High temperature oxidation resistance of plasma sprayed NiCrAl+(ZrO_2+Y_2O_3) gradated coating on stainless steel surface

The plasma sprayed gradated coating with the bottom layer of NiCrAl and the top layer of(ZrO2+Y2O3) was prepared by the plasma spraying technique. The phase structure and morphology of the gradated coating were analyzed by means of X-ray diffractometry(XRD) and scanning electron microscopy(SEM). The high temperature oxidation resistance of the plasma sprayed samples at 800 ℃ was investigated. The oxidation kinetics curve was obtained. The results show that the thickness of gradated coating is about 410 μm. The plasma sprayed gradated coating on stainless steel surface can improve the high temperature oxidation resistance of stainless steel. The oxidation rate of stainless steel is less than that of plasma sprayed gradated coating. The oxidation film of plasma sprayed sample is very dense and is not easily exfoliated. The dense oxidation film prevents the stainless steel from more oxidation.

Preparation and Properties of High Hardness and Oxidation Resisting Coating Using Electric Arc Spray

A coating with high hardness, wear and oxidation resistance was prepared by electric arc spray. The hardness, bonding strength, abrasive wear and values of porosity and oxidation resistance of the coating were investigated. The microstructures and function of Cr3C2 of the coating were analyzed. The results showed surface Rockness Hardness HR30 reached 72.5 and average bond strength reached 49.1Mpa. Also porosity value was less than 2%. In addition, it was found from the comparison between the coating and 45CT coating that, oxidation resistance of the coating was less than that of 45CT, but the abrasive wear of the coating was obvious better than that of 45CT.

Preparation of aluminide coatings at relatively low temperatures

A method was presented to prepare aluminide coatings on metals by combining the pack aluminizing with the ball impact process. This technique applied mechanical vibration to a retort, which was loaded with pack-aluminizing powder, specimens and alloy balls. Pack aluminizing was carried out with repeated ball impact, which accelerated chemical reactions and atomic diffusion. Aluminide coatings were formed at a relatively lower temperature (below 600 ℃) and in a shorter treatment time, compared with the conventional pack aluminizing. The effects of the operation temperature and the treatment time on the formation of the coatings were analysed. The SEM, EDS and XRD analysis results show that the aluminide coatings appear to be homogeneous, with a high density and free of porosity, and have excellent adherence to the substrate. The coatings mainly consist of Al-rich phases such as η-Fe2Al5, θ-FeAl3 and ?CrAl5. Oxidation resistance was studied by high-temperature tests. The formation mechanism of the Al-coatings was also investigated. This technique provides a new approach for industrial diffusion coatings with great energy and time savings.

Morphology and structure of high temperature MoSi_2 coating on niobium

The high-temperature oxidation-resistant MoSi2 coating on the Nb substrate was prepared by slurry firing. The structure, compositions and phase distribution of the coating and the relationship between these features and the oxidation resistance of the coating were investigated by SEM, EDS and XRD. The results indicate that the interface between the coating and the substrate has metallurgic combination, and a transitional layer is formed by diffusion. The multi-layer structure improves the oxidation resistance of the coating. The method of slurry firing to prepare the high-temperature MoSi2 coating on Nb is feasible. The SiO2 scale, which is formed on the surface of the coating by the self-oxidation of MoSi2, prevents the further diffusion of oxygen.

Study on High Temperature Corrosion Performance and Protective Coatings of Mo-containing Intermetallic Alloy IC6

Oxidation and hot corrosion behaviors of Ni3Al-Mo （IC6） alloy were studied. Surface protective coatings were also developed for the engineering application of the alloy. The sputtered NiCrAlY coating may greatly improve the oxidation and hot corrosion resistance of IC6 alloy by forming a protective Al2O3 scale, and the coating shows little effect on the mechanical properties of IC6 alloy.

