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4. Simplified Numerical Tool for a Fast Strength Estimation of Squared Masonry Columns Reinforced with FRP Jackets

Author

da Silva, Luis C. M., Grande, Ernesto, Milani, Gabriele, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Capozucca, Roberto, editor, Khatir, Samir, editor, and Milani, Gabriele, editor

Published
2023
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5. Experimental study on the eccentrically compressive performance of square masonry columns repaired with UHPC jackets

Author

Yifei Zhang, Peng Jiang, Hezhao Song, Jingchen Leng, Rui Chen, and Zhimei Jiang

Subjects
ultra-high performance concrete, masonry columns, strengthening, compressive performance, theoretical predictions, Technology
Abstract

Ultra-high performance concrete (UHPC) is a new class of structural material with outstanding properties of high strength, excellent ductility, and durability, which has an extremely broad application field. To examine the rehabilitation potential of UHPC on the existing masonry structures, the mechanical behavior of square masonry columns strengthened with UHPC under eccentric loading was investigated in this paper. A total of six masonry columns with or without the confinement of UHPC jackets were axially and eccentrically loaded. The strengthening effectiveness of UHPC on masonry columns was explored in terms of failure mode, deformation capacity, and carrying capacity. The results showed that UHPC jacketing is a highly effective technique for strengthening masonry columns, significantly increasing both the load-carrying capacity and transverse deformability of eccentrically compressed masonry columns (up to 103.64% and 71.43%, respectively). Furthermore, the UHPC strengthening technique modified brittle damage in unconfined masonry columns. A theoretical calculation was carried out for determining the bearing capacity of masonry columns strengthened with UHPC under eccentric loading. The accuracy of the theoretical calculation method was verified by comparing the theoretical values with the experimental values. Thus, this study provides a theoretical basis for the practical application of masonry structures strengthened with UHPC.

Published
2023
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6. Experimental Investigation on the Effectiveness of Masonry Columns Confinement Using Lime-Based Composite Material

Author

Alecci, Valerio, De Stefano, Mario, Galassi, Stefano, Magos, Raymundo, Stipo, Gianfranco, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Calabrò, Francesco, editor, Della Spina, Lucia, editor, and Piñeira Mantiñán, María José, editor

Published
2022
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7. Numerical Strategy for Column Strengthened with FRCM/SRG System.

Author

Verre, Salvatore

Subjects
COLUMNS, REINFORCED masonry, TRANSFER matrix, MASONRY, COMPOSITE columns, MORTAR
Abstract

The use of fabric-reinforced cementitious mortar (FRCM) or steel-reinforced grout (SRG) is now recognized to be effective in enhancing the axial capacity of masonry columns when confinement is achieved. Numerous experimental tests demonstrated the symbiotic role of the fabric and the inorganic matrix. An open issue is still related to the numerical simulation. In fact, if the compressive behavior by the numerical simulation of the unreinforced and reinforced masonry columns confined by a FRCM/SRG jacket may follow different approaches. The inorganic matrix transfers the stresses from the substrate to the fabric differently, depending on the presence or absence of cracks. The fabric consists of an open grid whose yard could be differently stressed after the matrix damage because of the occurrence of a possible slippage at the fabric–matrix interface. Definitely, these aspects are difficult to numerically predict. The paper herein is devoted to the assessment of different numerical approaches for the FRCM/SRG confinement of masonry columns by considering data from the literature and varying the parameters related to the matrix, the fabric, and the masonry itself. The goal is to best fit the experimental outcomes (from different available sources) with different strategies based on a finite element (FE) modeling. The results show good matching between the experimental and theoretical curves for the different FRCM/SRG systems. The results evidenced that the accuracy of the experimental versus the numerical curves match is met for the different FRCM/SRG systems. [ABSTRACT FROM AUTHOR]

Published
2022
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9. Numerical Strategy for Column Strengthened with FRCM/SRG System

Author

Salvatore Verre

Subjects
FRCM systems, SRG systems, masonry columns, numerical modeling, Building construction, TH1-9745
Abstract

The use of fabric-reinforced cementitious mortar (FRCM) or steel-reinforced grout (SRG) is now recognized to be effective in enhancing the axial capacity of masonry columns when confinement is achieved. Numerous experimental tests demonstrated the symbiotic role of the fabric and the inorganic matrix. An open issue is still related to the numerical simulation. In fact, if the compressive behavior by the numerical simulation of the unreinforced and reinforced masonry columns confined by a FRCM/SRG jacket may follow different approaches. The inorganic matrix transfers the stresses from the substrate to the fabric differently, depending on the presence or absence of cracks. The fabric consists of an open grid whose yard could be differently stressed after the matrix damage because of the occurrence of a possible slippage at the fabric–matrix interface. Definitely, these aspects are difficult to numerically predict. The paper herein is devoted to the assessment of different numerical approaches for the FRCM/SRG confinement of masonry columns by considering data from the literature and varying the parameters related to the matrix, the fabric, and the masonry itself. The goal is to best fit the experimental outcomes (from different available sources) with different strategies based on a finite element (FE) modeling. The results show good matching between the experimental and theoretical curves for the different FRCM/SRG systems. The results evidenced that the accuracy of the experimental versus the numerical curves match is met for the different FRCM/SRG systems.

Published
2022
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10. Mechanistic model for the compression strength prediction of masonry columns strengthened with fibre–polymer composites.

Author

da Silva, Luis C.M., Milani, Gabriele, Grande, Ernesto, and Funari, Marco F.

Subjects
*COLUMNS, *MASONRY, *COMPRESSIVE strength, *MORTAR, *FIBROUS composites
Abstract

A mechanistic model is presented for the strength prediction of squared columns made of masonry with a periodic arrangement and strengthened with a fibre–polymer composite jacketing. The formulation is based on an incremental plasticity theory that relies on equilibrium, compatibility, and kinematic equations. The strength domain of brick units and mortar joints is bounded by a multi-surface yield criterion: a Mohr–Coulomb strength domain with a linear cap in compression and a Rankine cut-off in tension. An elasto-plastic response with limited ductility is assumed for both masonry components. Differently, the FRP response is assumed elastic with a brittle failure governed by a limited tensile strain. Phenomenological-based assumptions are undertaken and justified. Details are also provided for the computational implementation of the procedure. The model accuracy is validated against experimental data on masonry squared columns and compared with existing standard-based formulas. Results demonstrate it provides real-time and accurate compressive strength solutions for squared masonry columns with or without a polymer-based wrapping and yet requiring few input parameters for the masonry constituents and reinforcement. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Statistical analysis of the compressive strength of fabric-reinforced cementitious matrix (FRCM)-confined masonry columns.

