Preparation and hot corrosion behaviour of an Al-gradient NiCoCrAlYSiB coating on a Ni-base superalloy

Zhang, Bao; Wang, Q.M.; Li, W.Z.; Liu, X.; Gong, Jun; Xiong, Tao; Sun, Chao

doi:10.1016/j.corsci.2009.01.003

Cited by 110 publications

(22 citation statements)

References 28 publications

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“…The morphology looks similar in all three cases. Similar morphological features are also reported during hot corrosion of MCrAlYSiB (M=Ni or Co) coated superalloys [35,36]. Though the coatings look like broken scales (plate like morphology), there was no spalling of the scales.…”

Section: Ti 31supporting

confidence: 78%

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr₃C₂-25(Ni20Cr)) + NiCrAlY Coating

Jegadeeswaran¹,

Рамеш²,

Bhat³

2013

International Journal of Corrosion

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High velocity oxy fuel process (HVOF) is an advanced coating process for thermal spraying of coatings on to components used in turbines. HVOF process is a thermal spray coating method and is widely used to apply wear, erosion, and corrosion protective coatings to the components used in industrial turbines. 25% (Cr 3 C 2-25(Ni20Cr)) + NiCrAlY based coatings have been sprayed on to three turbine materials, namely, Ti-31, Superco-605, and MDN-121. Coated and uncoated substrates were subjected to hot corrosion study under cyclic conditions. Each cycle consisted of 1 hour heating at 800 ∘ C followed by 20 minutes air cooling. Gravimetric measurements were done after each cycle and a plot of weight gain as a function of number of cycles is drawn. Parabolic rate constants were estimated for the understanding of corrosion behaviour. It was observed that coated Ti-31 and MDN-121 were more resistant compared to the uncoated ones. Uncoated superco-605 was undergoing sputtering during corrosion study and hence comparison between coated and uncoated superco-605 was difficult. The cross-sectional analysis of the corroded, coated samples indicated the presence of a thin layer of chromium oxide scale on the top of the coating and it imparted better corrosion resistance. Parabolic rate constants also indicated that coating is more beneficial to Ti-31 than to MDN-121.

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Section: Ti 31supporting

confidence: 78%

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr₃C₂-25(Ni20Cr)) + NiCrAlY Coating

Jegadeeswaran¹,

Рамеш²,

Bhat³

2013

International Journal of Corrosion

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“…This indicates that the coated specimens exhibited significant improvement as compared to the bare specimen. The DZ125 superalloy is poor in the corrosion performance, which has been also reported by Wang et al 11,12 The interesting phenomenon for the bare specimen is that the mass change in the first 50 h is lower than 1 mg/cm 2 , very similar to those of the coated specimen, despite a disastrous spallation after 50 h. As the hot corrosion of the superalloy is an electrochemical process at 900°C, 7 the corrosion rate approaches to the maximum when the corrosive deposits survive in the molten state. Fig.…”

Section: Methodssupporting

confidence: 77%

“…Also, the mixed salt could cause severe hot-corrosion than pure Na 2 SO 4. 11 The molten salts such as Na 2 SO 4 and NaCl, could dissolve the protective scales, resulting in internal oxidation in the bare and aluminized alloys. At high temperature the reaction of 2NaCl (l)+1/2O 2 (g)=Na 2 O (S)+Cl 2 (g) could occur and produce Cl 2 2, 18 .…”

mentioning

confidence: 99%

Hot-Corrosion Behavior of Thermal Barrier Coated Dz125 Superalloy Exposed to Atomized Seawater and Kerosene

Bai

Zhou

Liang

et al. 2010

Int. J. Mod. Phys. B

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The bare superalloy DZ 125 alloy, the aluminide coated specimens and electron beam physical vapor deposited (EB-PVD) thermal barrier coating (TBC) consisting of yttria stabilizied zirconia (YSZ) topcoat and NiCoCrAlY bond coat specimens were exposed to atomized seawater and kerosene at 900ºC and the cyclic hot-corrosion behaviors of the specimens were investigated. Disastrous spallation of the bare superalloy occurred within 50 h hot-corrosion. In contrast to this, after 100 h hot-corrosion, the average mass change for the aluminized and TBC coated specimens is 0.7 mg/cm 2 and 0.63 mg/cm 2 , respectively, exhibiting excellent hot-corrosion resistance.

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“…Hot corrosion of TBCs and superalloy base materials is a widely studied topic [16][17][18][19][20][21][22][23][24][25]. Hot corrosion in TBCs refers to the degradation by molten salt deposits (V 2 O 5 or NaVO 3 ) that react with yttria to form YVO 4 .…”

Section: Spps Tbcs Offer (A) Higher Thermal Cycling Durability Than Amentioning

confidence: 99%

Hot corrosion behavior of solution precursor and atmospheric plasma sprayed thermal barrier coatings

et al. 2015

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Preparation and hot corrosion behaviour of an Al-gradient NiCoCrAlYSiB coating on a Ni-base superalloy

Cited by 110 publications

References 28 publications

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr₃C₂-25(Ni20Cr)) + NiCrAlY Coating

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr₃C₂-25(Ni20Cr)) + NiCrAlY Coating

Hot-Corrosion Behavior of Thermal Barrier Coated Dz125 Superalloy Exposed to Atomized Seawater and Kerosene

Hot corrosion behavior of solution precursor and atmospheric plasma sprayed thermal barrier coatings

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Preparation and hot corrosion behaviour of an Al-gradient NiCoCrAlYSiB coating on a Ni-base superalloy

Cited by 110 publications

References 28 publications

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr3C2-25(Ni20Cr)) + NiCrAlY Coating

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr3C2-25(Ni20Cr)) + NiCrAlY Coating

Hot-Corrosion Behavior of Thermal Barrier Coated Dz125 Superalloy Exposed to Atomized Seawater and Kerosene

Hot corrosion behavior of solution precursor and atmospheric plasma sprayed thermal barrier coatings

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Product

Resources

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Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr₃C₂-25(Ni20Cr)) + NiCrAlY Coating

Combating Corrosion Degradation of Turbine Materials Using HVOF Sprayed 25% (Cr₃C₂-25(Ni20Cr)) + NiCrAlY Coating