Development of Al–Mn–Mg 3004 alloy for applications at elevated temperature via dispersoid strengthening

Liu, Kun; Chen, X-Grant

doi:10.1016/j.matdes.2015.06.140

Cited by 112 publications

(119 citation statements)

References 36 publications

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“…A trace of Cu was detected in the dispersoids in the Cu containing alloys by TEM-EDS analysis. All dispersoids are identified as α-Al(Mn,Fe)Si according to the results of TEM-EDS and literature [1][2][3]5,6]. The equivalent diameter of the dispersoids in the base alloy (DU0) is 47 nm, whereas the diameters of the dispersoids in the Cu containing alloys are between 32 and 37 nm (Figure 7a), which is smaller than that in the base alloy.…”

Section: The Influence Of Cu On Dispersoid Features and Thermal Stabimentioning

confidence: 87%

“…In the base alloy (DU0, Cu-free), two types of intermetallic particles were observed (Figure 2a). The grey particles correspond to the Al 6 (Mn,Fe) intermetallic phase and the black ones are primary Mg 2 Si [6,9,13]; both are intermetalllics distributed in the interdendrite regions. In the Cu containing alloys, the grey particles are Al 6 (Mn,Fe) intermetallic, in which a small amount of Cu can be detected.…”

Section: Influence Of Cu On Intermetallic Phases and Dispersoid Distrmentioning

confidence: 99%

“…The microstructure of the alloy containing 1.2% Cu is shown in Figure 2b. Using image analysis, the volume fractions of intermetallics as a function of Cu content were evaluated (Figure 3 α-Al(Mn,Fe)Si dispersoids can precipitate at approximately 400 °C during heat treatment in 3xxx alloys [3,6,7]. Figure 4 shows the optical images of DU0 and DU120 alloys after heat treatment at 425 °C for 6 h. The light yellow regions are the dispersoid zones where most of the dispersoids are concentrated and they are located inside the dendrite cells.…”

Section: Influence Of Cu On Intermetallic Phases and Dispersoid Distrmentioning

confidence: 99%

“…Recently, the strengthening effect of α-Al(Mn,Fe)Si dispersoids at ambient and elevated temperatures has been reported [1,[6][7][8]. Moreover, the α-Al(Mn,Fe)Si dispersoids have been proven to be thermally stable at 300 • C [6], which is especially attractive to materials for elevated temperature applications.…”

Section: Introductionmentioning

confidence: 99%

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The Influence of Cu Addition on Dispersoid Formation and Mechanical Properties of Al-Mn-Mg 3004 Alloy

Zhang

Chen

2018

Metals

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Abstract:The effect of Cu addition on dispersoid precipitation, mechanical properties and creep resistance was investigated in an Al-Mn-Mg 3004 alloy. The addition of Cu promoted dispersoid precipitation by increasing the number density and decreasing the size of dispersoids. Metastable β -Mg 2 Si and Q-AlCuMgSi precipitates were observed during the heating process and both could provide favorable nucleation sites for dispersoid precipitation. The addition of Cu improved the thermal stability of dispersoids during a long-term thermal holding at 350 • C for 500 h. Results of mechanical testing show that the addition of Cu remarkably improved the hardness at room temperature, as well as the yield strength and creep resistance at 300 • C, which was mainly attributed to dispersoid strengthening and Cu solid solution strengthening. The yield strength contribution at 300 • C was quantitatively evaluated based on the dispersoid, solid solution and matrix contributions. It was confirmed that dispersoid strengthening is the main strengthening mechanism in the experimental alloys.

