Effects of mechanical fibrillation time by disk grinding on the properties of cellulose nanofibrils

IF 0.6 4区 农林科学 Q4 MATERIALS SCIENCE, PAPER & WOOD
Tappi Journal Pub Date : 2016-07-01 DOI:10.32964/TJ15.6.419
Quian Wang, J. Zhu
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Specific tensile strength and Young’s modulus of the CNF films made of CNF suspension with only 0.5 h grinding were increased approximately 30% and 200%, respectively, compared with conventional handsheets prepared by valley beating to 300 Canadian Standard Freeness (CSF). Energy input was only 1.38 kWh/kg for 0.5 h grinding. Grinding beyond 0.5 h produced negligible improvement in specific tensile and specific modulus. Opacity of CNF films decreased rapidly during the first 1.5 h of fibrillation and then plateaued. Application: Disk milling time affects the morphology of cellulose nanofibrils as well as the optical and mechanical properties of film made of the resultant fibrils. Cellulose nanomaterials, such as cellulose nanofibrils (CNF) derived from renewable lignocelluloses, have attracted great interest recently. Lignocelluloses are available in nature in great abundance. Cellulose nanofibrils have been used for producing a range of functional materials including films, membranes, aerogels, scaffolds, and hybrid composites [1-4] and have the potential to replace a variety of materials derived from nonrenewable petroleum. Mechanical fibrillation remains the most common approach to produce CNF from lignocelluloses. Microgrinding has the potential for large-scale CNF production and has been widely used [5-9]. Microgrinding leads to a series of dramatic changes in fibers, such as internal fibrillation, external fibrillation, and fiber shortening. Continued fibrillation resulted in fragmentation of cell wall and produced microand nanofibrils [10]. The dominant factors that dictate nanocellulose material strength are the fibril length and fiber bonding. The orientation of bonds between nanoparticles is an important factor in tuning the Young’s modulus [11]. Increased grinding often results in increased bonding as a result of the fine materials produced that substantially increase fibril surface area. On the other hand, increased grinding time can also result in short fibrils simply because of mechanical actions. There is a tradeoff between increasing bonding and reducing fibril length with extended grinding; in other words, an optimal grinding time exists for producing CNF for polymer reinforcement. Unfortunately, such an understanding has not been well documented. The objective of the present study is to investigate the effects of mechanical fibrillation time on the properties of resultant CNF films. MATERIAL AND METHODS Dry lap of a bleached kraft eucalyptus pulp from Fibria (Aracruz, Brazil) was the same pulp used in previous studies [10,12–14], with major chemical composition of 78.1% ± 1.0% glucan, 15.3% ± 0.6% xylan, and 0.7% ± 0.1% Klason lignin. The