Investigation and Benefits of the Use of Enzymes for Unbleached Kraft Recycling Wet Strength Paper at Lab and Industrial Scale

The deterioration of recycled fibers especially unbleached kraft with high wet strength resin content due to the irreversible structural changes caused by drying and added chemicals makes the raw material difficult to repulp.The mechanical effect in the pulper over time with chemical treatment has a negative impact on the recycled fibers.At lab scale,different compositions of enzymatic treatment C022L were under investigation to select the most efficient laccase Lacc1,Lacc2 or Lacc3 and to observe the impact of lipases during repulping at low and high consistencies.Pulp disintegration at different times was evaluated to define the level of rejects and to analyze the morphology of fibers after treatments.These results were more significant for Lacc2,by increasing the pulp consistency to 15%in the pulper.Combining lipases with CELODASE 022L appeared to decrease the efficiency of enzymes.The results showed a high reduction of energy power with the enzymatic treatment and a significant reduction of fines level in fibers’suspension.The most efficient version of C022L was used at industrial scale to compare directly with the standard conditions used in a paper mill.

WET STRENGTH PAPER REPULPING: LABORATORY EVALUATION

The recycling of wet strength papers in a normal recycling mill is often troublesome due to the severe operating conditions required to defibre wet strength papers. The various methods are presented which will quickly allow mills to determine the most effective pulping aids to use when repulping wet strength papers. The repulping of wet strength paper with inorganic chemicals was investigated in the laboratory. The effects of major variables, that is, repulping time, pulp consistency, soaking time, temperature, and reactant concentration in the repulping stage were examined using Plackett-Burman design. The repulping time was the most crucial & influential process variable affecting repulping characteristic and formation related properties. The more significant repulping process variables affecting pulp yield were repulping time, soaking temperature and pulp consistency whereas for formation index and feature size, repulping time, pulp consistency, soaking temperature and time were the more important variables. The formation index is increased by an increase in repulping time, pulp consistency and soaking time whereas the feature size is decreased by an increase in repulping time, soaking temperature and pulp consistency. The formation index and the rejects were more sensitive to changes in process variables than were the feature size or the pulp yield. The pulp recycled from wet strength waste paper had good physical strength properties.

STUDY ON WET STRENGTH PERFORMANCE OF KENAF MULCH

Optimum applied technical conditions of wet strength agent for kenaf mulch were studied in this article. Breaking length, wet-dry strength ratio, tear index and burst index of kenaf mulch were measured and optimum wet strength agent was selected. The aim is to make mulch have properties of heat preservation, humidity preservation, growth prompting, biodegradation and maximum wet strength and to improve impact resistance of mulch to rainwater so as to assure growth of plant and replace plastic film.

Cationized Melamine-formaldehyde Resin for Improving the Wet Strength of Paper

In this work, melamine-formaldehyde resin was cationized by adding modifiers so that the fibers closely bonded to improve their usability and the wet strength of paper was greatly improved. Triethanolamine and dimethylamine were added to modify the melamine-formaldehyde resin,respectively.The mechanism of the cationized resin was explored and the possible chemical reactions were deduced. It was concluded that,with the use of triethanolamine,the most optimum product was obtained by hydroxymethylation for 30 min with a temperature of 85℃ and p H of 9. 0 where n( melamine) ∶ n( formaldehyde) ∶ n( methanol) ∶ n( triethanolamine) was 100 ∶ 330 ∶ 450 ∶ 15. With the combined use of dimethylamine and methanol,the optimal product was acquired by condensation for 30 min at a temperature of 50℃ and p H of 2. 0 at melamine, formaldehyde, methanol, and dimethylamine molar ratio of100∶ 330∶ 350∶ 20. With the only use of dimethylamine,the optimal product was obtained by condensation at melamine,formaldehyde,dimethylamine molar ratio of 100∶ 330∶ 10. The wet tensile strength of fruit-bagging paper was improved by adding cationized melamine-formaldehyde resin. The zeta potential,charge density,and conductivity of the melamine-formaldehyde resin were also studied.

