US1863711A

US1863711A - Reducing zinciferous materials

Info

Publication number: US1863711A
Application number: US417471A
Authority: US
Inventors: Earl H Bunce
Original assignee: New Jersey Zinc Co
Current assignee: New Jersey Zinc Co
Priority date: 1929-12-30
Filing date: 1929-12-30
Publication date: 1932-06-21
Anticipated expiration: 1949-06-21

Description

June 21, 1932. E. H. BUNCE REDUCING ZINCIFEROUS MATERIALS Filed Dec. so, 1929 mi@ JNDI@ NNIVW M wm.

Mmm. 2N D200 lNVENTOR E af/ Bunce Patented June 21, 1932 UNITED STATES PATENT. OFFICE EARL H. BUNCE, F PALMERTON, PENNSYLVANIA, ASSIGNOR TO TH\ NEW JERSEY ZINC COMPANZ'OF NEW YORK, N. Y., A CORPORATION 0F NEW JERSEY REDUCING ZINCIFETBOUS IlllIIA'l'ERIAIiS4 Application led December 30, 1929. Serial No. 417,471.

This invention relates to the reduction or smeltmg of zinciferous materials and has -for its object the provision of certain improvements in the reduction or smelting of such materials. The invention is particularly concernedwvith that method' of zinc reduction or smelting in which a mixture of zinciferous and carbonaceous materials is agglomerated and coked and the coked agglomerates are subjected to a reducing op eration carried out in a substantially continuous manner, as for example in a vertical retort. The invention is characterized by a new combination of operative features and manipulative steps never before so combined and producing results not heretofore achieved in commercial zinc smelting.

The improved method of the invention, in its entirety, comprises five main operations, viz :-(l) appropriate preparation of a suitable mixture of zinciferous and carbonaceous materials, (2) agglomerating (as by briquetting) the mixture, (3) coking the agglomerates, (4) reducing or smelting the coked agglomerates in a substantially continuous manner and (5) recovering Zinc from the reducing operation, preferably after elimination of lead and. similar contaminating metals from the gaseous product of the reducing operation. It is characteristic of one aspect of the invention that the operations of agglomerating, coking, and reducing are individually carried out in a substantially continuous manner and are so correlated each to the other that the material undergoing treatment passes directly and in a substantially continuous manner from a preceding operation'to the next succeeding operation. Preferably, the entire 'method from the preparation of the agglomerate mixture to the-recovery of the zinc is closely articulated, with each operation so correlated to the. others that the progress of material is substantially continuous from each operation to the next succeeding operation with no substantial intermediate accumula,.- tion of material. l

In a method of zinc reduction in which the various operations are so closely articulated as is contemplated in the preferred practice coking of the present invention, it has been found that a certain operating reserve of the mixed l zinciferous and carbonaeeous materials should be maintained in advance' of the agglomeratlng operation'. The maintenance of thls operating reserve, as Well as the transfer of the mixed zinciferous and carbonaceous materials, has been found to lower the moisture content of the mixture below that requlred for satisfactory agglomerating especially by briquetting. To overcome this diliiculty, the present invention contemplates the treatment of the mixture with the addition thereto of an appropriate amount of Water in a paddle type of mixer followed by compacting of the resulting mixture preparatory to agglomerating` for coking.

Another feature o'f the invention involves accumulating the product of the substantially continuous agglomerating operation in units corresponding in amount to a single charge for the subsequent coking operation and timed to meet the periodic charging requirements of the coking operation. It will be understood that the agglomerating operation, such as briquetting, is most conveniently and economically carried out in a substantially continuous manner. On the other hand, `While the coking operation as a Whole may be substantiall continuous, the charging of the furnace or furnaces is for practical reasons carried out periodically, say at twenty-minute intervals. The accumulation of the product of the continuous agglomerating operation in units suitable for charging into and substantially timed to meet the periodic charging requirements of the subsequent coking operation materially promotes the closely articulated conduct of the operations of agglomerating and coking.

