Low-cost automated flat-sheet membrane casting: An open-source, advanced manufacturing approach

IF 4.9 Q1 ENGINEERING, CHEMICAL Journal of Membrane Science Letters Pub Date : 2024-05-02 DOI:10.1016/j.memlet.2024.100075
Nathan Mullins, Irina Babamova, Charles-François de Lannoy, David R. Latulippe
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Abstract

Novel membrane materials developed in research labs struggle to gain widespread industrial adoption due in part to insufficient reproducibility and unreliable performance data. Open-source hardware approaches, especially 3D printing, enable the democratization of automation within a laboratory setting, and in the context of membranes, can minimize the inherent variability associated with manual methods of membrane casting. In this study, the native hardware and firmware of an inexpensive, conventional 3D printer was extensively modified for the purpose of flat-sheet membrane casting. Replicate poly (ether-ether ketone) (PEEK) membranes were cast with a thickness coefficient of variation of ∼10 % using the modified device. Cast membranes were used to assess the importance of controlling shear rate by characterizing both intra- and inter-film variability. Statistical differences in pure water permeability were observed across tested shear rates, with distinct morphological changes occurring to the membrane substructure. Overall, the technology developed in this study is shown to be an extremely useful approach for improving the process of developing membranes at the bench-scale.

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低成本自动化平板膜铸造:一种开源的先进制造方法
研究实验室开发的新型膜材料难以获得广泛的工业应用,部分原因是可重复性不足和性能数据不可靠。开源硬件方法,尤其是三维打印,使实验室环境内的自动化民主化成为可能,在膜方面,可以最大限度地减少与手动膜铸造方法相关的固有可变性。在这项研究中,我们对廉价的传统 3D 打印机的本地硬件和固件进行了广泛修改,以用于平板膜浇铸。使用改进后的设备浇铸了厚度变化系数为 10 % 的聚醚醚酮(PEEK)膜。通过确定膜内和膜间变化的特征,利用浇铸膜来评估控制剪切率的重要性。在不同的测试剪切率下,纯水渗透性存在统计差异,膜的下部结构也发生了明显的形态变化。总之,本研究中开发的技术已被证明是一种非常有用的方法,可用于改进工作台规模的膜开发过程。
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