Your search keyword '"Takeo KAJISHIMA"' showing total 320 results

1. Direct numercal simulation for focused acoustic field with water surface rising by underwater ultrasonic wave

Author

Masaya ORISAKI and Takeo KAJISHIMA

Subjects

ultrasonic atomization, ultrasonic fountain, focusing, numerical simulation, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

The focused acoustic field formed under the water surface raised by ultrasound exposure was numerically investigated to elucidate the relationship with the surface rising prior to ultrasonic atomization. The effect of surface tension was newly added to the computational scheme constructed in the previous paper (Orisaki and Kajishima, 2022) and the direct numerical simulation based on compressible fluid dynamics was conducted. The water surface above the sound source rises. When the risen surface shape changes into a dome due to the effect of surface tension, the acoustic antinode with strong focusing appears inside the dome and the water surface begins to rise rapidly. In case of the insufficient sound source pressure, the gentle risen surface is kept, and acoustic peak spots remain deep due to the small curvature of the surface. These results suggest that the dome formation increases the acoustic pressure amplitude at the dome center and promotes acoustic cavitation there. On the dome surface, the kinetic energy density with the phase opposite to acoustic pressure increases, which causes the increase in the acoustic radiation pressure.

Published

2024

2. Numerical analysis of water surface rising caused by underwater ultrasonic wave

Author

Masaya ORISAKI and Takeo KAJISHIMA

Subjects

ultrasonic fountain, numerical simulation, acoustic radiation pressure, acoustic streaming, resonance, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

When an underwater ultrasonic wave is emitted toward an air-water interface, the water surface rises and droplets are generated from the formed fountain. The rising process of water surface was numerically investigated for better understanding the mechanism of ultrasonic fountain prior to the atomization. To analyze the water surface rising that occurs in a very short time, it is necessary to simulate the rapid increase of acoustic radiation pressure and the rapid development of acoustic streaming. Therefore, the direct numerical simulation based on compressible fluid dynamics was carried out. The water surface rising as observed in the formation process of ultrasonic fountain was successfully reproduced. In the region between sound source and water surface, standing wave is established and acoustic kinetic energy density increases significantly while water surface rises with acceleration. The kinetic energy density is associated with the acoustic radiation pressure acted on free surface based on the theory of Yosioka-Kawasima (1955). After the rising speed becomes to be constant, the standing wave fades and the kinetic energy density decreases. These results suggest that the acoustic radiation pressure acted on water surface increases significantly due to temporary resonance and water surface rises rapidly. By drawing a fluid due to rapid rising of water surface, acoustic streaming is induced toward the risen region.

Published

2022

3. Meandering airflows beneath the underbody of a train model including bogie (LES of large-scale flow structure around real-shaped train model)

Author

Koji NAKADE, Atsushi IDO, and Takeo KAJISHIMA

Subjects

railway, high-speed train, underbody flow, meandering airflow, large-eddy simulation, wind tunnel test, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

In this study, a large-eddy simulation (LES) is conducted to investigate meandering airflows generated throughout the underbody of a real-shaped train model in open air. In our previous study, this was shown by an LES of airflows around a simplified train model. The shape of the underbody affects the flow. However, thus far, no systematic analyses that consider bogies have been conducted. Our experimental results qualitatively reproduced the power spectra of lateral velocity fluctuations in the underbody obtained using a 1:8.4-scale train model on a moving belt in a wind tunnel. Results on the effects of various bogie shapes suggested that the meandering flow was primarily affected by the time-averaged profile of streamwise velocity. Thus, the effects of the bogie shape on airflow are considerable. Comparing bogie shapes with and without a side cover, that without a side cover generated meandering airflow with a slightly smaller peak frequency than that with a side cover, and a completely smooth bogie generated no meandering airflows. It was confirmed that this LES was useful as a technical tool to develop measures to reduce meandering airflows around high-speed trains.

Published

2021

4. Mechanism of aerodynamic force generation concerning train vibration in tunnel (LES of large-scale flow structure around simplified train model)

Author

Koji NAKADE, Yutaka SAKUMA, and Takeo KAJISHIMA

Subjects

railway, high-speed train, tunnel, aerodynamic force, large-eddy simulation, gap vortex streets, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

To clarify the mechanisms underlying airflow-induced vibrations of high-speed trains running through tunnels, large-eddy simulation of a large-scale flow structure around a simplified 6-car train model was conducted. Since actual trains run on one of the double track lines, the position of the train model was made to deviate from the tunnel center and hence the gap between one of the sides of the train and the tunnel wall is narrower than that of the other side. A train running in the open air was also calculated for comparison. The results of this study shed light on the generation mechanism of the pressure fluctuations acting on the side of high-speed trains as follows. Firstly, in the open air, the air velocity in the space between the underbody and the ground gradually decreases from the head toward the tail of the train. Thus, the air velocity is slower than that on both sides of the train, which generates shear flows near the bottom edges of both sides of the train. The shear flows cause large Karman vortex-like vortices (staggered Karman vortex street), which in turn lead to a meandering airflow beneath the underbody of the train. Secondly, in the tunnel, the air velocity not only in the gap between the underbody and the ground but also in the narrower gap between the side of the train and the tunnel wall gradually decreases from the head toward the tail of the train. In the same mechanism as the open air, a meandering airflow is generated throughout the side and underbody of the train and causes pressure fluctuations along the side of the train. Finally, it is demonstrated that the wavelength of pressure fluctuations along the side of the actual train can be estimated from the present LES results.

Published

2020

5. The unsteady simulation for turbulent cavitating flow around a hydrofoil at a low angle of attack

Author

Kie OKABAYASHI, Takuya INAOKA, Wenyang LUO, and Takeo KAJISHIMA

Subjects

cavitation, turbulent flow, hydrofoil, large-eddy simulation, cfd, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Large-eddy simulation (LES) of the cavitating turbulent flow around a hydrofoil was conducted. Especially, we focused on the improvement of the reproducibility of the hydrofoil performance under the condition of cavitation when considering the unsteadiness of the flow field sufficiently by LES. The analysis object is the cavitating turbulent flow around a Clark-Y11.7% hydrofoil at the angle-of-attack of 2 degrees. The weak compressibility was taken into account in the governing equation. The cavitation is represented by the cavity source based on the homogeneous fluid model. For LES, the subgrid scale (SGS) eddy viscosity was determined by solving the transport equation of SGS kinetic energy. Typical patterns of cavitation that was observed experimentally for various cavitation number were successfully reproduced: e.g., attached sheet cavitation of steady as well as unsteady modes. The reproducibility of the cavitation characteristics of the hydrofoil was improved in comparison with that by previous Reynolds-averaged turbulence models. In addition, by reducing the cavitation number, the slight increase of lift coefficient was observed before the breakdown. These are due to the streamline curvature around the sheet cavity. We found this feature is related to the unsteady motion of large-scale spanwise vortices. LES revealed that the vortices are intermittently generated by the baroclinic torque originated from the onset of sheet cavitation.

