Method of obtaining blister copper from copper ore

专利摘要:
A method of producing black copper from copper ore containing antimony impurities, including melting the raw material in a rotary converter with top blasting to form matte and slag, separating 1 matte and slag, and converting matte, characterized in that, in order to reduce the content of matte and slag, and in order to reduce matte, in order to reduce the content of antimony, slag processing ores with its higher content, matte immediately after slag separation is treated with an inert gas. SP
公开号:SU1128844A3
申请号:SU792817353
申请日:1979-09-20
公开日:1984-12-07
发明作者:Арвид Петерссон Стиг；Суне Эрикссон Бенгт；Кристер Фридфелдт Арне
申请人:Болиден Актиеболаг (Фирма)；
IPC主号:

专利说明:

The invention relates to a method for producing blister copper from copper ore containing antimony, and can be used in non-ferrous metallurgy.
Usually blister copper is produced from sulphide copper ore, which most often contains iron. In most of the processes used, the ore is first partially fired, and the calcined product is melted to form Kupferstein. The molten Kupferstein is then transformed into blister copper, introducing into it an oxygen-containing gas, usually air, and simultaneously removing slag iron oxides by adding silica, for example sand. In the partial calcination process, when the sulphide ore is heated, the oxide contains sulfur: sulfur and oxygen is supplied, the sulfur content in the calcined ore is adjusted so that its quantity is sufficient to form a cup-type copper having a predetermined copper content corresponding to subsequent smelting. The cupferstein obtained in this way usually contains 30–40% copper and 22–26% sulfur. The chemical composition of such a kupferstein usually varies depending on the composition of the ore and the degree of roasting. These figures reflect the data on cupferstein derived from the most frequently used ore.
Upon melting of the burned ore, in addition to the cupferstein, iron-containing slag is formed, which is given the desired composition by adding sand (SiOy) and in some cases small amounts of limestone, due to which the slag acquires a low viscosity, which usually contains 0.40, 8% copper, is drained and sent to the dump, i.e. placed in any suitable place. In some cases, the slag also contains significant amounts of valuable materials, such as zinc, etc., which, if desired, can be mined out of it by burning shiak with waste gases.
 Typically, when melting, the copper content in the cupsupply is regulated in the range of 30-40%. Kupferstein with a higher copper content than 3040% gives slag in which too much copper is contained, and its loss becomes very susceptible.
Various furnaces have been proposed for smelting copper ore. Usually, their design is such that copper ore should be continuously fed into the furnace along with slag-forming additives. The resulting slag and kupferstea are continuously or periodically drained.
The most commonly used type of melting furnace is a reflective furnace, which contains a long, narrow chamber with a rectangular bottom, heated by oil or gas burners. In the combustion process, air is supplied in a pure form or enriched with oxygen. For economic reasons and because of the need to protect the environment, such reflective furnaces are increasingly being replaced by other types of melting furnaces, since it has proven to be very difficult to process the exhaust gases of these furnaces containing sulfur dioxide formed during the smelting process. It is known that reflective furnaces form a large amount of such gases, which makes it necessary to build large and expensive purification devices. One way to avoid these problems is by melting the ore with electricity.
Electric melting furnace. usually has a long and narrow chamber with a rectangular bottom and submersible electrodes in the melt. The energy required for the production process is provided by the heating resistance. Such electric furnaces represent a significant step forward in this field of technology, since they provide the opportunity for a more complete cleaning and use of the gases generated during smelting, partly because the furnace can operate with controlled discharge, in which uncontrolled emissions can be avoided. to the atmosphere, which is important from the point of view of environmental protection, and partly due to the fact that the volume of the gas produced is less than in a reflective furnace, therefore gas cleaning devices can be used smaller size.
