Title:
Model for Lightweight Concrete Columns Confined by Either Single Hoops or Interlocking Double Spirals
Author(s):
A. R. Khaloo, K. M. El-Dash, and S. H. Ahmad
Publication:
Structural Journal
Volume:
96
Issue:
6
Appears on pages(s):
883-890
Keywords:
columns (supports); concretes; models.
DOI:
10.14359/783
Date:
11/1/1999
Abstract:
This article presents an analytical model to predict the stress-strain relationship of spirally confined medium- and high-strength lightweight aggregate (HS-LWA) concrete columns. The confinement pressure is assumed to vary along the height and the lateral dimension of the column section. The internal force equilibrium, the properties of the materials, and the geometry of the section are used to evaluate the lateral pressure. The model uses a single fractional equation that captures the realistic behavior of the response in the ascending and descending portions of the stress-strain curve. The parameters in the model are calibrated using the results of 16 spirally confined LWA column specimens tested recently at North Carolina State University. The column test specimens were from an elliptical cross section and confined by single hoops or interlocking double spirals. The analytical model is sensitive to influencing parameters, including the strength of concrete, yield strength of the confining reinforcement, volumetric ratio of the confining reinforcement to the concrete core, spacing of the confining reinforcement, cross section of the confined core, and configuration of the lateral confining reinforcement. The model demonstrates good predictive capability for the behavior of LWA concrete column specimens with concrete strengths from 40 to 103 MPa (5.8 to 15 ksi).