OA21702A - Method for reducing carbon footprint in operating a metallurgical plant for producing pig iron. - Google Patents

Abstract

A method for reducing carbon footprint in operating a metallurgical plant for producing pig iron (P), the method comprising the steps of: (a) pre-heating iron ore fines (A) in a first electric preheater (10) based on Joule effect and/or microwave heating to a temperature above 600 °C to obtain pre-heated iron ore fines (B), (b) partially reducing the pre-heated iron ore fines (B) in one or more fluidized bed reactors (50) in the presence of a hot reducing gas (J) to obtain partially reduced iron (K, L); (c) feeding the partially reduced iron (K, L) to a submerged arc furnace (70) comprising a bath of molten métal with a top slag layer; (d) further reducing and melting the partially reduced iron (K, L) within the submerged arc furnace (70) in the presence of a carbonaceous material (M) to obtain molten pig iron (P); wherein, in step (b), the hot reducing gas (J) comprises hydrogen (D), syngas (I), off-gas (O) of the submerged arc furnace, other off-gases (H) from the metallurgical plant, or mixtures of two or more thereof, wherein said syngas (I) is produced from natural gas or biomethane (F), blast furnace gas (G), off-gas (O) of the submerged arc furnace (O), other off-gases from the metallurgical plant (H), or mixtures of two or more thereof in the presence of air or oxygen enriched air, steam or carbon dioxide (E) in one or more reforming reactors (40), wherein, in step b), the hot reducing gas (J) has a temperature above 550 °C, and wherein, in step b), the partially reduced iron (K, L) has a metallization degree of 55 to 75 %, preferably 60 to 70 %. <img file="OA21702A_A0001.tif"/> Planche Unique - Fig. 1

Description

METHOD FOR REDUCING CARBON FOOTPRINT IN OPERATING A METALLURGICAL PLANT FOR PRODUCING PIG IRON

Technical field

[0001] The présent invention generally relates to a method for reducing carbon 5 footprint in operating a metallurgical plant for producing pig iron and a metallurgical plant for producing pig iron with a reduced carbon footprint.

Background Art

[0002] The necessity as well as the duty to reduce global CO2 émissions is influencing the Steel industry as one of the main responsible player. The worldwide 10 decarbonisation is pushing the steelmakers towards a transition for a moresustainable production, based on maximization of so-called “green” sources, like “green” electrical energy and renewable reductant and fuels, as replacement of fossil ones.

[0003] Hydrogen appears to be the new key factor for CO2 réduction at the présent 15 days and in particular for a future decarbonised Steel production. To fulfil the decarbonisation target, the hydrogen should be produced without carbon dioxide émissions, which means production for instance via electrolysis process fed by electrical energy from renewable sources. In this way, a “green” hydrogen is produced, completely free from carbon dioxide émissions. Nevertheless, green 20 hydrogen production costs are currently high and, although a decreasing is foreseen in next years, this can compromise the feasibility of its application in the steelmaking sector, even in future scénarios, due to the huge energy and flowrate demand in iron and Steel production processes.

Technical problem

[0004] It is an object of the présent invention to provide a new route for a more sustainable pig iron production from iron ore fines, in particular a method for pig iron production suitable to be installed in metallurgical plants, such as in integrated Steel works, which method should offerthe flexibility to be operated in a range from limited to zéro carbon dioxide émissions, such as for allowing either to ensure a more

I 2 graduai transition in reducing carbon footprint or to operate at least at low carbon dioxide émissions in case of temporary non-availability of certain renewable resources.

General Description of the Invention

[0005] In order to overcome the above-mentioned problem, the présent invention proposes, in a first aspect, a method for reducing carbon footprint in operating a metallurgical plant for producing pig iron, the method comprising the steps of:

a) pre-heating iron ore fines in a first electric pre-heater based on Joule effect and/or microwave heating to a température above 600 °C, preferably from 700 10 to 900 °C, in particular from 750 °C to 850 °C, such as about 800 °C, to obtain pre-heated iron ore fines;

b) partially reducing the pre-heated iron ore fines in one or more fluidized bed reactors in the presence of a hot reducing gas to obtain partially reduced iron;

c) feeding the partially reduced iron to a submerged arc furnace comprising a 15 bath of molten métal with a top slag layer;

d) further reducing and melting the partially reduced iron within the submerged arc furnace in the presence of a carbonaceous material to obtain molten pig iron;

wherein, in step b), the hot reducing gas comprises hydrogen, syngas, i.e. synthetic 20 gas, off-gas of the fluidized bed reactor(s), off-gas of the submerged arc furnace, other (CO-containing) off-gases from the metallurgical plant, or mixtures thereof, wherein said syngas is produced from natural gas or biomethane, blast furnace gas, off-gas of the submerged arc furnace itself or another submerged arc furnace, other off-gases from the metallurgical plant, or mixtures of two or more thereof in one or 25 more (catalytic or non-catalytic) reforming reactors in the presence of air or oxygenenriched air, steam or carbon dioxide (depending on the reforming process used); wherein, in step b), the hot reducing gas has a température above 550 °C; and wherein, in step b), the partially reduced iron has a metallization degree of 55 to 75 %, preferably 60 to 70 %.

