Interaction of a spherical shockwave and an elastic circular cylindrical shell

Artsykova, N. A.; Pertsev, A. K.; Yakovlev, S. V.

doi:10.1007/s10778-005-0006-7

Int Appl Mech

2004

DOI: 10.1007/s10778-005-0006-7

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Interaction of a spherical shockwave and an elastic circular cylindrical shell

N. A. Artsykova

A. K. Pertsev

S. V. Yakovlev

Abstract: The paper studies the interaction of a spherical shock wave with an elastic circular cylindrical shell immersed in an infinite acoustic medium. The shell is assumed infinitely long. The wave source is quite close to the shell, causing deformation of just a small portion of the shell, which makes it possible to represent the solution by a double Fourier series. The method allows the exact determination of the hydrodynamic forces acting on the shell and analysis of its stress state. Some characteristic features … Show more

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Cited by 4 publications

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“…The validity of these relations was proved in [11,12]. Issues associated with the interaction of differently shaped bodies in a fluid were addressed, for example, in [13,16,18,20,22].The present paper studies an axisymmetric system consisting of an infinitely long, thin-walled, elastic, cylindrical shell that contains a potential flow of perfect compressible fluid and a vibrating spherical inclusion. Our analysis of the phenomena occurring in this system will be mainly based on the monographs and publications [1, 3, 5, 7, 8, 13, 20, etc.…”

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confidence: 99%

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Interaction of differently shaped bodies in a potential flow of perfect compressible fluid: Axisymmetric internal problem

2006

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An approach is proposed to investigate an axisymmetric system consisting of an infinite thin elastic cylindrical shell that contains a potential flow of perfect compressible fluid and a periodically vibrating spherical inclusion. The approach emerged as part of a project devoted to developing methods to bring plugged oil wells back into production by the Vibration Theory Department of the S. P. Timoshenko Institute of Mechanics. This mathematical approach allows transforming the general solutions to equations of mathematical physics from one coordinate system to another to obtain an exact analytical solution (in the form of Fourier series) to interaction problems for systems of rigid and elastic bodies Keywords: Kirchhoff-Love hypotheses, wave equation, thin-walled elastic cylindrical shell, perfect compressible fluid, spherical inclusion, potential flowIntroduction. The behavior of structural members interacting with a compressible liquid or gas has recently become of great interest. Among the variety of structure-fluid interaction problems, there are problems that are not restricted to the interaction of various structures (bodies) with the fluid, but are also concerned with the interaction between these structures.The interaction of bodies of similar geometry in one medium or another has been studied most adequately because the fact that components of the general solution are described in the same coordinate system makes it much easier to find this solution. This allows using the summation theorems for special functions to express the general solution in the coordinate systems fixed to the bodies. Techniques of solving such problems are outlined, for example, in [1,10,14,19,23].A completely different situation arises with the general solution for interacting bodies of different geometries in one medium or another that is at rest or moving with a certain velocity. Since the components of the general solution are described in different coordinate systems, the summation theorems for special functions are not sufficient to express the general solution in one coordinate system. For this purpose, use is made of expressions that relate cylindrical and spherical wave functions. The validity of these relations was proved in [11,12]. Issues associated with the interaction of differently shaped bodies in a fluid were addressed, for example, in [13,16,18,20,22].The present paper studies an axisymmetric system consisting of an infinitely long, thin-walled, elastic, cylindrical shell that contains a potential flow of perfect compressible fluid and a vibrating spherical inclusion. Our analysis of the phenomena occurring in this system will be mainly based on the monographs and publications [1, 3, 5, 7, 8, 13, 20, etc.].To analyze the dynamic behavior of the hydroelastic system, we will simultaneously solve equations describing the motion of the fluid and the shell. These equations are taken from the linear theory of potential flows and the theory of thin elastic shells based on the Kirchhoff-Love hypotheses. The solution can...

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mentioning

confidence: 99%

“…The validity of these relations was proved in [11,12]. Issues associated with the interaction of differently shaped bodies in a fluid were addressed, for example, in [13,16,18,20,22].…”

mentioning

confidence: 99%

Interaction of differently shaped bodies in a potential flow of perfect compressible fluid: Axisymmetric internal problem

2006

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“…In addition to periodic publications (such as [12,13]), these results are partially generalized in the monograph [1] and review [14]. Of the recent studies on nonstationary continuum mechanics, it is worthwhile to mention the papers [9,16,17]. There are hydroelectroelastic systems where the piezoelectric transducer and the generator are spaced far apart and connected by a long cable.…”

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confidence: 99%

Generation of nonstationary waves by a thick-walled piezoceramic cylinder excited by electric signals

