Your search keyword '"Juray De Wilde"' showing total 27 results

1. The Ultra-Fast Oxidation Rate of a Synthetic Fe-Based Oxygen Carrier: Experiment and Simulation Study

Author

Zirui He, Florent Minette, and Juray De Wilde

Subjects

History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering

Published

2022

2. Structured ZoneFlow™-Bayonet steam reforming reactor for reduced firing and steam export: Pressure drop and heat transfer modelling and evaluation of the reactor performance

Author

Florent Minette, Luis Calamote de Almeida, Jonathan Feinstein, Juray De Wilde, UCL - SST/IMMC/IMAP - Materials and process engineering, Research and Innovation Centre for Process Engineering - ReCIPE, and ZoneFlowTM Reactor Technologies

Subjects

Steam methane reforming, Chemical engineering, Structured reactor, Heat recovery, Heat transfer, TP155-156, General Medicine, Pressure drop

Abstract

The ZoneFlow™ reactor is an annular structured reactor that offers lower pressure drop and significantly better heat transfer than standard pellets used in Steam Methane Reforming. The annular ZoneFlow™ reactor is particularly suited for use in a bayonet configuration. The produced syngas then returns via the central tube, the so-called bayonet, allowing counter-current heat exchange between the return gas and the gas reacting in the ZoneFlow™ reactor. As such, the heat supplied by the furnace can be maximally used for the reactions and steam export can be reduced. To intensify the heat transfer between the gas in the bayonet and in the annulus, an insert is installed inside the bayonet, forming a second annulus that forces the gas to flow close to the bayonet wall at high velocity. In the present work, the pressure drop and heat transfer resulting from various bayonet configurations are experimentally measured at commercial scale reactor dimensions and air flow rates equivalent to commercial conditions. Correlations for the friction factors and the heat transfer coefficients are derived from the data. The correlations are then used to simulate a commercial scale ZoneFlow™-bayonet reactor and optimize the design.

Published

2022

3. Multi-scale modeling and simulation of low-pressure methane bi-reforming using structured catalytic reactors

Author

Juray De Wilde, Florent Minette, and UCL - SST/IMMC/IMAP - Materials and process engineering

Subjects

Materials science, General Chemical Engineering, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, Industrial and Manufacturing Engineering, Methane, chemistry.chemical_compound, Coating, Environmental Chemistry, Process engineering, Pressure drop, business.industry, Drop (liquid), Multi-scale modeling, General Chemistry, Coke, Sstructured catalytic reactors, 021001 nanoscience & nanotechnology, Thermal conduction, 0104 chemical sciences, Methane bi-reforming, Pilot plant, chemistry, Heat transfer, engineering, 0210 nano-technology, business

Abstract

Methane bi-reforming has gained interest recently for its potential of converting CH4 and CO2 into chemicals while avoiding catalyst deactivation by coke formation. Recycling CO2 produced can be considered, but introduces constraints on the allowable pressure drop over the reactor. The latter is particularly the case in low-pressure processes, such as those encountered in the steel industry. The paper reports on a multi-scale modeling approach for a structured catalytic reactor that offers lower pressure drop than classical pellets while improving heat transfer. The use of a thin catalytic coating furthermore improves the catalyst effectiveness. The coupled CFD-reaction model accounts for the details of the reaction mechanism and kinetics, intra-catalyst transport and the details of the flow pattern. Radiative heat transfer and thermal conduction in the reactor tube walls and in the reactor internals coated with catalyst are also taken into account. Several scale-bridging strategies have to be introduced and combined to allow a computationally tractable solution. This requires a variety of detailed experimental data, an aspect that is also discussed. The coupled CFD-reaction model was first validated using data from a bi-reforming pilot plant and then used to evaluate the performance of a structured reactor under typical commercial process conditions and to study optimization of the reactor design and potential increase in capacity.

Published

2021

4. Simulation of the flow past random arrays of spherical particles: Microstructure-based tensor quantities as a tool to predict fluid–particle forces

Author

Baptiste Hardy, Olivier Simonin, Juray De Wilde, Grégoire Winckelmans, UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, UCL - SST/IMMC/IMAP - Materials and process engineering, and Institut de Mécanique des Fluides de Toulouse

Subjects

Fluid Flow and Transfer Processes, Mechanical Engineering, General Physics and Astronomy, Fluid-particle force, Particle-resolved flow simulation, Microstructure, Fabric tensor

Abstract

A recent challenge in the modeling of particle flows is to build microstructure-informed drag models to overcome the average description of the fluid-particle force in the drag force correlations currently used in Euler-Lagrange and Euler-Euler models. To that end, we study through particle- resolved direct numerical simulations (PR-DNS) the flow past random assemblies of mono-dispersed spherical particles at three particle Reynolds numbers (10, 50, 100) and four solid volume fractions (0.10, 0.20, 0.30, 0.40). The present methodology is validated against theoretical and numerical results for the mean drag force in Stokes flows and finite Reynolds numbers flows. PR-DNS results are then used to characterize in details the statistics of the force distribution over the particle array, highlighting the substantial dispersion of the fluid force along the streamwise and transverse directions. The microstructure formed by the solid phase is described by means of a limited number of tensor quantities inspired from the fabric tensor used in granular media. Significant correlations are identified between the force experienced by a given particle immersed in a random array and a few key quantities that describe the anisotropy of its neighbourhood. A microstructure-based multi-linear model is proposed and validated against independent test cases. The model appears to perform best in the viscous and dense regimes. The addition of a stochastic contribution to the model allows to recover the correct level of force fluctuations at the cost of a lower correlation between the model and the data.

