Porous Cylinder Research Articles

Thermal flows around a fully permeable short circular cylinder

Secondary flows and corresponding endwall heat transfer around a fully permeable (porous) short circular cylinder differ from those around an impermeable (solid) cylinder. There exists a through flow which is portion of the mainstream entering the front of the cylinder and exiting at the rear of the cylinder, and the alteration of an adverse pressure gradient along the plane of symmetry that causes three-dimensional boundary layer separation (or forms horseshoe vortices). This study experimentally demonstrates how these distinctive features vary horseshoe vortices, wake patterns, and endwall heat transfer around the porous short circular cylinder. Furthermore, the fluidic effect of the extent of the through-flow that is determined by the permeability of the porous cylinder on downstream heat transfer is discussed.

Normal impact response of a saturated porous cylinder with a penny-shaped crack

The transient response of a saturated porous cylinder containing a penny-shaped crack and subjected to a suddenly applied normal loading is investigated. The general field equations of Biot’s theory are applied in the formulation in conjunction with the Laplace and integral transforms to reduce the mixed boundary-value problem to the solution of Fredholm integral equation of the second kind. A numerical Laplace inversion technique is used, and the time-dependent magnitudes of the local stress field near the crack border measured in terms of the dynamic stress-intensity factor are computed for selected material property values. These results are presented and compared to the results of dry medium to find out the influence of pore fluid and its extent on the dynamic stress-intensity factor.

Disintegration process and performance of a coaxial porous injector

In order to understand the breakup performance of coaxial porous injectors, the sprays of coaxial porous injectors with two different porous material cylinder lengths were compared with those of conventional shear coaxial injectors. To allow comparison, the wall injection lengths were designed to be equivalent to the value of the recess depth. Cold flow sprays were visualized using back-lit photography methods and analyzed quantitatively with a laser diffraction apparatus, in order to study the effects of the momentum flux ratio and Weber number on the breakup for each type of injector. In case of the shear coaxial injector, the large liquid core was observed in low air mass flow rate condition. However, the destabilization of the liquid jet from the coaxial porous injector is almost complete within the inner region, near the injector face plate. Additionally, better breakup performance in low gas flow rate condition was obtained when the porous cylinder length decreased, while the shear coaxial injectors showed better breakup efficiency when the recess length increased. In conclusion, the different breakup process caused by the radial momentum in the inner region of the porous injector disintegrated the liquid core.

Heat transfer in a conical porous cylinder with partial heating

The current work simulates the heat transfer across a porous medium fixed in an annular conical cylinder. The geometry is such that the lower part is conical annulus supporting a regular annular cylinder. The porous medium is fixed between inner and outer radius of conical annular cylinder. The inner radius until conical section is heated with constant temperature Th whereas the outer radius is cooled to isothermal temperature Tc such that Th>Tc. The heat transfer phenomenon in this case can be described by two coupled partial differential equations which are solved using finite element method by using 3-node triangular elements. The heat transfer characteristics in this case are quite different from other geometries being discussed in the literature. It is observed that the fluid flow is stronger in the conical section as compared to the cylindrical part of porous geometry. A very few isothermal lines penetrate into the cylindrical porous region as compared to that of conical section.

Mass removal by oxidation and sublimation of porous graphite during fiber laser irradiation

The various effects of laser heating of carbon materials are key to assessing laser weapon effectiveness. Porous graphite plates, cylinders, and cones with densities of 1.55 to 1.82 g/cm3 were irradiated by a 10-kW fiber laser at 0.075 to 3.525 kW/cm2 for 120 s to study mass removal and crater formation. Surface temperatures reached steady state values as high as 3767 K. The total decrease in sample mass ranged from 0.06 to 6.29 g, with crater volumes of 0.52 to 838 mm3, and penetration times for 12.7-mm-thick plates as short as 38 s. Minor contaminants in the graphite samples produced calcium and iron oxide to be redeposited on the graphite surface. Dramatic graphite crystalline structures are also produced at higher laser irradiances. Significantly increased porosity of the sample is observed even outside the laser-irradiated region. Total mass removed increases with deposited laser energy at a rate of 4.83 g/MJ for medium extruded graphite with an apparent threshold of 0.15 MJ. At ∼3.5 kW/cm2, the fractions of the mass removed from the cylindrical samples in the crater, surrounding trench, and outer region of decreased porosity are 38%, 47%, and 15%, respectively. Graphite is particularly resistant to damage by high power lasers. The new understanding of graphite combustion and sublimation during laser irradiation is vital to the more complex behavior of carbon composites.

