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Assessment of a multistep revamping methodology for cleaner steel production
A novel revamping methodology is proposed to achieve the decarbonization of currently operating integrated steel mills (step 0) without reducing steel production levels. Such a method encompasses four successive steps involving cleaner and more energy efficient technological pathways for steel produ...
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| Published in: | Journal of cleaner production 2022-12, Vol.381, p.135146, Article 135146 |
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| container_title | Journal of cleaner production |
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| creator | Palone, O. Barberi, G. Di Gruttola, F. Gagliardi, G.G. Cedola, L. Borello, D. |
| description | A novel revamping methodology is proposed to achieve the decarbonization of currently operating integrated steel mills (step 0) without reducing steel production levels. Such a method encompasses four successive steps involving cleaner and more energy efficient technological pathways for steel production.
The decarbonization strategy is reported: step 1, partial replacement of coke with recycled plastic in a conventional Blast Furnace – Basic Oxygen Furnace (BF-BOF) plant; step 2, implementation of a Direct Reduction-Electric Arc Furnace (DR-EAF) line combined with the BF-BOF plant; step 3, complete shut-down of the BF-BOF line and full operation of two DR-EAF lines fed by CH4; step 4, installation of an alkaline electrolyzer and use of 100% green H2 as a reducing agent in the DR plants.
The gradual replacement of the integrated steel mill with DR-EAF lines causes a progressive drop in CO2 emissions, ranging from 8.5 Mt/y at step 0 to a minimum of 0.68 Mt/y at step 4 (92% decrease).
Coke replacement with recycled plastic in the blast furnace in step 1 leads to a slight decrease in CO2 emissions without altering the structural layout of the plant. In step 2, the combined operation of BF-BOF and DR-EAF lines determines a 39% decrease in CO2 emission compared to the initial configuration, while keeping total steel production constant. Step 3 involves two DR-EAF lines fed by CH4 and reduces the CO2 emissions by 75% compared to the initial configuration. The operation of two DR-EAF lines increases the electricity consumption, especially when 100% green H2 is involved as a reducing agent in step 4. By increasing the scrap mass fraction in the EAFs of step 4, both electricity and H2 demands of the DR plant are expected to decrease, while the CO2 emission levels remain almost unchanged, leading to about 92% total CO2 emissions reduction compared to the initial configuration (provided that green electricity is used). By assuming an initial 10% scrap mass fraction at the EAFs inlet of step 4, the demand of green hydrogen is significant, thus requiring the installation of a 1.42 GW electrolyzer. The capital expenditure (CAPEX) estimated upon completion of the revamping methodology amounts to approximately 2.97 B€. The transition towards a full decarbonization of steel production technologies is demonstrated to be technically feasible, though strictly dependent upon the large availability of low emissions electric power and scrap material.
•The transition from convent |
| doi_str_mv | 10.1016/j.jclepro.2022.135146 |
| format | article |
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The decarbonization strategy is reported: step 1, partial replacement of coke with recycled plastic in a conventional Blast Furnace – Basic Oxygen Furnace (BF-BOF) plant; step 2, implementation of a Direct Reduction-Electric Arc Furnace (DR-EAF) line combined with the BF-BOF plant; step 3, complete shut-down of the BF-BOF line and full operation of two DR-EAF lines fed by CH4; step 4, installation of an alkaline electrolyzer and use of 100% green H2 as a reducing agent in the DR plants.
The gradual replacement of the integrated steel mill with DR-EAF lines causes a progressive drop in CO2 emissions, ranging from 8.5 Mt/y at step 0 to a minimum of 0.68 Mt/y at step 4 (92% decrease).
Coke replacement with recycled plastic in the blast furnace in step 1 leads to a slight decrease in CO2 emissions without altering the structural layout of the plant. In step 2, the combined operation of BF-BOF and DR-EAF lines determines a 39% decrease in CO2 emission compared to the initial configuration, while keeping total steel production constant. Step 3 involves two DR-EAF lines fed by CH4 and reduces the CO2 emissions by 75% compared to the initial configuration. The operation of two DR-EAF lines increases the electricity consumption, especially when 100% green H2 is involved as a reducing agent in step 4. By increasing the scrap mass fraction in the EAFs of step 4, both electricity and H2 demands of the DR plant are expected to decrease, while the CO2 emission levels remain almost unchanged, leading to about 92% total CO2 emissions reduction compared to the initial configuration (provided that green electricity is used). By assuming an initial 10% scrap mass fraction at the EAFs inlet of step 4, the demand of green hydrogen is significant, thus requiring the installation of a 1.42 GW electrolyzer. The capital expenditure (CAPEX) estimated upon completion of the revamping methodology amounts to approximately 2.97 B€. The transition towards a full decarbonization of steel production technologies is demonstrated to be technically feasible, though strictly dependent upon the large availability of low emissions electric power and scrap material.
