Papers
Info
Extensão do molhe norte do Porto de Leixões: modelação física de um navio amarrado no posto A
O Porto de Leixões, localizado na costa norte de Portugal, é um dos maiores do país, recebendo diariamentevários navios de grandes dimensões. Um dos principais postos de acostagem situa-se à entrada do porto e encontra-se sujeito à agitação marítima que é difratada pelo olhe principal de proteção do porto. Para avaliar dos movimentos induzidos no navio estacionado nesse posto de acostagem e as forças exercidas nas suas amarras e defensas pela agitação incidente, utilizou-se o modelo físico de Leixões, construído num dos tanques do LNEC. Neste modelo físico, encontra-se representada a envolvente do porto de Leixões, assim como a sua batimetria. O modelo do navio
Year: 2020
Number Pages:
17-28pp.
Author(s): Pinheiro, L.; Pedro, F.; Abdelwahab, H.S.; Fortes, C. J. E. M.; Santos, J. A.; Capitão, R.
: Revista Recursos Hidricos
Editor: APRH
Volume:
Volume 41, Nº 1.
Keywords: Motions measurement; Constitutive relations; Moored ship; Scale model
Info
Numerical analysis of an onshore oscillating water column wave energy converter for different wall slopes
An alternative to the energy matrix expansion, due to the increase of global electricity demand, is the renewable sea wave energy source, which has high energy potential. The Oscillating Water Column (OWC) converter is one of the most studied, although it is not yet used at commercial scale. Therefore, searching the optimal geometric configuration is fundamental to turn this device viable. This study proposes a numerical analysis of an onshore OWC for different slopes of chamber walls (from 40o to 90o) and equipped with a Wells turbine. Simulations of incompressible 2D flows are performed by means of the FLUENT® software, which is based on Reynolds-averaged Navier-Stokes (RANS) equations. The k-
Year: 2020
Number Pages:
10-22pp.
Author(s): Güths, A.K.; Teixeira, P. R. F.; Didier, E.
: Revista Interdisciplinar de Pesquisa em Engenharia
Editor: RIPE
Volume:
Volume 6 No. 2.
Keywords: Numerical simulation; Renewable energy; Wave energy; Oscillating water column
Info
Numerical analysis of the influence of air compressibility effects on an oscillating water column wave energy converter chamber
The most studied device used for extracting wave energy is the Oscillating Water Column (OWC). In general, numerical simulations of these cases by means of models based on Reynolds Averaged Navier-Stokes equations adopt the Volume of Fluid method to deal with the free surface flow which is considered incompressible in both water and air. The aim of this study is to investigate the influence of the compressibility effect on the air inside the OWC chamber by the FLUENT® numerical model. A methodology is implemented, taking into account both water and air flows incompressible, but, at every instant, a pressure condition is imposed on the top boundary of the chamber to consider the compressibility effect. This pressure condition is based on an analytical equation that considers the isentropic transformation of the air and effects of Wells and impulse turbines. Results of compressible and incompressible numerical models are compared. The amplification factor, the root mean square of air pressure inside the chamber and OWC efficiency in relation to incident wave period, wave height and turbine characteristic relation are analyzed. Results show that air compressibility effects can diminish the predicted OWC efficiency up to about 20% in both Wells and impulse turbines.
Year: 2020
Number Pages:
1183-1193pp.
Author(s): Gonçalves, R.; Teixeira, P.; Didier, E.; Torres, F.
Editor: Elsevier
Volume:
Volume 153.
