Your search keyword '"Daniel Trias"' showing total 20 results

1. Analysis of Stress Intensity Factor of a Fibre Embedded in a Matrix

Author

Mostafa Barzegar, Josep Costa, Daniel Trias, Jose M. Guerrero, Claudio Lopes, and Carlos Gonzalez

Subjects

Ceramics and Composites, stress intensity factor, finite element method, fibre-reinforced polymer, micromechanics modelling, linear elastic fracture mechanic, Engineering (miscellaneous)

Abstract

The analytical or numerical determination of the stress intensity factor (SIF) in cracked bodies usually assumes the body to be isolated. However, in fibre-reinforced composites, the fibre, which is the main load-carrying component, is embedded in a matrix. To clarify the effect the embedding matrix has on the SIF of the fibre, we propose a 3D computational model of an orthotropic fibre embedded in an isotropic matrix, and compute the SIF using the J-integral method. A parametric analysis based on dimensionless variables explores the effect of the fibre–matrix stiffness ratio as well as the effect of the degree of elastic orthotropy of the fibre. The results show that the SIF is strongly influenced by both factors, and that the matrix reduces the SIF by limiting the crack opening.

Published

2023

2. Specimen geometry and specimen size dependence of the $${\mathcal {R}}$$ R -curve and the size effect law from a cohesive model point of view

Author

Emilio Vicente González, AMADE AMADE, Daniel Trias, Adrián Ortega Novillo, and Pere Maimí

Subjects

Analytic model, Computational Mechanics, Order (ring theory), Geometry, 02 engineering and technology, 021001 nanoscience & nanotechnology, Displacement (vector), 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, Modeling and Simulation, Law, Point (geometry), Fracture process, 0210 nano-technology, Linear elastic fracture mechanics, Size dependence, Compact tension specimen, Mathematics

Abstract

An analytic model has been developed for a Compact Tension specimen subjected to a controlled displacement and corresponding load within a cohesive model framework. The model is able to capture the material response while the Fracture Process Zone is being developed, obtaining the evolution of multiple variables such as the crack opening and the cohesive stresses, for an arbitrary Cohesive Law shape. The crack growth prediction based on the $${\mathcal {R}}$$ -curve and the nominal strength prediction based on Bažant’s Size Effect Law have been implemented using the output variables available from the proposed analytic model. The minimum specimen size has been found in order to properly apply $${\mathcal {R}}$$ -curve based methods. The study has concluded that only the cohesive model is able to properly capture the changes of the Specimen Geometry and Specimen Size, as unlike in other theories, no Linear Elastic Fracture Mechanics assumptions are made.

Published

2017

3. Enseñanza de la autorregulación en Matemáticas: estudio cuasiexperimental con escolares de bajo desempeño

Author

Daniel Trias Seferian, Cindy Mels Auman, Juan Antonio Huertas Martínez, and UAM. Departamento de Psicología Básica

Subjects

Intervention fidelity, learning, mathematics, education, 05 social sciences, Control (management), 050301 education, Metacognition, emotion, Cognition, Psicología, Education, motivation, Intervention (counseling), Quasi experimental study, Mathematics education, 0501 psychology and cognitive sciences, Mathematical problem solving, lcsh:L, 0503 education, metacognition, lcsh:Education, 050104 developmental & child psychology, Differential impact

Abstract

Teaching students to self-regulate enhances their mathematics performance, yet few studies have investigated the long-term differential impact of particular self-regulation strategies specifically for low-achieving students. This quasi-experimental study evaluates the effect of teaching different self-regulation strategies on mathematical problem solving in low-achieving students. The participants were 69 sixth-grade elementary school students randomly assigned to one of three experimental groups (and taught predominantly cognitive, metacognitive or volitional strategies, while verifying intervention fidelity) or a control group for 16 sessions. Mathematical problem-solving skills were evaluated prior to the intervention, upon completion, and two months later. While all three intervention groups obtained significantly better results compared to the control group immediately after the intervention, volitional and metacognitive strategies showed the strongest and most lasting positive effects. We conclude that low-achieving students could benefit from learning self-regulation strategies, particularly when these strategies take into account the affective and motivational dynamics of learning. Keywords: mathematics, metacognition, motivation, emotion, learning

