Inclusion Engineering in Medium Mn Steels: Effect of Hot-Rolling Process on the Deformation Behaviors of Oxide and Sulfide Inclusions View Full Text


Ontology type: schema:ScholarlyArticle      Open Access: True


Article Info

DATE

2022-04-26

AUTHORS

Yong Wang, Yonggang Yang, Zhihua Dong, Joo Hyun Park, Zhenli Mi, Xinping Mao, Wangzhong Mu

ABSTRACT

Medium Mn steel (MMS) is a new category of the third-generation advanced high strength steel (3rd AHSS) which is developed in the recent 1-2 decades due to a unique trade-off of strength and ductility. Thus, this steel grade has a wide application potential in different fields of industry. The current work provides a fundamental study of the effect of hot-rolling on the inclusion deformation in MMS including a varied 7 to 9 mass pct Mn. Specifically, the deformation behavior of different types of inclusions (i.e., Mn(S,Se), liquid oxide (MnSiO3), MnAl2O4, and complex oxy-sulfide) was investigated. The results show that both MnSiO3 and Mn(S,Se) are soft inclusions which are able to be deformed during the hot-rolling process but MnAl2O4 does not. The aspect ratio of soft inclusions increases significantly from as-cast to hot-rolling conditions. When the maximum size of different inclusions is similar, Mn(S,Se) deforms more than MnSiO3 does. This is due to a joint influence of physical parameters including Young’s modulus, coefficient of thermal expansion (α), etc. However, when the maximum size of one type of inclusion (e.g., MnSiO3) is much larger than another one (e.g., Mn(S,Se)), this maximum size of soft inclusions plays a dominant role than other factors. In addition, the deformation behavior of dual-phase inclusion depends on the major phase, i.e., either oxide or sulfide. Last but not least, empirical correlations between the reduction ratio of the thickness of plate, grain size, and aspect ratio of oxide and sulfide inclusions after hot-rolling are provided quantitatively. This work aims to contribute to the ‘inclusion engineering’ concept in the manufacturing of new generation AHSS. More... »

PAGES

1-16

References to SciGraph publications

  • 2012-12-11. A Reaction Between High Mn-High Al Steel and CaO-SiO2-Type Molten Mold Flux: Part II. Reaction Mechanism, Interface Morphology, and Al2O3 Accumulation in Molten Mold Flux in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2015-07-09. Formation Mechanism of SiO2-Type Inclusions in Si-Mn-Killed Steel Wires Containing Limited Aluminum Content in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2019-11-04. Behavior of Dual-Phase (MnO-SiO2-Al2O3) + (SiO2) Inclusions in Saw Wire Steels During Hot Rolling and Cold Drawing in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2019-01-23. Evolution Mechanism of Inclusions in Medium-Manganese Steel by Mg Treatment with Different Aluminum Contents in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2017-05-24. Agglomeration of Non-metallic Inclusions at the Steel/Ar Interface: Model Application in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2022-01-15. Effect of Al content on the reaction between Fe-10Mn-xAl (x = 0.035wt%, 0.5wt%, 1wt%, and 2wt%) steel and CaO-SiO2-Al2O3-MgO slag in INTERNATIONAL JOURNAL OF MINERALS, METALLURGY AND MATERIALS
  • 2019-04-19. Effect of volume fraction and mechanical stability of austenite on ductility of medium Mn steel in JOURNAL OF IRON AND STEEL RESEARCH INTERNATIONAL
  • 2007-08-16. Synthesis and characteristics of monticellite bioactive ceramic in JOURNAL OF MATERIALS SCIENCE: MATERIALS IN MEDICINE
  • 2021-05-06. New insights into the properties of high-manganese steel in INTERNATIONAL JOURNAL OF MINERALS, METALLURGY AND MATERIALS
  • 2017-07-24. Agglomeration of Non-metallic Inclusions at Steel/Ar Interface: In-Situ Observation Experiments and Model Validation in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2017-07-18. Evolution of Oxide Inclusions in Si-Mn Killed Steels During Hot-Rolling Process in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2012-04-20. Interfacial Reaction Between CaO-SiO2-MgO-Al2O3 Flux and Fe-xMn-yAl (x = 10 and 20 mass pct, y = 1, 3, and 6 mass pct) Steel at 1873 K (1600 °C) in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2018-06-08. High-Temperature Deformation Behavior of MnS in 1215MS Steel in METALS AND MATERIALS INTERNATIONAL
  • 2017-11-01. Effects of strain states on stability of retained austenite in medium Mn steels in JOURNAL OF IRON AND STEEL RESEARCH INTERNATIONAL
  • 2021-08-10. Mn evaporation and denitrification behaviors of molten Mn steel in the vacuum refining with slag process in INTERNATIONAL JOURNAL OF MINERALS, METALLURGY AND MATERIALS
  • 2010-06. Intrinsic hardness of crystalline solids in JOURNAL OF SUPERHARD MATERIALS
  • 2012-02-18. Characterization of Nonmetallic Inclusions in High-Manganese and Aluminum-Alloyed Austenitic Steels in METALLURGICAL AND MATERIALS TRANSACTIONS A
  • 2017-12-27. Deformability of Oxide Inclusions in Tire Cord Steels in METALLURGICAL AND MATERIALS TRANSACTIONS B
  • 2011-04-27. Austenite Stability Effects on Tensile Behavior of Manganese-Enriched-Austenite Transformation-Induced Plasticity Steel in METALLURGICAL AND MATERIALS TRANSACTIONS A
  • 2021-02-28. Effects of strain rate on austenite stability and mechanical properties in a 5Mn steel in JOURNAL OF IRON AND STEEL RESEARCH INTERNATIONAL
  • Identifiers