Published

2022

5. Pressure drop and heat transfer of ZoneFlowTM structured catalytic reactors and reference pellets for Steam Methane Reforming

Author

Sanjiv Ratan, Florent Minette, Luis Calamote de Almeida, and Juray De Wilde

Subjects

Pressure drop, Materials science, Atmospheric pressure, General Chemical Engineering, Pellets, 02 engineering and technology, General Chemistry, Mechanics, Heat transfer coefficient, equipment and supplies, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Nusselt number, Industrial and Manufacturing Engineering, 0104 chemical sciences, Steam reforming, Heat transfer, Environmental Chemistry, 0210 nano-technology, Casing

Abstract

Structured catalytic reactors have the potential to combine reduced pressure drop and improved heat transfer compared to conventional pellets. In the present study, the pressure drop and heat transfer coefficient between the tube wall and the process gas were measured experimentally for annular structured ZoneFlow TM reactors of different design and for two commercial reference pellets. The ZoneFlow TM reactors differ by the design of the central rod that supports the near-wall annular casing. The experiments were carried out in a 1 m long reactor, at atmospheric pressure and with air flow rates from 70 to 330 Nm 3 /h. To measure the heat transfer coefficient, the furnace was set at a constant temperature that was varied in the range 100–500 °C and the axial profiles of the tube wall and gas temperatures were measured. Using the experimental data, correlations for the friction factor and the Nusselt number were derived and the introduced parameters estimated using non-linear regression. A correlation for the static contribution to heat transfer for the structured reactors was derived from 3D numerical simulations. The correlations were then used to evaluate the pressure drop–heat transfer advantage of the structured reactors compared to the reference pellets at typical industrial steam methane reforming conditions. The data show that ZoneFlow TM reactors can provide a roughly doubled heat transfer coefficient at comparable pressure drop than the tested reference pellets. Furthermore, modification of the central rod support structure was found an efficient way to balance the pressure drop–heat transfer advantage of ZoneFlow TM reactors using an identical design casing.

Published

2021

6. Coarse-grained discrete particle simulations of particle segregation in rotating fluidized beds in vortex chambers

Author

Tingwen Li, Juray De Wilde, Vikrant Vijay Verma, UCL - SST/IMMC/IMAP - Materials and process engineering, US Department of Energy - National Energy Technology Laboratory, and AECOM

Subjects

Rotating fluidized bed, Range (particle radiation), geography, geography.geographical_feature_category, Particle segregation, Chemistry, General Chemical Engineering, Discrete particle method, Segregation, 02 engineering and technology, Mechanics, Vortex chamber, 021001 nanoscience & nanotechnology, Inlet, Vortex, Volumetric flow rate, 020401 chemical engineering, Coarse-grained DPM, Particle, Discrete particle, 0204 chemical engineering, 0210 nano-technology, Porosity, Simulation

Abstract

Vortex chambers allow the generation of rotating fluidized beds, offering high-G intensified gas-solid contact, gas-solids separation and solids-solids segregation. Focusing on binary particle mixtures and fixing the density and diameter of the heavy/large particles, transient batch CFD-coarse-grained DPM simulations were carried out with varying densities or sizes of the light/small particles to evaluate to what extent combining these three functionalities is possible within a vortex chamber of given design. Both the rate and quality of segregation were analyzed. Within a relatively wide density and size range, fast and efficient segregation takes place, with an inner and slower rotating bed of the lighter/small particles forming within the outer and faster rotating bed of the heavier/large particles. Simulations show that the contamination of the outer bed with lighter particles occurs more easily than contamination of the inner bed with heavier particles and increases with decreasing difference in size or density of the particles. Bubbling in the inner bed is observed with an inner bed of very low density or small particles. Porosity plots show that vortex chambers with a sufficient number of gas inlet slots have to be used to guarantee a uniform gas distribution and particle bed. Finally, the flexibility of particle segregation in vortex chambers with respect to the gas flow rate is demonstrated.

Published

2017

7. Experimental study of the application of rotating fluidized beds to particle separation

Author

Justin Weber, Juray De Wilde, Richard C. Stehle, Ronald W. Breault, UCL - SST/IMMC/IMAP - Materials and process engineering, US Department of Energy - National Energy Technology Laboratory, and Oak Ridge Institute for Science and Education

Subjects

Fluidization, Rotating fluidized bed, Petroleum engineering, Chemistry, General Chemical Engineering, Bubble, High-G, Ash separation, 02 engineering and technology, Mechanics, Chemical looping, 021001 nanoscience & nanotechnology, Separation process, 020401 chemical engineering, Process intensification, Fluidized bed, Drag, Mass transfer, Heat transfer, 0204 chemical engineering, Carbon capture, 0210 nano-technology, Chemical looping combustion

Abstract

Rotating fluidized beds provide a unique opportunity to exploit fluidization under higher particle forces. The centripetal force in a rotating fluid bed is typically on the order of 10 times the force of gravity. Since the force keeping the particles in the unit is larger, the drag force can also be larger, allowing for higher gas and slip velocities. This operating regime provides intensified gas-solids contact through higher mass transfer, heat transfer, gas throughput, and bubble suppression. One application for using a rotating fluidized bed is in Chemical Looping Combustion (CLC). When solid fuels are used, oxygen carrier and ash are mixed in the process. In order to maintain high carbon capture efficiencies and recyclability of the oxygen carrier, the ash needs to be separated from the oxygen carrier. This separation can be done aerodynamically since the oxygen carrier is larger and heavier than the ash. It is theorized that rotating fluidized beds could improve both the gas-solid and solid-solid separation process efficiency and throughput as compared to conventional fluidized beds. A 43 cm diameter, 2.5 cm long vortex chamber has been designed and constructed to investigate the application to particle separation. A series of experiments have been performed to investigate the separation of different binary mixtures of solids. These experiments demonstrate the use of a rotating fluidized bed for high-G intensified particle separation that can be combined with high-G intensified gas-solids contact and gas-solids separation.

