Bulge testing of copper and niobium tubes for hydroformed RF cavities

Kim, H.S.; Sumption, M.D.; Susner, Michael A.; Lim, Hojun; Collings, E. W.

doi:10.1016/j.msea.2015.12.033

Cited by 4 publications

(5 citation statements)

References 18 publications

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“…The experimental tensile and bulge data of Nb samples heat treated for 2h/1000°C in previous work was used for this study [9]. For the Nb samples heat treated multiple times, numerical analysis based on the microstructure and tensile test was performed.…”

Section: Methodsmentioning

confidence: 99%

“…We first examined the validity of various analytical models for obtaining the flow stress curve from the tube bulge test results [8]. Subsequently, the constitutive relationships of tubular materials were obtained from the tensile and tube bulge tests using a previous verified and selected analytical model [9]. The continuum numerical simulation analyses were performed using these constitutive equations.…”

Section: Evolution Of the Modelling Approachmentioning

confidence: 99%

“…Tables I and II list the sample dimension, preparation, testing, and numerical simulation analyses performed in this and related studies. Some data from [9] were used in this study.…”

Section: Evolution Of the Modelling Approachmentioning

confidence: 99%

“…In Tables Table I Dimensions of starting Cu alloy and Nb tubes Table II Materials, experiments, and numerical simulations included in this and related [9] studies Table III Material parameters for CP-FEM Figure 1. Evolution of our research on the hydroforming of tubular materials Figure 2.…”

Section: Continuum Simulationmentioning

confidence: 99%

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Development of a multi-scale simulation model of tube hydroforming for superconducting RF cavities

Kim

Sumption

Bong

et al. 2017

Materials Science and Engineering: A

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This work focuses on finite element modeling of the hydroforming process for niobium tubes intended for use in superconducting radio frequency (SRF) cavities. The hydroforming of tubular samples into SRF-relevant shapes involves the complex geometries and loading conditions which develop during the deformation, as well as anisotropic materials properties. Numerical description of the process entails relatively complex numerical simulations. A crystal plasticity (CP) model was constructed that included the evolution of crystallographic orientation during deformation as well as the anisotropy of tubes in all directions and loading conditions. In this work we demonstrate a multi-scale simulation approach which uses both microscopic CP and macroscopic continuum models. In this approach a CP model (developed and implemented into ABAQUS using UMAT) was used for determining the flow stress curve only under bi-axial loading in order to reduce the computing time. The texture of the materials obtained using orientation imaging microscopy (OIM) and tensile test data were inputs for this model. Continuum FE analysis of tube hydroforming using the obtained constitutive equation from the CP modeling was then performed and compared to the results of hydraulic bulge testing. The results show that high quality predictions of the deformation under hydroforming of Nb tubes can be obtained using CP-FEM based on their known texture and the results of tensile tests. The importance of the CP

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Section: Methodsmentioning

confidence: 99%

Section: Evolution Of the Modelling Approachmentioning

confidence: 99%

“…Tables I and II list the sample dimension, preparation, testing, and numerical simulation analyses performed in this and related studies. Some data from [9] were used in this study.…”

Section: Evolution Of the Modelling Approachmentioning

confidence: 99%

Section: Continuum Simulationmentioning

confidence: 99%

See 2 more Smart Citations

Development of a multi-scale simulation model of tube hydroforming for superconducting RF cavities

Kim

Sumption

Bong

et al. 2017

Materials Science and Engineering: A

Self Cite

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“…The above equations 2.1 and 2.2 lay the foundation to calculate the circumferential and longitudinal stress components and fit the flow stress curve, which are first derived by Woo et al [50] and then used in many studies [23,56,66,[88][89][90][91][92][93]. Fuchizawa et al [53] improve this stress model by taking into account the wall thickness of metal tubes, and following re-searchers [54,55,58,59,63,71,72,81,87,[94][95][96][97][98][99][100] recommend this new formula because it is more in line with the actual situation.…”

Section: Analytical Modelmentioning

confidence: 99%

The automatic optimization of metal forming processes: Inverse identification of constitutive parameters for tubular materials based on hydraulic bulge test

Zhang¹

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Tube hydroforming process is an advanced manufacturing technology for complex thin-walled tubular components applied in the aerospace, aviation and automotive industries. The fluid medium is used as a pressure source to deform tubular materials into the desired shape in this process. Finite element model is a popular method to describe and analyze this innovative process. A successful tube hydroforming operation and reliable finite element simulation depend heavily on the accurate characterization of mechanical properties of the incoming tubular materials. As a result, it is critical to determine these material parameters utilizing suitable experimental tests and evaluation procedures.This thesis presents the development of an automatic inverse parameter identification framework combining finite element models with gradientbased algorithms and its utilization in determining material parameters for thin-walled metallic tubes. The main principle of the inverse framework is the minimization of the objective function defined as the least square error between simulated results and experimental observations. Finite element methods are used to describe and analyze the experimental testing process and gradient-based optimization techniques adjust the input material parameters in the model until the calculated results have a good agreement with the experimental measurements.The feasibility and performance of this proposed inverse framework are demonstrated through applying it to different tube hydraulic bulge tests with fixed and forced end-conditions to identify the flow stress data of thin-walled aluminium tubes. The bulge height, axial compressive force and pole thickness are measured during the experiment and input into the inverse strategy. Based on the obtained material values, finite element simulated models of hydroforming processes are established and used to predict the shape properties of final products. The comparison between simulated predictions and experimental data shows that the developed inverse strategy provide a robust and effective method to determine material properties for thin-walled metallic tubes.Furthermore, a theoretical analysis is integrated into the inverse frameiii work, and the two are recombined into a hybrid strategy to avoid local minimums in the parameter identification process. The new strategy is tested by the experimental data from fixed and forced tube hydraulic bulge tests. As a result of this research, it is possible to conclude that the novel hybrid strategy does not depend heavily on the initial points and can improve the computation robustness and identify more accurate constitutive parameters for tubular materials.

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Off-axis electron holography of bacterial cells and magnetic nanoparticles in liquid

Prozorov

Almeida

Kovács

et al. 2017

J. R. Soc. Interface.

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17The mapping of electrostatic potentials and magnetic fields in liquids using electron holography has 18 been considered to be unrealistic. Here, we show that hydrated cells of Magnetospirillum 19 magneticum strain AMB-1 and assemblies of magnetic nanoparticles can be studied using off-axis 20 electron holography in a fluid-cell specimen holder within the transmission electron microscope. 21Considering that the holographic object and reference wave both pass through liquid, the recorded

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Bulge testing of copper and niobium tubes for hydroformed RF cavities

Cited by 4 publications

References 18 publications

Development of a multi-scale simulation model of tube hydroforming for superconducting RF cavities

Development of a multi-scale simulation model of tube hydroforming for superconducting RF cavities

The automatic optimization of metal forming processes: Inverse identification of constitutive parameters for tubular materials based on hydraulic bulge test

Off-axis electron holography of bacterial cells and magnetic nanoparticles in liquid

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