Cathodic activated stainless steel mesh as a highly active electrocatalyst for the oxygen evolution reaction with self-healing possibility

The oxygen evolution reaction(OER)represents one of the major bottlenecks for broad-based applications of many clean energy storage/conversion technologies.The key to solving this problem lies in developing high-performing,cost effective and stable catalysts for the OER.Herein,we demonstrate that ubiquitous stainless steel mesh(SSM)materials activated by a facile cathodization treatment can be employed as a high performing OER catalyst,as showcased by the impressively low overpotentials of 275 and 319 mV to reach the benchmark current densities of 10 and 100 mA cm^−2(1.0 M KOH),respectively.Cathodized SSM also exhibits excellent performance in a two-electrode water electrolyzer,which requires a low cell voltage of 1.58 at 10 mA cm^−2 and outperforms many of water electrolyzers using earth-abundant OER catalysts.Moreover,cathodized SSM with minor performance degradation after the stability test can also be readily healed by subjecting it to an additional cathodization treatment.It is disclosed that the superior performance of cathodized SSMs stems from the surface enrichment of OER active Ni(oxy)hydroxide,facile gas-bubble removal and transportation over the unique mesh-structured surfaces,while the abundant reservoir of nickel in the bulk allows healing of the catalyst by a facile cathodization.

Three-dimensional interconnected Ni（Fe）OxHy nanosheets on stainless steel mesh as a robust integrated oxygen evolution electrode

The development of an electrocatalyst based on abundant elements for the oxygen evolution reaction （OER） is important for water splitting associated with renewable energy sources. In this study, we develop an interconnected Ni（Fe）OxHy nanosheet array on a stainless steel mesh （SSNNi） as an integrated OER electrode, without using any polymer binder. Benefiting from the well- defined three-dimensional （3D） architecture with highly exposed surface area, intimate contact between the active species and conductive substrate improved electron and mass transport capacity, facilitated electrolyte penetration, and improved mechanical stability. The SSNNi electrode also has excellent OER performance, including low overpotential, a small Tafel slope, and long-term durability in the alkaline electrolyte, making it one of the most promising OER electrodes developed.

Fabrication of a superhydrophilic/underwater superoleophobic stainless steel mesh for oil/water separation with ultrahigh flux

Because of the increasing amount of oily wastewater produced each day,it is important to develop superhydrophilic/underwater superoleophobic oil/water separation membranes with ultrahigh flux and high separation efficiency.In this paper,a superhydrophilic/underwater superoleophobic N-isopropylacrylamide-coated stainless steel mesh was prepared through a simple and convenient graft polymerization approach.The obtained mesh was able to separate oil/water mixtures only by gravity.In addition,the mesh showed high-efficiency separation ability(99.2%)and ultrahigh flux(235239 L·m^(−2)·h^(−1)).Importantly,due to the complex cross-linked bilayer structure,the prepared mesh exhibited good recycling performance and chemical stability in highly saline,alkaline and acidic environments.

Preparation of stainless steel mesh-supported ZnO and graphene/ZnO nanorod arrays with high photocatalytic performance

A series of zinc oxide(ZnO)nanorods arrays with different morphologies are synthesized on stainless steel mesh via a facile electrodeposition method.The influences of electrodeposition parameters on the diameter,length,density and morphology of obtained ZnO nanorods are investigated systematically.The results indicate that the electrodeposition potential is the key factor for the morphology of the obtained ZnO nanorods,which further showed the effect on the photocatalytic property of the obtained samples.Meanwhile,the prepared ZnO nanorods array exhibits an excellent photocatalytic activity for methylene blue(MB)in ultraviolet light.The degradation efficiency for MB solution reaches 95.1%under the irradiation of ultraviolet light for 120 min.In addition,the photocatalytic property of the prepared ZnO nanorods can be extended to the visible light region after the modified with graphene oxide(GO).The obtained GO/ZnO composite also shows remarkable photocatalytic activity and photostability.The photodegradation efficiency for MB is 83.6%,and the catalytic performance retains 97.3% of its initial photocatalytic activity after five cycles.