Keywords: Air compressibility; Volume of fluid; Numerical simulation; Oscillating water column device; Wave energy
Info
Numerical analysis of the performance of two onshore oscillating water column wave energy converters at different chamber wall slopes
In this study, a numerical analysis of the performance of two Oscillating Water Column (OWC) wave energy converters, at different front and back wall slopes, was carried out. The first device had vertical front and back walls and the second one had its wall slopes of 40° in relation to the horizontal plane. The FLUENT® numerical model, which is based on the Reynolds-Averaged Navier-Stokes (RANS) equations, was used. The Volume of Fluid (VoF) method was employed to take into account free surface flows. The case study comprised a 10 m deep flume with an onshore OWC at its end, equipped with a Wells turbine. A 2D hydrodynamic mathematical model was employed and a 3D air pressure effect inside the OWC air-chamber was considered. Analyses of the hydrodynamics behavior, fluid-structure interaction outside (run-up/down, reflected waves) and inside the chamber (free surface elevation, sloshing) and energy distribution (pneumatic extracted energy, reflected wave energy and energy losses) were conducted. Results showed that the device with inclined walls had the best efficiency in comparison with the other one. However, the latter showed lower variation in efficiency in the wave period range than the former.
Year: 2020
Number Pages:
14p.
Author(s): Gaspar, L. A.; Teixeira, P.; Didier, E.
: Revista Ocean Engineering
Editor: Elsevier
Volume:
Volume 201.
Keywords: Volume of fluid; Finite volume method; Numerical simulation; Oscillating water column device; Wave energy
Info
Numerical analysis of the response of an onshore oscillating water column wave energy converter to random waves
The main objective of this study is to investigate differences of random incident waves from regular ones in performance of wave energy converters (WEC). A numerical analysis of an onshore oscillating water column (OWC) WEC is carried out by means of the FLUENT® software, which is based on Reynolds - Averaged Navier-Stokes equations. Analyses of the efficiency of an onshore OWC device with similar characteristics of the Pico
Year: 2020
Number Pages:
12p.
Author(s): Teixeira, P. R. F.; Didier, E.
: Revista Energy
Editor: Elsevier
Volume:
Volume 220.
Keywords: Irregular/Random waves; RANS-VoF; Wells turbine; Oscillating water column; Wave energy
Info
O papel da engenharia na proteção do território e das suas gentes
Atualmente, mais importante que assegurar a resistência de um aglomerado urbano a um eventual invasor, importa garantir a sobrevivência a catástrofes naturais das infraestruturas críticas que garantem a salubridade das condições de vida nesse aglomerado, a mobilidade dos habitantes e o abastecimento de bens essenciais. Em rigor, face ao carater aleatório destas solicitações, pretende-se que, uma vez terminadas essas solicitações extremas, eventuais estragos causados pelas mesmas não impeçam o restabelecimento, em tempo útil, das atividades normais da população. Nesta comunicação apresentam-se ferramentas e procedimentos para avaliação do risco associado a infraestruturas críticas com um viés para o controlo de cheias urbanas e de infraestruturas de transporte marítimo.
Year: 2020
Number Pages:
201-221pp.
Author(s): Santos, J. A.; Pinheiro, L.; Fortes, C. J. E. M.
: Madeira Região Resiliente. Aprender com o Passado. Série Estudos Cindínicos
Editor: RISCOS - Associação Portuguesa de Riscos, Prevenção e Segurança
Volume:
Volume 9 (2020).
Keywords: Avaliação do risco; Resiliência; Infraestruturas críticas
Info
Sines breakwater harbour: the OSOM+ monitoring program
The current program of Systematic Observation of Maritime Works (OSOM+), under development at the National Laboratory for Civil Engineering (LNEC), is essentially applied to rubble mound breakwaters. The OSOM
Year: 2020
Number Pages:
49-57pp.
Author(s): Fortes, C. J. E. M.; Capitão, R.; Lemos, R.; Neves, M. G.; Silva, L. G.; Henriques, M. J.; Martins, T.
: Italian Journal of Engineering Geology and Environment
Editor: Sapienza Università Editrice
Volume:
1 (2020).
