高氮无镍奥氏体不锈钢耐蚀性的研究

以常压下冶炼的高氮无镍奥氏体不锈钢为材料,经1150℃强烈塑性变形,轧制成2 mm厚的板材,将热轧后的板材进行1100℃、保温10 h、水淬的固溶处理。通过酸浸试验、极化曲线测试和盐雾腐蚀试验,并与1Cr18N i9Ti钢的耐蚀性进行比较。结果表明,冶炼高氮无镍奥氏体不锈钢具有优异的耐腐蚀性能。     

电弧喷涂316L不锈钢涂层的结构与性能

采用电弧喷涂优化工艺制备316L不锈钢涂层,利用扫描电镜、能谱仪和X射线衍射仪等对涂层的组织及物相进行分析,同时对涂层的硬度、结合强度进行了测定。结果表明：涂层具有典型的层状形貌,涂层截面较为致密,局部区域出现粗大孔洞;涂层与基体之间主要为机械结合,结合强度较高;涂层硬度的最大值出现在涂层中部,靠近界面的基体组织发生加工硬化。     

Corrosion monitoring system design for coating wire of steel in ocean

The monitoring system design used in anti-corrosion of coating wire of steel in ocean were concerned. A corrosion monitoring system adapting to corrosion observation of coating wire of steel was introduced in details, including design and choice of software and hardware. This system will play an important role in the collection, procession, demonstration, deposition and accident alarm of corrosion data of oceanic coating wire of steel.     

Ni-Cu-P镀层和316L不锈钢在热盐酸溶液中的耐蚀性及机制

采用质量损失法研究了温度和浓度对化学镀Ni-Cu-P镀层和316L不锈钢在盐酸溶液中的腐蚀行为.结果表明,在高温盐酸溶液中,Ni-Cu-P镀层的耐蚀性优于316L不锈钢,盐酸浓度对316L不锈钢腐蚀速率的影响大于Ni-Cu-P镀层,盐酸浓度由5％升高到20％,316L不锈钢和Ni-Cu-P镀层的腐蚀速率分别增大了2.7倍和0.6倍;在盐酸溶液中,Ni-Cu-P镀层发生均匀腐蚀,316L不锈钢发生选择性腐蚀,且温度和浓度越高,选择性腐蚀越严重.     

Droplet transfer behavior of the stainless steel coated electrode with double-layer coating

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Corrosion resistance of stainless steel pipes in soil

To be able to give safe recommendations concerning the choice of suitable stainless steel grades for pipelines to be buried in various soil environments, a large research programme, including field exposures of test specimens buried in soil in Sweden and in France, has been performed. Resistance against external corrosion of austenitic, super austenitic, lean duplex, duplex and super duplex steel grades in soil has been investigated by laboratory tests and field exposures. The grades included have been screened according to their critical pitting‐corrosion temperature and according to their time‐to‐re‐passivation after the passive layer has been destroyed locally by scratching. The field exposures programme, being the core of the investigation, uses large specimens: 2 m pipes and plates, of different grades. The exposure has been performed to reveal effects of aeration cells, deposits or confined areas, welds and burial depth. Additionally, investigations of the tendency of stainless steel to corrode under the influence of alternating current (AC) have been performed, both in the laboratory and in the field. Recommendations for use of stainless steels under different soil conditions are given based on experimental results and on operating experiences of existing stainless steel pipelines in soil.     

Fracture behavior of 304 stainless steel coatings by cold gas dynamic spray

304 stainless steel coating was deposited on the Interstitial-Free steel substrate by cold gas dynamic spraying (CGDS).Three-point bending test of the cold sprayed 304 stainless steel coating was tested by SHIMADZU electro-hydraulic servo-controlled fatigue testing machine and the fracture morphology was examined by scanning electron microscopy.The results showed that the fracture behavior of the cold sprayed 304 stainless steel coating was brittleness fracture.The crack in the coating occurred in the interfaces between particles and the crack extended to the internal of the coating with the increase of the load.When the crack has extended to the combination interface between coating and substrate,the crack extended to the two sides.The microstructure and mechanical property of the cold sprayed 304 stainless steel coating have been optimized after heat treatment.     

