Your search keyword '"Gattulli, V"' showing total 9 results

1. Transient calculation of pressure waves in a well induced by tubular expansion

Author

Assaad, W., Pasaribu, H.R., Zijsling, DJ, van Dalen, K.N., Metrikine, A., Vestroni, F., Romeo, F., and Gattulli, V.

Subjects

genetic structures, Flow (psychology), Shell (structure), fluid-structure interaction, 02 engineering and technology, Drill pipe, 010502 geochemistry & geophysics, oil, 01 natural sciences, 020401 chemical engineering, gas, 0204 chemical engineering, Surge, 0105 earth and related environmental sciences, business.industry, General Medicine, Structural engineering, Mechanics, Cone (topology), Volume (thermodynamics), Transient (oscillation), business, method of characteristics, Casing, Geology, compressible

Abstract

Shell has developed a novel mono-diameter well concept for oil and gas wells as opposed to the traditional telescopic well design. A Mono- diameter well contains multiple casing sections with the same internal diameter. This is achieved by expansion of the casing sections concerned using an expansion cone. Since the well is drilled in stages and casings are inserted to support the open hole, an overlap section between two consecutive (expandable) casings exists which has to be expanded. When the cone enters the overlap section, the expansion force increases dramatically due to the expansion of two casings, cured cement and formation layers. When the cone finalizes the expansion of the overlap section it pops out, the expansion force vanishes and the cone accelerates upwards and it generates an empty volume to be filled by the well fluid (mud). As a result of this, fluid starts to flow through the drill pipe, around the cone and the fluid volume below the cone starts to decompress. This induces a surge pressure wave traveling upwards and a swab pressure wave in the expanded casing traveling downwards. If the pressure difference between outside and inside of the expanded casing exceeds the collapse rating of the casing, the casing will collapse which leads to the loss of the concerned well section. Repair of such a failure costs time and money, therefore this swab pressure must be well predicted to enable the installation process to be designed such that this collapse can be avoided. A model of fully coupled fluid-structure interaction between cone and the well fluid is built for calculating the swab pressure propagating downward and surge pressure propagating upward resulted from transient process occurring after cone pops out. This model has shown an effective tool for predicting the swabbing pressure in field deployments performed lately in Gulf of Mexico and according to its output the suitable cone is selected in order to avoid the casing collapse.

Published

2017

2. Non-destructive structural integrity testing of finite plates based on the wave scattering at defects with sub-wavelength size

Author

Elke Deckers, Bert Pluymers, Claus Claeys, Philip Becht, Wim Desmet, Vestroni, F, Romeo, F, and Gattulli, V

Subjects

010302 applied physics, Frequency response, ANTARES, Materials science, business.industry, Scattering, Structural integrity, Natural frequency, General Medicine, 01 natural sciences, Square (algebra), Sub wavelength, Optics, PDmandaat_Elke, IOF, DEMOPRECI, Nondestructive testing, Non destructive, 0103 physical sciences, FM_affiliated, business, 010301 acoustics

Abstract

This paper describes a technique to magnify the scattering of a wave at a defect by using the natural behavior of a structure. The fundamental physical principle of the detection strategy as well as the way to exploit this principle for detecting defects are explained. The influence of the parameters defect location, defect size and natural frequency selected, is investigated in a numerical example considering a 1mm thick A3 Aluminum plate. The proposed defect detection strategy is based on the measurement of frequency response functions at a very limited number of response locations and is therefore very easy to apply. Furthermore, an experimental validation of the detectability of a square 4mm through thickness defect is performed. Due to its simplicity and the low number of sensors necessary, the strategy explained in this paper allows the detection of a defect very rapidly. ispartof: pages:2020-2025 ispartof: X International Conference on Structural Dynamics, EURODYN 2017 vol:199 pages:2020-2025 ispartof: International Conference on Structural Dynamics, EURODYN location:Rome date:11 Sep - 13 Sep 2017 status: published

Published

2017

3. On the structural response of a tall hybrid onshore wind turbine tower

Author

Charalampos Baniotopoulos, Michaela Gkantou, Pedro Martinez-Vazquez, Vestroni, F, Romeo, F, and Gattulli, V

Subjects

Engineering, Wind power, business.industry, Turbulence, 020209 energy, 02 engineering and technology, General Medicine, Structural engineering, Design load, Aeroelasticity, Turbine, Wind speed, Aerodynamic force, Wind profile power law, TA, 0202 electrical engineering, electronic engineering, information engineering, TH, TD, business

