Dimensionless Acceleration Research Articles

Transitions to vibro-fluidization in a deep granular bed

Granular media subjected to vibration can approximate fluid behavior with sufficient vibration acceleration. Unlike gas fluidization, the transition from a static bed to a liquid-like state is poorly defined and has primarily studied previously in shallow or 2D granular beds. Three granular states are identified in this work: the static, the quasi-static, and the vibro-fluidized state. These states are characterized for a deep granular bed through quantitative measurements of the power or torque required to rotate a vane within the granular media. In this study, the vane is rotated while the bed is subjected to vibration at 10 Hz with acceleration in the range 0 ≤ Γ = ω 2 x max/g ≤ 4.0. We define a critical dimensionless vibration acceleration, Γ c, based on a dramatic decrease in vane power and the absence of a dynamic zero-shear rate torque, as the transition to vibro-fluidization. Typical of granular materials, significant hysteresis is observed in measuring these bed state transitions. These measurements of “granular rheology” provide a quantitative framework for defining these transitions.

관 내 과도 난류유동에 대한 대형와 모사

Time delay effects on near-wall turbulent structures are investigated by performing a large-eddy simulation of a transient turbulent flow in a pipe. To elucidate the time delay effects on the near-wall turbulence, we selected the dimensionless acceleration parameter which was used in the previous study. Various turbulent statistics revealed the distinctive features of the delay. It was shown that the dynamic Smagorinsky model is valid to capture the alterations of the turbulence physics well. A dimensionless time for the responses of the flow quantities was introduced to give the detailed information on the delay of the nearwall turbulence. The conditionally-averaged flow fields associated with Reynolds shear stress producing events show that sweep and ejections are closely related to the delays of the turbulence production and the turbulence propagation toward the pipe center. The present study suggested that the enhanced anisotropy of the turbulence in the initial and transient stages would be a challenging problem to standard turbulence models.

A Nearly Model-Independent Characterization of Dark Energy Properties as a Function of Redshift

Understanding the acceleration of the universe and its cause is one of the key problems in physics and cosmology today, and is best studied using a variety of mutually complementary approaches. Daly and Djorgovski (2003, 2004) proposed a model independent approach to determine the expansion and acceleration history of the universe and a number of important physical parameters of the dark energy as functions of redshift directly from the data. Here, we apply the method to explicitly determine the first and second derivatives of the coordinate distance with respect to redshift, y ′ and y ″ , and combine them to solve for the kinetic and potential energy density of the dark energy as functions of redshift, K ( z ) and V ( z ) . A data set of 228 supernova and 20 radio galaxy measurements with redshifts from zero to 1.79 is used for this study. Values of y ′ and y ″ are combined to study the dimensionless acceleration rate of the universe as a function of redshift, q ( z ) . The only assumptions underlying our determination of q ( z ) are that the universe is described by a Robertson-Walker (RW) metric and is spatially flat. We find that the universe is accelerating today, and was decelerating in the recent past. The transition from acceleration to deceleration occurs at a redshift of about z T = 0.42 ± 0.06 0.08 . Values of y ′ and y ″ are combined to determine K ( z ) and V ( z ) . These are shown to be consistent with the values expected in a standard Lambda Cold Dark Matter (LCDM) model.

Investigating the use of vertical vibration to recover metal from electrical and electronic waste

Due to the current and future environmental legislation there is a need to develop cleaner technologies for separating materials in the mineral and recycling industries. This paper discusses the use of vertical vibration to recover valuable materials from electrical wastes. Under vertical vibration granular materials segregate by size and/or density. Previous studies have shown that glass/bronze mixtures [Burtally, N., King, P.J., Swift, M.R., Leaper, M., 2003. Dynamical behaviour of fine granular glass/bronze mixtures under vertical vibration. Granular Matter 5, 57–66] and mixed-plastics/bronze mixtures [Mohabuth, N., Miles, N., 2005. The recovery of recyclable materials from Waste Electrical and Electronic Equipment (WEEE) by using vertical vibration separation. Resour. Conserv. Recy. 45, 60–69] can be separated under vibration. This new separation technique is now extended to recover copper from electrical wires and computer circuit boards. The materials were reduced to a granular state and fed into a specially designed semi-batch cell consisting of two chambers. The cell was placed between a pair of sinusoidally driven loudspeakers which induced vibration. Under vibration the denser materials were found to concentrate into the adjacent chamber leaving the rest of the materials in the original chamber. The separation behaviour was studied at different combinations of frequencies and dimensionless accelerations. Assays were also carried out to assess the efficiency of separation. Understanding the separation behaviour in the batch cell will possibly lead to the design information for the future development of a continuous separation system.

