Hydration Heat Effect of Cement Pastes Modified with Hydroxypropyl Methyl Cellulose Ether and Expanded Perlite

Hydration heat effect of cement pastes and mechanism of hydroxypropyl methyl cellulose ether （HPMC） and expanded perlite in cement pastes were studied by means of hydration exothermic rate, hydration heat amount, FTIR and TG-DTG. The results show that HPMC can significantly delay the hydration induction period and acceleration period of cement pastes. As mixing amount increased, hydration induction period of cement pastes enlarged and accelerated period gradually went back. At the same time, the amount of hydration heat gradually decreased. Expanded perlite had worse delay effects and less change of hydration heat amount of cement pastes than HPMC. HPMC changed the structure of C-S-H during cement hydration. The more amount of HPMC, the more obvious effect. However, EXP had little influence on the structure of C-S-H. At the same age, the content of Ca （OH）2 in cement pastes gradually decreased as the mixing amount increase of HPMC and expanded perlite, and had better delay effect than that single-doped with HPMC or expanded perlite when HPMC and expanded nerlite were both dooed in cement pastes.

Thermal and structural studies of poly (vinyl alcohol) and hydroxypropyl cellulose blends

Polymers and polymeric composites have steadily reflected their importance in our daily life. Blending poly(vinyl alcohol) (PVA) with a potentially useful natural biopolymers such as hydroxypropyl cellulose (HPC) seems to be an interesting way of preparing a polymeric blends. In the present work, blends of PVA/HPC of compositions (100/0, 90/10, 75/25, 50/50, 25/75, and 0/100 wt/wt%) were prepared to be used as bioequivalent materials. Thermal analyses [differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA)], and X-ray diffraction (XRD) were employed to characterize and reveal the miscibility map and the structural properties of such blend system. The obtained results of the thermal analyses showed variations in the glass transition temperature (Tg) indicating the miscibility of the blend systems. Moreover, the changes in the melting temperature (Tm), shape and area were attributed to the different degrees of crystallinity and the existence of polymer-polymer interactions between PVA and HPC molecules. The X-ray diffraction (XRD) analysis showed broadening and sharpening of peaks at different HPC concentrations with PVA. This indicated changes in the crystallinity/amorphosity ratio, and also suggested that the miscibility between the amorphous components of homo-polymers PVA and HPC is possible. The results showed that HPC doped in PVA film can improve the thermal stability of the film under investigation, leading to interesting technological applications.

Regulating the Function of Nanocomposite Made from Hydroxypropyl Methyl Cellulose with Bacterial Cellulose Nanocrystal

Hydroxypropyl methyl cellulose(HPMC)-based hybrid nanocomposites reinforced with bacterial cellulose nanocrystals(BCNC) were prepared and characterized.The HPMC nanocomposites exhibited good thermal stability,with a thermogravimetric peak temperature of around 346℃.The addition of BCNC did not significantly affect the thermal degradation temperature or improve the transparency of HPMC nanocomposites.However,the addition of BCNC favorably affected the light scattering properties of the nanocomposites and enhanced mechanical properties such as tensile stress and Young's modulus from 65 MPa and 1.5 GPa up to 139 MPa and 3.2 GPa,respectively.The oxygen permeability of the HPMC nanocomposites also increased with increase in the amount of BCNC added.

Structure Elucidation of Hydroxypropyl Cellulose Homogenously Prepared from NaOH/Urea Aqueous Solution

Hydroxypropyl celluloses(HPC) were homogenously synthesized by the reaction of cellulose with propylene oxide in NaOH/urea aqueous solution.Water-soluble HPC with molar degree of substitution(MSNMR) in the range of 0.52~0.78 was prepared from microcrystalline cellulose,cotton linters,and spruce sulfite pulp.The structure of the HPC samples was characterized by means of FT-IR,NMR,gas chromatography(GC),and size exclusion chromatography(SEC) analyses.Three types of cellulose samples with different molecular weights were found to dissolve well in the NaOH/urea solvent with no obvious differences in reactivity and regioselectivity.The relative reactivity of hydroxyl groups in the glycosyl unit was in the following order:O-6>O-2>O-3.In addition,the results of the study indicated that the tandem reaction during hydroxypropylation could be ignored.