Published

2017

8. Qualitative numerical study of simultaneous high-G-intensified gas–solids contact, separation and segregation in a bi-disperse rotating fluidized bed in a vortex chamber

Author

Sofiane Benyahia, Juray De Wilde, and George A. Richards

Subjects

geography, Materials science, geography.geographical_feature_category, Meteorology, business.industry, General Chemical Engineering, 02 engineering and technology, Mechanics, Computational fluid dynamics, 021001 nanoscience & nanotechnology, Inlet, Vortex, Volumetric flow rate, Physics::Fluid Dynamics, 020401 chemical engineering, Eddy, Mechanics of Materials, Fluidized bed, Chimney, Fluidization, 0204 chemical engineering, 0210 nano-technology, business

Abstract

Coupled discrete particle method – computational fluid dynamics simulations are carried out to demonstrate the potential of combined high-G-intensified gas–solids contact, gas–solids separation and segregation in a rotating fluidized bed in a static vortex chamber. A case study with two distinct types of particles is focused on. When feeding solids using a standard solids inlet design, a dense and uniform rotating fluidized bed is formed, guaranteeing intense gas–solids contact. The presence of both types of particles near the chimney region reduces, however, the strength of the central vortex and is detrimental for separation and segregation. Optimization of the solids inlet design is required, as illustrated by stopping the solids feeding. High-G separation and segregation of the batch of particles is demonstrated, as the strength of the central vortex is restored. The flexibility with respect to the gas flow rate of the bed density and uniformity and of the gas–solids separation and segregation is demonstrated, a unique feature of vortex chamber generated rotating fluidized beds. With the particles considered in this case study, turbulent dispersion by large eddies in the gas phase is shown to have only a minor impact on the height of the inner bed of small/light particles.

Published

2016

9. Modeling and simulation of biomass drying in vortex chambers

Author

Juray De Wilde, Philippe Eliaers, Jnyana Ranjan Pati, and Subhajit Dutta

Subjects

Engineering, Waste management, Moisture, Physics::Instrumentation and Detectors, Continuous operation, business.industry, Applied Mathematics, General Chemical Engineering, Biomass, General Chemistry, Mechanics, Industrial and Manufacturing Engineering, Vortex, Modeling and simulation, Heat transfer, SCALE-UP, Fluidization, business, Physics::Atmospheric and Oceanic Physics

Abstract

High-G fluidization in vortex chambers allows intensifying the drying of granular materials. The modeling, simulation and scale-up of vortex chamber based biomass dryers are addressed. Non-stationary experiments, batch for the biomass, are carried out to complement the data on continuous woody biomass drying in vortex chambers available in the literature. The drying models differ in the way they do or do not account for interfacial mass and heat transfer limitations, a non-uniform distribution of the moisture in the biomass particles and intra-particle diffusion limitations. Discrimination between the different proposed drying models and estimation of the model parameter(s) follows from simulations of both the continuous and batch experiments and regression. The retained biomass drying model is then used to study scale-up of the technology, focusing on continuous operation. Two major issues are addressed: (i) the product uniformity and (ii) the air consumption and utilization. Different vortex chamber configurations are simulated and analyzed: a single chamber or different chambers operated in parallel or in series (compartmented), allowing introducing a CSTR-in-series type behavior for the particles, combined with air feeding in parallel or in series over the different chambers.

Published

2015

10. Intrinsic kinetics of steam methane reforming on a thin, nanostructured and adherent Ni coating

Author

Florent Minette, Marco J. Castaldi, Michael Lugo-Pimentel, Juray De Wilde, Rajinder Gill, Dean Modroukas, Andrew Davis, UCL - SST/IMMC/IMAP - Materials and process engineering, City University of New York - Dept. of Chemical Engineerging, Innoveering LLC, NY, USA - n/a, and Alloy Surfaces, Co.Inc., PA, USA - n/a

Subjects

Materials science, Natural gas steam reforming, Diffusion, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, Catalysis, Water-gas shift reaction, Steam reforming, Adsorption, Coating, Structure catalyst, Desorption, Catalyst coating, General Environmental Science, Packed bed, Plug flow, Process Chemistry and Technology, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical engineering, Intrinsic reaction kinetics, engineering, 0210 nano-technology, Hydrogen

Abstract

The intrinsic kinetics of Steam Methane Reforming (SMR) on a non-conventional nanostructured and strongly adherent Ni coating on a metal substrate was experimentally studied using an integral packed bed reactor. The coating was characterized by means of SEM, N2 adsorption/desorption, EDX, XRD and TPR. The reactor was designed and the operating conditions selected to guarantee negligible interfacial and intra-particle transport limitations, plug flow, isothermal operation and a sufficiently small pressure drop. Experiments were carried out at temperatures between 450 and 600 °C, space times between 0.033 and 0.1 mol/(gcat.s) and steam-to-carbon ratios of 2.87 to 5.53. Discrimination between potential reaction mechanisms and rate determining steps and estimation of the rate parameters and their confidence intervals followed from regression and statistical and physicochemical testing. Measurements confirmed that the water gas shift reaction reached equilibrium for each condition. A comparison with reported intrinsic kinetics for a conventional SMR catalyst was made and optimal catalyst coating thickness, accounting for intra-catalyst diffusion limitations was evaluated.

