5 research outputs found
Sustainability optimization of the thermo-biochemical pathway for the production of second-generation ethanol
Renewable energy plays a key role in the fight to reduce greenhouse gas emissions while providing for human well-being and economic development. However, despite environmental benefits in terms of carbon sequestration, largely promoted biorenewable resources such as sugarcane and corn starch, so-called 1st generation (1G) feedstocks, are associated with other types of social and environmental issues that highly contradict the notion of sustainability, such as the food versus fuel conflict and the contribution to impacts such as deforestation, soil degradation, loss of biodiversity and contamination of water resources. As reaction to these issues, a lot of effort has been put into the development of technologies to extract and convert useful energy from non-food crops and agro-industrial residues, such as sugarcane bagasse, corn stover, and wheat straw. These now called 2nd generation (2G) feedstocks offer an extra challenge since fermentable sugars are not readily available; nonetheless, myriad technologies have been (and are being) developed to convert 2G materials into fuels and chemicals, with perhaps the most representative product being ethanol, a widely employed engine fuel and gasoline additive. 2G or cellulosic ethanol can be produced via biochemical pathways, thermochemical pathways, or a third option that combines aspects of the other two, commonly called the thermo-biochemical, or hybrid, pathway. The latter is the focus of this thesis, which explores this pathway via process modeling, simulations, (multi-objective) optimization, and other strategies applied in order to determine which process choices and conditions lead to the best performance in terms of main sustainability aspects. While the thermochemical process of gasification enables the nearly full conversion of biomass without the need for complex and expensive stages of pretreatment and hydrolysis, the subsequent biological conversion (fermentation) of syngas might offer several advantages when compared to the traditional catalytic conversion, e.g. higher flexibility of H2:CO ratios and tolerance to gas contaminants . Although certain challenges may drawback the commercial competitiveness of syngas fermentation, such as the low productivity when compared to heterotrophic fermentation, intelligent choices of process integration and design parameters could substantially enhance the performance of the process.BT/Bioprocess Engineerin
Dynamic modeling of syngas fermentation in a continuous stirred-tank reactor: Multi-response parameter estimation and process optimization
Syngas fermentation is one of the bets for the future sustainable biobased economies due to its potential as an intermediate step in the conversion of waste carbon to ethanol fuel and other chemicals. Integrated with gasification and suitable downstream processing, it may constitute an efficient and competitive route for the valorization of various waste materials, especially if systems engineering principles are employed targeting process optimization. In this study, a dynamic multi-response model is presented for syngas fermentation with acetogenic bacteria in a continuous stirred-tank reactor, accounting for gas–liquid mass transfer, substrate (CO, H2) uptake, biomass growth and death, acetic acid reassimilation, and product selectivity. The unknown parameters were estimated from literature data using the maximum likelihood principle with a multi-response nonlinear modeling framework and metaheuristic optimization, and model adequacy was verified with statistical analysis via generation of confidence intervals as well as parameter significance tests. The model was then used to study the effects of process conditions (gas composition, dilution rate, gas flow rates, and cell recycle) as well as the sensitivity of kinetic parameters, and multiobjective genetic algorithm was used to maximize ethanol productivity and CO conversion. It was observed that these two objectives were clearly conflicting when CO-rich gas was used, but increasing the content of H2 favored higher productivities while maintaining 100% CO conversion. The maximum productivity predicted with full conversion was 2 g·L−1·hr−1 with a feed gas composition of 54% CO and 46% H2 and a dilution rate of 0.06 hr−1 with roughly 90% of cell recycle.BT/Bioprocess EngineeringBT/Biotechnology and Societ
Production of ethanol fuel via syngas fermentation: Optimization of economic performance and energy efficiency
