INFLUENCE OF SILOXANE CO-SEGMENT LENGTH AND CONTENT OF WATERBORNE POLYSILOXANE-URETHANE COPOLYMERS ON THEIR WATER RESISTANCE,THERMAL STABILITY AND MECHANICAL PROPERTIES

A series of stable waterborne polysiloxaneurethane （WPSUR） dispersions were prepared using amino-terminated polydimethylsiloxane （NS）, dimethylolpropionic acid （DMPA）, castor oil, polypropylene glycol and toluene diisocyanate. Meanwhile, NS with different molecular weights was synthesized and used as the soft co-segment. Effects of types and contents of soft co-segments as well as chain extenders on the thermal degradation and stability for WPSUR films were examined. Results reveal that WPSUR films exhibit excellent water resistance and mechanical properties as compared with pure polyurethane （PU） films, and the NS soft co-segment possesses a remarkable effect on the second stage （stage Ⅱ）, while the content of the hard segment is propitious to the initial stage （stage Ⅰ）. Moreover, the highest temperature of stage Ⅱ （T2m） for WPSUR films using NS as soft co-segment is 413℃, approximately being 30℃ higher than that of those typical PUs using HDA and APDMS as the chain extenders, respectively.

Effect of the Proportion of Bamboo Scraps on the Properties of Bamboo Scraps/Magnesium Oxychloride Composites

This study was designed to solve the problem of large waste volume from bamboo processing residues in recent years.Using magnesium oxychloride(MO)cementitious material as the main material and bamboo residue(BR)as the reinforcing material,a BR/MO composite material was prepared.The effects of BR amount on the molding properties,mechanical strength,and water resistance of BR/MO composites were examined and discussed.Scanning electron microscopy(SEM),X-ray diffractometry(XRD),and thermogravimetric analysis were used to characterize composite microscopic morphology,crystalline structure,and heat resistance.The results showed that,when the BR content was 1.00%(by wt),the flowability of MO paste was beneficial to composite molding.Composite mechanical properties and water resistance were greatly affected by BR addition.When the BR content was 1.00%,composite compressive and bending strengths and softening coefficient all reached maximum values.Meanwhile,increases in water absorption by 24 h and decreases of contact angle were small.These results suggested that,when the BR content was 1.00%,composite mechanical properties and water resistance were the best and the mechanical strength also improved with extended composite storage time.SEM analysis indicated that BR played the role of a reinforcing phase in MO matrices.However,when the BR content exceeded 1.00%,interfacial bonding between BR and MO became less.XRD analysis showed that,with 1.00%BR content,composites showed more 5-phase crystals with high strength.This further explained the reason why this composite’s mechanical properties were the best and the heat resistance not deteriorated due to BR,which was easily decomposed.

Long-Term No-Tillage Direct Seeding Mode for Water-Saving and Drought-Resistance Rice Production in Rice-Rapeseed Rotation System

To study the effects of long-term no-tillage direct seeding mode on rice yield and the soil physiochemical property in a rice-rapeseed rotation system, a comparative experiment with a water-saving and drought-resistance rice （WDR） variety and a double low rapeseed variety as materials was conducted under no-tillage direct seeding （NTDS） mode and conventional tillage direct seeding （CTDS） mode for four years, using the CTDS mode as the control. Compared with the CTDS mode, the actual rice yield of WDR decreased by 8.10% at the first year, whereas the plant height, spikelet number per panicle, spikelet fertility, 1000-grain weight, grain yield, actual yield, and harvest index increased with no-tillage years, which led to the actual yield increase by 6.49% at the fourth year. Correlation analysis showed that the panicle length was significantly related to the actual yield of WDR. Compared with the CTDS mode in terms of the soil properties, the pH value of the NTDS mode decreased every year, whereas the contents of soil organic matter and total N of the NTDS mode increased. In the 0-5 cm layer of the NTDS mode, the soil bulk decreased, whereas the contents of soil organic matter, total N, and available N increased. In the 5-20 cm layer of the NTDS mode, the available N and K decreased, whereas the soil bulk, contents of soil organic matter, and total N increased. In summary, the NTDS mode increased the rice yield, and could improve the paddy soil fertility of the top layer.

