the existing body of research by considering the effect of the relative orientation between members on the dynamic behavior of the system. In this manuscript, we derive a generalized reduced-order model for the design of a multi-member planar resonator that has integer multiple modal frequencies. The model is based on a Rayleigh Ritz approximation where the number of degrees of freedom equals the number of structural members in the resonator. The analysis allows the generation of design curves, representing all the possible solutions for modal frequencies that are commensurate. The generalized model, valid for an N-DOF structure, is then restricted for a 2- and 3-DOF system/member resonator, where the linear dynamic behavior of the resonator is investigated in depth. Furthermore, this analysis demonstrates a rule of thumb; relaxing restrictions on the relative orientation of members in a planar structure, allows the structure to exhibit exactly N commensurable frequencies if it contains N members.

Published

2018

11. Topology Synthesis of Planar Ground Structures for Energy Harvesting Applications

Author

Enrico Cestino, Giacomo Frulla, Francesco Danzi, and James M. Gibert

Subjects

Physics, Mathematical optimization, Topology Optimization, Resonator, Modal analysis, Topology optimization, Piezoelectricity, Topology (electrical circuits), Energy Harvesting, Resonator, Topology Optimization, Ground Structure, Piezoelectricity, 02 engineering and technology, 021001 nanoscience & nanotechnology, Base (topology), Topology, 01 natural sciences, Modal, Harmonics, 0103 physical sciences, Energy Harvesting, Linear scale, Ground Structure, 0210 nano-technology, 010301 acoustics

Abstract

In this manuscript, we investigate the use topology optimization to design planar resonators with modal fre- quencies that occur at 1 : n ratios for kinetic energy scavenging of ambient vibrations that exhibit at least two frequency components. Furthermore, we are interested in excitations with a fundamental component containing large amounts of energy and secondary component with smaller energy content. This phenomenon is often seen in rotary machines; their frequency spectrum exhibits peaks on multiple harmonics, where the energy is primarily contained in the rotation frequency of the device. Several theoretical resonators are known to exhibit modal frequencies that at integer multiples 1:2 or 1:3. However, designing manufacturable resonators for other geometries is still a daunting task. With this goal in mind, we utilize topology optimization to determine the layout of the resonator. We formulate the problem in its non-dimensional form, eliminating the constraint on the allowable frequency. The frequency can be obtained a posteriori by means of linear scaling. Conversely, to previous research, which use the clamped beam as initial guess, we synthesize the final shape starting from a ground structure (or structural universe) and remove of the unnecessary beams from the initial guess by means of a graph-based filtering scheme. The algorithm determines the simplest structure that gives the desired frequency’s ratio. Within the optimization, the structural design is accomplished by a linear FE analysis. The optimization reveals several trends, the most notable being that having members connected orthogonally as in the L-shaped resonator is not the preferred topology of this devices. In order to fully explore the angle of orientation of connected members on the modal characteristics of the device; we derive a reduced-order model that allows a bifurcation analysis on the effect of member orientation on modal frequency. Furthermore, the reduced order approximation is used solve the coupled electro-mechanical equation of a vibration based energy harvester (VEH). Finally, we present the performance of the VEH under various base excitations. These results show an infinite number of topologies that can have integer ratio modal frequencies, and in some cases harvest more power than a nominal L shaped harvester, operating in the linear regime.

Published

2017

12. Constrained combinatorial optimization of multi-layered composite structures by means of Stud GA with proportionate selection and extinction

Author

Francesco Danzi, Giacomo Frulla, and Enrico Cestino

Subjects

Population based algorithm, 020301 aerospace & aeronautics, Sequence, Mathematical optimization, Control and Optimization, Buckling load maximization, Combinatorial optimization, Composite structures, 02 engineering and technology, Computer Graphics and Computer-Aided Design, Stacking sequence, Computer Science Applications, Permutation, 020303 mechanical engineering & transports, 0203 mechanical engineering, Control and Systems Engineering, Convergence (routing), Benchmark (computing), Software, Selection (genetic algorithm), Mathematics, Premature convergence, Parametric statistics

Abstract

In this paper a revised algorithm, derived by the Stud GA, to optimize the stacking sequence of layered composite structures is presented. The constrained combinatorial problem is formulated and hence solved by means of the algorithm presented herein. Unlike the Stud GA, the proposed algorithm uses a fitness-proportionate selection to find potential mates to the Stud and a self-adaptive extinction to avoid premature convergence. Elitism is also allowed. Standard benchmark problems have been used to fully assess the validity of the proposed algorithm. Results in terms of reliability and efficiency are compared against three GAs and a Permutation Search (PS) algorithm. It has been demonstrated, by means of a parametric study, that a low probability of extinction is sufficient to ensure fast convergence as well as reliable results. Finally the optimization of a more complex aeronautic structure is addressed aiming to prove the validity of the proposed algorithm in a two level optimization strategy. Results in terms of efficiency are compared against those of an in-house standard GA.

