Radial Hydrodynamics in Risers

Godfroy, Larin; Patience, Gregory S.; Chaouki, Jamal

doi:10.1021/ie960784i

Cited by 22 publications

(19 citation statements)

References 11 publications

(20 reference statements)

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“…Agreement with the FCC data was poor although the general trends were reasonable. The predicted solids mass flux at the centre line was approximately a factor of two greater than the measured value and solids downflow along the wall was over-predicted (Godefroy et al, 1999). However, by simply changing the exponent, , from 0.4 to 0.27, the fit between the experimental data and model is excellent, as shown in Figure 7.…”

Section: Radial Profilesmentioning

confidence: 83%

“…There are few pressure taps to cover the entire 27 m but the data would suggest that the entrance and exit effects are minimal: the suspension density decreases linearly with height and the decrease is proportional to the increase in gas velocity. Void fraction data collected by Knowlton (1995) for the CFB Workshop are reproduced in Figure 5 (Godefroy et al, 1999) together with pilot plant data at similar operating conditions. FCC catalyst with a density of 1712 kg/m 3 and an average particle diameter of 76 m was used in the study and the diameter of the riser was 0.2 m. The experiment was conducted at ambient conditions with air.…”

Section: Riser Longitudinal Hold-up Profilementioning

confidence: 99%

“…The data were generated in two risers with a diameter of 0.2 and 0.4 m and three types of particles. Knowlton measured the longitudinal pressure drop as well as the radial profile of the axial mass flux and void fraction at gas velocities ranging from 2.4 and 11 m/s and mass fluxes as high as 800 kg/m 2 s. The comparison between the experimental data and the mathematical modelling was generally poor: some models could account for some of the reported trends in the data but more work was required to capture entrance region affects and the affect of particle diameter on solids hold-up (Godefroy et al, 1999). Experimental studies continue to swell the scientific literature with an ever increasing number of riser conditions, geometries, applications and powder properties.…”

Section: Riser Longitudinal Hold-up Profilementioning

confidence: 99%

“…Godefroy et al (1999) reported an expression for ␥ for a value of ␤ equal to 6 and = 0.4. A more general form for the equation is:…”

Section: Radial Profilesmentioning

confidence: 99%

“…Progress has been made on computational fluid dynamic modelling but it would appear that empirical correlations are more practical and at least as accurate at characterizing the radial and axial solids hold-up (Godefroy et al, 1999). A more ambitious effort has been undertaken to develop a generic fluidized bed reactor model that spans the flow regimes (Abba et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

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Drift flux modelling of CFB risers

Patience¹,

Bockrath²

2008

Can J Chem Eng

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Solids inventory is a critical parameter for catalytic reactors: it impacts the geometrical configuration of the reactor, compressor/blower requirements, and the overall economics of the process. Although significant advances have been made for characterizing the hydrodynamic regimes in gas-solid fluidization, empirical relationships for predicting the solids inventory in risers are largely in the developmental stages. Empirical models are either based on the slip velocity, slip factor or the Richardson-Zaki bed expansion relationship. We propose the drift flux model, commonly for gas-liquid hydrodynamic modelling. The drift flux model accounts for radial variations in the axial velocity profile and void fraction with a distribution parameter, C 0 , and the relative velocity between the phases with the drift velocity, U 2j :In high density risers, the distribution parameter varies between 1.03 and 1.12. The drift velocity is a function of the product of the particle terminal velocity and varies with solids hold-up.L'inventaire des solides est un paramètre critique pour les réacteurs catalytiques: il a une influence sur la configuration géométrique du réacteur, les besoins du compresseur/soufflante et les aspectséconomiques du procédé. Bien que des avancées significatives aientété réalisées dans la caractérisation des régimes hydrodynamiques en fluidisation gaz-solide, les relations empiriques pour prédire l'inventaire des solides dans les colonnes montantes en sont encore largementà un stade de développement. Les modèles empiriques reposent soit sur la vitesse de glissement, le facteur de glissement ou la relation d'expansion de lit de Richardson-Zaki. Nous proposons le modèle de flux de dérive qui est commun pour la modélisation hydrodynamique gaz-liquide. Le flux de dérive tient compte des variations radiales du profil de vitesse axiale et de fraction de vide avec un paramètre de distribution, C 0 , et de la vitesse relative entre les phases avec la vitesse de dérive, V gj :Dans les colonnes montantes de grande densité, le paramètre de distribution varie entre 1,03 et 1,12. La vitesse de dérive est une fonction du produit de la vitesse terminale des particules et varie avec la rétention de solides.

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Section: Radial Profilesmentioning

confidence: 83%

Section: Riser Longitudinal Hold-up Profilementioning

confidence: 99%

Section: Riser Longitudinal Hold-up Profilementioning

confidence: 99%

“…Godefroy et al (1999) reported an expression for ␥ for a value of ␤ equal to 6 and = 0.4. A more general form for the equation is:…”

Section: Radial Profilesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Drift flux modelling of CFB risers

Patience¹,

Bockrath²

2008

Can J Chem Eng

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Effect of Fuel Size and Process Temperature on Fuel Gas Quality from CFB Gasification of Biomass

Drift

Doorn

2001

Progress in Thermochemical Biomass Conversion

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A bench-scale CFB-gasifier with a capacity of max. 500 kW th has been used to study the effect of fuel size and process temperature. A higher process temperature (range tested: 750 to 910°C) results in more air needed to maintain the desired temperature, a lower heating value of the product gas, a higher carbon conversion and a net increase of cold gas efficiency of the gasifier. A higher process temperature also results in less heavy tars. However, light tars (measured using the SPA-method) do show an odd behaviour. Some individual components within the group of light tars even increase in concentration when process temperature is raised. The main reason probably is that heavy tars decompose to these relatively stable light tar components. The particle size of the fuel does influence some product gas parameters considerably. The presence of small particles seems to increase the (heavy) tar concentration and decrease the conversion of fuel-nitrogen to ammonia. Small particles can also be responsible for large temperature gradients along the axis of the riser of a CFB-gasifier. This effect can be avoided by either mixing the fuel with larger particles or feed the small particles at the bottom of the reactor. ACKNOWLEDGEMENTThe Dutch agency for energy and environment (Novem) and EnergieNed, Federation of energy companies in the Netherlands, are greatly acknowledged for their (financial) contribution to the work reported in this paper.

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