[0006] In a second aspect, the invention proposes a metallurgical plant for producing pig iron with a reduced carbon footprint, preferably by implementing the method for reducing carbon footprint in operating a metallurgical plant for producing pig iron according to the first aspect, the metallurgical plant comprising:

- a first electric pre-heater configured for pre-heating iron ore fines based on Joule effect and/or microwave heating into pre-heated iron ore fines at a température above 600 °C, preferably from 700 to 900 °C, in particular from 750 °C to 850 °C, such as about 800 °C;

- one or more fluidized bed reactors configured for partially reducing the preheated iron ore fines in the presence of a hot reducing gas into partially reduced iron to a metallization degree of 55 to 75 %, preferably 60 to 70 %;

- a submerged arc furnace comprising a bath of molten métal with a top slag layer, configured for receiving the partially reduced iron and further reducing and melting the partially reduced iron in the presence of a carbonaceous material to obtain molten pig iron;

wherein the metallurgical plant further comprises one or more (catalytic or noncatalytic) reforming reactors configured for producing a syngas from a feed of natural gas or biomethane, a feed of blast furnace gas, one or more feeds of off-gas of the submerged arc furnace and other off-gases from the metallurgical plant, or a feed of mixtures thereof and a feed of air or oxygen-enriched air, steam or carbon dioxide (as required by the chosen reforming process); wherein the metallurgical plant further comprises a feed of hydrogen; a hot reducing gas mixing device fluidly connected upstream to the one or more (catalytic or non-catalytic) reforming reactors and to the feed of hydrogen, and optionally to one or more of said feeds of an off-gas of the submerged arc furnace and of other off-gases of the metallurgical plant, or a feed of mixtures thereof and downstream to an inlet of the one or more fluidized bed reactors, said hot reducing gas mixing device being configured for providing hot reducing gas at a température above 550 °C comprising hydrogen, syngas, off-gas of the fluidized bed reactor(s), off-gas of the submerged arc furnace, other off-gases of the metallurgical plant, or mixtures of two or more thereof. The hot reducing gas mixing device may be a dedicated mixing unit or may only be the confluence of feed of (preheated) hydrogen, the syngas from the (catalytic or non-catalytic) reforming reactor, the off-gas of the fluidized bed reactor(s), the off-gas of a/the submerged arc furnace and the other off-gases of the metallurgical plant.

[0007] In the context of the invention, other off-gases from the metallurgical plant may be any available and appropriate CO-containing off-gas or mixtures of two or more thereof. They may be selected from one or more off-gases from a coke oven plant, a DRI (Direct Reduced Iron) plant, a basic oxygen furnace, an electric furnace (other than of the submerged arc furnace used in the présent method), etc.

[0008] As such, the core of the proposed method and metallurgical plant is based on a partial (pre-)reduction step in one or more fluidized bed reactors to a metallization degree of 55 to 75 %, preferably 60 to 70 %, based only on hot gaseous reductants, followed by an electric smelter of the submerged arc furnace (SAF) type, where smelting and the completion of the réduction take place.

[0009] Consequently, the invention takes advantage of a combination of three findings: (1) that the kinetics curve of the iron ore fines réduction is very steep up to 70 to 75 %, meaning that the metallization degree of 75 % can be reached e.g. within 20 to 30 minutes, whereas the further metallization from 75 % to 95 % in the same conditions would then take more than two hours; (2) that this partial réduction can be obtained when effected with only hot reducing gas as a reductant, which moreover can be at least partially based on off-gases available on a metallurgical plant, such as the off-gas ofthe submerged arc furnace ofthe method itself or of other processes, but also other off-gases as further detailed below, (3) that this partial réduction can be obtained at least partially based on natural gas, biomethane or mixtures thereof and/or blast furnace gas, off-gas ofthe submerged arc furnace, other off-gases from the metallurgical plant or mixtures thereof, if they are converted in a catalytic or noncatalytic reforming reactor into an efficient reducing (syn)gas to be used directly as such or in combination with variable proportions of hydrogen and/or other CO rich available off-gas(es); and (4) that the further treatment in a submerged arc furnace in the presence of a solid carbonaceous material acting as further reductant allows to transform the only partially reduced iron ore into pig iron.

[0010] According to the invention, the hot reducing gas in step b), comprises or consists of hydrogen, syngas, off-gas of the fluidized bed reactor(s), off-gas of the submerged arc furnace, other (CO-containing) off-gases from the metallurgical plant, or mixtures thereof. Preferably, said hot reducing gas comprises or consists of at least syngas as defined in the présent context, meaning a syngas produced from natural gas or biomethane, blast furnace gas, off-gas of the fluidized bed reactor(s), off-gas of the submerged arc furnace, other off-gases from the metallurgical plant, or mixtures of two or more thereof in one or more (catalytic or non-catalytic) reforming reactors in the presence of air or oxygen-enriched air, steam or carbon dioxide 5 (depending on the reforming process used). It optionally advantageously comprises (additional) hydrogen, off-gas of the fluidized bed reactor(s), off-gas of the submerged arc furnace, other (CO-containing) off-gases from the metallurgical plant, or mixtures of two or more thereof. In embodiments, said hot reducing gas comprises or consists of said syngas, (additional) hydrogen and at least one gas selected from 10 off-gas ofthe fluidized bed reactor(s), off-gas ofthe submerged arc furnace and other (CO-containing) off-gases from the metallurgical plant.

[0011 ] A preferred fluidized bed reactor for this purpose is a circulating type fluidized bed reactor providing high slip velocity between gas and solids resulting in high mass and heat transfer coefficients. Hence, the one or more fluidized bed reactors are 15 preferably of the circulating type.