Published

2019

6. Direct numerical simulation of turbulent flow above zigzag riblets

Author

Kie Okabayashi, Kenshi Hirai, Shintaro Takeuchi, and Takeo Kajishima

Subjects

Physics, QC1-999

Abstract

We investigate the drag-reducing performance of a zigzag riblet inspired by the “Miura fold” and its influence on the streamwise vortices above a wall-bounded turbulent flow through direct numerical simulations of channel flows. The employed channel wall geometries are a flat plate, straight riblet, and zigzag riblet. The drag-reducing performance of various zigzag riblets with adjusted configuration parameters is superior or at least comparable to that of the straight riblet. We assume an analogy between the drag reduction mechanisms of spatially periodic forcing and the zigzag riblet, because both methods induce similar sinusoidal velocity profiles. To investigate the characteristics of the zigzag riblets, we apply a conditional sampling technique to the near-wall streamwise vortices that is also applied to the wall-bounded flow under spatially periodic forcing. The flow toward the wall of the rotating motion of a vortex becomes relatively small, as the main flow levitates at the tips of the zigzag riblet. Thus, the ejection increases and the sweep decreases. In the phase where the direction of the induced spanwise velocity coincides with the vortical motion, the latter is weakened because the vortex tilts in the spanwise direction at the phase; then, vortex stretching is suppressed. The zigzag riblet can reduce the drag via a mechanism analogous to active control, such as periodic oscillation. However, the effect of the upward flow is dominant above the zigzag riblet, and the analogous mechanisms are less remarkable. The considered zigzag riblet has potential application as a kind of active feedback control.

Published

2018

7. SIMULATION OF FLUID-STRUCTURE INTERACTIONBASED ON AN IMMERSED-SOLID METHOD

Author

Takeo Kajishima and Shintaro Takeuchi

Subjects

Computational mechanics, finite difference method, finite element method, deformable solid, multiphase flow, Mechanical engineering and machinery, TJ1-1570, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

A new method for studying the interaction between an elastic object and a fluid has been developed. The fluid phase including solid interface is solved by our immersed solid method of body-force type. In the present study, the fluid-solid interaction force is incorporated into the finite-element method. This process is done by a superposition of the hydrodynamic force field with the solid internal force field. The inter-phase momentum exchange is implemented through the distributed force field shared by both Eulerian and moving Lagrangian references. In this paper, we demonstrate the recent results of our conservative momentum exchange algorithm for the fluid flow bounded by elastic walls. Examples include two-dimensional flows through a gap between modeled vocal cords, and some three-dimensional demonstrations.

Published

2013

8. Transition from Rotating Cavitation to Cavitation Surge in a Two-Dimensional Cascade

Author

Byungjin AN and Takeo KAJISHIMA

Subjects

cavitation instability, rotating cavitation, cavitation surge, inducer, numerical simulation, Science (General), Q1-390, Technology

Abstract

Cavitation instability in the turbo-pump can be divided into two different stages: the local instability such as the rotating cavitation and the system instability such as the cavitation surge. In our study, a numerical analysis of cavitating flow in a two-dimensional cascade, which represents the tip region in an inducer of liquid-fuel rocket engine, was conducted to find an indicator of the onset of cavitation surge. The response characteristic of cavitating flow field to three types of inflow boundary conditions was examined: steady inflow, inflow with sinusoidal fluctuation and inflow considering the characteristic of piping system. The last one is modeled by the unsteady Bernoulli's equation. Various cavitation modes that cause local instability and system instability were reproduced by considering flow rate variation in piping system. It is found that the specific mode, which is hidden behind the fluctuation of rotating cavities, is to be developed to the cavitation surge. The frequency of the surge was confirmed to be in the experimentally observed range and the ratio of the surge frequency to the propagating frequency, which is generated by rotating cavitaion, is almost constant while inflow changes.

Published

2013

9. Numerical study on the aerodynamics of an airfoil moving close to an air-water interface

Author

Yasuaki KANEKO, Takeshi OMORI, and Takeo KAJISHIMA

Subjects

wig, heaving airfoil, unsteady lift force, air-water interface, navier-stokes equation, cip method, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

This study investigates the aerodynamics of an airfoil which passes close to an air-water interface with heaving motions by means of numerical simulation. Simulations are performed by solving the Navier-Stokes equation on a curvilinear coordinate system whose axes fit the moving airfoil surface in contrast to the conventional approaches which neglect the air viscosity. The air-water interface is captured by a CIP method. We show the crucial importance of taking the air viscosity into account for the successful prediction of the airfoil aerodynamics in heaving motions by demonstrating the observation of vortex separations near the leading edge of a NACA0012 airfoil at the Reynolds numbers of 50000 and 66138 based on the viscosity and the density of air and the translational velocity of the airfoil. It is found in this study that the existence of the water surface has a significant impact on the lift force on the heaving NACA0012 airfoil and the deviation of the lift coefficient from the one measured in the simulation conducted in the open space depends not only on the clearance between the airfoil and the water surface but on the mean angle of attack and the phase of the heaving. When the airfoil moves close to the surface, the surface effect on the airfoil-aerodynamics is emphasized due to the squeezed-film damping and the interaction of the separated vortices and the air-water interface. The importance of analyzing the fluid motion of both air and water phases is illustrated by showing that the kinetic energy of the moving airfoil transferred through the the air-water interface is rather significant.

Published

2016

10. Higher-order non-linear scheme of finite-difference lattice Boltzmann method (Evaluation by direct numerical simulation of turbulent channel flow)

Author

Yuichi KUNISHIMA, Takeo KAJISHIMA, and Michihisa TSUTAHARA

Subjects

finite-difference lattice boltzmann method, turbulent chennel flow, higher-order scheme, nonlinear upwind scheme, direct numerical simulation, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

The resolution and efficiency of the finite-difference lattice Boltzmann method (FDLBM) is improved to deal with wall-bounded turbulence, which is characterized by the strong shear and anisotropy. FDLBM puts the merit of LBM, which is the explicit and non-iterative algorithm, into practice on the body-fitted coordinate in the conventional solvers based on Navier-Stokes equation of motion. Thus the performance of FDLBM is mostly affected by the finite-difference scheme for the advection terms of LBM, which has to be an upwind one from a stand point of numerical stability. Particularly in this study, the influences of the the order of accuracy and upwind method are assessed by the direct numerical simulation of fully-developed turbulent flow in a plane channel. We introduce a discretization method with numerical flux similar to the finite-volume method, and a nonlinear scheme which localizes the effect of the numerical diffusion. Our method successfully reproduced the mean velocity and turbulence statistics in comparison with standard database. We confirmed that the nonlinear scheme improved the resolution. Increase of reproducibility with the higher order scheme surpassed increment of its computational cost. The 7th-order scheme, for example, provided a comparable result to that by the 3rd-order scheme using 4 times finer grid, though the calculation time increases just 20 % at the same resolution. This higher-order nonlinear scheme proposed in this study, by reducing the requirement of computational resources, can extend the applicability of LBM for DNS and LES of turbulent flows.