Abstract

Given the increasing demand for taller structures in wind energy applications and the accompanying need for a better understanding of their structural response, the present study performs aeroelastic analysis on a novel wind turbine structure and discusses the obtained results. The response of a hybrid onshore wind turbine tower consisting of a 60 m lattice structure and a 60 m tapered tubular structure, with a 5 MW class AII turbine, is investigated. From the Design Load Cases (DLC) established in IEC64100-1 standard, focus is set on DLC 1.1 and DLC 1.3 which correspond to power production conditions and embody the requirements for loads resulting from atmospheric turbulence during normal and extreme operating conditions respectively. DLC 6.1 which refers to standstill or idling conditions under extreme wind model is also studied. In order to account for the interaction between elastic, viscous and inertial forces of the structure and the external aerodynamic forces, ashes, an integrated analysis software, is used. After developing the wind turbine tower model and generating the turbulence models, 600 seconds simulations are performed. The wind flow is assumed to be parallel to the hub axis. For DLC 1.1 and DLC 1.3, parametric studies with the wind speed ranging from 3 to 25 m/s, with an incremental step of 1 m/s, are executed. In DLC 6.1, the blades are feathered and the wind speed is rapidly increased to 42.5 m/s. Time histories of the elemental forces and the nodal displacements are extracted in critical positions of both the lattice and the tubular part. The mean values of the output data are evaluated and plotted against the wind speed. Conclusions regarding the influence of the wind speed on the induced tower behaviour are drawn.

Published

2017

4. Strength demands of tall wind turbines subject to earthquakes and wind load

Author

Pedro Martinez-Vazquez, Michaela Gkantou, Charalampos Baniotopoulos, Vestroni, F, Romeo, F, and Gattulli, V

Subjects

Engineering, Wind power, Meteorology, business.industry, 020209 energy, 02 engineering and technology, General Medicine, Wind engineering, TA, Wind force, 0202 electrical engineering, electronic engineering, information engineering, TH, Probabilistic analysis of algorithms, Geotechnical engineering, TD, business, Aftershock

Abstract

Wind and earthquake load have historically been conceived to act independently. However, if we reflect on the fact that major seismic events are usually followed by a number of aftershocks and that wind is constantly flowing at high intensities around wind farms, which induces additional demands of resistance to infrastructure, then the joint probability of middle-to strong earthquakes and low-to mild wind events becomes more relevant. In this paper a generalised approach is used to estimate the ratio between earthquake and wind forces and their effect on infrastructure. Following, a probabilistic analysis is carried out to show that under certain conditions the combination of these natural events can induce additional demands of strength and ductility to wind turbines which could lead to unforeseen damage.

Published

2017

5. On the role of vibro-acoustics in leak detection for plastic water distribution pipes

Author

F.C.L. Almeida, Mahmoud Karimi, F. Kroll de Lima, Michael J. Brennan, Nicole Kessissoglou, Daniel Henrique de Sousa Obata, Pedro Ayala, Amarildo Tabone Paschoalini, Vestroni, F, Romeo, F, and Gattulli, V

Subjects

Leak, Engineering, Shear stiffness, business.industry, Acoustics, Attenuation, education, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, 01 natural sciences, 09 Engineering, Vibration, Noise, 0103 physical sciences, Strong coupling, Water pipe, Leak detection, 0210 nano-technology, business, 010301 acoustics

Abstract

Leaks have been detected and localized in water distribution in many countries for years, by using the cross-correlation of pipe vibration measured either side of a suspected leak and/or by using listening sticks. However, in modern plastic pipes this is problematic because of the strong coupling between the water and the pipe which results in significant attenuation of the coupled fluid-pipe wave, which in turn is responsible for the propagation of leak noise. Hence leak noise does not propagate as far as it did in older metallic pipes. This paper discusses how the vibro-acoustic behavior of the water-pipe-soil system influences leak noise propagation. To investigate this, a numerical model is developed, and the results are compared with those from an analytical model for two water pipe systems, one in the UK and one in Brazil. Experimental results are also presented. It is shown that the important difference between the two systems is the shear stiffness of the surrounding soil, which has a profound effect on both the speed of leak noise propagation and the attenuation of the noise along the pipe.

Published

2017

6. A simplified method to account for the effect of human-human interaction on the pedestrian-induced vibrations of footbridges

Author

Guido De Roeck, Peter Van den Broeck, Katrien Van Nimmen, Xinxin Wei, Vestroni, F, Romeo, F, and Gattulli, V

Subjects

Engineering, Serviceability (structure), Design stage, business.industry, Modal analysis, 020101 civil engineering, 010103 numerical & computational mathematics, 02 engineering and technology, General Medicine, Pedestrian flow, Pedestrian, Structural engineering, 01 natural sciences, 0201 civil engineering, Vibration, Human interaction, Social force model, 0101 mathematics, business

Abstract

© 2017 The Authors. Published by Elsevier Ltd. For the design of slender footbridges, the vibration serviceability under pedestrian excitation is often the governing criterion. In design stage, vibration levels are predicted using simplified load models that are extrapolated from single-person force models to represent the effect of a crowd. However, these load models disregard Human-Human Interaction (HHI) and Human-Structure Interaction (HSI). This contribution investigates the effect of human-human interaction on the resulting structural response. A social force model is applied to simulate the realistic pedestrian traffic. The time-varying position and velocity of each pedestrian in the crowd are transferred into the necessary inputs for detailed step-by-step simulations of the pedestrian-induced forces and the resulting pedestrian-induced vibrations. The results show that accounting for HHI results into a reduced global walking speed. Also, the inter-person variability of the step frequencies is lower than when HHI is disregarded. As an alternative to the computationally expensive social force model, the effect of HHI is translated into an equivalent distribution of step frequencies of the pedestrians in the crowd. The results show that this simplified model allows for a very good approximation of the HHI effects on the resulting crowd-induced loading and structural response. ispartof: pages:2907-2912 ispartof: Procedia Engineering vol:199 pages:2907-2912 ispartof: X International Conference on Structural Dynamics location:Rome, Italy date:10 Sep - 13 Sep 2017 status: published

