US178998A - Improvement in processes for extracting zinc from its ores - Google Patents

Improvement in processes for extracting zinc from its ores Download PDF

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US178998A
US178998A US178998DA US178998A US 178998 A US178998 A US 178998A US 178998D A US178998D A US 178998DA US 178998 A US178998 A US 178998A
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furnace
zinc
ores
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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
    • C22B19/00Obtaining zinc or zinc oxide
    • C22B19/34Obtaining zinc oxide
    • C22B19/36Obtaining zinc oxide in blast or reverberatory furnaces

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  • FRANK L OLERO, 0F BETHLEHEM, PENNSYLVANIA.
  • the main object of my invention is to extract metallic zinc from its ores and oxide more economically and completely than by any process heretofore practiced.
  • My process is a continuous one, and consists. of the following operations, namely: First, the reduction of the metal from its oxide in the form of a gas; second, the protection of the metallic vapor from reoxidation third, the condensation of the metallic vapor to a liquid form; and, fourth, the disposal of the residues and the ashes of the coal.
  • the reduction is effected by. carbonic oxide generated in the lower part of a furnace, by injecting a blast of superheated air, through tuyeres, into a mass of incandescent fuel.
  • the zinc vapor is condensed to aliquid form out of the furnacegases by passing them thewfurnace,-condenser, and feeding-shaft;
  • Fig. 2 Sheet 2, a sectional plan. of the same on the line 1 2; Fig. 3, Sheet 2, a sectional plan on the line 3 4; Fig. 4, Sheet 3, a "sectional plan on the line 5 6; and'Figs. 5 and 6, Sheet 4, illustrate a Washing apparatus connected with the furnace.
  • the furnace proper, A is made inthe-form of an inverted frustum ofa widely-flaringcona on a cylindrical shaft, A, called the hearth.
  • the said furnace proper is arched over by a dome, at, having a large central opening, I), and lateral passage-ways c, as clearly shown in Fig. 1.
  • I central opening
  • c lateral passage-ways
  • the condenser is placed over and around the furnace proper, and consists of fire-brick flues, twelve in the present instance, passing over the dome of the furnace. These flues communicate with each other at the top in sets of four, through thetransverse passages e, and lead into thethree chimneys F.. At the bottom the flues are connected together in sets of two, adjacent flues uniting at the bottom to form around'the furnace the six receptacles d, for the collection of the condensed metal. The sides of these receptacles are inclined toward each other, and converge to the tapping-holes f. The sides of the flues are formed by the twelve arched radial walls g,
  • the condenser carrying with it the dome ofthe furnace, feeding-shaft, &c., is built on an annular bedplate, which is supported, in the present in stance, by a double'row of pillars, as shown in the figure. 7
  • Sheet 4 consists of a series of vertical pipes, I, connected nearthe top with the chimneys F by means of cooling-pipes J.
  • the operation of the process is as follows: The furnace is dried and lighted up in the same manner as a blast-furnace for smelting iron.
  • the charge consists of an intimate mixture of calcined ore, crushed to about the size of a pea, or of oxide of zinc, artificially prepared, with proper proportions of fuel and flux, to which may be added the metallic blue powder, recovered in the washer from a previous charge. About one-half of the coal should be crushed as fine as the ore, and the remainder may be as coarse as egg-size.
  • the proper proportions of coal and flux will vary in accordance with the characterof the ore and fuel, temperature of blast, &c.
  • the gases After leaving thecondenser the gases are still further cooled by passing them through the cooling-pipes J before they reach the washer, which they enter near the top of the vertical pipes I, and descend, along witha shower of water from the water-tank above, into the covered tank K, in which operation whatever zinc has escaped condensation in the condenser is washed out of the said gases in the form of a heavy metallic powder, known as blue powder, which settles quickly to the bottom of the tank, and is withdrawn therefrom to be dried and returned to the furnace.
  • the washed gases are conducted from the top of the tank, to be burned as in the iron blast-furnace for heating the blast, or for other purposes.
  • Atile constituents which are as much as possible to be avoided, will descend with the flux and gangue into the lower portion of the furnace, where it encounters the free oxygen of the blast.
  • it is rapidly burned to carbonic oxide with the generation of the heat necessary to melt the non-volatile elements of the charge, and .to carry on the work of reductionin its upward passage through the furnace.
  • the ore or the flux contains any met 211, such as copper, manganese, or iron not vol atile at'the temperature obtained, and which does not flux with the gangue in the reducingatmosphere to which it is exposed, it may be collected in. a sump at the bottom of the fursistent with thedurability of the furnace and blast apparatus, in order to compensate as much as possible for the heat withdrawn from the furnace by taking the gases out of the same at the required high temperature,
  • the temperature absolutely required in any case will depend upon the; nature of the fuel. It will be less with charcoal and soft coke than with hard coke or anthracite coal. It must in any case be sufficient to kindle the fuel All the coal in excess of this amount, less the vol-v wherever it comes'in contact with it, and to insure a perfect conversion of its oxygen to carbonic oxide in passing through even a thin layer of the fuel.