    URI

    http://scigraph.springernature.com/pub.10.1007/s11663-022-02517-2

    DOI

    http://dx.doi.org/10.1007/s11663-022-02517-2

    DIMENSIONS

    https://app.dimensions.ai/details/publication/pub.1147386192


    Indexing Status Check whether this publication has been indexed by Scopus and Web Of Science using the SN Indexing Status Tool
    Incoming Citations Browse incoming citations for this publication using opencitations.net

    JSON-LD is the canonical representation for SciGraph data.

    TIP: You can open this SciGraph record using an external JSON-LD service: JSON-LD Playground Google SDTT

    [
      {
        "@context": "https://springernature.github.io/scigraph/jsonld/sgcontext.json", 
        "about": [
          {
            "id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/09", 
            "inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/", 
            "name": "Engineering", 
            "type": "DefinedTerm"
          }, 
          {
            "id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/0912", 
            "inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/", 
            "name": "Materials Engineering", 
            "type": "DefinedTerm"
          }
        ], 
        "author": [
          {
            "affiliation": {
              "alternateName": "Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden", 
              "id": "http://www.grid.ac/institutes/grid.5037.1", 
              "name": [
                "The State Key Laboratory of Refractories and Metallurgy, Wuhan University of Science and Technology, 430081, Wuhan, China", 
                "Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Wang", 
            "givenName": "Yong", 
            "type": "Person"
          }, 
          {
            "affiliation": {
              "alternateName": "Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China", 
              "id": "http://www.grid.ac/institutes/grid.69775.3a", 
              "name": [
                "Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden", 
                "Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Yang", 
            "givenName": "Yonggang", 
            "id": "sg:person.010072304706.86", 
            "sameAs": [
              "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.010072304706.86"
            ], 
            "type": "Person"
          }, 
          {
            "affiliation": {
              "alternateName": "College of Materials Science and Engineering, Chongqing University, 400044, Chongqing, China", 
              "id": "http://www.grid.ac/institutes/grid.190737.b", 
              "name": [
                "National Engineering Research Center for Magnesium Alloys, Chongqing University, 400044, Chongqing, China", 
                "College of Materials Science and Engineering, Chongqing University, 400044, Chongqing, China"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Dong", 
            "givenName": "Zhihua", 
            "id": "sg:person.016021575573.69", 
            "sameAs": [
              "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.016021575573.69"
            ], 
            "type": "Person"
          }, 
          {
            "affiliation": {
              "alternateName": "Department of Materials Science and Chemical Engineering, Hanyang University, 15588, Ansan, Korea", 
              "id": "http://www.grid.ac/institutes/grid.49606.3d", 
              "name": [
                "Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden", 
                "Department of Materials Science and Chemical Engineering, Hanyang University, 15588, Ansan, Korea"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Park", 
            "givenName": "Joo Hyun", 
            "id": "sg:person.012760302120.62", 
            "sameAs": [
              "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.012760302120.62"
            ], 
            "type": "Person"
          }, 
          {
            "affiliation": {
              "alternateName": "Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China", 
              "id": "http://www.grid.ac/institutes/grid.69775.3a", 
              "name": [
                "Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Mi", 
            "givenName": "Zhenli", 
            "id": "sg:person.014204661730.85", 
            "sameAs": [
              "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.014204661730.85"
            ], 
            "type": "Person"
          }, 
          {
            "affiliation": {
              "alternateName": "Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China", 
              "id": "http://www.grid.ac/institutes/grid.69775.3a", 
              "name": [
                "Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Mao", 
            "givenName": "Xinping", 
            "id": "sg:person.011350756314.16", 
            "sameAs": [
              "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.011350756314.16"
            ], 
            "type": "Person"
          }, 
          {
            "affiliation": {
              "alternateName": "Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden", 
              "id": "http://www.grid.ac/institutes/grid.5037.1", 
