Abstract
Pushed to the forefront by the objective to drastically reduce the CO2emissions from the steel industry, a new steelmaking route based on hydrogen and electricity is the subject of a great deal of attention and numerous R&D projects. The first step is to chemically reduce iron ore with H2, which is produced by electrolysis of water with low-carbon electricity, and then to transform the direct reduced iron into steel in an electric arc furnace. The second step is a conventional one, similar to that used for scrap recycling. The first step is similar to the so-called direct reduction process but would use pure electrolytic H2instead of the H2–CO syngas obtained from natural gas reforming. In this paper, we first show how the reduction by pure H2takes place at the microscopic level of the iron oxide grains and pellets. The three-step (hematite-magnetite-wüstite-iron) reduction occurs successively in time and simultaneously in the pellets. Secondly, a sophisticated kinetic model of the reduction of a single pellet based on the experimental findings is described. Lastly, we present a mathematical model for the simulation of the reduction by pure H2in a shaft furnace, which can be very useful for the design of a future installation. The main results are that using pure hydrogen, the reduction kinetics are faster and can end with full metallization, the direct reduction process would be simpler, and the shaft furnace could be squatter. The gains in terms of CO2emissions are quantified (85% off) and the whole route is compared to other zero-carbon solutions in Part 2.
Highlights
Given its volume (1.88 billion tons of steel produced in 2019 [1]) and its demand for fossil energy, mainly coal, the steel industry is one of the world’s leading emitters of CO2 (7% of global anthropogenic emissions [2])
The shaft furnace for the reduction of iron ore with pure H2 is the core of the new process
The most promising hydrogen-based steelmaking route is the direct reduction of iron ore by pure H2 followed by electric steelmaking
Summary
Given its volume (1.88 billion tons of steel produced in 2019 [1]) and its demand for fossil energy, mainly coal, the steel industry is one of the world’s leading emitters of CO2 (7% of global anthropogenic emissions [2]) This situation is not new and the steel sector has been investigating low-carbon solutions for producing steel, including hydrogen-based ones, for the last 60 years at least [3,4]. The most advanced current projects, such as HYBRIT [12], are already approaching it from the point of view of reduced-scale industrial demonstration This route is clearly different from the conventional BF-BOF (Blast Furnace-Basic Oxygen Furnace) route, and different from the existing DREAF (Direct Reduction-Electric Arc Furnace) route, which uses a CO-H2 syngas, produced from natural gas. The present paper is organized as follows: first, the physical-chemical aspects of the iron oxide reduction by hydrogen are recalled, the features that can influence an industrial process are highlighted, and a comparison with CO is given; second, the findings obtained from mathematical modeling, both on the pellet and reactor scales, are discussed
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