Optimization of corrosion process of stainless steel coating during cleaning in steel brewery tanks

The aim of this research was to optimize and investigate effects of corrosion process during cleaning of stainless‐steel coatings in microbrewery tanks and to predict their resistance to nitric acid in washing solution. Experimental conditions were limited with minimal concentration of acid that satisfied requirements of sanitation protocol, and maximal concentration of acid that did not cause corrosion and release of metals higher then prescribed law limits. Process was monitored by release of metal ions and optimized by design of experiment (DOE) using software Design‐Expert. This approach proved to be very beneficial, cost reductive, and effective for optimization of complex systems. The results of experiments prediction were compared to additional testing, and their matching proved the effectiveness of modeling. Therefore DOE is an effective tool for estimation of steel coating corrosion processes. In addition, optimized values satisfied required criteria, so the proposed protocol can be used in the effective sanitation of industrial tanks and pipelines in brewing industry.     

Structure and sliding wear behavior of 321 stainless steel/Al composite coating deposited by high velocity arc spraying technique

A typical 321 stainless steel/aluminum composite coating （321/Al coating） was prepared by high velocity arc spraying technique （HVAS） with 321 stainless steel wire as the anode and aluminum wire as the cathode. The traditional 321 stainless steel coating was also prepared for comparison. Tribological properties of the coatings were evaluated with the ring-block wear tester under different conditions. The structure and worn surface of the coatings were analyzed by scanning electron microscopy（SEM）, X-ray diffractometry（XRD） and energy dispersion spectroscopy（EDS）. The results show that, except for aluminum phase addition in the 32 l/Al coating, no other phases are created compared with the 321 coating. However, due to the addition of aluminum, the 32 l/Al coating forms a type of ＂ductile/hard phases inter-deposited＂ structure and performs quite different tribological behavior. Under the dry sliding condition, the anti-wear property of 32 l/Al coating is about 42% lower than that of 321 coating. But under the oil lubricated conditions with or without 32 h oil-dipping pretreatment, the anti-wear property of 321/AI coating is about 9% and 5% higher than that of 321 coating, respectively. The anti-wear mechanism of the composite coating is mainly relevant to the decrease of oxide impurities and the strengthening action resulted from the ＂ductile/hard phases inter-deposited＂ coating structure.     

Corrosion of stainless steels and carbon steel by molten mixtures of commercial nitrate salts

The isothermal corrosion behavior of two stainless steels and a carbon (C) steel in mixtures of NaNO₃ and KNO₃ was evaluated to determine if the impurities found in commodity grades of alkali nitrates aggravate corrosivity as applicable to an advanced solar thermal energy system. Corrosion tests were conducted for approximately 7000 hours with Types 304 and 316 stainless steels at 570 °C and A36 C steel at 316 °C in seven mixtures of NaNO₃ and KNO₃ containing variations in impurity concentrations. Corrosion tests were also conducted in a ternary mixture of NaNO₃, KNO₃, and Ca(NO₃)₂. Corrosion rates were determined by descaled weight losses while oxidation products were examined by scanning electron microscopy (SEM), electron microprobe analysis (EPMA), and x-ray diffraction (XRD). The nitrate mixtures were periodically analyzed for changes in impurity concentrations and for soluble corrosion products. Results of these tests indicated that the short-term corrosion rates of the stainless steel specimens in many of the mixtures could be described in terms of parabolic kinetics. However, no single rate law could be assigned to the corrosion kinetics resulting from exposure in all of the mixtures. For engineering applications, corrosion rates over the entire exposure period are best described as linear with respect to time. In the binary nitrate mixtures, the annualized rates of metal loss were found to be between 6 and 15 μm/year for the stainless steel specimens at 570 °C depending on the particular mixture. Metal loss for the C steel specimens immersed in these same mixtures at 316 °C extrapolated to approximately 1–4 μm/year. SEM and XRD revealed that the complex, multiphase surface oxides formed on the stainless steel coupons were composed primarily of iron-chromium spinel, iron oxides, and sodium ferrite. Magnetite was the principal corrosion product formed on the carbon steel specimens. Overall, for the typical range of impurities in commercially available nitrate salts, corrosion rates for solar thermal energy applications remained acceptable for all of the materials examined.     

