21 MCC Projects Win 2024 Metallurgical Science and Technology Award

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21 MCC Projects �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Win 2024 Meta�� Ƴ�� Ƴ�� Ƴ�� Ƴ��llurgical Scienc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e and Technolog�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y Award

source:Scientific�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Technolo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gical Managemen�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t Department Author:Scientific an�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d Technologi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cal Management Departmen�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t Release time:2024-08-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��12

�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Ƴ��Recently, the results�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of the 2024 Metal�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lurgical Science�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Technology Awar�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d of the China Iron and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Steel Association and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��the Chinese Society fo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r Metals were �� Ƴ�� Ƴ�� Ƴ�� Ƴ��officially anno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��unced. The Metall�� Ƴ�� Ƴ�� Ƴ�� Ƴ��urgical Science and Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology Award Committee �� Ƴ�� Ƴ�� Ƴ�� Ƴ��decided to grant �� Ƴ�� Ƴ�� Ƴ�� Ƴ��the 2024 Metall�� Ƴ�� Ƴ�� Ƴ�� Ƴ��urgical Science and Te�� Ƴ�� Ƴ�� Ƴ�� Ƴ��chnology Award to�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� 110 project�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s, including 3 gran�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d prizes, 21 first p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rizes, 29 second prizes,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and 57 third �� Ƴ�� Ƴ�� Ƴ�� Ƴ��prizes. This year, MCC �� Ƴ�� Ƴ�� Ƴ�� Ƴ��won a total of �� Ƴ�� Ƴ�� Ƴ�� Ƴ��21 awards, including�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� 1 grand prize�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, 5 first prize�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s, 5 second pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��izes, and 10 th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ird prizes, continuin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g to rank among the top�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� in the industry in term�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s of both qu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��antity and qu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ality of awards.

�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� The "NISCO �� Ƴ�� Ƴ�� Ƴ�� Ƴ��All-Factor Digital Produ�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ction Operation and I�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntelligent Manufactur�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing Core Key Tec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hnology Innovatio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n" project pa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rticipated and complete�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d by CISDI ai�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ms at the series of iss�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ues faced by steel ent�� Ƴ�� Ƴ�� Ƴ�� Ƴ��erprises in the pro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cess of digital transfo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rmation. It has resear�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ched and developed�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� the prediction �� Ƴ�� Ƴ�� Ƴ�� Ƴ��models for silicon a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd phosphorus conten�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t in molten iron�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, molten iron char�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ging accuracy, real-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��time predict�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion of molten iron �� Ƴ�� Ƴ�� Ƴ�� Ƴ��output, and i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntelligent prediction m�� Ƴ�� Ƴ�� Ƴ�� Ƴ��odels of special furn�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ace conditions, realizin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g the intelligent pe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rception of th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e entire productio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n scenario in the iron�� Ƴ�� Ƴ�� Ƴ�� Ƴ��making area and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� integrated cluster�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� management and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� control of pre�� Ƴ�� Ƴ�� Ƴ�� Ƴ��-ironmaking processes. �� Ƴ�� Ƴ�� Ƴ�� Ƴ��It has constructe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d a full-process digi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tal twin from raw ma�� Ƴ�� Ƴ�� Ƴ�� Ƴ��terials to finished pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oducts for st�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eel enterprises, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��thereby achi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eving model-bas�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ed, intelligent, and le�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ss-manned pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oduction across the enti�� Ƴ�� Ƴ�� Ƴ�� Ƴ��re process. Fur�� Ƴ�� Ƴ�� Ƴ�� Ƴ��thermore, it has pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ovided a tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nologically ad�� Ƴ�� Ƴ�� Ƴ�� Ƴ��vanced, mature, and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� reliable technology sy�� Ƴ�� Ƴ�� Ƴ�� Ƴ��stem that helps �� Ƴ�� Ƴ�� Ƴ�� Ƴ��NISCO realize the�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� significant improvemen�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t of product�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion efficiency �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and the research and de�� Ƴ�� Ƴ�� Ƴ�� Ƴ��velopment of hi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gh-end produc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ts.