dry lap was soaked in distilled water for 24 h before disintegration in a laboratory disintegrator. Mechanical fibrillation For the experiment, 140 g of o.d. bleached kraft eucalyptus pulp was fibrillated at 2 wt% consistency using a supermasscolloider (model MKZA6-2, Masuko Sangyo; Kawaguchi, Japan) at 1500 rpm as described previously [10]. Approximately 130 g was beaten in a Valley beater (Valley Laboratory Equipment, Voith; Appleton, WI, USA) to approximately 300 mL Canadian Standard Freeness (CSF) as a control sample. Fractionation of CNF by centrifuge An attempt was made to fractionate large networked CNF from small ones by centrifuge. Cellulose nanofibrils solution from 11 h of fibrillation was diluted to 0.2 wt% and continuously stirred for 1 h and then centrifuged at 1000 rpm for 15 JUNE 2016 | VOL. 15 NO. 6 | TAPPI JOURNAL 419 CELLULOSE NANOFIBRILS 1. Transmission electron microscopy images of cellulose nanofibrils (CNF) samples at different fibrillation times: (a) 0.5 h, (b) 3 h, (c) 7 h, and (d) 11 h; scale bar = 500 nm. min in a Sorvall Superspeed RC2-B 5.75-in. rotator (Ivan Sorvall; Norwalk, CT, USA). The supernatant liquid was carefully removed with a pipette from the precipitation layer. Preparation and testing of CNF film Solutions of CNF were diluted to 0.1 wt% and mixed for 4 h using a magnetic stir. A 9-in. vacuum filtration system with a 0.45-μm Durapore membrane (Millipore; Billerica, MA, USA) was used to prepare CNF film. Wet films together with blotting paper were pressed at 206 and 345 kPa for 3 min and then dried in a copper dry ring. Film opacity, basis weight, and thickness were measured according to TAPPI T519 om-06 “Diffuse opacity of paper (d/0 paper backing),” T410 om-08 “Grammage of paper and paperboard (weight per unit area),” and T411 om-10 “Thickness (caliper) of paper, paperboard, and combined board,” respectively. Strain-stress testing was determined using an Instron 5865 Advanced Mechanical Testing System (Instron; Norwood, MA, USA). 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引用次数: 11

Abstract

Cellulose nanofibrils (CNF) were successfully produced from a bleach kraft eucalyptus pulp by a supermasscolloider. Effects of grinding time on structure and properties of CNF and the corresponding CNF films were investigated. Grinding time was important to increase the optical transparency of CNF suspensions. The degree of polymerization (DP) and crystallinity index (CrI) of CNF decreased linearly with the increase in CNF suspension transparency. This suggests optical transparency of a CNF suspension can be used to characterize the degree of fibrillation. Specific tensile strength and Young’s modulus of the CNF films made of CNF suspension with only 0.5 h grinding were increased approximately 30% and 200%, respectively, compared with conventional handsheets prepared by valley beating to 300 Canadian Standard Freeness (CSF). Energy input was only 1.38 kWh/kg for 0.5 h grinding. Grinding beyond 