29 research outputs found
Macro-mechanical modelling and simulation of textile fabric and clothing with S-FEM
Tese de Doutoramento Programa Doutoral em Engenharia TêxtilEsta tese propõe um método de elementos finitos, designado por S-FEM (Smoothed Finite Element
Method), para modelação e análise mecânica de estruturas têxteis planas. Neste enquadramento
teórico, supõe-se que a estrutura têxtil não-tecida é um material isotrópico elástico, enquanto a
estrutura têxtil tecida é um material elástico com anisotropia ortotrópica, para os quais as leis
constitutivas utilizam propriedades mecânicas de baixa pressão (low stress) com base na Medição
Objetiva de Tecidos (FOM - Fabric Objective Measurement).
As formulações de elementos finitos de baixa ordem baseadas em deslocamento quando aplicadas a
elementos finitos de placas (plate/shell) quadriláteras de 4 nós, incluindo campos de tensão de
cisalhamento transversal, baseiam-se nas contribuições de Raymond Mindlin e por Eric Reissner, no
que agora se designa teoria de deformação por cisalhamento de primeira ordem (first-order shear
deformation, do inglês, ou FSDT de forma abreviada), ou simplesmente teoria de Mindlin-Reissner, e
nas abordagens MITC (Mixed Interpolation of Tensorial Components), são nesta tese combinadas com
a técnica de suavização do/da gradiente/tensão nos termos dos modelos S-FEM por forma a mitigar
problemas como são o caso da distorção de elementos finitos, da granularidade grosseira da malha,
bem como dos bem conhecidos fenómenos de bloqueio. As malhas de quadriláteros são utilizadas
nesta tese devido à sua capacidade de representar geometrias complexas de tecidos em resultado de
deformações mecânicas como são os casos da recuperação face à pressão planar, flexão,
deformação, vibração, drapejamento, etc.
Refira-se que foi desenvolvido e implementado em Matlab um software para os novos modelos de
elementos finitos, em grande medida devido à inexistência de modelos S-FEM em softwares de análise
de elementos finitos (finite element analysis ou FEA), lacuna esta que ocorre quer em softwares
comerciais, quer não comerciais, e até em códigos abertos. Exemplos numéricos para as aplicações
básicas de engenharia no que respeita à modelação mecânica de folhas de tecido fino e de folhas de
tecido de espessura média em estudos de casos típicos, como é o caso da recuperação face a pressão
planar, flexão, deformação e comportamento livre de vibrações, indicam que os elementos finitos
(plate/shell) desenvolvidos com a técnica de suavização de tensão e MITC acabam por aliviar os
efeitos de distorção dos elementos, a granularidade grosseira da malha e efeito de bloqueio na
modelação e análise mecânica de tecidos muito finos e até mesmo de tecidos de espessura média. Os modelos de elementos finitos de placas (plate/shell) desenvolvidos durante o trajeto desta tese,
bem como as suas propriedades mecânicas de baixa tensão em termos de FOM, são, portanto, bem
adaptados à modelação e análise numérica de deformação macro-mecânica de folhas de tecido muito
fino e de folhas de tecido de espessura média, incluindo ao mesmo tempo análise de deformação
mecânica simples e complexa.An S-FEM (Smoothed Finite Element Method) for mechanical analysis and modelling of the textile
fabrics is proposed. In this theoretical framework, one assumes that the non-woven fabric is an elastic
isotropic material, while the woven fabric is an elastic with orthotropic anisotropy for which the
constitutive laws formulated are using low-stress mechanical properties based on FOM (Fabric
Objective Measurement). The displacement-based low-order finite element formulations for four-node
quadrilateral plate/shell finite element, including assumed transverse shear strain fields, are based
on the contributions of Raymond Mindlin and by Eric Reissner as FSDT (first-order shear deformation
theory and so-called the Mindlin-Reissner theory) together with MITC (Mixed Interpolation of Tensorial
Components) approaches, which are combined with the gradient/strain smoothing technique in terms
of S-FEM models contributed by G. R. Liu et al. in order to mitigate problems as element distortion,
mesh coarseness as well as the well-known locking phenomena. Quadrilateral meshes are used due
to ability to represent complicated geometries of complex mechanical deformation of the fabric such
as plane stress recovery, bending, buckling, vibration, draping behavior, etc. The finite element
computer codes were developed in MATLAB for the new formulated plate/shell finite element models
due to the lack of FEM (Finite Element Method) packages for S-FEM models in both commercial and
non-commercial FEA (Finite Element Analysis) computer applications, and even from open-source