Published

2016

11. Development of numerical method for mass transfer from a buoyant bubble under a high Schmidt number condition

Author

Rihito ADACHI, Takeshi OMORI, and Takeo KAJISHIMA

Subjects

comuputational fluid dynamics, multiphase flow, volume-of-fluid method, bubble, mass transfer, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Under a high Schmidt number condition, concentration boundary layers get much thinner than momentum boundary layers. Resolution requirement to numerically capture the steep concentration gradient near an interface is therefore significantly high. This article presents a novel VOF-based method to predict mass transfer from gas-liquid interfaces using a computational grid of a marginal resolution required for the solution of the Navier-Stokes equation. The solution procedure to the mass conservation equation is divided into two steps: the dissolution and diffusion step and the advection step. The concentration profiles near gas-liquid interfaces, which are identified as segments (in case of two-dimensional computations) in each computational cell, are reconstructed in terms of the complementary error function by virtue of the boundary layer approximation to the solution of the unsteady advection-diffusion equation of mass. The amount of dissolution from the interfaces and diffusion in the vicinity of the interfaces is obtained by taking advantage of the reconstructed concentration profile on each interface segment. In the advection step, the un-smoothness of concentration profiles in the interface cells is explicitly taken into consideration by taking full advantage of a VOF advection scheme. The present method is validated in two-dimensional test problems with the Schmidt number of 100 which cover a pure diffusion problem and a mass transfer problem from a freely rising buoyant bubble. The validation shows the present method is capable of resolving a concentration boundary layer which is as thin as a computational cell. The reduction rate in the overall computational cost is O(10-3) compared to one of the conventional methods (Ezu et al., 2011) without the subgrid-scale resolution.

Published

2016

12. Numerical Simulation of Flow with Phase Change Using Phase Boundary Conditions Based on the Kinetic Theory of Gases

Author

Tsubasa OHSHIMA and Takeo KAJISHIMA

Subjects

phase change, numerical simulation, multi-phase flow, kinetic theory of gases, heat transfer, Science (General), Q1-390, Technology

Abstract

A numerical method for liquid-vapor two-phase flows accompanied by condensation/evaporation is proposed. The phase change model at the vapor-liquid interface, which had been theoretically derived by Sone and Onishi, is coupled with an interface capturing scheme. The model gives the condensation/evaporation rate as boundary conditions. The interface is captured by the volume-of-fluid method associated by the reconstruction scheme, and the scheme to obtain the pressure with consideration for thermodynamics in the vicinity of the interface is employed. These methods are coupled and arranged on the cylindrical coordinate system to appropriately deal with the liquid film flow around a cool cylinder in a natural convection of vapor. The development of a liquid film due to the condensation, the flow in a thin layer and a drop of the distilled liquid are successfully reproduced in our result. The influence of the volumetric conservation is confirmed by comparing the results of condensation case and a non-condensation case. Besides the Nusselt number is in good agreement with a theoretically estimated value.

Published

2012

13. Investigation of Interaction between Vortices and Cavitation in a Turbulent Shear Layer

Author

Takashi OHTA, Hiroki SAKAI, Kie OKABAYASHI, and Takeo KAJISHIMA

Subjects

cavitation, vortex, shear layer flow, turbulent flow, numerical simulation, Science (General), Q1-390, Technology

Abstract

We performed numerical simulations of a non-steady separated shear layer with and without cavitation to examine the effect on flow dynamics. Particular focus was given to the interaction between vortices and cavitation. In the simulations, streamwise and spanwise vortices generated by the instability of a shear layer flow, typical features in such a flow field, were formed further upstream in cavitating than in non-cavitating flows. In cavitating flows, the vortex shedding frequency and the Reynolds stresses increase, and we observed vortex weakening caused by cavitation. We found that a Burgers-type vortex can become the origin of a cavity. Contrarily, the growth of the cavity attenuates the corresponding vortex. We described this influence of a cavity on a streamwise vortex with a simple inviscid model.

Published

2011

14. Evaluation of Aircraft Cabin Air Quality Considering Breath by People on Board

Author

Hidefumi SAITO and Takeo KAJISHIMA

Subjects

air quality, inhalation air, unsteady flow, large-eddy simulation, immersed boundary method, oxygen concentration, Science (General), Q1-390, Technology

Abstract

For the application to optimal design and effective operation of air-conditioning system in an aircraft cabin, we propose an indicator to represent the air quality. It was derived from the result of the large-eddy simulation (LES) of turbulent flow with the immersed boundary (IB) method, which took into account the respiration of passengers. The cabin air quality is defined as an oxygen concentration of inhalation air (OCIA) per each breath. Degree of air renewal in reference volume is a dominant factor of air quality, OCIA. Intensity of time-averaged velocities by cross-sectional components closely correlates with the degree of the air replacement, and becomes the most suitable indicator of air quality. In case of decrease of the intensity, each of two different flow conditions, namely stagnation and circular flow just around a mouth, was found out at the reference volume as inactivation elements of the air renewal.

Published

2011

15. Modeling of the Subgrid-Scale Pressure Distribution in Turbulent Mixing Layer

Author

Kie OKABAYASHI and Takeo KAJISHIMA

Subjects

turbulent flow, pressure fluctuation, large-eddy simulation, mixing layer, cavitation, Science (General), Q1-390, Technology

Abstract

Attention was focused on the statistical properties of pressure fluctuation, which is caused by fine-scale vortices in turbulent flow. The aim is improvement in the prediction of cavitation inception due to fine-scale turbulence vortices, which are usually in subgrid-scale (SGS) in Large-eddy simulation (LES). We conducted a finely-resolved direct numerical simulation (DNS) of a spatially-developing turbulent mixing layer in cavitating and non-cavitating (single-phase) conditions. The result under cavitating condition suggested that low-pressure region corresponding to the core of fine-scale vortices could become an origin of cavitation. We applied filtering technique to DNS database under non-cavitating condition to model the low-pressure region of subfilter vortices observed in result under cavitating condition. Filtering volume is corresponding to that in the probable LES. In fully developed turbulence, proportional relation was found out between intensity of SGS pressure fluctuation and turbulent kinetic energy. In addition, Gaussian profile reasonably approximated instantaneous pressure distribution within a filtering volume. We therefore think the possibility of cavitation inception can be accurately estimated by using the intensity of SGS kinetic energy in couple with filtered pressure field.

