Critical Assessment of the Effect of Atmospheric Corrosion Induced Hydrogen on Mechanical Properties of Advanced High Strength Steel

Rudomilova, Darya; Prošek, Tomáš; Traxler, Ines; Faderl, Josef; Luckeneder, Gerald; Schimo-Aichhorn, Gabriela; Muhr, Andreas

doi:10.3390/met11010044

Cited by 7 publications

(4 citation statements)

References 60 publications

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“…Tensile strength [8], yielding strength [9], crack propagation [10,11,12], fatigue life [13,14,15] are main mechanical properties that is affect by corrosion when the materials are exposed to aggressive mediums such as acidic [16] and saline [7,17]. Corrosion effect on mechanical behavior of materials were studied experimentally [18] and/or numerically [19].…”

Section: Introductionmentioning

confidence: 99%

“…In the study, Rudomilova observed that dual phase steel demonstrated a reduction in properties of tensile strength and elongation because corrosion caused a decrease in cross-sectional area of the specimens and pitting was formed. On the other hand, Rudomilova demonstrated that hydrogen absorption for 27 days is inadequate to affect the mechanical properties [8]. Li et al investigated corrosion effect on G250 mild steel used in bridge under stressed and non-stressed cases.…”

Section: Introductionmentioning

confidence: 99%

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An Experimental Investigation of Mechanical Behavior of HY 80 Steel in Corrosive Mediums

Yılmaz,

Kosa,

Durmuşoğlu

2024

DEUFMD

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In this study, mechanical behavior of HY 80 steel in various mediums such as solutions of HCl, H2 S0 4 and NaOH has been investigated experimentally. The plate specimens, tensile specimens and V-notched specimens are immersed in solutions of HCl, H2 S0 4 and NaOH. Mass losses of immersed HY 80 flat plate specimens are measured after 1 week, 2 weeks and 4 weeks for each H2 S04 , NaOH and HCl solutions to determine the aggressivity of the corrosive medium to surface of HY 80 steel. Also, tensile specimens and V-notched specimens are immersed for 1, 2 and 4 weeks to study on the effect of corrosive medium on fracture toughness and yielding behavior of HY 80 steels. The results show that however, yielding strength and ultimate tensile strength of HY 80 steel have reduced after immersed in acidic solutions of HCl and H2 S04 , are stable after immersed in solution of NaOH. Furthermore, effect of acidic medium lower the fracture toughness of HY 80 steel.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An Experimental Investigation of Mechanical Behavior of HY 80 Steel in Corrosive Mediums

Yılmaz,

Kosa,

Durmuşoğlu

2024

DEUFMD

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“…For investigation of hydrogen embrittlement, different test methods exist. Tests regarding the influence of diffusible hydrogen on degradation of different microstructures and steels are mainly carried out on electrochemically hydrogen charged tensile specimens [28][29][30][31]. When it comes to welding, there are numerous self-restraint and externally loaded test procedures for investigating HAC [32,33].…”

Section: Introductionmentioning

confidence: 99%

Hydrogen-Assisted Cracking in GMA Welding of High-Strength Structural Steel—A New Look into This Issue at Narrow Groove

Schaupp

Schroëder

Schroepfer

et al. 2021

Metals

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Modern arc processes, such as the modified spray arc (Mod. SA), have been developed for gas metal arc welding of high-strength structural steels with which even narrow weld seams can be welded. High-strength joints are subjected to increasingly stringent requirements in terms of welding processing and the resulting component performance. In the present work, this challenge is to be met by clarifying the influences on hydrogen-assisted cracking (HAC) in a high-strength structural steel S960QL. Adapted samples analogous to the self-restraint TEKKEN test are used and analyzed with respect to crack formation, microstructure, diffusible hydrogen concentration and residual stresses. The variation of the seam opening angle of the test seams is between 30° and 60°. To prevent HAC, the effectiveness of a dehydrogenation heat treatment (DHT) from the welding heat is investigated. As a result, the weld metals produced at reduced weld opening angle show slightly higher hydrogen concentrations on average. In addition, increased micro- as well as macro-crack formation can be observed on these weld metal samples. On all samples without DHT, cracks in the root notch occur due to HAC, which can be prevented by DHT immediately after welding.