Author

Jing, Lei, Yin, Shiping, and Aslani, Farhad

Abstract

Strengthening is a valid measure for improving the mechanical performance of unreinforced masonry (URM) structures. Fabric-reinforced cementitious matrix (FRCM) is effectively compatible with masonry materials due to the use of an inorganic matrix. Therefore, FRCM boasts extensive application prospects in strengthening URM structures. Nevertheless, further research still needs to be conducted on the compressive performance of FRCM-confined masonry columns. In this paper, the uniaxial compressive test results of seventy-five FRCM-confined masonry columns were collected from the available literature. Two existing prediction models of the compressive strength of FRCM-confined masonry columns were adopted, and a model was also proposed based on the regression analysis of the collected data. The prediction accuracies of the three models were compared and analyzed, and the characteristic values of the compressive strength of FRCM-confined masonry columns were further obtained via a probabilistic method. These research results can be used to guide the compressive strength design of FRCM-confined masonry columns. [ABSTRACT FROM AUTHOR]

Published
2021
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12. Inherent Adaptive Structures Using Nature-Inspired Compound Elements

Author

Mohammad Reza Chenaghlou, Mohammad Kheirollahi, Karim Abedi, Ahmad Akbari, and Aydin Fathpour

Subjects
inherent adaptivity, compound element, self-centering system, masonry columns, truss structures, seismic excitation, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9
Abstract

Biomimicry studies have attracted significant attention in research and practice, leading to effective engineering solutions to develop new types of structures inspired by natural systems. The objective of this study is to employ natural structures' inherent adaptivity under changing loading conditions. Three new types of compound elements are proposed that are able to improve the structure load-bearing capacity through passive inherent adaptivity. A self-centering system, inspired by the human spine, which comprises a column pre-stressed through cables, is employed as a kinematic isolator. A similar self-centering system is applied to increase the load-bearing capacity of unreinforced masonry columns. An axially loaded element, inspired by the bamboo stem, which comprises a steel core reinforced by a series of cylindrical plates that are encased in a steel tube, is employed to control the onset of instability in long-span truss structures. Application to typical frame, masonry, and truss structures is investigated through finite element analysis. Results show that the proposed compound elements are effective to increase the structure load-bearing capacity and to reduce the response under seismic excitation owning to their inherent adaptive features.

Published
2020
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13. Axial compressive performance of masonry columns strengthened with ECC jacket and FRP strips.

Author

Zhang, Pu, Fan, Shaohua, Liu, Ye, Su, Chang, Hu, Junmin, and Sheikh, Shamim Ahmed

Subjects
*MASONRY, *MASONRY testing, *CEMENT composites, *FAILURE mode & effects analysis, *COMPRESSIVE strength, *COMPOSITE columns
Abstract

Fiber Reinforced Polymer (FRP) and Engineered Cementitious Composites (ECC) have been widely used to strengthen masonry columns due to their superior mechanical performance. Compression tests of masonry columns strengthened with ECC-jacket, FRP-strips, and ECC-jacket-FRP-strips were conducted in this study. The influence of the ultimate tensile strain of ECC and the number of FRP strip layers was investigated. The failure modes, load-displacement curves, strength, deformation, lateral strain, and energy absorption were analyzed and discussed. The results indicate that, compared with unconfined columns, the load-bearing capacity of columns strengthened by ECC jacket and two layers of FRP strips was significantly improved; 119% and 90.2% increases were achieved, respectively. There was a 242.4% and 119.4% increase in the corresponding ultimate deformation, respectively. In addition, the columns combine strengthened with ECC jacket and two layers of FRP strips exhibited excellent compression behavior, and their compressive strength was 274.5% higher than that of unconfined columns. The compressive strengths predicted by the available analytical models were adopted to evaluate the predictive ability of different models. The prediction model of the code CNR-DT 200/2013 exhibited better agreement with the experimental results in this study. • Compression performance of ECC-jacket-FRP-strips combined strengthened masonry columns. • The effects of ECC elongation and FRP sheet distribution on the load-bearing capacity of columns. • Strength, deformation, and energy absorption capacity of strengthened masonry columns were revealed. • A recalibrated analytical model was proposed to predict the compressive strength. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Numerical Modeling Approaches of FRCMs/SRG Confined Masonry Columns

Author

Luciano Ombres and Salvatore Verre

Subjects
FRCM systems, masonry columns, confinement, fabric/matrix bond, numerical modeling, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9
Abstract

The Fabric Reinforced Cementitious Matrices (FRCMs) and Steel Reinforced Grout (SRG) are a promising strengthening solution for existing masonry since inorganic matrix is considerably compatible with historical substrates. The present paper is focused on a Finite Element (FE) analysis of masonry columns confined with FRCM composites developed by Abaqus-code. The masonry columns were modeled using a macro model approach. The model was performed by using the following functions Concrete Damage Plasticity (CDP) and the Plastic (P) in order to describe the constitutive laws of material for masonry columns and external reinforcement, respectively. Typical failures of FRCM-systems are slippage of the fibers within the embedding matrix, instead for SRG-systems are detachment of the composite strip at the fabric-matrix interface and fiber rupture. In addition, perfect bond was considered for the interaction between the masonry column and in the overlap zone the bond slip law was modeled on the base of the failure mode. Results of an experimental investigation on FRCM and SRG clay brick masonry columns are used to calibrate the numerical model.

Published
2019
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15. Analysis of the Behavior of FRCM Confined Clay Brick Masonry Columns

Author

Luciano Ombres and Salvatore Verre

Subjects
masonry columns, frcm, confinement, Chemicals: Manufacture, use, etc., TP200-248, Textile bleaching, dyeing, printing, etc., TP890-933, Biology (General), QH301-705.5, Physics, QC1-999
Abstract

The behavior of FRCM (Fabric Reinforced Cementitious Mortar) confined clay brick masonry columns is analyzed in this paper. The results of an experimental investigation conducted on small-scale columns made by clay brick masonry confined with steel-FRCM (or Steel Reinforced Grout, SRG), PBO (poly-paraphenylene-benzo-bisoxazole) FRCM and basalt-FRCM, tested under monotonic compressive load, are described and discussed. Tests were conducted on thirteen prismatic columns; eleven columns (two unconfined and nine confined) were tested under concentric load while an eccentric load was applied on two confined columns. For each confinement system, the parameters investigated were the ‘confinement ratio’, the ‘load eccentricity’ and the ‘overlap configuration of the fiber fabrics’. FRCM confinement improved the structural response of masonry columns in terms of ultimate strength, ultimate strain and ductility. Some models from the literature were also examined to evaluate their applicability in predicting the axial capacity of confined columns.

Published
2020
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16. Cyclic behaviour of hinged steel frames enhanced by masonry columns and/or infill walls with/without CFRP.