Microstructure and corrosion resistance of sputtered TiN coatings on surface of Zr-4 alloy

To improve the oxidation resistance and corrosion resistance of Zr-4 alloy, titanium nitride(TiN) coatings were prepared on the Zr-4 alloy with a TiN ceramic target with different ratios of N_2. Microstructure and high-temperature properties of the TiN coated samples were studied by scanning electron microscopy(SEM), energy dispersive spectrometer(EDS), X-ray diffraction meter(XRD), X-ray photoelectron spectroscopy(XPS), heat treatment furnace and autoclaves, respectively. The x value of the TiN coatings(TiN_x) ranges from 0.96 to 1.33. After the introduction of N_2, TiN coating exhibits a weak(200) plane and a preferred(111) orientation. The coating prepared with an N_2 flow ratio of 15% shows an optimal oxidation resistance in the atmospheric environment at 800 °C. In either 1 200 °C steam environment for one hour, or deionized water at 360 °C and a pressure of 18.6 Mpa for 16 d, the opitimized TiN coated samples have no delamination or spallation; and the gains in the masses of samples are much smaller than Zr-4 alloy. These results demonstrate the effectiveness of the optimized TiN coating as the protective coating on the Zr-4 alloy under extreme conditons.

Thermodynamic principle and properties of electroplated RE-Ni-W-P-B_4C composite coatings

The -pH diagram of Ni-W-P-H2O system at 298.15 K,10 1325 Pa was plotted by thermodynamic calculation software FactSageTM 5.1. The results show that tungsten and phosphorus can be co-deposited with nickel in type of Ni4W,Ni3P,Ni5P2,respectively. XRD analysis shows that the main phase of RE-Ni-W-P-B4C coatings is amorphous as deposited. After heated at 673 K for 3 h,part phases change to crystalline which are Ni,Ni3P,P,W,Ni3C,Ni3B,CeO2. SEM shows the micrograph of the coatings is even and the solid particles scatter well. The thickness of the coating is 2 219 μm after electroplating for 96 h. The micro-hardness of the coatings is HV 825-HV 1 097 as-deposited and increases to HV 1 236 after heat treated. The wear resistance of the coatings is good and the friction coefficient changes from 0.10 to 0.33 during the abrasion process. The resistance to oxidation of the composite coatings is better than Ni-W-P alloy coatings and worse than that of RE-Ni-W-P-SiC coatings.

镀铝对CoCrNiAlY-YSZ-LaMgAl_(11)O_(19)双陶瓷热障涂层高温抗氧化行为的影响

采用电弧离子镀(AIP)技术在CoCrNiAlY-YSZ-LaMA双陶瓷涂层表面沉积一层Al镀层,利用XRD、SEM和EDS等微尺度分析表征方法,全面解析涂层在大气暴露过程中的高温氧化行为。研究结果表明,未镀铝LaMA层在氧化过程中发生严重体积收缩,导致纵向微裂纹萌生和扩展。这些微裂纹成为氧气向内部扩散的通道,导致涂层呈现持续氧化增重趋势、TGO快速生长和严重的元素扩散,并最终加剧涂层断裂失效。但镀铝涂层样品表现出更好的高温抗氧化性能与结构稳定性,高温氧化过程中,表面Al镀层与氧气发生原位反应生成致密Al2O3屏障层,有效阻止或延迟氧气内部渗透,使TGO缓慢生长,其氧化增重从20h时的8.59mg/cm^(2)略微上升到80h时的9.46mg/cm^(2)。本研究结果为双陶瓷热障涂层的延寿设计与界面热生长应力调控开辟出全新技术途径和理论视野。

不锈钢表面Al/Cu涂层制备与第一性原理计算

为了研究Al/Cu涂层中金属间化合物的生成顺序和形成机理,在304不锈钢基体表面制备了Al/Cu涂层。对试样进行热处理使得Al/Cu涂层原位反应生成金属间化合物,随后测试了涂层的高温抗氧化性能。采用第一性原理计算Al-Cu金属间化合物的焓、熵、吉布斯自由能和热容等数据。将热力学和扩散动力学相结合,提出有效生成自由能模型来预测化合物在Al/Cu界面的生成顺序。结果表明:Al/Cu涂层中首先形成Al_(2)Cu相,在Al/Cu界面处出现了AlCu相,加热时间增加至20 h后出现了富Cu的Al_(4)Cu_(9)相。由第一性原理计算得出,Al-Cu金属间化合物的形成顺序为Al_(2)Cu→AlCu→Al_(4)Cu_(9),与实验结果一致。此外,氧化实验结果表明,涂层具有良好高温抗氧化性能。

