Synthesis and Surface Activity of Cashew-Based Anion-Nonionic Surfactants

Four novel anion-nonionic surfactants were synthesized using cashew phenol as raw material. The four structures were characterized by IR and elemental analysis. Their surface activities were investigated. Their critical micelle concentrations (CMC) are 9.30 × 10 –3 mol/L, 8.50 × 10–3 mol/L, 8.10 × 10–3 mol/L and 7.71 ×–3 mol/L respectively, and the corresponding surface tensions at CMC are 28.38 mN/m, 28.60 mN/m, 30.40 mN/m and 30.00 mN/m respectively. The contact angles of the solutions on sheet galsses were measured to observe their surface wettabilities. The effects of their concentrations, the concentrations of NaCl and temperature on their foaming capacity and foam stability were studied.

Theoretical and Experimental Studies on Interactions of Cationic-Anionic Surfactants

Typical cationic and anionic surfactants were chosen and their interactions were calculated by quantum chemical method. Interaction energies are -0.2378 kJ·mol^-1, -3.3394 kJ·mol^-1 and 0.1204 kJ·mol^-1 for the molecular pairs with fluocarbon and hydrocarbon chain: C4H10/C5H12, C4F10/C5H12, and C4F10 /C5F12, respectively.When hydrophilic group with cationic and anionicions is introduced, interaction energies are -287.40kJ·mol^-1,-311.18 kJ·mo1^-1 and -345.83 kJ·mo1^-1. The results show that there is strong static interaction between cationic and anionic surfactants. It has been predicted that mixed monolayer may be formed and surface activity is enhanced favorably, especially for mixtures of cationic and anionic surfactants with fluocarbon and hydrocarbon chains. The anionic surfactants, sodium octadecylbenzenesulfonate perfluopolyetherbenzenesulonate(ANF-I) was synthesized, mixture effects of ANF-I with sodium octadecylbenzenesulfonate or dodecyldimethyl benzylammonium bromide were studied. The results indicate that the efficiency of mixing increased and the theoretical prediction was testified. These results can provide useful information for the design of new surfactants.

Pilot test of polymer microsphere alternate surfactant flood(PMAS)with mixtures of anionic-cationic surfactants under harsh conditions in a sandstone reservoir

The first pilot test of polyacrylamide microsphere alternate surfactant flood(PMAS)with mixtures of anionic-cationic surfactants(Sa/c)was carried out for a high-temperature,high-salinity,and highhardness sandstone reservoir to demonstrate the potential of this novel technique to improve oil recovery.A critical micelle concentration(CMC)of 4.82 mg/L,an ultralow interfacial tension(IFT)of 8104 mN/m,and a high oil solubilization of 22 were obtained.Static and dynamic adsorptions of Sa/c on natural core containing 15 wt%clay were reduced to about 2.20 and 0.30 mg/g-core,respectively,with the addition of adsorption inhibitor(AI).Since June 2014,the pilot test of PMAS was carried out in a Sinopec reservoir with a temperature of 87C,a salinity of 260,393 mg/L,and a hardness of 6,401 mg/L.Twelve cycles of alternative injection of 0.0125 PV Sa/c with a concentration of 0.1%and 0.0125 PV polyacrylamide microsphere with a concentration of 0.2%were conducted at an injection rate of 0.1 PV/yr,for a total of 0.3 PV chemical injection.As a result,the net daily oil production increased from 0 t to 6.5 t,and the water cut decreased from 96.3%to 93.8%,leading to an ultimate improved oil recovery of 6.3%original oil-in-place.

Effect of anionic-nonionic mixed surfactant on ryegrass uptake of phenanthrene and pyrene from water

The effect of anionic-nonionic mixed surfactant (SDBS-TX100) on the uptake of phenanthrene and pyrene by ryegrass in a hydroponic system was studied, and the influence factors including the com- positions and concentrations of mixed surfactants and the compounds properties were also discussed. The results showed that SDBS-TX100 mixtures with certain compositions and concentrations could enhance the uptake of phenanthrene and pyrene by ryegrass, which could be attributed to the im- proved uptake capacity of ryegrass roots for phenanthrene and pyrene. SDBS-TX100 can enhance the uptake of phenanthrene and pyrene by ryegrass in a wider range of surfactant concentrations (0―0.8 mmol/L) in comparison with corresponding single surfactants, and the maximal contents of phenan- threne and pyrene in ryegrass roots were obtained with the concentrations of SDBS-TX100 around the corresponding critical micelle concentrations. The uptake of phenanthrene and pyrene by ryegrass increased with the increasing mole fraction of SDBS in mixed surfactant solutions, and SDBS-TX100 mixture with a mole ratio of SDBS to TX100 at 9:1 had the greatest capacity in enhancing the uptake of phenanthrene and pyrene, at which the corresponding maximal concentrations of phenanthrene and pyrene in ryegrass roots were 216 and 8.16 times those without surfactants, respectively. Results from this study indicate that the anionic-nonionic mixed surfactants (SDBS-TX100) would be a preferred selection for the application of surfactant-enhanced phytoremediation technology to contaminated soils.

