Abstract
Pervaporation is a peculiar membrane separation process, which is considered for integration with a variety of reactions in promising new applications. Pervaporation membrane reactors have some specific uses in sustainable chemistry, such as the esterification processes. This theoretical study based on the computational fluid dynamics method aims to evaluate the performance of a multi-bed pervaporation membrane reactor (including poly (vinyl alcohol) membrane) to produce ethyl levulinate as a significant fuel additive, coming from the esterification of levulinic acid. For comparison, an equivalent multi-bed traditional reactor is also studied at the same operating conditions of the aforementioned pervaporation membrane reactor. A computational fluid dynamics model was developed and validated by experimental literature data. The effects of reaction temperature, catalyst loading, feed molar ratio, and feed flow rate on the reactor’s performance in terms of levulinic acid conversion and water removal were hence studied. The simulations indicated that the multi-bed pervaporation membrane reactor results to be the best solution over the multi-bed traditional reactor, presenting the best simulation results at 343 K, 2 bar, catalyst loading 8.6 g, feed flow rate 7 mm3/s, and feed molar ratio 3 with levulinic acid conversion equal to 95.3% and 91.1% water removal.
Highlights
Global warming caused by the growing greenhouse gases generation has been currently recognized as a major environmental problem
Since diesel engines are responsible for high nitrogen oxides (NOx) and exhaust gas emissions, they have negative effects on the environment
One of the most effective methods consists of the addition of oxygenates to fossil fuels, which are known as alkyl levulinate as a fuel oxygenate
Summary
Global warming caused by the growing greenhouse gases generation has been currently recognized as a major environmental problem. Numerical models could be useful to avoid high experimental costs and to develop a better understanding of the effects of various parameters for the design and the fruitful application of PVMR in the levulinic acid esterification (LA-ESR) as well as for specific features and constraints such as the need of obtaining high conversion. To this purpose, the computational fluid dynamic (CFD) tool is a feasible method to simulate detailed liquid flow characteristics at any point of a membrane system. The water permeating flux (J0,H2O) is reported at different temperatures in Table 2 [25]
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