Experimental Study of the Wake behind a Circular Cylinder under Excitation

Chang, Tien-Li

30 July 2002

This experiment is to investigate the effects of fluid with and without mass injection through a slit on the vortex shedding from a single cylinder. We research Reynolds Numbers on ranges from 800 to 4000. We used four kinds of ways which contain no mass injection, steady blowing, steady suction and oscillatory jet to study of the wake behind a circular cylinder under excitation in this experiment. No mass injection is measured for the sake of its reliability and comparability of experiment. Steady blowing and suction are applied to influence the wake flow. An oscillatory jet is used to influence the wake flow with varying frequencies and amplitudes. The experiment looks forward to use the results of this experiment so as to research into the effects on the wake flow, including the velocity values of fluctuation and turbulence intensity of the vortices structure, the dominant frequency in the flow pattern on a single cylinder. The main parameters in the study are the frequency, momentum and the location of the blowing and suction jet, which are a steady jet or unsteady oscillatory jet. Flow visualization has been carried out to investigate the interaction of steady or unsteady fluid perturbation and the vortex shedding of a cylinder.

steady blowing or suction jet

flow control

vortex shedding

a single cylinder

oscillatory jet

Experimental studies of wind turbine wakes : power optimisation and meandering

Medici, Davide

January 2005

<p>Wind tunnel studies of the wake behind model wind turbines with one, two and three blades have been made in order to get a better understanding of wake development as well as the possibility to predict the power output from downstream turbines working in the wake of an upstream one. Both two-component hot-wire anemometry and particle image velocimetry (PIV) have been used to map the flow field downstream as well as upstream the turbine. All three velocity components were measured both for the turbine rotor normal to the oncoming flow as well as with the turbine inclined to the free stream direction (the yaw angle was varied from 0 to 30 degrees). The measurements showed, as expected, a wake rotation in the opposite direction to that of the turbine. A yawed turbine is found to clearly deflect the wake flow to the side showing the potential of controlling the wake position by yawing the turbine. The power output of a yawed turbine was found to depend strongly on the rotor. The possibility to use active wake control by yawing an upstream turbine was evaluated and was shown to have a potential to increase the power output significantly for certain configurations. An unexpected feature of the flow was that spectra from the time signals showed the appearance of a low frequency fluctuation both in the wake and in the flow outside. This fluctuation was found both with and without free stream turbulence and also with a yawed turbine. The non-dimensional frequency (Strouhal number) was independent of the freestream velocity and turbulence level but increases with the yaw angle. However the low frequency fluctuations were only observed when the tip speed ratio was high. Porous discs have been used to compare the meandering frequencies and the cause in wind turbines seems to be related to the blade rotational frequency. It is hypothesized that the observed meandering of wakes in field measurements is due to this shedding.</p>

wind energy

power optimisation

active control

yaw

vortex shedding

wake meandering

Fluid mechanics

Strömningsmekanik

The effects of forebody strakes on asymmetric vortices on a vertically launched missile

Yuan, Chih-Chung.

January 1990

Thesis (M.S. in Aeronautical Engineering)--Naval Postgraduate School, September 1990. / Thesis Advisor(s): Howard, Richard M. Second Reader: Healey, J. Val. "September 1990." Description based on title screen as viewed on December 15, 2009. DTIC Identifier(s): Strakes, Yaw, Aerodynamic Forces, Surface To Air Missiles, Angle Of Attack, High Angles, Sides, Side Forces, Wind Tunnel Models, Guided Missile Models, Vortex Shedding, High Angle Of Attack, Turbulence, Forebody Strakes, Ogives, Computer Programs, Theses, Vertical Launch. Author(s) subject terms: Vortex, Vertical Launch, Surface to Air Missile, High Angle of Attack, Turbulence, Strakes, Forebody, Ogive. Includes bibliographical references (p. 154-157). Also available in print.