Three dimensional numerical simulation of welding temperature fields in stainless steel

Three kinds of mathematical models representing welding heat sources are presented. Among them, Gaussian model and double ellipsoidal model are used to analyze the thermal distributions with finite element method. At the same time, this paper analyzed the influences of the heat source models, the latent heat and the welding parameters on the temperature distributions. The comparisons between the simulated results and the experiments show double ellipsoidal model is good for three-dimensional numerical simulations. Furthermore, the adaptive mesh technique is applied in the three-dimensional model which greatly reduces the number of nodes and elements in the simulation.

Composite Mesh Electrodes with Immobilized Bacteria for Bio-Batteries

An anode was constructed using a novel technique and subsequently tested in a bio-battery. The anode comprised of a composite electrode coated with immobilized bacteria. The immobilized bacteria used in this study were Escherichia coli K-12. The composite electrode contained three layers: a 304 L stainless steel mesh base, an electro-polymerized layer of pyrrole, and an electro-polymerized layer of methylene blue. The bacteria were immobilized utilizing a technique incorporating a carbon nanoparticle and TeflonTM emulsion. The composite electrode combined with immobilized bacteria was examined whilst incorporated into the anodic chamber of a bio-battery. Different tests were conducted, including Electrochemical Impedance Spectroscopy. Results from these tests were compared with data obtained from alternate configurations and values from the open literature. The maximum power density generated by the composite electrode with immobilized bacteria whilst incorporated into the anodic chamber of a bio-battery was 378 mW/m2. Results demonstrate this composite anode configuration with immobilized bacteria produced approximately 69% more power density and 53% more current density than alternate electrode configurations with bacteria suspended in solution. Also, it was found that a significant portion of the bio-battery’s resistance to charge transfer occurred at the surface of the anode and this resistance was lowered by 51% through bacteria immobilization.

超亲水-水下超疏油ZnCo_(2)O_(4)-不锈钢的制备及油水分离性能研究

目的通过简易的方法制备耐久性的油水分离材料。方法采用水热-退火方法在不锈钢网(SSM)基底上制备了ZnCo_(2)O_(4)纳米针状阵列(ZnCo_(2)O_(4)-SSM)。利用扫描电镜、X射线衍射仪、傅里叶变换红外光谱仪、X射线光电子能谱和接触角测量仪对油水分离材料的表面形貌、组分和表面润湿性进行了表征和研究。结果ZnCo_(2)O_(4)-SSM空气中水的接触角为0°,水下油的接触角≥155°,显示了超亲水-水下超疏油的特殊润湿性。ZnCo_(2)O_(4)-SSM呈现出优异的抗油污性能和重力驱动油水分离性能。对油-水混合物的分离效率大于99.8%,通量为3861~6114 L/(m^(2)·h),对水包油乳液的分离效率大于99.5%,通量为231~322 L/(m^(2)·h)。ZnCo_(2)O_(4)-SSM具有循环使用稳定性,在连续分离煤油-水混合物30次后,分离效率仍然能够达到99.8%以上。更重要的是,ZnCo_(2)O_(4)-SSM显示了优秀的长期稳定性、机械耐久性和强腐蚀环境耐久性(强酸,pH=1;强碱,pH=14;高盐,3.5%(质量分数)NaCl溶液)。结论ZnCo_(2)O_(4)-SSM以不锈钢网为载体,弥补了机械强度差的缺点。ZnCo_(2)O_(4)-SSM以高化学稳定的ZnCo_(2)O_(4)作为微纳米结构,提高了分离材料的耐久性。因此,ZnCo_(2)O_(4)-SSM制备方法简单,在工业含油污水的分离中具有很好的潜在应用前景。

