CA1045830A - Metallurgical process using oxygen - Google Patents
Metallurgical process using oxygenInfo
- Publication number
- CA1045830A CA1045830A CA297,210A CA297210A CA1045830A CA 1045830 A CA1045830 A CA 1045830A CA 297210 A CA297210 A CA 297210A CA 1045830 A CA1045830 A CA 1045830A
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- CA
- Canada
- Prior art keywords
- slag
- oxygen
- gas
- matte
- iron
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
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Classifications
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P10/00—Technologies related to metal processing
- Y02P10/20—Recycling
Abstract
Abstract of the Disclosure A process for treating liquid slag to recover non-ferrous metal sulfides. A bath of such liquid slag is estab-lished in a tiltable non-rotary sealed refractory-lined vessel.
A carbonaceous reducing agent, sulfur dioxide and oxygen are directed upwardly through the slag to create strong reducing conditions and controlled turbulence in the bath. Metal sulfides are formed and separated from said slag.
A carbonaceous reducing agent, sulfur dioxide and oxygen are directed upwardly through the slag to create strong reducing conditions and controlled turbulence in the bath. Metal sulfides are formed and separated from said slag.
Description
104583C~
This invention relates to a converting process for the extraction of heavy non-ferrous metals from their ores and to apparatus. This is a division of application Serial No. 195,116, filed March 15, 1974.
It has preferred reference to the continuous converting of copper, nickel,~cobalt or lead sulfides.
The continuous smelting and converting of sulfide minerals to matte or metal is an old concept well known in the art. As long ago as 1898, Garretson in U.S. Patent 596,992 disclosed a three zone smelting, converting and slag settling procedure. He teaches a method for the continuous production of non-ferrous metals from their sulfide ores comprising the steps of continuous smelting of the sulfides in a fuel burning furnace with a long narrow slightly sloped bottom; the resulting matte flows continuously to one or re separate, but communicating, converters in series at one end of the furnace, there the matte is progressively and continuously blown to metal which is with-` drawn, the resulting rich slag flows back continuously -countercurrently to the matte - through the smelting furnace, is improverished by contact with the low grade matte therein, flows into a separate but communicating, slag settling zone at the other end of the furnace, and is there subjected to the heating and reducing action of charcoal, matte settles out and flows back to the furnace and the cleaned slag is discharged.
The concept of the autogenous production of copper matte from sulfide minerals was disclosed in 1915 by Klepinger et al in U.S. Patent 1,164,653. He teaches the spraying of dry, finely divided copp;er sulfide concentrates with preheated air into a reverberatory-type furnace. The concept of slag cleaning by the washing and reducing action of iron sulfide was disclosed by Stout in U.S. Patents 1,416,262 (1922) and 1,544,048 (1925).
- He teaches progressive cleaning of molten copper-containing slags by their agitation and thorough mixing with pyrite, low
This invention relates to a converting process for the extraction of heavy non-ferrous metals from their ores and to apparatus. This is a division of application Serial No. 195,116, filed March 15, 1974.
It has preferred reference to the continuous converting of copper, nickel,~cobalt or lead sulfides.
The continuous smelting and converting of sulfide minerals to matte or metal is an old concept well known in the art. As long ago as 1898, Garretson in U.S. Patent 596,992 disclosed a three zone smelting, converting and slag settling procedure. He teaches a method for the continuous production of non-ferrous metals from their sulfide ores comprising the steps of continuous smelting of the sulfides in a fuel burning furnace with a long narrow slightly sloped bottom; the resulting matte flows continuously to one or re separate, but communicating, converters in series at one end of the furnace, there the matte is progressively and continuously blown to metal which is with-` drawn, the resulting rich slag flows back continuously -countercurrently to the matte - through the smelting furnace, is improverished by contact with the low grade matte therein, flows into a separate but communicating, slag settling zone at the other end of the furnace, and is there subjected to the heating and reducing action of charcoal, matte settles out and flows back to the furnace and the cleaned slag is discharged.
The concept of the autogenous production of copper matte from sulfide minerals was disclosed in 1915 by Klepinger et al in U.S. Patent 1,164,653. He teaches the spraying of dry, finely divided copp;er sulfide concentrates with preheated air into a reverberatory-type furnace. The concept of slag cleaning by the washing and reducing action of iron sulfide was disclosed by Stout in U.S. Patents 1,416,262 (1922) and 1,544,048 (1925).
- He teaches progressive cleaning of molten copper-containing slags by their agitation and thorough mixing with pyrite, low
- 2 -10~830 grade matte or iron, followed by slag settling under quiescent conditions. Gronningsaeter disclosed in U.S. Patent 2,426,607 (1947) apparatus for reacting slags to recover metals from them by subjecting the slags to reduction and mixing by injection of fuel and air through tuyeres into the body of the slags.
The concept of an elongated, slightly inclined, rotary furnace sufficiently long to provide substantially separate, continuous metal melting and refining zones was disclosed by Sherwood in 1970 in~U.S. Patent 3,542,350. Much information ~ -pertinent to non-ferrous pyrometallurgy is furnished in many of the Reports of Investigation of the U.S. Bureau of Mines, e.g., "Autogenous Smelting of Copper Sulfide Concentrate", R.I. 7705 (1973), One of the present applicants disclosed in 1954, U.S.
Patent 2,668,107, autogenous smelting of copper and nickel sulfide concentrates by injecting dry sulfides with tonnage oxygen and flux into an impermeably encased chamber. Matte or metal and slag are continuously produced, the matte or metal is discharged from one end of the furnace, and the slag is dis-charged from the other end. The rich slag from the high grade matte end of the furnace is depleted of its metal values by -employing the principle of countercurrent flow of matte or metal relative to the slag. If desired, after passage over a raised hearth barrier to separate the slag and matte layers, and, in any event, prior to discharge from the furnace, the slag is given a final cleaning by washing it with a shower of molten, low grade matte droplets rich in iron sulfide. Furnace off-gas contains a high concentration of sulfur dioxide. He also disclosed in 1961, U~S. Patent 3,004,846 and in subsequent U.S. Patents 3,030,201: 3,069,254, 3,468,629; 3,516,818:
The concept of an elongated, slightly inclined, rotary furnace sufficiently long to provide substantially separate, continuous metal melting and refining zones was disclosed by Sherwood in 1970 in~U.S. Patent 3,542,350. Much information ~ -pertinent to non-ferrous pyrometallurgy is furnished in many of the Reports of Investigation of the U.S. Bureau of Mines, e.g., "Autogenous Smelting of Copper Sulfide Concentrate", R.I. 7705 (1973), One of the present applicants disclosed in 1954, U.S.
Patent 2,668,107, autogenous smelting of copper and nickel sulfide concentrates by injecting dry sulfides with tonnage oxygen and flux into an impermeably encased chamber. Matte or metal and slag are continuously produced, the matte or metal is discharged from one end of the furnace, and the slag is dis-charged from the other end. The rich slag from the high grade matte end of the furnace is depleted of its metal values by -employing the principle of countercurrent flow of matte or metal relative to the slag. If desired, after passage over a raised hearth barrier to separate the slag and matte layers, and, in any event, prior to discharge from the furnace, the slag is given a final cleaning by washing it with a shower of molten, low grade matte droplets rich in iron sulfide. Furnace off-gas contains a high concentration of sulfur dioxide. He also disclosed in 1961, U~S. Patent 3,004,846 and in subsequent U.S. Patents 3,030,201: 3,069,254, 3,468,629; 3,516,818:
3,615,361 and 3,615,362 the conversion of copper, nickel and lead sulfide materials to metal, in appropriately operated top-: , . ,~ , -.
blown rotary oxygen converters. He teaches top blowing tech-niques using downwardly directed gas lances to impinge process gases of controlled analysis onto or through the surface of the bath at controlled temperatures. He also teaches the need for "a sufficiently high degree of agitation to provide efficient and effective gas-solid-liquid contact throughout the bath, which is conducive to efficient elimination of iron, sulfur and impurities" and he emphasizes "the extreme importance and necessity connected with strong induced turbulence of the furnace bath". Application of his turbulent bath principle "enhances heat transfer, increases the overall rate of the chemical reactions, minimizes compositional gradients within each phase and significantly reduces diffusion barriers be-tween the slag and the sulfide phase".
In a 1950 publication "A Survey of the Thermodynamics - of Copper Smelting" (Transactions AIME, Volume 188) one of the present applicants presented an analysis of the physical chemistry involved in the smelting and converting of mixtures of copper and iron sulfides to produce crude metal and waste slag. A major teaching is that "the chemical activities of oxygen and sulfur are two of the most important thermodynamic yardsticks to be applied to copper smelting processes". The publication also includes quantitative demonstrations that the production of crude metal and waste slag from sulfide concen-trate should be regarded as a process of "progressive and con-trolled oxidation" in a "sequence of steps". Thermodynamic calculations provide numerical estimates of the oxygen and sulfur activities which prevail in conventional copper smelting, converting and fire refining operations. The publication dis-closes that the matte-slag systems characteristic of these operations are subject to "tremendous variation in oxygen pressure", as much as 106-fold. He teaches that these varia-: :,
blown rotary oxygen converters. He teaches top blowing tech-niques using downwardly directed gas lances to impinge process gases of controlled analysis onto or through the surface of the bath at controlled temperatures. He also teaches the need for "a sufficiently high degree of agitation to provide efficient and effective gas-solid-liquid contact throughout the bath, which is conducive to efficient elimination of iron, sulfur and impurities" and he emphasizes "the extreme importance and necessity connected with strong induced turbulence of the furnace bath". Application of his turbulent bath principle "enhances heat transfer, increases the overall rate of the chemical reactions, minimizes compositional gradients within each phase and significantly reduces diffusion barriers be-tween the slag and the sulfide phase".
In a 1950 publication "A Survey of the Thermodynamics - of Copper Smelting" (Transactions AIME, Volume 188) one of the present applicants presented an analysis of the physical chemistry involved in the smelting and converting of mixtures of copper and iron sulfides to produce crude metal and waste slag. A major teaching is that "the chemical activities of oxygen and sulfur are two of the most important thermodynamic yardsticks to be applied to copper smelting processes". The publication also includes quantitative demonstrations that the production of crude metal and waste slag from sulfide concen-trate should be regarded as a process of "progressive and con-trolled oxidation" in a "sequence of steps". Thermodynamic calculations provide numerical estimates of the oxygen and sulfur activities which prevail in conventional copper smelting, converting and fire refining operations. The publication dis-closes that the matte-slag systems characteristic of these operations are subject to "tremendous variation in oxygen pressure", as much as 106-fold. He teaches that these varia-: :,
- 4 - ~
- , -: ., :: . . : . .