Numerical analysis of particle mixing in a rotating fluidized bed

This paper describes the numerical analysis of particle mixing in a rotating fluidized bed (RFB). A two-dimensional discrete element method (DEM) and computational fluid dynamics (CFD) coupling model were proposed to analyze the radial particle mixing in the RFB. Spherical polyethylene particles (Geldart group B particles) were used as model particles under the assumptions that they were cohesionless and mono-disperse with their diameter of 0.5 mm. The validity of the proposed model was confirmed by the comparison between the calculated degree of particle mixing and the experimental one, which was obtained by measuring the lightness of the recorded image taken by a high-speed video camera. Effects of the operating parameters (gas velocity, centrifugal acceleration, particle bed height, and vessel radius) on the radial particle mixing rate were numerically analyzed. The radial particle mixing rate was found to be strongly affected by the bubble characteristics, especially by the bubble size. The mathematical model for the rate coefficient of particle mixing as functions of operating parameters was empirically proposed. The radial particle mixing rate in a RFB could be well correlated by the three dimensionless numbers: dimensionless acceleration ( Ac), bubble Froude number ( Fr b ) , and dimensionless radius on the surface of particle bed ( β s ) .

Stochastic dynamics of a rod bouncing upon a vibrating surface

We describe the behavior of a rod bouncing upon a horizontal surface which is undergoing sinusoidal vertical vibration. The predictions of computer simulations are compared with experiments in which a stainless-steel rod bounces upon a metal-coated glass surface. We find that, as the dimensionless acceleration parameter Gamma is increased appreciably above unity, the motion of a long rod passes from periodic or near-periodic motion into stochastic dynamics. Within this stochastic regime the statistics of the times between impacts follow distributions with tails of approximately Gaussian form while the probability distributions of the angles at impact have tails that are close to exponential. We determine the dependence of each distribution upon the length of the rod, upon frequency, and on Gamma. The statistics of the total energy and of the translational and rotational components each approximately follow a Boltzmann distribution in their tails, the translational and rotational energy components being strongly correlated. The time-averaged mean vertical translational energy is significantly larger than the mean rotational energy, and both are considerably larger than the energy associated with horizontal motion.

Phases of granular segregation in a binary mixture

We present results from an extensive experimental investigation into granular segregation of a shallow binary mixture in which particles are driven by frictional interactions with the surface of a vibrating horizontal tray. Three distinct phases of the mixture are established viz. binary gas (unsegregated), segregation liquid, and segregation crystal. Their ranges of existence are mapped out as a function of the system's primary control parameters using a number of measures based on Voronoi tessellation. We study the associated transitions and show that segregation can be suppressed as the total filling fraction of the granular layer, C, is decreased below a critical value, Cc, or if the dimensionless acceleration of the driving, gamma, is increased above a value gammac.

Instabilities in vertically vibrated granular beds at the single particle scale

The dynamics of granular motion have been studied in a vertically vibrated bed using positron emission particle tracking, which allows the motion of a single tracer particle to be followed in a noninvasive way. The particle movement is closely correlated with the oscillation of the bottom plate. Two types of granular motion have been observed in beds with heap formation: convection and fluctuation. The effects of system parameters, including vibration amplitude, frequency, and bed weight, have been studied. The particle cycle frequency was found to correlate well with the dimensionless acceleration. Cycle frequency appears to be inversely proportional to bed mass. The particle dispersion was determined by following the tracer particle trajectory. The system is highly anisotropic, as the horizontal dispersion is stronger than the vertical dispersion.