Published

2019

4. Characterization of the translaminar fracture Cohesive Law

Author

Emilio Vicente González, AMADE AMADE, Daniel Trias, Adrián Ortega Novillo, Pere Maimí, and Ministerio de Economía y Competitividad (Espanya)

Subjects

Work (thermodynamics), Materials science, Assaigs de materials, Analytic model, Materials -- Testing, 02 engineering and technology, 021001 nanoscience & nanotechnology, Characterization (materials science), Laminated materials -- Fracture, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, Law, Materials laminats -- Fractura, Ceramics and Composites, Fracture (geology), Point (geometry), Composite material, 0210 nano-technology, Compact tension specimen, Softening, Inverse method

Abstract

Quasi-brittle materials such as fibre-reinforced composite materials develop a relatively large Fracture Process Zone where material toughening mechanisms such as matrix cracking, fibre-bridging and fibre pull-outs take place. The damage onset and damage propagation are well defined from a cohesive model point of view, although no standard procedure has been yet developed to characterize the translaminar Cohesive Law. The present work proposes an objective inverse method for obtaining the Cohesive Law with the use of an analytic model capable of predicting the load–displacement curve of a Compact Tension specimen for any arbitrary Cohesive Law shape. The softening law has been obtained for two laminates, providing an excellent agreement with the experimental results. With the obtained softening function, the nominal strengths of a Center Cracked Specimen and an Open Hole specimen have been predicted for a wide range of specimen sizes This work has been partially funded by the Spanish Government through the Ministerio de Economía y Competitividad, under contracts MAT2013-46749-R (subprogram MAT) and MAT2012-37552-C03-03

Published

2016

5. Hygrothermal effects on the translaminar fracture toughness of cross-ply carbon/epoxy laminates: Failure mechanisms

Author

Emilio Vicente González, Lorena Marín, Pedro Camanho, AMADE AMADE, Daniel Trias, Pere Maimí, and Ministerio de Economía y Competitividad (Espanya)

Subjects

Microscòpia electrònica d'escombratge, chemistry.chemical_classification, Materials science, Scanning electron microscope, Assaigs de materials, General Engineering, chemistry.chemical_element, Materials -- Testing, Fractography, Fracture mechanics, Polymer, Epoxy, Environmental degradation, Laminated materials -- Fracture, Fracture toughness, chemistry, Medi ambient -- Degradació, visual_art, Materials laminats -- Fractura, Ultimate tensile strength, Ceramics and Composites, visual_art.visual_art_medium, Composite material, Scanning electron microscopy, Carbon

Abstract

The present work addresses the damage mechanisms of polymer-based laminated composite materials under different hygrothermal conditions by means of the translaminar fracture toughness using Double Edge Notched Tensile tests of a cross-ply laminate manufactured with T800S/M21 carbon/epoxy material.Three different conditions were considered: as received-room temperature (AR/RT), wet-room temperature (WET/RT), and wet-high temperature (WET/HOT). The highest fracture toughness was for WET/HOT and the lowest for WET/RT. To observe the corresponding failure mechanisms, Scanning Electronic Microscopy (SEM) analysis was performed. The SEM inspections show that the pull-out length and the frictional coefficient are the most significant parameters that best explain the differences observed in the crack propagation and the fracture toughness. For AR/RT, the suitable adhesion between components allows stresses to be transferred from the matrix to the fibers, so the crack is practically continuous in the same failure plane and the pull-out is barely visible. However, higher pull-out lengths can be observed in WET/RT and WET/HOT, especially in the second one. For WET/RT, the crack surface shows fiber bundles at different pull-out lengths, while for WET/HOT fibers are broken individually at longer pull-out lengths. According to the moisture absorption in WET/RT and WET/HOT, a lower frictional coefficient is thought to slightly reduce the fracture toughness, which can be compared between AR/RT and WET/RT. Nevertheless, the highest fracture toughness is caused by the large pull-out lengths in WET/HOT tests, despite the reduction of the frictional coefficient The authors acknowledge the financial support of the Spanish Government under project MAT2013-46749-R. The first author would like to thank the Spanish Government for the FPI predoctoral grant BES-2010-042387 and for the mobility grant EEBBI-13-06186