Gemini阳离子/含氟阴离子表面活性剂混合体系的界面润湿调控及解水锁机制研究

为有效解决低渗透致密砂岩气藏开采普遍存在的水锁伤害问题,研究了Gemini阳离子表面活性剂双季铵盐BQ-16和含氟阴离子表面活性剂全氟辛基磺酸钾(PPS)在降低表面张力和润湿调控方面的协同作用,并探究了BQ-16/PPS表面活性剂混合体系的润湿调控及解水锁机制。结果表明,当PPS的摩尔分数(α_(PPS))为0.7时,BQ-16/PPS表面活性剂混合体系的表面张力达到最低,低于任一纯组分,此时BQ-16/PPS表面活性剂混合体系接近电中性;BQ-16和PPS在岩心表面润湿调控方面表现出协同效应,当BQ-16/PPS表面活性剂混合体系总浓度为1×10^(-4)mol·L^(-1)、α_(PPS)为0.7时,盐水滴接触角最大,达到84.23°;BQ-16/PPS表面活性剂混合体系(α_(PPS)=0.7)在石英砂表面的吸附过程符合准二级动力学方程和Freundlich等温吸附模型,低浓度时为单分子层吸附,高浓度时为多分子层吸附;BQ-16/PPS表面活性剂混合体系(α_(PPS)=0.7)可将岩心的液体饱和度降至0.410,并将渗透率恢复值提高至0.78,说明BQ-16/PPS表面活性剂混合体系可有效解决水锁伤害,这主要与混合体系能够显著降低表面张力并通过在岩心表面的吸附改变岩心表面润湿性有关。

脂肪醇嵌段聚醚硫酸盐的合成与性能

以脂肪醇嵌段聚醚即一种脂肪醇聚氧丙烯聚氧乙烯醚、氨基磺酸为原料,尿素为催化剂,合成了硫酸酯盐延展型阴-非离子表面活性剂,采用红外光谱对其结构进行了表征,采用浊度法、滴体积法、分水时间法、分散指数法对其低温溶解性能、表面性能、乳化性能、分散性能进行了测定。采用单因素实验法,研究了反应温度、反应时间、催化剂用量、原料配比等因素对产物中活性物含量的影响,并确定了最佳合成反应条件。结果表明,在反应温度100℃、反应时间3 h、催化剂用量为反应物总质量的1%、n(嵌段聚醚)∶n(氨基磺酸)=1∶1.5条件下,产物中活性物含量达到96.49%。

非离子-阴离子Bola型表面活性剂和纳米SiO2颗粒协同稳定的双重响应型O/W乳状液

合成了一种非离子-阴离子Bola型智能表面活性剂,通过pH-响应可以在非离子型CH_(3)O(EO)_(5)-R_(11)-COOH(pHpKa)之间转换。单独使用时,非离子型和Bola型分别表现为不良乳化剂和优良乳化剂。与纳米SiO_(2)颗粒复配使用时,非离子型能与SiO_(2)颗粒协同稳定O/W(正癸烷)型Pickering乳状液,其中表面活性剂通过氢键作用吸附到颗粒表面产生原位疏水化作用,提高了颗粒的表面活性,并且这种Pickering乳状液具有pH-和温度-双重响应性,能够通过改变pH或者温度使乳状液在稳定和破乳之间实现多次转换。另一方面,Bola型CH_(3)O(EO)5-R_(11)-COONa能够与纳米SiO_(2)颗粒协同稳定分散液包油(oil-in-dispersion)乳状液,该乳状液具有良好的耐温性,但对调节pH时产生的盐较为敏感。然而与破乳后能完全返回水相便于回收再利用的同系物CH_(3)O(EO)7-R_(11)-COOH相比,具有较短EO链的CH_(3)O(EO)_(5)-R_(11)-COOH无论处于非离子型还是Bola型状态仍具有相当的油溶性,破乳后不能完全返回水相,表明EO数大小对这类新型智能表面活性剂的性能有显著的影响。

阴-非离子型Gemini表面活性剂的合成研究进展

介绍了磺酸盐型、羧酸盐型和其他类型阴-非离子型Gemini表面活性剂的合成研究进展,简述了阴-非离子型Gemini表面活性剂与其他表面活性剂复配体系的性能特点及相关应用,并对阴-非离子型Gemini表面活性剂的发展趋势进行了展望。