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Section: The Influence Of Cu On Dispersoid Features and Thermal Stabimentioning

confidence: 87%

Section: Influence Of Cu On Intermetallic Phases and Dispersoid Distrmentioning

confidence: 99%

Section: Influence Of Cu On Intermetallic Phases and Dispersoid Distrmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Influence of Cu Addition on Dispersoid Formation and Mechanical Properties of Al-Mn-Mg 3004 Alloy

Zhang

Chen

2018

Metals

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“…It is reported that the yield strength of 3003 at room temperature (RT) after 375°C/24h has been improved to 80 MPa compared with 52MPa after 600°C/24h due to precipitation of dispersoids [7]. Recently, present authors have systematically studied the evolution of dispersoids at relative lower heat treatment temperature (300-425°C) and their influence on elevated-temperature properties in AlMn-Mg 3004 alloys [6,[8][9][10][11][12]. It is found that high volume fraction and well distributed α-Al(MnFe)Si dispersoids are observed after treated at 375°C for 48h, leading to the remarkable improved YS and creep resistance at elevated-temperature.…”

Section: Introductionmentioning

confidence: 99%

Evolution of Elevated-Temperature Strength and Creep Resistance during Multi-Step Heat Treatments in Al-Mn-Mg Alloy

Wang¹,

Liu²,

Wang³

2018

Preprint

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Abstract:Present work has systematically investigated the evolution of dispersoid and elevated-temperature properties including the strength and creep resistance during the various multi-step heat treatments in Al-Mn-Mg 3004 alloys. Results show that only α-Al(MnFe)Si dispersoid is observed in the studied temperature range (up to 625°C) and it coarsens with increasing temperature to 500°C but dissolves at 625°C. The evolution of elevated-temperature strength and creep resistance is greatly related to the temperature of each step during the multi-step heat treatments. Generally, lower temperature at the first-step heat treatment leads to higher properties while the properties decrease with increasing temperature of last-step heat treatment. Suitable models have been introduced to explain the evolution of strength and the creep threshold stress at elevated-temperature during the various heat treatments.

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Effect of Mn‐Bearing Dispersoids on Tensile Properties and Recrystallization Resistance of Al‐3Mg‐0.8Mn Rolled Alloy

2023

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Herein, the precipitation behavior of Mn‐bearing dispersoids in Al‐3Mg‐0.8Mn (AA5454) alloy subjected to different heat treatments is investigated. The effects of Mn‐bearing dispersoids on the tensile properties and recrystallization resistance of the abovementioned alloy during hot/cold rolling and postrolling annealing are evaluated. The results show that a low‐temperature three‐step heat treatment (275 °C/12 h + 375 °C/48 h + 425 °C/12 h) generates a higher number density of Mn‐bearing dispersoids with finer sizes compared with the typical high‐temperature heat treatment (430 °C/2 h + 480 °C/2 h + 525 °C/2 h), thus resulting in significantly improved tensile strengths of hot/cold‐rolled sheets. After annealing at 300 °C, the yield strength (YS) of the alloy reached 196 MPa after hot rolling and 237 MPa after cold rolling, showing an improvement of 30%–32% over samples subjected to high‐temperature heat treatment. In addition, the low‐temperature heat treatment provides a higher recrystallization resistance after hot and cold rolling owing to the higher number density of Mn‐bearing dispersoids and the lower fraction of dispersoid‐free zones. The YS contributions of various strengthening components after hot and cold rolling are discussed based on constitutive models. The predicted yield strengths agree well with the experimental values.

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Development of Al–Mn–Mg 3004 alloy for applications at elevated temperature via dispersoid strengthening

Cited by 112 publications

References 36 publications

The Influence of Cu Addition on Dispersoid Formation and Mechanical Properties of Al-Mn-Mg 3004 Alloy

The Influence of Cu Addition on Dispersoid Formation and Mechanical Properties of Al-Mn-Mg 3004 Alloy

Evolution of Elevated-Temperature Strength and Creep Resistance during Multi-Step Heat Treatments in Al-Mn-Mg Alloy

Effect of Mn‐Bearing Dispersoids on Tensile Properties and Recrystallization Resistance of Al‐3Mg‐0.8Mn Rolled Alloy

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