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EP0530893B1 - Method for continuously melting metallic lead - Google Patents

Method for continuously melting metallic lead Download PDF

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Publication number
EP0530893B1
EP0530893B1 EP92202548A EP92202548A EP0530893B1 EP 0530893 B1 EP0530893 B1 EP 0530893B1 EP 92202548 A EP92202548 A EP 92202548A EP 92202548 A EP92202548 A EP 92202548A EP 0530893 B1 EP0530893 B1 EP 0530893B1
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EP
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Prior art keywords
lead
slag
phase
primary
zone
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EP92202548A
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German (de)
French (fr)
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EP0530893A1 (en
Inventor
Lutz Dr. Deininger
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GEA Group AG
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Metallgesellschaft AG
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B13/00Obtaining lead
    • C22B13/02Obtaining lead by dry processes

Definitions

  • the invention relates to a process for the continuous melting of metallic lead from noble metal-containing and lead-containing precursors.
  • Lead ores practically always contain silver and in many cases gold and platinum. Precious metals can also be contained in lead-containing intermediates or waste. In the pyrometallurgical extraction of lead, the precious metals go into the lead. After refining to remove copper, nickel, cobalt, tin, arsenic and antimony, the removal and extraction of the noble metals from the pre-refined lead lead is generally carried out using the Parkes process. Excess zinc is introduced into the liquid lead and silver-zinc-lead mixed crystals are precipitated by cooling, which are skimmed off as so-called foams or crusts from the lead bath. These foams also contain the other precious metals.
  • the excess zinc present in the desilvered lead is removed either by the Harris method by adding NaOH, by the Betterton method by chlorination or by vacuum dezincification.
  • the zinc is mechanically adhered to the foams by pressing or segregation and the zinc is removed by distillation and the so-called rich lead is produced, which contains the precious metals in high concentration.
  • the rich lead which can contain up to about 50% silver
  • the lead is oxidized to PbO in the so-called propellant process by selective oxidation with air and drawn off as a liquid smoothness, leaving behind the silver or guildish silver.
  • the Güldisch silver is then subjected to refining electrolysis.
  • a method for lead extraction in which a mixture of oxidic and sulfidic lead compounds in a first stage in a moving furnace, e.g. a rotary kiln is melted down, whereby in addition to primary lead, a high-lead-containing slag is formed, which contains the lead partly as an oxide and partly as a silicate. Lead and slag are withdrawn from the first stage, the slag being extracted in pieces. In a second stage, the slag is melted in a shaft furnace to reduce it, resulting in a low-lead slag and secondary lead. Precious metals in the feed go into the primary lead almost quantitatively.
  • Part of the primary lead obtained in the first stage can be oxidized again and form the feed for the first stage as an oxidic component with fresh amounts of sulfidic ore.
  • the silver contained in the primary lead is enriched in a small amount of lead so that it can be directly subjected to the driving process.
  • This process relates to a batch process in which the slag tapped from the first stage has to be melted down again in the second stage.
  • the lead tapped from the first stage must be oxidized in order to produce a lead worthy of driving.
  • a method for processing lead, copper and sulfur-containing materials in two separate stages is known, a copper stone phase and a lead-containing primary lead phase being formed in the first stage.
  • the separated slag phase is reduced in a second stage, with low-lead slag and secondary lead as well as possibly a cobalt-containing arsenic alloy.
  • Both stages can be carried out in shaft furnaces, flame furnaces, short drum furnaces, head-blown rotary converters or bottom-blown tilting converters.
  • Arc resistance furnaces are specified as advantageous units.
  • Most of the leading silver is accumulated in the first stage in the primary lead and in the copper stone.
  • the lead content of the slag in the first stage is set at 20 to 40%.
  • the silver content of the lead is largely in the copper stone and the primary lead.
  • the silver content of the primary lead is less than 1%, so that the primary lead has to be subjected to the usual refining in order to obtain the silver.
  • this method is only intended for copper-rich lead materials.
  • the precursors can be in any form, for example as oxides, sulfides, sulfates, silicates. It is also possible to add or use metallic raw materials such as computer scrap, in which case additives for the formation of slag may then have to be added. If the precursors do not contain any fuel, for example in sulfidic form, or if their fuel content is insufficient to cover the heat requirement in the oxidation zone, the required fuel is added to the oxidation zone in solid, gaseous or liquid form. The fuel can be added by means of nozzles from below or laterally into the melt and / or into the gas space or with the feed mixture.
  • the metal phases in the oxidation zone and the reduction zone are separated from one another by a partition arranged on the bottom of the reactor.
  • the slag flows from the oxidation zone through this partition or through an opening in the partition into the reduction zone.
  • the gas spaces of the oxidation and reduction zones can be separated from one another or the gas from the reduction zone flows into the oxidation zone and is used there for after-combustion to cover the heat.
  • oxygen-containing gases are blown into the lead phase from below or from the side.
  • the oxygen partial pressure in the oxidation zone is set so that only the desired amount of primary lead is obtained from the leading amount of lead and the remaining lead content is driven into the slag as oxide.
  • an appropriate rich lead with the desired silver content can be presented, then the oxygen partial pressure required for continuous operation can be set directly. If lead is presented when starting, an oxygen partial pressure must first be used, in which the lead is enriched with silver to the desired value and little or no primary lead is obtained. To When the desired concentration is reached, the oxygen partial pressure is then set to the value for continuous operation. The oxygen partial pressure is adjusted by regulating the ratio of the amount of oxygen blown in to the amount of the oxidizable constituents contained in the primary substances. If fuels are blown into the melt, these must be taken into account. Oxygen, oxygen-enriched air or air can be used as the oxygen-containing gases.
