Abstract
The use of recycled glass powder (RCGP) is investigated as a partial replacement for ground granulated blast furnace slag in blended CEM II/A-LL cements using thermodynamic modelling to simulate cement paste hydration at a water-to-cement (w/c) ratio of 0.5.
This study allows a rapid means of examining the likely evolution of these materials over the first two to three years, allowing experimental work to focus on promising formulations.
A comparison is made between the evolving solid phase and solution chemistries of four materials: a standard Portland-limestone (CEM II/A-LL), a ‘control’ blend, comprising equal quantities of CEM II/A-LL with GGBS and two novel blended cements containing RCGP.
These represent 15% replacement (by mass) of GGBS by RCGP blended with either 40% or 60% CEM II/A-LL.
The simulations were performed using the code HYDCEM, a cement hydration simulator, which calls on the thermodynamic model PHREEQC to sequentially simulate the evolution of the four cements.
The results suggest that partial replacement of GGBS by 15% RCGP results in no significant change in system chemistry.
The partial replacement of cementitious slag by waste container glass provides a route by which this material can be diverted from the landfill inventory, and the mass balance and energy balance implications will be reported elsewhere.
This study allows a rapid means of examining the likely evolution of these materials over the first two to three years, allowing experimental work to focus on promising formulations.
A comparison is made between the evolving solid phase and solution chemistries of four materials: a standard Portland-limestone (CEM II/A-LL), a ‘control’ blend, comprising equal quantities of CEM II/A-LL with GGBS and two novel blended cements containing RCGP.
These represent 15% replacement (by mass) of GGBS by RCGP blended with either 40% or 60% CEM II/A-LL.
The simulations were performed using the code HYDCEM, a cement hydration simulator, which calls on the thermodynamic model PHREEQC to sequentially simulate the evolution of the four cements.
The results suggest that partial replacement of GGBS by 15% RCGP results in no significant change in system chemistry.
The partial replacement of cementitious slag by waste container glass provides a route by which this material can be diverted from the landfill inventory, and the mass balance and energy balance implications will be reported elsewhere.
| Original language | English (Ireland) |
|---|---|
| Article number | 6872 |
| Number of pages | 17 |
| Journal | Applied Sciences (Switzerland) |
| Volume | 15 |
| Issue number | 12 |
| DOIs | |
| Publication status | Published - 18 Jun 2025 |
Keywords
- CEM II/A-LL
- blended cements
- hydration
- modelling
- recycled glass
- slag cement