Surface treatment technology of downhole water cut sensor

Based on the structure,working principle,and working conditions of conductance water cut sensor,it is revealed that the early failure of the metal electrode of the sensor is due to the comprehensive influence of well fluid erosion,electrochemical corrosion,and oil pollution during its long-term service in the downhole.A technology for electrode surface treatment is proposed using boron-doped diamond(BDD)films to improve the service performance of the modified electrode.The hot wire chemical vapor deposition method was adopted to fabricate BDD film,the boron doping concentration and deposition time were optimized,and fluorination treatment was applied to improve the wear resistance,electrochemical corrosion resistance,and oleophobic property of the BDD film comprehensively.The results showed that BDD film with boron doping concentration of 6×10^(-3) exhibited high wear resistance and good electrochemical corrosion resistance,and endowed the modified electrode with superior erosion resistance and corrosion resistance.The friction coefficient and wear rate of BDD modified electrode were 92%and 78%lower than those of Invar alloy,also,the low-frequency impedance modulus value of the modified electrode was higher than 1×10^(4) Ω·cm^(2).The BDD film prepared with a deposition time of 8 h had a favorable micro-nano structure owing to small grain size and uniform distribution.Such morphology was conducive to enhancing the oleophobic performance of the modified electrode,and its contact angle in the simulated well fluid was high to 102°.The engineering applicability of BDD film modified electrode under simulated working conditions indicated that,the modified electrode had excellent comprehensive performances of erosion resistance,electrochemical corrosion resistance and oil adhesion resistance,and can realize the long-term stable operation of the conductance water cut sensor under harsh downhole conditions.

阴/非离子型水性聚氨酯的制备及其性能研究

通过采用复合型亲水单体2,2-双(羟甲基)丙酸(DMPA)和非离子二元醇(Ymer N120),制备了阴/非离子型水性聚氨酯,研究了N120与DMPA不同摩尔比对乳液及涂膜性能的影响。结果表明:不同摩尔比对乳液粒径大小及涂膜力学性能有显著影响。随着两种亲水单体摩尔比的改变,当Ymer N120用量逐渐增多时,乳液粒径及分散指数先增加后减小再增加,最小粒径为816nm,分散指数为0.112。涂膜吸水率亦是先增加后减小再增加,最低吸水率为22%。涂膜接触角随Ymer N120用量增大逐渐增大,最大为82.17°。当DMPA与Ymer N120的摩尔比为4∶1时,拉伸强度最大为13MPa,断裂伸长率最大为672%,此时乳液涂膜的机械性能最佳。

环氧树脂基近红外吸收涂层的近红外光谱、力学及耐盐水性能研究

以环氧树脂为粘合剂,Sm2O3为功能颜料,硅烷偶联剂和石墨烯为改性剂,制备得到了一种同时具有突出力学性能和耐盐水性能的近红外低反射率涂层。系统研究了Sm2O3添加量、硅烷偶联剂种类、硅烷偶联剂添加量和石墨烯添加量对涂层性能的影响。结果表明:Sm2O3添加量的增加可明显降低涂层对1.06μm近红外光的反射率,当Sm2O3添加量为50%,涂层对1.06μm近红外光的反射率可低至31.2%。此时,涂层的附着力和耐冲击强度分别可达到1级和50 kg·cm。用硅烷偶联剂改性涂层,偶联剂上的强极性基团分别可与涂层中的树脂基体和颜料形成共价键结合,从而可发挥桥连作用,进而可明显改善涂层的柔韧性,其中KH560的改性效果最佳。当KH560添加量为5%,涂层的柔韧性可从改性前的9 mm显著改善为改性后的4 mm。石墨烯具有特殊的共平面结构和超长共轭结构特征,使其对入射光的吸收可延伸到近红外区域。石墨烯特殊的片层结构使其具有很高的耐冲击强度和柔韧性,在涂层中添加石墨烯可明显改善涂层的力学性能。研究发现石墨烯的添加可在进一步改善涂层力学性能的前提下显著降低涂层对1.06μm近红外光的反射率。当石墨烯添加量为8%,涂层对1.06μm近红外光的反射率可低至12.6%,此时涂层可具备突出的激光隐身效能。同时,涂层的附着力、柔韧性和耐冲击强度分别可达到1级、2 mm和50 kg·cm,可很好地满足实际工程应用要求。在环氧树脂、硅烷偶联剂和石墨烯的协同界面优化作用下,最佳配方(Sm2O3添加量为50%、KH560添加量为5%、石墨烯添加量为8%)的涂层经盐水腐蚀21 d后,涂层的微结构、近红外低反射率性能和力学性能可保持稳定。此时,涂层对1.06μm近红外光的反射率为12.47%,涂层的附着力、柔韧性和耐冲击强度分别可保持在1级、2 mm和45 kg·cm,表明制备的涂层具有良好的耐盐水性能。

