Mechanical Behaviour of an Al2O3 Dispersion Strengthened γTiAl Alloy Produced by Centrifugal Casting

Pilone, D.; Pulci, Giovanni; Paglia, Laura; Mondal, A.; Marra, Francesco; Felli, F.; Brotzu, A.

doi:10.3390/met10111457

Cited by 12 publications

(10 citation statements)

References 27 publications

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“…At 850 and 900 °C, the reference specimens bent but did not fracture when tested in 4-point bending, while the strengthened alloy fractured both at 850 °C and 900 °C and bent at 950 °C (Figure 11). By comparing the results obtained in this research with the results obtained in a previous published work, 18 in which we tested a TiAl alloy reinforced with nanometric alumina particles, it is evident that in situ formed alumina allows to obtain better mechanical properties. Yield stress obtained with nanometric alumina dispersion is 372 MPa at 850 °C and 267 MPa at 900 °C, while yield stress obtained with in situ formed alumina reaches 435 MPa at 850 °C and 329 MPa at 900 °C.…”

Section: Resultssupporting

confidence: 58%

“…Dispersion strengthening of the metal matrix has been studied by adding particles characterized by high thermal stability and elastic modulus, such as oxides (Al 2 O 3 , Y 2 O 3 , CeO 2 , ZrO 2 and ThO 2 ) and carbides (SiC, NbC, MoC, WC). 18 Dispersion strengthening is a widespread practice in the industry, and it is extensively used to reinforce materials from steel to superalloys. This process is already being used to harden nickel-based superalloys used for aerospace engines 19 above 1000 °C.…”

Section: Introductionmentioning

confidence: 99%

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Enhanced High-Temperature Mechanical Behavior of an in Situ TiAl Matrix Composite Reinforced With Alumina

et al. 2022

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A Ti-45Al-3Cr-2.5Nb alloy reinforced with in situ formed alumina has been produced by means of centrifugal casting by adding zirconium oxide in the crucible. The dispersion-strengthened alloy has been characterized to verify its microstructure and particle distribution. Mechanical tests carried out over the temperature range 850–950 °C highlighted that in situ formed alumina allows to increase the alloy yield stress by 21% at 850 °C and by 35% at 900 °C. Moreover, the in situ formed oxide particles produced an increase of the Young’s modulus of about 10% at 850 °C and of about 8% at 900 °C. Considering that the tested alloy has a density that is about a half of nickel superalloys, obtaining high specific mechanical properties over the temperature range 850–950 °C can boost its application in the production of turbine blades. Graphical abstract

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Section: Resultssupporting

confidence: 58%

Section: Introductionmentioning

confidence: 99%

Enhanced High-Temperature Mechanical Behavior of an in Situ TiAl Matrix Composite Reinforced With Alumina

et al. 2022

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“…The strengthening is due to dislocation motion in the metal being impeded by the presence of small, hard particles. The Orowan bypassing [50][51][52][53] of the particle by the movement of dislocation increases the material's strength:…”

Section: Based On Position Of Mouldmentioning

confidence: 99%

“…This nucleation is followed by grain growth, which continues until the particle impedes the grain boundary movement [57]. The following expression, which shows the relationship between the particle size (d), the grain size of the matrix (D), and the volume fraction of the particle (V r ), is expressed as [51]:…”

Section: Based On Position Of Mouldmentioning

confidence: 99%

A review on fabrication and characteristics of functionally graded aluminum matrix composites fabricated by centrifugal casting method

2021

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This paper delivers a detailed review of the influence of material and process variables on the microstructure, mechanical and tribological characteristics of functionally graded aluminum matrix composites (FGAMCs) produced by the ex-situ centrifugal casting method from previous studies. Also, the basic principle and classification of centrifugal casting to produce FGAMCs are illustrated. The ceramic reinforcement particles are classified based upon their uses in the processing of FGAMCs through the ex-situ centrifugal casting technique. In addition, using the linear regression model, an effort has been made to optimize the material and process variables to get enhance the mechanical properties. It is seen from the optimization while mold preheating temperature ranges 250–350 °C, centrifugal speed kept between 600 and 1300 rpm, pouring temperature in the range of 740–760 °C having reinforcement particle of 10–15 wt%, with an average particle size of 18–50 µm yield the maximum of hardness and tensile strength. This paper aims to provide direction to future researchers to develop advanced material using this route and thus, to boost technological growth.

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“…Materials used in hot sections of aero-and land-based gas turbines are designed to endure severe operating conditions and must be able to resist both hot corrosion and high temperature oxidation. Nickel-based superalloys are usually employed in high temperature sections of the engine, whereas TiAl components have aroused great interest in recent decades for the less thermally stressed areas [1][2][3]. A great scientific and technological interest is thus devoted to thermal barrier coatings (TBCs) [4][5][6][7][8][9] as heat resistant surface layers deposited on metallic components of gas turbine engines (usually made of Ni-or Co-based superalloys), allowing for efficient protection from high temperature inlet gases and therefore providing improved engine performance.…”

Section: Introductionmentioning

confidence: 99%

Diffusion Aluminide Coatings for Hot Corrosion and Oxidation Protection of Nickel-Based Superalloys: Effect of Fluoride-Based Activator Salts

Genova¹,

Paglia²,

Pulci³

et al. 2021

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The influence of two different fluoride-based activator salts (NH4F and AlF3) was studied for diffusion aluminide coatings obtained via pack cementation on a Ni-based superalloy (René 108DS). The resistance to oxidation and hot corrosion was assessed as a function of the concentration of activator salts used during the synthesis process by means of pack cementation. Two different concentrations were selected for activator salts (respecting the equimolarity of fluoride in the synthesis) and the obtained diffusion coatings were compared in terms of morphology, thickness and composition, as well as in terms of microstructural evolution after high temperature exposure. Isothermal oxidation tests were conducted at 1050 °C in air for 100 h in a tubular furnace. The oxidation kinetics were evaluated by measuring the weight variation with exposure time. The microstructural evolution induced by the high temperature exposure was investigated by SEM microscopy, EDS analysis and X-ray diffraction. Results showed that the coatings obtained with AlF3 activator salt are thicker than those obtained using NH4F as a consequence of different growth mechanism during pack-cementation. Despite this evidence, it was found that the NH4F coatings show a better oxidation resistance, both in terms of total mass gain and of quality of the microstructure of the thermally grown oxide. On the other hand, coatings produced with high concentration of AlF3 exhibited a better resistance in hot corrosion conditions, showing negligible mass variations after 200 h of high temperature exposure to aggressive NaCl and Na2SO4 salts.

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Mechanical Behaviour of an Al2O3 Dispersion Strengthened γTiAl Alloy Produced by Centrifugal Casting

Cited by 12 publications

References 27 publications

Enhanced High-Temperature Mechanical Behavior of an in Situ TiAl Matrix Composite Reinforced With Alumina

Enhanced High-Temperature Mechanical Behavior of an in Situ TiAl Matrix Composite Reinforced With Alumina

A review on fabrication and characteristics of functionally graded aluminum matrix composites fabricated by centrifugal casting method

Diffusion Aluminide Coatings for Hot Corrosion and Oxidation Protection of Nickel-Based Superalloys: Effect of Fluoride-Based Activator Salts

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