[0012] A Submerged Arc Furnace (SAF) is a spécial type of electric (arc) furnace suitable to perform réduction process. In the submerged arc furnace, the tips of électrodes are buried in the slag, where the active power is converted into thermal energy by Joule effect and where the reactions take place. The burden, consisting of 20 lump ore and/or agglomerated fine and/or pre-reduced ore, fluxes and carbon carriers, descends according to the furnace throughput and is heated. When entering in the reaction zone, the oxides with the lowest melting point are liquefied. As the energy density increases towards the électrodes, ail oxides are finally molten. Thus, carbo-thermic réduction by means of solid carbon bearing material take place.

Depending on the température control and the slag melting point, the métal oxides are reduced, in the order of the demand of electric energy required for the réduction with carbon. The slag forms a liquid layer, made mainly by gangue, through which the reduced métal droplets descend to form the métal bath at the bottom of the hearth. The bath is carbon saturated, in order to guarantee the carbo-thermic 30 réduction in the slag, and the final product is therefore hot pig iron, e.g. with a carbon content of 3 - 4 %. In the context of this invention, the term “submerged arc furnace” or “SAF” includes ail the different possible electric arc furnace types optimized for the ⁶ spécifie application, e.g Direct Current furnace, Alternate Current furnace, Open Bath Furnace, circular types, rectangular types, etc.

[0013] Consequently, the submerged arc furnace can be considered a flexible electric smelter, able to perform réduction of métal oxides, charged both as iron ore 5 or as pre-reduced iron (or direct reduced iron, DRI). Generally speaking, for iron making applications, its advisable to hâve a pre-reduction step between the submerged arc furnace, to limit the electrical energy consumption and improve the overall plant efficiency. Nevertheless, a high DRI metallization is not required by a submerged arc furnace, unlike in the case of state-of-art Electric Arc Furnace (EAF).

This allowed the inventors to find the optimal trade-off operational point for the présent invention of 55 to 75 %, preferably 60 to 70 % of metallization, being the last part of metalization performed in a separated reactor, which has been experienced as the most critical part, due to availability issues (mainly for sticking problems) and constraints which can compromize the feasibility, such as lower productivity, higher 15 résidence time, lower efficiency, etc.

[0014] Furthermore, the method and metallurgical plant described herein are particularly adapted to make use of renewable resources as energy source and solid and gaseous reducing agents, such as “green” hydrogen, bio-char and “green” electricity. Moreover, the method can be flexibly and gradually converted to a full 20 green operation (zéro carbon dioxide émission), depending on the resources availability: hydrogen for the fluidized bed reactor can be produced by electrolysis using (only) renewable electricity (“green” H2) or produced by fossil resources with application of CO2 capture technology (“blue” H2) or produced by fossil resources (“grey” H2); fossil coal and/or bio-char can be used in the submerged arc furnace; 25 other métallurgie plant off-gases, such as integrated steelworks gases, can be fed into the fluidized bed reactor. The method is also particularly aimed at allowing for a mixed operation with (varying proportions of) hydrogen, recirculated CO-containing metallurgical off-gas(es) and syngas, with an enhanced flexibility in conversion to “green” operation depending on sources availability and costs. In this regard, the 30 proposed method can be flexibly operated from completely avoiding carbon dioxide émissions to limited émissions, depending on type and quantity of energy resources used: the same metallurgical plant can be fed only by renewable energy sources, reducmg gas, biomethane and solid reductant (carbonaceous matenal), with zéro CO2 émissions or it can still be partially fed by fossil resources (e.g. grey/blue hydrogen, coal, natural gas, electricity from fossil fuel, etc.) with a limited CO2 footprint, but in any case lowerthan currently used iron-making technologies.

[0015] Biomethane is a renewable energy source derived from agricultural biomass (dedicated crops, by-products and agricultural waste and animal waste), agroindustrial (waste from the food processing chain) and the Organic Fraction Municipal Solid Waste (OFMSW). Biomethane is obtained in two phases: raw biogas production - predominantly through anaérobie digestion of biomass - and subséquent removal of non-compatible components (CO2), a process also known as upgrading. Biomethane has a quality similar to fossil natural gas, having a methane concentration of 90 % or greater. Hence, the product of the présent invention is a “green” pig iron which can be produced totally CO2-free, if only renewable sources are used as energy input and solid and gaseous reductants.

[0016] As a conséquence, in advantageous embodiments, at least part, preferably ail of the electric energy needed in the method or in the metallurgical plant is renewable electricity. In particular, at least part the electrical energy needed in the pre-heater(s) and the submerged arc furnace is renewable electricity.

[0017] Alternatively or additionally, the carbonaceous material in step d) comprises (or consiste of) bio-char produced by biomass, optionally including démolition wood, such as up to 40 wt.-%, and/or waste plastics, such as up to 20 wt.-%. The carbonaceous material can be fed to the submerged arc furnace as such and separately form the partially reduced iron. It may be of benefit however to feed the carbonaceous material at least partially to the submerged arc furnace in combination or admixture with the partially reduced iron. One particularly advantageous way to add said carbonaceous material will be described herein below.