单板厚度对杨木重组木性能的影响

以杨木单板为原料制备高性能特种重组木,重点探讨单板厚度对重组木性能的影响。结果表明,单板越薄,重组木及其内部单板表芯层密度差异越小,耐水性能也越好,但是垂直层向的抗压强度越低;0.7 mm单板制备重组木的静曲强度最高,为203.3 MPa,0.7 mm和1.0 mm单板制备重组木的弹性模量高于1.3 mm和1.8 mm单板制备重组木。

壬酸增塑改性明胶膜的制备及性能研究

可生物降解塑料的研发对于实现“双碳”目标具有重要的意义和价值。以明胶为原材料,通过壬酸增塑、双醛淀粉交联和热压处理相结合的方法制得明胶膜,探究壬酸增塑和热压处理对双醛淀粉交联的明胶膜结构和性能的影响。结果表明,当壬酸添加比例为20%时,改性的明胶膜表面光滑、结构致密,具有最高的抗张强度和较低的断裂伸长率、水蒸气透过率和溶胀性能。经过11 min的热压处理后,明胶膜表现出良好的耐水性和力学性能,且在土壤中被降解22 d后仍然能够维持较完整的薄膜形貌,降解34 d后其质量损失超80%。基于壬酸增塑、双醛淀粉交联和热压处理制备的明胶膜机械强度高、耐水性好且可生物降解,其为环境友好蛋白塑料的研发提供了有益策略。

固废基盾构惰性同步注浆材料力学性能及抗水分散性研究

以典型固废矿渣微粉、粉煤灰、硅灰为原料制备固废基盾构惰性同步注浆材料,采用六因素五水平正交试验,开展了注浆材料力学性能及抗水分散性的试验研究。结果发现:增大碱激发剂模数,减小其掺量,则浆液抗压强度下降;水胶比、膨水比对浆液抗动水冲刷能力的影响较大;碱激发剂掺量和水胶比是影响浆液水陆强度比的主要因素。根据正交试验极差分析和综合性能平衡,确定了注浆材料的优选配合比:水胶比1.00,胶砂比0.45,膨水比0.35,减水剂掺量1.5%(质量分数),碱激发剂模数1.6,碱激发剂掺量20%(质量分数),此时注浆材料28 d抗压强度为13.02 MPa,水陆强度比为80.83%,3 h动水冲刷质量损失率为5.62%;并开展了稠度、凝结时间、泌水率和结石率等性能试验,测试指标均达到了活性浆液的要求。以上研究为工业固废在盾构注浆技术领域的应用提供了一定的研究基础和实验依据。

柠檬酸对竹屑-硫氧镁水泥物理性能的影响

硫氧镁(magnesium oxysulfate, MOS)水泥具有耐火性好、轻质、导热系数低和早强等优点,但其强度低,耐水性差。为了改善其性能,在MOS水泥中掺入竹屑和改性剂柠檬酸,研究了竹屑和柠檬酸对MOS水泥凝结时间、孔隙率、力学性能及耐水性的影响,并进行了X射线衍射(X-ray diffraction, XRD)和电镜扫描(scanning electron microscope, SEM)。结果表明,竹屑的掺入缩短了MOS水泥凝结时间,增强了MOS水泥的力学性能和耐水性;柠檬酸的加入延长了竹屑-硫氧镁水泥(bamboo sawdust-MOS cement, BSMOSC)的水化诱导期,增长了水泥的凝结时间,并进一步提升了BSMOSC的力学性能和耐水性。竹屑和柠檬酸可分别作为填充剂和改性剂解决MOS水泥强度低、耐水性差的问题。