结构钢电沉积Co-W/CeO_(2)复合镀层及其性能研究

选择CeO_(2)颗粒作为复合相,利用电沉积技术在普通结构钢表面制备出Co-W/CeO_(2)复合镀层,并研究镀液中CeO_(2)颗粒浓度对复合镀层的微观形貌、化学成分、结合力、硬度、耐磨性能以及高温抗氧化性能的影响。结果表明:Co-W/CeO_(2)复合镀层与基体结合牢固,表面分布着类似胞状的晶粒团聚体,其化学成分为Co、W、Ce和O元素。随着镀液中CeO_(2)颗粒浓度从2 g/L升高到15 g/L,复合镀层的晶粒团聚体尺寸差异先减小后增大,吸附在晶粒团聚体表面及边界处的CeO_(2)颗粒量先增多后减少,导致复合镀层的硬度、耐磨性能和高温抗氧化性能都呈先增强后下降的趋势。当镀液中CeO_(2)颗粒浓度为8g/L时,Co-W/CeO_(2)复合镀层的晶粒团聚体大小较为均匀,具有良好的致密性,其表面粗糙度仅为0.39μm。该复合镀层的硬度较Co-W合金镀层增大约76 HV,表现出良好的耐磨性能和高温抗氧化性能,摩擦系数和氧化增重量仅为0.43和0.74mg/cm^(2)。

γ-TiAl基合金用Al_(2)O_(3)-SiC-AlPO_(4)复合涂层抗高温氧化性能研究

目的通过表面涂层提高γ-TiAl基合金的抗高温氧化性能。方法采用常规喷涂涂料法在γ-TiAl合金基体上制备Al_(2)O_(3)-SiC-AlPO_(4)磷酸盐复合抗高温氧化涂层。研究γ-TiAl合金和涂层样品在900℃、静态空气条件下的准等温氧化动力学行为。用XRD和SEM/EDS分别对涂层样品氧化前后的物相组成、组织形貌和微区成分进行表征分析;用电子探针(EPMA)分析涂层样品的元素分布情况。结果900℃恒温氧化动力学研究结果表明,γ-TiAl基合金初期氧化速率常数为32.501×10^(-2)mg/(cm^(2)·h^(1/2)),与后期氧化速率常数28.113×10^(-2)mg/(cm^(2)·h^(1/2))基本接近,呈直线规律,不具有抗氧化性能;而Al_(2)O_(3)-SiC-AlPO_(4)磷酸盐复合涂层样品氧化后期氧化速率常数为5.967×10^(-2) mg/(cm^(2)·h^(1/2)),与氧化初期8 h内氧化速率常数23.941×10^(-2) mg/(cm^(2)·h^(1/2))相比,明显降低,遵循典型抛物线规律,具有抗氧化性能。微观分析结果表明,原始涂层与γ-TiAl合金基体结合紧密,涂层主要相组成为Al_(2)O_(3)、SiC、SiO_(2);AlPO_(4)以无定形状态构成涂层连续相。氧化后,AlPO_(4)演变成晶态,形成涂层致密的网络结构;部分基体钛元素扩散进入涂层中疏松部位,氧化后形成TiO_(2)弥散分布在涂层中,填补了涂层疏松部位,使涂层更加致密;在涂层与基体界面2μm区域内形成连续致密Al_(2)O_(3)膜,阻挡了空气中的氧进一步扩散进入基体。结论Al_(2)O_(3)-SiC-AlPO_(4)复合涂层有效降低了γ-TiAl基合金氧化速率,有助于形成保护性Al_(2)O_(3)膜,明显改善了900℃γ-TiAl基合金抗高温氧化性能。

