Influence of the Compaction Pressure and Sintering Temperature on the Mechanical Properties of Porous Titanium for Biomedical Applications

Castillo, Sandra Molina; Muñoz, Sergio; Trueba, Paloma; Díaz, Eduardo García; Torres, Yadir

doi:10.3390/met9121249

Cited by 12 publications

(9 citation statements)

References 57 publications

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“…Considering the advantages and disadvantages of the experimental techniques to evaluate the Young's modulus of porous material, in this work, it has been evaluated following the two methods above mentioned (uniaxial compression test and ultrasounds technique), obtaining a higher value by ultrasounds than compression test (35 GPa vs 19 GPa, respectively). It has been previously reported by some of authors of this work [33,34,37,38] that there is a discrepancy between the value obtained by applying both experimental techniques. In Ni-Ti materials, this difference in the measured values is related to a super-elastic deformation within the linear-elastic range; it has been observed that, by the ultrasound technique, stiffness decreases for higher porosity values, according to the elastic Eshelby-based theory for closed, spherical porosity [39].…”

Section: Mechanical Behavior Of Porous Titanium Cylinderscontrasting

confidence: 58%

Porous Titanium Cylinders Obtained by the Freeze-Casting Technique: Influence of Process Parameters on Porosity and Mechanical Behavior

Trueba

Beltrán

Bayo

et al. 2020

Metals

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The discrepancy between the stiffness of commercially pure titanium and cortical bone tissue compromises its success as a biomaterial. The use of porous titanium has been widely studied, however, it is still challenging to obtain materials able to replicate the porous structure of the bones (content, size, morphology and distribution). In this work, the freeze-casting technique is used to manufacture cylinders with elongated porosity, using a home-made and economical device. The relationship between the processing parameters (diameter and material of the mold, temperature gradient), microstructural features and mechanical properties is established and discussed, in terms of ensuring biomechanical and biofunctional balance. The cylinders have a gradient porosity suitable for use in dentistry, presenting higher Young’s modulus at the bottom, near the cold spot and, therefore better mechanical resistance (it would be in contact with a prosthetic crown), while the opposite side, the hot spot, has bigger, elongated pores and walls.

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Section: Mechanical Behavior Of Porous Titanium Cylinderscontrasting

confidence: 58%

Porous Titanium Cylinders Obtained by the Freeze-Casting Technique: Influence of Process Parameters on Porosity and Mechanical Behavior

Trueba

Beltrán

Bayo

et al. 2020

Metals

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“…It is observed that pores of the specimens produced with uniaxial press method have a spherical morphology and shrink with the increase of compression pressure. The compression pressure applied to the powder material enables the small irregular pores to combine and hence lead to a reduction of the large-sized pores (Amidon et al, 2017;Castillo et al, 2019). It is seen that the pores of specimens fabricated by 3D printer are non-uniform and exist in different sizes.…”

Section: Density and Porositymentioning

confidence: 99%

“…It is seen that the pores of specimens fabricated by 3D printer are non-uniform and exist in different sizes. In the Binder Jetting method, pores are non-uniform due to the lack of compression pressure, the droplet effect of the liquid binder and, the accumulation of binder between particles (Kunchala and Kappagantula, 2018;Stevens et al, 2018;Castillo et al, 2019).…”

Section: Density and Porositymentioning

confidence: 99%

“…These problems can be minimized by producing porous implants with similar mechanical properties to bone tissue. Porous Ti implants with low density can be manufactured by conventional powder metallurgy method and additive manufacturing techniques (Wiria et al, 2010;Goia et al, 2013;Tojal et al, 2013;Yang et al, 2018;Yılmaz et al, 2018;Castillo et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…Although this method is fast and economical to produce a large number of small and uncomplicated parts, the cost and time of production are high for producing complex and low quantity of patient-specific implants. In this method, powder material properties, compression pressure, and sintering conditions directly affect the density and mechanical properties of the final products (Esteban et al, 2011;Castillo et al, 2019;Cuesta et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Caracterización de CP-Titanio producido mediante inyección aglutinante y pulvimetalurgia convencional