Author

Gu, Xianglin, Wang, Lu, Zhang, Weiping, and Cui, Wei

Subjects
*STEEL framing, *MASONRY, *CARBON fiber-reinforced plastics, *HISTORIC buildings, *CYCLIC loads
Abstract

This paper investigates the in-plane seismic behaviour of hinged steel frames that are enhanced with masonry columns and/or infilled walls. First, eight half-scaled hinged steel frame specimens were constructed according to the realistic structural system of Bund 18, which is a historical building in Shanghai, China. Then, cyclic loads were exerted on these frames. The test results indicated that the seismic behaviours of the hinged steel frames can be significantly improved with the use of masonry columns and/or infilled masonry walls as well as with proper strengthening due to carbon fibre-reinforced polymer (CFRP) sheets. A simplified model was developed to simulate the seismic behaviours of these frames. In this model, infilled walls and CFRP sheets were replaced by diagonal struts, and the steel members and their surrounding elements were treated as composite members. Finally, this model was verified by experimental results. [ABSTRACT FROM AUTHOR]

Published
2018
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17. Comparative experimental analysis on the compressive behaviour of masonry columns strengthened by FRP, BFRCM or steel wires.

Author

Fossetti, Marinella and Minafò, Giovanni

Subjects
*REINFORCED masonry, *COMPRESSIVE strength, *FIBROUS composites, *DUCTILITY, *STEEL wire, *STRESS-strain curves, *COMPARATIVE studies
Abstract

In the last decade, several studies have investigated the application of Fibre Reinforced Polymer (FRP) wraps to masonry piers in order to provide a confinement effect and enhance compressive strength and ductility. Although this technique has proved to be quite effective, various drawbacks arise when organic resins are used to bind fibres. To solve these problems, different techniques have been developed to be used as alternative methods for enhancing the structural performances of weak masonry columns. Among these, the use of Basalt Fibre Reinforced Cementitious Matrix (BFRCM) wrapping, or the application of steel wires at mortar joints. This paper presents the results of an experimental study on the compressive behaviour of clay brick masonry columns reinforced with FRP wraps, Basalt Fibre Reinforced Cementitious Matrix (BFRCM) or with steel wires. Uniaxial compressive tests were performed on twelve retrofitted columns and four control specimens up to failure. Two masonry grades were considered varying the mix used for the mortar. The results are presented and discussed in terms of axial stress-strain curves, failure modes and crack patterns of tested specimens. Comparisons with unreinforced columns show the capabilities of these techniques in increasing the structural efficiency with reduced aesthetical impact. [ABSTRACT FROM AUTHOR]

Published
2017
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18. Modelling of FRP and FRCM-Confined Masonry Columns: Critical Review for Design and Intervention Strategies

Author

Monaco A., D'Anna J., Minafo' G., LA MENDOLA L., Monaco A., D'Anna J., Minafo' G., and LA MENDOLA L.

Subjects
Analytical modelling, Masonry columns, Parametric analysis, FRCM, Confinement, FRP
Abstract

This paper presents a critical review of the most established analytical models for the prediction of the compressive strength of FRP and FRCM-confined masonry columns. In particular, two types of fibres are analysed, i.e. glass and basalt. A wide dataset available in the literature is used for the application of the analytical models and for the development of parametric analyses useful for the critical comparison of FRP vs. FRCM confinement technique and glass vs. basalt fibres to be adopted as reinforcement of masonry substrate. The effects of stiffness and strength of the reinforcement, the number of reinforcing layers, the compressive strength of masonry and the cross-section shape are investigated.

Published
2022

19. Modelling of FRP and FRCM-confined masonry columns: critical review for design and intervention strategies

Author

Alessia Monaco, Jennifer D'Anna, Giovanni Minafò, and Lidia La Mendola

Subjects
analytical modelling, masonry columns, Mechanics of Materials, Mechanical Engineering, confinement, parametric analysis, General Materials Science, FRP, FRCM
Abstract

This paper presents a critical review of the most established analytical models for the prediction of the compressive strength of FRP and FRCM-confined masonry columns. In particular, two types of fibres are analysed, i.e. glass and basalt. A wide dataset available in the literature is used for the application of the analytical models and for the development of parametric analyses useful for the critical comparison of FRP vs. FRCM confinement technique and glass vs. basalt fibres to be adopted as reinforcement of masonry substrate. The effects of stiffness and strength of the reinforcement, the number of reinforcing layers, the compressive strength of masonry and the cross-section shape are investigated.

Published
2022

20. Confinement of Masonry Columns with Natural Lime-Based Mortar Composite: An Experimental Investigation

Author

Valerio Alecci, Mario De Stefano, Stefano Galassi, Raymundo Magos, and Gianfranco Stipo

Subjects
experimental campaign, masonry columns, FRCM composites, confinement, analytical predictions, Environmental effects of industries and plants, Renewable Energy, Sustainability and the Environment, Geography, Planning and Development, TJ807-830, Management, Monitoring, Policy and Law, TD194-195, Renewable energy sources, Environmental sciences, masonry columns, FRCM composites, confinement, experimental campaign, analytical predictions, GE1-350
Abstract

The paper presents the results of an experimental campaign on the confinement of masonry square columns with fiber-reinforced lime mortar (FRLM) composites made of a natural lime-based matrix. The experimental results show the effectiveness of such a composite for increasing both strength and ductility performances of strengthened columns. Predictive formulas from the literature and from the Italian guidelines CNR-DT 215/2018 do not perfectly fit the experimental outcomes and do not confirm the strength increase of the confined columns. The reason can be attributed to the very low mechanical properties of the natural matrix used to form such a composite. Therefore, considering that the use of a natural and sustainable matrix fully compatible with the masonry substrate is a fundamental requirement for strengthening masonry columns of buildings belonging to architectural heritage, an additional future effort should be made by researchers involved in this field. In particular, for a reliable prediction of the strength of masonry columns confined with composites made of natural matrices, wider experimental campaigns are necessary to refine available formulas with respect to different substrates and component materials.

Published
2021

21. Stability analysis of clay brick masonry columns: numerical aspects and modelling strategies.

Author

Fossetti, Marinella, Giacchino, Carmelo, and Minafò, Giovanni

Abstract

Stability analysis of masonry piers and columns is one of the most frequently treated subjects in the field of structural engineering. This attention is probably due to the challenge to solving the problem including different effects, which play an important role in evaluating the response of eccentrically-loaded columns. In this connection, accurate stability analysis of masonry piers and columns has to take into account the non-linear stress-strain law of masonry in compression, the limited tensile strength, the induced slenderness due to crack formation and geometrical non-linearity. Different theoretical models and numerical approaches were developed in the past to analyze the combined effect of buckling and strength in such structural members. In this paper a numerical method is derived and particularized for the case of clay brick masonry members. After a review of the most widely used analytical models for the compressive behaviour of masonry, the effects of a non-linear constitutive law in compression and cracking were taken into account with suitable moment-curvature curves. The latter were implemented in a simple numerical procedure, and made it possible to calculate the force-displacement curves and safety domains, which account for both strength and stability. The method was finally verified with results derived from non-linear finite element analyses, making it possible to make considerations about the suitability of the method and the related computational effort. [ABSTRACT FROM AUTHOR]

Published
2015
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22. FRP confinement of masonry: analytical modeling.

