AISIBy Jeremy A. T. Jones, Nupro Corporation.
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Courtesy of Mannesmann Demag Corp. FURNACE OPERATIONS The electric arc furnace operates as a batch melting process producing batches of molten steel known "heats". The electric arc furnace operating cycle is called the tap- to- tap cycle and is made up of the following operations: Modern operations aim for a tap- to- tap time of less than 6. Some twin shell furnace operations are achieving tap- to- tap times of 3. The first step in the production of any heat is to select the grade of steel to be made.
Usually a schedule is developed prior to each production shift. Thus the melter will know in advance the schedule for his shift. The scrap yard operator will prepare buckets of scrap according to the needs of the melter. Preparation of the charge bucket is an important operation, not only to ensure proper melt- in chemistry but also to ensure good melting conditions.
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The scrap must be layered in the bucket according to size and density to promote the rapid formation of a liquid pool of steel in the hearth while providing protection for the sidewalls and roof from electric arc radiation. Other considerations include minimization of scrap cave- ins which can break electrodes and ensuring that large heavy pieces of scrap do not lie directly in front of burner ports which would result in blow- back of the flame onto the water cooled panels.
The use of electric arc furnaces. process is an important source. Understanding Electric Arc Furnace Operations.
Iron and Steel - Electric Arc Furnace Steelmaking 10.1 This Section. by 6 companies, including Corus, using the electric arc furnace process route. Inerals processed via electric arc furnace. THE FUSION PROCESS Simply put, an electric arc furnace. Understanding the Benefits of Electric Arc.
Direct arc electric furnaces are very popular for the melting of. Electric Arc Furnace Process | Electric Arc Furnace Steel. electric arc furnace. Electric Arc Furnace Steelmaking. FURNACE OPERATIONS. The electric arc furnace operates as a batch melting process producing batches of molten steel. Electric arc furnaces are also used for production of calcium carbide. Electric arc furnace; Basic oxygen process; HIsarna process; Secondary. Study about the Process Control of an Electric Arc Furnace using Simulations based on an Adaptive Algorithm MANUELA PANOIU1, CAIUS PANOIU1, IOAN ŞORA2.
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Of electric arc furnaces, resulting in: Production efficiency. The electric arc process, during which the electrical energy for melting of the.
The charge can include lime and carbon or these can be injected into the furnace during the heat. Many operations add some lime and carbon in the scrap bucket and supplement this with injection. The first step in any tap- to- tap cycle is "charging" into the scrap. The roof and electrodes are raised and are swung to the side of the furnace to allow the scrap charging crane to move a full bucket of scrap into place over the furnace.
The bucket bottom is usually a clam shell design - i. The scrap falls into the furnace and the scrap crane removes the scrap bucket. The roof and electrodes swing back into place over the furnace. The roof is lowered and then the electrodes are lowered to strike an arc on the scrap.
This commences the melting portion of the cycle. The number of charge buckets of scrap required to produce a heat of steel is dependent primarily on the volume of the furnace and the scrap density. Most modern furnaces are designed to operate with a minimum of back- charges. This is advantageous because charging is a dead- time where the furnace does not have power on and therefore is not melting. Minimizing these dead- times helps to maximize the productivity of the furnace.
In addition, energy is lost every time the furnace roof is opened. This can amount to 1. Wh/ton for each occurrence. Most operations aim for 2 to 3 buckets of scrap per heat and will attempt to blend their scrap to meet this requirement.
Some operations achieve a single bucket charge. Continuous charging operations such as CONSTEEL and the Fuchs Shaft Furnace eliminate the charging cycle.
The melting period is the heart of EAF operations. The EAF has evolved into a highly efficient melting apparatus and modern designs are focused on maximizing the melting capacity of the EAF. Melting is accomplished by supplying energy to the furnace interior. This energy can be electrical or chemical.
Electrical energy is supplied via the graphite electrodes and is usually the largest contributor in melting operations. Initially, an intermediate voltage tap is selected until the electrodes bore into the scrap. Usually, light scrap is placed on top of the charge to accelerate bore- in. Approximately 1. 5 % of the scrap is melted during the initial bore- in period. After a few minutes, the electrodes will have penetrated the scrap sufficiently so that a long arc (high voltage) tap can be used without fear of radiation damage to the roof. The long arc maximizes the transfer of power to the scrap and a liquid pool of metal will form in the furnace hearth At the start of melting the arc is erratic and unstable.
Wide swings in current are observed accompanied by rapid movement of the electrodes. As the furnace atmosphere heats up the arc stabilizes and once the molten pool is formed, the arc becomes quite stable and the average power input increases. Chemical energy is be supplied via several sources including oxy- fuel burners and oxygen lances. Oxy- fuel burners burn natural gas using oxygen or a blend of oxygen and air.