&nb�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sp; The "Dev�� Ƴ�� Ƴ�� Ƴ�� Ƴ��elopment and Applic�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ation of High De�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gree-of-Freedom Precis�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion Rolling Technol�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ogy and Core Eq�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uipment for Ultra-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��Heavy Load Wire Ro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d Reducing and Sizing" �� Ƴ�� Ƴ�� Ƴ�� Ƴ��project, led by CERI,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� based on the hig�� Ƴ�� Ƴ�� Ƴ�� Ƴ��her-level requir�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ements of high-quality d�� Ƴ�� Ƴ�� Ƴ�� Ƴ��evelopment of high-speed�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� wire rods for �� Ƴ�� Ƴ�� Ƴ�� Ƴ��product quality,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� small-batch cus�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tomization, di�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mensional acc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uracy, and operati�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng costs, has pi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oneered the "1+1+2" redu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cing and sizing p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rocess model and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��the high degree-of-fr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eedom precision rol�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ling technology�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� with unified �� Ƴ�� Ƴ�� Ƴ�� Ƴ��hole shapes, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��developed the reduci�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng and sizing mill equi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��pment featuring "high-l�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oad reducing + sma�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ll-pitch sizing," and bu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ilt a comple�� Ƴ�� Ƴ�� Ƴ�� Ƴ��te set of el�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ectrical control �� Ƴ�� Ƴ�� Ƴ�� Ƴ��technology f�� Ƴ�� Ƴ�� Ƴ�� Ƴ��or reducing and sizi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng centered on h�� Ƴ�� Ƴ�� Ƴ�� Ƴ��igh-rigidity roll�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing control �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and adaptive �� Ƴ�� Ƴ�� Ƴ�� Ƴ��tension recon�� Ƴ�� Ƴ�� Ƴ�� Ƴ��struction control,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� realizing free�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� reducing, pre�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cise sizing,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and efficient�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and stable rolling. Th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��is provides reliable�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� equipment support for�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� low-temperatur�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e controlled rolling, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��effectively improving p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��roduction flexi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��bility, mill efficiency,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� product precision, a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd product y�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ield. The project h�� Ƴ�� Ƴ�� Ƴ�� Ƴ��as successfully brok�� Ƴ�� Ƴ�� Ƴ�� Ƴ��en the long-t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��erm technological monop�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oly held by fore�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ign countries in the fie�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ld of reducing a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd sizing te�� Ƴ�� Ƴ�� Ƴ�� Ƴ��chnology, making signif�� Ƴ�� Ƴ�� Ƴ�� Ƴ��icant contribution�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s to improving the wi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��re rod produc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion equipme�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nt and technologica�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l level in China.

&nb�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sp; The "Devel�� Ƴ�� Ƴ�� Ƴ�� Ƴ��opment and Applic�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ation of Dry Waste Heat�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Recovery Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology for Converter �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Flue Gas in �� Ƴ�� Ƴ�� Ƴ�� Ƴ��a Wide Temperature Rang�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e (800°C−200°C)" pro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ject, led by CERI�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, is dedicated to�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� advancing the �� Ƴ�� Ƴ�� Ƴ�� Ƴ��ultimate energy eff�� Ƴ�� Ƴ�� Ƴ�� Ƴ��iciency project i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n the steel indus�� Ƴ�� Ƴ�� Ƴ�� Ƴ��try. Focusing on t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he long-standing ch�� Ƴ�� Ƴ�� Ƴ�� Ƴ��allenge of reco�� Ƴ�� Ƴ�� Ƴ�� Ƴ��vering waste �� Ƴ�� Ƴ�� Ƴ�� Ƴ��heat from converter f�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lue gas in the temperatu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��re range of 800°C−2�� Ƴ�� Ƴ�� Ƴ�� Ƴ��00°C, the projec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t has developed innovati�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ve explosion-proof, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��full waste he�� Ƴ�� Ƴ�� Ƴ�� Ƴ��at dry recov�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ery technology, hig�� Ƴ�� Ƴ�� Ƴ�� Ƴ��h-temperature kindling �� Ƴ�� Ƴ�� Ƴ�� Ƴ��capture techn�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ology, and f�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lue dust control tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology. Under th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e premise of en�� Ƴ�� Ƴ�� Ƴ�� Ƴ��suring safe, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��stable, and continu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ous production, th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ese technologie�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s enable rel�� Ƴ�� Ƴ�� Ƴ�� Ƴ��iable and effic�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ient recovery of was�� Ƴ�� Ƴ�� Ƴ�� Ƴ��te heat in the �� Ƴ�� Ƴ�� Ƴ�� Ƴ��range of 800°C−200°C�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and have been succe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ssfully applied i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n production pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��actices. The ac�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hievements hav�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e been implemented at J�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ianlong Xilin Iro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n and Steel Co., Lt�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d., resulting in an inc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rease in steam re�� Ƴ�� Ƴ�� Ƴ�� Ƴ��covery by ove�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r 40%, energy savi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ngs of 5 kgce pe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r ton of steel�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, a profit of 10−15 y�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uan per ton of stee�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l, and a reduction i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n carbon dioxide emis�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sions by 13.3 kg per�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� ton of steel. T�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he implementation �� Ƴ�� Ƴ�� Ƴ�� Ƴ��of these achievements�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� has significantly impr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oved the energy effi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ciency indicat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ors of the converter �� Ƴ�� Ƴ�� Ƴ�� Ƴ��process, promoting the�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� steel indus�� Ƴ�� Ƴ�� Ƴ�� Ƴ��try to achieve its "dua�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l carbon" goals and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� sustainable high-quali�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ty development.