Author

Lignola, Gian, Angiuli, Riccardo, Prota, Andrea, and Aiello, Maria

Abstract

International and National Building Codes provide requirements for design and construction of new masonry structures, but design provisions for the repair, retrofitting, and rehabilitation of masonry structures are not always available and included in the same documents. Due to the extremely large variability in masonry performances, equations of general validity cannot often be provided, namely relationships suitable for every masonry type. Despite the great research effort in the experimental field, considerable theoretical work is still needed to fully outline a definitive analytical model to predict the behavior of FRP confined masonry. Most of the available models, empirical in nature, have been calibrated against their own sets of experimental data, or they are simply derived from concrete. Even if large amount of results obtained for concrete led to consolidated design guidelines, they cannot be simply extended to masonry. In this study, a mechanically based confinement model is proposed based on mechanical parameters able to differentiate similar masonry types and to highlight that they present different confinement performance. Crucial aspects of masonry confinement will be also discussed, namely: lateral dilation; confinement effectiveness; lateral pressure also in non-circular shapes; effective strain of FRP. [ABSTRACT FROM AUTHOR]

Published
2014
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23. Analytical model for CFRP confined masonry columns subjected to monotonic and cyclic compression.

Author

Thamboo, Julian, Zahra, Tatheer, Asad, Mohammad, Silva, Lakshitha, and Gimhani, Jeewamali

Subjects
*COMPOSITE columns, *MASONRY, *CONCRETE columns, *COMPRESSION loads, *STRAINS & stresses (Mechanics), *CYCLIC loads, *MASONRY testing, *MORTAR
Abstract

• Confined masonry columns were subjected to monotonic and cyclic compression. • Axial behaviour of continuously and discontinuously confined masonry are different. • Cyclic stress–strain characteristics of confined masonry columns were verified. • Formulations to describe the stress–strain model under cyclic loading are suggested. Confinement of masonry columns using fibre reinforced polymer (FRP) composites have displayed to enhance the axial capacity and ductility. Although, mechanisms of FRP confined masonry column (CMC) subjected to monotonic compression loading with various configurations have been investigated and rational design rules were developed, the response of FRP-CMC under cyclic compression is not widely researched. Therefore, this paper presents an analytical stress–strain model for FRP-CMC subjected to cyclic compression based on the experimental data generated through a testing program. The experimental program has been executed in this research by testing twelve masonry columns confined with discontinuous FRP sheets subjected to monotonic and cyclic compression. The masonry columns were assembled with two varieties of masonry bricks and mortars. The data from the testing of discontinuously CMCs and previous experimental program involving twenty-four continuously CMCs were employed to analytically predict the cyclic compression characteristics. The testing results of discontinuously CMCs subjected to axial monotonic and cyclic compression have shown that they are quite different in terms of their strength and deformability compared to continuously CMCs. The discontinuous FRP strengthening columns resulted in strength and ductility increments in the range of 100–150% and 60–80%, respectively. For the analytical model, the envelop curve, plastic strain, stress deteriorations in cycles, unloading and reloading segments of the proposed stress–strain model have been verified against the experimental data. It has been shown that the suggested analytical model is capable of describing the cyclic axial stress–strain characteristics of FRP-CMCs. [ABSTRACT FROM AUTHOR]

Published
2022
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24. Sprayed glass fibre reinforced polymer masonry columns under concentric and eccentric loading.

Author

Shaheen, E. and Shrive, N. G.

Subjects
*MASONRY, *BUILDING foundations, *GLASS fibers, *POLYMERS, *STRENGTH of materials, *STRAINS & stresses (Mechanics), *MORTAR, *BINDING agents, *STRUCTURAL analysis (Engineering), *STRUCTURAL engineering
Abstract

Strengthening masonry columns by spraying them with glass fibre reinforced polymer (GFRP) was investigated experimentally. The study was aimed at assessing the strength and strain increases imparted by the technique under both concentric and eccentric axial loading. Plain and steel-reinforced columns were tested. Twenty-four columns were constructed from Type S mortar and straight and bullnose clay masonry units. The columns were 1 m high and either 290 mm × 290 mm or 390 mm × 390 mm in cross section. Two thicknesses of sprayed GFRP (SGFRP) were attempted, but it was found to be difficult to maintain uniform thickness. Nevertheless, with only minor increases in strength, large increases in strain capacity were achieved with both the plain and reinforced columns under concentric axial compression. Eccentric loading reduced the effect of the SGFRP laminate on the strength of masonry columns. Failure of SGFRP included both mode I and mode III fractures. [ABSTRACT FROM AUTHOR]

Published
2007
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25. No tension beam-columns with bounded compressive strength and deformability undergoing eccentric vertical loads

Author

De Falco, Anna and Lucchesi, Massimiliano

Subjects
*COLUMNS, *MECHANICS (Physics), *DEFORMATIONS (Mechanics), *ELASTIC solids
Abstract

Abstract: This work concerns the static behaviour of rectangular cross-section beam-columns made of a no-tension material with limited compressive strength and deformability and subjected to eccentric vertical loads acting at their extremities. The explicitly obtained results allow for thorough description of the stability characteristics of such a pile. A final example shows the practical potentials of the method. [Copyright &y& Elsevier]

Published
2007
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26. Comportamento estrutural de pilares armados e não armados, construídos com blocos de terra compactados

Author

Borja, Rômulo Thomaz de Figueiredo and Azeredo, Givanildo Alves de

Subjects
Construção com terra, Bloco de Terra Compactado (BTC), Pilares de alvenaria, Compacted Earth Block (CEB), Masonry columns, Sistema construtivo de BTC, Earth construction, ENGENHARIAS::ENGENHARIA CIVIL [CNPQ], CEB Building System
Abstract

