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Home > Publications > International Concrete Abstracts Portal
Showing 1-5 of 69 Abstracts search results
Document:
SP358_09
Date:
October 1, 2023
Author(s):
Raquib Ahsan, Shegufta Zahan, and Jannatun Nahar
Publication:
Symposium Papers
Volume:
358
Abstract:
Unreinforced masonry (URM) structures are very common in South Asian countries. They can sustain vertical loads but are vulnerable against lateral loadings. This paper presents review of previously performed research on wall unit, reduced scale model and full-scale model of URM structures retrofitted with ferrocement. Researchers of Bangladesh, over the last five years, have implemented ferrocement overlay retrofitting on URM structures using indigenous materials. The research covered examining the performance of unit wall (without frame), half scale wall, full scale wall, and half scale room of retrofitted URM. The present study describes the differences in the experimental set ups and loading patterns of these studies, examines the lateral loading capacity determined in these studies and compares the failure patterns observed in the tests to the theoretically predicted ones. Finally, the paper compares performance in terms of load bearing capacity, cumulative energy consumption and stiffness degradation per cycle. It is found that previous studies were consistent in showing that ferrocement retrofitting using 18-gauge wire having mesh opening of 12.5 mm [0.5 in] x 12.5 mm [0.5 in] can improve the load bearing capacity of a wall by 40-50%, and the energy consumption before failure increases 1.4 times the reference unreinforced structure.
DOI:
10.14359/51740236
SP358
ACI Committees 341 and 441
With the aging and deterioration of infrastructure, the need for repair, strengthening, and rehabilitation of existing structures continues to increase. Climate change makes extending the service life of our infrastructure critical since any demolition and new construction will trigger substantial amounts of carbon emissions. Research related to repairing and strengthening existing infrastructure is seeing major developments as new green materials and technologies become available. Improved assessment and retrofit of deficient structures, and performance-based design of new structures are also in high demand. Despite the progress, there are many challenges yet to be addressed. The main objective of this Special Publication is to present results from recent research studies (experimental/numerical/analytical) on the retrofit and repair of structural elements along with the assessment, analysis, and design of structures. Several of these papers were presented at the ACI Fall Convention “Seismic Repair/Retrofit/Strengthening of Bridges at the Element or System Level: Parts 1 and 2.” The presented studies cover various aspects of structural retrofitting and strengthening techniques including the use of rubberized engineered cementitious composite for enhancing the properties of lightweight concrete elements, high-performance concrete jacketing to strengthen reinforced concrete piers/columns, and the behavior of fiber-reinforced-polymer-wrapped concrete cylinders under different environmental conditions. Additionally, the research explores the behavior of concrete-filled FRP tubes under axial compression, innovative bridge retrofit technologies, and retrofit techniques for deficient reinforced concrete columns. There is also a focus on evaluating the seismic response of retrofitted structures, designing guidelines for seismic retrofitting using tension-hardening fiber-reinforced concrete, strengthening unreinforced masonry walls with ferrocement overlays, and developing seismically resilient concrete piers reinforced with titanium alloy bars. The seismic response of a retrofitted curved bridge was also presented where elastomeric bearings of the as-built bridge were replaced by high damping rubber bearings as a part of the seismic retrofit. Recommendations for nonlinear finite element analysis of reinforced concrete columns under seismic loading are also presented to simulate their behavior up to collapse. Overall, the presented studies in this Special Publication demonstrate the potential of new materials, methods, and technologies to improve the performance of various structural elements under different loading conditions, including seismic and environmental loads. These studies are expected to help our practitioners and researchers not only develop more effective and sustainable methods for repairing and strengthening of structures but also improve their analysis and design skills.
10.14359/51740242
SP324
May 16, 2018
Gianmarco de Felice, Lesley H. Sneed, and Antonio Nanni
324
This SP is the result of two technical sessions held during the 2017 ACI Spring Convention in Detroit, MI. Via presentations and the resulting collection of papers, it was the intention of the sponsoring committees (ACI Committees 549 and 562 together with Rilem TC 250) to bring to the attention of the technical community the progress being made on a new class of repair/strengthening materials for concrete and masonry structures. These materials are characterized by a cementitious matrix made of hydraulic or lime-based binders, which embeds reinforcement in the form of one or more fabrics also known as textiles. The great variability of fabric architectures (for example, cross sectional area, strand spacing, and fiber impregnation with organic resin) coupled with the types of material used (aramid, basalt, carbon, glass, polyparaphenylene benzobisoxazole (PBO) and coated ultra-high strength steel) makes the characterization, validation, and design of these systems rather challenging. Irrespective of the reinforcement type (synthetic or ultra-high strength steel), the impregnating mortar is applied by trowel or spray-up. It should also be noted that fabric reinforced cementitious matrix and steel reinforced grout, in particular, are very different from other repair technologies such as FRC (fiber reinforced concrete) and UHPC (Ultra High-Performance Concrete) in that they utilize continuous and oriented reinforcement. In a sense FRCM and SRG can be viewed as the modern evolution of ferrocement.
10.14359/51711159
CI3411Naaman
November 1, 2012
Antoine E. Naaman and Pierre Brenet
Concrete International
34
Issue:
11
A ferrocement schooner with a quarter century of successful service
CI3403Chiorino
March 1, 2012
Mario A. Chiorino
3
With his masterpieces scattered the world over, Pier Luigi Nervi contributed to a glorious period for structural architecture. He was a designer, builder, researcher, creator of new construction techniques, professor, and author. Some of his greatest works are described in the context of his philosophy and technique. An international traveling exhibition, “Pier Luigi Nervi—Architecture as Challenge,” was launched in 2009 on the 30th anniversary of Nervi’s death.
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