Soft Template-Induced Porous Polyvinylidene Fluoride Membrane for Vanadium Flow Batteries

Vanadium flow batteries(VFBs)are considered ideal for grid-sc ale,long-duration energy storage applications owing to their decoupled output power and storage capacity,high safety,efficiency,and long cycle life.However,the widespread adoption of VFB s is hindered by the use of expensive Nafion membranes.Herein,we report a soft template-induced method to develop a porous polyvinylidene fluoride(PVDF)membrane for VFB applications.By incorporating water-soluble and flexible polyethylene glycol(PEG 400)as a soft template,we induced the aggregation of hydrophilic sulfonated poly(ether ether ketone),resulting in phase separation from the hydrophobic PVDF polymer during membrane formation.This process led to the creation of a porous PVDF membrane with controllable morphologies determined by the polyethylene glycol content in the cast solution.The optimized porous PVDF membrane enabled a stable VFB performance for 200 cycles at a current density of 80 mA/cm^(2),and the VFB exhibited a Coulombic efficiency of 95.2%and a voltage efficiency of 87.8%.These findings provide valuable insights for the development of highly stable membranes for VFB applications.

Preparation and Characterization of the Modified Polyvinylidene Fluoride (PVDF) Hollow Fibre Microfiltration Membrane

A novel thermally induced graft polymerization technique was used to modify a polyvinylidene fluoride （PVDF） hollow fibre microfiltration membrane. An artificial neural network （ANN） was applied to optimize the prepared condition of the membrane. The optimized dosing of acrylic acid （AA）, acrylamide （AM）, N, N＇- methylenebisacrylamide （NMBA） and potassium persulphate （KSP） designed by ANN was that AA was 40.63 ml/L; AM acted as 6.25 g/L; NMBA was 1.72 g/L and KSP was 1.5 g/L, respectively. The thermal stability of the PVDF modified hollow fibre membrane （PVDF-PAA） was investigated by thermogravimetric （TG） and differential scanning calorimetry （DSC） analysis. The polycrystallinity of the PVDF-PAA membrane was evaluated by X-ray diffraction （XRD） analysis. The complex formation of the modified membrane was ascertained by Fourier transform infrared spectroscopy （FTIR）. The morphology of the PVDF-PAA membrane was studied by environmental scanning electron microscopy （ESEM）. The surface compositions of the membrane were analyzed by X-ray photoelectron spectroscopy （XPS）. The adsorption capacity of Cu^2＋ ion on the PVDF-PAA hollow fibre membrane was also investigated.

Preparation and Properties of Electrospun Polyvinylidene Fluoride (PVDF)/Polyurethane (PU) Composite Nanofiber Membranes

Polyvinylidene fluoride(PVDF)/polyurethane(PU)composite nanofiber membranes were prepared by mixing PVDF and PU at different mass ratios.The microstructure and the crystal structure of the composite nanofiber membranes were analyzed by scanning electron microscopy(SEM),Fourier transform infrared(FTIR)spectroscopy and X-ray diffraction(XRD).The hydrophilicity,mechanical properties and piezoelectric properties were also tested.Results showed that when the mass ratio of PVDF to PU was 9∶1,the fiber membrane had the best microstructure,and the crystal form of PVDF changed fromαcrystal toβcrystal in the electrospinning.The addition of PU improved the hydrophilicity,mechanical properties,and piezoelectric signal of the fiber membrane.When the mass ratio of PVDF to PU was 9∶1,the tensile strength reached the peak value of(10.39±0.41)N,and the output voltage reached the maximum value of(1.98±0.12)V.

PVDF/PVA共混膜的制备及其在去除污水COD中的应用

以聚乙烯醇(PVA)、聚偏氟乙烯(PVDF)为原料,聚乙烯吡咯烷酮为溶剂,制备了PVDF/PVA共混膜。将该膜应用于膜生物反应器处理污水,测试化学需氧量(COD)去除率和膜的使用性能。结果表明:膜的水通量随PVA加入量的增加而逐渐增加,在牵伸比为1.7时,膜的水通量达到最大值;平板膜用清水清洗后,膜的水通量恢复率较高,膜的运行周期经第一次清洗后下降了18 h,经第二次和第三次清洗后,膜的运行周期基本稳定在6~8 h,COD去除率高于90%,表明该膜具有良好的使用性能。