KGM/CNF-不锈钢网油水分离材料的制备及其油水分离性能研究

目的在KGM/CNF包覆不锈钢网表面制备超亲水、水下超疏油功能材料,实现油水体系的分离。方法采用溶液浸泡法在不锈钢网上沉积魔芋葡甘聚糖(Konjac Gluco Mannan,KGM)/纤维素纳米纤维(CelluloseNanoFiber,CNF),构造超亲水/水下超疏油表面。通过加热使KGM脱乙酰化、KGM/CNF分子间氢键重构、CNF在材料表面重新排布,制备了KGM/CNF-不锈钢网油水分离材料;利用扫描电镜、傅里叶变换红外光谱仪、X射线衍射仪和界面接触角对油水分离材料的表面形貌及物化性质进行了表征和研究,采用红外测油仪研究了油水分离性能。结果KGM/CNF-不锈钢网油水分离材料在空气中具有优异的超亲水性(WCA=0°)和水下超疏油性能(OCA≥151°)。通过油水分离性能研究发现,KGM/CNF-不锈钢网油水分离材料在自身重力下可以对大豆油、汽油等不同油水混合物进行高效分离,对油水混合物的分离效率可达97.40%,分离通量为1236.75L/(m^(2)·h)。结论KGM/CNF-不锈钢网油水分离材料以不锈钢网为载体,弥补了力学强度差的缺点,具有优异的油水分离性能以及良好的耐腐蚀性和循环使用性;该材料制备方法简单,制备过程绿色环保、成本低,在油水体系的分离中具有较好的潜在应用前景。

纳米二氧化硅改性不锈钢网用于油水分离

以正硅酸乙酯为原料,采用溶胶-凝胶法制备了硅溶胶,将硅溶胶与预沉积聚多巴胺(PDA)的不锈钢网(SSM)反应,采用分步沉积和原位生长法制备了超亲水-水下超疏油不锈钢网(SSM-PDA-SiO_(2))。采用FTIR、XRD、TG、SEM和接触角测量仪对其进行了测试。探究了硅溶胶反应时间对SSM-PDA-SiO_(2)亲水-疏油性能的影响,通过自重力驱动测试了其油水分离性能,考察了其循环分离性和力学稳定性。结果表明,PDA作为“桥梁”将纳米SiO_(2)沉积到SSM表面上,硅溶胶与SSM反应8 h制备的SSM-PDA-SiO_(2)-8具有最佳的亲水-疏油性能,水滴能在其表面60 ms内完全铺展,其对二氯甲烷等5种有机溶剂的水下油接触角在156.4°~160.9°之间,对二氯甲烷的滚动角为4.0°,表现出超亲水-水下超疏油特性。首次分离正庚烷/水的油水混合物水通量为40165 L/(m^(2)·h),分离效率99.3%,在50次分离循环时水通量为17728 L/(m^(2)·h),分离效率仍>98%。经过35次砂纸摩擦循环后,SSM-PDA-SiO_(2)-8保持了98%以上的分离效率。PDA的羟基、氨基等亲水基团提高了SSM-PDA-SiO_(2)的超亲水-水下超疏油特性,纳米SiO_(2)增加了其表面粗糙度。

基于正交实验优化304不锈钢丝网吸液芯制备工艺

为制备混合型多孔丝网吸液芯,为金属热管的设计与加工提供基础数据,本文以100目、200目、300目304不锈钢丝网为原材料,试样采用电阻焊进行焊接,研究了搭接目数、搭接角度、焊点间距以及焊接能量对组合型丝网吸液芯的拉伸和顶破性能.研究结果表明:搭接目数对试样的拉伸与顶破性能影响最大,焊接能量对试样的拉伸与顶破性能的影响最小.

甲苯、丙酮和乙酸乙酯在新型铂-钯/不锈钢丝网催化剂上的催化氧化(英文)

采用阳极氧化法制备了一种用于催化氧化处理挥发性有机化合物(VOCs)的0.1%Pt-0.5%Pd/不锈钢丝网(SSWM)催化剂.活性测试结果表明,0.1%Pt-0.5%Pd/不锈钢丝网催化剂具有较高的催化活性和热稳定性.该催化剂上甲苯、丙酮和乙酸乙酯的完全氧化温度分别为220、260和280℃.通过扫描电镜(SEM)、X射线光电子能谱(XPS)和超声波等手段对催化剂和不锈钢丝网进行了表征.SEM结果表明,经阳极氧化工艺处理过的不锈钢金属丝网载体表面形成了一层沟壑形态的复合氧化膜.该阳极氧化膜有利于活性组分Pd、Pt的分散.