Active control of fan noise and vortex shedding

Wong, Yee-Jun

January 2005

[Truncated abstract] The subject of fan noise generating mechanisms and its control has been studied intensively over the past few decades as a result of the ever-increasing demand for more powerful fans. A unique feature of fan noise is that it consists of high-level discrete frequency noise related to the blade passing frequency, and low-level broadband noise due mostly to turbulent airflow around the fan. Of the two types of fan noise, the discrete frequency noise is the more psychologically annoying component. Past research into fan noise has shown that the discrete frequency fan noise are dipole in nature and are caused predominantly by the fluctuating lift acting on the surfaces of the fan blades. Based on this, several theoretical models have been established to correlate these fluctuating lift forces to the far-field sound pressure. However, one general assumption in these models is that the fan blades are assumed rigid, and the consequence of such an assumption is that it is unclear if the far-field sound pressure is caused solely by the aerodynamic lift force, or whether the blade vibration also plays a substantial role in the generation of the far-field fan noise. One of the goal of this thesis was thus to experimentally quantify the contribution of blade vibration to far-field fan noise and it was found that blade vibration, whilst coherent with the far-field fan noise, did not contribute significantly. Aside of this, several experiments aimed at filling knowledge gaps in the understanding of fan noise characteristics were also be conducted, in particular, to understand the relationship between far-field sound pressure level to blade lengths as well as the number of blades on the fan. The experiments showed that for fans with many blades, the dependency of the far-field sound pressure on blade length is stronger than fans with less blades. Furthermore, dipole measurements showed that the dipole characteristics of fan noise does not occur only at the discrete frequencies, but also within a range of broadband frequencies, implying that the source for both discrete and broadband is the same. The second section of this thesis deals with the study of vortex shedding and its active control. When a circular cylinder (or any object) is placed in a flow within a specified Reynolds number range, flow separation and periodical wake motion is formed behind the cylinder, which is known as vortex shedding. It has been found in previous research that this wake motion is affected by acoustic field imposed on it via loudspeakers. This suggests that there is a strong acoustic-vortex relationship. However, little of this relationship is understood as conventional methods of studying vortex centre around the use of hot-wire anemometry, which effectively measures the velocity fluctuation in the flow. This thesis is the first in using a microphone to study the acoustic characteristic of the vortex wake, and experimental results shows that the two parallel shear layers of the wake carry the strongest pressure signals at the vortex shedding frequency, whilst the entrapped region between the layers carries the strongest pressure signals at the first harmonic.

Fans (Machinery) -- Noise

Vortex-motion

Fan noise

Vortex shedding

Active noise control

Investigação experimental do efeito de interferência de tabuleiros paralelos de pontes em túnel de vento frente ao desprendimento de vórtices / Wind tunnel experimental investigation on the interference effects of parallel bridge decks due to vortex shedding

