基于PTFE矩形密封圈的高压容器密封结构设计

PTFE矩形密封圈具有耐化学性能好、截面稳定性高等优点,可以有效解决腐蚀性介质的密封问题。但在实际使用中,PTFE矩形密封圈及其适配沟槽的尺寸设计缺乏参考依据。针对上述问题,根据高压容器端面密封结构的形状与受力特征,在Ansys Workbench中建立PTFE矩形密封圈的二维轴对称模型,采用双线性等向强化模型表征PTFE的力学性能,对基于PTFE矩形密封圈的高压容器端面密封结构进行分析和设计,讨论压缩率、PTFE矩形密封圈几何参数和沟槽结构参数对高压容器端面密封性能的影响。结果表明,压缩率、矩形圈的高度和宽度以及矩形圈与沟槽侧壁的间隙对密封性能的影响较大,而内径对密封性能的影响较小,因而设计时应优先考虑沟槽深度、矩形圈的截面尺寸以及与沟槽的装配位置等参数。确定PTFE矩形密封圈及适配沟槽的尺寸后,采用有限元仿真手段验证了设计的密封结构在常温30 MPa高压下的密封性能,证实了设计的合理性。

芳纶纱的结构形貌对芳纶/PTFE织物复合材料摩擦学性能的影响

为了研究纱线结构形貌对织物复合材料摩擦学性能的影响,选用对位芳纶纤维,制备成3种具有不同结构形貌的芳纶纱,分别为长丝平行纱、长丝加捻纱和短纤维加捻纱。以相同的制备工艺得到3种芳纶/PTFE织物复合材料,采用多试件摩擦磨损试验机测试复合材料的摩擦学性能,并对芳纶/PTFE混编织物及相应复合材料的结构形貌、力学性能和磨损表面进行分析与探讨。实验结果表明:芳纶纱的结构形貌可直接影响纱线的断裂强度、纱线拔出强力、纱线与树脂的界面结合力,进而影响织物复合材料的摩擦学性能;在不同的磨损条件下3种混编织物的耐磨性表现有所不同,当载荷相对较低时,芳纶短纤维加捻纱/PTFE织物复合材料磨损率更低,而当载荷较高时,芳纶长丝加捻纱/PTFE织物复合材料耐磨性更好。

PTFE/Cu材料动态压缩特性

通过冷等静压和冷压烧结制备出六种不同密度的聚四氟乙烯(polytetrafluoroethylene,PTFE)/Cu复合材料,并采用霍普金森系统研究了密度和制备方法对PTFE/Cu动态力学性能影响。结果表明,冷压烧结试样在其烧结过程中发生纵向膨胀,导致密度降低,且试样表面生成一层金属膜;冷压烧结试样的动态压缩性能优于冷等静压试样;冷压烧结后的PTFE/Cu材料中PTFE晶体发育更好,对Cu颗粒包裹力更大,界面结合力更高,提升了冷压烧结PTFE/Cu材料的力学性能。

超声检测识别CFRP复合材料PTFE夹杂与富树脂缺陷

针对碳纤维增强复合材料(Carbon fiber reinforced polymer,CFRP)缺陷试样制作困难且不同夹杂缺陷难识别的问题,采用仿真与试验相结合的方法,开展聚四氟乙烯(PTFE)夹杂与富树脂缺陷超声检测研究。首先建立考虑CFRP层结构弹性各向异性的多向层合板超声反射法有限元模型,对比模拟与试验得到的A扫描时域信号,证明了模型的有效性。在CFRP层合板内部设置宽度6 mm,厚度0.03~0.40 mm的PTFE夹杂和厚度0.03~0.85 mm的富树脂缺陷,模拟得到超声A扫描信号,分析比较两种缺陷厚度变化对超声信号幅值最大值和波形峭度因子的影响。结果显示,随着缺陷厚度增加,PTFE夹杂及富树脂缺陷信号的幅值最大值和峭度因子均呈现先上升后下降最后趋于稳定的趋势,但富树脂缺陷信号幅值最大值低于PTFE夹杂,其峭度因子随厚度变化滞后于PTFE夹杂。