İyibilgin

Gepek

2021

revmetal

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El titanio (Ti) y sus aleaciones se encuentran entre los materiales más utilizados en aplicaciones biomédicas. Además de ser biocompatibles, estos materiales tienen una baja densidad, una alta resistencia a la corrosión y unas propiedades mecánicas notables. Es muy difícil producir piezas con geometría compleja utilizando métodos convencionales de pulvimetalurgia (PM) ya que este método se basa en dar forma a polvos bajo fuerzas uniaxiales utilizando moldes. La Inyección Aglutinante (Binder Jetting) es un tipo de técnica de fabricación aditiva que no necesita moldes para dar forma a los polvos. Este estudio se centra en comparar las propiedades de las piezas porosas de CP-Ti producidas con PM e Inyección Aglutinante. Las piezas se sinterizaron durante 120 min en una atmósfera de argón a 1200 °C. Después de la sinterización, se alcanzaron valores de densidad relativa de aproximadamente el 94% y el 92% en las muestras producidas por PM y con la impresora 3D, respectivamente. También se observó que la muestra producida con una presión de compactación de 25 MPa tiene una dureza de 317 ± 10 HV0.05 y un límite elástico bajo compresión de 928 MPa, mientras que la pieza producida con la impresora 3D tiene una dureza de 238 ± 8 HV0. 05 y un límite elástico bajo compresión de 342 MPa. Aunque la dureza y resistencia de las muestras producidas con la impresora 3D fueron menores que las de PM, sus propiedades son adecuadas para producir implantes que reemplacen las estructuras óseas.

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Development of Ti‐10Nb alloy by powder metallurgy processing route for dental application

Kumar,

Gautam

2023

J Biomed Mater Res

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Titanium and its alloys are used to make dental implants because of its low density, high strength, and corrosion resistance. This paper describes the development of a potential biomaterial Ti‐10Nb by powder metallurgy utilizing four different compaction pressures and analyses its microstructural, physical, mechanical, electrochemical, biological, and tribological behavior under various situations. The alloys were fabricated using four different compaction pressures, that is, 600, 650, 700, and 750 MPa, and sintered in a vacuum atmosphere at 1000°C for 1.5 h. The density of the samples was measured using Archimedes principle. X‐ray diffraction and scanning electron microscopy equipped with energy dispersive spectroscopy were used to investigate the phase composition and microstructure, and a profilometer was used to examine the surface roughness of various samples. Vickers hardness tester was used to evaluate hardness, and a universal testing machine was used for compression testing. Corrosion and wear behavior were examined using a potentiostat and a Bio‐Tribometer, respectively. This Ti‐10Nb alloys consist of α + β phase, and have 16% highest porosity in sample compacted at 600 MPa. The samples compacted at 750 MPa achieved highest hardness, yield strength, compressive strength, and elastic modulus of 450 ± 29.72 HV, 718.22 ± 16.37 MPa, 1543.59 ± 24.37 MPa, and 41.27 ± 3.29 GPa, respectively. In addition, it also possesses highest corrosion and wear resistance with lowest icorr of 0.3954 ± 0.008 μA/cm2 and wear volume of (31.25 ± 0.206) × 10−3 mm3. These results indicate that the developed alloys have a variety of desirable properties, including high hardness, adequate compressive strength, good corrosion and wear resistance, apatite‐forming capability, and a low elastic modulus, which is advantageous for avoiding stress shielding. Therefore, it may be recommended to use it as a dental implant material.

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Influence of the Compaction Pressure and Sintering Temperature on the Mechanical Properties of Porous Titanium for Biomedical Applications

Cited by 12 publications

References 57 publications

Porous Titanium Cylinders Obtained by the Freeze-Casting Technique: Influence of Process Parameters on Porosity and Mechanical Behavior

Porous Titanium Cylinders Obtained by the Freeze-Casting Technique: Influence of Process Parameters on Porosity and Mechanical Behavior

Caracterización de CP-Titanio producido mediante inyección aglutinante y pulvimetalurgia convencional

Development of Ti‐10Nb alloy by powder metallurgy processing route for dental application

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