Núñez, Gustavo Javier Zani

January 2008

O conhecimento do comportamento aerodinâmico do tabuleiro de uma ponte é um fator determinante em projetos de pontes e na resolução de problemas práticos de engenharia associados. No Brasil ainda são poucas, mas crescentes, as construções de pontes com cabos, sejam elas pênseis ou estaiadas. Estas fazem parte do foco do estudo desta tese de doutorado que visa à obtenção de contribuições para ampliar a base de dados referentes aos parâmetros que influenciam o comportamento aerodinâmico de pontes. Busca-se investigar e quantificar os efeitos de interferência devidos à ação do vento em tabuleiros paralelos (próximos) de pontes, frente à resposta induzida pelo desprendimento de vórtices, gerando subsídios para a elaboração de projetos e solução de problemas da prática da Engenharia Civil. O programa experimental foi realizado nas instalações do Túnel de Vento Prof. Joaquim Blessmann da Universidade Federal do Rio Grande do Sul. Foram realizadas medidas em modelos seccionais reduzidos de um tabuleiro de ponte. Um modelo teve sua secção transversal média instrumentada com tomadas de pressão para determinação do campo de pressões. Foram obtidos campos de pressões para o modelo isolado e para distintas configurações de vizinhança (posicionamento de outro tabuleiro idêntico paralelo ao instrumentado) O outro modelo seccional foi ensaiado com o auxílio de um dispositivo que permite a simulação de dois graus de liberdade, vertical e torcional, utilizado para a determinação do comportamento dinâmico do tabuleiro frente ao desprendimento de vórtices. Nestes testes foram investigadas as condições de vizinhança, de dispositivos aerodinâmicos (nariz de vento) além da variação do nível de amortecimento em relação ao crítico, sendo a seguir realizadas medidas do campo de velocidades no entorno do modelo do tabuleiro. Os efeitos de interferência observados, a partir dos testes com modelos estáticos, variaram de acordo com cada uma das disposições geométricas estudadas. Em determinadas situações foram observados efeitos benéficos de proteção, entretanto, aumentos nos coeficientes também ocorreram. Os resultados obtidos com os modelos dinâmicos indicaram, de uma forma geral, melhora na estabilidade aerodinâmica em relação à situação com modelo isolado. Foi observada a ocorrência de mais de um pico na resposta vertical por desprendimento de vórtices o que ocasionou estudos adicionais aos inicialmente propostos. A partir da verificação da real possibilidade de ocorrência de mais de um pico na resposta, propõe-se a inclusão de novas orientações para o projeto de estruturas suscetíveis a vibrações verticais por desprendimento de vórtices em texto de normas ou recomendações de projeto. / The knowledge of the aerodynamic behavior of a bridge deck is a major factor in the design of bridges and in the solving of related engineering problems. There are still not many suspension or cable stayed bridges in Brazil, although the construction of these kind of structures has been increasing in the last years. This Thesis has the aim of contributing with the broadening of the state of the art in the aerodynamics of cable stayed bridges. The objective is to investigate the effects of aerodynamic interference in closely spaced bridge decks due to vortex shedding. The experimental program was performed in the boundary layer wind tunnel Prof. Joaquim Blessmann of the Universidade Federal do Rio Grande do Sul. The measurements were obtained through sectional models of bridge decks. One of the models was instrumented with pressure taps for the measurement of the individual pressure field (isolated model) as well as for several vicinity configurations (two closely spaced parallel models). The other sectional model was tested through an experimental device which allows the simulation of two degrees of freedom, vertical and torsional, used for the investigation of the bridge deck behavior under vortex shedding excitation. Several vicinity configurations, aerodynamic devices, damping levels and measurement points around the models were investigated in the wind tunnel tests. The interference effects observed from the static models vary according to each one of the geometric positions studied. For some situations there were beneficial protection effects, although an increase in the value of the coefficients also occurred. The results from the dynamic model have generally indicated an improvement in the aerodynamic stability in relation to the isolated model. It was also observed that more than one peak occurred for the vertical response due to vortex shedding, which lead to additional studies to the initial planned. From these observations, the inclusion of new guidelines for the design of structures susceptible to vertical vibrations due to vortex shedding, in the specific codes, are recommended.

Túnel de vento

Pontes (Engenharia)

Vento

Modelos dinâmicos

Aerodinâmica

Vortex-shedding

Bridges

Wind tunnel

Estudo das metodologias para o cálculo da resposta de estruturas cilíndrico circulares frente ao fenômeno de desprendimento de vórtices : proposta atualizada para a NBR- 6123 / Study of the methodologies for the calculation of the response of circular cylindrical structures due to vortex shedding phenomenon : updated proposal for the brazilian wind code