[0018] Moreover, the process can easily be configured to recycle a certain percentage of integrated Steel solid residues, either by addition to the feed of iron ore fines in step a) and/or to the pre-heated iron ore fines obtained in step a) and/or to the partially reduced iron obtained in step b), in accordance with the “circular economy” concept, with additional both environmental and économie benefits.

[0019] The reformmg in the présent invention can be done in any appropriate reforming reactor or combinations of two or more reforming reactors, which may be of the same type or use a different technology and are known in the art of syngas production. The reforming reactors are either catalytic or non-catalytic reforming reactors and examples of such reactors are steam reforming reactors, such as catalytic steam reforming (CSR) reactors, dry reforming (DR) reactors, autothermal reforming (ATR) reactors, partial oxidation (POX) reactors, such as catalytic partial oxidation (CPO) reactors, membrane reforming (MR) reactors, or any combination of two or more different types of reactors.

[0020] Steam reforming (SMR) is a process for producing syngas by reaction of hydrocarbons with water in the form of steam. The reaction can be represented by the following reaction:

CH₄ + H₂O θ CO + 3 H₂ (1)

[0021] Dry reforming (DR), also known as carbon dioxide reforming, is a process of producing syngas from the reaction of hydrocarbons such as methane with carbon dioxide with the aid of noble métal catalysts, such as typically Ni or Ni alloys. The dry reforming reaction may be represented by:

CH₄ + CO2 θ 2 CO + 2 H2 (2)

[0022] Autothermal reforming (ATR) uses oxygen and carbon dioxide or steam in a reaction with methane to form syngas. The reaction takes place in a single chamber where the methane is partially oxidized. The reaction is exothermic. When the ATR uses carbon dioxide, the H₂:CO ratio produced is 1:1 ; when the ATR uses steam, the H₂:CO ratio produced is 2.5:1. The outlet température ofthe syngas is between 9501100 °C. In addition to reaction (1), ATR introduces the following reaction:

CH4 + 0.5 O₂ θ CO + 2 H₂ (3)

[0023] Partial oxidation (POX) occurs when a substoichiometric fuel-air mixture is partially combusted in a reformer, creating a hydrogen-rich syngas. A distinction is made between thermal partial oxidation (TPO) and catalytic partial oxidation (CPO).

[0024] The process of catalytic partial oxidation (CPO) is also based on reaction (3), where oxygen can corne from air or oxygen-enriched air or a combination of oxygen and nitrogen conducted by colliding forfew milliseconds, gaseous premixed reactant flows through extremely hot catalytic surfaces. The fast and sélective chemistry that is originated is confined inside a thin solid-gas interphase zone surrounding the catalyst particles. Here, the molécules typically spend very short time at températures variable between 600 and 1200 °C. A key issue for the technological exploitation is in the possibility of avoiding the propagation of reactions into the gas phase, which has to remain at a “relatively low” température. This condition favors the formation of primary reaction products (namely CO and H2) inhibiting chain reactions.

[0025] A membrane reforming (MR) reactor is a reactor wherein oxygen séparation, steam reforming (SR) and partial oxidation (POX) are combined in a single step.

[0026] In preferred embodiments, the hydrogen and/or the blast furnace gas, the off-gas of the submerged arc furnace, the other off-gases from the metallurgical plant, or mixtures thereof is/are pre-heated in one or more further (e.g. second or second and third) electric pre-heater(s) based on Joule effect and/or microwave heating to a température above 700 °C before being fed to the fluidized bed reactor, preferably before being mixed to the (already hot) syngas from the catalytic or non-catalytic reforming reactor, said syngas having been produced from natural gas or biomethane and, optionally a certain percentage of blast furnace gas. In case of circulating fluidized bed reactor(s), their exhaust is preferably re-heated before being recirculated, either in a separate electric heater or advantageously also in the second electric pre-heater.

[0027] In further preferred embodiments, the iron ore fines hâve a grainsize distribution in the range 0,05 - 2 mm, advantageously in the range of 0,1 - 1 mm.

[0028] If necessary or desired, the method further comprises in step b) the (hot) briquetting of the partially reduced iron ore fines to obtain briquetted partially reduced iron, which preferably are the hot-charged to the submerged arc furnace. As already briefly mentioned above, the carbonaceous material is advantageously at least partially (such as to at least 60 wt.-%, e.g. at least 80 wt.-% or even at least 90 wt%), preferably entirely fed to the submerged arc furnace in combination or admixture with the partially reduced iron. Most preferably, at least part of, preferably the entirety of the carbonaceous material is first introduced into the briquetted partially reduced iron during hot briquetting and then fed to the submerged arc furnace in step d). In such embodiments, the carbonaceous material is thus briquetted with the partially ¹⁰ reduced iron into (mixed carbonaceous and) partially reduced iron briquettes, ready for use in step d). The carbonaceous material added to the briquettes and that added separately may be different, such as coal and bio-char, etc. Mixing a certain fraction of carbonaceous fine material with the DRI fines to produce DRI briquettes with a 5 certain carbon content may be useful to optimize the electric smelter process, including better control of the final C content of the hot métal. The remaining part of carbonaceous materials required for HBI smelting can be separately charged into the electric smelter, as done in state-of-art processes.

[0029] In fact, in the state-of-art electric smelter processes for Direct Reduced Iron 10 (DRI) and Hot Briquetted Iron (HBI) smelting, such as in an Electric Arc Furnace or

Submerged Arc Furnace, solid carbon is generally used to complété iron oxide réduction: solid coal is top-charged in the electric furnace together with other input feed, in addition to the carbon content from DRI.

