WO2020020478A1 - Detection system, method for detecting of a melting condition of metal materials inside a furnace and for electromagnetic stirring, and furnace provided with such systems - Google Patents

Detection system, method for detecting of a melting condition of metal materials inside a furnace and for electromagnetic stirring, and furnace provided with such systems Download PDF

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Publication number
WO2020020478A1
WO2020020478A1 PCT/EP2019/000227 EP2019000227W WO2020020478A1 WO 2020020478 A1 WO2020020478 A1 WO 2020020478A1 EP 2019000227 W EP2019000227 W EP 2019000227W WO 2020020478 A1 WO2020020478 A1 WO 2020020478A1
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WO
WIPO (PCT)
Prior art keywords
furnace
metal materials
melting
detection system
materials inside
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Application number
PCT/EP2019/000227
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English (en)
French (fr)
Inventor
Sabrina Strolego
Stefano De Monte
Stefano Spagnul
Cristiano PERSI
Original Assignee
Ergolines Lab S.R.L.
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Application filed by Ergolines Lab S.R.L. filed Critical Ergolines Lab S.R.L.
Publication of WO2020020478A1 publication Critical patent/WO2020020478A1/en

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D27/00Stirring devices for molten material
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D19/00Arrangements of controlling devices
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D21/00Arrangements of monitoring devices; Arrangements of safety devices

Definitions

  • the present invention relates to a measuring system and method and to a measuring and stirring system and method for a melting furnace according to the characteristics of the pre-characterizing part of the main claims. Furthermore, the present invention relates to a furnace comprising such systems.
  • recycled metal materials that are molten in a melting furnace to be then cast into dies or ingot moulds for the purpose of obtaining processable metal elements for making finished or semifinished products.
  • the recycled metal materials are introduced into the melting furnace in the solid state and the supply of energy by the furnace allows reaching the melting temperature of the recycled metal materials, which progressively melt forming metal in the liquid state.
  • the metal in the liquid state is measured in order to identify its chemical composition to then introduce additives for adjusting the composition until reaching the desired composition.
  • the metal in the liquid state may be steel.
  • Different types of melting furnaces are known, such as electric arc furnaces (EAF), induction furnaces, burner furnaces.
  • a measurement signal is acquired from a sensor, which is inserted into the electrically conductive material, during a relative displacement between the electrically conductive material and the sensor.
  • the measurement signal is indicative of electrical conductivity in the vicinity of the sensor.
  • the measurement signal is generated to represent momentary changes of an electromagnetic field around the sensor, which is generated by at least one coil in the sensor.
  • a signal profile is generated, which is indicative of electrical conductivity as a function of the relative displacement between the electrically conductive material and the sensor.
  • the method enables probing of the internal distribution of the electrically conductive material in the vessel.
  • the signal profile can be analysed to provide information about zones or layers that differ, for example, by composition, degree of melting, degree of mixing.
  • Patent application US 9 599 401 describes a method and device for controlling a melting and refining process in an electric arc furnace for melting a metal, wherein the electric arc furnace includes molten and solid metal and a slag layer on the surface of the molten metal, wherein an electromagnetic stirrer is arranged for stirring the molten metal.
  • the method comprises the steps of:
  • Patent application US 201 3/269483 describes an apparatus for the electromagnetic stirring of cast steel in an electric arc furnace in which the apparatus comprises two electromagnetic stirring units, a power supply and a control unit.
  • the electromagnetic stirring units are mounted on an external lower surface of the electric arc furnace on opposite sides with respect to a central position of the external lower surface of the furnace.
  • the power supply is operatively connected to the two electromagnetic stirring units and the control unit is operatively connected to the power supply to control the operation of the two electromagnetic stirring units.
  • Patent application WO 201 8/096368 describes an apparatus and a method for mixing molten metal.
  • the apparatus comprises an electromagnetic stirrer that comprises a core.
  • the core is provided with two or more teeth, two or more electrically conductive coils and connections for applying a current to the electrically conductive coils.
  • the two or more teeth have a proximal end with respect to the core and a distal end with respect to the core.
  • the distal end of the core defines a terminal face of the tooth in which the terminal face of the tooth for at least one of the teeth is not aligned with the face of the end of the tooth of at least one of the other teeth. In this way the gap between the teeth and the container in which the molten metal has to be stirred can be kept small, also in the presence of curved bases or walls of the container.
  • stirrers electromagnetic stirring devices for furnaces, known as stirrers.
  • the stirrer cannot be activated arbitrarily during the melting process of the recycled metal materials but it must be activated when the melting process has passed an initial phase and the recycled metal materials are at least partially molten.
  • the decision about the right moment for starting the stirrer during the melting process is made based on preparation recipes of the particular steel formulation being produced or based on complex state models of the melting process that are based on acquisitions of measurements that are mostly of the indirect type, which, introduced into the particular state model of the melting process, provide information about the start of the stirring by means of the stirrer.
