Towards a rationally based elastic-plastic shell buckling design methodology

The currently valid worldwide standards allow for taking into consideration plastic deformations in order to achieve a higher degree of utilization. The maximum plastic strains, which can be allowed for steel pipes subjected to internal pressure and additional loads, are particularly interesting. In this paper results of investigations on the elasto-plastic bearing behavior of steel pipelines subjected to internal pressure and bending are presented. Four-point bending tests on eight steel pipes were carried out in order to make the buckling analysis in the elasto-plastic range possible. Finite-element-models were checked by test results for the application on buried pipelines. Taking into account bedding conditions of the pipeline in the soil was made possible. Furthermore, an analytical method based on the differential equation for beams with longitudinal tensile force and variable bending stiffness was developed. It is suitable to determine the elasto-plastic bearing capacity for internal pressure and bending. The collapse due to plastic shell buckling is considered by a limit criterion based on critical strains.

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Expansion/contraction of a spherical elastic/plastic shell revisited

Continuum Mechanics and Thermodynamics ◽

10.1007/s00161-014-0365-6 ◽

2014 ◽

Vol 27 (3) ◽

pp. 483-494

Author(s):

Sergei Alexandrov ◽

Alexander Pirumov ◽

Yeau-Ren Jeng

Keyword(s):

Plastic Shell ◽

Elastic Plastic

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Analysis of numerical calculation of elastic-plastic shell collapse with growing instability

Engineering Journal Science and Innovation ◽

10.18698/2308-6033-2020-3-1962 ◽

2020 ◽

Author(s):

А.S. Novoseltsev ◽

A.V. Babkin

Keyword(s):

External Surface ◽

Stationary Problem ◽

Explosive Loading ◽

Surface Forces ◽

Maximum Pressure ◽

Plastic Shell ◽

Explosive Load ◽

Elastic Plastic ◽

Time Of Application ◽

Pressure Fall

The paper presents research of the collapse of the elastic-plastic shell under external surface forces simulating explosive loading by mathematical simulation using numerical methods. The problem was solved in two-dimensional curved geometries as a non-stationary problem of continuum mechanics. We applied the Wilkins Lagrangian method. The instability of the shell was initiated by harmonic surface perturbations on the outer or inner surfaces. The characteristics of the explosive loading were also changed: the maximum pressure, pressure fall time constant, and the time of application of the explosive load. The size of instability was determined by the deviation of the disturbed surface or the boundary of the jet-forming layer from the cylindrical one. We have established the parameters of the shell and the impulse loading on the shell, which affect most strongly the growth of instability during collapse.

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Shakedown and Fatigue Evaluations of Overlay Cladding on Reactor Pressure Vessels

ASME 2011 Pressure Vessels and Piping Conference: Volume 3 ◽

10.1115/pvp2011-57233 ◽

2011 ◽

Author(s):

Seiji Asada ◽

Harutaka Suzuki ◽

Toshiya Saruwatari

Keyword(s):

Stress Distribution ◽

Base Metal ◽

Design Methodology ◽

Evaluation Method ◽

Pressure Vessels ◽

Stress Evaluation ◽

Alternative Design ◽

Elastic Plastic ◽

Plastic Analysis ◽

Reactor Pressure

Overlay cladding is classified to non-pressure boundary. Not only the ASME Boiler & Pressure Vessels Code Section III [1] but also the JSME Design and Construction Code [2] prescribe that no structural strength shall be attributed to cladding and the presence of the cladding shall be considered with respect to both the thermal analysis and the stress analysis. This means the codes do not require stress evaluation for overlay cladding itself. If overlay cladding has a fatigue crack, the crack may grow and extend to the base metal. Thus overlay cladding may give an influence on the integrity of base metal in the pressure boundary. The thermal expansion of stainless steel cladding is different from that of base metal made of low alloy steel, and this difference causes discontinuity of stress distribution between the cladding and the base metal. It is questionable that a stress evaluation line is set on such stress distribution including discontinuity between the cladding and the base metal. An evaluation method based on elastic-plastic analysis is preferable to evaluate such portion. ASME B&PV Sec.III and Sec.VIII, Div. 2 [3] have plastic analysis provisions. Also the JSME D&C Code issued a code case on alternative design methodology by using elastic-plastic finite element analysis for Class 1 vessels [4, 5]. In this paper, shakedown, fatigue and environmental fatigue evaluations are performed for the overlay cladding of direct vessel injection nozzle of Reactor Pressure Vessel by using the JSME Code Case on the alternative design methodology.