  • the silver content in the primary lead can be increased to such an extent that, for example, Güldischsilver is obtained with a high silver content in the primary materials.
  • the secondary lead phase is located under the slag phase in the reduction zone.
  • the reducing agent is blown into the lead phase from below or from the side and flows from there into the slag phase and then into the free reactor space.
  • Carbon-containing solid, liquid or gaseous materials are used as reducing agents. They are blown in with oxygen-containing gases and at least partially converted to CO and possibly H2 in the lead phase, so that a reducing gas from the lead phase enters the slag phase.
  • the combustible components can be post-burned in the escaping gas. If necessary, fuel is burned in the gas space of the reduction zone to cover the heat requirement.
  • the advantage of the method of operation according to the invention is that no classical enrichment by adding zinc, Seigers and distillation is required to remove the precious metals from the lead, but the primary lead can be used directly in the driving work. in addition, there is only a very small amount of precious metal in the cycle and / or intermediate products.
  • the secondary lead produced in the reduction zone is largely free of precious metals and does not require desilvering.
  • a preferred embodiment consists in that according to c) the oxygen partial pressure in the oxidation zone is controlled so that the melted primary lead has a silver content of at least 50% and the amount of primary lead is less than 5% of the leading lead content. This makes the extraction of the precious metals from the primary lead particularly economical.
  • the starting materials used contain sulfidic lead materials.
  • Sulfidic lead materials are primarily lead ore concentrates. They are processed in accordance with the QSL procedure, e.g. in U.S. Patent 4,266,971 and U.S. Patent 4,895,595. Other materials containing precious metals can be added to the lead ore.
  • the fuel required in the form of sulfide sulfur is already contained in the feedstock in a very uniform distribution, so that very good operating conditions result.
  • a preferred embodiment consists in that in the reduction zone carbon-containing reducing agents and oxygen-containing gases are blown into the secondary lead phase by means of nozzles and a level of the lead phase is set which converts the reducing agent to CO and, if appropriate, H2 of at least 50% in the lead phase before Entry into the slag phase causes.
  • the amount of oxygen introduced in the oxygen-containing gases is such that the reducing agent in the lead phase is converted to CO and possibly H2 in the desired percentage.
  • the education of H2 occurs when using hydrocarbons or through the implementation of volatile components that are contained in the coal.
  • the height of the lead phase required for the desired implementation of the reducing agent in the lead phase depends on the type of reducing agent and the oxygen-containing gas, the temperature of the lead phase and the strength and speed of the blowing jets.
  • the required height can, however, be determined relatively easily empirically for each operating case.
  • a protective gas can be blown in as a jacket gas in multi-component nozzles to protect the nozzle mouthpieces against severe erosion.
  • the CO and H2-containing reducing gas produced by the reaction is simultaneously heated up strongly in the metal layer and accordingly enters the slag at high temperature, creating very good reduction conditions. In addition, in the event of an incomplete implementation, this favors a further conversion to CO and H2 in the slag layer.
  • the height of the lead phase above floor-blowing nozzles is at least 4 cm and is preferably above 20 cm.
  • the QSL reactor has a length of 33 m, an inner diameter of 3 m in the oxidation zone and 2.5 m in the reduction zone.
  • a weir is arranged between the oxidation zone and the reduction zone, which mixes the lead phases of the oxidation and reduction zones prevents, but allows the high lead-containing slag to flow out of the oxidation zone into the reduction zone.
  • the reactor is equipped with six bottom-blowing nozzles in the oxidation zone and five in the reduction zone.
  • Technically pure oxygen is blown into the oxidation zone. Fine-grained coal, technically pure oxygen and nitrogen or natural gas or mixtures as a protective gas for the nozzles are blown into the reduction zone.
  • Secondary lead and slag are alternately tapped from the reduction zone, while a lead bath of approx. 250 mm is maintained.
  • the primary lead or rich lead is continuously withdrawn from the oxidation zone.
  • the exhaust gas from the oxidation zone and the reduction zone is drawn off together on the side of the lead of the oxidation zone.
  • Approx. 25 t / h of a feed mixture with 10% Ag, 40% Pb and the rest of the slag components are charged onto the slag layer in the oxidation zone.
  • the oxygen potential in the oxidation zone is adjusted by adjusting the amount of oxygen blown in so that 10% of the lead flow is obtained as primary lead and about 99% of the silver lead is collected in this primary lead.
  • a rich lead or raw silver with about 70% Ag is generated in the oxidation zone and drawn off from it.
  • the low-silver secondary lead with a silver content of approximately 0.01 to 0.02% and the slag are drawn off from the reduction zone.
  • the feed mixture corresponds to Example 1.
  • the oxygen potential in the oxidation zone is set so that 5% of the lead flow as primary lead accumulate and about 99% of the silver lead is collected in the primary lead. A rich lead or raw silver with about 83% Ag is produced.
  • Approx. 25 t / h of a feed mixture with 1% Ag, 40% Pb and the rest of the slag components are fed into the oxidation zone.
  • the oxygen potential is adjusted in such a way that about 10% of the lead lead is obtained as primary lead and about 99% of the silver lead is collected in this primary lead.
  • a rich lead with about 20% Ag is generated in the oxidation zone and drawn off from it.
  • the low-silver secondary lead with a silver content of approximately 0.01% and the slag are drawn off from the reduction zone.
  • the feed mixture corresponds to Example 3.
  • the oxygen potential in the oxidation zone is set so that 5% of the lead lead is obtained as the primary lead and about 99% of the silver lead is collected in the primary lead. A rich lead with about 32% Ag is produced.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Manufacturing & Machinery (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Manufacture And Refinement Of Metals (AREA)

Description

Die Erfindung betrifft ein Verfahren zum kontinuierlichen Erschmelzen von metallischem Blei aus edelmetallhaltigen und bleihaltigen Vorstoffen.The invention relates to a process for the continuous melting of metallic lead from noble metal-containing and lead-containing precursors.

