Finite Element Analysis of a Burnishing Process for the Inner Surface of a Cylinder

ASME Code stress assessment of pressure vessels in the power generation industry is usually done by finite element analysis using one of the two approaches. In the first, “shell-element” approach, vessels are modeled out of shell elements; primary plus bending and primary plus secondary stresses are taken directly from the finite element analysis results and the alternating stresses are based on primary plus secondary stresses prorated by respective stress concentration factors. The strength of the “shell-element” approach is its simplicity; its weakness is problematic modeling of the stress concentration and some modeling difficulties (varying wall thickness, nozzle/vessel connectivity, pressure applied to the mid-surface instead of to the inner surface.) In the second, “solid-element” approach, vessels are modeled out of solid elements; “linearized” stresses can not be taken directly from the finite element analysis results, first they must be linearized, and only then, can be compared against their allowable counterparts; the alternating stresses can be based directly on the outer/inner-surface-node-stresses, provided that the mesh of the model is fine enough to account for the stress concentration effect. The strength of the “solid-element” approach is its high accuracy; its weakness is the time consuming, sometimes ambiguous, stress linearization process. This paper proposes a modification of the “solid-element” approach, in which the time consuming linearization process is replaced by a modification of the original model. To do so, a vessel must be modeled out of quadratic 20 node solid elements; the mesh density of the model (on its surface and through thickness) must be adequate for stress concentration representation and the mesh lines in the thickness direction must be more or less normal to the surfaces. The results from this original model can be taken directly for fatigue evaluation. To obtain the “linearized” stresses the original model must be slightly modified, specifically the number of elements through thickness must be reduced to one, and the reduced integration technique is recommended. For such a modified model, the nodal stresses are equivalent to the “linearized stresses” of the original model. The equivalence is discussed on a model of a circular nozzle attached to a cylindrical vessel. The vessel loads are pressure and thermal expansion.

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Finite element analysis and design optimization of low plasticity burnishing process

The International Journal of Advanced Manufacturing Technology ◽

10.1007/s00170-013-5406-y ◽

2013 ◽

Vol 70 (5-8) ◽

pp. 1337-1354 ◽

Cited By ~ 31

Author(s):

Farough Mohammadi ◽

Ramin Sedaghati ◽

Ali Bonakdar

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Design Optimization ◽

Element Analysis ◽

Analysis And Design ◽

Low Plasticity Burnishing ◽

Burnishing Process

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FINITE ELEMENT ANALYSIS OF THE SPACE CREATED BY SPLIT SPINOUS PROCESSES IN DOUBLE-DOOR LAMINOPLASTY TO OPTIMIZE SHAPE OF AN ARTIFICIAL SPACER

Journal of Musculoskeletal Research ◽

10.1142/s0218957700000070 ◽

2000 ◽

Vol 04 (01) ◽

pp. 47-54 ◽

Cited By ~ 4

Author(s):

Shigeru Hirabayashi ◽

Kiyoshi Kumano

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Vertebral Body ◽

Clinical Case ◽

Spinous Process ◽

Lateral Deviation ◽

Element Analysis ◽

Spinous Processes ◽

Inner Surface ◽

The Difference

In double-door laminoplasty, several types of artificial spinous process spacers have been used instead of grafted bone from the iliac crest. However, inadequate contact between the spacer and the spinous process has recently been reported. From the observation during operation, we suspect that the main cause of the inadequate contact is the difference in shape between the spacer and the widened space created by the split spinous processes. The purpose of this study was to investigate the shape of the widened space by means of a finite element analysis in order to confirm our observation objectively and to provide a shape design of a spacer adapting to the space. Half-sectioned finite element models of the second cervical (C2) vertebra and the C6 vertebra were made from both the computed tomography (CT) of a clinical case and a plastic model of a cervical spine. The finite element model was designed to have almost the same size and shape as those of the genuine vertebra in the clinical case. Since cancellous bone and soft tissues were thought not to meaningfully influence the rigidity of the model, the model was made of only cortical bone with a thickness of 1.5 mm. The x-axis was defined as the lateral direction of the vertebral body, the y-axis as the anteroposterior direction of the vertebral body and the z-axis as the craniocaudal direction along the posterior margin of the vertebral body. The boundary conditions were fixed at the inner surface of the half-sectioned vertebral body. A force of 100 N was applied to the inner surface of the half-sectioned spinous process (to the cranial side and the caudal side, 50 N each) in the direction of the x-axis. The lateral deviation of each split spinous process was defined as the degree of deviation in the x-axis direction. The degree of lateral deviation of each split spinous process was analyzed in two types of models with and without making a lateral gutter 4 mm wide along the z-axis direction. The lateral deviation at the cranial side was larger than that at the caudal side in both the C2 and C6 vertebrae. The difference between the lateral deviation at the cranial side and the caudal side of each vertebra was larger in the type of model with the lateral gutter than in the type of model without it. It was confirmed that the shape of the widened space is trapezoidal in not only the axial but also frontal sections. In conclusion, the optimal shape of a spacer adapting to the widened space in double-door laminoplasty is trapezoidal in not only the axial but also frontal sections.

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The finite element analysis of stress concentration factor for the V-notch on the inner surface of cylindrical shell

2010 The 2nd International Conference on Industrial Mechatronics and Automation ◽

10.1109/icindma.2010.5538153 ◽

2010 ◽

Author(s):

Ni Yanguang ◽

Guo Guangli

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Cylindrical Shell ◽

Stress Concentration ◽

Stress Concentration Factor ◽

Concentration Factor ◽

Element Analysis ◽

The Finite Element Analysis ◽

Inner Surface

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Analysis of the Thermal Fatigue Cracking of 316L Model Pipe Components Under Cyclic Down-Shocks

Volume 3: Design and Analysis ◽

10.1115/pvp2005-71738 ◽

2005 ◽

Cited By ~ 1

Author(s):

Elena Paffumi ◽

Karl-Fredrik Nilsson ◽

Nigel Taylor

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Fatigue Cracking ◽

Analysis Procedure ◽

Crack Model ◽

Low Carbon ◽

Element Analysis ◽

Test Pieces ◽

Inner Surface ◽

Cylindrical Test

Cylindrical test pieces of low-carbon austenitic steel 316L are subjected to cyclic thermal loads in a specially designed rig. Intermittent stops allowed measurement of cycles to initiation and of the propagation of the networks of axial and circumferential cracks. These results have been used to validate an analysis procedure, based on a sequentially coupled thermal-stress finite element analysis. It is found that the initiation life can be reliably predicted from the stain range at the inner surface, while a simplified semi-elliptical crack model best described the subsequent crack growth.

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