However, for electric melting to be economical, it is necessary to have a cheap source of electrical energy. These methods of melting provide cupranstein with a copper content of 30-40% and ai: aka, containing 0.4-0.8% of copper and usually sent to the dump. However, in some cases it is required to obtain a kupferstein with a maximum copper content in the process of dosing, for example with a content of 60-77%, preferably 65-75%, although most often this is uneconomical if you use known melting methods. the amount of copper is lost in the slag. When refining matte with low copper content in a cylindrical converter with intermittent or continuous FISH loading, a large amount of slag containing 4-8% of copper is formed, which needs to be re-melted or cooled, and then subjected to grinding and flotation to extract copper. The cost of these operations is significant. It was established that if the copper content in the matte exceeds 40% in the smelting process, the amount of copper in the pshak increases so that its loss leads to a sharp decrease in the cost-effectiveness of the process. Another disadvantage of these smelting methods is that the ore must be subjected to roasting or sintering before being fed into the furnace. Recently, new smelting furnaces have been developed in which copper can be directly smelted into concentrates and the heat required for the process to flow is provided by burning sulfur present in the ore. This is called autogenous fusion. An example of such furnaces is the so-called suspended-melting furnace, which contains a vertical reaction shaft 45, a horizontal settling section for the melt and a section for exhaust gases. Copper concentrates are loaded into the reaction center from above and heated air is supplied. An exothermic reaction takes place in the mine between the air supplied to the furnace and the sulfur contained in the copper concentrates, as a result of which the particles reaching the melting point are lowered into the settling section, where they form a molten bath containing matte and slag. In such furnaces, slag is 44. 4 is usually lowered continuously, while Kupferstein is periodically drained. The amount of copper in the matte is controlled by controlling the amount of oxygen supplied to the furnace, which is usually about 60% and the slag contains 0.8-2.0% copper. When the amount of copper in pshak is so large, for economic reasons, the slag can be subjected to refining, performed in a separate furnace, in which the copper content in the slag is reduced to 0.4-0.8%. Furnaces of this type can be of two types: the Otokumpu furnace and the INCO furnace. The main difference between the two is that the Otukumpu furnaces, when the ore is melted in the mine, use heated air, and the INCO furnaces operate on air enriched with oxygen, and do not use the mine for suspension. Another disadvantage of smelting furnaces in a suspended state is, besides a too high copper content in the slag, that such furnaces cannot be used to melt scrap and / or oxidized materials. Kupferstein, obtained in accordance with these methods, is transferred to a copper converter, in which the residual sulfur is oxidized by feeding air or oxygen-containing gas into the matte, due to which black copper and sulfur dioxide are formed. There is a method according to which blister copper is produced by melting sulphide copper ore in an inclined rotary kiln in the presence of oxygen and slag-forming materials, and turning matte into blister copper, while melting is carried out by simultaneously feeding ore, slag-forming materials and rotary inclined furnace oxygen and stop the supply of oxygen when not less than 75% of copper ore is loaded into the furnace, after which the melt is treated with a reducing agent. Thereafter, the melt is transferred in portions to a temperature oven, in which matte is separated from the slag formed, after which the slag is acidified and drained, and matte is transferred to the appropriate converter.
Preferably, a rotary kiln with an inclined axis of rotation is used as melting equipment in this method. An example of such a furnace is the Kal-Do Converter, which is also called the top-blown converter. The converter is rotated at such a rate that the material is taken out of the bath by the rotating wall of the converter and transferred to the lower part of the bath, thereby creating a particularly effective contact between the bath and the gas phase existing above it. This ensures a rapid course of reactions and rapid equilibrium between different parts of the bath. .
Such a converter contains a cylindrical part and a top conic part. The converter is lined with refractory material and has the means to bring it into rotation with a speed of, for example, 10-60 rpm, which can be made in the form of a friction or gear wheel with a corresponding drive. Means are also available for tilting the converter and means for rotating it, allowing the melt to drain.
According to this method, the Kupferstein is transferred to a conventional converter, for example, into a cylindrical or, if necessary, into a Kal-Do converter. The question of which type of converter should be used depends on the composition of the matte, i.e. from the content of copper in it and from the amount of impurities. In most cases, Kupferstein contains impurities J which are difficult to remove using conventional transformation processes in cylindrical converters and which are substances whose presence in blister copper is undesirable.