  • the aim of the present invention is to provide a detection system and method enabling to establish more precisely the melting condition of recycled metal materials inside a melting furnace for the purpose of establishing the most appropriate moment for enabling an electromagnetic stirrer for a melting furnace.
  • Another aim of the present invention is to provide a detection and stirring system and method for a melting furnace in which the system and the method allow to establish the melting condition of recycled metal materials inside a melting furnace and, by integrating a detection system and a stirrer, allow to improve the melting process of the recycled metal materials inside the melting furnace.
  • the solution according to the present invention allows to obtain a measure of the melting condition of the recycled metal materials inside the melting furnace, thus allowing to establish which actions should be undertaken for the purpose, for example, of starting the stirrer in an optimal moment of the melting process or of postponing or anticipating the addition into the furnace of additional recycled metal materials to be molten or for activating systems for providing heat like the electrodes of arc furnaces or like burners, or for activating oxygen injection nozzles or for adding additives, undertaking slagging actions, etc.
  • a mapping of the measurement of the melting condition of the recycled metal materials inside the melting furnace also allowing to know the position inside the furnace of any aggregates or high- mass elements for which it is difficult to achieve a molten state, thus enabling the adoption of suitable adjusting measures, such as an activation of the stirrer intended to induce a displacement of the aggregates or high-mass elements to facilitate their melting or the activation of additional means for providing melting energy that are suitably directed towards the zone of the melting furnace in which such aggregates or high-mass elements are located.
  • Said additional means for providing melting energy may be, for example, orientable burners or oxygen injection nozzles that may be advantageously directed in a more precise way towards the zone of interest.
  • a whole integrated system is advantageously obtained, which is able to manage in an optimal way the starting of the stirrer and the optional adjustment of its power and frequency parameters as a function of the measurement by the detection system itself.
  • the melting of the recycled metal materials is more uniform and efficient, with the reduction of “cave-in” phenomena and breaking of the electrodes, limited to the application on electric arc furnaces.
  • the melting of any large-sized metal materials is also facilitated thanks to a better heat distribution and thanks to the establishment of convective heat exchange phenomena in addition to the conductive ones, also reducing the presence of non-molten scrap at the slagging port or at the tapping hole, improving the spontaneous opening rate.
  • the increase in the reaction kinetics improves the decarbonization rate of the bath of metal in the molten state by a two factor, reducing oxygen consumption to obtain the same degree of decarbonization.
  • the lower oxygen supply reduces the oxidation of Fe and Mn, increasing the final yield and the chemical reduction of the slag, which is less aggressive on the refractory materials, thus extending their useful life, including the refractory materials of the tapping hole.
  • the formation of foamy slag is promoted.
  • the oxygen content at tapping is lower and this causes a reduction in the use of deoxidizers in the ladle.
  • the steel bath is homogeneous.
  • the samples taken for the chemical analysis and the temperature measures are representative of the whole molten bath, thus requiring a smaller number of samples.
  • the slag is not overheated or partially molten. The more uniform temperature of the bath and of the slag reduces the wear of the refractory materials.
  • the final productivity of the furnace is increased by over 5% thanks to the improvement of the chemical yield and to the reduction in processing times.
  • the opening rate of the porous baffles for blowing gas into the ladle is improved, reducing the risk of nonconnection with the continuous casting sequence. It is thus possible to reduce the formation of swirls during tapping and the passage of the furnace slag in the ladle.
  • Fig. 1 is an example view of the detection system and of the electromagnetic stirring system according to the present invention applied in correspondence of the bottom of a melting furnace for recycled metal materials.
  • Fig. 2 is a schematic sectional view of the detection system and of the electromagnetic stirring system according to the present invention, applied in correspondence of the bottom of a melting furnace for recycled metal materials in which the induced movement of the metal in the liquid state contained in the melting furnace is highlighted.
  • Fig. 3 is a schematic plan view of the detection system and of the electromagnetic stirring system according to the present invention applied in correspondence of the bottom of a melting furnace for recycled metal materials in which the induced movement of the metal in the liquid state contained in the melting furnace is highlighted.
  • Fig. 4 is a schematic sectional view of the detection system and of the electromagnetic stirring system according to the present invention, applied in correspondence of the bottom of a melting furnace for recycled metal materials in which the force field intended to induce the movement of the metal in the liquid state contained in the melting furnace is highlighted.
  • Fig. 5 is a schematic plan view showing the different speeds of induced movement of the metal in the liquid state contained in the melting furnace, obtained by means of the detection system and electromagnetic stirring system according to the present invention, applied in correspondence of the bottom of a melting furnace for recycled metal materials.