干湿循环下木质素改良粉土抗剪强度特性

为克服粉土强度低、干湿循环性能差的特点,同时解决固体废弃物木质素的资源化利用的问题,将木质素掺入粉土中,形成木质素改良粉土。为研究木质素改良粉土抗剪强度特性及干湿循环性能,对经历干湿循环后的木质素改良粉土进行直接剪切试验和X射线衍射试验,研究了木质素掺量0、2%、5%、8%、12%、15%和干湿循环0、1、2、3、4次对改良土抗剪强度特性的影响。结果表明:掺入木质素可以显著提升粉土的抗剪强度及干湿循环性能;一定干湿循环次数下,改良土的抗剪强度及黏聚力随着木质素掺量的增加先增大后降低,内摩擦角随着木质素掺量的增加先快速增大后基本不变;当木质素掺量为8%时,改良土的抗剪强度、黏聚力和内摩擦角最高。改良土的抗剪强度、黏聚力和内摩擦角均随着干湿循环次数的增加而降低,当木质素掺量为0时,纯土试样经过1次干湿循环即崩解,强度损失率为100%;当木质素掺量为8%时,改良土的强度损失率最低,黏聚力及内摩擦角的降低幅度均较低。X射线衍射试验表明,木质素掺量为8%时,石英、方解石、白云石含量最高,黏土矿物含量较高,钠长石含量最低,这是造成改良土强度及干湿循环性能提升的直接原因。结果显示,当木质素掺量为8%时,改良土在提高抗剪强度及干湿循环性能方面具有明显优势。研究结果可为实际施工设计提供理论支撑。

干湿循环作用下融雪剂对玻璃纤维水泥土力学性能影响的试验研究

为研究在干湿循环作用下不同种类融雪剂对玻璃纤维水泥土力学性能的影响,制备浓度为0.2mol/L的醋酸钾、氯化镁和硫酸钠溶液作为融雪剂溶液,将养护后的无纤维水泥土和有纤维水泥土试块在不同种类的融雪剂溶液中浸泡3d,然后将试块取出放入烘干箱内分别进行8~10次干湿循环。进而分析融雪剂类型、干湿循环次数对试块表面破坏状态、强度和质量等的影响。试验结果表明:经过10次干湿循环后,醋酸钾融雪剂溶液对试块质量和强度的影响程度小于氯化镁溶液和硫酸钠溶液,说明醋酸钾融雪剂对水泥土侵蚀作用较小;试块表面裂纹随着干湿循环次数的增加逐渐增多加深,在经历相同干湿循环次数后,有纤维水泥土试块的裂纹发展程度、质量损失率和强度损失率均低于无纤维水泥土试块,说明通过添加玻璃纤维可有效提高水泥土抗干湿循环和融雪剂侵蚀的能力。

液控智能完井井下湿式对接工具的设计研究

智能完井系统发生井下设备故障时,为实现无需将井下设备全部提出即可检修等目的,设计一种液控智能完井井下湿式对接工具。该工具可在油井内将地面液控管线与井下液控管线实现对接和分离,且在对接时能够保证地面和井下液控管线稳定导通,在分离时可实现分离的两部分液控管线各自密封。工具采用卡爪结构提供对接锁紧力,并对卡爪的锁紧力进行推导计算,得到结构不同设计参数下的锁紧力。最后通过有限元仿真对卡爪进行强度校核,并根据结果确定卡爪的设计参数。经过设计分析,该工具满足井下使用要求,为智能完井系统检修提供新的解决方案。

湿基α-半水石膏制备高强石膏制品研究

为实现湿基α-半水石膏制备高强石膏制品,研究了湿基α-半水石膏陈化时间、粉磨时间、浇筑料浆温度及缓凝剂掺量等工艺参数对高强石膏凝结时间和强度的影响,并确定最佳制备工艺。此外,采用X射线衍射、扫描电子显微镜等微观测试手段,揭示了各因素对强度的影响机理。结果表明:陈化时间越长,石膏凝结时间越短,制品强度越低;随着粉磨时间延长,石膏凝结时间显著缩短,制品强度先升高后降低;料浆温度越高,石膏凝结时间越长,制品强度越低。最佳制备工艺:陈化时间5 min、粉磨时间20 s、料浆温度20℃。在此基础上加入0.08%(质量分数)缓凝剂能够有效地延长石膏凝结时间并提高硬化强度,制备的石膏制品性能优异,绝干抗折强度为14.1 MPa,绝干抗压强度为58.3 MPa。微观测试结果表明,各工艺参数会通过改变石膏标稠用水量和水化进程来影响石膏内部结构的密实程度和二水石膏晶体的生长发育,最终影响制品硬化强度。

