|Table of Contents|

Experimental study on flexural performance of full iron tailings concrete beam(PDF)

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:
2024年03期
Page:
120-128
Research Field:
建筑结构
Publishing date:

Info

Title:
Experimental study on flexural performance of full iron tailings concrete beam
Author(s):
MA Xinxin12 SUN Jianheng1 ZHANG Ruolan1 ZHANG Fengshuang1 YUAN Jing1 MENG Zhiliang1
(1. College of Urban and Rural Construction, Hebei Agricultural University, Baoding 071001, Hebei, China; 2. China Academy of Building Research Co., Ltd., Beijing 100013, China)
Keywords:
full iron tailings concrete beam bending test characteristic bending moment plane section assumption flexural stiffness
PACS:
TU528.57
DOI:
10.19815/j.jace.2022.05051
Abstract:
In order to make full use of iron tailings, and study the mechanical properties of concrete structures with iron tailings, using iron tailing powder as admixture, iron tailing gravel and iron tailing sand as coarse and fine aggregate respectively, the full iron tailings concrete(FITC)beams were prepared. FITC was compared with conventional concrete(CC)beam using fly ash as admixture, common crushed stone and river sand as coarse and fine aggregate in the bending test. First of all, the parameters of iron tailings were tested to verify their feasibility as concrete raw materials. Secondly, the bearing capacity and deflection of each stage of the beam were calculated based on the current code formula. Finally, the measured and calculated values of FITC beams and CC beam were compared and analyzed. The results show that the strength of FITC is slightly lower than that of CC, and the elastic modulus is significantly reduced. The cracking moment and ultimate moment of FITC beam are equivalent to those of CC beam. The crack resistance and bearing capacity of the beam do not significantly decrease due to the lower strength and elastic modulus of FITC compared to CC. The concrete strain of FITC beams is in good agreement with the plane section assumption before cracks appear. Under load, the strain of concrete in the tension area of FITC beams is larger than that of the CC beam. The ductility and crack spacing of FITC beams are close to those of CC beam, and the oblique crack in bending shear zone of FITC beam is closer to the top of beam than that of CC beam. The deflection of FITC beams is larger than that of CC beam under the same bending moment, and the strain of longitudinal reinforcement in FITC beams is also larger than that in CC beam. The current design code of China is appropriate for calculating the bearing capacity of FITC beams, but the deflection calculation formula should be modified.

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Last Update: 2024-05-20