Published

2018

11. Advances in mathematical modeling of fluidized bed gasification

Author

Chanchal Loha, Pradip K. Chatterjee, Sai Gu, Pinakeswar Mahanta, and Juray De Wilde

Subjects

Work (thermodynamics), Engineering, Petroleum engineering, Hydrogen, Wood gas generator, Renewable Energy, Sustainability and the Environment, business.industry, chemistry.chemical_element, Computational fluid dynamics, Solid fuel, Methane, Modeling and simulation, chemistry.chemical_compound, chemistry, Fluidized bed, Process engineering, business

Abstract

Gasification is the thermochemical conversion of solid fuel into the gas which contains mainly hydrogen, carbon monoxide, carbon dioxide, methane and nitrogen. In gasification, fluidized bed technology is widely used due to its various advantageous features which include high heat transfer, uniform and controllable temperature and favorable gas–solid contacting. Modeling and simulation of fluidized bed gasification is useful for optimizing the gasifier design and operation with minimal temporal and financial cost. The present work investigates the different modeling approaches applied to the fluidized bed gasification systems. These models are broadly classified as the equilibrium model and the rate based or kinetic model. On the other hand, depending on the description of the hydrodynamic of the bed, fluidized bed models may also be classified as the two-phase flow model, the Euler–Euler model and the Euler–Lagrange model. Mathematical formulation of each of the model mentioned above and their merits and demerits are discussed. Detail reviews of different model used by different researchers with major results obtained by them are presented while the special focus is given on Euler–Euler and Euler–Lagrange CFD models.

Published

2014

12. Gas–solid fluidized beds in vortex chambers

Author

Juray De Wilde and UCL - SST/IMMC/IMAP - Materials and process engineering

Subjects

Engineering, High-G fluidization, business.industry, Contact time, Process Chemistry and Technology, General Chemical Engineering, Energy Engineering and Power Technology, Mechanical engineering, General Chemistry, Slip (materials science), Gas solid, Mechanics, Vortex chamber, Computational fluid dynamics, Industrial and Manufacturing Engineering, Rotating fluidizd bed, Vortex, Process intensification, Fluidized bed, Interfacial transfer, Fluidization, business

Abstract

This review deals with gas–solid fluidized beds in vortex chambers. High-G fluidization can be achieved in a static geometry and allows significant process intensification. Thin, dense and more uniform particle beds can be obtained at high gas–solid slip velocities, intensifying interfacial transfer of mass, heat and momentum and reducing the gas–solid contact time. Existing fluidized bed processes can be carried out more efficiently and novel processing routes can be developed, e.g., involving cohesive particles or a dispersed liquid phase in relatively high concentrations. The first section of the review discusses the unique hydrodynamic characteristics of gas–solid fluidized beds in vortex chambers. The flow pattern, flexibility in the operating conditions and stability conditions are explained. The design of vortex chambers is dealt with in the second section and is critical for processing both larger and fine particles. The influence of the gas and solids in- and outlet design is focused on and insight is gained from recent theoretical, experimental and CFD studies. In the third section (potential) applications are discussed and process intensification and novel processing routes demonstrated. The fourth and last section presents extensions of the concept. Multi-zone operation and the integration of other technologies in vortex chambers are considered.

Published

2014

13. High-G, low-temperature coating of cohesive particles in a vortex chamber

Author

Axel de Broqueville, Albert T. Poortinga, Tom van Hengstum, Philippe Eliaers, and Juray De Wilde

Subjects

Diffraction, Materials science, Economies of agglomeration, General Chemical Engineering, engineering.material, Vortex, Spray nozzle, Volumetric flow rate, Coating, Particle-size distribution, engineering, Forensic engineering, Fluidization, Composite material

Abstract

Vortex chambers allow high-G fluidization and are as such potentially interesting for processing cohesive particles. The first part of the paper deals with the formation of a rotating bed of cohesive particles in a vortex chamber. A careful vortex chamber design is required to generate a sufficiently strong high-G field and related sufficiently high particle residence time. Next, the low-temperature coating of the particles is addressed. A centrally positioned single-fluid pressure spray nozzle directed towards the bed is used. The influence of a dispersed coating solution on the bed stability and the segregation of uncoated and coated particles are studied. Agglomeration and the particle coating quality are analyzed by means of laser diffraction based particle size distribution measurements, SEM imaging and an active component release test. Because vortex chambers are extremely flexible with respect to the gas flow rate, the variation of the latter to control the agglomeration is focused on. The influence of the coating time and the coating solution injection pressure are also studied and the maximization of the coating efficiency discussed.

Published

2014

14. Computational Fluid Dynamics in chemical reactor analysis and design: Application to the ZoneFlow™ reactor for methane steam reforming

Author

Juray De Wilde and Gilbert F. Froment

Subjects

Packed bed, Methane reformer, Chemistry, General Chemical Engineering, Nuclear engineering, Organic Chemistry, Energy Engineering and Power Technology, Continuous stirred-tank reactor, Trickle-bed reactor, Chemical reactor, Steam reforming, Fuel Technology, Chemical engineering, Plug flow reactor model, Syngas

Abstract

The ZoneFlow reactor (Tribute Creations, LLC) is a tubular reactor with two types of internals: a core type and adjacent to the wall, a casing type, both covered with a thin layer of catalyst. It aims for higher energy efficiency and lower steam-to-carbon ratios in methane steam reforming by a judicious design of the relative position of the internals and their geometrical characteristics and a higher catalyst effectiveness. The performance of this novel structured catalytic reactor for synthesis gas production by methane steam reforming was simulated using a reactor model accounting in detail for the flow pattern by means of Computational Fluid Dynamics (CFD). A Reynolds Averaged Navier Stokes (RANS) approach was taken. Turbulence, heat transfer by convection and radiation, detailed reaction kinetics including coking, intraparticle diffusion limitations, and the compressibility of the gas phase were accounted for. Simulations were carried out to investigate the ZoneFlow reactor performance under typical commercial operating conditions and compare it with a conventional packed bed reactor using the same Ni catalyst.