An experimental investigation of the oil film distribution in an oil–gas cyclone separator

The film flow behavior in an oil–gas cyclone separator was experimentally studied to improve the separation efficiency in terms of the effect of the oil film on the cylinder wall. The oil film flow pattern was captured using a high-speed camera, and the cylinder wall was divided into seven regions to analyze according to the different oil film flow patterns. Along the cyclone cylinder height, the central part of the cylinder was the main flow area, in which droplet–wall collisions and oil film splashing were severe. Additionally, the oil film’s distribution characteristics under inlet velocities of 14.0, 16.0, and 18.0 m/s were compared, and the results showed that more splashing oil droplets were generated under higher inlet velocity. Moreover, changing the structure of the central channel and outer cylinder slightly changed the oil film’s area and flow pattern but exhibited a weak effect on the oil film thickness and re-entrainment. Then, an improved structure was proposed by adding a porous cylinder to the outer cyclone to avoid the generation of small splashing droplets from the oil film. The performance of the modified separator was measured in a real oil-injected compressor system, which demonstrated higher separation efficiency with no increase in static pressure loss. The separation efficiency increased by up to 2.7%, while the pressure loss decreased by up to 10%. Thus, the improved structure can improve the performance of oil–gas separators by changing the distribution and thickness of the oil film on the cylinder wall.

Mechanics of instability-induced pattern transformations in elastomeric porous cylinders

In this paper, we combine experiments and numerical simulations to investigate the large deformation mechanics of periodically patterned cylindrical structures under uniaxial compression. Focusing on cylinders with a square array of circular pores, we show that their buckling behavior is not only controlled by the porosity (as for the case of the corresponding infinitely large planar structures), but also by the length and thickness of the shell and the number of pores along the full circumference. While infinitely long cylindrical shells only support long wavelength (global) modes, by reducing the length and tuning the thickness, short wavelength (local) modes can be observed. Furthermore, frustrated short wavelength modes are triggered when a local instability is critical, but the buckling pattern is not compatible with the number of pores along the circumference.

Rayleigh limits for effective wavenumbers of randomly distributed porous cylinders. Comparison of explicit and implicit methods

The effective wavenumber of the coherent wave propagating in a fluid containing parallel porous cylinders randomly distributed in space is derived at the Rayleigh limit for (i) explicit formulas: Independent Scattering Approximation (ISA), Waterman and Truell (WT) and Linton and Martin (LM) and (ii) for implicit formulas: Coherent Potential Approximation (CPA) and Generalized Self Consistent Method (GSCM) applied to WT and to LM. The effective mass density and bulk modulus are also derived. The validity of all the effective quantities is checked by recovering, when the porosity of the scatterers tends to zero, the case of an inhomogeneous medium of elastic cylinders.

