原位界面聚合制备PVDF复合纳滤膜的研究

为改善聚偏氟乙烯(PVDF)复合纳滤膜性能，以掺入单体哌嗪(PIP)的铸膜液制备基膜，通过原位界面聚合快速制备复合纳滤膜，简化了制备程序。ATR-FTIR分析结果表明，基膜上成功生成聚酰胺(PA)层，SEM观察到PA层表面具有典型结节结构。得到的复合纳滤膜对Na₂SO₄截留率为95.59%,渗透通量为12.37 L/(m²·h·bar),远高于传统界面聚合制备的PVDF复合纳滤膜。72 h的持续测试结果表明该复合纳滤膜具有良好的长期稳定性。     

聚酰胺/ZIF-8双层复合纳滤膜的制备及其性能研究

采用界面聚合和层层自组装法制备了具有双层分离层的聚酰胺/ZIF-8复合纳滤膜,并研究了界面聚合条件和ZIF-8自组装时间、层数对膜结构以及膜纳滤性能的影响。结果表明,具有磺酸基的界面聚合层和ZIF-8层通过配位键的化学作用具有很好的结合性。相对于只有一层分离层的聚酰胺膜,组装ZIF-8层后膜对甲基蓝的截留率有了明显提升;并且随着组装层数的增加,膜致密度增加,对于甲基蓝的截留率升高,但是通量有所下降。当ZIF-8层组装层数为2层时得到的复合纳滤膜,在0.5 MPa压力下,对于100 mg/L的甲基蓝溶液的通量为25.3 L/(m2·h),截留率达到96.5%,且分离性能保持稳定。     

聚偏氟乙烯纳滤膜制备及其处理模拟活性黑废水

为研制适用于染料废水处理的新型纳滤膜,以自制的PVDF膜为基膜,通过溶胶-凝胶方法在膜表面涂覆TiO2纳米颗粒层,然后再涂敷多巴胺/PEI层,以制备PVDF纳滤膜.考察了制备条件对膜的表面特性及过滤性能的影响.结果表明,TiO2和多巴胺/PEI可以顺序的涂覆在PVDF膜表面.表面涂覆后,膜的通量急剧下降,截留率大幅度上...     

界面聚合聚酰胺纳滤膜渗透选择性能优化的研究进展

纳滤因其分离效率高、操作压力低、环境友好等优点,在废水处理、海水淡化和工业分离纯化等众多领域有着重要的应用。界面聚合法制备的聚酰胺（PA）纳滤膜是最为常用的纳滤膜种类之一。然而界面聚合反应速度快,如何通过调控界面聚合过程,优化纳滤膜选择分离层的结构从而提高渗透选择性,以满足不同领域对纳滤膜需求仍是亟需解决的问题。本文从影响界面聚合单体扩散因素的角度出发,综述了近年来PA纳滤膜渗透选择性能优化的研究进展,包括新型PA纳滤膜、纳米材料/PA混合基质膜及超薄PA纳滤膜3个方面,探讨了选择分离层结构调控与纳滤膜渗透选择性能优化的关系,最后指出目前界面聚合制备高渗透选择性PA纳滤膜在规模化、稳定性及可控性存在的问题,并对未来界面聚合纳滤膜在微观结构和聚合过程调控方面的研究进行了展望。     

MOF-199@GO改性PVDF荷电纳滤膜的制备及其性能

采用原位生长法制备了MOF-199@氧化石墨烯（GO）纳米复合材料,并对聚偏氟乙烯（PVDF）支撑膜进行表面改性,以克服PVDF膜表面疏水性。通过界面聚合反应,制备了基于MOF-199@GO改性PVDF的聚酰胺复合荷电纳滤膜。采用XRD、SEM、TEM、AFM和zeta电位等手段表征了MOF-199@GO复合材料及MOF-199@GO改性PVDF聚酰胺复合纳滤膜的结构及微观形貌,并测试了MOF-199@GO改性PVDF聚酰胺复合纳滤膜的脱盐性能。结果表明：通过MOF-199@GO复合材料对PVDF支撑膜的表面改性,有效克服了PVDF支撑膜的疏水性,实现了表面聚酰胺薄层的均匀连续生长,荷电纳滤膜表面荷负电性能显著增强,其中经MOF-199@GO充分改性的复合荷电纳滤膜表现出优异的脱盐性能,对MgSO₄、Na₂SO₄、NaCl和MgCl₂四种盐的截留率分别达到了93.56%、93.04%、87.48%和87.11%。     