Compacted Earth Block (CEB) construction uses technology that converts the earth into structure, bringing the simplicity of the natural soil supply along with adequate standards of strength and durability. The flexibility of load bearing masonry design allows for various building styles, from traditional walls to pillars and arches. The objective of this work was to analyze the structural behavior of reinforced and non reinforced CEB columns subjected to centered loading. The blocks were characterized by axial compression and absorption tests. Three types of columns were made and characterized by the axial compression test, rupture mode analysis, displacements and cracking in the structural element. It was observed that the reinforced CEB columns performed better when compared to the non reinforced ones. However, block crushing was the main cause for the structural collapse of all columns. Finally, we conclude that we cannot consider the design model proposed by NBR 15812 (2010) for ceramic block masonry columns, as a representative model for CEB columns. Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES A construção com bloco de terra compactado (BTC) usa tecnologia que converte a terra em estrutura, trazendo a simplicidade da oferta natural do solo, juntamente com padrões adequados de resistência e durabilidade. A flexibilidade de projeto de alvenaria portante, permite vários estilos de construção, desde paredes tradicionais a pilares e arcos. O objetivo deste trabalho foi analisar o comportamento estrutural de pilares armados e não armados de BTC, submetidos a carregamento centrado. Os blocos foram caracterizados através dos ensaios de compressão axial e absorção. Três tipos de pilares foram realizados e caracterizados pelo ensaio de compressão axial, análise do modo de ruptura, deslocamentos e fissurações no elemento estrutural. Observou-se que os pilares de BTC armados obtiveram melhor desempenho quando comparados aos não armados. Entretanto, o esmagamento dos blocos foi a principal causa para o colapso estrutural de todos os pilares. Por fim, concluímos que não podemos considerar o modelo de dimensionamento proposto pela NBR 15812 (2010) para pilares de alvenaria de bloco cerâmico, como um modelo representativo para pilares de BTC.

Published
2019

27. Confinement of Masonry Columns with Natural Lime-Based Mortar Composite: An Experimental Investigation.

Author

Alecci, Valerio, De Stefano, Mario, Galassi, Stefano, Magos, Raymundo, and Stipo, Gianfranco

Abstract

The paper presents the results of an experimental campaign on the confinement of masonry square columns with fiber-reinforced lime mortar (FRLM) composites made of a natural lime-based matrix. The experimental results show the effectiveness of such a composite for increasing both strength and ductility performances of strengthened columns. Predictive formulas from the literature and from the Italian guidelines CNR-DT 215/2018 do not perfectly fit the experimental outcomes and do not confirm the strength increase of the confined columns. The reason can be attributed to the very low mechanical properties of the natural matrix used to form such a composite. Therefore, considering that the use of a natural and sustainable matrix fully compatible with the masonry substrate is a fundamental requirement for strengthening masonry columns of buildings belonging to architectural heritage, an additional future effort should be made by researchers involved in this field. In particular, for a reliable prediction of the strength of masonry columns confined with composites made of natural matrices, wider experimental campaigns are necessary to refine available formulas with respect to different substrates and component materials. [ABSTRACT FROM AUTHOR]

Published
2021
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28. Performance of axially loaded masonry columns confined using textile reinforced concrete (TRC) added with short fibers.

Author

Li, Tong, Deng, Mingke, Jin, Mengna, Dong, Zhifang, and Zhang, Yangxi

Subjects
*REINFORCED concrete, *MASONRY, *POLYVINYL alcohol, *FIBERS, *AXIAL loads
Abstract

• TRC optimized with short fibers, is used in the masonry confinement. • Eighteen masonry piers are tested under concentric axial loading. • TRHDC confinement can improve strength, ductility and energy absorption. • Applicability of models from literature are evaluated to predict the masonry strength. Textile-reinforced high ductile concrete (TRHDC) (Li et al., 2020) is an optimized textile reinforced concrete (TRC) by using short polyvinyl alcohol (PVA) fibers. This work presented an experimental study on the compressive behavior of masonry piers confined with TRHDC jacket. The considered parameters were textile types, number of textile layers, together with a group of fiber reinforced polymer (FRP) confined columns as a reference set. Although the strength was greatly improved by the FRP wraps, the brittle failure and rather weak post-peak behavior were observed in the FRP strengthened columns. By contrast, TRHDC composites changed failure mode of columns with multiple thin cracks opening on the jacket. The compressive strength, ultimate strain and energy absorption capacity were improved by the TRHDC confinement. Analytical models from the literature were evaluated for their applicability to estimate the compressive strength of masonry piers confined with FRP or TRHDC jacket. Predictions were in good agreement with experimental data, which can be adopted in the engineering application. [ABSTRACT FROM AUTHOR]

Published
2021
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29. Performance of masonry columns confined with composites under axial compression: A state-of-the-art review.

Author

Thamboo, Julian

Subjects
*COMPOSITE columns, *MASONRY, *CONCRETE columns, *STRAINS & stresses (Mechanics), *COMPRESSIVE strength, *STEEL wire, *TENSILE strength
Abstract

• Masonry columns confined with three different techniques were reviewed. • Strength and deformation characteristics of the confined masonry columns were evaluated. • Analytical models to predict the confined masonry compressive strengths were appraised. • The compressive stress–strain behaviour of confined masonries was assessed. The confinement technique has been effectively used to enhance the strength and ductility of structural elements. Since masonry possesses relatively limited ductility and tensile strength, the confinement has been shown to improve the performance of masonry elements, particularly the columns. Primarily three different techniques are implemented to confine the masonry columns (1) fibre reinforced polymer (FRP) wrapping (2) fabric reinforced cementitious matrix (FRCM) application and (3) confinement of mortar joints by steel grinds or wire hooping. Although the above mentioned techniques have shown to provide confinement and improve the performance of masonry columns, each has its own advantages and disadvantages in terms of applicability, compatibility, strength enhancement, ductility gain and reversibility. Therefore in this paper, an attempt has been made to critically review the performance of masonry columns confined with above mentioned techniques to appraise their performances in relation to various parameters. For these purposes, three sets of experimental databases have been developed for the above stated techniques from the past research studies. Further several analytical models have been independently developed to predict the confined compressive strength and axial stress–strain behaviour of the masonry columns; subsequently the predictabilities of those analytical models were verified by comparing against with the experimental database. The analyses revealed, that the analytical models given in the Italian guidelines CNR DT 200/215 conservatively predict the confined strength of masonry columns. Therefore it can be recommended to use deliberately across different confinement techniques investigated. [ABSTRACT FROM AUTHOR]

Published
2021
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30. Mechanical behavior of masonry columns strengthened with basalt textile reinforced concrete under eccentric loading: Experimental investigation and analytical modelling.

