System And Method For Determining Temperature Of A Metal Melt In An Electric Arc Furnace

Abstract

A system and a method for determining/predicting a tapping time for a metal melt in an electric arc furnace (EAF), at least one electrode is provided for melting the metal melt until it reach a target tapping temperature, the EAF further includes a slag and smoke layer on the surface of the metal melt, wherein an electromagnetic stirrer is provided for stirring the metal melt.

Claims

1. A method for determining/predicting a tapping time for a metal melt in an electric arc furnace (EAF), wherein at least one electrode is provided for melting the metal melt until it reach a target tapping temperature, wherein the EAF further comprises a slag and smoke layer on the surface of the metal melt, wherein an electromagnetic stirrer is provided for stirring the metal melt, the method comprising a) supplying a power to the electrode in order to melt a scrap to a metal melt, b) electromagnetic stirring the metal melt in the EAF, c) arranging a lance unit dedicatedly configured to including an inert gas, d) blowing away the slag and smoke from the surface of the metal melt by the dedicatedly arranged lance unit, e) non-contactingly measuring a temperature of the metal melt, f) receiving the measured temperature, g) calculating a temperature profile based on the received temperature, h) estimating/predicting a tapping temperature at a time point based on the calculated temperature profile, and i) determining a tapping time based on the estimated temperature, the target tapping temperature and the power supplied to the electrode.

2. The method according to claim 1, comprising j) re-calculating/adjusting the temperature profile upon receiving a new measured temperature, k) estimating/predicting a tapping temperature at a time point based on the re-calculated/adjusted temperature profile, and l) determining a tapping time based on the estimated temperature, the target tapping temperature and the power supplied to the electrode.

3. A system for determining/predicting a tapping time of a metal melt in an electric arc furnace comprising an electromagnetic stirrer provided for stirring the metal melt, a temperature measuring device for providing temperature measurements of the metal melt and a temperature control unit, wherein the electric arc furnace includes at least one electrode connected to a power supply, wherein temperature control unit is configured to control the metal melt temperature based on the power supplied to the electrode, wherein the temperature measuring device comprises a non-contact sensing unit and a processing unit connected to the sensing unit, wherein the sensing unit is configured to sense/measure the temperature of the metal melt and to send the measured temperature to the processing unit, and the processing unit is configured to receive the measured temperature and to process the received temperature, characterized in that the temperature measuring device comprises a dedicated lance unit including an inert gas provided to blow away slag and smoke layers on surface of the metal melt, wherein the processing unit is further configured to send the processed measured temperature to the temperature control unit and the temperature control unit configured to perform steps f)-i) of claim 1.

4. The system according to claim 3, wherein the temperature control unit is further configured to re-calculate the temperature profile based on a new temperature measurement.

5. The system according to claim 3, wherein the sensing unit comprises a non-contact sensor in form of microwave radiometer, infrared sensor or fibred optic sensor.

6. The system according to claim 3, wherein the temperature measuring device is arranged to measure temperature of the metal melt continuously or at discrete time points.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0022] The invention will now be explained more closely by the description of different embodiments of the invention and with reference to the appended figures.

[0023] FIG. 1a shows a flowchart of controlling a tapping temperature, according to one embodiment of the invention.

[0024] FIG. 1b shows a flowchart of controlling a tapping temperature, according to another embodiment of the invention.

[0025] FIG. 2 illustrates a system schematic chart of a system for controlling a tapping temperature of a metal melt in an EAF, according to a third embodiment of the invention.

[0026] FIG. 3 illustrates a tapping temperature estimation of the embodiments of FIGS. 1a-1b and FIG. 2.

DETAILED DESCRIPTION

[0027] FIG. 2 illustrates a system 1 for determining/predicting a tapping time of metal melt in an electric arc furnace (EAF) 20 comprising an electromagnetic stirring system (EMS) 30 with an electromagnetic stirrer provided for stirring the metal melt, a temperature measuring device 40 for providing a temperature measurements of the metal melt, and a temperature control unit 50 for estimating/predicting the temperature of the metal melt.

[0028] The EAF 20 is arranged for melting metallic materials, for example metals or metal alloys. The EAF may be a DC EAF or an AC EAF.

[0029] The EAF 20 further comprises one or more electrodes 22 (This example shows three electrodes equipped with the EAF), a vessel 24 covered with a retractable roof (not shown in FIG. 2) through which the electrodes enter the furnace and a power supply system 26 operatively connected to the electrodes 22 for supplying a power to the electrodes in order to melt a scrap to a metal melt, step S10 with reference to FIG. 1.

