Abstract
Gasification represents a potential technology for the conversion of biomass into usable energy. The influence of the main gasification parameters, i.e. the type of biomass used and its composition, as well as the composition of the outlet gas, were studied by a multivariate statistical analysis based on principal component analysis (PCA) and partial least square (PLS) regression models in order to identify the main correlations between them and to the contents of methane, ethylene and tar in the outlet gas. In this work, the experimental data used as input for the multivariate statistical analysis came from a TRL-4 gasification plant running under sorption enhanced conditions, i.e. using steam as the gasifying agent and CaO as the bed material. The composition of the biomass feed played an important role in the quality of the outlet gas composition. In fact, biomasses with high ash and sulphur contents (municipal solid waste) increased ethylene content, while those with high-volatile matter content and fixed C content (wood pellets, straw pellets and grape seeds) mainly increased CO and CO2 formation. By increasing the gasification bed temperature and the CaO/C ratio, it was possible to reduce the methane and the collected tar contents in the outlet gas. Other light hydrocarbons could also be reduced by controlling the Treactor and TFB. Methane, ethylene and tar contents were modelled, cross-validated and tested with a new set of samples by PLS obtaining results with an average overall error between 8 and 26%. The statistically significant variables to predict methane and ethylene content were positively associated to the thermal input and negatively to the CaO/C ratio. The biomass composition was also remarkable for both variables, as mentioned in the PCA analysis. As far as the tar content, which is undesirable in all gasification processes, the decrease in the tar content was favoured by high bed temperature, low thermal input and biomass with high-volatile matter content. In order to produce an outlet gas with adequate quality (e.g. low tar content), a compromise should be found to balance average bed temperature, sorbent-to-mass ratio, and ultimate and proximate analyses of the biomass feed.Graphical abstract
Highlights
Effective climate change mitigation needs a substantial reduction of greenhouse gas emissions, and to do so, an important shift from fossil to renewable energy is needed [1]
The second factor (Fig. 5b) was associated with thermal input and negatively correlated to CaO-to-C molar ratio (CaO/C), Tbed, Treactor and TFB and confirmed the results shown in the principal component analysis (PCA) analysis
The PCA study provided valuable information concerning the relationships between the gasification parameters in an sorption-enhanced gasification (SEG) process, the biomass feedstock used and the composition of the outlet gas, indicating which variables had the greatest effect on this composition
Summary
Effective climate change mitigation needs a substantial reduction of greenhouse gas emissions, and to do so, an important shift from fossil to renewable energy is needed [1]. Biomass is a renewable energy source that could play a crucial role in climate change mitigation due to its consideration as carbon–neutral energy compared to fossil fuels, since the CO2 released when biomass is burned is the C O2 that plants capture through photosynthesis as they grow [2]. In this way, biofuels produced from biomass could be decisive in the decarbonisation of heat, transport, electricity and high-value chemical production sectors [3]. The resulting solid phase, referred to as char, is composed of the inert and the unconverted organic fraction, mainly carbon and ash
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