[0030] However, the inventors found that the carbonaceous material added to the 15 partially reduced iron (before its feeding to the electric arc furnace) is more efficient within the electric smelter process than carbonaceous material fed separately, such as externally charged coal/bio-char. Indeed, the inventors noted lower consumptions, optimized process parameters and more flexible carbon content to be reached in the final product. It is admitted by the inventors that these advantages are due to the fact 20 that the carbonaceous material admixed and/or briquetted with the partially reduced iron is in fine grainsize form and homogenously mixed with the partially reduced iron fines , making more efficient the coal use in the smelter process, while in the separate coal charging, some undesirable phenomena hâve been observed, such as coal carry-over with the offgas, carbon burnt out and lower réduction efficiency, ail of 25 which lead to higher consumptions and less productivity.

[0031] One topic of particular interest is the C content in the métal product which is required depending on its use and the C content which is provided during the early steps of the présent process due to the context of its installation in integrated steelworks. In fact, in order to be able to exploit the availability of existing downstream 30 processes (e.g. Blast Oxygen Furnace), > 4 wt.-% C content (typically 4.5 wt.-%) are required in the produced hot métal, similar to Blast Furnace Hot Métal. If this target is met, there is no need of installing/modifying the existing downstream hot métal treatment plant.

[0032] However, the C content of the partially reduced iron strongly dépends on the direct réduction process, and in case of gas based direct réduction as in the présent 5 method, a certain C content in the partially reduced iron basically stems from COcontaining reductants, such as syngas. The use of a reducing gas with low CO content and thus higher hydrogen content than the reducing gas from natural gas reforming processes commonly used in state-of-art technologies, means lower carbon content in the partially reduced iron, such as in a range of 0.1 to 3 wt.-%, 10 depending on the spécifie réduction reactor type. This also means that the total replacement of C containing fuel and reductant with hydrogen, will lead to partially reduced iron with zéro or almost zéro carbon content.

[0033] In particular in the cases of such zéro or very low carbon contents, direct coal charging in the electric furnace is not optimal for the smelting process in step d), 15 which as explained above lead to higher consumption, lower productivity and lower flexibility in product characteristics (mainly referring to carbon content in the métal product). Moreover, this would more than likely increase the CO2 footprint of the overall electric smelter process as well.

[0034] As a conclusion, the présent invention aims at producing “green” pig iron 20 inside an integrated steelwork or metallurgical plant, exploiting the availability of COrich syngas enhanced by the enrichment with syngas from catalytic or non-catalytic reforming of natural gas or biomethane, limiting the degree of réduction of the iron ore fines and completing the réduction in a submerged arc furnace using different renewable energy sources and selecting spécifie solutions to improve the économie 25 feasibility of the application. The method is flexible to be also operated totally or partially with fossil fuel and reductant, depending on spécifie local availability and costs, such that a certain carbon dioxide footprint may be foreseen, but limited in comparison with state-of-art routes and including the possibility of further réduction moving towards higher amount of “green” resources, when available atfeasible costs.

Brief Description of the Drawings

[0035] Preferred embodiments of the invention will now be described, by way of example, with reference to the accompanying drawing:

Fig. 1 is a schematic view of an embodiment of a metallurgical plant for producing pig iron with a reduced carbon footprint or a method for reducing carbon footprint in operating a metallurgical plant for producing pig iron.

[0036] Further details and advantages ofthe présent invention will be apparent from the following detailed description of several not limiting embodiments with reference to the attached drawing.

Description of Preferred Embodiments

[0037] The plant is fed by iron ore fines, even low grade, with a grainsize distribution generally in the range from 0,05 - 5 mm, such as from 0,1 - 1 mm, which could include pre-agglomerated ultra-fines particles. In this context, it is noteworthy that iron ore fines generally contain hématite, goethite and magnetite with varying iron content having a bulk density range from 1,500 to 3,500 kg/m³. Such iron ore fines are particularly well suited for methods as disclosed herein, which comprise the partial réduction when fluidized with reducing gases. Should integrated Steel solid residues be added to the feed of step a), they preferably hâve particle sizes similar to those of the iron ore fines. The iron ore fines A are first conveyed from a storage area to the a first elecrtic pre-heater 10. Pre-heating is performed by means of an electric pre-heater based on Joule effect or microwave heating, optionally coupled with a heat recovery System, exploiting the available residual heat from the integrated steelwork or the fludized bed reactor syngas.

[0038] The preheated iron ore fines B are then conveyed to a fluidized bed charging System through handling equipment suitable for fines transportation, such as chain conveyors or pneumatic transport, to be fed to a fluidized bed reactor 50. The fluidized bed reactor 50 preferably is of the circulating type, wherein the exhaust of fluidized bed reactor C is recirculated, preferably after being (p)re-heated in the second electric pre-heater 20, allowing for an enhanced flexilibity in fines grainsize distribution, as well as the optimal process efficiency, with regards to thermal exchanges and résidence time.

