Highly transient axi-symmetric squeeze flows

Krassnokutski, Alexei E. Krass de

04 April 2011

The aim of this work was to use experimental, analytical and computational Computational Fluid Dynamic - CFD methodologies to investigate so-called highly transient axi-symmetric squeeze flows. These flows occur between two co-axial and parallel discs which are subjected to an impact, arising from a falling mass, which induces a constant energy squeezing system, as distinct from the traditionally investigated constant force or constant velocity squeezing systems. Experiments were conducted using a test cell comprising two parallel discs of diameter 120 mm with a flexible bladder used to contain fluid. This test cell was bolted onto the base of a drop-weight tester used to induce constant energy squeeze flows. Glycerine was used as the working fluid, the temperature of which was appropriately monitored. Disc separation, together with pressures at three radial positions, were measured throughout the experimental stroke typically less than 10 ms duration. Two additional pressure transducers at the same radial position as the outermost transducer were also used to monitor and subsequently correct for minor non-axi-symmetries that arose in the system. Approximately 150 tests were conducted, embracing combinations of drop height from 0.1 to 1 m, drop mass from 10 to 55 kg and initial disc separation from 3 to 10 mm. Three elementary features were typically observed: a distinct preliminary pressure spike 1 immediately after impact corresponding to very large accelerations exceeding over 6 km/s2 in some experiments, a secondary major pressure spike 2 towards the termination of the stroke corresponding to diminishing disc separations and a bridging region 3 joining the two spikes corresponding to somewhat reduced pressures. While pressure distributions were observed to be closely parabolic during the major pressure spike, some uncertainty was present during the preliminary pressure spike, ascribed to sensitivities to deviations from axi-symmetry, and the likelihood of inertially generated pressures at the edge of the disc. The former feature appears not to have been reported on in the formal literature. iii Four analytical models were considered, invoking the parallel flow assumption in conjunction with the Navier Stokes equations: an inviscid/inertial model, a viscous model the lubrication approximation, a quasi-steady linear QSL model and a quasi-steady corrected linear QSCL model. The first two of these models, on incorporation of measured disc separations, and the derived velocities and accelerations, achieved acceptable correlations with pressure measurements largely within uncertainty bounds during the initial impact and towards the end of the stroke, respectively. The QSL model agreed satisfactorily with measurements throughout the entire duration of the experiment, while the QSCL model, by incorporating non-linear effects in an approximate linear way, yielded somewhat better correlations. By invoking the parallel flow assumption, all four models predict a parabolic radial pressure distribution. Utilizing a hypothetical case in which variations of disc separation, velocity and acceleration were considered employing similar magnitudes and timescales to those that were measured, outputs of the QSL model yielded results that correlated closely with CFD predictions, while the QSCL data were somewhat better. On the basis of the CFD data it was also inferred that, within practical uncertainty bounds, the parallel flow assumption was valid for the range of disc separation to radius ratios embraced in the current investigation.

Squeeze flow systems

Computational Fluid Dynamic - CFD

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Ignition enhancement for scramjet combustion

McGuire, Jeffrey Robert, Aerospace, Civil & Mechanical Engineering, Australian Defence Force Academy, UNSW

