Intermetallic Compound Produced by Semi-Solid Processing from Al/Ni Powder Mixture and its Mechanical Strength at Elevated Temperature.

The paper introduces a new method to produce large sized Al-B4C-Al2O3np composites, which combines ball milling to prepare Al2O3np/Al mixed powder and semi-solid casting to contribute the injection of Al2O3np/Al mixed powder into the melt. The deformation performance of Al2O3np and micro-Al through ball milling with different Al/Al2O3np ratios, different milling time and different balls were studied respectively. It was revealed that micro-Al particles were milled from twisted and crimpled foil pieces to shuttles with Al2O3np embedded on it through 4h milling with 10mm balls. And we consider it as the best bonding between Al2O3np and micro-Al we could attain. And a plate of 25kg of Al-B4C-Al2O3np composite was fabricated successfully with the injection of the Al2O3np/Al mixed powder. Spherical Al2O3np of 300nm and needle-like TiB2 with 200nm in radius and 800nm-4μm in length were found in SEM photographs. Tensile properties of Al-B4C-Al2O3np composites were tested at room temperature and high temperature. It was showed higher mechanical properties than Al-B4C composites at room temperature and elevated temperature. Particularly, a 40% increase of UTS of Al-15wt.% B4C-1wt.%Al2O3np at 350°C was observed.

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Elevated Temperature Tensile Behavior of Rheo-Cast 7075-T6 Al Alloy Produced by GISS Technique

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.881-883.1597 ◽

2014 ◽

Vol 881-883 ◽

pp. 1597-1600 ◽

Cited By ~ 1

Author(s):

Narissara Mahathaninwong ◽

Sirikul Wisutmethangoon ◽

Thawatchai Plookphol ◽

Jessada Wannasin ◽

Suchart Chantaramanee

Keyword(s):

Tensile Strength ◽

Elevated Temperature ◽

Ultimate Tensile Strength ◽

Yield Strength ◽

Room Temperature ◽

Tensile Behavior ◽

Al Alloy ◽

Elevated Temperature Tensile ◽

Semi Solid ◽

Increasing Temperature

Tensile properties of rheo-cast 7075-T6 Al alloy produced by Gas Induced Semi-Solid (GISS) technique was investigated as a function of temperatures from 25°C to 250 °C in order to assess the potent of high temperature applications. It was found that the ultimate tensile strength and yield strength of the alloy decreased steadily with increasing temperature. There was loss in strength of about 33% at 200°C and 46% at 250 °C comparing to the strength at room temperature. At T = 250 °C, the ultimate tensile strength and yield strength of the rheo-cast 7075-T6 Al alloy were higher than those of the wrought 7075-T651 Al alloy. Keyword: 7075 Al alloy; Gas Induced Semi Solid (GISS) technique; Elevated temperature tensile.

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The Compatibility of Nuclear Graphite With Molten Salt in the Molten Salt Reactor

Volume 2: Plant Systems, Structures, Components, and Materials; Risk Assessments and Management ◽

10.1115/icone26-82065 ◽

2018 ◽

Author(s):

Zhoutong He ◽

Hui Tang ◽

Can Zhang ◽

Yantao Gao ◽

Huihao Xia ◽

...

Keyword(s):

Thermal Expansion ◽

Elevated Temperature ◽

Mechanical Strength ◽

Molten Salt ◽

Room Temperature ◽

Nuclear Graphite ◽

Expansion Behavior ◽

Fracture Surface Analysis ◽

Property Changes ◽

Infiltration Behavior

In thermal Molten Salt Reactors, the nuclear graphite core is in direct contact with the molten salt coolant. Due to the porous nature of nuclear graphite, the molten salt may infiltrate the nuclear graphite, which may affect the mechanical strength and irradiation behavior of the nuclear graphite. In order to evaluate the infiltration behavior of molten salt in nuclear graphite, both FLiNaK and FLiBe salts were used to infiltrate two typical nuclear graphite grades: IG110 and NBG18. The pressure dependence of the infiltration weight gain ratio was measured. The influence of molten salt infiltration on the thermal properties of these two graphite grades, such as their thermal expansion behavior and thermal conductivity, was also measured. The mechanical strength of the FLiNaK-infiltrated graphite was measured at room temperature and elevated temperature, and showed that the mechanical strength of the nuclear graphite was enhanced at room temperature and weakened at elevated temperature by molten salt infiltration. Finally, the thermal expansion coefficient and the fracture surface analysis measured after FLiNaK infiltration indicated that the stress induced by molten salt infiltration could be one of the reasons for the graphite property changes.

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