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“…Essentially a variation on a conventional tensile test (often abbreviated in the context of hydrogen research to CSRT, or 'conventional strain-rate test'), this involves running a tensile test upon a prefabricated and hydrogen-charged specimen at a strain-rate sufficiently low to allow hydrogen atoms to diffuse to high-stress regions, with a resultant loss of ductility and premature failure. Hydrogen charging can be performed in gaseous hydrogen [141], under atmospheric corrosion conditions [139,142], or, commonly, under imposed electrochemical charging conditions [136,140,143], and can be performed in situ during straining, or ex situ, prior to charging, or with a combination of both. Quantifying embrittlement is typically done via an assessment of the reduction in ductility during hydrogen-charged tests, such as decreases in total elongation at failure, reduction in cross-sectional area of the fracture surface, or the reduction in area under the tensile curve (absorbed energy), or may be assessed through the resultant decrease in test time-to-failure as a result of hydrogen ingress.…”

Section: Characterising Mechanical Degradationmentioning

confidence: 99%

Hydrogen Embrittlement of Automotive Ultra-High-Strength Steels: Mechanism and Minimisation

Lelliott¹

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Automotive manufacturers are increasingly using ultra-high-strength steels in vehicle components to facilitate mass reduction via downgauging. Unfortunately, as the strength of steels increases, so does susceptibility to ‘hydrogen embrittlement’, a process in which ductility is significantly impaired by ingress of hydrogen. Mechanisms and environmental conditions by which this degradation occurs are not fully understood. In this work, 2 fully-ferritic, 2 fully-martensitic boron, and 2 ferrite-martensite dual-phase, ultra-high-strength steels, were assessed for susceptibility to hydrogen embrittlement via 3 key characteristics: firstly, with particular regard to hydrogen evolution under corrosion conditions, through well-established open circuit potential and potentiodynamic polarisation experiments. Exacerbation of hydrogen evolution through galvanic corrosion of a zinc coating was assessed by scanning vibrating electrode technique (SVET), and an attempt made to quantify increased risk of hydrogen evolution during crevice corrosion through a novel time-lapse photography experiment. Secondly, hydrogen diffusivity was assessed via permeation experiments. Finally, degradation in mechanical properties due to diffusing hydrogen was evaluated through slow strain rate tests (SSRT), whereby susceptibility to embrittlement was equated to reduction in ductility of hydrogen-charged test specimens. The fully-ferritic steels showed the greatest resistance to mechanical degradation, attributed to micro-alloy nano-precipitates within their microstructure acting as ‘traps’, leading to lower diffusivity compared to dual-phase steels of equivalent strength. Indeed, lower diffusivity showed a strong correlation with lower levels of embrittlement across all steels. 1000 MPa dual-phase steel showed the greatest degradation in mechanical properties, with fully-martensitic boron steels also found to be particularly susceptible. 1000 MPa dual-phase steel also showed the largest increase in hydrogen evolution reaction in response to polarisation, thought to result from the inherent potential difference between ferrite and martensite phases. Galvanic corrosion of a damaged zinc coating was found to polarise the exposed steel substrate, triggering sufficient hydrogen evolution to reach critical concentrations for embrittlement.

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Critical Assessment of the Effect of Atmospheric Corrosion Induced Hydrogen on Mechanical Properties of Advanced High Strength Steel

Cited by 7 publications

References 60 publications

An Experimental Investigation of Mechanical Behavior of HY 80 Steel in Corrosive Mediums

An Experimental Investigation of Mechanical Behavior of HY 80 Steel in Corrosive Mediums

Hydrogen-Assisted Cracking in GMA Welding of High-Strength Structural Steel—A New Look into This Issue at Narrow Groove

Hydrogen Embrittlement of Automotive Ultra-High-Strength Steels: Mechanism and Minimisation

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