January 2007

The process of shock-induced ignition has been investigated both computa- tionally and experimentally, with particular emphasis on the concept of radical farming. The first component of the investigation contained Computational Fluid Dynamic (CFD) calculations of an ignition delay study, a 2D pre-mixed flow over flat plate at a constant angle to the freestream, and through a generic 2D scramjet model. The focal point of the investigation however examined the complex 3D flow through a generic scramjet model. Five experimental test conditions were ex- amined over flow enthalpies from 3.4 MJ/kg to 6.4 MJ/kg. All test conditions simulated flight at 21000 metres ([symbol=almost equal to] 70000 ft), while the equivalent flight Mach number varied from approximately 8.5 at the lowest enthalpy, to approximately Mach 12 at the highest enthalpy condition. The presence of H2 fuel injected in the intake caused a separated region to form on the lower surface of the model at the entrance to the combustor. A fraction of the total mass of fuel was entrained in this separated region, providing long residence times, hence increased time for the chemical reactions that lead to ignition to occur. In addition, extremely high temperatures were found to exist between each fuel jet. Both fuel and air are present in these regions, therefore the chance of ignition in these regions is high. Streamlines passing through the recirculation zone ignited within this zone, while streamlines passing between the fuel jets ignited soon after entry into the combustor. The first instance of a pressure rise from combustion was observed on the centreline of the model where the reflected bow shock around the fuel jets crossed the centreline of the combus- tor. Upstream of this location the static pressure of the flow was too low for the chemical reactions that release heat to occur. The comparison between the experimental and computational results was lim- ited due to inaccuracies in modelling the thermal state of the gas in the CFD calculations. The gas was modelled as being in a state of thermal equilibrium at all times, which incorrectly models the freestream flow from the nozzle of the shock tunnel, and also the flow downstream of oblique shock wave within the scramjet model. As a result combustion occurs sooner in the CFD calculations than in the experimental result.

Shock-induced ignition

2D scramjet model

radical farming

Desenvolvimento e otimização de misturador estatico com o uso da fluidinamica computacional (C.F.D.) / Development and optimization of a statistic mixer with the use of computational fluid dynamics (C.F.D.)

Joaquim Junior, Celso Fernandes, 1971-

29 May 2008

Orientadore: Jose Roberto Nunhez, Efraim Cekinski / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Quimica / Made available in DSpace on 2018-08-11T21:24:27Z (GMT). No. of bitstreams: 1 JoaquimJunior_CelsoFernandes_M.pdf: 1822240 bytes, checksum: 1c74330095d87b01b823d7d17fbc50c9 (MD5) Previous issue date: 2008 / Resumo: Nos processos convencionais de agitação e mistura um acionamento, através de um eixo-árvore, rotaciona um ou mais impelidores no interior de um fluido, normalmente contido em um vaso de processo. Os processos de mistura que usam dispositivos estáticos no interior de dutos de escoamento são uma opção aos processos convencionais, tendo crescente aplicação e interesse, visto utilizar-se de parte da energia cedida para o bombeamento dos fluidos, permitindo a mistura em um processo contínuo, minimizando o uso de equipamentos e instalações industriais. Contudo, sua aplicação ainda é restrita a alguns processos específicos por questões tecnológicas e, principalmente, pelo pouco conhecimento de técnicos e engenheiros dos fenômenos físicos que regem sua aplicabilidade. A inexistência de tecnologia e conhecimento nacional nesta área impõe a dependência frente a empresas estrangeiras, encarecendo e dificultando sua aplicação. Na última década, técnicas computacionais tem sido utilizadas para o projeto e otimização desses dispositivos, conhecidos como misturadores estáticos, com destaque para a fluidodinâmica computacional ¿ CFD (Computational Fluid Dynamics). Este trabalho tem como objetivo, através da aplicação de técnicas de CFD, permitir um melhor entendimento dos fenômenos que regem o escoamento de fluidos no interior de misturadores estáticos, especificamente desenhados para esta análise, permitindo sugerir e estudar seus desenhos, propondo soluções e modificações a fim de melhorar a mistura e minimizar o gasto de energia no processo. A ferramenta de CFD utilizada foi o pacote computacional CFX. Os resultados obtidos permitiram uma boa compreensão dos fenômenos envolvidos e foram coerentes com os dados experimentais disponíveis na literatura. Foram criados dois novos conceitos geométricos de misturadores estáticos, denominados de EDA e ALETAS, cujas performances permitem seu emprego em condições reais de aplicação na indústria. / Abstract: On conventional mixing processes, a shaft rotates one or more impellers in a fluid generally inside a process vessel. The mixing processes that use static mixers on tube fluid flow are an option to conventional processes which application and interest is continuously growing, minimizing the use of equipment industrial devices. However its application is restricted to some specific processes because of technological reasons and mainly due to the lack or absence of acknowledgement of technicians and engineers about the physical phenomena involved on static mixing application. The absence of national technology on this field, demands foreign companies¿ technological dependence, making more difficult more and turning expensive the applications. On the last decade, computational techniques have been used for the design and optimization of these equipments, known as static mixers, specially the computational fluid dynamics ¿ CFD. This research has the goal, by using CFD techniques, to allow a better understanding of the phenomena that determine the fluid flow in static mixers specifically designed for this analysis, permitting to study and suggest modifications and solutions to increase mixing and minimize power consumption on the process. The CFD tool used was the CFX package. The results obtained permitted a good comprehension of the phenomena involved and were in accordance with experimental data available on literature review. Two new geometric concepts of static mixers were created, named EDA and ALETAS, whose performances allow their use on industrial applications. / Mestrado / Desenvolvimento de Processos Químicos / Mestre em Engenharia Química