Published

2017

13. Acknowledgment to the Reviewers of Machines in 2022.

Subjects

SCHOLARLY publishing, MACHINERY

Abstract

I Machines i was able to uphold its high standards for published papers due to the outstanding efforts of our reviewers. [Extracted from the article]

Published

2023

14. Acknowledgment to the Reviewers of Applied Sciences in 2022.

Subjects

APPLIED sciences, SCHOLARLY publishing

Abstract

Regardless of whether the articles they examined were ultimately published, the editors would like to express their appreciation and thank the following reviewers for the time and dedication that they have shown I Applied Sciences i : se of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). I Applied Sciences i was able to uphold its high standards for published papers due to the outstanding efforts of our reviewers. [Extracted from the article]

Published

2023

15. Acknowledgment to the Reviewers of Aerospace in 2022.

Subjects

SCHOLARLY publishing

Abstract

I Aerospace i was able to uphold its high standards for published papers due to the outstanding efforts of our reviewers. MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. [Extracted from the article]

Published

2023

16. The role of topology on the response of a V-shaped resonator.

Author

Danzi, Francesco, Tao, Hongcheng, and Gibert, James M.

Abstract

The objective of this manuscript is to elucidate the role of topology on the nonlinear response of resonators. The resonators are composed of two beams and designed to exhibit two-to-one internal resonances. The manuscript explores the sensitivity to variations in the topological parameters, i.e., the relative orientation, and the ratio of lengths and heights, on the modal frequencies of the structure. The nonlinear governing equations are solved using the method of multiple scales when the system is excited near the first and second resonances. The occurrence of bifurcations and modal interactions has been shown both numerically and experimentally and related to the topological parameters. The effect of the topology on modal saturation has also been studied. [ABSTRACT FROM AUTHOR]

Published

2020

17. Exact Dynamics of an Angle-shaped Resonator for Energy Scavenging Applications.

Author

Danzi, Francesco and Gibert, James M.

Published

2018

18. An invariant-based performance-oriented procedure for preliminary design of composite structures.

Author

Danzi, Francesco, Frulla, Giacomo, and Romeo, Giulio

Subjects

COMPOSITE structures, STRUCTURAL design, YOUNG'S modulus, MODULUS of rigidity, POISSON regression

Abstract

Purpose This paper aims to present a systematic performance-oriented procedure to predict structural responses of composite layered structures. The procedure has a direct application in the preliminary design of aerospace composite structures evaluating the right and most effective material.Design/methodology/approach The aforementioned procedure is based upon the definition of stiffness invariants. In the paper, the authors briefly recall the definition and the physical explanation of the invariants, i.e. the trace; then they present the scaling procedure for the selection of the best material for a fixed geometrical shape.Findings The authors report the basic principles of the scaling procedure and several examples pertaining typical responses sought in the preliminary design of aeronautic structuresResearch limitations/implications Typically, during early stages, engineers had to perform the daunting task of balancing among functional requirements and constraints and give the optimum solution in terms of structural concept and material selection. Moreover, preliminary design activities require evaluating different responses as a function of as less as possible parameters, ensuring medium to high fidelity. The importance of incorporating as much physics and understanding of the problem as early as possible in the preliminary design stages is therefore fundamental. A robust and systematic procedure is necessary.Practical implications The time/effort reduction in the preliminary design of composite structures can increase the overall quality of the configuration chosen.Social implications Reduction in design costs and time.Originality/value In spite of the well-known invariant properties of composites, the application and extension to the preliminary design of composite structures by means of a scaling rule is new and original. [ABSTRACT FROM AUTHOR]

Published

2018

19. Graph-based element removal method for topology synthesis of beam based ground structures.

Author

Danzi, Francesco, Gibert, James M., Frulla, Giacomo, and Cestino, Enrico

Subjects

TOPOLOGY, MATHEMATICAL optimization, DIELECTRIC resonators, FILTERING software, GRAPH algorithms

Abstract

This note proposes a novel element removal method for ground structured based topology optimization that utilizes a double-filtering scheme based on a graph representation of the topology. Two types of systems: planar resonators and compliant mechanisms, are used to illustrate the method. [ABSTRACT FROM AUTHOR]

Published

2018

20. Constrained combinatorial optimization of multi-layered composite structures by means of Stud GA with proportionate selection and extinction.

Author

Danzi, Francesco, Frulla, Giacomo, and Cestino, Enrico

Subjects

COMBINATORIAL optimization, COMPOSITE structures, PERMUTATIONS, COMBINATORICS, PROBABILITY theory

Abstract

In this paper a revised algorithm, derived by the Stud GA, to optimize the stacking sequence of layered composite structures is presented. The constrained combinatorial problem is formulated and hence solved by means of the algorithm presented herein. Unlike the Stud GA, the proposed algorithm uses a fitness-proportionate selection to find potential mates to the Stud and a self-adaptive extinction to avoid premature convergence. Elitism is also allowed. Standard benchmark problems have been used to fully assess the validity of the proposed algorithm. Results in terms of reliability and efficiency are compared against three GAs and a Permutation Search (PS) algorithm. It has been demonstrated, by means of a parametric study, that a low probability of extinction is sufficient to ensure fast convergence as well as reliable results. Finally the optimization of a more complex aeronautic structure is addressed aiming to prove the validity of the proposed algorithm in a two level optimization strategy. Results in terms of efficiency are compared against those of an in-house standard GA. [ABSTRACT FROM AUTHOR]

Published

2017