旋翼轴用Ni−Al_(2)O_(3)−PTFE复合镀层的制备与摩擦学性能

针对国内航空传动系统翻修间隔时间短的不足,以硬质颗粒Al_(2)O_(3)和润滑材料PTFE作为微粒,采用电刷镀技术在旋翼轴常用过渡层金属材料T2紫铜片表面,制备Ni−Al_(2)O_(3),Ni−PTFE,Ni−Al_(2)O_(3)−PTFE复合镀层,采用扫描电镜、显微硬度仪表征分析镀层微观形貌、元素含量分布及硬度;采用自制的销盘式摩擦磨损试验机对镀层试样进行摩擦磨损试验,探究镀层摩擦学性能及其磨损机理。结果表明:随Al_(2)O_(3)颗粒含量的提高,Ni−Al_(2)O_(3)−PTFE复合镀层表面微晶单元尺寸减小,硬度提高,Ni−Al_(2)O_(3)−PTFE(3∶1)显微硬度最大为236 HV,相比于Ni−PTFE复合镀层提升约66%;Ni−Al_(2)O_(3)−PTFE复合镀层结合了Al_(2)O_(3)和PTFE两者的优势,在具有减摩的同时,还具有良好的耐磨性能,Ni−Al_(2)O_(3)−PTFE(1∶1)复合镀层的减摩性能最优,相比于Ni−Al_(2)O_(3)其摩擦系数降低约52%;Ni−Al_(2)O_(3)−PTFE(3∶1)复合镀层的耐磨性能最优,相比于Ni−PTFE其磨损率降低约85%;Ni−Al_(2)O_(3)−PTFE复合镀层的磨损形式主要是机械磨损,存在轻微的氧化磨损和黏着磨损,复合镀层表面微凸体的塑性变形可为摩擦表面提供润滑膜,其中PTFE是自润滑颗粒,Al_(2)O_(3)颗粒起到支撑与强化的作用,保护镀层免受磨损。

Si_(3)N_(4)/PTFE复合材料转移膜形貌与磨损率定量分析

聚四氟乙烯(PTFE)基复合材料摩擦转移膜对其摩擦学性能有着决定性影响,转移膜形貌与磨损率定量关系对PTFE基复合材料的摩擦学性能优化有重要意义。文章对Si_(3)N_(4)/PTFE复合材料转移膜膜厚与覆盖率进行定量表征并建立两者与磨损率的函数关系。结果表明:转移膜最大厚度和覆盖率均与复合材料磨损率之间有较高的拟合度,最大厚度与覆盖率在转移膜不同形貌时对复合材料磨损率的影响起不同作用;转移膜最大厚度大于0.319μm时,其最大厚度的增加对提高复合材料磨损变化起主导作用;转移膜最大厚度小于0.319μm时,覆盖率的增加对降低复合材料的磨损起主导作用。

空爆条件下硼基燃料对Al/PTFE复合装药能量输出特性的影响

为研究空爆条件下硼基燃料对铝/聚四氟乙烯(Al/PTFE)活性材料与温压炸药组成的复合装药的能量输出特性的影响规律,设计并制备了质量相同、组分不同的3种复合装药试样,进行了自由场静爆试验,获取了不同爆心距处的冲击波超压,通过高速摄像仪记录了爆炸火球的演变过程。试验结果表明,Al/PTFE活性材料能够提高复合装药的冲击波超压,发生剧烈的后燃烧反应。硼基燃料分解过程具有2.0 ms左右的延迟,反应初期能量贡献较低,使得复合装药冲击波峰值超压降低;但是,后燃烧反应能够促进火球体积的进一步膨胀,降低冲击波超压的下降速率,提高冲击波冲量。适当配比的Al/PTFE和硼基燃料能够使复合装药冲击波峰值超压和冲量均获得增强。在Al/PTFE中加入硼基燃料,发生了爆燃以上反应,冲击波超压出现了明显的二次峰值,约为0.478 MPa。

