Your search keyword '"J. Hernandez-Sandoval"' showing total 9 results

1. Change of Tensile Properties with Aging Time and Temperature in Al-Si-Cu-Mg 354 Cast Alloys with/without Minor Addition of Ni and/or Zr

Author

J. Hernandez-Sandoval, M. H. Abdelaziz, E. A. Elsharkawi, A. M. Samuel, and F. H. Samuel

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The principal aim of the present research work was to investigate the effects of minor additions of nickel and zirconium on the strength of cast aluminum alloy 354 at room temperature (25°C). A decrease in tensile properties of ∼10% with the addition of 0.4 wt.% nickel is attributed to a nickel-copper reaction which interferes with the formation of Al2Cu precipitates. The platelet-like phases (Al,Si)3(Zr,Ni,Fe) and (Al,Si)3(Zr,Ti) are the main features observed in the microstructures of the tensile samples of alloys with Zr additions. The reduction in mechanical properties is due to the increase in the percentage of intermetallic phases formed during solidification; such particles would act as stress concentrators, decreasing the alloy ductility. The main effect of Zr addition lies in a significant reduction in the alloy grain size ∼40%, rather than an increase in the mechanical properties. Quality index charts could be used in assessing the effects of the Ni and Zr additions to the base alloy, as well as evaluating the heat treatment relationships to the alloy tensile properties, in particular when the system shows multiple precipitation reactions. Due to the high liquidus temperature of the Al-Zr binary phase diagram, addition of Zr beyond 0.2% is not recommended to avoid undissolved Zr.

Published

2021

2. Effect of Dispersoids and Intermetallics on Hardening the Al-Si-Cu-Mg Cast Alloys

Author

J. Hernandez-Sandoval, M. H. Abdelaziz, A. M. Samuel, H. W. Doty, and F. H. Samuel

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The principal aim of the present research work was to compare the role of dispersoids Al2O3 (∼15 μm average particle size) and SiC (∼15 μm average particle size) with that offered by Zr- and Ni-based intermetallics (∼35–70 μm average particle size) on the hardening of cast aluminum 354 alloy (9.1% Si, 0.12% Fe, 1.8% Cu, 0.008% Mn, 0.6% Mg, and 87.6% Al) at ambient temperature. There is no observable poisoning effect on the refinement of grain size after the addition of Zr to the alloys investigated in this study. The tensile test results were examined in light of the microstructural features of the corresponding alloy samples. The contribution of the added dispersoids or Ni and Zr alloying elements on the tensile properties of the 354 alloys was determined employing ∆P plots (where P = Property, UTS, YS, or %El), using the base alloy (in the as-cast condition) as a reference point. The tensile results were supported by investigating the precipitation-hardening phases using scanning and transmission electron microscopy as well as examining the fracture surfaces of selected conditions applying field emission scanning electron microscopy. The results show that, in all cases, Al2Cu phase is the main hardening agent. The contribution of about 1.5 vol% of SiC or Al2O3 to the strength of the base alloy is higher than that offered by Zr- and Ni-based intermetallics, under the same aging treatment.

Published

2021

3. Effect of Minor Addition of Ni and Zr on the High-Temperature Performance of Al–Si–Cu–Mg Cast Alloys

Author

J. Hernandez-Sandoval, Yasser Zedan, M. H. Abdelaziz, G. H. Garza-Elizondo, Victor Songmene, and F. H. Samuel

Subjects

Zirconium, Materials science, Alloy, Metallurgy, Metals and Alloys, chemistry.chemical_element, Context (language use), engineering.material, Casting, Industrial and Manufacturing Engineering, Nickel, Precipitation hardening, chemistry, Mechanics of Materials, Ultimate tensile strength, Materials Chemistry, engineering, Softening

