Characteristics and microstructures of the GFRP waste powder/GGBS-based geopolymer paste and concrete

A novel method is developed for reusing the waste glass fiber-reinforced polymer (GFRP) powder as a precursor in geopolymer production. Several activation parameters that affect the workability and strength gain of GFRP powder-based geopolymers are investigated. The results of an experimental study reveal that the early strength of GFRP powder-based geopolymer pastes develops slowly at ambient temperature. The highest compressive strength of GFRP powder-based geopolymer pastes is 7.13 MPa at an age of 28 days. The ratio of compressive strength to flexural strength of GFRP powder-based-geopolymers is lower than that of fly ash and ground granulated blast furnace slag (GGBS)-based geopolymers, indicating that the incorporation of GFRP powder can improve the geopolymer brittleness. GGBS is incorporated into geopolymer blends to accelerate the early activity of GFRP powder. The binary geopolymer pastes exhibit shorter setting times and higher mechanical strength values than those of single GFRP powder geopolymer pastes. The GGBS geopolymer concrete mixture with 30 wt% GFRP powder displayed the highest compressive strength and flexural strength values and was less brittle. The developed binary GFRP powder/GGBS-based geopolymers reduce the disadvantages of single GFRP powder or GGBS geopolymers, and thus, offer high potential as a building construction material.

Automated summary

A novel method has been developed for reusing waste glass fiber-reinforced polymer (GFRP) powder in geopolymer production. The addition of GFRP powder improves the brittleness of geopolymer, and the incorporation of ground granulated blast furnace slag (GGBS) accelerates the early activity of GFRP powder-based geopolymers. The binary GFRP powder/GGBS-based geopolymers exhibit shorter setting times and higher mechanical strength values, making them promising materials for construction.