Bleierze enthalten praktisch immer Silber und in vielen Fällen auch Gold und Platin. Auch in bleihaltigen Zwischenprodukten oder Abfällen können Edelmetalle enthalten sein. Bei der pyrometallurgischen Gewinnung von Blei gehen die Edelmetalle in das Werkblei. Nach einer Raffination zur Entfernung von Kupfer, Nickel, Kobalt, Zinn, Arsen und Antimon erfolgt die Entfernung und Gewinnung der Edelmetalle aus dem vorraffinierten Werkblei im allgemeinen nach dem Parkes-Verfahren. Dabei wird Zink im Überschuß in das flüssige Blei eingebracht und durch Abkühlen werden Silber-Zink-Blei-Mischkristalle ausgeschieden, die als sog. Schäume oder Krusten vom Bleibad abgeschöpft werden. Diese Schäume enthalten auch die anderen Edelmetalle. Der im entsilberten Blei vorhandene Überschuß an Zink wird entweder nach dem Harris-Verfahren durch Zugabe von NaOH, nach dem Betterton-Verfahren durch Chlorierung oder durch Vakuumentzinkung entfernt. Aus den Schäumen wird durch Abpressen oder Seigern mechanisch anhaftendes Blei und durch Abdestillieren das Zink entfernt und das sog. Reichblei erzeugt, das die Edelmetalle in hoher Konzentration enthält. Aus dem Reichblei, das bis zu etwa 50% Silber enthalten kann, wird im sog. Treibprozeß durch selektive Oxidation mit Luft das Blei zu PbO oxidiert und als flüssige Glätte abgezogen, wobei dann das Blicksilber oder Güldischsilber zurückbleibt. Das Güldischsilber wird dann einer Raffinationselektrolyse unterworfen. Bei höherem Gold- und Platingehalt im Werkblei kann durch Zugabe von geringen Mengen Zink der Gold- und Platingehalt vor der eigentlichen Entsilberung in einem Goldschaum angereichert werden, der nur wenig Silber enthält. Dieser Goldschaum wird dann separat zu Güldischsilber verarbeitet. Bei der üblichen Entsilberung muß also das gesamte Werkblei dem beschriebenen Verfahrensgang unterworfen werden.Lead ores practically always contain silver and in many cases gold and platinum. Precious metals can also be contained in lead-containing intermediates or waste. In the pyrometallurgical extraction of lead, the precious metals go into the lead. After refining to remove copper, nickel, cobalt, tin, arsenic and antimony, the removal and extraction of the noble metals from the pre-refined lead lead is generally carried out using the Parkes process. Excess zinc is introduced into the liquid lead and silver-zinc-lead mixed crystals are precipitated by cooling, which are skimmed off as so-called foams or crusts from the lead bath. These foams also contain the other precious metals. The excess zinc present in the desilvered lead is removed either by the Harris method by adding NaOH, by the Betterton method by chlorination or by vacuum dezincification. The zinc is mechanically adhered to the foams by pressing or segregation and the zinc is removed by distillation and the so-called rich lead is produced, which contains the precious metals in high concentration. From the rich lead, which can contain up to about 50% silver, the lead is oxidized to PbO in the so-called propellant process by selective oxidation with air and drawn off as a liquid smoothness, leaving behind the silver or guildish silver. The Güldisch silver is then subjected to refining electrolysis. In the case of higher gold and platinum content in the lead, the addition of small amounts of zinc can increase the gold and platinum content before the actual one Desilvering can be enriched in a gold foam that contains little silver. This gold foam is then processed separately to Güldisch silver. In the usual desilvering, the entire lead must be subjected to the process described.

Aus der DE-PS 589738 ist ein Verfahren zur Bleigewinnung bekannt, bei dem ein Gemisch aus oxidischen und sulfidischen Bleiverbindungen in einer ersten Stufe in einem bewegten Ofen, z.B. einem Drehrohrofen, eingeschmolzen wird, wobei neben Primärblei eine hochbleihaltige Schlacke entsteht, die das Blei teils als Oxid und teils als Silikat enthält. Blei und Schlacke werden aus der ersten Stufe abgezogen, wobei die Schlacke in Stückform gewonnen wird. Die Schlacke wird in einer zweiten Stufe in einem Schachtofen reduzierend verschmolzen, wobei eine bleiarme Schlacke und Sekundärblei anfallen. Im Einsatzgut vorhandene Edelmetalle gehen nahezu quantitativ in das Primärblei. Ein Teil des in der ersten Stufe gewonnenen Primärbleis kann wieder oxidiert werden und als oxidischer Bestandteil mit frischen Mengen sulfidischen Erzes die Beschickung für die erste Stufe bilden. Dabei wird das im Primärblei enthaltene Silber in einer kleinen Menge Blei angereichert, so daß diese direkt dem Treibprozeß unterworfen werden kann. Dieses Verfahren betrifft ein diskontinuierliches Verfahren, bei dem die aus der ersten Stufe abgestochene Schlacke in der zweiten Stufe wieder eingeschmolzen werden muß. Außerdem muß zur Erzeugung eines treibwürdigen Bleis das aus der ersten Stufe abgestochene Blei oxidiert werden.From DE-PS 589738 a method for lead extraction is known in which a mixture of oxidic and sulfidic lead compounds in a first stage in a moving furnace, e.g. a rotary kiln is melted down, whereby in addition to primary lead, a high-lead-containing slag is formed, which contains the lead partly as an oxide and partly as a silicate. Lead and slag are withdrawn from the first stage, the slag being extracted in pieces. In a second stage, the slag is melted in a shaft furnace to reduce it, resulting in a low-lead slag and secondary lead. Precious metals in the feed go into the primary lead almost quantitatively. Part of the primary lead obtained in the first stage can be oxidized again and form the feed for the first stage as an oxidic component with fresh amounts of sulfidic ore. The silver contained in the primary lead is enriched in a small amount of lead so that it can be directly subjected to the driving process. This process relates to a batch process in which the slag tapped from the first stage has to be melted down again in the second stage. In addition, the lead tapped from the first stage must be oxidized in order to produce a lead worthy of driving.