Published

2012

15. Fluid catalytic cracking in a rotating fluidized bed in a static geometry: a CFD analysis accounting for the distribution of the catalyst coke content

Author

Waldo Rosales Trujillo and Juray De Wilde

Subjects

Cracking, Chemistry, Fluidized bed, General Chemical Engineering, Thermodynamics, Geometry, Fluidization, Coke, Residence time (fluid dynamics), Fluid catalytic cracking, Endothermic process, Catalysis

Abstract

Computational Fluid Dynamics is used to evaluate the use of a rotating fluidized bed in a static geometry for the catalytic cracking of gas oil. A Eulerian–Eulerian flow model is used in combination with the Kinetic Theory of Granular Flow. The catalytic cracking reactions are described by a 10-lump model. Catalyst deactivation by coke formation is included. To operate at low catalyst coke content, the catalyst residence time is small and the catalyst makes on average only a limited number of rotations in the reactor. Therefore,the catalyst bed cannot be considered well-mixed and a local distribution of the catalyst coke content is to be accounted for. The catalyst coke content distribution function has no pre-described functional form and is discretized. A continuity equation is then solved for each of the classes of catalyst with a given coke content. The impact of the strongly endothermic cracking reactions on the particle bed temperature uniformity is also studied.

Published

2012

16. Experimental and computational study of T- and L-outlet effects in dilute riser flow

Author

Guy B. Marin, Geraldine Heynderickx, Juray De Wilde, and G. Van Engelandt

Subjects

Meteorology, business.industry, Applied Mathematics, General Chemical Engineering, Flow (psychology), Flux, General Chemistry, Mechanics, Laser Doppler velocimetry, Computational fluid dynamics, Industrial and Manufacturing Engineering, Vortex, Creep, cardiovascular system, Particle, Fluidized bed combustion, business

Abstract

Riser outlet effects induced by an L-outlet and by abrupt T-outlets with different extension heights and outlet surface areas are studied experimentally and computationally. Experiments are carried out in a cold flow riser. The cold flow riser has a diameter of 0.1 m and a height of 8.765 m and is operated in the dilute flow regime with a superficial gas velocity of 2.48-7.43 m/s and a solids flux of 3.0 kg/m²/s. Particle velocities are measured using Laser Doppler Anemometry (LDA). Vortex formation in the extension part of the riser is observed. The vortex circulates the solids along the wall opposite to the outlet, thus inducing a solids reflux. The flow pattern upstream the outlet is, however, hardly affected in the small diameter riser. The vortex position and length are affected by the extension height, but hardly by the outlet surface area and the superficial gas velocity. The use of an L-outlet significantly reduces the vortex formation. The experimental measurements are used to validate a 3D Eulerian–Eulerian and Kinetic Theory of Granular Flow (KTGF) based gas–solid flow model. In general, the calculated trends are qualitatively in agreement with the experimentally observed phenomena. The exact shape of the vortex is not always accurately predicted.

Published

2011

17. A rotating chimney for compressing rotating fluidized beds

Author

Axel de Broqueville and Juray De Wilde

Subjects

Barbotage, Centrifugal force, Materials science, Fluidized bed, General Chemical Engineering, Particle, Geotechnical engineering, Chimney, Mechanics, Fluidization

Abstract

The concept and use of a rotating chimney for compressing rotating fluidized beds is theoretically and experimentally studied. A rotating chimney is shown to drastically increase the operating flexibility of rotating fluidized beds and to allow a significant improvement of the particle bed uniformity. In particular, the rate of solids losses via the chimney can be reduced and bubbling can be suppressed by compressing the rotating particle bed. (c) 2009 Elsevier B.V. All rights reserved.

Published

2010

18. Numerical investigation of gas-solid heat transfer in rotating fluidized beds in a static geometry

Author

Juray De Wilde and Axel de Broqueville

Subjects

Centrifugal force, Chemistry, Applied Mathematics, General Chemical Engineering, Geometry, General Chemistry, Heat transfer coefficient, Slip (materials science), Industrial and Manufacturing Engineering, Volumetric flow rate, Condensed Matter::Soft Condensed Matter, Physics::Fluid Dynamics, Drag, Fluidized bed, Heat transfer, Fluidization

Abstract

Gas-solid heat transfer in rotating fluidized beds in a static geometry is theoretically and numerically investigated. Computational fluid dynamics (CFD) simulations of the particle bed temperature response to a step change in the fluidization gas temperature are presented to illustrate the gas-solid heat transfer characteristics. A comparison with conventional fluidized beds is made. Rotating fluidized beds in a static geometry can operate at centrifugal forces multiple times gravity, allowing increased gas-solid slip velocities and resulting gas-solid heat transfer coefficients. The high ratio of the cylindrically shaped particle bed "width" to "height" allows a further increase of the specific fluidization gas flow rates. The higher specific fluidization gas flow rates and increased gas-solid slip velocities drastically increase the rate of gas-solid heat transfer in rotating fluidized beds in a static geometry. Furthermore, both the centrifugal force and the counteracting radial gas-solid drag force being influenced by the fluidization gas flow rate in a similar way. rotating fluidized beds in a static geometry offer extreme flexibility with respect to the fluidization gas flow rate and the related cooling or heating. Finally, the uniformity of the particle bed temperature is improved by the tangential fluidization and resulting rotational motion of the particle bed. (c) 2008 Elsevier Ltd. All rights reserved.

