What does this research mean for the field?

Unsaturated polyester polymer concrete outperforms traditional materials for rapid highway repair, offering high early strength that requires only standard surface preparation on rigid pavements but necessitates primer and mechanical scarification to prevent debonding on flexible pavements. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to evaluate the structural performance of polymer concrete for highway pavement repair and rehabilitation.

May 20, 2026Open Access

Experimental and Numerical Evaluation of Unsaturated Polyester Polymer Concrete for Highway Pavement Repair and Surface Rehabilitation

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This research aims to evaluate the structural performance of polymer concrete for highway pavement repair and rehabilitation.
Combined laboratory characterization and three-dimensional finite element analysis were used.
Compressive and tensile strengths were measured at various curing times and structural performance analyzed through 36 static analyses in ANSYS 2024 R2.
Scenarios included various patch sizes and load conditions on flexible and rigid pavements.
Polymer concrete reached 85.97 MPa in compressive strength and 7.63 MPa in tensile strength by day three, demonstrating rapid strength gain.
Safety factors for polymer concrete patches on rigid pavements exceeded 22.0, indicating robust performance.
Flexible pavements showed a range of interfacial safety factors, indicating the need for surface preparation.

Resumen

Pavement repair has become an increasingly time-critical operation as traffic volumes grow and lane-closure windows shrink. This has driven demand for materials that gain full structural strength quickly, reopen to traffic within hours, and hold up longer than conventional patches. This study evaluates polymer concrete (PC), a thermosetting resin-bound aggregate system, through combined laboratory characterization and three-dimensional finite element analysis. Compressive strength, splitting tensile strength, unit weight, and apparent porosity were measured at 1, 3, 7, and 28 days of curing. PC reached 85.97 MPa in compression and 7.63 MPa in tension by day three, with near-zero porosity (0.15%) maintained throughout. These three-day values were used directly as material inputs in the three-dimensional finite element analysis (FEA), reflecting the early traffic reopening scenario that defines rapid repair practice. Structural performance was assessed through 36 static analyses in ANSYS 2024 R2, covering flexible (Hot Mix Asphalt, HMA) and rigid (Jointed Plain Concrete Pavement, JPCP) pavement types, three patch sizes (250 × 250 mm, 500 × 500 mm, and 1000 × 1000 mm), and nine load scenarios per configuration. Safety factors (SF) against internal cracking, interfacial debonding, and compressive failure were computed for both PC and traditional patches. PC consistently outperformed HMA and Portland cement concrete patches across all metrics. On rigid pavements, interfacial safety factors exceeded 22.0, confirming that standard surface preparation is sufficient. On flexible pavements, adopting 0.78 MPa as a conservative lower-bound estimate of PC-HMA interfacial bond strength, five scenarios exhibit debonding risk (250-C, 500-C, 500-D, 1000-C, and 1000-D; SF = 0.47–0.99), while the remaining four show high interfacial risk (SF = 1.11–1.30); primer application and mechanical scarification are required for all PC repairs on flexible pavements regardless of patch geometry. Taken together, the experimental and numerical evidence positions PC as a credible, high-performance option for highway repair.

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