Aus der DE-PS 590 505 ist eine Abänderung des vorstehend beschriebenen Verfahrens bekannt, bei dem die oxidische Komponente durch Einblasen von Luft in ein Bleibad in der ersten Stufe selbst erzeugt wird, so daß nur noch die sulfidische Komponente in die erste Stufe chargiert werden muß. Die im Laufe des Verfahrens entstehenden Metallmengen sowie ein Teil der oxidischen Bleischlacke werden in gegebenen Zeitabständen aus dem Ofen entfernt. Die Schlacke wird zweckmäßigerweise wieder in einem Schachtofen weiterverarbeitet. Auch dieses Verfahren arbeitet diskontinuierlich. Außerdem muß das gesamte Primärblei dem üblichen Raffinationsgang für die Edelmetallgewinnung unterworfen werden.From DE-PS 590 505 a modification of the method described above is known, in which the oxidic component itself is generated by blowing air into a lead bath in the first stage, so that only the sulfidic component is charged in the first stage got to. The quantities of metal produced in the course of the process and part of the oxidic lead slag are removed from the furnace at given intervals. The slag is expediently further processed in a shaft furnace. This process also works discontinuously. In addition, the entire primary lead must be subjected to the usual refining process for precious metal extraction.

Aus der DE-PS 27 39 963 ist ein Verfahren zur Verarbeitung von blei-, kupfer- und schwefelhaltigen Materialien in zwei separaten Stufen bekannt, wobei in der ersten Stufe eine Kupfersteinphase und eine bleihaltige Primärbleiphase gebildet werden. Nach Trennung der Phasen wird die abgetrennte Schlackenphase in einer zweiten Stufe reduziert, wobei bleiarme Schlacke und Sekundärblei sowie evtl. eine kobalthaltige Arsenlegierung anfallen. Beide Stufen können in Schachtöfen, Flammöfen, Kurztrommelöfen, kopfbeblasenen Drehkonvertern oder bodenbeblasenen Kipppkonvertern durchgeführt werden. Als vorteilhafte Aggregate werden Lichtbogenwiderstandsöfen angegeben. Der größte Teil des vorlaufenden Silbers wird in der ersten Stufe im Primärblei und im Kupferstein angesammelt. Der Bleigehalt der Schlacke in der ersten Stufe wird auf 20 bis 40% eingestellt. Der Silbergehalt des Vorlaufes geht zum größten Teil in den Kupferstein und das Primärblei. Der Silbergehalt des Primärbleis liegt unter 1%, so daß das Primärblei der üblichen Raffination zur Gewinnung des Silbers unterworfen werden muß. Außerdem ist dieses Verfahren nur für kupferreiche Bleimaterialien bestimmt.From DE-PS 27 39 963 a method for processing lead, copper and sulfur-containing materials in two separate stages is known, a copper stone phase and a lead-containing primary lead phase being formed in the first stage. After the phases have been separated, the separated slag phase is reduced in a second stage, with low-lead slag and secondary lead as well as possibly a cobalt-containing arsenic alloy. Both stages can be carried out in shaft furnaces, flame furnaces, short drum furnaces, head-blown rotary converters or bottom-blown tilting converters. Arc resistance furnaces are specified as advantageous units. Most of the leading silver is accumulated in the first stage in the primary lead and in the copper stone. The lead content of the slag in the first stage is set at 20 to 40%. The silver content of the lead is largely in the copper stone and the primary lead. The silver content of the primary lead is less than 1%, so that the primary lead has to be subjected to the usual refining in order to obtain the silver. In addition, this method is only intended for copper-rich lead materials.

Der Erfindung liegt die Aufgabe zugrunde, bei einem kontinuierlichen Verfahren zum Verschmelzen von Blei aus edelmetall- und bleihaltigen Vorstoffen den Edelmetallgehalt der Beschickung in einer Blei-Silber-Legierung zu sammeln, die direkt in die Treibarbeit eingesetzt werden kann. Die Lösung dieser Aufgabe erfolgt erfindungsgemäß durch ein Verfahren zum kontinuierlichen Erschmelzen von metallischen Blei aus edelmetallhaltigen und bleihaltigen Vorstoffen, das dadurch gekennzeichnet ist, daß

  • a) das Erschmelzen der Beschickung in einem länglichen, liegenden Reaktor mit einer Schmelze aus Schlackenphase und zwei getrennten Bleiphasen erfolgt,
  • b) die Beschickung auf einer Seite des Reaktors in einer Oxidationszone auf die Schlackenphase chargiert wird und sauerstoffhaltige Gase in die Bleiphase eingeblasen werden,
  • c) der Sauerstoffpartialdruck in der Oxidationszone so gesteuert wird, daß das erschmolzene Primärblei einen Silbergehalt von mindestens 20% aufweist, die Menge an Primärblei unter 10% des vorlaufenden Bleigehaltes beträgt und eine Bleioxid enthaltende Schlacke anfällt,
  • d) das Primärblei aus der Oxidationszone abgezogen wird und die Bleioxid enthaltende Schlacke in eine Reduktionszone auf die andere Seite des Reaktors fließt,
  • e) in der Reduktionszone reduzierende Stoffe in die Schlackenphase eingebracht werden und
  • f) aus der Reduktionszone ein bleiarme Schlacke und Sekundärblei aus ihren Phasen abgezogen werden.
The invention is based on the object of collecting the noble metal content of the feed in a lead-silver alloy in a continuous process for melting lead from noble metal and lead-containing materials. that can be used directly in the driving work. This object is achieved according to the invention by a process for the continuous melting of metallic lead from noble metal-containing and lead-containing materials, which is characterized in that
  • a) the feed is melted in an elongated, horizontal reactor with a melt from the slag phase and two separate lead phases,
  • b) the charge on one side of the reactor is charged to the slag phase in an oxidation zone and oxygen-containing gases are blown into the lead phase,
  • c) the oxygen partial pressure in the oxidation zone is controlled so that the molten primary lead has a silver content of at least 20%, the amount of primary lead is less than 10% of the leading lead content and a slag containing lead oxide is obtained,
  • d) the primary lead is withdrawn from the oxidation zone and the slag containing lead oxide flows into a reduction zone on the other side of the reactor,
  • e) reducing substances are introduced into the slag phase in the reduction zone and
  • f) a low-lead slag and secondary lead are withdrawn from their phases from the reduction zone.

