Y2O3含量对大气等离子喷涂Al2O3-Y2O3复合涂层微观结构和力学性能的影响

目的 探究掺杂不同质量分数Y₂O₃对Al₂O₃-Y₂O₃复合涂层微观结构及其力学性能的影响。方法 采用大气等离子喷涂制备Al₂O₃涂层,以及Y₂O₃质量分数分别为10%、20%、30%、40%的Al₂O₃-Y₂O₃复合涂层。利用SEM、EDS对粉末以及不同涂层的形貌、组织结构、元素分布进行分析。使用XRD表征粉末和涂层的物相。使用显微硬度仪、纳米压痕测试仪和电子万能试验机对涂层的显微硬度、弹性模量以及断裂韧性等力学性能进行测试分析。结果 Al₂O₃喷涂粉末的物相由α-Al₂O₃组成,而喷涂得到的Al₂O₃涂层则由α-Al₂O     

激光重熔对Al2O3-40% TiO2等离子喷涂层耐冲蚀性能的影响

利用等离子喷涂方法制备Al₂O₃-40% TiO₂涂层,对涂层进行激光重熔处理.分别对等离子喷涂层和激光重熔涂层进行耐冲蚀磨损性能试验,研究了激光重熔对Al₂O₃-40% TiO₂等离子喷涂层耐冲蚀性能的影响.结果表明,激光重熔消除了Al₂O₃-40% TiO₂等离子喷涂层的层状结构,使得等离子喷涂层中γ-Al₂O₃转变为α-Al₂O₃,形成了α-Al₂O₃+TiAl₂O₅稳定结构.激光重熔后的涂层组织致密均匀、硬度高,具有冶金结合特征,使得耐冲蚀性能得到极大提高,其磨损特征为冲蚀粒子冲击作用下产生的裂纹、破碎与块状剥落.     

TiAl合金表面激光重熔MCrAlY涂层热腐蚀性能

采用等离子喷涂技术在TiAl合金表面制备了MCrAlY涂层,并用激光重熔工艺对涂层进行处理,研究了TiAl合金、等离子喷涂MCrAlY涂层及激光重熔MCrAlY涂层850℃下75%Na₂SO₄+25%NaCl(质量分数)混合盐浸泡热腐蚀性能,分析了不同试样的热腐蚀破坏机理,并讨论了激光重熔处理对涂层热腐蚀性能的影响.结果表明,等离子喷涂MCrAlY涂层能显著提高TiAl合金的耐热腐蚀性能,经过激光重熔后可进一步提高其耐热腐蚀性能.MCrAlY涂层在高温熔盐中的热腐蚀发生的是表面氧化反应和内部硫化反应,主要生成Al₂O₃,Cr₂O₃,NiO,NiCr₂O₄,Ni₃S₂及CrS等腐蚀产物.     

一种可内生Al2O3扩散障的δ-Ni2Al3-Cr2O3/ Ni-Cr2O3涂层体系

通过对Ni-Cr₂O₃复合镀层620 ℃部分渗铝制备了δ-Ni₂Al₃-Cr₂O₃/Ni-Cr₂O₃涂层体系。Cr₂O₃颗粒在渗铝的过程中和Al反应生成更为稳定的Al₂O₃。1000 ℃恒温氧化20 h后发现,铝化物涂层和复合镀层内掺杂的Cr₂O₃颗粒完全转化为Al₂O₃,并在铝化物涂层/Ni镀层界面自发形成了一层Al₂O₃富集层,该富集层起扩散障作用,阻碍铝化物涂层因互扩散所致的退化。     

热喷涂TiB2-Ni复合涂层组织结构和力学性能

采用团聚烧结方法制备TiB₂-Ni复合粉末喂料,并采用大气等离子喷涂和高速火焰喷涂两种喷涂方法制备了TiB₂-Ni涂层,比较分析了两种涂层的显微组织、物相组成、孔隙率、硬度和断裂韧性.结果表明,与等离子喷涂相比,高速火焰喷涂制备的TiB₂-Ni涂层具有更高的致密度,TiB₂含量,硬度和断裂韧性.两种涂层中TiB₂都没有发生明显的脱硼,氧化,但等离子喷涂过程中TiB₂向金属相中发生了溶解生成了大量脆性Ni₂₀Ti₃B₆相,并降低了涂层中TiB₂的含量,这是涂层硬度和断裂韧性相对较低的主要原因.     

