Effect of the Cold Rolling Reduction on the Microstructural Characteristics and Mechanical Behavior of a 0.06%C–17%Mn TRIP/TWIP Steel

Escobar, Diana María Pérez; Dafé, Sara Silva Ferreira de; Verbeken, Kim; Santos, Dagoberto Brandão

doi:10.1002/srin.201400555

Cited by 10 publications

(6 citation statements)

References 56 publications

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“…The values of UTS for the present steels processed by warm to hot rolling do not depend on the magnitude of work hardening (Fig. 7) similar to other studies on high-Mn TRIP/TWIP steels subjected to conventional rolling [17,34,53,54]. Therefore, the product of UTS×δ progressively increases from 35 to 95 GPa % with an increase in the rolling temperature from 773 K to 1373 K. It is worth noting that the Fe-18Mn-0.6C steel processed by warm rolling exhibits very high value of the yield strength up to 950 MPa provided by high dislocation density of 3.6×10 15 m −2 , which is comparable to that of (3.5-4.5)×10 15 m −2 observed in other high-Mn steel after large strain cold rolling [44].…”

Section: Discussionsupporting

confidence: 90%

“…The total elongation up to 90% and the ultimate tensile strength of about 1000 MPa can be attained, although the yield strength is approx. 300 MPa in such steels with recrystallized microstructure after conventional hot working or cold rolling followed by annealing [8,[15][16][17][18][19][20][21][22][23][24][25]. Commonly, an increase in the carbon content was favorable for the yield strength, ultimate tensile strength, and ductility [20,26,27], although even 0.8%C did not result in significant changes of the strength and plastic properties, namely, the ultimate tensile strength and yield strength of about 1000 and 300 MPa, respectively, and a total elongation of 80% were reported for Fe-17Mn-0.6C hot rolled at 1273 K [28].…”

Section: Introductionmentioning

confidence: 99%

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Effect of rolling temperature on microstructure and mechanical properties of 18%Mn TWIP/TRIP steels

Torganchuk

Belyakov

Kaibyshev

2017

Materials Science and Engineering: A

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The microstructure and mechanical properties of Fe-18Mn-0.6C and Fe-18Mn-0.4C steels subjected to rolling with a total reduction of 60% at temperatures of 773 K to 1373 K were investigated. Warm rolling at temperatures of 773-1073 K resulted in flattened grain structure with the transverse grain size of 7 µm, whereas hot rolling at 1073-1373 K was accompanied by the dynamic recrystallization leading to almost equiaxed grains, the size of which increased with temperature. Internal stresses and corresponding dislocation densities increased as the rolling temperature decreased. The steel with higher carbon content exhibited finer grains and higher dislocation density after rolling. A decrease in the rolling temperature from 1373 K to 773 K resulted in a significant increase in the yield strength from about 300-400 MPa to 850-950 MPa, while ultimate tensile strength increased from 1000-1100 MPa to 1200-1300 MPa (the higher strength corresponds to higher carbon content). On the other hand, the total elongation decreased from approx. 85% in the Fe-18Mn-0.6C steel and from 65% in the Fe-18Mn-0.4C steel to approx. 30% in the both steels as the rolling temperature decreased from 1373 K to 773 K. The difference in the tensile behavior at room temperature was attributed to the variation in the deformation mechanisms. Namely, mechanical twinning operated in the both steels during tension, whereas ε-martensite formation took place in the Fe-18Mn-0.4C steel.

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Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Effect of rolling temperature on microstructure and mechanical properties of 18%Mn TWIP/TRIP steels

Torganchuk

Belyakov

Kaibyshev

2017

Materials Science and Engineering: A

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“…The total elongation (TEL) versus ultimate tensile strength (UTS) diagram for steels utilizing the TRIP effect; representative mechanical properties of HMnS TRIP, Q&P TRIP, MMnS TRIP, Maraging TRIP, HEA TRIP from literature, LC TRIP from Autosteel website, and Meta‐stable ASS from standard EN10088‐2 …”

Section: Steels With Trip Effectmentioning

confidence: 99%

“…It has been reported that the TRIP effect in high‐manganese steels could result in superior mechanical properties, an excellent combination of high strength and good ductility, and high strain‐hardening capacity . There are mainly three high‐manganese steel groups, which have been intensively studied, namely Fe–Mn–Al–Si, Fe–Mn–C, and Fe–Mn–Al–C alloys. The chemical composition and corresponding SFE of some typical high‐manganese TRIP steels are listed in Table .…”

Section: Trip Effect In High‐manganese Steelsmentioning

confidence: 99%

The TRIP Effect and Its Application in Cold Formable Sheet Steels

Bleck

Guo

2017

steel research int.

172

100

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The Transformation-Induced-Plasticity (TRIP) effect is used for enhancing the formability of cold formable sheet steels. While the first observation of this phenomenon dates back to the 1930's, the industrial usage of the TRIP steels started after 1950. First fully austenitic steels, later on multiphase steels have been developed with a meta-stable austenitic phase that can transform stress-assisted or strain-induced into eor a 0 -martensite during deformation. The historic development, the principles of the TRIP effect, and the different groups of steels using the TRIP effect are described. For the already commercialized TRIP steels, characteristic chemical compositions and microstructures are discussed; the requirements for the process design as well as new annealing concepts after cold rolling are explained. . Since 2016, he has been working in the Steel Institute of RWTH Aachen University as a scientific researcher. His research topic focuses on the microstructuremechanical properties relationship of high-Mn and medium-Mn steels.

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“…However, another mechanism described as deformation-induced martensite formation could be observed as a result of rolling. Depending on the temperature, stress-or straininduced martensite can be formed, while stacking faults may also occur [24]. Indeed, Eskandari et al find that martensitic transformation can be minimized or completely suppressed at increased rolling temperatures [37].…”

Section: Final Rollingmentioning

confidence: 98%

Formability of strong metastable Fe–15Cr–3Mn–3Ni–0.2C–0.1N austenitic TRIP/(TWIP) steel – A comparison of different base materials

Pranke

Wendler

Weidner

et al. 2015

Journal of Alloys and Compounds

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Effect of the Cold Rolling Reduction on the Microstructural Characteristics and Mechanical Behavior of a 0.06%C–17%Mn TRIP/TWIP Steel

Cited by 10 publications

References 56 publications

Effect of rolling temperature on microstructure and mechanical properties of 18%Mn TWIP/TRIP steels

Effect of rolling temperature on microstructure and mechanical properties of 18%Mn TWIP/TRIP steels

The TRIP Effect and Its Application in Cold Formable Sheet Steels

Formability of strong metastable Fe–15Cr–3Mn–3Ni–0.2C–0.1N austenitic TRIP/(TWIP) steel – A comparison of different base materials

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