On the boundary layer structure near a highly permeable porous interface

The method of matched asymptotic expansions is used to study the canonical problem of steady laminar flow through a narrow two-dimensional channel blocked by a tight-fitting finite-length highly permeable porous obstacle. We investigate the behaviour of the local flow close to the interface between the single-phase and porous regions (governed by the incompressible Navier–Stokes and Darcy flow equations, respectively). We solve for the flow in these inner regions in the limits of low and high Reynolds number, facilitating an understanding of the nature of the transition from Poiseuille to plug to Poiseuille flow in each of these limits. Significant analytical progress is made in the high Reynolds number limit, and we explore in detail the rich boundary layer structure that occurs. We derive general results for the interfacial stress and for the conditions that couple the flow in the outer regions away from the interface. We consider the three-dimensional generalization to unsteady laminar flow through and around a tight-fitting highly permeable cylindrical porous obstacle within a Hele-Shaw cell. For the high Reynolds number limit, we give the coupling conditions and interfacial stress in terms of the outer flow variables, allowing information from a nonlinear three-dimensional problem to be obtained by solving a linear two-dimensional problem. Finally, we illustrate the utility of our analysis by considering the specific example of time-dependent forced far-field flow in a Hele-Shaw cell containing a porous cylinder with a circular cross-section. We determine the internal stress within the porous obstacle, which is key for tissue engineering applications, and the interfacial stress on the boundary of the porous obstacle, which has applications to biofilm erosion. In the high Reynolds number limit, we demonstrate that the fluid inertia can result in the cylinder experiencing a time-independent net force, even when the far-field forcing is periodic with zero mean.

Spontaneous emission intensity and anisotropy of quantum dot films in proximity to nanoscale photonic–plasmonic templates

We discuss results on spontaneous emission intensity and lifetime anisotropy of cadmium selenide quantum dot monolayer films placed in close proximity to a porous block copolymer based photonic–plasmonic two dimensional array. The porous block copolymer cylinders can be filled with metal nanoparticles and the concentration of these nanoparticles is varied to control both the photoluminescence intensity and lifetime of a layer of quantum dots placed above the template. Significant emission enhancement is achieved even for the quantum dot layer whose core lies about 1 nm above the template surface. Interestingly, polarised decay lifetime analysis indicates considerable emission anisotropy, as well for these quantum dots. Our results thus demonstrates how such hybrid optical materials can be created with controlled optical properties and suggests extension of this method to other novel two dimensional materials in combination with the photonic–plasmonic template.

New benchmark solutions for transient natural convection in partially porous annuli

Purpose – The purpose of this paper is to focus on the numerical analysis of transient free convection heat transfer in partially porous cylindrical domains. The authors analyze the dependence of velocity and temperature fields on the geometry, by analyzing transient flow behavior for different values of cavity aspect ratio and radii ratio; both inner and outer radius are assumed variable in order to not change the difference ro-ri. Moreover, several Darcy numbers have been considered. Design/methodology/approach – A dual time-stepping procedure based on the transient artificial compressibility version of the characteristic-based split algorithm has been adopted in order to solve the transient equations of the generalized model for heat and fluid flow through porous media. The present model has been validated against experimental data available in the scientific literature for two different problems, steady-state free convection in a porous annulus and transient natural convection in a porous cylinder, showing an excellent agreement. Findings – For vertically divided half porous cavities, with Rayleigh numbers equal to 3.4×106 for the 4:1 cavity and 3.4×105 for the 8:1 cavity, the numerical results show that transient oscillations tend to disappear in presence of cylindrical geometry, differently from what happens for rectangular one. The magnitude of this phenomenon increases with radii ratio; the porous layer also affects the stability of velocity and temperature fields, as oscillations tend to decrease in presence of a porous matrix with lower value of the Darcy number. Research limitations/implications – A proper analysis of partially porous annular cavities is fundamental for the correct estimation of Nusselt numbers, as the formulas provided for rectangular domains are not able to describe these problems. Practical implications – The proposed model represents a useful tool for the study of transient natural convection problems in porous and partially porous cylindrical and annular cavities, typical of many engineering applications. Moreover, a fully explicit scheme reduces the computational costs and ensures flexibility. Originality/value – This is the first time that a fully explicit finite element scheme is employed for the solution of transient natural convection in partially porous tall annular cavities.