  • Fig. 6 is a schematic view of the detection system and of the electromagnetic stirring system according to the present invention including a respective cooling station and control unit.
  • Fig. 7 is a schematic sectional view of a first preferred embodiment in which only the detection system according to the present invention is applied in correspondence of the bottom of a melting furnace for recycled metal materials.
  • Fig. 8 is a schematic sectional view of a first preferred embodiment of the detection system and of the electromagnetic stirring system according to the present invention, applied in correspondence of the bottom of a melting furnace for recycled metal materials.
  • Fig. 9 is a schematic sectional view of a second preferred embodiment of the detection system and of the electromagnetic stirring system according to the present invention, applied in correspondence of the bottom of a melting furnace for recycled metal materials.
  • Fig. 10 is a schematic sectional view of a third preferred embodiment of the detection system and of the electromagnetic stirring system according to the present invention, applied in correspondence of the bottom of a melting furnace for recycled metal materials.
  • Fig. ⁇ 1 , Fig. ⁇ 2, Fig. 1 3 schematically show different phases of the detection method according to the invention for establishing the melting condition of the recycled metal materials inside a melting furnace.
  • Fig. 14 schematically shows an exploded view of an integrated embodiment of stirrer and detection system.
  • Fig. 1 5 schematically shows an exploded view of an embodiment of the detection system only.
  • Fig. 1 6 schematically shows an exploded view of an integrated embodiment of stirrer and detection system in which the stirrer and the detection system are made as separate components.
  • Fig. 1 7 schematically shows a first possible configuration of the detection system.
  • Fig. 1 8 schematically shows a second possible configuration of the detection system. Description of the invention
  • the modern melting furnaces of recycled metal materials such as the electric arc furnaces, known by the acronym of EAF, induction furnaces, burner furnaces, have problems concerning the need of operating with times of tapping from the tapping hole (10) that are as reduced as possible.
  • the main problems that can be found in the furnace can be, for example, the presence of solid scrap that is difficult to be molten, high levels of FeO and of oxygen in the metal in the liquid state contained in the melting furnace, chemical and thermal stratification of the bath of metal in the liquid state contained in the melting furnace, problems of opening the tapping hole owing to localised solidifications due to non-homogeneity of the temperature of metal in the liquid state contained in the melting furnace, breaking of the electrodes in the case of electric arc furnaces, establishment of “cave-in” and “cold boiling” phenomena.
  • the solution for simultaneously solving these problems is to increase the kinetics of the system through the stirring of the metal in the liquid state of the steel bath by supplying a flow of inert gas or by using an electromagnetic stirrer.
  • the system according to the invention comprises (Fig. 1 , Fig. 2, Fig. 3, Fig. 4, Fig. 6, Fig. 7, Fig. 8, Fig. 9, Fig. 1 0, Fig. 1 1 , Fig. 1 2, Fig. 1 3) a detection system (3) intended to measure the melting condition of the recycled metal materials inside the melting furnace (1 ) thus allowing to decide which actions to undertake to, for example, start a stirrer (2) in an optimal moment of the melting process.
  • Fig. 7 use can be made only of the detection system (3) intended to measure the melting condition of the recycled metal materials inside the melting furnace thus allowing to decide which actions to undertake to, for example, control the power of the electrodes (4) of the furnace (1 ) or the starting of further devices for providing heat, such as burners or other systems, or to control the addition of additives to the metal in the molten state (5) contained inside the furnace (1 ). Therefore, it should be understood that the detection system (3) for measuring the melting condition inside the melting furnace can also be effectively used without it being combined or integrated with a stirrer (2).
  • a component of an embodiment of the system according to the present invention is a stirrer (2) of the electromagnetic type (Fig. 1 , Fig. 2, Fig. 3, Fig. 4, Fig. 6, Fig. 8, Fig. 9, Fig. 1 0, Fig. 1 1 , Fig. 1 2, Fig. 1 3, Fig. 14, Fig. 1 6) which is applied in correspondence of the bottom of a melting furnace (1 ) for recycled metal materials, such as an electric arc furnace, known by the acronym of EAF, an induction furnace, a burner furnace.
  • the detection system (3) can be provided independently of the stirrer (2) or can be provided as a whole integrated detection and stirring system (20), which comprises a detection system (3) and a stirrer (2) as integrated parts of the system with advantages in terms of higher efficiency of the whole system.
  • FIG. 8 a first embodiment (Fig. 8) in which the whole integrated detection and stirring system (20) consists of a detection system (3) and a stirrer (2) according to an embodiment in which the detection system (3) and the stirrer (2) are housed within one single body, thus being integral with each other;
  • FIG. 9 a second embodiment (Fig. 9) in which the whole integrated detection and stirring system (20) consists of a detection system (3) and a stirrer (2) according to an embodiment in which the detection system (3) is housed within a casing of the detection system (1 7) and the stirrer (2) is housed within a casing of the stirrer ( 1 6) and the detection system (3) and the stirrer (2) are positioned on top of each other in a condition of essential contact and are mounted on the furnace (1 ) in such a way that the detection system (3) is between the lower outer wall, i.e. the bottom, of the furnace and the stirrer (2), attached to the stirrer (2).