  • the ore, fuel, and flux should be thoroughly dry before entering the furnace, and free from volatile constituents capable of oxidizing the zinc vapor, if given off at the top of the furnace; for this reason, the ore and flux should be carefully calcined, and only such fuel as anthracite coke or charcoal containing but a small proportion of volatile matter can be employed.
  • the object in charging a portion of the coal and flux in lumps is to prevent the premature the furnace, since the presence of even a small proportion of oxide of zinc in the gases will suflice to choke up' the pipes and obstruct the washing apparatus.
  • the cooling-pipes should be made as thin and light as possible, and should be so constructed that they may be replaced by duplicate pieces in case they become choked, as they are liable to do when the furnaceis working irregularly. These pipes also serve to indicate the temperature at which the gases leave the furnaces. These gases should not remain in the condenser after they have cooled below the melting-point of zinc; otherwise the condensing conduits may become filled with blue powder. Nor must the gases leave the condenser while condensation is still possible. i
  • the height of the feeding-shaft will depend upon the pressure of the blast and the fineness of the charge. It must besuflicient to prevent the gases from escaping upward through it, instead of passing into the condenser.
  • the large open chambers in the condenser are constantly filled with a gas which will explode when mixed with air; hence the necessity of adopting precautions to prevent such a mixture.
  • the furnace used costs less to build, requires fewer repairs, is continuous in its operation, instead of intermittent, andutilizes the carbonic oxide formed in reduction.
  • a zinc-furnace in which are combined the following elements, namely, a hearth, A,
  • furnace proper made in the form of an" inverted frustum of a cone, the dome a, central feeder B, and passages and lines, all substantially as set forth.

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  • Chemical & Material Sciences (AREA)
  • Manufacturing & Machinery (AREA)
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  • Organic Chemistry (AREA)
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Description

4 Sheets-:Sheet 1.
F. L. CLERC.
PROCESS FOR EXTRACTING zmc mom ms ems. No.17.8,998. Patented June-20.1876.
4 Sheets-Sheet 2. F. L. CLERC. V PROCESS FOREX-TRACTING' ZINC FROM ITS ORES.
Patented June 20,1876.
NJEI'ERS, PHOTO-L THOGRAPHER WASHINGTON D C 4 Sheets-Sheet 3.
F. L. CLERC.'
RACTIN'G ZINC FROM ITS ORES.
P aaaa Led. June 20,1876.
4 Sheets-Sheet 4.
I F. L. CLERC. PROCESS FOR EXTRACTING ZINC FROM ITS ORES.
Patented June 20,1876.
N-PETERS. PHOTO-UTHQGRAFHEL WASHINGTON, D C,
FRANK L. OLERO, 0F BETHLEHEM, PENNSYLVANIA.
IMPRQVEMENT IN PROCESSES FOR EXTRACIITING ZINC'FROM ITS ORES.
Specification forming part of Letters Patent No. 178,998, dated June 20, 1876; application filed March 29, 1876.
To all whom it may concern:
Be it known that I, FRANK LAURENT 0mm, of Bethlehem, Northampton county, Pennsylvania, have invented certain Improvements in the Extraction of Zinc, and in Apparatus Employed Therefor, of which the following is a specification: v
The main object of my invention is to extract metallic zinc from its ores and oxide more economically and completely than by any process heretofore practiced.
My process is a continuous one, and consists. of the following operations, namely: First, the reduction of the metal from its oxide in the form of a gas; second, the protection of the metallic vapor from reoxidation third, the condensation of the metallic vapor to a liquid form; and, fourth, the disposal of the residues and the ashes of the coal.
The reduction is effected by. carbonic oxide generated in the lower part of a furnace, by injecting a blast of superheated air, through tuyeres, into a mass of incandescent fuel. The
metallic vapor is protected from oxidation by maintaining a layer. of heated charcoal or soft. coke on the top of the charge in the furnace, as described hereafter.
The zinc vapor is condensed to aliquid form out of the furnacegases by passing them thewfurnace,-condenser, and feeding-shaft;
Fig. 2, Sheet 2, a sectional plan. of the same on the line 1 2; Fig. 3, Sheet 2, a sectional plan on the line 3 4; Fig. 4, Sheet 3, a "sectional plan on the line 5 6; and'Figs. 5 and 6, Sheet 4, illustrate a Washing apparatus connected with the furnace.
