Mechanical properties and debonding strength of Fabric Reinforced Cementitious Matrix (FRCM) systems for masonry strengthening

Carozzi, Francesca Giulia; Poggi, Carlo

doi:10.1016/j.compositesb.2014.10.056

Cited by 266 publications

(180 citation statements)

References 30 publications

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“…The embedded region interaction is defined in Abaqus to remove the intersection volume of the fibers with the matrix from the matrix volume, and create the interaction between them with the bonding strength values. These values are calculated based on the fibers and matrix properties according to the failure criteria discussed in the mechanics of composites book (Tamuzs, 2015) and by Carozzi (2015). The coupling are fixed at the effective area around the bolts holes on the friction sides of the coupling and the load is defined as a pressure on the keyway face as shown in figure 6.…”

Section: Rigid Power Transmission Coupling Finite Element Analysis Modelmentioning

confidence: 99%

“…The bonding interfacial strength is defined as an interaction limiting value between the fibers and matrix. The interfacial bonding strength is calculated according to the procedure found in the mechanics of composites book (Tamuzs, 2015) and the deboning strength of fabrics with cementations matrix research conducted by Carozzi (2015).…”

Section: Random Discontinuous 3d Fibers Distribution Algorithmmentioning

confidence: 99%

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Application of Short Fibers Reinforced Composites in Power Transmission Coupling

Hamza

Shash

Abd-Rabou

2017

Lat. Am. j. solids struct.

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In this study the use of short glass, carbon and hybrid glass-carbon fibers reinforced polymeric composites in power transmission coupling is investigated. The presented work is generalized to thermoplastic and thermoset polymeric matrix composites. The effects of the constituents weight percentages, and average fibers length on the composite tensile strength and modulus are studied using the Taguchi design of experiments method. A new approach of Finite Element analysis is introduced to model the effect of the hybrid fibers random distribution and average fibers length among the volume of the matrix. Each fiber is simulated independently in the model as a three dimensional truss element embedded in the matrix. The FEA model is applied on the tensile specimen and then on the power transmission coupling simulation. Finally, the new approach of finite element analysis results on the coupling are validated.

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Section: Rigid Power Transmission Coupling Finite Element Analysis Modelmentioning

confidence: 99%

Section: Random Discontinuous 3d Fibers Distribution Algorithmmentioning

confidence: 99%

Application of Short Fibers Reinforced Composites in Power Transmission Coupling

Hamza

Shash

Abd-Rabou

2017

Lat. Am. j. solids struct.

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“…The utilization of inorganic matrices, based on hydraulic and cement mortars, is thus a desirable device to avoid the use of epoxy or organic resins (Prota et al 2006, Papanicolaou et al 2008, Borri at al. 2014, Gattesco et al 2015, Carozzi and Poggi 2015.…”

Section: Introductionmentioning

confidence: 99%

The Reticulatus method for shear strengthening of fair-faced masonry

Corradi

Borri

Castori

et al. 2016

Bull Earthquake Eng

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This paper presents the results of several experimental campaigns recently carried out by the authors and devoted to the investigation of the mechanical performance of wall panels strengthened by applying repointing mortar and high strength stainless steel or composite cords. The reinforcement system, known as Reticulatus, allows the reinforcement of regular and irregular-shape masonry walls, when the fair-faced aspect must be kept. In the perspective of using this reinforcement method, this article summarizes the research that has been done so far, presenting new original test results and discussing the design procedures. Twenty-two square wall panels were loaded in their plane by means of a single point load acting through the panel's diagonal. Experimental results are presented for four types of cord 2 reinforcement using matched samples, reinforced and not. Increases in shear strength from 15 to 170% were achieved for the strengthened panels. Each wall panel was loaded well into the lateral post-elastic regime and then unloaded.Experimental results were in good agreement with predictions from simple models which assume the wall panels to behave like a plate, neglecting the contribution of the repointing mortar, and accounting for the non-linear behavior of the masonry.

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“…We assume a tensile strength σ b equal to 376.13 MPa, which corresponds to an average value of the bond strengths of the FRP and FRCM reinforcements of masonry structures analyzed in [7,8], respectively (we employed formula (5.6) of [21] to estimate such a strength). Fig.…”

Section: Cloister Vaultmentioning

confidence: 99%

“…Nowadays, it is a common practice to reinforce such structures by applying tensile reinforcements made of traditional materials, such as steel, or innovative high-strength materials [4,5,6]. Strips and/or meshes of materials like Fiber Reinforced Polymers (FRP) or Fabric Reinforced Cementitious Matrix (FRCM) composites are often bonded to masonry structures to improve their mechanical properties [7,8,9]. However, it is worth remarking that such strengthening techniques, when improperly used, may lead to an excessive over-strength of the reinforced structure, and reduced 'cracking-adaptation' capacity [10].…”

Section: Introductionmentioning

confidence: 99%

Minimal Mass Design of Strengthening Techniques for Planar and Curved Masonry Structures

Carpentieri¹,

Fabbrocino²,

Piano³

et al. 2016

Proceedings of the VII European Congress on Computational Methods in Applied Sciences and Engineering (ECCOMAS Congress 2016)

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Abstract. We present a discrete element model of a masonry structure strengthened through the application of reinforcing elements designed to work in tension. We describe the reinforced masonry structure as a tensegrity network of masonry rods, mainly working in compression, and tension elements corresponding to fiber-reinforced composite reinforcements, which are assumed to behave as elastic-perfectly-plastic members. We optimize a background structure connecting each node of the discrete model of the structure with all the neighbors lying inside a sphere of prescribed radius, in order to determine a minimal mass resisting structure under the given loading conditions and prescribed yielding constraints. Fiber-reinforced composite reinforcements can be naturally replaced by any other reinforcements that are strong in tension (e.g., timber or steel beams/ties). Some numerical examples illustrate the potential of the proposed strategy in designing tensile reinforcements of a three-dimensional structure composed of a masonry vault and supporting walls.

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Mechanical properties and debonding strength of Fabric Reinforced Cementitious Matrix (FRCM) systems for masonry strengthening

Cited by 266 publications

References 30 publications

Application of Short Fibers Reinforced Composites in Power Transmission Coupling

Application of Short Fibers Reinforced Composites in Power Transmission Coupling

The Reticulatus method for shear strengthening of fair-faced masonry

Minimal Mass Design of Strengthening Techniques for Planar and Curved Masonry Structures

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