  • the detection system (3) is between the lower outer wall, i.e. the bottom, of the furnace and the stirrer (2), attached to the stirrer (2).
  • the whole integrated detection and stirring system (20) is represented as mounted spaced apart by a space (S) with respect to the lower outer wall, i.e. the bottom, of the furnace, in different embodiments the whole integrated detection and stirring system (20) may be attached to the bottom of the furnace (1 );
  • FIG. 1 0 a third embodiment (Fig. 1 0) in which the whole integrated detection and stirring system (20) consists of a detection system (3) and a stirrer (2) according to an embodiment in which the detection system (3) is housed within a casing of the detection system (1 7) and the stirrer (2) is housed within a casing of the stirrer (1 6) and the detection system (3) and the stirrer (2) are positioned in the vicinity of each other but spaced apart from each other by a distance (D) and are mounted on the furnace (1 ) in such a way that the detection system (3) is between the lower outer wall, i.e. the bottom, of the furnace and the stirrer (2), spaced apart from the stirrer (2) by the distance (D).
  • the detection system (3) is between the lower outer wall, i.e. the bottom, of the furnace and the stirrer (2), spaced apart from the stirrer (2) by the distance (D).
  • the whole integrated detection and stirring system (20) is represented as having the detection system (3) and the stirrer (2) that are spaced apart from each other by the distance (D), in different embodiments the stirrer (2) may be attached to the detection system (3) which is in turn attached to the bottom of the furnace (1 ).
  • the detection system (3) may be spaced apart from the bottom of the furnace (1 ) by the space (S), like in the second embodiment (Fig. 9), and at the same time the stirrer (2) may be spaced apart from the detection system (3) by the distance (D), like in the third embodiment (Fig. 1 0).
  • Expected values for the distance (D) between the detection system (3) and the stirrer (2) may range from 30 to 1 20 mm, preferably from 50 to 1 00 mm. In the space defined by the distance (D) an airflow may pass, for example by means of a forced airflow, for cooling and cleaning purposes.
  • a cooling station (1 1 ) is present (Fig. 6), which sends a cooling fluid, typically water, towards the stirrer (2) and optionally also towards the detection system (3) and which afterwards, after the fluid has removed heat from the components that are installed in correspondence of the furnace (1 ), recovers the heated fluid. Therefore, the cooling fluid will circulate according to fluid delivery and return directions (1 4) along connection pipes for connection to the whole integrated detection and stirring system (20), for example with the stirrer (2) only or with the detection system (3) only in the absence of the stirrer (2) as a component of an integrated system or with both the stirrer (2) and the detection system (3).
  • the cooling station (1 1 ) along with the respective fluid connections forms a closed circuit.
  • a fluid control system (1 5) is also present, which for example can be made in the form of a pipe portion provided with fluid measuring and adjusting instruments and connected to a control unit (1 2) by means of a local junction box (1 3).
  • the fluid control system (1 5) can be positioned on the fluid return pipe in such a way as to be able to monitor the temperature of the fluid coming out of the stirrer (2) or out of the detection system (3) or both.
  • the cooling fluid can be water, preferably demineralized, with a flow rate of 1 5-25 m3/h.
  • the cooling station (1 1 ) can comprise a first pumping unit and an optional second safety pumping unit, one or more filters, a heat exchanger, a tank, and can be provided with an automation switchboard connected to the fluid control system (1 5) for the correct and safe operation of the system components installed on the furnace.
  • the stirrer (2) is controlled with an alternating current preferably having a current intensity between 1 500 A and 2500 A, preferably of 2000 A, a voltage between 400 V and 900 V, preferably of 650 V, a frequency between 0.1 Hz and 1 .0 Hz, preferably of 0.5 Hz.
  • the direction of the stirring induced by the stirrer (2) in the metal in the liquid state of the steel bath is generally such as to obtain a flow of hot metal in the liquid state directed towards the tapping hole (1 0) of the furnace (1 ), in such a way as to move the hot metal in the liquid state according to (Fig. 2) a preferred direction of movement (6) towards such area and to improve the spontaneous opening rate of the tapping hole (1 0), as will be explained in the following of the present description.
  • the stirrer (2) is preferably made (Fig. 1 6) in the form of a sealed closed body made up of a set of closing elements (28) constituting the casing (1 6) of the stirrer (2).
