Thermodynamic Simulation and Computational Study of the Carbothermal Reduction of Converter Steel Slag
Micropulverization of steel slag is an important way to achieve its efficient utilization. Its purpose is to reduce the particle size of steel slag and improve its iron recovery rate. However, the high hardness and poor grindability of steel slag make it constrained by process and cost. Carbon therm...
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| Veröffentlicht in: | JOM (1989) 2024-11, Vol.76 (11), p.6568-6576 |
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| description | Micropulverization of steel slag is an important way to achieve its efficient utilization. Its purpose is to reduce the particle size of steel slag and improve its iron recovery rate. However, the high hardness and poor grindability of steel slag make it constrained by process and cost. Carbon thermal reduction can reduce the phosphorus dissolved in dicalcium silicate, reduce the influence of phosphorus on the crystal transformation of dicalcium silicate, and facilitate the self-pulverization of steel slag. At the same time, it can reduce the iron oxide in the slag to metallic iron, achieving the goal of recovering iron. To study the changes in phase types and contents of equilibrium products during the carbothermal reduction of converter slag, based on the variables of reduction temperature, alkalinity, and carbon ratio (coke-to-slag ratio), FactSage 7.1 thermodynamic software was used for calculation and analysis. The study reveals under a certain coke-slag ratio, with the increase of reduction temperature, the residual C content in the equilibrium phase composition shows a decreasing trend, while the Fe
3
C and P
2
gas contents show an increasing trend, indicating that the high temperature is favorable to the reduction of iron oxides and apatite, especially to the gasification of dephosphorization. With reduction temperature increasing, the contents of Fe
3
P/Fe
2
P in the equilibrium phase composition decrease, while the contents of Mn
2
P and P
2
(g) increase. This indicates that the reduction temperature has significant influence on the stability sequence of phosphorus-containing phases, with the stability enhancement order as Fe
3
P → Fe
2
P → Mn
2
P → P
2
(g). High temperature favors the gasification and removal of phosphorus. Under constant coke-to-slag ratio and reduction temperature, the increase in the alkalinity of charge leads to elevation of Fe
3
C content in the equilibrium phase composition, indicating that higher alkalinity promotes the reduction of iron oxides. As the alkalinity of the mixture increases, the silicate liquid phase content in the equilibrium phase composition shows a decreasing trend, and an alkalinity of 1.8 generates the largest amount of liquid phase. The alkalinity of the mixture in the range of 1.8 to 2.2 is conducive to the generation of
α
-C
2
S and self-pulverization of the product, with the content of
α
-C
2
S being the largest when the alkalinity is 2.0. Changes in the coke-to-slag ratio have minimal impact on th |
| doi_str_mv | 10.1007/s11837-024-06822-w |
| format | Article |
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3
C and P
2
gas contents show an increasing trend, indicating that the high temperature is favorable to the reduction of iron oxides and apatite, especially to the gasification of dephosphorization. With reduction temperature increasing, the contents of Fe
3
P/Fe
2
P in the equilibrium phase composition decrease, while the contents of Mn
2
P and P
2
(g) increase. This indicates that the reduction temperature has significant influence on the stability sequence of phosphorus-containing phases, with the stability enhancement order as Fe
3
P → Fe
2
P → Mn
2
P → P
2
(g). High temperature favors the gasification and removal of phosphorus. Under constant coke-to-slag ratio and reduction temperature, the increase in the alkalinity of charge leads to elevation of Fe
3
C content in the equilibrium phase composition, indicating that higher alkalinity promotes the reduction of iron oxides. As the alkalinity of the mixture increases, the silicate liquid phase content in the equilibrium phase composition shows a decreasing trend, and an alkalinity of 1.8 generates the largest amount of liquid phase. The alkalinity of the mixture in the range of 1.8 to 2.2 is conducive to the generation of
α
-C
2
S and self-pulverization of the product, with the content of