A two-phase model for the aqueous outflow through the trabecular meshwork

A two-phase steady-state model for the percolation of aqueous humor through the trabecular meshwork (TM) in eye has been developed. The model treats the meshwork as an annular porous cylinder comprised of two concentric rings that represent the uveal-corneoscleral meshwork and juxtacanalicular meshwork. Both the rings are assumed to be made up of homogeneous, isotropic, viscoelastic material swollen with continuously flowing aqueous humor through the tissue with different structural properties. The model incorporates a strain-dependent permeability function. An analytical solution to the mathematical model has been obtained and the expressions for the displacement and fluid pressure distributions have been derived. The computational results for the displacement in solid phase, the fluid pressure distribution and the dilatation of the ocular tissue material have been presented through the graphs. The effects of structural model parameters on the displacement and the dilatation have also been investigated.

Modeling of fluid flow in periodic cell with porous cylinder using a boundary element method

The problem of viscous incompressible flow past a periodic array of porous cylinders (a model of flow in an aerosol filter) is solved. The approximate periodic cell model of Kuwabara is used to formulate the fluid flow problem. The Stokes flow model is then adopted to model the flow outside the cylinder and the Darcy law of drag is applied to find the filtration velocity field inside the porous cylinder. The boundary value problems for biharmonic and Laplace equations for stream functions outside and inside the porous cylinder are solved using a boundary elements method. A good agreement of numerical and analytical models is shown. The analytical formulas for the integrals in the expressions for the stream function, vorticity and Cartesian velocity components are obtained. It is shown that the use of analytical integration gives considerable advantage in computing time.

Gravity wave interaction with a flexible circular cage system

The present study deals with the hydroelastic analysis of a floating flexible circular cage system in finite water depth under the assumption of small amplitude waves and structural response. The flexible cage system is modeled as a surface-piercing porous flexible cylinder having a flexible porous membrane type bed which is under the action of uniform tension. Using the Fourier-Bessel series solution and least squares approximation method, the mathematical problem is handled for solution by matching the velocity and pressure at the fluid-structure interfaces. Further, the flexible cage system is assumed to be kept fixed at the free surface and the submerged end. The efficiency of the cage system is studied by analyzing the hydrodynamic force, effect of structural porosity and deflections of the flexible walls and bed of the cage system. The findings of the present study are helpful in the design of various types of floating cage system for marine aquaculture which can withstand the wave loads of varied nature at calm water location in the coastal area.

동축형 다공성재 분사기의 분열 메커니즘

동축형 다공성재 분사기에서는 기체가 분사기 중심을 지나는 액체 제트 주위를 둘러싼 다공성재를 통해 액체 제트를 향해 분사된다. 분사 방법의 차이로 인한 전단동축 분사기와 동축형 다공성재 분사기의 분열 메커니즘 차이를 살펴보기 위해, 전단동축 분사기와 동축형 다공성재 분사기를 사용하여 수류시험과 2-D 축대칭 수치해석을 진행하였다. 같은 유량조건에서의 가시화 이미지와 분무 평균입경을 비교하였으며, 수치해석을 통해 분사기 내부에서의 속도 분포가 액체 제트에 어떤 영향을 끼치는지 고찰하였다. 결과적으로, 기체의 유량이 늘어날수록 분사기 내부 속도가 낮음에도 동축형 다공성재 분사기의 미립화 및 혼합 성능이 전단동축 분사기에 비해 유리함을 확인할 수 있었다. In a coaxial porous injector, a gas propellant is injected through the porous cylinder surface to the liquid jet which is encircled by a porous cylinder. In this study, to observe the differences in disintegration mechanisms between a shear coaxial injector and a coaxial porous injector, cold-flow tests and 2-D axisymmetric numerical analysis have been carried out. The shadowgraph images and Sauter mean diameters were compared in similar experimental conditions, and the effects of velocity distributions at the inner injector region on the disintegration of liquid jet were investigated through the numerical calculations. As a result, in high air mass flow rate condition, the disintegration performance of coaxial porous injector is better than shear coaxial injector, in spite of a lower velocity at the inner injector region.