: -tions can be related to the practical problems of controlling matte and slag stoichiometry, operating temperatures, magnetite - formation and slag losses. His subsequent publications disclose ` oxygen and sulfur activities in mattes and slags over the wide ranges of composition and temperature encountered in the smelt-ing and converting of copper- and iron-containing sulfides.
During the past several years a number of skilled and forward-looking investigators have proposed a variety of ways and means for solving the serious problems connected with pyro-metallurgical transformation of sulfide concentrates to metal in a continuous process. These include Worner, U.S. Patent ~
3,326,671 (1967), Themelis et al, U.S. Patent 3,542,352 (1970), `
Maelzer et al, U.S~ Patent 3,687,656 (1972), and Morisaki et al of Mitsubishi Metal Corporation. Despite their efforts none have satisfactorily overcome all of the crucial obstacles in-volved. In the first of these patents, operating complications and limitations are imposed by the three zone concept in the ` type of apparatus employed and by the reliance on top blowing techniques using downwardly directed gas lances. The second procedure utilizes concurrent-flow of matte and slag. The white metal blowing section - where high oxygen and low iron sulfide activities are essential - is contiguous to the slag reducing section - where low oxygen and high iron sulfide activities are essential. The process has some of the restrictions character-izing current industrial operations because of the similarity of the apparatus employed to a conventional Pierce-Smith con-verter. The third patent describes a-semi-continuous series of intricate operations in a multi-compartment apparatus, w~ich include top blowing techniques using downwardly directed gas lances. The fourth procedure employs three separate, but communicating, individual furnaces for continuous smelting, converting and slag cleaning, it also relies on top blowing
- , -: ., :: . . : . .
: -tions can be related to the practical problems of controlling matte and slag stoichiometry, operating temperatures, magnetite - formation and slag losses. His subsequent publications disclose ` oxygen and sulfur activities in mattes and slags over the wide ranges of composition and temperature encountered in the smelt-ing and converting of copper- and iron-containing sulfides.
During the past several years a number of skilled and forward-looking investigators have proposed a variety of ways and means for solving the serious problems connected with pyro-metallurgical transformation of sulfide concentrates to metal in a continuous process. These include Worner, U.S. Patent ~
3,326,671 (1967), Themelis et al, U.S. Patent 3,542,352 (1970), `
Maelzer et al, U.S~ Patent 3,687,656 (1972), and Morisaki et al of Mitsubishi Metal Corporation. Despite their efforts none have satisfactorily overcome all of the crucial obstacles in-volved. In the first of these patents, operating complications and limitations are imposed by the three zone concept in the ` type of apparatus employed and by the reliance on top blowing techniques using downwardly directed gas lances. The second procedure utilizes concurrent-flow of matte and slag. The white metal blowing section - where high oxygen and low iron sulfide activities are essential - is contiguous to the slag reducing section - where low oxygen and high iron sulfide activities are essential. The process has some of the restrictions character-izing current industrial operations because of the similarity of the apparatus employed to a conventional Pierce-Smith con-verter. The third patent describes a-semi-continuous series of intricate operations in a multi-compartment apparatus, w~ich include top blowing techniques using downwardly directed gas lances. The fourth procedure employs three separate, but communicating, individual furnaces for continuous smelting, converting and slag cleaning, it also relies on top blowing
- 5 -' : .
techniques using downwardly directed gas lances. This process retains several disadvantages of the establis~ed art.
It is an aim of the present invention to provide means of avoiding disadvantages of the prior art procedures and to provide positive economic and environmental advantages as will be described.
A preferred embodiment of the parent invention involves a continuous, autogenous, multi-stage, countercurrent process for converting copper or nickel sulfide concentrates and fluxes to crude metal or low iron matte, waste slag and sulfur dioxide.
-The converting reactions are disposed stage-wise along the length of a slowly oscillating, elongated, gently sloped, rounded cross-section sealed furnace of a simple and symmetrical configuration, discharging crude metal or low iron matte at one end, and sili-cate slag impoverished in metal values and sulfur dioxide-rich gas at the other end; with staged introduction of sulfide con-centrates, fluxes, commercial oxygen, sulfur dioxide, water, a carbonaceous reducing agent and iron sulfide at intermediate points along its length. The staged introduction of fèed mate-rials establishes the conditions essential for progressive oxida-tion along the length of the converter. Near the crude metal or . low-iron matte discharge end, the activity of oxygen in the molten bath reaches a maximum ~ufficiently high to insure satis-factory low residual iron content in the value metal product;
near the slag discharge end, activity of oxygen in the molten bath is brought to a minimum by introducing sulfur dioxide with a carbonaceious material, which reagents react with ferrous oxide in the slag to reverse the converting reaction so as to form, in situ, a cleansing nascent non-ferrous metal bearing iron sulfide.
A substantial proportion of the commercial oxygen is blown into the furnace through injectors extending through the :
1~)4S830 ~ -refractory lining of the furnace and having openings communicat-ing with the interior of the furnace beneath the surface of the liquid. The injector nozzles and refractory are protected during the introduction of the oxygen into the molten metal, by injecting along with the oxygen, protective fluids, either mixed with the oxygen or surrounding the oxygen streams. The injec-tion of gas-protected converting oxygen, directed upwardly into the molten matte bath, through the refractory wall and below the liquid surface, minimizes slag, dust, refractory and other difficulties such as those caused by reliance on top blowing techniques using downwardly directed gas lances and provides unique capabilities for practical achievement of a multi-stage, progressive converting process, and the preferred vessel de-signed to exploit these capabilities provides highly flexible means for control of the chemical and physical environments necessary for efficient staging of the operations along the length of the apparatus~.
Oscillation of the converter causes the injected gases to sweep back and forth through the molten bath, eliminates ; 20 stagnant zones and distributes the sulfide concentrates and fluxes over the surface of the bath, and thereby imparts the controlled bath turbulence and intimate interphase contact re-quired for effective approach to equilibrium stage separation.
Furnace oscillation also promotes positive matte flow, decreases refractory degradation and increases injector nozzle life.
Control of temperature, oxygen potential and metal sulfide activity gradients along the length of the converter is readily and straightforwardly accomplished, by adjusting and proportioning the flow rates of sulfide concentrates, oxygen, sulfur dioxide, water, coal or other feed materials such as a hydrocarbon gas at their several points of entry. No fuel-fired smelting zone lS required with all its attendant disadvantages, ' - , , ' . - :, 1~)45830 because melting of the sulfide concentrates and fluxes is accom-plished incidental to converting, utilizing the heat generated by the chemical reactions. Melting of the sulfide concentrates and fluxes may be largely accomplished by partial flash oxidation of the sulfides in the atmosphere above the molten bath. ~o refining zone is required because the object is to produce only crude metal or low iron matte, suitable as feed material for refining or other processing steps. The invention broadens the ranges of oxygen and metal sulfide activities characteristic of the prior art, it normally includes the controlled reversal of the converting reactions so as to apply deconverting to the ex-tent required for slag scavenging purposes.
Another advantageous feature of this preferred embodi-ment of the invention is the use of recirculated sulfur dioxide -preferably recirculated furnace off-gas - for protection of the oxygen injectors and refractories, for furnace temperature con-trol and for heat recuperation, for chemical reaction control in - and physical agitation of - the bath and for deconverting, all while maintaining a high sulfur dioxide content in the furnace off-gas. Sulfur dioxide has a significantly higher-heat capacity and density than nitrogen, and does not contaminate furnace off-gas.
The parent invention is also embodied in preferred apparatus for carrying out the process. mis apparatus includes an elongated,`gently sloped, oscillable, rounded cross-section sealed furnace having discharge means at one end for a non-ferrous metal-rich phase and discharge means at the other for ,- -slag and a discharge for off-gases at the slag discharge end.
m e sealing of the converter is important to prevent air ingress and/or sulfur dioxide leakage. me vessel is sloped at less than 5 downwardly towards the metal-rich product discharge end and its bottom is stepped to provide a pool or reservoir at one end ' ' ~' - 8 - ~
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bottom is stepped to provide a pool or reservoir at one end for the metal-rich product and toward the other end for slag separa-tion. Means are provided for feeding concentrates and flux optionally with oxygen through the top onto the surface of the bath. Injectors extend through the refractory lining of the `
furnace through openings communicating with the interior of the furnace beneath the surface of the liquid. The injectors are equipped for blowing a protective gas during the introduction of the oxygen into the molten metal, along with the oxygen so as to protect the injectors and the surrounding refractories. There is means for oscillating the furnace slowly, e.g. through 200 to 40 and at 1 to 6 reciprocations per minute and for tilting it, e.g. through 75 for servicing the injectors. All feed and discharge connections are such that they permit this oscillation and tilting. Suitable means are provided for metering, regulat-ing, and analyzing the feed and product materials to effect appropriate control as described herein.
The invention to which the present application is `~
directed relates to a process for treating slag containing non-ferrous metal values to recover such values therefrom in the form of metal sulfides. According to this method, a bath of liquid slag is established in a sealed refractory-lined vessel which is preferably non-rotary and may be tiltable. A carbon-aceous reducing agent, sulfur dioxide, and oxygen are directed upwardly through the slag bath in amounts effective to create strong reducing conditions in the slag to form metal sulfides in said slag. The metal sulfides are separated from the slag.
The accompanying drawings illustrate preferred embodi-ments of the parent invention and the present invention. In the drawings:
_ g _ - . ,: . . . : -Figure 1 is a schematic diagram showing an elongated kiln-like vessel, of preferred configura-tion, in which the treatment of the inven-tion may be carried out, Figure 2 is a vertical cross-section along the line 2-2 of Figure 1, and Figure 3 is an equilibrium diagram which illustrates desirable relationships between physical-chemical variables in the preferred sequen-tial converting process of the invention.
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1~)45830 Referring more particularly to Figure 1, a preferred treatment vessel is shown in the form of an elongated, gently sloped, rounded cross-section sealed furnace A which serves as a trough for a molten bath. The vessel is provided internally with a refractory lining which is stepped inwards at 13 and the vessel is stepped outwards as at 4. An intermediate step may be included if required. The furnace walls may have heat exchangers, e.g. steam tubes, evaporative air cooling tubes:
water jackets:i to suit the process conditions. Suitable mechanisms are provided for introducing feed, e.g. sulfide materials and fluids. Introducing the sulfide materials above the surface of the molten bath avoids the refractory degrada-tion and other difficulties which result from their introduction beneath the surface.
The vessel A is mounted for oscillation about its longitudinal axis, for example, through about 30 and is tilt-able, for example, through about 75 to permit maintenance, for example, of the injectors.
With the process in operation the molten bath will layer out into a matte M, a slag S and a pool of crude molten copper C.