DIMENSIONLESS ANALYSIS OF HUMAN LOWER LIMB

This study derives a dimensionless kinematic model using a coordinate transformation matrix to analyze the kinematic characteristics of human lower limb. The lower limb model in this study considers three segments including the thigh, shank and foot, and three joints, namely the hip, knee, ankle and the two extremes of the foot, namely the heel and toe. Based on the dimensionless analysis model ignoring human stature, the kinematic characteristics of lower limb can be described by the relationships of the dimensionless displacements, velocities and accelerations with respect to dimensionless time. The results of an experimental data have shown that dimensionless kinematic characteristics follow the same trends as current gait analysis. This study proposed a dimensionless kinematic model that is capable of analyzing kinematic characteristics of lower limb joints. In the future, this model is anticipated to investigate the dynamics of gait and clinical application.

축 방향 가속을 받는 보 구조물의 동적 안정성 해석

Dynamic stability of an axially accelerating beam structure is investigated in this paper. The equations of motion of a fixed-free beam are derived using the hybrid deformation variable method and the assumed mode method. Unstable regions due to periodical acceleration are obtained by using the Floquet's theory. Stability diagrams are presented to illustrate the influence of the dimensionless acceleration, amplitude, and frequency. Also, buckling occurs when the acceleration exceeds a certain value. It is found that relatively large unstable regions exist around the first bending natural frequency, twice the first bending natural frequency, and twice the second bending natural frequency. The validity of the stability diagram is confirmed by direct numerical integration of the equations of motion.

DIRECT DETERMINATIONS OF THE REDSHIFT BEHAVIOR OF THE PRESSURE, ENERGY DENSITY, AND EQUATION OF STATE OF THE DARK ENERGY AND THE ACCELERATION OF THE UNIVERSE

One of the goals of current cosmological studies is the determination of the expansion and acceleration rates of the universe as functions of redshift, and the determination of the properties of the dark energy that can explain these observations. Here the expansion and acceleration rates are determined directly from the data, without the need for the specification of a theory of gravity, and without adopting an a priori parameterization of the form or redshift evolution of the dark energy. We use the latest set of distances to SN standard candles from Riess et al. (2004), supplemented by data on radio galaxy standard ruler sizes, as described by Daly & Djorgovski (2003, 2004). We find that the universe transitions from acceleration to deceleration at a redshift of zT≈0.4, with the present value of q0=-0.35±0.15. The standard "concordance model" with Ω0=0.3 and Λ=0.7 provides a reasonably good fit to the dimensionless expansion rate as a function of redshift, though it fits the dimensionless acceleration rate as a function of redshift less well. The expansion and acceleration rates are then combined with a theory of gravity to determine the pressure, energy density, and equation of state of the dark energy as functions of redshift. Adopting General Relativity as the correct theory of gravity, the redshift trends for the pressure, energy density, and equation of state of the dark energy out to z~1 are determined, and are found to be generally consistent with the concordance model; they have zero redshift values of p0=-0.6±0.15, f0=0.62±0.05, and w0=-0.9±0.1.

NMR experiments on a three-dimensional vibrofluidized granular medium.

A three-dimensional granular system fluidized by vertical container vibrations was studied using pulsed field gradient NMR coupled with one-dimensional magnetic resonance imaging. The system consisted of mustard seeds vibrated vertically at 50 Hz, and the number of layers N(l)<or=4 was sufficiently low to achieve a nearly time-independent granular fluid. Using NMR, the vertical profiles of density and granular temperature were directly measured, along with the distributions of vertical and horizontal grain velocities. The velocity distributions showed modest deviations from Maxwell-Boltzmann statistics, except for the vertical velocity distribution near the sample bottom, which was highly skewed and non-Gaussian. Data taken for three values of N(l) and two dimensionless accelerations Gamma=15,18 were fitted to a hydrodynamic theory, which successfully models the density and temperature profiles away from the vibrating container bottom. A temperature inversion near the free upper surface is observed, in agreement with predictions based on the hydrodynamic parameter micro which is nonzero only in inelastic systems.

Energy of a single bead bouncing on a vibrating plate: experiments and numerical simulations.

