Your search keyword '"Dai, Fuhong"' showing total 15 results

1. Bi-stable piezoelectric composite laminate for energy harvesting

Author

International Conference on Composite Materials (22nd : 2019 : Melboune, VIC.), Dai, Fuhong, and Pan, Diankun

Published

2019

2. Segmented layered bistable piezoelectric laminates for enhanced energy harvesting from wind‐induced vibration.

Author

Liu, Xiaohui, Yan, Tao, and Dai, Fuhong

Subjects

*ENERGY harvesting, *MICROBIAL fuel cells, *SMART structures, *FINITE element method, *WIND speed, *WIND power, *WIND tunnels

Abstract

In this study, a segmented layered bistable piezoelectric energy harvester (SBPEH) has been developed and thoroughly investigated for its wind energy harvesting capabilities. The SBPEH's performance was comprehensively evaluated through the creation of a detailed 3D finite element model using Abaqus and XFlow software, and further validated via rigorous wind tunnel experiments. The results of this research demonstrate the SBPEH's remarkable potential for wind energy harvesting. With a wide operational wind speed range, it achieved a maximum measured power output of 5.476 mW, coupled with an outstanding power density of 68.45 mW/cm3, both of which were realized at a wind speed of 13 m/s. It is worth noting that as the wind speed surpasses a specific threshold, the energy harvesting efficiency of the SBPEH experiences a decline, emphasizing the importance of identifying the optimal operational wind speed range for maximizing energy output. These findings offer valuable insights for the enhancement and application of SBPEHs, contributing to the advancement of renewable energy technologies and providing an eco‐friendly solution for power generation. Highlights: The study introduces a new segmented layered bistable piezoelectric energy harvester (SBPEH) design for wind energy harvesting, addressing the limitations of traditional harvesters.Performance is evaluated through 3D finite element modeling, ABAQUS, Xflow simulations, and wind tunnel experiments.The SBPEH operates efficiently across a broad wind speed range (6–14 m/s), showcasing optimal output power of 5.476 mW at 13 m/s. [ABSTRACT FROM AUTHOR]

Published

2024

3. Design and analysis of a broadband vibratory energy harvester using bi-stable piezoelectric composite laminate.

Author

Pan, Diankun and Dai, Fuhong

Subjects

*PIEZOELECTRIC composites, *LAMINATED materials, *ENERGY harvesting, *FINITE element method, *ACCELERATION (Mechanics)

Abstract

In this paper, a bi-stable piezoelectric energy harvester based on the bi-stable hybrid composite laminate with a new stacking sequence design is proposed. The new stacking sequence enables this bi-stable energy harvester to have some unique features, such as uniform strains of piezoelectric elements and symmetric stable configurations. Meanwhile, the new stacking sequence design enhances the room to adjust its natural frequency such that this proposed harvester allows for adjusting to lower frequency range and increasing the inertia by a tip mass to lower the demand of excitation level in comparison to previous settings. A finite element analysis is developed to investigate the static and dynamic characteristics of this new bi-stable energy harvester. A simple numerical model with a modified version of the Duffing equation is developed based on the unique nonlinear restoring force obtained from finite element analysis to describe the fundamental response characteristics of this nonlinear bi-stable energy harvester. Numerical simulations and experiments are carried out at different harmonic excitation levels ranging from 10 to 40 Hz. The results verify that the proposed model can reasonably capture the dynamic characteristics of this broadband bi-stable energy harvester. The output powers were measured under different vibration patterns. Maximum power of 31.1 mW was generated under large-amplitude and high-energy orbits cross-well vibration pattern at an excitation frequency of 22 Hz and acceleration of 3 g ( g  = 9.8 m/s 2 ). [ABSTRACT FROM AUTHOR]

Published

2018

4. A multi-scale moisture diffusion coupled with stress model for composite materials.

Author

Wang, Jingze, Dai, Fuhong, and Ma, Li

Subjects

*COMPOSITE materials, *MATHEMATICAL models of strains & stresses, *MOISTURE, *FINITE element method, *FICK'S laws of diffusion, *MANAGEMENT

Abstract

In this paper, an equivalent model on coefficient of hygrothermal expansion for composite layer and a multi-scale model for calculating the strain and stress of composite plates are proposed. These two models also can be applied to thermal expansion problems and guide the structure design of the composite materials. A model descripting the coupling behavior of moisture diffusion and stress in composite laminates is proposed based on the second Fick’s law. Compared to other models, this model can accurately predict the anomalous behavior in the process of moisture absorption. A number of experiments and finite-element simulations are conducted to validate this model. A comparison of the model’s predictions with experimental data shows a good agreement. [ABSTRACT FROM AUTHOR]