Heat is transferred to the scrap by flame radiation and convection by the hot products of combustion. Heat is transferred within the scrap by conduction. Large pieces of scrap take longer to melt into the bath than smaller pieces.
In some operations, oxygen is injected via a consumable pipe lance to "cut" the scrap. The oxygen reacts with the hot scrap and burns iron to produce intense heat for cutting the scrap. Once a molten pool of steel is generated in the furnace, oxygen can be lanced directly into the bath. This oxygen will react with several components in the bath including, aluminum, silicon, manganese, phosphorus, carbon and iron. All of these reactions are exothermic (i. The metallic oxides that are formed will end up in the slag. The reaction of oxygen with carbon in the bath produces carbon monoxide, which either burns in the furnace if there is sufficient oxygen, and/or is exhausted through the direct evacuation system where it is burned and conveyed to the pollution control system.
Auxiliary fuel operations are discussed in more detail in the section on EAF operations. Once enough scrap has been melted to accommodate the second charge, the charging process is repeated.
Once the final scrap charge is melted, the furnace sidewalls are exposed to intense radiation from the arc. As a result, the voltage must be reduced. Alternatively, creation of a foamy slag will allow the arc to be buried and will protect the furnace shell. In addition, a greater amount of energy will be retained in the slag and is transferred to the bath resulting in greater energy efficiency. Once the final scrap charge is fully melted, flat bath conditions are reached. At this point, a bath temperature and sample will be taken. The analysis of the bath chemistry will allow the melter to determine the amount of oxygen to be blown during refining.
At this point, the melter can also start to arrange for the bulk tap alloy additions to be made. These quantities are finalized after the refining period. Refining operations in the electric arc furnace have traditionally involved the removal of phosphorus, sulfur, aluminum, silicon, manganese and carbon from the steel. In recent times, dissolved gases, especially hydrogen and nitrogen, been recognized as a concern. Traditionally, refining operations were carried out following meltdown i.
These refining reactions are all dependent on the availability of oxygen. Oxygen was lanced at the end of meltdown to lower the bath carbon content to the desired level for tapping.
Most of the compounds which are to be removed during refining have a higher affinity for oxygen that the carbon. Thus the oxygen will preferentially react with these elements to form oxides which float out of the steel and into the slag. In modern EAF operations, especially those operating with a "hot heel" of molten steel and slag retained from the prior heat, oxygen may be blown into the bath throughout most of the heat. As a result, some of the melting and refining operations occur simultaneously. Phosphorus and sulfur occur normally in the furnace charge in higher concentrations than are generally permitted in steel and must be removed. Unfortunately the conditions favorable for removing phosphorus are the opposite of those promoting the removal of sulfur. Therefore once these materials are pushed into the slag phase they may revert back into the steel.
Phosphorus retention in the slag is a function of the bath temperature, the slag basicity and Fe. O levels in the slag. At higher temperature or low Fe. O levels, the phosphorus will revert from the slag back into the bath. Phosphorus removal is usually carried out as early as possible in the heat.
Hot heel practice is very beneficial for phosphorus removal because oxygen can be lanced into the bath while its temperature is quite low. Early in the heat the slag will contain high Fe. O levels carried over from the previous heat thus aiding in phosphorus removal.
High slag basicity (i. This will lead to an increase in slag viscosity, which will make the slag less effective. Sometimes fluorspar is added to help fluidize the slag.
Stirring the bath with inert gas is also beneficial because it renews the slag/metal interface thus improving the reaction kinetics. In general, if low phosphorus levels are a requirement for a particular steel grade, the scrap is selected to give a low level at melt- in. The partition of phosphorus in the slag to phosphorus in the bath ranges from 5 to 1. Usually the phosphorus is reduced by 2. EAF. Sulfur is removed mainly as a sulfide dissolved in the slag.
The sulfur partition between the slag and metal is dependent on slag chemistry and is favored at low steel oxidation levels. Removal of sulfur in the EAF is difficult especially given modern practices where the oxidation level of the bath is quite high. Generally the partition ratio is between 3 and 5 for EAF operations.
Most operations find it more effective to carry out desulfurization during the reducing phase of steelmaking. This means that desulfurization is performed during tapping (where a calcium aluminate slag is built) and during ladle furnace operations. For reducing conditions where the bath has a much lower oxygen activity, distribution ratios for sulfur of between 2. Control of the metallic constituents in the bath is important as it determines the properties of the final product. Usually, the melter will aim at lower levels in the bath than are specified for the final product.
Oxygen reacts with aluminum, silicon and manganese to form metallic oxides, which are slag components.