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2. Experimentation and analysis of powder injection molded Ti10Nb10Zr alloy: a promising candidate for electrochemical and biomedical application

Author

Isıl Yemisci, Ozal Mutlu, Nagihan Gulsoy, Kate Kunal, Sundar Atre, and H. Ozkan Gulsoy

Subjects
Mining engineering. Metallurgy, TN1-997
Abstract

This paper describes the microstructural, mechanical and corrosion properties of injection molded Ti10Nb10Zr alloys. Ti10Nb10Zr powder was injection molded with wax-based binder. The critical powder loading for injection molding was 55 vol% for feedstock. Binder debinding was performed in solvent and thermal method. After debinding the samples were sintered at different temperatures and times in vacuum atmosphere (10−5 mbar) to obtain fully dense parts. Metallographic studies were conducted to determine the extent of densification and the corresponding microstructural changes. The electrochemical property and biocompatibility of the sintered samples were performed electrochemically, by self-body-fluid immersion tests and cell culture experiments. The results show that Ti10Nb10Zr alloys could be sintered to a maximum 99% of theoretical density. Maximum ultimate tensile strength, elongation and hardness obtained were 748 MPa, 14.3 and 114 HRB respectively at 1500 °C for 3 h. Additionally, the sintered Ti10Nb10Zr alloys exhibited high mechanical and corrosion properties in a physiological environment. Keywords: Powder injection molding, Titanium alloy, Sintering, Mechanical properties, Biocompatible

Published
2019
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3. Effects of layer thickness in laser-powder bed fusion of 420 stainless steel

Author

Ozkan Gulsoy, Martin Kearns, Gautam Gupta, Sundar V. Atre, and Subrata Deb Nath

Subjects
0209 industrial biotechnology, Materials science, Mechanical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, Industrial and Manufacturing Engineering, Corrosion, 020901 industrial engineering & automation, Metal injection molding, Martensite, Ultimate tensile strength, Surface roughness, Tempering, Composite material, Elongation, 0210 nano-technology
Abstract

Purpose The purpose of this paper is to investigate effects of layer thickness on densification, surface morphology, microstructure and mechanical and corrosion properties of 420 stainless steel fabricated by laser-powder bed fusion (L-PBF). Design/methodology/approach Standard specimens were printed at layer thickness of 10, 20 and 30 µm to characterize Archimedes density, surface roughness, tensile strength, elongation, hardness, microstructural phases and corrosion performance in the as-printed and heat-treated condition. Findings Archimedes density slightly increased from 7.67 ± 0.02 to 7.70 ± 0.02g/cm3 and notably decreased to 7.35 ± 0.05 g/cm3 as the layer thickness was changed from 20 µm to 10 and 30 µm, respectively. The sensitivity to layer thickness variation was also evident in properties, the ultimate tensile strength of as-printed parts increased from 1050 ± 25 MPa to 1130 ± 35 MPa and decreased to 760 ± 35 MPa, elongation increased from 2.5 ± 0.2% to 2.8 ± 0.3% and decreased to 1.5 ± 0.2, and hardness increased from 55 ± 1 HRC to 57 ± 1 HRC and decreased to 51 ± 1 HRC, respectively. Following heat treatment, the ultimate tensile strength and elongation improved but the general trends of effects of layer thickness remained the same. Practical implications Properties obtained by L-PBF are superior to reported properties of 420 stainless steel fabricated by metal injection molding and comparable to wrought properties. Originality/value This study successfully the sensitivity of mechanical and corrosion properties of the as-printed and heat-treated parts to not only physical density but also microstructure (martensite content and tempering), as a result of changing the layer thickness. This manuscript also demonstrates porosity evolution as a combination of reduced energy flux and lower packing density for parts processed at an increasing layer thickness.

Published
2020

4. Effects of Nb and Mo on the microstructure and properties of 420 stainless steel processed by laser-powder bed fusion

Author

Vincent Wuelfrath-Poirier, Subrata Deb Nath, Sundar V. Atre, Gautam Gupta, Ozkan Gulsoy, Emma Clinning, Martin Kearns, and Gilles L'Espérance

Subjects
0209 industrial biotechnology, Materials science, Metallurgy, Biomedical Engineering, Niobium, chemistry.chemical_element, Context (language use), 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, Industrial and Manufacturing Engineering, Corrosion, 020901 industrial engineering & automation, chemistry, Molybdenum, Martensite, General Materials Science, Tempering, Elongation, 0210 nano-technology, Engineering (miscellaneous)
Abstract