磷建筑石膏基无砂自流平砂浆的制备与性能研究

采用磷建筑石膏、P·O 42.5水泥、粉煤灰、矿粉、石粉及外加剂为原材料制备高强耐水型磷建筑石膏基无砂自流平砂浆。通过正交试验确定砂浆中胶凝材料的最优掺量,研究减水剂和可再分散性乳胶粉对砂浆性能的影响,并采用XRD及SEM对砂浆进行微观分析。结果表明,当磷建筑石膏、水泥、粉煤灰、矿粉及石粉质量比为73∶5∶5∶15∶2时,砂浆综合性能最优,28 d绝干抗压强度为33.0 MPa,软化系数为0.774。减水剂能够提高砂浆30 min的流动度、力学性能及耐水性能,但当掺量为0.30%(质量分数)时,会降低砂浆的后期强度。可再分散性乳胶粉会降低砂浆的流动性能及力学性能,但能提升砂浆的耐水性能。制备的磷建筑石膏基无砂自流平砂浆的性能满足《石膏基自流平砂浆》(JC/T 1023—2021)的要求,砂浆的28 d绝干抗折强度、28 d绝干抗压强度分别为12.0、45.9 MPa,软化系数高达0.886,吸水率低至2.8%。

PCB基板用高耐热双环戊二烯环氧树脂的合成及性能

本文以双环戊二烯、邻烯丙基苯酚、环氧氯丙烷为原料,合成了高耐热的邻烯丙基苯酚-双环戊二烯环氧树脂,采用红外光谱、凝胶色谱对其结构进行表征;分别采用双酚A酚醛树脂、苯并噁嗪树脂及活性酯对环氧树脂进行固化,压制了PCB基板,采用差示扫描量热及热失重分析对体系的固化行为进行研究,测试了板材的力学性能、介电性能及吸水性能,并将其与苯酚-双环戊二烯环氧树脂的固化体系进行了对比。结果表明:邻烯丙基苯酚-双环戊二烯环氧树脂较苯酚-双环戊二烯环氧树脂具有更高的耐热性(玻璃化转变温度Tg和5%热失重温度Td5%较高)、弯曲强度、冲击强度、高温弯曲强度保持率以及更优的介电性能和更低的吸水率。

氨基酸功能化二硫化钼/环氧树脂复合材料耐水性能的研究

环氧树脂因其优异物理化学性能在各种高新领域得到了重要发展。近年来随着材料科学在某些极端环境下的需求越来越多,对提高环氧树脂的耐水性需求日渐迫切。本文首先制备了氨基乙酸(Gly)改性二硫化钼(MoS_(2))纳米片,然后用其改性环氧树脂,制备了Gly-MoS_(2)/环氧树脂复合材料。对其结构、微观形貌、力学性能、热机械性能和吸水率等指标进行表征。研究结果表明:(1)成功制备了目标产物,经氨基乙酸剥离和改性的MoS_(2)纳米片在树脂基体中分散更均匀,在保证适宜的横向尺寸的同时厚度更薄,与基体树脂相容性更好。(2)随着纳米片添加量的增加,树脂体系水煮后的常温和高温剪切强度、拉伸强度和抗冲击强度均有提升。这是由于改性后纳米片在基体中分散均匀,且与环氧基形成更稳定的海岛结构,从而提升了材料本身的耐水性。(3)热机械性能测试表明,Gly-MoS_(2)纳米片对增强材料水煮后的耐温性有着重要的作用。吸水率测试表明,Gly-MoS_(2)极大地改善了环氧树脂的耐水性能,并且随着Gly-MoS_(2)纳米片的增加,吸水率随之降低。其中1.00%Gly-MoS_(2)/环氧树脂体系的耐水效果最好,水煮192 h后最终吸水率仅为1.2%。