Published

2011

16. Analysis of Non-steady Separated Turbulent Flow in an Asymmetric Plane Diffuser by Direct Numerical Simulations

Author

Takashi OHTA and Takeo KAJISHIMA

Subjects

flow separation, negative pressure gradient, diffuser, turbulence, coherent structure, direct numerical simulation, Science (General), Q1-390, Technology

Abstract

Direct numerical simulations (DNS) of turbulent flow through an asymmetric plane diffuser, consisting of a flat wall and an inclined wall, were performed using a high-order finite difference method, to reveal the relationship between turbulence and flow separations under negative pressure gradients. A typical feature of this flow field is the non-steady three-dimensional separation region formed near the inclined wall. At the opening of the diffuser, low speed streaks in wall turbulence cause the initial non-steady separation layer, which includes small-scale reverse flow regions. Because turbulent eddies growing from this initial separation suppress the separated flow, a small reattachment section is formed downstream. When turbulent eddies start to decay and the negative pressure gradient begins to dominate, the flow separates again, and then a large-scale separation region is formed. In summary, the intensity of turbulent eddies affects the formation of the separation and reattachment regions near the inclined wall.

Published

2010

17. LES of Turbulent Flow in Subchannel and Analysis of Driving Force of Secondary Flow

Author

Tsutomu IKENO and Takeo KAJISHIMA

Subjects

secondary flow, turbulent flow, computational fluid dynamics, finite difference method, internal flow, Science (General), Q1-390, Technology

Abstract

The mechanism of secondary flow was discussed based on a result of LES of turbulent flow in a subchannel. The LES was carried out on the Cartesian grid system using an improved immersed boundary method developed for accurate simulation of complex wall boundary of industrial interest. The method was verified by comparing the LES with a DNS of turbulent flow in a pipe. The LES for the subchannel reasonably reproduced the secondary flow of the second kind. To analyze the mechanism of the secondary flow, a theoretical method was proposed. The result of the analysis indicated that main source of the secondary flow was a non-conservative component of Reynolds stress as was the case for a square duct. The theory suggested that the non-conservative force corresponds to an imbalance between pressure along the wall and Reynolds stress decreasing rapidly near the wall. The present theory will unify an understanding between secondary flows of the first and second kind. The present LES technique and theory are useful for investigating physics in turbulent flow bounded by complex walls.

Published

2007

18. Numerical Investigation of Turbulent Flows in a Rotating Channel: Transient States After the Onset of Rotation

Author

Yohei INOUE and Takeo KAJISHIMA

Subjects

turbulence, rotating flow, direct numerical simulation, unsteady flow, transient states, Science (General), Q1-390, Technology

Abstract

The direct numerical simulations of turbulent flow in a rotating channel are executed, with the attention on a transient state after an onset of the rotation. Some different rotation numbers which contain 0, 0.5, 1, 2.5 and 5 are tested. To clarify a relationship between rotation numbers and the alteration of turbulence structures, we paid notice to temporal evolutions of wall friction velocities on both sides, volume-averaged velocity, kinetic energy and its production and dissipation. We found that the time evolutions of flow rates indicate non-monotonic behaviors due to the system rotation. The major reason of it is the difference in response of wall friction velocities on both walls. Moreover, we applied an analysis based on the theory of the invariants of Reynolds stress tensor to associate the status of turbulence with turbulence structures. From the result of the analysis, the three-dimensionality of turbulence is emphasized by the system rotation except for the vicinity of the wall on the pressure side. On the suction side, however, flow field indicates the feature of two-dimensionality.

Published

2007

19. Efficient Immersed Boundary Method for Strong Interaction Problem of Arbitrary Shape Object with the Self-Induced Flow

Author

Yoshihiko YUKI, Shintaro TAKEUCHI, and Takeo KAJISHIMA

Subjects

immersed boundary method, fluid-solid interaction, non-spherical object, surface digitiser, computational fluid dynamics, Science (General), Q1-390, Technology

Abstract

An immersed boundary method is improved and applied to 2-D flow fields involving a single stationary/moving object. The present immersed boundary method employs a body force proportional to a solid volume fraction for coupling the solid and fluid motions at the interface. A hyperbolic-tangent function is newly introduced as a surface digitiser for computing the volume fractions at the interface cells, and this improvement is proved to be efficient for problems involving arbitrary shape object. The present method is applied to a uniform flow field around a circular cylinder and an interaction problem of fluid and free-falling object. The computational results are found to agree with the results by the different methods of the present authors and the results reported in the literatures. Also the computation time is considerably cut down compared to the other methods by the series of improvements to the immersed boundary method.

Published

2007

20. Study on the Navier boundary condition for flows with a moving contact line by means of molecular dynamics simulation

Author

Yuka HIZUMI, Takeshi OMORI, Yasutaka YAMAGUCHI, and Takeo KAJISHIMA

Subjects

dynamic wetting, moving contact line, contact line dynamics, slip velocity, molecular dynamics, navier boundary condition, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

While the Navier boundary condition, which claims the proportionality between fluid slip velocity and wall shear stress (Qian et al., 2003, Bocquet and Barrat, 2007), was established by Thompson and Troian (1997) for a single-phase Newtonian fluid flowing along an atomically defect-less solid wall under a wide range of shear rate conditions, its validity for flows with a contact line has not been proved yet even for the simplest pairing of a monoatomic fluid and a solid with a face-centered cubic structure. In the studies of Qian et al. (2003, 2006) the static wall shear stress was subtracted in the formulation of their Navier boundary condition, but as we show, it is not physically justified. Ren and E (2007) formulated a Navier boundary condition in terms of the fluid slip velocity and wall shear stress integrated through the region containing the contact line in a similar fashion to the present work, providing no physical grounds regarding their particular choice of the integration region and the interfacial region. We performed molecular dynamics simulations of Couette flows where two immiscible liquids with an identical molecular mass and identical interaction potentials were driven by two parallel solid walls so that steady flows with moving contact lines were formed. Based on the detailed analysis of stress tensor and slip velocity distributions both for static and dynamic cases, we show that the Navier boundary condition should be formulated in terms of the quantities integrated through the fluid-fluid interaction region in the first adsorption layer formed on the solid wall. In order to investigate the relevance of the Navier boundary condition as a boundary condition of the Navier-Stokes equation, the validity of Newton's law of viscosity between the first and second adsorption layers is also examined.

Published

2015

21. Development of numerical method for two-phase flow on polyhedral meshes (Part 1, Development of advection scheme and curvature calculation method)

Author

Kohei SUZUKI, Takeshi OMORI, and Takeo KAJISHIMA

Subjects

computational fluid dynamics, two-phase flow, polyhedral mesh, unstructured mesh, vof, thinc, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Although the advantage of using arbitrarily-shaped polyhedral meshes for the industrial flow applications is clear, their employment to two-phase flows is rather limited due to difficulty in deriving and implementing algorithms without overwhelming complexity on such meshes. We present a numerical method based on the VOF (Volume of Fluid) method which works on arbitrarily-shaped three-dimensional polyhedral meshes with comparable accuracy to the methods for structured meshes. We extend the THINC (Tangent of Hyperbola Interface Capturing) method and the RDF (Reconstructed Distance Function) method respectively, to solve the advection equation of the color function and to estimate the interface curvature on polyhedral meshes without laborious geometric arithmetics.