Niobium (Nb) and molybdenum (Mo) are conventionally added to stainless steels to improve their mechanical and corrosion properties. However, the effects of Nb and Mo addition on the processing and properties in laser-powder bed fusion (L-PBF) have not been well investigated, especially in the context of 420 stainless steel. In this study, 420 stainless steel pre-alloyed with Nb (1.2 wt.%) and Mo (0.57 wt.%) was processed by L-PBF and characterized in terms of its physical, mechanical and corrosion properties as well as microstructure. The addition of Nb and Mo did not significantly affect the densification of 420 stainless steel when printed over an energy range of 28–75 J/mm3 and a maximum density of 99.3 ± 0.02% theoretical at 63 J/mm3 was achieved. In mechanical tests, L-PBF 420 stainless steel specimens exhibited higher mechanical properties in the presence of Nb and Mo. After heat treatment, the UTS of 420 stainless steel with Nb and Mo improved to 1750 ± 30 MPa and elongation to 9.0 ± 0.2%, much higher than previously reported properties achieved in L-PBF and exceeding wrought 420 stainless steel. The tempering of martensite phases as well as the presence of nanoscale NbC were found to correlate with improved mechanical properties. In electrochemical tests, 420 stainless steel exhibited slightly better corrosion properties with the addition of Nb and Mo.

Published
2019

6. Microstructure-property relationships of 420 stainless steel fabricated by laser-powder bed fusion

Author

Ozkan Gulsoy, Martin Kearns, Gautam Gupta, Subrata Deb Nath, Sundar V. Atre, and Harish Irrinki

Subjects
Austenite, Materials science, General Chemical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, Corrosion, 020401 chemical engineering, Metal injection molding, Powder metallurgy, Martensite, Ultimate tensile strength, 0204 chemical engineering, Elongation, Composite material, 0210 nano-technology
Abstract

In this study, we report the mechanical properties, microstructure and corrosion behavior 99+ % dense 420 stainless steel parts fabricated by laser-powder bed fusion (L-PBF). As-printed L-PBF parts exhibited an ultimate tensile strength of 1050 ± 25 MPa, yield strength of 700 ± 15 MPa, an elongation of 2.5 ± 0.2% and a hardness of HRC 55 ± 1. After the heat treatment operation at 315 °C, the ultimate tensile strength improved significantly to 1520 ± 30 MPa, yield strength increased to 950 ± 20 MPa, and elongation increased to 6.3 ± 0.2% respectively whereas hardness remained at HRC 53 ± 1. These properties are higher than previously reported literature values for 420 stainless steel fabricated by L-PBF, metal injection molding and powder metallurgy routes. The microstructure indicated a mixture of martensite and retained austenite phases in the as-printed parts. After heat treatment, the microstructure was richer in tempered martensitic laths that is consistent with the enhancement of ultimate tensile strength, yield strength, and elongation without appreciable change in hardness. The corrosion behavior of the as-printed L-PBF parts exhibited a corrosion current of 2.85 ± 0.4 mA.cm−2, a polarization resistance of 17,100 ± 520 Ω.cm−2 and a corrosion rate of 28 ± 2 μm/year which were comparable to the corrosion properties of wrought 420 stainless steel. A significant increase in pitting potential (170 mV) was obtained after the heat treatment.

Published
2019

8. Effects of powder characteristics and processing conditions on the corrosion performance of 17-4 PH stainless steel fabricated by laser-powder bed fusion

Author

Harish Irrinki, Ozkan Gulsoy, Gautam Gupta, Jason Stitzel, Sundar V. Atre, Talia Harper, and Sunil Badwe

Subjects
Fusion, Materials science, 020209 energy, Metallurgy, 030206 dentistry, 02 engineering and technology, Laser, Industrial and Manufacturing Engineering, Corrosion, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Powder bed, 0202 electrical engineering, electronic engineering, information engineering, Energy density, Polarization (electrochemistry)
Abstract

Powder characteristics and processing conditions are known to strongly influence the densification of parts fabricated by the laser-powder bed fusion (L-PBF) process. However, the influence of powder and L-PBF process parameters on corrosion performance of parts has not been studied extensively. In this paper, the effects of processing conditions (energy density) and powder characteristics (shape and size) on the corrosion performance of 17-4 PH stainless steel parts produced by L-PBF were investigated. The corrosion performance of the L-PBF parts was evaluated using corrosion current, polarization resistance and corrosion rate values from the potentiostatic polarization curves. It was observed that the density and consequently corrosion performance of L-PBF parts using coarser water-atomized (D50 = 24 and 43 µm) powders increased when the energy density was increased from 64 to 104 J/mm3. However, the density and subsequent corrosion performance of the L-PBF parts was relatively higher for the finer gas (D50 = 13 µm) and water-atomized (D50 = 17 µm) powders when fabricated using the same range of energy densities. At an energy density of 104 J/mm3, the corrosion performance of L-PBF parts fabricated using water-atomized 17-4 PH stainless steel powders all powders exhibited higher polarization resistance (28,000 ± 500 Ω) than the wrought sample (25,000 ± 1000 Ω) in the 0.5 M NaCl environment, indicative of better corrosion properties.

