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Main Authors: Ullah, Sana, Wu, Peng, Peng, Ting, Fan, Zujin, Long, Tianhao, Li, Yuan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.23006
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author Ullah, Sana
Wu, Peng
Peng, Ting
Fan, Zujin
Long, Tianhao
Li, Yuan
author_facet Ullah, Sana
Wu, Peng
Peng, Ting
Fan, Zujin
Long, Tianhao
Li, Yuan
contents Mass concrete plays a crucial role in large-scale projects such as water conservancy hubs and transportation infrastructure. Due to its substantial volume and poor thermal conductivity, the accumulation of hydration heat during the curing process can lead to uneven temperature gradients and stress field distribution, which may cause structural cracking. This phenomenon represents one of the critical challenges in quality control for hydraulic dams, bridge piers and abutments, tunnel linings, and similar engineering structures. To ensure structural safety, it is imperative to calculate temperature variations while optimizing and controlling the temperature stress field. In this paper, a novel method for calculating the zero-stress temperature field is proposed, considering the temperature history and hydration heat release increments at various locations within mass concrete during the curing period, the parameter of average forming temperature field is defined to subsequently solve the temperature stress field. Several typical hydration heat release models were selected to calibrate the computational accuracy of the average forming temperature. Based on simulation results, an optimal model was applied to validate the effectiveness of the proposed method through practical engineering case studies. The impacts of casting temperature, ambient temperature during the curing period, and dimensional thickness on temperature-induced stresses were systematically investigated. Additionally, stress variations at different representative points were compared with the overall mean stress distribution. The results demonstrate that this method can more accurately evaluate temperature induced stresses caused by seasonal temperature variations. This study provides a more reliable computational basis for ensuring the long-term service safety of mass concrete structures.
format Preprint
id arxiv_https___arxiv_org_abs_2503_23006
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Numerical Analysis of Temperature and Stress Fields in Mass Concrete Based on Average Forming Temperature Method
Ullah, Sana
Wu, Peng
Peng, Ting
Fan, Zujin
Long, Tianhao
Li, Yuan
Computational Physics
Mass concrete plays a crucial role in large-scale projects such as water conservancy hubs and transportation infrastructure. Due to its substantial volume and poor thermal conductivity, the accumulation of hydration heat during the curing process can lead to uneven temperature gradients and stress field distribution, which may cause structural cracking. This phenomenon represents one of the critical challenges in quality control for hydraulic dams, bridge piers and abutments, tunnel linings, and similar engineering structures. To ensure structural safety, it is imperative to calculate temperature variations while optimizing and controlling the temperature stress field. In this paper, a novel method for calculating the zero-stress temperature field is proposed, considering the temperature history and hydration heat release increments at various locations within mass concrete during the curing period, the parameter of average forming temperature field is defined to subsequently solve the temperature stress field. Several typical hydration heat release models were selected to calibrate the computational accuracy of the average forming temperature. Based on simulation results, an optimal model was applied to validate the effectiveness of the proposed method through practical engineering case studies. The impacts of casting temperature, ambient temperature during the curing period, and dimensional thickness on temperature-induced stresses were systematically investigated. Additionally, stress variations at different representative points were compared with the overall mean stress distribution. The results demonstrate that this method can more accurately evaluate temperature induced stresses caused by seasonal temperature variations. This study provides a more reliable computational basis for ensuring the long-term service safety of mass concrete structures.
title Numerical Analysis of Temperature and Stress Fields in Mass Concrete Based on Average Forming Temperature Method
topic Computational Physics
url https://arxiv.org/abs/2503.23006