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Mechanistic-data-driven modeling of multi-material composite columns: Toward intelligent lightweight design

Shan Gao, Jicheng Xu, Feng Fu, Zhenhua Huang, Jean Francois Demonceau, Jie Yang

2026Engineering Structures10 citationsDOIOpen Access PDF

Abstract

This study examines the axial compressive performance of multi-material composite columns consisting of concrete-filled steel tubes with embedded CFRP-confined timber cores. A data-driven framework integrating theoretical model, finite element simulation and machine learning prediction is established to address the limited accuracy and scalability of conventional dual-material designs. An analytical bearing-capacity model is derived by accounting for steel confinement, CFRP hoop restraint, and timber orthotropy, of which results match FE results well with 5% deviations. Parametric investigations show that increasing steel yield strength and tube thickness would enhance the capacity of the composite columns, whereas CFRP confinement improves the post-crushing response and ductility of the timber core. The columns with circular cores exhibit better deformability than those with square ones. For axial bearing capacity prediction, a theory-residual-modified XGBoost model is proposed, in which theoretical estimates are corrected via SHAP-guided residual learning, achieving higher accuracy than single learners and ensemble baselines. A lightweight design tool is further developed for single/batch evaluation, automatic capacity-to-self-weight assessment, and interpretable prediction, enabling up to 22% self-weight reduction. The proposed methodology provides a validated and practical route for optimizing sustainable, lightweight multi-material composite columns.

Topics & Concepts

Parametric statisticsComposite numberStructural engineeringDuctility (Earth science)Finite element methodResidualCompressive strengthColumn (typography)ScalabilityYield (engineering)Bearing capacityEngineeringResidual strengthMaterials scienceComputer scienceTube (container)Square (algebra)Composite materialParametric modelMaterial propertiesMechanical engineeringStructural Behavior of Reinforced ConcreteTopology Optimization in EngineeringStructural Load-Bearing Analysis
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