Design and vibration damping study of a novel variable stiffness composite based on electrorheological fluid

Abstract

We propose a novel variable stiffness composite (VSERF) made of soft materials, featuring a three-layer fluid-membrane composite structure with electrorheological fluid encapsulated in a thin film. The overall shear storage modulus of this composite can be described using a viscoelastic model. Under a 3 kV/mm electric field, the electrorheological fluid transitions from a liquid to a quasi-solid state, resulting in a 25-fold increase in the overall shear storage modulus of the VSERF, allowing for controllable changes in stiffness. We used VSERF as a variable stiffness element in a vibration absorber. When the electric field strength was increased from 0 to 3 kV/mm, the natural frequency of the absorber shifted from 13 to 21 Hz, indicating that vibrations within this range of excitation frequencies could be effectively controlled. The damping ratio of the VSERF absorber is below 0.189, and its transmissibility peak exceeds 2.9, ensuring that the absorber can effectively transmit vibrations from the excitation source to the mass, enhancing vibration damping. Consequently, VSERF shows promising potential for energy absorption and vibration damping applications.

Keywords

Electrorheological fluid variable stiffness composite viscoelastic model vibration absorber

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References

Alexander

Agafonov

ASKA

(2020) Electrorheological properties of polydimethylsiloxane/tio 2-based composite elastomers. Polymers 12(9): E2137.

Cassagnau

(2003) Payne effect and shear elasticity of silica-filled polymers in concentrated solutions and in molten state. Polymer 12(9): 2455–2462.

Dong

, et al. (2024) Medium-high frequency vibration control of an industrial pipeline using squeeze-mode magnetorheological dampers. Journal of Intelligent Material Systems and Structures 35(6): 621–632.

Yaying

Weijia

(2014) Sedimentation upon different carrier liquid in giant electrorheological fluid and its application. Frontiers in Materials 1: 24.

Yining

Jiheng

, et al. (2022) Design and analysis of a stiffness and damping regulator based on giant electrorheological fluid under multilayered squeeze mode. Journal of Sound & Vibration 527: 116864.

Jamari

SKM

Ubaidillah

Aziz

SAA

, et al. (2020) Mini review on effect of coatings on the performance of magnetorheological materials. Proceedings of the 6th International Conference and Exhibition on Sustainable Energy and Advanced Materials4: 191–199.

Leng

Feng

Ning

, et al. (2022) Analysis and design of a semi-active x-structured vibration isolator with magnetorheological elastomers. Mechanical Systems & Signal Processing 181: 109492.

Liang

Huang

Zhou

, et al. (2023) Efficient electrorheological technology for materials, energy, and mechanical engineering: From mechanisms to applications. Engineering 24: 151–171.

Liang

Yuan

, et al. (2018) Research progress of electrorheological smart fluid(article). Materials China 37(10): 803–810.

10.

Makhaniok

Korobko

Zhurauski

(2015) Rheological models of mechanical behavior of electrorheological fluids under different electric field strength. Journal of Intelligent Material Systems and Structures 26(14): 1776–1781.

11.

Mutra

Srinivas

(2018) Semi-active vibration control of high-speed rotor system with electrorheological bearing fluid. MATEC Web of Conferences211: 14008.

12.

Rong

Kunquan

Zhaohui

, et al. (2023) Induced dipole dominant giant electrorheological fluid. Chinese Physics B 32: 548–557.

13.

Serra-Aguila

Puigoriol-Forcada

J. M.

Reyes

Menacho

(2019) Viscoelastic models revisited: Characteristics and interconversion formulas for generalized kelvin-voigt and maxwell models. Journal of Mechanics 35(6): 1191–1209.

14.

Sun

Chen

Yang

, et al. (2014) The development of an adaptive tuned magnetorheological elastomer absorber working in squeeze mode. Smart Materials and Structures 23(7): 075009.

15.

Sun

Huang

Wang

, et al. (2020) Design, testing and modelling of a tuneable ger fluid damper under shear mode. Smart Materials and Structures 29(8): 085011.

16.

Kexiang

Quan

Guang

, et al. (2011) Vibration characteristics of electrorheological elastomer sandwich beams. Smart Materials and Structures 20(5): 055012.

17.

Dongwon

Chanhun

Dongil

, et al. (2022) Magnetorheological damper for vibration reduction in a robot arm. Intelligent Service Robotics 15: 671–678.

18.

Jiarui

Yaoyang

Jianwei

, et al. (2022) Development and vibration control of frequency adjustable tuned mass damper based on magnetorheological elastomer. Materials 15(5): 1829.

19.

Shisha

Xuepeng

Hao

, et al. (2013) Experimental research about the application of er elastomer in the shock absorber. Biotechnology, Chemical and Materials Engineering II, PTS 1 and 2641: 371–376.

20.

Lujun

Binghui

Yong

, et al. (2021) Active vibration control technology for low-speed wind tunnel test models. Journal of Nanjing University of Aeronautics & Astronautics 53(4): 591–597.