WRC 573 Effects of Heat Treatment and Chemical Composition on High Temperatur...

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WRC 573Title                  Effects of Heat Treatment and Chemical Composition on High Temperature Hydrogen Attack Resistance of C-1/2 Mo Steels               
Publication Date                    2018               
Authors                    W.C. Hoskins, M. Bharadwaj, Ph.D., C.D. Lundin, Ph.D., R. Lovely, M. Prager, Ph.D.               
Publication Type                    Bulletin               
Number of Pages                    62               
Abstract

High temperature hydrogen attack (HTHA) is a phenomenon which has plagued the petrochemical industry in applications where low alloy steels are employed in hot hydrogen environments (greater than 500°F [260°C]).  Recent failures of equipment in hydrogen service stemming from HTHA damage have intensified the need for a further understanding of the behavior of low alloy steels in elevated temperature hydrogen environments.  In this study, a unique autoclave hydrogen exposure experiment evaluated the effects of heat treatment and chemical composition on the HTHA resistance of Carbon-½ Molybdenum (C-½ Mo) steels.  The autoclave hydrogen exposure experiment utilized a unique “HTHA box” that was designed to accurately simulate a hydrogen pressure differential through the wall thickness, as experienced by piping and vessels operating in hydrogen service.  The C-½ Mo HTHA boxes were also fabricated such that there was a thick side and a thin side, which allowed the investigation of the performance of two different wall thicknesses with a unidirectional hydrogen concentration gradient.  Using this box technique, two heats of C-½ Mo steel in the normalized and tempered (N&T) and annealed and tempered (A&T) conditions were investigated regarding their resistance to HTHA.  The C-½ Mo boxes were exposed at a temperature of 900°F (482°C) and hydrogen pressure of 900 psi (6.2 MPa) for 1248 hours. The conditions of the autoclave hydrogen exposure experiment were chosen to be severe in order to expedite HTHA damage.  Subsequent to autoclave hydrogen exposure, the extent of HTHA damage was evaluated in each of the four C-½ Mo HTHA boxes by the following methods:  (i) determination of the methane content as a function of distance from the hydrogen exposed surface, (ii) characterization of metallography specimens using optical light microscopy (OLM) and scanning electron microscopy (SEM), and (iii) fractographic examination of cryo-cracked samples using SEM.

The N&T boxes exhibited superior performance to the A&T boxes.  The bainitic and ferritic microstructure of the N&T boxes was more resistant to HTHA than the pearlitic and ferritic microstructure of the A&T boxes because of the stability of the carbides in the bainite colonies of the N&T boxes as well as the higher strength of the N&T boxes in comparison to the A&T boxes.  Significant variation in the HTHA resistance of the two C-½ Mo heats was also observed.  The two materials selected in this study were chosen based on their molybdenum to carbon (Mo/C) ratio, such that the Mo/C ratio of one material was high (3.80) and the other was low (2.29).  In the same heat treatment condition, the C-½ Mo steel with a higher Mo/C ratio exhibited superior performance (greater resistance to HTHA).  C-½ Mo steels with a higher Mo/C ratio have a reduced carbon activity because of the formation of a greater fraction of thermodynamically more stable carbides, thus, reducing the propensity for methane formation.  Apart from determining the effects of heat treatment and chemical composition on the HTHA resistance of C-½ Mo steels, a deeper mechanistic understanding of the morphological characteristics of HTHA damage was developed through the completion of detailed metallographic examination and the implementation of cryo-cracking to provide an enhanced view of intergranular HTHA damage.

Keywords: High Temperature Hydrogen Attack, HTHA, C-1/2 Mo Steel, Nelson Curve, API RP 941, Autoclave Hydrogen Exposure Experiment, HTHA Boxes, Cryo-Cracking