α
-C
2
S being the largest when the alkalinity is 2.0. Changes in the coke-to-slag ratio have minimal impact on the phase types and contents of equilibrium products during the carbothermal reduction of converter slag. Thermodynamic calculations indicate that the temperature range favorable for steel slag micronization is 1450–1500°C, the alkalinity range is 1.8–2.2, and the coke-slag ratio range is 10:90–15:85. This range of conditions facilitates the generation of
α
-C
2
S and the best pulverization of steel slag.</description><identifier>ISSN: 1047-4838</identifier><identifier>EISSN: 1543-1851</identifier><identifier>DOI: 10.1007/s11837-024-06822-w</identifier><language>eng</language><publisher>New York: Springer US</publisher><subject>Alkalinity ; Apatite ; Carbon ; Cementite ; Chemistry/Food Science ; Coke ; Dephosphorizing ; Dicalcium silicate ; Earth Sciences ; Engineering ; Environment ; Equilibrium ; Gasification ; Grindability ; High temperature ; Iron ; Iron carbides ; Iron oxides ; Liquid phases ; Minerals ; Mixtures ; Phase composition ; Phosphorus ; Physics ; Ratios ; Raw materials ; Slag ; Stability ; Steel industry ; Technical Article ; Thermal reduction ; Thermal transformations ; Thermodynamics</subject><ispartof>JOM (1989), 2024-11, Vol.76 (11), p.6568-6576</ispartof><rights>The Minerals, Metals & Materials Society 2024. Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.</rights><rights>Copyright Springer Nature B.V. Nov 2024</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><cites>FETCH-LOGICAL-c200t-f6e877105de2873b37dea91c16645e58b1d78cb8b8457fdb6b0da166843274e73</cites><orcidid>0009-0001-7342-8433</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://link.springer.com/content/pdf/10.1007/s11837-024-06822-w$$EPDF$$P50$$Gspringer$$H</linktopdf><linktohtml>$$Uhttps://link.springer.com/10.1007/s11837-024-06822-w$$EHTML$$P50$$Gspringer$$H</linktohtml><link.rule.ids>314,776,780,27901,27902,41464,42533,51294</link.rule.ids></links><search><creatorcontrib>Zhang, Bokang</creatorcontrib><creatorcontrib>Luo, Guoping</creatorcontrib><creatorcontrib>Hao, Shuai</creatorcontrib><creatorcontrib>Chai, Yifan</creatorcontrib><title>Thermodynamic Simulation and Computational Study of the Carbothermal Reduction of Converter Steel Slag</title><title>JOM (1989)</title><addtitle>JOM</addtitle><description>Micropulverization of steel slag is an important way to achieve its efficient utilization. Its purpose is to reduce the particle size of steel slag and improve its iron recovery rate. However, the high hardness and poor grindability of steel slag make it constrained by process and cost. Carbon thermal reduction can reduce the phosphorus dissolved in dicalcium silicate, reduce the influence of phosphorus on the crystal transformation of dicalcium silicate, and facilitate the self-pulverization of steel slag. At the same time, it can reduce the iron oxide in the slag to metallic iron, achieving the goal of recovering iron. To study the changes in phase types and contents of equilibrium products during the carbothermal reduction of converter slag, based on the variables of reduction temperature, alkalinity, and carbon ratio (coke-to-slag ratio), FactSage 7.1 thermodynamic software was used for calculation and analysis. The study reveals under a certain coke-slag ratio, with the increase of reduction temperature, the residual C content in the equilibrium phase composition shows a decreasing trend, while the Fe
3
C and P
2
gas contents show an increasing trend, indicating that the high temperature is favorable to the reduction of iron oxides and apatite, especially to the gasification of dephosphorization. With reduction temperature increasing, the contents of Fe
3
P/Fe
2
P in the equilibrium phase composition decrease, while the contents of Mn
2
P and P
2
(g) increase. This indicates that the reduction temperature has significant influence on the stability sequence of phosphorus-containing phases, with the stability enhancement order as Fe
3
P → Fe
2
P → Mn
2
P → P
2
(g). High temperature favors the gasification and removal of phosphorus. Under constant coke-to-slag ratio and reduction temperature, the increase in the alkalinity of charge leads to elevation of Fe
3