Published

2015

22. Decay of Swirling Turbulent Flow in Rod-bundle

Author

Tsutomu IKENO and Takeo KAJISHIMA

Subjects

turbulent flow, swirling flow, vortex, les, immersed boundary method, finite difference method, Science (General), Q1-390, Technology

Abstract

An LES was carried out to clarify the mechanism of decaying swirl in a rod-bundle. In our LES, an immersed boundary method was used to treat this complex wall boundary in the Cartesian grid system. A consistent immersed boundary method and a one-equation dynamic SGS model were introduced for an accurate simulation of no-slip wall condition. The Reynolds number based on the bulk velocity, the rod pitch and the kinematic viscosity was approximately 4100. Our computational results were compared well with experimental and computational data obtained in other studies. The results were able to represent the effect of flow geometry: the flow around the mixing-vanes caused the swirl with a large-scale fluctuation enhancing heat transfer; a vortex enhancing enthalpy mixing between channels was produced in the rod gap; this developing vortex and the decreasing wake promoted the decay of the swirl more strongly than in a pipe. The LES technique introduced in this study is useful for designing the spacer by predicting the effect of flow control.

Published

2006

23. Study of Solid-Fluid Interaction in Body-Fixed Non-Inertial Frame of Reference

Author

Shintaro TAKEUCHI, Takahiro YAMAZAKI, and Takeo KAJISHIMA

Subjects

non-inertial frame of reference, body-fixed coordinate, fluid-solid interaction, least square adjustment, free-falling body, quaternion, Science (General), Q1-390, Technology

Abstract

Motion of solid object in fluid is studied in moving frame of reference. Navier-Stokes (N-S) equations in a non-inertial frame of reference is coupled with the equations of linear and angular momentums for the solid object. It is shown that the numerical implementation for solving the non-inertial N-S equations is equivalent to that of the arbitrary Lagrangian-Eulerian (ALE) method. The simulation results by the two methods show reasonable agreements for a 2-D flow field including a cylinder. In the present work, a generalised convective boundary condition is constructed for non-inertial frame of reference. Also, an appropriate boundary condition is proposed for fluid phase based on a least square adjustment (LSA) method. It is shown that the LSA is essential for the non-inertial study fluid-solid interaction. Also, the non-inertial N-S equation is applied to a problem of a concave object falling in a fluid. It is shown that traditional time-advancement schemes undermine the ortho-normality of the rotation matrix, resulting in non-physical deformation of the object. However, our time-advancement procedure with quaternion is found to be robust and effective even under a violent manoeuvre of the object.

Published

2006

24. Large eddy simulation of weakly compressible turbulent flows around an airfoil

Author

Changhwa HAN and Takeo KAJISHIMA

Subjects

large eddy simulation, one-equation subgrid scale model, low mach number flows, channel, naca0012 airfoil, Science (General), Q1-390, Technology

Abstract

The purpose of this study is to develop a numerical method for turbulent flows at low Mach number range. To account for the weak compressibility, we modify the time marching method of the usual incompressible scheme which is based on the elliptic equation for pressure. To deal with high Reynolds number flows appropriately, we propose a new one-equation subgrid scale model (SGS). In this model, the concept of coherent structure function model is introduced to treat the energy transfer from grid scale to SGS portion of turbulence kinetic energy. The feature of our one-equation SGS model is that the energy production rate of SGS kinetic energy is calculated without the dynamic procedure, and any parameters such as the friction velocity on the wall or distance from the wall are not necessary. The new one-equation SGS model is incorporated into the weakly compressible scheme to treat a small density variation. Computational examinations have been conducted for fully developed turbulent flows in a plane channel and turbulent flows around NACA0012 airfoil at low Mach number, and have shown satisfactory results. We show that the consideration of the density variation even in low Mach number flows is essential to reproduce the pressure fluctuation and vortical structure appropriately.

Published

2014

25. Computations of flows with phase change by implicit coupling of vof method and boundary conditions based on kinetic theory

Author

Tsubasa OHSHIMA and Takeo KAJISHIMA

Subjects

phase change, numerical simulation, multi-phase flow, kinetic theory of gases, condensation, heat transfer, Science (General), Q1-390, Technology

Abstract

We developed a practical method for the computation of liquid-vapor two-phase flows accompanied by phase change at the interface. In this paper, we propose an intrinsic improvement by introducing a boundary condition at the non-equilibrium interface, which was derived by Sone and Onishi (Journal of the Physical Society of Japan, Vol.44, (1978),pp.1981-1994.) on the basis of the kinetic theory of gases. The boundary condition, which gives the relationship between the phase change rate and the jump in physical properties, was appropriately integrated with a numerical simulation based on continuum mechanics. The interface was captured by the volume-of-fluid (VOF) method with the piecewise linear interface construction (PLIC) scheme to improve the conservation property of volume. This method was applied to simulating film condensation around a horizontal cylinder. Our results showed that heat and fluid phenomena, including condensation to a liquid film, were successfully reproduced. The order of the spatially averaged Nusselt number on the cylinder was in good agreement with the theoretical value. We compared the results of our method with those of a method that obtains the phase change rate without considering the boundary condition on a molecular scale. We found that our method was effective at simulating film condensation.

Published

2014

26. Low dissipative finite difference hybrid scheme by discontinuity sensor of detecting shock and material interface in multi-component compressible flows.

Author

Kazuki Koga and Takeo Kajishima

Published

2022

27. Interaction problem between fluid and membrane by a consistent direct discretisation approach.

Author

Shintaro Takeuchi, Hiroki Fukuoka, Jingchen Gu, and Takeo Kajishima

Published

2018

28. Semi-explicit large eddy simulation in non-reacting air/gas fuel jet flows

Author

Kazuki Koga and Takeo Kajishima

Subjects

General Medicine

Published

2023

29. A numerical method for interaction problems between fluid and membranes with arbitrary permeability for fluid.

Author

Suguru Miyauchi, Shintaro Takeuchi, and Takeo Kajishima

Published

2017

30. A consistent direct discretization scheme on Cartesian grids for convective and conjugate heat transfer.

Author

Norikazu Sato, Shintaro Takeuchi, Takeo Kajishima, Masahide Inagaki, and Nariaki Horinouchi

Published

2016

31. Coupled Simulation of Flow and Chemical Reaction with Finite Reaction Rate for Decarburization of Molten Iron using Gas Jet of Carbon Dioxide

Author

Tetsuya Yamamoto, Takeshi Omori, and Takeo Kajishima

Subjects

Mechanics of Materials, Mechanical Engineering, Materials Chemistry, Metals and Alloys

Published

2022

32. Large Eddy Simulation Study on the Relationship Between Large-Scale Turbulence Vortices and Unsteady Cavitation Around a Hydrofoil

Author

Kie Okabayashi, Ayumu Furukawa, Takeshi Otsu, and Takeo Kajishima

Subjects

Mechanical Engineering

Abstract

We conducted a large eddy simulation (LES) of cavitating turbulent flow around a Clark-Y11.7% hydrofoil at an angle of attack of 8 deg. We focused on the improvement of the reproducibility of hydrofoil performance under cavitating conditions when considering the unsteadiness of the flow field sufficiently by LES. A homogeneous cavitation model was adopted. The subgrid-scale model for LES was the one-equation dynamic model. The unsteady phenomena such as cavity oscillation and cloud cavity shedding accompanied by the reentrant jet were simulated. Large-scale spanwise vortices were also captured, which occurred intermittently from the onset of the sheet cavity. Then, the flow inside the sheet cavity was de-accelerated and the streamlines went around the sheet cavity. Streamline curvature formed a separation bubble behind the sheet cavity accompanied by a low-pressure region. Thus, the sheet cavity length was sufficient and the reproducibility of the pressure distribution around the hydrofoil and lift coefficient were improved.