NiCoCrAlY/Al2O3复合涂层的组织与性能

采用离子喷涂和超音速火焰喷涂技术分别制备了NiCoCrAlY/Al₂O₃耐磨复合涂层,通过SEM、显微硬度计和万能材料测试机研究了粉体和涂层的显微结构、显微硬度和结合强度。结果表明,Al₂O₃颗粒表面包覆着一层致密的NiCoCrAlY合金,涂层与基体结合良好,超音速火焰喷涂涂层的孔隙率仅为等离子喷涂涂层的1/7。超音速火焰喷涂涂层的显微硬度和结合强度均高于等离子喷涂涂层。两种方法制备的涂层的破坏属脆性断裂机理。     

CeO2/ZrO2-Y2O3纳米结构热障涂层的高温稳定性及耐腐蚀性能

采用等离子喷涂方法（APS）在GH30高温合金表面分别制备了纳米ZrO₂-8%Y₂O₃（YSZ,质量分数）和掺杂25%（质量分数）纳米CeO₂的三元CeO₂/ZrO₂-8%Y₂O₃（CSZ）热障涂层.使用FESEM和XRD分析了涂层的微观组织,研究了CSZ涂层在1100℃加热条件下分别保温不同时间及固定加热时间10 h,改变加热温度时涂层晶粒尺寸的变化情况,测试了2种涂层在高温下的耐Na₂SO₄熔盐腐蚀能力.结果表明,CSZ涂层在高温长时间加热时,平均晶粒尺寸从喷涂态的45 nm增至63 nm,变化较小,在900℃,Na₂SO₄熔盐腐蚀条件下长时间加热无m-ZrO₂相析出,耐蚀性能要高于YSZ涂层.     

等离子喷涂NiCoCrAlYTa-Al2O3复合涂层的高温摩擦性能

采用大气等离子喷涂(APS)技术在0Cr25Ni20奥氏体不锈钢表面制备了NiCoCrAlYTa-Al₂O₃涂层,并对该涂层的显微组织、相组成、显微硬度以及在500 ℃时涂层的高温摩擦性能进行了研究。结果表明,NiCoCrAlYTa-Al₂O₃涂层呈典型层状结构,各层间结合良好。涂层内存在大量微孔隙,且硬质相与软质相分散分布,有效抑制了高温磨擦过程中裂纹的产生和扩展,涂层耐磨性能较奥氏体不锈钢基体材料显著提高。高温磨损过程中,涂层表面形成氧化产物,起到固体润滑作用。NiCoCrAlYTa-Al₂O₃涂层的磨损失效形式主要是磨粒磨损、疲劳磨损和粘着磨损。     

铝镁合金等离子喷涂复相陶瓷涂层微观组织

为解决铝镁合金表面耐磨性差的问题,利用机械球磨法和PVA造粒技术制备复合陶瓷粉末,采用等离子喷涂技术在XGFH-3铝镁合金表面制备了反应复相陶瓷涂层,利用扫描电镜(SEM)、X射线衍射仪(XRD)分析了喷涂复合粉末和复相陶瓷涂层的形貌及组成.结果表明,复合粉末随着球磨时间的延长明显趋于扁平化和均匀化,并且生成了Al₃Ti,Ni₄Ti₃等新相.而在喷涂过程中Al₃Ti和Ni₄Ti₃中间相又会消失,涂层中出现了MgAl₂O₄和Ti₅Si₃等新相,基体和涂层之间有元素扩散,这使得涂层有良好的结合强度.     

Fe基非晶/纳米晶涂层的微结构及其在H2O2溶液中的腐蚀性能

为研究强氧化环境中,显微结构和相组成对Fe基非晶/纳米晶复合涂层的腐蚀腐蚀性能的影响,采用大气等离子喷涂(APS)技术,在1Cr18Ni9Ti不锈钢基体上喷涂制得具有不同微结构和相组成的Fe基非晶/纳米晶的复合涂层。采用XRD、SEM、TEM和DSC等检测方法对涂层的组织和相组成、晶化行为、晶化程度、内部的孔隙等微观结构进行表征。采用电化学法研究具有不同微结构和相组成的涂层在30%H₂O₂ (质量分数,下同)溶液中的腐蚀行为,探讨Fe基非晶/纳米晶复合涂层在强氧化环境中的腐蚀机理。研究表明,Mo₃Si和Fe₅Si₃相的形成使得涂层耐腐蚀性能明显降低。     

