期刊
CHEMICAL ENGINEERING RESEARCH & DESIGN
卷 195, 期 -, 页码 637-650出版社
ELSEVIER
DOI: 10.1016/j.cherd.2023.06.008
关键词
Liquid-gas multiphase contactors; 3D foam-printed packing; Mass-transfer coefficients; Pressure drops; Flue Gas Desulfurization; ASPEN PLUS (R)
In this study, pilot-scale tests were conducted on a new design of Y-type corrugated polylactic acid (PLA) packing produced by a one-step 3D foam-printing process. Experimental tests showed that the FT.Y packing exhibited comparable or superior performance to the benchmark commercial Mellapak 250Y packing in terms of pressure drops and mass transfer coefficients. The FT.Y packing also demonstrated higher desulfurization efficiencies in wet Flue Gas Desulfurization than the benchmark packing. Overall, the 3D foam-printed FT.Y packing shows great potential in process intensification for absorption and distillation processes.
In this work, we report pilot-scale tests on a new design of Y-type corrugated polylactic acid (PLA) packing (Prototype FT.Y), produced by an innovative additive manufacturing process consisting of a one-step 3D foam-printing process. The design characteristics of the packing and the surface texture of the prototype, which is analyzed with optical measurements, are presented. The performances of the FT.Y packing are characterized and compared with those of a benchmark commercial Mellapak 250Y packing, through experimental tests aimed to estimate pressure drops and mass transfer coefficients. The new packing is also tested for a reference absorption case study, the wet Flue Gas Desulfurization (wet-FGD), for its large application in the process industry and as a lab testing method. The 3D foam printing technology allows for an easy tailor-made design of the packing, providing lower weights and interesting surface properties. These translate in low pressure drops and high mass transfer coefficients, which are comparable or superior to those of the Mellapak 250.Y. Indeed, the FT.Y packing provides high liquid-film mass transfer coefficients, which allows desulfurization efficiencies up to 42 % higher than those expected for the benchmark packing. Beyond the potential manufacturing advantages provided by the 3D-foam printing, the FT.Y packing performances make this unit a valuable alternative for process intensification in absorption and distillation processes, especially in those cases when the liquid-film mass transfer resistance has a relevant role in the process design. (c) 2023 Institution of Chemical Engineers. Published by Elsevier Ltd. All rights reserved.
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