Experimental Fact-Finding in CFB Biomass Gasification for ECN's 500 kW<sub>th</sub> Pilot Plant

Kersten, Sascha R.A.; Prins, Wolter; Drift, A. van der; Swaaij, W.P.M. van

doi:10.1021/ie020818o

Cited by 36 publications

(37 citation statements)

References 18 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Li et al showed that the carbon conversion for coal gasification in the temperature range of 747–877°C was similar to the carbon conversion for assumed equilibrium conditions at 250°C. Kersten et al found that for char gasification in the temperature range of 740–910°C, the measured unconverted carbon was close to the equilibrium value obtained in the temperature range of 450–580°C.…”

Section: Review Of Previous Workmentioning

confidence: 56%

A modified thermodynamic equilibrium model for woody biomass gasification

et al. 2013

View full text Add to dashboard Cite

A modified thermodynamic equilibrium model has been developed to improve the prediction of syngas composition produced by the gasification of woody biomass. A comparison of data produced by an equilibrium model with available experimental data from bubbling biomass fluidised bed gasifiers indicates that the equilibrium model significantly underestimates the methane yield. In the proposed model, a semi‐empirical devolatilisation model is used to eliminate the methane deviation by taking into account the fact that methane, which is initially generated in the devolatilisation process, does not reform through gasification reactions. The modified model estimates the syngas composition more accurately than previously published modified equilibrium models.

show abstract

Section: Review Of Previous Workmentioning

confidence: 56%

A modified thermodynamic equilibrium model for woody biomass gasification

et al. 2013

View full text Add to dashboard Cite

show abstract

“…The Energy Research Centre of the Netherlands (ECN) 500 kW th air gasification process was also modeled using this procedure. The inlet parameters and experiment results are obtained from the literature 11. Table 4 shows that the method predicts the composition results well compared with the ECN’s literature value.…”

Section: Methods Validation Using Pilot Experimental Datamentioning

confidence: 93%

Simulation of Biomass Gasification and Application in Pilot Plant

Han

et al. 2015

Energy Tech

View full text Add to dashboard Cite

In the present work, a revised equilibrium model (gas–solid) was built. The temperature approach to equilibrium for the methane cracking reaction was specified to improve the prediction accuracy. The model was applied and validated in pilot scale experiments using a 150 kg h−1 two‐stage downdraft gasifier and a gasifier from the Energy Research Centre of the Netherlands (ECN). The type of gasification agent is a dominant factor that determines product gas composition, quality, and end‐use. A theoretical analysis of the effect of gasifying agent on product gas quality and process efficiency was executed based on the model calculation. The optimal operation conditions were established for the three (air, steam, oxygen–steam) gasification processes. For air gasification, an optimal value of equivalence ratio (ER) of 0.31 corresponds to the maximum gasification efficiency. The optimal range of steam/carbon ratio (SR) is between 0.7 and 0.8 for the equilibrium of the water–gas shift and steam reforming reactions. For autothermal oxygen–steam gasification, the H2 concentration reaches the highest value for SR=1.0.

show abstract

“…However, it is energy consuming when large quantities of iron oxide are circulated between the oxidator and reductor. Therefore, a ratio of 60, which is close to normal circulation rates of solids in biomass gasifiers (Kersten et al 2003), is chosen. The pumping requirements for the circulation of the iron oxides are not taken into consideration in the present analysis.…”

Section: Experimental Approachmentioning

confidence: 99%

Hydrogen production from pyrolysis oil using the steam-iron process: a process design study

Bleeker

Gorter

Kersten

et al. 2009

Clean Techn Environ Policy

View full text Add to dashboard Cite

The overall energy efficiency of the production of pure hydrogen using the pyrolysis oil driven steam-iron process is evaluated for different process conditions. The process consists of a two-step process (reduction with pyrolysis oil, oxidation with steam) from which pure hydrogen can be obtained, without purification steps. An optimum energy efficiency of 53% is achieved when the equilibrium conversion is obtained in the redox cycle at 800°C. When assuming chemical equilibrium, increasing the process temperature results in a low process efficiency due to a large amount of unreacted steam that needs to be condensed to separate the hydrogen product. Using experimental data in the process simulation, a high-energy efficiency is obtained at 920°C (39%) compared with the efficiency at 800°C (29%). This is caused by the low conversion in the reduction at 800°C. Improving the iron oxide material to enhance the reduction with pyrolysis oil at 800°C, is therefore suggested.

show abstract

Experimental Fact-Finding in CFB Biomass Gasification for ECN's 500 kW_th Pilot Plant

Cited by 36 publications

References 18 publications

A modified thermodynamic equilibrium model for woody biomass gasification

A modified thermodynamic equilibrium model for woody biomass gasification

Simulation of Biomass Gasification and Application in Pilot Plant

Hydrogen production from pyrolysis oil using the steam-iron process: a process design study

Contact Info

Product

Resources

About

Experimental Fact-Finding in CFB Biomass Gasification for ECN's 500 kWth Pilot Plant

Cited by 36 publications

References 18 publications

A modified thermodynamic equilibrium model for woody biomass gasification

A modified thermodynamic equilibrium model for woody biomass gasification

Simulation of Biomass Gasification and Application in Pilot Plant

Hydrogen production from pyrolysis oil using the steam-iron process: a process design study

Contact Info

Product

Resources

About

Experimental Fact-Finding in CFB Biomass Gasification for ECN's 500 kW_th Pilot Plant