Non-destructive evaluation of residual strength distribution of recycled aggregate concrete and bond strength between recycled aggregate concrete and deformed bar with different cover thicknesses after freeze-thaw cycles

The thickness of a cover significantly influences both the bonding performance and the durability of materials against frost resistance. This research investigates the degradation and damage distribution of fundamental mechanical properties in two specimens of recycled aggregate concrete (RAC), each...

Full description

Saved in:
Bibliographic Details
Published in:Case Studies in Construction Materials 2024-07, Vol.20, p.e03347, Article e03347
Main Authors: Li, Zuohua, Yang, Haifeng, Tang, Zhiyu, Zhao, Binjie, Lv, Haoheng, Meng, Lilin
Format: Article
Language:English
Subjects:
Cover thickness
Damage distribution
Freeze-thaw cycle
Non-destructive test
Recycled aggregate concrete
Wedge-splitting angle
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The thickness of a cover significantly influences both the bonding performance and the durability of materials against frost resistance. This research investigates the degradation and damage distribution of fundamental mechanical properties in two specimens of recycled aggregate concrete (RAC), each with varying sizes, following freeze-thaw cycles (FTCs). This comparison is facilitated through non-destructive and damage tests. Subsequently, the influence of freeze-thaw damage (FTD) on the bond strength of specimens with differing cover thicknesses is examined via pull-out tests on 14 groups of center pull-out specimens. Lastly, the bond strength is theoretically analyzed. The test results reveal that FTCs diminish the material strength of RAC, and the FTD distribution within RAC specimens is not uniform. The surface concrete sustains a higher degree of damage compared to the internal concrete, resulting in an average FTD of small-size specimens that surpasses that of large-size specimens. The residual strength of RAC can be assessed using a non-destructive test, specifically the ultrasonic wave velocity test. For center pull-out specimens, FTD not only decreases the material strength but also increases the wedge splitting angle while reducing the critical protective layer thickness. This paper proposes a soft sleeve correction theory that comprehensively accounts for the effects of FTD. When combined with non-destructive test results—namely those from the ultrasonic wave velocity test—this theory can effectively evaluate the bond strength of RAC post-FTD. This approach offers valuable insights for the design and assessment of recycled concrete in cold climates. •Non-destructive and destructive tests were used to investigate RAC after FTD.•A prediction model based on the ultrasonic velocity change in RAC after FTD was proposed.•The formula of wedge splitting Angle was obtained by fitting the cover thickness and brittleness index.•A fitted formula for the thickness of the critical cover considering the brittleness index was proposed.•A softening sleeve correction theory considering friction was proposed.
ISSN:2214-5095
2214-5095
DOI:10.1016/j.cscm.2024.e03347