The effect of concrete creep on the long-term tension-stiffening law and prediction of a time-dependent inertia moment of the cracked RC flexural cross-sections

The proceedings of the 13th international conference "Modern Building Materials, Structures and Techniques" (MBMST 2019) Pub Date : 2019-12-03 DOI:10.3846/mbmst.2019.017

R. Balevicius

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Abstract

In the paper, a long-term stress-strain model is proposed for predicting the deformational response of the cracked reinforced concrete beams subjected to sustained bending. The linear and non-linear evolution creep strains is evaluated in the analytical manner by using an average stress-strain approach. The cracking and creep phenomena are coupled by two reologic elements connected in a series. In this way, the total strain of concrete prior to cracking is determined by a linear creep law accounting for the stress rate effect, while the post-cracking behavior is specified as a sum of elastic strain between cracks, creep and cracked concrete strain, defined by the descending branch of the stress-strain law. The smeared crack approach is adopted and, in turn, this law is associated with the tension stiffening phenomenon. The formulae accounting for the tension stiffening decay with time due to time-variable stress are proposed and applied in prediction of the inertia moment of the cracked RC flexural members along with the obtained results verification with the experimental data.

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混凝土徐变对开裂钢筋混凝土受弯截面长期拉加筋规律的影响及随时间变化的惯性矩预测

本文提出了一种长期应力-应变模型，用于预测钢筋混凝土裂缝梁在持续弯曲作用下的变形响应。采用平均应力-应变法对线性和非线性演化蠕变应变进行了分析。裂缝和蠕变现象是由两个串联的流变因素引起的。这样，混凝土开裂前的总应变由考虑应力率效应的线性徐变定律决定，而开裂后的行为被指定为裂缝、徐变和开裂混凝土应变之间的弹性应变之和，由应力-应变定律的下降分支定义。采用涂抹裂纹方法，反过来，这一规律与拉筋现象有关。提出了受拉刚度随时间衰减的计算公式，并将其应用于开裂钢筋混凝土受弯构件的惯性矩预测，并与实验数据进行了验证。

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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The proceedings of the 13th international conference "Modern Building Materials, Structures and Techniques" (MBMST 2019)

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