Published
2018

9. Effects of particle characteristics on the microstructure and mechanical properties of 17-4 PH stainless steel fabricated by laser-powder bed fusion

Author

Sundar V. Atre, Somayeh Pasebani, Harish Irrinki, Sunil Badwe, Ozkan Gulsoy, John Samuel Dilip Jangam, Kunal H. Kate, and Jason Stitzel

Subjects
010302 applied physics, Austenite, Materials science, General Chemical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Grain size, Phase (matter), Martensite, 0103 physical sciences, Ultimate tensile strength, Particle, Laser power scaling, Composite material, 0210 nano-technology
Abstract

The effects of powder characteristics (powder shape, size and type) and processing conditions (laser power and scanning speed) on the mechanical properties and microstructures of laser powder bed fusion (L-PBF) 17-4 PH stainless steel were studied using four types of powders. The % theoretical density, ultimate tensile strength, hardness of L-PBF parts are sensitive to energy density and starting powder shape, size and type. The density and mechanical properties of both water and gas-atomized powders increased with increased energy density. The gas-atomized (D50 = 13 μm) powders which are spherical in shape and water-atomized (D50 = 17 μm) powders of high tap density produced low-porosity and high-density (~97% density) L-PBF parts at low energy densities of 64 and 80 J/mm3. The increase in energy density to 104 J/mm3 resulted in high dense (97 ± 0.5%) water- and gas-atomized powders L-PBF parts. However, even at a high % theoretical density (97 ± 1%), the properties of L-PBF parts varied over a relatively large range (UTS: 500–1100 MPa; hardness: 25–39 HRC; elongation: 10–25%). This large variation in mechanical properties could be attributed the martensite and austenite phase as well as grain size in the L-PBF parts. Furthermore, the martensite and austenite phase content and of the L-PBF parts were also sensitive to the energy density and starting powder type.

Published
2018

10. Water Absorption, Friction and Wear Behaviors of Polypropylene Composites Filled with Hydroxyapatite

Author

Münir Taşdemir and Ozkan Gulsoy

Subjects
Polypropylene, Friction coefficient, Materials science, Absorption of water, Mechanical Engineering, Polypropylene composites, Composite number, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Mechanics of Materials, Polymer composites, General Materials Science, Composite material, 0210 nano-technology
Abstract

In the present work, the friction and wear properties of Polypropylene (PP) based composites filled with Hydroxyapatite (HA) particles were studied. Fillers contents in the PP were 10, 20, and 30 wt%. The effects of hydroxyapatite ratio on the water absorption, friction and wear properties of the polymer composites is presented. The result showed that the addition of HA to the composite changed the water absorption, friction coefficient and wear rate.

Published
2017

11. Investigation of Creep Behavior of CNT Reinforced Ti6Al4V Under Dynamic Loads

Author

Ozkan Gulsoy, A. N. Gulluoglu, Burcu Nilgün Çetiner, İsmail Topcu, ALKÜ, and 0-belirlenecek

Subjects
Dynamic creep, Materials science, Sintering, Creep, law, Carbon nanotubes, Ti6Al4V, Titanium alloy, General Chemistry, Carbon nanotube, Composite material, law.invention
Abstract

WOS: 000510612100009 This study investigates the effects of addition of Carbon nanotube (CNT) at different volume ratios (0.5- 5%) into Ti6Al4V matrix by mechanical alloying in terms of the density, microstructure, hardness and creep under dynamic load. As a result of the good bonding of carbon nanotubes powders with the main matrix, Ti-6Al-4V/CNT composites have experienced change both in microstructure and mechanical properties (such as hardness, density) and, correspondingly, qualitatively creep behaviour of Ti-6Al-4V matrix alloy has been improved compared to the lean one. The density of CNT reinforced Ti6Al4V composites sintered at 1300 degrees C for 3h decreases with increasing CNT content. The hardness tests indicated that the hardness of composites increased with CNT addition. In addition, although creep strain is decreased continually with CNT content until 5%, creep life increased with increasing CNT content until 4% of CNT but decreased above 4%. After sintering at 1300 degrees C under vacuum for 3 hours the density of the composite material reached to a level of 98.5 %, the microhardness to 538 HV and the creep behaviour was improved. The characterization of Ti6Al4V/CNT composites after mechanical alloying was carried out using scanning electron microscopy (SEM), energy dispersive x-rays spectroscopy (EDS) analysis and X-ray diffraction (XRD) methods. Although Ti-6Al-4V alloys are used as biomaterial, this study aimed at using MWCNTs containing Ti-6Al-4V composites at high temperature applications. Because MWCNTs reinforced Ti-6Al-4V composites are cheaper and have lower weight than the other materials used in this kind of applications. Scientific Research Project Program of Marmara UniversityMarmara University [FEN-K-070317-0107] This work was supported by the Scientific Research Project Program of Marmara University (FEN-K-070317-0107).

Published
2020

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