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

Abuzaid, Wael; Hawileh, Rami A.; Abdalla, Jamal A.

doi:10.3390/infrastructures6060087

Cited by 10 publications

(1 citation statement)

References 39 publications

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“…The welded thick-walled structures were made of the EN AW5083-H111 aluminum alloy [24] with the chemical composition given in table 1. The thermophysical properties of the EN AW5083-H111 aluminum alloy as a function of temperature (figure 3) were calculated using the JMatPro 6.1 code [25] based on its chemical composition.…”

Section: Materials Modelmentioning

confidence: 99%

Design of welding parameters for laser welding of thick-walled structures made of aluminum alloy

Babalová

Ďuriš

Behúlová

2022

J. Phys.: Conf. Ser.

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The paper deals with the laser welding of thick-walled plates with a thickness of 20 mm made of EN AW5083-H111 aluminum alloy. A simulation model for the analysis of the laser welding process is developed and verify using temperature measurement during experimental laser welding of samples by a TruDisk 4002 laser device. Based on the numerical simulation of the laser welding process in the ANSYS program code, suitable parameters for production of high-quality weld joints were suggested. For welding at a speed of 10 mm.s−1, the laser power of 7 kW is recommended. A laser with the power of 10 kW is required for the higher welding speed of 20 mm.s−1.

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Section: Materials Modelmentioning

confidence: 99%

Design of welding parameters for laser welding of thick-walled structures made of aluminum alloy

Babalová

Ďuriš

Behúlová

2022

J. Phys.: Conf. Ser.

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Structural Metals after Exposure to High Temperatures: Residual Mechanical Properties and Predictions

Cai,

Ho,

et al. 2024

steel research int.

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Most research works have focused on studying the postfire (after exposure to high temperatures) mechanical properties of either carbon steel, stainless steel, or aluminum alloy. There are few studies directly comparing the mechanical properties of these structural metals after exposure to high temperatures, and there is no universal predictive equation describing their postfire retention factors. Herein, mechanical properties of structural metals (i.e., carbon steel, stainless steel, and aluminum alloy) after exposure to high temperatures are experimentally investigated. The mechanical properties of these structural metals are compared and rigorously analyzed. Existing equations are assessed by comparing their predictions against the corresponding postfire retention factors of the coupon specimens. A unified equation for the postfire mechanical properties of structural metals is developed, proposing different sets of coefficients for various structural metals based on the new test data from this study and the existing literature. The unified equation generally provides a safe and convenient assessment method, enabling practical engineers to determine the mechanical properties of metal structures after exposure to high temperatures in terms of Young's modulus, 0.2% proof stress (yield strength), and ultimate strength.

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Fatigue crack propagation in AA5083 structures additively manufactured via multi-layer friction surfacing

Kallien

Horstmann

Klusemann

2023

Additive Manufacturing Letters

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

Cited by 10 publications

References 39 publications

Design of welding parameters for laser welding of thick-walled structures made of aluminum alloy

Design of welding parameters for laser welding of thick-walled structures made of aluminum alloy

Structural Metals after Exposure to High Temperatures: Residual Mechanical Properties and Predictions

Fatigue crack propagation in AA5083 structures additively manufactured via multi-layer friction surfacing

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