US2347264A - Process and apparatus for separating fragmentary materials - Google Patents

Process and apparatus for separating fragmentary materials Download PDF

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US2347264A
US2347264A US362144A US36214440A US2347264A US 2347264 A US2347264 A US 2347264A US 362144 A US362144 A US 362144A US 36214440 A US36214440 A US 36214440A US 2347264 A US2347264 A US 2347264A
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medium
tank
specific gravity
separating
particles
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US362144A
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Grover J Holt
Rakowsky Victor
Ray W Arms
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MINERALS BENEFICIATION Inc
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MINERALS BENEFICIATION Inc
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B03SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03BSEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
    • B03B5/00Washing granular, powdered or lumpy materials; Wet separating
    • B03B5/28Washing granular, powdered or lumpy materials; Wet separating by sink-float separation
    • B03B5/30Washing granular, powdered or lumpy materials; Wet separating by sink-float separation using heavy liquids or suspensions
    • B03B5/36Devices therefor, other than using centrifugal force
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B03SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03BSEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
    • B03B11/00Feed or discharge devices integral with washing or wet-separating equipment
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B03SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03BSEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
    • B03B11/00Feed or discharge devices integral with washing or wet-separating equipment
    • B03B2011/006Scraper dischargers

Definitions

  • This invention has for its object to provide anovel continuous and emcient process and apparatus for separating fragmentary materials of different specific gravities, such as coal, ores and the like,
  • a tank of some considerable extent. in length and of approximately uniform width is provided, which tank preferably gradually increases in depth from the rear end where the materials to be separated are introduced toward the opposite rear end, While this gradual increase in depth of the tank is preferred, it is not essential, since in some cases a tank of approximately uniform depth from the rear end to the front end and of uniform width may be employed.
  • a separating medium composed of water and comminuted solids and preferably of uniform specific gravity is continuously introduced adjacent the rear end of the tank and is caused to flow through the tank toward the front end at a slow rate.
  • the medium flows slowly through the tank the comminuted solids of the medium very slowly settle, the rate of settling depending on the strength of ,the current and the make-up of the medium.
  • the medium becomes one of gradually increasing specific gravity from the top downward, the rate of increase being controlled by the rate of fiow of the medium, whereby a constantly increasing differential between the specific gravities of the top and bottom of the tank is established.
  • the specific gravity of the upper portion gradually decreases while that of thelower portion gradually becomes greater.
  • the current through the tank is secured and controlled by a plurality of means.
  • One is in the form of an overflow at a point toward the front end of the tank opposite from the point of introduction of the medium.
  • Another is in the form of means for withdrawing medium from the tank at some point or even a plurality of points below the surface thereof and intermediate the point of introduction and said overflow.
  • Both the overflow and the intermediate means for withdrawing medium from the tank are preferably adjustable longitudinally along the tank. That is, the overflow means are preferably arranged to be adjusted toward or from the point of introduction of the medium; and the means for removing the medium from the tank intermediate the point of introduction and the overflow may be adjusted toward or from the point of introduction. Moreover. this intermediate means of removal of the medium may be adjusted to difi'erent heights within the body of the medium to the end that the medium may be removed from the tank at different levels therein.
  • FIG. 1 is a diagrammatic view somewhat in perspective of one form of tank which may be employed;
  • Fig. 2 is a diagrammatic longitudinal sectional elevation of the tank shown in Fig. 1;
  • Fig. 3 is a diagrammatic plan view of said tank
  • FIG. 4 is a diagrammatic view illustrating the apparatus employed for recovering the solids from the used medium
  • FiFig. 5 is a view on the section line 5-5 of Fig. 6 is a diagrammatic side elevation of a modified form of the tank;
  • Fig. 7 is a like diagrammatic side elevation of still another form of tank that may be employed.
  • Fig. 8 illustrates a construction alternative to that shown in Fig. u;
  • Fig. 9 is a detail of the entrance ports of the air lifts.
  • a tank of considerable longitudinal extent and preferably of approximately uniform width which tank is of constantly increasing depth from the rear end I to the point I". While the tank may be of constantly increasing depth from the rear end to the other,
  • a chute 6 Extending across the tank from side to side near the shallow end thereof, is a chute 6 through which a ribbon of a separating medium of uniform specific gravity is continuously introduced into the tank, said ribbon extending across the tank from side to side.
  • an overflow trough or conduit 1 Extending across the tank'and adjacent the end opposite from the medium feed chute 6 is an overflow trough or conduit 1, the bottom of which is somewhat below the surface of the medium in the tank when in operation.
  • This overflow chute i may be and preferably is adjustable longitudinally of the tank. That is, it may be moved nearer to or more remote from the medium feed chute
  • Between the medium feed chute t and the overflow 8 means are provided for removing medium from the tank which means are preferably ad justable both longitudinally and vertically in the tank.
  • such means take the form of a chute 8 adjustable longitudinally of the tank i toward or from. the overflow.
  • the chute carries telescopic conduits 8' which, by reason of the telescopic construction, enable the entry ports 8" to the conduits to be adjusted vertically, thus providing means whereby the inlet ports 3" (Fig. 2) of the conduits 8' may be raised or lowered within the tank. While this construction is preferred, any suitable means for adjusting the entrance ports 8" vertically and longitudinally of the tank may be employed. As illustrated in Fig. 8.