丝素蛋白联合壳聚糖基热敏水凝胶的性能评估

目的在壳聚糖(CS)/羟丙基甲基纤维素(HPMC)热敏水凝胶的基础上,利用丝素蛋白(SF)与CS交联,构建CS/HPMC/SF水凝胶,研究SF对水凝胶的性能影响。方法共混法制备CS/HPMC混合溶液,向其中分别添加1%、5%、10%的SF溶液及交联剂京尼平,加入圆柱形模具中,升温至37℃,使溶液转为凝胶态。对水凝胶进行形貌、傅里叶变换红外光谱仪(FTIR)、X射线衍射(XRD)以及亲水性及力学性能表征检测。结果扫描电子显微镜下观察水凝胶为多孔状,随着SF的加入,孔隙减少,出现裂痕。FTIR和XRD结果显示,CS与HPMC混合后结晶程度改变,当加入SF后,SF与CS发生化学交联,结构发生转变,水凝胶的亲水性也因此减弱。力学表征显示,当SF的添加量为5%时,水凝胶的回弹性最优,弹性模量最大,且基本保持不变。结论SF与CS的交联改进了CS基热敏水凝胶的性能,相比于其他组水凝胶,CS/HPMC-5%SF保持良好的亲水性且具有较好的力学性能。

基于羟丙基纤维素制备乙醇凝胶推进剂

传统的乙醇胶凝剂甲基纤维素(MC)和羟丙基甲基纤维素(HPMC)必须加入一定比例的水作为溶剂才能形成凝胶。为了制备高性能的乙醇凝胶绿色推进剂,采用羟丙基纤维素(HPC)作为无水胶凝剂,并对其制备的乙醇凝胶推进剂进行剪切测试、屈服应力测试、应变扫描和频率扫描等测试。结果表明,HPMC凝胶需加入质量分数为6%的水作为溶剂,其临界胶凝剂质量分数为10%;HPC凝胶不需要加水,其临界胶凝剂质量分数为8%。当胶凝剂质量分数为8%时,HPMC、HPC凝胶的屈服应力分别在2.5 Pa左右和24.8 Pa,HPC凝胶具有更大的屈服应力;同时HPC比HPMC具有更大的线性黏弹区域,临界应变更大。

聚乙醇酸与羟丙基甲基纤维素用于远端胰腺切除模型术后缝合的有效性和安全性评估

目的探讨应用聚乙醇酸(polyglycolic acid,PGA)与羟丙基甲基纤维素(hydroxypropyl methylcellulose,HPMC)复合材料在远端胰腺切除术后缝合中的有效性和安全性。方法选用36只健康成年比格犬,将其随机均分为观察组和对照组,每组各18只行远端胰腺切除手术。观察组实验犬使用PGA+HPMC复合材料进行切口加固;对照组实验犬使用NEOVEIL进行切口加固。术前、术后3 d及解剖前,分别对各组实验犬进行血常规检测。设置2周、4周、8周观察周期,每个观察点各6只动物进行心肝脾肺肾组织学检查、硬组织切片病理诊断等评估,并进行安全性评价。结果观察组和对照组实验犬在术前血常规检测比较差异无统计学意义。重复测量方差分析结果显示,不同时间点的白细胞计数(WBC)(F=14.875,P=0.001)、平均红细胞血红蛋白浓度(MCHC)(F=5.049,P=0.009)、中性粒细胞百分比(Neu%)(F=4.794,P=0.011)、红细胞计数(RBC)(F=6.591,P=0.002)、血红蛋白(HGB)(F=8.154,P=0.001)、红细胞比容(HCT)(F=5.281,P=0.007)、血小板计数(PLT)(F=6.560,P=0.014)、红细胞分布宽度变异系数(RDW-CV)(F=33.950,P=0.039)、淋巴细胞百分比(Lym%)(F=3.299,P=0.043)均值存在差异,但观察组和对照组组间无统计学差异,且时间与组别交互作用对其无显著影响,表明两组实验犬均出现了炎症反应或手术应激。两组实验犬在术后8周的硬组织病理切片评分中,观察组和对照组实验犬的炎症与坏死相关评分、纤维化、修复等相关评分和总分方面差异均无统计学意义(P>0.05)。两组实验犬在术后8周的解剖中,均未发现心肝脾肺肾等器官有明显的损伤,也未发现缝合材料残留、胰液渗漏或胰瘘等情况,表明两组缝合材料均已完全被吸收代谢,且切口愈合良好不会对内脏器官造成不良影响。结论PGA与HPMC是一种有效和安全的术后缝合材料,具有良好的生物可降解性、生物相容性、缝合强度和创面愈合质量,可以在远端胰腺切除术后缝合中与传统的可吸收性加固材料相媲美,为其在临床上的应用提供了科学依据。