0.5 h produced negligible improvement in specific tensile and specific modulus. Opacity of CNF films decreased rapidly during the first 1.5 h of fibrillation and then plateaued. Application: Disk milling time affects the morphology of cellulose nanofibrils as well as the optical and mechanical properties of film made of the resultant fibrils. Cellulose nanomaterials, such as cellulose nanofibrils (CNF) derived from renewable lignocelluloses, have attracted great interest recently. Lignocelluloses are available in nature in great abundance. Cellulose nanofibrils have been used for producing a range of functional materials including films, membranes, aerogels, scaffolds, and hybrid composites [1-4] and have the potential to replace a variety of materials derived from nonrenewable petroleum. Mechanical fibrillation remains the most common approach to produce CNF from lignocelluloses. Microgrinding has the potential for large-scale CNF production and has been widely used [5-9]. Microgrinding leads to a series of dramatic changes in fibers, such as internal fibrillation, external fibrillation, and fiber shortening. Continued fibrillation resulted in fragmentation of cell wall and produced microand nanofibrils [10]. The dominant factors that dictate nanocellulose material strength are the fibril length and fiber bonding. The orientation of bonds between nanoparticles is an important factor in tuning the Young’s modulus [11]. Increased grinding often results in increased bonding as a result of the fine materials produced that substantially increase fibril surface area. On the other hand, increased grinding time can also result in short fibrils simply because of mechanical actions. There is a tradeoff between increasing bonding and reducing fibril length with extended grinding; in other words, an optimal grinding time exists for producing CNF for polymer reinforcement. Unfortunately, such an understanding has not been well documented. The objective of the present study is to investigate the effects of mechanical fibrillation time on the properties of resultant CNF films. MATERIAL AND METHODS Dry lap of a bleached kraft eucalyptus pulp from Fibria (Aracruz, Brazil) was the same pulp used in previous studies [10,12–14], with major chemical composition of 78.1% ± 1.0% glucan, 15.3% ± 0.6% xylan, and 0.7% ± 0.1% Klason lignin. The dry lap was soaked in distilled water for 24 h before disintegration in a laboratory disintegrator. Mechanical fibrillation For the experiment, 140 g of o.d. bleached kraft eucalyptus pulp was fibrillated at 2 wt% consistency using a supermasscolloider (model MKZA6-2, Masuko Sangyo; Kawaguchi, Japan) at 1500 rpm as described previously [10]. Approximately 130 g was beaten in a Valley beater (Valley Laboratory Equipment, Voith; Appleton, WI, USA) to approximately 300 mL Canadian Standard Freeness (CSF) as a control sample. Fractionation of CNF by centrifuge An attempt was made to fractionate large networked CNF from small