Corrosion process and control (TKK-2289) 15/16 Semester genap Corrosion process and control (TKK-2289) Instructor: Rama Oktavian; Vivi Nurhadianty. Email: rama.oktavian86@gmail.com Office Hr.: T. 11-12, Th. 08-10; 13-15, F. 08-10; 13-15

Corrosion types Hydrogen damage embrittlement is not the only way in which materials are damaged by hydrogen. Steels are also damaged by hydrogen blistering at high temperatures three categories of hydrogen damage: a. High temperature hydrogen attack b. Hydrogen blistering c. Hydrogen embrittlement

Corrosion types Hydrogen damage

Corrosion types Hydrogen damage

Corrosion types Hydrogen damage High temperature hydrogen attack requires the presence of atomic hydrogen At temperatures above 230◦C hydrogen partial pressure above 100 psi (7 kg/cm2) atomic hydrogen reacts with the carbon component in the steel to form methane

Corrosion types Hydrogen damage b. Hydrogen blistering (hydrogen induced cracking) caused by the atomic hydrogen diffusing into a steel and being trapped at a non-metallic inclusion a high pressure is localized at the inclusions or grain boundaries until the bulging occurs, producing blisters or cracks Stepwise cracking occurs when short blisters at varying depths within the steel link together to form a series of steps

Corrosion types Hydrogen damage b. Hydrogen blistering (hydrogen induced cracking)

Corrosion types Hydrogen damage b. Hydrogen blistering (hydrogen induced cracking) Condition for HIC to occur: The presence of water phase The presence of atomic hydrogen An agent that retards the formation of molecular hydrogen at the surface Presence of grain boundaries or inclusions Maintenance of an active surface Discontinuity in metal, such as slag, inclusion and/or void

Corrosion types Hydrogen damage b. Hydrogen blistering (hydrogen induced cracking) Source of hydrogen: Surface treatment of metal Hydrogen absorption from metal fabrication Mechanism of hydrogen formation

Corrosion types Hydrogen damage c. Hydrogen embrittlement Cathodic hydrogen is adsorbed on the surface as atomic hydrogen (reduced) The internal pressure produced by the gaseous hydrogen is much lower than produced by cathodic hydrogen occurs during the plastic deformation of alloys in contact with hydrogen gas

Corrosion types Hydrogen damage c. Hydrogen embrittlement Example: In plating operations. In pickling operations In cleaning of high strength steels in chloride or fluoride solution Manufacturing and fabrication processes Materials that are most susceptible to hydrogen embrittlement: Iron, titanium, zirconium, martensitic steels, high strength aluminum alloys.

Corrosion types Hydrogen damage c. Hydrogen embrittlement Example: In plating operations. In pickling operations In cleaning of high strength steels in chloride or fluoride solution Manufacturing and fabrication processes Materials that are most susceptible to hydrogen embrittlement: Iron, titanium, zirconium, martensitic steels, high strength aluminum alloys.

Corrosion types Hydrogen damage c. Hydrogen embrittlement Different between SCC and Hydrogen embrittlement SCC begins at the surface, whereas hydrogen embrittlement begins internally The magnitude of corrosion is higher at the origin of SCC than observed with hydrogen embrittlement

Corrosion types Hydrogen damage c. Hydrogen embrittlement Different between SCC and Hydrogen embrittlement

Corrosion types Hydrogen damage Important parameter : THE TEMPERATURE c. Hydrogen embrittlement Important parameter : THE TEMPERATURE T  200°C Hydrogen embrittlement T  200°C Hydrogen attack

FAILURE OF A HYDROGEN TRANSPORT VESSEL IN 1980 Corrosion types Hydrogen damage c. Hydrogen embrittlement Example FAILURE OF A HYDROGEN TRANSPORT VESSEL IN 1980

Corrosion types Hydrogen damage FAILURE OF A HYDROGEN TRANSPORT VESSEL IN 1983. HYDROGEN CRACK INITIATED ON INTERNAL CORROSION PITS

Corrosion types Hydrogen damage

Corrosion types Hydrogen damage

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