Influence of Adding Ti Powder in Preform on Microstructure and Mechanical Properties of Al_2O_3p/Steel Composites by Squeeze Casting

To improve the mechanical properties of alumina particulates reinforced steel matrix composite, Ti powder was added into the alumina preform, a 5140 steel matrix composite was fabricated by squeeze casting, and the influences of Ti powder on the microstructure, hardness and bending strength of the composite were investigated, compared with the composite without adding Ti powder. Applied Ti powder and alumina particulates were 10-25 μm and 100-180 μm in size, respectively. Both composites were successfully fabricated, however Ti powder addition increased the infiltration thickness of the composite. In the Ti contained composite, a TiC film in micron scale is formed on the surface of alumina particles, many TiC aggregates are dispersed in the steel matrix without obvious remaining Ti powder. The hardness and the three-point bending strength of the composite reach 49.5 HRC and 1 018 MPa, respectively, which are 17.9% and 52.4% higher than those of the composite in the absence of Ti addition. Fracture morphology shows that the debonding of alumina particulates is eliminated for the composite in the presence of Ti addition. Sessile drop test shows the average wetting angle between 5140 steel and that of Ti coated Al2O3 is about 82.15°, much lower than the wetting angle 150° between steel and pure Al2O3. Therefore, the increase in the mechanical properties of the composite is attributed to the improvement of Al2O3 p/steel interface wetting and bonding by adding Ti powder in the preform.

Microstructure and Performance of 2Y-PSZ/TRIP Steel Composites

2Y-PSZ/TRIP steel composites have been sintered by hot-pressing method. Their microstructure and mechanical properties were investigated by means of SEM, TEM, XRD and static tension, split Hopkinson pressure bar method. The results showed that the strength and elastic modulus of 2Y-PSZ/TRIP steel composites at room temperature decreased with the increase of 2Y-PSZ content. The main reason was that the combining strength was quite weak between the grains of ZrO2. Distortion induced martensite transformation and plasticity during the dynamic loading increased the strength and distortion capability of the composites. The transformation was carried out mainly through twins formation. The shape of martensite induced by distortion was lamellate with substructures of twins. The habit plane was near {259}T with no mid-ridge and no explosion phenomena. The interface was straight between the austenite and martensite induced by distortion. The increase of 2Y-PSZ content, on the one hand, made the composite dynamic flow stress improved. Thereby, the fracture strength was improved. On the other hand, it depressed both the distortion capability and the martensite transformation induced by distortion. This resulted in the decrease of dynamic fracture strength.

CYCLIC OXIDATION OF Ni-La_2O_3 COMPOSITE COATINGS ELECTRODEPOSITED ON NICKEL AND Fe26Cr STAINLESS STEEL

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Oxidation Behavior of Fe26Cr1Mo Stainless Steel in the Presence of Ni-La_2O_3 Electrodeposited Composite Film

The oxidation behaviors of Fe26Cr1Mo with and without the Ni La 2O 3 electrodeposited composite film have been investigated by thermogravimetric analysis (TGA) and a scanning electron microscope equipped with an energy dispersive analytical X ray system(SEM/EDAX). The experimental results show that the oxide scale growing on Fe26Cr1Mo exposed at 900 ℃ spalled severely during cooling, while after the stainless steel was coated with the Ni La 2O 3 electrodeposited composite film, its high temperature cyclic oxidation resistance was significantly improved. The reason is that a La 2O 3 modified NiO scale, which has a superior adhesion to the substrate, was formed on the Fe26Cr1Mo stainless steel coated with Ni La 2O 3 composite film.

Surface Modification of AH36 Steel Using ENi-P-nano TiO2 Composite Coatings Through ANN-Based Modelling and Prediction

This study aims to analyse and forecast the significance of input process parameters to obtain a better ENi-P-TiO_(2) coated surface using artificial neural networks(ANN).By varying the four process parameters with the Taguchi L9 design,fortyfive numbers of AH36 steel specimens are coated with ENi-P-TiO_(2) composites,and their microhardness values are determined.The ANN model was formulated using the input and output data obtained from the 45 specimens.The optimal design was developed based on mean squared error(MSE)and R2 values.The experimentally measured values were compared with their predicted values to determine the ANN model’s predictability.The efficiency of the ANN model is evaluated with an R2 value of 0.959 and an MSE value of 34.5634.The authors have concluded that the developed model is suitable for designing and predicting ENi-P-TiO_(2) composite coatings to avoid extensive experimentation with economic production.Scanning Electron Microscope(SEM)and X-ray diffraction analysis(XRD)are also utilised to compare the base metal and optimal coated surface.

