Nonlinear creep of concrete: Stress-activated stick–slip transition of viscous interfaces and microcracking-induced damage

IF 10.9 1区工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY

Cement and Concrete Research Pub Date : 2025-02-16 DOI:10.1016/j.cemconres.2025.107809

Rodrigo Díaz Flores, Christian Hellmich, Bernhard Pichler

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Abstract

With the aim to identify the mechanisms governing nonlinear basic creep of concrete under uniaxial compression, a micromechanics model is presented. Extending the affinity concept for nonlinear creep, it describes that every microcrack incrementally increases the damage of concrete, leading to a step-wise increase of its compliance. Experimental data are taken from the literature. Strain and acoustic emission measurements from a multi-stage creep test are used to develop the model. This includes identification of microcrack evolution laws for both short-term load application and sustained loading. Strain measurements from four single-stage creep tests are used for model validation. It is concluded that nonlinear creep of concrete is governed by two mechanisms: (i) stress-induced stick–slip transition of viscous interfaces at the nanostructure of cement paste, which is phenomenologically accounted for by the affinity concept, and (ii) microcracking-induced damage, which is of major importance once the stress exceeds some 70% of the strength.

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混凝土的非线性徐变：应力激活黏性界面的粘滑过渡和微裂纹引起的损伤

为了确定单轴压缩下混凝土非线性基本徐变的控制机制，建立了细观力学模型。扩展了非线性蠕变的亲和关系概念，它描述了每一个微裂缝都会增加混凝土的损伤，从而导致混凝土的柔度逐步增加。实验数据来源于文献。采用多阶段蠕变试验的应变和声发射测量来开发模型。这包括识别微裂纹在短期载荷和持续载荷下的演化规律。应变测量从四个单阶段蠕变试验用于模型验证。结果表明，混凝土的非线性徐变由两种机制控制：(1)水泥浆体纳米结构黏性界面的应力诱导黏滑过渡，这在现象上由亲和概念解释；(2)微裂纹诱导损伤，当应力超过强度的70%时，微裂纹引起的损伤尤为重要。

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来源期刊

Cement and Concrete Research 工程技术-材料科学：综合

CiteScore

20.90

自引率

12.30%

发文量

318

审稿时长

53 days

期刊介绍： Cement and Concrete Research is dedicated to publishing top-notch research on the materials science and engineering of cement, cement composites, mortars, concrete, and related materials incorporating cement or other mineral binders. The journal prioritizes reporting significant findings in research on the properties and performance of cementitious materials. It also covers novel experimental techniques, the latest analytical and modeling methods, examination and diagnosis of actual cement and concrete structures, and the exploration of potential improvements in materials.