Observations and improvements on the impact-echo method used for blast furnace hearth refractory measurement

Commandeur, Colin; Sprik, R.; Stolk, Christiaan C.; Louwerse, Gerard

doi:10.1080/03019233.2022.2081956

Ironmaking & Steelmaking

2022

DOI: 10.1080/03019233.2022.2081956

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Observations and improvements on the impact-echo method used for blast furnace hearth refractory measurement

Colin Commandeur

R. Sprik

Christiaan C. Stolk

et al.

Abstract: The refractory thickness of the blast furnace hearth is a critical parameter for the safe operation of a blast furnace. A replacement of the refractory comes with high costs and, therefore, unnecessary repairs should be avoided. A promising method to estimate the refractory thickness is the impactecho method. For the interpretation of impact-echo, often, the peaks in the spectrum of the measured signal are associated with the echo from an interface. In this paper, it is shown that this method should be used wi… Show more

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2024

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Blast furnace hearth erosion modelling based on the dataset approach

Wang,

Guo

et al. 2024

Ironmaking & Steelmaking: Processes, Products and Applicati

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To monitor and diagnose the erosion status of the blast furnace hearth lining during operation, this study utilises the high precision and rapid processing capabilities of ANSYS finite element software for secondary development. It integrates temperature data from various thermocouples at the blast furnace hearth bottom with samples for erosion thickness calculation, developing a model based on extensive datasets of erosion status. This model can display isotherms for any user-specified temperature and combines calculated longitudinal profile data to create a three-dimensional representation of the hearth bottom through the secondary development of Solidworks 3D modeling software. This flexibility allows for an arbitrary view of the blast furnace's erosion state. This method significantly enhances both the speed and accuracy of calculations compared to other erosion models. It addresses the challenge of constructing a reliable heat transfer model for the furnace hearth and bottom when numerous thermocouples fail in the later stages of furnace operation. By improving the model's applicability throughout the entire lifecycle of the blast furnace, it ensures real-time feedback to users by continuously calculating the erosion status.

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Blast furnace hearth erosion modelling based on the dataset approach

Wang,

Guo

et al. 2024

Ironmaking & Steelmaking: Processes, Products and Applicati

View full text Add to dashboard Cite

show abstract

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Observations and improvements on the impact-echo method used for blast furnace hearth refractory measurement

Cited by 1 publication

References 11 publications

Blast furnace hearth erosion modelling based on the dataset approach

Blast furnace hearth erosion modelling based on the dataset approach

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