platforms. Numerical examples for the basic engineering applications of mechanical modelling of thin
to moderately thick fabric sheet in the typical case studies such as in-plane stress recovery, bending,
buckling and free-vibration behavior, indicate that the developed plate/shell finite elements with
assumed strain smoothing technique and MITC, do alleviate element distortion, mesh coarseness,
and locking effect even for mechanical analysis and modelling very thin to moderately thick fabric. The
developed plate/shell finite element models and low-stress mechanic properties in terms of FOM are,
therefore, well adapted for numerical analysis and modelling of macro-mechanical deformation of the
thin to moderately thick fabric sheet including both simple and complex mechanical deformation
analysis.EMECW L12 MOBILITY GRANT AWARD CONTRACT BTG_559
Grant agreement n 2009/1661-001 001EC
Modelling the bending behaviour of plain-woven fabric using flat shell element and strain smoothing technique
This paper describes a new approach to improve on modelling the bending behaviour of plain-woven fabric. The four-node flat shell element is developed by incorporating a strain smoothing technique, six degrees of freedom at each node. The material laws for in-plane and out-of-plane behaviors are expressed in terms of orthotropic elastic material. The physical and mechanical parameters of fabric samples are measured using Kawabata Evaluating System for Fabric (KES-F). An improved numerical model with a strain smoothing operation for modelling the bending behaviour of plain-woven fabric is then carried out. The bending behavior of a rectangular plain-woven fabric sheet with clamped edges is simulated.Fundação para a Ciência e a Tecnologia (FCT
A node-based strain smoothing technique for free vibration analysis of textile-like sheet materials
This paper presents an implementation of the node-based smoothed finite element method
and Reissner-Mindlin plate theory for a four node isoparametric shell element to improve the
numerical precision and computational efficiency subjected to free vibration analysis of textile-like
sheet materials. A one smoothing cell integration scheme in the strain smoothing technique is
implemented to contrast the shear locking phenomenon that may exists in the analysis for moderatelythick and thick shell models. Various numerical results of free vibration analysis for a multi-layer
nonwoven fabric sample are compared with other existing analytical solutions and numerical
solutions in literatures to demonstrate the effectiveness of the present method. An advantage of the
present formulation is that it can improve the numerical precision without decreasing the
computational efficiency.The first and fourth author acknowledge FCT for the conceded financial support through Project
UID/CTM/00264/2019 of 2C2T – Centro de Ciência e Tecnologia Têxtil, hold by National Founds
of FCT/MCTES. The second and third author acknowledge support by FCT/MCTES through national
funds and when applicable co-funded EU funds under the project SFRH/BD/136554/2018
Eigenvalue analysis for plain-woven fabric structure using shell element and one smoothing cell in the smoothed finite element method
An efficient four-node quadrilateral (Q4) shell element based on the first-order shear
deformation theory of plate (FSDT) and the strain smoothing technique in finite elements
(referred as SFEM) was proposed for eigenvalue analysis of plain-woven fabric structure. A one
smoothing domain (or cell) integration scheme in SFEM was proposed to evaluate the nodal train
fields of Q4 shell elements. The numerical result of eigenvalue analysis, which was in the case
of free vibration analysis, approximated to that one implemented in the finite element method
(FEM) but gave a higher efficiency in computation in terms of central processing unit (CPU)
time and numerical implementation.The authors wish to express their acknowledgment to FCT funding from FCT – Foundation for Science and Technology within the scope of the project “PEST UID/CTM/00264; POCI-01-0145-FEDER 007136
Buckling analysis of plain-woven fabric structure using shell element and a one cell-based integration scheme in smoothed finite element method
A one smoothing cell integration scheme in the strain smoothing technique in finite
elements (referred as SFEM) was proposed to evaluate the nodal train fields of a four-node
quadrilateral (Q4) shell element, which is based on the first-order shear deformation theory of
plate (FSDT). A mixed interpolation of tensorial components (MITC) approaches for Q4
transverse shear strains also applied to eliminate a shear locking phenomenon that may occur
when the thin plate/shell elements are geometrically distorted in curved geometries of fabric
sheet. The numerical eigenvalues of buckling analysis of a plain-woven fabric sample, of which