湿CO_(2)环境中316不锈钢腐蚀行为研究

针对CO_(2)管输过程中碳钢因发生腐蚀而导致失效的问题,开展了316不锈钢的腐蚀行为研究。使用失重法研究含水率、CO_(2)分压以及Cl-浓度对316不锈钢腐蚀行为的影响,并绘制了腐蚀特征图谱;采用扫描电镜分析了腐蚀产物的微光形貌,X-射线衍射仪分析了腐蚀产物成分。结果表明:316不锈钢在管输CO_(2)工况条件下表现出较好的耐腐蚀性,处于轻度腐蚀状态,腐蚀速率极低;316不锈钢腐蚀速率随含水率的增大而增大,随CO_(2)分压的增大而减小,随Cl-浓度的增加而增大;316不锈钢含有Cr可以在不锈钢表面形成致密的钝化膜,这使得Cr成为不锈钢防腐的关键;由于316不锈钢腐蚀速率远小于碳钢,在腐蚀“重灾区”,可以考虑将集输管道更换成316不锈钢。该研究成果为CCUS中CO_(2)管输钢材的选型提供重要的理论依据。

激光熔覆Co-2%Ti_(3)SiC_(2)复合涂层在不同温度及载荷下的摩擦学性能

为了提高304不锈钢的耐磨减摩性能,采用激光熔覆技术在其表面制备了Co-2%Ti_(3)SiC_(2)复合涂层。通过扫描电镜(SEM)、能谱仪(EDS)和X射线衍射仪(XRD)对Co-2%Ti_(3)SiC_(2)复合涂层的微观结构进行表征,并分析了304不锈钢基体与Co-2%Ti_(3)SiC_(2)复合涂层在等温摩擦实验(25和600℃)中不同载荷(2、5和8 N)下的摩擦学性能和磨损机理。结果表明:Co-2%Ti_(3)SiC_(2)复合涂层主要由γ-Co固溶体,硬质相Fe_(2)C、Cr_(7)C_(3)和TiC及润滑相Ti_(3)SiC_(2)组成。Co-2%Ti_(3)SiC_(2)复合涂层的平均显微硬度为358.61 HV0.5,约是304不锈钢基体(239.32 HV0.5)的1.5倍。在等温摩擦实验中,Co-2%Ti_(3)SiC_(2)复合涂层的磨损率均随着载荷的增加而减少,而摩擦系数在室温下随载荷的增加先增大后减小,在高温(600℃)下随载荷的增加而减小。在不同温度及载荷下,Co-2%Ti_(3)SiC_(2)复合涂层的磨损机理略有不同。

MMFX-2钢筋性能综述和抗腐蚀性现场实验

水泥混凝土桥面钢筋腐蚀是一普遍且复杂的问题,采用替代钢筋能有效地预防或延缓钢筋腐蚀,而近年应用的MMFX-2钢被认为具有更好的抗锈蚀性能。印第安纳州交通厅对现有的MMFX-2钢的研究成果进行了综合分析,并修建了现场试验桥面以长期评价MMFX钢筋抗腐蚀能力。同普通碳钢相比,MMFX-2钢的屈服强度和抗拉强度更高、抗腐蚀性更好,但没有明显的屈服点。试验桥面铺装的实验结果表明,施工竣工不久至竣工两年期间,MMFX-2钢筋腐蚀很少,混凝土中氯化物含量没有达到钢筋去钝化水平,但在桥面铺装上部氯离子浓度显著增加。笔者建议对于氯化物影响较大场合的混凝土桥面铺装,如果希望提供二次腐蚀保护时,可考虑使用MMFX-2钢。