油田用非离子型及阴-非离子型表面活性剂的应用进展

简述了国内外油田用非离子、阴-非离子表面活性剂的研究现状,介绍了非离子、阴-非离子表面活性剂在油田中应用进展,并探讨了两种表面活性剂与其它类型表面活性剂复配的应用前景。

阴离子与非离子表面活性剂混合体系的胶束性质

为了研究化学驱中表面活性剂复配体系的混合胶束性质,给表面活性剂复配体系的色谱分离预测提供必要的参数,测定了十二烷基苯磺酸钠(SDBS)和TX 100混合体系的表面张力,考察了电解质浓度、种类和温度对混合体系临界胶束浓度(cmc)和相互作用参数的影响。测试结果表明,混合表面活性剂的表面张力最低值介于两种表面活性剂之间。在相同表面张力下,混合表面活性剂的浓度比单一表面活性剂浓度低,说明SDBS与TX 100混合体系的表面活性剂在降低表面张力效率方面能够产生协同效应。在无机电解质浓度远大于表面活性剂浓度时,SDBS/TX 100混合表面活性剂临界胶束浓度可用规则溶液理论来描述,但测试中的温度、电解质浓度和种类的变化对该体系相互作用参数均产生影响,说明规则溶液理论有一定局限性。

阳、阴、非离子表面活性剂胶束对酯碱性水解的影响

应用紫外分光光度法和热动力学方法研究了芳香酸酯和正脂肪酸酯在表面活性剂ＤＴＡＢ、ＴＴＡＢ、ＣＴＡＢ、ＳＤＳ、Ｂｒｉｊ３５、ＴｒｉｔｏｎＸ－１００胶束中的碱性水解反应。阳、阴、非离子表面活性剂胶束对酯的碱性水解均有禁阻作用。讨论了胶束对酯碱性水解禁阻作用的原因。

高浓度无机盐对正负离子等摩尔混合表面活性剂表面活性的影响

一般认为无机盐对等链长正负离子表面活性剂等摩尔混合体系的表面活性没有明显影响 .通过测定等摩尔癸基三乙基溴化铵和癸烷磺酸钠混合体系在卤化钠 (NaX ,X =F-,Cl-,Br-,I-)溶液中的表面活性 ,发现高浓度的无机盐具有明显影响 ,使混合表面活性剂的临界胶束浓度 (cmc)降低 ,水溶液的最低表面张力 (γcmc)升高 .无机盐的影响程度随NaX中X的离子半径增加而增大 .可通过无机反离子对正负离子表面活性剂头基之间吸引作用的“屏蔽”及“盐析”

塿土对阴-非离子表面活性剂的吸附特征研究

以平衡吸附法研究了塿土对阴离子表面活性剂(SDS)、非离子表面活性剂(TritonX-100、Tween80和Brij35)的吸附特征,考察了pH、阴-非离子表面活性剂混合对塿土吸附表面活性剂的影响。结果表明,非离子表面活性剂在塿土上吸附等温线均呈L型,且均符合Freundlich和Langmuir方程;塿土对SDS的吸附等温线呈LS型,可用Freundlich方程来描述;塿土对4种表面活性剂吸附量的大小顺序为Tween80>SDS>Brij35>TritonX-100。当阴-非离子表面活性剂一起进入土壤中,SDS-Brij35之间的相互影响不大;TritonX-100与SDS相互作用较大,无论二者以何种方式混合都会使TritonX-100在塿土上的吸附量增加,SDS的吸附量下降;SDS与Tween80之间的相互作用最大,混合后吸附量均下降,但Tween80吸附量降低的幅度最大。pH对非离子表面活性剂的吸附影响不大,而随着pH的增加,塿土对SDS的吸附百分率明显下降;在pH为8.0时,塿土对非离子表面活性剂的吸附百分率达到80以上。因此在选择合适的表面活性剂进行有机污染土壤修复和治理时,考虑土壤的特性和表面活性剂的结构是非常重要的。

烷基苯磺酸盐Gemini表面活性剂与非离子表面活性剂C_(10)E_6混合溶液的胶团化

研究了烷基苯磺酸盐Gemini表面活性剂Ia与非离子表面活性剂C10E6溶液混合胶团中分子间的相互作用.通过表面张力法测定了Ia和C10E6不同比例不同温度下的临界胶束浓度(cmc).结果表明,两种表面活性剂以任何比例复配的cmc比单一表面活性剂的cmc都低,表现出良好的协同效应.传统型非离子表面活性剂C10E6、Gemini表面活性剂Ia及混合物的cmc都随着温度升高而降低.而且,任何配比的混合胶团中两种表面活性剂分子间的相互作用参数β都是负值,这说明两种表面活性剂在混合胶团中产生了相互吸引的作用.混合表面活性剂体系的胶团聚集数比单一Ia的大,但比单一C10E6的小.向Gemini表面活性剂Ia胶束中加入非离子表面活性剂C10E6会使胶束的微观极性变小.