In Situ Synthesis of FeAl Dense Coatings by Very Low Pressure Reactive Plasma Spraying

With the purpose of elaborating high-quality FeAl coatings, a so-called very low pressure reactive plasma spray technique that combines very low pressure plasma spray and self-propagation high-temperature synthesis processes was used in the present study. A dense and homogeneous FeAl coating was thus successfully in situ synthesized by reactive plasma spraying of an Al/Fe₂O₃ composite powder under 1 mbar. The phase composition and microstructural features of the coating were characterized by XRD and SEM. Results indicated that the B2 ordered FeAl phase was synthesized, and the coating featured a dense and defect-free microstructure. The fracture mechanism of the coating remains mainly a brittle failure but the appearance of some dimples in local zones suggested some unexpected toughness.     

低气压等离子喷涂TiO2涂层结构的研究

本研究分析了在低气压等离子喷涂条件下,TiO_2涂层的结构受等离子弧喷涂过程中氧分解量所影响。氧分解量很大程度上依赖于离子气中氢流量的大小,此外喷涂室压力也有一定影响。而等离子弧功率和喷涂距离对TiO_2涂层的氧分解量没有多大影响。在离子气中氢流量不变的条件下,涂层中Ti_3O_5量随喷涂室压力(从100×133.322Pa至400×133.322Pa)增加而增加。     

Reactive Plasma Spraying of Fine Al2O3/AlN Feedstock Powder

Reactive plasma spraying (RPS) is a promising technology for in situ formation of aluminum nitride (AlN) coatings. Recently, AlN-based coatings were fabricated by RPS of alumina (Al₂O₃) powder in N₂/H₂ thermal plasma. This study investigated the feasibility of RPS of a fine Al₂O₃/AlN mixture and the influence of the plasma gases (N₂, H₂) on the nitriding conversion, and coating microstructure and properties. Thick AlN/Al₂O₃ coatings with high nitride content were successfully fabricated. The coatings consist of h-AlN, c-AlN, Al₅O₆N, γ-Al₂O₃, and a small amount of α-Al₂O₃. Use of fine particles enhanced the nitriding conversion and the melting tendency by increasing the surface area. Furthermore, the AlN additive improved the AlN content in the coatings. Increasing the N₂ gas flow rate improved the nitride content and complete crystal growth to the h-AlN phase, and enhanced the coating thickness. On the other hand, though the H₂ gas is required for plasma nitriding of the Al₂O₃ particles, increasing its flow rate decreased the nitride content and the coating thickness. Remarkable influence of the plasma gases on the coating composition, microstructure, and properties was observed during RPS of the fine particles.     

Study of Al2O3 coatings on AISI 316 stainless steel obtained by controlled atmosphere plasma spraying (CAPS)

The tribological behaviour of Al₂O₃ coatings on AISI 316 stainless steel, obtained by the process of controlled atmosphere plasma spraying (CAPS), is studied in this work. Atmospheric plasma spraying (APS) and high pressure plasma spraying (HPPS) were applied in order to produce these coatings. The APS coatings exhibited lower microhardness values compared to the values of HPPS coatings. Regarding the HPPS coatings it was found that plasma composition, through its heat capacity, does influence the heat transfer to particles, and, consequently, their flattening and densification process, which govern coating properties. It was revealed that tribological behaviour of coatings was influenced by the applied spraying method too. Coatings from HPPS under high-enthalpy conditions led to worst wear behaviour. In general, properties, such as microstructure, microhardness, coefficient of friction and wear resistance depended on the processing conditions such as pressure and composition of the spraying chamber atmosphere.     

In-situ TiB2 and Al2O3 formation by DC plasma spraying

In-situ plasma spraying (IPS) is a promising process to fabricate composite coatings with in-situ formed thermodynamically stable phases. In the present study, mechanically alloyed Al-12Si, B₂O₃ and TiO₂ powder was deposited onto an aluminum substrate using atmospheric plasma spraying (APS). It has been observed that, during the coating process, TiB₂ and Al₂O₃ are in-situ formed through the reaction between starting powders and finely dispersed in hypereutectic Al-Si matrix alloy. Also, obtained results demonstrate that in-situ reaction intensity strongly depends on spray conditions.     

