Lower Bound Methods in Elastic-Plastic Shakedown Analysis

Several methods were proposed in recent years that allow the efficient calculation of elastic and elastic-plastic shakedown limits. This paper establishes a uniform framework for such methods that are based on perfectly-plastic material behavour, and demonstrates the connection to Melan’s theorem of elastic shakedown. The paper discusses implications for simplified methods of establishing shakedown, such as those used in the ASME Code. The framework allows a clearer assessment of the limitations of such simplified approaches. Application examples are given.

Lower Bound Methods in Elastic-Plastic Shakedown Analysis

10.1115/1.4025941 ◽

2014 ◽

Vol 136 (2) ◽

Author(s):

Wolf Reinhardt ◽

Reza Adibi-Asl

Keyword(s):

Lower Bound ◽

Plastic Material ◽

Material Behavior ◽

Shakedown Analysis ◽

Elastic Plastic ◽

Perfectly Plastic ◽

Efficient Calculation ◽

Asme Code ◽

Elastic Shakedown ◽

Several methods were proposed in recent years that allow the efficient calculation of elastic and elastic-plastic shakedown limits. This paper establishes a uniform framework for such methods that are based on perfectly-plastic material behavior, and demonstrates the connection to Melan's theorem of elastic shakedown. The paper discusses implications for simplified methods of establishing shakedown, such as those used in the ASME Code. The framework allows a clearer assessment of the limitations of such simplified approaches. Application examples are given.

On the Conditions to Prevent Plastic Shakedown of Structures: Part II—The Plastic Shakedown Limit Load

Journal of Applied Mechanics ◽

10.1115/1.2900750 ◽

1993 ◽

Vol 60 (1) ◽

pp. 20-25 ◽

Cited By ~ 26

Author(s):

Castrenze Polizzotto

Keyword(s):

Mechanical Load ◽

Plastic Material ◽

Limit State ◽

Limit Load ◽

Companion Paper ◽

Material Structure ◽

Perfectly Plastic ◽

Shakedown Limit ◽

Elastic Shakedown ◽

Following the results of a companion paper, the concept of plastic shakedown limit load is introduced for an elastic-perfectly plastic material structure subjected to combined cyclic (mechanical and/or kinematical) loads and steady (mechanical) load. Static and kinematic approaches are available for the computation of this load, in perfect analogy with the classic (elastic) shakedown limit load. The plastic shakedown limit state of the structure being in an impending alternating plasticity collapse is studied and a number of interesting features of it are pointed out.

Shakedown Analysis of Nuclear Components Using Linear and Nonlinear Methods

10.1115/1.4000505 ◽

2010 ◽

Vol 132 (2) ◽

Cited By ~ 2

Author(s):

Dan Vlaicu

Keyword(s):

Lower Bound ◽

Plastic Material ◽

Nonlinear Material ◽

The Finite Element Method ◽

Shakedown Analysis ◽

Periodic Loading ◽

Elastic Plastic Material ◽

Compensation Approach ◽

Elastic Shakedown ◽

Loaded Structure

A cyclically loaded structure made of elastic-plastic material is considered as an elastic shakedown if plastic straining occurs in the first few cycles and the sequent response is wholly elastic. In this paper, the finite element method is used to develop upper and lower bound limits for the elastic shakedown of structures under periodic loading conditions. Linear methods using elastic compensation approach and the residual stress method derived from Melan’s theorem are used to generate the lower bound limit for the shakedown load, while the upper bound is found through a method derived from Koiter’s theorem. Furthermore, the results are compared with cycle-by-cycle method based on nonlinear material properties.