physical and mechanical parameters extracted from Kawabata evaluation system for fabrics
(KES-FB), obtained a higher efficiency in numerical computation and approximated to Q4 shell
element implemented in the finite element method (FEM).The authors wish to express their acknowledgment to FCT funding from FCT – Foundation for Science and Technology within the scope of the project “PEST UID/CTM/00264; POCI-01-0145-FEDER 007136”
A Novel Self-organizing Fuzzy Cerebellar Model Articulation Controller Based Overlapping Gaussian Membership Function for Controlling Robotic System
This paper introduces an effective intelligent controller for robotic systems with uncertainties. The proposed method is a novel self-organizing fuzzy cerebellar model articulation controller (NSOFC) which is a combination of a cerebellar model articulation controller (CMAC) and sliding mode control (SMC). We also present a new Gaussian membership function (GMF) that is designed by the combination of the prior and current GMF for each layer of CMAC. In addition, the relevant data of the prior GMF is used to check tracking errors more accurately. The inputs of the proposed controller can be mixed simultaneously between the prior and current states according to the corresponding errors. Moreover, the controller uses a self-organizing approach which can increase or decrease the number of layers, therefore the structures of NSOFC can be adjusted automatically. The proposed method consists of a NSOFC controller and a compensation controller. The NSOFC controller is used to estimate the ideal controller, and the compensation controller is used to eliminate the approximated error. The online parameters tuning law of NSOFC is designed based on Lyapunov’s theory to ensure stability of the system. Finally, the experimental results of a 2 DOF robot arm are used to demonstrate the efficiency of the proposed controller
Load Shedding in Microgrid System with Combination of AHP Algorithm and Hybrid ANN-ACO Algorithm
This paper proposes a new load shedding method based on the application of intelligent algorithms, the process of calculating and load shedding is carried out in two stages. Stage-1 uses a backpropagation neural network to classify faults in the system, thereby determining whether or not to shed the load in that particular case. Stage-2 uses an artificial neural network combined with an ant colony algorithm (ANN-ACO) to determine a load shedding strategy. The AHP algorithm is applied to propose load shedding strategies based on ranking the importance of loads in the system. The proposed method in the article helps to solve the integrated problem of load shedding, classifying the fault to determine whether or not to shedding the load and proposing a correct strategy for shedding the load. The IEEE 25-bus 8-generator power system is used to simulate and test the effectiveness of the proposed method, the results show that the frequency of recovery is good in the allowable range
Identification of apple fruit-skin constitutive laws by full-field methods using uniaxial tensile loading
The protective and preservative role of apple skin in maintaining the integrity of the fruit is
well-known, with its mechanical behaviour playing a pivotal role in determining fruit storage capacity.
This study employs a combination of experimental and numerical methodologies, specifically utilising
the digital image correlation (DIC) technique. A specially devised inverse strategy is applied to
evaluate the mechanical behaviour of apple skin under uniaxial tensile loading. Three apple cultivars
were tested in this work: Malus domestica Starking Delicious, Malus pumila Rennet, and Malus
domestica Golden Delicious. Stress–strain curves were reconstructed, revealing distinct variations
in the mechanical responses among these cultivars. Yeoh’s hyperelastic model was fitted to the
experimental data to identify the coefficients capable of reproducing the non-linear deformation.
The results suggest that apple skin varies significantly in composition and structure among the
tested cultivars, as evidenced by differences in elastic properties and non-linear behaviour. These
differences can significantly affect how fruit is handled, stored, and transported. Thus, the insights
resulting from this research enable the development of mathematical models based on the mechanical
behaviour of apple tissue, constituting important data for improvements in the economics of the
agri-food industry.The authors acknowledge the Portuguese Foundation for Science and Technology (FCT—MCTES) for the conceded financial support through the reference grant EXPL/EMEAPL/0587/2021. The second author also acknowledges FCT for his grant ref. BI/UTAD/22/2022.
