Recovery of volatile solutes from dilute aqueous solutions using immobilized silicalite

Separations Technology Pub Date : 1994-10-01 DOI:10.1016/0956-9618(94)80026-X

Mark T. Holtzapple, Kathryn L. Flores, Russell F. Brown

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引用次数: 8

Abstract

A silicalite/polyethylene mixture was sintered to the exterior of a heat exchanger tube allowing regeneration by steam or hot water, rather than by inefficient, hot stripping gases. Ethanol, acetone, and butanol were adsorbed onto the silicalite until a final bulk concentration of 4 g/L was obtained. Single-step desorption would enrich ethanol 5.2 times, 1-butanol 9.3 times, and acetone 10.1 times. In an attempt to increase the product concentration even more, the silicalite was regenerated using “temperature-programmed desorption,” where the water was selectively removed at a lower temperature and the solute was selectively removed at a higher temperature. The high-temperature desorption enriched ethanol up to 11.1 times, 1-butanol 4.44 times, and acetone 22.1 times, but at the expense of lower solute recovery. Temperature-programmed desorption was able to significantly enrich the product compared to single-step desorption except for butanol, for which higher regeneration temperatures were required.

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用固定化硅石从稀水溶液中回收挥发性溶质

硅石/聚乙烯混合物烧结到热交换器管的外部，允许蒸汽或热水再生，而不是低效的热汽提气体。乙醇、丙酮和丁醇被吸附到硅石上，直到最终体积浓度为4 g/L。一步解吸可富集乙醇5.2倍，1-丁醇9.3倍，丙酮10.1倍。为了进一步提高产品浓度，硅石采用“温度程序解吸”再生，即在较低温度下选择性地去除水，在较高温度下选择性地去除溶质。高温解吸可使乙醇富集11.1倍，丁醇富集4.44倍，丙酮富集22.1倍，但溶质回收率较低。与单步脱附相比，程序升温脱附能显著富集产物，但对再生温度要求较高的丁醇除外。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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