乳液自组装法制备Al/B/PTFE含能微球及其性能表征

为了探究高活性金属含能微球的制备工艺以及燃烧性能,以Viton为黏结剂,聚四氟乙烯(PTFE)、硼粉(B)和铝粉(Al)为高能组分,采用乳液自组装技术制备了Al/B/PTFE含能微球,并对溶剂的挥发温度、乳化剂的种类、水相和油相的体积比和搅拌速度等工艺进行了优化;采用扫描电子显微镜(SEM)对Al/B/PTFE含能微球形貌进行了表征;采用TG-DSC法分析了Al/B/PTFE含能微球的热分解性能;通过高速摄影和密闭爆发器表征了Al/B/PTFE含能微球的燃烧反应性能。结果表面,水浴温度为25℃、乳化剂为PVA、水油比为80∶30和搅拌速度为700 r/min是Al/B/PTFE含能微球的最佳制备工艺;所制备的Al/B/PTFE含能微球的粒径均匀、球形度高且粒径可控,主要粒径分布范围在约300~900μm;微球的流散性、反应热、燃烧火焰面积和压力输出性能随着粒径的增加,出现先增加后减弱的现象;Al/B/PTFE含能微球的最大反应热,最大火焰面积和最高峰值压力为1097.97 J/g,186.06 cm^(2)和213.3 kPa,分别是物理混合样品的1.77倍、5.16倍和1.37倍。

The Application of Polytetrafluoroethylene (PTFE) Fiber Grafted Acrylic Acid as a Cation Exchanger for Removing Cu^(12)

The polytetrafluoroethylene fiber grafted acrylic acid was used as a cation exchanger. The exchange capacity of the cation fiber is 3.06 mmol/g. The maximum Cu2+ adsorption capacity is 107.48 mg/g. It could be desorbed completely by 1mol/L HCl.

原位成纤PTFE对PP/CNT微孔注塑发泡材料电磁屏蔽性能的影响

采用聚丙烯(PP)为基体、以多壁碳纳米管(CNT)为碳纳米填料,制备二元复合泡孔材料PP/CNT,并且,当CNT含量为1%时,复合微孔材料泡孔质量及电磁屏蔽性能均较好。以聚四氟乙烯(PTFE)为原位成纤增强相,进行微孔注塑发泡成型,探究PP/CNT/PTFE三元复合微孔材料的电磁屏蔽性能,制备了力学性能较好、对电磁辐射吸收率较高的微发泡电磁屏蔽复合材料;研究了PTFE微纤含量对PP/CNT/PTFE三元复合微孔材料注塑发泡泡孔形貌及电磁屏蔽性能的影响规律;得到了该实验条件下PTFE的最佳添加量。结果表明,当PTFE含量为1%时,原位成纤效果较好,三元复合微孔材料的泡孔直径显著减小,电磁屏蔽性能从未添加PTFE时的12.6 dB提高至24.8 dB。

Effect of polytetrafluoroethylene hollow fiber microstructure on formaldehyde carbonylation performance in membrane contactor

Membrane contactor is regarded as a promising method for reaction and process intensification. The feasibility of formaldehyde carbonylation to synthesize glycolic acid using polytetrafluoroethylene(PTFE)membrane contactor has been proved in our previous study. In this paper, the effect of membrane microstructure on process performance was further investigated. Three porous PTFE hollow fibers with different pore sizes and one polydimethylsiloxane(PDMS)/PTFE composite membrane with dense layer were fabricated for comparison. The physical and chemical properties of four membranes, including chemical composition, morphology, contact angle, liquid entry pressure, thermodynamic analysis and gas permeability, were systemically characterized. Experiments of formaldehyde carbonylation under different reaction conditions were conducted. The results indicated that the yield of glycolic acid increased with decreasing pore size for porous membranes, which was due to the improvement of wetting behavior. The dense layer of PDMS in composite hollow fiber could effectively prevent the solvent from entering membrane pores, thus the membrane exhibited the best performance. At reaction temperature of 120℃ and operation pressure of 3.0 MPa, the yield of glycolic acid was always higher than 90% as the mass ratio of trioxane and phosphotungstic acid increased from 0.2:1 to 0.8:1. The highest turnover frequency was up to 26.37 mol·g^(-1)·h^(-1). This study provided a reference for the understanding and optimization of membrane contactors for the synthesis of glycolic acid using solvent with low surface tension.

Enhancing surface adhesion of polytetrafluoroethylene induced by two-step in-situ treatment with radiofrequency capacitively coupled Ar/Ar+CH_(4)+NH_(3) plasma

Although some progress in plasma modification of the polytetrafluoroethylene(PTFE) surface has been made recently,its adhesion strength still needs to be further improved.In this work,the surface of a PTFE sample was treated with a two-step in-situ method.Firstly,the PTFE surface was treated with capacitively coupled Ar plasma to improve its mechanical interlocking performance;then,Ar+NH_(3)+CH_(4) plasma was used to deposit an a-CNx:H cross-linking layer on the PTFE surface to improve the molecular bonding ability.After treatment,a high specific surface area of 2.20 and a low F/C ratio of 0.32 were achieved on the PTFE surface.Its surface free energy was increased significantly and its maximum adhesion strength reached77.1 N·10 mm^(-1),which is 56% higher than that of the single-step Ar plasma-treated sample and32% higher than that of the single-step Ar+CH_(4)+NH_(3) plasma-treated sample.