Abstract

In this study, the results pertaining to the influence of various metallurgical parameters on the tensile properties of Al–Si–Cu–Mg 354-type casting alloys are presented. This is discussed with an emphasis on acquiring an insight regarding the mechanical limits of Al–Si–Cu–Mg 354-type alloys in the context of these parameters, and to obtain an understanding of the effects of the addition of nickel and/or zirconium on alloy 354 with respect to the mechanical properties obtained at high temperature (155 °C and 300 °C for holding times at temperature ranging from 10 to 100 h). Based on an analysis of the results obtained, the following conclusions may be drawn. The results show that additions of Zr and Zr + Ni increase the high-temperature tensile properties, in particular for the alloy containing 0.2 wt% Zr + 0.2 wt% Ni, which exhibits an increase of more than 30% in the tensile properties at 300 °C compared with the base 354 alloy. In other words, the addition of 0.4 wt% Ni + 0.4 wt% Zr to the 354 alloy is not sufficient to resist softening at 300 °C/100 h (cf. UTS: 52 MPa, YS: 45 MPa, %El: 23% with UTS: 361 MPa, YS: 343 MPa, %El 1.23%, observed after T6 treatment). The addition of 0.4 wt% Ni to alloy 354 leads to a decrease in the tensile properties, compared to the base alloy. This decrease may be attributed to a Ni–Cu reaction which could interfere with the formation of the Al2Cu strengthening precipitates, thereby affecting the age hardening process. As a consequence, percentage elongation increases with the testing temperature, from as-cast to T6-treated samples tested at high temperature (155 °C and 300 °C, respectively). In summary, the best high-temperature tensile properties are displayed by the alloy containing 0.2 wt% Zr + 0.2 wt% Ni.

Published

2021

4. The Effect of Ni and Zr Additions on the Tensile Properties of Isothermally Aged Ai–Si–Cu–Mg Cast Alloys

Author

Herbert W. Doty, G. H. Garza-Elizondo, M. H. Abdelaziz, F. H. Samuel, J. Hernandez-Sandoval, and Agnes M. Samuel

Subjects

Zirconium, Materials science, Structural material, 020502 materials, Metallurgy, Alloy, Metals and Alloys, chemistry.chemical_element, 02 engineering and technology, engineering.material, Casting, Industrial and Manufacturing Engineering, Isothermal process, Grain size, 020501 mining & metallurgy, 0205 materials engineering, chemistry, Mechanics of Materials, Ultimate tensile strength, Materials Chemistry, engineering, Tensile testing

Abstract

The present study was carried out to investigate the effects of Ni and Zr additions, individually or in combination, on the room-temperature tensile properties of 354 casting alloy (Al–9wt%Si–1.8wt%Cu–0.5wt%Mg) which was isothermally treated at temperatures in the range of 155–350 °C and aging times up to 1000 h. Tensile tests were carried out in the as-cast, solution heat-treated, and aged conditions using different aging times up to 1000 h. Quality charts were used as an evaluation tool for selecting the optimum conditions to achieve superior tensile properties and optimum quality in 354-type alloys. Zirconium reacts only with Ti, Si, and Al to form (Al,Si)2(Zr,Ti), (Al,Si)3(Zr,Ti), and Al3Zr phases. The beneficial effects of Zr and Ti additions appear in the refining of the α-Al grain size which reduces the size of the Al2Cu and α-Fe particles. Tensile test results at ambient temperature show a slight increase in alloys with Zr and Zr/Ni additions, particularly at aging temperatures above 240 oC. It is suggested that the maximum obtainable quality index values by means of heat treatment are the difference between the quality index values for the as-cast and solution heat treatment conditions.

Published

2021

5. Change of Tensile Properties with Aging Time and Temperature in Al-Si-Cu-Mg 354 Cast Alloys with/without Minor Addition of Ni and/or Zr

Author

Agnes M. Samuel, F. H. Samuel, M. H. Abdelaziz, E. A. Elsharkawi, and J. Hernandez-Sandoval

Subjects

Materials science, Article Subject, Alloy, Intermetallic, chemistry.chemical_element, 02 engineering and technology, Liquidus, engineering.material, 01 natural sciences, 0103 physical sciences, Ultimate tensile strength, General Materials Science, Ductility, Materials of engineering and construction. Mechanics of materials, 010302 applied physics, Zirconium, Metallurgy, General Engineering, technology, industry, and agriculture, 021001 nanoscience & nanotechnology, Microstructure, equipment and supplies, Nickel, chemistry, engineering, TA401-492, 0210 nano-technology