Babaev

2005

Int Appl Mech

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Coupled electroelasticity theory, acoustic approximation, and two-wire transmission line theory are used to study the generation of waves by a submerged cylindrical piezoelectric transducer connected by a cable to a source of nonstationary electric signals. The problem is reduced to a system of integral Volterra equations using the Laplace transform and analytical inversion of boundary conditions. The results of calculations for different cable lengths are presented Keywords: electroelasticity, piezoelectricity, generation of nonstationary waves, two-wire line Most studies on electroelasticity and hydroelectroelasticity have been carried out for time-periodic dynamic processes [5,8]. The significance of these results does not detract from the importance of such problems in a nonstationary formulation. This is due to the wide application of piezoceramic transducers that operate in pulse modes. There was a series of studies in which such problems were formulated assuming a potential difference between conductive coatings of the transducer. In addition to periodic publications (such as [12,13]), these results are partially generalized in the monograph [1] and review [14]. Of the recent studies on nonstationary continuum mechanics, it is worthwhile to mention the papers [9,16,17]. There are hydroelectroelastic systems where the piezoelectric transducer and the generator are spaced far apart and connected by a long cable. The influence of such a wire line on the transient characteristics was analyzed in [10,11,15], where the transducer is thin-walled and its behavior is described by the theory of electroelastic shells based on the Kirchhoff-Love hypotheses [5].The present paper addresses the problem of wave generation by a thick-walled, infinitely long, cylindrical piezoelectric transducer immersed in a perfect compressible liquid. The solid conductive coatings on the inner and outer surfaces of the transducer are connected by a two-wire line with distributed parameters (cable) to a source of nonstationary electric signals. The medium inside the cylinder is vacuum. A similar problem where a transducer is excited by a signal supplied directly to its electrodes was solved in [2].The dynamic processes in the hydroelectroelastic system in question are modeled using coupled electroelasticity theory [5], acoustic approximation, and two-wire transmission line theory [3].We will use the following notation: u r is the radial displacement of the transducer; σ rr and σ θθ are the radial and circumferential components of the stress tensor; Ψ and D r are the potential and electric displacements of the electric field; C E 11 , C E 13 , and C E 33 are the elastic moduli; ρ c is density; e 33 and e 31 are the piezoelectric moduli; d 33 is a piezoelectric constant; ε 33 s is the dielectric permittivity of the material; R 1 and R 2 are the outer and inner radii of the cylinder; r is the radial coordinate; ϕ is the velocity potential of the ambient acoustic medium; p and V r are the pressure and velocity in this medium; ρ and c are its ...

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“…The equations of motion (1)-(5), the initial conditions (6), and the boundary conditions (7), (8) constitute the statement of an axisymmetric nonlinear initial-boundary-value problem of elasticity for a rib-reinforced cylindrical shell with an initial deflection under dynamic loading.…”

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confidence: 99%

On the deformation of a ribbed cylindrical shell with initial deflection under dynamic loading

Shul’ga

Bogdanov

2005

Int Appl Mech

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The finite-difference method with explicit time coordinate is used to study the dynamic stress-strain state of a cylindrical shell with ribs and initial deflections. A specific numerical example is considered to trace the time evolution of longitudinal and transverse displacements for different parameters of the initial deflection Keywords: cylindrical shell, rib, axisymmetric dynamic load, initial deflection, uniform difference scheme Introduction. Initial imperfections have a strong effect on the deformation of shells, especially under external forces (static or dynamic) disturbing the equilibrium state or steady motion. Inevitable initial imperfections in shells are aggravated with manufacturing inhomogeneities (holes, recesses, cover plates, ribs, etc.). In the present paper, we develop a numerical method for axisymmetric elastic analysis of reinforced cylindrical shells with local inhomogeneities such as circular ribs and initial deflections under dynamic loads. We will use the variational Hamilton-Ostrogradskii principle to derive nonlinear Timoshenko equations describing the vibrations of shells with large deflections. The resulting nonlinear initial-boundary-value problem will be solved by the finite-difference method. The integro-interpolation method will be used to construct a difference scheme that is uniform in the space coordinate, despite the discontinuity of the derivative (with respect to this coordinate) of the displacements of the mid-surface where the stiffening ribs are located. An advantage of this approach is its capability of being algorithmized and numerically implemented. A specific numerical example will be considered to trace the time evolution of longitudinal and transverse displacements for different parameters of the initial deflection.1. Nonlinear Axisymmetric Vibration Equations for a Reinforced Cylindrical Shell with Initial Deflection. Problem Formulation. A reinforced shell is considered a system consisting of a casing (shell itself) and ribs rigidly connected to it along the contact lines. The contact conditions have the following integral form [1]:

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Interaction of a spherical shockwave and an elastic circular cylindrical shell

Cited by 4 publications

References 6 publications

Interaction of differently shaped bodies in a potential flow of perfect compressible fluid: Axisymmetric internal problem

Interaction of differently shaped bodies in a potential flow of perfect compressible fluid: Axisymmetric internal problem

Generation of nonstationary waves by a thick-walled piezoceramic cylinder excited by electric signals

On the deformation of a ribbed cylindrical shell with initial deflection under dynamic loading

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