The foregoing and other novel features of the invention Will be best understood from the following description taken in Conjunction with the single ligure of the accompanying drawing. This figure diagrammatically illustrates a plant adapted for the practice of the invention.

The zinciferous material (e. g. zinc ore) and the carbonaceous material (e. g. coal) are separately crushed and stored in ap

roriate bins

5 and 6, respectively. From t ese ins, the zinc ore and coal, in app'roprlate predetermined proportions, are continuously supplied to and mixed in a rotary cylindrical mixer 7, or other approprlate mlxmg devlce. The mixed charge will usuall contam fr om to 35% by weight of zinci erous materlal, and from 35 to 65% by weight of carbonaceous material. In general, the higher the zinc content and the more finely divided the zinciferous material the more carbonaceous material will be needed in the mixture.

From the rotary mixer 7, the mixture of ore and coal is conveyed, in any appropriate manner, to two or more Chilean mills or edge-runners 8 in series, in which it is subjected to the characteristic kneading action of that apparatus. If necessary, a conditioning agent or a binder, such as sulfiteliquor, tar, pitch, or the like, may be added during the treatment in the edge-runner. From the second or last edge-runner, the kneaded mixture is appropriately conveyed to a briquetting press. It is to be understood that the plant may, and usually will, have several mixing devices, edge-runners and briquetting presses. The progress of the materials through these preparatory operations is as nearly continuous as practicable. Between the edge-runners and the briquetting presses, it is advisable to provide a certain storage 9 of the kneaded mixture as an operating reserve in order to insure continuity of the succeeding operations in the event 'of temporary interruptions in the contemplated contmuous supply of the zinciferous or carbonaceous materials.

A certain amountof moisture is necessary for satisfactory agglomeration especially by briquetting; from 6 to 12% of moisture on the dry weight of the mixture being usually satisfactory. Where the kneaded mixture has been stored or conveyed any distance in shallow layers, itsmoisture content is likely to be reduced below that required for satisfactory briquetting. In accordance with one aspect of the present invention, additional water-is incorporated in the kneaded mixture by passing the mixture in the presence of the added water through a paddle type of mixer 10. While the paddle mixer effectively incorporates the added water uniformly throughout the kneaded mixture of ore and coal, paddle mixing tends to fluff' up the mixture to such an extent that it is not dense enough to form good briquettes. It is essential in briquetting in a roll press machine to feed to the press a material so dense that the entire pressure of the mamine is taken by the materia-l confined within the depressions or pockets in the rolls. Consequently, I have found it advantageous, if not in fact necessary, to follow the paddle mixing with a compacting or densifying treatment such as results from passing the mixture through a briquette press, grooved or corru ated rolls, or a similar densif ing device. t is referable that the ag omerates formed y the densifying device of smaller size than the final agglomerates for coking. In the apparatus illustrated in the accompanyin drawing, the densifying treatment, followlng the paddle mixing, is effected by ooved rolls l1 forming agglomerates sma ler than the final briquette size.

The moisture added at the paddle mixer appears to be particularly effective in that it moistens the surfaces of any lumps or granules that are present so that in the pre-pressing rolls these moist surfaces .join together and form coherent masses whose surfaces are likewise wet. Such surface wet masses form very hard coherent agglomerates in the final briquetting press. In the case of both the mixture fed to the pre-pressing rolls and the pre-pressed material fed tothe final briquetting press, it is essential to have moist, wet surfaces in order to get good coherence and the strongest briquette.