羟丙基淀粉植物胶囊的研究

以羟丙基淀粉(HPS)为主料,羧甲基纤维素钠(CMC-Na)和海藻酸钠(SA)为增强剂,并辅以凝胶剂和塑化剂,制备了复合植物胶囊HPS/CMC-Na/SA,采用单因素实验和正交实验优化了制备工艺,并通过SEM、FTIR、XRD对其进行表征。结果表明,当HPS加量为85 mg·mL^(-1)、CMC-Na加量为8.5 mg·mL^(-1)、SA加量为4.5 mg·mL^(-1)时,复合植物胶囊的抗拉强度为30.08 MPa,断裂伸长率为14.49%,杨氏模量为1289.77 MPa,800 nm透光率为78.068%,400 nm透光率为63.072%。

纤维素醚改性粉煤灰基薄喷材料性能研究

采用纤维素醚(羟乙基纤维素醚、羟丙基甲基纤维素醚)对粉煤灰基薄喷材料的粘结性能进行改性研究,研究了纤维素醚的黏度、取代基对粉煤灰基薄喷材料粘结强度、稠度及其抗拉强度、抗压强度的影响规律。采用扫描电子显微镜研究了纤维素醚掺入前后粉煤灰基薄喷材料28 d试样的微观结构,揭示了纤维素醚对薄喷材料粘结性能改性机理。结果表明,加入纤维素醚后,薄喷材料的粘结强度显著提高。相同取代基下,掺入低黏度的纤维素醚试样的粘结性能更高。不同取代基下,羟乙基纤维素醚试样粘结强度更高,对力学性能的不良影响更小。掺入0.05%(占胶凝材料质量分数)羟乙基纤维素醚的粉煤灰基薄喷材料28 d粘结强度达到1.67 MPa,抗压强度为11.4 MPa。

可控交联PVA导电水凝胶织物柔性传感器的制备与性能

为了制备交联程度可控的导电水凝胶,以聚乙烯醇(PVA)为原料,添加羟丙基纤维(HPC)来控制水凝胶的交联度,制备了羟丙基纤维-聚乙烯醇(HPC-PVA)导电水凝胶溶液。将水凝胶溶液涂覆在涤氨织物上,通过循环冷冻-解冻法制得羟丙基纤维素-聚乙烯醇(HPC-PVA)导电水凝胶织物。对导电水凝胶织物的形貌、组成、机械性能、抗冻性、热稳定性及传感性能进行分析。结果表明,当HPC质量分数为2%、PVA质量分数为10%时,HPC-PVA导电水凝胶织物具有良好的力学强度(断裂强度为16.77 MPa)、优异的抗冻性、较好的导电率(1.48 S/m),对人体运动以及面部微表情变化具有较好的灵敏度。

琥珀酸美托洛尔缓释微丸保护性衣层对其缓释片形成的影响与初步评价

目的评价羟丙纤维素及羟丙甲纤维素对琥珀酸美托洛尔缓释微丸的机械保护作用及差异。方法用不同分子量等级的羟丙纤维素和羟丙甲纤维素对琥珀酸美托洛尔缓释微丸进行包衣,通过检测微丸负压载荷、微丸完整性、体外溶出曲线,评价两种高分子材料对微丸的保护效果。通过制备了羟丙纤维素和羟丙甲纤维素薄膜并考察两种高分子材料薄膜的抗张强度、延展率、韧性和弹性模量等方面的机械性能差异。结果包被羟丙纤维素和羟丙甲纤维素的琥珀酸美托洛尔微丸,断裂载荷增加,压片后微丸完整性提高,机械性能提升,药物泄漏率降低。结论羟丙纤维素和羟丙甲纤维素保护层包衣对琥珀酸美托洛尔片释放单元有一定的机械保护作用,羟丙纤维素具有相对更高的保护能力,可以为多单元微丸药物释放系统的微丸保护策略提供借鉴。