[0039] Green or blue or grey hydrogen (or a mixture of them) D can be used as reducing gas J in the fluidized bed reactor 50. Due to the completely endothermie iron oxide réduction reactions with hydrogen D, other (recirculated) metallurgical plant offgas(es) H, syngas I, or mixtures thereof J, not only iron ore fines, but preferably also hydrogen and any other metallurgical plant off gases are pre-heated in one or more further pre-heaters 10, 20, 30 before being fed into the fluidized bed reactor 50, up to a température of approx. 800°C. In preferred embodiments, a second electric pre-heater 20 is provided for pre-heating hydrogen D and the recirculated exhaust of fluidized bed reactor C, optionally coupled with an heat recovery System from available steelwork gases; and a third electric pre-heater 30 is provided for pre-heating the off-gas of the submerged arc furnace and any other metallurgical plant off gases (except blast furnace gas, which is fed to the catalytic or non-catalytic reforming reactor). This allows to reduce the consumption of hydrogen used as a fuel.

[0040] The hydrogen D fed into the fluidized bed reactor 50 can be partially replaced by a syngas I and other (CO-containing) off-gas(es) of the metallurgical plant H. Said syngas, rich in carbon monoxide and with a certain amount of hydrogen, which is produced in a catalytic or non-catalytic reforming reactor or reformer 40, fed by natural gas and/or biomethane F, blast furnace gas G, off-gas O of the submerged arc furnace and/or other off-gases from the metallurgical plant H and air or oxygen enriched air (autothermal reforming or (catalytic) partial oxidation), steam (autothermal reforming or steam reforming) or carbon dioxide (dry reforming) E depending on the reforming technology used, see reactions (1) to (3) above. In other words, if off-gas O of the submerged arc furnace and/or other off-gases H from the metallurgical plant are used, they can be used either as such or with prior reforming, or both. The main advantage of this “recycling” is the réduction of hydrogen consumption, exploiting availability of CO-rich gas at limited calorific value, such as blast furnace gas, which can be more efficienlty used in a réduction process than for energy production. Moreover the use of CO containing syngas in the fluidized bed reactor 50 provides benefits to the process, due to the exothermic CO combustion reaction with heat release and to a certain carbon content remaining in the partially reduced iron K or L, with conséquent réduction of the consumption of carbonaceous material M, such as coal/bio-char, in the submerged arc furnace 70, more efficient réduction process in the submerged arc furnace 70 and limited re-oxidation phenomena in the hot partially reduced iron K or L handling. The carbonaceous material M may also comprise further additives, such as slag forming agents, etc.

[0041] The partially reduced iron K in the form of fines, with a pre-reduction degree of metallization limited at e.g. about 60-70% are discharged and conveyed from the reactor in an inert atmosphère (e.g. nitrogen or argon) to avoid re-oxidation phenomena. Then, the partially reduced iron fines K are either directly fed to the submerged arc furnace 70, or preferably hot briquetted in a hot briquetting unit 60 in order to improve their mechanical characteristics, before being handled into the downstream electric arc furnace charging System. The sélection among hot partially reduced iron charging into submerged arc furnace as fines or briquettes dépends on the spécifie project conditions (such as raw materials characteristics, utilities, price, etc.), impacting on submerged arc furnace design and performance. If required by the hot briquetting process (depending on the spécifie equipment type), the hot partially reduced iron fines, discharged from the fluidized bed reactor at a température of 600-650°C can be heated up to 700-750°C, via for instance a third electric heater (e.g. based on Joule effect concept or on microwave heating). In advantageous embodiments, at least part of the carbonaceous material can be fed to the electric arc furnace in combination or admixture with the partially reduced iron. It is of particular benefit to introduce at least part of the carbonaceous material within the briquetted reduced iron. Indeed, the concept of hot briquetting the partially reduced fines with a certain amount of carbonaceous material, such as coal, is advantageous to optimize the smelting process. In comparison to the partially reduced iron fines hot briquetting without carbonaceous material, this bénéficiai solution to help facilitating a proper feeding to the electric furnace may further include: - the installation of additional handling equipment, such as in an inert atmosphère, for carbonaceous material (such as coal) handling and mixing with partially reduced iron,

- a preferably modified hot briquetting machine design (e.g. size, pressure, etc.) to be suitable for treating the different input feed,

- optionally, a carbonaceous material preheating device (e.g. to up to 200 °C 400 °C), if required by the hot briquetting process, depending on spécifie partially reduced iron fines and carbonaceous material properties (mainly: température, metallization degree of the partially reduced iron, quantity of the carbonaceous material, etc.).

[0042] Such a carbonaceous material and partially reduced iron briquetting allows 5 to homogenize and compact the admixture of carbonaceous material and partially reduced iron fines to limit the loss of efficiency of external carbonaceous material charging into the electric smelter, mainly due to coal carry-over, burn out and coarser grainsize.

[0043] The briquetting System (and possibly upstream and downstream thereof) will 10 preferably be configured to work under an inert atmosphère to avoid an undesirable re-oxidation of the partially reduced iron.

[0044] The partially reduced iron in the form of fines K or briquettes L (containing carbonaceous material or not) are then hot charged at approx. 700°C into the electric smelter, submerged arc furnace type 70, where the réduction completion and 15 smelting is performed by a carbonaceous material M (contained in the briquettes L and/or added separately).

[0045] For a completely carbon dioxide free pig iron production, in the proposed invention, bio-char is used as the carbonaceous material M (reductant) in the submerged arc furnace 70 (added as part of the briquettes L and/or seapartely), 20 instead of the conventionally used fossil coal, such as anthracite or coke. Bio-char can be produced by biomass torréfaction process, eventually including a certain percentage of démolition wood (up to 40%) and waste plastics (up to 20%). The biochar characteristics dépend on the type of input biomass and torréfaction process, being in any case suitable for the use into the submerged arc furnace 70.

