Arseny Schaefer scite author profile

The new technology of producing ingot of AlSi7Fe1 high-strength is described. This new technology consists in saturation of melt with hydrogen, with further blowing with oxygen. Studied the microstructure, phase composition and mechanical properties of ingot after blowing oxygen of melt and ingot obtained with the traditional method. Have suggested that in liquid aluminum alloy AlSi7Fe1 because of blowing with oxygen arise refractory particles Al2O3. These particles Al2O3 further in crystallization serve as a modifier of the microstructure of ingot. Mostly observed modifications of eutectic phases. Thus saturation of melt with hydrogen, with further blowing with oxygen provides an increased tensile strength of ingot AlSi7Fe1.

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Dehydrogenation of AlSi7Fe1 Melt during In Situ Composite Production by Oxygen Blowing

Finkelstein

Schaefer

Dubinin

2021

Metals

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The technology of producing a composite material in situ envisages the pre-saturation of an AlSi7Fe1 melt with hydrogen; afterwards, the melt is blown with oxygen until the hydrogen dissolved in the melt is burned out. The hydrogen content was researched during the manufacturing process of the composite material; before oxygen blowing, and at incomplete and complete burning out of the dissolved hydrogen. The interrelation between the absorbed hydrogen content and the aluminum oxide fraction was identified. A mathematical model was proposed which demonstrated that during the saturation process of the melt with oxide particles, hydrogen was absorbed on their surface as a layer close to monoatomic, which does not lead to the realization of the pores’ heterogeneous nucleation mechanism. Due to this, castings produced from the researched composite material are leakless. Incomplete burning out of hydrogen dissolved in the melt leads to the formation of significant hydrogen porosity. The proposed method of prevention of gas porosity in cast composites is an alternative to the conventional one and offers not only the purging of the melt from oxide inclusions but, on the contrary, a significant increase in their specific surface, which allows for the reduction in hydrogen content on the inclusion surface to the monoatomic level.

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Study of Al-Si Alloy Oxygen Saturation on Its Microstructure and Mechanical Properties

et al. 2017

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One of the main goals of modern materials research is obtaining different microstructures and studying their influence on the mechanical properties of metals; aluminum alloys are particularly of interest due to their advanced performance. Traditionally, their required properties are obtained by alloying process, modification, or physical influence during solidification. The present work describes a saturation of the overheated AlSi7Fe1 casting alloy by oxides using oxygen blowing approach in overheated alloy. Changes in metals’ microstructural and mechanical properties are also described in the work. An Al10SiFe intermetallic complex compound was obtained as a preferable component to Al2O3 precipitation on it, and its morphology was investigated by scanning electron microscopy. The mechanical properties of the alloy after the oxygen blowing treatment are discussed in this work.

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Corrosion of an Aluminum Matrix Composite in situ Based on Al–7Si–1Fe Alloy

Finkelstein

Шак

Schaefer

2020

Russ. J. Non-ferrous Metals

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Приведены результаты сравнительного исследования коррозионной стойкости алюмоматричного композита, полученного методом продувки кислородом предварительно гидрогенизированного расплава на основе сплава Al-Si-Fe с содержанием железа более 1 %, предназначенного для литья под давлением, и сплава Al-7Si с 0,3 % Fe, модифицированного лигатурой 5Al-Ti в количестве 2 %. Коррозия в алюминиевых сплавах обусловлена нарушением сплошности оксидной пленки на некоторых фазах, прежде всего на фазе Al 5 SiFe. Пары образцов из композита и сплава сравнения диаметром 15 мм и длиной 50 мм подверглись испытаниям в 7 %-ном растворе солевого тумана NaCl в камере КСТ-1 на подвесках при температуре 22 °С в течение 300 ч. Полученные результаты показали близкие значения убыли массы образцов, несмотря на значительно более высокое содержание железа в материале, поскольку сформировавшиеся в расплаве при продувке кислородом частицы Al 2 O 3 размером 100-200 нм, осаждаясь на границах фаз, снижают площадь поверхности взаимодействия с коррозионной средой. Литературные данные показывают существенное отличие сопротивления коррозионному воздействию композитов ex situ от in situ вследствие различий в размерах и расположении в матрице упрочняющей фазы. Исследованный композиционный материал может быть рекомендован как коррозионно-стойкая альтернатива сплавам с повышенным содержанием железа, используемым для литья под давлением.

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Aluminum Alloy Selection for In Situ Composite Production by Oxygen Blowing

Finkelstein

Schaefer

Dubinin

2021

Metals

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We considered the possibility of using AlMg10, AlCu5, AlCu5Cd, AlSi12, and AlSi7Zn9 as initial alloys for in situ composites production via oxygen blowing of hydrogen pre-saturated melts as an alternative to AlSi7Fe. The production process provides the destruction of the oxide film on the melt surface. It was demonstrated that oxide film on AlMg10 alloy did not get destroyed due to the heavy thickness because of the porous structure that contributed to its kinetically based growth. Copper-bearing alloys AlCu5 and AlCu5Cd were characterized by the low-strength oxide film and got destroyed before floating, causing the oxide porosity. Silicon-bearing alloys AlSi12 and AlSi7Zn9 provide the dense structure, which makes it clear that to understand the Pilling–Bedworth ratio for basic alloying elements is required for a non-destructed oxide void floating and shall exceed the range of 1.64–1.77. However, the oxide film in silicon-bearing alloys under investigation did not get destroyed into fine particles. AlSi7Zn9 alloy had inclusions of smaller sizes as compared to AlSi12 alloy due to the ZnO that embrittled the film, but which were grouped to form oxide islands. Moreover, zinc was evaporated during blowing. The mechanical properties of the produced composites were based on the alloys under investigation which were in line with their structures. A higher value of the Pilling–Bedworth ratio of impurities was required for fine crushing: The conventionally used AlSi7Fe alloy met this requirement and was therefore considered to be the optimum version.

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Arseny Schaefer

MICROSTRUCTURES, MECHANICAL PROPERTIES INGOT AlSi7Fe1 AFTER BLOWING OXYGEN THROUGH MELT

Dehydrogenation of AlSi7Fe1 Melt during In Situ Composite Production by Oxygen Blowing

Study of Al-Si Alloy Oxygen Saturation on Its Microstructure and Mechanical Properties

Corrosion of an Aluminum Matrix Composite in situ Based on Al–7Si–1Fe Alloy

Aluminum Alloy Selection for In Situ Composite Production by Oxygen Blowing

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