TY - JOUR ID - 26198 TI - Impact of Measuring Devices and Data Analysis on the Determination of Gas Membrane Properties JO - Journal of Membrane Science and Research JA - JMSR LA - en SN - AU - Wu, Haoyu AU - Kruczek, Boguslaw AU - Thibault, Jules AD - University of Ottawa, Department of Chemical and Biological Engineering 161 Louis Pasteur, Ottawa, Ontario, Canada K1N 6N5 AD - Department of Chemical Engineering, Faculty of Engineering, University of Ottawa AD - Department of Chemical and Biological Engineering, Faculty of Engineering, University of Ottawa, Ottawa, Ontario, Canada Y1 - 2018 PY - 2018 VL - 4 IS - 1 SP - 4 EP - 14 KW - Gas Membrane Characterization KW - Time-lag KW - Pressure Transducer KW - Data Variability KW - Nonlinear Least Squares DO - 10.22079/jmsr.2017.63433.1136 N2 - The time-lag method, using a gas permeation experiment, is currently the most popular method for determining the membrane properties: diffusivity coefcient and permeability coefcient, and from which the solubility coefcient can be calculated. In this investigation, the impact of systematic, random (noise), resolution and extrapolation errors associated with gas permeation experiments on the determination of the membrane properties using the time-lag method is investigated. A comprehensive error analysis for each type of errors and their combination is presented. Random and resolution errors have a greater impact on the determination of the time lag for low rates of downstream pressure accumulation which can be alleviated by increasing the capacity parameter. Increasing the feed pressure lowers the resolution errors, but has no effect on random errors. Extrapolation errors associated with the time-lag method, which increase with time, can be reduced by increasing the number of evaluation points and the length of the evaluation window. Because of their strong correlation, it is difcult to decouple solubility and diffusivity coefcients accurately without using the time-lag. A judicious balance between data precision, the drop in the driving force and the duration of an experiment must be considered in the design of a constant-volume membrane system and in the selection of experimental operating conditions to minimize the impact of pressure variability. The necessity of a small capacity parameter for the accurate determination of membrane properties needs to be reconsidered in the presence of experimental noise. UR - https://www.msrjournal.com/article_26198.html L1 - https://www.msrjournal.com/article_26198_dd87a0903c1adbfbc92a9605a71377fe.pdf ER -