Among such hard-to-remove impurities are antimony, blend, vismfg, and tin; therefore, they are always present in limited quantities in the cupferstein processed by conventional methods. The known pyrometallurgical processes for removing such impurities from blister copper are inefficient or excessively expensive.
The known method involves melting and converting materials containing copper, nickel, lead and antimony into corresponding metals in rotary kilns. In such furnaces, working gas with controlled temperature and adjustable oxygen content is fed from the top through downhill tuyeres, which are supplied to the melt surface and through it. By rotating such furnaces, they provide vigorous mixing, creating the necessary gas, solid particles and melt in the furnace, which leads to the removal of iron, sulfur and other impurities, such as antimony and carbon dioxide. Using the principle of a turbulent bath increases the heat transfer rate and chemical reactions, going through the kiln, resulting in a significant decrease in diffusion barriers between the slag and the sulphide phase.
In order to remove such impurities from copper-nickel sulphide fannage in a top blown converter, for example, in a Cal-Do converter, the surface is blown with a neutral or slightly oxidized gas, creating a suitable atmosphere above the bath surface, in which the impurity in the bath is partially evaporated. It is recommended to use a temperature range of 1300-1500 ° C and an atmosphere that is neutral with respect to copper sulfide. It is also proposed to treat the blister copper with vacuum, which helps to remove these impurities. In addition, it is indicated that the iron present in the sulfide bath must be oxidized before the impurities are evaporated. Regarding impurities, it is said that it is particularly difficult to remove antimony from the metal phase by evaporation from the sulfide phase or by subsequent oxidation and evaporation from the metal phase. It has been proposed to remove antimony, transfer it to the metal phase, which is formed during the oxidation of a small part of the copper-nickel sulphide melt, after which the said metal phase containing antimony is removed from the bath and treated separately. The process is repeated until the antimony content in the copper sulphide melt reaches an acceptable level.
The operations of this method can be better understood by referring to examples of its implementation. There go71
It is assumed that first, for example, the surface of the cupferstein is blown with oxygen for 0.5-1 hours, after which the partially oxidized matte thus obtained is flushed with nitrogen for 2 hours and then with oxygen for 1 hour to obtain the metallic phase, and then some more time to get a new metallic phase. The metal phases thus formed, containing a large amount of antimony and other valuable metals, are removed from the furnace for separate processing pj
This method is too complicated and expensive, as it requires separate processing of some products.
Furthermore, the method is completely unsatisfactory with respect to the processing of a matte with a high content of antimony, since too large quantities of the metal phase have to be subjected to a separate treatment in order to extract antimony from it.
. The offer is to process a kupferstein with bismuth content (about 0.2%) in inclined rotary converters, in which 60-70% blowing of inert gas is used to evaporate bismuth from a kupferstein with a copper content of 60–70%. 0.04%.
The disadvantages of this method are the length of the conversion process and the high cost due to high fuel consumption, as well as the wear of the converter lining. In order to reduce the bismuth content by 75%, when conducting a bismuth removal operation, approximately 2000 m of gas per ton of matte is consumed. No data are given on the removal of other impurities, such as antimony. In addition, nothing is said about at what stage of the copper production process the removal of the bismus is carried out.
There is a known method for removing antimony piermetallurgical treatment of a copper melt containing more than 0.1% antimony. In this case, the material containing antimony is melted in an inclined rotating converter with topically with iron-containing slag in such quantities that the iron content is not less than 44 times.
88448
exceeded the antimony content, and that a certain amount of antimony passed through the slag phase, after which the melted matte thus obtained was converted by blowing oxygen through it into a matte with a copper content of 72-78% and with a reduced antimony content z1.
In practice, the known method can
0 be used only in the processing of material with a relatively low content of antimony and a relatively high iron content. The method also creates an unnecessary ball5 in the furnace in the form of an additional amount of speck.
