Your search keyword '"Ronny Gueguen"' showing total 9 results

1. Managing Heat Transfer Intensity in a Fluidized Particle-in-Tube Solar Receiver

Author

Ronny Gueguen, Samuel Mer, Adrien Toutant, Françoise Bataille, and Gilles Flamant

Subjects

Particle-Driven CSP, Solar Receiver, Fluidized Bed, Heat Transfer, Physics, QC1-999

Abstract

Particle flow structure and associated heat transfer coefficient are examined as a function of temperature in a single-tube fluidized bed solar receiver operating in upward particle flow mode. It is found that temperature has a strong effect on both fluidization regimes and wall-to-bed heat transfer coefficient that varies in the range 800-1200 W/(m2.K). Turbulent fluidization regime results in the most intense heat transfer between the irradiated wall and the fluidized particle.

Published

2024

2. Influence of Temperature on Properties and Dynamics of Gas-Solid Flow in Fluidized-Particle Tubular Solar Receiver

Author

Ronny Gueguen, Guillaume Sahuquet, Jean-Louis Sans, Samuel Mer, Adrien Toutant, Françoise Bataille, and Gilles Flamant

Subjects

Concentrated Solar Power, Particles Solar Receiver, Fluidized Particles, Physics, QC1-999

Abstract

A fluidized particle single-tube solar receiver has been tested for investigating the gas-particle characteristics that enable the best operating conditions in a commercial-scale plant. The principle of the solar receiver is to fluidize the particles in a vessel – the dispenser – in which the receiver tube is plunged. The particles are flowing upward in the tube, irradiated over 1-meter height, by applying an overpressure in the dispenser. Experiments with a concentrated solar flux varying between 188 and 358 kW/m² are carried out, and the particle mass flux varied from 0 to 72 kg/(m²s). The mean particles and external tube wall temperatures in the irradiated zone are heated from the ambient to respectively 700°C and 940°C. It is shown that the temperature rise leads to a decrease of the particle volume fraction. Furthermore, a self-regulation of the system is evidenced with a short transient regime. This characteristic is essential from the operational viewpoint. The thermal efficiency of the receiver increases with the particle flow rate, reaching between 60 and 75% above 30 kg/(m²s). Several fluidization regimes are identified thanks to pressure signal analyses, like slugging, turbulent and fast fluidization, showing that regimes transitions are strongly affected by the temperature.

Published

2024

3. Particle Flow Distribution in a Fluidized-Particles Multitube Solar Receiver

Author

Guillaume Sahuquet, Ronny Gueguen, Lilian Fontalvo, Samuel Mer, Adrien Toutant, Françoise Bataille, and Gilles Flamant

Subjects

Concentrated Solar Power, Particles Solar Receiver, Fluidized Particles, Particle Flow Heterogeneity in Solar Receiver, Physics, QC1-999

Abstract

A fluidized-particles two-tube solar receiver was tested at ambient temperature at PROMES Laboratory to investigate the influence of an inhomogeneous solar flux density on the particle mass flow rate between the tubes. The principle of this 3rd generation solar receiver is to fluidize the particles in a container, called dispenser, in which the tubes’ bottom are immersed. The fluidized particles are flowing upward the tubes by applying an overpressure in the dispenser. Air velocities are changed inside the tubes, thanks to air mass flow controllers, to represent temperature heterogeneity between the tubes. Air velocities from 0.05 up to 0.52 m/s were tested, both in homogeneous and heterogeneous conditions. In the heterogeneous ones, the differences in air velocity between the tubes aim to mimic a difference in temperature from 20 to 100 % with homogeneous air flow rates injected. The following conclusions were drawn. First, the particle mass flux in the tubes are the same with homogeneous air velocities, each one following a calibration map previously obtained. Second, different air velocities lead to different particle mass flux. Third, the rise of the total particle mass flux diminishes the pressure in the dispenser. Four, this diminution of pressure leads to a decrease of the particle mass flow rate of the tube with the lower air velocity. This influence can lead in some cases to the stop of the fluidized bed circulation in the affected tube.

Published

2024

4. Gas-Solid Flow in a Fluidized-Particle Tubular Solar Receiver: Off-Sun Experimental Flow Regimes Characterization

Author

Ronny Gueguen, Guillaume Sahuquet, Samuel Mer, Adrien Toutant, Françoise Bataille, and Gilles Flamant

Subjects

fluidization regimes, dense particle suspension, particle-in-tube solar receivers, hydrodynamics of gas-solid flow, upward circulation, pressure signal processing, Technology

