Access the full text.
Sign up today, get DeepDyve free for 14 days.
L. Salmén (2004)
Plant biology and pathology / Biologie et pathologie végétales Micromechanical understanding of the cell-wall structure ✩
D. Ribeiro, R. Calçada, R. Delgado, Maik Brehm, V. Zabel (2012)
Finite element model updating of a bowstring-arch railway bridge based on experimental modal parametersEngineering Structures, 40
K. Hofstetter, C. Hellmich, J. Eberhardsteiner (2005)
Development and experimental validation of a continuum micromechanics model for the elasticity of woodEuropean Journal of Mechanics A-solids, 24
E. Flores, F. DiazDelaO, M. Friswell, R. Ajaj (2014)
Investigation on the extensibility of the wood cell-wall composite by an approach based on homogenisation and uncertainty analysisComposite Structures, 108
Simon Aicher, Gerhard Dill-Langer (2001)
BASIC CONSIDERATIONS TO ROLLING SHEAR MODULUS IN WOODEN BOARDS ELEMENTARE BETRACHTUNGEN ZUM THEMA ROLLSCHUB- MODUL IN HOLZBRETTERN ÉLÉMENTS DE BASE SUR LE MODULE DE CISAILLEMENT DE PLANCHES EN BOIS
S. Z̆ivanović, A. Pavic, P. Reynolds (2006)
Modal testing and FE model tuning of a lively footbridge structureEngineering Structures, 28
Maderas, Ciencia y Tecnología, 9
E. Saraçoğlu, S. Bergstrand (2015)
Continuous monitoring of a long-span cable-stayed timber bridgeJournal of Civil Structural Health Monitoring, 5
S. Haldar, N. Gheewala, K. Grande-Allen, M. Sutton, Hugh Bruck (2011)
Multi-scale Mechanical Characterization of Palmetto Wood using Digital Image Correlation to Develop a Template for Biologically-Inspired Polymer CompositesExperimental Mechanics, 51
Otto-Graf-Journal, 11
K. Nimmen, G. Lombaert, G. Roeck, P. Broeck (2014)
Vibration serviceability of footbridges: Evaluation of the current codes of practiceEngineering Structures, 59
J. Bujňák, R. Hlinka, J. Odrobiňák, J. Vičan (2012)
Diagnostics and Evaluation of FootbridgesProcedia Engineering, 40
S. Fortino, Alessandra Genoese, A. Genoese, L. Nunes, Pedro Palma (2013)
Numerical modelling of the hygro-thermal response of timber bridges during their service life: A monitoring case-studyConstruction and Building Materials, 47
Ho-Kyung Kim, Nam-Sik Kim, J. Jang, Young-Ho Kim (2012)
Analysis Model Verification of a Suspension Bridge Exploiting Configuration Survey and Field-Measured DataJournal of Bridge Engineering, 17
U. Watanabe, M. Norimoto, T. Morooka (2000)
Cell wall thickness and tangential Young's modulus in coniferous early woodJournal of Wood Science, 46
Weihua Hu, C. Moutinho, E. Caetano, F. Magalhães, Á. Cunha (2012)
Continuous dynamic monitoring of a lively footbridge for serviceability assessment and damage detectionMechanical Systems and Signal Processing, 33
Holzforschung, 52
D. Heiss-Czedik (1997)
An Introduction to Genetic Algorithms.Artificial Life, 3
T. Timell (1982)
Recent progress in the chemistry and topochemistry of compression woodWood Science and Technology, 16
O. Bilgen, M. Friswell (2012)
Implementation of a Continuous-Inextensible-Surface Piezocomposite AirfoilJournal of Aircraft, 50
B. Peeters, H. Auweraer, F. Vanhollebeke, P. Guillaume (2007)
Operational modal analysis for estimating the dynamic properties of a stadium structure during a football gameShock and Vibration, 14
S. Andersson (2007)
A study of the nanostructure of the cell wall of the tracheids of conifer xylem by x-ray scattering
Y. Chandra, R. Chowdhury, F. Scarpa, S. Adhikari, J. Sienz, Cris Arnold, T. Murmu, D. Bould (2012)
Vibration frequency of graphene based composites: A multiscale approachMaterials Science and Engineering B-advanced Functional Solid-state Materials, 177
B. Moaveni, I. Behmanesh (2012)
Effects of changing ambient temperature on finite element model updating of the Dowling Hall FootbridgeEngineering Structures, 43
S. Andersson, H. Wikberg, E. Pesonen, S. Maunu, R. Serimaa (2004)
Studies of crystallinity of Scots pine and Norway spruce celluloseTrees, 18
D. Frangopol, A. Strauss, Sunyong Kim (2008)
Bridge Reliability Assessment Based on MonitoringJournal of Bridge Engineering, 13
D. Inman, B. Grisso (2007)
Adaptive Structures for Structural Health Monitoring
A. Altunışık, A. Bayraktar, B. Sevim, H. Ozdemir (2011)
Experimental and analytical system identification of Eynel arch type steel highway bridgeJournal of Constructional Steel Research, 67
L. Donaldson, A. Singh (1998)
Bridge-Like Structures Between Cellulose Microfibrils in Radiata Pine (Pinus radiata D. Don) Kraft Pulp and Holocellulose, 52
R. Das, Rhys Jones (2015)
