Hot Deformation Resistance of an AA5083 Alloy under High Strain Rate

Chen, Shi Rong; Wu, Chung Yung; Ou, Yi Liang; Yeh, Yen Liang

doi:10.4028/www.scientific.net/kem.626.553

Cited by 6 publications

(4 citation statements)

References 11 publications

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“…Various aspects of the high-temperature performance of this alloy have been investigated in previous studies [22][23][24][25][26][27][28][29]. Summers et al [22,23] studied post-fire residual mechanical properties of 5083-H116, 6082-T651, and 6082-T6 aluminum alloy extrusions.…”

Section: Introductionmentioning

confidence: 99%

“…After exposing the alloys to elevated temperatures, tension tests and Vickers hardness measurements tests were performed to determine the mechanical response of the alloys and quantify the time and temperature-dependent behavior. Chen et al [24] investigated the hot deformation resistance of an AA5083 alloy under high strain rate. They made quantitative analyses over the effects of temperature, strain rate, and work hardening behavior on the flow curves and developed a modified constitutive equation for prediction of hot deformation resistance of the AA5083 alloy at high temperatures and high strain rate.…”

Section: Introductionmentioning

confidence: 99%

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Mechanical Properties of Strengthening 5083-H111 Aluminum Alloy Plates at Elevated Temperatures

2021

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The use of aluminum alloys for external strengthening of reinforced concrete (RC) beams has been capturing research interest. Exposure to harsh environmental conditions can severely impact the strengthening efficiency. This works aims to investigate the degradation in the mechanical properties of aluminum alloy AA 5083 plates when exposed to temperatures ranging from 25 to 300 °C. Quasi-static Isothermal tensile experiments were conducted at different temperatures. It was observed from the experimental results that the yield strength remained constant in the temperature range of 25–150 °C before starting to drop beyond 150 °C, with a total reduction of ≈ 40% at 300 °C. The elastic modulus was temperature sensitive with about 25% reduction at 200 °C before experiencing a significant and pronounced reduction at 300 °C. The percentage drops in stiffness and yield strength at 300 °C were 62.8% and 38%, respectively. In addition, the Mechanical Threshold Strength Model (MTS) parameters were established to capture the yield strength temperature dependence. Two analytical models were developed based on the experimental results. Both models can reasonably predict the elastic modulus and yield strength of AA 5083 plates as a function of temperature. It was concluded that AA plates should be properly insulated when used as externally bonded reinforcement to strengthen RC beams.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mechanical Properties of Strengthening 5083-H111 Aluminum Alloy Plates at Elevated Temperatures

2021

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“…The understanding of metals and alloys deformation behavior during hot working is of a great importance, rst of all, from the point of view of product properties formation. To study machinability and to establish optimal hot deformation parameters for certain metals and alloys, a number of research groups have made efforts to carry out thermomechanical experiments (compression, tensile and torsion tests) at wide temperatures and strain rates [5][6][7][8]. At the same time, the processes of metal forming in industrial conditions are different from the ones in laboratory.…”

Section: Introductionmentioning

confidence: 99%

Effect of Process Parameters on the Microstructure and Mechanical Properties of Bars from Al-Cu-Mg Alloy Processed by Multipass Radial-Shear Rolling

Akopyan¹,

Gamin²,

Галкин³

et al. 2021

Preprint

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The study of microstructure and mechanical properties formation of A2024 alloy obtained by the multipass radial-shear rolling (RSR) method is discussed in this article. FEM simulation was carried out that made it possible to evaluate the influence degree of rolling temperature-velocity parameters on the strain state of material. It has been found the increase in rotary velocity of rolls significantly influences on the deformation heating of bar after RSR (predominantly in its surface layer). The combination of rolling temperature-velocity conditions at selection of deformation regime has complex effect on structure and properties formation. The analysis of sizes and distribution of phase particles has shown that the rolling at lower temperatures allowed to increase the mechanical strength due to the more intensive refinement of undissolved Fe-containing phase. The gradual decrease in the rolling temperature in each pass makes possible to achieve the high strength (UTS~430 MPa and YS~255 MPa) while maintaining the ductility level ~15%, that are comparable to ones obtained at some severe plastic deformation (SPD) methods.

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“…Similarly, Sloof et al [30] incorporated a strain dependent parameter enabling accurate predictions of flow stress during deformation for a wide range of temperature and strain values. Lin et al [31], Shi et al [32] and Mandal et al [27] amongst others have successfully employed the strain and strain rate compensated Arrhenius type (ATC) equation to accurately predict flow stress behaviour of an assortment of materials for a broad collection of temperature and strain values.…”

Section: Introductionmentioning

confidence: 99%

Constitutive analysis of biomedical grade Co-27Cr-5Mo alloy at high strain rates

Trimble

Shipley

Lea

et al. 2017

Materials Science and Engineering: A

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Cobalt Chrome is used extensively within the biomedical industry for hip, knee and shoulder prostheses. These components are manufactured using a range of different processes which includes machining. In order to develop Finite Element Models of machining processes, it is necessary to develop the constitutive model of the workpiece material at high strain rates over different temperatures. During this research, Split Hopkinson Pressure Bar tests were conducted over a wide processing domain of temperatures (298-873 K) and strain-rates (600-1400s-1) to predict the constitutive model of biomedical grade Cobalt Chrome based on modified Zerilli-Armstrong, modified Johnson-Cook and strain compensated Arrhenius-type models. The prediction capability of these models was evaluated in terms of average absolute relative error and correlation coefficient between predicted and experimental flow stress values. Results demonstrated that the modified Zerilli-Armstrong model can track the deformational behaviour more accurately throughout the entire processing domain investigated compared to the other models. The model recorded an average absolute relative error of 2.71% and a correlational coefficient of 0.98.

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Hot Deformation Resistance of an AA5083 Alloy under High Strain Rate

Cited by 6 publications

References 11 publications

Mechanical Properties of Strengthening 5083-H111 Aluminum Alloy Plates at Elevated Temperatures

Mechanical Properties of Strengthening 5083-H111 Aluminum Alloy Plates at Elevated Temperatures

Effect of Process Parameters on the Microstructure and Mechanical Properties of Bars from Al-Cu-Mg Alloy Processed by Multipass Radial-Shear Rolling

Constitutive analysis of biomedical grade Co-27Cr-5Mo alloy at high strain rates

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