Author

Wan, Chenglin, Wang, Jiyang, Zeng, Qiang, Shen, Linghua, Yan, Dongming, and Peng, Yu

Subjects
*ECCENTRIC loads, *REINFORCED concrete, *STRAINS & stresses (Mechanics), *MASONRY, *BASALT, *COMPRESSION loads
Abstract

• A study on the mechanical behavior of eccentrically loaded BTRC confined masonry. • BTRC confinement can significantly improve the ultimate compressive strength of masonry columns. • Strain gradient effect existed on the strains of BTRC jackets. • A nonlinear iterative procedure was proposed to evaluate the second order effect. The mechanical behavior of masonry columns confined with basalt textile reinforced concrete (BTRC) under eccentric compression was investigated. The main objects of this research include: i) the effects of load eccentricity and confinement ratio on the failure modes of masonry columns; ii) the confinement effectiveness of BTRC on columns involving increases in peak load and ductility; iii) confinement mechanism of BTRC jackets under eccentric loading, i.e. , how the confinement was activated; iv) the theoretical predictions of mechanical behavior of masonry columns through an analytical procedure. A total of 20 masonry columns with or without confinement of BTRC jackets were eccentrically loaded and two parameters were varied, i.e. , confinement ratio, ρ f , and eccentricity-to-section height ratio, e/h. The experimental results were discussed and analyzed in terms of failure modes, load-axial deformation response, load-lateral deflection response and load-strains curves of BTRC jackets. A nonlinear second order iterative procedure was developed to predict mechanical behavior of eccentrically loaded masonry columns, in which the variation of eccentricity along the entire height induced by lateral deformations could be considered. Finally, the theoretical predictions were compared with experimental results to evaluate the findings herein. [ABSTRACT FROM AUTHOR]

Published
2021
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31. Experimental investigation on compressive performance of masonry columns confined with textile-reinforced concrete.

Author

Jing, Lei, Yin, Shiping, and Aslani, Farhad

Subjects
*MASONRY, *ULTIMATE strength, *COMPRESSIVE strength, *FAILURE mode & effects analysis, *ENERGY dissipation, *REINFORCED masonry, *COMPOSITE columns
Abstract

• TRC confinement effectively improved the compressive performance of masonry columns. • The prediction model of compressive strength was proposed with a better generality. • Some available data in other literature were considered in the analytical models. Masonry structures strengthened with textile-reinforced concrete (TRC) have been extensively studied, and many results have confirmed the TRC-strengthened effectiveness. The present paper demonstrated the experimental investigation on the compressive performance of TRC-confined masonry columns in terms of failure mode, carrying capacity, deformability and energy dissipation. The prediction formulas of the compressive strength and ultimate strain were also proposed based on the test results in this paper and available data in other literature. The results indicated that the brittle failure feature of unconfined masonry columns was relieved after TRC confinement. The specimens confined with the carbon-glass TRC showed a better ductile behavior compared with that of the basalt-glass TRC because a relatively poor ability to disperse cracks was observed for basalt-glass TRC-confined specimens in this test. The carrying capacity, deformability and energy dissipation of the specimens after TRC confinement all gained the different degrees of increase, and the increased effectiveness of the carbon-glass TRC-confined specimens was more prominent compared with that of basalt-glass TRC. The compressive strength of TRC-confined masonry columns can be well predicted by the formula obtained in this paper with a better generality, while the prediction formula of the ultimate strain for TRC-confined masonry columns has a lower accuracy, and needs to be further researched. [ABSTRACT FROM AUTHOR]

Published
2021
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32. Masonry columns behaviour analyses due to a different mode of confinement with GFRP straps

Author

Josip Galić, Hrvoje Vukić, and Ivan Kalafatić

Subjects
tests, masonry columns, strengthening, glass fibre reinforced polymer straps, GFRP, results
Abstract

The paper describes the experimental research of masonry columns behavior under the load of vertical compression. A total of thirty-four specimens were tested: three unconfined specimens and thirty-one specimens confined with GFRP straps. In addition to the load-bearing efficiency analysis of confined columns in relation to the number of the confinement layers, the intention of these tests was to determine the efficiency of spiral confinement in relation to conventional confinement. The impact of the existing compressive stress in a column during confinement to the final increased load-bearing capacity of the confined column was also studied.. The test results have shown that all of the confined specimens have a greater load-bearing capacity and ductility than the unconfined specimens. The results of spiral confinement were almost identical to the results of conventional confinement, which is vital considering that spiral confinement is easier to perform. The results of the test lead to the conclusion that the presence of compressive stress in a column during confinement does not significantly reduce confinement efficiency. This makes it possible to effectively increase the bearing capacity of masonry columns without the need to previously unload the structure, while the structure is in service. The paper also provides expressions for the estimated increase in the compressive strength of confined columns that well correspond to the testing results.

Published
2018

33. Masonry columns confined with glass textile-reinforced high ductile concrete (TRHDC) jacket.

Author

Li, Tong, Deng, Mingke, Dong, Zhifang, Zhang, Yangxi, and Zhang, Cong

Subjects
*MASONRY, *CONCRETE columns, *ECCENTRIC loads, *FIBROUS composites, *TEXTILE fibers, *AXIAL loads
Abstract

In this study, a new type of composite comprised of glass textiles embedded in the short fiber reinforced cementitious composite, referred to as textile-reinforced high ductile concrete (TRHDC), is explored for use in the confinement of masonry columns. This paper presents the results of an experimental study on the effect of TRHDC jacket on the compressive behavior of clay brick masonry columns. Six unconfined and twelve confined columns with a rectangular cross-section are tested under monotonic concentric and eccentric loads. Test parameters are binding mortar grade and loading eccentricity. The data in terms of failure mode, peak load, stress-strain and moment-curvature response are analyzed and discussed. The test results indicate that TRHDC confinement can clearly improve both the load carrying capacity and the deformability of masonry columns relative to the unconfined condition. However, a noticeable reduction in peak load is observed under strain gradient condition with the increase of eccentricity level. Analytical models available in the literatures are used to predict the strength increase from the TRHDC jacket, with certain models predicting the confined compressive strength accurately. For the eccentrically-loaded masonry columns confined with TRHDC jacket, the confined compressive strength is reduced depending on the eccentricity ratio (e / h) to evaluate the axial load carrying capacity. The predicted values are in agreement with test results but should need further experimental investigations in the future to verify the reliability of expressions rather than those used in this paper. [ABSTRACT FROM AUTHOR]

Published
2020
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34. Compressive performance of masonry columns confined with highly ductile fiber reinforced concrete (HDC).

Author

Deng, Mingke, Li, Tong, and Zhang, Yangxi

Subjects
*MASONRY, *REINFORCED concrete, *FAILURE mode & effects analysis, *STEEL tubes, *MORTAR, *FIBER-reinforced concrete
Abstract

• ·The effectiveness of HDC system used to confine masonry was studied. • ·The HDC as binding mortar clearly improved the deformability rather than strength. • ·The HDC jacket could increase both the strength and deformability. • ·Analytical model was proposed for predicting strength of confined masonry. This work presents the results of an experimental investigation on the compressive behavior of clay brick masonry columns confined with highly ductile fiber reinforced concrete (HDC). The study aims to prove the effectiveness of the proposed confinement technique and detect the efficiency of different confinement forms of HDC, including internally-placed HDC which was used as binding mortar in the joints (i.e. internal HDC mortar) and external HDC jacket. Furthermore, the effect of confinement materials is examined. Analysis of the failure mode, axial load–displacement curves, peak load and ductility reveals that internal HDC mortar could considerably improve the deformability of masonry columns. Although the external HDC jacket could increase the load carrying capacity and deformability, the detachment between the external layer and masonry substrate is observed at the post-peak stage. Contribution of cement-based mortar jacket to the masonry columns is merely enhancing the load carrying capacity rather than deformability, which was caused by its quite low tensile strength. Moreover, based on the theories of mesh-reinforced brick masonry and steel tube confined concrete, analytical models available in the literatures are adopted to predict the compressive strength of HDC systems confined masonry columns. The calculation model gives a better approximation to predict the compressive strength of confined masonry columns but should need further experimental data in the future other than those adopted in this paper to verify the accuracy and reliability. [ABSTRACT FROM AUTHOR]

Published
2020
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35. Masonry columns strengthened with bar mesh highly ductile fiber reinforced concrete (BMHDC) jacket under concentric and eccentric loads.