Elastic-Shakedown Analysis of Axisymmetric Nozzles

10.1115/1.1613301 ◽

2003 ◽

Vol 125 (4) ◽

pp. 365-370 ◽

Cited By ~ 20

Author(s):

Martin Muscat ◽

Donald Mackenzie

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Lower Bound ◽

Pressure Vessel ◽

Element Analysis ◽

Shakedown Analysis ◽

Elastic Plastic ◽

Section Viii ◽

Elastic Shakedown ◽

Division 2

An investigation of the shakedown behavior of axisymmetric nozzles under internal pressure is presented. The analysis is based on elastic-plastic finite element analysis and Melan’s lower bound shakedown theorem. Calculated shakedown pressures are compared with values from the literature and with the ASME Boiler and Pressure Vessel Code Section VIII Division 2 primary plus secondary stress limits. Results obtained by the lower bound method are also verified by cyclic elastic-plastic finite element analysis.

On the Conditions to Prevent Plastic Shakedown of Structures: Part I—Theory

Journal of Applied Mechanics ◽

10.1115/1.2900739 ◽

1993 ◽

Vol 60 (1) ◽

pp. 15-19 ◽

Cited By ~ 38

Author(s):

Castrenze Polizzotto

Keyword(s):

Mechanical Load ◽

Plastic Material ◽

Perfectly Plastic ◽

Shakedown Theory ◽

Elastic Perfectly Plastic ◽

Plastic Shakedown ◽

Steady Load

For a structure of elastic perfectly plastic material subjected to a given cyclic (mechanical and/or kinematical) load and to a steady (mechanical) load, the conditions are established in which plastic shakedown cannot occur whatever the steady load, and thus the structure is safe against the alternating plasticity collapse. Static and kinematic theorems, analogous to those of classical shakedown theory, are presented.

An elastic–plastic shakedown analysis of fretting wear

Wear ◽

10.1016/s0043-1648(00)00508-1 ◽

2001 ◽

Vol 247 (1) ◽

pp. 41-54 ◽

Cited By ~ 67

Author(s):

S. Fouvry ◽

Ph. Kapsa ◽

L. Vincent

Keyword(s):

Fretting Wear ◽

Shakedown Analysis ◽

Elastic Plastic ◽

Strength Limit of Thimble Tube With Material Plasticity Under Bending Moment and Axial Compression Force

Volume 3: Nuclear Fuel and Material, Reactor Physics, and Transport Theory ◽

10.1115/icone26-81468 ◽

2018 ◽

Author(s):

Hisashi Koike ◽

Masaji Mori ◽

Daisuke Fujiwara ◽

Takashi Shimomura

Keyword(s):

Fuel Assembly ◽

Seismic Event ◽

Plastic Material ◽

Bending Moment ◽

Normal Operation ◽

Beam Model ◽

Allowable Limit ◽

Perfectly Plastic ◽

Asme Code ◽

Elastic Perfectly Plastic

The thimble tube, which is made of Zircaly-4, is one of the main components of a PWR fuel assembly. The thimble tube has an important role as a structural member of the skeleton. Another role of the thimble tube is to guide a rod cluster control assembly (RCCA) for insertion during the reactor operation, and the function has to be assured not only in normal operation but in a seismic event. In a horizontal seismic event, the fuel assembly vibrates laterally, which gives bending moment to the thimble tube. In addition, axial compressive force acts on the thimble tube in a vertical seismic event. The integrity of the thimble tube has to be maintained while this force and moment act. Mitsubishi has confirmed by the elastic stress analysis that the stress of the thimble tube is lower than the limit value requested for the seismic event. The stress evaluation method is based on the ASME code. The ASME code also describes the limit analysis which is available when the predicted stress is beyond elastic region of the material. In the analysis, the material is assumed to be elastic-perfectly plastic, and the maximum load that the structure can carry is calculated. For the reason mentioned above, the allowable limit of the thimble tube should be determined as a function between the force and the moment. We are planning to examine the allowable limit experimentally. As a step before testing, an analytical approach for the limit is discussed in this paper. Firstly, the allowable limit is calculated by a beam model assuming elastic-perfectly plastic material, based on the ASME code. Secondly, a 3D model analysis with elastic-plastic material is performed to predict the practical strength. Based on the comparison with the analysis using elastic-perfectly plastic material, ASME based limit is considerably conservative compared with the one with the actual stress-strain curve. Conversely, this means there is enough room to rationalize the allowable limit. As the future work, the experiment will be conducted to obtain the practical limit of the thimble tube and to verify the analysis results.

