Once the ore is removed from veins (narrow channels) or lodes (roughly spherical deposits) in the Earth, usually at depths of about 60 metres, the ore is treated at concentrating mills. Here the ore is finely crushed, sometimes to particle diameters of less than 0.1 millimetre (0.004 inch), and then treated by one of several mineral concentration processes. Such processes are designed to remove as much as possible of the waste rock, known as gangue.

Flotation separation generally is used for sulfide ores. In this process, the finely crushed ore is diluted with water and agitated violently with air in a tank to which 1 percent pine oil or other suitable chemicals have been added. The sulfide particles attach themselves to the chemicals, and, when the air is bubbled into the mixture, an oily froth containing most of the metallic constituents of the ore floats to the top while the mostly valueless gangue sinks to the bottom. Aggregation of the metallic concentrate is initiated in the flotation bath, where flocculation agents such as alum and lime help increase the average size of particles; xanthate is also added to the froth to help float the particles to the surface. The froth then flows from the tank and is dried. Lead concentrates shipped from the concentration mill to the smelter contain 40 to 80 percent or more lead, with varying amounts of impurities, of which sulfur (up to 30 percent) and zinc (up to 15 percent) are most common.

Extraction

Indirect smelting

Before lead concentrate can be charged into traditional blast furnaces for smelting, it must be roasted to remove most of the sulfur and to agglomerate further the fine flotation products so that they will not be blown out of the blast furnace. Various fluxing materials, such as limestone or iron ore, are mixed with the ore concentrate. The mix is spread on a moving grate, and air is blown through at a temperature of 1,400 °C (2,550 °F). The sulfur, along with coke additions, serves as a fuel and is combusted to sulfur dioxide gas, which is usually recovered for the production of sulfuric acid as a by-product.

Roasting fuses the remaining ingredients into a brittle product called sinter, which consists of oxides of lead, zinc, iron, and silicon along with lime, metallic lead, and some remaining sulfur. This material is broken into lumps as it is discharged from the moving grate. The prefluxed, lumpy sinter is then loaded into the top of a heated blast furnace, along with the coke fuel. A blast of air is admitted to the lower part of the furnace to aid combustion of the coke, generating a temperature of about 1,200 °C (2,200 °F) and producing carbon monoxide. This gas then reacts with the metallic oxides, producing carbon dioxide and molten metal. Nonmetallic wastes form a slag with the fluxing materials.

When reduction is complete, the furnace is tapped and the lead drawn off to flow into drossing kettles or molds. At this stage, the semifinished product, 95 to 99 percent lead and containing dissolved metallic and nonmetallic (oxide and sulfide) impurities, is known as base bullion. The bullion is maintained at a temperature just above its melting point, about 330 °C (626 °F). At this temperature, the solubility of copper in lead is very low, so that the copper content segregates and forms a scum, or dross, on the surface of the bath in the drossing kettle. After this is skimmed off, more copper and other impurities are brought to the surface by stirring sulfur and lead pyrite into the bath or by agitating it with submerged air lances. These impurities are also skimmed off, and the remaining base bullion is refined to yield lead of commercial quality (see below).

Direct smelting

Indirect smelting in roasters and blast furnaces began to be replaced in the 1970s by several direct smelting processes conducted in relatively small, intensive reactors. These processes require neither the sintering of feed materials nor the use of metallurgical coke; also, they produce lower volumes of gas and dust that would require treatment with pollution-control equipment. In general, direct smelting can be divided into two categories: (1) submerged smelting, as in the QSL and Isasmelt processes, in which the refining reactions occur in a liquid (i.e., molten metal, matte, or slag), and (2) suspension smelting, as in the KIVCET process, in which the reactions occur between gases and solids.

KIVCET is a Russian acronym for “flash-cyclone-oxygen-electric-smelting.” A three-part KIVCET furnace comprises the reaction shaft, waste-gas shaft, and electric furnace, all connected with a common settling hearth. It employs the autogenous (that is, fuel-less) flash smelting of raw materials, with the heat-producing oxidation of the concentrated sulfide ore raising the temperature to 1,300–1,400 °C (2,375–2,550 °F), which is enough to reduce the oxidized materials to metal. In operation, the process involves the proportioning, drying, and mixing of the lead-bearing materials and fluxes, followed by their injection into the reaction shaft, where they are ignited by a heated blast of commercially pure oxygen. The smelted lead bullion and slag collect in the hearth, while zinc vapour undergoes combustion with carbon monoxide in the electric furnace to produce zinc oxide. Sulfurous gases generated by the smelting process are tapped from the waste shaft to heat steam and to produce sulfuric acid as a by-product.

The KIVCET process appears to produce significantly less flue dust than other direct processes, and its furnace brickwork has a longer service life. However, its use of electricity rather than fossil fuel usually militates against its use for eliminating zinc from the slag.

