A Review of Current Research on the Use of Geopolymer Recycled Aggregate Concrete for Structural Members
Abstract
:1. Introduction
2. Research Development on the Mechanical Properties of GRAC
2.1. Fly Ash (FA)
2.2. FA+GGBS (Flyash Combined with GGBS)
2.3. Metakaolin (MK)
2.4. Mixing Procedure
2.5. Comparison of Results
3. Research Progress on the Structural Members Made up of GRAC
4. Discussion
- The use of geopolymer concrete with recycled aggregate is a complex topic. The efficiency of GRAC depends on several factors: the type and composition of GPC, the molarity of the alkaline solutions, the mixing procedure, the curing temperature and environmental conditions, and the mechanical and chemical characteristics of the RA and ITZ; how these factors relate to the amount and characteristics of the attached mortar; the extraction process from the demolition construction waste; and, lastly, the replacement percentage of RA with NA, etc.
- The type of geopolymer cement created is one of the most important aspects, as different amounts and types of chemicals are used in the production of GPC. In older studies, GPC was prepared with fly ash and the results were not very encouraging (the recycled aggregate replacement ratio was limited to 30–40%).
- In recent research, it was found that when metakaolin and GGBS-based GPC were used, larger values of replacement ratios (up to 100%) can occur without a significant reduction in the flexural strength of the structural member. The tensile strength of GPC concrete can increase the cracking strength of the beam, which decreases with an increase in the RA replacement ratio; however, OPC with NA-reinforced beams and GRAC-reinforced beams usually exhibit a similar failure mode and cracking pattern. Only a shear-critical beam can exhibit premature failure when GRAC with a large RA replacement ratio is used.
- A large amount of RA can cause workability issues, but from the latest research, it was also found that the use of polycarboxylate superplasticizers and methyl isobutyl carbinol (MIBC) can improve workability, allowing for a reduction in the W/B ratio and increasing the strength of metakaolin-based geopolymers.
- In this regard, it must be pointed out that most of the research was performed using RA in a saturated surface condition which reduces the compressive strength and elastic modulus of the concrete.
- The excessive use of alkali activators reduces the elastic modulus of concrete, causing an increase in beam deflection. Hence, a precise quantity of alkali activators in relation to other materials should be used in GPC production. There is not yet a unanimous consensus on the exact quantity and type of material; therefore, the quantity and type of GPC should be chosen depending on the characteristics of available RA.
- An Interfacial Transition Zone (ITZ) develops between the attached mortar and the new cement paste. This is one of the weakest zones, so proper chemical and mechanical treatment is advised before using RA. It was found in the latest research that the addition of fillers and fly ash is helpful to fill the pores of RA, thus reducing the vulnerability of failure along the ITZ; to this aim, the Two Stage Mixing Technique (TSMA) can also be adopted, in which a cement coating forms on the surface of the recycled aggregate, thus filling up the cracks before actual mixing of concrete.
- From the literature review, it is seen that there are no general limits to the use of coarse RA in a concrete mixture. Some of the former researchers recommended a maximum 30% replacement of NA with RA, while recent researchers suggest that the RA replacement can be up to 50% or 100% if the mix design, batching methodology, and moisture condition of the RA are properly handled. In most of the research, the use of a 70% RA replacement ratio does not significantly affect the load capacity and only slightly affects the deformability of the GRAC beam loaded in flexure.
- In general, much research is still needed to identify the optimal mix design and to optimize the production methods and rules for setting the geopolymer concrete and its mechanical properties, particle size distributions, and aggregate processing for the production of GRAC. However, current knowledge already makes it possible to produce GRAC with a predetermined class of compressive strength, while its tensile strength and related characteristics, such as the bond between GRAC and reinforcement, related cracking phenomena, and ductility that can be conferred through confinement, are more uncertain.
- Particular attention must be paid when GRAC is to be used in conjunction with GFRP bars, since the confinement of the transverse reinforcement, which is able to provide an increase in compressive strength, is not always effective in increasing the deformation at the decay of resistance to 85% of the maximum value, and, more generally, ductility and toughness, a condition which can only be achieved in the presence of an adequate number of longitudinal bars capable of transferring the confinement action exerted by the transverse reinforcement more uniformly.
- Regarding the bond between GRAC and reinforcement, GRAC has exhibited promising behavior when used in conjunction with steel cold-form reinforcement, while bond strength is reduced up to 33% when used with sand-coated GFRP bars. This is because the predominant influence ensuring the bond between concrete and steel bars is mechanical interlocking, while in the case of GFRP bars, the predominant mechanisms are those of adhesion and friction.
- It is also found that no research has been conducted on the beam-to-column joint made up of GRAC. The beam-column joint is one of the most vulnerable structural members belonging to moment-resisting frames made of cast-in-situ concrete. Thus, in order to prove the effectiveness of GRAC, this aspect should also be analyzed.
- Similarly, a research gap has been found regarding the seismic behavior of GRAC structural members. The seismic assessment of GRAC structural members should be carried out in order to evaluate the ductility and energy dissipation capacity of reinforced GRAC for construction in seismic areas.
- Therefore, from the above literature review, it can be concluded that there is still a need for experimental tests that study the behavior of structural members made up of GRAC, characterizing the phenomenon of bond, the strength and ductility of members subjected to bending with or without axial load, and the shear strength of members with and without transverse reinforcement. Moreover, there is a need for studies focusing on the influence of the casting and curing conditions on the mechanical strengths of the structural member.
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
GRAC | Geopolymer Recycled Aggregate Concrete |
OPC | Ordinary Portland Cement |
GPC | Geo Polymer Cement |
GGBS | Ground Granulated Blast Furnace Slag |
RA | Recycled Aggregates |
ITZs | Interfacial Transition Zones |
NA | Natural Aggregate |
MK | Metakaolin |
HCFA | High Calcium Fly Ash |
PGC | Pressed Geopolymer Concrete |
RB | Recycled Concrete Block Aggregate |
FA | Fly ash |
MMA | Mortar Mixing Approach |
SEMA | Sand-Enveloped Mixing Approach |
GFRP | Glass Fiber Reinforced Polymer |
TSMA | Two-Stage Mixing Technique |
BW | By Weight |
W/B | Water to Binder ratio |
MIBC | Methyl Isobutyl Carbinol |
W/C | Water Cement Ratio |
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Ahmed, M.; Colajanni, P.; Pagnotta, S. A Review of Current Research on the Use of Geopolymer Recycled Aggregate Concrete for Structural Members. Materials 2022, 15, 8911. https://doi.org/10.3390/ma15248911
Ahmed M, Colajanni P, Pagnotta S. A Review of Current Research on the Use of Geopolymer Recycled Aggregate Concrete for Structural Members. Materials. 2022; 15(24):8911. https://doi.org/10.3390/ma15248911
Chicago/Turabian StyleAhmed, Muhammad, Piero Colajanni, and Salvatore Pagnotta. 2022. "A Review of Current Research on the Use of Geopolymer Recycled Aggregate Concrete for Structural Members" Materials 15, no. 24: 8911. https://doi.org/10.3390/ma15248911
APA StyleAhmed, M., Colajanni, P., & Pagnotta, S. (2022). A Review of Current Research on the Use of Geopolymer Recycled Aggregate Concrete for Structural Members. Materials, 15(24), 8911. https://doi.org/10.3390/ma15248911