BNi-2+BNi-5复合钎料钎焊316L不锈钢接头界面组织及分析

为克服单独使用BNi-2钎料真空钎焊不锈钢时存在界面化合物多和母材晶界渗入脆化等缺陷,采用在BNi-2钎料中加入高熔点BNi5钎料的方法对316L不锈钢进行真空钎焊研究,主要研究了6种不同比例复合钎料的高温熔化特征、钎焊接头微观组织和钎缝成分分布等内容.研究结果表明复合钎料加热时出现两个熔化区分别是BNi-2钎料熔化区和BNi-5钎料熔化区,当复合钎料的质量比例为60%BNi-2+40%BNi-5时,钎缝内部为固溶体组织和断续的化合物组织,并且此时钎缝附近母材和钎料成分相互作用减弱,晶界渗透现象明显减少.

膨润土-钢渣复合颗粒对Zn^(2+)的去除机理

为了探索酸性矿山废水中重金属离子的高效协同处理方法和开发新型多功能处理材料,采用自行研制的膨润土-钢渣复合颗粒对含Zn^(2+)酸性矿山废水的去除效果和实验现象进行对比实验研究,并利用SEM和XRD进行微观分析,结果表明:该复合颗粒不仅可以释放碱度中和酸,而且对Zn^(2+)的吸附、化学沉淀作用发生于整个反应过程,对Zn^(2+)的平衡去除量可达8.01 mg/g;SEM表面微观分析揭示了复合颗粒表面吸附Zn^(2+)并形成沉淀后还会继续吸附Zn^(2+)并发生聚沉作用,即发生了吸附-聚沉协同作用;XRD微观分析进一步揭示了Zn^(2+)在复合颗粒表面的赋存状态主要以Zn-SiO相结合的矿物相以及Zn_(12)(CO_3)_3SO_4(OH)_(16)聚合沉淀存在。膨润土-钢渣复合颗粒可发挥吸附-聚沉协同作用,是处理含重金属离子酸性矿山废水的优良多功能矿物环保材料。

TiB_2/Cu复合材料作电极点焊镀锌钢板的失效分析

研究了含 Ti B2 为 1.5 %的铜基复合材料 (Ti B2 /Cu)作电极在点焊镀锌钢板时的失效形式 ,结果表明 :Ti B2 /Cu电极在点焊镀锌钢板时的平均使用寿命是 Cu Cr Zr合金电极的 4倍 ,Ti B2 /Cu电极的失效形式主要是表面的合金化 ,少量的细碎翻边、粘附和坑蚀 ,不出现蘑菇状 。

BNi-2+BNi-5复合钎料钎焊不锈钢填缝能力及其组织性能研究

采用在BNi-2钎料中加入高熔点BNi-5钎料的方法对316L不锈钢进行真空钎焊研究,搭接接头头部为自然间隙,尾部加Mo丝确定间隙的方式,着重了解使用复合钎料时钎料的填缝能力。结果表明,复合钎料具有较好的填缝性能,并且钎焊接头在不同位置出现了不同性能的钎缝,在钎缝头部以镍基固溶体为主,随着距离的深入,金属间化合物的含量逐渐增加,显微硬度峰值也逐渐增加。

膨润土-钢渣复合吸附剂对Fe^2+的吸附性能

研究了膨润土-钢渣复合吸附剂对模拟酸性矿山废水中Fe^2+的吸附去除效果、Fe^2+在吸附剂表面的赋存形态及其吸附机理和规律。结果表明:复合吸附剂在处理含Fe^2+模拟酸性矿山废水时,不仅能释放碱性物质中和酸,且发生了吸附-聚沉协同作用;Fe^2+可与膨润土发生晶格置换,还可通过静电吸附作用形成硅酸盐类矿物相,还有一部分通过配合作用生成多金属氧化物,最后一类是通过化学沉淀作用生成的 Fe(OH)2或Fe(OH)3受热分解而形成Fe2O3;被吸附的Fe^2+中98.62%以残渣态形式存在于复合吸附剂中;复合吸附剂对Fe^2+的吸附行为符合BET等温吸附模型和准二级动力学模型。