  • the casing (1 6) is provided (Fig. 1 4, Fig. 1 6) with the previously described couplings (30) for feeding and taking the cooling fluid of the stirrer (2), which are part of a cooling fluid circuit inside the stirrer (2) consisting of ducts (21 ) of a fluid circuit.
  • a base (34) constitutes the support for mounting at least one series of coils (1 8) of the stirrer each of which preferably consists of an essentially quadrangular winding, according to a plan view, in which the coils develop vertically for a certain height in such a way as to define a closed path of the driving current such as to generate a force field directed according to an orthogonal direction with respect to the quadrangular shape.
  • the coils (1 8) of the stirrer can optionally be further protected by a respective protection capsule (29).
  • the stirrer (2) comprises one single row of six coils (1 8) of the stirrer, which are arranged after one another according to a direction of development along a longitudinal axis (35) of the stirrer (2) that essentially corresponds to the direction of longitudinal development of the furnace (1 ) or to the preferred stirring direction induced by the stirrer (2) in the metal in the liquid state of the steel bath facing the tapping hole (1 0) of the furnace (1 ).
  • the sequence of the phase displacements of the coils (R, S, T) that generates the pushing effect of the hot metal flow in the liquid state in a direction towards the tapping hole (1 0) is, for example, as follows: R - T / S - R / T - S, where the minus sign indicates that the coil is run through in the opposite direction, that is to say, an additional phase displacement of 1 80 electrical degrees is applied. Any even permutations of the phase displacements will bring about the same effect.
  • the coils (1 8) of the stirrer consist of a winding of a hollow copper conductor inside which the cooling water flows. This technology is mainly used to reduce as much possible the amount of water inside the stirrer and thus below the furnace. The stirrer is thus safer if the bottom breaks. Such a technology, which defines the stirrer as“dry type”, also enables simpler maintenance since it does not require a joint external resin treatment of the coils and magnetic pack.
  • the detection system (3) can be an independent system relative to the presence (Fig. 8, Fig. 9, Fig. 1 0) or absence (Fig. 7) of the stirrer (2).
  • the detection system (3) can be for example:
  • the detection system (3) is based on the use of a measuring technique of the magnetic induction tomographic type.
  • the measuring principle is based on the mutual inductance theory associated with the problem of the Foucault's currents or eddy currents.
  • the measuring method is conceived in such a way that one of the coils of the detection system is used as a transmission coil for generating a measuring field (22) and is conceived in such a way that another one of the coils of the detection system is used to acquire the signal due to the eddy currents generated in the set of metal in the molten state (5) and metal materials not yet molten (36).
  • the detection system (3) comprises (Fig. 1 1 , Fig. 1 2, Fig. 1 3) a measuring device (27), which comprises one or more signal generators (23), one or more transmission systems (24), one or more reception systems (25), a processing system (26).
  • the signal generator (23) provides a sinusoidal signal at a transmission frequency to the transmission system (24) that amplifies the sinusoidal signal to drive the coil (1 9) of the detection system that is used for transmission.
  • One or more coils (1 9) of the detection system are in their turn connected to the reception system (25) for measuring the signals received by said coils following the transmission of the sinusoidal signal and the generation of the eddy currents on the set of metal in the molten state (5) and metal materials not yet molten (36).
  • all the coils (1 9) of the detection system are each alternatively configurable as a transmission coil and as a reception coil in different phases of the measuring method.
  • the processing system (26) acquires the measuring signals and sends the result of processing to the control unit (1 2), which provides useful information for acting on the melting process in progress, in order to identify any necessary corrective actions on the melting process in progress.
  • the control unit can also acquire further measuring signals (37) to be used in combination with the measurement performed by means of the detection system (3) to provide more precise information about the melting condition of the recycled metal materials inside the melting furnace (1 ).
  • Such further measuring signals (37) can be acquired by means of sensors (38) or by means of a communication interface (39) with the management system of the furnace (1 ) and of the melting process.
  • the control unit can, for the purpose of providing more precise information about the melting condition of the recycled metal materials inside the melting furnace ( ⁇ ), acquire at least one measuring signal (37) selected from:
  • the method according to the invention can correspondingly provide phases of acquisition of such measuring signals (37).
  • control unit (1 2) can, for example, control one or more actions between:
  • the method according to the invention can further comprise a control phase of control means for controlling the indicated devices or units, such as systems for providing melting heat for increasing or decreasing or adjusting the heat provided to the set of metal in the molten state (5) and metal materials not yet molten (36) in the furnace (1 ), gas injection units arranged to supply gas to the molten material for increasing or decreasing or adjusting the gas quantity, carbon powder supply units for the supply to the metal in the molten state for increasing or decreasing or adjusting the carbon powder quantity.
  • the control phase of control means of such devices can be a control phase in which the control of the devices occurs based on at least the electrical conductivity or resistivity values of the metal materials inside the furnace (1 ) or based on at least the calculated melting condition of the metal materials inside the furnace (1 ).