Effect of a Cylindrical Permeable Wall on the Performance of Hydrocyclones

AbstractHydrocyclones are designed for solid‐liquid separation widely used in industry due to their advantages including high separation efficiency. Depending on the purpose desired by the user, it is possible to enhance the performance of the hydrocyclone through the combined use of other unit operations with the hydrocycloning such as filtration. The incorporation effect of a porous cylinder on a hydrocyclone with optimized geometry was studied experimentally. According to the main results, the filtering cylindrical hydrocyclone showed significant average reductions in energy consumption compared to conventional hydrocyclones of the same geometry. Minor differences in terms of total efficiency of the filtering equipment were observed compared to the conventional one.

Circular cylinders with soft porous cover for flow noise reduction

The use of porous materials is one of several approaches to passively control or minimize the generation of flow noise. In order to investigate the possible reduction of noise from struts and other protruding parts (for example components of the landing gear or pantographs), acoustic measurements were taken in a small aeroacoustic wind tunnel on a set of circular cylinders with a soft porous cover. The aim of this study was to identify those materials that result in the best noise reduction, which refers to both tonal noise and broadband noise. The porous covers were characterized by their air flow resistivity, a parameter describing the permeability of an open-porous material. The results show that materials with low air flow resistivities lead to a noticeable flow noise reduction. Thereby, the main effect of the porous cylinder covers is that the spectral peak of the aeolian tone due to vortex shedding appears much narrower, but is not suppressed completely. Based on the measurement results, a basic model for the estimation of the total peak level of the aeolian tone was derived. In addition to the minimization of the vortex shedding noise, a reduction of broadband noise can be observed, especially at higher Reynolds numbers. The noise reduction increases with decreasing air flow resistivity of the porous covers, which means that materials that are highly permeable to air result in the best noise reduction.

Sound propagation around arrays of rigid and porous cylinders in free space and near a ground boundary

Sound propagation through sonic crystals has been widely studied both theoretically and experimentally, because of its potential applications in many areas such as environmental noise barriers and sound cloaking. In this paper, a finite-difference time-domain (FDTD) numerical simulation coupled with the immersed boundary method is used to investigate the transmission properties of sonic crystals modeled as arrays of cylinders. Arrays in free field as well as those arranged above a ground boundary are studied. In the latter case, the cylinder axes are parallel to the ground plane. By comparing with the semi-analytical solutions, the numerical scheme is validated for simple arrays of rigid cylinders. The effects of locations and materials of cylinders, along with the ground effect, are investigated. The results are presented with discussions on achieving optimized sonic crystals for sound blockage.

Experimental and numerical investigations on the flow around and through the fractal soft rocks with water vapor absorption

Previous studies show that the rock–water interaction is one of the critical scientific issues for the soft rocks engineering. In this work, we propose a numerical model to study the flow across a hygroscopic rock cylinder subjected to a uniform flow of vapor–air mixture. To better understand the characteristics of water vapor absorption, dynamic moisture absorption measurements are carried out and a fractal model to describe the particle size distribution (PSD) of the soft rocks is presented. The time-dependent Navier–Stokes equation and the Darcy–Brinkmann–Forchheimer model are respectively adopted for the homogenous fluid region and the porous rock region, while the energy and species equations are used for both the porous and fluid regions. Based on the high order compact finite difference schemes with body-fitted grids, a single-domain approach is devised from above governing equations to describe the flow in both the porous and fluid regions, in which the effects of the hygroscopicity, the fractal dimension, the Darcy and Reynolds numbers on the streamline, flow separation, concentration field and thermal field can be evaluated in detail. Our preliminary simulations show that the hygroscopicity, which suppress the occurrence of recirculating (i.e. the critical Reynolds number of a recirculating wake becomes higher), may have a slight effect on the flow behind the porous rock cylinder in the beginning, and dribble away with increase of the time frame. Specially, the higher the fractal dimension (D), the lower the penetrability and hygroscopicity of soft rocks; the higher the Darcy number (Da) and Reynolds numbers (Re), the more penetration of the flow pattern, thermal field and moisture sorption inside the cylinder as well as the larger size of the concentration plume in the elongated recirculation region. This may help us establish a physically reasonable methodology to systemically assess fluid flow in soft rocks.