高强不锈钢绞线网-渗透性聚合砂浆加固的T型梁桥试验

以采用高强不锈钢绞线网-渗透性聚合砂浆加固技术加固的某大桥为工程背景,采用大比例模型试验,分析加固T型梁抗弯承载力的影响因素及其破坏特征。在试验研究的基础上,给出采用此法进行抗弯加固的T型梁承载力、刚度以及最大裂缝宽度的计算公式。同时对试验桥梁在加固前后进行了静力荷载试验。结果表明:该加固措施有效提高了梁的抗弯承载力和刚度,显著减小了桥梁裂缝宽度,并延迟了裂缝的出现;该加固技术可在不影响桥梁通行的情况下进行,具有良好的经济与社会效益。

Ce-Pt-Pd/不锈钢丝网催化剂的制备与催化性能

采用阳极氧化技术在不锈钢丝网上自生长了一层结构致密的阳极氧化膜,并以此为载体,制备出一种高活性、高稳定性的负载型Ce-Pt-Pd催化剂.考察了该系列催化剂对甲苯、丙酮和乙酸乙酯的氧化活性,并用扫描电镜、X射线光电子能谱和程序升温氧化技术对催化剂进行了表征.结果表明,不锈钢丝网载体表面自生长的氧化物膜十分有利于活性组分的负载,制得的催化剂具有较高的催化燃烧有机化合物的活性和稳定性.

含POSS含氟杂化丙烯酸酯共聚物的制备及其涂膜疏水性

以甲基丙烯酸甲酯(MMA)、丙烯酸正丁酯(BA)、甲基丙烯酸-β-羟乙酯(HEMA)、2-(全氟辛基)乙基甲基丙烯酸酯(FMA)、甲基丙烯酸酯基异丁基八面低聚倍半硅氧烷(MAPOSS)为单体,偶氮二异丁腈(AIBN)为引发剂,采用自由基溶液聚合法合成了含POSS含氟杂化丙烯酸酯共聚物。然后用二甲苯与三氟三氯乙烷的混合溶剂溶解该共聚物,将玻璃片和不锈钢滤网浸入其中,通过浸渍提拉法得到一层疏水涂膜。研究了POSS的含量对涂膜疏水性的影响。采用场发射扫描电子显微镜(SEM)、原子力显微镜(AFM)和X射线光电子能谱仪(XPS)对涂膜的表面形貌和元素进行了表征。结果表明,杂化共聚物中的POSS能够自发聚集在玻璃片和滤网表面,形成特定的粗糙结构,而随POSS含量增多,其聚集带来的表面粗糙度增加,导致涂膜的水接触角更大。当POSS质量分数为20%时,POSS聚集表面的平均粗糙度(Ra)达到209 nm,同时低表面能的氟在涂膜表面的质量分数为25.70%,结合滤网本身的微米孔结构,三者共同作用造就了涂膜滤网表面良好的疏水性,其水接触角达到144°。

高强不锈钢绞线网-渗透性聚合砂浆加固梁抗弯承载力试验研究

高强不锈钢绞线网-渗透性聚合砂浆加固技术是一项新型加固工艺,具有耐火、耐腐蚀、耐老化等优点。针对采用高强不锈钢绞线网-渗透性聚合砂浆加固的河北沧州某大桥,采用缩尺比例模型,对4根由该工艺加固的钢筋混凝土T型梁和1根对比梁的抗弯性能试验进行对比研究,分析加固梁抗弯承载力的影响因素及其破坏模式。在试验研究的基础上,提出此类加固梁的抗弯承载力计算公式。

高强不锈钢绞线网与ECC黏结-滑移关系模型

高强不锈钢绞线网与ECC的黏结是二者协同工作的基础,且黏结-滑移关系模型是其黏结性能的综合反映,故通过对17组51个高强不锈钢绞网增强ECC薄板试件进行单边拉拔试验,研究横向钢绞线间距、纵向钢绞线直径和相对锚固长度等因素对钢绞线网在ECC中黏结性能的影响规律。试验结果表明,横向钢绞线的设置可使黏结破坏由脆性破坏转变为延性破坏;高强不锈钢绞线网与ECC的黏结滑移曲线可分为5个阶段,分别为上升段、微降段、延性强化段、下降段和残余段。基于试验结果,对钢绞线网在ECC中的黏结破坏特征和黏结-滑移机理进行分析,在相关黏结-滑移关系模型的基础上,提出钢绞线网与ECC的黏结-滑移关系模型,并进行模型参数分析。所提模型及模型参数计算公式与试验结果吻合良好,能较好地反映钢绞线网与ECC的界面黏结滑移特征。

