Strength of a Cylindrical Shell under Internal Pressure Reinforced by Rings Made of Different Materials and Optimization of Structure. 2nd Report. Research for Optimum Structure.

Strain growth is a phenomenon observed in the elastic response of containment vessels subjected to internal blast loading. The local dynamic response of a containment vessel may become larger in a later stage than its response in the earlier stage. In order to understand the possible mechanisms of the strain growth phenomenon in a cylindrical vessel, dynamic elastic responses of a finite-length cylindrical shell with different boundary conditions subjected to internal pressure pulse are studied by finite-element simulation using LS-DYNA. It is found that the strain growth in a finite-length cylindrical shell with sliding–sliding boundary conditions is caused by nonlinear modal coupling. Strain growth in a finite-length cylindrical shell with free–free or simply supported boundary conditions is primarily caused by the linear modal superposition, possibly enhanced by the nonlinear modal coupling. The understanding of these strain growth mechanisms can guide the design of cylindrical containment vessels.

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Strength of a Cylindrical Shell under Internal Pressure Reinforced by Rings Made of Different Materials and Optimization of Structure. 1st Report, Study on Behavoir of Stress and Deformation.

TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A ◽

10.1299/kikaia.60.1222 ◽

1994 ◽

Vol 60 (573) ◽

pp. 1222-1229

Author(s):

Keinosuke Inoue

Keyword(s):

Cylindrical Shell ◽

Internal Pressure ◽

Stress And Deformation

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Dynamic Behavior of a Nonlinear Viscoelastic Cylindrical Shell Subjected to Internal Pressure

Journal of Elastomers & Plastics ◽

10.1177/009524439602800103 ◽

1996 ◽

Vol 28 (1) ◽

pp. 34-62

Author(s):

D. M. Darwish ◽

John R. Cannon

Keyword(s):

Cylindrical Shell ◽

Internal Pressure ◽

Dynamic Behavior ◽

Viscoelastic Cylindrical Shell ◽

Nonlinear Viscoelastic

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Design Equation for Minimum Required Thickness of a Cylindrical Shell Subject to Internal Pressure Based on Von Mises Criterion

Volume 3: Design and Analysis ◽

10.1115/pvp2019-93155 ◽

2019 ◽

Author(s):

James Lu ◽

Barry Millet ◽

Kenneth Kirkpatrick ◽

Bryan Mosher

Keyword(s):

Cylindrical Shell ◽

Internal Pressure ◽

Yield Criterion ◽

Design Equation ◽

Shell Wall ◽

Section Viii ◽

Von Mises Yield Criterion ◽

Von Mises ◽

Division 2 ◽

Shell Wall Thickness

Abstract Design equation (4.3.1) for the minimum required thickness of a cylindrical shell subjected to internal pressure in Part 4 “design by rule (DBR)” of the ASME Boiler and Pressure Vessel Code, Section VIII, Division 2 [1] is based on the Tresca Yield Criterion, while design by analysis (DBA) in Part 5 of the Division 2 Code is based on the von Mises Yield Criterion. According to ASME PTB-1 “ASME Section VIII – Division 2 Criteria and Commentary”, the difference in results is about 15% due to use of the two different criteria. Although the von Mises Yield Criterion will result in a shell wall thickness less than that from Tresca Yield Criterion, Part 4 (DBR) of ASME Division 2 adopts the latter for a more convenient design equation. To use the von Mises Criterion in lieu of Tresca to reduce shell wall thickness, one has to follow DBA rules in Part 5 of Division 2, which typically requires detailed numeric analysis performed by experienced stress analysts. This paper proposes a simple design equation for the minimum required thickness of a cylindrical shell subjected to internal pressure based on the von Mises Yield Criterion. The equation is suitable for both thin and thick cylindrical shells. Calculation results from the equation are validated by results from limit load analyses in accordance with Part 5 of ASME Division 2 Code.

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Free Vibration and Elastic Critical Load of Functionally Graded Material Thin Cylindrical Shells Under Internal Pressure

International Journal of Structural Stability and Dynamics ◽

10.1142/s0219455418501389 ◽

2018 ◽

Vol 18 (11) ◽

pp. 1850138 ◽

Cited By ~ 8

Author(s):

Yueyang Han ◽

Xiang Zhu ◽

Tianyun Li ◽

Yunyan Yu ◽

Xiaofang Hu

Keyword(s):

Cylindrical Shell ◽

Free Vibration ◽

Internal Pressure ◽

Critical Load ◽

Natural Frequency ◽

Functionally Graded Material ◽

Present Method ◽

Cylindrical Shells ◽

Functionally Graded ◽

Graded Material

An analytical approach for predicting the free vibration and elastic critical load of functionally graded material (FGM) thin cylindrical shells filled with internal pressured fluid is presented in this study. The vibration of the FGM cylindrical shell is described by the Flügge shell theory, where the internal static pressure is considered as the prestress term in the shell equations. The motion of the internal fluid is described by the acoustic wave equation. The natural frequencies of the FGM cylindrical shell under different internal pressures are obtained with the wave propagation method. The relationship between the internal pressure and the natural frequency of the cylindrical shell is analyzed. Then the linear extrapolation method is employed to obtain the elastic critical load of the FGM cylindrical shell from the condition that the increasing pressure has resulted in zero natural frequency. The accuracy of the present method is verified by comparison with the published results. The effects of gradient index, boundary conditions and structural parameters on the elastic critical load of the FGM cylindrical shell are discussed. Compared with the experimental and numerical analyses based on the external pressure, the present method is simple and easy to carry out.

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