The compacted or densified mixture is fed to the briquetting press or presses 12. The agglomerates are dropped from the briquetting press or presses 12 onto-a traveling platform or accumulator 13 adapted to hold the predetermined amount of agglomerates introduced into a coking furnace at each charging. The briquetting press or presses are so operated that a charge of agglomerates is always in readiness on an accumulator 13 whenever required for the charging of a coking furnace. Some such storage, as provided by the accumulator 13, is necessary in the ciosely articulated operation, since a coking furnace is generally charged every twenty minutes, and the briquetting press or presses run more or less continuously, so that there must be some way of storing the briquettes over the twenty-minute period. Also, it is advantageous to charge the coking furnaces as fast as possible, and it is therefore desirable to have a full charge on hand, so that it can be quickly fed into the furnace readyfor charging.

The accumulator 13 may conveniently be of the form of an endless conveyor moving beneath the discharge of the briquetting press. It will be understood that the accumulator is transversely movable as a whole, so that it can be moved into operative position to receive the briquettes as dropped from the press and also into operative position to feed the accumulated charging unit of agglomerates into the hopper of the coking furnace to be charged. The accumulator is thus a larry (movable along a track at right angles to the drawing) equipped with a conveyor belt. The traveling platform or conveyor of the accumulator should be capable of movement at different speeds, for example relatively lli slow when accumulating the charging unit of agglomerates, and relatively fast when feeding the accumulated unit of agglomerates into a coking furnace.

The coking furnaces 14 are preferably of the cross-current vertical type, such as disclosed in my copending applicatlon, Serial No. 391,825, filed September 11, 1929, although other appropriate types of coking furnaces may of course be used. In the crosscurrent vertical coking furnace, the agglomerates are progressively passed through an upright or vertical cokng chamber and are heated to the requisite temperature of coking by direct contact with hot gas passed transversely through the vertical column of agglomerates. Periodically, an appropriate amount of coked agglomerates is Withdrawn from the bottom of the coking chamber and simultaneously a corresponding amount of fresh agglomerates is introduced (from an accumulator 13) into the top of the chamber.

The coked agglomerates are discharged from the bottom of the coking furnace into buckets 15. These buckets are hoisted by a charge larry 2O and carried over to hoppers 21 feeding the vertical reduction retorts, and the hot coked agglomerates are dumped directly into a hopper 21, with as little loss of heat as possible between their discharge from the coking furnace and their introduction into the reduction retort. The charging hopper 21 is provided at its bottom With a gate, of any conventional design, for dumping the charge from the hopper into the retort below. This gate serves to seal the top of the retort when it is closed s0 that zinc vapor will not escape from the top of the retort at any point except intoorifices leading to the condenser.

The coking furnaces are appropriately operated to supply the charging requirements of the reduction retorts. Thus, an appropriate amount of coked agglomerates is withdrawn from a coking furnace as and when required for charging a reduction re tort. At predetermined intervals, an appropriate amount of worked-off or exhausted agglomerates is Withdrawn from the bottom of a reduction retort While simultaneously introducing a corresponding amount of hot freshly coked agglomeratesinto the top of the retort.

The reduction retorts 16 are preferably attached to thel furnace structure at one end only, so that they can expand and contract freely. The retorts may advantageously be built up of circle or other appropriate brick shapes of temperature-resistant material bonded together into a substantially zincvapor-tight chamber supported at its lower' end and free to expand and contract independently of the furnace structure, as described in United States patent of Frank G. Breyer and myself No. 1,680,726.