Published

2017

5. A multi-stable lattice structure and its snap-through behavior among multiple states

Author

Dai, Fuhong, Li, Hao, and Du, Shanyi

Subjects

*LATTICE dynamics, *STRUCTURAL stability, *BISTABLE devices, *LAMINATED materials, *NUMERICAL analysis, *FINITE element method

Abstract

Abstract: This paper develops a multi-stable lattice structure consisting of tri-stable lattice cell which is made by bistable laminates. The multi-stable lattice structure with N tri-stable lattice cells, which can exhibit 2 N stable states, is successfully designed and fabricated. The critical loads snapping lattice structure are investigated by the experimental and finite element techniques. The method to simulate the behaviors of contact and constraint between the neighboring bistable laminates are presented. The snap through process of multi-stable lattice structures among multiple states are numerically simulated and experimentally validated. The multiple stabilities highlight the potential to achieve a smooth shape variation in the large area multi-stable structures. [Copyright &y& Elsevier]

Published

2013

6. Numerical and experimental study on morphing bi-stable composite laminates actuated by a heating method

Author

Li, Hao, Dai, Fuhong, and Du, Shanyi

Subjects

*BISMUTH, *LAMINATED materials, *RESIDUAL stresses, *NUMERICAL analysis, *FINITE element method, *THICKNESS measurement

Abstract

Abstract: This paper presents a new heating actuation method to induce the snap-through phenomenon of bi-stable laminates by manipulating the residual stress in laminates. The mechanism of the heating actuation method is analyzed, and the snap-through process is simulated by the finite element method. The heating actuation experiments on two types of laminates with different stacking sequences are performed. Good agreement is obtained between the experimental data and the finite element analysis (FEA). Subsequently, the heating actuation method is applied to several different bi-stable laminates and investigated by FEA. The FEA results show that this heating actuation method is an effective way to induce the snap-through phenomenon of bi-stable laminates of different thicknesses, sizes and shapes. [Copyright &y& Elsevier]

Published

2012

7. Three-dimensional Cure Simulation of Stiffened Thermosetting Composite Panels.

Author

Yue, Guangquan, Zhang, Boming, Dai, Fuhong, and Du, Shanyi

Subjects

THERMOSETTING composites, TEMPERATURE, AUTOCLAVES, HEAT transfer, FINITE element method, POLYESTERS

Abstract

Stiffened thermosetting composite panels were fabricated with co-curing processing. In the co-curing processing, the temperature distribution in the composite panels was nonuniform. An investigation into the three-dimensional cure simulation of T-shape stiffened thermosetting composite panels was presented. Flexible tools and locating tools were considered in the cure simulation. Temperature distribution in the composites was predicted as a function of the autoclave temperature history. A nonlinear transient heat transfer finite element model was developed to simulate the curing process of stiffened thermosetting composite panels. And a simulation example was presented to demonstrate the use of the present finite element procedure for analyzing composite curing process. The glass/polyester structure was investigated to provide insight into the nonuniform cure process and the effect of flexible tools and locating tools on temperature distribution. Temperature gradient in the intersection between the skin and the flange was shown to be strongly dependent on the structure of the flexible tools and the thickness of the skin. [ABSTRACT FROM AUTHOR]

Published

2010

8. The influence of lay-up design on the performance of bi-stable piezoelectric energy harvester.

Author

Pan, Diankun, Li, Yanqi, and Dai, Fuhong

Subjects

*BISMUTH alloys, *PIEZOELECTRICITY, *ENERGY harvesting, *LAMINATED materials, *FINITE element method

Abstract

Bi-stable composite laminates with piezoelectric transducers have been shown to capture energy over a wide frequency range and deliver significantly greater energy than resonant devices. In this work, the influence of lay-up design on the performance of bi-stable piezoelectric energy harvester (BPEH) based on bi-stable hybrid symmetric laminate (BHSL) is analyzed and verified. The initial voltage induced by stable configuration and longitudinal curvature of BPEH with different lay-up and hybrid width were calculated and analyzed by a static finite element analysis. The lay-up can vary initial voltage and longitudinal in opposite directions, and hybrid width can adjust these two variables in the same direction. The strain variations of piezoelectric transducer between two stable configurations were also analyzed. The initial voltage of BPEH depends on strain variations in the two directions. And then the finite element results are verified by experiment. Three types of BPEH were manufactured and actuated by two methods to measure their output powers. These BPEHs presented different dynamic responses, and the output powers under different vibration modes were measured. The highest output power of BPEH in this work is 42.2 mW and the highest power density is 78.1 mW/cm 3 . [ABSTRACT FROM AUTHOR]