PVDF纳米纤维膜对工业除尘滤料的性能强化

为了利用聚偏氟乙烯(PVDF)纤维膜的细直径和热/压电性提升过滤效率,用静电纺丝方法制备了PVDF纤维膜,通过SEM和XRD表征了PVDF纤维膜形貌和β晶相转化,并将PVDF纤维膜附着在PPS滤料上制备成PPS/PVDF复合滤料,对其过滤效率及压差特性进行了评估.结果表明:PVDF纤维膜无串珠结构,纤维直径分布在270~780 nm,中值427.3 nm,晶型结构以β晶相为主.随着风速升高,PPS/PVDF纤维膜复合滤料过滤效率下降更小,证明PVDF纤维膜的压电效应对微细粒子过滤效率有改善作用.随着温度的提高,PVDF纤维膜呈现热电性,复合滤料的过滤效率上升,当温度升高到70℃,其对小粒径0.3μm粒子过滤效率提升幅度最大为28.37%.

蒸汽诱导相分离法制备PVDF多孔膜及其膜蒸馏性能研究

制备具有优异抗润湿性能的膜蒸馏(MD)用膜是膜分离领域的一个挑战.本文以聚偏氟乙烯(PVDF)为膜材料,N,N-二甲基甲酰胺(DMF)为溶剂,1,2-丙二醇为添加剂,采用蒸汽诱导相分离法(VIPS)制备了高疏水性PVDF多孔膜.考察了暴露时间、相对湿度以及蒸汽温度等工艺参数对PVDF多孔膜结构与性能的影响.结果表明,当暴露时间为1 min,相对湿度为85%,蒸汽温度为60℃时,PVDF多孔膜表面呈现出微/纳米分级结构,静态水接触角为141°,孔隙率约为78%.在使用含有表面活性剂的盐溶液作为进料液的DCMD实验中,所制备的PVDF疏水膜表现出20 L/(m^(2)·h)的稳定水通量和接近100%的盐截留率.

AlB_(2)@PVDF壳核结构制备及其在点火药中的应用

为改善含硼(B)含能体系的能量释放,采用NaOH水溶液对原料AlB_(2)进行刻蚀,并采用PVDF对刻蚀AlB_(2)进行包覆,得到了AlB_(2)@PVDF壳核结构材料,并对其形貌和热行为进行了表征和测试;以KNO_(3)为氧化剂,分别以单质B、原料AlB_(2)、AlB_(2)@PVDF为可燃剂,制备了3种配方的点火药,并对其燃烧性能进行了对比研究。结果表明:刻蚀后AlB2的XRD谱图出现B基特征衍射峰;AlB_(2)@PVDF材料中PVDF以丝状和团状形态附着和悬挂在刻蚀AlB2的表面和沟壑内部;AlB_(2)@PVDF的实测燃烧热值为25.5 kJ·g^(-1),相比单质B提高了56.4%;与基于单质B的点火药相比,基于AlB_(2)@PVDF的点火药的燃烧火焰更稳定且燃烧更剧烈,其燃烧时间缩短了28.1%,平均燃烧温度提升了31.2%,最高燃烧温度提高了172.49℃。

Effect of Packaging Material on Piezoelectric Response of Sensor with Electrospinning Polyvinylidene Fluoride (PVDF) Nanofiber Web

The polyvinylidene fluoride(PVDF)nanofiber web by electrospinning technology has the characteristics of fast response,high sensitivity,wide range of pressure,etc.,and provides new sensitive materials for the sensor testing the dynamic pressure such as foot pressure during walking.Because of the nanofiber mesh structure,it must be packaged to collect piezoelectric charge and bear strong mechanical behavior before industrial practice.The PVDF nanofiber web is usually packaged by incorporating a pair of flexible electrode as well as the lead of signal output.This present work will introduce the detailed packaging process and technology of PVDF nanofiber web,and three different types of packaging electrode materials(adhesive copper foil tape,indium tin oxide(ITO)thin plate,and adhesive conductive cloth)in previously published literatures are compared by the piezoelectric response of their sensor prototypes to a periodic mechanical activation.The results showed that the surface property of packaging material had a significant effect on the piezoelectric response of sensor by PVDF nanofiber web.For PVDF nanofiber web sensor,therefore,it needed a deep investigation on the specific packaging technology in terms of different working conditions.

