Analysis on microstructure and properties evolution and life prediction of P92 steel in high temperature service

P92 steel (10Cr9MoW2VNbBN) is widely used in high-temperature steam piping and high-temperature header fabrications of ultra-supercritical units. In this paper, a follow-up study on the microstructure, mechanical properties and life of P92 steel steam pipes which are virgin, 31,000 h in service, 49,...

Full description

Saved in:
Bibliographic Details
Published in:The International journal of pressure vessels and piping 2021-12, Vol.194, p.104482, Article 104482
Main Authors: Xia, Xianxi, Zhu, Baoyin, Jin, Xiao, Tang, Minjin, Yang, Lukuan, Xue, Fei, Shi, Jinhua, Zhang, Guodong
Format: Article
Language:English
Subjects:
Life assessment
Mechanical properties
Metal supervision
Microstructure
P92 steel
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:P92 steel (10Cr9MoW2VNbBN) is widely used in high-temperature steam piping and high-temperature header fabrications of ultra-supercritical units. In this paper, a follow-up study on the microstructure, mechanical properties and life of P92 steel steam pipes which are virgin, 31,000 h in service, 49,000 h in service and 71,000 h in service was carried out. The results show that the mechanical properties of the P92 steel drop significantly after 31,000 h of service, then decrease slowly with the increase of the service time. When the service time reaches 71,000 h, the high temperature yield strength, percentage elongation, and impact absorbed energy are all close to the lower limit regulated by the ASME standard. Moreover, the morphology of lath martensite becomes fragmentary, the width of the martensitic lath increases and carbide particles cluster and grow at the grain boundary. M23C6 phase coarsens and local Laves phase precipitates. Meanwhile, the dislocation density decreases to some degree. Furthermore, there is a good corresponding relationship between the room temperature hardness and the high temperature tensile strength of the P92 steel after a long period of service. The prediction model of the remaining endurance life of P92 components is proposed on the basis of the room temperature hardness. •Changes in dislocation density and martensitic lath width lead to a decrease in mechanical properties.•The mechanical properties of the P92 steel drop significantly in the initial stage of service, then decrease slowly.•The remaining endurance life of P92 components can be predicted by using the room temperature hardness.
ISSN:0308-0161
1879-3541
DOI:10.1016/j.ijpvp.2021.104482