•The transition from conventional steel mills to H2/DR-EAF lines is assessed in 4 steps.•Plastic injection in the blast furnace slightly reduces CO2 emissions and energy demand.•Significant decarbonization is achieved with H2 reduction (92% less CO2).•Electricity saving is relevant when increasing scrap mass fraction in the EAF.•The capital cost of the four steps methodology amounts to 2.97 B€.</description><identifier>ISSN: 0959-6526</identifier><identifier>EISSN: 1879-1786</identifier><identifier>DOI: 10.1016/j.jclepro.2022.135146</identifier><language>eng</language><publisher>Elsevier Ltd</publisher><subject>CO2 emissions ; Decarbonization ; Direct reduction-electric arc furnace ; Green hydrogen ; Green steel ; Revamping methodology</subject><ispartof>Journal of cleaner production, 2022-12, Vol.381, p.135146, Article 135146</ispartof><rights>2022 Elsevier Ltd</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c309t-bc5ec54d527f924665d36be1ff42080d2347c029f1c7293c88718db2a02bf66a3</citedby><cites>FETCH-LOGICAL-c309t-bc5ec54d527f924665d36be1ff42080d2347c029f1c7293c88718db2a02bf66a3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids></links><search><creatorcontrib>Palone, O.</creatorcontrib><creatorcontrib>Barberi, G.</creatorcontrib><creatorcontrib>Di Gruttola, F.</creatorcontrib><creatorcontrib>Gagliardi, G.G.</creatorcontrib><creatorcontrib>Cedola, L.</creatorcontrib><creatorcontrib>Borello, D.</creatorcontrib><title>Assessment of a multistep revamping methodology for cleaner steel production</title><title>Journal of cleaner production</title><description>A novel revamping methodology is proposed to achieve the decarbonization of currently operating integrated steel mills (step 0) without reducing steel production levels. Such a method encompasses four successive steps involving cleaner and more energy efficient technological pathways for steel production.
The decarbonization strategy is reported: step 1, partial replacement of coke with recycled plastic in a conventional Blast Furnace – Basic Oxygen Furnace (BF-BOF) plant; step 2, implementation of a Direct Reduction-Electric Arc Furnace (DR-EAF) line combined with the BF-BOF plant; step 3, complete shut-down of the BF-BOF line and full operation of two DR-EAF lines fed by CH4; step 4, installation of an alkaline electrolyzer and use of 100% green H2 as a reducing agent in the DR plants.
The gradual replacement of the integrated steel mill with DR-EAF lines causes a progressive drop in CO2 emissions, ranging from 8.5 Mt/y at step 0 to a minimum of 0.68 Mt/y at step 4 (92% decrease).
Coke replacement with recycled plastic in the blast furnace in step 1 leads to a slight decrease in CO2 emissions without altering the structural layout of the plant. In step 2, the combined operation of BF-BOF and DR-EAF lines determines a 39% decrease in CO2 emission compared to the initial configuration, while keeping total steel production constant. Step 3 involves two DR-EAF lines fed by CH4 and reduces the CO2 emissions by 75% compared to the initial configuration. The operation of two DR-EAF lines increases the electricity consumption, especially when 100% green H2 is involved as a reducing agent in step 4. By increasing the scrap mass fraction in the EAFs of step 4, both electricity and H2 demands of the DR plant are expected to decrease, while the CO2 emission levels remain almost unchanged, leading to about 92% total CO2 emissions reduction compared to the initial configuration (provided that green electricity is used). By assuming an initial 10% scrap mass fraction at the EAFs inlet of step 4, the demand of green hydrogen is significant, thus requiring the installation of a 1.42 GW electrolyzer. The capital expenditure (CAPEX) estimated upon completion of the revamping methodology amounts to approximately 2.97 B€. The transition towards a full decarbonization of steel production technologies is demonstrated to be technically feasible, though strictly dependent upon the large availability of low emissions electric power and scrap material.