&n�� Ƴ�� Ƴ�� Ƴ�� Ƴ��bsp; The "D�� Ƴ�� Ƴ�� Ƴ�� Ƴ��evelopment and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Application�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of Coking Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology for Collaborative�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Governance of Pollution�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Reduction and Carb�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on Emission Reducti�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on" project, led �� Ƴ�� Ƴ�� Ƴ�� Ƴ��by ACRE, aims at t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he prominent issues�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� such as high NOx g�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eneration at�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� the source of�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� coke oven flue gas, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��high energy consumption �� Ƴ�� Ƴ�� Ƴ�� Ƴ��in coking, short ser�� Ƴ�� Ƴ�� Ƴ�� Ƴ��vice life of cok�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e oven bodies, and t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he inability of traditio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nal desulfurization and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� denitrificati�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on processes�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� to achieve simul�� Ƴ�� Ƴ�� Ƴ�� Ƴ��taneous removal of �� Ƴ�� Ƴ�� Ƴ�� Ƴ��multiple pollutants. T�� Ƴ�� Ƴ�� Ƴ�� Ƴ��o address the�� Ƴ�� Ƴ�� Ƴ�� Ƴ��se issues, new technolog�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ies, materials, p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rocesses, and equipment �� Ƴ�� Ƴ�� Ƴ�� Ƴ��have been develope�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d, including NOx�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� source reduc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion control, lo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��w-energy coking,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� long-life a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd clean production of c�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oke oven bodies, and e�� Ƴ�� Ƴ�� Ƴ�� Ƴ��fficient multi-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��pollutant removal thro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ugh activated carbon�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� denitrification�� Ƴ�� Ƴ�� Ƴ�� Ƴ��. This has r�� Ƴ�� Ƴ�� Ƴ�� Ƴ��esulted in t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he integration �� Ƴ�� Ƴ�� Ƴ�� Ƴ��of green and low-carb�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on coking technologies,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� offering signific�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ant advantages i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n pollution reduc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion and carbon emission�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� reduction for coke ov�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ens. The ach�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ievements ha�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ve been succes�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sfully applied i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n 65 coking proje�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cts both domesti�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cally and international�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ly, with a total�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� production capacit�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y of 118 millio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n tons, saving 714 milli�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on cubic meters o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f coke oven gas and 2.5�� Ƴ�� Ƴ�� Ƴ�� Ƴ��2 billion cubic mete�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rs of lean gas annuall�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y, and significa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntly improving�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� the green and low-ca�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rbon level of t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he industry.