聚哌嗪酰胺复合纳滤膜制备及其性能表征

以聚砜超滤膜为基膜,采用界面聚合方法制备了聚哌嗪酰胺复合纳滤膜,并对其膜性能进行了表征。实验重点考察了基膜性质、聚合单体浓度、聚合反应时间、表面活性剂浓度、酸受体添加量等因素对纳滤膜性能的影响,确定了纳滤膜制备过程的界面聚合优化条件,即:水相单体(哌嗪)浓度0.08~0.12molL-1;有机相单体(间苯二甲酰氯和均苯三甲酰氯混合物)浓度0.08~0.1molL-1;聚合反应时间3~5min。在0.4MPa、25℃条件下,实验测得复合纳滤膜的水通量为4.12Lm-2h-1bar-1,膜对浓度为0.01molL-1的NaCl的截留率为30%~40%,对浓度为0.005molL-1的Na2SO4的截留率为80%~90%;对分子量不低于300gmol-1的有机物的截留率高于95%。该膜的分离性能接近于商业纳滤膜,其分离机理主要表现为“筛分机理以及膜与电解质之间的荷电作用。     

原位生长法制备ZIF-8/PAN超滤膜用于染料废水处理

以六水合硝酸锌与2-甲基咪唑为前驱体,在聚丙烯腈(PAN)铸膜液中原位生长ZIF-8制备ZIF-8/PAN超滤膜,对其表面形态,化学结构,元素分布进行了表征,并研究了前驱体浓度对于膜结构以及膜性能的影响结果表明。ZIF-8在超滤膜断面及表面均有生长,在膜表面ZIF-8层均匀致密。超滤膜对于伊文思蓝染料截留率高达93.1%,纯水通量为140 L/(m~2·h)。随着前驱体浓度的增加,ZIF-8含量亦随之增加。通量显著升高,截留率略有下降。在循环过滤实验中超滤膜亦显示出优良的分离性能和抗污染性能。     

基于树状分子聚酰胺-胺(PAMAM)的复合纳滤膜制备及性能研究

以聚砜超滤膜为支撑膜,通过聚酰胺-胺(PAMAM,G0)与均苯三甲酰氯(TMC)的界面聚合反应制备复合纳滤膜。首先优化了界面聚合过程,并通过场发射扫描电子显微镜(FESEM)进行了膜的表面形貌分析,最后考察了纳滤膜对Na2SO4、不同分子量聚乙二醇及小分子有机物的分离性能。结果表明:较优的纳滤膜制备条件为:PAMAM浓度0.25%(wt),TMC浓度0.3%(wt),界面聚合时间90 s,热处理温度60℃。FESEM分析表明经界面聚合反应后,超滤膜表面形成了一层致密的活性层。随着操作压力的增加及Na2SO4浓度的降低,膜对盐的截留率均不断增大。复合纳滤膜可有效截留盐,且其截留分子量(MWCO)处于600~1000 g mol 1。     

耐溶剂复合纳滤膜的研究进展

耐溶剂纳滤是一种新型的膜分离技术,用于有机混合物的分离。商品耐溶剂纳滤膜大多是采用相转化法制备的整体皮层非对称膜,膜皮层较厚,通量较低。耐溶剂复合纳滤膜由基膜和分离层组成,具有薄皮层、高溶剂通量和高溶质截留率的优点。耐溶剂复合纳滤膜的制备与改性也因此成为近年来的研究热点。本文从界面聚合、表面涂覆、层层自组装、原位生长、有机-无机杂化和表面改性六个方面介绍耐溶剂复合纳滤膜的研究进展,最后对其发展前景进行展望。     

