钢轨轨底上表面缝隙腐蚀研究现状

在潮湿的环境中,铁路系统中的轨底上表面和绝缘轨距块之间容易发生缝隙腐蚀,这种现象导致轨底逐渐变薄,造成严重的安全隐患。目前缝隙腐蚀研究主要涉及螺栓螺母、边缘板等异形结构,而对轨底上表面与绝缘轨距块之间的缝隙腐蚀的研究报道较少。对轨底上表面的缝隙腐蚀现象进行深入分析,探讨了现阶段轨底上表面缝隙腐蚀的产生和机械辅助缝隙腐蚀机制、相关的检测技术和方法以及防护措施的研究现状。

电阻抗成像技术在肺功能检测的研究进展

电阻抗成像技术(EIT)通过对电极施加安全的交流激励电流信号,测量其余电极对的电压信号,借助重构图像算法,利用采集到的电压数据重构肺部阻抗分布情况。EIT技术具有实时、无创、便携的特点,能够动态监测肺部功能,有利于辅助肺疾病的诊断和治疗。概括了肺功能EIT技术的发展历程与原理,并对EIT硬件系统、图像重建算法和临床应用的研究进展进行了总结和分析;对肺功能EIT技术发展方向和趋势进行探讨与展望。

复层矿脂包覆防腐蚀技术(PTC)在悬索桥锚碇防护中的应用

锚碇系统是悬索桥的安全所系。分析了锚碇腐蚀的主要原因。将复层矿脂包覆防腐技术(PTC)应用于柳州红光桥锚碇中的索股及联接件,介绍了表面处理、涂抹矿脂防蚀膏、缠绕矿脂防蚀带、制作玻璃钢外壳等步骤。3年后跟踪检查的结果证明了PTC具有良好的防腐蚀性能。

单链环化/打结有机硅聚合物防污涂层的制备及性能研究

有机硅低表面能防污涂料不含杀生剂,绿色环保,但存在静态防污能力较差的问题。本研究采用可逆加成断裂链转移(RAFT)聚合的方法,通过动力学控制将多烯基硅氧烷单体进行均聚,合成了不同相对分子质量的单链环化/打结有机硅聚合物,随后通过紫外光固化进一步制备了防污涂层。研究表明,防污涂层的可见光透过率大于95%;涂层疏水且表面能较低(21~25 mJ/m^(2));通过原子力显微镜(AFM)测试发现,使用相对分子质量较高的聚合物所制备的防污涂层SCKP-3表面形成了大量均匀的球型纳米颗粒;实验室条件下防污实验表明,涂层表面的微观纳米结构可有效抑制假单胞菌、希瓦氏菌和硅藻的附着。本研究为开发新型有机硅低表面能防污涂料提供了新的思路。

我国腐蚀管理体系研究

腐蚀管理关乎安全生产,关乎国民经济,关乎生态文明,关乎资源节约和国家建设。虽然少数行业在腐蚀管理方面已经进行了一些卓有成效的探索和实践,但是总体上腐蚀管理在我国发展十分不平衡,存在着腐蚀管理意识薄弱、专业人才短缺和管理系统不健全等问题。因此,有必要进一步明确腐蚀管理的内涵,明确我国腐蚀管理体系化发展的基本要求,推动腐蚀管理体系化持续健康发展。本文基于中国工程院重点咨询项目"我国腐蚀管理状况与对策战略研究"主要研究成果,阐述了腐蚀管理的内涵及体系化发展的重要意义,分析了我国腐蚀管理的现状及问题,总结提出了腐蚀管理体系基本框架及管理要点,提出了将腐蚀管理纳入国家安全战略,成立腐蚀管理战略研究常设机构;加强腐蚀学科建设,强化人才战略;建立健全腐蚀防护相关法规标准,强化标准意识;加强腐蚀数据库建设,畅通沟通渠道;搭建腐蚀管理信息及大数据交流平台,打造共享管理新模式等对策建议。