Published

2009

19. Experimental investigation of a rotating fluidized bed in a static geometry

Author

Axel de Broqueville and Juray De Wilde

Subjects

Barbotage, Centrifugal force, Fluidized bed, Chemistry, General Chemical Engineering, Slugging, Particle, Geometry, Chimney, Fluidization, Volumetric flow rate

Abstract

Rotating fluidized beds in a static geometry are based on the new concept of injecting the fluidization gas tangentially in the fluidization chamber, via multiple gas inlet slots in its cylindrical outer wall. The tangential injection of the fluidization gas fluidizes the particles tangentially and induces a rotating motion, generating a centrifugal field. Radial fluidization of the particle bed is created by introducing a radially inwards motion of the fluidization gas, towards a centrally positioned chimney. Correctly balancing the centrifugal force and the radial gas-solid drag force requires an optimization of the fluidization chamber design for each given type of particles. Solids feeding and removal can be continuous, via one of the end plates of the fluidization chamber. The fluidization behavior of both large diameter, low density polymer particles and small diameter, higher density salt particles is investigated at different solids loadings in a 24 cm diameter, 13.5 cm long non-optimized fluidization chamber. Scale-up to a 36 cm diameter fluidization chamber is illustrated. Provided that the solids loading is sufficiently high, a stable rotating fluidized bed in a static geometry is obtained. This requires to minimize the solids losses via the chimney. With the polymer particles, a dense and uniform bed is observed, whereas with the salt particles a less dense and less uniform bubbling bed is observed. Solids losses via the chimney are much more pronounced with the salt than with the polymer particles. Slugging and channeling occur at too low solids loadings. The hydrostatic gas phase pressure profiles along the outer cylindrical wall of the fluidization chamber are a good indicator of the particle bed uniformity and of channeling and slugging. The fluidization gas flow rate has only a minor effect on the occurrence of channeling and slugging, the solids loading in the fluidization chamber being the determining factor for obtaining a stable and uniform rotating fluidized bed in a static geometry. (C) 2008 Elsevier B.V. All rights reserved.

Published

2008

20. Filtered gas–solid momentum transfer models and their application to 3D steady-state riser simulations

Author

Guy Marin, Geraldine Heynderickx, and Juray De Wilde

Subjects

Drag coefficient, Chemistry, business.industry, Applied Mathematics, General Chemical Engineering, Momentum transfer, Thermodynamics, General Chemistry, Mechanics, Computational fluid dynamics, Industrial and Manufacturing Engineering, Drag, Speed of sound, Two-phase flow, business, Pressure gradient, Added mass

Abstract

To account for meso-scale phenomena in coarse grid simulations, correlation terms appearing in the filtered gas-solid flow equations have to be modeled. Possible approaches to describe filtered gas-solid momentum transfer are evaluated via a mixture speed of sound test. In contrast to the effective drag coefficient closure model for the filtered drag force, the generalized added mass closure model for the correlation between the solid volume fraction and the gas phase pressure gradient shows an acceptable behavior. Furthermore, the generalized added mass may become determining in describing filtered gas-solid momentum transfer when sufficiently coarse grids are used. 3D steady-state riser simulations demonstrate the impact of the generalized added mass based description of filtered gas-solid momentum transfer on the calculated gas-solid flow behavior, in particular on the gas-solid slip velocity profile. (c) 2007 Elsevier Ltd. All rights reserved.

Published

2007

21. Assessment of filtered gas–solid momentum transfer models via a linear wave propagation speed test

Author

Denis Constales, Juray De Wilde, Geraldine Heynderickx, and Guy Marin

Subjects

Fluid Flow and Transfer Processes, Drag coefficient, Classical mechanics, Drag, Wave propagation, Mechanical Engineering, Wave shoaling, Momentum transfer, General Physics and Astronomy, Velocity factor, Wave vector, Mechanics, Added mass

Abstract

The propagation speeds of linear waves in gas-solid suspensions depend strongly on the solids volume fraction and the wave frequency. The latter is due to gas-solid momentum transfer and allows a simple test on filtered gas-solid momentum transfer models. Such models may predict linear wave propagation speeds different from those obtained with the nonfiltered model at wave frequencies higher than the filter frequency, but not at wave frequencies lower than the filter frequency. For the filtered drag, an effective drag coefficient approach is shown to alter the linear wave propagation speeds in the entire wave frequency range, independent of the applied effective drag coefficient. Furthermore, as the effective drag coefficient decreases, the high frequency linear wave propagation speeds are gradually introduced at lower wave frequencies. For the filtered momentum transfer due to the correlation between the solids volume fraction and the gas phase pressure gradient, the behavior of an apparent added mass closure model and an apparent history force closure model are investigated. An apparent added mass introduces the filter frequency linear wave propagation speeds to frequencies higher than the filter frequency. The linear wave propagation speeds for wave frequencies lower than the filter frequency are, however, not altered. Furthermore, an apparent added mass introduces no intrinsic wave frequency dependence in the linear wave propagation speeds, in agreement with its source term in the non-filtered model. Hence, the frequency dependence of the linear wave propagation speeds at frequencies lower than the filter frequency is still to be provided by a drag type term. As such, the behavior introduced by an apparent added mass is acceptable for filtered models. Also, to a certain extent, an apparent added mass can restore the linear wave propagation speed behavior at wave frequencies lower than the filter frequency altered by an effective drag coefficient approach. The reformulation of the apparent added mass in terms of an apparent distribution of the filtered gas phase pressure gradient over the phases and an apparent (effective) drag force is investigated. An apparent history force introduces intrinsic wave frequency dependence in the linear wave propagation speeds and alters the latter from the low wave frequencies on. As such, the behavior introduced by an apparent history force is unacceptable for filtered models, (C) 2006 Elsevier Ltd. All rights reserved.