A Study of Elastic-Plastic Boundary Propagation in a Tube of Elastic-Perfectly Plastic Material Under Dynamic Loadings of Different Types

Journal of Mathematical Sciences ◽

10.1007/s10958-019-04172-6 ◽

2019 ◽

Vol 237 (3) ◽

pp. 473-484

Author(s):

P. V. Tishin

Keyword(s):

Plastic Material ◽

Elastic Plastic ◽

Perfectly Plastic ◽

Dynamic Loadings ◽

Different Types ◽

Elastic Perfectly Plastic

Ratcheting Assessment of a Fixed Tube Sheet Heat Exchanger Subject to In Phase Pressure and Temperature Cycles

10.1115/1.4003623 ◽

2011 ◽

Vol 133 (4) ◽

Cited By ~ 1

Author(s):

Khosrow Behseta ◽

Donald Mackenzie ◽

Robert Hamilton

Keyword(s):

Heat Exchanger ◽

Plastic Material ◽

Sheet Thickness ◽

Peak Stress ◽

Material Model ◽

Tube Sheet ◽

Hardening Material ◽

Perfectly Plastic ◽

Inelastic Analysis ◽

An investigation of the cyclic elastic-plastic response of an Olefin plant heat exchanger subject to cyclic thermal and pressure loading is presented. Design by analysis procedures for assessment of shakedown and ratcheting are considered, based on elastic and inelastic analysis methods. The heat exchanger tube sheet thickness is nonstandard as it is considerably less than that required by conventional design by formula rules. Ratcheting assessment performed using elastic stress analysis and stress linearization indicates that shakedown occurs under the specified loading when the nonlinear component of the through thickness stress is categorized as peak stress. In practice, the presence of the peak stress will cause local reverse plasticity or plastic shakedown in the component. In nonlinear analysis with an elastic–perfectly plastic material model the vessel exhibits incremental plastic strain accumulation for 10 full load cycles, with no indication that the configuration will adapt to steady state elastic or plastic action, i.e., elastic shakedown or plastic shakedown. However, the strain increments are small and would not lead to the development of a global plastic collapse or gross plastic deformation during the specified life of the vessel. Cyclic analysis based on a strain hardening material model indicates that the vessel will adapt to plastic shakedown after 6 load cycles. This indicates that the stress categorization and linearization assumptions made in the elastic analysis are valid for this configuration.

Case Study of Shakedown Evaluation of a Shell With Nozzle Based on Elastic-Plastic Analysis

Volume 1B: Codes and Standards ◽

10.1115/pvp2017-65492 ◽

2017 ◽

Author(s):

Jun Shen ◽

Heng Peng ◽

Liping Wan ◽

Yanfang Tang ◽

Yinghua Liu

Keyword(s):

Temperature Change ◽

Plastic Material ◽

Material Model ◽

Elastic Plastic ◽

Perfectly Plastic ◽

Plastic Analysis ◽

Elastic Perfectly Plastic ◽

Temperature Loads ◽

The Impact

In the past, shakedown evaluation was usually based on the elastic method that the sum of the primary and secondary stress should be limited to 3Sm or the simplified elastic-plastic analysis method. The elastic method is just an approximate analysis, and the rigorous evaluation of shakedown normally requires an elastic-plastic analysis. In this paper, using an elastic perfectly plastic material model, the shakedown analysis was performed by a series of elastic-plastic analyses. Taking a shell with a nozzle subjected to parameterized temperature loads as an example, the impact of temperature change on the shakedown load was discussed and the shakedown loads of this structure at different temperature change rates were also obtained. This study can provide helpful references for engineering design.