[0030] The EAF operation starts with the vessel 24 being charged with scrap metal, wherein the meltdown commences. The electrodes 22 are lowered onto the scrap and an arc is struck thereby starting to melt the scrap. Lower voltages are selected for this first part of the operation to protect the roof and walls of the furnace from excessive heat and damage from the arcs. Once the electrodes 22 have reached the heavy melt at the base of the furnace 24 and the arcs are shielded by slag, the voltage can be increased and the electrodes are raised slightly, thereby lengthening the arcs and increasing power to the melt. As the scrap is melt into a metal melt 21, a slag layer 23 is formed on the surface of the melt 21. Moreover, a smoke layer 23′ may be formed above the slag layer.

[0031] The EMS 30 is mounted on an outer surface, preferably the bottom of the EAF vessel 24. The EMS system 30 includes at least one electromagnetic sitter arranged to stir a metal melt in the EAF, step S20. With the electromagnetic stirring, the melting rate in the vessel 24 is accelerated and the melt temperature becomes more homogeneous. The homogeneous temperature is particularly important for a modern EAF that has a big vessel with a diameter up to 8 meters to decrease local variations of the melt temperature. Thus, the local variations of the melt temperature is decreased tremendously comparing with no stirring and consequently, the temperature of the melt is uniform.

[0032] Due to smoke and harsh environment of production sites, it is difficult to measure the temperature of a melt. One way to measure a melt temperature is to use disposable temperature probes or cartridges. A probe or cartridge is thrown into the melt at end of the refining process. If not a sufficient temperature is obtained a further probe is placed until a correct or close enough temperature is obtained. Thus, to measure the melt temperature, an operator may have to repeat this tasks several times. If the obtained melt temperature is above the target tapping temperature, a large amount of arc power/energy has been already wasted. Therefore, it is advantageous that melt temperatures can be measured continuously or at a sufficiently high sampling rate to prevent the melt from a late tapping.

[0033] To this end, the temperature measuring device 40 is arranged to measure melt temperature. The temperature measuring device 40 comprises a non-contact sensing unit 42 and a processing unit 44 connected to the sensing unit 42. The sensing unit 42 is configured to sense/measure the temperature of the metal melt and to send the measured temperature to the processing unit 44, step S40. While the processing unit 44 is configured to receive the measured temperature, to process the received temperature and to send the processed measured temperature to the temperature control unit 50. The temperature measuring device 40 further comprises a dedicated lance unit 46 that may be mounted on a side wall of the EAF. A non-contact sensing unit includes a non-contact sensor. Essentially, any kind of non-contact sensors may be used for measuring the temperature of the melt. In this example, an optic fiber is used and is mounted inside a metal tube. The metal tube is further mounted inside the lance unit. This arrangement may measure a high temperature over 2000° C. For cooling the optic sensor, a cooling media is arranged outside of the metal tube.

[0034] However, the slag and smoke layers 23′, 23 formed on the surface of the metal melt in the vessel 24 prevents the non-contact sensing unit 42 from accurately measuring. The lance unit 46 is therefore provided and configured to inject an inert gas to the melt surface. The inert gas is injected with a high pressure to blow away the slag and smoke layers 23′, 23, which drills a hole through the smoke and the slag layers 23′, 23 so that the optical sensor can measure the temperature with a slag and smoke-free melt surface, step S30. The measured temperature will be further sent to the processing unit 44 in which the measured signal is analyzed and processed, S40.

[0035] The measured temperatures are transferred through the optic fiber to the processing unit 44 that may include, for example, a spectrometer. Spectrums are processed analyzed and thereafter to input to the temperature control unit 50, step S50.

[0036] The temperature control unit 50 is provided with an EAF melt temperature prediction model that is built in for calculating a melt temperature profile in order to estimate/predict a melt temperature at a time point, step S60 and S70. The profile is calculated based on the processed temperature measurements T.sub.m and power P supplied to the electrodes. There are many well-known control models that can be used for this purpose. For the present invention, an extended Kalman filter is applied for the estimation prediction of the tapping time. The temperature profile is further adjusted upon receiving a new measured temperature to achieve a more accurate temperature estimation, step S60′ and S70′. With the adjusted temperature profile, a time to reach a pre-defined tapping temperature can be predicted and a tapping time therefore is determined, step S80.

[0037] Besides the advantages mentioned above, further advantages of using non-contact sensing unit are that wide range of wavelengths can be covered and measurement area or points can be well defined, for example a number of measuring points can be defined for a sensor. Moreover, other physical properties can be sensed as well.

[0038] FIG. 3 shows that a temperature profile is continuously adjusted based on measured temperatures. Based on the profile, the tapping temperature is predicted accordingly and thus a tapping time as well.

[0039] The temperature control unit 50 may comprise hardware, a memory unit, at least a processing unit into which software is loaded.

[0040] Using non-contact sensors enables a tapping just in time and thus increases productivity and saves large amount energy of arc power.

[0041] It should be understood that the scope of the invention must not be limited the presented embodiments, it shall cover other embodiments that are obvious to a person skilled in the art.