Abstract

The fluidized particle-in-tube solar receiver concept is promoted as an attractive solution for heating particles at high temperature in the context of the next generation of solar power tower. Similar to most existing central solar receivers, the irradiated part of the system, the absorber, is composed of tubes in which circulate the fluidized particles. In this concept, the bottom tip of the tubes is immersed in a fluidized bed generated in a vessel named the dispenser. A secondary air injection, called aeration, is added at the bottom of the tube to stabilize the flow. Contrary to risers, the particle mass flow rate is controlled by a combination of the overpressure in the dispenser and the aeration air velocity in the tube. This is an originality of the system that justifies a specific study of the fluidization regimes in a wide range of operating parameters. Moreover, due to the high value of the aspect ratio, the particle flow structure varies along the tube. Experiments were conducted with Geldart Group A particles at ambient temperature with a 0.045 m internal diameter and 3 m long tube. Various temporal pressure signal processing methods, applied in the case of classical risers, are applied. Over a short acquisition time, a cross-reference of the results is necessary to identify and characterize the fluidization regimes. Bubbling, slugging, turbulent and fast fluidization regimes are encountered and the two operation modes, without and with particle circulation, are compared.

Published

2021

5. Shaping High Efficiency, High Temperature Cavity Tubular Solar Central Receivers

Author

Ronny Gueguen, Benjamin Grange, Françoise Bataille, Samuel Mer, and Gilles Flamant

Subjects

concentrated solar power, solar power tower, cavity solar receiver, shape optimization, particle technology, high temperature, Technology

Abstract

High temperature solar receivers are developed in the context of the Gen3 solar thermal power plants, in order to power high efficiency heat-to-electricity cycles. Since particle technology collects and stores high temperature solar heat, CNRS (French National Center for Scientific Research) develops an original technology using fluidized particles as HTF (heat transfer fluid). The targeted particle temperature is around 750 °C, and the walls of the receiver tubes, reach high working temperatures, which impose the design of a cavity receiver to limit the radiative losses. Therefore, the objective of this work is to explore the cavity shape effect on the absorber performances. Geometrical parameters are defined to parametrize the design. The size and shape of the cavity, the aperture-to-absorber distance and its tilt angle. A thermal model of a 50 MW hemi-cylindrical tubular receiver, closed by refractory panels, is developed, which accounts for radiation and convection losses. Parameter ranges that reach a thermal efficiency of at least 85% are explored. This sensitivity analysis allows the definition of cavity shape and dimensions to reach the targeted efficiency. For an aperture-to-absorber distance of 9 m, the 85% efficiency is obtained for aperture areas equal or less than 20 m2 and 25 m2 for high, and low convection losses, respectively.

Published

2020

6. Fluidization regimes of dense suspensions of Geldart group A fluidized particles in a high aspect ratio column

Author

Ronny Gueguen, Guillaume Sahuquet, Samuel Mer, Adrien Toutant, Françoise Bataille, and Gilles Flamant

Subjects

Applied Mathematics, General Chemical Engineering, General Chemistry, Industrial and Manufacturing Engineering

Published

2023

7. Experimental Study of an upflow Fluidized Bed: Identification of Fluidization Regimes

Author

Ronny Gueguen, Guillaume Sahuquet, Samuel Mer, Adrien Toutant, Françoise Bataille, and Gilles Flamant

Subjects

General Medicine

Abstract

The concept of solar receiver using fluidized particles as heat transfer fluid is attractive from the point of view of its performance but also of the material used. In this concept, the receiver is composed of tubes subjected to concentrated solar radiation in which the fluidized particles circulate vertically. Circulation in the tubes, immersed in a “nurse” fluidized bed, is ensured thanks to a controlled pressure difference imposed on the latter and secondary aeration. This ventilation located at the bottom of the absorber tubes makes it possible to control the fluidization regimes. The latter strongly influence the parietal heat transfers and therefore the performance of the receiver. In order to better understand the conditions of appearance of these regimes and to better identify them, a study at room temperature was carried out with a tube 45 mm in internal diameter and 3.63 m in height. The tube is instrumented with several pressure sensors distributed over its height. More than 170 experiments have been performed exploring wide ranges of particle and aeration flow rates, with and without particle circulation. Signal processing methods, classically used in the scientific literature of fluidized beds, are applied. Combined together, these methods have enabled the identification of bubbling, pistoning (of the wall and axisymmetric), turbulent fluidization and rapid fluidization regimes. The pooling of all this information allows the establishment of a diagram of the fluidization regimes and their transition, showing that the local slip velocity is the key parameter governing the structure of the flow.

Published

2023

8. Dense upflow fluidized bed (DUFB) solar receivers of high aspect ratio: Different fluidization modes through inserting bubble rupture promoters

Author

Raf Dewil, Gilles Flamant, Yimin Deng, Jan Baeyens, Renaud Ansart, Alex Le Gal, Shuo Li, Ronny Gueguen, Florian Sabatier, Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Laboratoire de génie chimique [ancien site de Basso-Cambo] (LGC), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées, Procédés, Matériaux et Energie Solaire (PROMES), Université de Perpignan Via Domitia (UPVD)-Centre National de la Recherche Scientifique (CNRS), Beijing University of Chemical Technology, University of Western Ontario (UWO), Centre National de la Recherche Scientifique - CNRS (FRANCE), Institut National Polytechnique de Toulouse - Toulouse INP (FRANCE), Université Toulouse III - Paul Sabatier - UT3 (FRANCE), Beijing University of Chemical Technology - BUCT (CHINA), Katholieke Universiteit Leuven - KU LEUVEN (BELGIUM), Université de Perpignan Via Domitia - UPVD (FRANCE), and Laboratoire de Génie Chimique - LGC (Toulouse, France)