Published

2017

9. Wind-induced vibration behavior of bistable hybrid symmetric laminate.

Author

Liu, Xiaohui, Li, Ming, and Dai, Fuhong

Subjects

*FLUID-structure interaction, *LATTICE Boltzmann methods, *WIND erosion, *WIND tunnel testing, *SOIL vibration, *ENERGY harvesting, *FINITE element method, *LAMINATED materials

Abstract

Bistable composite laminates have the potential advantage in the fields of wind energy harvesting and deformable wings, which involve many fluid–structure interaction issues. This paper presents the fluid–structure interaction analysis of a cantilevered bistable hybrid symmetrical laminate (BHSL) in the uniform wind. In this work, a finite element model based on the Lattice Boltzmann Method (LBM) is used to analyze the wind-induced response of the BHSL and its variations with respect to wind speed and laminate length. Then, the wind-induced vibration behavior of BHSL is verified by wind tunnel tests. The finite element analysis (FEA) results are in good agreement with the experimental results. The results show that as the wind speed increases, the BHSL transitions from a single-well vibration response to a cross-well vibration response. The wind-induced vibration analysis of BHSL will provide analytical methods for its application in deformable wings and energy harvesting for wind-induced vibration. [ABSTRACT FROM AUTHOR]

Published

2022

10. Piezoelectric wind energy harvester of bi-stable hybrid symmetric laminates.

Author

Liu, Xiaohui, Jia, Hexuan, Li, Ming, Li, Yanqi, Tao, Yan, and Dai, Fuhong

Subjects

*WIND power, *COMPOSITE structures, *FINITE element method, *WIND speed, *FLOW velocity

Abstract

In this work, a bistable piezoelectric wind energy harvester (BPEH) is proposed, which is primarily made of bistable hybrid symmetric laminate (BHSL) and PZT, manufactured through a curing process. The air-solid-electric coupled finite element analysis model is established to simulate the dynamic response behavior of the BPEH and investigate the effects of varying airflow velocities on the flow field characteristics and performance output. A series of experimental studies on BPEH were conducted in the wind speed range of 8.5 m/s-16.5 m/s. The results show that at a wind speed of 14.5 m/s, the BPEH has an optimum external load of 60 k Ω , a maximum power output of 7.21 mW and a maximum amplitude of 93.065 mm. Therefore, the simple structure of the harvester proposed in this work may open a new way for bistable composite structures to acquire wind energy widely in natural environments. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

11. Design of a multistable composite laminate by variable cross-section method and applying the displacement constraint.

Author

Jiang, Weihong, Li, Ming, Yao, Yongtao, and Dai, Fuhong

Subjects

*LAMINATED materials, *DISPLACEMENT (Mechanics), *FINITE element method, *FIBER-reinforced plastics, *CROSS-sectional method

Abstract

This paper presents a multistable variable cross-section laminate (MVCL), which is designed by applying the displacement constraint at the two opposing ends of the laminate. A theoretical model describing the MVCL as rigid bars connected with compliant hinges is built to predict the equilibrium configurations and snap-through loads of the MVCL. The snap-through process of the multistable structure is investigated via experiment and finite element analysis (FEA). Subsequently, the theoretical model is improved by simplifying the middle segment of the MVCL as an elastic beam. Good agreement is obtained between the experimental test, FEA, and improved theoretical model results. It is shown that the current approach can be successfully applied to predict the equilibrium configurations and snap-through loads of an MVCL. The snap-through loads can be adjusted by changing the middle segment length of an MVCL. [ABSTRACT FROM AUTHOR]

Published

2018

12. A bi-stable nonlinear energy sink using the cantilever bi-stable hybrid symmetric laminate.

Author

Li, Ming, Li, Yanqi, Liu, Xiaohui, and Dai, Fuhong

Subjects

*FINITE element method, *PERIODIC motion, *HARMONIC oscillators, *ENERGY consumption, *CANTILEVERS, *NONLINEAR oscillators

Abstract

This paper develops a new bi-stable nonlinear energy sink (BNES) only consisting of the cantilever bi-stable hybrid symmetric laminate (BHSL) and tip masses. This BNES has advantages of light weight, simple and reliable structure, since it does not need external devices or magnets to maintain its bi-stable characteristic. A finite element model (FEM) is developed to perform static and dynamic analyses of a harmonically excited linear oscillator coupled with BNES. An equivalent theoretical model is developed to model the coupled system based on the relationship between the restoring force and the displacement of BHSL. The Runge-Kutta method is used to perform direct numerical solutions. Different types of the steady-state response for BNES contain the local and global periodic motions, the local and global strongly modulated responses and chaos, while the primary object exhibits the periodic motion and the strongly modulated response. The effects of the excitation amplitude, the tip mass of BNES, the lay-up design and the length of BHSL are considered on the dynamic responses and vibration suppression efficiency of BNES. The results show adjusting these parameters and lay-up designs can improve the vibration suppression efficiency of BNES. In addition, the experimental prototype is prepared and verifies the rightness of the finite element model and theoretical model. [ABSTRACT FROM AUTHOR]

Published

2023

13. Study on stiffness distribution and failure mechanisms of the twisted profiled textile composite structure under cantilever load.