微波辅助Al@PVDF⁃OH复合燃料的制备及其燃烧性能

聚偏氟乙烯(PVDF)等氟聚物可有效抑制铝粉的团聚并提高铝粉的反应活性。但氟聚物与被氧化铝覆盖的Al颗粒表面之间亲和性较差,氟聚物直接包覆在Al表面对团聚的抑制效果并不理想。为增强氟聚物与铝粉间的相互作用,改善铝粉燃烧性能,研究采用微波辅助反应的方法得到了羟基化改性的PVDF-OH,利用溶剂/非溶剂法将PVDF-OH包覆在铝粉表面得到了Al@PVDF-OH复合燃料,并进一步制备了复合固体推进剂。采用红外光谱、X射线衍射仪对PVDF-OH的分子结构与元素组成进行了研究;采用扫描电子显微镜、差示扫描量热仪、高速摄像机和氧弹量热仪等设备对Al@PVDF-OH复合燃料的微观结构组成及其燃烧性能进行了研究。结果表明,微波辅助制备得到的PVDF-OH有着较高的羟基含量,微波功率240 W下处理1 min时制备得到的PVDF-OH最佳。Al@PVDF-OH复合燃料的燃烧性能优于包覆PVDF的Al@PVDF复合燃料与加热改性处理PVDF-OH(H)的Al@PVDF-OH(H)复合燃料,在PVDF-OH含量为15%时最佳。与纯Al相比,PVDF-OH含量为15%的Al@PVDF-OH复合燃料的燃烧热值由19140 kJ·kg^(-1)增加到24912 kJ·kg^(-1);与AP混合后的燃烧测试结果表明,Al@PVDF-OH复合燃料燃烧性能相较于Al有明显改善,点火延迟时间由77 ms缩短至70 ms,燃速由195.7 mm·s^(-1)提高到225.7 mm·s^(-1)。基于Al@PVDF-OH复合燃料的固体推进剂与铝基固体推进剂相比,其燃烧热值由13281 kJ·kg^(-1)增加到14020 kJ·kg^(-1);燃速由1.281 mm·s^(-1)提高到1.915 mm·s^(-1),凝聚相燃烧产物D90由74.324μm降至52.749μm。

聚苯乙烯马来酸酐对PVDF膜结构和性能的影响

聚偏氟乙烯(PVDF)膜易受化学污染,常需要进行表面改性。然而,PVDF作为一种化学惰性高分子聚合物,很难直接进行化学改性。为解决该问题,本文将聚苯乙烯马来酸酐共聚物(SMA)与PVDF共混,采用非溶剂致相转化法(NIPS)制备具有丰富酸酐活性基团的PVDF/SMA共混膜,考察了PVDF和SMA聚合物相容性,探究了铸膜液中PVDF含量、SMA含量以及凝固浴温度等参数对PVDF/SMA共混膜表面结构、孔结构、纯水通量、BSA截留、润湿性等的影响。结果表明:SMA与PVDF为部分相容体系,当SMA含量低于60%时,二者具有良好相容性;水为凝固浴可制备PVDF/SMA共混膜,随着凝固浴温度升高,PVDF/SMA共混膜纯水通量上升,BSA截留率下降;随铸膜液中PVDF聚合物含量增加,膜表面亲水性下降,导致其纯水通量显著降低;铸膜液中添加剂SMA含量对膜结构和性能等均有显著影响,随着SMA含量增加,膜表面开孔率提高,平均孔径和孔隙率均上升,亲水性增强,水通量增大,与未加SMA的PVDF膜相比,通量提升了38倍。

CdS/ZnS-PVDF/PSF光催化膜的制备及其刚果红降解性能研究

光催化膜分离耦合技术处理废水是水处理研究方向之一,它是将膜分离技术与光催化技术结合,有效地解决了催化剂回收难的问题,同时也缓解了膜污染问题。利用水热法制备了CdS和CdS/ZnS光催化剂,用相转化法分别制备出聚偏氟乙烯/聚砜(PVDF/PSF)膜,以及CdS和CdS/ZnS光催化剂嵌入其中的CdS-PVDF/PSF光催化膜和CdS/ZnS-PVDF/PSF光催化膜。将刚果红溶液作为污染物,氙灯作为光源,分别对这3种膜的膜通量、截留率和刚果红降解率进行测试比较和分析。结果表明:反应进行360 min后,CdS/ZnS-PVDF/PSF光催化膜的膜通量能够达到63.0 L·h^(-1)·m^(2),相比PVDF/PSF膜(36.0L·h^(-1)·m^(2))和CdS-PVDF/PSF光催化膜(52.1L·h^(-1)·m^(2))的膜通量有显著增加,说明CdS/ZnS的负载有效缓解了PVDF/PSF膜的膜通量由于刚果红分子堵塞孔道引起的衰减。在膜通量增加的同时,CdS/ZnS-PVDF/PSF光催化膜的截留率在360min后依然保持在100%。CdS/ZnS-PVDF/PSF光催化膜对刚果红的降解率可以达到86.9%,分别比使用PVDF/PSF膜和CdS-PVDF/PSF光催化膜提高了18.1%和6.2%。CdS/ZnS-PVDF/PSF光催化膜能够获得最高的膜通量和降解率,因此用于降解废水中的有机污染物具有很好的应用前景。