[0046] The submerged arc furnace 70 is able also to recycle a certain percentage of integrated steelworks solid residues as a solid waste injection N, such as for instance dust and sludge from blast furnace or basic oxygen furnace, mill scales, dedusting dust, etc. Solid residue recycling improves the feasibility of the présent invention application, as well as the environmental benefit, due to the avoiding of 30 landfill, the recovery of the iron, carbon and zinc content of solid waste. A residues flowrate up to 5 % of total submerged arc furnace input feed can be directly injected in the furnace métal bath, in the form of dry dust (moisture <3%) with a grainsize

100 % < 250 micron. Wet and/or coarse residues hâve to be pre-treated in a dryer and/or a mill before electric submerged arc furnace injection, while low moisture and fines dust (such for instance stockhouse dust, BOF dust, ...) can be directly injected without any pre-treatment. In case of solid waste injection flowrate higher than 5 % of total submerged arc furnace input feed, the additional waste can be top charged in form of dry pellets orcold briquettes, after a suitable cold agglomération treatment, consisiting in mixing, pellettizing or briquetting and drying process. In case of carbon bearing solid reasidues, such for instance blast furnace sludge and dust, no additional bio-char is required for waste iron ore réduction and an overall saving in bio-char (or coal) consumption can be obtained.

[0047] The flexibility of submerged arc furnace type electric smelter operations allows to accept also a not optimal quality of partially reduced iron briquettes, and a certain amount of partially reduced iron briquette fines coming from the screening of hot briquetting; this improves the availability of hot briquetting process, avoinding totally or partially the fines internai recirculation.

[0048] The hot reducing gas J fed into the fluidized bed 50 can be a mixture of different proportions of hydrogen D, of the CO-rich submerged arc furnace offgas O, of other recirculated metallurgical off-gas(es) H and of the syngas I produced in the catalytic or non-catalytic reforming reactor/reformer 40 fed by natural gas or biomethane F, blast furnace gas G, off-gas O of the submerged arc furnace and/or other off-gases from the metallurgical plant H and air or oxygen-enriched air, steam or carbon dioxide E: The product of this catalytic or non-catalytic reforming reactor 40 is a syngas I suitable to be used as a reducing gas J in the fluidized bed reactor, e.g. by replacing a certain amount of hydrogen or other recirculated offgas(es). This option can hâve a significant OpEx advantage due to the replacement of a certain amount of hydrogen D with the syngas I produced by natural gas or biomethane F and blast furnace furnace gas G, off-gas O of the submerged arc furnace and/or other off-gases from the metallurgical plant H.

[0049] The proposed method and metallurgical plant has a modular size: each fuidized bed reactor 50 can reach e.g. a maximum production of 550 kty DRI, each submerged arc furnace 70 a maximum size of 1.5 Mtpy of hot pig iron P.

[0050] The hot pig iron P may be thereafter cast as cast pig iron Q in a casting unit 80.

Legend:

First electric pre-heater

Second electric pre-heater

Third electric pre-heater

Reforming reactor

Fluidized bed reactor

Hot briquetting unit

Submerged arc furnace

Casting unit

A Iron ore fines

B Pre-heated iron ore fines

C Exhaust of fluidized bed reactor

D Hydrogen

E Air or oxygen enriched air, steam or carbon dioxide

F Natural gas or biomethane

G Blast furnace gas

H Other metallurgical plant off-gas(es)

I Syngas

J (Hot) reducing gas

K Partially reduced iron (fines)

L Partially reduced iron (briquettes)

M Carbonaceous material (and additives)

N Solid waste injection

O Submerged arc furnace off-gas

P Hot metal/molten pig iron

Q Cast pig iron

Claims (20)

1. A method for reducing carbon footprint in operating a metallurgical plant for producing pig iron (P), the method comprising the steps of:

a) pre-heating iron ore fines (A) in a first electric pre-heater (10) based on Joule effect and/or microwave heating to a température above 600 °C to obtain pre-heated iron ore fines (B);

b) partially reducing the pre-heated iron ore fines (B) in one or more fluidized bed reactors (50) in presence of only hot reducing gas (J) as a reductant to obtain partially reduced iron (K, L);

c) feeding the partially reduced iron (K, L) to a submerged arc furnace (70) comprising a bath of molten métal with a top slag layer;

d) further reducing and melting the partially reduced iron (K, L) within the submerged arc furnace (70) in the presence of a carbonaceous material (M) to obtain molten pig iron (P);

wherein, in step b), the hot reducing gas (J) comprises hydrogen (D), syngas (I), off-gas (O) of the submerged arc furnace, other off-gases (H) from the metallurgical plant, or mixtures of two or more thereof, wherein said syngas (I) is produced from natural gas or biomethane (F), blast furnace gas (G), off-gas (O) of the submerged arc furnace, other off-gases (H) from the metallurgical plant, or mixtures of two or more thereof in one or more reforming reactors (40) in the presence of air or oxygen-enriched air, steam or carbon dioxide (E); wherein, in step b), the hot reducing gas (J) has a température above 550 °C; and wherein, in step b), the partially reduced iron (K, L) has a metallization degree of 55 to 75 %.

