MasterGlenium ACE 8710

High Early Strength, High Range Water-Reducing Admixture with Improved Slump Retention and Workability

How Does MasterGlenium ACE 8710 Work?

MasterGlenium ACE 8710 is an innovative second generation polycarboxylic ether polymer hyperplasticiser with high early strength, improved slump retention and lower paste viscosity, especially at lower w/c ratios and high binder contents.
The particular molecular configuration of MasterGlenium ACE 8710 accelerates the cement hydration. Rapid absorption of the molecule onto the cement particles, combined with an efficient dispersion effect maintains workability yet exposes increased surface area of the cement grains to react with water.
As a result of this effect, it is possible to obtain earlier development of the heat of hydration, rapid development of the hydration products and, as a consequence, higher strengths at a very early age.
MasterGlenium ACE 8710 conforms to AS 1478 Type HWR.

What Makes MasterGlenium ACE 8710 a Unique Solution?

The particular molecular configuration of MasterGlenium ACE 8710 accelerates the cement hydration. Rapid absorption of the molecule onto the cement particles, combined with an efficient dispersion effect maintains workability yet exposes increased surface area of the cement grains to react with water.
As a result of this effect, it is possible to obtain earlier development of the heat of hydration, rapid development of the hydration products and, as a consequence, higher strengths at a very early age.

What Are the Benefits of MasterGlenium ACE 8710?

• Produce Rheoplastic and Rheodynamic (SWC) concrete having a low water binder ratio

• Superior slump retention over conventional admixtures

• Optimise curing cycles by reducing curing time or curing temperature

• Eliminate the energy required for placing and compacting concrete

• Increase productivity by reducing cycle times

• Improve surface appearance

• Produce durable precast concrete elements

• Improved engineering properties compared to traditional superplasticisers, such as early and ultimate compressive and flexural strengths, shrinkage, and permeability