ones by centrifuge. Cellulose nanofibrils solution from 11 h of fibrillation was diluted to 0.2 wt% and continuously stirred for 1 h and then centrifuged at 1000 rpm for 15 JUNE 2016 | VOL. 15 NO. 6 | TAPPI JOURNAL 419 CELLULOSE NANOFIBRILS 1. Transmission electron microscopy images of cellulose nanofibrils (CNF) samples at different fibrillation times: (a) 0.5 h, (b) 3 h, (c) 7 h, and (d) 11 h; scale bar = 500 nm. min in a Sorvall Superspeed RC2-B 5.75-in. rotator (Ivan Sorvall; Norwalk, CT, USA). The supernatant liquid was carefully removed with a pipette from the precipitation layer. Preparation and testing of CNF film Solutions of CNF were diluted to 0.1 wt% and mixed for 4 h using a magnetic stir. A 9-in. vacuum filtration system with a 0.45-μm Durapore membrane (Millipore; Billerica, MA, USA) was used to prepare CNF film. Wet films together with blotting paper were pressed at 206 and 345 kPa for 3 min and then dried in a copper dry ring. Film opacity, basis weight, and thickness were measured according to TAPPI T519 om-06 “Diffuse opacity of paper (d/0 paper backing),” T410 om-08 “Grammage of paper and paperboard (weight per unit area),” and T411 om-10 “Thickness (caliper) of paper, paperboard, and combined board,” respectively. Strain-stress testing was determined using an Instron 5865 Advanced Mechanical Testing System (Instron; Norwood, MA, USA). Conventional handsheets as control were also made using the Valley-beaten pulp (control sample) and tested using the same procedure.
圆盘研磨机械纤颤时间对纤维素纳米原纤维性能的影响
以漂白硫酸盐桉木浆为原料,采用超质量胶体法制备了纤维素纳米原纤维。研究了磨削时间对CNF结构和性能的影响以及相应的CNF薄膜。磨削时间是提高CNF悬浮液光学透明度的重要因素。CNF的聚合度(DP)和结晶度指数(CrI)随CNF悬浮液透明度的增加而线性降低。这表明CNF悬浮液的光学透明度可以用来表征纤颤的程度。经过0.5 h研磨的CNF悬浮液制备的CNF膜的比拉伸强度和杨氏模量分别比谷打至300加拿大标准自由度(CSF)制备的传统手纸提高了约30%和200%。研磨0.5 h,能量输入仅为1.38 kWh/kg。磨削超过0.5 h,比拉伸和比模量的改善可以忽略不计。纤维纤维膜的不透明度在纤维性颤动的前1.5小时迅速下降,然后趋于稳定。应用:圆盘研磨时间影响纤维素纳米原纤维的形态以及由所得原纤维制成的薄膜的光学和机械性能。纤维素纳米材料,如源自可再生木质纤维素的纤维素纳米原纤维(CNF),近年来引起了人们的极大兴趣。木质纤维素在自然界中是非常丰富的。纤维素纳米原纤维已被用于生产一系列功能材料,包括薄膜、膜、气凝胶、支架和杂化复合材料[1-4],并有可能取代来自不可再生石油的各种材料。机械纤颤仍然是从木质纤维素生产CNF的最常见方法。微磨削具有大规模生产CNF的潜力,并已得到广泛应用[5-9]。微磨导致纤维发生一系列剧烈变化,如内纤、外纤、纤维缩短等。持续的纤维性颤动导致细胞壁断裂并产生微纤维和纳米纤维[10]。决定纳米纤维素材料强度的主要因素是纤维的长度和纤维的结合。纳米颗粒之间键的取向是调整杨氏模量的一个重要因素。由于生产的细材料大大增加了原纤维的表面积,增加研磨通常会导致增加粘合。另一方面,由于机械作用,研磨时间的增加也会导致纤维变短。延长磨削时间,在增加结合和减少纤维长度之间存在权衡;也就是说,存在一个最佳的磨削时间来生产用于增强聚合物的CNF。不幸的是,这样的理解并没有得到很好的证明。本研究的目的是研究机械纤颤时间对合成CNF膜性能的影响。材料和方法来自Fibria (Aracruz, Brazil)的漂白硫酸盐桉木浆的干lap与先前研究中使用的纸浆相同[10,12 - 14],主要化学成分为78.1%±1.0%葡聚糖,15.3%±0.6%木聚糖和0.7%±0.1%木质素。干膝在蒸馏水中浸泡24小时,然后在实验室粉碎机中分解。在实验中,140 g o.d.漂白硫酸盐桉木浆以2 wt%的浓度使用超级胶体(型号MKZA6-2, Masuko Sangyo;川口,日本)1500转,如前所述[10]。大约130克在山谷打蛋器中打(山谷实验室设备,福伊特;Appleton, WI, USA)至约300 mL加拿大标准游离度(CSF)作为对照样本。用离心分离法分离大的网状CNF和小的网状CNF。纤维素纳米原纤维溶液从11小时的纤颤稀释到0.2 wt%,连续搅拌1小时,然后在1000 rpm离心,2016年6月15日| VOL. 15 NO. 1。[6] [j] .纤维素学报。纤维素纳米原纤维(CNF)样品在不同纤颤时间的透射电镜图像:(a) 0.5 h, (b) 3 h, (c) 7 h, (d) 11 h;比例尺= 500 nm。在Sorvall超速RC2-B 5.75英寸。旋转(伊万·索瓦尔;诺沃克,康涅狄格州,美国)。用移液管小心地从沉淀层中除去上清液。CNF薄膜的制备和测试CNF溶液稀释至0.1 wt%,用磁力搅拌混合4小时。一个9。