&n�� Ƴ�� Ƴ�� Ƴ�� Ƴ��bsp; Th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e "Research a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd Application of Key�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Technologies�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� for the Quality and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Energy Recyclin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g of Complex �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Solid Wastes in Me�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tallurgy" proj�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ect, led by CIE, aims �� Ƴ�� Ƴ�� Ƴ�� Ƴ��at the challenges�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of difficult�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� resource-based di�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sposal of compl�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ex solid wastes i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n steel metall�� Ƴ�� Ƴ�� Ƴ�� Ƴ��urgy and the lack of �� Ƴ�� Ƴ�� Ƴ�� Ƴ��technology for large�� Ƴ�� Ƴ�� Ƴ�� Ƴ��-scale consum�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ption of socia�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l wastes in metallurgica�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l processes. Th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e project has proposed �� Ƴ�� Ƴ�� Ƴ�� Ƴ��an overall technical�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� route for quality and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� energy recycling, which�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� involves targeted sepa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ration of complex solid �� Ƴ�� Ƴ�� Ƴ�� Ƴ��waste components, eff�� Ƴ�� Ƴ�� Ƴ�� Ƴ��icient utilization of�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� material and energ�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y attributes, and full u�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tilization of toxic �� Ƴ�� Ƴ�� Ƴ�� Ƴ��attributes trans�� Ƴ�� Ƴ�� Ƴ�� Ƴ��formed into �� Ƴ�� Ƴ�� Ƴ�� Ƴ��resource attributes.�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� It has pioneered th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e technology of high�� Ƴ�� Ƴ�� Ƴ�� Ƴ��-value preparation of me�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tallurgical raw �� Ƴ�� Ƴ�� Ƴ�� Ƴ��materials (fuels) f�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rom organic soli�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d wastes, inve�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nted a low-cost and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� efficient sepa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ration technology for i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ron and zinc from o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rganic/zinc-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��containing du�� Ƴ�� Ƴ�� Ƴ�� Ƴ��st and sludge �� Ƴ�� Ƴ�� Ƴ�� Ƴ��using a rotary kiln m�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ethod, developed a pro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cess technology for rec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ycling and uti�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lizing complex solid wa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��stes in steel pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oduction processe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s, and created co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��re equipment �� Ƴ�� Ƴ�� Ƴ�� Ƴ��for efficient separa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion, recove�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ry, and utilization of�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� valuable com�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ponents from typical�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� complex solid wastes.�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� These technologies hav�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e been applied in�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� multiple domestic �� Ƴ�� Ƴ�� Ƴ�� Ƴ��steel, non-ferrous met�� Ƴ�� Ƴ�� Ƴ�� Ƴ��allurgy, and enviro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nmental protection ent�� Ƴ�� Ƴ�� Ƴ�� Ƴ��erprises, making posit�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ive contribu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tions to the g�� Ƴ�� Ƴ�� Ƴ�� Ƴ��reen and susta�� Ƴ�� Ƴ�� Ƴ�� Ƴ��inable development of th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e steel industry as �� Ƴ�� Ƴ�� Ƴ�� Ƴ��well as the har�� Ƴ�� Ƴ�� Ƴ�� Ƴ��monious coexistence�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� between steel ente�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rprises and cities.�� Ƴ�� Ƴ�� Ƴ�� Ƴ��

�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� The "Key�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Technologies�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� for Intelli�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gent, Efficient and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Rapid Overhaul of La�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rge Slab Con�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tinuous Casters" proje�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ct, led by China MCC2�� Ƴ�� Ƴ�� Ƴ�� Ƴ��0, aims to achieve th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e overarching�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� goal of energy co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nservation, environme�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntal protectio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n, and low car�� Ƴ�� Ƴ�� Ƴ�� Ƴ��bon in the meta�� Ƴ�� Ƴ�� Ƴ�� Ƴ��llurgical indust�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ry. Targeting the chal�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lenges of high safe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ty risks, long cycles, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��limited space, and diff�� Ƴ�� Ƴ�� Ƴ�� Ƴ��iculty in ensu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ring quality during ma�� Ƴ�� Ƴ�� Ƴ�� Ƴ��jor overhauls of con�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tinuous cast�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ers, it has pioneer�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ed intelligent, r�� Ƴ�� Ƴ�� Ƴ�� Ƴ��apid, and precise adjus�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tment technology for �� Ƴ�� Ƴ�� Ƴ�� Ƴ��casting equipment,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� developed the �� Ƴ�� Ƴ�� Ƴ�� Ƴ��modular updating tec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hnology for p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ouring equip�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ment under l�� Ƴ�� Ƴ�� Ƴ�� Ƴ��imited space conditions�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, invented eco-frie�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ndly and efficient �� Ƴ�� Ƴ�� Ƴ�� Ƴ��installation of medium�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� pipelines based on BI�� Ƴ�� Ƴ�� Ƴ�� Ƴ��M technology, and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��created rapid debu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gging technology for el�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ectrical systems�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� that enhances control �� Ƴ�� Ƴ�� Ƴ�� Ƴ��performance. �� Ƴ�� Ƴ�� Ƴ�� Ƴ��These achievem�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ents have shortened the �� Ƴ�� Ƴ�� Ƴ�� Ƴ��overhaul period of slab �� Ƴ�� Ƴ�� Ƴ�� Ƴ��continuous casters by �� Ƴ�� Ƴ�� Ƴ�� Ƴ��16.7%. They h�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ave been appl�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ied to more th�� Ƴ�� Ƴ�� Ƴ�� Ƴ��an 30 continuous castin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g projects, includin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g those of Baowu, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and are signi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ficant for promoti�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng the digitaliza�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion, intelli�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gence, and green deve�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lopment of steel ente�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rprises.

�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� The�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� outstanding�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� achievements of MCC i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n the Metallurgical Scie�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nce and Techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logy Awards r�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eflect the effect�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ive implemen�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tation of the MCC's�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� strategic de�� Ƴ�� Ƴ�� Ƴ�� Ƴ��velopment position�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing in scien�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tific and technolo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gical work. MCC's �� Ƴ�� Ƴ�� Ƴ�� Ƴ��scientific and techn�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ological work has alway�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s followed the strateg�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ic path of the "One Es�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tablishment, the Best an�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d the Most Trusted,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Five Streng�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ths" busines�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s system, continuously�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� intensifying �� Ƴ�� Ƴ�� Ƴ�� Ƴ��the layout and cultiva�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion of major sci�� Ƴ�� Ƴ�� Ƴ�� Ƴ��entific and te�� Ƴ�� Ƴ�� Ƴ�� Ƴ��chnological achievem�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ents. It vigoro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��usly promotes the deep�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� integration of industr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y, university, and re�� Ƴ�� Ƴ�� Ƴ�� Ƴ��search, fully stimulat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��es the vitality �� Ƴ�� Ƴ�� Ƴ�� Ƴ��of research and innova�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion, comprehensivel�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y enhances the level �� Ƴ�� Ƴ�� Ƴ�� Ƴ��of scientific and techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logical achi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��evement summarization�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and transformatio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n, and focuse�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s on the goal o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f "One Establishme�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nt, the Best and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��the Most Trusted,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Five Stre�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ngths" to provide�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� high-quality scienti�� Ƴ�� Ƴ�� Ƴ�� Ƴ��fic and technologi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cal innovation imp�� Ƴ�� Ƴ�� Ƴ�� Ƴ��etus for driving the ent�� Ƴ�� Ƴ�� Ƴ�� Ƴ��erprise's furt�� Ƴ�� Ƴ�� Ƴ�� Ƴ��her transformation and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� upgrading.

List of 2024 Metallurgic�� Ƴ�� Ƴ�� Ƴ�� Ƴ��al Science and Technol�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ogy Award-Winnin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g Projects of �� Ƴ�� Ƴ�� Ƴ�� Ƴ��MCC

No.	Project Name	Main Completing Units	Award Level
1	NISCO All-Factor Di�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gital Production O�� Ƴ�� Ƴ�� Ƴ�� Ƴ��peration and Intel�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ligent Manufacturing Co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��re Key Technolo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gy Innovation	Nanjing Iron & Ste�� Ƴ�� Ƴ�� Ƴ�� Ƴ��el Co., Ltd., Universit�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y of Science and Techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logy Beijing, Northeas�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tern Univers�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ity, Jiangsu Jinheng�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Information Technolo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gy Co., Ltd., Southe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ast University, CISDI�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Information Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology (Chongqin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g) Co., Ltd., Jiangna�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n Shipyard (Group) Co.�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, Ltd., Shanghai Waigaoq�� Ƴ�� Ƴ�� Ƴ�� Ƴ��iao Shipbuilding Co., Lt�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d., and Nanj�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing Xin Intelligent Ch�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ain Technology�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Information Co., L�� Ƴ�� Ƴ�� Ƴ�� Ƴ��td.	Grand Prize
2	Development a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd Application of Hig�� Ƴ�� Ƴ�� Ƴ�� Ƴ��h Degree-of-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��Freedom Precision �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Rolling Techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logy and Core E�� Ƴ�� Ƴ�� Ƴ�� Ƴ��quipment for U�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ltra-Heavy Load Wi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��re Rod Reduc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing and Sizing	MCC Capital Engine�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ering & Re�� Ƴ�� Ƴ�� Ƴ�� Ƴ��search Incor�� Ƴ�� Ƴ�� Ƴ�� Ƴ��poration Limited,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� CERI Long Produ�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ct Co., Ltd.�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, CERI Digita�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l Technology (Bei�� Ƴ�� Ƴ�� Ƴ�� Ƴ��jing) Co., Ltd., W�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uhan Iron and Stee�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l (Group) Corporation�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, and Kunming Steel &am�� Ƴ�� Ƴ�� Ƴ�� Ƴ��p; Iron Co., Ltd.	First Prize