高温酸性溶液中316L不锈钢/Ni-Cu-P镀层的耐蚀性能

为了改善316L 不锈钢在高温酸性溶液中的耐蚀性,采用化学镀技术在316L 不锈钢表面沉积高铜高磷Ni?Cu?P 镀层。采用扫描电镜(SEM)、能谱仪(EDS)和 X 射线衍射仪(XRD)对其结构进行分析,利用极化曲线、阻抗谱(EIS)及浸泡腐蚀试验对其在高温酸性溶液中的耐蚀性进行研究。结果表明,Ni?Cu?P 镀层由铜含量分别为19.98%和39.17%(质量分数)两种类型的胞状组织组成;在高温酸性溶液中,这种新型Ni?Cu?P镀层可显著改善316L不锈钢的耐蚀性;镀态镀层的耐蚀性优于热处理态的;镀态镀层和经673 K热处理镀层的腐蚀机制是选择性腐蚀,而经773和873 K热处理镀层的腐蚀机制为点腐蚀。     

Influence of superficial coating of CeO2 on the oxidation behavior of AISI 304 stainless steel

The effect of a superficially-applied, cerium-oxide coating on the non-isothermal oxidation behavior of AISI 304 stainless steel in dry air has been investigated. The heating rate employed was 3 K/min up to a final temperature of 1423 K. The reactive oxide coating not only reduced the reaction rate but also facilitated scale adhesion to the alloy substrate. Post-oxidation analyses of the alloy/scale combination using optical microscopy, SEM, EDAX, and XRD provide evidence for a changeover in the mechanism of oxide growth from the scale/gas interface to the alloy/scale interface for the coated steel.     

Corrosion behavior of austenitic 304L and 316LN stainless steel clad reinforcing bars in cracked concrete

A study has been conducted on the chloride-induced corrosion behavior of 304L and 316LN stainless steel clad reinforcing bars (rebar) in concrete and in synthetic concrete pore solution. Metallographic examination of the as-received clad bars confirmed a strong metallurgical bond at the core/clad interface and some grain growth interdiffusion of species at the interface. Both bars showed a wide variation in coating thickness around the rebar circumference, from a minimum of 0.32 and 0.60 mm to a maximum of 1.4 and 2.8 mm in the 304L clad and 316LN clad, respectively. The electrochemical results and visual examination after autopsy showed that active corrosion was yet initiated on either the solid and clad stainless steel or carbon steel rebar in the sound noncracked concrete specimens. In contrast, corrosion had initiated in the bars embedded in cracked concrete at the base of the crack and extended along or around the bars. In the concrete and synthetic pore solution tests, the current densities of both solid and clad stainless steel rebar exposed to ∼21% chloride brine solution for days between 400 and 1,500 were similar. This was also the case for current densities of the straight and bent stainless steel bars tested in the synthetic pore solution test.     

Galvanic current induced by heterogeneous structures on stainless steel wire

Galvanic corrosion could be initialized between the heterogeneous structures of an implant and the resulting corrosion products could act as a trigger for thrombosis and inflammation leading to restenosis after deployment of implant inside the artery. Experimental evidence showed that there were significant differences in the electrochemical behaviors among the different grain sizes of an implant. Galvanic current was detected between different grain sizes of 316L stainless steel wires both in vitro and in vivo. Severe corrosion and thrombosis were observed at anodic sites. Results demonstrated that homogeneous structure is the essential requirement for an implant in order to minimize the development of galvanic corrosion and to prevent its aftermath after percutaneous transluminal coronary angioplasty (PTCA).