表面活性剂清洗处理重度石油污染土壤

为了优化表面活性剂清洗处理重度石油污染土壤的方法和具体洗脱条件参数,采集山东省东营市胜利油田污染土壤,研究了阴离子-非离子混合表面活性剂对该土壤中石油类污染物的去除效果。应用化学热洗原理,主要考查了表面活性剂配比、投加量、清洗温度及清洗助剂对去除效果的影响。实验得到的清洗处理最佳条件为:使用LAS与TX-100质量比为8∶2的组合表面活性剂,总表面活性剂浓度为3 g/L,助剂硅酸钠浓度为5 g/L,75℃条件下搅拌1 h。清洗后土壤含油量从20%下降到4.6%,去除率达到76.9%。废水回用实验表明,清洗处理的废水对土壤中石油烃类物质仍有一定的去除效果。废水回用比从30%到100%时,对土壤中石油烃的去除率都可达到55%以上。对废水进行二次回用时仍能去除18.8%的污染物。

月桂醇聚氧乙烯醚(7)己基磺基琥珀酸混合双酯钠的合成与性能

采用控制酯化率和非外加相转移催化剂在常压进行反应的方法合成了月桂醇聚氧乙烯醚(7)己基磺基琥珀酸混合双酯钠。最佳工艺条件为:n〔月桂醇聚氧乙烯醚(7)〕∶n(顺酐)=1 00∶1 10,于130℃下单酯化反应2 5h,得到产率为99 6%的单酯化产物。n(己醇)∶n(顺酐)=4 0∶1 0,于170℃下双酯化反应2 0h,得到产率为95 8%的双酯化产物。n(亚硫酸氢钠)∶n(顺酐)=1 10∶1 00,加热介质温度为170℃下磺化反应2 5h。测得产物的表面张力、临界胶束浓度、乳化力、渗透力、分散力、耐硬水性能分别为30 7mN/m、3 548×10-5mol/L、3 5min、3 7s、59 5%和14min。与磺基琥珀酸双己酯钠盐(DHSS)和月桂醇聚氧乙烯醚(7)磺基琥珀酸单酯二钠盐(LESS)进行了性能对比。结果表明:分散力、乳化力和耐硬水性能较DHSS均得到了改善,渗透性能较LESS得到了较大的提高。

阴-非离子表面活性剂微乳捕收剂的制备及应用

针对煤泥浮选过程中烃油捕收剂分散性差、耗量大的缺陷,采用自制的阴-非离子表面活性剂LYS制备柴油微乳捕收剂LY,并通过煤泥浮选试验对LY和柴油的浮选性能进行了比较。通过拟三元相图法,确定微乳捕收剂配方中最佳助表面活性剂为正戊醇,最佳Km(表面活性剂/助表面活性剂的质量比)=1.5;通过激光粒度测试法、电导率法和染色法测定和评价微乳捕收剂的性质,优化出最佳配方为柴油∶LYS∶正戊醇:水=5∶3∶2∶6(质量比),微乳类型为O/W,平均粒径30.71 nm;分别采用柴油和LY作为捕收剂对试验煤样进行了浮选试验,试验结果表明,两种捕收剂获得的最佳浮选完善指标相近,但LY的用量比柴油低100 g/t,柴油节油率可达到73%左右(不考虑表面活性剂),综合成本比柴油节省0.23元/t煤泥。

正负离子表面活性剂混合体系中高稳定性囊泡的形成

对总浓度为 0 0 1mol/L ,摩尔比为 2∶1的十二烷基硫酸钠 /溴化十二烷基三乙铵的正负离子表面活性剂混合体系形成的囊泡的稳定性进行了研究 .发现这一体系形成的囊泡在长时间放置 (5个月 )后依然存在 .在加入较大量的无机盐 (0 15mol/LNaBr)、较大幅度pH变化 (pH =2～ 12 )、温度变化 (从 80℃到 -2 2℃ )情况下体系中的囊泡依然呈现出优异的稳定性 .在非水溶剂乙醇 (10 0 % )中这类正负离子表面活性剂仍然可以形成囊泡 .

非离子-阴离子型表面活性剂的耐盐性能

使用相图法评价了４ 种类型非离子阴离子型表面活性剂的耐盐性能。结果表明它们具有优异的耐盐能力，且随氧乙烯数的增加而增强，其中非离子磺酸盐型表面活性剂的耐盐能力最强。结合相图、浊点和Ｋｒａｆｆｔ 点的变化综合分析了非离子阴离子型表面活性剂耐盐性能增强的原因，认为同时存在两种不同类型的亲水基团是耐盐能力提高的根本原因。