复合纳滤膜的研究进展

纳滤膜是孔径介于反渗透膜和超滤膜之间的一种分离膜,对二价、高价离子,及分子量大于200的有机物有较高脱除率,广泛用于海水淡化、城市污水处理等领域.纳滤复合膜是在微孔基膜表面复合上具有纳米级孔径的功能层,而获得的膜材料.本文介绍了一系列通过物理涂覆、接枝及界面聚合等方法制备的复合纳滤膜,综述了此领域的最新进展,并对纳滤膜的研究做出展望.     

Fouling-resistant Composite Membranes for Separation of Oil-in-water Microemulsions

Fouling-resistant ceramic-supported polymer composite membranes were developed for removal of oil-in-water （O/W） mieroemulsions. The composite membranes were featured with an asymmetric three-layer structure, i.e., a porous ceramic membrane substrate, a polyvinylidene fluoride （PVDF） ultrafiltration sub-layer, and a polyamide/polyvinyl alcohol （PVA） composite thin top-layer. The PVDF polymer was east onto the tubular porous ceramic membranes with an immersion precipitation method, and the polyamide/PVA composite thin top-layer was fabricated with an inteffaeial polymerization method. The effects of the sub-layer composition and the recipe in the inteffaeial polymerization for fabricating the top-layer on the structure and performance of composite membranes were systematically investigated. The prepared composite membranes showed a good performance for treating the O/W microemulsions with a mean diameter of about 2.41μm. At the operating pressure of 0.4MPa, the hydraulic permeability remained steadily about 190L·m^-2·h^-1, the oil concentration in the permeate was less than 1.6mg·L^-1, and the oil rejection coefficient was always higher than 98.5% throughout the operation from the beginning.     

Preparation and properties of MOF-199@GO modified PVDF charged composite nanofiltration membrane

As novel functional materials, metal-organic framework (MOF) and graphene oxide (GO) have received great attentions in recent years. In this work, MOF@GO nanocomposite (MOF-199@GO) is prepared by an in-situ growth method. A novel and highly efficient nanofiltration (NF) membrane can be facilely fabricated via surface decoration of MOF-199@GO onto poly(vinylidene fluoride) (PVDF) substrate before interfacial polymerization of m-phenylenediamine (MPD) and trimesoyl chloride (TMC) in order to overcome the hydrophobicity of PVDF membrane. The structure and morphology of MOF-199@GO and MOF-199@GO modified PVDF polyamide composite membrane are characterized by XRD, SEM, TEM, AFM and zeta potential. MOF-199@GO modified PVDF composite NF membrane which possesses dense and uniform polyamide thin-layer exhibits higher negative surface potential (up to ~37 mV) at pH 9.5. The performance of MOF-199@GO modified PVDF polyamide composite NF membrane has been investigated by determination of pure water flux and salt rejection. The prepared NF membrane MG3 exhibited highly efficient rejection of MgSO₄, Na₂SO₄, NaCl and MgCl₂, which are 93.56%, 93.04%, 87.48% and 87.11%, respectively. This work provides a worthy reference for designing highly efficient NF membranes modified by MOF and relevant materials.     

PDMS/ZIF-8 coating polymeric hollow fiber substrate for alcohol permselective pervaporation membranes

In order to develop high performance composite membranes for alcohol permselective pervaporation (PV), poly (dimethylsiloxane)/ZIF-8 (PDMS/ZIF-8) coated polymeric hollow fiber membranes were studied in this research. First, PDMS was used for the active layer, and Torlon®, PVDF, Ultem®, and Matrimid® with different porosity were used as support layer for fabrication of hollow fiber composite membranes. The performance of the membranes varied with different hollow fiber substrates was investigated. Pure gas permeance of the hollow fiber was tested to investigate the pore size of all fibers. The effect of support layer on the mass transfer in hydrophobic PV composite membrane was investigated. The results show that proper porosity and pore diameter of the support are demanded to minimize the Knudsen effect. Based on the result, ZIF-8 was introduced to prepare more selective separation layer, in order to improve the PV performance. The PDMS/ZIF-8/Torlon® membrane had a separation factor of 8.9 and a total flux of 847 g·m^-2·h^-1. This hollow fiber PDMS/ZIF-8/Torlon® composite membrane has a great potential in the industrial application.     

