Microwave Sintering of Ti6Al4V: Optimization of Processing Parameters for Maximal Tensile Strength and Minimal Pore Size

Singh, Dilpreet; Rana, Abhishek; Sharma, Pawan; Pandey, Pulak M.; Kalyanasundaram, Dinesh

doi:10.3390/met8121086

Cited by 10 publications

(5 citation statements)

References 20 publications

(22 reference statements)

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“…In the research article published by our group earlier, experiments were conducted on cadaveric human elbow bones. The flexural strength of the humerus and ulna bones were 128.43 ± 6.17 MPa and 135.16 ± 30.43 MPa, respectively (Singh et al , 2018c). The flexural strength of the developed Ti6Al4V sintered implant overlaps with the elbow bone.…”

Section: Resultsmentioning

confidence: 99%

“…Post extraction, the implant was cleaned using a wire brush for any leftover mold debris attached to the surface of the sintered implant. The effect of processing parameters of the sintering process was studied earlier (Singh et al, 2018b). The microwave pressureless sintering process was optimized for obtaining maximum strength, density and minimum shrinkage in an earlier publication by the authors and has been published elsewhere (Singh et al, 2018a).…”

Section: Manufacturing Of the Elbow Implantmentioning

confidence: 99%

“…This manufacturing process has an inherent capability to produce porous structures at optimized process parameters at low cost and with operational ease. The authors in their earlier publications had performed a multi-parametric optimization of the Polyjet rapid prototyping followed by a microwave sintering process for various desired output responses such as pore size, compressive strength and tensile strength (Singh et al, 2018a(Singh et al, , 2018b.…”

Section: Introductionmentioning

confidence: 99%

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Design and development of 3D printing assisted microwave sintering of elbow implant with biomechanical properties similar tohuman elbow

Singh

Garg

Pandey

et al. 2021

RPJ

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Purpose The purpose of this paper is to establish a methodology for the design and development of patient-specific elbow implant with an elastic modulus close to that of the human bone. One of the most preferred implant material is titanium alloy which is about 8 to 9 times higher in strength than that of the human bone and is the closest than other metallic biomedical materials. Design/methodology/approach The methodology begins with the design of the implant from patient-specific computed tomography information and incorporates the manufacturing of the implant via a novel rapid prototyping assisted microwave sintering process. Findings The elastic modulus and the flexural strength of the implant were observed to be comparable to that of human elbow bones. The fatigue test depicts that the implant survives the one million cycles under physiological loading conditions. Other mechanical properties such as impact energy absorption, hardness and life cycle tests were also evaluated. The implant surface promotes human cell growth and adhesion and does not cause any adverse or undesired effects i.e. no cytotoxicity. Practical implications Stress shielding, and therefore, aseptic loosening of the implant shall be avoided. In the event of any trauma post-implantation, the implant would not hurt the patient. Originality/value The present study describes a methodology for the first time to be able to obtain the strength required for the medical implant without sacrificing the fatigue life requirement.

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Section: Resultsmentioning

confidence: 99%

Section: Manufacturing Of the Elbow Implantmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Design and development of 3D printing assisted microwave sintering of elbow implant with biomechanical properties similar tohuman elbow

Singh

Garg

Pandey

et al. 2021

RPJ

Self Cite

View full text Add to dashboard Cite

show abstract

“…These studies include identifying the optimized process parameters that lead to the maximal tensile strength [24], deposition orientation optimization [25], and establishing a differential evolution that optimizes the model to achieve good tensile strength [26], to name a few [27,28]. For other AM processes, optimizing processing parameters to maximize the tensile strength for microwave sintering of Ti6Al4V [29] and selective electron beam melting (SEBM) of stainless steel 316L parts were investigated [30]. However, the modeling and optimization of the tensile strength of SLM processed parts are still lacking.…”

Section: Introductionmentioning

confidence: 99%

Multi-Objective Optimization of Selective Laser Melting Processes for Minimizing Energy Consumption and Maximizing Product Tensile Strength