  • the entrance port or ports 8" may be'in the form of an open end or ends of a tube or tubes having a universal mounting 8a in the side walls of the tank and connected with suitable means ill) for withdrawing medium from the tank through the ports 8", such as a pump, air lift or the like.
  • Means for feeding the material to be separated are provided, preferably adjacent to and immediately in front of the medium feed chute 6, said means taking the form of a chute 9 Or other feed means extending across the tank from side to side and arranged to feed a ribbon of the ores or other materials across the tank from side to side and immediately in front of the ribbon of medium delivered into the tank from the medium chute 6, to the end that the separating medium and the materials to be separated are fed in the form of adjacent ribbons extending across the tank.
  • the medium When the medium enters the tank at the chute 6 it is of uniform specific gravity, and being composed of water and comminuted solids, the solids will tend to very gradually settle toward the bottom of the tank as the current or medium moves alongtowards the overflow I and the air 7 21a plurality of endless carriers 2-2, preferably in the form of chains, and carrying suitably or the comminuted solids is to convert the medium which was of uniform specific gravity when it was introduced into the tank into a medium oi differential density, that is, one in which the specific gravity of the medium gradually increases from the top to the bottom. Moreover, as the.
  • Fig. 2 This is diagrammatically illustrated in Fig. 2.
  • medium of 'a uniform specific gravity for example, 3.06, and composed of water-and comminuted solids
  • the solids in the medium will very slowly settle, the rate of settling depending upon a number of factors, such as the character of the solids in the medium, the proportion of solids and water and the rate of flow of the medium through the tank.
  • This gradual settling of the solids will produce in the tank ually and continuously increases.
  • There will always he a line extending from the feed chute 8 towards the opposite end of the tank which will be of the same specific gravity as that of the'medium at the point of introduction.
  • the specific gravity of the introduced medium is 3.06
  • the exact position of this line will, of course, vary, but for the purpose of illustration it is shown in Fig, 2 at 11/. All of the ore particles introduced at the chute 9 whose specific gravity exceeds 3.06 will settle below this line 1!, and all of those particles whose specific gravity is less than 3.06 will be floating or suspended in the medium above or but slightly below that line.
  • That portion of the particles of intermediate specific gravity which is thus suspended within' 7 the gradient or controlled differential of the medium will be drawn by the air lifts thereinto and discharged from the tank together with some medium.
  • the result of this is that all of the ore particles whose specific gravity is greater than that of the medium along the bottom of the tank are removed by the drag, while those whose specific gravity is less than that of the bottom are eliminated by the overflow of the air lifts from the tank. This produces a highly eflicient and accurate separation of the particles into concentrates, tails and middlings.
  • the medium flows through the screen into a receptacle l3, while the particles descend along the screen and are subjected to sprays ll whichwash the comminuted solids therefrom, the water and solids passing through the screen and into a receptacle I5, the washedparticles being delivered from the screen i2.
  • the discharge from the air lifts 8' consists of a considerable body of medium carrying therein the ore particles withdrawn therewith and this medium, together with the particles, is delivered to a ,screen [6, the medium flowing are delivered into a receptacle the particles are advanced along the screen u der a spray l8 where any of the comminuted solids of the medium adhering thereto are washed therefrom, and together with the spray water, l9.
  • the medium which is thus delivered into the receptacles I3 and I1 may be and preferably is returned to the tank I together with medium from the tank 20 through the chute 6 by means of a pump or otherwise; or such portion of it as may be desired may be returned from receptacle H to the tank through conduits 30 (Fig.
  • the wash water from the sprays l, l4 and I8 and which is received in the receptacle ll, l and I9 may be and preferably is conveyed to a suitable settling tank for reconditioning and reuse.
  • This tank 20 is of considerable size, and as the solids settle therein, the settling tends to more or less clarify the water at the surface of the tank and it may be delivered to the respective sprays'by minuted solids employed in the medium.
  • the ores or other particles that are fed into the tank are washed before being introduced thereinto in order to free them from slimes and other objectionable particles.
  • the films of water surrounding each particle in the aggregate constitute a considerable amount of water, and this water being of less specific gravity than that of the medium itself would immediately rise to the surface of the medium in'the tank.
  • Means are provided in the form of suitable outlet croutlets for removing this water. This rising of water may even occur in the lower portion of the infeed ribbon, and in that case suitable outlet 22 (Fig. 2) or outlets are provided for eliminating such water.
  • baflles 23 In order to effect this delivery of the 'water from the tank before it is carried along to any extent on the surface of the medium, a baflie or plurality of baflles 23 (Fig. -2) extends across the tank, and to a limited extent-below the surface of the medium. These baffles interrupt the flow of water along the surface of the medium and serve to more effectively remove this water through outlets 22'.
  • a baflie 24 extends across the tank and downwardly into the medium to approximately the path of the drag flights, and an inlet 25, preferably in the form of sprays, is provided for introducing water to the rear of this baflle, thereby decreasing the specific gravity of the-medium to the rear of the, baffle and insuring the settling of any of these particles to a point within the range of the bame flights.
  • An outlet 26 is provided for through the screen into a receptacle ll, while 15 carrying of! the water which will thus rise to the surface of the medium immediately to the rear'of the baflle 24.