3	Development and Ap�� Ƴ�� Ƴ�� Ƴ�� Ƴ��plication of D�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ry Waste Heat�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Recovery Technolog�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y for Convert�� Ƴ�� Ƴ�� Ƴ�� Ƴ��er Flue Gas in a �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Wide Temperature Range �� Ƴ�� Ƴ�� Ƴ�� Ƴ��(800°C−200°C)	MCC Capital Engin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eering & Researc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��h Incorporation Lim�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ited, Beijing Jia�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nlong Heavy Industry Gro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��up Co., Ltd., Be�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ijing Jingcheng K�� Ƴ�� Ƴ�� Ƴ�� Ƴ��elin Environmental�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Protection Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology Co., Lt�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d., Jianlong Xi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lin Iron and S�� Ƴ�� Ƴ�� Ƴ�� Ƴ��teel Co., Ltd., Sichua�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n Chuanguo Boiler�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Co., Ltd., and Univer�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sity of Science�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Technology Beijing	First Prize
4	Development an�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d Application o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f Coking Technology �� Ƴ�� Ƴ�� Ƴ�� Ƴ��for Collaborative �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Governance of Po�� Ƴ�� Ƴ�� Ƴ�� Ƴ��llution Reduction and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Carbon Emissi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on Reduction	ACRE Coking & Ref�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ractory (Dalian) E�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ngineering Consult�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing Corporation, M�� Ƴ�� Ƴ�� Ƴ�� Ƴ��CC, Institute of P�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rocess Engine�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ering, Chinese�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Academy of Science�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s, Shougang J�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ingtang United Iron�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� & Steel C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��o., Ltd., Univer�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sity of Science and T�� Ƴ�� Ƴ�� Ƴ�� Ƴ��echnology Beijing, a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd Ansteel Be�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ijing Researc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��h Institute Co.,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Ltd.	First Prize
5	Research and Ap�� Ƴ�� Ƴ�� Ƴ�� Ƴ��plication of Key Technol�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ogies for the Quality �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and Energy Recyclin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g of Complex Solid Wa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��stes in Metallurg�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y	Zhongye Chang�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tian International Engi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��neering Co., Ltd., Ce�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntral South Un�� Ƴ�� Ƴ�� Ƴ�� Ƴ��iversity, Baoshan Iron �� Ƴ�� Ƴ�� Ƴ�� Ƴ��& Steel Co., Ltd.,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Shandong Iron �� Ƴ�� Ƴ�� Ƴ�� Ƴ��& Steel Group Yongfe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng Lingang Co.�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, Ltd., Anhui Univ�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ersity of Technology, H�� Ƴ�� Ƴ�� Ƴ�� Ƴ��unan MCC Changtian E�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nergy Conservatio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n and Environmental�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Protection Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology Co., Ltd.,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Hunan C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hengyu Environmental P�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rotection Technology Co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��., Ltd.	First Prize
6	Key Technologies for I�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntelligent, Efficient�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Rapid Overhaul of�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Large Slab Continuo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��us Casters	Shanghai MCC20 Construct�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion Corp., Ltd. and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� China MCC20 Group Cor�� Ƴ�� Ƴ�� Ƴ�� Ƴ��p., Ltd.	First Prize
7	Key Technolo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gies and Applications�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of Ultra-Larg�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e and Ultra-Deep Shaf�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t Construction�� Ƴ�� Ƴ�� Ƴ�� Ƴ��	China ENFI Eng�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ineering Co., Ltd.�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, China Huaye Gro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��up Company Limited,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Benxi Longxin Mining C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��o., Ltd., and N�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ortheastern University	Second prize
