Hot Corrosion Behavior of Stainless Steel with Al-Si/Al-Si-Cr Coating

Fu, Guang; Wu, Yongzhao; Li, Qun; Li, Rongguang; Su, Yong

doi:10.1515/htmp-2015-0154

Cited by 6 publications

(9 citation statements)

References 4 publications

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“…Such layers have proven themselves in aggressive media at high temperatures, because aluminium oxide has outstanding mechanical properties and high chemical stability at high temperatures. Silicon oxide [15,37,38] in addition to chemical stability has high hardness and strength.…”

Section: Introductionmentioning

confidence: 99%

Si-Al-N-O Multi-Layer Coatings with Increased Corrosion Resistance Deposited on Stainless Steel by Magnetron Sputtering

Dorofeeva

Gubaidulina

Сергеев

et al. 2022

Metals

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This work studies single-layer (Al-Si-N) and multi-layer (Al-Si-N-O/Al-Si-O) coatings deposited by magnetron sputtering on stainless steel specimens (AISI 321), which can be used under aggressive conditions. The multi-layer coating consists of six alternating layers of Al-Si-N-O and Al-Si-O with a thickness of 0.9 µm and 0.2 µm, respectively. The structural-phase state and the chemical composition of the coatings were studied by transmission and scanning electron microscopy and XPS analysis. It was revealed that single-layer coatings are nanocrystalline and contain AlN and α-Si3N4 phases. Multi-layer coatings (Al-Si-N-O/Al-Si-O) are amorphous in each of the layers. The corrosion properties of substrate and coated specimens were investigated using a potentiostat in the 3.5 mg/l sea salt solution. It was found that corrosion resistance of stainless steel specimens with multi-layer coating is substantially (tenfold) higher compared with substrates and the specimens with single-layer coating.

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Section: Introductionmentioning

confidence: 99%

Si-Al-N-O Multi-Layer Coatings with Increased Corrosion Resistance Deposited on Stainless Steel by Magnetron Sputtering

Dorofeeva

Gubaidulina

Сергеев

et al. 2022

Metals

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“…Furthermore, the Si doping accelerated the selective oxidation of Al to generate an Al 2 O 3 protective layer. Unfortunately, during high-temperature corrosion exposure, the AlSi coatings suffered from significant elemental inter-diffusion [24][25][26][27][28][29][30]. According to the literature, the upward diffusion of Fe caused the creation of the (Fe 2 Al 5 + FeAl) alloy phase, which resulted in significant volume shrinkage and coating cracking.…”

Section: Introductionmentioning

confidence: 99%

“…According to the literature, the upward diffusion of Fe caused the creation of the (Fe 2 Al 5 + FeAl) alloy phase, which resulted in significant volume shrinkage and coating cracking. These microcracks served as the diffusion pathways for the combined salt, speeding up the interaction between the developing Cl 2 and Al, resulting in significant coating deterioration and mass loss [28,29].…”

Section: Introductionmentioning

confidence: 99%

Understanding the Role of a Cr Transition Layer in the Hot-Salt Corrosion Behavior of an AlSi Alloy Coating

Liu

Chen

et al. 2022

Coatings

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The effect of a chromium (Cr) transition layer on the hot-salt corrosion behavior of an AlSi alloy coating was studied. Hot-salt corrosion experiments were performed at 650 °C and corrosion kinetic curves were plotted. The weight gain of the AlSi-coated samples increased to 0.89 mg/cm2 at 100 h and then decreased steadily to 0.77 mg/cm2 at 200 h. The weight of the AlSi-coated samples with the addition of a Cr transition layer increased immediately to 0.79 mg/cm2 at 20 h and then gradually increased to 0.85 mg/cm2 at 200 h. This Cr diffusion promoted the preferential creation of an Al2O3 layer, which effectively hindered the upward diffusion of Fe and also resulted in the production of a Cr2O3-SiO2 layer, which impeded the multi-scale salt mixture’s penetration. The Cr diffusion also caused a notable seal-healing effect, which healed the micro-pores. These oxidation and degradation reactions were considerably repressed by the high barrier properties of these oxide layers and the dense surface, resulting in the increased hot-salt corrosion resistance of the AlSi alloy coating. The current findings provide a feasible strategy for the design of a diffusion barrier layer of a thermal protective coating on martensitic stainless steel.

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“…Of all coatings, thermal barrier coatings (TBCs) have the most complex structure and can even operate in the most demanding high-temperature environments. TBCs, which comprise metal, intermetallic, ceramic and multilayers, insulate turbine and combustor engine components from the hot gas stream and improve the durability and the time-life in exercise [1][2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

“…(1) As aluminized by a 5 min hot-dipping ( Figure 1a), having an inner intermetallic layer and an outer Al-Si alloy layer, 200 µm thick. (2) As aluminized by a 3 min hot-dipping ( Figure 1b), having an inner intermetallic layer and an outer Al-Si alloy layer, 130 µm thick. (3) As aluminized by hot-dipping and successively oxidized in furnace at 900 • C for 1 h (Figure 1c).…”

Section: Introductionmentioning

confidence: 99%

Damping Behavior of Layered Aluminium and Aluminide Coatings on AISI 316 Austenitic Steel

et al. 2020

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Several coating configurations on AISI 316 steel were obtained by a hot dipping process followed by isothermal interdiffusion. Six different kind of multilayered specimens were produced and characterized. These coatings, typically employed as bond coat in thermal barrier coating (TBC), can also be effective as vibration reduction elements at intermediate and high temperatures. This preliminary work was focused on the microstructural design and processing effects of the coatings. The damping of the produced specimens was measured up to 450 °C and compared with that of the steel substrate. The most performing coatings contain an Al-Si layer and exhibit a steep damping increase above 200 °C, reasonably due to dislocation movements by plastic straining of soft alloy layer and to the interface sliding between layers with different elastic moduli.

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Hot Corrosion Behavior of Stainless Steel with Al-Si/Al-Si-Cr Coating

Cited by 6 publications

References 4 publications

Si-Al-N-O Multi-Layer Coatings with Increased Corrosion Resistance Deposited on Stainless Steel by Magnetron Sputtering

Si-Al-N-O Multi-Layer Coatings with Increased Corrosion Resistance Deposited on Stainless Steel by Magnetron Sputtering

Understanding the Role of a Cr Transition Layer in the Hot-Salt Corrosion Behavior of an AlSi Alloy Coating

Damping Behavior of Layered Aluminium and Aluminide Coatings on AISI 316 Austenitic Steel

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