Subjects

Materials science, General Chemical Engineering, Bubble, Particle-in-tube solar receivers, 02 engineering and technology, Heat transfer coefficient, 010402 general chemistry, 01 natural sciences, Industrial and Manufacturing Engineering, [SPI.MECA.MEFL]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph], Physics::Fluid Dynamics, Bubble rupture promoters, Slugging, Gas through flow, Génie chimique, Environmental Chemistry, Two Fluid Model and sub-grid model, Fluidization, Génie des procédés, Fluidization regimes, ComputingMilieux_MISCELLANEOUS, Turbulence, General Chemistry, Mechanics, Chemical reactor, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Fluidized bed, CFD simulation, Heat transfer, 0210 nano-technology

Abstract

A fluidized bed of Geldart-A particles is promoted as heat transfer fluid in the tubular solar receivers of solar towers. A pressure-driven upward particle flow affects the hydrodynamic flow structure and properties of the fluidized bed. Experiments involved a tube of 0.05 m internal diameter but of very high height/diameter ratio (>120), representative of the future solar receiver and of numerous chemical reactors. Solid circulation fluxes and aeration velocities were varied. Configurations of a bare tube and a tube with bubble rupture promoters were compared. In the bare tube, freely bubbling is transformed into axi-symmetric slugging at a bed level of ~1 m. With bubble rupture promoters, freely bubbling prevails to about a bed level of 3 m, and a turbulent fluidization mode develops higher up the tube (a more chaotic two-phase system with elongated and unstable “gas voids” and “dense solid clusters”), without axi-symmetric slugging detected. Experimental results for both tube configurations were assessed and compared with CFD predictions by the Euler n-fluid code, NEPTUNE_CFD. A good agreement of bed properties was obtained for slug/void frequencies and solids volume fraction in both tube configurations. BRPs moreover enhance the bubble through flow of the fluidizing gas, thus limiting the visible bubble flow rate and bubble sizes while increasing the gas/particle contact, and hence important in designing multi-tube chemical reactors. Whereas slugging limits the heat transfer from the tube wall to the suspension at ~200 W/m2K, the presence of BRPs maintains a heat transfer coefficient in excess of 600 W/m2K.

Published

2021

9. Particle flow and heat transfer in fluidized bed-in-tube solar receivers

Author

Michael Donovan, Gilles Flamant, Jean-Yves Peroy, Alex Le Gal, Ronny Gueguen, Benjamin Grange, Procédés, Matériaux et Energie Solaire (PROMES), and Université de Perpignan Via Domitia (UPVD)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Particle technology, Materials science, 020209 energy, 02 engineering and technology, Mechanics, Heat transfer coefficient, 021001 nanoscience & nanotechnology, 7. Clean energy, [SPI.MECA.MEFL]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph], Volumetric flow rate, Fluidized bed, Heat transfer, Heat exchanger, Concentrated solar power, 0202 electrical engineering, electronic engineering, information engineering, Particle, 0210 nano-technology, ComputingMilieux_MISCELLANEOUS

Abstract

This work is part of the European project “Next-CSP” which aims to develop a next generation of concentrated solar power plants using the particle technology and, particularly, the fluidized particle-in-tube technology working at high temperature (>700°C). A 3MWth pilot unit including a solar receiver, storage tanks, a heat exchanger and a gas turbine is under assembly at the top of a solar tower (Themis-France) to demonstrate this technology. The unit will use the fluidized particle-in-tube solar receiver concept. The scaling up of this concept needs researches on the gas-particle flow structure evolution along the tube and on wall-to-fluidized particles heat transfer. Therefore, several experimental set-ups were implemented to study the particle flow and heat exchanges in order to define the best operational conditions for the fullscale 3MW test unit. The first one is a cold experiment with three 3m-long transparent tubes implemented to study the stability of dense particle suspension (DPS) flow in tube and the flow distribution between the different tubes. 3m is the length of the solar receiver tubes. The second one is an on-sun experiment equipped with a one meter-long finned tube to collect data on the distribution of wall surface and particles temperature, thermal exchange and thermal performance useful for further modelling and up scaling. Experiments with the cold mockup indicate that stable particle flowrate ranging from 10 to 340 kg/m2.s (0.015 to 0.53 g/s) can be obtained per tube with mean particle volume fraction in the range 0.29-0.36. Solar experiments with finned tube designed to increase the heat exchange between the particle suspension and the irradiated tube result in rather constant values of the heat transfer coefficient at about 1200 ± 400 W/m².K for particle mass flux between 40 and 110 kg/m2 .s.

Published

2020