Amir Ghazanfari scite author profile

An extrusion-based additive manufacturing process, called the Ceramic On-Demand Extrusion (CODE) process, for producing three-dimensional ceramic components with near theoretical densityis introduced in this paper.In this process, an aqueous paste of ceramic particles with a very low binder content (<1vol%) is extruded through a moving nozzle at room temperature. After a layer is deposited, it is surrounded by oil (to a level just below the top surface of most recent layer) to preclude non-uniform evaporation from the sides. Infrared radiation is then used to partially, and uniformly, dry the just-deposited layer so that the yield stress of the paste increases and the part maintains its shape. The same procedure is repeated for every layer until part fabrication is completed. Several sample parts for various applications were produced using this process and their properties were obtained. The results indicate that the proposed method enables fabrication of large, dense ceramic parts with complex geometries.

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Additive manufacturing and mechanical characterization of high density fully stabilized zirconia

Ghazanfari

Leu

et al. 2017

Ceramics International

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Mechanical properties of additively manufactured 8 mol% yttria-stabilized zirconia (8YSZ) parts were extensively studied for the first time. A novel freeform extrusion fabrication process, called Ceramic On-Demand Extrusion (CODE), was employed to deposit an aqueous viscous suspension (~50 vol% solids loading) of fully stabilized zirconia powder in a layer-by-layer fashion. Each layer was exposed to infrared radiation after deposition to attain partial solidification due to drying. Before exposure, the layer was surrounded by oil to preclude nonuniform evaporation, which could cause warpage and crack formation. After the fabrication process was completed, the parts were humid-dried in an environmental chamber and densified by sintering under atmospheric pressure. Standard test methods were employed to examine the properties of sintered parts including density, Vickers hardness, fracture toughness, Young's modulus, and flexural strength. Microstructural evaluation was also performed to observe the

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Extrusion-on-demand methods for high solids loading ceramic paste in freeform extrusion fabrication

Ghazanfari

Leu

et al. 2017

Virtual and Physical Prototyping

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Characterization of zirconia specimens fabricated by ceramic on-demand extrusion

Ghazanfari

McMillen

et al. 2018

Ceramics International

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Enhancing the Mechanical Properties and Formability of Low Carbon Steel with Dual-Phase Microstructures

Habibi

Hashemi

Sadeghi

et al. 2016

J. of Materi Eng and Perform

102

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In the present study, a special heat treatment cycle (step quenching) was used to produce a dual-phase (DP) microstructure in low carbon steel. By producing this DP microstructure, the mechanical properties of the investigated steel such as yield stress, tensile strength, and Vickers hardness were increased 14, 55, and 38%, respectively. In order to investigate the effect of heat treatment on formability of the steel, Nakazima forming test was applied and subsequently finite element base modeling was used to predict the outcome on forming limit diagrams. The results show that the DP microstructure also has a positive effect on formability. The results of finite element simulations are in a good agreement with those obtained by the experimental test.

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Amir Ghazanfari

A novel freeform extrusion fabrication process for producing solid ceramic components with uniform layered radiation drying

Additive manufacturing and mechanical characterization of high density fully stabilized zirconia

Extrusion-on-demand methods for high solids loading ceramic paste in freeform extrusion fabrication

Characterization of zirconia specimens fabricated by ceramic on-demand extrusion

Enhancing the Mechanical Properties and Formability of Low Carbon Steel with Dual-Phase Microstructures

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