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Overview of Code Case on Alternative Design Methodology by Using Elastic-Plastic Finite Element Analysis for Class 1 Vessels in the JSME Rules on Design and Construction

ASME 2010 Pressure Vessels and Piping Conference: Volume 1 ◽

10.1115/pvp2010-25525 ◽

2010 ◽

Cited By ~ 2

Author(s):

Seiji Asada ◽

Takashi Hirano ◽

Tetsuya Nagata ◽

Naoto Kasahara

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Design Methodology ◽

Evaluation Method ◽

Plastic Collapse ◽

Element Analysis ◽

Alternative Design ◽

Elastic Plastic ◽

Plastic Analysis ◽

Design And Construction

An alternative design methodology by using elastic-plastic finite element analysis has been developed and published as a code case of the JSME Rules on Design and Construction for Nuclear Power Plants (The First Part: Light Water Reactor Structural Design Standard). This code case applies elastic-plastic analysis to evaluation of such failure modes as plastic collapse, shakedown, thermal ratchet and fatigue. Advantages of this evaluation method are no use of stress linearization/classification, consistent use of Mises equivalent stress and applicability to complex 3-dimentional structures which are hard to be treated by the conventional stress classification method. The evaluation method for plastic collapse consists of the Lower Bound Approach Method, Twice-Elastic-Slope Method and Elastic Compensation Method. Cyclic Yield Area (CYA) criterion based on elastic analysis is applied to screening evaluation of shakedown limit instead of secondary stress evaluation, and elastic-plastic analysis is performed when the CYA screening criterion is not satisfied. Strain concentration factors can be directly calculated based on elastic-plastic analysis.

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Buckling Design of Confined Steel Cylinders Under External Pressure

Volume 5: High Pressure Technology; Nondestructive Evaluation Division; Student Paper Competition ◽

10.1115/pvp2009-77216 ◽

2009 ◽

Author(s):

Daniel Vasilikis ◽

Spyros A. Karamanos

Keyword(s):

Design Methodology ◽

Surrounding Medium ◽

Structural Response ◽

External Pressure ◽

Design Guidelines ◽

Efficient Design ◽

Imperfection Sensitivity ◽

Initial Imperfections ◽

Shell Buckling ◽

Nonlinear Finite Elements

Thin-walled steel cylinders surrounded by an elastic medium, when subjected to uniform external pressure may buckle. In the present paper, using a two dimensional model with nonlinear finite elements, which accounts for both geometric and material nonlinearities, the structural response of those cylinders is investigated, towards developing relevant design guidelines. Special emphasis is given on the response of the confined cylinders in terms of initial imperfections; those are considered in the form of initial out-of-roundness of the cylinder and as an initial gap between the cylinder and the medium. Furthermore, the effects of the deformability of the surrounding medium are examined. The results indicate significant imperfection sensitivity and a strong dependency on the medium stiffness. The numerical results are employed to develop a simple and efficient design methodology, which is compatible with the recent general provisions of European design recommendations for shell buckling, and could be used for design purposes.

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Accurate Determination of Plastic Collapse Loads From Finite Element Analyses

Journal of Pressure Vessel Technology ◽

10.1115/1.4002770 ◽

2010 ◽

Vol 133 (1) ◽

Cited By ~ 6

Author(s):

C. Doerich ◽

J. M. Rotter

Keyword(s):

Finite Element ◽

Accurate Determination ◽

Shell Structures ◽

Collapse Mechanism ◽

Plastic Shell ◽

Plastic Collapse ◽

Collapse Load ◽

Plastic Limit ◽

Elastic Plastic ◽

Collapse Strength

When computational modeling is used to evaluate the true strength of an imperfect elastic-plastic shell structure, the current European standard on shell structures requires that two reference strengths are always determined: the linear bifurcation load and the plastic limit (plastic collapse) load. These two loads are used in more than one way to characterize the strength of all imperfect elastic-plastic systems. Where parametric studies of a problem are being undertaken, it is particularly important that these two loads are accurately defined, since all other strengths will be related to them. For complex problems in shell structures, it is not possible to develop analytical solutions for the plastic collapse strength, and finite element analysis must be used. Unfortunately, because a collapse mechanism often requires the development of very extensive plasticity involving large local strains, and the collapse load is simply at the end of a slowly rising load-deflection curve, it is sometimes difficult for the analyst to accurately determine this plastic collapse strength. This paper describes two methods, based on modifications of the Southwell plot, of obtaining very accurate evaluations of the plastic limit load, irrespective of whether a fairly complete plastic strain field has developed or not. These two methods allow plastic collapse limit loads to be reported with great precision.

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