Author

Wang, Bing, Zhu, Jiaqi, Fang, Guodong, Huang, Jian, Liang, Jun, Dai, Fuhong, and Meng, Songhe

Subjects

*COMPOSITE structures, *CANTILEVERS, *STRAIN gages, *FINITE element method, *COMPRESSION fractures

Abstract

The mechanical behaviors of the twisted profiled textile composite structures with different twist angles were studied by using a novel cantilever beam experiment. The strain distributions on the upper surface of the specimen were monitored by using DIC. Several strain gauges were located at different positions on the lower surface of the specimen. With the increase of cantilever load, the deformation of twisted specimen experienced from the initial torsion to the bending-torsion coupling deformation. The effects of twist angles on stiffness and strength of the twisted composite structures were analyzed. The stiffness distributions of the twisted composite structures are determined by using the finite element analysis (FEA) combining with the experimental results. There is a cubic polynomial function relationship between the macroscopic local twisted angle and the local material stiffness. The stiffness and strength of 135° twisted specimen are higher than that of 45°twisted specimen. The dominant failure mode was the compression fracture at the edge of the lower right corner of the twisted specimen. This study can be helpful of guiding the design of the twisted profiled textile composites structures. [ABSTRACT FROM AUTHOR]

Published

2023

14. A quasi-zero-stiffness vibration isolator using bi-stable hybrid symmetric laminate.

Author

Li, Ming, Li, Yanqi, Liu, Xiaohui, and Dai, Fuhong

Subjects

*VIBRATION isolation, *LAMINATED materials, *FINITE element method, *RUNGE-Kutta formulas, *STEADY-state responses

Abstract

The quasi-zero-stiffness (QZS) vibration isolator is usually composed of positive and negative stiffness elements in parallel. The negative stiffness element usually requires specific constraint boundaries to form negative stiffness characteristics, which cannot meet the lightweight design of spacecraft structures. So the bi-stable hybrid symmetric laminate (BHSL) is presented as a negative stiffness element. A finite element model (FEM) is developed to carry out static and dynamic analyses of this vibration isolator. An equivalent theoretical model is developed based on the restoring force–displacement curve of BHSL. The approximate analytical solutions and direct numerical solutions are obtained by employing the averaging method and the Runge-Kutta method, respectively. Different types of the steady-state response are obtained, namely the symmetrical multi-harmonic response, the asymmetric multi-harmonic response and the single-harmonic response. There exists a small gap between the analytical solutions and the Runge-Kutta solutions or the FEM results only at the low frequency excitation due to the super-harmonics. The displacement transmissibility is used to quantify the vibration isolation performance of this vibration isolator. The experiment is designed to verify the theoretical and FEM models from static and dynamic analysis perspectives. The results show adjusting geometric parameters and lay-up designs can improve the vibration isolation performance. [ABSTRACT FROM AUTHOR]

Published

2022

15. Tool-part interaction effect on configurations of bistable composite shell with initial curvature.

Author

Li, Yanqi, Li, Ming, Liu, Xiaohui, and Dai, Fuhong

Subjects

*CURVATURE, *FINITE element method, *STOCHASTIC resonance, *RAYLEIGH model, *COMPOSITE structures

Abstract

Tool-part interaction during the manufacture of the bistable composite shells with initial curvature is inevitable, which has a noticeable influence on stable configurations. The effect of tool-part interaction is considered by introducing a shear layer whose parameters are determined by a series of experiments. This paper develops an analytical model with shear layer effect based on the Rayleigh-Ritz model to capture the configuration variation with bistable composite shell with initial curvature. The model reveals the rule of curvature change in different radii and plies, which provides a criterion for the existence of bistability. The results show tool-part interaction has a significant influence on thin bistable composite shells with initial curvature whose prediction accuracy is improved. The analytical predictions are verified by results based on the experiments and finite element models. Moreover, the influences of initial radius, cross-section angle, stacking sequence, and twisting response are analyzed. The twist behavior of two stable configurations is investigated, which can provide a guide for designing the bistable composite structures. [ABSTRACT FROM AUTHOR]

Published

2022