              "name": [
                "Key Laboratory of Electromagnetic Processing of Materials (Ministry of Education), School of Metallurgy, Northeastern University, 110819, Shenyang, China", 
                "Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden"
              ], 
              "type": "Organization"
            }, 
            "familyName": "Mu", 
            "givenName": "Wangzhong", 
            "id": "sg:person.010526521245.76", 
            "sameAs": [
              "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.010526521245.76"
            ], 
            "type": "Person"
          }
        ], 
        "citation": [
          {
            "id": "sg:pub.10.1007/s11663-017-1134-2", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1100090001", 
              "https://doi.org/10.1007/s11663-017-1134-2"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11661-011-0687-y", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1027321423", 
              "https://doi.org/10.1007/s11661-011-0687-y"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s12540-018-0137-0", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1104476549", 
              "https://doi.org/10.1007/s12540-018-0137-0"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s12613-021-2311-5", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1140292929", 
              "https://doi.org/10.1007/s12613-021-2311-5"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-017-0998-5", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1085584938", 
              "https://doi.org/10.1007/s11663-017-0998-5"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-012-9769-5", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1007305668", 
              "https://doi.org/10.1007/s11663-012-9769-5"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-012-9667-x", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1033302420", 
              "https://doi.org/10.1007/s11663-012-9667-x"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s42243-019-00267-1", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1113603262", 
              "https://doi.org/10.1007/s42243-019-00267-1"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-015-0411-1", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1040365362", 
              "https://doi.org/10.1007/s11663-015-0411-1"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s10856-007-3233-0", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1048773263", 
              "https://doi.org/10.1007/s10856-007-3233-0"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s12613-021-2298-y", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1144706890", 
              "https://doi.org/10.1007/s12613-021-2298-y"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-019-01727-5", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1122305063", 
              "https://doi.org/10.1007/s11663-019-01727-5"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s42243-021-00569-3", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1135846836", 
              "https://doi.org/10.1007/s42243-021-00569-3"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-017-1027-4", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1090880989", 
              "https://doi.org/10.1007/s11663-017-1027-4"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s12613-020-2166-1", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1137808579", 
              "https://doi.org/10.1007/s12613-020-2166-1"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-017-1025-6", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1090773778", 
              "https://doi.org/10.1007/s11663-017-1025-6"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11663-019-01514-2", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1111630049", 
              "https://doi.org/10.1007/s11663-019-01514-2"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1016/s1006-706x(17)30163-2", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1092690947", 
              "https://doi.org/10.1016/s1006-706x(17)30163-2"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.1007/s11661-012-1088-6", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1047966465", 
              "https://doi.org/10.1007/s11661-012-1088-6"
            ], 
            "type": "CreativeWork"
          }, 
          {
            "id": "sg:pub.10.3103/s1063457610030044", 
            "sameAs": [
              "https://app.dimensions.ai/details/publication/pub.1070974020", 
              "https://doi.org/10.3103/s1063457610030044"
            ], 
            "type": "CreativeWork"
          }
        ], 
        "datePublished": "2022-04-26", 
        "datePublishedReg": "2022-04-26", 