Grala, Pedro

January 2016

Estruturas como torres e chaminés industriais são bastante vulneráveis ao fenômeno de desprendimento de vórtices, devido à sua esbeltez e forma rombuda. Além disso, devido ao baixo amortecimento estrutural que possuem, essas estruturas também têm maiores chances de atingir grandes amplitudes de deslocamento, o que é causado pelo efeito de captura. Apesar de esse tipo de estrutura ser considerado simples dos pontos de vista estrutural e aerodinâmico, o estudo das vibrações transversais nessas estruturas é bastante complicado, pois envolve a interação entre tópicos complexos da mecânica dos fluidos e estrutural, tornando a determinação confiável da resposta estrutural um dos problemas mais difíceis da Engenharia do Vento. Ao longo das últimas cinco décadas, diversos pesquisadores vêm estudando esse fenômeno, buscando uma abordagem que consiga considerar todos os tópicos que envolvem o mecanismo de vibração por desprendimento de vórtices. Entretanto, apesar dos esforços, os modelos existentes para a verificação da resposta da estrutura são de caráter empírico, sendo os dois mais aceitos pela comunidade científica o modelo de comprimento de correlação de Ruscheweyh e o modelo matemático espectral de Vickery e Clark, o qual foi posteriormente aprimorado por Vickery e Basu. Primeiramente, são estudados em detalhe esses dois modelos e seus métodos derivados, os quais são apresentados em normas e códigos. Após isso, é feita uma proposta de cálculo de dimensionamento do deslocamento do topo de tais estruturas baseada no modelo de Vickery e Basu e adaptada às necessidades da NBR- 6123. E finalmente, são apresentados dados de 42 estruturas, as quais atingiram grandes amplitudes de vibração em seu topo. Essas estruturas foram dimensionadas segundo as diretrizes de cada um dos métodos estudados neste trabalho, o que demonstrou o bom desempenho do Método II do Eurocódigo, do Método do CICIND e da Proposta III-B para a NBR-6123. / Structures like towers and industrial chimneys are quite vulnerable to the vortex shedding phenomenon, due to their slenderness and non-aerodynamic form. Furthermore, due to their low structural damping, these structures are also more likely to reach large displacement amplitudes, which is caused by the lock-in effect. Although these structures are considered as simple from structural and aerodynamic points of view, the study of cross-wind vibrations in these structures is quite complicated, as it involves the interaction of complex topics of fluid and structural mechanics, turning a reliable determination of the structural response into one of the most complicated problems in Wind Engineering. Over the past five decades, several researchers have been studying this phenomenon, seeking an approach that could consider all topics involving the vibrating mechanism by vortex shedding. However, despite the efforts, the existing models for predicting the response of the structure are empirical, with the two most accepted by the scientific community being the Ruscheweyh’s correlation length model and the Vickery & Clark’s spectral mathematical model, which was further enhanced by Vickery & Basu. Firstly, these two models and their derivative methods, which are reported in standards and codes, are studied in detail. After, a calculation proposal for predicting the top displacement of such structures is presented, which is based on the Vickery & Basu model and adapted to the needs of NBR-6123. Finally, data for 42 real structures which have reached large vibration amplitudes at their tops is presented. These structures were designed according to the guidelines for each of the methods studied in this work, which demonstrated the good performance of the Eurocode II Method, of the CICIND Method and of the NBR-6123 III-B Proposal.

Estruturas (Engenharia)

Torres (Engenharia)

Chaminés

Vento

Modelos matemáticos

Vortex shedding

Industrial chimney

Dynamic response

Investigação experimental do efeito de interferência de tabuleiros paralelos de pontes em túnel de vento frente ao desprendimento de vórtices / Wind tunnel experimental investigation on the interference effects of parallel bridge decks due to vortex shedding