C content in the equilibrium phase composition, indicating that higher alkalinity promotes the reduction of iron oxides. As the alkalinity of the mixture increases, the silicate liquid phase content in the equilibrium phase composition shows a decreasing trend, and an alkalinity of 1.8 generates the largest amount of liquid phase. The alkalinity of the mixture in the range of 1.8 to 2.2 is conducive to the generation of
α
-C
2
S and self-pulverization of the product, with the content of
α
-C
2
S being the largest when the alkalinity is 2.0. Changes in the coke-to-slag ratio have minimal impact on the phase types and contents of equilibrium products during the carbothermal reduction of converter slag. Thermodynamic calculations indicate that the temperature range favorable for steel slag micronization is 1450–1500°C, the alkalinity range is 1.8–2.2, and the coke-slag ratio range is 10:90–15:85. This range of conditions facilitates the generation of
α
-C
2
S and the best pulverization of steel slag.</description><subject>Alkalinity</subject><subject>Apatite</subject><subject>Carbon</subject><subject>Cementite</subject><subject>Chemistry/Food Science</subject><subject>Coke</subject><subject>Dephosphorizing</subject><subject>Dicalcium silicate</subject><subject>Earth Sciences</subject><subject>Engineering</subject><subject>Environment</subject><subject>Equilibrium</subject><subject>Gasification</subject><subject>Grindability</subject><subject>High temperature</subject><subject>Iron</subject><subject>Iron carbides</subject><subject>Iron oxides</subject><subject>Liquid phases</subject><subject>Minerals</subject><subject>Mixtures</subject><subject>Phase composition</subject><subject>Phosphorus</subject><subject>Physics</subject><subject>Ratios</subject><subject>Raw materials</subject><subject>Slag</subject><subject>Stability</subject><subject>Steel industry</subject><subject>Technical Article</subject><subject>Thermal reduction</subject><subject>Thermal transformations</subject><subject>Thermodynamics</subject><issn>1047-4838</issn><issn>1543-1851</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><recordid>eNp9kN1LwzAUxYMoOKf_gE8Fn6P5apM9SvELBoKbzyFtbreOtplJ6th_b7YJvvl07-Wc3-FyELql5J4SIh8CpYpLTJjApFCM4d0ZmtBccExVTs_TToTEQnF1ia5C2JAEiRmdoGa5Bt87ux9M39bZou3HzsTWDZkZbFa6fjvG4226bBFHu89ck8U1ZKXxlYsHOCkfYMf6SCW1dMM3-Ag-AQAJ68zqGl00pgtw8zun6PP5aVm-4vn7y1v5OMc1IyTipgAlJSW5BaYkr7i0YGa0pkUhcshVRa1UdaUqJXLZ2KqoiDVJVIIzKUDyKbo75W69-xohRL1xo0_PB80pk1xykpPkYidX7V0IHhq99W1v_F5Tog996lOfOvWpj33qXYL4CQrJPKzA_0X_Q_0Apox5yw</recordid><startdate>20241101</startdate><enddate>20241101</enddate><creator>Zhang, Bokang</creator><creator>Luo, Guoping</creator><creator>Hao, Shuai</creator><creator>Chai, Yifan</creator><general>Springer US</general><general>Springer Nature B.V</general><scope>AAYXX</scope><scope>CITATION</scope><scope>4T-</scope><scope>4U-</scope><scope>7SR</scope><scope>7TA</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><orcidid>https://orcid.org/0009-0001-7342-8433</orcidid></search><sort><creationdate>20241101</creationdate><title>Thermodynamic Simulation and Computational Study of the Carbothermal Reduction of Converter Steel Slag</title><author>Zhang, Bokang ; Luo, Guoping ; Hao, Shuai ; Chai, Yifan</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c200t-f6e877105de2873b37dea91c16645e58b1d78cb8b8457fdb6b0da166843274e73</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2024</creationdate><topic>Alkalinity</topic><topic>Apatite</topic><topic>Carbon</topic><topic>Cementite</topic><topic>Chemistry/Food Science</topic><topic>Coke</topic><topic>Dephosphorizing</topic><topic>Dicalcium silicate</topic><topic>Earth Sciences</topic><topic>Engineering</topic><topic>Environment</topic><topic>Equilibrium</topic><topic>Gasification</topic><topic>Grindability</topic><topic>High temperature</topic><topic>Iron</topic><topic>Iron carbides</topic><topic>Iron oxides</topic><topic>Liquid phases</topic><topic>Minerals</topic><topic>Mixtures</topic><topic>Phase composition</topic><topic>Phosphorus</topic><topic>Physics</topic><topic>Ratios</topic><topic>Raw materials</topic><topic>Slag</topic><topic>Stability</topic><topic>Steel industry</topic><topic>Technical Article</topic><topic>Thermal reduction</topic><topic>Thermal transformations</topic><topic>Thermodynamics</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Zhang, Bokang</creatorcontrib><creatorcontrib>Luo, Guoping</creatorcontrib><creatorcontrib>Hao, Shuai</creatorcontrib><creatorcontrib>Chai, Yifan</creatorcontrib><collection>CrossRef</collection><collection>Docstoc</collection><collection>University