Methods for removing antimony are also known, all of which, without exception, are limited by the presence of its small
0 quantities in the starting material.
Many copper ores have a relatively high content of antimony, the removal of which by known methods represents considerable difficulty. In the electrolytic refining of copper, which currently represents the end operation of the copper production process for electrical circuits, so-called electrolytic copper, the amount of antimony in the initial product, anodic copper should not exceed 400 g / t, if normal flow is required electrolytic process.
five
It has been found that in dp maintaining the required level of raw materials, the amount of antimony in matte containing 40% copper should not exceed 0.15% if the matte conversion is carried out in a cylindrical converter. If the copper content is 45%, the antimony content should not exceed 0.13%. It means,
5 that, when carrying out the usual copper production processes, the antimony content in the initial material should not exceed 0.1-0.3%, depending on the copper content in the matte.
0 It is doubtful that a material containing more than 0.2% antimony can be processed in a known manner with. satisfactory economic indicators. When purging such
5 matte in the bulk converter, the content of antimony is reduced to about 0.08% in the resulting sulpha-copper melt (a matte with a copper content of 72-78%). At this level of impurity content, the antimony content in the rough or anodic copper subjected to treatment in the converter is less than 400 g / t (i.e., 0.04%), which is quite acceptable for electrolysis. As mentioned, dp of removing antimony from cupferstein, copper sulphide and / or blister copper melt various pyrometallurgical processes have been used. Their efficiency is very low or economically such methods turned out to be unjustified, therefore, to date, there is no technologically and economically acceptable process for reducing the content of antimony in black copper to a level of 0.04% or less. A common method of reducing the content of antimony in blister copper is to treat it after purging with sodium carbonate, which forms a slag that takes away a small amount from the area. The so-called sodium carbonate refining process is usually used only in cases where too much antimony is present. The cost of reagents is quite high; in addition, carbonate. The material causes significant wear to the converter lining and an increase in the amount of copper in the slag. To ensure a low content of antimony, it is necessary to mix with an antimony-containing copper ore a significant amount of copper melt containing almost no antimony, which leads to the need for frequent sampling and control of the melt introduced, and also limits the choice of copper ores. As a result, huge amounts of antimony-rich copper ore are essentially not used. The aim of the invention is to reduce the antimony content in the processing of ores with its higher content. The aim is achieved by the fact that according to the method for producing blister copper from copper ore, containing an admixture of antimony, including the smelting of the source material in a rotary converter with top blasting with the formation of matte and slag, slag removal and matte and matte conversion immediately after the removal410 no slag is treated with inert gas. According to the invention, after the slag is removed from the matte, prior to the transformation of the matte into blister copper, it is brought into contact with an inert gas with vigorous stirring, and the amount of gas is taken sufficient to reduce the antimony content by evaporation and other impurities, such as bismuth. Slurry and zinc, to a level acceptable for the subsequent purge process, at which the desired rough copper is formed. The implementation of the proposed method can be carried out in furnaces in which the mixing of blister copper can be carried out mechanically, pneumatically or electromagnetic, although certain advantages can be obtained when performing mixing by rotating the kupfershteyn in a rotating Kal-Do converter. The rotation of the cupferstein is sufficiently achieved at the speed of rotation of the furnace, at which the circumferential speed of the inner cylindrical wall of the furnace is about 0.5-7 m / s, preferably 2-5 m / s. To obtain such peripheral speeds, the furnace must rotate at a speed of 10-60 ~ 6. / MIN depending on its diameter. Large furnaces with a diameter of about five meters provide the necessary peripheral speed at rotational speeds of about 10 rpm, while small ones, whose diameter is less than 1 m, should be rotated at speeds of more than 40 rpm to provide intensive mixing and the necessary contact of the gas with the melt. The inert gas may contain some amount of fuel, substances, such as oil, oxygen or air enriched with oxygen. You can use a suitable oxygen-injected burner, which is easy to adjust and set to a given degree of combustion. The time period during which the indicated melt