Abstract

The principal aim of the present research work was to investigate the effects of minor additions of nickel and zirconium on the strength of cast aluminum alloy 354 at room temperature (25°C). A decrease in tensile properties of ∼10% with the addition of 0.4 wt.% nickel is attributed to a nickel-copper reaction which interferes with the formation of Al2Cu precipitates. The platelet-like phases (Al,Si)3(Zr,Ni,Fe) and (Al,Si)3(Zr,Ti) are the main features observed in the microstructures of the tensile samples of alloys with Zr additions. The reduction in mechanical properties is due to the increase in the percentage of intermetallic phases formed during solidification; such particles would act as stress concentrators, decreasing the alloy ductility. The main effect of Zr addition lies in a significant reduction in the alloy grain size ∼40%, rather than an increase in the mechanical properties. Quality index charts could be used in assessing the effects of the Ni and Zr additions to the base alloy, as well as evaluating the heat treatment relationships to the alloy tensile properties, in particular when the system shows multiple precipitation reactions. Due to the high liquidus temperature of the Al-Zr binary phase diagram, addition of Zr beyond 0.2% is not recommended to avoid undissolved Zr.

Published

2021

6. Effect of Dispersoids and Intermetallics on Hardening the Al-Si-Cu-Mg Cast Alloys

Author

Herbert W. Doty, Agnes M. Samuel, F. H. Samuel, M. H. Abdelaziz, and J. Hernandez-Sandoval

Subjects

010302 applied physics, Materials science, Article Subject, Alloy, Metallurgy, General Engineering, Intermetallic, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, Grain size, Transmission electron microscopy, 0103 physical sciences, Ultimate tensile strength, engineering, Hardening (metallurgy), TA401-492, General Materials Science, Particle size, 0210 nano-technology, Materials of engineering and construction. Mechanics of materials, Tensile testing

Abstract

The principal aim of the present research work was to compare the role of dispersoids Al2O3 (∼15 μm average particle size) and SiC (∼15 μm average particle size) with that offered by Zr- and Ni-based intermetallics (∼35–70 μm average particle size) on the hardening of cast aluminum 354 alloy (9.1% Si, 0.12% Fe, 1.8% Cu, 0.008% Mn, 0.6% Mg, and 87.6% Al) at ambient temperature. There is no observable poisoning effect on the refinement of grain size after the addition of Zr to the alloys investigated in this study. The tensile test results were examined in light of the microstructural features of the corresponding alloy samples. The contribution of the added dispersoids or Ni and Zr alloying elements on the tensile properties of the 354 alloys was determined employing ∆P plots (where P = Property, UTS, YS, or %El), using the base alloy (in the as-cast condition) as a reference point. The tensile results were supported by investigating the precipitation-hardening phases using scanning and transmission electron microscopy as well as examining the fracture surfaces of selected conditions applying field emission scanning electron microscopy. The results show that, in all cases, Al2Cu phase is the main hardening agent. The contribution of about 1.5 vol% of SiC or Al2O3 to the strength of the base alloy is higher than that offered by Zr- and Ni-based intermetallics, under the same aging treatment.

Published

2021

7. Localized corrosion in an electrical submergible pump (ESP)

Author

A.M. Guzmán, R. Gonzalez-Lopez, J. Hernandez-Sandoval, and M.A.L. Hernandez-Rodriguez

Subjects

Mechanical load, Materials science, Metallurgy, General Engineering, Transgranular fracture, Monel, engineering.material, Corrosion, Intergranular fracture, Cracking, Pitting corrosion, Fracture (geology), engineering, General Materials Science

Abstract

A failure analysis was performed on bolts (Monel K-500) that serve to support and join critical components of an electrical submergible pump (ESP) located in a saline solution environment. Based on the experimental results, it can be concluded that pitting corrosion was the primary cause of failure. All fracture surfaces displayed an initial zone of intergranular fracture promoted by pitting corrosion and a propagation zone with transgranular fracture due to mechanical load. High concentrations of sulfur (S) and chlorine (Cl) were found on two corrosion product layers covering the bolt surface, revealing that an aggressive electrochemical reaction occurred in the stagnant environment. Under these layers, small pits of 10–30 μm in depth were observed that initiated the cracking paths that eventually became complete fractures.