Núñez, Gustavo Javier Zani

January 2008

O conhecimento do comportamento aerodinâmico do tabuleiro de uma ponte é um fator determinante em projetos de pontes e na resolução de problemas práticos de engenharia associados. No Brasil ainda são poucas, mas crescentes, as construções de pontes com cabos, sejam elas pênseis ou estaiadas. Estas fazem parte do foco do estudo desta tese de doutorado que visa à obtenção de contribuições para ampliar a base de dados referentes aos parâmetros que influenciam o comportamento aerodinâmico de pontes. Busca-se investigar e quantificar os efeitos de interferência devidos à ação do vento em tabuleiros paralelos (próximos) de pontes, frente à resposta induzida pelo desprendimento de vórtices, gerando subsídios para a elaboração de projetos e solução de problemas da prática da Engenharia Civil. O programa experimental foi realizado nas instalações do Túnel de Vento Prof. Joaquim Blessmann da Universidade Federal do Rio Grande do Sul. Foram realizadas medidas em modelos seccionais reduzidos de um tabuleiro de ponte. Um modelo teve sua secção transversal média instrumentada com tomadas de pressão para determinação do campo de pressões. Foram obtidos campos de pressões para o modelo isolado e para distintas configurações de vizinhança (posicionamento de outro tabuleiro idêntico paralelo ao instrumentado) O outro modelo seccional foi ensaiado com o auxílio de um dispositivo que permite a simulação de dois graus de liberdade, vertical e torcional, utilizado para a determinação do comportamento dinâmico do tabuleiro frente ao desprendimento de vórtices. Nestes testes foram investigadas as condições de vizinhança, de dispositivos aerodinâmicos (nariz de vento) além da variação do nível de amortecimento em relação ao crítico, sendo a seguir realizadas medidas do campo de velocidades no entorno do modelo do tabuleiro. Os efeitos de interferência observados, a partir dos testes com modelos estáticos, variaram de acordo com cada uma das disposições geométricas estudadas. Em determinadas situações foram observados efeitos benéficos de proteção, entretanto, aumentos nos coeficientes também ocorreram. Os resultados obtidos com os modelos dinâmicos indicaram, de uma forma geral, melhora na estabilidade aerodinâmica em relação à situação com modelo isolado. Foi observada a ocorrência de mais de um pico na resposta vertical por desprendimento de vórtices o que ocasionou estudos adicionais aos inicialmente propostos. A partir da verificação da real possibilidade de ocorrência de mais de um pico na resposta, propõe-se a inclusão de novas orientações para o projeto de estruturas suscetíveis a vibrações verticais por desprendimento de vórtices em texto de normas ou recomendações de projeto. / The knowledge of the aerodynamic behavior of a bridge deck is a major factor in the design of bridges and in the solving of related engineering problems. There are still not many suspension or cable stayed bridges in Brazil, although the construction of these kind of structures has been increasing in the last years. This Thesis has the aim of contributing with the broadening of the state of the art in the aerodynamics of cable stayed bridges. The objective is to investigate the effects of aerodynamic interference in closely spaced bridge decks due to vortex shedding. The experimental program was performed in the boundary layer wind tunnel Prof. Joaquim Blessmann of the Universidade Federal do Rio Grande do Sul. The measurements were obtained through sectional models of bridge decks. One of the models was instrumented with pressure taps for the measurement of the individual pressure field (isolated model) as well as for several vicinity configurations (two closely spaced parallel models). The other sectional model was tested through an experimental device which allows the simulation of two degrees of freedom, vertical and torsional, used for the investigation of the bridge deck behavior under vortex shedding excitation. Several vicinity configurations, aerodynamic devices, damping levels and measurement points around the models were investigated in the wind tunnel tests. The interference effects observed from the static models vary according to each one of the geometric positions studied. For some situations there were beneficial protection effects, although an increase in the value of the coefficients also occurred. The results from the dynamic model have generally indicated an improvement in the aerodynamic stability in relation to the isolated model. It was also observed that more than one peak occurred for the vertical response due to vortex shedding, which lead to additional studies to the initial planned. From these observations, the inclusion of new guidelines for the design of structures susceptible to vertical vibrations due to vortex shedding, in the specific codes, are recommended.

Túnel de vento

Pontes (Engenharia)

Vento

Modelos dinâmicos

Aerodinâmica

Vortex-shedding

Bridges

Wind tunnel

Estudo das metodologias para o cálculo da resposta de estruturas cilíndrico circulares frente ao fenômeno de desprendimento de vórtices : proposta atualizada para a NBR- 6123 / Study of the methodologies for the calculation of the response of circular cylindrical structures due to vortex shedding phenomenon : updated proposal for the brazilian wind code