Published

2016

6. Accelerated Life Testing

Author

Laurent Denis, David Delaux, Henri Grzeskowiak, and Daniel Trias

Subjects

Exploit, Computer science, media_common.quotation_subject, Rare events, Production (economics), Sample (statistics), Product (category theory), Function (engineering), Reliability (statistics), Accelerated life testing, Reliability engineering, media_common

Abstract

In the case of very reliable materials, failures are rare events, and it is often difficult to find a sample of the product that includes instances of failure merely by analyzing feedback from experience (or performing dedicated reliability tests) in order to estimate the reliability parameters. Success often varies wildly as a function of the size of this sample. Thus, the need to understand the behavior of a long-life product before it is commissioned frequently leads to so-called accelerated life testing during the development, qualification or even production phases. This chapter presents the methodology of accelerated life testing, as well as the methods and tools used to exploit accelerated life tests, and gives a selection of examples.

Published

2017

7. The Reliability of Components: A New Generation of Film Capacitors

Author

David Delaux, Daniel Trias, and Henri Grzeskowiak

Subjects

Reliability (semiconductor), Film capacitor, Hardware_GENERAL, Computer science, Electronic engineering, Mechatronics, Filter capacitor, GeneralLiterature_MISCELLANEOUS

Abstract

The reliability of high-power mechatronic systems fundamentally depends on the reliability of film capacitors.

Published

2017

8. Estimated Reliability Prediction

Author

Daniel Trias, Henri Grezoskowiak, David Delaux, and Rémy Fouchereau

Subjects

Engineering, Operations research, business.industry, Failure rate, Product (category theory), business, Reliability (statistics), Reliability engineering

Abstract

The purpose of this chapter is to provide the reader with an overview of the methods and modeling used in reliability prediction, that is to say, in terms of pre-project reliability. How can we quantify a failure rate for a product that is not yet on the market?

Published

2017

9. Methodology and Physicochemical Characterization Techniques Used for Failure Analysis in Laboratories

Author

Sébastien Boileau, Daniel Trias, and Morgane Presle

Subjects

Computer science, business.industry, visual_art, Component (UML), Electronic component, visual_art.visual_art_medium, Process engineering, business, Characterization (materials science)

Abstract

The failure of an electronic component may be described in terms of the deterioration of its electrical characteristics and is caused by modifications in the physical and chemical properties of its constituents and/or the emergence of defects. This chapter begins by discussing an experimental approach that allows these modifications to be analyzed throughout the life of a component. A description of the physicochemical techniques commonly used in laboratories is then given.

Published

2017

10. Maximization of the fundamental frequency of plates and cylinders

Author

Daniel Trias, Norbert Blanco, Pere Maimí, AMADE AMADE, and Ministerio de Economía y Competitividad (Espanya)

Subjects

Engineering, Work (thermodynamics), Modal analysis, Optimització matemàtica, Stacking, 02 engineering and technology, Mathematical analysis, Cylinder (engine), law.invention, 0203 mechanical engineering, law, Anàlisi matemàtica, Civil and Structural Engineering, Sequence, business.industry, Mathematical optimization, Maximization, Structural engineering, Fundamental frequency, 021001 nanoscience & nanotechnology, Làmines (Enginyeria), Lamination (geology), 020303 mechanical engineering & transports, Ceramics and Composites, Shells (Engineering), 0210 nano-technology, business

Abstract

This work deals with the maximization of the fundamental frequency of laminated plates and cylinders by finding the optimal stacking sequence for symmetric and balanced laminates with neglectable bending–twisting and torsion–curvature couplings are considered. Instead of using the angle at each ply the so-called lamination parameters are used as design variables. Results for the plate problem are compared to those using analytical expressions found in the literature. The cylinder problem is solved for a large number of thickness and radius-to-length ratio combinations. Values of the optimal stacking sequence are given considering the angle can take any value between 0° and 90° or the case when the angle can only take a discrete set of values The authors acknowledge funding from the Spanish government through the Ministerio de Economía y Competitividad under contract MAT2013-46749-R