Preparation and Swelling Kinetic Analysis of Poly (HPMC-co-AA-co-AM) Super Absorbent Resin

Super absorbent resin(SAR)is prepared by aqueous high temperature polymerization using hydroxypropyl methylcellulose(HPMC)as monomer backbone material,acrylic acid(AA)and acrylamide(AM)as the graft copolymer monomer,potassium persulfate(KPS)as the initiator to generate free radicals,and N,N`-methylenebisacrylamide(MBA)as cross-linking agent for cross-linking reaction.Simutaneously,the influence of individual factors on the water absorption is investigated,and these factors are mainly AA,AM,KPS,MBA,HPMC,and reaction temperature.The optimized conditions are obtained by the experiment repeating for several times.The water absorption multiplicity and salt absorption multiplicity under the conditions are 782.4 and 132.5 g/g,respectivity.Furthermore,the effects of different temperatures and salt concentrations on its water absorption,as well as the swelling kinetics of SAR are studied.It is indicated the water-absorbing swelling process is mainly caused by the difference in water osmotic pressure and Na+concentration inside and outside the cross-linked molecular structure of the resin,which is not only consistent with the quasi-secondary kinetic model,but also with the Fick diffusion model.

高性能多层氧化石墨烯基复合水凝胶的可控合成方法研究

以多层氧化石墨烯(GO)为原料,羟丙基纤维素(HPC)为骨架,采用溶剂热法制备还原氧化石墨烯复合海绵的前驱物——三维还原氧化石墨烯复合水凝胶。考察分散液配比、置换程度、pH、反应时间与温度、HPC添加量等因素对水凝胶成型性的影响。结果表明:分散液中无水乙醇与去离子水最佳配比为1∶1;离心时间30min、置换次数6次时层间水分置换最彻底;pH=8、反应温度210℃、时间14h、HPC添加量10mg时制备效果最佳。

季铵盐双子表面活性剂与HPC在水溶液中的相互作用

采用稳态荧光和电导方法研究了系列季铵盐阳离子双子表面活性剂C12-S-C12·2Br(S代表亚甲基的个数)与水溶性高分子羟丙基纤维素(Hydroxypropyl cellulose,HPC)在水溶液中的相互作用。实验结果表明:在低于双子表面活性剂自身临界胶团浓度(Critical miceue concentration,cmc)时,在HPC分子上发生了聚集。当E12-S-C12·2Br/HPC体系混合溶液中C12-S-C12·2Br。的浓度达到c2(c2>cmc)时才有表面活性剂自由胶团生成。揭示了临界聚集浓度(Critical aggregation concentration,cac)和C12-S-C12·2Br/HPC体系混合溶液中自由胶团生成浓度c2与系列C12-S-C12·2Br表面活性剂cmc的比例关系及与链接链S的关联。

有机/无机掺杂复合水凝胶智能窗的结构设计与性能

水凝胶智能窗是一种智能响应窗户,其特点是在临界溶液温度附近能够通过可逆状态转变来调制太阳光,从而达到减少能耗的目的。以羟丙基纤维素、聚(N-异丙基丙烯酰胺)和上铯钨青铜纳米材料为原料,设计制备了一种复合水凝胶(HPC-PNIPAM/Cs_(x)WO_(3))智能窗。该复合水凝胶在低温下透过率为68.93%,高温下则降至0.82%,太阳光调制能力优异。其响应时间缩短至12.9 s,响应效率明显提升。与传统的水凝胶智能窗相比,这种新型窗户不仅具有更适宜的临界溶液温度,还展现出优秀的太阳光调制能力。这为新型水凝胶类智能窗的开发提供了重要的理论基础。