Grala, Pedro

January 2016

Estruturas como torres e chaminés industriais são bastante vulneráveis ao fenômeno de desprendimento de vórtices, devido à sua esbeltez e forma rombuda. Além disso, devido ao baixo amortecimento estrutural que possuem, essas estruturas também têm maiores chances de atingir grandes amplitudes de deslocamento, o que é causado pelo efeito de captura. Apesar de esse tipo de estrutura ser considerado simples dos pontos de vista estrutural e aerodinâmico, o estudo das vibrações transversais nessas estruturas é bastante complicado, pois envolve a interação entre tópicos complexos da mecânica dos fluidos e estrutural, tornando a determinação confiável da resposta estrutural um dos problemas mais difíceis da Engenharia do Vento. Ao longo das últimas cinco décadas, diversos pesquisadores vêm estudando esse fenômeno, buscando uma abordagem que consiga considerar todos os tópicos que envolvem o mecanismo de vibração por desprendimento de vórtices. Entretanto, apesar dos esforços, os modelos existentes para a verificação da resposta da estrutura são de caráter empírico, sendo os dois mais aceitos pela comunidade científica o modelo de comprimento de correlação de Ruscheweyh e o modelo matemático espectral de Vickery e Clark, o qual foi posteriormente aprimorado por Vickery e Basu. Primeiramente, são estudados em detalhe esses dois modelos e seus métodos derivados, os quais são apresentados em normas e códigos. Após isso, é feita uma proposta de cálculo de dimensionamento do deslocamento do topo de tais estruturas baseada no modelo de Vickery e Basu e adaptada às necessidades da NBR- 6123. E finalmente, são apresentados dados de 42 estruturas, as quais atingiram grandes amplitudes de vibração em seu topo. Essas estruturas foram dimensionadas segundo as diretrizes de cada um dos métodos estudados neste trabalho, o que demonstrou o bom desempenho do Método II do Eurocódigo, do Método do CICIND e da Proposta III-B para a NBR-6123. / Structures like towers and industrial chimneys are quite vulnerable to the vortex shedding phenomenon, due to their slenderness and non-aerodynamic form. Furthermore, due to their low structural damping, these structures are also more likely to reach large displacement amplitudes, which is caused by the lock-in effect. Although these structures are considered as simple from structural and aerodynamic points of view, the study of cross-wind vibrations in these structures is quite complicated, as it involves the interaction of complex topics of fluid and structural mechanics, turning a reliable determination of the structural response into one of the most complicated problems in Wind Engineering. Over the past five decades, several researchers have been studying this phenomenon, seeking an approach that could consider all topics involving the vibrating mechanism by vortex shedding. However, despite the efforts, the existing models for predicting the response of the structure are empirical, with the two most accepted by the scientific community being the Ruscheweyh’s correlation length model and the Vickery & Clark’s spectral mathematical model, which was further enhanced by Vickery & Basu. Firstly, these two models and their derivative methods, which are reported in standards and codes, are studied in detail. After, a calculation proposal for predicting the top displacement of such structures is presented, which is based on the Vickery & Basu model and adapted to the needs of NBR-6123. Finally, data for 42 real structures which have reached large vibration amplitudes at their tops is presented. These structures were designed according to the guidelines for each of the methods studied in this work, which demonstrated the good performance of the Eurocode II Method, of the CICIND Method and of the NBR-6123 III-B Proposal.

Estruturas (Engenharia)

Torres (Engenharia)

Chaminés

Vento

Modelos matemáticos

Vortex shedding

Industrial chimney

Dynamic response

Investigação experimental do efeito de interferência de tabuleiros paralelos de pontes em túnel de vento frente ao desprendimento de vórtices / Wind tunnel experimental investigation on the interference effects of parallel bridge decks due to vortex shedding