rotation is performed varies depending on the amount of impurities present that must be evaporated from the melt, although it may be affected by other factors. The possible 111 further decrease in the content of impurities in subsequent operations depends on the choice of the method of converting cupferstein to blister copper. Thus, the possibility of eliminating impurities is somewhat higher if the matte transformation is carried out in a Cal-Do converter than in a cylindrical converter. The degree of impurity reduction is influenced by economic considerations, for example, whether refining with sodium carbonate is carried out further or not. It is preferable, however, to continue the rotation of the melt during such a period of time, after which the antimony content does not exceed 0.04%, and the bismuth content is 0.03%. It is understood that during the rotation it is necessary to maintain a sufficiently high temperature in the furnace in order to ensure the evaporation of the impurities present, although due to the conditions created by this intensive mixing the temperature can be maintained somewhat lower than when using known methods, it is therefore preferable that The rotation temperature was maintained in the IZSO-OSO C range. In addition, no copper content in the matte interferes with the process, and therefore it is possible to have up to 80% copper, ho. As suggested in the known methods for removing impurities, in which matte processing with a copper content of more than 60% is not provided, antimony can be effectively removed with a copper content in matte up to 25%. Preferably, the copper content is 25-60%. Particularly preferred is a content in the range of about 30-40%. In some cases, during rotation, a slag former, such as sand, should be added to the kupferstein. The proposed method can also be used to process silver-bearing copper ore with a very high content of antimony and to produce black copper with a high silver content and low content of antimony .. Silver can be extracted from roughing with the help of pyrometallurgical or hydrometallic processes. copper. In order to optimize the evaporation of antimony 412, reducing the time required for evaporation and reducing fuel consumption, evaporation of antimony is carried out practically without matte oxidation: .If there is or ish, the required rotation time is increased, since a significant part of impurities is converted into the slag oxide phase, and this delays evaporation From the sulfide phase, obviously for thermodynamic reasons. Therefore, when implementing the proposed method, it is important during melting to carefully separate the spar from the melt before starting to rotate. Copper ore can be melted in most types of known smelting furnaces, for example, in electric furnaces or in furnaces for melting in a suspended state, but in most cases. It is preferable to melt the copper ore in portions directly in a Kal-Do converter, especially if the copper ore periodically decreases, thus greatly increasing the freedom in choosing the composition of the copper ore for processing. For example, if melting is carried out in a Cal-Do converter, copper concentrates with an antimony content of 10% or more can be used. Therefore, according to the invention. it is preferable to perform the rotation in a Kal-Do rotary converter which is suitable for smelting copper ore. The transformation process after rotation can be done in a similar way. For example, copper sulphide (matte with a content of 72-78% copper) can be purged in a separate device, for example in a Cal-Do converter, and final purging to produce blister copper can be performed in a cylindrical converter. In many cases, it is preferable to create a rotation in a rotary converter of the Kal-Do type used to convert cupferstein to blister copper. It may be an advantage to perform melting, rotating, and turning in a Kal-Do rotary converter. In this case, the same or different devices can be used for different process operations. The amount of gas required during the rotation operation is about 350-400 m / - of kupferstein, containing about 5% antimony or more to provide about 50% reduction in antimony content. During the evaporation operation, the antimony also vaporizes approximately 75% of the bismuth 60% zinc and 85% mouse present in the melt. To ensure that the antimony content is reduced by about 75%, about 600-650 m of gas per tonne of matte is required. When antimony is removed to such an extent, bismuth is about 100% elongated, zinc about 65%, and the mouse about 90%. These Amounts of gas can be compared with the amounts used to remove bismuth according to the method proposed in Australia, which requires about 2000 m of gas per ton of matte to remove 75% bismuth and about 7000 m for 90-95% removal. Thus, the proposed method provides significant fuel savings compared to the known method of bismuth evaporation. The invention is provided with references to preferred forms of its