Published

2007

22. Experimental study of inlet phenomena of 35∘ inclined non-aerated and aerated Y-inlets in a dilute cold-flow riser

Author

Juray De Wilde, Geraldine Heynderickx, Gorik Van engelandt, and Guy B. Marin

Subjects

Jet (fluid), geography, geography.geographical_feature_category, Chemistry, Applied Mathematics, General Chemical Engineering, Mixing (process engineering), Mineralogy, General Chemistry, Mechanics, Inlet, Industrial and Manufacturing Engineering, Vortex, Physics::Fluid Dynamics, Standpipe (firefighting), Particle, Two-phase flow, Penetration depth

Abstract

Inlet phenomena in a 0.1 m diameter cold-flow riser with a 35 ∘ inclined side inlet are studied experimentally using 3D-Laser Doppler Anemometry for solids fluxes of 0.5– 4.5 kg / m 2 / s and gas velocities of 5.3–7.4 m/s. In the vicinity of the solids inlet, radial gas-solids mixing is hindered and bypassing of the solids jet occurs, resulting in steep velocity gradients and off-centre maxima in the velocity field. The feeding conditions and the type of the solids affect the bottom operation and gas–solids mixing to a large extent: compared to FCC particles, silica particles extend the acceleration zone in the riser. Low gas flow rates and/or high solids feeding rates result in an increased penetration depth of the solids jet and in explicit bypass zones in the plane facing the inlet. High root mean square fluctuating particle velocities are observed at the solids jet boundaries. A non-aerated Y-inlet configuration causes vortex formation, inducing a small reflux into the upper dilute part of the standpipe. The influence of dilution of the inlet solids jet is also investigated using an “aerated” inlet configuration. Aerated inlets lead to better entrainment, improved radial mixing, less pronounced broader bypass zones and a firm reduction of the penetration depth. In the 0.1 m diameter riser, radial mixing quickly dissipates the non-uniformities introduced by the solids inlet. Reflection phenomena can, however, occur in the case of a non-aerated solids inlet.

Published

2007

23. Simultaneous solution algorithms for Eulerian–Eulerian gas–solid flow models: Stability analysis and convergence behaviour of a point and a plane solver

Author

Juray De Wilde, Geraldine Heynderickx, Guy Marin, and Jan Vierendeels

Subjects

Numerical Analysis, Physics and Astronomy (miscellaneous), Discretization, Applied Mathematics, Eulerian path, Slip (materials science), Solver, Dissipation, Computer Science Applications, Physics::Fluid Dynamics, Computational Mathematics, symbols.namesake, Fourier transform, Inviscid flow, Modeling and Simulation, symbols, Algorithm, Numerical stability, Mathematics

Abstract

Simultaneous solution algorithms for Eulerian-Eulerian gas-solid flow models are presented and their stability analyzed. The integration algorithms are based on dual-time stepping with fourth-order Runge-Kutta in pseudo-time. The domain is solved point or plane wise. The discretization of the inviscid terms is based on a low-Mach limit of the multi-phase preconditioned advection upstream splitting method (MP-AUSMP). The numerical stability of the simultaneous solution algorithms is analyzed in 2D with the Fourier method. Stability results are compared with the convergence behaviour of 3D riser simulations. The impact of the grid aspect ratio, preconditioning, artificial dissipation, and the treatment of the source terms is investigated. A particular advantage of the simultaneous solution algorithms is that they allow a fully implicit treatment of the source terms which are of crucial importance for the Eulerian-Eulerian gas-solid flow models and their solution. The numerical stability of the optimal simultaneous solution algorithm is analyzed for different solids volume fractions and gas-solid slip velocities. Furthermore, the effect of the grid resolution on the convergence behaviour and the simulation results is investigated. Finally, simulations of the bottom zone of a pilot-scale riser with a side solids inlet are experimentally validated.

Published

2005

24. Gas–solids mixing in the inlet zone of a dilute circulating fluidized bed

Author

Geraldine Heynderickx, Guy B. Marin, Juray De Wilde, and Gorik Van engelandt

Subjects

geography, geography.geographical_feature_category, Materials science, Turbulence, General Chemical Engineering, Flow (psychology), Mixing (process engineering), Mechanics, Inlet, Inviscid flow, Phase (matter), Geotechnical engineering, Fluidization, Fluidized bed combustion