Die Vorstoffe können in beliebiger Form vorliegen, z.B. als Oxide, Sulfide, Sulfate, Silikate. Es können auch metallische Vorstoffe wie z.B. Computerschrott zugesetzt oder eingesetzt werden, wobei dann evtl. Zuschlagstoffe für die Schlackenbildung zugesetzt werden müssen. Wenn die Vorstoffe keinen Brennstoff, z.B. in sulfidischer Form, enthalten oder ihr Brennstoffgehalt nicht zur Deckung des Wärmebedarfs in der Oxidationszone ausreicht, wird in die Oxidationszone der erforderliche Brennstoff in fester, gasförmiger oder flüssiger Form zugegeben. Der Brennstoff kann mittels Düsen von unten oder seitlich in die Schmelze und/oder in den Gasraum oder mit der Vorstoffmischung zugegeben werden. Die Metallphasen in der Oxidationszone und der Reduktionszone werden durch eine auf dem Boden des Reaktors angeordnete Trennwand voneinander getrennt. Die Schlacke fließt aus der Oxidationszone über diese Trennwand oder durch eine Öffnung in der Trennwand in die Reduktionszone. Die Gasräume der Oxidations- und der Reduktionszone können voneinander getrennt werden oder das Gas aus der Reduktionszone strömt in die Oxidationszone und wird dort durch Nachverbrennung zur Wärmedeckung ausgenutzt. In der Oxidationszone werden sauerstoffhaltige Gase mittels Düsen von unten oder von der Seite in die Bleiphase eingeblasen. Der Sauerstoffpartialdruck in der Oxidationszone wird so eingestellt, daß von der vorlaufenden Bleimenge nur die gewünschte Menge an Primärblei anfällt und der restliche Bleigehalt als Oxid in die Schlacke getrieben wird. Beim Anfahren kann ein entsprechendes Reichblei mit dem gewünschten Silbergehalt vorgelegt werden, dann kann direkt der für den kontinuierlichen Betrieb erforderliche Sauerstoffpartialdruck eingestellt werden. Wenn beim Anfahren Blei vorgelegt wird, muß zunächst mit einem Sauerstoffpartialdruck gearbeitet werden, bei dem sich das vorgelegte Blei mit Silber auf den gewünschten Wert anreichert und kein oder nur wenig Primärblei anfällt. Nach Erreichen der gewünschten Konzentration wird dann der Sauerstoffpartialdruck auf den Wert für den kontinuierlichen Betrieb eingestellt. Der Sauerstoffpartialdruck wird durch Regelung des Verhältnisses von eingeblasener Sauerstoffmenge zur Menge der in den Vorstoffen enthaltenen oxidierbaren Bestandteile eingestellt. Wenn Brennstoffe in die Schmelze eingeblasen werden, müssen diese berücksichtigt werden. Als sauerstoffhaltige Gase können Sauerstoff, sauerstoffangereicherte Luft oder Luft verwendet werden. Durch präzise Steuerung des Sauerstoffpartialdruckes kann bei einem hohen Silbergehalt in den Vorstoffen der Silbergehalt im Primärblei soweit gesteigert werden, daß etwa ein Güldischsilber anfällt. In der Reduktionszone befindet sich unter der Schlackenphase die Sekundärbleiphase. Das Reduktionsmittel wird mittels Düsen von unten oder von der Seite in die Bleiphase geblasen und strömt von dort in die Schlackenphase und dann in den freien Reaktorraum. Als Reduktionsmittel werden kohlenstoffhaltige feste, flüssige oder gasförmige Materialien verwendet. Sie werden mit sauerstoffhaltigen Gasen eingeblasen und in der Bleiphase zu CO und evtl. H₂ wenigstens teilweise umgesetzt, so daß ein reduzierendes Gas aus der Bleiphase in die Schlackenphase eintritt. Im Gasraum der Reduktionszone kann eine Nachverbrennung der brennbaren Bestandteile im austretenden Gas vorgenommen werden. Falls erforderlich wird im Gasraum der Reduktionszone Brennstoff zur Deckung des Wärmebedarfs verbrannt.The precursors can be in any form, for example as oxides, sulfides, sulfates, silicates. It is also possible to add or use metallic raw materials such as computer scrap, in which case additives for the formation of slag may then have to be added. If the precursors do not contain any fuel, for example in sulfidic form, or if their fuel content is insufficient to cover the heat requirement in the oxidation zone, the required fuel is added to the oxidation zone in solid, gaseous or liquid form. The fuel can be added by means of nozzles from below or laterally into the melt and / or into the gas space or with the feed mixture. The metal phases in the oxidation zone and the reduction zone are separated from one another by a partition arranged on the bottom of the reactor. The slag flows from the oxidation zone through this partition or through an opening in the partition into the reduction zone. The gas spaces of the oxidation and reduction zones can be separated from one another or the gas from the reduction zone flows into the oxidation zone and is used there for after-combustion to cover the heat. In the oxidation zone, oxygen-containing gases are blown into the lead phase from below or from the side. The oxygen partial pressure in the oxidation zone is set so that only the desired amount of primary lead is obtained from the leading amount of lead and the remaining lead content is driven into the slag as oxide. When starting, an appropriate rich lead with the desired silver content can be presented, then the oxygen partial pressure required for continuous operation can be set directly. If lead is presented when starting, an oxygen partial pressure must first be used, in which the lead is enriched with silver to the desired value and little or no primary lead is obtained. To When the desired concentration is reached, the oxygen partial pressure is then set to the value for continuous operation. The oxygen partial pressure is adjusted by regulating the ratio of the amount of oxygen blown in to the amount of the oxidizable constituents contained in the primary substances. If fuels are blown into the melt, these must be taken into account. Oxygen, oxygen-enriched air or air can be used as the oxygen-containing gases. By precisely controlling the oxygen partial pressure, the silver content in the primary lead can be increased to such an extent that, for example, Güldischsilver is obtained with a high silver content in the primary materials. The secondary lead phase is located under the slag phase in the reduction zone. The reducing agent is blown into the lead phase from below or from the side and flows from there into the slag phase and then into the free reactor space. Carbon-containing solid, liquid or gaseous materials are used as reducing agents. They are blown in with oxygen-containing gases and at least partially converted to CO and possibly H₂ in the lead phase, so that a reducing gas from the lead phase enters the slag phase. In the gas space of the reduction zone, the combustible components can be post-burned in the escaping gas. If necessary, fuel is burned in the gas space of the reduction zone to cover the heat requirement.