8	Key Technology Devel�� Ƴ�� Ƴ�� Ƴ�� Ƴ��opment and Enginee�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ring Application�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of Power Down�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Coiler for Hot�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Strip	CISDI Engineering Co., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Ltd., Yanshan Universi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ty, and Chongqing Univers�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ity	Second prize
9	Development and Applica�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion of Key �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Technology a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd Standard Equipmen�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t for Modular Overh�� Ƴ�� Ƴ�� Ƴ�� Ƴ��aul of Large �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Blast Furnac�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e	Shanghai Baoye Metall�� Ƴ�� Ƴ�� Ƴ�� Ƴ��urgical Engin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��eering Co., Ltd. and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Shanghai Baoye �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Group Corp.,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Ltd.	Second prize
10	Development and App�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lication of Digital�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Intelligence-Driven U�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ltimate Energy Efficien�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cy Technology for �� Ƴ�� Ƴ�� Ƴ�� Ƴ��the Ironmaking�� Ƴ�� Ƴ�� Ƴ�� Ƴ��-Steelmaking Interface�� Ƴ�� Ƴ�� Ƴ�� Ƴ��	Baoshan Iron &a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mp; Steel Co., Ltd., CI�� Ƴ�� Ƴ�� Ƴ�� Ƴ��SDI Chongqing Env�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ironmental Consulting C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��o., Ltd., Inner Mongolia�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� University of S�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cience and Technology�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, Shanghai Baosight �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Software Co., Ltd, Sha�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ndong Iron & S�� Ƴ�� Ƴ�� Ƴ�� Ƴ��teel Group Yongfeng L�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ingang Co., Ltd., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Jiangsu Yonggang Gr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oup Co., Ltd.,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Northeastern �� Ƴ�� Ƴ�� Ƴ�� Ƴ��University	Second prize
11	Development and Applicat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion of Key Technol�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ogies for Eff�� Ƴ�� Ƴ�� Ƴ�� Ƴ��icient Continuous�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Casting of Hi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gh-Quality Special S�� Ƴ�� Ƴ�� Ƴ�� Ƴ��teel Billets	Zenith Steel Group C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ompany Limited, WISDRI C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ontinuous Casting Techn�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ology Engineeri�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng Co., Ltd., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and University �� Ƴ�� Ƴ�� Ƴ�� Ƴ��of Science and Te�� Ƴ�� Ƴ�� Ƴ�� Ƴ��chnology Beijing	Second prize
12	Development and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Application of Integra�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ted Key Techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logies and Equipment fo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r Coupling C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��onverter Subla�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nce with Steelm�� Ƴ�� Ƴ�� Ƴ�� Ƴ��aking Model System	MCC Capital Engineerin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g & Research I�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ncorporation Li�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mited	Third Prize
13	Development an�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d Application of M�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ulti-Dimensional�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Environmental Pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��otection Management�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Control Syst�� Ƴ�� Ƴ�� Ƴ�� Ƴ��em for Steel�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Enterprises	MCC Capital Engineer�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing & Re�� Ƴ�� Ƴ�� Ƴ�� Ƴ��search Incorporati�� Ƴ�� Ƴ�� Ƴ�� Ƴ��on Limited, CERI Digita�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l Technology (Beij�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing) Co., Ltd., Be�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ijing Jingcheng Jiayu En�� Ƴ�� Ƴ�� Ƴ�� Ƴ��vironmental Tec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hnology Co., Ltd., an�� Ƴ�� Ƴ�� Ƴ�� Ƴ��d Wuhan Iron and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Steel Company L�� Ƴ�� Ƴ�� Ƴ�� Ƴ��imited	Third Prize
14	Research and A�� Ƴ�� Ƴ�� Ƴ�� Ƴ��pplication o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f Key Technologies�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Equipment for High-�� Ƴ�� Ƴ�� Ƴ�� Ƴ��Performance Full-Digita�� Ƴ�� Ƴ�� Ƴ�� Ƴ��l Cycloconverte�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r Frequency Control �� Ƴ�� Ƴ�� Ƴ�� Ƴ��in Rolling Mill Main Dri�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ve	CISDI Electr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ic Technology�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Co., Ltd., Shangh�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ai Jiao Tong Uni�� Ƴ�� Ƴ�� Ƴ�� Ƴ��versity, Southw�� Ƴ�� Ƴ�� Ƴ�� Ƴ��estern Institute o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f Physics, and Shaa�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nxi TianCheng Aerosp�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ace Co., Ltd.	Third Prize