The third author also acknowledges FCT for its financial support via the projects UIDB/00667/2020
and UIDP/00667/2020 (UNIDEMI)
Developing a comprehensive quality control framework for roadway bridge management: a case study approach using key performance indicators
Transportation infrastructures, especially roadway bridges, play a pivotal role in socioeconomic development. Recently, bridge engineers are increasingly facing the challenge in terms of shifting their strategy from building new facilities to maintaining the existing aging infrastructures, to preserve their service performance during the operational stage. In fact, the infrastructure administrators lack a quality control (QC) strategy for the existing roadway bridges, which leads to the decision-making application and tool being still minor. To overcome those
challenging issues, this paper proposes a quality control framework for roadway bridge management using key performance indicators (KPIs). The case study methodology is suggested to be used and then conducted for several bridges, mostly in European countries. In which the performance indicators (PIs) and goals (PGs) are defined, after assessing the bridges and vulnerable zones, the derivation KPIs from those PIs are introduced and developed considering time functions and different maintenance scenarios. Eventually, a two-stage quality control framework will be proposed in which the static stage includes preparatory works, inspection responsibilities, and a quick assessment of KPIs; while the dynamic stage helps the decision maker in estimating the time remaining of the bridge service life, managing the evolution of KPIs as well as planning the best possible maintenance strategy. The selected two case studies are present and curated, which show
the excellent potential to develop a long-term strategy for roadway bridge management on a lifecycle level.This research was funded by FCT/MCTES through national funds (PIDDAC) from the
R&D Unit Institute for Sustainability and Innovation in Structural Engineering (ISISE), under the
reference UIDB/04029/2020, and from the Associate Laboratory Advanced Production and
Intelligent Systems ARISE, under the reference LA/P/0112/2020, as well as financial support of the
project re-search “B2022-GHA-03” from the Ministry of Education and Training. And The APC was
funded by ANI (“Agência Nacional de Inovação”) through the financial support given to the R&D
Project “GOA Bridge Management System—Bridge Intelligence”, with reference PO-CI-01-0247-
FEDER-069642, which was cofinanced by the European Regional Development Fund (FEDER)
through the Operational Competitiveness and Internationalisation Program (POCI).Minh Q. Tran acknowledges the support by the doctoral grant reference
PRT/BD/154268/2022, financed by Portuguese Foundation for Science and Technology (FCT), under
the MIT Portugal Program (2022 MPP2030-FCT)
Finite element model updating for composite plate structures using particle swarm optimization algorithm
In the Architecture, Engineering, and Construction (AEC) industry, particularly civil
engineering, the Finite Element Method (FEM) is a widely applied method for computational
designs. In this regard, computational simulation has increasingly become challenging due to
uncertain parameters, significantly affecting structural analysis and evaluation results, especially
for composite and complex structures. Therefore, determining the exact computational parameters
is crucial since the structures involve many components with different material properties, even
removing some additional components affects the calculation results. This study presents a solution
to increase the accuracy of the finite element (FE) model using a swarm intelligence-based approach
called the particle swarm optimization (PSO) algorithm. The FE model is created based on the
structure’s easily observable characteristics, in which uncertainty parameters are assumed
empirically and will be updated via PSO using dynamic experimental results. The results show that
the finite element model achieves high accuracy, significantly improved after updating (shown by
the evaluation parameters presented in the article). In this way, a precise and reliable model can be
applied to reliability analysis and structural design optimization tasks. During this research project,
the FE model considering the PSO algorithm was integrated into an actual bridge’s structural health
monitoring (SHM) system, which was the premise for creating the initial digital twin model for the
advanced digital twinning technologyThis work was partly financed by FCT/MCTES through national funds (PIDDAC) under the R&D Unit Institute for Sustainability and Innovation in Structural Engineering (ISISE), under reference UIDB/04029/2020, and under the Associate Laboratory Advanced Production and Intelligent Systems ARISE under reference LA/P/0112/2020. The authors also acknowledge ANI (“Agência Nacional de Inovação”) for the financial support given to the R&D Project “GOA Bridge Management System—Bridge Intelligence”, with reference POCI-01-0247-FEDER-069642,
cofinanced by the European Regional Development Fund (FEDER) through the Operational Competitiveness and Internationalization Program (POCI).Minh Q. Tran was supported by the doctoral grant reference PRT/BD/154268/2022 financed by the Portuguese Foundation for Science and Technology (FCT), under the MIT Portugal Program (2022 MPP2030-FCT). Minh Q. Tran acknowledges Huan X. Nguyen (Faculty of Science and Technology, Middlesex University, London NW4 4BT, UK) and Thuc V. Ngo (Mien Tay Construction University, Institute of Science and International Cooperation, 85100 Vĩnh Long, Vietnam) for their support as cosupervisors as well as specific suggestions in terms of the “conceptualization” and “methodology” of this paper. Helder S. Sousa acknowledges the funding by FCT through the Scientific Employment Stimulus—4th Editio