Characteristics of the design surface of damage tolerance parameters and their relation to shape optimisationInternational Journal of Fatigue, 70
G. Kaliyaperumal, B. Imam, T. Righiniotis (2011)
Advanced dynamic finite element analysis of a skew steel railway bridgeEngineering Structures, 33
Youming Chen, R. Das, M. Battley (2015)
Effects of cell size and cell wall thickness variations on the stiffness of closed-cell foamsInternational Journal of Solids and Structures, 52
Comptes Rendus Biologies, 327
D. Inman, B. Grisso (2007)
1 Adaptive Structures for Structural Health Monitoring
Qinyi Zhou, M. Gong, Y. Chui, M. Mohammad (2014)
Measurement of rolling shear modulus and strength of cross laminated timber fabricated with black spruceConstruction and Building Materials, 64
F. Magalhães, E. Caetano, Á. Cunha, O. Flamand, G. Grillaud (2012)
Ambient and free vibration tests of the Millau Viaduct: Evaluation of alternative processing strategiesEngineering Structures, 45
S. Z̆ivanović, A. Pavic, P. Reynolds (2007)
Finite element modelling and updating of a lively footbridge: The complete processJournal of Sound and Vibration, 301
A. Cury, C. Cremona, J. Dumoulin (2012)
Long-term monitoring of a PSC box girder bridge : operational modal analysis, data normalization and structural modification assessment.Mechanical Systems and Signal Processing, 33
D. Kammer (1990)
Sensor Placement for On-Orbit Modal Identification and Correlation of Large Space Structures1990 American Control Conference
D. Goldberg (1988)
Genetic Algorithms in Search Optimization and Machine Learning
J. Bodig, B. Jayne (1982)
Mechanics of Wood and Wood Composites
E. Caetano, Á. Cunha, C. Moutinho, F. Magalhães (2010)
Studies for controlling human-induced vibration of the Pedro e Inês footbridge, Portugal. Part 2: Implementation of tuned mass dampersEngineering Structures, 32
(2010)
Structural health monitoring of timber bridges
E. Caetano, Á. Cunha, F. Magalhães, C. Moutinho (2010)
Studies for controlling human-induced vibration of the Pedro e Ines footbridge, Portugal. Part 1: Assessment of dynamic behaviourEngineering Structures, 32
Y. Chandra, F. Scarpa, R. Chowdhury, S. Adhikari, J. Sienz (2013)
Multiscale hybrid atomistic-FE approach for the nonlinear tensile behaviour of graphene nanocompositesComposites Part A-applied Science and Manufacturing, 46
S. Stiros, F. Moschas (2014)
Rapid Decay of a Timber Footbridge and Changes in Its Modal Frequencies Derived from Multiannual Lateral Deflection MeasurementsJournal of Bridge Engineering, 19
Giuseppe Chellini, G. Roeck, Kai Liu, L. Nardini, B. Peeters, E. Reynders, W. Salvatore (2008)
Experimental dynamic analysis of the Sesia viaduct, a composite high-speed railway bridge
E. Flores, E. Neto (2010)
Remarks on symmetry conditions in computational homogenisation problemsEngineering Computations, 27
D. Goldberg, W. Shakespeare (2002)
Genetic Algorithms
Wei Chen, G. Lickfield, Charles Yang (2004)
Molecular modeling of cellulose in amorphous state. Part I: model building and plastic deformation studyPolymer, 45
S. Ivorra, D. Foti, D. Bru, F. Baeza (2015)
Dynamic Behavior of a Pedestrian Bridge in Alicante, SpainJournal of Performance of Constructed Facilities, 29
J. Brownjohn, P. Moyo, P. Omenzetter, Yong Lu (2003)
Assessment of highway bridge upgrading by dynamic testing and finite element model updatingJournal of Bridge Engineering, 8
E. Flores, I. Dayyani, R. Ajaj, R. Castro-Triguero, F. DiazDelaO, R. Das, P. Soto (2015)
Analysis of cross-laminated timber by computational homogenisation and experimental validationComposite Structures, 121
D. Inman (2005)
Damage Prognosis For Aerospace, Civil and Mechanical Systems Preface
H. Sixta (2006)
Handbook of Pulp
S. Z̆ivanović, A. Pavic, P. Reynolds (2005)
Vibration serviceability of footbridges under human-induced excitation : a literature reviewJournal of Sound and Vibration, 279
Salvo Linette, R. Ananías, Alain Cloutier (2004)
Influencia de la estructura anatómica en la permeabilidad especifica transversal al gas del Pino radiataMaderas-ciencia Y Tecnologia, 6
R. Castro-Triguero, E. Flores, F. DiazDelaO, M. Friswell, R. Gallego (2014)
Optimal sensor placement in timber structures by means of a multi‐scale approach with material uncertaintyStructural Control and Health Monitoring, 21
J. Valenzuela, Iván Ulloa, M. Rallo (2003)
ESTUDIO DEL ANGULO FIBRILAR Y SU RELACION CON LA EDAD CAMBIAL EN Pinus radiata D.DON, PROVENIENTE DE LA SEPTIMA REGION, CHILEMaderas-ciencia Y Tecnologia, 5
J. Pina, V. Kouznetsova, M. Geers (2015)