  • FIG. 6 there is therein-shown a tank in of uniform depth for the greater portion of its length with its bottom to the rear of the intake of medium and ore materials extending upward along an incline at the rear end of the tank for the delivery of the heavier separated particles by a suitable drag.
  • Fig. 7 there is shown atank lb of uniform depth from end to end and a drag which delivers the heavier particles from the bottomof the rear end of the tank from which they may be deliveredby an air lift or otherwise as desired.
  • a tank containing a liquid separating medium consisting of water and comminuted solids means introducing said medium at uniform speciflc gravity adjacent one end of said tank and into the surface portion of the medium in the tank, overflow means adjacent the other end of the tank, means for feeding ore particles into the surface portion of the medium in the tank and intermediate the introduction of the medium and said overflow means, a bailie extending across the tank and projecting downward into the surface portion of the tank between the ore feed inlet and said overflow, and a liquid outlet between the baflle and ore feed and adjacent the surface of the medium in the tank.
  • a tank containing a separating medium composed of water and comminuted solids means continuously introducing said medium at uniform specific gravity into the surface portion of the medium in the tank adjacent one end thereof, overflow means adjacent the opposite end of the tank, ore feeding means introducing the ore particles into the surface portion of the tank intermediate said medium inlet and said overflow, a bave extending across and projecting above the surface portion of the tank, a liquid outlet between the time and ore feed and adjacent the surface of the medium in the tank, and an air lift between said bave and said overflow means and removing portions of the medium intermediate the top and bottom portions thereof with associated ore particles from the tank.
  • a tank containing separating medium composed of water and comminuted solids means continuously introducing said medium at uniform speciflc gravity into the surface portion of the medium in. the tank at one end thereof, overflow means adjacent the opposite end of the tank, ore feeding means introducing the ore particles into the surface portion of the medium in the tank intermediate said medium inlet and said overflow, and an air lift the inlet to which is between said 4.
  • a continuous process of separating ore particles the steps of continuously introducing into a tank a separating medium consisting of water and comminuted solids and of uniform specific gravity, flowing the medium along the tank to a point of overflow, continuously introducing ore particles into the tank between said overflow point and the point of introduction of the medium, removing a portion of the medium with the ore particles suspended therein at a point intermediate the upper and lower zones of the medium through a common passage, separating the removed ore particles from such removed medium and returning removed medium to-the tank at a point therein between the point of removal and the overflow point.
  • a continuous process of separating ore particles the steps of continuously introducing into a tank a separating medium consisting of water and comminuted solids and of uniform speciflc gravity, flowing the medium from the point of introduction along the tank to a point of overflow, introducing ore particles into the tankbetween said overflow point and the point of introduction of the medium, removing a portion of the medium together with the ore particles suspended therein at a point intermediate the upper and lower zones of the medium, separating the removed ore particles from such removed medium and returning removed medium to the tank at a point therein within the body of the flowing medium.
  • an ore feed conduit extend,- ing down to the surface of the medium in the tank, said feed conduit having'a liquid outlet therefrom above the surface of the medium in the tank.
  • a tank containing a liquid separating medium, an ore feed conduit extendin down below the surface of the medium in the tank, said feed conduit having a liquid outlet therefrom above the surface of the medium in the 8.
  • a tank containing separating medium composed of water and comminuted solids means continuously introducing said medium at uniform specific gravity into the surface portion of the memm in the tank at one end thereof, overflow means adjacent the opposite end of the tank, whereby the medium is converted into one of constantly increasing diflerential between specific gravities of the top and bottom portions of the medium as it flows along the tank,'ore feeding means introducing the ore particles into the surface portion f the tank intermediate said medium inlet and said overflow, and an airlift in the tank between the ore feed and said overflow and between the top and bottom of the medium, and means for adjusting the inlet to said airlift in the medium to points of different specific gravity thereof, whereby portions of the medium of a desired specific gravity and the ore particles associated therewith may be removed from the tank.
  • the continuous process'of separating ore particles which consists in continuously introducing a separating medium of uniform specific gravity and consisting of water and comminuted solids into a tank adjacent one end thereof, flowing said medium along the tank and thereby converting it into a medium of increasing specific gravity from the top to the bottom, controlling the differential in specific gravity thus created, continuously overflowing the surface portion of the medium from the tank adjacent the other end thereof, continuously introducing the ore particles into the tank near the point of introduction of the medium, and removing from the tank a portion of the medium intermediate the top and bottom portions thereof together with ore particles suspended in saidremoved portion through a common passage intermediate the ore feed and said overflow.
  • the continuous process of separating ore particles which consists in continuously introducing a separating medium consisting of water and comminuted solids and ofuniform specific gravity into a tank, continuously flowing said medium along the tank, continuously overflowing the surface portion of the medium from the tank, converting said medium into one of constantly increasing specific gravity, introducing the ore particles into the tank near the point of introduction of the medium, and removing medium intermediate the top and bottom zones thereof together with ore particles suspended in theremoved medium through a common passage from the tank intermediate the ore feed and such overflow.