Osteogenesis of biomimetic calcium phosphate coating on porous tantalum implants

Event Abstract Back to Event Osteogenesis of biomimetic calcium phosphate coating on porous tantalum implants Huipin Yuan1, 2, 3*, Joost D. De Bruijn2, 4*, Clemens A. Van Blitterswijk1, 4* and Klaas De Groot1, 4* 1 Maastricht University, MERLN Institute, Netherlands 2 Xapnd Biotechnology BV, Biomaterial Research Group, Netherlands 3 Sichuan University, Colleage of Physical Science and Technology, China 4 Twente University, MIRA Institute, Netherlands Introduction: When CaP ceramics were structurally mimicking bone, they positively stimulated bone formation and became osteoinductive[1],[2]. Osteoinductive CaP ceramics could replace autologous bone graft for bone regeneration in critical-sized bone defects[3]. To overcome the brittleness of osteoinductive CaP ceramics for load-bearing application, we developed herein an osteoinductive metal implant using a biomimetic CaP coating technique. Materials and Methods: Porous Tantalum cylinders (HedrocelTM, Implex Corporation), Φ5*10 mm with 75-80% porosity, with highly interconnected pores (600-700 μm), were coated with CaP layer. Firstly, porous tantalum cylinders were soaked in 1000 ml de-ionized watera containing 40.00 g NaCl, 1.84 g CaCl2.2H2O, 1.52 g MgCl2.6H2O, 1.06 g NaHCO3 and 0.86 g Na2HPO4.2H2O in for 24hrs.Thereafter the samples were immersed in 1000 ml de-ionized water consisting 8.00 g NaCl, 0.59 g CaCl2.2H2O and 0.36 g Na2HPO4.2H2O at pH 7.4 buffered with 50 mM TRIS-HCl. Finally the samples were rinsed with de-ionized water and dried. The morphology and the chemical composition of the CaP coating were analyzed with SEM, XRD and EDX. The Ta cylinders with and without CaP coating were implanted ectopically in thigh muscle of 8 dogs for 90 days. The explants were subjected to histological observation and hisotomorphometrical assays after PMMA embedding. BSEM was applied to the PMMA-embedded explants after polishing the cross sections and coated with carbon. Results: SEM showed the surface of coated Ta was fully covered with a CaP layer of ACP (peripheral) and OCP (central). Bone was formed in all coated Ta implants (8 out of 8), while no bone was found in any of un-coated Ta implants (0 out of 8) (Figure 1, A&B). Mineralized bone with bone marrow-like tissue was seen in the central region of coated Ta (Figure 1C). Fibrous soft tissues were noted in centric region of un-coated Ta and peripheral region of coated Ta (Figure 1, A&B). CaP coating was also histologically observed on coated Ta, followed sequentially by mineralized bone, newly formed bone and osteoblast seam (Figure 1,D), indicating a bonding osteogenesis on CaP coating. BSEM showed a close contact between the layers of Tantalum surface, CaP coating and mineralized bone. Quantitatively 13±5% of the pores in the ccoated Ta implants was occupied by mineralized bone. Figure 1. Tissue responses to Tantalum implants in muscle of dogs for 90 days (1% methylen blue and 0.3% basic fuchsin staining). Two histological overviews (A and B) showing bone formation in coated Ta (B) and no bone in un-coated Ta (A), a light microscopic image (C) showing the mineralized bone (MB) and bone marrow-like tissue in the central region of coated implants and an enlargement (D) showing the sequences of tantalum (Ta), CaP coating (cap), mineralized bone (MB), newly formed bone martix (BM) and osteoblast seam (OB). Results and Discussion: By such a biomimetic technique, inner surface of porous metal implants was coated with CaP. Nevertheless, the thickness, the morphology and phase composition of the coating varied from peripheral to the central. It is not clear yet whether the missing of bone close to peripheral region of coated implants is because of the chemistry (OCP at outer surface vs ACP in the central) or the dimension of crystal size (micron scale OCP vs nano or submicron scale ACP), while it is clear that mechanically strong osteoinductive implants could be achieved with biomimetic CaP-coated metals.