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Luiz Carlos Casteletti
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Proceedings Papers
Pedro Gabriel Bonella de Oliveira, Ricardo Tadeu Junior Aureliano, Luiz Carlos Casteletti, André Itman Filho, Amadeu Lombardi Neto ...
HT 2019, Heat Treat 2019: Proceedings from the 30th Heat Treating Society Conference and Exposition, 193-199, October 15–17, 2019,
Abstract
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This paper evaluates the influence of niobium additions on the wear behavior of high-silicon steel, representative of the advanced high strength steels used in the automotive industry. It describes the alloy compositions of the test samples used, the heat treatments to which they were subjected, and the tests that were subsequently performed. It also interprets test results and outlines key findings.
Proceedings Papers
Rafael Magalhães Triani, Lucas Fuscaldi De Assis Gomes, Luiz Carlos Casteletti, Amadeu Lombardi Neto, George Edward Totten
HT 2019, Heat Treat 2019: Proceedings from the 30th Heat Treating Society Conference and Exposition, 200-206, October 15–17, 2019,
Abstract
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This work investigates the effect of boriding and thermo-reactive deposition on 15B30 steel. The results presented in the paper show that these thermochemical treatments produce boride and carbide rich layers that improve surface hardness and wear resistance, and they do so without the adverse effects of adding more boron to the alloy.
Proceedings Papers
Pedro Gabriel Bonella de Oliveira, Fábio Edson Mariani, Luiz Carlos Casteletti, André Itman Filho, Amadeu Lombardi Neto ...
HT 2019, Heat Treat 2019: Proceedings from the 30th Heat Treating Society Conference and Exposition, 207-213, October 15–17, 2019,
Abstract
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The purpose of this work is to incorporate boriding and austempering treatments in a single thermal cycle and assess its effect on two high strength bainitic steels. The combined process, called boro-austempering, is a promising alternative to increase the surface wear resistance of advanced high strength steels as shown in the test results presented.
Proceedings Papers
Pedro Gabriel Bonella de Oliveira, Ricardo Tadeu Junior Aureliano, Fábio Edson Mariani, George Edward Totten, Luiz Carlos Casteletti
HT2017, Heat Treat 2017: Proceedings from the 29th Heat Treating Society Conference and Exposition, 469-473, October 24–26, 2017,
Abstract
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The AISI 440B (DIN 1.2210, X90CrMoV18) steel is one of the hardest among martensitic stainless steels. This type of steel is used in a variety of industrial applications where wear and corrosion are determinant, such as molds, parts and tools for the automotive and biomedical industries. Their superior mechanical properties are due to its high carbon (0.75-0.95 % C) and chromium (16-18% Cr) contents. Suitable coatings can increase wear resistance and expand these materials usability range. Boride coatings, with their high hardness and wear resistance are good candidates for this purpose. Boride layers were obtained by boriding treatment in a salt bath (a mixture of sodium borate and aluminum). The layer properties, such as hardness, thickness, layer/substrate interface morphology and phases formed are influenced by steel composition. In this work, the layers produced on AISI 440B steel were harder, thinner, with a smoother interface when compared to plain carbon steels due the larger amount of alloying elements. In order to evaluate mechanical properties of borided layers in samples of stainless steel AISI 440B, Optical Microscopy (OM) microstructural analysis, Vickers microhardness tests and micro-adhesive and micro-abrasive wear resistance tests were performed. The layers produced exhibited a hardness close to 2250 HV and excellent wear resistance far superior to that of substrate.
Proceedings Papers
Carolina Soares, Fábio Edson Mariani, Galtiere Corrêa Rêgo, Gustavo Satoru Takeya, George Edward Totten ...
HT2017, Heat Treat 2017: Proceedings from the 29th Heat Treating Society Conference and Exposition, 474-479, October 24–26, 2017,
Abstract
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In the present study unalloyed spheroidal graphite iron was compared with a sample alloyed with copper and nickel (Cu- Ni). Samples of those materials were treated in salt bath (a composite of sodium borate, aluminum, iron-niobium and/or iron-vanadium) at 1000 °C for 2 hours. This resulted in layers of niobium carbide (NbC), vanadium carbide (VC) and ternary carbide of niobium and vanadium (NbVC2). Characterization of these layers was obtained by optical microscopy, X-ray diffraction and microhardness Vickers. The microhardness and the thickness results were statistically analyzed by the two factors variance analysis method. The efficiency of the layered surface in increasing corrosion resistance was demonstrated by submitting it to potentiodynamic polarization corrosion tests.