The reduction furnaces illustrated in thc accompanying drawing are of the gas-fired recuperator type, similar in general to the furnace illustrated in the aforementioned Patent No. 1,680,726. Thus, the vertical rcduction retorts of the furnace are externally heated by the hot products of combustion resulting from the burning of an appropriate fuel gas supplied to the furnace by a pipe 22. A heat recuperator 23 is operatively associated With each reduction furnace, air for thc combustion of the fuel gas being introduced into the combustion chamber of the furnace through the heat recuperator, whereby it is preheated, and the exhaust gases from the combustion chamber pass from the reduction furnace through the recuperator to a Hue 24 connected to the gas-inlet of the coking furnaces. The gases initially exhausted from the recuperator 23 are ordinarily too hot for coking the ore-fuel agglomerates because of 4the zinc loss that such high temperatures would cause. Regulated and controlled cooling of these exhaust gases may, therefore, be necessary, as for example by radiation of heat in the passage through the metallic transfer flue 24 or by the introduction of steam or other appropriate cooling medium. The heating gas passed through the cokmg furnaces must be substantially devoid of oxidizing influences, and it may therefore bc desirable, or even necessary, to add a small quantity of unburnt fuel gas to the exhaust combustion gases of the recuperator in order to react with or neutralize any oxidizing constituent therein. The heating gases are drawn through the recuperator 23, the transfer flue 24 and the coking furnaces 14 by a hot fan 25 on the gas-exit side of the coking furnaces. The heat of the exhaust gases of the coking furnaces may be used in waste heat boilers, or otherwise economically utilized.

While I have hereinbefore particularly described a high temperature rapid coking operation, it is to be understood that the agglomerates may, Where necessary or desirable, be subjected to a slow coking operation, such as described in the copending application of Mahler and Handwerk, Serial No. 394,134, filed September 20, 1929. Appropriate modification of the construction and arrangement of the /coking furnaces for practicing slow coking will be apparent to those skilled in the art.

The purpose of coking the agglomerates is to utilize the coke bond for holding the ore and coal particles together. Where the coked agglomerates are smelted in a vertical retort, they must possess sufficient strength to pass progressively through the retort without substantial breaking down or sanding and to provide a residue of sufficient strength to prevent disintegration by crumbling, rupturing or abrading. The preparation of the agglom- C5 issued into patent No. 1,749,127 of March 4,

erate mixture exercises a marked influence on the ultimate properties of the coked agglomerates. Accordingly, in the practice of the present invention, I preferably prepare the agglomerate mixture with graded sizing of the ore and coal and blending of the coal, as described in the pending` application of Thomas C. Routson and myself, Serial No.

301,709, filed August 23, 1928. vWhere the zinciferous material is a flotation concentrate I preferably sinter the material, as described in my copending application, Serial No. 319,- 735 filed November 15, 1928.

It is characteristic of the reduction operation that the coked agglomerates pass through thevertical retort Without disintegration or breaking down and without slagging or fusing, as described in the United States patent of Frank G. Breyer and myself, No. 1,712,132.

rIhe gaseous product of the reducing operation is approprlately treated for the recovery of its zinc content as zinc metal, zinc oxide, zinc dust, or the like. In the apparatus illustrated in the drawing acondenser 17 is shown for the recoveryof zinc metal, this condenser being advantageously of the type disclosed in my copending application, Serial No. 400,064, tiled October 16, 1929.

The reduction retorts are sealed or closed atv the bottom only to the extent that they are lled with Worked-olf or exhausted ag-' glomerates. In practice, it has been found advantageous to permit some air to be drawn into the bottom of the retort by the stack draft, in order to prevent downdraft of gas within the retort due to the gas pressure enerated therein, as disclosed in the copen ing patent application of Frank G. Breyer, Serial No. 180,107, filed April 1, 1927 (which has since issued into Patent No. 1,811,910, of June 30, 1931). The air drawn in contact-s with the incandescent carbon of the agglomerates near the bottom of the retort and sufficient heat is generated by combustion to volatilize any condensed zinc metal and/or to reduce any residual compounds of zinc in the agglomerates near the bottom of the retort. The stack draft is conveniently controlled by throttling the gas exhausted'from the condenser stack or chimney 18.

