Influence of Laves Phase Precipitation and Coarsening on High‐Temperature Strength of Ferritic Stainless Steels

High Temperature Materials and Processes

Theisen

2013

Ferritic heat-resistant steels are commonly used for automotive exhaust systems and have replaced cast iron, the traditional material for this application. Efforts to improve the efficiency of engines, reduce weight, and minimize toxic ingredients by increasing the gas temperature have shifted the requirement for ferritic heat-resistant steels to a higher hot strength. Methods of improving the high-temperature strength are solid-solution strengthening, precipitation hardening, and grain refinement. In this work, the influence of MX precipitates on the hightemperature mechanical properties of three different ferritic Fe-Cr stainless steels was investigated and compared to a reference material. Investigations were performed with uniaxial compression tests of samples aged isothermally at 900 °C for up to 1440 h. The most effective method of increasing the high-temperature strength is to alloy the steel with 2 mass% tungsten. Grain growth during annealing at 900 °C was decelerated by solid-state formation of MX carbonitrides. Microstructural investigations also revealed a slow coarsening rate of the MX precipitates.

Section: Influence Of the Alloying Elementsmentioning

confidence: 99%

Section: Influence Of the Alloying Elementsmentioning

confidence: 99%

Ferritic Stainless Steels for High-Temperature Applications: Stabilization of the Microstructure by Solid State Precipitation of MX Carbonitrides

High Temperature Materials and Processes

Theisen

2013

“…From the literature [19] and our previous investigations, Nb is known to be the most potent Laves phase former and its strong effect can be enhanced by combining it with Si. [20] However, low concentrations of C and N, which are unavoidable during steel production, decrease the solvus temperature of the Laves phase due to the high affinity of Nb for C and N, thus leading to the formation of carbides/nitrides instead of the Laves phase. [21] Microalloying with Ti minimizes primary precipitation of niobium nitrides and niobium carbides, so that this element is still available for Laves phase formation.…”

Section: A Alloy Designmentioning

confidence: 99%

Evolution of the Laves Phase in Ferritic Heat-Resistant Steels During Long-term Annealing and its Influence on the High-Temperature Strength

Klein

et al. 2014

Metall Mater Trans A

Self Cite

Heat-resistant ferritic steels containing Laves phase precipitates were designed supported by thermodynamic modeling. High-temperature compression tests at 1173.15 K (900°C) and a detailed characterization of the microstructural evolution during annealing at 1173.15 K (900°C) were carried out to investigate the effect of Laves phase formation on the high-temperature strength. Due to the addition of W/Mo and/or Nb, the high-temperature strength of the newly designed alloys is significantly higher than that of the reference steels. However, the high-temperature strength of all investigated steels decreases slightly as the annealing time is increased up to 1440 hours. To determine the influence of Laves phase formation and coarsening on the high-temperature strength during long-term annealing, the precipitates were extracted from the ferritic matrix in different annealing states. The phases in the powder residue were determined by XRD, and the chemical composition of the Laves phase in dependence of the annealing time was analyzed by EDS measurements.

“…This leads to the conclusion that a stable Laves phase content of about 1 vol% at service temperature could effectively retard grain coarsening . Thus, systematic formation of the Laves phase in addition to solid‐solution hardening may lead to a new way of enhancing the high‐temperature strength of heat‐resistant ferritic steels …”

Section: Introductionmentioning

confidence: 99%

“…This work investigates the influence of the Laves phase and grain size on strength, toughness, and ductility at room temperature. Three previously developed steels of the system Fe‐Cr‐Nb(‐Al) (designated Fe18CrW, Fe18CrMoW, and Fe19CrWAl) are the basis of this investigation. These steels are designed to contain about 1 vol% Laves phase at 900°C, and their high‐temperature strength is enhanced by alloying with Nb, W, and/or Al .…”

Section: Introductionmentioning

confidence: 99%

Influence of Formation and Coarsening of the Laves Phase on the Mechanical Properties of Heat‐Resistant Ferritic Steels

Klein

et al. 2013

steel research int.

Self Cite

Three newly designed heat‐resistant ferritic alloys containing the intermetallic Laves phase were investigated with respect to an annealing dwell time of up to 1440 h at 900°C and were compared with commercially available steels. A detailed characterization of the microstructure evolution in dependence of the annealing dwell time was performed. In order to estimate the influence of Laves phase formation and coarsening on the strength, ductility and toughness, the results of the microstructural analysis were correlated with tensile tests at room temperature and with Charpy‐V impact tests. Precipitates of the Laves phase were observed in the recrystallized state with a mean particle diameter about 0.25 μm. The Laves phase in all investigated alloys showed rapid growth and coarsening with increasing annealing time. In spite of this behavior, the strength and ductility of the newly designed alloys were conserved, even after annealing for 1440 h. However, the toughness decreased with coarsening of the Laves phase, which is expressed by a shift of the ductile‐to‐brittle transition temperature to a higher temperature. Overall, it was shown that the influence of grain growth on the mechanical properties is more significant than the presence of the Laves phase. Precipitation of Laves phase lowers the mobility of the grain boundaries so that grain growth can be avoided.