纳米材料改性自抛光海洋防污涂料的制备与性能

纳米材料具有量子尺寸效应、表面效应、体积效应和宏观量子隧道效应等优点,其会改善传统材料的诸多性能。针对纳米材料是否增效防污的问题,为了深入理解纳米材料的添加对无锡自抛光防污涂料的主要性能的影响,通过超声-机械共混方法将纳米氧化锌与氧化石墨烯纳米材料添加到无锡自抛光防污涂料中,研究了纳米材料对无锡自抛光防污涂料表面性能、机械性能尤其是粘结强度和实海防污性能以及铜离子释放速率等的影响。浸泡前后,添加纳米材料的防污涂层的表面由疏水(接触角>90°)变为亲水(接触角约为70°),与未加纳米材料的防污涂层一致。添加0.1wt%纳米材料的防污涂层的粘接强度约在3.0~4.5 MPa,与未加纳米材料的防污涂层(约3.8 MPa)相比,粘接强度没有显著变化。添加纳米材料的防污涂层中铜离子释放速率稳定在约15~25μg/(cm2·d)。此外,长达约180 d的实海浸泡挂板表面无任何海洋生物的附着。总之,少量纳米材料的添加可以在不明显牺牲表面性能、粘接强度等物理化学性能的前提下提高了无锡自抛光防污涂料的防污性能。

海水中小球藻对Q235碳钢腐蚀行为的影响

采用表面分析技术以及电化学测试技术研究了海水中小球藻对Q235碳钢腐蚀的影响。结果表明:在不含小球藻培养液中Q235碳钢发生均匀腐蚀,而在含小球藻培养液中碳钢发生不均匀腐蚀;在含小球藻体系中,开路电位随浸泡时间的变化呈周期振荡;小球藻及其代谢产物能够在材料表面附着并形成一层生物膜,减缓金属的腐蚀;小球藻光合作用产生的氧导致阴极氧去极化作用,加速了金属的腐蚀。

羟基硅油改性环氧树脂富镁底漆的制备与性能研究

研究了一种羟基硅油改性环氧树脂的方法,通过红外光谱、GPC测试、DSC测试以及稳定性分析详细考察了反应物配比对改性树脂性能的影响。研究表明:羟基硅油和环氧树脂质量比为5∶1的体系获得的改性产物稳定性好,且具有高的柔韧性和强度;进一步,利用改性树脂配制羟基硅油改性环氧-富镁底漆,通过涂层基本性能测试,盐雾试验和老化试验研究了涂层对铝合金的保护性能。研究表明:涂层附着力得到改善,柔韧性和耐冲击性提高,耐盐雾性优异,耐老化性一般,需与面漆配套使用。

MDI和硅油改性环氧树脂的制备及其在富镁底漆中的应用

利用二苯基甲烷二异氰酸酯(MDI)的桥接作用通过半连续滴加工艺首先合成了MDI-羟基硅油预聚物,通过FTIR和稳定性分析确定了预聚物的最佳合成工艺;然后利用含有NCO基团的预聚物和E-20环氧树脂共聚得到了MDI和硅油改性环氧树脂。通过FTIR、GPC及稳定性分析考察了催化剂用量、反应时间以及反应物配比对改性树脂性能的影响。结果表明,较优的反应条件为:m(环氧树脂)∶m(预聚物)=4∶1,二月桂酸二丁基锡用量为0.6%(以环氧树脂和预聚物总质量为基准,下同),反应时间4h。利用改性环氧树脂配制了富镁涂层,通过基本性能测试、盐雾实验和老化实验考察了涂层对铝合金的保护性能。发现涂层具有较高的附着力、柔韧性和耐冲击性,耐盐雾且耐老化性能优越。

青岛中港微型生物膜中污损细菌群落初探

本研究拟通过揭示微型生物膜中的细菌群落特征,为污损生物学和海洋腐蚀学的微观研究提供参考和启示。试验采用3种方法:传统稀释涂布法、流式细胞仪计数法以及16srDNA扩增子高通量测序对青岛中港冬季海水以及玻璃板中微型生物膜中的污损细菌群落结构进行分析。试验结果表明冬季海水表层和底层中细菌的浓度分别为3.0×10^8CFU/L和6.9×10^7CFU/L,表层和底层玻璃板微型生物膜中的细菌浓度分别为7.2×10^7CFU/L和2.1×10^7CFU/L,海水和玻璃板中的细菌以Proteobacteria和Bacteroidetes为主。另外,海水中细菌群落结构组成与玻璃板微型生物膜中细菌具有较高的一致性。本研究利用不同的试验方法揭示微型生物膜中的细菌群落特征,对深入研究生物污损,从根本上解决海洋生物污损问题、制定绿色防污措施具有重要的现实意义。

硫酸盐还原菌附着对阴极保护条件下钙质沉积层形成及其对金属保护性能的影响

通过扫描电镜(SEM)、能谱(EDS)、电化学阻抗谱(EIS)等方法研究了硫酸盐还原菌的附着对阴极保护条件下钙质沉积层形成及其对金属保护性能的影响。结果表明:硫酸盐还原菌附着后,施加阴极保护的碳钢表面依然能形成钙质沉积层,无论硫酸盐还原菌附着时间长短,生物膜的形成都导致金属表面钙质沉积层量减少,使其对金属的保护性减弱,硫酸盐还原菌局部腐蚀加速。