2. The method according to claim 1, wherein in step b), the partially reduced iron (K, L) has a metallization degree of 60 to 70 %.

3. The method according to claim 1 or 2, wherein the one or more fluidized bed reactors (50) is/are of a circulating type.

4. The method according to any one of the preceding claims, wherein the hydrogen (D) is pre-heated in a second electric pre-heater (20) and off-gas (O) of the submerged arc furnace and optional other off-gases (H) from the metallurgical plant are pre-heated in a third electric pre-heater (30), both second and third preheaters being independently based on Joule effect and/or microwave heating to a température above 700 °C.

5. The method according to any one of the preceding daims, wherein the carbonaceous material (M) in step d) comprises or consists of bio-char produced by biomass.

6. The method according to claim 5, wherein the bio-char produced by biomass includes démolition wood, such as up to 40 wt.-%, and/or waste plastics, such as up to 20 wt.-%.

7. The method according to any one of preceding daims, wherein the iron ore fines (A) hâve a grainsize distribution in the range 0,1 - 1 mm.

8. The method according to any one of the preceding daims, wherein step b) further comprises hot briquetting partially reduced iron ore fines (K) to obtain briquetted partially reduced iron (L).

9. The method according to claim 8, wherein the carbonaceous material (M) is at least partially introduced into the briquetted partially reduced iron (L) during hot briquetting and fed to submerged arc furnace (70) in step d).

10. The method according to any one of the preceding daims, wherein the other offgases (H) of the metallurgical plant comprise one or more of off-gases from a coke oven plant, a Direct Reduced Iron plant and basic oxygen furnace.

11. The method according to any one of the preceding daims, wherein ail electrical energy needed in the pre-heater(s) and the submerged arc furnace is renewable electricity.

12. A metallurgical plant for producing pig iron (P) with a reduced carbon footprint, the metallurgical plant comprising:

- a first electric pre-heater (10) configured for pre-heating iron ore fines (A) based on Joule effect and/or microwave heating into pre-heated iron ore fines (B) at a température above 600 °C;

- one or more fluidized bed reactors (50) configured for partially reducing the pre-heated iron ore fines (B) in the presence of only hot reducing gas (J) as a reductant into partially reduced iron (K, L) to a metallization degree of 55 to 75 %;

- a submerged arc furnace (70) comprising a bath of molten métal with a top slag layer, configured for receiving the partially reduced iron (K, L) and further reducing and melting the partially reduced iron (K, L) in the presence of a carbonaceous material (M) to obtain molten pig iron (P);

wherein the metallurgical plant further comprises one or more reforming reactors (40) configured for producing a syngas (I) from a feed of natural gas or biomethane (F), a feed of blast furnace gas (G), one or more feeds of off-gas (O) ofthe submerged arc furnace and other off-gases (H) from the metallurgical plant, or a feed of mixtures of two or more thereof, and a feed of air or oxygen-enriched air, steam or carbon dioxide (E); wherein the metallurgical plant further comprises a feed of hydrogen (D); a hot reducing gas mixing device fluidly connected upstream to the one or more reforming reactors (40) and to the feed of hydrogen (D), and optionally to one or more of said feeds of an off-gas (O) of the submerged arc furnace and of other off-gases (H) of the metallurgical plant, or a feed of mixtures of two or more thereof, and downstream to an inlet of the one or more fluidized bed reactors (50), said hot reducing gas mixing device being configured for providing hot reducing gas (J) at a température above 550 °C comprising hydrogen (D), syngas (I), off-gas (O) of the submerged arc furnace, other offgases (H) of the metallurgical plant, or mixtures of two or more thereof.

13. The metallurgical plant according to claim 12, wherein the partially reduced iron (K, L) has a metallization degree of 60 to 70 %.

14. The metallurgical plant according to claim 12 or 13, wherein the one or more fluidized bed reactors (50) is/are of a circulating type.

15. The metallurgical plant according to any one of daims 12 to 14, comprising a second electric pre-heater (20) based on Joule effect and/or microwave heating fluidly connected between said feed of hydrogen (D) and the hot reducing gas mixing device, and a third electric pre-heater (30) based on Joule effect and/or microwave heating fluidly connected between said one or more feeds of off-gas (O) of the submerged arc furnace and other off-gases (H) of the metallurgical plant and the hot reducing gas mixing device, said second and third electric pre heaters (20, 30) being configured for pre-heating the relevant off-gas(es) and syngas to a température above 700 °C.

16. The metallurgical plant according to any of claims 12 to 15, wherein the carbonaceous material (M) is provided from a source comprising or consisting of bio-char produced by biomass.

17. The metallurgical plant according to claim 16, wherein the bio-char produced by biomass includes démolition wood, such as up to 40 wt.-%, and/or waste plastics, such as up to 20 wt.-%.

18. The metallurgical plant according to any one of claims 12 to 17, further comprising a hot briquetting apparatus configured for briquetting partially reduced iron ore fines (K) into briquetted partially reduced iron (L).

19. The metallurgical plant according to any one of claims 12 to 18, wherein the metallurgical plant comprises one or more among, a coke oven plant, a Direct Reduced Iron plant, a blast furnace and basic oxygen furnace, providing said otheroff-gases (H) ofthe metallurgical plant.

20. The metallurgical plant according to any one of claims 12 to 19, wherein ail electrical energy needed in the pre-heater(s) and the submerged arc furnace is renewable electricity.