  • an apparatus for continuously separating ore particles in a tank containing a liquid separating medium consisting of water and comminuted solids means continuously introducing the medium into the tank near the'rear end thereof, means continuously feeding the ore particles into the tank, means removing the heavier ore particles from the tank to the rear of the medium inlet, a bafllewithin the tank to the rear of said medium inlet and extending across the tank and from the surface of the medium in the tank to a point adjacent the means for removing the heavier ore particles, means reducing the specific gravity of the medium to the rear of said baflie, said'means consisting of a water inlet to the tank below the surface of the medium and a liquid outlet adjacent the said surface, both the inlet and outlet being located to the rear of said baflie.

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  • Separation Of Solids By Using Liquids Or Pneumatic Power (AREA)

Description

April 1 4- G. J. HOLT ETAL 2,347,264
PROCESS AND APPARATUS FOR SEPARATING FRAGMENTARY MATERIALS Filed Oct. 21, 1940 3 Sheets-Sheet l April 25, 1944. G. J. HOLT ETAL PROCESS AND APPARATUS FOR SEPARATING FRAGMENTARY MATERIALS Filed Oct. 21, 1940 3 Sheets-Sheet 2 .N um UH v w m n55 O 35 59: 6 wwimhzuuzou Eu. 0 nuhqmkzuuzou u= manna wmcan; 1 i
m w l -H WW n.l l l n m NW N N ll ||mlll gmls EQ GroverJi How Rwy-sky Rag W Arms April 25, 1944. G. J. HOLT EIAL PROCESS AND APPARATUS FOR SEPARATING FRAGMENTARY MATERIALS Filed Oct. 21, 1940 3 Sheets-Sheet 5 N swan M5 Grover J: 1 0
Yc'clor Rafiousky 1 Ray W Ann-s Ca mwn, i/L aim Patented Apr. 25, 1944' om cs PROCESS AND APPARATUS FOR SEPARAT- ING FRAGMENTARY MATERIALS Grover J. Holt, St. Paul, Minn, Victor Rakowsky, Joplin, 'Mo.. and Ray W. Anna-Evanston, 111., assignors to Minerals Beneficiatlon Incorporated, Chicago, 111., a corporation of Delaware Application October 21, 1940, sonar No. 362,144
17 Claims.
This invention has for its object to provide anovel continuous and emcient process and apparatus for separating fragmentary materials of different specific gravities, such as coal, ores and the like,
With this object in view, according to the present invention a tank of some considerable extent. in length and of approximately uniform width is provided, which tank preferably gradually increases in depth from the rear end where the materials to be separated are introduced toward the opposite rear end, While this gradual increase in depth of the tank is preferred, it is not essential, since in some cases a tank of approximately uniform depth from the rear end to the front end and of uniform width may be employed.
Into a tank of. the character described a separating medium composed of water and comminuted solids and preferably of uniform specific gravity is continuously introduced adjacent the rear end of the tank and is caused to flow through the tank toward the front end at a slow rate. As the medium flows slowly through the tank the comminuted solids of the medium very slowly settle, the rate of settling depending on the strength of ,the current and the make-up of the medium.
The result is that the medium becomes one of gradually increasing specific gravity from the top downward, the rate of increase being controlled by the rate of fiow of the medium, whereby a constantly increasing differential between the specific gravities of the top and bottom of the tank is established. Moreover, as the medium flows through the tank from the point of introduction the specific gravity of the upper portion gradually decreases while that of thelower portion gradually becomes greater. The current through the tank is secured and controlled by a plurality of means. One is in the form of an overflow at a point toward the front end of the tank opposite from the point of introduction of the medium. Another is in the form of means for withdrawing medium from the tank at some point or even a plurality of points below the surface thereof and intermediate the point of introduction and said overflow. Both the overflow and the intermediate means for withdrawing medium from the tank are preferably adjustable longitudinally along the tank. That is, the overflow means are preferably arranged to be adjusted toward or from the point of introduction of the medium; and the means for removing the medium from the tank intermediate the point of introduction and the overflow may be adjusted toward or from the point of introduction. Moreover. this intermediate means of removal of the medium may be adjusted to difi'erent heights within the body of the medium to the end that the medium may be removed from the tank at different levels therein.
By the means described there is aflorded a control of the increase in the specific gravity of the medium from the top downward, which control may be effected anywhere along the tank between the point of introduction of the medium and the point of overfiow. There is thus secured a plural control; that of the rate of increase in the differential density of the medium (degree of increase in specific gravity from the top downward) and the position of withdrawal of the medium at any point in the tank between the point of introduction and the overflow, whereby the operator is enabled to select the particular diflerential density best adapted to eflect a separation of the ores under treatment.
For the purpose of illustrating the invention, reference is had to the accompanying drawings, in which- Fig. 1 is a diagrammatic view somewhat in perspective of one form of tank which may be employed;
Fig. 2 is a diagrammatic longitudinal sectional elevation of the tank shown in Fig. 1;
Fig. 3 is a diagrammatic plan view of said tank;
I Fig. 4 is a diagrammatic view illustrating the apparatus employed for recovering the solids from the used medium; FiFig. 5 is a view on the section line 5-5 of Fig. 6 is a diagrammatic side elevation of a modified form of the tank;
Fig. 7 is a like diagrammatic side elevation of still another form of tank that may be employed;
Fig. 8 illustrates a construction alternative to that shown in Fig. u; and
Fig. 9 is a detail of the entrance ports of the air lifts.