Published

2023

33. A numerical method for mass transfer by a thin moving membrane with selective permeabilities.

Author

Suguru Miyauchi, Shintaro Takeuchi, and Takeo Kajishima

Published

2015

34. Flow Rate Prediction for a Semi-permeable Membrane at Low Reynolds Number in a Circular Pipe

Author

Shuji Yamada, Takeo Kajishima, Shintaro Takeuchi, Asahi Tazaki, and Suguru Miyauchi

Subjects

Materials science, Membrane permeability, General Chemical Engineering, Reynolds number, Péclet number, Mechanics, Catalysis, Volumetric flow rate, symbols.namesake, Viscosity, symbols, Osmotic pressure, Semipermeable membrane, Concentration polarization

Abstract

A concise and accurate prediction method is required for membrane permeability in chemical engineering and biological fields. As a preliminary study on this topic, we propose the concentration polarization model (CPM) of the permeate flux and flow rate under dominant effects of viscosity and solute diffusion. In this model, concentration polarization is incorporated for the solution flow through a semi-permeable membrane (i.e., permeable for solvent but not for solute) in a circular pipe. The effect of the concentration polarization on the flow field in a circular pipe under a viscous-dominant condition (i.e., at a low Reynolds number) is discussed by comparing the CPM with the numerical simulation results and infinitesimal Péclet number model (IPM) for the membrane permeability, strength of the osmotic pressure, and Péclet number. The CPM and IPM are confirmed to be a reasonable extension of the model for a pure fluid, which was proposed previously. The application range of the IPM is narrow because the advection of the solute concentration is not considered, whereas the CPM demonstrates superior applicability in a wide range of parameters, including the permeability coefficient, strength of the osmotic pressure, and Péclet number. This suggests the necessity for considering concentration polarization. Although the mathematical expression of the CPM is more complex than that of the IPM, the CPM exhibits a potential to accurately predict the permeability parameters for a condition in which a large permeate flux and osmotic pressure occur.

Published

2021

35. Large-Eddy Simulation of Unsteady Pitching Aerofoil using a Oneequation Subgrid Scale (SGS) Model based on Dynamic Procedure

Author

Takeo Kajishima and Firdaus Mohamad

Subjects

Mechanical Engineering

Abstract

Large-Eddy Simulations (LES) for an oscillating NACA0012 aerofoil at Reynolds number 1.35 × 105 have been performed to investigate the capability of a new approach of a One-equation SGS model. The phenomena of the oscillating aerofoil at higher amplitude angle (𝛼𝑎𝑚𝑝) is believed to produce deep dynamic stall in which strong non-equilibrium turbulence could also visible. Hence, a new approach of a one-equation SGS model is proposed where the coefficient of production term in the kSGS transport equation is defined dynamically. From the simulations, the leading-edge vortex (LEV), dynamic stall vortex (DSV), shedding mechanism and trailing edge vortex (TEV) are captured in this study.

Published

2021

36. Mechanism of aerodynamic force generation concerning train vibration in tunnel (LES of large-scale flow structure around simplified train model)

Author

Takeo Kajishima, Yutaka Sakuma, and Koji Nakade

Subjects

Aerodynamic force, Vibration, Mechanism (engineering), Scale (ratio), business.industry, Computer science, Flow (psychology), Structure (category theory), Structural engineering, business

Published

2021

37. Meandering airflows beneath the underbody of a train model including bogie (LES of large-scale flow structure around real-shaped train model)

Author

Takeo Kajishima, Atsushi Ido, and Koji Nakade

Subjects

Scale (ratio), Flow (psychology), Geology, Bogie, Marine engineering

Published

2021

38. Anisotropic Reaction Force Model in Two-way Coupling Simulation for a Smaller Particle Than Grid Spacing Based on Volume Averaging

Author

Takeo Kajishima, Shintaro Takeuchi, and Toshiaki Fukada

Subjects

Physics, Computer simulation, General Chemical Engineering, Surface stress, General Physics and Astronomy, Mechanics, Physics::Fluid Dynamics, Boundary layer, Reaction, Particle, Potential flow, Physical and Theoretical Chemistry, Shear flow, Smoothing

Abstract

In the framework of local volume-averaging for two-way coupling simulation of particle-laden flows, we have developed a force model that represents the particle reaction to the fluid. By considering the stress profile on the surface of finite size particles, our previous model was capable of representing the reaction force distribution even without fully resolving the boundary layer around the particle of comparable size to the grid spacing. In our method, the anisotropy of the surface stress is reasonably taken into account in the reaction force. To extend the applicability for particles smaller than the grid spacing, a smoothing method is developed in a consistent way with the discretization of the numerical simulation. The effectiveness of the smoothing method is demonstrated by applying to the following four fundamental fluid-particle interaction problems; a stationary particle in a uniform flow, a moving particle in a vortical flow, a rotating particle in fluid at rest and a particle suspension in a shear flow. The anisotropic contribution of the reaction force is reasonably represented by the smoothing method applied to the volume averaging technique particularly for rotating particle case. For the suspension in the shear flow, the non-physical effect of the grid size is suppressed by the smoothing method. Therefore, the developed reaction force model is effective for the case that the effects of shear and rotation are dominant.

Published

2020

39. The immersed boundary projection method for the slip boundary condition

Author

Takehiro Fujii, Takeshi Omori, and Takeo Kajishima

Subjects

Projection method, Boundary (topology), Geometry, Boundary value problem, Slip (materials science), Geology

Published

2020

40. Fluid Permeation through A Membrane with Infinitesimal Permeability under Reynolds Lubrication

Author

Takeo Kajishima, Asahi Tazaki, Ryo Onishi, Shintaro Takeuchi, Suguru Miyauchi, and Lucy T. Zhang

Subjects

Materials science, Applied Mathematics, Mechanical Engineering, Numerical analysis, Pressure discontinuity, Mechanics, Linear analysis, Permeation, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, 010101 applied mathematics, Permeability (earth sciences), Membrane, Lubrication, 0103 physical sciences, Discrete-forcing immersed boundary method, Semipermeable membrane, 0101 mathematics, Permeable membrane, Tangential and normal components

Abstract

This article has been published in a revised form in Journal of Mechanics [https://doi.org/10.1017/jmech.2020.38]. This version is published under a Creative Commons CC-BY-NC-ND. No commercial re-distribution or re-use allowed. Derivative works cannot be distributed. © 2020 The Society of Theoretical and Applied Mechanics., To understand the lubrication-dominated permeation through a membrane, numerical simulations of permeation through a moving corrugated permeable membrane is carried out with a fully validated numerical method. Through comparisons between the numerical results and the results of an asymptotic analysis of permeate flux (under an infinitesimal permeability condition) using Reynolds lubrication equation, the effect of permeation on lubrication and its inverse effect (i.e., the dependence of permeation on lubrication) are discussed. The linear and nonlinear dependences of the relaxation of the lubrication pressure due to membrane permeation are identified. The effect of the tangential component of the permeate flux is evaluated by a linear analysis, and the limitation of Reynolds-type lubrication is discussed.

