High temperature degradation by erosion-corrosion in bubbling fluidized bed combustors

Hou, P.Y.; MacAdam, S.; Niu, Y.; Stringer, J.

doi:10.1590/s1516-14392004000100011

Cited by 14 publications

(7 citation statements)

References 19 publications

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“…The condition at which this layer forms depends on the amount of fine dust particles retained in the bed, which is closely related to the composition of the bed, the specimen and bed temperatures and the oxidation rate of the specimen. 4 Currently superalloys are being used to increase the service life of the boilers, especially in the superheater zones of the boilers. Although the superalloys have adequate mechanical strength at elevated temperatures, they often lack resistance to erosion-corrosion environments.…”

Section: Introductionmentioning

confidence: 99%

Erosion–corrosion behaviour of Ni–20Cr plasma coating in actual boiler environment

Mishra

Prakash

2015

Surface Engineering

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Erosion-corrosion is encountered in a large variety of engineering industries. In such environments, protective coatings are used. In this investigation, erosion-corrosion of the Ni-20Cr coating on nickel and iron based superalloys has been investigated by subjecting them to the boiler of coal fired thermal power plant at the temperature zone of 540uC for 1000 h duration. The erosion-corrosion kinetics of the plasma sprayed Ni-20Cr coating on different superalloys has been investigated. XRD, SEM with EDS and EPMA have been used to analyse the eroded-corroded products along the surface and cross-section. Main phases identified in all the Ni-20Cr coated superalloys after exposure are NiO, Cr 2 O 3 , Al 2 O 3 and SiO 2 . Aluminium has penetrated from the bond coat to the top coat along the splat boundaries. Oxides of chromium, nickel and aluminium are recognized as protective oxides for boiler environment. The probable mechanism of attack for Ni-20Cr coating in the given boiler environment is discussed.

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Section: Introductionmentioning

confidence: 99%

Erosion–corrosion behaviour of Ni–20Cr plasma coating in actual boiler environment

Mishra

Prakash

2015

Surface Engineering

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“…Previous work has included the development of custom experimental rigs, 20 which attempt to replicate fluidized-bed combustors, as well as tests in which samples are exposed to gas flows containing HCl or similar gases. 21,22 Work has also been conducted in which corrosion probes were placed in a biomass combined heat and power (CHP) plant.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Previous work has included the development of custom experimental rigs, which attempt to replicate fluidized-bed combustors, as well as tests in which samples are exposed to gas flows containing HCl or similar gases. , Work has also been conducted in which corrosion probes were placed in a biomass combined heat and power (CHP) plant . A review of recent research on ash-related issues in fluidized-bed combustion of biomass has been carried out by Hupa, while a review paper focusing specifically on the chlorine-associated corrosion in biomass boilers was carried out by Nielsen et al…”

Section: Introductionmentioning

confidence: 99%

Porosity-Based Corrosion Model for Alkali Halide Ash Deposits during Biomass Co-firing

O’Hagan¹,

O’Brien²,

Griffin

et al. 2015

Energy Fuels

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Publication InformationO'Hagan, CP, O'Brien, BJ, Leen, SB, Monaghan, RFD. (2015) 'A porosity-based corrosion model for alkali halide ash deposits during biomass co-firing'. Energy & Fuels,. PublisherAmerican Chemical Society AbstractThis paper presents a physics-based model to describe accelerated corrosion due to alkali halidecontaining deposits, which form on superheater tube walls during biomass co-firing. Increased rates of corrosion during the co-firing of peat with biomass have been identified as a limiting factor on the level of biomass which is viable to use at elevated temperatures. In the present work a synthetic salt, representative of a 70:30 peat-biomass mix, has been applied to pure iron samples in air at 540 C and 600 C. The corrosion layers have been examined using scanning electron microscopy (SEM), optical microscopy and energy dispersive X-ray (EDX) spectroscopy elemental mapping to provide insight into the material degradation and structure of the corrosion layer. Two distinct types of oxide are found to form on the iron substrate. Initially, a compact, uniform oxide layer forms over the substrate. As the process continues, this oxide layer degrades, leading to spalling which sees the broken oxide pieces mix with the salt layer. Additional test samples were examined without deposits as controls to highlight the accelerated rate of corrosion. Two modelling techniques are examined; the widely-used labyrinth factor method (LFM) and the newly proposed porosity-based corrosion method (PCM). The PCM method uses measurements of porosity and pore radius, coupled with a physically-based corrosion mechanism, to predict corrosion rates. Results from the two modelling techniques are compared and both agree satisfactorily with experimental measurements for times of up to 28 days.

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“…Some of the outstanding characteristics are: excellent heat transfer, low emission of contaminants, good combustion efficiencies and good fuel flexibility. However, FBC units can suffer materials deterioration due to particle interaction of solid particles with the heat transfer tubes immersed on the bed (Hou, 2004, Oka, 2004, Rademarkers et al, 1990. Among other issues, some of the most important factors believed to cause wear problems are: the motion of slowly but relatively coarse particles, particles loaded onto the surface by other particles, erosion by relatively fast-moving particles associated with bubbles, and abrasion by blocks of particles thrown into the surface by bubble collapse.…”

Section: Introductionmentioning

confidence: 99%

Abrasion Resistance of Materials

Adamiak¹

2012

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High temperature degradation by erosion-corrosion in bubbling fluidized bed combustors

Cited by 14 publications

References 19 publications

Erosion–corrosion behaviour of Ni–20Cr plasma coating in actual boiler environment

Erosion–corrosion behaviour of Ni–20Cr plasma coating in actual boiler environment

Porosity-Based Corrosion Model for Alkali Halide Ash Deposits during Biomass Co-firing

Abrasion Resistance of Materials

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