Keywords: Drone; Visual observations; Maintenance; Monitoring; Rubble mound breakwaters
Info
The HIDRALERTA system: Application to the ports of Madalena do Pico and S. Roque do Pico, Azores
HIDRALERTA is a forecast and early warning system for coastal and port regions capable of predicting emergency situations, as well as carrying out risk assessment. The system concentrates on evaluating wave overtopping and flooding scenarios. It uses offshore sea-wave and wind forecast data, as well as tide data, as input to determine wave overtopping at specific locations. The calculation of the mean overtopping discharge over a structure is made through artificial neural network (ANN) tools and/or empirical formulae, which are able to define the spatial distribution of the flow behind the structure.The HIDRALERTA system is composed of four modules developed in Open Source Web Technology, mainly using the Python Language. The Warning System can be configured and adapted for specific scenarios. The system has been successfully tested for the Port and Bay of Praia da Vitória, Terceira Island, Azores, Portugal, and is now under development and being implemented at the ports of Madalena do Pico and S. Roque do Pico.This paper describes the work carried out to date on the system and its application to these two ports in the Pico Island, Azores.
Year: 2020
Number Pages:
10p.
Author(s): Fortes, C. J. E. M.; Reis, M. T. L. G. V.; Pinheiro, L.; Poseiro, P.; Serrazina, V.; Mendonça, A. C.; SMITHERS, N; SANTOS, M.I.; Barateiro, J.; Azevedo, E. B.; SALVADOR, M.; Reis, F.
: Revista Aquatic Ecosystem Health & Management
Editor: Taylor & Francis
Keywords: Warning system; Flooding; Wave overtopping
Info
3-D scale model study of wave run-up, overtopping and damage in a rubble-mound breakwater subject to oblique extreme wave conditions
A set of scale-model tests carried out to enlarge the range of wave steepness values analysed in run-up, overtopping and armour layer stability studies, focusing on oblique extreme wave conditions and on their effects on a gentler slope breakwater
Year: 2019
Number Pages:
32-41pp..
Author(s): Santos, J. A.; Pedro, F.; Coimbra, M.; Figuero, A.; Fortes, C. J. E. M.; Sande, J.; Körner, M.; Lemos, R.; Bornschein, A.; Weimper, J.; van den Bos, J.; Dost, B.; Hofland, B.; Carvalho, R.; Alvarellos
: Defect and Diffusion Forum
Editor: Trans Tech Publications Ltd, Switzerland
Volume:
Volume 396.
Keywords: Instrumentation; 3D-Wave basin; Physical modelling
Info
A numerical tool for modelling oscillating wave surge converter with nonlinear mechanical constraints
Mechanical constraints have a non-negligible influence in the motion of oscillating wave surge converter (OWSC) devices. The key novelty of this paper is a numerical simulation tool for OWSCs that does not neglect or significantly compromise mechanical constraints such as hydraulic power take-off (PTO) system, revolute joints and frictional contacts among components. The paper is aimed at presenting the key components of the numerical simulation tool and at validating it with laboratory data featuring an OWSC with mechanical constraints under regular and irregular waves. It is based on the implementation of the multibody solver of Project Chrono under the Smoothed Particle Hydrodynamics (SPH) model of DualSPHysics, where the SPH solver resolves the interaction between wave and flap and the multibody solver resolves the interaction between flap and mechanical constraints. Comparison between numerical results and experimental data show that the numerical simulation tool properly predicts the dynamics of the OWSC. Furthermore, in what concerns hydrodynamics of the near-flap flow, the computed and measured free-surface elevations and phase-averaged flow field show reasonable agreement. Once properly validated, the numerical simulation tool is then applied to study the influence of several mechanical constraints, PTO damping characteristics and flap inertia on the hydrodynamic of the OWSC. The viability of OWSC design solutions based on the developed numerical simulation tool is emphasised, in view of its performance in the test cases to which it was subjected.
Year: 2019
Number Pages:
2024-2043pp.
Author(s): Brito, M.; R. Canelas; García-Feal, O.; Domínguez, J. M.; Crespo, A. C.; Ferreira, R. L.; Neves, M. G.; Teixeira, L.
: Renewable Energy
Editor: Elsevier
Volume:
146.
Keywords: Wave-structure interaction; Wave energy; Mechanical constraints; Oscillating wave surge converter (OWSC); Smoothed particle hydrodynamics (SPH); Numerical modelling
|