Abstract

The influence of the inlet configuration on the flow pattern in dilute circulating fluidized beds is investigated. The solid flow model used is based on the kinetic theory of granular flow (KTGF). Interactions between the fluctuating motion of the gas and the solid phase are accounted for. A line-implicit simultaneous solution algorithm based on dual-time stepping is used for the numerical integration. The discretization of the inviscid fluxes is based on a low-Mach reformulation of the multi-phase preconditioned advection upstream splitting method (MP-AUSMP). Simulation results for a side solids inlet configuration are qualitatively verified using 3D LDA data of a cold-flow circulating fluidized bed pilot unit. The pilot riser has a diameter of 0.1 m and a height of 8.765 m. The side inlet used for solids feeding is positioned 0.58 m above the gas inlet and makes a 35° angle with the riser axis. The cold-flow pilot unit is operated in the dilute regime with a superficial gas velocity of 5.31 m s−1 and a solids flux of 3 kg m−2 s−1. Experimental and simulation results show that bypassing of solids by the gas occurs, but that the bypassing effects are quickly dissipated by the viscous terms. The gas–solid flow model is capable of describing the experimentally observed mixing behaviour. In simulations of dilute industrial scale risers, the gas is fed over the entire bottom section, whereas two kinds of solids inlet configurations are used: (1) the solids are fed through a central inlet tube at the bottom of the riser; (2) the solids are fed through a side inlet at a certain distance from the bottom of the riser. The outlet is of the abrupt T-type. With the first inlet configuration, the radial mixing of the solids is seen to be hindered, due to bypassing of the gas via the outer ring of the reactor tube. The bypassing effects are not quickly dissipated by the viscous terms. The impact of the latter is less important in large than in small diameter risers. Bypassing of the gas also plays an important role with the second inlet configuration. At the height of the solids inlet, the gas is seen to flow preferentially aside of the solids inlet and at the opposite site of the riser. This results in vortex formation, responsible for the primary mixing of gas and solids. More downstream, the maximum solids flux is calculated at the side of the solids inlet. Radial mixing is seen to be related to the granular temperature and the gas phase turbulence. The dilute industrial scale riser simulations show that inlet and outlet configuration effects are not independent, but interact. This has an important impact on radial mixing. Inlet and outlet effects can oppose each other or cooperate, resulting in complex riser behaviour.

Published

2005

25. CFD simulation of dilute phase gas–solid riser reactors: part II—simultaneous adsorption of SO2–NOx from flue gases

Author

Geraldine Heynderickx, Guy Marin, Asit Kumar Das, and Juray De Wilde

Subjects

Flue gas, Sorbent, Waste management, Chemistry, Applied Mathematics, General Chemical Engineering, Multiphase flow, Analytical chemistry, General Chemistry, Industrial and Manufacturing Engineering, Flux (metallurgy), Adsorption, Phase (matter), Fluidization, NOx

Abstract

Simultaneous adsorption of SO 2 –NO x in a riser configuration is a novel route for flue gas cleaning. The riser operates at a low flux (2 kg m −2 s −1 ) of small diameter (d p =60 μm ) Na- γ -Al 2 O 3 sorbent particles. The reaction scheme is adopted from previous work (Ind. Eng. Chem. Res. 40 (2001) 119), without adjusting any of the kinetic parameters. The significant concentration gradient between the gas and solid phase mainly arises from the low solid fraction (typically 5×10 −4 ) in the riser. Enhancing the fluctuating kinetic motion of gas and solid phase increases the SO 2 adsorption, whereas the NO adsorption is decreased marginally. The solid recirculation in the top section of the riser, induced by the abrupt T outlets, significantly decreases the NO and NO 2 removal, while the SO 2 removal remains mostly unaffected. Therefore, it is desirable to avoid recirculation for a maximum NO x removal. A comparison of the 3D and a 1D model shows that higher SO 2 and NO removal efficiencies are predicted by the 3D model in the major part of the riser. However, these positive effects are largely neutralized by the negative effects of the outlet-induced recirculation, resulting in similar overall removal efficiencies calculated by the two models. Unlike the 1D model, the 3D simulation shows a considerable axial variation in the solid fraction and slip velocity. The 3D simulation also allows to calculate the effects of outlet geometry on the flow and reaction fields. The reactor efficiency can be improved by modifying the outlet configuration to minimize the recirculation.

Published

2004

26. The effects of abrupt T-outlets in a riser: 3D simulation using the kinetic theory of granular flow

Author

Geraldine Heynderickx, Juray De Wilde, and Guy Marin

Subjects

Computer simulation, Turbulence, Applied Mathematics, General Chemical Engineering, Multiphase flow, Flow (psychology), General Chemistry, Mechanics, Industrial and Manufacturing Engineering, Physics::Fluid Dynamics, Kinetic theory of gases, Fluidized bed combustion, Fluidization, Two-phase flow, Physics::Atmospheric and Oceanic Physics, Simulation, Mathematics

Abstract

Gas–solid flow in circulating fluidized beds is calculated using the Eulerian–Eulerian approach with the kinetic theory of granular flow. The usefulness of this approach and the necessity of performing 3D calculations are illustrated by calculating the exit effects of single abrupt outlet configurations of different outlet surface area.

Published

2003

27. Investigation of simultaneous adsorption of SO2 and NOx on Na-γ-alumina with transient techniques

Author

Guy B. Marin and Juray De Wilde

Subjects

Plug flow, Atmospheric pressure, Inorganic chemistry, chemistry.chemical_element, General Chemistry, Oxygen, Catalysis, chemistry.chemical_compound, Adsorption, chemistry, Nitrogen oxide, Plug flow reactor model, NOx

Abstract

The simultaneous adsorption of SO 2 and NO x on Na-γ-alumina was studied by means of step experiments in a fixed bed plug flow reactor at 387 K and atmospheric pressure. Typically the molar composition of the feed gas was 1.5% SO 2 , 1% O 2 , 4000 ppm NO, 500 ppm NO 2 , and Ar. First the adsorption behavior of the pure components was measured. SO 2 and NO 2 adsorb easily, whereas NO and O 2 do not adsorb. Moreover there is no influence of O 2 on the adsorption behavior of the pure components. NO and O 2 adsorption require the simultaneous presence of SO 2 , NO, and O 2 . The NO and O 2 adsorption rate is enhanced by an increasing SO 2 /NO ratio. The total amount of SO 2 adsorbed is not affected by the simultaneous adsorption of NO and O 2 . However, NO 2 adsorption increases the SO 2 adsorption capacity. In the presence of NO 2 most of the adsorbed NO x is released as NO.

Published

2000