In this work, a model was developed to predict the performance of a bubble column reactor for syngas fermentation and the subsequent recovery of anhydrous ethanol. The model was embedded in an optimization framework which employs surrogate models (artificial neural networks) and multi-objective genetic algorithm to optimize different process conditions and design variables with objectives related to investment, minimum selling price, energy efficiency and bioreactor productivity. The results indicate the optimal trade-offs between these objectives while providing a range of solutions such that, if desired, a single solution can be picked, depending on the priority conferred to different process targets. The Pareto-optimal values of the decision variables were discussed for different case studies with and without the recovery unit. It was shown that enhancing the gas-liquid mass transfer coefficient is a key strategy toward sustainability improvement.BT/Bioprocess EngineeringBT/Biotechnology and Societ
Multi-Objective Sustainability Optimization of Biomass Residues to Ethanol via Gasification and Syngas Fermentation: Trade-Offs between Profitability, Energy Efficiency, and Carbon Emissions
This work presents a strategy for optimizing the production process of ethanol via integrated gasification and syngas fermentation, a conversion platform of growing interest for its contribution to carbon recycling. The objective functions (minimum ethanol selling price (MESP), energy efficiency, and carbon footprint) were evaluated for the combinations of different input variables in models of biomass gasification, energy production from syngas, fermentation, and ethanol distillation, and a multi-objective genetic algorithm was employed for the optimization of the integrated process. Two types of waste feedstocks were considered, wood residues and sugarcane bagasse, with the former leading to lower MESP and a carbon footprint of 0.93 USD/L and 3 g CO2eq/MJ comparedto 1.00 USD/L and 10 g CO2eq/MJ for sugarcane bagasse. The energy efficiency was found to be 32% in both cases. An uncertainty analysis was conducted to determine critical decision variables, which were found to be the gasification zone temperature, the split fraction of the unreformed syngas sent to the combustion chamber, the dilution rate, and the gas residence time in the bioreactor. Apart from the abovementioned objectives, other aspects such as water footprint, ethanol yield, and energyself-sufficiency were also discussed.BT/Bioprocess EngineeringBT/Biotechnology and Societ
Environmental trade-offs of renewable jet fuels in Brazil: Beyond the carbon footprint
The use of renewable jet fuels (RJFs) is an option for meeting the greenhouse gases (GHG) reduction targets of the aviation sector. Therefore, most of the studies have focused on climate change indicators, but other environmental impacts have been disregarded. In this paper, an attributional life cycle assessment is performed for ten RJF pathways in Brazil, considering the environmental trade-offs between climate change and seven other categories, i.e., fossil depletion, terrestrial acidification, eutrophication, human and environmental toxicity, and air quality-related categories, such as particulate matter and photochemical oxidant formation. The scope includes sugarcane and soybean for first-generation (1G) pathways and residual materials (wood and sugarcane residues, beef tallow, and used cooking oil-UCO) for second-generation (2G) pathways. Three certified technologies to produce RJF are considered: hydroprocessed esters and fatty acids (HEFA), alcohol-to-jet (ATJ), and Fischer-Tropsch (FT). Assuming the residual feedstocks as wastes or by-products, the 2G pathways are evaluated by two different approaches, in which the biomass sourcing processes are either accounted for or not. Results show that 1G pathways lead to significant GHG reductions compared to fossil kerosene from 55% (soybean/HEFA) to 65% (sugarcane/ATJ). However, the sugarcane-based pathway generated three-fold higher values than fossil kerosene for terrestrial acidification and air quality impacts, and seven-fold for eutrophication. In turn, soybean/HEFA caused five-fold higher levels of human toxicity. For 2G pathways, when the residual feedstock is assumed to be waste, the potential GHG emission reduction is over 74% with no relevant trade-offs. On the other hand, if the residual feedstocks are assumed as valuable by-products, tallow/HEFA becomes the worst option and pathways from sugarcane residues, even providing a GHG reduction of 67% to 94%, are related to higher impacts than soybean/HEFA for terrestrial acidification and air quality. FT pathways represent the lowest impacts for all categories within both approaches, followed by UCO/HEFA.BT/Biotechnology and SocietyBT/Bioprocess Engineerin