        "description": "Medium Mn steel (MMS) is a new category of the third-generation advanced high strength steel (3rd AHSS) which is developed in the recent 1-2 decades due to a unique trade-off of strength and ductility. Thus, this steel grade has a wide application potential in different fields of industry. The current work provides a fundamental study of the effect of hot-rolling on the inclusion deformation in MMS including a varied 7 to 9 mass pct Mn. Specifically, the deformation behavior of different types of inclusions (i.e., Mn(S,Se), liquid oxide (MnSiO3), MnAl2O4, and complex oxy-sulfide) was investigated. The results show that both MnSiO3 and Mn(S,Se) are soft inclusions which are able to be deformed during the hot-rolling process but MnAl2O4 does not. The aspect ratio of soft inclusions increases significantly from as-cast to hot-rolling conditions. When the maximum size of different inclusions is similar, Mn(S,Se) deforms more than MnSiO3 does. This is due to a joint influence of physical parameters including Young\u2019s modulus, coefficient of thermal expansion (\u03b1), etc. However, when the maximum size of one type of inclusion (e.g., MnSiO3) is much larger than another one (e.g., Mn(S,Se)), this maximum size of soft inclusions plays a dominant role than other factors. In addition, the deformation behavior of dual-phase inclusion depends on the major phase, i.e., either oxide or sulfide. Last but not least, empirical correlations between the reduction ratio of the thickness of plate, grain size, and aspect ratio of oxide and sulfide inclusions after hot-rolling are provided quantitatively. This work aims to contribute to the \u2018inclusion engineering\u2019 concept in the manufacturing of new generation AHSS.", 
        "genre": "article", 
        "id": "sg:pub.10.1007/s11663-022-02517-2", 
        "inLanguage": "en", 
        "isAccessibleForFree": true, 
        "isPartOf": [
          {
            "id": "sg:journal.1136775", 
            "issn": [
              "1073-5615", 
              "1543-1916"
            ], 
            "name": "Metallurgical and Materials Transactions B", 
            "publisher": "Springer Nature", 
            "type": "Periodical"
          }
        ], 
        "keywords": [
          "medium Mn steel", 
          "deformation behavior", 
          "soft inclusions", 
          "inclusion engineering", 
          "Mn steel", 
          "third-generation advanced high-strength steels", 
          "advanced high strength steels", 
          "hot-rolling conditions", 
          "dual-phase inclusions", 
          "high strength steel", 
          "hot rolling process", 
          "sulfide inclusions", 
          "thickness of plate", 
          "ratio of oxide", 
          "generation AHSS", 
          "strength steel", 
          "steel grades", 
          "pct Mn", 
          "inclusion deformation", 
          "wide application potential", 
          "Young's modulus", 
          "grain size", 
          "thermal expansion", 
          "steel", 
          "aspect ratio", 
          "empirical correlations", 
          "reduction ratio", 
          "application potential", 
          "rolling", 
          "fundamental studies", 
          "modulus", 
          "physical parameters", 
          "oxide", 
          "MnSiO3", 
          "types of inclusions", 
          "major phases", 
          "current work", 
          "different inclusions", 
          "engineering", 
          "maximum size", 
          "ductility", 
          "AHSS", 
          "deformation", 
          "manufacturing", 
          "behavior", 
          "MnAl2O4", 
          "thickness", 
          "ratio", 
          "size", 
          "dominant role", 
          "plate", 
          "strength", 
          "different fields", 
          "process", 
          "work", 
          "different types", 
          "coefficient", 
          "parameters", 
          "joint influence", 
          "cast", 
          "industry", 
          "phase", 
          "sulfide", 
          "field", 
          "influence", 
          "conditions", 
          "effect", 
          "Mn", 
          "inclusion", 
          "types", 
          "results", 
          "potential", 
          "expansion", 
          "addition", 
          "one", 
          "concept", 
          "new category", 
          "study", 
          "correlation", 
          "factors", 
          "decades", 
          "grade", 
          "role", 
          "categories"
        ], 
        "name": "Inclusion Engineering in Medium Mn Steels: Effect of Hot-Rolling Process on the Deformation Behaviors of Oxide and Sulfide Inclusions", 
        "pagination": "1-16", 
        "productId": [
          {
            "name": "dimensions_id", 
            "type": "PropertyValue", 
            "value": [
              "pub.1147386192"
            ]
          }, 
          {
            "name": "doi", 
            "type": "PropertyValue", 
            "value": [
              "10.1007/s11663-022-02517-2"
            ]
          }
        ], 
        "sameAs": [
          "https://doi.org/10.1007/s11663-022-02517-2", 
          "https://app.dimensions.ai/details/publication/pub.1147386192"
        ], 
        "sdDataset": "articles", 
        "sdDatePublished": "2022-06-01T22:25", 
        "sdLicense": "https://scigraph.springernature.com/explorer/license/", 
        "sdPublisher": {
          "name": "Springer Nature - SN SciGraph project", 
          "type": "Organization"
        }, 
        "sdSource": "s3://com-springernature-scigraph/baseset/20220601/entities/gbq_results/article/article_942.jsonl", 
        "type": "ScholarlyArticle", 
        "url": "https://doi.org/10.1007/s11663-022-02517-2"
      }
    ]
     