The QSL, or Queneau-Schuhmann-Lurgi, process treats all grades of lead concentrates, including chemically complex secondary minerals, in a refractory-lined reactor into which oxygen and natural gas are blown through tuyeres at the bottom. The “green,” or unroasted, charge is first oxidized in a molten bath by the submerged oxygen injection; this produces a flue gas carrying oxides of lead and zinc as well as a slag containing 80 percent of the zinc from the charge. Reduction of the metal oxides occurs when they contact carbon monoxide produced by the natural-gas injection. The concentrates employed in the QSL process are not briquetted or dried before being fed to the reactor. Moisture content is held to 7–8 percent in order to minimize dusting.

In the Isasmelt process, a gas or air lance is brought in through the top of a furnace and its tip submerged in the sulfide concentrate. A blast from the lance produces a turbulent bath in which the concentrates are oxidized to produce a high-lead slag. This slag is tapped continuously and transferred to a second furnace, where it is reduced with coal. Crude lead and slag are tapped continuously from the second furnace and separated for further refining.

Refining

Refining of bullion

To remove and recover remaining impurities from lead bullion, either pyrometallurgical or electrolytic refining is used; the choice between the two methods is dictated by the amount of bismuth that must be eliminated from the bullion and by the availability and cost of energy.

The Parkes zinc-desilvering process is the most widely used pyrometallurgical method of refining lead bullion. As in smelting, the lead is first melted and again allowed to cool below the freezing point of copper, which crystallizes and, along with any remaining nickel, cobalt, and zinc, is removed by skimming. The lead mix then passes to a reverberatory “softening” furnace, where the temperature is raised and the molten lead is stirred. A blast of air oxidizes any remaining antimony or arsenic, both of which harden lead (hence the term softening furnace), and these are skimmed off to be recovered later.

After softening, the lead goes to desilvering kettles, where small quantities (less than 1 percent by weight) of zinc are added. With stirring, the molten zinc reacts to form compounds with gold and silver, both of which are more soluble in zinc than in lead. The compounds are lighter than the lead, so that, on cooling to below 370 °C (700 °F) but above the melting point of lead, they form a crust that is removed and taken to a parting plant for recovery of the precious metals. The remaining zinc is then removed by reheating the molten lead to 500 °C (1,100 °F) and creating a vacuum over the surface. The zinc vaporizes, and the vapour is condensed as metal on the cool dome of the vacuum vessel, where it is collected for reuse.

The Harris process of softening and dezincing is designed to remove impurities from desilvered lead by stirring a mixture of molten caustic salts at a temperature of 450–500 °C (840–930 °F) into the molten lead. Metallic impurities react with the chemicals and are collected in the form of their oxides or oxysalts.

Lead bullion containing more than 0.1 percent bismuth can be purified by the Betterton-Kroll process, which usually follows softening, desilvering, and dezincing and involves treatment of the melt with calcium and magnesium. Bismuth unites with these metals to form compounds that rise to the surface. The compounds are skimmed off and treated for recovery of bismuth, a valuable by-product.

The Betterton-Kroll process produces a refined lead with bismuth contents of 0.005 to 0.01 percent. When a refined lead of higher purity is required, or when a lead bullion high in bismuth has to be refined, employment is made of electrolytic refining. This process is costly, but it has the major advantage of separating lead from every impurity except tin in one vessel or one stage, and it does so without emitting lead-bearing fumes or gases. The bullion is cast into large plates, which are hung as anodes in electrolytic tanks where they dissolve. Pure lead is deposited on a thin sheet of lead that serves as the cathode. Impurities left behind can be recovered by many complex operations.

Secondary refining

Secondary lead is lead derived from scrap. Accounting for nearly half of the total output of refined lead, it is a significant factor in the lead market because it is easily melted and refined and rarely becomes contaminated by impurities during service. About 85 percent of secondary lead comes from discarded automobile batteries. The imposition of stringent environmental regulations governing disposal of spent batteries has led to greater recycling efforts that will ensure the growth of this supply.

The recycling of lead from battery scrap involves treating and separating the scrap, reducing and smelting the lead-containing fractions, and refining and alloying the lead bullion into a commercial product. It is usually conducted in reverberatory and blast furnaces at refineries devoted exclusively to handling secondary lead and lead alloys. However, some primary refineries also refine secondary lead; this has led to a growing use of rotary furnaces, which are batch kilns that are rotated during the smelting process.

The bulk of secondary lead alloy recovered from reclaimed batteries and cable sheathing contains small percentages of antimony and other metals. After this antimony-containing secondary lead is refined, it is largely resold to battery manufacturers. Secondary lead containing tin is most often reused in the manufacture of solder, bearing metals, and other lead-tin alloys.

Calcium-lead alloys can also be made from recycled lead. Antimony is removed by oxygen injection, and, after copper and other impurities are removed, the molten lead is cast into blocks, or “pigs,” weighing 50 kilograms (110 pounds) or more. The molten lead may also be pumped into an alloying kettle for production of lead-calcium alloys, with the optional addition of tin or aluminum.

Secondary raw materials are usually processed separately. Sometimes, however, lead residues, sludges, or flue dusts are mixed with oxides from the battery treatment plant and processed together.