The energy of a single bead bouncing on a vibrating plate is determined in simulations and experiments by tracking the bead-plate collision times. The plate oscillates sinusoidally along the vertical with the dimensionless peak acceleration Gamma, and the bead-plate collisions are characterized by the velocity restitution coefficient epsilon. Above the threshold dimensionless peak acceleration Gamma(s) approximately 0.85, which does not depend on the restitution coefficient, the bead energy is shown to initially increase linearly with the vibration amplitude A, whereas it is found to scale like v(2)(p)/(1-epsilon), where v(p) is the peak velocity of the plate, only in the limit Gamma>>Gamma(s). The threshold Gamma(s) is shown to decrease when the bead is subjected, in simulations, to additional nondissipative collisions occurring with the typical frequency nu(c). As a consequence, the bead energy scales like v(2)(p)/(1-epsilon) for all vibration strengths in the limit nu(c)>>nu(*)(c). From the experimental and numerical findings, an analytical expression of the bead energy as a function of the experimental parameters is proposed.

Determination of dimensionless attenuation coefficient in shaped resonators

The value of the dimensionless attenuation coefficient is an important factor when numerically predicting high-amplitude acoustic waves in shaped resonators. Both the magnitude of the pressure waveform and the quality factor rely heavily on this dimensionless parameter. Previous authors have stated the values used, but have not completely explained their methods of determination. This work fully describes the methodology used to establish this important parameter. Over a range of frequencies encompassing the fundamental resonance, the pressure waves were experimentally measured at each end of the shaped resonators. At the corresponding dimensionless acceleration, the numerical code modeled the acoustic waveforms generated in the resonator using various dimensionless attenuation coefficients. The dimensionless attenuation coefficient that most closely matched the pressure amplitudes and quality factors of the experimental and numerical results was determined and will be used in subsequent studies.

Run-up distances to supersonic flames in obstacle-laden tubes

The problem of the minimum run-up distance for the flame acceleration to supersonic combustion regimes in tubes with obstacles is studied both experimentally and numerically. Experiments were made in an explosion tube equipped with orifice plate obstacles. The tube was of 12-m long with internal tube diameter of 0.35 m. Blockage ratios (BR) of the orifice plates were 0.3, 0.45, 0.6 and 0.75. Hydrogen mixtures were used in the tests. The process of the flame acceleration in a geometry, which is similar to the experimental one, was studied numerically in a series of 3D gasdynamic simulations. It was found both in the tests and in the simulations that characteristic distance of the flame acceleration decreases with the increase of the blockage ratio and with the increase of the mixture reactivity (burning rate). A simple analytical model is proposed, which describes the evolution of the flame shape in the channel with obstacles. The dimensionless flame acceleration distance is determined in the model, which accounts for BR, laminar burning rate, and sound speed in combustion products.

Ordering dynamics of striped patterns in vertically vibrated granular layers

We experimentally studied the process of pattern formation in granular layers. Ten layers of granular materials inside a vacuum container were placed under a vertical vibration of A sin 2πft . Control parameters were the dimensionless acceleration Γ= A(2 πf) 2/ g and vibration frequency f. When the system was quenched from a flat pattern state to a striped pattern state by instantly increasing Γ, there were more than 10 4 periods before a full steady striped pattern appeared. This non-equilibrium and non-steady process showed dynamic scaling behavior, where the growth exponent of the ordered domain was 0.25, which agrees with that of the Swift–Hohenberg system. Furthermore, dependency of the ordering process on Γ was studied.

Coarsening dynamics of striped patterns in thin granular layers under vertical vibration.

The process of pattern formation in granular layers was experimentally studied. Ten layers of granular materials inside a vacuum container were placed under a vertical vibration of A sin2pi f t. Control parameters were the dimensionless acceleration Gamma = A(2pi f)(2)/g and vibration frequency f. When the system was quenched from a flat pattern state to a striped pattern state by instantly increasing Gamma, there were more than 10(4) periods before a full steady striped pattern appeared. This nonequilibrium and nonsteady process showed dynamic scaling behavior. The growth exponent of the characteristic length scale of the ordered domain was 0.25, which agrees with that of the Swift-Hohenberg system.

Granular friction, Coulomb failure, and the fluid-solid transition for horizontally shaken granular materials.

