Factors influencing properties of phosphate cement-based binder for rapid repair of concrete

TL;DR: The biological in vitro and in vivo properties of magnesium phosphates for bone regeneration are summarized, which show promising results regarding the application as bone replacement material, but still lack in terms of testing in large animal models, load-bearing application sites and clinical data.

TL;DR: In this article, the compressive strength of MPC mortar with fly ash contents was measured at ages of 3h, 1d, 7d and 28d using XRD and SEM.

TL;DR: In this paper, the first definitive evidence that dissolution of the glassy aluminosilicate phases of both fly ash (FA) and ground granulated blast furnace slag (GBFS) occurred under the pH conditions of MKPC was presented.

TL;DR: This study primarily concentrates on the information collection of the production and utilization of MPC in bio-materials, crack repair in pavements, hazardous waste management, fibre reinforced mortar, particle boards and clinical bio-ceramics using different design mixes of the MPC ingredients by the previous scholars.

TL;DR: The major hydrate formed was struvite, NH4MgPO4·6H2O, usually accompanied by schertelite, at least initially as discussed by the authors.

TL;DR: In this paper, Magnesium monophosphate cementitious materials were prepared by mixing calcined magnesium oxide (MgO) powder with an aqueous solution of diammonium phosphate (ADP) at 24°C The activation energy for the curing reaction of the cement paste was determined to be 3029 kcal/mole, and at age 1 hr the compressive strength was ≈900 psi (62 MPa).

TL;DR: In this article, Magnesia-phosphate cement at a water:solids ratio of 1:16 was used to make mortars with high early strength and low porosity.

TL;DR: The use of 20% borax by weight of ammonium polyphosphate (AmPP) has been shown to increase the reaction time to 20 min, compared with a reaction time of <3 min for specimens without boredax as mentioned in this paper.