Published

2020

41. Finite-difference immersed boundary method consistent with wall conditions for incompressible turbulent flow simulations.

Author

Tsutomu Ikeno and Takeo Kajishima

Published

2007

42. Lubrication pressure model in a non-negligible gap for fluid permeation through a membrane with finite permeability

Author

Shuji Yamada, Takeo Kajishima, Toshiaki Fukada, Shintaro Takeuchi, and Suguru Miyauchi

Subjects

Fluid Flow and Transfer Processes, Physics::Biological Physics, Range (particle radiation), Materials science, Component (thermodynamics), Computational Mechanics, Mechanics, Derivative, Permeation, Quantitative Biology::Subcellular Processes, Condensed Matter::Soft Condensed Matter, Physics::Fluid Dynamics, Membrane, Permeability (electromagnetism), Modeling and Simulation, Lubrication, Permeate flux

Abstract

Shintaro Takeuchi, Toshiaki Fukada, Shuji Yamada, Suguru Miyauchi, and Takeo Kajishima, "Lubrication pressure model in a non-negligible gap for fluid permeation through a membrane with finite permeability", Physical Review Fluids, 6(11), 114101, https://doi.org/10.1103/PhysRevFluids.6.114101., The membrane permeation of a fluid occurring near the wall is strongly influenced by lubrication because the generated pressure accelerates the fluid passing through the membrane. In the present study, the membrane permeation of a pure fluid driven by the lubrication pressure is modeled for a general wall-membrane geometry to understand the effect of permeability on the permeate flux in a range of wall-membrane gap widths that cannot be treated by the Reynolds lubrication equation. This lubrication effect (referred to as the non-Reynolds lubrication effect) is modeled by including a higher-order pressure component described by the wall-tangential derivative of the local Couette-Poiseuille velocity, and a permeate flux model with the non-Reynolds lubrication effect is developed. The permeation model is validated with a corrugated membrane placed in a two-dimensional parallel channel with a fixed aspect ratio (i.e., the average wall-membrane distance to the longitudinal membrane length) of 0.1. The permeation driven by the lubrication pressure between the membrane and wall is studied by varying the nondimensional permeability. At an infinitesimal permeability, the permeate flux model shows good agreement with the fully resolved numerical simulation owing to the comparable contribution of the Couette and Poiseuille components in the permeation model, whereas the permeation model exhibits a diverging trend at finite permeabilities because the Couette component in the model produces an excessive contribution to the lubrication pressure. However, by applying a simplified renormalization procedure to the Couette component into the lowest-order pressure component, the diverging trend is suppressed and the permeate flux in a finite permeability range is reproduced. The applicability of the renormalization-group permeation model is discussed in terms of the conditions of the wall-membrane gap and permeability range.

Published

2021

43. A relation between membrane permeability and flow rate at low Reynolds number in circular pipe

Author

Shintaro Takeuchi, Takeo Kajishima, Suguru Miyauchi, and Asahi Tazaki

Subjects

Physics::Biological Physics, Materials science, Membrane permeability, Reynolds number, Filtration and Separation, 02 engineering and technology, Mechanics, Immersed boundary method, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, 0104 chemical sciences, Volumetric flow rate, Pipe flow, Physics::Fluid Dynamics, Permeability (earth sciences), symbols.namesake, Compressibility, symbols, General Materials Science, Semipermeable membrane, Physical and Theoretical Chemistry, 0210 nano-technology

Abstract

A relation between membrane permeability to a pure solvent and flow rate is derived in a circular pipe driven by a constant pressure difference across the pipe length. Membrane is assumed to be non-deformable and zero thickness, and the permeate flux of pure solvent due to pressure discontinuity across the flat membrane is coupled with the governing equations for incompressible Newtonian fluid in the Stokes regime. The permeation flow rate (normalised by that of the Hagen-Poiseuille flow for the no-membrane case or with a membrane of infinite permeability) is represented as a function of a non-dimensional permeability including the aspect ratio of the pipe geometry. The relation is established through comparison with a fully-validated numerical simulation result: the numerical discretisation is based on our original discrete-forcing immersed boundary method, which guarantees (i) conservations of mass and momentum even in the immediate vicinity of the membrane surface and (ii) consistency between incompressible velocity and pressure fields. Inverse analysis of the above formula yields the permeability as function of the flow rate through the pipe, comprising three equations covering the entire permeability ranges. The established permeability formulae are expected to be useful for identifying effective permeabilities of membrane to single-component fluid or pure solvent in practical applications.

Published

2019

44. Estimation of fluid forces on a spherical particle for two-way coupling simulation based on the volume averaging

Author

Toshiaki Fukada, Shintaro Takeuchi, and Takeo Kajishima

Subjects

Fluid Flow and Transfer Processes, Length scale, Volume averaging, Physics, Coupling, Field (physics), Mechanical Engineering, General Physics and Astronomy, 02 engineering and technology, Radius, Mechanics, Function (mathematics), 01 natural sciences, 010305 fluids & plasmas, 020303 mechanical engineering & transports, 0203 mechanical engineering, Volume (thermodynamics), 0103 physical sciences, Particle

Abstract

The relationship between the flow field numerically obtained by the two-way coupling simulation and the fluid force on each particle is discussed. For estimating the fluid force on a particle, the effect of the disturbance by the particle needs to be considered. In the present study, for a particle located in a steady ambient flow, the fluid force is modelled as a function of the averaged velocity and pressure over an explicitly-defined averaging volume in the disturbed field. The gradients of the pressure and velocity induced by the particle are also modelled. It is found that the discretised gradients are almost independent of the distance between the reference points for sufficiently small distances. This fact makes the gradient models independent of the grid width of the two-way coupling simulation. The proposed steady viscous force model implicitly includes the correction terms due to the strain of the undisturbed flow and the history effect as the model is constructed with the disturbed flow. For the radius of the averaging volume smaller than 5 times the particle radius, the present force estimation method based on the disturbed flow particularly works well. The results suggest that the present method is effective in the two-way coupling simulation with the particles of comparable size to the minimum length scale of the background flow.