反应等离子喷涂 Al2O3-TiB2-Al 复相涂层的反应机理

目的在铝合金表面制备Al2O3-TiB2-Al复合涂层,研究Al,TiO2,B2O3在等离子喷涂中的反应机理。方法采用反应等离子喷涂技术在铝合金表面制备复合涂层,应用扫描电镜与X射线衍射技术测试复合涂层的物相组成和显微组织,并通过燃烧波淬熄试验分析等离子喷涂产物。结果机械球磨可以有效降低粉末发生反应的活化能,等离子喷涂最佳飞行距离范围为150~200 mm。结论喷涂粉末在飞行过程中发生反应,经历了预热、熔化、分解、团聚等过程,验证了最终引燃发生燃烧化学反应的机理。     

等离子喷涂制备ZrB2/SiC/Ta2O5涂层抗烧蚀性能研究

为了提高C/C复合材料的抗烧蚀性能,通过等离子喷涂法在C/C表面制备了SiC/Al₂O₃内层和ZrB₂/SiC/Ta₂O₅外层的双层涂层,通过XRD,SEM和EDS分析了涂层烧蚀前后的物相组成、微观结构和成分分布。烧蚀前涂层表面没有裂纹并且内层与基体、内层与外层之间结合良好。元素Zr、Si、Ta在涂层表面的分布相近,涂层表面成分分布均匀性良好。通过氧乙炔火焰在1800 ℃下对涂层的抗烧蚀性能进行考核。烧蚀过程中形成的镶嵌结构有利于阻挡氧气的渗入,Ta-Si-O玻璃层的形成封填了涂层孔隙,对基体有良好的保护效果,涂层表现出了较好的抗烧蚀性能。     

Structural, Mechanical and Erosion Properties of Yttrium Oxide Coatings by Axial Suspension Plasma Spraying for Electronics Applications

Yttrium oxide (Y₂O₃) coatings have been prepared by axial suspension plasma spraying with fine powders. It is clarified that the coatings have high hardness, low porosity, high erosion resistance against CF₄ -containing plasma and retention of smooth eroded surface. This suggests that the axial suspension plasma spraying of Y₂O₃ is applicable to fabricating equipment for electronic devices, such as dry etching. Surface morphologies of the slurry coatings with splats are similar to conventional plasma-sprayed Y₂O₃ coatings, identified from microstructural analysis. Dense coating structures with no lamellar boundaries have been seen, which is apparently different from the conventional coatings. It has also been found that crystal structure of the suspension coatings mainly composed of metastable monoclinic phase, whereas the powders and the conventional plasma spray coatings have stable cubic phase. Mechanism of coating formation by plasma spraying with fine powder slurries is discussed based on the results.     

Thermal conductivity and thermal cycle life of La2O3 and HfO2 doped ZrO2-Y2O3 coatings produced by EB-PVD

The effects of La₂O₃ and HfO₂ addition on thermal conductivity and thermal cycle life of EB-PVD YSZ coatings were investigated. La₂O₃ and HfO₂ were selected as additives, because they significantly suppress the sintering of YSZ. The developed coating showed low thermal conductivity as well as high resistance to sintering. Burner rig tests confirmed that the developed coating have a superior thermal insulating effect and have a longer life than that of a coating with conventional composition.     

超音速等离子喷涂工艺参数对 Cr2O3涂层硬度的影响

目的研究影响超音速等离子喷涂Cr2O3涂层硬度的主要因素,制备出高硬度涂层。方法首先采用单变量法研究超音速等离子生成气体压力(空气压力)和喷涂距离对涂层显微结构的影响,然后采用正交试验研究喷涂电流、空气压力、喷涂距离对Cr2O3涂层硬度的影响。结果工艺参数对Cr2O3涂层硬度影响的主次顺序为:空气压力>喷涂电流>喷涂距离。结论获得高硬度涂层的最佳工艺参数组合为:空气压力0.4 MPa,喷涂电流270 A,喷涂距离200 mm。在该工艺条件下获得的涂层致密、均匀,孔隙率小。