    Download the RDF metadata as:  json-ld nt turtle xml License info

    HOW TO GET THIS DATA PROGRAMMATICALLY:

    JSON-LD is a popular format for linked data which is fully compatible with JSON.

    curl -H 'Accept: application/ld+json' 'https://scigraph.springernature.com/pub.10.1007/s11663-022-02517-2'

    N-Triples is a line-based linked data format ideal for batch operations.

    curl -H 'Accept: application/n-triples' 'https://scigraph.springernature.com/pub.10.1007/s11663-022-02517-2'

    Turtle is a human-readable linked data format.

    curl -H 'Accept: text/turtle' 'https://scigraph.springernature.com/pub.10.1007/s11663-022-02517-2'

    RDF/XML is a standard XML format for linked data.

    curl -H 'Accept: application/rdf+xml' 'https://scigraph.springernature.com/pub.10.1007/s11663-022-02517-2'


     

    This table displays all metadata directly associated to this object as RDF triples.

    271 TRIPLES      22 PREDICATES      127 URIs      99 LITERALS      4 BLANK NODES

    Subject Predicate Object
    1 sg:pub.10.1007/s11663-022-02517-2 schema:about anzsrc-for:09
    2 anzsrc-for:0912
    3 schema:author Nf741891018484e038b2cb500dc74a8bb
    4 schema:citation sg:pub.10.1007/s10856-007-3233-0
    5 sg:pub.10.1007/s11661-011-0687-y
    6 sg:pub.10.1007/s11661-012-1088-6
    7 sg:pub.10.1007/s11663-012-9667-x
    8 sg:pub.10.1007/s11663-012-9769-5
    9 sg:pub.10.1007/s11663-015-0411-1
    10 sg:pub.10.1007/s11663-017-0998-5
    11 sg:pub.10.1007/s11663-017-1025-6
    12 sg:pub.10.1007/s11663-017-1027-4
    13 sg:pub.10.1007/s11663-017-1134-2
    14 sg:pub.10.1007/s11663-019-01514-2
    15 sg:pub.10.1007/s11663-019-01727-5
    16 sg:pub.10.1007/s12540-018-0137-0
    17 sg:pub.10.1007/s12613-020-2166-1
    18 sg:pub.10.1007/s12613-021-2298-y
    19 sg:pub.10.1007/s12613-021-2311-5
    20 sg:pub.10.1007/s42243-019-00267-1
    21 sg:pub.10.1007/s42243-021-00569-3
    22 sg:pub.10.1016/s1006-706x(17)30163-2
    23 sg:pub.10.3103/s1063457610030044
    24 schema:datePublished 2022-04-26
    25 schema:datePublishedReg 2022-04-26
    26 schema:description Medium Mn steel (MMS) is a new category of the third-generation advanced high strength steel (3rd AHSS) which is developed in the recent 1-2 decades due to a unique trade-off of strength and ductility. Thus, this steel grade has a wide application potential in different fields of industry. The current work provides a fundamental study of the effect of hot-rolling on the inclusion deformation in MMS including a varied 7 to 9 mass pct Mn. Specifically, the deformation behavior of different types of inclusions (i.e., Mn(S,Se), liquid oxide (MnSiO3), MnAl2O4, and complex oxy-sulfide) was investigated. The results show that both MnSiO3 and Mn(S,Se) are soft inclusions which are able to be deformed during the hot-rolling process but MnAl2O4 does not. The aspect ratio of soft inclusions increases significantly from as-cast to hot-rolling conditions. When the maximum size of different inclusions is similar, Mn(S,Se) deforms more than MnSiO3 does. This is due to a joint influence of physical parameters including Young’s modulus, coefficient of thermal expansion (α), etc. However, when the maximum size of one type of inclusion (e.g., MnSiO3) is much larger than another one (e.g., Mn(S,Se)), this maximum size of soft inclusions plays a dominant role than other factors. In addition, the deformation behavior of dual-phase inclusion depends on the major phase, i.e., either oxide or sulfide. Last but not least, empirical correlations between the reduction ratio of the thickness of plate, grain size, and aspect ratio of oxide and sulfide inclusions after hot-rolling are provided quantitatively. This work aims to contribute to the ‘inclusion engineering’ concept in the manufacturing of new generation AHSS.
    27 schema:genre article
    28 schema:inLanguage en
    29 schema:isAccessibleForFree true
    30 schema:isPartOf sg:journal.1136775
