Abstract
Direct ink writing of dense and strong ceramic objects remains an important open challenge. We develop a universal dimensionless criterion for printing such objects. Boehmite, an Al2O3 precursor, was used to assess the rheological properties leading to dense structures in ceramics manufactured by direct ink writing. Boehmite suspensions undergo time dependent gelation, thus providing a rheological laboratory of flow behaviours that can be correlated with printability requirements. We measured the evolution of rheological properties over several days and quantified the deformation of simple printed shapes at different aging times. We then identified the relevant physical parameters leading to printable suspensions. We defined a dimensionless number, Ξ, based on measured rheological properties, that predicts deformation of the printed object and determines the printability criterion. An important difference with this criterion is that Ξ necessarily accounts for capillary forces and gravitational slumping. We show that boehmite inks reach a printed shape fidelity > 90% when Ξ > 1, and that Al2O3 bars printed under these conditions can be sintered to 97% density, without printing defects, and have flexural strengths (500–600 MPa) competitive with commercial aluminas. Using Ξ, researchers can rationally design inks for printing dense materials by tailoring their rheological properties such that Ξ ≈ 1.
Highlights
A major goal of ceramic processing science is to produce complex three dimensional structures with excellent mechanical and/or functional properties
We study the viscoelastic flow behaviour of boehmite gels as a function of time with special attention paid to the shear-dependent viscosity and yield stress
The time-dependent rheology of boehmite gels was linked to deformation of 3D printed objects in order to produce a dimensionless criterion for printability, Ξ
Summary
A major goal of ceramic processing science is to produce complex three dimensional structures with excellent mechanical and/or functional properties. A colloidal suspension is passed through a computer controlled needle depositing a spatially controlled continuous filament of material This process imposes stringent requirements on the rheological behaviour of the inks; they must flow through a narrow opening, but they must resist deformation immediately after printing. The key factor in dense structures is that the cylindrical depositions from the nozzles must flow enough after deposition to fill the inevitable void space formed when stacking cylinders, and must resist larger scale slumping of the printed object Achieving this narrow range of rheological behaviour has been elusive. We study the viscoelastic flow behaviour of boehmite gels as a function of time with special attention paid to the shear-dependent viscosity and yield stress These measured rheological parameters are compared to image analysis of printed objects to identify the physical forces behind shape deformation after printing. We show that sintered objects printed from gels that meet this definition of printability are highly dense and mechanically resistant
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