10 results on '"Bontha, Srikanth"'
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2. An Experimental Investigation on Microstructure, Mechanical Properties and Corrosion Performance of CMT-Wire Arc Additively Manufactured Al-4043 Alloy
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Manjhi, Shambhu Kumar, Kumar, Bobbili Sai Suneel, Rodrigues, Joswin Prajwal, Sekar, Prithvirajan, Bontha, Srikanth, and Balan, A. S. S.
- Published
- 2023
- Full Text
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3. Additive manufacturing of magnesium alloys: Characterization and post-processing.
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Manjhi, Shambhu Kumar, Sekar, Prithivirajan, Bontha, Srikanth, and Balan, A. S. S.
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THREE-dimensional printing ,MAGNESIUM alloys ,DIRECT energy conversion ,MICROSTRUCTURE ,CORROSION & anti-corrosives - Abstract
Magnesium and its alloys remain perilous in the framework of light weighting and advanced devices structure such as rockets and satellites. However, the utilization of Magnesium (Mg) is increasing every year, revealing growing demands in manufacturing industries. Manufacturing of Mg components is challenging because of their HCP crystal structure and limited ductility. In this context, additive manufacturing (AM) provides the flexibility to manufacture complex shape components with excellent dimensional stability. It also provides a new possibility for utilizing novel component structures that increase the applications for Mg alloy. This review herein pursues to holistically explore the additive manufacturing of Mg alloy with a synopsis of processes used and microstructure, mechanical properties, corrosion behaviour and postprocessing of AMed Mg alloy. The challenges and future scope of AMed Mg alloys are critically explored. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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4. Effect of equiaxed grains and secondary phase particles on mechanical properties and corrosion behaviour of CMT- based wire arc additive manufactured AZ31 Mg alloy.
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Manjhi, Shambhu Kumar, Sekar, Prithivirajan, Bontha, Srikanth, and Balan, A.S.S.
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PHYSIOLOGIC salines ,TENSILE strength ,LIGHTWEIGHT materials ,ALLOYS ,MAGNESIUM alloys ,CORROSION resistance - Abstract
Wire arc additive manufacturing (WAAM) has drawn tremendous attention for manufacturing large and complex components of lightweight material at a moderate cost due to its high deposition rate and energy efficiency. Generally, WAAM-Mg alloy comprises columnar and columnar dendrite grains due to high cooling rates and thermal gradients responsible for anisotropic mechanical properties. To overcome this challenge, in this work, CMT-WAAM, which generally uses comparatively low heat input (33% lower than conventional WAAM), was used to deposit AZ31 Mg thin wall. The metallurgical characterization of the deposited thin wall of the top (T), middle (M) and bottom (B) sections reveals equiaxed grains of average sizes ∼ 58, ∼ 63 and ∼ 38 µm, respectively. In addition, TEM results exhibit the formation of secondary phase particles, i.e., β-Mg 17 Al 12 and ɳ-Al 8 Mn 5. Further, the ultimate tensile strength (UTS) and % elongation (% EL) in the travel direction (UTS = 224 MPa, % EL= 23.47%) are superior to that obtained in the build direction (UTS = 217 MPa, % EL = 20.82%). The corrosion resistance of WAAMed AZ31 Mg alloy is higher than wrought (cold rolled) AZ31 Mg alloy in Hank's balanced salt solution (HBSS). The results of this study reveal the potential of CMT-WAAM to deposit different grades of Mg with desired microstructure, mechanical properties and corrosion resistance. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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5. Microstructure, mechanical and wear properties of the A357 composites reinforced with dual sized SiC particles.
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Lakshmikanthan, Avinash, Bontha, Srikanth, Krishna, M., Koppad, Praveennath G., and Ramprabhu, T.