Published

2017

7. On surface wave fields arising in soil-structure interaction problems

Author

Andreas Chorozoglou, Julius Kaplunov, Danila A. Prikazchikov, Nihal Ege, Barış Erbaş, Vestroni, F, Romeo, F, Gattulli, V, Anadolu Üniversitesi, Fen Fakültesi, Matematik Bölümü, and Erbaş, Barış

Subjects

Soil-Structure Interaction, Point source, Internal Source, Perturbation (astronomy), General Medicine, Mechanics, 01 natural sciences, 010305 fluids & plasmas, 010101 applied mathematics, symbols.namesake, Rayleigh Wave, Classical mechanics, Surface wave, Soil structure interaction, 0103 physical sciences, symbols, 0101 mathematics, Rayleigh wave, QC, Mathematics

Abstract

10th International Conference on Structural Dynamics (EURODYN) -- SEP 10-13, 2017 -- Sapienza Univ Rome, Fac Civil & Ind Engn, Rome, ITALY, WOS: 000422868902085, The paper aims at generalization of the specialized formulation, originally developed for the surface wave fields induced by prescribed surface stresses. We extend this formulation to soil-structure interaction problems with unknown contact stresses and internal sources. The problem for an internal source embedded in an elastic half-plane is reduced to that for prescribed surface stresses by considering the point source solution for an unbounded medium. In this case the sub-problems corresponding to normal and tangential stresses assume a separate treatment. Then, we analyze interaction of an elastic half-plane with a one degree of freedom mass-spring system. The focus is on a near-resonant regime investigated by a perturbation technique., European Assoc Struct Dynam, Research Projects of Anadolu University [1408F370], The work of NE and BE was supported by the Research Projects of Anadolu University, No: 1408F370, which is gratefully acknowledged.

Published

2017

8. Quantification of non-homogeneous interval uncertainty based on scatter in modal properties

Author

David Moens, Matthias Faes, Vestroni, F, Romeo, F, and Gattulli, V

Subjects

Mathematical optimization, 0211 other engineering and technologies, 02 engineering and technology, General Medicine, Interval (mathematics), Inverse problem, 01 natural sciences, 010101 applied mathematics, Data set, Identification (information), Bounding overwatch, Sensitivity analysis, 0101 mathematics, Uncertainty quantification, Focus (optics), Algorithm, 021106 design practice & management, Mathematics

Abstract

The objective of this work is to develop and validate a methodology for the identification of intra-variability based on the Interval Field concept, with a specific focus on dynamic FE models. The principal idea is to find a solution to an inverse problem, where the variability on the output side of the model (i.e., the eigenfrequencies) is known from measurement data, but the spatial uncertainty on the input parameters is unknown. Specifically, focus is placed on the identification of the topology of the non-homogeneous interval uncertainty, modelled as an interval field. This identification is performed by comparing the gradients of the halfspaces bounding the uncertain set resulting from the propagation of the interval field and the measurement data set. It is shown that an accurate identification is feasible following the proposed methodology. ispartof: pages:1216-1221 ispartof: Procedia Engineering vol:199 pages:1216-1221 ispartof: EURODYN 2017 - International conference on structural dynamics location:Rome, Italy date:10 Sep - 13 Sep 2017 status: published

Published

2017

9. Computational Framework for Online Estimation of Fatigue Damage using Vibration Measurements from a Limited Number of Sensors

Author

Dimitrios Giagopoulos, Alexandros Arailopoulos, V. Dertimanis, Costas Papadimitriou, Eleni Chatzi, Konstantinos Grompanopoulos, Vestroni, F., Gattulli, V., and Romeo, F.

Subjects

0209 industrial biotechnology, 020901 industrial engineering & automation, Output-Only Measurements, System Identification, FE Model Updating, Strain and Fatigue Predictions, 020101 civil engineering, General Medicine, 02 engineering and technology, 0201 civil engineering

Abstract

This study proposes a computational framework for the online estimation of fatigue damage using operational vibration measurements from a limited number of sensors. To infer the stress response time histories required for fatigue prediction, the measured structural response is driven to a high fidelity finite element (FE) model, which is reconciled using appropriate model updating techniques that minimize the discrepancy between the experimental and analytical frequency response functions (FRFs). Fatigue is accordingly estimated via the Palmgren-Miner rule, while the available FE model allows for stress estimation at unmeasured spots. The method is successfully validated and assessed through an experimental study that pertains to a linear steel substructure supporting the entire body of a pre-beater assembly at a PPC power plant., Procedia Engineering, 199

Published

2017