PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS

Sharma, Shamurailatpam Vivekananda; Gladston, Hemalatha; Ebanezer, Arunraj

doi:10.13167/2023.27.4

Advances in Civil and Architectural Engineering, Vol. 14 No. 27, 2023.

Original scientific paper

https://doi.org/10.13167/2023.27.4

PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS

Shamurailatpam Vivekananda Sharma orcid.org/0000-0003-4923-621X ; Karunya Institute of Technology and Sciences, Department of Civil Engineering, 641114, Coimbatore, India
Hemalatha Gladston ; Karunya Institute of Technology and Sciences, Department of Civil Engineering, 641114, Coimbatore, India
Arunraj Ebanezer ; Karunya Institute of Technology and Sciences, Department of Civil Engineering, 641114, Coimbatore, India

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APA 6th Edition

Sharma, S.V., Gladston, H. & Ebanezer, A. (2023). PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS. Advances in Civil and Architectural Engineering, 14 (27), 44-66. https://doi.org/10.13167/2023.27.4

MLA 8th Edition

Sharma, Shamurailatpam Vivekananda, et al. "PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS." Advances in Civil and Architectural Engineering, vol. 14, no. 27, 2023, pp. 44-66. https://doi.org/10.13167/2023.27.4. Accessed 19 May 2024.

Chicago 17th Edition

Sharma, Shamurailatpam Vivekananda, Hemalatha Gladston and Arunraj Ebanezer. "PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS." Advances in Civil and Architectural Engineering 14, no. 27 (2023): 44-66. https://doi.org/10.13167/2023.27.4

Harvard

Sharma, S.V., Gladston, H., and Ebanezer, A. (2023). 'PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS', Advances in Civil and Architectural Engineering, 14(27), pp. 44-66. https://doi.org/10.13167/2023.27.4

Vancouver

Sharma SV, Gladston H, Ebanezer A. PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS. Advances in Civil and Architectural Engineering [Internet]. 2023 [cited 2024 May 19];14(27):44-66. https://doi.org/10.13167/2023.27.4

IEEE

S.V. Sharma, H. Gladston and A. Ebanezer, "PERFORMANCE EVALUATION OF A SMALL-SCALE MAGNETORHEOLOGICAL DAMPER FOR CIVIL ENGINEERING APPLICATIONS", Advances in Civil and Architectural Engineering, vol.14, no. 27, pp. 44-66, 2023. [Online]. https://doi.org/10.13167/2023.27.4

Abstract

Magnetorheological dampers (MRDs) are devices that adjust their damping properties in response to an external magnetic field. Large-scale MRDs have been successfully used as vibration control devices in structures. This study focuses on modelling and optimizing an MRD using COMSOL Multiphysics. Various parameters, such as coil turns and current, are optimized to achieve the maximum flux value in the MRD. The simulation yielded a maximum magnetic flux of 0,44 T with 500 coil turns. Based on the optimized MRD parameters, a numerical equation is then used to calculate the total damping force. The maximum numerical and experimental damping forces corresponding to a 2,0 A current were 989,39 and 1004,63 N, respectively. The numerical damping force is then compared to the experimental results to validate the accuracy of the model. The MRD is integrated into a scaled-down reinforced concrete frame and subjected to a cyclic loading test for performance evaluation. The results show that the MR dampers improve the performance of the frame structure, increasing its load-carrying capacity and energy dissipation by 19,45 % and 20,43 %, respectively. The findings of the study provide valuable insights into the behaviour of MRDs and their optimization using numerical simulations, as well as highlight the importance of experimental validation for accurate prediction of the performance of MRDs in practical civil engineering applications.

Keywords

Magnetorheological fluids; Magnetic circuit; Magneto static analysis; FEM; Magnetic-flux density; Force-Displacement; Force-Velocity; Damping force; Energy Dissipation

Hrčak ID:

308737

URI

https://hrcak.srce.hr/308737

Publication date:

6.10.2023.

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Advances in Civil and Architectural Engineering, Vol. 14 No. 27, 2023.

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