We present the results of an extensive series of experiments, molecular dynamics simulations, and models that address horizontal shaking of a layer of granular material. The goal of this work was to better understand the transition between the "fluid" and "solid" states of granular materials. In the experiments, the material-consisting of glass spheres, smooth and rough sand-was contained in a container of rectangular cross section, and subjected to horizontal shaking of the form x=A sin(omega(t)). The base of the container was porous, so that it was possible to reduce the effective weight of the sample by means of a vertical gas flow. The acceleration of the shaking could be precisely controlled by means of an accelerometer mounted onboard the shaker, plus feedback control and lockin detection. The relevant control parameter for this system was the dimensionless acceleration, Gamma=Aomega(2)/g, where g was the acceleration of gravity. As Gamma was varied, the layer underwent a backward bifurcation between a solidlike state that was stationary in the frame of the shaker and a fluidlike state that typically consisted of a sloshing layer of maximum depth H riding on top of a solid layer. That is, with increasing Gamma, the solid state made a transition to the fluid state at Gamma(cu) and once the system was in the fluid state, a decrease in Gamma left the system in the fluidized state until Gamma reached Gamma(cd)<Gamma(cu). In the fluidized state, the flow consisted of back and forth sloshing at the shaker frequency, plus a slower convective flow along the shaking direction and additionally in the horizontal direction transverse to the shaking direction. Molecular dynamics simulations show that the last of these flows is associated with shear and dilation at the vertical sidewalls. For Gamma<Gamma(cu) and in the solid state, there was a "gas" of free particles sliding on the surface of the material. These constituted much less than one layer's worth of particles in all cases. If these "sliders" were suppressed by placing a thin strip of plastic on the surface, the hysteresis was removed, and the transition to fluidization occurred at a slightly lower value than Gamma(cd) for the free surface case. The hysteresis was also suppressed if a vertical gas flow from the base was sufficient to support roughly 40% of the weight of the sample. Both the transition to the fluid state from the solid and the reverse transition from the fluid to the solid were characterized by similar divergent time scales. If Gamma was increased above Gamma(cu) by a fractional amount epsilon=(Gamma-Gamma(cu))/Gamma(cu), where epsilon was small, there was a characteristic time tau=Aepsilon(-beta) for the transition from solid to fluid to occur, where beta is 1.00+/-0.06. Similarly, if Gamma was decreased below Gamma(cd) in the fluidized state by an amount epsilon=(Gamma-Gamma(cd))/Gamma(cd), there was also a transient time tau=Bepsilon(-beta), where beta is again indistinguishable from 1.00. In addition, the amplitudes A and B are essentially identical. By placing a small "impurity" on top of the layer, consisting of a heavier particle, we found that the exponent beta varied as the impurity mass squared and changed by a factor of 3. A simple Coulomb friction model with friction coefficients mu(k)<mu(s) for the fluid and solid states predicts a reversible rather than hysteretic transition to the fluid state, similar to what we observe with the addition of the small overload from a plastic strip. In an improved model, we provide a relaxational mechanism that allows the friction coefficient to change continuously between the low and high values. This model produces the hysteresis seen in experiments.

Surface Instability of a Vertically Oscillating Granular Layer

In the study of the surface instability of a vertically oscillatinggranular layer, we obtained experimentally the phase diagram for thesurface states of the layer in the driving frequency-accelerationplane, and measured the dispersion relation for the surface wavesin a granular layer in comparison to that in viscous fluids. Ourexperiments show that the onset dimensionless acceleration increaseswith the driving frequency, and the wavelength of the surface wavesincreases with the depth of granular layer. These experimentalresults are in agreement with our theoretical model qualitatively.

Self-diffusion analysis in a vibrated granular bed

Abstract The influences of flow parameters on self-diffusion in a vibrated granular bed were studied by simulation and experiment. Employing image processing technology and a particle tracking method, the local displacements and velocities of particles were measured. The self-diffusion coefficients were determined from the history of particles' diffusive displacements. Discrete element method simulation was performed to calculate the particles' self-diffusive displacements. The simulation results were compared to the experimental tests. The flow behavior of convection rolls in a vibrated bed occurred by the particles' self-diffusion induced by the energy input from vertical external vibration. The velocity fluctuations, granular temperature and self-diffusions were anisotropic with greatest components in the vertical direction. The dependence of the diffusion coefficients on the dimensionless acceleration amplitude, vibration amplitude, vibration frequency, velocity fluctuations, granular temperature, vibration velocity, restitution coefficient and solid fraction are discussed.