Cr_(2)O_(3)-Al_(2)O_(3)复合薄膜对304不锈钢抗高温氧化性能的影响

电沉积-热解法沉积氧化物薄膜是提高材料抗高温氧化性能的重要途径。采用电沉积-热解法在304不锈钢表面制备了Cr_(2)O3-Al_(2)O_(3)单一薄膜和复合薄膜,研究了单一薄膜和不同沉积液浓度制备的复合薄膜在900℃下的高温循环氧化行为。氧化动力学曲线、SEM形貌及XRD分析结果表明:电沉积-热解沉积薄膜明显提高了304不锈钢的抗高温氧化性能。Cr(NO3)3与Al(NO3)3酒精溶液摩尔浓度比为2∶1制备的Cr_(2)O3-Al_(2)O_(3)复合薄膜经高温氧化后表面生成了保护性的Cr1.3Fe0.7O3和NiCr_(2)O_(4) 氧化层,其氧化增重和氧化膜剥落量分别是未沉积试样的27.3%和17.6%,抗高温氧化性能最佳。复合薄膜降低了合金表面的氧分压,有利于形成保护性的选择性氧化膜,Cr_(2)O3和Al_(2)O_(3)均具有优异的抗氧化性能,而且Al_(2)O_(3)降低了高温下Cr_(2)O3的挥发,因此显著提高了试样的抗高温氧化性能。

钢水连续测温用BN-AlN-TiB_2复合陶瓷热电偶保护管

首次采用BN -AlN -TiB2 复合陶瓷材料制作的热电偶保护管 ,在中间包钢水中连续使用了 4 .5h ,连续测温与点测值的误差仅为± 2℃ 保护管侵蚀最严重的部分是与钢渣的接触面 ,厚度仅减薄了 2 .5mm 造成保护管侵蚀较少的原因是TiB2 被氧化成TiO2 后阻止了氧化层向内部进一步扩散以及TiB2 ,TiO2

冷作模具钢化学镀Ni-P-SiO_2复合镀层的耐磨性

研究了Ni P SiO2 复合镀层的施镀工艺 ;热处理对复合镀层的硬度、耐磨性的影响。试验结果表明 :含SiO2 微粒可明显改善复合镀层耐磨性。

Zn-SiO_2复合涂层在水介质中的耐冲刷腐蚀性能

渗锌钢不耐冲刷腐蚀 ,其应用受到了限制。在料浆渗锌涂层上采用溶胶 -凝胶法研究了制备SiO2 涂层的过程 ,获得了具有优异抗蚀性能的Zn -SiO2 复合涂层的新技术。EDS和XRD分析证明 ,Zn -SiO2 复合涂层的外层是一层较薄的非晶态SiO2 薄膜 ,内层是与基体结合紧密的由FeZn11,FeZn9,FeZn7相组成的Zn -Fe合金层。在 4 0℃自来水中冲刷腐蚀 10 0h后 ,Zn -SiO2 复合涂层的腐蚀速率约是渗锌层的 1/ 2 0 ,2 0钢的 1/ 170。在 4 0℃ ,3.5 %NaCl溶液中冲刷腐蚀 10 0h后 ,Zn -SiO2 复合涂层仍然保持光泽的表面。电化学测试结果表明 ,渗锌涂层涂覆一层SiO2 薄膜后电极电位大幅度向正方向移动 ,是Zn -SiO2 复合涂层提高抗腐蚀性能的主要原因。