The furnace proper, A, is made inthe-form of an inverted frustum ofa widely-flaringcona on a cylindrical shaft, A, called the hearth. The said furnace proper is arched over by a dome, at, having a large central opening, I), and lateral passage-ways c, as clearly shown in Fig. 1. In the hearth of the furnace are the openings z, for the insertion of tuyeres, the slageye 00, and, in special cases, the additional tappin ghole y. The feeding apparatus B, Fig. 1, consists of a shaft of brickwork extending through the dome a into the furnace, and'terminating atthe top in a hopper, B, through which descends, into the shaft, B, an inner funnel-shaped hopper, D, supported by arms The condenser is placed over and around the furnace proper, and consists of fire-brick flues, twelve in the present instance, passing over the dome of the furnace. These flues communicate with each other at the top in sets of four, through thetransverse passages e, and lead into thethree chimneys F.. At the bottom the flues are connected together in sets of two, adjacent flues uniting at the bottom to form around'the furnace the six receptacles d, for the collection of the condensed metal. The sides of these receptacles are inclined toward each other, and converge to the tapping-holes f. The sides of the flues are formed by the twelve arched radial walls g,
extending over and across the furnace, but
interrupted in the center to admit the feedingshaft B. These walls also support the dome of the furnace and the lower portion of the feeding-shaft, and are continued above the fines to carry the superstructure of the furnace. by the dome of the furnace. The condenser, carrying with it the dome ofthe furnace, feeding-shaft, &c., is built on an annular bedplate, which is supported, in the present in stance, by a double'row of pillars, as shown in the figure. 7
The Washing apparatus, shown in Figs. 5
and 6, Sheet 4, consists of a series of vertical pipes, I, connected nearthe top with the chimneys F by means of cooling-pipes J.
These vertical pipes communicate with theupper Water-tank h, and each pipe is' covered FIGE.
The bottoms of all the flues are formed the water in which traps the gases, the latter passingofl' through the pipe 11..
The operation of the process is as follows: The furnace is dried and lighted up in the same manner as a blast-furnace for smelting iron. The charge consists of an intimate mixture of calcined ore, crushed to about the size of a pea, or of oxide of zinc, artificially prepared, with proper proportions of fuel and flux, to which may be added the metallic blue powder, recovered in the washer from a previous charge. About one-half of the coal should be crushed as fine as the ore, and the remainder may be as coarse as egg-size. The proper proportions of coal and flux will vary in accordance with the characterof the ore and fuel, temperature of blast, &c. Theycan be approximately determined in any case by apreliminary analysis of the fuel and ores, and accurately adjusted, so as to secure the best results, by a careful experimental working. For fluxes, quicklime, iron, or the oxides of manganese are generally applicable, and with rich ores, andwith a fusible slag, and a highly-heated blast, a weight of coal equal to onehalf the weight of the charge will be found sufficient. The charge is fed into the inner hopper as fast asit sinks in the shaft, and at the same time some charcoal or soft coke,
easily acted on by carbonic acid, is fed into the exterior hopper. As they descend together they unite in a solid column, and are gradually heated before reaching the furnace, on enter ing which they spread outward, falling with a natural talus to the outer wall of the furnace. The charcoal, being on the outside, is thrust upward, forming a layer on the top of the charge, where, as it is gradually deposited, and in close proximity to the heated dome of the furnace, it is maintained at a sufficientlyhigh temperature to reduce the issuing gases. As the oxide of zinc descends in the furnace it encounters carbonic oxide sufficiently hot to reduce it. The reaction which takes place is as follows: ZnO+CO=Zn (zinc vapor) +00 but this is immediately followed by the action of the carbonic acid, so formed on the heated carbon of the fuel, namely, (J0 +0= OO. These two reactions may, in fact, be considered as taking placesimultaneously, and may be written ZnO+OO+O=Zn(zinc vapor);- 200. The zinc vapor, so liberated, rises with the other gases, passes through the layer of heated charcoal, in which operation Whatever carbonic acid there may be remaining in the accompanying gases is effectually reduced to carbonic oxide, and escaping from its free surface issues into the condenser through the passage-ways G. In passing through the condensing-conduits it parts slowly with its heat and condensesinto drops, which gather on the sides of the conduits, run together, and trickle off the sloping bottom of the fines into the receptacles d, from which the metal is drawn off from time to time. After leaving thecondenser the gases are still further cooled by passing them through the cooling-pipes J before they reach the washer, which they enter near the top of the vertical pipes I, and descend, along witha shower of water from the water-tank above, into the covered tank K, in which operation whatever zinc has escaped condensation in the condenser is washed out of the said gases in the form of a heavy metallic powder, known as blue powder, which settles quickly to the bottom of the tank, and is withdrawn therefrom to be dried and returned to the furnace. The washed gases are conducted from the top of the tank, to be burned as in the iron blast-furnace for heating the blast, or for other purposes.