Published

2016

11. Nominal strength of quasi-brittle open hole specimens

Author

Emilio Vicente González, Jordi Renart, AMADE AMADE, Daniel Trias, and Pere Maimí

Subjects

Materials science, Brittleness, Design charts, Isotropy, General Engineering, Ceramics and Composites, Composite material, Open hole, B fracture

Abstract

The relation between the nominal strength of open hole specimens manufactured with quasi-brittle isotropic materials with respect to the specimen size and the shape of the cohesive law is examined in the present paper. The obtained results can be used by engineers as design charts or to obtain valuable information on the failure characteristics of quasi-brittle materials.

Published

2012

12. Numerical and experimental analysis of stresses and failure in T-bolt joints

Author

Alfredo Guemes, Víctor Martínez-Moll, Norbert Blanco, AMADE AMADE, and Daniel Trias

Subjects

Engineering, Bearing (mechanical), business.industry, Tension (physics), Stress–strain curve, Glass fiber, Epoxy, Structural engineering, Finite element method, law.invention, law, visual_art, Ceramics and Composites, visual_art.visual_art_medium, Cylinder, business, Joint (geology), Civil and Structural Engineering

Abstract

T-bolt joints are widely used in the wind turbine industry. This paper describes the constitution and function of the different components of the joint, showing the different parameters that affect its performance, and presents a parametric analysis, useful for joint design and optimization, relating laminate thickness, bolt and cylinder diameters to pitch distance, and pretension of the bolt with external load. In order to provide information on the influence of the T-bolt geometry on the strength of the laminate in the net tension and bearing zones, tests for two different glass fiber – epoxy laminates, under different pitch/diameter ratios have been performed, forcing either bearing or tension failure modes. Stress and strain concentrations in the laminate have been estimated trough a three-dimensional finite element model that takes into account pretension effects and contact nonlinearities. How experimental results correlate with simple and finite element model analysis is discussed. Stress Point Criteria may be applied for joint tension failure with a characteristic distance of d 0 = 0.9 mm.

Published

2011

13. Crack propagation in quasi-brittle two-dimensional isotropic lattices

Author

Daniel Trias, Pere Maimí, AMADE AMADE, and Albert Turon

Subjects

Materials science, business.industry, Mechanical Engineering, Isotropy, Fracture mechanics, Mechanics, Structural engineering, Stress field, Stress (mechanics), Cohesive zone model, Fracture toughness, Brittleness, Mechanics of Materials, Fracture (geology), General Materials Science, business

Abstract

Materials with cellular structure are gaining prominence in recent years due to improvements in production processes, that enable the manufacture of new materials, and biomechanics, that requires mechanical analysis of cellular structures such as bones. The possibility to use the Fracture Mechanics tools developed for the continua to the fracture of cellular materials is analyzed in the present paper. As proposed by Maiti et al. the fracture toughness of cellular solids can be obtained through two procedures: taking into account the stress at crack tip or the fracture toughness of the base material. Both procedures are analyzed and the equivalent R-curve and a cohesive law is obtained in function of the cell size and structure morphology. A critical truss length exists from which crack propagation goes from being governed by the energy dissipated to being governed by the stress field.

Published

2011

14. Flexural behaviour of GFRP–concrete hybrid beams with interconnection slip

Author

Fernando Branco, Daniel Trias, João Gomes Ferreira, Given Names Deactivated Family Name Deactivated, and João Ramôa Correia

Subjects

Materials science, business.industry, Stiffness, Slip (materials science), Structural engineering, Fibre-reinforced plastic, Flexural strength, Pultrusion, Ceramics and Composites, medicine, Direct shear test, medicine.symptom, Composite material, Material properties, business, Beam (structure), Civil and Structural Engineering

