Free vibration and buckling analysis of composite cylindrical shells conveying hot fluid
TL;DR: In this paper, a coupled fluid structure interaction problem is analyzed using semi-analytical finite element method involving composite cylindrical shells conveying hot fluid for free vibration and buckling behavior.
About: This article is published in Composite Structures.The article was published on 2003-04-01. It has received 34 citations till now. The article focuses on the topics: Herschel–Bulkley fluid & Vortex-induced vibration.
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TL;DR: In this article , the free and forced vibro-acoustic characteristics of fluid-filled laminated cylindrical shell under initial hydrostatic pressure are analyzed, and the vibration equation of shell is based on Love's theory, and filled fluid is adopted acoustic wave equation.
1 citations
TL;DR: In this paper, the instable fluid velocity in the pipes with internal nanofluid is studied and the fluid is mixed by SiO2, AL2O3, CuO and TiO2 nanoparticles.
Abstract: In this article, the instable fluid velocity in the pipes with internal nanofluid is studied. The fluid is mixed by SiO2, AL2O3, CuO and TiO2 nanoparticles in which the equivalent characteristic of nanofluid is calculated by rule of mixture. The force induced by the nanofluid is assumed in radial direction and is obtained by Navier-Stokes equation considering viscosity of nanofluid. The displacements of the structure are described by first order shear deformation theory (FSDT). The final equations are calculated by Hamilton's principle. Differential quadrature method (DQM) is utilized for presenting the instable fluid velocity. The influences of length to radius ratio of pipe, volume fraction, diameter and type of nanoparticles are shown on the instable fluid velocity. The outcomes are compared with other published articles where shows good accuracy. Numerical results indicate that with enhancing the volume fraction of nanoparticles, the instable fluid velocity is increased. In addition, the instable fluid velocity of SiO2-water is higher than other types of nanoparticles assumed in this work.
1 citations
Cites methods from "Free vibration and buckling analysi..."
...[6] Zhang Y.L., Reese J.M., Gorman D.G., 2002, Initially tensioned orthotropic cylindrical shells conveying fluid: A vibration analysis, Journal of Fluids and Structures, 161: 53–70,. [7] Kadoli R., Ganesan N., 2003 وFree vibration and buckling analysis of composite cylindrical shells conveying hot fluid, Composite Structures, 60: 19–32....
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...The interaction of fluid on the cylindrical shells with internal fluid flow was calculated by Kadoli and Ganesan [7] based on finite element method in order to buckling and vibration responses....
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...The interaction of fluid on the cylindrical shells with internal fluid flow was calculated by Kadoli and Ganesan [7] based on finite element method in order to buckling and vibration responses....
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...[5] Jayaraj K., Ganesan N., Chandramouli P., 2002, A semi-analytical coupled finite element formulation for composite shells conveying fluids, Journal of Sound and Vibration, 258: 287–307....
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Journal Article•
TL;DR: In this paper, free vibration of a foam-core smart composite cylindrical shell (SCCS) filled with a non-viscous compressible fluid, subjected to combined electro-thermo-mechanical loads is investigated.
Abstract: In this study, free vibration of a foam-core orthotropic smart composite cylindrical shell (SCCS) filled with a non-viscous compressible fluid, subjected to combined electro-thermo-mechanical loads is investigated. Piezoelectric polymeric cylindrical shell, is made from polyvinylidene fluoride (PVDF) and reinforced by armchair double walled boron nitride nanotubes (DWBNNTs). Characteristics of the equivalent composite are determined using micro-electro-mechanical models. The poly ethylene (PE) foam-core is modeled based on Winkler and Pasternak foundations. Employing the charge equation for coupling electrical and mechanical fields, the problem is turned into an eigenvalue one, for which analytical frequency equations are derived considering free electrical and simply supported mechanical boundary conditions at circular surfaces at either ends of the cylindrical shell. The influence of electric potential generated, filled-fluid, orientation angle of DWBNNTs, foam-core and a few other parameters on the resonance frequency of SCCS are investigated. Results show that SCCS and consequently the generated Φ improve sensor and actuator applications in several process industries, because it not only increases the vibration frequency, but also extends economic viability of the smart structure.
1 citations
Cites methods from "Free vibration and buckling analysi..."
...Free vibration and buckling analysis of composite cylindrical shells conveying hot fluid was proposed by Kadoli and Ganesan [29]....
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...[29] Kadoli R., Ganesan N., 2003, Free vibration and buckling analysis of composite cylindrical shells conveying hot fluid, Composite Structures 60: 19–32....
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TL;DR: In this article, the smart buckling control of concrete beams armed by zinc oxide (ZnO) nanoparticles is studied. But the authors focus on the smart control of the concrete beam.
Abstract: This paper deals with the smart buckling control of concrete beams armed by zinc oxide (ZnO) nanoparticles. As it is known, the ZnO nanoparticles are smart, and hence, the concrete beam is subjecte...
