Activation Energy for the Concrete Maturity Model – Part 1: Compressive Strength Tests at Different Curing Temperatures

IF 0.7 Q4 CONSTRUCTION & BUILDING TECHNOLOGY

Nordic Concrete Research Pub Date : 2020-06-01 DOI:10.2478/ncr-2020-0002

C. V. Nielsen, M. Kaasgaard

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引用次数: 4

Abstract

Abstract The article addresses the modelling of the maturity of concrete. The apparent activation energy is the backbone of the Arrhenius model, which is typically used to model the maturity of concrete. The maturity (or the equivalent age) is influenced by the curing temperature and it is applied when modelling the hydration process and the hardening of concrete for instance in order to forecast the early-age strength to determine the time for removal of formwork or the time for prestressing. Part 1 of the article describes the background for the maturity model and the test series carried out at the DTI concrete lab. Laboratory tests at different curing temperatures (from 5°C to 60°C) are presented and the compressive strength results are modelled according to the original Freiesleben Hansen and Pedersen maturity model that has been applied in the field for many years. The tests include five different concretes, using three different cement types and the addition of fly ash. There are significant differences especially when considering the later-age strength modelling at either low temperatures or at high temperature curing.

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混凝土成熟度模型的活化能。第1部分:不同养护温度下的抗压强度试验

摘要本文讨论了混凝土成熟度的建模问题。表观活化能是阿伦尼乌斯模型的主干，该模型通常用于模拟混凝土的成熟度。成熟度(或等效龄期)受养护温度的影响，在模拟混凝土的水化过程和硬化过程时，例如，为了预测早期强度，以确定拆除模板的时间或预应力的时间，成熟度(或等效龄期)被应用。本文的第1部分描述了成熟度模型的背景和在DTI混凝土实验室进行的一系列测试。介绍了在不同养护温度(从5°C到60°C)下的实验室测试，并根据在该领域应用多年的原始Freiesleben Hansen和Pedersen成熟度模型对抗压强度结果进行了建模。试验包括五种不同的混凝土，使用三种不同的水泥类型，并添加了粉煤灰。特别是考虑低温和高温固化下的后期强度模型时，存在显著差异。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nordic Concrete Research CONSTRUCTION & BUILDING TECHNOLOGY-

自引率

20.00%

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