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- Title
Effect of Fluid–Structure Interaction on Vibration and Deflection Analysis of Generally Orthotropic Submerged Micro-plate with Crack Under Thermal Environment: An Analytical Approach.
- Authors
Soni, Shashank; Jain, N. K.; Joshi, P. V.; Gupta, Ankur
- Abstract
Purpose: To develop a new analytical model for vibration analysis of cracked-submerged orthotropic micro-plate affected by fibre orientation and thermal environment. Methods: The proposed analytical model is based on Kirchhoff's classical thin plate theory and the size effect is introduced using the modified couple stress theory. Effect of crack is deduced using appropriate crack compliance coefficients based on line spring model while the effect of thermal environment is introduced in terms of thermal in-plane moments and forces. The coupling of shear and normal stresses for fibre orientation is represented using the coefficient of mutual influence. The fluid forces associated with its inertial effects are added in the governing differential equation to incorporate the fluid–structure interaction effect. Results: The results are presented for frequency response as affected by different fibre orientation, crack length, crack location, level of submergence, temperature variation and material length-scale parameter for simply supported boundary condition. Furthermore, to study the phenomenon of shifting of primary resonance in a cracked micro-plate, the classical relations for central deflection of plate is also proposed. Conclusions: The results show that the fundamental frequency of micro-plate decreases by the presence of crack and thermal environment and this decrease in frequency is further intensified by the presence of surrounding fluid medium in present study. Another important conclusion is that with increase in temperature variation the reduction in frequency at 45° of fibre orientation is less when compared to 0 and 90° for both intact and cracked orthotropic plates.
- Subjects
DEFLECTION (Mechanics); ACOUSTIC vibrations; ORTHOTROPIC plates; FREQUENCY (Linguistics); SHEAR (Mechanics)
- Publication
Journal of Vibration Engineering & Technologies, 2020, Vol 8, Issue 5, p643
- ISSN
2523-3920
- Publication type
Article
- DOI
10.1007/s42417-019-00135-y