Behaviour of a novel functionally graded 3D re-entrant lattice reinforced high-performance concrete under static and dynamic compression

IF 13.1 1区工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY

Cement & concrete composites Pub Date : 2025-08-04 DOI:10.1016/j.cemconcomp.2025.106261

Yiwei Xuan , Dianwei Gao , Mingzhong Zhang

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Abstract

This paper presents a systematic experimental study on the static and dynamic mechanical behaviour of high-performance concrete (HPC) reinforced with 3D re-entrant lattice, accounting for the effect of functionally gradient design. The uniform 3D re-entrant lattice (U) and the corresponding vertically positively and negatively graded lattices (FG1 and FG2) were designed and manufactured with 3D printing. The plain HPC (P-HPC) and HPC reinforced with U (U-HPC), FG1 (G1-HPC) and FG2 (G2-HPC) were fabricated accordingly. Static compressive and split Hopkinson pressure bar tests were then conducted to investigate the static and dynamic compressive behaviour of 3D re-entrant lattice reinforced HPC under various strain rates (i.e., 0, 28.1, 50.6, 72.0 and 100.6 s⁻¹). Results indicate that the static compressive strength of HPC specimens is slightly improved owing to re-entrant lattice reinforcement, while the static dissipated energy of P-HPC is 55.7 %, 53.2 % and 57.5 % lower than that of U-HPC, G1-HPC and G2-HPC, respectively. Regarding dynamic compressive behaviour, although the dynamic strength of P-HPC is 11.3–24.6 % higher than that of lattice reinforced HPC at a strain rate of around 30 s⁻¹, with the further increase of strain rates, the re-entrant lattice reinforced HPC presents higher strength improvement. G2-HPC has the highest dynamic compressive strength of 198.3 MPa at a strain rate of approximately 100.6 s⁻¹, followed by G1-HPC, P-HPC and U-HPC. At low strain rates, the plain and lattice reinforced HPC exhibit the similar energy absorption. When the strain rate reaches around 100.6 s⁻¹, U-HPC, G1-HPC and G2-HPC exhibit a 29.8 %, 36.8 % and 54.3 %, respectively higher dissipated energy than P-HPC. The gradient design of lattice reinforcement brings a more gradual and smooth dissipation of energy, thereby improving the overall energy absorption capacity. The excellent dynamic compressive behaviour of functionally graded 3D re-entrant lattice reinforced HPC offers a promising solution for protective structures subjected to high strain rates, including impact, blast, and seismic loadings.

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一种新型的功能分级三维可重入网格增强高性能混凝土在静态和动态压缩下的行为

本文对考虑梯度设计影响的三维重入格构增强高性能混凝土（HPC）的静、动态力学性能进行了系统的试验研究。采用3D打印技术设计并制造了均匀三维重入晶格(U)和相应的垂直正、负梯度晶格（FG1和FG2）。分别制备了普通HPC （P-HPC）和U增强HPC （U-HPC）、FG1 （G1-HPC）和FG2 （G2-HPC）。然后进行静态压缩和劈裂霍普金森压杆试验，以研究不同应变速率（即0、28.1、50.6、72.0和100.6 s−1）下三维网格增强HPC的静态和动态压缩行为。结果表明：通过重入点阵加固，HPC试件的静抗压强度略有提高，而P-HPC的静耗散能比U-HPC、G1-HPC和G2-HPC分别降低55.7%、53.2%和57.5%；在动态压缩性能方面，虽然在应变速率为30 s−1左右时，P-HPC的动态强度比晶格增强HPC高11.3 - 24.6%，但随着应变速率的进一步增大，重入式晶格增强HPC的强度提高幅度更大。在应变速率约为100.6 s−1时，G2-HPC的动态抗压强度最高，为198.3 MPa， G1-HPC次之，P-HPC次之，U-HPC次之。在低应变速率下，普通和晶格增强的高性能混凝土表现出相似的能量吸收。当应变速率达到100.6 s−1左右时，U-HPC、G1-HPC和G2-HPC的耗散能分别比P-HPC高29.8%、36.8%和54.3%。栅格加固的梯度设计使能量的耗散更加平缓，从而提高了整体吸能能力。具有优异动态压缩性能的功能梯度3D可重入点阵增强高性能混凝土，为承受高应变率（包括冲击、爆炸和地震载荷）的保护结构提供了一种很有前途的解决方案。

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来源期刊

Cement & concrete composites 工程技术-材料科学：复合

CiteScore

18.70

自引率

11.40%

发文量

459

审稿时长

65 days

期刊介绍： Cement & concrete composites focuses on advancements in cement-concrete composite technology and the production, use, and performance of cement-based construction materials. It covers a wide range of materials, including fiber-reinforced composites, polymer composites, ferrocement, and those incorporating special aggregates or waste materials. Major themes include microstructure, material properties, testing, durability, mechanics, modeling, design, fabrication, and practical applications. The journal welcomes papers on structural behavior, field studies, repair and maintenance, serviceability, and sustainability. It aims to enhance understanding, provide a platform for unconventional materials, promote low-cost energy-saving materials, and bridge the gap between materials science, engineering, and construction. Special issues on emerging topics are also published to encourage collaboration between materials scientists, engineers, designers, and fabricators.