Diagnostics of the Engineering State of Steam Pipelines of Thermal Power Plants by the Hardness and Crack Resistance of Steel

Diagnostics of the Engineering State of Steam Pipelines of Thermal Power Plants by the Hardness and Crack Resistance of Steel

We propose a nondestructive method for the diagnostics of the current state of heat-resistant steels after long-term operation in the steam pipelines of thermal power plants (TPP). It is based on measuring the sizes of ferrite grains and the hardness of 15Kh1M1F heat-resistant steel directly on the...

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Bibliographic Details
Published in:Materials science (New York, N.Y.) Vol. 54; no. 5; pp. 627 - 637
Main Authors: Krechkovs’ka, H. V., Student, O. Z., Nykyforchyn, H. M.
Format: Journal Article
Language:English
Published: New York Springer US 01-03-2019
Springer
Springer Nature B.V
Subjects:
Brittle fracture
Characterization and Evaluation of Materials
Chemistry and Materials Science
Crack closure
Crack propagation
Crack tips
Crystal defects
Dependence
Electric power plants
Fatigue failure
Fracture mechanics
Grain size
Hardness
Hardness (Materials)
Heat resistant steels
Hydrogen embrittlement
Iron compounds
Materials Science
Mechanical properties
Metal fatigue
Nondestructive testing
Parameters
Pipelines
Power plants
Solid Mechanics
Steam electric power generation
Steel
Stress intensity factors
Structural Materials
Thermal power plants
Thermoelectricity
hardness
grain size
steam pipelines of the TPP
heat-resistant steels
shutdowns of the technological process
in-service damages
cyclic crack-growth resistance
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Summary:We propose a nondestructive method for the diagnostics of the current state of heat-resistant steels after long-term operation in the steam pipelines of thermal power plants (TPP). It is based on measuring the sizes of ferrite grains and the hardness of 15Kh1M1F heat-resistant steel directly on the pipe surface and on the use of the deduced relationship between these characteristics (of the Hall–Petch type). The plot of this relationship contains two rectilinear parts. The first part agrees with the physical ideas concerning the correlation between the grain size and the strength (hardness) of the material. The second part with a rapid decrease in the hardness of steel is connected not only with the subsequent changes in the microstructure of steel but also with the development of the in-service defects scattered in the volume of the metal. To determine the limiting state of degraded steel, we used one of the parameters of fracture mechanics, namely, the effective threshold amplitude of the stress intensity factor (SIF) Δ K th eff determined with regard for the effect of fatigue crack closure. The application of this parameter is substantiated by the detected inversion of the influence of hydrogen on Δ K th eff (from positive to negative) observed as the degree of in-service degradation of steel increases. The indicated inversion is caused by the transformation of the mechanism of fatigue crack growth in the subthreshold part of the fatigue crack growth diagram from transgranular (caused by microshears at the crack tip in each loading cycle) into a brittler mechanism accompanied by the formation of intergranular fragments of mode I fracture in the damaged areas. Therefore, the threshold of cyclic crack-growth resistance corresponding to this inversion is taken as the critical value Δ K th eff c below which the probability of brittle fracture of the exploited steel becomes much higher. By using the constructed correlation dependence between ΔK th eff and the hardness of the metal and the determined critical value Δ K th eff c , we estimate the critical value of hardness. Below this value, the hazard of uncontrolled brittle fracture noticeably increases due to the presence of defects scattered in the bulk of the metal.
ISSN:1068-820X
1573-885X
DOI:10.1007/s11003-019-00227-w