预应力高强不锈钢绞线网-高性能砂浆抗弯加固试验研究

在以往试验研究的基础上,对钢绞线施加预应力,以研究预应力高强不锈钢绞线网-高性能砂浆加固技术对RC梁的适用性。对5根预应力高强不锈钢绞线网-高性能砂浆加固的钢筋混凝土梁和1根对比梁进行了抗弯试验研究,试验结果表明,采用预应力措施有效地提高了梁的抗弯承载力和刚度,较好地约束了裂缝的发展。同时提出利用该种加固方法进行抗弯加固的承载力设计计算公式。计算结果与试验结果吻合较好。另外,还就高强不锈钢绞线网的预应力张拉、预应力损失等进行试验研究,提出完整的预应力高强不锈钢绞线网加固受弯构件的施工工艺,并给出采用不同张拉方法时预应力有效值系数的取值,使得该种加固方法能够更好地应用于实际工程中。

高强钢绞线网-聚合物砂浆加固层粘结滑移

为避免高强不锈钢绞线网-渗透性聚合物砂浆加固层发生早期剥离破坏,保证加固层与混凝土界面的粘结性能,通过9个试件的剥离破坏试验,分析了加固层与混凝土界面剥离破坏特征,测试了加固层与混凝土粘结-滑移曲线,并通过ANSYS有限元程序建立模型,对剥离破坏试验进行数值模拟,得到了加固层粘结-滑移特征参数,建立了高强钢绞线网-聚合物砂浆加固钢筋混凝土粘结-滑移本构方程。剥离破坏试验与有限元计算的对比分析表明,建立的粘结-滑移本构方程可用于实际工程计算。

不锈钢网阴极微生物燃料电池的产电性能研究

构建了一个以曝气池污泥为阳极接种微生物、碳毡为阳极、无任何修饰的不锈钢网为阴极的双室微生物燃料电池.通过输出电压、功率密度以及电化学阻抗等考察了阴极面积对电池产电性能的影响,并对电池的长期运行稳定性进行评价.研究结果表明,不锈钢网作为微生物燃料电池的阴极性能稳定.当不锈钢网面积为2×2 cm^2时,最大输出电压达到0.411 V,功率密度为0.303 W·m^(-2),内阻841Ω,极化内阻80Ω.增大阴极面积至2×4 cm^2,最大输出电压能达到0.499 V,内阻减小至793Ω.不锈钢网价格便宜,具有长期运行稳定性,适宜做MFCs的阴极.

还原氧化石墨烯对复合材料电阻焊接头强度的增强作用

目的通过还原氧化石墨烯(RGO)与不锈钢网的结合,改善不锈钢网作为电阻焊接玻璃纤维增强聚醚酰亚胺(GF/PEI)层合板植入体时的界面性能。方法在相同的焊接工艺下,对不同焊接时间的焊接强度进行比较。利用扫描电镜、红外光谱、拉曼光谱对改进的Hummers法合成的氧化石墨烯(GO)和水合肼还原的GO进行表征。使用扫描电镜和动态接触角对包裹不同次数RGO的不锈钢网进行测试分析。以包裹不同次数RGO的不锈钢网为植入体进行电阻焊接试验,并对焊接强度和失效模式进行分析。结果不同的焊接时间下,确定120 s左右时达到最高单搭接剪切强度,为26.6 MPa。由于RGO的疏水性,表面包裹不同次数RGO的不锈钢网动态接触角由89.8°增长到127.7°。在优化后的焊接时间下,用包裹5次RGO的不锈钢网为植入体的电阻焊接强度达到最高,为41 MPa。同时,RGO的加入使电阻焊接失效模式由最初的不锈钢网直接剥离失效向不锈钢网与层合板同时撕裂失效转变。结论RGO包裹的不锈钢网有效地改善了纯不锈钢网作为植入体和PEI树脂的界面相容性,对电阻焊接接头强度有着明显的提高。