|
|
|
| Long-term Deflection Prediction and Correction of Creep and Shrinkage Model of High-strength Concrete Based on Short-term Measured Data for Bridge |
| ZENG Ding, XIE Jun, ZHENG Xiao-hua, REN Hong-wei, WANG Guo-liang |
| Research Institute of Highway, Ministry of Transport, Beijing 100088, China |
|
|
|
|
Abstract To investigate the laws of creep and shrinkage in high-strength concrete for long-span pre-stressed continuous box girder bridge and predict long-term deflection, strain sensors were embedded in the midspan of a box girder bridge. The shrinkage strain of concrete was then directly measured, and the creep strain was obtained using the incremental algorithm of measured data. The measured data show that if the creep and shrinkage model in the existing specification is used, then the shrinkage effect is underestimated as a whole and the creep effect is overrated for the C55 high-strength concrete of the bridge. The long-term deflection is predicted using the modified prediction models of creep and shrinkage that are based on short-term measured data when the bridge is under dead load. The deflection prediction values of two modified prediction models were compared with the measured deflection. Results of the comparison indicate that the integrality of the short-term measured strain data in concrete, measurement accuracy, and modified prediction model that is based on the measured data influence the prediction accuracy of the modified prediction models.
|
|
Received: 03 January 2015
|
| Fund:Supported by the Traffic Technology Project of Zhejiang Province (No.2011H17) |
|
|
|
[1] CHEN Can-ming, HUANG Wei-lan, LU Cai-rong et al. Creep of High-performance Concrete for Bridges and Its Application[J]. Hydro-science and Engineering, 2007(2):1-9(in Chinese).
[2] BROOKS J J, NEVILLE A M. Estimating Long-term Creep and Shrinkage from Short-term Test[J]. Magazine of Concrete Research, 1975, 27(90):3-12.
[3] SIRIVIVATNANON V. Predicting Long-term Creep from Short-term Test[J]. ACI Special Publication, 2005, 229:49-62.
[4] BAZANT Z P, PANULA L, KIM J K,et al. Improved Prediction Model for Time-dependent Deformations of Concrete:Part 6-Simplified Code-type Formulation[J]. Materials and Structures, 1992, 25:219-223.
[5] BAZANT Z P, XI Yun-ping, BAWEJA S. Improved Prediction Model for Time-dependent Deformations of Concrete:Part 7-Short Form of BP-KX Model Statistics and Extrapolation of Short Time Data[J]. Materials and Structures, 1993, 26:567-574.
[6] XU Hang, PENG Xiao-ming, ZOU Li-qun. Prediction Research of Long-term Creep for Bridge Concrete Based on Short-term Test[J]. Journal of Chongqing Jiaotong University:Natural Science Edition, 2010, 29(4):518-520. (in Chinese).
[7] OJDROVIC R P, ZARGHAMEE M S. Concrete Creep and Shrinkage Prediction from Short-term Tests[J]. ACI Materials Journal, 1996, 93(2):169-177.
[8] WANG Hui, QIAN Chun-xiang. Modification of Creep Prediction Models Based on Short-term Concrete Test Data of Sutong Bridge[J]. Bridge Construction, 2010(2):32-36(in Chinese).
[9] MENG Shao-ping, PAN Zuan-feng, WANG Hui, et al. Creep and Shrinkage Experiments and Analysis on High-performance Concrete of Sutong Bridge[J]. Modern Transportation Technology, 2009, 6(5):15-20. (in Chinese).
[10] ZHANG Yun-tao, MENG Shao-ping, HUI Zhuo, et al. Experimental Research on Concrete Creep for Main Girder of Continuous Rigid Frame Bridge of Sutong Bridge[J]. Journal of Highway and Transportation Research and Development, 2010, 27(4):101-104. (in Chinese).
[11] ZHANG Yun-tao, MENG Shao-ping, HUI Zhuo. Experimental Study on Creep and Shrinkage of High-performance Reinforced Concrete[J]. Building Science, 2010, 26(3):1-5. (in Chinese).
[12] ZHAO Qi-lin, CHEN li, ZHAI Ke-wei,et al. Creep and Shrinkage of High Strength Concrete for Bridges under Complex Condition[J]. Journal of PLA University of Science and Technology:Natural Science Edition, 2011, 12(5):459-465. (in Chinese).
[13] PAN Zuan-feng, LÜ Zhi-tao, LIU Zhao et al. Uncertainty Analysis of Creep and Shrinkage Effect in Continuous Rigid Frame of Sutong Bridge[J]. Engineering Mechanics, 2009, 26(9):67-73. (in Chinese).
[14] RILEM Technical Committees. Guidelines for Characterizing Concrete Creep and Shrinkage in Structural Design Codes or Recommendations[J]. Materials and Structures, 1995, 28:52-55.
[15] XIE Jun, ZENG Ding, ZHENG Xiao-hua. Long-term Deflection Prediction of Long-span Beam Bridge Based on Shrinkage Creep Self-identification[J]. Journal of Highway and Transportation Research and Development, 2013, 30(8):88-91. (in Chinese).
[16] KE Min-yong, LIU Hai-xiang, CHEN Can-ming et al. Prediction Model of Index Type Shrinkage and Creep for High-strength Concrete and Its Engineering Application[J]. Bridge Construction, 2011(4):49-52. (in Chinese). |
| [1] |
CHANG Zhu-gang, WANG Lin-kai, XIA Fei-long. Fluid-structure Interaction Numerical Simulation of Bridge Wind-induced Vibration Based on CV Newmark-β Method[J]. Journal of Highway and Transportation Research and Development, 2019, 13(2): 28-37. |
| [2] |
XU Bai-shun, YAO Chao-yi, YAO Ya-dong, QIAN Yong-jiu, MA Ming. Carbon Fiber Reinforced Polymer-to-steel Interfacial Stress Parameter Sensitivity Based on Viscoelastic Constitutive[J]. Journal of Highway and Transportation Research and Development, 2019, 13(2): 20-27. |
| [3] |
WEN Cheng, ZHANG Hong-xian. Influence of Material Time-dependent Performance on the Cantilever Construction of PSC Box Girder Bridge[J]. Journal of Highway and Transportation Research and Development, 2019, 13(2): 38-44. |
| [4] |
LU Guan-ya, WANG Ke-hai, ZHANG Pan-pan. Seismic Design and Evaluation Methods for Small-to-Medium-Span Highway Girder Bridges Based on Machine Learning and Earthquake Damage Experience[J]. Journal of Highway and Transportation Research and Development, 2019, 13(1): 24-37. |
| [5] |
YANG Yi-ming, PENG Jian-xin, ZHANG Jian-ren. Random Field Parameter Estimation of Service Bridge Component and Comparative Analysis of Estimation Methods[J]. Journal of Highway and Transportation Research and Development, 2019, 13(1): 38-49. |
| [6] |
ZHAN Jian, SHAO Xu-dong, QU Wan-tong, CAO Jun-hui. Multi-parameter Fatigue Analysis of a Steel-super Toughness Concrete Lightweight Composite Bridge Deck[J]. Journal of Highway and Transportation Research and Development, 2019, 13(1): 50-59. |
|
|
|
|
2015, Vol. 9 