Der Vorteil der erfindungsgemäßen Arbeitsweise besteht darin, daß zur Entfernung der Edelmetalle aus dem Blei keine klassische Anreicherung durch Zinkzusatz, Seigern und Destillation erforderlich ist, sondern das Primärblei direkt in die Treibarbeit eingesetzt werden kann. außerdem befindet sich nur eine sehr geringe Menge an Edelmetall in den Kreislauf- und/oder Zwischenprodukten.The advantage of the method of operation according to the invention is that no classical enrichment by adding zinc, Seigers and distillation is required to remove the precious metals from the lead, but the primary lead can be used directly in the driving work. in addition, there is only a very small amount of precious metal in the cycle and / or intermediate products.

Das in der Reduktionszone anfallende Sekundärblei ist weitgehend frei von Edelmetallen und bedarf keiner Entsilberung.The secondary lead produced in the reduction zone is largely free of precious metals and does not require desilvering.

Eine vorzugsweise Ausgestaltung besteht darin, daß gemäß c) der Sauerstoffpartialdruck in der Oxidationszone so gesteuert wird, daß das erschmolzene Primärblei einen Silbergehalt von mindestens 50% aufweist und die Menge an Primärblei unter 5% des vorlaufenden Bleigehaltes beträgt. Dadurch wird die Gewinnung der Edelmetalle aus dem Primärblei besonders wirtschaftlich.A preferred embodiment consists in that according to c) the oxygen partial pressure in the oxidation zone is controlled so that the melted primary lead has a silver content of at least 50% and the amount of primary lead is less than 5% of the leading lead content. This makes the extraction of the precious metals from the primary lead particularly economical.

Eine vorzugsweise Ausgestaltung besteht darin, daß die eingesetzten Vorstoffe sulfidische Bleimaterialien enthalten. Sulfidische Bleimaterialien sind in erster Linie Bleierzkonzentrate. Ihre Verarbeitung erfolgt nach dem QSL-Verfahren, wie es z.B. in der US-PS 4,266,971 und der US-PS 4,895,595 beschrieben ist. Dem Bleierz können andere, edelmetallhaltige Materialen zugesetzt werden. Bei der Verarbeitung von Bleierzen ist der erforderliche Brennstoff in Form des Sulfidschwefels in sehr gleichmäßiger Verteilung im Einsatzmaterial bereits enthalten, so daß sich sehr gute Betriebsbedingungen ergeben.A preferred embodiment is that the starting materials used contain sulfidic lead materials. Sulfidic lead materials are primarily lead ore concentrates. They are processed in accordance with the QSL procedure, e.g. in U.S. Patent 4,266,971 and U.S. Patent 4,895,595. Other materials containing precious metals can be added to the lead ore. When processing lead ores, the fuel required in the form of sulfide sulfur is already contained in the feedstock in a very uniform distribution, so that very good operating conditions result.