异质双丝超音速电弧喷涂涂层的高温氧化行为和机理研究

目的采用异质双丝和同质双丝制备3种超音速电弧喷涂铁基涂层,对比研究3种防护涂层在700℃下的抗高温氧化性能。方法采用光学显微镜(OM)、扫描电镜(SEM)、能谱仪(EDS)和X射线衍射仪(XRD)对在700℃高温氧化前后涂层的微观结构、表面形貌和化学成分以及物相组成进行表征和分析。采用Matlab软件对涂层的孔隙率进行测定,采用显微硬度计测量涂层的显微硬度。结果制备得到的3种涂层的孔隙率均低于10%,满足电弧喷涂的要求。3种涂层的显微硬度均达到了400HV以上,其中FeAlCrMoVC/FeAlNiMoCrC涂层的孔隙率最低、显微硬度最高,分别为5.00%和456.91HV。在700℃循环氧化下,FeAlCrMoVC、FeAlNiMoCrC和FeAlCrMoVC/FeAlNiMoCrC涂层的单位面积氧化增重分别为10.67、3.32和2.02mg/cm^(2)。它们的氧化动力学符合经典的抛物线规律,抛物线速率常数(kp)分别为3.08×10^(-10)、2.20×10^(-11)和5.60×10^(-12)g^(2)·cm^(-4)·s^(-1)。从高温氧化后涂层的扫描电镜图观察到,异质双丝法制备的涂层表面氧化膜主要由3种致密形貌组成,结合EDS和XRD分析,推断它们主要由Fe_(3)O_(4)、Fe_(2)O_(3)、Cr_(2)O_(3)和Al_(2)O_(3)以及尖晶石结构的NiCr_(2)O_(4)组成。截面分析发现,异质双丝制备的FeAlCrMoVC/FeAlNiMoCrC涂层的内氧化和表面氧化膜厚度最小,分别约为5.3、24.7和118.2μm。结论涂层的内氧化从孔隙和氧化夹杂物等缺陷开始,而生成的致密氧化物能够提高涂层的抗氧化性。超音速电弧喷涂制备的3种涂层都具有良好的抗高温氧化性能,而异质双丝法制备的FeAlMoCrC/FeAlNiMoCrVC涂层的抗高温氧化性能更好。

石墨模具耐高温抗氧化涂层制备工艺研究

针对生产过程中石墨模具在高温时易氧化的问题,开展石墨模具耐高温抗氧化涂层的研究,以提高石墨模具的使用性能。采用等离子喷涂技术在石墨基体上制备Si层,利用金相显微镜、X射线衍射仪、扫描电子显微镜表征界面显微结构,并利用拉伸试验机测试界面结合力,研究涂层厚度、后处理加热温度和保温时间对Si层的影响。实验结果表明:当涂层厚度为0.03 mm时,经1380℃保温6 h后,能够形成均匀连续的过渡层,涂层有较好的结合强度和力学性能,且可以保护基体长达16 h不被严重氧化。

高温抗氧化涂料石墨电极在LF炉上应用初探

石墨电极作为LF炉炼钢中的重要原料,起着导电、加热、增碳、调质等作用,其消耗对电炉炼钢的成本、质量影响较大。本文从石墨电极的品级、影响因素、损耗机理等方面,分析了降低消耗的条件,然后以高温抗氧化涂料的作用机理、使用方法和节约价值等方面为切入点,结合产品的具体使用效果进行讨论,希望对石墨电极的生产和使用有所借鉴。

熔烧温度对铌钨合金表面硅化物涂层显微组织和抗高温氧化性能的影响研究

硅化物涂层是航天航空用铌合金高温结构部件最常用的高温防护涂层,为了提高硅化物涂层的性能以满足铌合金高温结构部件越来越严苛的服役条件,采用料浆熔烧法在铌钨合金表面制备硅化物涂层,并通过改变涂层熔烧温度(1350,1400,1450,1500℃),研究熔烧温度对涂层微观结构和抗高温氧化性能的影响。结果表明:4种熔烧温度涂层致密层的主成分为(Nb,X)Si_(2)(X为Zr、Cr和Ti),过渡层为稳定的Nb_(5)Si_(3);涂层在1600℃高温下氧化2 h,氧化反应主要发生在表面的疏松层,Si、Zr、Ti、Cr等元素发生了选择性氧化,ZrO_(2)作为“氧化物钉”弥散在SiO_(2)玻璃膜中,涂层展现出良好的抗高温氧化性能。熔烧温度为1350℃样品的抗高温氧化性能最优。

Cf/SiC复合材料表面抗氧化涂层研究进展

Cf/SiC复合材料因其低密度,高比强度,优异的抗热震、抗氧化和抗烧蚀性能以及高温强度保持率,被认为是高速飞行器的重要热防护材料之一。然而,由于碳纤维在500℃以上发生显著氧化导致材料逐渐失效,因此需对其进行有效的氧化防护。抗氧化涂层被认为是实现Cf/SiC复合材料长时氧化防护的有效手段。本文基于热防护系统对Cf/SiC复合材料抗氧化性能的苛刻要求,综述了现有Cf/SiC复合材料表面抗氧化涂层的研究进展,着重对抗氧化涂层制备技术及涂层体系进行了梳理。提升Cf/SiC复合材料抗氧化涂层使用温度(≥1800℃)及结合强度是当前需要重点解决的问题,制备更长服役时间、更高服役温度同时兼具抗氧化、抗水蒸气腐蚀乃至较好隔热性能的多功能涂层是未来发展的重要方向。