真空过滤系统采用0.45 μm Durapore膜(Millipore;使用Billerica, MA, USA)制备CNF薄膜。将湿膜与吸墨纸一起在206和345 kPa下压压3 min,然后在铜干环中干燥。 以漂白硫酸盐桉木浆为原料,采用超质量胶体法制备了纤维素纳米原纤维。研究了磨削时间对CNF结构和性能的影响以及相应的CNF薄膜。磨削时间是提高CNF悬浮液光学透明度的重要因素。CNF的聚合度(DP)和结晶度指数(CrI)随CNF悬浮液透明度的增加而线性降低。这表明CNF悬浮液的光学透明度可以用来表征纤颤的程度。经过0.5 h研磨的CNF悬浮液制备的CNF膜的比拉伸强度和杨氏模量分别比谷打至300加拿大标准自由度(CSF)制备的传统手纸提高了约30%和200%。研磨0.5 h,能量输入仅为1.38 kWh/kg。磨削超过0.5 h,比拉伸和比模量的改善可以忽略不计。纤维纤维膜的不透明度在纤维性颤动的前1.5小时迅速下降,然后趋于稳定。应用:圆盘研磨时间影响纤维素纳米原纤维的形态以及由所得原纤维制成的薄膜的光学和机械性能。纤维素纳米材料,如源自可再生木质纤维素的纤维素纳米原纤维(CNF),近年来引起了人们的极大兴趣。木质纤维素在自然界中是非常丰富的。纤维素纳米原纤维已被用于生产一系列功能材料,包括薄膜、膜、气凝胶、支架和杂化复合材料[1-4],并有可能取代来自不可再生石油的各种材料。机械纤颤仍然是从木质纤维素生产CNF的最常见方法。微磨削具有大规模生产CNF的潜力,并已得到广泛应用[5-9]。微磨导致纤维发生一系列剧烈变化,如内纤、外纤、纤维缩短等。持续的纤维性颤动导致细胞壁断裂并产生微纤维和纳米纤维[10]。决定纳米纤维素材料强度的主要因素是纤维的长度和纤维的结合。纳米颗粒之间键的取向是调整杨氏模量的一个重要因素。由于生产的细材料大大增加了原纤维的表面积,增加研磨通常会导致增加粘合。另一方面,由于机械作用,研磨时间的增加也会导致纤维变短。延长磨削时间,在增加结合和减少纤维长度之间存在权衡;也就是说,存在一个最佳的磨削时间来生产用于增强聚合物的CNF。不幸的是,这样的理解并没有得到很好的证明。本研究的目的是研究机械纤颤时间对合成CNF膜性能的影响。材料和方法来自Fibria (Aracruz, Brazil)的漂白硫酸盐桉木浆的干lap与先前研究中使用的纸浆相同[10,12 - 14],主要化学成分为78.1%±1.0%葡聚糖,15.3%±0.6%木聚糖和0.7%±0.1%木质素。干膝在蒸馏水中浸泡24小时,然后在实验室粉碎机中分解。在实验中,140 g o.d.漂白硫酸盐桉木浆以2 wt%的浓度使用超级胶体(型号MKZA6-2, Masuko Sangyo;川口,日本)1500转,如前所述[10]。大约130克在山谷打蛋器中打(山谷实验室设备,福伊特;Appleton, WI, USA)至约300 mL加拿大标准游离度(CSF)作为对照样本。用离心分离法分离大的网状CNF和小的网状CNF。纤维素纳米原纤维溶液从11小时的纤颤稀释到0.2 wt%,连续搅拌1小时,然后在1000 rpm离心,2016年6月15日| VOL. 15 NO. 1。[6] [j] .纤维素学报。纤维素纳米原纤维(CNF)样品在不同纤颤时间的透射电镜图像:(a) 0.5 h, (b) 3 h, (c) 7 h, (d) 11 h;比例尺= 500 nm。在Sorvall超速RC2-B 5.75英寸。旋转(伊万·索瓦尔;诺沃克,康涅狄格州,美国)。用移液管小心地从沉淀层中除去上清液。CNF薄膜的制备和测试CNF溶液稀释至0.1 wt%,用磁力搅拌混合4小时。一个9。真空过滤系统采用0.45 μm Durapore膜(Millipore;使用Billerica, MA, USA)制备CNF薄膜。将湿膜与吸墨纸一起在206和345 kPa下压压3 min,然后在铜干环中干燥。 薄膜不透明度、基础重量和厚度分别根据TAPPI T519 om-06“纸张的漫反射不透明度(d/0纸背)”、T410 om-08“纸张和纸板的克重(单位面积重量)”和T411 om-10“纸张、纸板和复合纸板的厚度(卡尺)”进行测量。采用Instron 5865先进机械测试系统(Instron;诺伍德,马萨诸塞州,美国)。常规手纸作为对照,也使用谷打浆(对照样品)制作,并使用相同的程序进行测试。 薄膜不透明度、基础重量和厚度分别根据TAPPI T519 om-06“纸张的漫反射不透明度(d/0纸背)”、T410 om-08“纸张和纸板的克重(单位面积重量)”和T411 om-10“纸张、纸板和复合纸板的厚度(卡尺)”进行测量。采用Instron 5865先进机械测试系统(Instron;诺伍德,马萨诸塞州,美国)。常规手纸作为对照,也使用谷打浆(对照样品)制作,并使用相同的程序进行测试。
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来源期刊
Tappi Journal
Tappi Journal 工程技术-材料科学:纸与木材
CiteScore
1.30
自引率
16.70%
发文量
59
审稿时长
6-12 weeks
期刊介绍: An internationally recognized technical publication for over 60 years, TAPPI Journal (TJ) publishes the latest and most relevant research on the forest products and related industries. A stringent peer-review process and distinguished editorial board of academic and industry experts set TAPPI Journal apart as a reliable source for impactful basic and applied research and technical reviews. Available at no charge to TAPPI members, each issue of TAPPI Journal features research in pulp, paper, packaging, tissue, nonwovens, converting, bioenergy, nanotechnology or other innovative cellulosic-based products and technologies. Publishing in TAPPI Journal delivers your research to a global audience of colleagues, peers and employers.
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