Referring to the drawings, in which like reference numerals indicate like parts throughout the several views, is a tank of considerable longitudinal extent and preferably of approximately uniform width, which tank is of constantly increasing depth from the rear end I to the point I". While the tank may be of constantly increasing depth from the rear end to the other,
as shown in Fig. 1, such increase in depth at the end I" is not absolutely essential. At or near the point I" the bottom of the tank may be fiat, or of other desired shape. As shown in Figs. 1 and spaced scraper flights 2' are passed over sprockets 3-3 driven from any suitable source of power, said sprockets being so arranged that the scraper flights 2' drag along or close to the bot tom of the tank, moving in the direction indicated by the arrows. An extension or the bottom of the tank (on the right hand as illustrated in Figs. 1 and 2) projects a considerable distance upward out of the tank to a chute d.
Extending across the tank from side to side near the shallow end thereof, is a chute 6 through which a ribbon of a separating medium of uniform specific gravity is continuously introduced into the tank, said ribbon extending across the tank from side to side. Extending across the tank'and adjacent the end opposite from the medium feed chute 6 is an overflow trough or conduit 1, the bottom of which is somewhat below the surface of the medium in the tank when in operation. This overflow chute i may be and preferably is adjustable longitudinally of the tank. That is, it may be moved nearer to or more remote from the medium feed chute Between the medium feed chute t and the overflow 8 means are provided for removing medium from the tank which means are preferably ad justable both longitudinally and vertically in the tank. As here shown, such means take the form of a chute 8 adjustable longitudinally of the tank i toward or from. the overflow. The chute carries telescopic conduits 8' which, by reason of the telescopic construction, enable the entry ports 8" to the conduits to be adjusted vertically, thus providing means whereby the inlet ports 3" (Fig. 2) of the conduits 8' may be raised or lowered within the tank. While this construction is preferred, any suitable means for adjusting the entrance ports 8" vertically and longitudinally of the tank may be employed. As illustrated in Fig. 8. the entrance port or ports 8" may be'in the form of an open end or ends of a tube or tubes having a universal mounting 8a in the side walls of the tank and connected with suitable means ill) for withdrawing medium from the tank through the ports 8", such as a pump, air lift or the like.
Means for feeding the material to be separated are provided, preferably adjacent to and immediately in front of the medium feed chute 6, said means taking the form of a chute 9 Or other feed means extending across the tank from side to side and arranged to feed a ribbon of the ores or other materials across the tank from side to side and immediately in front of the ribbon of medium delivered into the tank from the medium chute 6, to the end that the separating medium and the materials to be separated are fed in the form of adjacent ribbons extending across the tank.
Disregarding now for the moment the infeed of the materials to be separated, it will benoted that when the medium is fed into the tank and the same becomes filled to the level of the overflow I, a current will be created. along the tank, the rate of flow of the current depending upon the rate of flow of the medium at the inlet. When the medium enters the tank at the chute 6 it is of uniform specific gravity, and being composed of water and comminuted solids, the solids will tend to very gradually settle toward the bottom of the tank as the current or medium moves alongtowards the overflow I and the air 7 21a plurality of endless carriers 2-2, preferably in the form of chains, and carrying suitably or the comminuted solids is to convert the medium which was of uniform specific gravity when it was introduced into the tank into a medium oi differential density, that is, one in which the specific gravity of the medium gradually increases from the top to the bottom. Moreover, as the. medium flows through the tank the specific gravity of the upper portion of the medium gradually decreases, while the specific gravity of the lower portion of the medium gradually increases, and these specific gravities will continue such gradual decrease and increase as the medium flows along through the tank. This gradient or difierential between the top and bottom specific gravity is controlled by the rate of flow oi the medium fromthe intake chute 6 to the overflow i and the air lifts 8'. The rate of flow of the current and the position of the overflow and the air lifts all being under the control of the operator, the gradients are under his control.
There will be a line between the top and bottom of the medium, as it flows along through the tank, where the specific gravity will be that of the medium at the point where it is introduced. The exact position of this line will vary dependme upon the rate of flow of the medium through the tank, but there will always be a line at any lift 8'. The result of this very gradual settling 7;
cross section of the tank and somewhere between the top and the bottom where the specific gravity of the medium will be that of the medium when introduced into the tank.
When the particles to be separated are fed across the tank in the form of a ribbon immediately adjacent or near the inflowing ribbon oi medium of uniform speciiic gravity, particles of ore fall upon said medium and the particles whose specific gravity materially exceeds that of the incoming medium will quickly sink to the bottom, while any of the particles which are lighter than the specific gravity of the medium at the point of introduction will float possibly carrying with them entangled therewith some particles whose specific gravity even exceeds that of the incoming medium; other particles having a specific gravity equal to or greater than that of the desired concentrates may be carried along I by the medium current for some distance but will sooner or later sink to the bottom. As the medium fiows along the specific gravity at the top decreases andany particles whose specific gravity exceeds that of the overflow will settle in the medium until they reach a depth where their specific gravity is the same as that of the medium. This separates the ore particles into concentrates, middlings and tails.