304不锈钢激光熔覆Co-Ti_(3)SiC_(2)自润滑复合涂层微观组织与摩擦学性能

采用激光熔覆同步送粉法在304不锈钢上制备出自润滑耐磨涂层,熔覆粉末配比为纯Co, Co-2%Ti_(3)SiC_(2)(质量分数,下同)和Co-8%Ti_(3)SiC_(2)。借助扫描电子显微镜(SEM),能谱分析仪(EDS)和X射线衍射仪(XRD)对熔覆涂层进行表征,系统地研究304不锈钢与涂层在室温和600℃下的摩擦学性能与磨损机理。结果表明:激光熔覆Co-Ti_(3)SiC_(2)涂层的平均显微硬度高于基体(240.3HV_(0.5)),N1,N2和N3涂层的硬度分别为285.7HV_(0.5),356.3HV_(0.5)和463.8HV_(0.5),涂层主要由连续基体γ-Co固溶体,硬质相Fe2C,Cr7C3和TiC,润滑相Ti_(3)SiC_(2)组成。在室温下,基体和N1,N2,N3涂层的摩擦因数分别为_(0.5)6,0.62,0.68和0.42,N1,N2,N3三种涂层的磨损率分别为9.15×10^(-5),7.81×10^(-5),4.66×10^(-5) mm^(3)/(N·m),均明显低于基体(66.42×10^(-5) mm^(3)/(N·m));在高温下,基体和N1,N2,N3涂层的摩擦因数为0.66,_(0.5)4,_(0.5)2和0.46,N1,N2,N3三种涂层磨损率分别为37.79×10^(-5),35.6×10^(-5),18.83×10^(-5) mm^(3)/(N·m),均低于基体(41.3×10^(-5) mm^(3)/(N·m))。在室温和600℃下,涂层具有高于304不锈钢基体的显微硬度,且Co-8%Ti_(3)SiC_(2)涂层呈现出最好的自润滑耐磨性能。

Q235碳钢表面SiO_(2)/PDMS超疏水涂层的制备及防腐性能研究

目的提高Q235碳钢的耐腐蚀性能。方法在Q235表面先提拉聚二甲基硅氧烷(PDMS),预固化后再次提拉含疏水气相二氧化硅的PDMS分散液,完全固化后在Q235表面构建一个SiO_(2)/PDMS超疏水涂层。通过扫描电镜、激光共聚焦显微镜、能谱、接触角、砂纸磨损、划格试验对涂层的形貌、结构和表面性质进行分析;采用电化学工作站对涂层的耐腐蚀性和耐久性进行评价。结果SiO_(2)纳米粒子被镶嵌在PDMS中,在Q235表面形成了一种微纳粗糙结构,平均粗糙度为2.2μm;涂层表面能仅为5.6 mJ/m^(2),接触角为152.6°;涂层机械稳定性和结合力优异,砂纸磨损15个周期及划格试验30个周期后,仍保持超疏水。电化学研究表明,在Q235表面引入SiO_(2)/PDMS后,阻抗提升了2个数量级,电容降低了6个数量级;腐蚀电位正向移动了0.4192 V,腐蚀电流密度降低了3个数量级;涂层对Q235的防腐效率高达99.8%,呈现出优异的耐腐蚀性。在腐蚀液中浸泡一周后,SiO_(2)/PDMS涂层仍保持超疏水和优异的耐腐蚀性,表明涂层耐久性良好。结论以PDMS为疏水层,纳米SiO_(2)为填料构筑粗糙表面,通过条件控制实现防腐底层和超疏水表层间的界面融合,从而引入稳定的SiO_(2)/PDMS超疏水涂层,提高了Q235的耐腐蚀性和耐久性。本研究为在金属表面构筑稳定的超疏水涂层提供了一种方法,有望拓展金属在恶劣环境中的应用。

基于复合胶凝材料的CO_(2)矿化养护实验研究

研究了粉煤灰-钢渣-水泥复合胶凝材料的水固比、原料配比、养护时间、CO_(2)压力等因素对固碳率和抗压强度的影响。实验结果表明,采用50%钢渣与10%粉煤灰掺比的试件,在剩余水固比w/s=0.25时达到了最高的固碳率和抗压强度。当CO_(2)养护压力由0.2 MPa上升到2 MPa时,固碳率提高了45%。XRD分析表明与自然养护对比,经矿化养护后样品生成了大量碳酸钙;SEM分析观察到矿化养护后矿化产物CaCO_(3)相互交织,填充了孔隙,使微观结构更加致密,因此在矿化养护后样品强度显著增长;孔隙分析揭示矿化养护后试件累计孔容积减小,小于100 nm的孔隙矿物填充更为明显。