Cites methods from "Free vibration and buckling analysi..."
...Free vibration of composite cylindrical shell containing fluid flow was performed by Kadoli and Ganesan (2003)....
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References
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Book•
25 Feb 2014
TL;DR: In this article, the first volume of the Fluid-Structure Interaction (FSI) series, Volume 1 covers the fundamentals and mechanisms giving rise to flow-induced vibration, with a particular focus on the challenges associated with pipes conveying fluid.
Abstract: The first of two books concentrating on the dynamics of slender bodies within or containing axial flow, Fluid-Structure Interaction, Volume 1 covers the fundamentals and mechanisms giving rise to flow-induced vibration, with a particular focus on the challenges associated with pipes conveying fluid. This volume has been thoroughly updated to reference the latest developments in the field, with a continued emphasis on the understanding of dynamical behaviour and analytical methods needed to provide long-term solutions and validate the latest computational methods and codes. In this edition, Chapter 7 from Volume 2 has also been moved to Volume 1, meaning that Volume 1 now mainly treats the dynamics of systems subjected to internal flow, whereas in Volume 2 the axial flow is in most cases external to the flow or annular. * Provides an in-depth review of an extensive range of fluid-structure interaction topics, with detailed real-world examples and thorough referencing throughout for additional detail. * Organized by structure and problem type, allowing you to dip into the sections that are relevant to the particular problem you are facing, with numerous appendices containing the equations relevant to specific problems. * Supports development of long-term solutions by focusing on the fundamentals and mechanisms needed to understand underlying causes and operating conditions under which apparent solutions might not prove effective.
1,175 citations
TL;DR: In this article, a review of the dynamics of pipes conveying fluid is presented, with a focus on the nonlinear and chaotic dynamics of pipe conveying systems, and a selective review of recent work on this problem is presented.
419 citations
TL;DR: A combined experimental-numerical method to evaluate powder thermal properties in laser powder bed fusion MSEC2018 (2018) A simplified and efficient analysis of Morton Effect GT2018(2018) Thermal Transport in Thorium Dioxide IMECE2017 (2017).
Abstract: Topic Collections Related Content Customize your page view by dragging and repositioning the boxes below. Related Journal Articles Filter by Topic > Homogenization of Reticulated Structures Appl. Mech. Rev (July, 2001) Research Advances in the Dynamic Stability Behavior of Plates and Shells: 1987–2005—Part I: Conservative Systems Appl. Mech. Rev (March, 2007) Historical review of Zig-Zag theories for multilayered plates and shells Appl. Mech. Rev (May, 2003) [+] View More Related Proceedings Articles Filter by Topic > A Combined Experimental-Numerical Method to Evaluate Powder Thermal Properties in Laser Powder Bed Fusion MSEC2018 (2018) A Simplified and Efficient Analysis of Morton Effect GT2018 (2018) Thermal Transport in Thorium Dioxide IMECE2017 (2017) [+] View More Related eBook Content Various Structures Design of Plate and Shell Structures> Chapter 12 Axially Loaded Members Design & Analysis of ASME Boiler and Pressure Vessel Components in the Creep Range> Chapter 2 Members in Bending Design & Analysis of ASME Boiler and Pressure Vessel Components in the Creep Range> Chapter 3 [+] View More Sections PDF Email Share Get Citation Get Alerts Some tools below are only available to our subscribers or users with an online account. SEARCH ADVANCED SEARCH Search Applied Mechanics Applied Mechanics Heat Transfer About ASME Digital Collection Email Alerts Library Service Center ASME Membership Contact Us Publications Permissions /Reprints Privacy Policy Terms of Use © 2019 ASME The American Society of Mechanical Engineers Journals Submit a Paper Announcements Call for Papers Title History Conference Proceedings About ASME Conference Publications Conference Proceedings Author Guidelines Conference Publications Toolbox eBooks About ASME eBooks Press Advisory & Oversight Committee Book Proposal Guidelines This site uses cookies. By continuing to use our website, you are agreeing to our privacy policy. | Accept Loading [Contrib]/a11y/accessibility-menu.js
173 citations
TL;DR: In this paper, the effects of temperature on buckling and post-buckling behavior of reinforced and unstiffened composite plates or cylindrical shells are considered, and equilibrium equations are formulated for a shell subjected to the simultaneous action of a thermal field and an axial loading.
Abstract: Effects of temperature on buckling and post-buckling behavior of reinforced and unstiffened composite plates or cylindrical shells are considered. First, equilibrium equations are formulated for a shell subjected to the simultaneous action of a thermal field and an axial loading. These equations are used to predict a general form of the algebraic equations describing the post-buckling response of a shell. Conditions for the snap-through of a shell subjected to thermomechanical loading are formulated. As an example, the theory is applied to prediction of post-buckling response of flat large-aspect-ratio panels reinforced in the direction of their short edges. 19 refs.
73 citations