Product or Service: Metallurgy

Focus Area

  • EAF/IF Performance Optimization
  • Secondary Metallurgy Optimization

Short Description

For this project, qoncept provided training in the metallurgical fundamentals and operational practices of induction furnace operations, as well as the secondary metallurgy of ladle furnaces and the VD and VOD processes. The training focused on translating experience-based observations from daily steelmaking operations into a consistent framework based on liquid metallurgy, thermodynamics and kinetics. Key topics included scrap melting in the induction furnace, and the metallurgical processes of desulphurisation (DeS), degassing (DeH and DeN), and decarburisation (DeC). Through guided discussions and worked examples, the training connected metallurgical targets with practical control actions in steelmaking operations. This approach provides a shared technical language and structured understanding to support stable furnace operation, informed decision-making, and reproducible metallurgical results.

Focus Area

  • EAF/IF Performance Optimization
  • Secondary Metallurgy Optimization

Short Description

For this project, qoncept conducted a training on the metallurgical fundamentals and operational practice of electric arc furnace and AOD steelmaking in order to strengthen process understanding among furnace operators and process engineers. The training focused on translating experience-based observations from daily steelmaking operation into a consistent framework based on liquid metallurgy, thermodynamics, and kinetics. Key topics included scrap melting, energy transfer, slag–metal–gas interactions, oxygen use, and metallurgical process levers such as temperature, material additions, and stirring. Through guided discussions and worked examples, the training connected metallurgical targets with practical control actions in steelmaking operations. The outcome provides a shared technical language and structured understanding to support stable furnace operation, informed decision-making, and reproducible metallurgical results.

Focus Area

  • Digitalization Strategy and Roadmapping
  • Scrap Yard Management and Charge Design
  • Strategic Metallurgy & Process Development

Short Description

Investigation of a potential reduction in production cost using the qontrol maps raw material optimization software.

Focus Area

  • Scrap Yard Management and Charge Design
  • EAF/IF Performance Optimization

Short Description

For this project, qoncept evaluated the existing scrap classification and electric arc furnace (EAF) performance in order to increase process stability and reduce material-related production costs. Using historical production data, key indicators of EAF efficiency and melt predictability were analyzed. The study identified significant variability within existing scrap categories and assessed their impact on alloying effort and operational performance. As a result, a refined classification concept was developed, providing the basis for more consistent melt compositions and improved material logistics. The findings support both immediate and mid-term actions for optimizing resource use and furnace operation.

Focus Area

  • Production Route Design, Logistics & Tendering Support

Short Description

For this project, qoncept conducted an on-site audit to evaluate storage technologies, internal transport flows, digitalization level, and external logistics interfaces at a steel production facility. The assessment focused on identifying inefficiencies related to unstructured storage strategies, manual data handling, and space utilization. Through detailed analysis of warehouse data and transport patterns, key areas for operational improvement were identified. The results form the basis for a prioritized set of measures to reduce truck loading times, optimize storage space, and improve logistics performance.

Focus Area

  • Strategic Metallurgy & Process Development

Short Description

For this project, qoncept conducted an on-site fact-finding mission to assess the readiness of an integrated steel plant for the production of advanced alloyed materials. The evaluation covered the entire process chain, including melting, casting, forging, rolling, and remelting operations. Particular focus was placed on the alignment between equipment, process design, and product requirements. The analysis identified key challenges in achieving consistent product quality and process stability, especially when applying high-complexity alloys in a high-throughput production environment. Additional aspects included the feasibility of producing forged and remelted components, as well as the current level of process control in secondary and special metallurgy. The results form the basis for a structured roadmap aimed at stabilizing existing production routes and preparing the facility for the reliable manufacture of advanced materials.

Focus Area

  • Strategic Metallurgy & Process Development

Short Description

For this project, qoncept provided strategic and technical consulting to support the production of ferrovanadium from vanadium-rich steelmaking slag. Since the raw material must meet strict chemical requirements, the project focused on developing the metallurgical and operational know-how required to identify and qualify suitable slag sources. In addition to technical expertise, qoncept supported the client in research activities, supplier engagement, and the preparation of technically sound business plans. The work included direct discussions with potential steel producers to evaluate collaboration opportunities and ensure supply chain feasibility.

Focus Area

  • Strategic Metallurgy & Process Development

Short Description

For this project, qoncept conducted an on-site fact-finding mission to evaluate the technical readiness and equipment capabilities of an integrated steel plant aiming to enter the electrical steel market. The evaluation included equipment condition, operational practices, metallurgical flexibility, and potential upgrade needs. Based on the analysis, three families of electrical steel grades were defined according to their chemical composition and process requirements. The study confirmed that the existing set-up can produce certain grades with medium silicon content, while the newl planned shop is capable of handling more demanding grades with low carbon and high silicon content. In addition to outlining feasible production routes, qoncept recommended targeted investments to support a stable and efficient production ramp-up.

Focus Area

  • Ingot and Continuous Casting Optimization
  • Production Route Design, Logistics & Tendering Support

Short Description

For this project, qoncept evaluated the preliminary technical proposals submitted by three OEMs for the design and delivery of a new bloom casting machine. The assessment focused on key technological aspects relevant to performance, including casting cycle time, machine radius, and essential metallurgical features. Productivity calculations were aligned with the existing BOF rhythm, and solidification simulations were conducted to analyze the optimal positioning of mechanical soft reduction units. The evaluation also included a comparative analysis of critical machine components and technological options, such as electromagnetic stirring, dummy bar systems, and cooling strategies. The report concludes with initial recommendations and identifies areas where design adjustments may be necessary to achieve optimal integration into the existing meltshop environment.

Focus Area

  • Ingot and Continuous Casting Optimization

Short Description

For this project, qoncept conducted a comprehensive two-phase technical evaluation of ingot casting operations at a compact steel plant with a focus on low- and medium-alloy tool steels. Phase 1 included an on-site assessment of the casting process, equipment, and technological parameters, covering casting system preparation, powder handling, superheat control, casting execution, argon shrouding, hot topping, stripping, and subsequent forging/rolling steps. Observations were made across multiple heats and mold formats to understand influencing factors on inclusion content, yield, and surface quality. Phase 2 focused on analyzing these results and discussing strategic measures for improvement. Key areas included enhancing liquid-to-solid yield, refining hot-top strategies, and adapting process parameters for higher alloyed products. Additional discussions addressed raw material utilization, ingot casting simulation, and best practices for stainless large ingots. The aim was to identify process-driven optimization opportunities while maintaining operational reliability and product quality.