Copper sulfide concentrates and oxygen are mixed and introduced in staged ratios through several inlets, e.g. vortex sprayers, at 6, with minimal oxygen introduction at the entry closest to the slag scavenging operation, and flux is intro-duced through inlets as at 7, into the atmosphere above the molten bath. Oxygen, shielded by sulfur dioxide, is blown into the converter A below the matte-slag interface through the several injectors at 8 extending through the refractory lining of the vessel. The staged injection of oxygen at 8 progres- -sively oxidizes the matte as it flows toward the copper dis-charge end, with formation of increasingly copper-rich matte 1~4S830 and finally crude copper. Simultaneously, the iron silicate slag formed flows countercurrently toward the slag discharge end. The sulfur dioxide-rich gas evolved passes concurrently over the slag on its way to the gas outlet 9 equipped with a labyrinth seal.
According to the present invention, there is introduced through the injector 10 beneath the surface of the slag and directed upwardly therethrough, a carbonaceous reducing agent, for example, coal, sulfur dioxide and oxygen in amounts suffi-cient to establish strongly reducing conditions and controlled bath turbulence. The resulting deconverting reaction scavenges the slag by formation in situ of metal sulfides, for example, cupriferous iron-sulfide. Simultaneously, the slag is optionally washed with a finely divided iron sulfide introduced, preferably as a shower, at the inlet 11 which further depletes the slag of its copper content. Finally the slag flows slowly through a calm pool to the slag discharge 12. ~he low grade matte which settles out of the slag flows countercurrently toward the copper discharge end. -As the procedure described is taking place, the re-actor is oscillated slowly through 30 at three reciprocations per minute. The oscillation increases gas-liquid-solid contact ~ -for effective heat and mass transfer.
The injection of the commercial oxygen, sulfur dioxide and other gases as the reactor is reciprocated causes these gases to enter the molten bath at continuously different angles to its surface and thus reaches constantly changing parts of the bath, with resultant turbulence of both chemical and physical origin. ;
Simultaneously, the copper-rich matte fraction flows towards the copper discharge end and the iron silicate-rich slag fraction to-wards the slag discharge end, so that in the longitudinal direc-tion fresh bath is being continuously subjected to advantageous gas-liquid and liquid-liquid contact.
' ~:
: :. - . - . : :
, ~',- , . - . . ~ ' . :
Also, as the reactor is reciprocated back and forth the concentrates and flux are fed into the atmosphere above the surface of the bath. secause the position of the feed entries is changing continuously with respect to the surface of the bath, the solids are distributed across its surface. Also, since the atmosphere above the bath is flowing towards the slag discharge end, the concentrates and flux fed are moving through the atmosphere transversely to its flow bringing about advan-tageous gas-solid contact. In sum, intimate interphase contact is achieved, bringing about efficient conversion of the concen-trates to crude copper, low copper-containing slag and sulfur ~-dioxide-rich gas.
The process may be started by first slowly heat soak-ing the refractories to about 1300C by the use of a fuel ~-burner at port 3. Then concentrates may be introduced, e.g.
partially flash converted for the time required to build up a shallow bath, maintaining enough gas flow, e.g. sulfur dioxide, through the injectors, to protect them, followed by normal operation of the converter. Alternatively, after refractory heat-soaking, matte may be poured into the furnace, followed by normal operation.
The reaction is autogenous and the operating tempera-ture is maintained by the exothermic reaction, within a range effective to keep the metal and slag satisfactorily fluid and maintain high reaction rates, for example, within the range from about 1000C to about 1650C. Preferably the oxidizing conditions will vary progressively and sequentially within the converting region.
Process ~ontrol Some of the qualitative aspects of the metallurgical control of a continuous converter will be apparent to those -~
skilled in standard batch converting. However, the continuous 1~)45830 process embodied in this invention provides, in addition, a number of highly flexible operating controls which are used in concert to establish and maintain a steady state of staged con-verting providing optimum metallurgical performance for wide ranges of compositions of sulfide concentrates and converter products. Primary stoichiometric control is based on metering and proportioning the total feed rates of sulfide concentrates, fluxes, and oxygen to obtain continuous production of a crude metal or low-iron matte product, a waste slag carrying substan-tially all the iron along with a sufficiently high content ofsilica and other fluxing oxides to give desirable slag proper-ties, and an S02-rich effluent gas containing a small excess - of oxygen. Short term fluctuations in the chemical composi-tions and converting behavior of the solid feed materials, or other divergences from the desired steady state proportioning o~ the total input materials will be absorbed by accumulation or depletion of the matte and/or metal layers in the converter, these layers thus serving as a large stabilizing reservoir within the furnace. Accordingly, stoichiometric control of the ratio of total oxygen input to total input of sulfide con-centrates is facilitated by appropriate monitoring of the depth of the matte layer in the apparatus.
; The distributions of oxygen inputs and sulfide con-centrate inputs among their respective points of feeding along the length of the converter are regulated, as already mentioned, to establish the appropriate gradients of chemical conditions along the converter. More specifically, the ratio of oxygen to sulfides is at a minimum near the slag scavenging section with much less oxygen being fed than required to fully convert the sulfides being added in that section. A convenient practical criterion for making these adjustments is the ratio of ferric iron to total iron in the slag, which is determined by slag ::, -. - . ~ : . . . ~ , . . : ,, :
sampling and analysis. The optimum range for a given operation is established by trial, but a typical range in converting copper sulfide concentrates at 1300C is from a ferric iron:
total iron ratio of 0.2 or higher at the metal discharge end down to 0.06 at the waste slag discharge end.
In the slag scavenging section, the quantities of iron sulfide, coal, S02, and 2 are adjusted to cause the continuous formation, within the slag layer, of low grade matte, e.g. less than 20% Cu, which settles through the slag and cleans the value metal from the slag to a low level before the slag is discharged from the furnace. The oxygen injected with the coal provides partial combustion of the coal, for formation of a hot, strongly reducing gas and localized heating to meet thermal requirements ; of the deconverting reactions. As already pointed out, the -~ ratio of ferric iron to total iron provides a useful operating criterion for guidance in the adjustments of input materials into the slag scavenging stage and this ratio preferably is brought substantially to a minimum by such adjustments.
A wide range of temperature control is available to the operator, independently of the proportioning of oxygen and sulfide, by varying the quantity of the recirculated S02.
Further flexibility is available, as needed, by the use of water or by the substitution of hydrocarbon shielding fluids for S02 or by varying the temperature of the S02. Through all these means, the opèrator can readily control the temperature, at high level, throughout the converter, e.g. so that the fluid high silica slag needed for rapid reaction and clean separation r ~. '. . .
is achieved, without localized overheating and resulting exces-sive erosion of injectors and refractories.
The various product streams are monitored continuously, using on-stream or rapid analysis instrumentation. Also, the temperatures are continuously determined along the length of .'' : . ' . :. ., . .
1~45830 the converter.
When fixation of all the sulfur in the converter off-gas - for instance mainly as elemental sulfur - cannot be justi-fied, the applicants' preferred alternative is to treat the gas by what they term "deconverting". In this operation, carried out in a separate apparatus, the S02-rich off-gas is injected, together with carbonaceous reducing agent and commercial oxygen, into the molten waste iron silicate slag from the converter so as to fix most of the sulfur in the gas as liquid iron sulfide.
This may be cast and stockpiled to conserve both the sulfur from the gas and the irpn from the slag for further consumption.
A fraction of the liquid iron sulfide may be granulated in water and recycled to the converter for slag cleaning purposes. If it is desired to fix substantially all of the sulfur in this form, additional iron required can be supplied by feeding the decon-verting furnace any suitable iron source material, e.g. scrap such as junk automobiles, or other slags. Judicious amounts of lime can, of course, be employed to maintain slag fluidity.
Sulfur fixation in this matter represents an extension of the slag cleaning procedure utilized in the continuous oxygen converter, and thus can be carried out in a continuously opera-ting furnace of quite similar design, with appropriate injection of oxygen,- sulfur dioxide, and carbonaceous reducing agent.
Those skilled in the art will recognize that deconverting, using SO2-rich gas, can also be carried out in other apparatus, quite similar to the water-jacketed slag fuming furnaces commonly used in treating slags, with pulverized coal and air mixtures, for other purposes, e.g. zinc recovery.
Physical-Chemical Variables The equilibrium diagram of Figure 3 illustrates the relationship among some of the most important physical-chemical variables at various stages of the applicants' sequential copper - ... . , :
iO4~830 converting process. Following common practice among chemical metallurgists, the oxygen activity is measured by log (Pco /Pco), and the temperature is measured by the reciprocal of absolute temperature. The minimum oxygen activity required to form metallic copper from white metal copper sulfide, at a given temperature, is shown by the line at the top of the Figure. If an iron silicate slag with FeO activity (aFeO) equal to 0.35 is present, on the other hand, the oxygen activity at a given tem-perature must be kept below the line corresponding to solid magnetite formation. The succession of lines for different values of iron sulfide activity correspond to successive stages of converting, because the copper content of the matte increases as the activity of iron sulfide decreases. The conditions corresponding to low grade mattes and to low metal contents in the waste slag lie just above the line for aFeS equal to 1Ø
Figure 3 also depicts the reversibility of the prin- ;
cipal converting reaction:
FeS (matte) + 2302 (gas) ~ FeO (slag) + S02 (gas) If the oxygen activity is maintained below the line for aFeS equal to 1 - by using an appropriate reducing agent -then SO2 gas at atmospheric pressure will react with the FeO and copper, nickel and cobalt oxides, in the slag, to form a non-ferrous metal-bearing iron sulfide, the reverse of the usual converting reaction. It seems appropriate, therefore, as has been done in this disclosure, to term these reactions "decon-verting".
Examples of deconverting reactions, utilizing carbo-naceous reducing agents and sulfur dioxide are as follows:
S2 + FeO ~slag) + 3C ~ FeS (matte) + 3CO
SO2 + FeO (slag) + 3CO ~ FeS (matte) + 3C02 S2 + Cu2O (slag) + 3C > Cu2S (matte) + 3CO
To achieve the low levels of slag oxygen activity re-:: :
.
1045830 :
quired for deconverting, it is necessary to reduce slag ferric oxide content to a relatlvely low level by use of a reducing agent. For example, if at 1350C a slag oxygen activity equi-og (PCo2/pco) of 0.5 is desired - so as to be below the line for aF S = 1 in Figure 3 - the proportion of ferric iron present must be less than 6% of the total iron content of the slag.
Thus, a major achievement of the present invention has been to provide a process embodying a progressive and controlled sequence of oxygen and other activities, ranging in a systematic fashion from the high oxygen activity necessary to oxidize the great bulk of the iron and sulfur in the feed so as to discharge a product high in metal value at one end of the converter, down to the low oxygen activity required at the other end of the vessel to discharge a slag low in metal values.