    31 schema:keywords AHSS
    32 Mn
    33 Mn steel
    34 MnAl2O4
    35 MnSiO3
    36 Young's modulus
    37 addition
    38 advanced high strength steels
    39 application potential
    40 aspect ratio
    41 behavior
    42 cast
    43 categories
    44 coefficient
    45 concept
    46 conditions
    47 correlation
    48 current work
    49 decades
    50 deformation
    51 deformation behavior
    52 different fields
    53 different inclusions
    54 different types
    55 dominant role
    56 dual-phase inclusions
    57 ductility
    58 effect
    59 empirical correlations
    60 engineering
    61 expansion
    62 factors
    63 field
    64 fundamental studies
    65 generation AHSS
    66 grade
    67 grain size
    68 high strength steel
    69 hot rolling process
    70 hot-rolling conditions
    71 inclusion
    72 inclusion deformation
    73 inclusion engineering
    74 industry
    75 influence
    76 joint influence
    77 major phases
    78 manufacturing
    79 maximum size
    80 medium Mn steel
    81 modulus
    82 new category
    83 one
    84 oxide
    85 parameters
    86 pct Mn
    87 phase
    88 physical parameters
    89 plate
    90 potential
    91 process
    92 ratio
    93 ratio of oxide
    94 reduction ratio
    95 results
    96 role
    97 rolling
    98 size
    99 soft inclusions
    100 steel
    101 steel grades
    102 strength
    103 strength steel
    104 study
    105 sulfide
    106 sulfide inclusions
    107 thermal expansion
    108 thickness
    109 thickness of plate
    110 third-generation advanced high-strength steels
    111 types
    112 types of inclusions
    113 wide application potential
    114 work
    115 schema:name Inclusion Engineering in Medium Mn Steels: Effect of Hot-Rolling Process on the Deformation Behaviors of Oxide and Sulfide Inclusions
    116 schema:pagination 1-16
    117 schema:productId N197f059ab2c14f9b919614c8b92f2d18
    118 Nb4bc36da09654066be21f26bcde01c00
    119 schema:sameAs https://app.dimensions.ai/details/publication/pub.1147386192
    120 https://doi.org/10.1007/s11663-022-02517-2
    121 schema:sdDatePublished 2022-06-01T22:25
    122 schema:sdLicense https://scigraph.springernature.com/explorer/license/
    123 schema:sdPublisher Nd31310c4e58e4881a2aebca63b6c0519
    124 schema:url https://doi.org/10.1007/s11663-022-02517-2
    125 sgo:license sg:explorer/license/
    126 sgo:sdDataset articles
    127 rdf:type schema:ScholarlyArticle
    128 N197f059ab2c14f9b919614c8b92f2d18 schema:name dimensions_id
    129 schema:value pub.1147386192
    130 rdf:type schema:PropertyValue
    131 N1d829b3f2d304144ab91e846021c4faa schema:affiliation grid-institutes:grid.5037.1
    132 schema:familyName Wang
    133 schema:givenName Yong
    134 rdf:type schema:Person
    135 N66e237bda9224c989fafba18f44cbfb6 rdf:first sg:person.016021575573.69
    136 rdf:rest N7578089491f8440dbd115813f1145fec
    137 N7578089491f8440dbd115813f1145fec rdf:first sg:person.012760302120.62
    138 rdf:rest Nf47eee100ce04b4087c44a9e72df0976
    139 Nb4bc36da09654066be21f26bcde01c00 schema:name doi
    140 schema:value 10.1007/s11663-022-02517-2
    141 rdf:type schema:PropertyValue
    142 Ncc9de99ad41040c6b2df82d7dc5804e7 rdf:first sg:person.010526521245.76
    143 rdf:rest rdf:nil
    144 Nd31310c4e58e4881a2aebca63b6c0519 schema:name Springer Nature - SN SciGraph project
    145 rdf:type schema:Organization
    146 Nd769510a06c14beb8ce8fa2ad61bb9b2 rdf:first sg:person.010072304706.86
    147 rdf:rest N66e237bda9224c989fafba18f44cbfb6
    148 Ne498ae86c2ff4b0ba9caac7b5fb64a18 rdf:first sg:person.011350756314.16
    149 rdf:rest Ncc9de99ad41040c6b2df82d7dc5804e7
    150 Nf47eee100ce04b4087c44a9e72df0976 rdf:first sg:person.014204661730.85
    151 rdf:rest Ne498ae86c2ff4b0ba9caac7b5fb64a18
    152 Nf741891018484e038b2cb500dc74a8bb rdf:first N1d829b3f2d304144ab91e846021c4faa
    153 rdf:rest Nd769510a06c14beb8ce8fa2ad61bb9b2