Published

2019

45. Vortical flow patterns by the cooperative effect of convective and conductive heat transfers in particle-dispersed natural convection

Author

Takeo Kajishima, Shintaro Takeuchi, Jingchen Gu, and Toshiaki Fukada

Subjects

Convection, Vortical structure, Materials science, Buoyancy, Convective heat transfer, 02 engineering and technology, engineering.material, Conduction, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, Inhomogeneous media, Heat transfer, 0103 physical sciences, Dense particle-laden flow, Fluid Flow and Transfer Processes, Natural convection, Mechanical Engineering, Rayleigh number, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Thermal conduction, Heat flux, engineering, 0210 nano-technology

Abstract

Cooperative effect of the conductive and convective heat fluxes on the development of vortical structures is studied in a particle-dispersed natural convection. A numerical approach is proposed that visualizes the heat transfer paths through the fluid and finite-volume particles (i.e., non-point particles) to show the spatial extension of the heat fluxes and its influence on the flow field. The approach is applied to a weakly-convective dense particulate system under the Rayleigh number 10 5 containing more than 4000 particles (solid volume fraction 42.8%) of various conductivities. With highly-conductive particles (in comparison to the ambient fluid), local downward convection of a large-scale vortical flow strengthens the conductive heat flux near the bottom hot wall in the counter-convective direction by the increase of the vertical temperature gradient, and the observation of the spatial extension of the heat flux lines indicates that the increase of the solid volume fraction near the hot wall further strengthens the conductive heat flux. The paired upward convection causes strengthened conductive heat flux near the top cold wall by the same increase mechanism. The above interplay of the local heat fluxes in the dense solid-dispersed media are found to influence on the formation and transition of the large-scale vortical structures through the distribution of the moment of buoyancy in a horizontal plane. An analytical model for a low-dimensional vortex system shows that buoyancy gradient and vorticity diffusion could determine the time-development of the large-scale vortical structure.

Published

2019

46. The unsteady simulation for turbulent cavitating flow around a hydrofoil at a low angle of attack

Author

Wenyang Luo, Kie Okabayashi, Takeo Kajishima, and Takuya Inaoka

Subjects

Materials science, Angle of attack, Turbulence, Cavitation, Flow (psychology), Mechanics

Published

2019

47. Understanding the asymmetry between advancing and receding microscopic contact angles

Author

Y. Kobayashi, Yasutaka Yamaguchi, Takeshi Omori, and Takeo Kajishima

Subjects

Materials science, media_common.quotation_subject, Contact line, 02 engineering and technology, General Chemistry, Mechanics, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Asymmetry, 0104 chemical sciences, Fluid density, Physics::Fluid Dynamics, Contact angle, Molecular dynamics, Density distribution, Wetting, 0210 nano-technology, Shear flow, media_common

Abstract

T. Omori, Y. Kobayashi, Y. Yamaguchi, T. Kajishima. Understanding the asymmetry between advancing and receding microscopic contact angles. Soft Matter, 2019, 15(19), 3923-2928. https://doi.org/10.1039/C9SM00521H., By means of molecular dynamics simulation, the advancing and receding microscopic contact angles were analyzed for a shear flow of two mono-atomic fluids confined between parallel non-polar solid walls. We defined the microscopic dynamic contact angle based on the coarse-grained microscopic density distribution of the fluids (the instantaneous interface method [Willard and Chandler, J. Phys. Chem. B, 2010, 114, 1954-1958]) near the moving contact line. We have found that the asymmetric change of fluid density near the wall with respect to the moving contact line results in a different dependence between the advancing and receding contact angles on the contact line velocity in a system where the two fluids across the interface have unequal wettability to the solid wall. This difference between the advancing and receding contact angles leads to different flow resistance caused by the advancing and receding contact lines, which should have impact on the industrial applications of the fine fluid transportation with contact lines.

Published

2019

48. The immersed boundary projection method for the Navier slip boundary condition

Author

Takehiro FUJII, Takeshi OMORI, and Takeo KAJISHIMA

Published

2019

49. Effect of lubrication in the non-Reynolds regime due to the non-negligible gap on the fluid permeation through a membrane

Author

Ryo Onishi, Asahi Tazaki, Shintaro Takeuchi, Shuji Yamada, Takeo Kajishima, Lucy T. Zhang, and Suguru Miyauchi

Subjects

Fluid Flow and Transfer Processes, Membrane, Materials science, Mechanical Engineering, Lubrication, General Physics and Astronomy, Permeation, Composite material

Abstract

To understand lubrication-induced membrane permeation, the effects of permeability and membrane geometry on lubrication pressure and permeate flux are studied in a range of a wall-membrane gap width wherein the effect of lubrication cannot be resolved using the Reynolds lubrication equation. The unresolvable lubrication effect (referred to as the non-Reynolds lubrication effect) is modelled by including a higher-order effect as the wall-tangential variation of the local Couette–Poiseuille velocity. Analytical prediction of the permeate flux is then validated with the fully validated numerical simulation. The result shows that, while the traditional Reynolds lubrication model underestimates the permeate flux, the permeation with the effect of the non-Reynolds lubrication is effectively improved in a small permeability range. Furthermore, the non-Reynolds lubrication model also enables reproduction of the characteristic variation in the permeate flux along the membrane. The effective range of the permeability for the non-Reynolds permeate model is discussed through the order analysis of the pressure terms in the Reynolds and non-Reynolds lubrication regimes.

Published

2021

50. Interaction problem between fluid and membrane by a consistent direct discretisation approach

Author

Hiroki Fukuoka, Jingchen Gu, Shintaro Takeuchi, and Takeo Kajishima

Subjects

Physics and Astronomy (miscellaneous), Discretization, Particle, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, Discrete-forcing, Immersed boundary, 0103 physical sciences, Moving boundary, Boundary value problem, 0101 mathematics, Physics, Numerical Analysis, Applied Mathematics, Numerical analysis, Membrane, Mechanics, Computer Science Applications, Vortex, 010101 applied mathematics, Computational Mathematics, Flow (mathematics), Modeling and Simulation, Compressibility, Vector field, Shear flow

Abstract

Numerical methods for solving the flow around a moving or deforming membrane are developed by employing the ideas of the direct-discretisation of the Navier–Stokes equation even in the immediate vicinity of the object surface and consistent-discretisation of the pressure Poisson equation with the incompressible velocity field (i.e., consistent-coupling) that incorporates the boundary conditions on the surface to the pressure equation. Comparative study of three different discretisation strategies is carried out to highlight the effect of the consistent and direct discretisations. The validity of the present “consistent direct discretisation” is established through comparisons with the analytical solutions for some fundamental shear-driven 2-D flow fields with a moving membrane of flat and corrugated geometries. Also, the flows induced by a membrane of circular geometry (i.e., particle) are compared with the reference numerical results under prescribed motion in a stationary fluid as well as lateral migration in a shear flow. A three dimensional problem is presented for an interaction problem between a spherical particle and Taylor–Green vortices, and the result is verified by comparing with the independently-conducted numerical results. Finally, the method is applied to an interaction problem between the fluid and flexible filament showing strong flapping and snapping motions.

Published

2018