For the specific conditions represented in Figure 3 and for an operating temperature of approximately 1600 degrees Kelvin (1327C), the general range of oxygen activities to be ~
established and controlled is from a C02/C0 ratio of about 100:1 -down to a C02/C0 ratio of about 5:1, corresponding to a 400-fold range in activity of 2 In order to achieve such a range of oxygen activities in a continuous, substantially steady state ~ -reactor, it is necessary to supply oxygen at a pressure above that corresponding to C02/C0 = 100 and to provide a reducing agent capable of lowering the C02/CO ratio below 5. Thus, when all process needs are taken into account, in the case of copper concentrate treatment, full realization of the thermodynamic process model requires positive and effective control of oxygen activity over as much as a 1000-fold range.
The thermodynamic feasibility of an equilibrium model, though an essential requirement, is, of course, not sufficient to demonstrate the feasibility of a large scale continuous 1~J4~830 pyrometallurgical process. The applicants' design is also based on stoichiometric and thermal balances among the interacting streams of solids, liquids, and gases flowing through the system.
Appropriate residence times and fluid flow conditions have been provided to achieve the necessary heat and mass transfer. The applicants' apparatus also has the physical configurations and capabilities needed to meet process requirements efficiently including control of essential operating variables. Thus, the converter can be designed for a very high capacity, adequate for single unit treatment of several thousand tons of solid charge daily. Important information relevant to these considerations is available in the technical books written or edited by the applicants over the past two decades. The applicants' appre-ciation of the difficulties and shortcomings of existing pyro-metallurgical practices, and their study of the attempts of others to solve these problems has led to the improvements over the prior art detailed in this disclosure.
Particular Concentrates The concentrates treated are those which contain enough iron and sulfur to be substantially autogenous when re-acted with oxygen-rich gas. Typical preferred analyses are contained in the following examples. The invention also con-templates that some or all of the sulfide feed material may be a pelletized wet concentrate, e.g. 8% free moisture, or even a concentrate slurry with water, e.g. 75% solids.
The invention is particularly useful in the recovery of nickel and cobalt from pentlandite concentrates. The con-centrates are treated in the applicants' continuous oxygen converter for production of matte containing a large proportion of the nickel and cobalt in the concentrate and a slag contain-ing a large proportion of the iron and a gas high in sulfur dioxide. The cobalt is removed from the discharged molten matte, . ~ . ..... - : :
1~)4S830 for separate recovery. This may be through its conversion to ~ -chloride by reaction of the liquid sulfides with gaseous chlorine or by solvent extraction, using a molten salt mixture of sodium and nickel chlorides. The thus cleansed molten matte may then be fire refined to metallic nickel in a bottom-blown, non-rotary converter which is sealed and tiltable, using gas-protected injectors to blow commercial oxygen through the matte or metal from below the liquid surface, employing hydrocarbon gas shielding of the oxygen during the final stages of the blow.
The invention may also be advantageously employed in ~ -treating copper-nickel or cupro-nickel concentrates accord1ng to the invention to form a metallic copper-nickel alloy as the metallic phase. The alloy may be dissolved by aqueous chlorina-tion and the dissolved metal chlorides subjected to solvent -extraction for copper and nickel isolation and, pure copper and nickel may be recovered from the aqueous extracts by electro-winning.
In converting lead sulfide concentrates into lead, according to the invention, the following procedure may be employed. The lead concentrates are dropped continuously onto the surface of a slag covered molten lead bath in a sealed con-verter, of the type described herein, which is continuously blown with commercial oxygen employing submerged fluid-protected injectors. There is thus produced continuously a substantially zinc-free bullion and a sulfur dioxide-rich gas. The slag produced is continuously fumed in the converter by injection of carbonaceous material for the production of a low lead and low zinc-containing slag. The lead in the converter gas particu-late matter may be continuously recycled.
Certain principles of the invention may be applied to - -producing copper, nickel, or cupro-nickel from their substan-tially iron-free sulfides. For example, there may be introduced - 19 - ~
-, . ...... .
1~4S830 below the surface of the molten bath of the sulfides contained in a tiltable sealed bottom-blown non-rotary converter an oxygen-rich gas having an oxygen content sufficient for autogenous con-version of the sulfides to metal. According to the invention, the gas is blown through the bath by means of appropriately positioned fluid-protected injectors extending through the re-fractory wall of the converter to openings in its lower part below the bath surface. Pneumatic bath turbulence is thus created for effective interphase contact. The gas flow rates are regulated so that bath temperature is maintained at uniform controlled levels effective for high reaction rates between oxygen and sulfur and so that the quantity of oxygen reacted is only about the stoichiometric amount necessary to convert sub-stantially all the sulfur present in the bath to sulfur dioxide.
According to the present invention, the protective fluid for the oxygen injectors is sulfur dioxide or water or both, until the sulfur content of the bath is less than about 5%, and then a hydrocarbon gas may be employed as shielding fluid for the re-mainder of the blow.
Gases The term "commercial oxygen" is defined as a gas normally having more than 90% free oxygen and it is preferred to employ commercial oxygen. The use of such oxygen permits, in addition to S02-rich gas production, furnace operation at ~
temperatures higher than conventional, with accompanying ~-kinetic and operating advantages in high reaction rates and in ~
control of matte and slag fluidity, provided the metal injectors ~ -and surrounding refractories are protected, as taught herein, from the increased temperatures. With some concentrates, an autogenous process may be carried out using oxygen-enriched air, containing down to as little as 40% oxygen, although introducing such large proportions of nitrogen into the system may be unde-sirable for environmental and other reasons. This is a higher 1~45830 oxygen level than normally tolerated by the standard Pierce-Smith converter, which suffers from over-oxidation and over-heating near the tuyeres and from relatively poor interphase contact, poor temperature distribution, and limited control of oxygen activity.
In the applicants' process, the furnace off-gas normally has a sulfur dioxide content over 70% dry basis and ~-preferably over 80%, and is substantially free of nitrogen oxides. Converter off-gas is passed through steam raising boilers for power generation purposes. It is then suitably cleansed of substantially all of its particulate matter con-tent, and most of the copper, nickel or lead in the latter recycled to the process. The sulfur dioxide injected into the converting operation is normally recycled converter off-gas.
The amount of S02 added, as a protective fluid, or otherwise will range from about 0 to about 150% by volume of the oxygen, measured at standard normal temperature and pressure, that is at 0C and one atmosphere of pressure.
Water may be added as an atomized fog in an amount within the range from 0 up to 25% by weight of the oxygen. The water may be added in the oxygen stream, in a shielding gas stream, or -both.
Slag A further advantage of the applicants' method and apparatus, with the flexible controls described, is the ability conferred to readily produce, when desired, ferrous silicate slags at higher than conventional temperatures, for example, over 1300C and at higher than conventional silica contents, e.g. over 39% silica, with consequent lower than conventional copper, nickel, or cobalt losses owing to the satisfactory fluidity of the slags, their low density and low ferric iron concentration.
., : ., : . .
. , , ' ~' - ~' 1~45830 Products The end product from copper sulfide concentrates may be a crude metal with a copper content of over 95% and an iron content of less than .2%, a sulfur content of less than 2% with a copper recovery of over 98~, or the process can produce a matte of over 7~% copper, less than 2% iron and the balance sulfur and impurities, again with a copper recovery of over 98%.
In the case of nickel, the end product may be a crude metal over 90~ nickel, less than 1% iron, less than 5~ sulfur for a nickel recovery of over 95%; or a matte of over 65% nickel, less than 5% iron with a cobalt recovery of over 75%. In either case the nickel recovery will be over 95~0. In the case of lead, the end product may be a bullion of over 95% lead, less than 1%
iron, less than 1% sulfur, with recovery of over 95~ of the lead.
Oxygen Injection The submerged oxygen inJection, employed by the appli-cants, for converting, involves blowing fluid protected oxygen-rich gas into a molten bath through the refractory wall of a converter below the liquid surface. In certain applications of the present invention, such fluid protection may be similar to the general Savard-Lee concept disclosed in French Patent 1,450j718 (1966), According to that concept, metal is refined, in batches, by blowing commercial oxygen into a molten bath through injectors extending through the refractory lining of a standard converter and having openings communicating with a lower part of the vessel beneath the metal surface. The injectors and surrounding refractories are protected, by surrounding the oxygen stream with a shielding hydrocarbon.
Contrariwise, for continuous converting of sulfide concentrates, in their special converter, the applicants ;'~
'' . ~''' ., ': ' ' , , 1~4S830 :
normally prefer to employ the non-combustible gas, sulfur dioxide, -as protective fluid. Also, when desirable for additional cooling purposes, the applicants may use atomized water in the central oxygen stream; also, atomized water may be introduced into a shielding fluid. In appropriate circumstances, either sulfur dioxide or atomized water, or both, is introduced into the oxygen stream as an alternative or supplement to their use in a surrounding shielding fluid. The oxygen may be blown in a direction from substantially horizontal to vertically upward.
The preferred process of the invention has been de-scribed as a continuous process made up of an integrated com-bination of steps and control features providing the special results described. Such combination includes, for example, the continuous process in which the metal-rich phase and the slag phase flow countercurrently, the slag and gas phases flow con-currently, and there are sequential stage converting and slag cleaning steps and, in which the vessel is oscillated. Some of ~-these and other expedients of the preferred process are in them-selves new and can be employed without other aspects. For instance, using submerged oxygen injection as described might -be employed with other continuous slag cleaning expedients.
Likewise, the slag scavenging or deconverting stage, as descri-bed, could also be applied to a molten slag bath resulting from ~-other than the applicants' converting stage. While oscillation of the vessel provides preferred effects, acceptable results ; could be achieved without oscillation of the vessel.
The applicants' apparatus can be dified for use in discontinuous copper or nickel matte converting or fire refining operations, e.g. in a bottom blown non-rotary tiltable sealed converter, using fluld protected in~ectors to blow commercial oxygen directed upwardly or substantially horizontally, i.e.
less than about 10 below the horizontal through the matte or , . . .
- . , :
. . , , ~ ~ . . .:
1~45830 metal from below the liquid surface. The applicants' apparatu~
can be also modified for continuous iron-making and for the continuous oxygen converting of pig-iron into steel.
The present invention meets the need for a simple, flexible, economic continuous converting process with a superior capability for environmental conservation which is lacking in prior art proposals. Losses of value metals incurred by usage of the novel continuous single furnace unit are less than half those associated with conventional pyrometallurgical practice.
Also, the cost of process off-gas treatment for sulfur fixation -either as iron sulfide or as elemental sulfur - is less than half that of similar fixation of sulfur in the off-gases from con-ventional practice. A main target of the applicants' invention is maximum utilization of the ore within boundary limits imposed by the market place on which the prior art fails to focus -adequately. The use of applicants' method and apparatus permits simultaneously increased unit metal production capacity, de-creased metal production costs, increased recovery of valuable components of the ore, and decreased environmental degradation.