Author

Deng, Mingke and Li, Tong

Subjects
*ECCENTRIC loads, *FAILURE mode & effects analysis, *PEAK load, *MASONRY, *REINFORCED concrete, *CONCRETE columns
Abstract

• The effectiveness of HDC system as a means for reinforcement of masonry was studied. • The BMHDC jacket improved both load bearing capacity and deformability. • The BMHDC jacket can be used to strengthen the large eccentric columns. • Theoretical prediction is proposed for strengthened masonry columns. This work presents the results of an experimental study on the compressive performance of clay brick masonry columns strengthened with bar mesh highly ductile fiber reinforced concrete (BMHDC) jacket. The test parameters consist of strengthening method and loading eccentricity. The analysis in terms of failure mode, peak load, axial load-displacement curves and ductility proves that BMHDC jacket is an effective reinforcing technique which can significantly improve the load carrying capacity and deformability of masonry columns. Although the maximum load of masonry column is decreased with the increase of loading eccentricity, the effectiveness of using BMHDC jacket is not weakened by the initial eccentricity. Moreover, for the convenience of strengthening design in the practical applications, a theoretical prediction of load carrying capacity for strengthened masonry columns tested under concentric and eccentric loads is proposed on the basis of the plane cross-section assumption and modified biaxial strength criterion of bricks. Predicted results are accurate and consistent with experimental results. [ABSTRACT FROM AUTHOR]

Published
2020
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36. Analysis of the Behavior of FRCM Confined Clay Brick Masonry Columns.

Author

Ombres, Luciano and Verre, Salvatore

Subjects
BEHAVIORAL assessment, MASONRY, BRICKS, ECCENTRIC loads, ULTIMATE strength, LEAD oxides
Abstract

The behavior of FRCM (Fabric Reinforced Cementitious Mortar) confined clay brick masonry columns is analyzed in this paper. The results of an experimental investigation conducted on small-scale columns made by clay brick masonry confined with steel-FRCM (or Steel Reinforced Grout, SRG), PBO (poly-paraphenylene-benzo-bisoxazole) FRCM and basalt-FRCM, tested under monotonic compressive load, are described and discussed. Tests were conducted on thirteen prismatic columns; eleven columns (two unconfined and nine confined) were tested under concentric load while an eccentric load was applied on two confined columns. For each confinement system, the parameters investigated were the 'confinement ratio', the 'load eccentricity' and the 'overlap configuration of the fiber fabrics'. FRCM confinement improved the structural response of masonry columns in terms of ultimate strength, ultimate strain and ductility. Some models from the literature were also examined to evaluate their applicability in predicting the axial capacity of confined columns. [ABSTRACT FROM AUTHOR]

Published
2020
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37. Effect of eccentricity on retrofitting efficiency of basalt textile reinforced concrete on partially damaged masonry columns.

Author

Wang, Jiyang, Wan, Chenglin, Zeng, Qiang, Shen, Linghua, Malik, Muhammad Akbar, and Yan, Dongming

Subjects
*MASONRY, *REINFORCED concrete, *ECCENTRIC loads, *BASALT, *STRESS-strain curves
Abstract

Retrofitting of damaged and/or ancient masonry structures is of significant importance to increase their structural safety. In this study, a retrofitting technique of basalt-textile-reinforced concrete (BTRC) was used to repair partially damaged rectangle masonry columns, and the repairing efficiency was assessed by different parameters. Compression tests with different eccentricities were conducted to explore the mechanical behaviors of initial and BTRC retrofitted masonry columns. The data in terms of crack patterns, load-displacement curves, peak load, ductility and longitudinal strains were analyzed and discussed in depth. Results show that BTRC retrofits can substantially improve the load carrying capacity and ductility of the partially damaged masonry columns under different eccentric loads that display different damage characteristics. The uniaxial constitutive (NTR-PP, NTR-PB and Sargin) models of masonry predict a relatively safe bearing capacity of BTRC-confined columns under eccentric loadings. This BTRC retrofitting technique with the features of cheap, easy-to-construct, long durability and environmental friendliness shows promising potentials in engineering applications. The findings of this study provide an effective way for repairing ancient and/or damaged masonry structures with BTRC. [ABSTRACT FROM AUTHOR]

Published
2020
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38. Masonry columns behaviour analyses due to different mode of confinement with GFRP straps

Author

Galić, Josip, Vukić, Hrvoje, Kalafatić, Ivan, and Lourenco, P.B., Haseltine, B.A., Vasconcelos, G.

Subjects
Tests, masonry columns, strengthening, glass fiber reinforced polymer straps, GFRP, results
Abstract

The paper describes experimental research of masonry columns’ behavior under the load of vertical compression. A total of thirty-four specimens were tested: three unconfined specimens and thirty-one specimens confined with GFRP straps. In addition to the load- bearing efficiency analysis of confined columns in relation to the number of the confinement layers, the intention of these tests was to determine the efficiency of spiral confinement in relation to the conventional confinement. Also studied was the impact of the existing compressive stress in a column during confinement to the final increased load-bearing capacity of the confined column. The test results have shown that all of the confined specimens have a greater load-bearing capacity and ductility than the unconfined specimens. The results of spiral confinement were almost identical to the results of conventional confinement, which is vital considering that spiral confinement is easier to perform. The results of the test lead to the conclusion that the presence of compressive stress in a column during confinement does not significantly reduce the efficiency of confinement. This enables the possibility of effectively increasing the bearing capacity of masonry columns without the need to previously unload the structure, while the structure is in service. The paper also gives expressions for the estimated increase of the compressive strength of confined columns that correspond well with the testing results.

Published
2014

39. Experimental and Numerical Analyses of Masonry Columns Confined with GFRP Straps

Author

Galić, Josip, Kišiček, Tomislav, Kalafatić, Ivan, Whysall, Claire J., and Taylor, Su E.

