Evaluating ultra-fine friction grinding for the continuous production of nanofibrillated cellulose

Huy Vu Duc, Nguyen, Angus C. L. A. , Crampton, Daniel F, Schmidt, Tim, Huber
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Abstract

Nanofibrillated cellulose (NFC) has applications in many sectors, but economical production of large volumes with a minimized ecological footprint remains challenging. In this study, we have developed a new design to upgrade the Masuko Supermasscolloider from a traditional batch mode to continuous circulation. This upgrade includes a pump-controlled circulating system, an in-line viscosimeter for real-time measurement of cellulose suspension viscosity, and a power meter to monitor and evaluate the energy consumption of both the pump and the grinder throughout the process. These modifications address the limitations of scaling up NFC production, offering a more efficient and effective approach. We investigated the production of NFC from cellulose feedstock derived from miscanthus biomass under various conditions, including different initial cellulose concentrations (1 wt%, 1.5 wt% and 2 wt%) and processing volumes (15L and 25 L) at different grinding time (from 15 minutes to 120 minutes, with 15 minutes intervals). A systematic study on the effect of these processing conditions on the size distribution of NFC particles was conducted using an analytical centrifuge (Lumisizer). A prevalence of particles with equivalent hydrodynamic diameters between ~250 nm and ~300 nm was observed regardless of the processing conditions. Notably, in the context of large-scale NFC production, our approach demonstrated a 70% reduction in specific energy consumption by either increasing the processing volume from 15 L to 25 L and increasing the initial cellulose concentration from 1 wt% to 2 wt%. Additionally, we explored the application of produced NFC as nanofillers in nanocomposite packaging materials. Specifically, NFC particles processed at different grinding times were incorporated into a glycerol-plasticized carboxymethyl cellulose (CMC) matrix to form bio-nanocomposite films. We have found that particles obtained with longer grinding time did not lead to increased mechanical performance. This simplifies the NFC production process by reducing the need for prolonged grinding, thereby saving time and energy while maintaining the desired properties of the nanocomposite samples.
评估用于连续生产纳米纤维素的超细摩擦研磨技术
纳米纤维素(NFC)在许多领域都有应用,但要在最大程度减少生态足迹的前提下实现大批量的经济生产仍具有挑战性。在这项研究中,我们开发了一种新的设计,将 Masuko Supermasscolloider 从传统的间歇模式升级为连续循环模式。这种升级包括一个由泵控制的循环系统、一个用于实时测量纤维素悬浮液粘度的在线粘度计,以及一个用于监测和评估整个过程中泵和粉碎机能耗的功率计。这些改进解决了扩大 NFC 生产规模的局限性,提供了一种更高效、更有效的方法。我们研究了在不同条件下,包括不同的初始纤维素浓度(1 wt%、1.5 wt% 和 2 wt%)和处理量(15 升和 25 升),以及不同的研磨时间(从 15 分钟到 120 分钟,间隔 15 分钟),利用芒草生物质纤维素原料生产 NFC 的情况。使用分析离心机(Lumisizer)对这些加工条件对 NFC 颗粒粒度分布的影响进行了系统研究。结果表明,无论加工条件如何,等效流体力学直径在 ~250 nm 到 ~300 nm 之间的颗粒都很普遍。值得注意的是,在大规模 NFC 生产的背景下,我们的方法证明,将处理量从 15 升增加到 25 升,并将初始纤维素浓度从 1 wt% 提高到 2 wt%,可将特定能耗降低 70%。此外,我们还探索了生产的 NFC 作为纳米填料在纳米复合包装材料中的应用。具体来说,我们将以不同研磨时间加工的 NFC 颗粒加入甘油塑化的羧甲基纤维素(CMC)基质中,形成生物纳米复合薄膜。我们发现,用较长的研磨时间获得的颗粒不会提高机械性能。这简化了 NFC 的生产过程,减少了长时间研磨的需要,从而节省了时间和能源,同时保持了纳米复合材料样品的理想性能。
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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