海藻酸钠载药口腔速溶膜的制备及性能研究

针对当前药物突释、利用率低和持续释放等问题,以海藻酸钠(SA)和羟丙甲基纤维素(HPMC)为成膜剂,采用流延成膜的方法制备了海藻酸钠口腔速溶膜,对其化学结构、透光性和水溶性进行了分析,得到最佳的SA和HPMC的成膜比例,在此基础上,负载盐酸苄达明(BH)制备海藻酸钠载药口腔速溶膜。结果表明,最佳成膜比例为w(SA):w(HPMC)=1:2;另外,当BH负载量为30%时,海藻酸钠载药口腔速溶膜力学性能最好,当负载量为40%时,其包封率和载药效率最佳,经济成本更好。

不同保水组分对混凝土性能的影响

在减水剂中掺入功能组分实现混凝土性能的优化是常用的技术手段,但是随着减水剂逐渐以聚羧酸减水剂为主,其酸碱体系的变化会影响功能组分效果的发挥。基于此,通过在聚羧酸减水剂中分别掺入羟丙基甲基纤维素和黄原胶,研究其对混凝土流动性、凝结时间、抗压强度的影响。结果表明,黄原胶多糖对混凝土的改善作用优于纤维素醚,能够起到更好的保水效果,与聚羧酸的相容性更好。

PVA/HPC相容性及共混膜的性能

共混改性是提高材料性能的简便而有效的方式,文中以聚乙烯醇(PVA)和羟丙基纤维素(HPC)为基本成膜材料,通过制备不同配比的共混溶液,探讨了PVA/HPC共混体系的相容性,并对共混膜的结构和性能进行了初步表征。稀溶液黏度法和扫描电镜分析表明,共混体系中PVA含量较多(>80%)时,共混膜呈现均一的相态结构,共混体系为相容体系;傅立叶红外光谱和热重分析显示,PVA/HPC共混体系中存在的氢键作用提高了共混体系的热稳定性。

羟丙基甲基纤维素对硫铝酸盐水泥水化的影响

采用X射线衍射分析、热分析、等温量热法和电感耦合等离子光谱法研究了羟丙基甲基纤维素(HPMC)对硫铝酸盐水泥水化的影响,并从孔溶液的性质和组成方面分析了其对水泥水化的影响机理.结果表明:HPMC改变硫铝酸盐水泥的水化放热速率,增加钙矾石(AFt)、单硫型水化硫铝酸钙(AFm)和铝胶(AH_(3))的含量,促进AH_(3)与CaSO_(4)和Ca(OH)_(2)反应,并促进AFt向AFm转变;HPMC降低硫铝酸盐水泥孔溶液的表面张力,增大孔溶液的pH值,降低孔溶液中SO_(4)^(2-)的浓度,增加Ca^(2+)和[Al(OH)_(4)]^(-)的浓度,进而增大AFt和AFm的离子浓度积,有利于水化产物的析出,从而促进水泥水化.

复合增稠剂对大流态薄层砂浆性能的影响及其抗裂机理

基于温轮胶(WG)和羟丙基甲基纤维素醚(HPMC)这两种增稠剂的特点,将二者复掺以解决严酷环境下薄层施工用水泥基大流态砂浆易开裂的问题。研究中通过对比WG、HPMC及复合增稠剂的作用效果,明晰了复合增稠剂对大流态砂浆工作性能、力学性能及抗裂性能的影响规律,并结合冷冻扫描电镜对复合增稠剂抗裂作用机理进行了剖析。结果表明:单掺WG、HPMC均无法解决严酷环境下砂浆开裂的问题;复合增稠剂在保水性和抗裂性能上表现更优,且砂浆弹性模量降低,柔韧性提升,夏季在室外暴晒也不会开裂。砂浆抗裂机理在于复合增稠剂融合了WG和HPMC各自优势特点,在体系浆液空间形成三维网状结构与膜状结构的叠加,三维网状结构可大幅增强浆料稳定性,而膜状结构在再次增强浆料稳定性的同时大幅提升砂浆的保水性,进而减弱水分扩散蒸发,达到砂浆抗裂的目的。