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MECHANICAL wear , *PARTICLES , *SCANNING electron microscopes , *OPTICAL microscopes , *MICROSTRUCTURE , *WEAR resistance - Abstract
Abstract Current work reports on the development of A357 alloy composite which is reinforced with dual size SiC particles by stir casting route. Influence of different weight fractions (3% coarse+ 3% fine, 4% coarse + 2% fine, and 2% coarse + 4% fine) of dual size SiC particles on mechanical properties and wear resistance of A357 composites is the focus of this work. Hardness and tensile properties were studied for dual size composites and then were compared with A357 alloy. Microstructural study, fractured surface and worn surface investigation were carried out using optical and scanning electron microscopes respectively. Microstructural analysis showed fairly uniform dispersion of dual size SiC particles in A357 matrix with good interfacial bonding. Compared to A357 alloy, the composites showed improvement in hardness, yield, and tensile strength. In particular, composite with 4 wt. % of fine and 2 wt. % of large SiC particles displayed the highest tensile strength while composite with 4 wt. % of large and 2 wt. % of fine SiC particles exhibited high hardness and wear resistance among A357 alloy and dual particle size composites. The strengthening mechanisms that contributed to improvement in strength values were effective load transfer and dislocation strengthening due to thermal mismatch. Highlights • Uniform dispersion of dual size SiC particles in A357 matrix. • Continuous interface and good bonding between A357 matrix and dual size SiC particles. • Significant improvement in hardness and mechanical properties of dual size composites compared to A357 alloy. • Improvement in wear resistance of dual size composites compared to A357 alloy. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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6. Effects of process variables and size-scale on solidification microstructure in beam-based fabrication of bulky 3D structures
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Bontha, Srikanth, Klingbeil, Nathan W., Kobryn, Pamela A., and Fraser, Hamish L.
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SOLIDIFICATION , *MICROSTRUCTURE , *CRYSTALS , *MICROFABRICATION , *INDUSTRIAL applications of electron beams , *TITANIUM-aluminum-vanadium alloys , *MATERIALS science , *LASERS in chemistry - Abstract
Abstract: A number of laser and electron beam-based fabrication processes are under consideration for aerospace components, where the ability to obtain a consistent and desirable microstructure and resulting mechanical properties is of critical concern. To this end, this work employs a combination of analytical and numerical modeling approaches to investigate the effects of process variables and size-scale on solidification microstructure (grain size and morphology) in beam-based fabrication of bulky 3D structures. Thermal process maps are developed for predicting solidification microstructure in any material system, and results are plotted on solidification maps to investigate trends in grain size and morphology in Ti–6Al–4V. The results of this work suggest that changes in process variables (beam power and velocity) can result in a grading of the microstructure throughout the depth of the deposit, with a transition from columnar to mixed or equiaxed microstructure at higher powers. [Copyright &y& Elsevier]
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- 2009
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7. A study on the effect of process parameters and scan strategies on microstructure and mechanical properties of laser directed energy deposited IN718.
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Thanumoorthy, Raja S., Sekar, Prithvirajan, Bontha, Srikanth, and Balan, ASS
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CRYSTAL texture , *LAVES phases (Metallurgy) , *GRAIN size , *MICROSTRUCTURE , *X-ray diffraction - Abstract
The present study focuses on understanding the effect of scan strategy on the microstructure and mechanical properties of LDED fabricated IN718 built at optimized process conditions from single track analysis. Initially, single track studies were conducted by varying laser power, scan speed, and feed rate (3 levels) to optimize process parameters for bulk deposition. Based on the dilution, aspect ratio, track continuity and melt pool shape, best process parameter were chosen for depositing bulk structures. Bulk rectangular specimens were fabricated using the LDED process for different infill rotation (0°, 45°, 67°, and 90°) at optimized process conditions. Infill rotation did not show any significant change in the density of the samples. However, grain size measurement from EBSD and SEM micrographs revealed a substantial difference in grain size between samples without infill rotation (0°) and samples with infill rotation (45°, 67°, and 90°). XRD and EDS mapping revealed higher the formation of secondary laves phases with infill rotation as a result of higher cooling rate. Similarly, melt pool shape and arrangement showed significant variation with different infill angles. Samples with 0° and 90° infill rotation exhibited strong crystallographic texture along the build direction. There was a significant variation in the microhardness and tensile strength of the build with variation in infill rotation. This variation in mechanical properties were attributed to grain size, LAGB's fraction, secondary phases, and crystallographic texture. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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8. Effect of deposition strategy and post processing on microstructure and mechanical properties of serviced Inconel 625 parts repaired using laser directed energy deposition.