  • control unit (1 2) can provide control signals (40) to the communication interface (39) with the management system of the furnace (1 ) and of the melting process.
  • the detection system (3) is preferably made (Fig. 1 5, Fig. 1 6) in the form of a sealed closed body made up of a set of cover elements (41 ) constituting the casing (1 7) of the detection system.
  • the detection system (3) comprises one single row of six coils (1 9) of the detection system, which are arranged after one another according to a direction of development along a longitudinal axis (42) of the detection system (3) that essentially corresponds to the direction of longitudinal development of the furnace (1 ) or to the preferred direction of the stirring induced by the stirrer (2) in the metal in the liquid state of the steel bath facing the tapping hole (1 0) of the furnace (1 ).
  • the coils (1 9, 1 9’, 1 9”, 1 9n) of the detection system are made with copper wire wound on a non-magnetic and non-conductive core. It is not necessary to cool the coils, because the current density is low and also the supply of each coil is not continuous. Therefore, in an embodiment, the detection system (3) is made in the form of a body containing the coils (1 9, 1 9', 1 9") of the detection system, wherein the body of the detection system (3) is devoid of a respective cooling system.
  • the dimensions in length or width of the coils can be substantially comparable to the length of the coils (1 8) of the stirrer (2), if present.
  • the series of coils (1 9) of the detection system is arranged in the vicinity of the bottom of the furnace (1 ) and, in the preferred embodiment of the present invention, each of the coils (1 9) of the detection system is alternatively used as a transmission coil and as a reception coil, although it will be evident to a person skilled in the art that it will be possible to provide solutions in which a first series of coils (1 9) of the detection system is exclusively intended to be used as a series of transmission coils and a second series of coils (1 9) of the detection system is exclusively intended to be used as a series of reception coils.
  • the first of the two solutions will be described in the following, it being evident that an extension is possible should one consider the second of the two solutions as defined herein.
  • a first coil (1 9') of the detection system is used as a transmission coil and generates a corresponding measuring field (22).
  • One or more second coils (1 9") of the detection system are used as reception coils and receive a corresponding reception signal due to the response to the measuring field (22) induced by the presence of the set of metal in the molten state (5) and metal materials not yet molten (36) inside the furnace (1 ).
  • any generic coil (1 9n) of the detection system in an“n” phase of the measuring process can be used as a transmission coil, while the remaining coils (1 9) of the detection system except for the generic coil ( 1 9n) will be used as reception coils.
  • the detection system (3) measures the electrical conductivity of the material contained inside the furnace ( 1 ), more particularly it measures and reconstructs a volumetric distribution of the electrical conductivity of the material contained inside the furnace (1 ).
  • the measuring method is based on the injection of a sinusoidal current onto one or more coils (1 9) of the detection system configured as transmission coils.
  • the sinusoidal current When the sinusoidal current is injected into the coil, it generates a magnetic field in the space, indicated as measuring field (22).
  • the magnetic field generated by the transmission coil generates an induced voltage or electromotive force onto the coils (1 9) of the detection system configured as reception coils.
  • the induced voltage or electromotive force is affected by the presence of the spatial distribution of electrical conductivity in the measuring field (22), which in turn is affected by the presence in the measuring field (22) both of metal in the molten state (5) and of metal materials not yet molten (36).
  • the detection system (3) by measuring the electrical conductivity of the material contained inside the furnace (1 ), is able to provide information or a measure of the melting state of the material contained inside the furnace (1 ), thus being able to indicate the presence or non-presence of metal materials not yet molten (36) or being able to provide information about a quantity ratio of metal in the molten state (5) versus metal materials not yet molten (36).
  • each of the coils (1 9) of the detection system is alternatively used as a transmission coil and as a reception coil, or solutions in which a first series of coils (1 9) of the detection system is exclusively intended to be used as a series of transmission coils and a second series of coils (1 9) of the detection system is exclusively intended to be used as a series of reception coils.
  • the transmission coil is periodically changed so as to cover the whole number of available coils (1 9) of the detection system.
  • phases and amplitudes of the electrical signal picked up by the coils (1 9) of the detection system, in this phase configured as reception coils, are recorded.
  • the complete data set so obtained is indicated by the term "scan".
  • a multiplexer device 43.
  • the processing system (26) can, for example, comprise acquisition and digital conversion systems of the electrical signals picked up by the coils (1 9) of the detection system. Based on the scans made, it is then possible to proceed in different ways, either simultaneously or alternatively:
  • the first way allows obtaining an immediate evaluation value of the melting condition that can be easily used for managing the previously explained actions to be undertaken.