高密度重组竹的物理力学性能研究

分析了高密度重组竹的孔隙率、微观结构、耐水性和力学性能,并通过构建性能参数与密度的关系,探究密度对物理力学性能的影响规律。结果表明:随着密度的增大,孔隙率逐渐降低。当密度为1.37 g/cm3时,孔隙率仅为5.52%,竹材细胞基本实现了密实化;薄壁细胞和导管细胞发生严重变形,但纤维细胞的形态几乎未受影响。经4 h水煮-20 h 60℃干燥-4 h水煮处理后,吸水率、厚度膨胀率和宽度膨胀率均随密度的增大而下降,分别低至9.67%、7.62%和1.47%。水平剪切强度、顺纹抗压强度、静曲强度(MOR)和弹性模量(MOE)则随密度的增大而增大,分别高达28.83、215.53、354.00 MPa和28.75 GPa。所有重组竹的性能参数均达到了户外用重组竹的性能要求,且部分参数远超国标中规定的最高等级要求。此研究结果可为重组竹性能的调控与应用提供理论依据和数据参考。

木薯淀粉-聚乙烯醇胶黏剂的合成与性能

为了提升淀粉基胶黏剂的耐水性能,采用3种酸作为催化剂(甲酸、乙酸、硫酸)水解木薯淀粉,再与聚乙烯醇聚合,制备环保型木薯淀粉-聚乙烯醇树脂(cassava starch-polyvinyl alcohol,CS-PVA)木材胶黏剂,测试胶黏剂的黏度、固体含量等基本性能,并通过X射线衍射(XRD)、傅里叶变换红外光谱(FTIR)、核磁共振碳谱(^(13)C-NMR)、X射线光电子能谱(XPS)及扫描电子显微镜(SEM)对其结构进行分析,采用差式扫描量热分析(DSC)与热重分析(TG)对其固化性能进行表征,利用接触角测试分析其润湿性能。结果表明,木薯淀粉经酸催化水解后,与PVA之间的相互作用显著增强,更好地形成醚键和氢键的交联结构,有效抑制水分子的渗透,从而提高胶黏剂的耐水性;SEM观察可见,相较于对照由未水解木薯淀粉(CS)制备的CS-PVA胶黏剂,水解CS制备的CS-PVA胶黏剂结构更加紧密且稳定。试验进一步探究甲酸添加量对CS-PVA胶黏剂性能的影响,其中,以1%质量分数的甲酸作为催化剂时,胶合板试样的干状、冷水24 h及63℃热水3 h剪切强度分别为2.45、1.31及0.93 MPa,符合GB/T 9846—2015《普通胶合板板》对II类胶合板强度的要求,相对于对照CS-PVA胶制备胶合板的剪切强度,分别提升了41.6%、151.9%与66.1%,表明酸水解木薯淀粉对CS-PVA胶黏剂耐水性和胶合强度的提升作用。

耐高温水基微球调驱剂性能评价

评价了一种耐高温水基微球调驱剂性能。实验结果表明:不同浓度耐温水基微球调驱剂注入不同渗透率岩心的阻力系数均小于等于5,注入性好;浓度为4 000 mg/L的耐温水基微球调驱剂在岩心中的有效封堵渗透率范围最大,封堵率最高超过90%;该水基微球调驱剂在150℃下有效封堵时间45 d左右,耐温性良好;该耐温水基微球调驱剂可提高渤海油田非均质储层原油采收率15.41%~17.92%。