微纳结构对混凝土PTFE超疏水涂层性能影响研究

为了探究微纳米粗糙结构对水泥混凝土基聚四氟乙烯(PTFE)超疏水涂层性能的影响。研究考虑了混凝土表面的粗糙结构及微米级金刚石、碳化硅、刚玉粉末与纳米级疏水二氧化硅粉末构筑的微纳米粗糙结构。利用接触角测量仪和扫描电子电镜(SEM)对各种粗糙结构下PTFE涂层的湿润性和微观形貌进行了表征。同时,还评价了涂层抗滑性和耐磨耗性。结果表明:两步法制备工艺,先构筑微纳米粗糙结构再修饰PTFE涂层,能获得最强超疏水性能。微米级与纳米级粉末复配使用效果最佳,且随用量增加而增强,推荐比例1∶1,粒径比控制在60~120倍间为宜。不同粗糙结构中,金刚石效果最佳,其次是碳化硅和刚玉,混凝土凿毛处理后其抗滑性均满足规范要求,采用湿轮磨耗仪在试件表面往复摩擦1 000次后也均可保持85%以上的疏水性。该研究深入揭示了微纳米粗糙结构对涂层性能的影响机制,可指导实用型高性能PTFE超疏水涂层的制备。

Energy reduction of a submerged membrane bioreactor using a polytetrafluoroethylene （PTFE） hollow-fiber membrane

在这研究，我们修改了空纤维的膜元素过去常让沉没的膜生物反应器(MBR ) 在 MBR 过程期间减少精力消费的 polytetrafluoroethylene (PTFE ) 。PTFE 膜的高机械的力量使从 2 ～ 3 m 增加膜纤维的有效长度可能。另外，收拾行李的密度被优化膜元素配置被 20% 增加。这些修正改进膜清洗的效率与通风联系了。特定的精力消费的目标是不到 0.4 kWh ?楤晳癡 吗？

Effect of Addition of Polytetrafluoroethylene (PTFE) and Silicon Carbide (SiC) on Properties of Electroless Nickel Alloy Coatings

Electroless nickel (copper)-phosphorus-silicon carbide (SiC)-polytetrafluoroethylene (PTFE) composite coatings were prepared by adding SiC and PTFE into electroless nickel (copper)-phosphorus alloy baths. The effects of addition of SiC and PTFE on depositing rate, microhardness, wear resistance and anti-friction of the resulted composite coatings were studied. The results indicated that electroless nickel (copper)-phosphorus alloy coatings were greatly improved in depositing rate, microhardness, wear resistance and antifriction by co-deposited proper amount of SiC and PTFE.

部分碳化PTFE/PVDF中空纤维膜的制备及油水分离性能研究

聚四氟乙烯(PTFE)是一种强疏水的氟碳材料,很难用相转化成膜。本文将PTFE粉体分散在聚偏氟乙烯(PVDF)溶液中得到PTFE悬浮液,首先用干湿相转化法制得PTFE/PVDF中空纤维膜胚;然后在氮气气氛下进行部分碳化,制得部分碳化PTFE/PVDF中空纤维膜.用热重分析法、X射线光电子能谱(XPS)和扫描电镜研究了PTFE/PVDF中空纤维膜胚的碳化工艺、膜碳化前后表面元素和微观结构变化情况;最后测试了膜的亲疏水变化和油水分离性能.结果表明:PTFE/PVDF中空纤维膜胚中的PVDF在360~450℃时发生C-H断裂,PTFE保持原结构,可以得到部分碳化PTFE/PVDF中空纤维膜.经部分碳化工艺制得的中空纤维膜孔径减小,形成连续、完整的微孔结构.当PTFE含量为40%时,碳化后制得的膜接触角达到102°,疏水性提高;对10%的模拟含油废水的渗透通量达到30 L/(m^(2)·h)(跨膜压差:0.1 MPa)、分离效率达到80%,呈现出较好的油水分离性能和商业应用价值.