造纸用湿强剂的研究进展

本文概述了造纸用湿强剂的技术现状和研究进展。根据工业化程度及应用情况将纸张湿强剂分为工业化湿强剂、其他湿强剂及增湿强体系;其中着重讨论了聚乙烯亚胺树脂(PEI)、脲醛树脂(UF)、三聚氰胺甲醛树脂(MF)、聚酰胺多胺环氧氯丙烷树脂(PAE)和双醛淀粉(DAS)等工业化湿强剂的合成、应用及优缺点;介绍了聚羧酸、壳聚糖、海藻酸钠类湿强剂及多元增湿强体系在造纸湿部领域的研究现状;并对造纸用湿强剂的未来发展趋势进行了展望。

兼具高湿强度及长开放期EPI木材胶粘剂的制备与性能表征

首先分别制备了湿强度优异(6.4 MPa)但开放期较短(40 min),以及开放期较长(145 min)但湿强度偏低(3.8 MPa)的EPI木材胶粘剂用两款乳液(SAEP3和SAEP4),然后探索了两种乳液的配比对复合乳液胶粘剂性能的影响。研究结果表明:当两款乳液用量一样时,产生了协同效应,制得的乳液(SAEP5)胶粘剂开放期为100~120 min,湿强度达6.4 MPa。与同样条件下测试的市售SL6517胶粘剂相比,其开放期相当,湿强度高出SL6517胶粘剂(均值5.1 MPa)约25%。由此,成功制备兼具高湿强度及长开放期的EPI木材胶粘剂。

干湿循环作用下镉污染红黏土的变形及强度特征

以桂林漓江流域的红黏土为研究对象,分别配置浓度为0%、0.1%、0.5%、2.5%的氯化镉溶液制成镉污染红黏土试样,在40℃条件下进行干湿循环,通过室内固结不排水三轴剪切试验研究了Cd^(^(2+))浓度及干湿循环耦合作用对红黏土的变形、强度特征的影响。结果表明:不同Cd^(2+)浓度红黏土的横向收缩率δ_(hs)、竖向收缩率δ_(ss)及体积收缩率δ_(v)随时间增长均呈“S”型曲线上升;不同Cd^(2+)浓度的红黏土剪应力峰值随干湿循环次数增加而增大;随着干湿循环次数的增加,镉污染红黏土黏聚力呈先增大后减小的趋势;Cd^(2+)在未进行干湿循环时就已完成了对红黏土结构的破坏,使内摩擦角达到极限值;Cd^(2+)浓度增大,强度特征破坏作用越明显。

大豆脲酶诱导碳酸钙固化黄河泥沙水稳定性试验研究

随着国家“交通强国”战略的提出,沿黄工程建设发展迅速,填筑用土需求剧增。黄河泥沙作为填筑材料的可行性已被证实,但其在多雨地区的服役性能需要改善,探索一种生态、高效的泥沙加固方法提高其水稳定性十分关键。本文基于酶诱导碳酸钙沉淀(EICP)技术固化黄河泥沙的方法,分别开展了常规浸水条件和干湿循环条件下固化黄河泥沙的水稳定性试验,研究了浸水后试样的质量损失及强度折损情况,分析了干湿循环对固化后黄河泥沙试样强度软化系数的影响规律。结果表明:采用EICP技术固化的黄河泥沙试样浸水崩解过程相比原状试样更加缓慢;胶结液浓度1.5 mol/L的黄河泥沙试样长期(56 d)浸水后,几乎保持完整,质量损失率仅为6.36%,强度折损率仅为6.21%;10次干湿循环后,不同胶结液浓度处理后的黄河泥沙试样均出现了不同程度的颗粒松散和脱落现象,胶结液浓度1.5 mol/L、灌浆10次的黄河泥沙试样的抗压强度损失仅为9.96%,抗干湿循环能力最强。利用EICP技术可以有效的固化黄河泥沙并提升其水稳定性,这对推进黄河泥沙的资源化利用进程十分重要。