激光熔覆高熵合金涂层组织结构及强化机理研究进展

激光熔覆作为一种绿色、高效的表面处理技术,能够快速制备组织致密、晶粒细小,与基体呈高强度冶金结合的涂层,是近年来高熵合金领域的研究热点之一。概述了现有高熵合金涂层材料体系和制备方法,重点讨论了激光熔覆CoCrFeNi-M典型过渡族高熵合金涂层的组织结构,及其耐磨、耐蚀、抗高温氧化等性能,并归纳了涂层的强化机制和方法。CoCrFeNi-M系合金涂层主要呈现FCC固溶体结构,综合力学性能普遍较好,通过合金体系调控,在细晶强化、固溶强化、第二相强化等作用下,能够获得硬度、耐磨性、耐蚀性等性能的进一步提升。同时,概述了激光熔覆难熔高熵合金涂层的组织结构,耐磨、耐蚀、抗高温氧化性能及性能强化机制,该体系合金涂层主要呈现BCC固溶体结构,硬度较高但室温韧性普遍不足,具有较好的高温强度,在高温领域具有较好的应用前景,但抗高温氧化性能普遍不足,仍需通过合金体系优化进一步提升。此外,总结了基于激光熔覆技术开展的高熵合金涂层制备及研究中存在的问题和不足,并展望了未来的发展方向。

钼及钼合金表面高温防护涂层的研究进展

系统总结了国内外关于钼及钼合金表面高温防护涂层的最新研究成果,分析了钼在不同温度区间的氧化特征,并基于涂层组织结构稳定性、涂层缺陷、涂层与基体界面结合强度、界面物理和化学相容性、氧扩散等多方面,概述了钼及钼合金表面高温防护涂层的性能要求。归纳了现阶段应用于钼及钼合金表面的高温防护涂层体系,主要包括单一硅化物涂层、改性的硅化物涂层、硅化物基梯度复合涂层、铝化物涂层、耐热合金涂层和氧化物涂层,重点讨论了涂层的成分和结构对其抗高温氧化性能的影响。同时,对比介绍了钼及钼合金表面高温防护涂层常用的制备方法,主要包括料浆烧结法、包埋渗法、等离子喷涂法、熔盐法、化学气相沉积法、磁控溅射法等。最后,对钼及钼合金表面高温防护涂层现阶段存在的问题及未来发展方向进行了展望。

粉末冶金靶材多弧离子镀HY3涂层抗氧化性能

目的研究靶材制备工艺对多弧离子镀(Arc ion plating,AIP)MCrAlY涂层抗氧化性能的影响。方法采用粉末冶金方法制备NiCrAlYSi(HY3)靶材,然后采用AIP在DZ125合金基体上制备HY3涂层。在1100℃下对粉末冶金靶材制备涂层进行200 h的静态氧化实验,采用SEM、XRD等对靶材和氧化前后的涂层进行微观组织分析,并与传统铸造靶材进行对比。结果采用粉末冶金方法制备的靶材成分更加均匀,相尺寸约为5μm,相较于铸造靶材降低了1个数量级。采用粉末冶金靶材制备的涂层(P涂层)元素分布更均匀、β相含量更高。经过1100℃、200 h的高温氧化,P涂层的氧化增量为1.01 mg/cm^(2),低于铸造靶材制备的涂层(C涂层,1.10 mg/cm^(2))。在200 h后,P涂层表面的热生长氧化物(TGO)完整,而C涂层表面的TGO出现了剥落现象,P涂层的活性元素均匀分布,促进TGO内生成了少量弥散分布的钉扎氧化物Y_(2)Hf_(2)O_(7),提高了TGO的抗剥落能力。更高的β相含量促进了氧化初期θ-Al_(2)O_(3)的快速生成,有利于P涂层生成保护性能更好的TGO。结论粉末冶金靶材成分的均匀性优于传统铸造靶材,采用粉末冶金靶材制备的HY3涂层的抗高温氧化性能优于铸造靶材制备的HY3涂层。