Specific examples of preferred procedures will now be given to illustrate the invention in more detail.
Example 1 One thousand metric tons per day of copper sulfide concentrates analyzing 28% Cu, 28% Fe, 30% S, 7% SiO2 (dry basis) and containing 1% water, are continuously stage fed into ~ ~
a 6 meter X 36 meter converter constructed and operated in the ~ -manner indicated for Figure 1, are flash converted at about -~
1330C with 320 tons per day of flux analyzing 78% SiO2 (dry basis) and containing 5% water, and 280 tons per day of commer-cial oxygen analyzing 98% 2' 2% argon. ~he rates of both oxygen and concentrate introduction are judiciously controlled at the several vortex spray entries, the ratio of oxygen mixed , :. . . : : . ~ .
.: . , . , :
16)4S830 with the concentrate introduced increasing progressively from minimal at the entry closest to the slag scavenging region, to a maximum at the feed entry closest to the metallic copper pro-ducing region. Water in the additional amount of 50 tons per day is introduced into the converter atmosphere for temperature control purposes. The molten matte so produced is blown in controlled stages at about 1330C by injection of 135 tons per day of commercial oxygen and 320 tons per day of sulfur dioxide as surrounding shielding gas and progressively oxidized to metallic copper in a controlled sequence of steps. 284 tons per day of crude copper analyzing 98% Cu, 0.1% Fe, 1% S are continuously discharged from the converter as indicated on Figure 1. This product contains about 99% of the copper in the sulfide concentrate fed to the converter. The molten slag pro-duced by these operations is scavenged at about 1330C by in-jection of 43 tons per day of a mixture of subbituminous coal,(dry) sulfur dioxide and oxygen in approximately a 3.5:3:1 weight ratio.
Concommitantly the slag is washed by a shower of 25 tons per day of iron sulfide, following which the slag is settled in a calm pool and then continuously discharged at the rate of 800 tons per day in a stream analyzing 0.2% Cu, 35% Fe, 40% SiO2.
This product contains substantially all of the iron in the sulfide concentrates fed to the converter. The gas from the conversion operations is discharged continuously at a tempera-ture of about 1330C and at a rate of 645 tons per day in a stream analyzing 88% S02, 9% C02, 2% Ar, 1% 2 (dry basis).
This product contains over 90% of the sulfur in the sulfide concentrate fed to the converter and is free of nitrogen oxides.
The hot gas flows to boilers for steam raising and power genera-tion and then to dry electrostatic precipitators, wet scrubbersand/or bag filters for dust recovery. Controlled fractions of the collected particulate material and cleaned gas are bled out - ~ . . , ~, 1~4~i830 for appropriate treatment and disposal, and the balance is re-cycled to the converter.
Example 2 A pentlandite concentrate analyzing 15% Ni, 0.6% Co, 40% Fe, 30% S, 10% SiO2, is treated in the applicants' con-tinuous oxygen converter for production of matte analyzing over 65% Ni, and containing over 95% of the nickel and over 75% of the cobalt in the concentrate, of a slag containing over 95%
of the iron in concentrate, and of a gas analyzing over 75%
S02 (dry basis) and containing over 75% of the sulfur in the concentrate. The cobalt is removed from the discharged molten matte, for separate recovery, through its conversion to chlo-ride by known procedures, e.g. by reaction of the liquid sulfides with gaseous ehlorine or by solvent extraction using a molten salt mixture of sodium and niekel ehlorides. If desired, the thus eleansed molten matte is then fire refined to metallic niekel in a bottom blown non-rotary eonverter whieh is sealed and tiltable, using gas proteeted injeetors to blow eommereial oxygen direeted upwardly through the matte or metal from below the liquid surfaee, employing hydroearbon gas shielding of the oxygen during the final stages of the blow.
In the ease of niekel, there ean be produeed anything from niekel-rieh matte, e.g. niekel sulfide eontaining more than 65% niekel and less than 5% iron and in which most of the Qobalt in furnace feed is recovered, to erude niekel metal eontaining less than 5% sulfur and less than 1% iron.
Example 3 A eopper-niekel concentrate of the following analysis is treated in a continuous oxygen eonverter similar to that deseribed herein and shown in Figures 1 and 2: 16% eopper, 4%
niekel, 32% iron, 27% sulfur and 10% siliea. There is produeed (a) metallie eopper-niekei alloy analyzing over 98% eombined - . - . ... .. . . :.
1~)45830 copper and nickel and less than 2% combined iron and sulfur and containing over 98% of the combined copper and nickel in the sulfide concentrate, (b) a slag containing over 98% of the iron in the sulfide concentrate, and (c) a gas analyzing over 80%
sulfur dioxide (dry basis) and containing over 90% of the sulfur in the sulfide concentrate fed to the converter. Only when the copper in the concentrate amounts to over about 70% of the combined copper-nickel content, will a metallic phase separate from and sink below the matte during the converting operation.
The metallic copper-nickel alloy product is dissolved by aqueous chlorination, the dissolved metal chlorides are subjected tc solvent extraction for copper and nickel isola-tion, and pure copper and nickel metals are recovered from the aqueous extracts by electrowinning.
Example 4 Lead concentrate, analyzing 72% lead, 3% zinc and 17%
sulfur and fluxes are introduced continuously into the converter as plus 4 mesh galena pellets, to prevent gas or slag suspension of the particulate lead sulfide containing material, and dropped on top of a slag covered lead bath which is bottom blown with oxygen employing fluid-protected injectors for production of a substantially zinc-free lead bullion analyzing over 95% lead and less than 1% sulfur, and containing over 95% of the lead in the concentrate, and a gas analyzing over 70% sulfur dioxide (dry basis) and containing over 90% of the sulfur in the con-centrate. The slag produced is continuously fumed in the con-verter, by coal injection, for lead and zinc recovery, and lead in the converter gas particulate matter is recycled.
., , . :
- ' ' ~'. .,~':
techniques using downwardly directed gas lances. This process retains several disadvantages of the establis~ed art.
It is an aim of the present invention to provide means of avoiding disadvantages of the prior art procedures and to provide positive economic and environmental advantages as will be described.
A preferred embodiment of the parent invention involves a continuous, autogenous, multi-stage, countercurrent process for converting copper or nickel sulfide concentrates and fluxes to crude metal or low iron matte, waste slag and sulfur dioxide.
-The converting reactions are disposed stage-wise along the length of a slowly oscillating, elongated, gently sloped, rounded cross-section sealed furnace of a simple and symmetrical configuration, discharging crude metal or low iron matte at one end, and sili-cate slag impoverished in metal values and sulfur dioxide-rich gas at the other end; with staged introduction of sulfide con-centrates, fluxes, commercial oxygen, sulfur dioxide, water, a carbonaceous reducing agent and iron sulfide at intermediate points along its length. The staged introduction of fèed mate-rials establishes the conditions essential for progressive oxida-tion along the length of the converter. Near the crude metal or . low-iron matte discharge end, the activity of oxygen in the molten bath reaches a maximum ~ufficiently high to insure satis-factory low residual iron content in the value metal product;
near the slag discharge end, activity of oxygen in the molten bath is brought to a minimum by introducing sulfur dioxide with a carbonaceious material, which reagents react with ferrous oxide in the slag to reverse the converting reaction so as to form, in situ, a cleansing nascent non-ferrous metal bearing iron sulfide.
A substantial proportion of the commercial oxygen is blown into the furnace through injectors extending through the :
1~)4S830 ~ -refractory lining of the furnace and having openings communicat-ing with the interior of the furnace beneath the surface of the liquid. The injector nozzles and refractory are protected during the introduction of the oxygen into the molten metal, by injecting along with the oxygen, protective fluids, either mixed with the oxygen or surrounding the oxygen streams. The injec-tion of gas-protected converting oxygen, directed upwardly into the molten matte bath, through the refractory wall and below the liquid surface, minimizes slag, dust, refractory and other difficulties such as those caused by reliance on top blowing techniques using downwardly directed gas lances and provides unique capabilities for practical achievement of a multi-stage, progressive converting process, and the preferred vessel de-signed to exploit these capabilities provides highly flexible means for control of the chemical and physical environments necessary for efficient staging of the operations along the length of the apparatus~.
Oscillation of the converter causes the injected gases to sweep back and forth through the molten bath, eliminates ; 20 stagnant zones and distributes the sulfide concentrates and fluxes over the surface of the bath, and thereby imparts the controlled bath turbulence and intimate interphase contact re-quired for effective approach to equilibrium stage separation.
Furnace oscillation also promotes positive matte flow, decreases refractory degradation and increases injector nozzle life.
Control of temperature, oxygen potential and metal sulfide activity gradients along the length of the converter is readily and straightforwardly accomplished, by adjusting and proportioning the flow rates of sulfide concentrates, oxygen, sulfur dioxide, water, coal or other feed materials such as a hydrocarbon gas at their several points of entry. No fuel-fired smelting zone lS required with all its attendant disadvantages, ' - , , ' . - :, 1~)45830 because melting of the sulfide concentrates and fluxes is accom-plished incidental to converting, utilizing the heat generated by the chemical reactions. Melting of the sulfide concentrates and fluxes may be largely accomplished by partial flash oxidation of the sulfides in the atmosphere above the molten bath. ~o refining zone is required because the object is to produce only crude metal or low iron matte, suitable as feed material for refining or other processing steps. The invention broadens the ranges of oxygen and metal sulfide activities characteristic of the prior art, it normally includes the controlled reversal of the converting reactions so as to apply deconverting to the ex-tent required for slag scavenging purposes.
Another advantageous feature of this preferred embodi-ment of the invention is the use of recirculated sulfur dioxide -preferably recirculated furnace off-gas - for protection of the oxygen injectors and refractories, for furnace temperature con-trol and for heat recuperation, for chemical reaction control in - and physical agitation of - the bath and for deconverting, all while maintaining a high sulfur dioxide content in the furnace off-gas. Sulfur dioxide has a significantly higher-heat capacity and density than nitrogen, and does not contaminate furnace off-gas.
The parent invention is also embodied in preferred apparatus for carrying out the process. mis apparatus includes an elongated,`gently sloped, oscillable, rounded cross-section sealed furnace having discharge means at one end for a non-ferrous metal-rich phase and discharge means at the other for ,- -slag and a discharge for off-gases at the slag discharge end.
m e sealing of the converter is important to prevent air ingress and/or sulfur dioxide leakage. me vessel is sloped at less than 5 downwardly towards the metal-rich product discharge end and its bottom is stepped to provide a pool or reservoir at one end ' ' ~' - 8 - ~
- . . . . . .