Proceedings Papers
HT2015, Heat Treat 2015: Proceedings from the 28th Heat Treating Society Conference, 682-685, October 20–22, 2015,
Abstract
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The powder injection molding process is used to manufacture parts with complex shapes and high production demand. In orthodontic and medical applications, in which high hardness and corrosion resistance are required, 17-4 PH stainless steel is used mainly by this forming technique. The sintering atmosphere is responsible for controlling the chemical reactions that occur during material densification and is critical to the ultimate product quality. This research evaluated the influence of the sintering atmosphere on the hardness and corrosion resistance of this type of steel. The removal of the primary binder was conducted by chemical extraction by using a solvent with less environmental impact which has proved to be suitable for this purpose. The subsequent binder thermal extraction was performed by heating at temperatures of 250 and 450 °C and afterwards to 900 °C to initiate sintering. Nitrogen, vacuum and hydrogen atmospheres were used with sintering temperatures at 1250 and 1330 °C with 30 and 60 minute time step. It was shown that the densities achieved in hydrogen and vacuum atmospheres are similar and suitable by the regulations, whereas the nitrogen atmosphere resulted in lower performance. The hardness and corrosion resistance obtained with the use of hydrogen and vacuum atmospheres were also higher than those obtained for samples sintered in the nitrogen atmosphere.
Proceedings Papers
Fábio Edson Mariani, Gustavo Satoru Takeya, Luiz Carlos Casteletti, Amadeu Lombardi Neto, George Edward Totten
HT2015, Heat Treat 2015: Proceedings from the 28th Heat Treating Society Conference, 686-691, October 20–22, 2015,
Abstract
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Ductile cast iron can be heat-treated to obtain a significant property improvement austempering, resulting in Austempered Ductile Iron (ADI). Performance can be further improved by using boronized surface layers which are capable of reaching high hardnesses (2100 HV). In this work, samples of nodular cast iron alloyed with copper, copper-nickel and copper-nickel molybdenum were borided in a salt bath (borax + aluminum) at temperatures 850, 900 and 950 °C for 2 and 4 hours. After these treatments, the samples were directly austempered from the boriding temperature in salt baths at temperatures of 240, 300 and 360°C (boroaustempering) which avoided the need for a subsequent reheating for such processing. The boriding treatment produced uniform layers with thicknesses in the range 35-130 micrometers and hardness in the range from 1300 to 1700 HV.
Proceedings Papers
Fábio Edson Mariani, Gustavo Bortoluci de Assis, Luiz Carlos Casteletti, Amadeu Lombardi Neto, George Edward Totten
HT2015, Heat Treat 2015: Proceedings from the 28th Heat Treating Society Conference, 692-695, October 20–22, 2015,
Abstract
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Gray cast iron is primarily used for its low cost, high damping capacity, and excellent machinability. These properties are attributed to the presence of free graphite and the high fluidity of the molten metal, which allows for the easy casting of complex parts with thin walls. Applying suitable coatings can enhance wear resistance and broaden the material's range of applications. Niobium carbide, known for its high hardness, is a promising candidate for this purpose. In this study, samples of gray cast iron with the composition 3.47% C, 2.39% Si, 0.55% Mn, 0.15% Ni, 0.65% Cu, and the balance Fe were subjected to a niobizing powder thermo-reactive diffusion treatment. The coating mixture consisted of ferro-niobium, NH 4 Cl, and Al 2 O 3 , and the treatment was conducted at 900 °C for 2 hours. The resulting layers exhibited hardness values of 2000 HV, characteristic of niobium carbides. Micro-adhesive and micro-abrasive wear tests showed a significant increase in wear resistance due to this treatment.