    154 anzsrc-for:09 schema:inDefinedTermSet anzsrc-for:
    155 schema:name Engineering
    156 rdf:type schema:DefinedTerm
    157 anzsrc-for:0912 schema:inDefinedTermSet anzsrc-for:
    158 schema:name Materials Engineering
    159 rdf:type schema:DefinedTerm
    160 sg:journal.1136775 schema:issn 1073-5615
    161 1543-1916
    162 schema:name Metallurgical and Materials Transactions B
    163 schema:publisher Springer Nature
    164 rdf:type schema:Periodical
    165 sg:person.010072304706.86 schema:affiliation grid-institutes:grid.69775.3a
    166 schema:familyName Yang
    167 schema:givenName Yonggang
    168 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.010072304706.86
    169 rdf:type schema:Person
    170 sg:person.010526521245.76 schema:affiliation grid-institutes:grid.5037.1
    171 schema:familyName Mu
    172 schema:givenName Wangzhong
    173 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.010526521245.76
    174 rdf:type schema:Person
    175 sg:person.011350756314.16 schema:affiliation grid-institutes:grid.69775.3a
    176 schema:familyName Mao
    177 schema:givenName Xinping
    178 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.011350756314.16
    179 rdf:type schema:Person
    180 sg:person.012760302120.62 schema:affiliation grid-institutes:grid.49606.3d
    181 schema:familyName Park
    182 schema:givenName Joo Hyun
    183 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.012760302120.62
    184 rdf:type schema:Person
    185 sg:person.014204661730.85 schema:affiliation grid-institutes:grid.69775.3a
    186 schema:familyName Mi
    187 schema:givenName Zhenli
    188 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.014204661730.85
    189 rdf:type schema:Person
    190 sg:person.016021575573.69 schema:affiliation grid-institutes:grid.190737.b
    191 schema:familyName Dong
    192 schema:givenName Zhihua
    193 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.016021575573.69
    194 rdf:type schema:Person
    195 sg:pub.10.1007/s10856-007-3233-0 schema:sameAs https://app.dimensions.ai/details/publication/pub.1048773263
    196 https://doi.org/10.1007/s10856-007-3233-0
    197 rdf:type schema:CreativeWork
    198 sg:pub.10.1007/s11661-011-0687-y schema:sameAs https://app.dimensions.ai/details/publication/pub.1027321423
    199 https://doi.org/10.1007/s11661-011-0687-y
    200 rdf:type schema:CreativeWork
    201 sg:pub.10.1007/s11661-012-1088-6 schema:sameAs https://app.dimensions.ai/details/publication/pub.1047966465
    202 https://doi.org/10.1007/s11661-012-1088-6
    203 rdf:type schema:CreativeWork
    204 sg:pub.10.1007/s11663-012-9667-x schema:sameAs https://app.dimensions.ai/details/publication/pub.1033302420
    205 https://doi.org/10.1007/s11663-012-9667-x
    206 rdf:type schema:CreativeWork
    207 sg:pub.10.1007/s11663-012-9769-5 schema:sameAs https://app.dimensions.ai/details/publication/pub.1007305668
    208 https://doi.org/10.1007/s11663-012-9769-5
    209 rdf:type schema:CreativeWork
    210 sg:pub.10.1007/s11663-015-0411-1 schema:sameAs https://app.dimensions.ai/details/publication/pub.1040365362
    211 https://doi.org/10.1007/s11663-015-0411-1
    212 rdf:type schema:CreativeWork
    213 sg:pub.10.1007/s11663-017-0998-5 schema:sameAs https://app.dimensions.ai/details/publication/pub.1085584938
    214 https://doi.org/10.1007/s11663-017-0998-5
    215 rdf:type schema:CreativeWork
    216 sg:pub.10.1007/s11663-017-1025-6 schema:sameAs https://app.dimensions.ai/details/publication/pub.1090773778
    217 https://doi.org/10.1007/s11663-017-1025-6
    218 rdf:type schema:CreativeWork
    219 sg:pub.10.1007/s11663-017-1027-4 schema:sameAs https://app.dimensions.ai/details/publication/pub.1090880989
    220 https://doi.org/10.1007/s11663-017-1027-4
    221 rdf:type schema:CreativeWork
    222 sg:pub.10.1007/s11663-017-1134-2 schema:sameAs https://app.dimensions.ai/details/publication/pub.1100090001
    223 https://doi.org/10.1007/s11663-017-1134-2