  • the second way allows obtaining a visual representation of the situation inside the furnace (1 ) from which it is possible not only to have a general picture of the melting condition, but also to find out any problems, such as the presence of large-sized metal materials not yet molten (36). In this case, too, it will be possible to provide suitable actions to be undertaken, which have been previously explained. For example, if it is found out that large-sized metal materials not yet molten (36), which are harder to be molten, are still present, it will be possible to direct the burners towards the zone indicated by the map or it will be possible to perform localized carbon or oxygen injections, or it will be possible to intervene on the power of the electrodes if the system is used in an electric arc furnace.
  • the distribution of the coils (1 9) of the detection system is planar with an arrangement on a plane following the lower profile of the wall of the furnace (1 ) in such a way that the coils (1 9) of the detection system are arranged on the deposition surface according to a configuration such as to have an approximately constant distance between the detection system (3) and the furnace (1 ) in correspondence of the measuring area corresponding to the deposition surface of the coils (1 9) of the detection system.
  • Maxwell's equations for the electromagnetic field, as it is known to a person skilled in the art.
  • “s” represents the electrical conductivity or the spatial distribution of electrical conductivity, which is the final physical quantity that one wishes to obtain for detecting the melting state of the metal materials (5, 36) inside a melting furnace (1 ).
  • “y” represents the measure actually obtained from the detection system (3), that is to say, for example, amplitude and phase values of the signal induced onto the coils (1 9, 1 9’, 1 9”, 1 9n) of the detection system.
  • “F” represents the functional, that is to say, the created electromagnetic model, which links to each other “s”, i. e. electrical conductivity or spatial distribution of electrical conductivity, and“y”, i. e. the measure actually obtained from the detection system (3).
  • FEM finite element methods
  • the sensitivity or Jacobian matrix J can be calculated beforehand solving the direct model.
  • the variables ds and dy represent the variations in electrical conductivity and the variations in the measures acquired by means of the coils (1 9, 1 9', 1 9", 1 9n) of the detection system, respectively.
  • the deposition surface (44) can be made up of deposition planes arranged after one another, wherein each plane is inclined with respect to the following one by an angle between 1 60° and 1 80° or can be an arched surface such as an arched surface in which the ratio between the bending radius and the length of the arc constituting the deposition surface (44) is between 1 .5 and 2.1 or, in general, an arched surface that follows the bottom of the furnace (1 ) in correspondence of which it is installed, i. e. having a bending corresponding to the bending of the lower part of the furnace (1 ).
  • the present invention also relates to a detection and stirring system (20) comprising a detection system (3) for detecting a melting state of metal materials inside a melting furnace (1 ) and an electromagnetic stirrer (2) for the electromagnetic stirring of the metal materials inside the furnace (1 ), wherein the electromagnetic stirrer (2) comprises at least one respective series of coils (1 8) of the stirrer in which each of the coils (1 8) of the stirrer consists of one or more windings closed in a loop configuration on a respective winding surface, wherein the detection system (3) comprises at least one series of coils (1 9, 1 9', 1 9"), the series of coils (1 9, 1 9', 1 9") comprising at least one first coil (1 9') configured as a transmission coil and at least one second coil (1 9") configured as a reception coil, the first coil (1 9') being connected to a transmission system (24) of a sinusoidal signal for driving at least one first coil (1 9') for the generation of a measuring field (22) for the interaction with the metal materials inside the furnace (1 ), the at least
  • the present invention relates to a detection method of a melting condition of metal materials for detecting the melting state of the metal materials inside a melting furnace (1 ), wherein the method provides the following phases:
  • the detection system (3) comprises at least one series of coils (1 9, 1 9', 1 9") in which each of the coils (1 9, 1 9', 1 9") consists of one or more windings closed in a loop configuration on a winding plane (45), the series of coils (1 9, 1 9', 1 9") comprising at least one first coil (1 9') configured as a transmission coil and at least one second coil (1 9") configured as a reception coil;
  • the phase of generation of the measuring field (22) is a phase of generation of an electromagnetic field in a measuring zone that is subject to the measuring field (22) and that is arranged parallel to a deposition surface (44) of the series of coils (1 9, 1 9', 1 9") on which both the at least one transmission coil and the at least one reception coil are arranged, the phase of generation of the measuring field (22) comprising a phase of penetration of the measuring field (22) up to the measuring zone subject to the measuring field (22) which is orthogonally spaced from the deposition surface (44) in such a way that the measuring field (22) penetrates up to the metal materials inside the melting furnace (1 ), the phase of reception being a phase of reception of the generated reception signal as resulting from eddy currents induced by the measuring field (22) on the metal materials inside the furnace ( 1 ), which occurs by means of the reception coil that is arranged on the same deposition surface (44) as the transmission coil in which the winding plane (45) is parallel to the deposition surface (44), the coils (1 9, 1 9', 1 9
  • the detection method can have a switching phase that is a phase of sequential switching of the connection of the transmission system (24) between adjacent coils of the series of coils ( ⁇ 9, 1 9', 1 9") and correspondingly for the sequential switching of the connection of the reception system (25) among coils of the series of coils (1 9, 1 9', 1 9") with the exclusion of the transmission coil.