“纳米沟壑”状PVDF多孔纳米纤维蛋白质吸附性能研究

以静电纺丝技术结合固相分离法,以PVDF为主体,分别以PEG、PVB为造孔剂制备出兼具疏水性能和优异蛋白质吸附性能的多孔PVDF-G、PVDF-B纳米纤维膜,结果显示当造孔剂为PVB时,即“纳米沟壑”状PVDF-B多孔纳米纤维膜的力学性能最高可达7.12 MPa,其纤维“纳米沟壑”状多孔结构分布均匀,且水接触角为119.3°,纤维膜整体对牛血清白蛋白吸附性能高达325μg/cm^(2)。基于本研究开发的“纳米沟壑”状蛋白质吸附纳米纤维材料,将为后续开发高性能蛋白质提纯材料提供一种新思路,该项研究有望拓展静电纺有机纳米纤维在生物医药、疾病诊断、免疫检测等领域的应用范畴。

PVDF膜接触器在电厂含氨废水处理中的应用研究

燃煤电厂含氨废水具有水量大、氨氮浓度高、水质波动大的特点,常规脱氨工艺处理困难.本文采用PVDF膜接触器处理燃煤电厂高浓含氨废水,考察了膜接触器类型、水侧流量、气侧真空度、气液接触面积、进水水质等因素对脱氮效率的影响.结果表明,基于PVDF膜接触器的气液分离工艺,能够将高浓含氨废水中的氨氮浓度由1 250 mg/L降至300 mg/L以下;外压式和内压式膜接触器都有理想的应用效果;提高膜接触器水侧流量、气侧真空度能够有效提高NH3传质效率;增大传质膜面积能够显著提升循环液氨氮脱除率.提出了分离NH3在燃煤电厂的多种资源化回用途径,为膜接触器的工程化应用提供参考.

低温热致相分离法制备PVDF-CTFE多孔膜的研究

利用低温热致相分离法制备了PVDF-CTFE多孔膜,重点考察了甘油含量和凝固浴温度对成膜机理和性能的影响.结果表明,甘油有促进热致相分离(TIPS)和非溶剂致相分离(NIPS)的双重作用.甘油含量的提高,一方面作为非溶剂使铸膜液浊点温度与凝固浴温度的温差变大,加强了TIPS效应,使膜结构呈TIPS效应为主的双连续结构,避免了NIPS效应所致典型的指状孔结构;另一方面作为NIPS的致孔剂,会加强NIPS效应,促使发生双扩散,生成更多孔结构,二者竞争共同作用.最终甘油含量的提高使TIPS效应占主导,NIPS所致的皮层结构变薄,膜断面结构从致密堆积状向多孔蜂窝状结构转变,提高了膜的通透性.当甘油添加量为7.5%(质量分数)时,PVDF-CTFE中空纤维多孔膜综合性能最佳,拉伸断裂强度达2.6 MPa,纯水通量达860 L/(m^(2)·h·MPa).凝固浴温度的提高,减少了铸膜液浊点温度与凝固浴的温差,减弱了TIPS效应,加强了NIPS效应的传质过程,使膜结构从蜂窝状结构向指状孔结构转变,皮层厚度增加,导致膜孔隙率和纯水通量提高,力学性能下降.当凝固浴温度为80℃时,PVDF-CTFE平板多孔膜的纯水通量为1510 L/(m^(2)·h·MPa),拉伸断裂强度为2.1 MPa.

MXene/PVDF复合膜的制备、性能调控及其应用研究进展

二维过渡金属碳(氮)化物(MXene)是一种新型二维碳化纳米材料,具有横向比率大、传输途径短和纳米通道多等独特优点。该文综述了MXene/聚偏氟乙烯(PVDF)膜的制备工艺,并分析了MXene与PVDF膜的电性能、机械性能、热性能、抗菌性能、环境稳定性等性能之间的调控关系;综述了MXene/PVDF复合膜在分离膜、高介电膜、电磁屏蔽膜等领域中的应用进展;最后,对MXene/PVDF膜的发展方向进行了展望:在当前研究阶段中,对PVDF膜进行抽滤处理仍是发挥MXene优异性能的有效途径之一;进一步深入研究MXene对PVDF膜定向调控的多功能性机制,有助于更好地理解MXene与PVDF膜之间的相互作用规律;此外,应该加强应用型研究,形成较完善的实际应用体系,有助于更好地理解MXene/PVDF复合膜的自身性质和性能,推动MXene/PVDF复合膜在各领域的应用研究和实际发展。

