利用硫酸盐浆进行超细摩擦磨机制备纳米纤化纤维素的有效预处理

IF 0.9 4区农林科学 Q3 MATERIALS SCIENCE, PAPER & WOOD

Nordic Pulp & Paper Research Journal Pub Date : 2023-03-31 DOI:10.1515/npprj-2022-0091

G. G. de Lima, B. Aggio, M. Matos, T. A. M. D. de Lima, B. Pereira, A. C. Pedro, W. L. Magalhães

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引用次数: 1

摘要

摘要获得纳米纤维素的方法已被广泛提出，其中最具竞争力的方法包括机械除颤，这产生了可用于各种应用的纳米纤维素凝胶悬浮液。然而，由于其物理方法，标准程序会导致纤维尺寸不均匀。有人建议进行预处理，例如酶，但它们的成本是不利的。在这项工作中，我们建议使用低温切割法漂白硫酸盐浆，使用一种简单的方法，将干燥的硫酸盐浆嵌入蒸馏水中，然后在−80°C下冷冻，使用普通搅拌器切割，并将其放入超细摩擦研磨机中。在不同的研磨步骤5、15、30、60和120对样品进行了研究。总的来说，在30步和120步时，用冷冻斜杠除颤所需的能量差分别为~3.26 kWh/kg和~6，这与用纳米纤维进行的酶促预处理相似，明显更小。Cryoslash从纳米纤维素中呈现出独特的C–H平面内结构，这与原纤维平均尺寸的减小有关，而纳米纤维素的结晶度和热性能在60步时保持稳定，但机械性能随着与能耗曲线有关的透射率值而增加，直到120步。

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Cryoslash as an effective pre-treatment to obtain nanofibrillated cellulose using ultra-fine friction grinder with kraft pulp

Abstract Approaches to obtain nanocellulose have been extensively suggested, and among the most competitive methodologies includes mechanical defibrillation, which results in a nanocellulose gel suspension that can be used in a variety of applications. However, standard procedures results in inhomogeneous fibre sizes due to its physical approach. Pre-treatments have been suggested, such as enzymes, but their cost is a disadvantage. In this work, we suggest the use of cryoslash for bleach kraft pulp using a simple methodology of embedding the dry kraft pulp in distilled water following by freezing at −80 °C, which was slashed using a common blender and submitted to an ultra-fine friction grinder. Samples were studied at various grinding steps 5, 15, 30, 60 and 120. Overall, the energy difference required to defibrillate with cryoslash was ∼3.26 kWh/kg at 30 steps and ∼6 at 120 steps, which was similar to enzymatic pre-treatment with nanofibrils significantly smaller. Cryoslash presented a unique C–H in plane structure from nanocellulose, related to a decrease in average size of fibrils, while crystallinity and thermal properties of nanocellulose remained stable at 60 steps, but mechanical properties increased until 120 steps along with the transmittance values related to the energy consumption curve.

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来源期刊

Nordic Pulp & Paper Research Journal 工程技术-材料科学：纸与木材

CiteScore

2.50

自引率

16.70%

发文量

审稿时长

1 months

期刊介绍： Nordic Pulp & Paper Research Journal (NPPRJ) is a peer-reviewed, international scientific journal covering to-date science and technology research in the areas of wood-based biomass: Pulp and paper: products and processes Wood constituents: characterization and nanotechnologies Bio-refining, recovery and energy issues Utilization of side-streams from pulping processes Novel fibre-based, sustainable and smart materials. The editors and the publisher are committed to high quality standards and rapid handling of the peer review and publication processes. Topics Cutting-edge topics such as, but not limited to, the following: Biorefining, energy issues Wood fibre characterization and nanotechnology Side-streams and new products from wood pulping processes Mechanical pulping Chemical pulping, recovery and bleaching Paper technology Paper chemistry and physics Coating Paper-ink-interactions Recycling Environmental issues.