Analysis of cultivable aerobic bacterial community composition and screening for facultative sulfate-reducing bacteria in marine corrosive steel

Anaerobic, aerobic, and facultative bacteria are all present in corrosive environments. However, as previous studies to address corrosion in the marine environment have largely focused on anaerobic bacteria, limited attention has been paid to the composition and function of aerobic and facultative bacteria in this process. For analysis in this study, ten samples were collected from rust layers on steel plates that had been immersed in seawater for diff erent periods (i.e., six months and eight years) at Sanya and Xiamen, China. The cultivable aerobic bacterial community structure as well as the number of sulfate-reducing bacteria (SRB) were analyzed in both cases, while the proportion of facultative SRB among the isolated aerobic bacteria in each sample was also evaluated using a novel approach. Bacterial abundance results show that the proportions are related to sea location and immersion time;abundances of culturable aerobic bacteria (CAB) and SRB from Sanya were greater in most corrosion samples than those from Xiamen, and abundances of both bacterial groups were greater in samples immersed for six months than for eight years. A total of 213 isolates were obtained from all samples in terms of CAB community composition, and a phylogenetic analysis revealed that the taxa comprised four phyla and 31 genera. Bacterial species composition is related to marine location;the results show that Firmicutes and Proteobacteria were the dominant phyla, accounting for 98.13% of the total, while Bacillus and Vibrio were the dominant genera, accounting for 53.06% of the total. An additional sixfacultative SRB strains were also screened from the isolates obtained and were found to encompass the genus Vibrio (four strains), Staphylococcus (one strain), and Photobacterium (one strain). It is noteworthy that mentions of Photobacterium species have so far been absent from the literature, both in terms of its membership of the SRB group and its relationship to corrosion.

Influence of Calcareous Deposit on Corrosion Behavior of Q235 Carbon Steel with Sulfate-Reducing Bacteria

Cathodic protection is a very effective method to protect metals, which can form calcareous deposits on metal surface. Research on the interrelationship between fouling organism and calcareous deposits is very important but very limited, especially sulfate-reducing bacteria(SRB). SRB is a kind of very important fouling organism that causes microbial corrosion of metals. A study of the influence of calcareous deposit on corrosion behavior of Q235 carbon steel in SRB-containing culture medium was carried out using electrochemical impedance spectroscopy(EIS), scanning electron microscopy(SEM) and surface spectroscopy(EDS). The calcareous deposit was formed with good crystallinity and smooth surface under the gradient current density of -30 μA cm^(-2) in natural seawater for 72 h. Our results can help elucidate the formation of calcareous deposits and reveal the interrelationship between SRB and calcareous deposits under cathodic protection. The results indicate that the corrosion tendency of carbon steel was obviously affected by Sulfate-reducing Bacteria(SRB) metabolic activity and the calcareous deposit formed on the surface of carbon steel under cathodic protection was favourable to reduce the corrosion rate. Calcareous deposits can promote bacterial adhesion before biofilm formation. The results revealed the interaction between biofouling and calcareous deposits, and the anti-corrosion ability was enhanced by a kind of inorganic and organic composite membranes formed by biofilm and calcareous deposits.

Fabrication of anodized superhydrophobic 5083 aluminum alloy surface for marine anti-corrosion and anti-biofouling

Marine corrosion and biofouling seriously affect the service life of marine structural materials,resulting in performance failure,enormous economic loss,and even catastrophic safety accidents.It is worthwhile and desirable to develop high-efficiency strategy for anti-corrosion and anti-biofouling.In this paper,superhydrophobic 5083 aluminum alloy(AA5083)surface with micro-nano hierarchical morphology was fabricated through anodization followed by 1H,1H,2H,2H-perfluorooctyltriethoxysilane(POTS)modification.The surface morphologies,roughness,and chemical compositions were revealed by scanning electron microscopy,atomic force microscopy,and X-ray diffraction.The self-cleaning ability,corrosion resistance and algae adhesion suppression ability of the fabricated surfaces were investigated,indicating an excellent water-proofing,anti-corrosion and anti-biofouling performance.We believe the superhydrophobic creation of metallic materials is expected to have potential applications in marine corrosion and antibiofouling fields.