15	Development a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd Application of�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Intelligent Posit�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ive Pressure D�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rying Furnace Tech�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nology and Equipment �� Ƴ�� Ƴ�� Ƴ�� Ƴ��for Large Coke Ov�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ens	ACRE Coking &a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mp; Refractory (D�� Ƴ�� Ƴ�� Ƴ�� Ƴ��alian) Engineer�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing Consulting Corpor�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ation, MCC, Northeastern�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� University, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Angang Steel Company�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Limited, Shougang Jingt�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ang United I�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ron & Steel Co., Ltd�� Ƴ�� Ƴ�� Ƴ�� Ƴ��., and MCC Jiaonai A�� Ƴ�� Ƴ�� Ƴ�� Ƴ��utomation Co.�� Ƴ�� Ƴ�� Ƴ�� Ƴ��, Ltd.	Third Prize
16	Large-Scale Safe and Eff�� Ƴ�� Ƴ�� Ƴ�� Ƴ��icient Mining Techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logy and Applica�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion for Thick and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Large Ore Bodies at Hig�� Ƴ�� Ƴ�� Ƴ�� Ƴ��h and Middle Sections	Northern Engineering &a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mp; Technology C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��orporation (Dal�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ian), MCC, Institut�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e of Rock and Soil�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Mechanics, Chinese �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Academy of Sciences, An�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hui Magang Zhangz�� Ƴ�� Ƴ�� Ƴ�� Ƴ��huang Mining Co., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Ltd., and Northe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��astern University	Third Prize
17	Large-Scale Design and M�� Ƴ�� Ƴ�� Ƴ�� Ƴ��anufacturing Te�� Ƴ�� Ƴ�� Ƴ�� Ƴ��chnology for �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Lime Shaft Kilns Bas�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ed on EPC Projects	Shanghai Baoye Metal�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lurgical Eng�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ineering Co., L�� Ƴ�� Ƴ�� Ƴ�� Ƴ��td. and Shanghai Baoye�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Group Corp., Ltd.	Third Prize
18	DFP Technology f�� Ƴ�� Ƴ�� Ƴ�� Ƴ��or Ultra-low Emis�� Ƴ�� Ƴ�� Ƴ�� Ƴ��sion Filtration of Pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��imary Converter Flu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e Gas and its A�� Ƴ�� Ƴ�� Ƴ�� Ƴ��pplications	BERIS Engineering &�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Research Corporation, �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Inner Mongolia BaoTou �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Steel Union Co., L�� Ƴ�� Ƴ�� Ƴ�� Ƴ��td., and Inner Mongolia �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Botong Technology Co., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Ltd.	Third Prize
19	Key Technologies and App�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lication of Str�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uctured Light 3D Vis�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion Measurem�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ent for Continuous �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Casting Bill�� Ƴ�� Ƴ�� Ƴ�� Ƴ��et Lines in Indust�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rial Production Environm�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ents	MCC Baosteel T�� Ƴ�� Ƴ�� Ƴ�� Ƴ��echnology Services C�� Ƴ�� Ƴ�� Ƴ�� Ƴ��o., Ltd.	Third Prize
20	Research, Development,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and Promotion�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of Highly Cor�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rosion-Resistant Hot�� Ƴ�� Ƴ�� Ƴ�� Ƴ��-dip Galvanized �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Steel Plates�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� with Aluminu�� Ƴ�� Ƴ�� Ƴ�� Ƴ��m-Magnesium Alloy�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Coating	Jiuquan Iron and S�� Ƴ�� Ƴ�� Ƴ�� Ƴ��teel (Group) Co., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Ltd., CISDI �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Thermal & Environm�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ental Engineering�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Co., Ltd., University o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f Science and Technology�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Beijing, and Lanzho�� Ƴ�� Ƴ�� Ƴ�� Ƴ��u University, Lanzhou U�� Ƴ�� Ƴ�� Ƴ�� Ƴ��niversity of Techno�� Ƴ�� Ƴ�� Ƴ�� Ƴ��logy	Third Prize
21	Development a�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nd Application o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f Key Technologies and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Equipment in t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he Whole Process of �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Efficient Coking	Angang Steel Co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mpany Limited, ACRE �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Coking & Refrac�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tory (Dalian�� Ƴ�� Ƴ�� Ƴ�� Ƴ��) Engineering Consultin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g Corporation, MCC,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and MCC Jiaonai Aut�� Ƴ�� Ƴ�� Ƴ�� Ƴ��omation Co., Ltd.	Third Prize

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