implementation, which from many points of view are suitable for processing complex copper ores. Mechanical stirring of the melt provides good mixing and good contact between the different phases of the melt and the reactants. The temperature and oxygen potential of the gas phase can be controlled by adding fuel. The process is periodic and can be divided into the following operands: autogenous melting to obtain Kupferstein removal of impurities by rotating the converter and setting a controlled atmosphere in it, turning matte into a melt, contents 72-78% copper transforming a melt containing 72-78% copper , to blister copper. If the process is conducted in a Kal-Do converter, melting and transformation of the material can be autogenous, since, if necessary, 100% oxygen can be blown into the converter. When melted, the dried concentrates, slag formers and return powder are pneumatically fed to the converter through tuyeres. A computer is used to estimate the loading speed, which also determines the oxygen concentration and the amount of air supplied to the furnace, which makes it possible to maintain the heat balance and a given amount of matte. Autogenous smelting takes place until the converter is filled to the required level. Then the slag is downloaded and transferred, for example, for subsequent processing in the corresponding furnace. When using complex copper ores, a significant amount of impurities is present, for example, bismuth, copper, antimony, zinc, and lead. The content of these substances in the matte is reduced during the operation in which the converter is rotated at a speed of, for example, approximately 30 rpm at an angle of inclination to the horizontal plane in the range of 15-25 degrees. At the same time, oil and air are blown into the converter. By controlling the supply of fuel and air in the converter, it is possible to set a predetermined temperature and control the oxygen potential of the gas so that impurities are largely evaporated. Thereafter, a transformation into a matte with a copper content of 72-75% and further into blister copper is carried out. The slag formers required to convert the bark is continuously fed to the furnace. The slag produced in the transformation operations is returned for addition during the subsequent melting. Example. The melting of multiple loads of complex copper concentrates is carried out in a Cal-Do converter with a capacity of 5 tons. With each load, 7 tons of copper concentrates are loaded into the converter, which melt at 1200-1300 0, after which the slag formed is downloaded. The melting rate, which provides for obtaining cupverstein with a copper content of about 40% from copper concentrates, containing approximately 22% copper, 30% iron and 34% sulfur, is maintained at about 5 tons / hour. The oxygen ratio is 95%. The content of impurities in the concentrates treated in the smelting process is,%: Antimony0.3-7 Mouse k0.2-2 Bismuth 0.1-0.3 Zinc 1-4 Lead 0.5-3 15, 1 According to their high pressure The vapor of mish k and bismuth was mainly dispersed into dust during the melting process, and antimony was uniformly distributed between the liquid phases, i.e. between slag and matte. The amounts of substances distributed in the formed phases are presented in Table. 1. Table 1 1 4416 The distribution of impurities during the subsequent transformations is given in Table. 3. Table 3

权利要求:
Claims (1)
[1]
METHOD FOR PRODUCING BLACK COPPER FROM COPPER ORE containing antimony impurities, including melting the starting material in a rotating converter with top blast to produce matte and slag, separating matte and slag and converting matte, characterized in that, in order to reduce the antimony content processing ores with its high content, matte immediately after separation of the slag is treated with an inert gas.
§
SU,. 1128844

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同族专利:

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GB2036085B|1982-05-06|

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FI782529A|1979-02-20|

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AU520763B2|1982-02-25|

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GB2036085A|1979-03-08|

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AU3880178A|1980-02-14|

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ZA784250B|1980-02-27|

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JPS5443122A|1979-04-05|

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NO153401C|1986-03-12|

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DE102014008987A1|2014-06-13|2015-12-17|Aurubis Ag|Process for the recovery of metals from secondary and other organic materials|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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SE7709355A|SE407424B|1977-08-19|1977-08-19|PROCEDURE FOR THE MANUFACTURE OF BLISTER COPPERS FROM ANTIMONOUS COPPER MATERIAL|

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