Misturas

Mistura (Quimica)

Fluidodinâmica computacional (CFD)

Mixing

Statistic mixer

Computational fluid dynamic (CFD)

Estudo da distribuição da temperatura em instalações para a criação de fêmeas suínas em fase de gestação com o uso da fluidodinâmica computacional (CFD) / The CFD technique for the study of the indoor distribution air temperature in pregnant sows facilities

Sabino, Luana Araujo, 1984-

02 June 2015

Orientador: Daniella Jorge de Moura / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Agrícola / Made available in DSpace on 2018-08-27T21:38:28Z (GMT). No. of bitstreams: 1 Sabino_LuanaAraujo_D.pdf: 5594290 bytes, checksum: 53aedcae8886f70448b204ed245f3d66 (MD5) Previous issue date: 2015 / Resumo: Um dos principais problemas no interior de instalações de criação animal é o controle do ambiente por meio ventilação, sendo de grande importância para a qualidade aérea e conforto térmico de verão e inverno, principalmente em regiões de clima tropical. O uso de técnicas para o estudo do ambiente avança a cada dia em qualidade e precisão dos resultados. Uma das novas técnicas é a modelagem computacional que auxilia, de forma rápida, a solução de diversos problemas, mesmos os complexos, com baixo custo, em comparação com métodos experimentais. Sendo assim, o objetivo deste projeto será de validar um modelo computacional de Fluidodinâmica Computacional (Computational Fluid Dynamics ¿ sigla em inglês, CFD) com o uso da geoestatística e com o cálculo do erro da variável temperatura de bulbo seco, demonstrando que podem ser utilizadas diferentes metodologias para sua validação. Além disso objetivou-se estudar os efeitos de diferentes malhas no processamento e na qualidade dos resultados obtidos, apresentando ou sugerindo uma metodologia para estudos futuros / Abstract: In animal production, the major problem of animal facilities is the internal temperature control through ventilation systems. This is responsible for maintaining proper air quality and thermal comfort for the animals during the summer and winter conditions, especially in regions with tropical climate. The environment at studies using new techniques, such as Computational Fluid Dynamics (CFD) has became more popular due to the quality and precision of the results. In this respect, the computational modelling is a powerful tool to help in the solution of several problems, including complex ones, with reduced cost when compared with experimental methods. Thus, the goal of this study is to validate a CFD computational model with geostatistics technique and the estimation of the error of the dry bulb temperature prediction by the model in order to validate the CFD model. It also, analyses the effect of different meshing methods in the results, developing thus way a methodology for future researches / Doutorado / Construções Rurais e Ambiencia / Doutora em Engenharia

Fluidodinâmica computacional (CFD)

Ventilação

Validação

Suíno - Criação

Temperatura

Computational fluid dynamic (CFD)

Ventilation

Validation

Swine - Breeding

Temperature