Abstract

The design of glass fibre reinforced polymer (GFRP) pultruded beams is usually governed by deformability or instability phenomena. To obtain a better use of the material properties, the GFRP profiles can be connected to concrete elements with several advantages, associated with the global stiffness and strength of the structural elements. This leads to solutions particularly useful for rehabilitation of old floors or even new construction slabs. This paper presents the results of an experimental research developed to characterize the flexural behaviour of a GFRP–concrete hybrid solution. Shear connection tests were first performed on GFRP I-profiles, connected to concrete with stainless steel bolts, to evaluate the behaviour of the shear connection. The results of those tests were then used to design simply supported GFRP–concrete hybrid beams that were tested under bending conditions. The flexural behaviour of the GFRP–concrete hybrid beams is discussed, with particular relevance to the effect of the interconnection slip. The overall behaviour of the hybrid beams is compared with that corresponding to a simple GFRP I-profile beam, demonstrating the structural advantages of this new hybrid constructive solution.

Published

2007

15. Analysis of the mixed-mode end load split delamination test

Author

Josep Costa Balanzat, Norbert Blanco, Kristofer Gamstedt, AMADE AMADE, and Daniel Trias

Subjects

Engineering, business.industry, Delamination, Fracture mechanics, Structural engineering, Bending, Composite laminates, Finite element method, Crack closure, Mode coupling, Ceramics and Composites, Fracture (geology), business, Civil and Structural Engineering

Abstract

Composite delaminations are commonly characterized using the double cantilever beam test for mode I, the end-notched flexure test or the end load split test for mode II and the mixed-mode bending test for mixed-mode. For all these tests, the mode mix remains constant and does not vary with the crack length. However, in the mixed-mode end load split test (MMELS), the delamination propagates under a varying mode mix that depends on the crack extension, which is a more realistic scenario. The MMELS test has been previously analysed by different researchers but the resulting expressions are not equivalent. A more accurate alternative analysis of the test, based on the finite element method and the virtual crack closure technique, is used in the present work for comparison. The results are compared to the predictions of approaches presented in the literature and significant findings are found for materials characterization using the MMELS test.

Published

2006

16. A progressive damage model for unidirectional fibre-reinforced composites based on fibre fragmentation. Part II: Stiffness reduction in environment sensitive fibres under fatigue

Author

Josep Costa Balanzat, Norbert Blanco, AMADE AMADE, Albert Turon, Daniel Trias, and Joan Andreu Mayugo

Subjects

Cyclic stress, Materials science, Effective stress, Constitutive equation, General Engineering, Stiffness, Fracture mechanics, Fatigue limit, Ceramics and Composites, medicine, Composite material, medicine.symptom, Stress corrosion cracking, Rule of mixtures

Abstract

The mechanical behaviour of glass–fibre composites under fatigue or under long term stress is strongly influenced by the stress corrosion cracking of the fibres. In this paper, a stress corrosion model for composite materials reinforced with environment sensitive fibres has been developed and incorporated into a progressive damage model. The model is based on the definition of an effective stress, σ *( t ), which depends on the stress story, that permits the initial failure probability, given by a Weibull distribution, to be used at any later time. This methodology has been incorporated to a thermodynamically consistent constitutive model valid for early fragmentation stages. The model may be used to account for the fibre’s behaviour in numerical models based on the rule of mixtures. The ability of the extended progressive damage model to reproduce the stiffness loss of the composite under static or cyclic fatigue loads is demonstrated.

Published

2005

17. A progressive damage model for unidirectional fibre-reinforced composites based on fibre fragmentation. Part I: Formulation

Author

Josep Costa Balanzat, AMADE AMADE, Albert Turon, Daniel Trias, Joan Andreu Mayugo, and Pere Maimí

Subjects

Materials science, Continuum mechanics, Glass fiber, Constitutive equation, General Engineering, Stiffness, Fracture mechanics, Breakage, Ceramics and Composites, medicine, medicine.symptom, Composite material, Rule of mixtures, Weibull distribution

Abstract

Constitutive damage models for fibre-reinforced composite materials should take into account the occurrence of the different damage mechanisms, their interaction and their influence on the resulting mechanical properties. Fibre breakage has usually been considered in damage models by means of deterministic failure criteria which thus leads to non-progressive behaviour or to a complete material collapse which is not realistic. This work presents a progressive damage model for fibre-reinforced composites based on the fragmentation analysis of the fibres. The stiffness loss of a unidirectional composite comes from the parameters of the Weibull distribution of the fibre strength and the mechanical properties of the fibre, matrix and the interface. The model has been developed for the initial stages of damage. The model is formulated in the framework of the mechanics of the continuous media. The constitutive model can be employed to simulate the contribution of fibres in damage models based on the rule of mixtures.