Núñez, Gustavo Javier Zani

January 2008

O conhecimento do comportamento aerodinâmico do tabuleiro de uma ponte é um fator determinante em projetos de pontes e na resolução de problemas práticos de engenharia associados. No Brasil ainda são poucas, mas crescentes, as construções de pontes com cabos, sejam elas pênseis ou estaiadas. Estas fazem parte do foco do estudo desta tese de doutorado que visa à obtenção de contribuições para ampliar a base de dados referentes aos parâmetros que influenciam o comportamento aerodinâmico de pontes. Busca-se investigar e quantificar os efeitos de interferência devidos à ação do vento em tabuleiros paralelos (próximos) de pontes, frente à resposta induzida pelo desprendimento de vórtices, gerando subsídios para a elaboração de projetos e solução de problemas da prática da Engenharia Civil. O programa experimental foi realizado nas instalações do Túnel de Vento Prof. Joaquim Blessmann da Universidade Federal do Rio Grande do Sul. Foram realizadas medidas em modelos seccionais reduzidos de um tabuleiro de ponte. Um modelo teve sua secção transversal média instrumentada com tomadas de pressão para determinação do campo de pressões. Foram obtidos campos de pressões para o modelo isolado e para distintas configurações de vizinhança (posicionamento de outro tabuleiro idêntico paralelo ao instrumentado) O outro modelo seccional foi ensaiado com o auxílio de um dispositivo que permite a simulação de dois graus de liberdade, vertical e torcional, utilizado para a determinação do comportamento dinâmico do tabuleiro frente ao desprendimento de vórtices. Nestes testes foram investigadas as condições de vizinhança, de dispositivos aerodinâmicos (nariz de vento) além da variação do nível de amortecimento em relação ao crítico, sendo a seguir realizadas medidas do campo de velocidades no entorno do modelo do tabuleiro. Os efeitos de interferência observados, a partir dos testes com modelos estáticos, variaram de acordo com cada uma das disposições geométricas estudadas. Em determinadas situações foram observados efeitos benéficos de proteção, entretanto, aumentos nos coeficientes também ocorreram. Os resultados obtidos com os modelos dinâmicos indicaram, de uma forma geral, melhora na estabilidade aerodinâmica em relação à situação com modelo isolado. Foi observada a ocorrência de mais de um pico na resposta vertical por desprendimento de vórtices o que ocasionou estudos adicionais aos inicialmente propostos. A partir da verificação da real possibilidade de ocorrência de mais de um pico na resposta, propõe-se a inclusão de novas orientações para o projeto de estruturas suscetíveis a vibrações verticais por desprendimento de vórtices em texto de normas ou recomendações de projeto. / The knowledge of the aerodynamic behavior of a bridge deck is a major factor in the design of bridges and in the solving of related engineering problems. There are still not many suspension or cable stayed bridges in Brazil, although the construction of these kind of structures has been increasing in the last years. This Thesis has the aim of contributing with the broadening of the state of the art in the aerodynamics of cable stayed bridges. The objective is to investigate the effects of aerodynamic interference in closely spaced bridge decks due to vortex shedding. The experimental program was performed in the boundary layer wind tunnel Prof. Joaquim Blessmann of the Universidade Federal do Rio Grande do Sul. The measurements were obtained through sectional models of bridge decks. One of the models was instrumented with pressure taps for the measurement of the individual pressure field (isolated model) as well as for several vicinity configurations (two closely spaced parallel models). The other sectional model was tested through an experimental device which allows the simulation of two degrees of freedom, vertical and torsional, used for the investigation of the bridge deck behavior under vortex shedding excitation. Several vicinity configurations, aerodynamic devices, damping levels and measurement points around the models were investigated in the wind tunnel tests. The interference effects observed from the static models vary according to each one of the geometric positions studied. For some situations there were beneficial protection effects, although an increase in the value of the coefficients also occurred. The results from the dynamic model have generally indicated an improvement in the aerodynamic stability in relation to the isolated model. It was also observed that more than one peak occurred for the vertical response due to vortex shedding, which lead to additional studies to the initial planned. From these observations, the inclusion of new guidelines for the design of structures susceptible to vertical vibrations due to vortex shedding, in the specific codes, are recommended.

Túnel de vento

Pontes (Engenharia)

Vento

Modelos dinâmicos

Aerodinâmica

Vortex-shedding

Bridges

Wind tunnel

Aerodynamic Testing of Variable Message Signs

Meyer, Debbie

12 November 2014

The increasing nationwide interest in intelligent transportation systems (ITS) and the need for more efficient transportation have led to the expanding use of variable message sign (VMS) technology. VMS panels are substantially heavier than flat panel aluminum signs and have a larger depth (dimension parallel to the direction of traffic). The additional weight and depth can have a significant effect on the aerodynamic forces and inertial loads transmitted to the support structure. The wind induced drag forces and the response of VMS structures is not well understood. Minimum design requirements for VMS structures are contained in the American Association of State Highway Transportation Officials Standard Specification for Structural Support for Highway Signs, Luminaires, and Traffic Signals (AASHTO Specification). However the Specification does not take into account the prismatic geometry of VMS and the complex interaction of the applied aerodynamic forces to the support structure. In view of the lack of code guidance and the limited number research performed so far, targeted experimentation and large scale testing was conducted at the Florida International University (FIU) Wall of Wind (WOW) to provide reliable drag coefficients and investigate the aerodynamic instability of VMS. A comprehensive range of VMS geometries was tested in turbulence representative of the high frequency end of the spectrum in a simulated suburban atmospheric boundary layer. The mean normal, lateral and vertical lift force coefficients, in addition to the twisting moment coefficient and eccentricity ratio, were determined using the measured data for each model. Wind tunnel testing confirmed that drag on a prismatic VMS is smaller than the 1.7 suggested value in the current AASHTO Specification (2013). An alternative to the AASHTO Specification code value is presented in the form of a design matrix. Testing and analysis also indicated that vortex shedding oscillations and galloping instability could be significant for VMS signs with a large depth ratio attached to a structure with a low natural frequency. The effect of corner modification was investigated by testing models with chamfered and rounded corners. Results demonstrated an additional decrease in the drag coefficient but a possible Reynolds number dependency for the rounded corner configuration.

variable message sign

drag

galloping

vortex shedding

gust factor

Civil Engineering

Structural Engineering