Subjects
masonry columns, strengthening, glass fiber straps, fiber reinforced polymers (FRP), MASA, microplane model, rehabilitation
Abstract

The paper describes an experimental analysis of masonry columns confined with GFRP straps that were tested under vertical compressive load. The main goal of these experiments was to determine the efficiency of the load bearing capacity of confined columns in relation to the number of confinement layers and the efficiency of spiral in relation to the conventional confinement (fabric is wrapped horizontally around masonry columns). Vertical compression test was made on 3 unconfined and 23 confined specimens. The test results showed that all the confined specimens have a greater load bearing capacity and ductility than the unconfined specimens. The spiral confinement was considerably easier to apply and it would be more acceptable in practical use. These experiments were analyzed using software called MASA. Three-dimensional nonlinear structural FEM analysis was made using microplane model to describe quasi-brittle material. The FEM results showed good compliance with the test results and confirmed that the reason for specimen failure wasn’t the failure of confinement, but a local damage of column specimens.

Published
2013

40. Micromorphic continua: Application to the homogenization of diatomic masonry columns

Author

Jean Sulem, Ioannis Stefanou, Matériaux et Structures Architecturés (msa), Laboratoire Navier (navier umr 8205), Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-École des Ponts ParisTech (ENPC)-Centre National de la Recherche Scientifique (CNRS)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-École des Ponts ParisTech (ENPC)-Centre National de la Recherche Scientifique (CNRS), and Géotechnique (cermes)

Subjects
Micromorphic continuum, Materials science, Computer Networks and Communications, Computational Mechanics, 02 engineering and technology, Kinematics, 01 natural sciences, Homogenization (chemistry), 0203 mechanical engineering, 11. Sustainability, Masonry columns, 0101 mathematics, Homogenization, Wave propagation, Continuum mechanics, Continuum (measurement), business.industry, Linear elasticity, Masonry, Discrete element method, 010101 applied mathematics, Mechanical system, [SPI.GCIV]Engineering Sciences [physics]/Civil Engineering, 020303 mechanical engineering & transports, Classical mechanics, Control and Systems Engineering, business
Abstract

International audience; In the frame of continuum mechanics, the theory of general micromorphic continua is a key element for modeling mechanical systems of discrete building blocks such as masonry structures. This stems from the fact that the kinematics of the particle, in the terminology of Germain (Germain, P., The Method of Virtual Power in Continuum Mechanics, Part 2: Microstructure. SIAM J. Appl. Math., vol. 25, pp. 556-575, 1973), is quite rich to cover the various degrees of freedom of the discrete microstructure. In the present paper, we derive a third-order micromorphic continuum for modeling diatomic masonry columns. Our analysis is extended to the dynamic regime. For linear elastic interfaces, the derived continuum is compared with the discrete model in terms of the dispersion curves. It is shown that the continuum approximates well the discrete structure for wavelengths five to ten times bigger than the size of the elementary cell. Therefore, the presented model may be the base for future engineering applications in the field of cultural heritage assets, because it might be an alternative approach in the mechanical modeling of ancient colonnades, whose study is mostly performed with the discrete element method. As it is well known, continuum models are quite flexible, computationally cheaper, and may give insight to the fundamental properties of the systems at hand.

Published
2012
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42. Stability of Columns with no Tension Strength and Bounded Compressive Strength and Deformability - Part I: large eccentricity

Author

Anna De Falco and Massimiliano Lucchesi

Subjects
Work (thermodynamics), Materials science, business.industry, Tension (physics), Differential equation, Masonry columns, No-tension material, Stability, Applied Mathematics, Mechanical Engineering, media_common.quotation_subject, Traction (engineering), Structural engineering, Condensed Matter Physics, Cross section (physics), Compressive strength, Mechanics of Materials, Modeling and Simulation, General Materials Science, Eccentricity (behavior), Pile, business, media_common
Abstract

This work concerns the stability of piles with rectangular cross section, made of a no-tension material with limited compressive strength and deformability, subjected to an axial load acting within the cross section but outside its middle third (large eccentricity). The differential equations obtained have been solved explicitly, and their solutions have allowed us to describe the stability characteristics of the pile through graphical representations.

Published
2002

43. Experimental investigation on compressive performance of masonry columns confined with textile-reinforced concrete

Author

<p>Future Scientists Program of China University of Mining and Technology Postgraduate Research & Practice Inovation Program of Jiangsu Province China Scholarship Council University of Western Australia</p>, Jing, Lei, Yin, Shiping, Aslani, Farhad, <p>Future Scientists Program of China University of Mining and Technology Postgraduate Research & Practice Inovation Program of Jiangsu Province China Scholarship Council University of Western Australia</p>, Jing, Lei, Yin, Shiping, and Aslani, Farhad

Abstract

Jing, L., Yin, S., & Aslani, F. (2021). Experimental investigation on compressive performance of masonry columns confined with textile-reinforced concrete. Construction and Building Materials, 269, Article 121270. https://doi.org/10.1016/j.conbuildmat.2020.121270

46. BFRP grid confined clay brick masonry cylinders under axial compression: Experimental results

Author

D Anna, J., giuseppina amato, Chen, J. -F, La Mendola, L., Minafò, G., and Jennifer D’Anna, Giuseppina Amato,Jian-Fei Chen, Lidia La Mendola, Giovanni Minafò

Subjects
Settore ICAR/09 - Tecnica Delle Costruzioni, Masonry columns, cylinders, Basalt fibre reinforced polymers, Basalt fibre reinforced polymer, Masonry column, BFRP, Strengthening and Repair
Abstract

The use of composite materials for retrofitting of masonry structures has received great attention during the last two decades. For masonry buildings there are several advantages in using composite materials. Traditional techniques that were largely used and investigated in the past, may be inadequate in seismic areas where the added mass could increase seismic actions. Moreover, for historical and architectural heritage structures, the compatibility, sustainability and reversibility of the intervention is a key factor for the selection of the most appropriate strengthening system. Many investigations have shown that fibre reinforced polymers (FRP) can be effectively used to induce a passive confinement action on masonry columns and improve the axial capacity and ductility of the structural members. This paper presents the results of an experimental study on the compressive behaviour of clay brick masonry cylinders reinforced with basalt fibre reinforced polymer (BFRP) grids. The main aim of this study is to assess the effectiveness of the BFRP wraps on the strength and ductility of masonry columns. Twelve clay brick masonry cylinders, cored from masonry walls and columns, were reinforced using either one or two layers of BFRP grids. Two different arrangements were used for producing the cylinders in order to investigate the effect of vertical joints on the response of masonry cylinders. The basalt grid had a cell size of 6x6 mm. After a preliminary experimental study aimed at characterizing the mechanical properties of bricks, mortar and basalt grid, the cylinders were tested under uniaxial compression loading. The test results showed a strength increase between 30% and 38% for cylinders wrapped with one layer and between 69% and 71% for those wrapped with two layers of BFRP grids.

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