Your search keyword '"Helmuth Sarmiento Klapper"' showing total 4 results

1. Pitting Corrosion Resistance Influencing Corrosion Fatigue Behavior of an Austenitic Stainless Steel in Chloride-Containing Environments

Author

Carlos M. Menendez, Helmuth Sarmiento Klapper, and Sebastian Jesse

Subjects

Austenite, Materials science, Structural material, General Chemical Engineering, Metallurgy, General Chemistry, engineering.material, Chloride, Corrosion fatigue, engineering, medicine, Pitting corrosion, General Materials Science, Austenitic stainless steel, medicine.drug

Abstract

Strain-hardened austenitic stainless steels are commonly used as structural materials in drilling equipment because they meet the demanding requirements in terms of mechanical, magnetic, and chemical properties necessary for drilling technologies in subterranean energy resources exploration. Drilling operational conditions might become a challenge for the integrity of these materials due to the cyclic loading the drillstring is subjected to, in combination with the downhole temperature, and the corrosivity of the drilling fluid. In this research work, the relationship among the pitting corrosion resistance of one Mn-stabilized austenitic stainless steel and its corrosion fatigue behavior has been determined by means of electrochemical methods, advanced surface characterization, and corrosion fatigue testing in brines of near-neutral pH with different chloride contents at room temperature (RT) and 150°C. It has been determined that the corrosion fatigue behavior of the investigated CrMn stainless steel is strongly affected by its susceptibility to pitting corrosion. The synergistic effect between the corrosive environment and the mechanical load depends upon the applied stress amplitude and the pitting resistance of the material. The corrosion fatigue behavior of the austenitic stainless steel at RT was synergistically affected by the environmental and loading conditions at low stress amplitudes. In contrast, the large susceptibility to pitting of the material at 150°C has a significant detrimental effect on its corrosion fatigue behavior when subjected to high stress amplitudes. The observed damage mechanism at 150°C can be described as pitting-induced corrosion fatigue because pit propagation controlled the corrosion fatigue behavior of the CrMn stainless steel. The obtained experimental results have shown that the pitting resistance, assessed for instance by multiple electrochemical methods, could in cases where pitting susceptibility has a large influence on the environmentally sustained cracking mechanism, be used as an indicator of the expected corrosion fatigue behavior of the material. As demonstrated in this study, however, results from accelerated electrochemical testing solely might have a limited prediction capability of long-term corrosion behavior.

Published

2020

2. Susceptibility to Pitting Corrosion of Nickel-Based Alloy 718 Exposed to Simulated Drilling Environments

Author

John H. Stevens and Helmuth Sarmiento Klapper

Subjects

Materials science, General Chemical Engineering, Alloy, Directional drilling, Metallurgy, Drilling, General Chemistry, Nickel based, engineering.material, Dielectric spectroscopy, Corrosion, engineering, Pitting corrosion, General Materials Science

Abstract

As a result of their appropriate mechanical and non-magnetic properties, Alloy 718 (UNS N07718) has been used in directional drilling tools, particularly in applications where superior corrosion re...

Published

2014

3. MATERIALS EVALUATION FOR GEOTHERMAL APPLICATIONS

Author

Ralph Bäßler, Amela Keserovi, Joana Sobetzki, and Helmuth Sarmiento Klapper

Subjects

Geothermal power, Materials science, business.industry, Geothermal energy, Metallurgy, Alloy, General Engineering, engineering.material, Intergranular corrosion, Corrosion, engineering, Pitting corrosion, business, Geothermal gradient, Crevice corrosion

Abstract

In order to provide basic information on corrosion resistance to the designers and users of geothermal plants different metallic materials including duplex and austenitic stainless steels as well as a nickel alloy have been evaluated in artificial geothermal fluids simulating the conditions in some locations with geothermal potential in Germany as well as two sites in Indonesia. By electrochemical and long-term exposure tests at 100 °C and 150 °C the suitability of low alloyed steel UNS G41300, stainless steels UNS S31603 UNS S31803, UNS S32760, super austenitic steel UNS N08031 and nickel based alloy UNS N06059 was investigated in these geothermal fluids, using critical potentials and corrosion rates. In high-saline environments the crevice corrosion turned out to be the determining mechanism. The nickel based alloy shows excellent corrosion resistance against pitting corrosion. Excluding its high cost, it is very good to be used in the construction of geothermal facilities having highly saline brines. Stainless and duplex steels exhibit a limited corrosion resistance concerning pitting and crevice corrosion. Therefore they are not suitable for highly saline brines. The super austenite UNS N08031 showed a temperature depending behavior. In non-saline environments the low-alloyed steel UNS G41300 (beside of the higher alloyed materials) could be employed as a constructional material for the geothermal power plant, as long as a sufficient wall thickness of the material is considered.

Published

2015

4. Hydrogen embrittlement: the game changing factor in the applicability of nickel alloys in oilfield technology

Author

Jutta Klöwer, Helmuth Sarmiento Klapper, and Olesya Gosheva

Subjects

Materials science, Hydrogen, Precipitation (chemistry), 020209 energy, General Mathematics, Metallurgy, Alloy, General Engineering, General Physics and Astronomy, chemistry.chemical_element, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Microstructure, Corrosion, Characterization (materials science), Nickel, chemistry, 0202 electrical engineering, electronic engineering, information engineering, engineering, 0210 nano-technology, Hydrogen embrittlement

Abstract

Precipitation hardenable (PH) nickel (Ni) alloys are often the most reliable engineering materials for demanding oilfield upstream and subsea applications especially in deep sour wells. Despite their superior corrosion resistance and mechanical properties over a broad range of temperatures, the applicability of PH Ni alloys has been questioned due to their susceptibility to hydrogen embrittlement (HE), as confirmed in documented failures of components in upstream applications. While extensive work has been done in recent years to develop testing methodologies for benchmarking PH Ni alloys in terms of their HE susceptibility, limited scientific research has been conducted to achieve improved foundational knowledge about the role of microstructural particularities in these alloys on their mechanical behaviour in environments promoting hydrogen uptake. Precipitates such as theγ′,γ′′ and δ-phase are well known for defining the mechanical and chemical properties of these alloys. To elucidate the effect of precipitates in the microstructure of the oil-patch PH Ni alloy 718 on its HE susceptibility, slow strain rate tests under continuous hydrogen charging were conducted on material after several different age-hardening treatments. By correlating the obtained results with those from the microstructural and fractographic characterization, it was concluded that HE susceptibility of oil-patch alloy 718 is strongly influenced by the amount and size of precipitates such as theγ′ andγ′′ as well as the δ-phase rather than by the strength level only. In addition, several HE mechanisms including hydrogen-enhanced decohesion and hydrogen-enhanced local plasticity were observed taking place on oil-patch alloy 718, depending upon the characteristics of these phases when present in the microstructure.This article is part of the themed issue ‘The challenges of hydrogen and metals’.

Published

2017