Eine vorzugsweise Ausgestaltung besteht darin, daß in der Reduktionszone kohlenstoffhaltige Reduktionsmittel und sauerstoffhaltige Gase mittels Düsen in die Sekundärbleiphase eingeblasen werden und eine Höhe der Bleiphase eingestellt wird, die eine Umsetzung des Reduktionsmittels zu CO und ggf. H₂ von mindestens 50% in der Bleiphase vor dem Eintritt in die Schlackenphase bewirkt. Die eingeleitete Menge an Sauerstoff in den sauerstoffhaltigen Gasen wird so bemessen, daß das Reduktionsmittel in der Bleiphase zu dem gewünschten Prozentsatz zu CO und ggf. H₂ umgesetzt wird. Die Bildung von H₂ erfolgt beim Einsatz von Kohlenwasserstoffen oder durch die Umsetzung flüchtiger Bestandteile, die in der Kohle enthalten sind. Die zur gewünschten Umsetzung des Reduktionsmittels in der Bleiphase erforderliche Höhe der Bleiphase ist abhängig von der Art des Reduktionsmittels und des sauerstoffhaltigen Gases, der Temperatur der Bleiphase sowie der Stärke und Geschwindigkeit der Einblasstrahlen. Die erforderliche Höhe kann jedoch empirisch für jeden Betriebsfall relativ einfach ermittelt werden. Zum Schutz der Düsenmundstücke gegen starken Abbrand kann ein Schutzgas als Mantelgas bei Mehrstoffdüsen eingeblasen werden. Das durch die Umsetzung entstandene CO und H₂ enthaltende Reduktionsgas wird gleichzeitig in der Metallschicht stark aufgeheizt und tritt dementsprechend mit hoher Temperatur in die Schlacke ein, wodurch sehr gute Reduktionsbedingungen geschaffen werden. Außerdem wird im Falle einer unvollständigen Umsetzung dadurch eine weitere Umsetzung zu CO und H₂ in der Schlackenschicht begünstigt. Dadurch wird sichergestellt, daß trotz des hohen Bleioxidgehaltes der in die Reduktionszone eintretenden Schlacke eine bleiarme Schlacke in der Reduktionszone erzeugt wird. Die Höhe der Bleiphase über bodenblasenden Düsen beträgt mindestens 4 cm und liegt vorzugsweise über 20 cm.A preferred embodiment consists in that in the reduction zone carbon-containing reducing agents and oxygen-containing gases are blown into the secondary lead phase by means of nozzles and a level of the lead phase is set which converts the reducing agent to CO and, if appropriate, H₂ of at least 50% in the lead phase before Entry into the slag phase causes. The amount of oxygen introduced in the oxygen-containing gases is such that the reducing agent in the lead phase is converted to CO and possibly H₂ in the desired percentage. The education of H₂ occurs when using hydrocarbons or through the implementation of volatile components that are contained in the coal. The height of the lead phase required for the desired implementation of the reducing agent in the lead phase depends on the type of reducing agent and the oxygen-containing gas, the temperature of the lead phase and the strength and speed of the blowing jets. The required height can, however, be determined relatively easily empirically for each operating case. A protective gas can be blown in as a jacket gas in multi-component nozzles to protect the nozzle mouthpieces against severe erosion. The CO and H₂-containing reducing gas produced by the reaction is simultaneously heated up strongly in the metal layer and accordingly enters the slag at high temperature, creating very good reduction conditions. In addition, in the event of an incomplete implementation, this favors a further conversion to CO and H₂ in the slag layer. This ensures that despite the high lead oxide content of the slag entering the reduction zone, a low-lead slag is generated in the reduction zone. The height of the lead phase above floor-blowing nozzles is at least 4 cm and is preferably above 20 cm.

Das erfindungsgemäße Verfahren wird anhand von Beispielen für einen QSL-Reaktor erläutert.The process according to the invention is explained using examples of a QSL reactor.

Der QSL-Reaktor hat eine Länge von 33 m, einen Innendurchmesser in der Oxidationszone von 3 m und in der Reduktionszone von 2,5 m. Zwischen Oxidationszone und Reduktionszone ist ein Wehr angeordnet, das eine Vermischung der Bleiphasen von Oxidations- und Reduktionszone verhindert, jedoch das Abfließen der hochbleihaltigen Schlacke aus der Oxidationszone in die Reduktionszone ermöglicht. Der Reaktor ist in der Oxidationszone mit sechs und in der Reduktionszone mit fünf bodenblasenden Düsen ausgerüstet. In die Oxidationszone wird technisch reiner Sauerstoff eingeblasen. In die Reduktionszone werden feinkörnige Kohle, technisch reiner Sauerstoff und als Schutzgas für die Düsen Stickstoff oder Erdgas oder Mischungen eingeblasen. Sekundärblei und Schlacke werden alternierend aus der Reduktionszone abgestochen, wobei ein Bleibad von ca. 250 mm aufrechterhalten bleibt. Das Primärblei oder Reichblei wird kontinuierlich aus der Oxidationszone abgezogen. Das Abgas aus der Oxidationszone und der Reduktionszone wird gemeinsam an der Seite des Bleistiches der Oxidationszone abgezogen.The QSL reactor has a length of 33 m, an inner diameter of 3 m in the oxidation zone and 2.5 m in the reduction zone. A weir is arranged between the oxidation zone and the reduction zone, which mixes the lead phases of the oxidation and reduction zones prevents, but allows the high lead-containing slag to flow out of the oxidation zone into the reduction zone. The reactor is equipped with six bottom-blowing nozzles in the oxidation zone and five in the reduction zone. Technically pure oxygen is blown into the oxidation zone. Fine-grained coal, technically pure oxygen and nitrogen or natural gas or mixtures as a protective gas for the nozzles are blown into the reduction zone. Secondary lead and slag are alternately tapped from the reduction zone, while a lead bath of approx. 250 mm is maintained. The primary lead or rich lead is continuously withdrawn from the oxidation zone. The exhaust gas from the oxidation zone and the reduction zone is drawn off together on the side of the lead of the oxidation zone.

Beispiel 1:Example 1:

In die Oxidationszone werden ca. 25 t/h einer Aufgabemischung mit 10% Ag, 40% Pb und Rest Schlackenkomponenten auf die Schlackenschicht chargiert. Das Sauerstoffpotential in der Oxidationszone wird durch Einstellung der eingeblasenen Sauerstoffmenge so eingeregelt, daß 10% des Bleivorlaufes als Primärblei anfallen und etwa 99% des Silbervorlaufes in diesem Primärblei gesammelt werden. Dabei wird ein Reichblei oder Rohsilber mit etwa 70% Ag in der Oxidationszone erzeugt und aus ihr abgezogen. Aus der Reduktionszone werden das silberarme Sekundärblei mit einem Silbergehalt von etwa 0,01 bis 0,02% und die Schlacke abgezogen.Approx. 25 t / h of a feed mixture with 10% Ag, 40% Pb and the rest of the slag components are charged onto the slag layer in the oxidation zone. The oxygen potential in the oxidation zone is adjusted by adjusting the amount of oxygen blown in so that 10% of the lead flow is obtained as primary lead and about 99% of the silver lead is collected in this primary lead. A rich lead or raw silver with about 70% Ag is generated in the oxidation zone and drawn off from it. The low-silver secondary lead with a silver content of approximately 0.01 to 0.02% and the slag are drawn off from the reduction zone.