聚乙烯亚胺接枝/微球共混改性PVDF膜的制备及其性能研究

聚偏氟乙烯(PVDF)是一类性能优异的膜材料,但膜表面的疏水性易引发膜污染,阻碍了其在污水处理方面的实际应用。为了提高PVDF的表面亲水性,合成了3种不同粒径的共聚微球,将其与PVDF共混后再在膜表面接枝聚乙烯亚胺,制备了聚乙烯亚胺接枝/微球共混改性PVDF膜。对改性后的PVDF膜进行了FTIR、XPS、SEM、Zeta电位等分析测试,考察了该膜的油水分离性能、抗蛋白质污染性能及对染料的吸附、截留性能。结果表明改性膜具有亲水性和水下疏油性,对油水乳液的分离率在99%以上;具有抗蛋白质污染性,牛血清蛋白过滤后通量恢复率可达99.3%;能够吸附和截留阴离子染料,对刚果红染料的截留率在90%以上。

PREPARATION AND CHARACTERIZATION OF ION EXCHANGE MEMBRANES BASED ON POLYVINYLIDENE FLUORIDE

A new ion exchange membrane based on polyvinylidene fluoride (PVDF) and sulfonated poly(styrene-divinylbenzene) was prepared by in-situ polymerization. The incorporation of sulfonic groups into the polyvinylidene fluoride composite membrane was confirmed by infrared spectroscopy (IR), ion exchange capacity (IEC) and energy dispersive X-ray analysis (EDAX). Area resistance, IEC and water uptake of the treated membrane were evaluated. When 20% of the crosslinked membrane was sulfonated at 80degreesC for 22 h, the PVDF ion exchange membrane can attain 0.8 Omega . cm(2) area resistance in NaCl aqueous solution at 25degreesC, IEC is as high as 2.43 millimoles per grain of the wet membrane. The hydrophilicity of PVDF membrane is also significantly improved after treatment. When 60% of crosslinked membrane was sulfonated at 80degreesC for 6 h, water uptake of the treated membrane can attain 64.7%.

Effect of Polyvinylidene Fluoride Hollow Fiber Membranes on Mass Transfer of Samarium

The influence of swelling and stripping acidity on the mass transfer coefficient based on water phase and the inner diameters of membranes were studied with P507-HCl-Sm as working system in the two different kinds of hollow fiber membranes. Effects of extractant concentration, H+ concentration in aqueous phase and Sm3+ concentration on extraction rate were discussed and the corresponding reaction series were obtained. According to the investigations on the interfacial kinetics, the reaction kinetics equation and reaction rate constant were obtained.

基于PVDF仿生侧线传感器的偶极子源参数估计

基于生物学原理,采用性能较好的聚偏二氟乙烯(PVDF)压电材料设计并制作仿生侧线传感器。为了对水下偶极子源的振动幅度和空间位置进行估计,采用6个间距为2cm的PVDF仿生侧线传感器组成长为10cm的感知阵列,建立相应的实验平台。通过解析从各只传感器采集到的电压数据得到各处的实际流速,利用改进型粒子群优化算法进行多次迭代搜索最为匹配的偶极子源相关信息。实验结果表明:在一定范围内,通过此方法可对偶极子源各参数进行估计,且误差较小,结果稳定性强。

CFGO@PVDF复合纳滤膜的结构调控及截留性能

以聚偏氟乙烯(PVDF)和羧基化氧化石墨烯(CFGO)为原料,制备了高亲水性和高脱盐效能的CFGO@PVDF复合纳滤膜(GONF膜),通过优化制备条件,结合微观结构及形貌表征,获得了GONF膜的最佳制备条件,实现了复合纳滤膜性能的显著提升。结果表明,与传统PVDF纳滤膜(CNF膜)相比,CFGO@PVDF复合纳滤膜展现了更深的孔通道和显著提高的亲水性,其纯水通量可达13.1 L/(m^(2)·h·bar)(1 bar=100 kPa),是CNF膜的2.5倍以上。此外,GONF膜的晶型实现了由α相向β相转化,膜表面的含氧官能团含量增加,大幅提升了对2 g/L不同盐溶液的截留率,其中对Na_(2)SO_(4)和MgSO_(4)的截留率分别高达96%和95%以上,且60 min内未发生明显衰减。研究成功研制了一种高水通量、高效稳定脱盐的CFGO@PVDF复合纳滤膜,为纳滤膜的设计与制备提供了新的思路,也为解决全球水处理问题提供了有效的技术思路。