- Author
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Chaurasia, Jitender K., Jinoop, A N, Paul, C.P., Bindra, K.S., Balla, Vamsi Krishna, and Bontha, Srikanth
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INCONEL , *TENSILE strength , *MICROSTRUCTURE , *ULTIMATE strength , *STRENGTH of materials , *HEAT treatment , *EDIBLE coatings - Abstract
[Display omitted] • Repair of IN625 serviced components is carried out using LDED process. • Yield strength is found to be highly influenced by solution treatment. • As-deposited samples exhibit better hardness than wrought and heat-treated samples. • LDED followed by heat-treatment results in consistent mechanical properties. In the present work, an attempt is made to understand and explore the repair capabilities of the Laser Directed Energy Deposition (LDED) process on Nickel based superalloy Inconel 625 (IN625). Samples were extracted from a wrought plate of IN625 and then were subjected to a fatigue test to mimic a component in service for repairing. Further, deposition was carried out on these fatigued tensile sample surfaces i.e., Top, Top & bottom, One side and Both sides. The samples were also solution-treated at 1200 °C for 90 mins. Microstructure and mechanical properties were evaluated and then compared between the different deposition strategies and sample heat-treatment conditions. Tensile properties were compared for all the three sample conditions viz. wrought alloy, as repaired and solution treated. Results indicate sound deposition with minimal porosity in all the four deposition strategies using the LDED process with a mean deposit height of 1.02 ± 0.25 mm. Microstructural analysis revealed mixed dendrite and columnar structure in the case of as-deposited samples whereas, solution treated samples exhibited recrystallized equiaxed grains with the presence of annealing twins. The as-deposited samples show a ductile mode of failure with a maximum ultimate strength of 830 MPa, yield strength of 350 MPa and elongation of 72%. For solution treated samples, a maximum ultimate tensile strength of 620 MPa, yield strength of 270 MPa and elongation of 73% were observed. The strength of the material was found to be highly influenced by the solution treatment. [ABSTRACT FROM AUTHOR]
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- 2024
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9. Effect of heat treatment on microstructure, corrosion, and shape memory characteristics of laser deposited NiTi alloy.
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Marattukalam, Jithin J., Balla, Vamsi K., Das, Mitun, Bontha, Srikanth, and Kalpathy, Sreeram K.
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ALLOYS , *ENERGY density , *MICROSTRUCTURE , *HEAT treatment , *X-ray diffraction , *LASER deposition - Abstract
The aim of this work is to study the effect of heat treatment on the microstructure, phase transformations, shape memory characteristics and corrosion behaviour of laser deposited equiatomic NiTi alloy. Dense samples of NiTi alloy were fabricated using Laser Engineered Net Shaping (LENS™) with two different laser energy densities by varying the scan speed and laser power. These samples were annealed for 30 min at 500 °C and 1000 °C in flowing argon, followed by furnace-cooling to room temperature. The resulting microstructures and properties were compared with the corresponding as-deposited samples. Microstructural analysis after heat treatment showed needle-shape martensite in the samples processed at lower laser energy density of 20 J/mm 2 , and lenticular or plate-like martensite in the samples processed at 80 J/mm 2 . The XRD results revealed relatively high concentration of martensite (B19′) in heat-treated NiTi alloy compared to as-processed samples. Furthermore, the heat treatment decreased the forward and reverse transformation temperatures of NiTi alloy from 80 – 95 °C to 20–40 °C, presumably due to annihilation of thermally induced defects. Interestingly, the samples annealed at 500 °C showed a measurable increase of 1–2% in the shape memory recovery, from the net recovery of 8% exhibited by the as-processed NiTi alloy. The corrosion resistance of laser-processed NiTi alloy decreased upon annealing. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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10. Microstructure and corrosion behavior of laser processed NiTi alloy.
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Marattukalam, Jithin J., Singh, Amit Kumar, Datta, Susmit, Das, Mitun, Balla, Vamsi Krishna, Bontha, Srikanth, and Kalpathy, Sreeram K.
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MICROSTRUCTURE , *NICKEL-titanium alloys , *MANUFACTURING processes , *LASER power transmission , *TEMPERATURE effect - Abstract
Laser Engineered Net Shaping (LENS™), a commercially available additive manufacturing technology, has been used to fabricate dense equiatomic NiTi alloy components. The primary aim of this work is to study the effect of laser power and scan speed on microstructure, phase constituents, hardness and corrosion behavior of laser processed NiTi alloy. The results showed retention of large amount of high-temperature austenite phase at room temperature due to high cooling rates associated with laser processing. The high amount of austenite in these samples increased the hardness. The grain size and corrosion resistance were found to increase with laser power. The surface energy of NiTi alloy, calculated using contact angles, decreased from 61 mN/m to 56 mN/m with increase in laser energy density from 20 J/mm 2 to 80 J/mm 2 . The decrease in surface energy shifted the corrosion potentials to nobler direction and decreased the corrosion current. Under present experimental conditions the laser power found to have strong influence on microstructure, phase constituents and corrosion resistance of NiTi alloy. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
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