.
bottom is stepped to provide a pool or reservoir at one end for the metal-rich product and toward the other end for slag separa-tion. Means are provided for feeding concentrates and flux optionally with oxygen through the top onto the surface of the bath. Injectors extend through the refractory lining of the `
furnace through openings communicating with the interior of the furnace beneath the surface of the liquid. The injectors are equipped for blowing a protective gas during the introduction of the oxygen into the molten metal, along with the oxygen so as to protect the injectors and the surrounding refractories. There is means for oscillating the furnace slowly, e.g. through 200 to 40 and at 1 to 6 reciprocations per minute and for tilting it, e.g. through 75 for servicing the injectors. All feed and discharge connections are such that they permit this oscillation and tilting. Suitable means are provided for metering, regulat-ing, and analyzing the feed and product materials to effect appropriate control as described herein.
The invention to which the present application is `~
directed relates to a process for treating slag containing non-ferrous metal values to recover such values therefrom in the form of metal sulfides. According to this method, a bath of liquid slag is established in a sealed refractory-lined vessel which is preferably non-rotary and may be tiltable. A carbon-aceous reducing agent, sulfur dioxide, and oxygen are directed upwardly through the slag bath in amounts effective to create strong reducing conditions in the slag to form metal sulfides in said slag. The metal sulfides are separated from the slag.
The accompanying drawings illustrate preferred embodi-ments of the parent invention and the present invention. In the drawings:
_ g _ - . ,: . . . : -Figure 1 is a schematic diagram showing an elongated kiln-like vessel, of preferred configura-tion, in which the treatment of the inven-tion may be carried out, Figure 2 is a vertical cross-section along the line 2-2 of Figure 1, and Figure 3 is an equilibrium diagram which illustrates desirable relationships between physical-chemical variables in the preferred sequen-tial converting process of the invention.
..
1~)45830 Referring more particularly to Figure 1, a preferred treatment vessel is shown in the form of an elongated, gently sloped, rounded cross-section sealed furnace A which serves as a trough for a molten bath. The vessel is provided internally with a refractory lining which is stepped inwards at 13 and the vessel is stepped outwards as at 4. An intermediate step may be included if required. The furnace walls may have heat exchangers, e.g. steam tubes, evaporative air cooling tubes:
water jackets:i to suit the process conditions. Suitable mechanisms are provided for introducing feed, e.g. sulfide materials and fluids. Introducing the sulfide materials above the surface of the molten bath avoids the refractory degrada-tion and other difficulties which result from their introduction beneath the surface.
The vessel A is mounted for oscillation about its longitudinal axis, for example, through about 30 and is tilt-able, for example, through about 75 to permit maintenance, for example, of the injectors.
With the process in operation the molten bath will layer out into a matte M, a slag S and a pool of crude molten copper C.
Copper sulfide concentrates and oxygen are mixed and introduced in staged ratios through several inlets, e.g. vortex sprayers, at 6, with minimal oxygen introduction at the entry closest to the slag scavenging operation, and flux is intro-duced through inlets as at 7, into the atmosphere above the molten bath. Oxygen, shielded by sulfur dioxide, is blown into the converter A below the matte-slag interface through the several injectors at 8 extending through the refractory lining of the vessel. The staged injection of oxygen at 8 progres- -sively oxidizes the matte as it flows toward the copper dis-charge end, with formation of increasingly copper-rich matte 1~4S830 and finally crude copper. Simultaneously, the iron silicate slag formed flows countercurrently toward the slag discharge end. The sulfur dioxide-rich gas evolved passes concurrently over the slag on its way to the gas outlet 9 equipped with a labyrinth seal.
According to the present invention, there is introduced through the injector 10 beneath the surface of the slag and directed upwardly therethrough, a carbonaceous reducing agent, for example, coal, sulfur dioxide and oxygen in amounts suffi-cient to establish strongly reducing conditions and controlled bath turbulence. The resulting deconverting reaction scavenges the slag by formation in situ of metal sulfides, for example, cupriferous iron-sulfide. Simultaneously, the slag is optionally washed with a finely divided iron sulfide introduced, preferably as a shower, at the inlet 11 which further depletes the slag of its copper content. Finally the slag flows slowly through a calm pool to the slag discharge 12. ~he low grade matte which settles out of the slag flows countercurrently toward the copper discharge end. -As the procedure described is taking place, the re-actor is oscillated slowly through 30 at three reciprocations per minute. The oscillation increases gas-liquid-solid contact ~ -for effective heat and mass transfer.
The injection of the commercial oxygen, sulfur dioxide and other gases as the reactor is reciprocated causes these gases to enter the molten bath at continuously different angles to its surface and thus reaches constantly changing parts of the bath, with resultant turbulence of both chemical and physical origin. ;
Simultaneously, the copper-rich matte fraction flows towards the copper discharge end and the iron silicate-rich slag fraction to-wards the slag discharge end, so that in the longitudinal direc-tion fresh bath is being continuously subjected to advantageous gas-liquid and liquid-liquid contact.
' ~:
: :. - . - . : :
, ~',- , . - . . ~ ' . :
Also, as the reactor is reciprocated back and forth the concentrates and flux are fed into the atmosphere above the surface of the bath. secause the position of the feed entries is changing continuously with respect to the surface of the bath, the solids are distributed across its surface. Also, since the atmosphere above the bath is flowing towards the slag discharge end, the concentrates and flux fed are moving through the atmosphere transversely to its flow bringing about advan-tageous gas-solid contact. In sum, intimate interphase contact is achieved, bringing about efficient conversion of the concen-trates to crude copper, low copper-containing slag and sulfur ~-dioxide-rich gas.
The process may be started by first slowly heat soak-ing the refractories to about 1300C by the use of a fuel ~-burner at port 3. Then concentrates may be introduced, e.g.
partially flash converted for the time required to build up a shallow bath, maintaining enough gas flow, e.g. sulfur dioxide, through the injectors, to protect them, followed by normal operation of the converter. Alternatively, after refractory heat-soaking, matte may be poured into the furnace, followed by normal operation.
The reaction is autogenous and the operating tempera-ture is maintained by the exothermic reaction, within a range effective to keep the metal and slag satisfactorily fluid and maintain high reaction rates, for example, within the range from about 1000C to about 1650C. Preferably the oxidizing conditions will vary progressively and sequentially within the converting region.
Process ~ontrol Some of the qualitative aspects of the metallurgical control of a continuous converter will be apparent to those -~
skilled in standard batch converting. However, the continuous 1~)45830 process embodied in this invention provides, in addition, a number of highly flexible operating controls which are used in concert to establish and maintain a steady state of staged con-verting providing optimum metallurgical performance for wide ranges of compositions of sulfide concentrates and converter products. Primary stoichiometric control is based on metering and proportioning the total feed rates of sulfide concentrates, fluxes, and oxygen to obtain continuous production of a crude metal or low-iron matte product, a waste slag carrying substan-tially all the iron along with a sufficiently high content ofsilica and other fluxing oxides to give desirable slag proper-ties, and an S02-rich effluent gas containing a small excess - of oxygen. Short term fluctuations in the chemical composi-tions and converting behavior of the solid feed materials, or other divergences from the desired steady state proportioning o~ the total input materials will be absorbed by accumulation or depletion of the matte and/or metal layers in the converter, these layers thus serving as a large stabilizing reservoir within the furnace. Accordingly, stoichiometric control of the ratio of total oxygen input to total input of sulfide con-centrates is facilitated by appropriate monitoring of the depth of the matte layer in the apparatus.
; The distributions of oxygen inputs and sulfide con-centrate inputs among their respective points of feeding along the length of the converter are regulated, as already mentioned, to establish the appropriate gradients of chemical conditions along the converter. More specifically, the ratio of oxygen to sulfides is at a minimum near the slag scavenging section with much less oxygen being fed than required to fully convert the sulfides being added in that section. A convenient practical criterion for making these adjustments is the ratio of ferric iron to total iron in the slag, which is determined by slag ::, -. - . ~ : . . . ~ , . . : ,, :
sampling and analysis. The optimum range for a given operation is established by trial, but a typical range in converting copper sulfide concentrates at 1300C is from a ferric iron:
total iron ratio of 0.2 or higher at the metal discharge end down to 0.06 at the waste slag discharge end.
In the slag scavenging section, the quantities of iron sulfide, coal, S02, and 2 are adjusted to cause the continuous formation, within the slag layer, of low grade matte, e.g. less than 20% Cu, which settles through the slag and cleans the value metal from the slag to a low level before the slag is discharged from the furnace. The oxygen injected with the coal provides partial combustion of the coal, for formation of a hot, strongly reducing gas and localized heating to meet thermal requirements ; of the deconverting reactions. As already pointed out, the -~ ratio of ferric iron to total iron provides a useful operating criterion for guidance in the adjustments of input materials into the slag scavenging stage and this ratio preferably is brought substantially to a minimum by such adjustments.
A wide range of temperature control is available to the operator, independently of the proportioning of oxygen and sulfide, by varying the quantity of the recirculated S02.
Further flexibility is available, as needed, by the use of water or by the substitution of hydrocarbon shielding fluids for S02 or by varying the temperature of the S02. Through all these means, the opèrator can readily control the temperature, at high level, throughout the converter, e.g. so that the fluid high silica slag needed for rapid reaction and clean separation r ~. '. . .
is achieved, without localized overheating and resulting exces-sive erosion of injectors and refractories.
The various product streams are monitored continuously, using on-stream or rapid analysis instrumentation. Also, the temperatures are continuously determined along the length of .'' : . ' . :. ., . .
1~45830 the converter.
When fixation of all the sulfur in the converter off-gas - for instance mainly as elemental sulfur - cannot be justi-fied, the applicants' preferred alternative is to treat the gas by what they term "deconverting". In this operation, carried out in a separate apparatus, the S02-rich off-gas is injected, together with carbonaceous reducing agent and commercial oxygen, into the molten waste iron silicate slag from the converter so as to fix most of the sulfur in the gas as liquid iron sulfide.
This may be cast and stockpiled to conserve both the sulfur from the gas and the irpn from the slag for further consumption.
A fraction of the liquid iron sulfide may be granulated in water and recycled to the converter for slag cleaning purposes. If it is desired to fix substantially all of the sulfur in this form, additional iron required can be supplied by feeding the decon-verting furnace any suitable iron source material, e.g. scrap such as junk automobiles, or other slags. Judicious amounts of lime can, of course, be employed to maintain slag fluidity.
Sulfur fixation in this matter represents an extension of the slag cleaning procedure utilized in the continuous oxygen converter, and thus can be carried out in a continuously opera-ting furnace of quite similar design, with appropriate injection of oxygen,- sulfur dioxide, and carbonaceous reducing agent.
Those skilled in the art will recognize that deconverting, using SO2-rich gas, can also be carried out in other apparatus, quite similar to the water-jacketed slag fuming furnaces commonly used in treating slags, with pulverized coal and air mixtures, for other purposes, e.g. zinc recovery.
