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Shear Performance of UHPC-NC Composite Structure Interface Treated with Retarder: Quantification by Fractal Dimension and Optimization of Process Parameters

Runcai Weng, Zhaoxiang He, Jiajie Liu, Bin Lei, Linhai Huang, Jiajing Xu, Lingfei Liu, Jie Xiao

2025Buildings21 citationsDOIOpen Access PDF

Abstract

Prefabricated Ultra-High-Performance Concrete (UHPC) and cast-in-place Normal Concrete (NC) composite members are increasingly used in bridge engineering because they combine high performance with cost-effectiveness. The bond at the UHPC-NC interface is critical as it directly impacts the composite structure’s safety. This study employed 3D laser scanning acquired the UHPC substrate geometry, utilized fractal dimension analysis to quantify the interface roughness, and adopted the slant shear test to evaluate the effects of retarder application mass and hydration delay duration on roughness and bond strength. The research results indicate that the failure modes of UHPC-NC specimens can be categorized into interface shear failure and NC splitting tensile failure. With the extension of hydration delay duration, both the interface roughness and bond strength show a decreasing trend. The influence of retarder dosage on interface roughness and bond strength exhibits a threshold effect. This study also confirms the effectiveness of fractal dimension as a quantitative tool for characterizing the macroscopic roughness features of the bonding interface. The findings of this paper provide a solid theoretical basis and quantitative support for optimizing key process parameters such as retarder dosage and precisely controlling hydration delay duration, offering significant engineering guidance for enhancing the interface bonding performance of UHPC-NC composite structures.

Topics & Concepts

RetarderFractal dimensionComposite numberMaterials scienceFractalShear (geology)Dimension (graph theory)Composite materialProcess (computing)Mechanical engineeringStructural engineeringEngineering drawingEngineeringComputer scienceMathematicsMathematical analysisPure mathematicsOperating systemInnovative concrete reinforcement materialsAdvanced ceramic materials synthesisConcrete and Cement Materials Research