Strengthening and Embrittling Mechanism of Super 304H Steel during Long-Term Aging at 650 °C

Wu, Yue; Chai, Fufangzhuo; Liu, Junjian; Wang, Jiaqing; Li, Yong; Du, Chengchao

doi:10.3390/ma17030740

Materials

2024

DOI: 10.3390/ma17030740

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Strengthening and Embrittling Mechanism of Super 304H Steel during Long-Term Aging at 650 °C

Yue Wu,

Fufangzhuo Chai,

Junjian Liu

et al.

Abstract: Super 304H has been a crucial material for ultra-supercritical boilers. However, the relationship between microstructure evolution, strengthening mechanism, and embrittling behavior during long-term aging was lacking investigation. This investigation aimed to reveal the strengthening and embrittling mechanism from precipitates in Super 304H. The results showed that the hardness increment came from the grain boundary’s M23C6 (GB’s M23C6) and intragranular nano Cu-rich particles. After being aged for 5000 h, the… Show more

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2024

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Microstructure characterization and mechanical properties of austenitic Super 304H steel after operation

Purzyńska,

Golański,

Sroka

et al. 2024

International Journal of Pressure Vessels and Piping

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Microstructure characterization and mechanical properties of austenitic Super 304H steel after operation

Purzyńska,

Golański,

Sroka

et al. 2024

International Journal of Pressure Vessels and Piping

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Microstructure Evolution of Super304H Steel Used in a Service Power Station Boiler

Wang,

Yuan,

et al. 2024

Materials

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The microstructure and structure of a Super304H superheater steel pipe after 47,000 h were analyzed by metallographic microscope, scanning electron microscope (SEM), and EDS, and its mechanical properties were measured by hardness meter. The results show that the austenitic grains appear on the outer wall of Super304H steel pipe after service, while the SEM and metallographic microscope tests show that the outer wall particles are coarse. There is an obvious corrosion layer on the outer surface, and the thickness of the corrosion layer on the windward surface is significantly higher than that on the leeward surface. The inner surface is refined and the hardness of the material is significantly increased; the outer surface, the inner surface, and the center all grow abnormally. In this case, the room temperature tensile strength and impact performance of the rough crystal area of the outer wall of the Super304H steel pipe are reduced and fracture along the crystal. Supervision should be strengthened to eliminate the safety risks caused by the abnormal growth of the outer wall austenite grain. The results of crystal phase microscopy show that the main structure of the material still maintains the basic structure of austenitic steel, and particle aggregation mainly occurs in the sub-inner layer of the inner and outer surface. Compared with the lee surface, the middle body structure is basically the same, but whether the thickness of the corrosion layer on the inner surface or the outer surface increases, the deformation degree of the deformation layer is greater. The hardness measurement finds that the hardness of the corrosion layer is caused by the increase in Super304H steel surface stress. In case of pipe explosion accident, the highest chance of pipe explosion here should be closely observed.

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Strengthening and Embrittling Mechanism of Super 304H Steel during Long-Term Aging at 650 °C

Cited by 2 publications

References 32 publications

Microstructure characterization and mechanical properties of austenitic Super 304H steel after operation

Microstructure characterization and mechanical properties of austenitic Super 304H steel after operation

Microstructure Evolution of Super304H Steel Used in a Service Power Station Boiler

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