Readers</collection><collection>Engineered Materials Abstracts</collection><collection>Materials Business File</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><jtitle>JOM (1989)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Zhang, Bokang</au><au>Luo, Guoping</au><au>Hao, Shuai</au><au>Chai, Yifan</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Thermodynamic Simulation and Computational Study of the Carbothermal Reduction of Converter Steel Slag</atitle><jtitle>JOM (1989)</jtitle><stitle>JOM</stitle><date>2024-11-01</date><risdate>2024</risdate><volume>76</volume><issue>11</issue><spage>6568</spage><epage>6576</epage><pages>6568-6576</pages><issn>1047-4838</issn><eissn>1543-1851</eissn><abstract>Micropulverization of steel slag is an important way to achieve its efficient utilization. Its purpose is to reduce the particle size of steel slag and improve its iron recovery rate. However, the high hardness and poor grindability of steel slag make it constrained by process and cost. Carbon thermal reduction can reduce the phosphorus dissolved in dicalcium silicate, reduce the influence of phosphorus on the crystal transformation of dicalcium silicate, and facilitate the self-pulverization of steel slag. At the same time, it can reduce the iron oxide in the slag to metallic iron, achieving the goal of recovering iron. To study the changes in phase types and contents of equilibrium products during the carbothermal reduction of converter slag, based on the variables of reduction temperature, alkalinity, and carbon ratio (coke-to-slag ratio), FactSage 7.1 thermodynamic software was used for calculation and analysis. The study reveals under a certain coke-slag ratio, with the increase of reduction temperature, the residual C content in the equilibrium phase composition shows a decreasing trend, while the Fe
3
C and P
2
gas contents show an increasing trend, indicating that the high temperature is favorable to the reduction of iron oxides and apatite, especially to the gasification of dephosphorization. With reduction temperature increasing, the contents of Fe
3
P/Fe
2
P in the equilibrium phase composition decrease, while the contents of Mn
2
P and P
2
(g) increase. This indicates that the reduction temperature has significant influence on the stability sequence of phosphorus-containing phases, with the stability enhancement order as Fe
3
P → Fe
2
P → Mn
2
P → P
2
(g). High temperature favors the gasification and removal of phosphorus. Under constant coke-to-slag ratio and reduction temperature, the increase in the alkalinity of charge leads to elevation of Fe
3
C content in the equilibrium phase composition, indicating that higher alkalinity promotes the reduction of iron oxides. As the alkalinity of the mixture increases, the silicate liquid phase content in the equilibrium phase composition shows a decreasing trend, and an alkalinity of 1.8 generates the largest amount of liquid phase. The alkalinity of the mixture in the range of 1.8 to 2.2 is conducive to the generation of
α
-C
2
S and self-pulverization of the product, with the content of
α
-C
2
S being the largest when the alkalinity is 2.0. Changes in the coke-to-slag ratio have minimal impact on the phase types and contents of equilibrium products during the carbothermal reduction of converter slag. Thermodynamic calculations indicate that the temperature range favorable for steel slag micronization is 1450–1500°C, the alkalinity range is 1.8–2.2, and the coke-slag ratio range is 10:90–15:85. This range of conditions facilitates the generation of
α
-C
2
S and the best pulverization of steel slag.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s11837-024-06822-w</doi><tpages>9</tpages><orcidid>https://orcid.org/0009-0001-7342-8433</orcidid></addata></record> |
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| subjects | Alkalinity Apatite Carbon Cementite Chemistry/Food Science Coke Dephosphorizing Dicalcium silicate Earth Sciences Engineering Environment Equilibrium Gasification Grindability High temperature Iron Iron carbides Iron oxides Liquid phases Minerals Mixtures Phase composition Phosphorus Physics Ratios Raw materials Slag Stability Steel industry Technical Article Thermal reduction Thermal transformations Thermodynamics |
| title | Thermodynamic Simulation and Computational Study of the Carbothermal Reduction of Converter Steel Slag |
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