Research progress of TiO2 photocathodic protection to metals in marine environment

Corrosion protection has become an important issue as the amount of infrastructure construction in marine environment increased.Photocathodic protection is a promising method to reduce the corrosion of metals,and titanium dioxide(TiO2) is the most widely used photoanode.This review summarizes the progress in TiO2 photo gene rated protection in recent years.Different types of semiconductors,including sulfides,metals,metal oxide s,polymers,and other materials,are used to design and modify TiO2.The strategy to dramatically improve the efficiency of photoactivity is proposed,and the mechanism is investigated in detail.Characterization methods are also introduced,including morphology testing,light absorption,photoelectrochemistry,and protected metal observation.This review aims to provide a comprehensive overview of Ti02 development and guide photocathodic protection.

Desulfovibrio Bizertensis SY-1在阴极极化条件下对X70管线钢的腐蚀行为研究

研究了从浸泡在中国南海的钢铁锈层中分离的腐蚀性硫酸盐还原菌Desulfovibrio bizertensis SY-1在-0.85和-1.05 V vs.SCE阴极极化电位下对X70管线钢腐蚀行为的影响。结果表明,-0.85 V vs.SCE电位尚不能有效抑制Desulfovibrio bizertensis SY-1细胞的生长与附着,同时试片表面也检测到了特征的四方硫铁矿和针铁矿的Raman峰。-1.05 V vs.SCE阴极极化电位能够有效抑制浮游Desulfovibrio bizertensis SY-1细胞的生长和代谢过程,腐蚀产物以磁铁矿为主。失重数据也表明,在-1.05 V vs.SCE电位下试片失重与无菌条件基本一致,且在该电位下最大点蚀坑深度与无极化条件相比减少了75%。该研究为含有Desulfovibrio bizertensis SY-1环境的阴极保护电位选择和微生物与极化电位的相互作用研究提供了参考。

硅烷偶联剂(KH550)和羟基硅油共同改性环氧树脂及配制富镁底漆性能研究

通过两步反应法实现了硅烷偶联剂KH550和羟基硅油对环氧树脂E-20的共同改性,利用胺基加成反应引入KH550的乙氧基基团增加E-20的活性,从而提高与羟基硅油的接枝效率。通过红外光谱、GPC测试、稳定性分析以及DSC测试研究了分步反应过程和反应物配比对改性树脂性能的影响,优化改性工艺。研究表明,合适的反应物配比为E-20∶羟基硅油∶KH550=10∶1.5∶0.5 (质量比)。进一步利用改性树脂配制富镁涂层,通过涂层基本性能测试、盐雾试验和老化试验,研究了涂层对铝合金的保护性能。研究表明,涂层具有高的附着力,柔韧性好,耐盐雾和耐老化性能提高明显。

超声辅助电沉积纯锌镀层的制备及耐磨、耐蚀性能研究

锌镀层由于其自腐蚀电位负、屏障作用良好而被广泛应用于海洋钢铁设施上。本工作将超声引入电沉积体系,利用超声辅助的方法在20#碳钢表面电沉积锌镀层,研究了超声功率变化对锌镀层性能的影响。沉积电位监测、电流效率计算结果显示,超声的引入能够明显增大电流效率,有利于节约电能。扫描电镜(SEM)、X射线衍射仪(XRD)、原子力显微镜(AFM)等结果显示,锌镀层晶体颗粒变小,形成的镀层更致密、均匀。磨耗测试、电化学阻抗谱(EIS)、极化曲线(Tafel)等结果显示,超声的引入使得锌镀层耐磨性与耐蚀性能明显提升。

海洋环境硫酸盐还原菌对金属材料腐蚀机理的研究进展

硫酸盐还原菌(SRB)是一类广泛存在于自然环境中可以利用硫酸盐类物质作为呼吸代谢电子受体的厌氧类微生物,是造成金属腐蚀破坏和设备故障的主要原因之一,已经成为一个重要的研究课题。由于微生物活动的复杂性,生物膜内SRB与金属表面的相互作用缺乏深入的研究,其诱导腐蚀机理和腐蚀过程尚不清楚,难以进行有效的腐蚀预测。基于此,本文从SRB生物膜的呼吸代谢角度介绍了其诱导金属腐蚀的研究进展。介绍了SRB的生态特征和厌氧呼吸过程,重点综述了SRB腐蚀机理,包括阴极去极化、代谢产物腐蚀、浓差电池作用和胞外电子传递等理论,最后简要介绍了微生物腐蚀(MIC)研究的方法与技术手段。