聚偏氟乙烯-聚酰胺管式复合膜的分离性能研究

以聚偏氟乙烯(PVDF)管式超滤膜为基膜,无水哌嗪(PIP)为水相单体,均苯三甲基酰氯(TMC)为有机相单体,采用界面聚合法制备了不同截留性能的PVDF/聚酰胺(PA)管式复合膜.研究了不同性能管式复合膜的截留分子量、膜表面荷电性测试、对无机盐的截留性能,以及染料废水脱盐的应用.实验结果表明,截留率R(MgSO4)由9...     

硅橡胶膜用于植物油/己烷胶团中溶剂回收的研究

Traditional solvent recovery in the extraction step of edible oil processing is distillation, which consumes large amounts of energy. If the distillation is replaced by membrane process, the energy consumption can be reduced greatly. In this work, two kinds of membrane, PDMS (polydimethylsiloxane) composite membrane and Zeolite filled PDMS membrane were prepared, in which asymmetric microporous PVDF (polyvinylidenefluoride) membrane prepared with phase inversion method was functioned as the microporous supporting layer in the flat-plate composite membrane. The different function compositions of the PDMS/PVDF com-posite membranes were characterized by reflection Fourier transform infrared (FTIR) spectroscopy. The surface and section of PDMS/PVDF composite membranes were investigated by scanning electron microscope (SEM). The PDMS NF (nanofiltration) membranes were then applied in the recovery of hexane from soybean oil/hexane miscellas (1︰3, mass ratio). The effects of pres-sure (0.5-1.5 MPa), cross-linking temperature and PDMS layer thickness on membrane performances were investigated. The results indicated that both two kinds of NF membranes were promising for solvent recovery, and zeolite filled in PDMS NF membrane could enhance the separation performance.     

Preparation and properties of hollow fibre nanofiltration membrane with continuous coffee-ring structure

Polyamide(PA)hollow fibre composite nanofiltration(NF)membranes with a coffee-ring structure and beneficial properties were prepared by adding graphene oxide(GO)into the interfacial polymerization process.The presentation of the coffee-ring structure was attributed to the heterogeneous,finely dispersed multiphase reaction system and the“coffee-stain”effect of the GO solution.When the piperazine concentration was 0.4 wt-%,the trimesoyl chloride concentration was 0.3 wt-%,and the GO concentration was 0.025 wt-%,the prepared NF membranes showed the best separation properties.The permeate flux was 76 L·m^?2·h^?1,and the rejection rate for MgSO4 was 98.6%at 0.4 MPa.Scanning electron microscopy,atomic force microscopy,and attenuated total reflectance-Fourier transform infrared spectroscopy were used to characterize the chemical structure and morphology of the PA/GO NF membrane.The results showed that GO was successfully entrapped into the PA functional layer.Under neutral operating conditions,the PA/GO membrane showed typical negatively charged NF membrane separation characteristics,and the rejection rate decreased in the order of Na2SO₄>MgSO₄>MgCl₂>NaCl.The PA/GO NF membrane showed better antifouling performance than the PA membrane.     