基于降雨—库水作用下的某库岸堆积体滑带土力学性能及损伤模型研究

库水及降雨往复作用下滑带土的力学性能演化是库岸滑坡形成发展及破坏的内在控制因素。基于宏微观室内试验和理论分析手段,研究了干湿循环作用下滑带土性能的劣化机理及力学损伤特性,并建立了基于宏观强度的微观损伤演化模型。结果表明,随干湿循环次数的增加,滑带土内摩擦角和粘聚力均出现降低趋势,剪切强度劣化率随干湿循环扰动程度的增加而显著提高;亲水矿物及干湿循环下的水动力影响效应,使得土样微观结构由致密向疏松多孔转变,颗粒间微裂纹及原生孔隙迅速增加。基于损伤力学和室内试验提出的宏微观损伤模型可有效表征干湿循环作用下滑带土的劣化规律。

硫酸盐环境下MKPC浆体干湿循环制度设计及性能评价

为评价硫酸盐干湿循环耦合作用下磷酸钾镁水泥(MKPC)浆体的力学性能和物理性能,根据GB/T 3810.3—2016测试方法,通过真空保水和不同温度的真空烘干试验,设计出适用于MKPC浆体试件的干湿制度。遵循设计的干湿制度,测试MKPC试件在硫酸盐环境下进行不同干湿循环次数和全浸泡不同龄期的质量损失、强度变化。试验结果如下:经过反复试验,以相邻两次质量变化率<0.1%为标准,设计出MKPC试件1个干湿循环周期为72 h。MKPC试件在5%Na_(2)SO_(4)溶液干湿循环120次后其抗折强度、抗压强度较未干湿循环试件的强度分别下降24.44%、18.63%,质量损失为4.12%;在5%Na_(2)SO_(4)溶液浸泡360 d后,MKPC试件的抗折强度较未浸泡的强度下降1.23%,抗压强度较未浸泡的试件强度增加1.11%,质量损失为1.54%。因此,MKPC试件在干湿循环作用下对抗折强度变化和质量损失更加敏感。

PAE湿强剂中氯丙醇含量对纸张水提取液中氯丙醇含量的影响

为检测PAE湿强剂中氯丙醇的含量,本研究建立了气相色谱-质谱联用法(GC-MS),检测PAE湿强剂中1,3-二氯-2-丙醇(1,3-DCP)与3-氯-1,2-丙二醇(3-MCPD)的含量,并进行了方法学验证,同时探究了PAE湿强剂中氯丙醇含量与纸张水提取液中氯丙醇含量之间的关系。本研究对4批次某款湿强剂进行检测,发现随着湿强剂制造工艺的改进,1,3-DCP与3-MCPD的含量均有明显的下降。调整湿强剂和助留剂的添加量,抄造不同批次的纸张,同时测定纸张水提取液中的氯丙醇含量与纸张的抗张强度。结果显示,纸张水提取液中的氯丙醇含量与湿强剂中氯丙醇含量呈正相关关系,与湿强剂添加量成正比;在助留剂实际添加量超过厂家推荐添加量的情况下,纸张水提取液中的氯丙醇含量与助留剂添加量无明显关系,但会导致纸张湿、干抗张指数下降。

掺粉煤灰混凝土强度劣化试验研究

为研究掺粉煤灰混凝土的抗压强度劣化规律,以碎石、水泥、粉煤灰、中砂与自来水为原材料,制备掺粉煤灰混凝土试件。在碳化与干湿循环等环境作用下,利用万能压力试验机,展开试件强度劣化试验。试验结果表明:粉煤灰掺量未超过30%(包含30%)时,试件抗压强度未出现劣化现象;粉煤灰掺量超过30%时,粉煤灰掺量越多,试件抗压强度劣化程度越大。龄期延长,各试件抗压强度均有所提升;增加粉煤灰掺量,会提升试件劈拉强度的劣化程度;延长龄期,会减缓试件劈拉强度的劣化速度。增加水胶比含量,导致试件劈拉、抗压强度劣化程度提升;碳化作用下,试件抗压及劈拉强度有所提升,碳化时间为13 d时,试件抗压及劈拉强度达到峰值;干湿循环作用下,试件的抗压及劈拉强度均会出现劣化情况,粉煤灰掺量为30%时,试件的抗压及劈拉强度均值相对较高。

