1. A novel semi-batch autoclave reactor to overcome thermal dwell time in solvent liquefaction experiments
- Author
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Jessica L. Brown, Emiel J. M. Hensen, Michael Boot, Sean A. Rollag, Panos D. Kouris, Ryan G. Smith, Robert C. Brown, Arpa Ghosh, Preston Gable, Jake K. Lindstrom, Chad A. Peterson, Inorganic Materials & Catalysis, Energy Technology, and EIRES Chem. for Sustainable Energy Systems
- Subjects
Process development ,Materials science ,General Chemical Engineering ,02 engineering and technology ,010402 general chemistry ,Lignin ,01 natural sciences ,Industrial and Manufacturing Engineering ,Autoclave ,Reaction rate ,Heat transfer ,Environmental Chemistry ,Process engineering ,business.industry ,Continuous reactor ,Liquefaction ,General Chemistry ,021001 nanoscience & nanotechnology ,Biorefinery ,Solvent liquefaction ,0104 chemical sciences ,Solvent ,Dwell time ,Isobaric process ,0210 nano-technology ,business - Abstract
The thermal profile of solvent liquefaction experiments must be well-controlled to generate data suitable for process scaling and technoeconomic analysis. Acknowledging the differences in small-scale batch systems compared to continuous commercial processes is important. In particular, many experiments have long heating and cooling periods, which influence rates of reaction in ways that would not occur in commercial continuous reactors. To overcome this problem, a novel semi-batch autoclave (SBA) system was built to rapidly heat reactants and cool products while maintaining constant pressure during solvent liquefaction experiments. In this study, the performance of the SBA reactor was compared to an isobaric conventional batch autoclave (ICBA) reactor in the solvent liquefaction of lignin in n-butanol. Heat transfer affected both the apparent reaction rate and measured product yields. Solvent liquefaction limited by slow heating gave the misperception that reaction rates were faster than was actually the case and promoted the formation of char-like solids. Experiments constrained by slow heat transfer are of limited use in process modeling and reactor design, which would otherwise result in undersized reactors for desired processing rates. The SBA system facilitates the design and scale-up of commercial SL plants as it approximates the thermal profile of a continuous system.
- Published
- 2021
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