This is diagrammatically illustrated in Fig. 2. When medium of 'a uniform specific gravity, for example, 3.06, and composed of water-and comminuted solids, is introduced at the chute 6 and caused to flow through the tank to the overflow 1 and air lifts 8', the solids in the medium will very slowly settle, the rate of settling depending upon a number of factors, such as the character of the solids in the medium, the proportion of solids and water and the rate of flow of the medium through the tank. This gradual settling of the solids will produce in the tank ually and continuously increases. There will always he a line extending from the feed chute 8 towards the opposite end of the tank which will be of the same specific gravity as that of the'medium at the point of introduction. If the specific gravity of the introduced medium is 3.06, forexample, there will be a line extending along through the medium in the tank where the medium has a specific gravity of 3.06. The exact position of this line will, of course, vary, but for the purpose of illustration it is shown in Fig, 2 at 11/. All of the ore particles introduced at the chute 9 whose specific gravity exceeds 3.06 will settle below this line 1!, and all of those particles whose specific gravity is less than 3.06 will be floating or suspended in the medium above or but slightly below that line. Before they reach the air lift 8 all of the concentrates whose specific gravity equals or exceeds that of the bottom (say 3.35) will have settled into the path of the flights 2'; all of the'ore particles whose specific gravity is equal to or less than that of the surface portion of the medium in the tank when it reaches the air lift will float and will be discharged through the overflow I; and all of the ore particles which are of greater specific gravity than the surface portion of the medium at this point and of less specific gravity than the bottom portion will be suspended in the medium below the upper portion thereof.
That portion of the particles of intermediate specific gravity which is thus suspended within' 7 the gradient or controlled differential of the medium will be drawn by the air lifts thereinto and discharged from the tank together with some medium. The result of this is that all of the ore particles whose specific gravity is greater than that of the medium along the bottom of the tank are removed by the drag, while those whose specific gravity is less than that of the bottom are eliminated by the overflow of the air lifts from the tank. This produces a highly eflicient and accurate separation of the particles into concentrates, tails and middlings.
By reason of the fact that the drags extend up an incline considerably above the surface of the medium in the tank, little or no medium in liquid form is discharged by the drags throughout the chute 4. The heavier particles thus discharged are wetted with the medium and carry more or less of the comminuted solids associated therewith. These particles are discharged through the chute 4 upon a suitable screen It) (Fig. 4) and are sprayed with water from the spray Ill. The water and comminuted solids washed off the heavier particles pass through the screen into a suitable receiver ll, while the heavier particles thus washed clean are delivered from the screen. The lighter particles carried out of the tankat the overflow I are accompanied by a considerable amount of the medium and are discharged upon a screen l2. The medium flows through the screen into a receptacle l3, while the particles descend along the screen and are subjected to sprays ll whichwash the comminuted solids therefrom, the water and solids passing through the screen and into a receptacle I5, the washedparticles being delivered from the screen i2.
The discharge from the air lifts 8' consists of a considerable body of medium carrying therein the ore particles withdrawn therewith and this medium, together with the particles, is delivered to a ,screen [6, the medium flowing are delivered into a receptacle the particles are advanced along the screen u der a spray l8 where any of the comminuted solids of the medium adhering thereto are washed therefrom, and together with the spray water, l9. The medium which is thus delivered into the receptacles I3 and I1 may be and preferably is returned to the tank I together with medium from the tank 20 through the chute 6 by means of a pump or otherwise; or such portion of it as may be desired may be returned from receptacle H to the tank through conduits 30 (Fig. 2) having universally mounted delivery portions 31 preferably located at a point beyond the air lifts 8' and not too close thereto. The wash water from the sprays l, l4 and I8 and which is received in the receptacle ll, l and I9 may be and preferably is conveyed to a suitable settling tank for reconditioning and reuse. This tank 20 is of considerable size, and as the solids settle therein, the settling tends to more or less clarify the water at the surface of the tank and it may be delivered to the respective sprays'by minuted solids employed in the medium.
In some cases the ores or other particles that are fed into the tank are washed before being introduced thereinto in order to free them from slimes and other objectionable particles. By reason of the large amount of ore or other particles thus washed and fed into the tank, the films of water surrounding each particle in the aggregate constitute a considerable amount of water, and this water being of less specific gravity than that of the medium itself would immediately rise to the surface of the medium in'the tank. Means are provided in the form of suitable outlet croutlets for removing this water. This rising of water may even occur in the lower portion of the infeed ribbon, and in that case suitable outlet 22 (Fig. 2) or outlets are provided for eliminating such water.
In order to effect this delivery of the 'water from the tank before it is carried along to any extent on the surface of the medium, a baflie or plurality of baflles 23 (Fig. -2) extends across the tank, and to a limited extent-below the surface of the medium. These baffles interrupt the flow of water along the surface of the medium and serve to more effectively remove this water through outlets 22'.
In that portion of the tank to the rear of the medium intake chute 6 the medium tends to be quiescent, with the result that some particles being elevated by drag flights 2 may tend to rise therein and escape the action of the flights. A baflie 24 extends across the tank and downwardly into the medium to approximately the path of the drag flights, and an inlet 25, preferably in the form of sprays, is provided for introducing water to the rear of this baflle, thereby decreasing the specific gravity of the-medium to the rear of the, baffle and insuring the settling of any of these particles to a point within the range of the bame flights. An outlet 26 is provided for through the screen into a receptacle ll, while 15 carrying of! the water which will thus rise to the surface of the medium immediately to the rear'of the baflle 24.
