20 resultados para Aço AISI 316L
Resumo:
综述了有关核聚变反应堆材料的辐照损伤问题的研究,主要包括国产316L奥氏体不锈钢中氦的扩散与氦泡形核生长的研究、316L及低活化FeCrMn合金的高能Ar离子辐照缺陷与空洞肿胀的研究、近期开展的低活化马氏体钢和氧化物颗粒弥散强化合金的高能Ne离子辐照损伤和效应的研究成果。
Resumo:
A FeNiSiBV amorphous composite coating was developed by laser cladding of metallic powders on AISI 1020 low carbon steel substrate. The coatings were studied using X-ray diffraction, transmission electron microscopy and scanning electron microscopy. The coating reveals different microstructures along the depth of the coating. The transition zone exhibits good metallurgical bonding between the substrate and the coating. The layer consists of amorphous phase in majority and nanocrystalline phase/crystalline phase in minority. Accompanied with the nanocrystalline phase, the amorphous phase is concentrated in the middle of the coating. The crystalline phase in the coating is identified as Fe2B. A gradient distribution of the microhardness ranges from 1208 HV0.2 to 891 HV0.2 in the coating along the depth. The coating shows higher microhardness and better wear property than the substrate.
Resumo:
海洋电活性微生物(又称电活性生物膜,electroactive biofilms, EABs)是自然界存在的一类功能性微生物,能够将代谢有机物产生的电子直接或间接传递给电极,人们对其在环境中的广泛性及其在生物防腐、生物能源和生物修复中的应用正在开展广泛的研究。 本论文着眼于海洋天然生物膜的电活性,从微生物腐蚀和微生物燃料电池的角度,考察研究了海洋天然生物膜对316L SS腐蚀行为的影响,发现海洋天然生物膜能抑制316L SS腐蚀,系统研究了海洋生物膜与石墨等电极的电子传递过程,提出了电活性生物膜(EABs)与电极间的电子传递机制,并初步研究了海洋电活性生物膜在微生物燃料电池(MFCs)中的应用。 对附着天然海洋生物膜的316L SS研究发现,生物膜使316L SS电位正移了500mV (vs. Ag/AgCl)。316L SS表面附着海洋生物膜后,其孔蚀电位由原来的50mV增加到540mV,孔蚀敏感性降低;同时,海洋生物膜的附着导致316L SS的阻抗增加,由此,我们明确提出海洋生物膜能够抑制316L SS腐蚀的发生。进一步研究了生物膜抑制腐蚀发生的可能机理。循环伏安实验表明,海洋生物膜与不锈钢电极之间存在电子传递过程。扫描电镜(SEM)及能谱(EDS)分析发现有钙盐的沉积生成。通过以上结果我们提出了生物膜对腐蚀的抑制机制假设,即在电极与电活性海洋生物膜间发生了电子传递,海洋生物膜能够将电子传递给不锈钢,316L SS作为电子接受体受到保护。 为进一步研究天然海洋生物膜的这种电活性,我们选择不会发生腐蚀的惰性电极材料石墨,玻碳,碳纸电极验证生物膜的电活性。 首次考察了天然海洋生物膜对石墨电极和玻碳电极的开路电位变化的影响,结果显示随电极在天然海水中浸泡时间,石墨电极正移50mV vs. Ag/AgCl,玻碳电极正移了300 mV (vs. Ag/AgCl)。与316L SS相似,三种电极的变正趋势相同,都经历了三个阶段,即初始缓慢变正期,随后的指数变正期和以后的稳定期,此与生物膜在固体表面形成的趋势相似。伏安曲线及阻抗实验结果表明,在石墨,玻碳和碳纸电极材料表面附着海洋生物膜后,电流密度增加,电荷转移电阻减小,说明生物膜与电极间存在电子传递,并能加速电子传递过程,不同材料表面生物膜的电活性能力由大到小为石墨>316L SS>碳纸>玻碳。 进一步研究了海洋沉积物-海水生物膜微生物燃料电池,初步建立了相应的电极材料和微生物燃料电池结构。我们选择石墨阳极和石墨阴极或316L SS阴极组装海泥沉积物(阳极区)和海水(阴极区)MFC,316L SS代替石墨做阴极最大输出电量达9mW.m-2,约为后者的2倍。两种MFC输出电流和功率密度随时间的延长而增加的趋势相同,都可以分为三个阶段,即初期的缓慢增加阶段,中期的指数增长阶段,后期的平台稳定期阶段。这也与生物膜在固体表面形成的趋势相似。此研究也说明优化316L SS表面性质筛选活性海洋生物膜用于MFC有其潜在的应用价值。
Resumo:
In corrosion medium, metals can deform under tensile stress and form a new active surface with the anodic dissolution of the metals being accelerated. At the same time, the anodic dissolution may accelerate the deformation of the metals. The synergy can lead to crack nucleation and development and shorten the service life of the component. Austenitic stainless steel in acidic chloride solution was in active dissolution condition when stress corrosion cracking (SCC) occurred. It is reasonable to assume that the anodic dissolution play an important role, so it's necessary to study the synergy between anodic dissolution and deformation of austenitic stainless steels. The synergy between deformation and anodic dissolution of AISI 321 austenitic stainless steel in an acidic chloride solution was studied in this paper. The corrosion rate of the steel increased remarkably due to the deformation-accelerated anodic and cathodic processes. The creep rate was increased while the yield strength was reduced by anodic dissolution. The analysis by thermal activation theory of deformation showed a linear relationship between the logarithm of creep rate and the logarithm of anodic cur-rent. Besides, the reciprocal of yield strength was also linearly dependent on the logarithm of anodic current. The theoretical deductions were in good agreement with experimental results.
Resumo:
A new technique was developed for characterisation of stainless steel to intergramilar stress corrosion cracking by atomic force microscopy. The technique proved to be effective in sensitisation identification of AISI 304 stainless steel and might be promising in sensitisation identification of other stainless steels. (c) 2007 Elsevier B.V. All rights reserved.
