Evaluation of the modal parameters of two shafts, one manufactured with a composite materials and the other manufactured with structural Steel, through the implementation of a technique of Operational Modal Analysis (OMA)
Evaluación de los parámetros modales de dos ejes, uno fabricado con materiales compuestos y otro en acero estructural, mediante la implementación de una técnica de Análisis Modal Operacional (OMA)
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Nova-Agudelo, F. ., Sánchez-Acevedo, H. G., & Villegas-Bermudez, D. . (2020). Evaluation of the modal parameters of two shafts, one manufactured with a composite materials and the other manufactured with structural Steel, through the implementation of a technique of Operational Modal Analysis (OMA). Respuestas, 25(2), 83–92. https://doi.org/10.22463/0122820X.2188
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Abstract
This paper focuses on obtaining the modal parameters of two shafts in operation. The research has been planned using a shaft with composite materials, carbon fibers in an epoxy matrix and an axis manufactured with structural steel A36. The objective is to assess and validate the implementation of a technique of Operational Modal Analysis (OMA) in axes of different materials, and at the same time, compare the dynamic answer of the elements involved in the research.
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References
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R. Ebrahimi, M. Esfahanian, and S. Ziaei-rad, “Vibration modeling and modification of cutting platform in a harvest combine by means of operational modal analysis,” Measurement, vol. 46, no. 10, pp. 3959–3967, 2013.
F. Lafleur, M. Thomas, and V. H. Vu, “Case study of Operational Modal Analysis (OMA) of a large hydroelectric generator”. Conference: 29Th seminar on machinery vibration, Canadian Machinery Vibration Association (CMVA), 2011.
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B. Vij, “ScienceD Direct esign and d Compa arison of f the Stre ength an d Efficie ency of Drive Sh haft mad e of Ste eel and C Composi ite Mater rials Muralidhar,” 2018.
O. Montagnier and C. Hochard, “Dynamics of a supercritical composite shaft mounted on viscoelastic supports,” J. Sound Vib., vol. 333, no. 2, pp. 470–484, 2014.
T. C. Henry and B. T. Mills, “Optimized design for projectile impact survivability of a carbon fi ber composite drive shaft,” Compos. Struct., vol. 207, no. August 2018, pp. 438–445, 2019.
S. Koch, M. Peter, and J. Fleischer, “Lightweight design and manufacturing of composites for high-performance electric motors,” ProcediaCIRP, vol. 66, pp. 283–288, 2017.
H. G. Sánchez, J. Uscátegui, and S. Gómez, “Metodología para la detección de fallas en una estructura entramada metálica empleando las técnicas de análisis modal y PSO” Rev. UIS Ing, vol. 16, no. 2, pp. 43–50, 2017.
A. Mbarek et al., “Comparison of experimental and operational modal analysis on a back to back planetary gear,” Mech. Mach. Theory, vol. 0, pp. 1–22, 2018.
A. Teter and J. Gawryluk, “Experimental modal analysis of a rotor with active composite blades,” Compos. Struct., vol. 153, pp. 451–467, 2016.
A. Cigada, A. Caprioli, M. Redaelli, and M. Vanali, “Vibration Testing at Meazza Stadium : Reliability of Operational Modal Analysis to Health,” vol. 22, no. 4, pp. 228–237, 2009.
A. C. Altunis and A. Bayraktar, “Earthquake Behavior of Berke Arch Dam Using Ambient Vibration Test Results,” vol. 26, no. December, pp. 780–792, 2012.
L. Zhang, T. Wang, and Y. Tamura, “A frequency – spatial domain decomposition ( FSDD ) method for operational modal analysis,” Mech. Syst. Signal Process., vol. 24, no. 5, pp. 1227–1239, 2010.
H. G. Sánchez, F. R. Nova, A. Gonzalez, “Implementation of the Operational Modal Analysis technique in a power transmission shaft Implementation of the Operational Modal Analysis technique in a power transmission shaft”. Journal of Physics: Conference Series, vol. 1247, conference 1, 2019.
R. Ebrahimi, M. Esfahanian, and S. Ziaei-rad, “Vibration modeling and modification of cutting platform in a harvest combine by means of operational modal analysis,” Measurement, vol. 46, no. 10, pp. 3959–3967, 2013.
F. Lafleur, M. Thomas, and V. H. Vu, “Case study of Operational Modal Analysis (OMA) of a large hydroelectric generator”. Conference: 29Th seminar on machinery vibration, Canadian Machinery Vibration Association (CMVA), 2011.
I. Gómez, E. Maldonado, G. Chio Cho, “Pruebas de Vibración Ambiental en Puentes”. Rev. UIS Ing, vol. 9, no. 1, pp. 55–68, 2010.
A. E. Castillo and R. L. Boroschek, “Uso del método de frecuencia no paramétrica y SSI para la identificación de propiedades modales de edificios”. Congreso Chileno de Sismología e Ingeniería Antisísmica, IX Jornadas, Concepción Chile, 2005