Zhu

Chen

et al. 2022

Metals

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As a sustainable manufacturing technology, selective laser melting (SLM) is a typical additive manufacturing (AM) method with high flexibility and material efficiency. However, SLM is intrinsically energy-intensive than conventional machining processes. By contrast, part quality, especially the tensile strength, is critical for applying SLM technology. Therefore, this study aims to minimize the process energy consumption and maximize the part tensile strength by optimizing three essential process parameters, namely laser power, scan speed, and overlap rate. First, single track and single layer experiments are applied to determine the constraints of process parameters. Then, analytical and statistical models are used to calculate energy consumption and part tensile strength. Finally, the process parameters to achieve compromised optimal solutions are located using the nondominated sorting genetic algorithm II (NSGA-II). A case study of a waveguide part manufactured via the SLM process is employed to demonstrate the effectiveness of the proposed approach. Results showed that both energy consumption and part tensile strength could be improved moderately using the proposed method. This study can potentially guide the process parameter selection for new material AM processes and improve the AM product quality.

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“…Currently, conventional sintering is restricted by its natural impediments of uneven temperature and long heating time, whereas microwave sintering features a fast heating speed and more uniform heating and delivers consistent temperature fields [6][7][8]. Microwave sintering technology is broadly adopted in the preparation of other materials: BCTZ piezoelectric ceramics [9], BaTiO 3 ceramics [10], lithium-ion battery electrodes (Li 2 TiO 3 ceramics) [11], ZnO-based piezoresistive materials [12], Si 3 N 4 ceramics [13], Ni-TiC composites [14], Cu-MWCNT nanocomposites [15], graphite alkene-ceramic composites [16], BaTiO 3 -Ag high-energy capacitors [17], various composite materials and hardened alloy materials [18,19], high-performance heat-resistant molybdenum materials [20], and titanium alloy materials [21]. Nevertheless, while utilizing microwave sintering, there are circumstances where the sample fails to absorb microwaves uniformly at low temperatures, leading to the results of uneven heating and potential cracks on the final products.…”

Section: Introductionmentioning

confidence: 99%

Effects of Simulation‐Guided Microwave Presintering Process on the Preparation and Final Properties of Pure Ceramic Rings: Lower Sintering Temperature and Higher Mechanical Properties

Xiao

Zhou

Zhao

et al. 2020

Advances in Materials Science and Engineering

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In order to improve the performance and endurance of steel rings used for twisting and winding yarns in the textile industry, a more wear-resistant ceramic version is studied and examined by conducting multiple simulations combined with microwave sintering experiments of the ring preparation process, aiming to reduce manufacturing costs and improve efficiency. The three-dimensional (3D) electromagnetic field simulation software HFSS is used to simulate the electromagnetic field distribution in the microwave sintering cavity and to determine the electromagnetic region with the most uniform electromagnetic field to guide the microwave sintering experiments. The 3Y-TZP ceramic rings are shaped by gel-casting. The effect of presintering on the performance of ceramic rings is investigated by applying conventional sintering and microwave sintering methods. The experimental results show that the simulation-guided microwave sintering process can resolve the deficiency of uneven microwave sintering at low temperatures. Comparing the final sintering temperatures and mechanical properties of the final ceramic-sintered rings obtained by microwave presintering to those obtained by conventional presintering, microwave presintered sample has a final temperature of 1400°C, which is 100°C lower than that of conventional presintering, which is 1500°C; its average grain size of 0.18 μm is dramatically smaller than that of conventional presintering, which is 0.24 μm, with about 80% of the grain sizes present in the range of 0.1-0.2 μm and a relative density of about 99%, as opposed to conventional presintering’s 70% falling between 0.2 and 0.3 μm and relative density of about 98%; the Vickers hardness and fracture toughness for microwave presintered sample reach 1550 kg·f·mm−2 and 9.05 MPa m1/2, respectively, which are both greater than 1431 kg·f·mm−2 and 8.86 MPa m1/2 in the conventional samples.

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Microwave Sintering of Ti6Al4V: Optimization of Processing Parameters for Maximal Tensile Strength and Minimal Pore Size

Cited by 10 publications

References 20 publications

Design and development of 3D printing assisted microwave sintering of elbow implant with biomechanical properties similar tohuman elbow

Design and development of 3D printing assisted microwave sintering of elbow implant with biomechanical properties similar tohuman elbow

Multi-Objective Optimization of Selective Laser Melting Processes for Minimizing Energy Consumption and Maximizing Product Tensile Strength

Effects of Simulation‐Guided Microwave Presintering Process on the Preparation and Final Properties of Pure Ceramic Rings: Lower Sintering Temperature and Higher Mechanical Properties

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