Beispiel 2:Example 2:

Die Aufgabemischung entspricht dem Beispiel 1. Das Sauerstoffpotential in der Oxidationszone wird so eingestellt, daß 5% des Bleivorlaufes als Primärblei anfallen und etwa 99% des Silbervorlaufes in dem Primärblei gesammelt werden. Dabei wird ein Reichblei oder Rohsilber mit etwa 83% Ag erzeugt.The feed mixture corresponds to Example 1. The oxygen potential in the oxidation zone is set so that 5% of the lead flow as primary lead accumulate and about 99% of the silver lead is collected in the primary lead. A rich lead or raw silver with about 83% Ag is produced.

Beispiel 3:Example 3:

In der Oxidationszone werden ca. 25 t/h einer Aufgabemischung mit 1% Ag, 40% Pb und Rest Schlackenkomponenten aufgegeben. Das Sauerstoffpotential wird so eingeregelt, daß etwa 10% des Bleivorlaufes als Primärblei anfallen und etwa 99% des Silbervorlaufes in diesem Primärblei gesammelt werden. Dabei wird ein Reichblei mit etwa 20% Ag in der Oxidationszone erzeugt und aus ihr abgezogen. Aus der Reduktionszone werden das silberarme Sekundärblei mit einem Silbergehalt von etwa 0,01% und die Schlacke abgezogen.Approx. 25 t / h of a feed mixture with 1% Ag, 40% Pb and the rest of the slag components are fed into the oxidation zone. The oxygen potential is adjusted in such a way that about 10% of the lead lead is obtained as primary lead and about 99% of the silver lead is collected in this primary lead. A rich lead with about 20% Ag is generated in the oxidation zone and drawn off from it. The low-silver secondary lead with a silver content of approximately 0.01% and the slag are drawn off from the reduction zone.

Beispiel 4:Example 4:

Die Aufgabemischung entspricht dem Beispiel 3. Das Sauerstoffpotential in der Oxidationszone wird so eingestellt, daß 5% des Bleivorlaufes als Primärblei anfallen und etwa 99% des Silbervorlaufes in dem Primärblei gesammelt werden. Dabei wird ein Reichblei mit etwa 32% Ag erzeugt.The feed mixture corresponds to Example 3. The oxygen potential in the oxidation zone is set so that 5% of the lead lead is obtained as the primary lead and about 99% of the silver lead is collected in the primary lead. A rich lead with about 32% Ag is produced.

Claims (4)

  1. A method for the continous smelting of metallic lead from raw materials containing precious metals and lead, characterised in that:
    a) the smelting of the charge is effected in an elongate, horizontal reactor with a melt consisting of slag phase and two separate lead phases,
    b) the charge is charged on to the slag phase on one side of the reactor in an oxidation zone and oxygen-containing gases are blown into the lead phase,
    c) the oxygen partial pressure in the oxidation zone is controlled such that the smelted primary lead has a silver content of at least 20 %, the amount of primary lead is less than 10 % of the preceding lead content and a slag containing lead oxide is produced,
    d) the primary lead is withdrawn from the oxidation zone and the slag containing lead oxide flows into an reduction zone to the other side of the reactor,
    e) reducing materials are introduced into the slag phase in the reduction zone and
    f) a low-lead slag and secondary lead are withdrawn from their phases from the reduction zone.
  2. A method according to Claim 1, characterised in that in c) the oxygen partial pressure in the oxidation zone is controlled such that the
       smelted primary lead has a silver content of at least 50 % and the amount of primary lead is less than 5 % of the preceding lead content.
  3. A method according to Claim 1 or 2, characterised in that the raw materials used contain sulphidic lead materials.
  4. A method according to one of Clains 1 to 3, characterised in that carbon-containing reduction agents and oxygen-containing gases are blown into the secondary lead phase by means of nozzles in the reduction zone and a height of the lead phase is set which effects a conversion of the reduction agent to CO and if applicable H₂ of at least 50 % in the lead phase before entry into the slag phase
EP92202548A 1991-09-05 1992-08-20 Method for continuously melting metallic lead Expired - Lifetime EP0530893B1 (en)

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DE4129475A DE4129475A1 (en) 1991-09-05 1991-09-05 METHOD FOR CONTINUOUSLY MELTING METAL LEAD
DE4129475 1991-09-05

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EP0530893A1 EP0530893A1 (en) 1993-03-10
EP0530893B1 true EP0530893B1 (en) 1995-11-08

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CN101200777B (en) * 2007-09-24 2010-06-16 云南锡业集团(控股)有限责任公司 Method and equipment for continuous smelting of lead sulphide concentrate
CN110804701A (en) * 2019-12-06 2020-02-18 湖北大江环保科技股份有限公司 Supersaturated oxygen-enriched smelting process for side-blown converter

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LU75732A1 (en) * 1976-09-06 1978-04-27
DE3029682A1 (en) * 1980-08-06 1982-03-11 Metallgesellschaft Ag, 6000 Frankfurt METHOD FOR CONTINUOUSLY DIRECT MELTING OF METAL LEAD FROM SULFIDIC LEAD CONCENTRATES
US4741770A (en) * 1985-04-03 1988-05-03 Cra Services Limited Zinc smelting process using oxidation zone and reduction zone
DE3539164C1 (en) * 1985-11-05 1987-04-23 Kloeckner Humboldt Deutz Ag Process and smelting furnace for producing non-ferrous metals

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GR3018515T3 (en) 1996-03-31
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ES2081034T3 (en) 1996-02-16

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