原文传递
Data-Driven Models for Predicting the Shear Strength of Rectangular and Circular Reinforced Concrete Columns
| 题名: | Data-Driven Models for Predicting the Shear Strength of Rectangular and Circular Reinforced Concrete Columns |
| 正文语种: | eng |
| 作者: | Kakavand, Mohammad Reza Azadi;Sezen, Halil;Taciroglu, Ertugrul |
| 作者单位: | Univ Innsbruck Dept Basic Sci Engn Sci Unit Strength Mat & Struct Anal A-6020 Innsbruck Tyrol Austria;Ohio State Univ Dept Civil Environm & Geodet Engn Columbus OH 43210 USA;Univ Calif Los Angeles Dept Civil & Environm Engn Los Angeles CA 90095 USA |
| 摘要: | Predicting the shear strength of structural elements subjected to gravity loads and ground motions is an important component of seismic design. Among all primary structural components, the vital role of columns in load transfer and redistribution, structural stability, and collapse prevention has been well recognized through observations made in the aftermath of past earthquakes. Numerous analytical, numeri-cal, and experimental studies have been conducted to assess the shear strength of RC columns in the past decades. However, there is still a large scatter (i.e., uncertainty) in the predictions of current empirical and numerical models relative to test data. In this paper, novel data driven models are presented for predicting the maximum shear strength of rectangular and circular RC columns. To this end, two extensive experimental databases for both types of columns were used in the present study. The data were randomly partitioned into calibration and validation sets. The calibration data sets served as the basis for developing linear and nonlinear equations for predicting the ultimate shear capacity of rectangular and circular RC columns through regression analyses. The Monte Carlo method was employed by conducting 106, 107, and 108 realizations to exhaustively examine the optimal parameter space of the postulated equations. The calibrated predictive models were then validated using the validation data sets; and their performances were also compared to existing models. These validation and comparison studies revealed that a new linear model devised and calibrated in the present study achieved very high accuracy, even compared to various nonlinear models considered. It was, moreover, significantly superior to all prior models in predicting the column shear strengths. This linear model, which is based on physical parameters, can therefore be recommended for engineering practice. |
| 出版年: | 2021 |
| 期刊名称: | Journal of Structural Engineering |
| 卷: | 147 |
| 期: | 1 |
| 页码: | 04020301.1-04020301.12 |
相关文献
- Data-Driven Approach to Predict the Plastic Hinge Length of Reinforced Concrete Columns and Its Application
- Strength and Behavior of Circular FRP-Reinforced Concrete Sections without Web Reinforcement in Shear
- Seismic Behavior of Circular Concrete Columns Reinforced by Low Bond Ultrahigh Strength Rebars
- Effect of Load Cycling, FRP Jackets, and Lap-Splicing of Longitudinal Bars on the Effective Stiffness and Ultimate Deformation of Flexure-Controlled RC Members
- Probabilistic Calibration for Shear Strength Models of Reinforced Concrete Columns
- High-Strength Rectangular CFT Members: Database, Modeling, and Design of Short Columns
检索历史
应用推荐