Preparation of graphene oxide/polyamide composite nanofiltration membranes for enhancing stability and separation efficiency

Polyamide (PA) NF membranes are synthesized on a hollow fiber support by the interfacial polymerization (IP) of piperazine (PIP) and trimesoyl chloride (TMC). Then, GO is coated on the PA layer to decorate the NF membrane surface (denoted GO/PA-NF). This strategy aims to improve the hydrophilicity, chlorine resistance and separation stability of the membrane. The optimization, chemical composition, morphology, and hydrophilicity of the synthesized GO/PA-NF membrane are characterized. Results indicate that the optimized GO/PA-NF in terms of rejection rate and flux are with 0.05 wt% GO. The rejection of GO/PA-NF for Na2SO₄ and MgSO₄ is 99.4% and 96.9%, respectively. Even if the GO/PA-NF is immersed in 1000 ppm NaClO solution for 48 h, the NF membrane still maintains stable salt rejection. The developed NF membranes exhibit excellent treatment performance on dying wastewater. The permeate flux and rejection of GO/PA-NF toward Congo red solution are determined to be 44.2 L/m²h and 100%, respectively. Compared with the PA membrane, GO/PA-NF presents a higher rejection for Na₂SO₄ (99.4%) and a lower rejection for NaCl (less than 20%), which shows that the NF membranes have a better divalent/monovalent salt separation performance. This study highlights the superior performance of GO/PA-NF and shows its high potential for application in wastewater treatment.     

纳米粒子/氧化石墨烯改性复合膜制备及其分离性能研究

采用真空抽滤-压力喷涂的方法，以聚酰胺纳滤膜为基膜，制备了氧化石墨烯和二氧化钛纳米粒子质量比为1∶1、2∶1、3∶1和4∶1的复合膜GOT1、GOT2、GOT3和GOT4以及氧化石墨烯和二氧化硅纳米粒子质量比为1∶1、2∶1、3∶1和4∶1的复合膜GOS1、GOS2、GOS3和GOS4。通过SEM、EDS、XPS和GIWAXS方法对GOT复合膜和GOS复合膜进行了分析表征，结果表明，氧化石墨烯和纳米粒子均匀负载在聚酰胺纳滤膜表面。研究了复合膜的性能，并推测了复合膜的净水机理。其中GOT复合膜在0.75 MPa下水通量可达50 L·m^-2·h^-1,相较于原始基膜提高了25%,显示出了最佳的水通量性能，并且在保持较高通量的同时，对盐溶液和重金属离子的截留率仍能维持在90%左右。真空抽滤-压力喷涂的方法为氧化石墨烯复合膜的制备提供一种新的工艺思路，为废水处理提供了一种更高净化效率的复合膜。     

N2优先渗透ZIF-8复合膜的制备及其CO2捕集

为了获得经济节能的烟道气CO₂回收方法,制备了一种新型的N₂优先渗透ZIF-8复合膜。以柔性聚砜(PSf)多孔膜为支撑层,采用Zn²⁺与壳聚糖的交联溶液对聚砜支撑层表面改性,使Zn²⁺固定在PSf膜表面;然后与2-甲基咪唑(Hmim)配位得到ZIF-8晶种层;最后通过界面聚合法二次生长制得ZIF-8复合膜。采用FTIR、XRD及SEM对ZIF-8复合膜的形貌结构进行表征,结果显示成功制备了致密的ZIF-8复合膜。在进料气为纯气条件下,探究了二次生长时间、Zn²⁺溶液的浓度、测试时间及测试压力对ZIF-8复合膜N₂/CO₂分离性能的影响,阐明其N₂优先渗透机理;并进一步考察了混合气分离性能。结果表明：在25℃和0.1 MPa下,最优ZIF-8复合膜的N₂渗透性为523 GPU,N₂/CO₂选择性为19;同条件下混合气的N₂渗透性和N₂/CO₂选择性分别为517 GPU和18。所制备的ZIF-8复合膜可以使N₂优先渗透,实现烟道气中高浓度N₂渗透,低浓度CO₂截留在膜的上游侧。原因主要是ZIF-8复合膜含有较多的CO₂强吸附位点,使CO₂被吸附在膜内不易从膜的下游侧脱附,渗透性小,而N₂优先渗透,这为N₂优先渗透膜的制备提供了一种新思路。