Published

2015

8. Tribological study of TiN monolayer and TiN/CrN (multilayer and superlattice) on Co–Cr alloy

Author

A. Juarez-Hernandez, R. Cue-Sampedro, S. Gallegos-Cantú, M.A.L. Hernandez-Rodriguez, J. Hernandez-Sandoval, and E. Garcia-Sanchez

Subjects

Materials science, Scanning electron microscope, Precipitation (chemistry), Alloy, Metallurgy, chemistry.chemical_element, Surfaces and Interfaces, Substrate (electronics), engineering.material, Tribology, Condensed Matter Physics, Surfaces, Coatings and Films, chemistry, Coating, Mechanics of Materials, Sputtering, Materials Chemistry, engineering, Tin

Abstract

The wear performance of the Co–Cr alloys used for total joint replacement is a critical variable for the success of the implant. In order to add information in this field, the effect of superlattice coatings on wear response was investigated. In this work, TiN/CrN superlattices produced alternating TiN and CrN layers of nanometer-scale, were deposited by the means of reactive magnetron sputtering technique using two types of disc substrates: cast Co–Cr (ASTM F75) and cast Co–Cr+1 wt% B alloys. As the first attempt, a simple ball-on-disc tribological configuration was performed using Ringer׳s solution and Al 2 O 3 balls. In addition, scratch testing, optical and scanning electron microscopy were used to elucidate on the wear mechanisms involved. Adhesive and abrasive wear mechanisms were found on the wear track. Co–Cr+1 wt% B showed massive secondary phases precipitation which increases the adherence resistance in the interface between the system coating and the substrate improving slightly the wear response.

Published

2015

9. The ambient and high temperature deformation behavior of Al–Si–Cu–Mg alloy with minor Ti, Zr, Ni additions

Author

J. Hernandez-Sandoval, G.H. Garza-Elizondo, S. Valtiierra, A. M. Samuel, and F. H. Samuel

Subjects

Silicon, Materials science, Intermetallics, Quality indices, Alloy, Intermetallic, chemistry.chemical_element, Mechanical properties, High temperature deformation behavior, engineering.material, Stress concentrators, Copper alloys, Nickel, Intermetallic phase, Ultimate tensile strength, Titanium alloys, Ductility, Tensile testing, Zirconium, Al-si-cu-mg alloys, Metallurgy, High temperature effects, Aluminum alloys, Quality assurance, Cast aluminum alloy, chemistry, Stress concentration, Solution-treated conditions, engineering, Deformation (engineering), Aluminum, High temperature tensile properties

Abstract

The principal aim of the present work was to investigate the effects of minor additions of nickel and zirconium on the strength of cast aluminum alloy 354 at ambient and high temperatures. Tensile properties of the as-cast and heat-treated alloys were determined at room temperature and at high temperatures (190. °C, 250. °C, 350. °C). The results show that Zr reacts only with Ti, Si and Al. From the quality index charts constructed for these alloys, the quality index attains minimum and maximum values of 259. MPa and 459. MPa, in the as-cast and solution-treated conditions; also, maximum and minimum values of yield strength are observed at 345. MPa and 80. MPa, respectively, within the series of aging treatments applied. A decrease in tensile properties of ~10% with the addition of 0.4. wt.% nickel is attributed to a nickel-copper reaction. The reduction in mechanical properties due to addition of different elements is attributed principally to the increase in the percentage of intermetallic phase particles formed during solidification; such particles act as stress concentrators, decreasing the alloy ductility. Tensile test results at ambient temperatures show a slight increase (~10%) in alloys with Zr and Zr/Ni additions, particularly at aging temperatures above 240. °C. Additions of Zr and Zr. +. Ni increase the high temperature tensile properties, in particular for the alloy containing 0.2. wt.% Zr. +. 0.2. wt.% Ni, which exhibits an increase of more than 30% in the tensile properties at 300. °C compared with the base 354 alloy.

Published

2014