Fabrication of injection moulded translucent alumina ceramics via pressureless sintering

Liu, W; Tang, Bo; Xie, Zhihui; Yin, Wang; Yang, Xianfeng

doi:10.1179/1743676111y.0000000005

Cited by 21 publications

(10 citation statements)

References 42 publications

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“…In particular for ceramics, suspension rheology is crucial in a variety of processing steps such as slip casting, [1][2][3] injection moulding, 4,5 screen printing, 6 tape casting 7 and extrusion. 8 Also for dry forming processes, the quality of the granules depends on the suspension rheology during spray drying.…”

Section: Introductionmentioning

confidence: 99%

Yield stress modelling of doped alumina suspensions for applications in freeze granulation: towards dry pressed transparent ceramics

Stuer

Bowen

2012

Advances in Applied Ceramics

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Rheology of powder suspensions is a key factor in many processing routes, and better understanding of the parameters that control the rheology improves technical progress by reducing the empirical factors in the formulation of powder slurries. The strict requirements for the production of transparent polycrystalline alumina demand a fundamental understanding of powder handling and processing steps. The use of dopants (Mg, Y, La) has proven useful, but produces noticeable effects on suspension rheology and influences the choice of the processing route. With the prospect of spray granulation of such slurries, the rheological behaviour of doped alumina suspensions was investigated from a fundamental approach taking into account slurry and particle characteristics, and computing the interparticle potentials. This information was then used in a yield stress model which successfully predicted the rheological behaviour of the doped alumina slurries. A strategy for improved slurry formulation is presented.

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Section: Introductionmentioning

confidence: 99%

Yield stress modelling of doped alumina suspensions for applications in freeze granulation: towards dry pressed transparent ceramics

Stuer

Bowen

2012

Advances in Applied Ceramics

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“…According to this figure, the maximum visible transmission has been about ∼35% at wavelength 650 nm. As‐obtained visible transmission was more than research that used pressure less sintering at 1800°C under H 2 atmosphere ( T = 12%) or co‐using slip casting and SPS method ( T = 28%) 5,25,26 . The theoretical transmission of alumina (based on Rayleigh–Gans–Debye theory) with zero porosity and grain boundary and thickness of 1.5 mm was ∼50% at a wavelength of 650 nm.…”

Section: Resultsmentioning

confidence: 90%

“…The optimal temperature of the materials to have a pseudoplastic behavior by this group was reported at 170°C. Liu et al 5 . examined the fluidity behavior of a feed containing commercial alumina powder with a mean grain size of .35 μm and a binder system consisting of pp, polyethylene vinyl acetate copolymer, paraffin wax, stearic acid dispersant agent, and dibutyl phthalate plasticizer with portions of 10, 60, 15, and 5 vol.%, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…3 To have a green part with no or minimal defects, the optimal feed for the CIM device is a feed with pseudoplastic rheological behavior. Wei et al 4 investigated the fluidity behavior of alumina powder with a mean particle size of 400 nm alongside polypropylene (pp), paraffin wax, and stearic acid with an 85-15 wt.% ratio of powder to the binder at 140-170 • C. The optimal temperature of the materials to have a pseudoplastic behavior by this group was reported at 170 • C. Liu et al 5 examined the fluidity behavior of a feed containing commercial alumina powder with a mean grain size of .35 μm and a binder system consisting of pp, polyethylene vinyl acetate copolymer, paraffin wax, stearic acid dispersant agent, and dibutyl phthalate plasticizer with portions of 10, 60, 15, and 5 vol.%, respectively. Various portions of alumina powder from 52 to 58 vol.% were examined in that research to obtain the optimal percentage.…”

Section: Introductionmentioning

confidence: 99%

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Investigation of nanosized alumina‐binder feedstock rheology for ceramics injection molding (CIM) and survey spark plasma sintering of output green body to obtain transparent alumina

Kallemasih

Loghman-Estarki

Mansouri

et al. 2022

Int J Applied Ceramic Tech

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The purpose of this work is to optimize the feed containing alumina-binder nanoparticles for ceramics injection molding to create transparent alumina parts.In this research, two Alumina with and without MgO as sintering aid fabricated via the spark plasma sintering method. Feed fluidity, fracture toughness, density, IR, and visible transmission of SPSed bodies of the sintered pieces were measured. Furthermore, a pin on the disc test was used on the disk to examine the alumina friction coefficient. The results of feed rheology showed that the sample prepared at 90 • C had the best conditions as a pseudoplastic fluid for the ceramic injection molding (CIM) method. The results showed that a combination of CIM and spark plasma sintering (SPS) methods cause more visible transmission than conventional SPS of alumina nanopowder. Also, the fracture toughness and hardness of as-obtained transparent alumina were in the range of 3.6 MPa m 0.5 and 20.1 MPa, respectively. The wear rate of the as-obtained transparent sample (4.5 × 10 −7 mm 3 /N m) was proportional to the alumina grain size (1-4 μm).

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“…These techniques, however, cost highly with complex process, and produce Ti 2 AlC with many impure phases such as TiC, Ti-Al compounds, and Ti 3 AlC 2 . In contrast, the pressureless sintering technique (PLS) is simple, efficient, and low-cost [23] , which is more meaningful for the practical application. In addition, the preparation, microstructure, interface bonding, and electrical contacting property of composite can be largely affected by the wettability between reinforcement and Ag matrix.…”

mentioning

confidence: 99%

High-purity Ti2AlC Powder: Preparation and Application in Ag-based Electrical Contact Materials

Jianxiang¹,

Peiyan²,

Zha³

et al. 2019

Journal of Inorganic Materials

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Ag-based electrical contact is the "heart" of low-voltage switch, and the Cd toxicity has long been a haunting problem. It is the research focus of the low-voltage switch to find new environment-friendly electrical contact materials. Starting from the design of reinforcement for Ag-based electrical contact in this work, the high-purity Ti 2 AlC powder (99.2%) was synthesized by a simple and fast pressureless technique. Ag/Ti 2 AlC composite electrical contact material was also prepared with homogeneous structure, good bonding between Ag and Ti 2 AlC particles, high relative density (95.7%), moderate hardness (96HV), satisfactory electrical conductivity (low resistivity of 79.5 nΩ•m), and favorable arc erosion resistance (mass loss of 4.4% after 5610 arc discharging cycles). These excellent structure and properties of Ag/Ti 2 AlC composite are mainly attributed to the good thermal and electrical conductivity of Ti 2 AlC and the good wettability between Ag and Ti 2 AlC. This composite is expected to replace the conventional electrical contact materials in the future.

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Fabrication of injection moulded translucent alumina ceramics via pressureless sintering

Cited by 21 publications

References 42 publications

Yield stress modelling of doped alumina suspensions for applications in freeze granulation: towards dry pressed transparent ceramics

Yield stress modelling of doped alumina suspensions for applications in freeze granulation: towards dry pressed transparent ceramics

Investigation of nanosized alumina‐binder feedstock rheology for ceramics injection molding (CIM) and survey spark plasma sintering of output green body to obtain transparent alumina

High-purity Ti2AlC Powder: Preparation and Application in Ag-based Electrical Contact Materials

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