Physical-Chemical Variables The equilibrium diagram of Figure 3 illustrates the relationship among some of the most important physical-chemical variables at various stages of the applicants' sequential copper - ... . , :
iO4~830 converting process. Following common practice among chemical metallurgists, the oxygen activity is measured by log (Pco /Pco), and the temperature is measured by the reciprocal of absolute temperature. The minimum oxygen activity required to form metallic copper from white metal copper sulfide, at a given temperature, is shown by the line at the top of the Figure. If an iron silicate slag with FeO activity (aFeO) equal to 0.35 is present, on the other hand, the oxygen activity at a given tem-perature must be kept below the line corresponding to solid magnetite formation. The succession of lines for different values of iron sulfide activity correspond to successive stages of converting, because the copper content of the matte increases as the activity of iron sulfide decreases. The conditions corresponding to low grade mattes and to low metal contents in the waste slag lie just above the line for aFeS equal to 1Ø
Figure 3 also depicts the reversibility of the prin- ;
cipal converting reaction:
FeS (matte) + 2302 (gas) ~ FeO (slag) + S02 (gas) If the oxygen activity is maintained below the line for aFeS equal to 1 - by using an appropriate reducing agent -then SO2 gas at atmospheric pressure will react with the FeO and copper, nickel and cobalt oxides, in the slag, to form a non-ferrous metal-bearing iron sulfide, the reverse of the usual converting reaction. It seems appropriate, therefore, as has been done in this disclosure, to term these reactions "decon-verting".
Examples of deconverting reactions, utilizing carbo-naceous reducing agents and sulfur dioxide are as follows:
S2 + FeO ~slag) + 3C ~ FeS (matte) + 3CO
SO2 + FeO (slag) + 3CO ~ FeS (matte) + 3C02 S2 + Cu2O (slag) + 3C > Cu2S (matte) + 3CO
To achieve the low levels of slag oxygen activity re-:: :
.
1045830 :
quired for deconverting, it is necessary to reduce slag ferric oxide content to a relatlvely low level by use of a reducing agent. For example, if at 1350C a slag oxygen activity equi-og (PCo2/pco) of 0.5 is desired - so as to be below the line for aF S = 1 in Figure 3 - the proportion of ferric iron present must be less than 6% of the total iron content of the slag.
Thus, a major achievement of the present invention has been to provide a process embodying a progressive and controlled sequence of oxygen and other activities, ranging in a systematic fashion from the high oxygen activity necessary to oxidize the great bulk of the iron and sulfur in the feed so as to discharge a product high in metal value at one end of the converter, down to the low oxygen activity required at the other end of the vessel to discharge a slag low in metal values.
For the specific conditions represented in Figure 3 and for an operating temperature of approximately 1600 degrees Kelvin (1327C), the general range of oxygen activities to be ~
established and controlled is from a C02/C0 ratio of about 100:1 -down to a C02/C0 ratio of about 5:1, corresponding to a 400-fold range in activity of 2 In order to achieve such a range of oxygen activities in a continuous, substantially steady state ~ -reactor, it is necessary to supply oxygen at a pressure above that corresponding to C02/C0 = 100 and to provide a reducing agent capable of lowering the C02/CO ratio below 5. Thus, when all process needs are taken into account, in the case of copper concentrate treatment, full realization of the thermodynamic process model requires positive and effective control of oxygen activity over as much as a 1000-fold range.
The thermodynamic feasibility of an equilibrium model, though an essential requirement, is, of course, not sufficient to demonstrate the feasibility of a large scale continuous 1~J4~830 pyrometallurgical process. The applicants' design is also based on stoichiometric and thermal balances among the interacting streams of solids, liquids, and gases flowing through the system.
Appropriate residence times and fluid flow conditions have been provided to achieve the necessary heat and mass transfer. The applicants' apparatus also has the physical configurations and capabilities needed to meet process requirements efficiently including control of essential operating variables. Thus, the converter can be designed for a very high capacity, adequate for single unit treatment of several thousand tons of solid charge daily. Important information relevant to these considerations is available in the technical books written or edited by the applicants over the past two decades. The applicants' appre-ciation of the difficulties and shortcomings of existing pyro-metallurgical practices, and their study of the attempts of others to solve these problems has led to the improvements over the prior art detailed in this disclosure.
Particular Concentrates The concentrates treated are those which contain enough iron and sulfur to be substantially autogenous when re-acted with oxygen-rich gas. Typical preferred analyses are contained in the following examples. The invention also con-templates that some or all of the sulfide feed material may be a pelletized wet concentrate, e.g. 8% free moisture, or even a concentrate slurry with water, e.g. 75% solids.
The invention is particularly useful in the recovery of nickel and cobalt from pentlandite concentrates. The con-centrates are treated in the applicants' continuous oxygen converter for production of matte containing a large proportion of the nickel and cobalt in the concentrate and a slag contain-ing a large proportion of the iron and a gas high in sulfur dioxide. The cobalt is removed from the discharged molten matte, . ~ . ..... - : :
1~)4S830 for separate recovery. This may be through its conversion to ~ -chloride by reaction of the liquid sulfides with gaseous chlorine or by solvent extraction, using a molten salt mixture of sodium and nickel chlorides. The thus cleansed molten matte may then be fire refined to metallic nickel in a bottom-blown, non-rotary converter which is sealed and tiltable, using gas-protected injectors to blow commercial oxygen through the matte or metal from below the liquid surface, employing hydrocarbon gas shielding of the oxygen during the final stages of the blow.
The invention may also be advantageously employed in ~ -treating copper-nickel or cupro-nickel concentrates accord1ng to the invention to form a metallic copper-nickel alloy as the metallic phase. The alloy may be dissolved by aqueous chlorina-tion and the dissolved metal chlorides subjected to solvent -extraction for copper and nickel isolation and, pure copper and nickel may be recovered from the aqueous extracts by electro-winning.
In converting lead sulfide concentrates into lead, according to the invention, the following procedure may be employed. The lead concentrates are dropped continuously onto the surface of a slag covered molten lead bath in a sealed con-verter, of the type described herein, which is continuously blown with commercial oxygen employing submerged fluid-protected injectors. There is thus produced continuously a substantially zinc-free bullion and a sulfur dioxide-rich gas. The slag produced is continuously fumed in the converter by injection of carbonaceous material for the production of a low lead and low zinc-containing slag. The lead in the converter gas particu-late matter may be continuously recycled.
Certain principles of the invention may be applied to - -producing copper, nickel, or cupro-nickel from their substan-tially iron-free sulfides. For example, there may be introduced - 19 - ~
-, . ...... .
1~4S830 below the surface of the molten bath of the sulfides contained in a tiltable sealed bottom-blown non-rotary converter an oxygen-rich gas having an oxygen content sufficient for autogenous con-version of the sulfides to metal. According to the invention, the gas is blown through the bath by means of appropriately positioned fluid-protected injectors extending through the re-fractory wall of the converter to openings in its lower part below the bath surface. Pneumatic bath turbulence is thus created for effective interphase contact. The gas flow rates are regulated so that bath temperature is maintained at uniform controlled levels effective for high reaction rates between oxygen and sulfur and so that the quantity of oxygen reacted is only about the stoichiometric amount necessary to convert sub-stantially all the sulfur present in the bath to sulfur dioxide.
According to the present invention, the protective fluid for the oxygen injectors is sulfur dioxide or water or both, until the sulfur content of the bath is less than about 5%, and then a hydrocarbon gas may be employed as shielding fluid for the re-mainder of the blow.
Gases The term "commercial oxygen" is defined as a gas normally having more than 90% free oxygen and it is preferred to employ commercial oxygen. The use of such oxygen permits, in addition to S02-rich gas production, furnace operation at ~
temperatures higher than conventional, with accompanying ~-kinetic and operating advantages in high reaction rates and in ~
control of matte and slag fluidity, provided the metal injectors ~ -and surrounding refractories are protected, as taught herein, from the increased temperatures. With some concentrates, an autogenous process may be carried out using oxygen-enriched air, containing down to as little as 40% oxygen, although introducing such large proportions of nitrogen into the system may be unde-sirable for environmental and other reasons. This is a higher 1~45830 oxygen level than normally tolerated by the standard Pierce-Smith converter, which suffers from over-oxidation and over-heating near the tuyeres and from relatively poor interphase contact, poor temperature distribution, and limited control of oxygen activity.
In the applicants' process, the furnace off-gas normally has a sulfur dioxide content over 70% dry basis and ~-preferably over 80%, and is substantially free of nitrogen oxides. Converter off-gas is passed through steam raising boilers for power generation purposes. It is then suitably cleansed of substantially all of its particulate matter con-tent, and most of the copper, nickel or lead in the latter recycled to the process. The sulfur dioxide injected into the converting operation is normally recycled converter off-gas.
The amount of S02 added, as a protective fluid, or otherwise will range from about 0 to about 150% by volume of the oxygen, measured at standard normal temperature and pressure, that is at 0C and one atmosphere of pressure.
Water may be added as an atomized fog in an amount within the range from 0 up to 25% by weight of the oxygen. The water may be added in the oxygen stream, in a shielding gas stream, or -both.
Slag A further advantage of the applicants' method and apparatus, with the flexible controls described, is the ability conferred to readily produce, when desired, ferrous silicate slags at higher than conventional temperatures, for example, over 1300C and at higher than conventional silica contents, e.g. over 39% silica, with consequent lower than conventional copper, nickel, or cobalt losses owing to the satisfactory fluidity of the slags, their low density and low ferric iron concentration.
., : ., : . .
. , , ' ~' - ~' 1~45830 Products The end product from copper sulfide concentrates may be a crude metal with a copper content of over 95% and an iron content of less than .2%, a sulfur content of less than 2% with a copper recovery of over 98~, or the process can produce a matte of over 7~% copper, less than 2% iron and the balance sulfur and impurities, again with a copper recovery of over 98%.
In the case of nickel, the end product may be a crude metal over 90~ nickel, less than 1% iron, less than 5~ sulfur for a nickel recovery of over 95%; or a matte of over 65% nickel, less than 5% iron with a cobalt recovery of over 75%. In either case the nickel recovery will be over 95~0. In the case of lead, the end product may be a bullion of over 95% lead, less than 1%
iron, less than 1% sulfur, with recovery of over 95~ of the lead.
Oxygen Injection The submerged oxygen inJection, employed by the appli-cants, for converting, involves blowing fluid protected oxygen-rich gas into a molten bath through the refractory wall of a converter below the liquid surface. In certain applications of the present invention, such fluid protection may be similar to the general Savard-Lee concept disclosed in French Patent 1,450j718 (1966), According to that concept, metal is refined, in batches, by blowing commercial oxygen into a molten bath through injectors extending through the refractory lining of a standard converter and having openings communicating with a lower part of the vessel beneath the metal surface. The injectors and surrounding refractories are protected, by surrounding the oxygen stream with a shielding hydrocarbon.