Proceedings Papers
Fábio Edson Mariani, Galtiere Correa Rego, Luiz Carlos Casteletti, Amadeu Lombardi Neto, George Edward Totten
HT2015, Heat Treat 2015: Proceedings from the 28th Heat Treating Society Conference, 696-701, October 20–22, 2015,
Abstract
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Boriding thermochemical treatment produces layers with high hardness which improves the tribological performance of ductile cast iron while the austempering treatment improves the mechanical performance of the substrate. In this work, samples of the ductile cast iron alloyed with copper, copper-nickel and copper-nickel-molybdenum were borided in a salt bath (borax + aluminum) at temperatures of 850, 900 and 950°C during 2 and 4 hours. The data for the layers obtained were used to determine the diffusion coefficients and activation energies of this process. The results of the calculated diffusion coefficients were similar to those obtained by the direct measurements of the layer thicknesses. For the sample alloyed with Cu or Cu-Ni the activation energy obtained was 141.27 kJ/mol, and for the sample alloyed with Cu-Ni-Mo the value was 212.98 kJ/mol. The statistical parameters and the correlation coefficients (R) showed satisfactory agreement.
Proceedings Papers
Stenio Cristaldo Heck, Gustavo Satoru Takeya, Luiz Carlos Casteletti, Amadeu Lombardi Neto, George Edward Totten
HT2015, Heat Treat 2015: Proceedings from the 28th Heat Treating Society Conference, 702-705, October 20–22, 2015,
Abstract
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The use of high hardness surface layers can extend the life of components such as molds and dies by increasing their wear resistance. However, corrosion and oxidation resistance are also important to improve the durability of the components, especially for those that work under more demanding environments. In this work, samples of AISI H13 tool steel for hot work were borided by the pack cementation process, producing uniform and high hardness layers (1400-1800 HV). Afterwards the samples were subjected to a quasi-isothermal oxidation testing at 550 °C, the same working temperature of H13 steel in aluminum extrusion dies. Throughout the test, the mass gain of the untreated substrate, used for comparison, was 100%, while the borided sample treated at 900 °C for 2 hours had mass gain of 83% and the sample treated at 1000 °C for 4 hours presented a mass gain of 43%. The oxidation coefficients of the borided samples were similar, indicating similar oxidation kinetics but different from the untreated substrate.
Proceedings Papers
Luiz Carlos Casteletti, Fábio Edson Mariani, Amadeu Lombardi Neto, André Itman Filho, George Edward Totten
HT2015, Heat Treat 2015: Proceedings from the 28th Heat Treating Society Conference, 706-710, October 20–22, 2015,
Abstract
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Precipitation-hardening stainless steels are iron-nickel chromium alloys containing precipitation hardening elements such as aluminum, titanium, niobium and copper. In this work, heat treatment of a novel precipitation hardening stainless steel using niobium as a forming element for the hardening precipitates in order to increase its surface hardness and wear resistance was performed. The steel composition was 0.03C - 0.22Si - 17.86Cr - 3.91Ni - 2.19Mo - 1.96Nb (in wt%). The samples were solubilized at 1100 °C for 2 hours. Cooling was done in oil and the samples were subsequently aged at 500, 550 and 600 °C. The solubilized samples exhibited an average hardness of 30 HRc and after the aging treatments, the hardness increased to 46 HRc. The hardness increases during the aging treatments were very fast. A 5 minute treatment achieved hardness levels that were close to the maximum obtained for this alloy. Niobium was an efficient precipitation hardeners forming a Laves phase of the type Fe 2 Nb.
Series: ASM Handbook
Volume: 4D
Publisher: ASM International
Published: 01 October 2014
DOI: 10.31399/asm.hb.v04d.a0005977
EISBN: 978-1-62708-168-9
Abstract
Stainless steels are essential for the modern industrial civilization because of their corrosion resistance, especially in the chemical, petrochemical, and food industries. This article discusses the classification of the various types of stainless steels, including martensitic, ferritic, austenitic, duplex (ferritic-austenitic), and precipitation-hardening stainless steels. It presents a checklist of characteristics to be considered in selecting the proper type of stainless steel for a specific application. The article also outlines the need to promote the formation of an effective protective passive layer in stainless steels. It discusses hardness, fatigue and fretting properties, tribological properties, wear resistance, and corrosion-wear process of the S-phase layer. The article describes two thermochemical nitriding techniques of stainless steels: plasma-assisted nitriding techniques and non-plasma assisted nitriding processes. It also describes the difficulties in stainless steel nitriding/carburizing.