  • the switching phase can comprise a subphase of switching between the two series of coils (1 9, 1 9', 1 9") of the detection system arranged on two parallel rows of coils (1 9) of the detection system.
  • the calculation phase of electrical conductivity or resistivity values of the metal materials inside the furnace (1 ) can be carried out by means of a tomographic calculation method in which there is a processing phase of the electrical conductivity or resistivity values of the metal materials inside the furnace (1 ) in such a way as to output a two-dimensional or three-dimensional map of the measured conductivity or resistivity of the material contained inside the furnace (1 ) and consisting of the set of metal in the molten state (5) and metal materials not yet molten (36).
  • the tomographic calculation method can comprise the following phases:
  • the detection method for detecting a melting condition of metal materials inside a melting furnace (1 ) and for electromagnetic stirring can also comprise calculation phases of power and frequency for starting the stirrer (2) for the application of new power and frequency values for starting the stirrer (2) in said phases of re-starting of the electromagnetic stirrer (2).
  • the present invention also relates to a melting furnace (1 ) for melting metal materials that comprises an electromagnetic stirrer (2) for the electromagnetic stirring of the metal materials inside the furnace (1 ), wherein the furnace comprises a detection and stirring system (20) as previously described.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Waste-Gas Treatment And Other Accessory Devices For Furnaces (AREA)
PCT/EP2019/000227 2018-07-27 2019-07-24 Detection system, method for detecting of a melting condition of metal materials inside a furnace and for electromagnetic stirring, and furnace provided with such systems WO2020020478A1 (en)

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IT102018000007563A IT201800007563A1 (it) 2018-07-27 2018-07-27 Sistema e metodo di rilevamento di condizione di fusione di materiali metallici entro un forno, sistema e metodo di rilevamento di condizione di fusione di materiali metallici e agitazione elettromagnetica, e forno dotato di tali sistemi
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WO2022028728A1 (en) 2020-08-04 2022-02-10 Ergolines Lab S.R.L. Agitation device and method for melting furnace and melting furnace
IT202000026807A1 (it) * 2020-11-11 2022-05-11 Ergolines Lab S R L Metodo di controllo di dispositivo di agitazione e dispositivo di agitazione
CN117906404A (zh) * 2024-03-19 2024-04-19 湖南科瑞变流电气股份有限公司 电弧炉及其整流器的控制方法、系统、装置及存储介质

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WO2011136729A1 (en) 2010-04-30 2011-11-03 Agellis Group Ab Measurements in metallurgical vessels
US20130269483A1 (en) 2010-09-14 2013-10-17 Jan-Erik Eriksson Apparatus And Method For Electromagnetic Stirring In An Electrical Arc Furnace
US9599401B2 (en) 2013-04-16 2017-03-21 Abb Schweiz Ag Method and a control system for controlling a melting and refining process
WO2018096368A1 (en) 2016-11-26 2018-05-31 Altek Europe Limited Improvements in and relating to stirring of molten metals

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US6693950B2 (en) * 2001-05-22 2004-02-17 Inductotherm Corp. Furnace with bottom induction coil
WO2011136729A1 (en) 2010-04-30 2011-11-03 Agellis Group Ab Measurements in metallurgical vessels
US20130269483A1 (en) 2010-09-14 2013-10-17 Jan-Erik Eriksson Apparatus And Method For Electromagnetic Stirring In An Electrical Arc Furnace
US9599401B2 (en) 2013-04-16 2017-03-21 Abb Schweiz Ag Method and a control system for controlling a melting and refining process
WO2018096368A1 (en) 2016-11-26 2018-05-31 Altek Europe Limited Improvements in and relating to stirring of molten metals

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2022028728A1 (en) 2020-08-04 2022-02-10 Ergolines Lab S.R.L. Agitation device and method for melting furnace and melting furnace
IT202000026807A1 (it) * 2020-11-11 2022-05-11 Ergolines Lab S R L Metodo di controllo di dispositivo di agitazione e dispositivo di agitazione
WO2022117219A1 (en) 2020-11-11 2022-06-09 Ergolines Lab S.R.L. Control method of stirring device and stirring device
CN117906404A (zh) * 2024-03-19 2024-04-19 湖南科瑞变流电气股份有限公司 电弧炉及其整流器的控制方法、系统、装置及存储介质
CN117906404B (zh) * 2024-03-19 2024-05-28 湖南科瑞变流电气股份有限公司 电弧炉及其整流器的控制方法、系统、装置及存储介质

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