•The transition from conventional steel mills to H2/DR-EAF lines is assessed in 4 steps.•Plastic injection in the blast furnace slightly reduces CO2 emissions and energy demand.•Significant decarbonization is achieved with H2 reduction (92% less CO2).•Electricity saving is relevant when increasing scrap mass fraction in the EAF.•The capital cost of the four steps methodology amounts to 2.97 B€.</description><subject>CO2 emissions</subject><subject>Decarbonization</subject><subject>Direct reduction-electric arc furnace</subject><subject>Green hydrogen</subject><subject>Green steel</subject><subject>Revamping methodology</subject><issn>0959-6526</issn><issn>1879-1786</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><recordid>eNqFkE1rwyAcxmVssK7bRxj4BZKpiZqcRil7g8Iu21mM_u0MSQxqC_32y2jvOz2X540fQo-UlJRQ8dSXvRlgjqFkhLGSVpzW4gqtaCPbgspGXKMVaXlbCM7ELbpLqSeESiLrFdptUoKURpgyDg5rPB6G7FOGGUc46nH20x6PkH-CDUPYn7ALES9reoKIFxsMeBm2B5N9mO7RjdNDgoeLrtH368vX9r3Yfb59bDe7wlSkzUVnOBheW86ka1ktBLeV6IA6VzPSEMuqWhrCWkeNZG1lmkbSxnZME9Y5IXS1Rvzca2JIKYJTc_SjjidFifpDonp1QaL-kKgzkiX3fM7Bcu7oIapkPEwGrI9gsrLB_9PwC2lrbhU</recordid><startdate>20221225</startdate><enddate>20221225</enddate><creator>Palone, O.</creator><creator>Barberi, G.</creator><creator>Di Gruttola, F.</creator><creator>Gagliardi, G.G.</creator><creator>Cedola, L.</creator><creator>Borello, D.</creator><general>Elsevier Ltd</general><scope>AAYXX</scope><scope>CITATION</scope></search><sort><creationdate>20221225</creationdate><title>Assessment of a multistep revamping methodology for cleaner steel production</title><author>Palone, O. ; Barberi, G. ; Di Gruttola, F. ; Gagliardi, G.G. ; Cedola, L. ; Borello, D.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c309t-bc5ec54d527f924665d36be1ff42080d2347c029f1c7293c88718db2a02bf66a3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2022</creationdate><topic>CO2 emissions</topic><topic>Decarbonization</topic><topic>Direct reduction-electric arc furnace</topic><topic>Green hydrogen</topic><topic>Green steel</topic><topic>Revamping methodology</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Palone, O.</creatorcontrib><creatorcontrib>Barberi, G.</creatorcontrib><creatorcontrib>Di Gruttola, F.</creatorcontrib><creatorcontrib>Gagliardi, G.G.</creatorcontrib><creatorcontrib>Cedola, L.</creatorcontrib><creatorcontrib>Borello, D.</creatorcontrib><collection>CrossRef</collection><jtitle>Journal of cleaner production</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Palone, O.</au><au>Barberi, G.</au><au>Di Gruttola, F.</au><au>Gagliardi, G.G.</au><au>Cedola, L.</au><au>Borello, D.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Assessment of a multistep revamping methodology for cleaner steel production</atitle><jtitle>Journal of cleaner production</jtitle><date>2022-12-25</date><risdate>2022</risdate><volume>381</volume><spage>135146</spage><pages>135146-</pages><artnum>135146</artnum><issn>0959-6526</issn><eissn>1879-1786</eissn><abstract>A novel revamping methodology is proposed to achieve the decarbonization of currently operating integrated steel mills (step 0) without reducing steel production levels. Such a method encompasses four successive steps involving cleaner and more energy efficient technological pathways for steel production.
The decarbonization strategy is reported: step 1, partial replacement of coke with recycled plastic in a conventional Blast Furnace – Basic Oxygen Furnace (BF-BOF) plant; step 2, implementation of a Direct Reduction-Electric Arc Furnace (DR-EAF) line combined with the BF-BOF plant; step 3, complete shut-down of the BF-BOF line and full operation of two DR-EAF lines fed by CH4; step 4, installation of an alkaline electrolyzer and use of 100% green H2 as a reducing agent in the DR plants.
The gradual replacement of the integrated steel mill with DR-EAF lines causes a progressive drop in CO2 emissions, ranging from 8.5 Mt/y at step 0 to a minimum of 0.68 Mt/y at step 4 (92% decrease).
Coke replacement with recycled plastic in the blast furnace in step 1 leads to a slight decrease in CO2 emissions without altering the structural layout of the plant. In step 2, the combined operation of BF-BOF and DR-EAF lines determines a 39% decrease in CO2 emission compared to the initial configuration, while keeping total steel production constant. Step 3 involves two DR-EAF lines fed by CH4 and reduces the CO2 emissions by 75% compared to the initial configuration. The operation of two DR-EAF lines increases the electricity consumption, especially when 100% green H2 is involved as a reducing agent in step 4. By increasing the scrap mass fraction in the EAFs of step 4, both electricity and H2 demands of the DR plant are expected to decrease, while the CO2 emission levels remain almost unchanged, leading to about 92% total CO2 emissions reduction compared to the initial configuration (provided that green electricity is used). By assuming an initial 10% scrap mass fraction at the EAFs inlet of step 4, the demand of green hydrogen is significant, thus requiring the installation of a 1.42 GW electrolyzer. The capital expenditure (CAPEX) estimated upon completion of the revamping methodology amounts to approximately 2.97 B€. The transition towards a full decarbonization of steel production technologies is demonstrated to be technically feasible, though strictly dependent upon the large availability of low emissions electric power and scrap material.
•The transition from conventional steel mills to H2/DR-EAF lines is assessed in 4 steps.•Plastic injection in the blast furnace slightly reduces CO2 emissions and energy demand.•Significant decarbonization is achieved with H2 reduction (92% less CO2).•Electricity saving is relevant when increasing scrap mass fraction in the EAF.•The capital cost of the four steps methodology amounts to 2.97 B€.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.jclepro.2022.135146</doi></addata></record> |
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| source | ScienceDirect Journals |
| subjects | CO2 emissions Decarbonization Direct reduction-electric arc furnace Green hydrogen Green steel Revamping methodology |
| title | Assessment of a multistep revamping methodology for cleaner steel production |
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