PTFE中空纤维膜蒸馏高盐废水浓缩实验研究

文章选择工业生产中常见的含氯化钠(NaCl)高盐废水,以疏水性PTFE中空纤维膜组件为载体,采用真空膜蒸馏的方式进行浓缩处理实验研究,研究各操作条件对膜通量和截盐率的影响,并验证实验可行性。实验结果表明,膜下游侧压力增加,膜通量会逐渐降低;废水料液流量和料液温度的增加均有助于提高膜通量;废水料液浓度的增加,会抑制传质过程,降低膜通量。各操作条件对膜截盐率的影响很小,膜截盐率一直保持在99.8%以上,说明PTFE中空纤维膜蒸馏用于高盐废水浓缩具备可行性。

Efficient and stable PtFe alloy catalyst for electrocatalytic methanol oxidation with high resistance to CO

Direct methanol fuel cells(DMFC) are widely considered to be an ideal green energy conversion device but their widespread applications are limited by the high price of the Pt-based catalysts and the instability in terms of surface CO toxicity in long-term operation.Herein,the PtFe alloy nanoparticles(NPs) with small particle size(~4.12 nm) supported on carbon black catalysts with different Pt/Fe atomic ratios(Pt_(1)Fe_(2)/C,Pt_(3)Fe_(4)/C,Pt_(1)Fe_(1)/C,and Pt_(2)Fe_(1)/C) are successfully prepared for enhanced anti-CO poisoning during methanol oxidation reaction(MOR).The optimal atomic ratio of Pt/Fe for the MOR is 1:2,and the mass activity of Pt_(1)Fe_(2)/C(5.40 A mg_(Pt)^(-1)) is 13.5 times higher than that of conventional commercial Pt/C(Pt/C-JM)(0.40 A mg_(Pt)^(-1)).The introduction of Fe into the Pt lattice forms the PtFe alloy phase,and the electron density of Pt is reduced after forming the PtFe alloy.In-situ Fourier transform infrared results indicate that the addition of oxyphilic metal Fe has reduced the adsorption of reactant molecules on Pt during the MOR.The doping of Fe atoms helps to desorb toxic intermediates and regenerate Pt active sites,promoting the cleavage of C-O bonds with good selectivity of CO_(2)(58.1%).Moreover,the Pt_(1)Fe_(2)/C catalyst exhibits higher CO tolerance,methanol electrooxidation activity,and long-term stability than other Pt_(x)Fe_(y)/C catalysts.

前沿科研成果融入化工环境保护实验教学——表面疏油改性提高PTFE膜抗污染性能

设计了一个制备疏油聚四氟乙烯(PTFE)膜,以提高其在油水分离中抗污染性能的本科生实验。首先,通过等离子体接处理调控PTFE膜疏油性能,分别表征膜材料表面对水的粘附力、膜表面油接触角,随后考察膜材料分离油水乳液性能,最后通过金相显微镜表征膜表面污染情况。本实验提供了一种新颖的膜改性及分离技术用于废水治理的思路。通过实验操作,学生可以深入了解疏油膜在环境治理中的重要应用,并了解其在化工领域中的潜在价值,使学生进一步了解环境治理前沿技术,激发学生想象力和创造力。

碳布负载PTFE/碳黑复合电极还原氧气产过氧化氢

以导电碳布为基体,负载PTFE/碳黑涂层制备复合电极。考察了碳黑类型、碳黑添加量对碳布负载PTFE/碳黑复合电极产H_(2)O_(2)性能的影响,同时考察了电极的重复使用稳定性。结果表明:在粘结剂PTFE浓度为20%、电流密度为10 mA/cm^(2)、氧气流量为200 mL/min、乙炔黑添加量为0.035 g时制备的复合电极产H_(2)O_(2)性能最佳,180 min内H_(2)O_(2)最高产量达到25.2 mg(/L·cm^(2)),比未添加乙炔黑的电极提高了31.3%。复合电极180 min内产H_(2)O_(2)的电流效率为47.2%,能耗为15.7 kW·h(每kg H_(2)O_(2))。碳布负载PTFE/碳黑复合电极重复使用8次后H_(2)O_(2)最高产量仅下降了8.4%,体现出较好的重复使用稳定性。