Published

2005

18. Optimization of composite stiffened panels under mechanical and hygrothermal loads using neural networks and genetic algorithms

Author

AMADE AMADE, Paloma Massó, Guillermo Rus, Daniel Trias, Joan Andreu Mayugo, Pere Badalló Cañellas, and Ministerio de Ciencia e Innovación (Espanya)

Subjects

Anàlisi numèrica, Work (thermodynamics), Engineering, Finite element method, Optimization problem, Artificial neural network, business.industry, Numerical analysis, Optimització matemàtica, Mathematical optimization, Elements finits, Mètode dels, Structural engineering, Static analysis, Genetic algorithms, Multi-objective optimization, Neural networks (Computer science), Algorismes genètics, Genetic algorithm, Ceramics and Composites, Xarxes neuronals (Informàtica), business, Civil and Structural Engineering

Abstract

The present work develops an optimization procedure for a geometric design of a composite material stiffened panel with conventional stacking sequence using static analysis and hygrothermal effects. The procedure is based on a global approach strategy, composed by two steps: first, the response of the panel is obtained by a neural network system using the results of finite element analyses and, in a second step, a multi-objective optimization problem is solved using a genetic algorithm. The neural network implemented in the first step uses a sub-problem approach which allows to consider different temperature ranges. The compression load and relative humidity of the air are assumed to be constants throughout the considered temperature range.The mass, the hygrothermal expansion and the stresses between the skin and the stiffeners are defined as the optimality criteria. The presented optimization procedure is shown to yield the optimal structure design without compromising the computational efficiency The authors acknowledge the financial support of the Spanish Government under the Project DPI2009-08048

Published

2012

19. Damage tolerance optimization of composite stringer run-out under tensile load

Author

Daniel Trias, Esben Lindgaard, AMADE AMADE, Pere Badalló Cañellas, and Ministerio de Economía y Competitividad (Espanya)

Subjects

Radial Basis Function, Engineering, Optimization problem, Metamodeling, Radial basis functions, Mecànica de fractura, Stringer, Genetic algorithm, medicine, Fracture mechanics, Algoritmes genètics, Civil and Structural Engineering, Parametric statistics, Strain energy release rate, Genetic Algorithm, Materials compostos, business.industry, Stiffness, Structural engineering, Composite materials, Genetic algorithms, Finite element method, Ceramics and Composites, Stiffened panels, medicine.symptom, business, Damage tolerance

Abstract

Stringer run-outs are a common solution to achieve the necessary strength, stiffness and geometric requirements of some structural solutions. The mechanical behavior and complexity of such design details requires careful and thorough studies to ensure the structural integrity of the structure. The influence of some geometric variables of the run-out in the interface of the set stringer-panel is crucial to avoid the onset and growth of delamination cracks. In this study, a damage tolerant design of a stringer run-out is achieved by a process of design optimization and surrogate modeling techniques. A parametric finite element model created with python was used to generate a number of different geometrical designs of the stringer run-out. The relevant information of these models was adjusted using Radial Basis Functions (RBF). Finally, the optimization problem was solved using Quasi-Newton method and Genetic Algorithms. In the solution process, the RBF were used to compute the objective function: ratio between the energy release rate and the critical energy release rate according to the Benzeggagh–Kenane mixed mode criterion. Some design guidelines to obtain a damage tolerant stringer-panel interface have been derived from the results The authors wish to acknowledge the Ministerio de Economía y Competitividad for the funding of the project MAT2013-46749-R and particularly to Universitat de Girona for the research Grant coded as BR2011/02

20. Ultrasonics inspections and confocal microscopy to evaluate fatigue damage in fiber reinforced polymer composites

Author

García, V. G., Sala, J., Crispí, L., Cabrera, J. M., Istúriz, A., Sàez, A., Millán, M., Comes, C., and Daniel Trias