Contaminating metals, such as lead, in the gaseous product of the reducing operationv can be ellj'ectively and advantageously liminated by passing the gaseous product through a body of fresh agglomerates, or an equivalent medium, maintained at-a temperature sufficient-ly low to effect substantial removal of lead and similar contaminating metals from the gaseous productwithout condensing any substantial amount of zinc vapor, as described in the copending application of George T. Mahlerand myself, Serial No. 244,519, tiled Jan. 4, 1928 (which has since 19 of the vertical retort, above the reducing zone thereof, adapted to confine an appropriate body vof the deleading agglomerates. The charging hopper 21 above the prolongation 19 of the retort is then charged with agglomerates transferred from the coke oven 14 by the hoist buckets 15. On opening the gate at the bottom of the hopper 21, the agglomerates enter the eliminator; that is to say, the prolongation 19 of the vertical retort. The agglomerated charge as a Whole then progressively passes throu h the eliminator into and through the vertical retort and is heated in the reducing zone of the retort to a suiciently high temperature to reduce compounds of zinc and volatilize the resulting metallic zinc and in the. prolongation of the retort is maintained at an appropriate temperature to effect substantial removal of lead and similar contaminating metals from thev gaseous product of the reducing operation. l

The residues from the vertical retort will contain not only any lead that may be present in the ore but likewise any silver, gold or copper. The agglomerated form and the high carbon content of these residues render them highly suitable for subsequent smelting by known methods to recover the lead, silver,

gold, copper and the like that were present 1n the original ore..

I claim:

1. The method of reducing zinciferous material which comprises agglomerating v-and coking an appropriately prepared mixture of zinciferous and carbonaceous materials and thereby producing coked agglomerates possessing adequate residue strength for vertical retort reduction, progressively passing the coked agglomerates through a vertical retort externally heated by hot gaseous products of combustion to a sufficiently high temperature to reduce the zinciferous material and volatilize the resulting metallic zinc without substantial disintegration of the agglomerates, subjecting the gaseous product of the reducing operation to appropriate treatment for the recovery of its zinc content, and utilizing the exhaust heating gases of the reducing operation for the coking operation.

2. The method of reducing zinciferous material in which coked agglomerates of mixed ing gases of the reducing operation for the coking operation.

3. The method of reducin zinciferous material in which a mixture o zinciferous and carbonaceous material is agglomerated and coked and the coked agglomerates are subjected to a reducing operation carried out in a vertical retort externally heated by hot gaseous products of combustion, characterized by accumulating the product of a continuous agglomerating operation in units corresponding in amount to asingle charge for the subsequent coking operation and timed to meet the periodic charging requirements of the coking operation, conducting the o er-l ations of agglomerating, coking and re ucing in a closely articulated manner so correlated each to the other that the material undergoing treatment passes directly and in a substantially continuous manner from a preceding operation to the next succeeding operation, and utilizing the exhaust heating gases of the reducing operation for the coking operation.

4f. The method of reducing zinciferous material in which coked agglomerates of mixed zinciferous and carbonaceous materials are progressively passed through a reducing chamber externally heated by hot gaseous products of combustion to a suiliciently high temperature to reduce the zinciferous material and volatilize the resulting metallic zinc, characterized by utilizing the exhaust heating gases of the reducing operation for the cokng operation.

5. In the method of preparing a briquetted charge of mixed zinciferous material and carbonaceous reducing agent for smelting, the step which comprises ormin ag lomerates of the charge relatively sma er t an the briquettes to be formed thereof.

6. In the method of preparing a briquetted charge of mixed zinciferous material and carbonaceous reducing agent for smelting, the steps which comprise first forming small briquettes of the charge materials, and then using said small briquettes to form larger briquettes for smelting.

7. In the method of preparing a briquetted charge of mixed zinciferous material and carbonaceous reducing agent for smelting, the steps Which comprise subjecting the mixture in the presence of added water to the action of aj paddle type of mixer, forming small briquettes of the moistened and mixed charge materials, and then using said small briquettes to form larger briquettes for smelting.

8. In the method of smelting a. briquetted charge of mixed zinciferous material and carbonaceous reducing agent confined in an externally heated retort, the step which comprises subjecting briquettes about to be smelted to a coking operation with exhaultno y