    224 rdf:type schema:CreativeWork
    225 sg:pub.10.1007/s11663-019-01514-2 schema:sameAs https://app.dimensions.ai/details/publication/pub.1111630049
    226 https://doi.org/10.1007/s11663-019-01514-2
    227 rdf:type schema:CreativeWork
    228 sg:pub.10.1007/s11663-019-01727-5 schema:sameAs https://app.dimensions.ai/details/publication/pub.1122305063
    229 https://doi.org/10.1007/s11663-019-01727-5
    230 rdf:type schema:CreativeWork
    231 sg:pub.10.1007/s12540-018-0137-0 schema:sameAs https://app.dimensions.ai/details/publication/pub.1104476549
    232 https://doi.org/10.1007/s12540-018-0137-0
    233 rdf:type schema:CreativeWork
    234 sg:pub.10.1007/s12613-020-2166-1 schema:sameAs https://app.dimensions.ai/details/publication/pub.1137808579
    235 https://doi.org/10.1007/s12613-020-2166-1
    236 rdf:type schema:CreativeWork
    237 sg:pub.10.1007/s12613-021-2298-y schema:sameAs https://app.dimensions.ai/details/publication/pub.1144706890
    238 https://doi.org/10.1007/s12613-021-2298-y
    239 rdf:type schema:CreativeWork
    240 sg:pub.10.1007/s12613-021-2311-5 schema:sameAs https://app.dimensions.ai/details/publication/pub.1140292929
    241 https://doi.org/10.1007/s12613-021-2311-5
    242 rdf:type schema:CreativeWork
    243 sg:pub.10.1007/s42243-019-00267-1 schema:sameAs https://app.dimensions.ai/details/publication/pub.1113603262
    244 https://doi.org/10.1007/s42243-019-00267-1
    245 rdf:type schema:CreativeWork
    246 sg:pub.10.1007/s42243-021-00569-3 schema:sameAs https://app.dimensions.ai/details/publication/pub.1135846836
    247 https://doi.org/10.1007/s42243-021-00569-3
    248 rdf:type schema:CreativeWork
    249 sg:pub.10.1016/s1006-706x(17)30163-2 schema:sameAs https://app.dimensions.ai/details/publication/pub.1092690947
    250 https://doi.org/10.1016/s1006-706x(17)30163-2
    251 rdf:type schema:CreativeWork
    252 sg:pub.10.3103/s1063457610030044 schema:sameAs https://app.dimensions.ai/details/publication/pub.1070974020
    253 https://doi.org/10.3103/s1063457610030044
    254 rdf:type schema:CreativeWork
    255 grid-institutes:grid.190737.b schema:alternateName College of Materials Science and Engineering, Chongqing University, 400044, Chongqing, China
    256 schema:name College of Materials Science and Engineering, Chongqing University, 400044, Chongqing, China
    257 National Engineering Research Center for Magnesium Alloys, Chongqing University, 400044, Chongqing, China
    258 rdf:type schema:Organization
    259 grid-institutes:grid.49606.3d schema:alternateName Department of Materials Science and Chemical Engineering, Hanyang University, 15588, Ansan, Korea
    260 schema:name Department of Materials Science and Chemical Engineering, Hanyang University, 15588, Ansan, Korea
    261 Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden
    262 rdf:type schema:Organization
    263 grid-institutes:grid.5037.1 schema:alternateName Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden
    264 schema:name Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden
    265 Key Laboratory of Electromagnetic Processing of Materials (Ministry of Education), School of Metallurgy, Northeastern University, 110819, Shenyang, China
    266 The State Key Laboratory of Refractories and Metallurgy, Wuhan University of Science and Technology, 430081, Wuhan, China
    267 rdf:type schema:Organization
    268 grid-institutes:grid.69775.3a schema:alternateName Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China
    269 schema:name Beijing Advanced Innovation Center for Materials Genome Engineering, National Engineering Research Center for Advanced Rolling Technology, University of Science and Technology Beijing, 100083, Beijing, China
    270 Department of Materials Science and Engineering, KTH Royal Institute of Technology, 100 44, Stockholm, Sweden
    271 rdf:type schema:Organization
     




    Preview window. Press ESC to close (or click here)


    ...