人工林柏木重组木的结构与性能

【目的】采用定向重组技术制备人工林柏木重组木,分析其结构与性能,揭示柏木制备成重组木后性能变化的内因,为人工林柏木高值化利用提供技术参考和理论依据。【方法】制备80%、100%和120%不同压缩率柏木重组木,探究压缩率对重组木耐水性能、力学性能(抗弯性能和水平剪切性能)的影响规律;应用超景深显微镜(UDM)、冷场发射扫描电子显微镜(SEM)、激光共聚焦显微镜(LSM)和透射电镜(TEM)观察重组木微观结构变化以及重组木中胶液分布情况;使用剖面密度测量仪测量垂直于板面表面方向的密度梯度,分析重组木剖面密度。【结果】随着压缩率增大,重组木表面纹理颜色加深,剖面密度逐渐均匀,吸水率(WAR)、吸水厚度膨胀率(TSR)和吸水宽度膨胀率(WSR)逐渐减小,静曲强度(MOR)和水平剪切强度(HSS⊥)逐渐增大。压缩率120%时重组木WAR最小,相比原木降低34.73%,同时重组木MOR和HSS⊥达到最大,分别为125.77和17.05 MPa,相比原木分别提升53.47%和84.32%。剖面密度测量仪、冷场发射扫描电子显微镜、激光共聚焦显微镜和透射电镜观测结果显示,重组木耐水性能和力学性能提升主要是因为随着压缩率增大,木材细胞压缩密实、胶液分布范围更广,在更多的细胞腔和胞间层形成胶合位点,减少吸水时水分进入通道,抑制细胞腔回弹,增强胞间层薄弱结构。【结论】采用定向重组技术将人工林柏木制备成高性能重组木后,其力学性能显著提升;随着压缩率增大,重组木的耐水性能显著增强,压缩率120%时重组木性能达到最优。

施胶方式和单板厚度对重组木物理力学性能的影响

采用不同树种的不同厚度单板制备重组木,考察了单板施胶方式、厚度和树种对重组木耐水性能与抗弯性能的影响。结果表明:在0.7~2.2 mm范围内,树种和单板厚度相同时,采用单板表面喷胶制备重组木的吸水厚度膨胀率低于单板浸胶制备的重组木,静曲强度高于后者。树种相同时,单板越厚制备的重组木耐水性能越差。单板厚度和树种对重组木的静曲强度影响较大。单板厚度相同时,桉木重组木的耐水性能和弹性模量高于杨木重组木,但静曲强度低于后者。本研究可为薄单板制备重组木原料和施胶工艺的选择提供重要参考依据。

基于分形理论的隔水性指数法对古风化壳隔水效果的评价

针对华北型煤田复杂构造区底板奥陶系灰岩岩溶水害威胁问题,目前采用的突水系数评价方法和注浆改造(加固)治理技术均未考虑奥灰顶部古风化壳的隔水性能。基于此,研究了奥灰顶部古风化壳的物性特征,在“隔水性指数法”思想指导下,提出了一种基于分形理论的隔水性指数法评价古风化壳隔水性,创建了评价流程,并以峰峰矿区南部研究区为例开展应用,结果表明:研究区古风化壳弱和较弱隔水性区呈条带状分布于井田中部和西南部,强和较强隔水性区分布于井田北部和南部边界,其他区域为中等隔水性。该方法有效减少了传统评价方法中构造要素描述的数量,更能够对断裂网络的复杂度进行定量化评价,对于华北型煤田古风化壳隔水性研究具有理论指导意义。

保水剂与氮肥配施对雪茄烟抗旱性相关理化性状的影响

为探讨保水剂与氮肥配施对雪茄烟不同时期抗旱性的影响,本试验以雪茄烟品种德雪一号为材料,通过盆栽方式研究干旱条件下不同浓度保水剂与不同用量氮肥配施对雪茄烟抗旱性相关生理生化指标的影响,并对其进行相关性分析、主成分分析和隶属函数综合评价。结果表明,与对照相比,保水剂和氮肥配施处理均可提高雪茄烟叶的叶绿素含量,保证叶绿素的正常合成和降解;均可显著增强雪茄烟叶片SOD、POD、CAT活性,显著降低叶片MDA含量,减少烟叶中过氧化物的产生,降低其膜脂过氧化损伤;均可显著提高雪茄烟叶脯氨酸、可溶性蛋白和可溶性糖含量,促进雪茄烟叶片渗透调节物质积累,增强水分调控能力。保水剂用量4 g/株、氮肥用量4.29 g/株处理(A1B2)效果最好,可显著增强雪茄烟品种德雪一号的抗旱性。本结论可为干旱且土壤保水保肥性能较差地区优质雪茄烟栽培提供理论依据和参考。