Referring now toFig. 6, there is therein-shown a tank in of uniform depth for the greater portion of its length with its bottom to the rear of the intake of medium and ore materials extending upward along an incline at the rear end of the tank for the delivery of the heavier separated particles by a suitable drag. In Fig. 7 there is shown atank lb of uniform depth from end to end and a drag which delivers the heavier particles from the bottomof the rear end of the tank from which they may be deliveredby an air lift or otherwise as desired.
It will be understood by those skilled in the art that the invention is not limited to the specific apparatus herein illustrated, but that various modifications thereof may be used for effecting the same result, and such modifications as fall within the terms of the appended claims are designed to be included therein, For the purpose of this description the point of overflow is to be regarded as the front end of the tank and the opposite end as the rear end thereof.
What is claimed is:
.1. In an apparatus for separating ore particles having difierent speciflc gravities, the combination of a tank containing a liquid separating medium consisting of water and comminuted solids, means introducing said medium at uniform speciflc gravity adjacent one end of said tank and into the surface portion of the medium in the tank, overflow means adjacent the other end of the tank, means for feeding ore particles into the surface portion of the medium in the tank and intermediate the introduction of the medium and said overflow means, a bailie extending across the tank and projecting downward into the surface portion of the tank between the ore feed inlet and said overflow, and a liquid outlet between the baflle and ore feed and adjacent the surface of the medium in the tank.
2. In an apparatus for separating ore particles, a tank containing a separating medium composed of water and comminuted solids, means continuously introducing said medium at uniform specific gravity into the surface portion of the medium in the tank adjacent one end thereof, overflow means adjacent the opposite end of the tank, ore feeding means introducing the ore particles into the surface portion of the tank intermediate said medium inlet and said overflow, a baiile extending across and projecting above the surface portion of the tank, a liquid outlet between the time and ore feed and adjacent the surface of the medium in the tank, and an air lift between said baiile and said overflow means and removing portions of the medium intermediate the top and bottom portions thereof with associated ore particles from the tank.
3. In an apparatus for separating ore particles, a tank containing separating medium composed of water and comminuted solids, means continuously introducing said medium at uniform speciflc gravity into the surface portion of the medium in. the tank at one end thereof, overflow means adjacent the opposite end of the tank, ore feeding means introducing the ore particles into the surface portion of the medium in the tank intermediate said medium inlet and said overflow, and an air lift the inlet to which is between said 4. In a continuous process of separating ore particles, the steps of continuously introducing into a tank a separating medium consisting of water and comminuted solids and of uniform specific gravity, flowing the medium along the tank to a point of overflow, continuously introducing ore particles into the tank between said overflow point and the point of introduction of the medium, removing a portion of the medium with the ore particles suspended therein at a point intermediate the upper and lower zones of the medium through a common passage, separating the removed ore particles from such removed medium and returning removed medium to-the tank at a point therein between the point of removal and the overflow point.
5. In a continuous process of separating ore particles, the steps of continuously introducing into a tank a separating medium consisting of water and comminuted solids and of uniform speciflc gravity, flowing the medium from the point of introduction along the tank to a point of overflow, introducing ore particles into the tankbetween said overflow point and the point of introduction of the medium, removing a portion of the medium together with the ore particles suspended therein at a point intermediate the upper and lower zones of the medium, separating the removed ore particles from such removed medium and returning removed medium to the tank at a point therein within the body of the flowing medium.
6. In an apparatus for separating ore particles wet with water in a tank containing a liquid separating medium, an ore feed conduit extend,- ing down to the surface of the medium in the tank, said feed conduit having'a liquid outlet therefrom above the surface of the medium in the tank.
'I. In an apparatus for separating ore particles wet with water, a tank containing a liquid separating medium, an ore feed conduit extendin down below the surface of the medium in the tank, said feed conduit having a liquid outlet therefrom above the surface of the medium in the 8. In a continuous process of separating ore particles, the steps of introducing into a tank a single separating medium of uniform specific medium to produce and maintain therein a difore feed means and said overflow means and intel-mediate the top and bottom of the tank and removing portions of the medium with associated ore particles from the tank.
gravity and composed of a liquid and comminuted solids, flowing this medium along the tank from the point of introduction, controlling the flow of the ferential density the diflerentia1 of which gradually and continuously increases as the medium moves from the point of introduction, controlling such increase in differential density, continuously introducing the ore particles into the medium, withdrawing a portion of the medium of intermediate specific gravity with the ore particles suspended therein from the tank and separating the withdrawn medium after withdrawal.
9. In a continuous process of separating ore particles the steps of introducing the ore particles into a medium of uniform speciflc gravity and flowing the particles through a body of said medium while its specific gravity gradually and continuously increases from top to bottom and the differential between the top and bottom specific gravities continuously increases as the ore particels move farther and farther from the point of introduction, withdrawing a portion of the meand ore particles dlum of intermediate specific gravity with the ore-particles suspended therein from the tank flow, whereby said medium is converted into a medium of constantly increasing specific gravity from the top to the bottom'thereof, controlling the rate of increase in the differential between the top and bottom gravities of the medium by controlling the rate of flow of the medium, and withdrawing medium of intermediate specific gravity and the middlings suspended therein from the tank through a common passage.