Contrariwise, for continuous converting of sulfide concentrates, in their special converter, the applicants ;'~
'' . ~''' ., ': ' ' , , 1~4S830 :
normally prefer to employ the non-combustible gas, sulfur dioxide, -as protective fluid. Also, when desirable for additional cooling purposes, the applicants may use atomized water in the central oxygen stream; also, atomized water may be introduced into a shielding fluid. In appropriate circumstances, either sulfur dioxide or atomized water, or both, is introduced into the oxygen stream as an alternative or supplement to their use in a surrounding shielding fluid. The oxygen may be blown in a direction from substantially horizontal to vertically upward.
The preferred process of the invention has been de-scribed as a continuous process made up of an integrated com-bination of steps and control features providing the special results described. Such combination includes, for example, the continuous process in which the metal-rich phase and the slag phase flow countercurrently, the slag and gas phases flow con-currently, and there are sequential stage converting and slag cleaning steps and, in which the vessel is oscillated. Some of ~-these and other expedients of the preferred process are in them-selves new and can be employed without other aspects. For instance, using submerged oxygen injection as described might -be employed with other continuous slag cleaning expedients.
Likewise, the slag scavenging or deconverting stage, as descri-bed, could also be applied to a molten slag bath resulting from ~-other than the applicants' converting stage. While oscillation of the vessel provides preferred effects, acceptable results ; could be achieved without oscillation of the vessel.
The applicants' apparatus can be dified for use in discontinuous copper or nickel matte converting or fire refining operations, e.g. in a bottom blown non-rotary tiltable sealed converter, using fluld protected in~ectors to blow commercial oxygen directed upwardly or substantially horizontally, i.e.
less than about 10 below the horizontal through the matte or , . . .
- . , :
. . , , ~ ~ . . .:
1~45830 metal from below the liquid surface. The applicants' apparatu~
can be also modified for continuous iron-making and for the continuous oxygen converting of pig-iron into steel.
The present invention meets the need for a simple, flexible, economic continuous converting process with a superior capability for environmental conservation which is lacking in prior art proposals. Losses of value metals incurred by usage of the novel continuous single furnace unit are less than half those associated with conventional pyrometallurgical practice.
Also, the cost of process off-gas treatment for sulfur fixation -either as iron sulfide or as elemental sulfur - is less than half that of similar fixation of sulfur in the off-gases from con-ventional practice. A main target of the applicants' invention is maximum utilization of the ore within boundary limits imposed by the market place on which the prior art fails to focus -adequately. The use of applicants' method and apparatus permits simultaneously increased unit metal production capacity, de-creased metal production costs, increased recovery of valuable components of the ore, and decreased environmental degradation.
Specific examples of preferred procedures will now be given to illustrate the invention in more detail.
Example 1 One thousand metric tons per day of copper sulfide concentrates analyzing 28% Cu, 28% Fe, 30% S, 7% SiO2 (dry basis) and containing 1% water, are continuously stage fed into ~ ~
a 6 meter X 36 meter converter constructed and operated in the ~ -manner indicated for Figure 1, are flash converted at about -~
1330C with 320 tons per day of flux analyzing 78% SiO2 (dry basis) and containing 5% water, and 280 tons per day of commer-cial oxygen analyzing 98% 2' 2% argon. ~he rates of both oxygen and concentrate introduction are judiciously controlled at the several vortex spray entries, the ratio of oxygen mixed , :. . . : : . ~ .
.: . , . , :
16)4S830 with the concentrate introduced increasing progressively from minimal at the entry closest to the slag scavenging region, to a maximum at the feed entry closest to the metallic copper pro-ducing region. Water in the additional amount of 50 tons per day is introduced into the converter atmosphere for temperature control purposes. The molten matte so produced is blown in controlled stages at about 1330C by injection of 135 tons per day of commercial oxygen and 320 tons per day of sulfur dioxide as surrounding shielding gas and progressively oxidized to metallic copper in a controlled sequence of steps. 284 tons per day of crude copper analyzing 98% Cu, 0.1% Fe, 1% S are continuously discharged from the converter as indicated on Figure 1. This product contains about 99% of the copper in the sulfide concentrate fed to the converter. The molten slag pro-duced by these operations is scavenged at about 1330C by in-jection of 43 tons per day of a mixture of subbituminous coal,(dry) sulfur dioxide and oxygen in approximately a 3.5:3:1 weight ratio.
Concommitantly the slag is washed by a shower of 25 tons per day of iron sulfide, following which the slag is settled in a calm pool and then continuously discharged at the rate of 800 tons per day in a stream analyzing 0.2% Cu, 35% Fe, 40% SiO2.
This product contains substantially all of the iron in the sulfide concentrates fed to the converter. The gas from the conversion operations is discharged continuously at a tempera-ture of about 1330C and at a rate of 645 tons per day in a stream analyzing 88% S02, 9% C02, 2% Ar, 1% 2 (dry basis).
This product contains over 90% of the sulfur in the sulfide concentrate fed to the converter and is free of nitrogen oxides.
The hot gas flows to boilers for steam raising and power genera-tion and then to dry electrostatic precipitators, wet scrubbersand/or bag filters for dust recovery. Controlled fractions of the collected particulate material and cleaned gas are bled out - ~ . . , ~, 1~4~i830 for appropriate treatment and disposal, and the balance is re-cycled to the converter.
Example 2 A pentlandite concentrate analyzing 15% Ni, 0.6% Co, 40% Fe, 30% S, 10% SiO2, is treated in the applicants' con-tinuous oxygen converter for production of matte analyzing over 65% Ni, and containing over 95% of the nickel and over 75% of the cobalt in the concentrate, of a slag containing over 95%
of the iron in concentrate, and of a gas analyzing over 75%
S02 (dry basis) and containing over 75% of the sulfur in the concentrate. The cobalt is removed from the discharged molten matte, for separate recovery, through its conversion to chlo-ride by known procedures, e.g. by reaction of the liquid sulfides with gaseous ehlorine or by solvent extraction using a molten salt mixture of sodium and niekel ehlorides. If desired, the thus eleansed molten matte is then fire refined to metallic niekel in a bottom blown non-rotary eonverter whieh is sealed and tiltable, using gas proteeted injeetors to blow eommereial oxygen direeted upwardly through the matte or metal from below the liquid surfaee, employing hydroearbon gas shielding of the oxygen during the final stages of the blow.
In the ease of niekel, there ean be produeed anything from niekel-rieh matte, e.g. niekel sulfide eontaining more than 65% niekel and less than 5% iron and in which most of the Qobalt in furnace feed is recovered, to erude niekel metal eontaining less than 5% sulfur and less than 1% iron.
Example 3 A eopper-niekel concentrate of the following analysis is treated in a continuous oxygen eonverter similar to that deseribed herein and shown in Figures 1 and 2: 16% eopper, 4%
niekel, 32% iron, 27% sulfur and 10% siliea. There is produeed (a) metallie eopper-niekei alloy analyzing over 98% eombined - . - . ... .. . . :.
1~)45830 copper and nickel and less than 2% combined iron and sulfur and containing over 98% of the combined copper and nickel in the sulfide concentrate, (b) a slag containing over 98% of the iron in the sulfide concentrate, and (c) a gas analyzing over 80%
sulfur dioxide (dry basis) and containing over 90% of the sulfur in the sulfide concentrate fed to the converter. Only when the copper in the concentrate amounts to over about 70% of the combined copper-nickel content, will a metallic phase separate from and sink below the matte during the converting operation.
The metallic copper-nickel alloy product is dissolved by aqueous chlorination, the dissolved metal chlorides are subjected tc solvent extraction for copper and nickel isola-tion, and pure copper and nickel metals are recovered from the aqueous extracts by electrowinning.
Example 4 Lead concentrate, analyzing 72% lead, 3% zinc and 17%
sulfur and fluxes are introduced continuously into the converter as plus 4 mesh galena pellets, to prevent gas or slag suspension of the particulate lead sulfide containing material, and dropped on top of a slag covered lead bath which is bottom blown with oxygen employing fluid-protected injectors for production of a substantially zinc-free lead bullion analyzing over 95% lead and less than 1% sulfur, and containing over 95% of the lead in the concentrate, and a gas analyzing over 70% sulfur dioxide (dry basis) and containing over 90% of the sulfur in the con-centrate. The slag produced is continuously fumed in the con-verter, by coal injection, for lead and zinc recovery, and lead in the converter gas particulate matter is recycled.
., , . :
- ' ' ~'. .,~':
Claims (2)
1. A process for treating liquid slag containing non-ferrous metal values to recover such values therefrom in the form of metal sulfides, characterized in that (a) a bath of such liquid slag is established in a sealed refractory-lined vessel:
(b) a carbonaceous reducing agent, sulfur dioxide, and oxygen are directed upwardly through said slag bath in amounts effective to create strongly reducing conditions and to form metal sulfides in said slag; and (c) said metal sulfides are separated from said slag.
(b) a carbonaceous reducing agent, sulfur dioxide, and oxygen are directed upwardly through said slag bath in amounts effective to create strongly reducing conditions and to form metal sulfides in said slag; and (c) said metal sulfides are separated from said slag.
2. A process, as defined in Claim 1, in which the vessel in which the bath of slag is formed is tiltable.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US05/357,012 US3941587A (en) | 1973-05-03 | 1973-05-03 | Metallurgical process using oxygen |
| CA195,116A CA1027374A (en) | 1973-05-03 | 1974-03-15 | Metallurgical process using oxygen |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1045830A true CA1045830A (en) | 1979-01-09 |
Family
ID=25667516
Family Applications (2)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA297,209A Expired CA1045831A (en) | 1973-05-03 | 1978-02-17 | Metallurgical process using oxygen |
| CA297,210A Expired CA1045830A (en) | 1973-05-03 | 1978-02-17 | Metallurgical process using oxygen |
Family Applications Before (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA297,209A Expired CA1045831A (en) | 1973-05-03 | 1978-02-17 | Metallurgical process using oxygen |
Country Status (1)
| Country | Link |
|---|---|
| CA (2) | CA1045831A (en) |
Families Citing this family (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114538545B (en) * | 2022-01-21 | 2022-08-23 | 王志梅 | Two state shunt extension contact type waste liquid filtering and sampling device for surgical drainage |
-
1978
- 1978-02-17 CA CA297,209A patent/CA1045831A/en not_active Expired
- 1978-02-17 CA CA297,210A patent/CA1045830A/en not_active Expired
Also Published As
| Publication number | Publication date |
|---|---|
| CA1045831A (en) | 1979-01-09 |
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