The aim of this work was to address the issues of high cost and limited application of magnesium phosphate cement (MPC) by using active magnesia (AM) as the primary raw material to prepare MPC. A self-developed quick-setting concrete three-dimensional (3D) printer was used to realise its 3D printing application. The effects of different metakaolin (MK) contents on macroscopic properties were explored, including the setting time, compressive strength and interfacial bonding strength of AM-based MPC. The effects of MK on the hydration products and the microscopic appearance of the AM-based MPC were investigated. On this basis, the MPC mix with optimal performance was selected for 3D printing performance testing. The effects of the rapid-solidification 3D printing process and conventional pouring process on the microstructure and composition of MPC were compared. The results showed that 4–6% MK improved the mechanical properties, bonding properties and later stability of the AM-based MPC. A 3D printer that integrates quick-setting concrete, mixing, stirring and extruding functions was developed. The printer can successfully print AM-based MPC, and the components have good extrusion, construction and mechanical properties. Compared with the traditional pouring process, this rapid-solidification 3D printing technology accelerates the formation of hydration products, but may reduce the compactness of the components.
Li et al. (Fri,) studied this question.