低有机氯环保型湿强剂的制备及应用

首先以己二酸、二乙烯三胺为原料加入自研催化剂A合成聚酰胺聚胺(PAE)中间体,在紫外光照射条件下加入环氧氯丙烷进行环氧化反应合成低氯聚酰胺聚胺环氧氯丙烷树脂。GC-MS结果表明,制备的湿强剂有机氯含量为0.35%、0.11%、0.083%,说明催化剂A能有效降低PAE树脂中有机氯含量。所制备的湿强剂具有优良的湿强效果和超过三个月储存稳定性。在不改变湿强剂用量情况下,纸张的耐破指数和干抗张强度分别提高了7.67%和16.67%。

干湿循环作用下伊犁黄土的强度及微观特性

为探讨干湿循环作用下伊犁黄土的强度劣化规律和微观结构特性,进行了5种干湿循环路径下的三轴剪切试验及扫描电镜测试,分析了不同干密度、干湿循环幅度和次数对伊犁黄土抗剪强度的影响和微观孔隙分布的演化规律,并进行了宏观强度和微观孔隙损失机制之间的探讨。结果表明:干湿循环幅度越大、循环次数越多,伊犁黄土抗剪强度的衰减速度越快,衰减幅度越大,原状土在5次干湿循环后的三轴剪切强度接近重塑黄土;同种干密度的伊犁黄土的黏聚力随循环次数的增加而降低,同一干湿循环路径下干密度为1.55 g/cm^(3)时,伊犁黄土的黏聚力劣化最显著,而干湿循环对内摩擦角有轻微影响。另外黏聚力的劣化与孔隙面积比和孔隙特征参数的变化有关,干湿循环后孔隙面积比和孔隙特征参数增加率越大,黏聚力劣化越明显;内摩擦角的变化与孔隙分形维数的变化趋势相近,但变化不显著。

基于延迟效应的干湿-冻融条件下水泥改良粉细砂影响分析

季节性冻土区土体的物理力学性质受干湿交替与冻融循环两种风化作用综合影响,开展单一冻融循环与干湿-冻融耦合作用下水泥改良粉细砂的UCS试验与剪切试验,并分析水泥延迟时间对土体物理力学参数的影响。试验结果表明:随着延迟时间的增大,水泥改良粉细砂的最大干密度先增大后减小,最优含水率先增大后趋于平缓再增大,延迟时间3 h时约为0 h时的70%;冻融循环3次后,随着延迟时间的增加,UCS值分别减小了-5.23%、5.15%、6.0%及6.32%,试样的UCS值、黏聚力整体减小,内摩擦角呈增大趋势;干湿-冻融循环作用下试样的各项参数均减小,先脱湿后吸湿路径下各项参数均比先吸湿后脱湿路径下略高。在不同风化作用下,试样的UCS值、黏聚力、内摩擦角均随延迟时间的增大而减小。研究结果可对季节性冻土区水泥改良粉细砂在施工及设计中的应用提供一定的参考。

干湿循环作用下渠道膨胀土裂隙演化规律及强度特性

为探究干湿循环作用下膨胀土渠道边坡裂隙演化特征与强度衰减规律,对北疆某渠道膨胀土开展了不同压实度的干湿循环试验,利用图像处理技术提取膨胀土表面裂隙参数,利用直剪试验测得膨胀土抗剪强度,并分析黏聚力随裂隙率的变化规律。结果表明:在干湿循环作用下,黏聚力的衰减速率随着压实度的增大而增大,内摩擦角总体呈减小趋势,裂隙率的增加速率随着压实度的增加而减小;裂隙相对面积呈先增后减的变化规律。最后,拟合获得不同压实度膨胀土黏聚力与表面裂隙率之间的关系式,通过确定膨胀土表层裂隙率可计算出其黏聚力。研究成果为进一步揭示剧烈干湿变化诱发的膨胀土渠道边坡失稳破坏提供了重要依据。