It will be seen that in the operation of reduction the effect is the same as if thezinc were reduced by the direct action of the carbon in the fuel, and that the amount of coal which can be consumed in the upper part of the furnace is strictly limited by the amount which can be dissolved by the carbonic acid formed in reduction, or, what is the same thing, by the amount which can be burned by the oxygen combined with the zinc in the ore, and this amount is almost exactly three-sixteenths of the weight of the zinc in the charge.
atile constituents, which are as much as possible to be avoided, will descend with the flux and gangue into the lower portion of the furnace, where it encounters the free oxygen of the blast. Here itis rapidly burned to carbonic oxide with the generation of the heat necessary to melt the non-volatile elements of the charge, and .to carry on the work of reductionin its upward passage through the furnace.-
When the ore or the flux contains any met 211, such as copper, manganese, or iron not vol atile at'the temperature obtained, and which does not flux with the gangue in the reducingatmosphere to which it is exposed, it may be collected in. a sump at the bottom of the fursistent with thedurability of the furnace and blast apparatus, in order to compensate as much as possible for the heat withdrawn from the furnace by taking the gases out of the same at the required high temperature,
and to counteract the cooling efi'ect in the upper-part of the furnace due to reduction, without unduly increasing the amount of fuel consumed, and consequently the volume of the gases with which the zinc vapor is diluted.
The temperature absolutely required in any case will depend upon the; nature of the fuel. It will be less with charcoal and soft coke than with hard coke or anthracite coal. It must in any case be sufficient to kindle the fuel All the coal in excess of this amount, less the vol-v wherever it comes'in contact with it, and to insure a perfect conversion of its oxygen to carbonic oxide in passing through even a thin layer of the fuel. It is also essential that the ore, fuel, and flux should be thoroughly dry before entering the furnace, and free from volatile constituents capable of oxidizing the zinc vapor, if given off at the top of the furnace; for this reason, the ore and flux should be carefully calcined, and only such fuel as anthracite coke or charcoal containing but a small proportion of volatile matter can be employed.
The object in charging a portion of the coal and flux in lumps is to prevent the premature the furnace, since the presence of even a small proportion of oxide of zinc in the gases will suflice to choke up' the pipes and obstruct the washing apparatus.
The cooling-pipes should be made as thin and light as possible, and should be so constructed that they may be replaced by duplicate pieces in case they become choked, as they are liable to do when the furnaceis working irregularly. These pipes also serve to indicate the temperature at which the gases leave the furnaces. These gases should not remain in the condenser after they have cooled below the melting-point of zinc; otherwise the condensing conduits may become filled with blue powder. Nor must the gases leave the condenser while condensation is still possible. i
The height of the feeding-shaft will depend upon the pressure of the blast and the fineness of the charge. It must besuflicient to prevent the gases from escaping upward through it, instead of passing into the condenser.
The large open chambers in the condenser are constantly filled with a gas which will explode when mixed with air; hence the necessity of adopting precautions to prevent such a mixture.
So long as the blast is continued there is an outward pressure at all parts of the furnace, and no air can enter; but should the Where the oreis The principal advantages claimed for my process over. those heretofore used are, that it effects a great saving of fuel, avoids loss of metal by imperfect condensation, extracts almost the last traces of metal from the slags, requires no articles of fire-clay of special construction, demands the attendance of onefourth' the number of men, and less skilled labor can be employed to work ores containing'other valuable constituents which cannot be worked directly in any other spelter-fun nace, and upon ores too poor to be worked by other processes.
The furnace used costs less to build, requires fewer repairs, is continuous in its operation, instead of intermittent, andutilizes the carbonic oxide formed in reduction.
I claim as my invention- 1. The mode or process herein described of extracting metallic zinc from its ores and oxide-that is to say, by injecting a blast of superheated air into and through a charge of calcined ore, fuel, and flux, causing the gases evolved to pass trough heated charcoal or of their exit from under the furnace-dome,
substantially as herein described.
3. Thecombination of the inletpipe J, downtake I, and water-reservoir h, with the water-seal tank K, having the inclined sides m,
whereby the escaping zinc-dust is precipitated and readily collected, substantially as herein set forth.
4:. A zinc-furnace in which are combined the following elements, namely, a hearth, A,
a furnace proper, A, made in the form of an" inverted frustum of a cone, the dome a, central feeder B, and passages and lines, all substantially as set forth. I
5,. The combination of the vertical feedingshaft B and its hopper B, with the inner concentric shaft D, whereby the charge and fuel are distributed in the furnace insuch manner as to present a hot superposed layer of fuel I to the outgoing gases and vapors, substantially as herein described.
In testimony whereof I have signed my name to this specification in the presence of two subscribing witnesses.
FRANK L. GLERO.
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