Thermo-mechanical analyses of heterogeneous materials with a strongly anisotropic phase: the case of cast ironInternational Journal of Solids and Structures, 63
U. Watanabe, M. Norimoto (2000)
Three dimensional analysis of elastic constants of the wood cell wall.Wood Research, 87
(2011)
Pasarela peatonal Montoro – Documento final de verificacion normativa. Z047
G. Munoz, J. González (2007)
CARACTERÍSTICAS FÍSICAS DE LA MADERA DE PINO PROCEDENTE DE RALEOS EN EL NOROESTE DE ESPAÑA PHYSICAL PROPERTIES OF WOOD FROM THINNED PINES IN NORTHWEST SPAIN
F. Moschas, S. Stiros (2014)
Three‐dimensional dynamic deflections and natural frequencies of a stiff footbridge based on measurements of collocated sensorsStructural Control and Health Monitoring, 21
C. Gentile, N. Gallino (2008)
Ambient vibration testing and structural evaluation of an historic suspension footbridgeAdv. Eng. Softw., 39
(1989)
Structural glued laminated timber - Design essentials
A. Bayraktar, Ahmet Altunişik, B. Sevim, T. Türker (2010)
Ambient Vibration Tests of a Steel FootbridgeJournal of Nondestructive Evaluation, 29
Dong-sheng Li, Hongnan Li (2006)
The state of the art of sensor placement methods in structural health monitoring, 6174
H. Qing, L. Mishnaevsky (2009)
Moisture-related mechanical properties of softwood: 3D micromechanical modelingComputational Materials Science, 46
E. Flores, F. DiazDelaO, R. Ajaj, M. Friswell, G. Fernando (2014)
Mathematical modelling of the stochastic mechanical properties of wood and its extensibility at small scalesApplied Mathematical Modelling, 38
S. Tang (1998)
Modeling the mechanical properties of Pinus Radiata
PurposeThe purpose of this paper is to capture the actual structural behavior of the longest timber footbridge in Spain by means of a multi-scale model updating approach in conjunction with ambient vibration tests.Design/methodology/approachIn a first stage, a numerical pre-test analysis of the full bridge is performed, using standard beam-type finite elements with isotropic material properties. This approach offers a first structural model in which optimal sensor placement (OSP) methodologies are applied to improve the system identification process. In particular, the effective independence (EFI) method is used to determine the optimal locations of a set of sensors. Ambient vibration tests are conducted to determine experimentally the modal characteristics of the structure. The identified modal parameters are compared with those values obtained from this preliminary model. To improve the accuracy of the numerical predictions, the material response is modeled by means of a homogenization-based multi-scale computational approach. In a second stage, the structure is modeled by means of three-dimensional solid elements with the above material definition, capturing realistically the full orthotropic mechanical properties of wood. A genetic algorithm (GA) technique is adopted to calibrate the micromechanical parameters which are either not well-known or susceptible to considerable variations when measured experimentally.FindingsAn overall good agreement is found between the results of the updated numerical simulations and the corresponding experimental measurements. The longitudinal and transverse Young's moduli, sliding and rolling shear moduli, density and natural frequencies are computed by the present approach. The obtained results reveal the potential predictive capabilities of the present GA/multi-scale/experimental approach to capture accurately the actual behavior of complex materials and structures.Originality/valueThe uniqueness and importance of this structure leads to an intensive study of its structural behavior. Ambient vibration tests are carried out under environmental excitation. Extraction of modal parameters is obtained from output-only experimental data. The EFI methodology is applied for the OSP on a large-scale structure. Information coming from several length scales, from sub-micrometer dimensions to macroscopic scales, is included in the material definition. The strong differences found between the stiffness along the longitudinal and transverse directions of wood lumbers are incorporated in the structural model. A multi-scale model updating approach is carried out by means of a GA technique to calibrate the micromechanical parameters which are either not well-known or susceptible to considerable variations when measured experimentally.
Engineering Computations: International Journal for Computer-Aided Engineering and Software – Emerald Publishing
Published: May 2, 2017
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.