11. In an apparatus for separating ore particles, a tank containing separating medium composed of water and comminuted solids, means continuously introducing said medium at uniform specific gravity into the surface portion of the memm in the tank at one end thereof, overflow means adjacent the opposite end of the tank, whereby the medium is converted into one of constantly increasing diflerential between specific gravities of the top and bottom portions of the medium as it flows along the tank,'ore feeding means introducing the ore particles into the surface portion f the tank intermediate said medium inlet and said overflow, and an airlift in the tank between the ore feed and said overflow and between the top and bottom of the medium, and means for adjusting the inlet to said airlift in the medium to points of different specific gravity thereof, whereby portions of the medium of a desired specific gravity and the ore particles associated therewith may be removed from the tank.
12. The continuous process'of separating ore particles which consists in continuously introducing a separating medium of uniform specific gravity and consisting of water and comminuted solids into a tank adjacent one end thereof, flowing said medium along the tank and thereby converting it into a medium of increasing specific gravity from the top to the bottom, controlling the differential in specific gravity thus created, continuously overflowing the surface portion of the medium from the tank adjacent the other end thereof, continuously introducing the ore particles into the tank near the point of introduction of the medium, and removing from the tank a portion of the medium intermediate the top and bottom portions thereof together with ore particles suspended in saidremoved portion through a common passage intermediate the ore feed and said overflow.
13. The continuous process of separating ore particles which consists in continuously introducing a separating medium consisting of water and comminuted solids and ofuniform specific gravity into a tank, continuously flowing said medium along the tank, continuously overflowing the surface portion of the medium from the tank, converting said medium into one of constantly increasing specific gravity, introducing the ore particles into the tank near the point of introduction of the medium, and removing medium intermediate the top and bottom zones thereof together with ore particles suspended in theremoved medium through a common passage from the tank intermediate the ore feed and such overflow.
14. In an apparatus for continuously separating ore particles in a tank containing a liquid separating medium consisting of water and comminuted solids, means continuously introducing the medium into the tank near the'rear end thereof, means continuously feeding the ore particles into the tank, means removing the heavier ore particles from the tank to the rear of the medium inlet, a bafllewithin the tank to the rear of said medium inlet and extending across the tank and from the surface of the medium in the tank to a point adjacent the means for removing the heavier ore particles, means reducing the specific gravity of the medium to the rear of said baflie, said'means consisting of a water inlet to the tank below the surface of the medium and a liquid outlet adjacent the said surface, both the inlet and outlet being located to the rear of said baflie.
15. In a continuous process of separating ore particles, the steps of continuously introducing rate of increase of such differential, continuously introducing ore particles into said medium adj acent the point of introduction of the medium,
separating said particles by the medium as it flows along the tank into tails middlings" and "concentrates, withdrawing separated middling and medium of intermediate specific, gravity supporting the same through a common, passage, then separating the withdrawn medium and middlings.
16. In .a continuous process of separating ore particles into concentrates, "tails" and middlings, the steps of feeding a single separating medium comprising water and comminuted solids, and whose speciflcgravity exceed that of the tails but is less than that of the concentrates, into a tank of horizontal extent and flowing said medium through the tank from the point of introduction toward a point of overflow from the tank, whereby there is established a medium of constantly increasing specific gravity from the top to the bottom thereof, controlling the rate of increase in the differential between the top and bottom gravities of the medium as it advances from the inlet by withdrawing medium at a point between the inlet and the overflow, introducing the ore particles into the medium adjacentthe point of introduction of the medium, whereby the tails float to the top and the concentrates sink to the bottom of the medium and the middlings are suspended in the medium, and removing suspended middlings from the tank, in company with the medium suspending .the same through a com mon passage.
17. In a continuous process of separating ore particles into concentrates, tails and middlings, the steps of continuously feeding a single separating medium comprising water and comminuted solids, and whose specific gravity exceeds that of the tails but is less than that of the concentrates, into a tank of horizontal extent and flowing said medium through the tank from the '6 I aaemea 'point of introduction toward a point of overflow from the tank. whereby there is established a medium of constantly increasing epecitic gravity from the top to the bottom thereof. controlling 3 middlings in company with the medium suspendthe rate of increase in the diflerential between the top and bottom gravities oi the medium by modifying the rate of flow of the medium as it advances from the inlet, continuously introducing the ore particlesinto the medium adjacent the point of introduction of the medium. whereby the tails --float to the top and the concentrates sink to the bottom of the medium and the middlinss are sue pended in the medium, and removing suspended ing the same from the tank.
GROVER J. HOLT. VICTORBAKOWSKY. RAY W. ARMS.
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Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2460802A (en) * 1945-01-09 1949-02-08 Colorado Iron Works Co Method of starting a fine heavy media separation plant
US2474774A (en) * 1945-06-01 1949-06-28 American Cyanamid Co Heavy-media separation apparatus
US2486682A (en) * 1942-11-14 1949-11-01 Ridley Frank Frost Gravity liquid separation of solids
US2678727A (en) * 1949-08-17 1954-05-18 Jaruza A G Chur Soc Separating solid materials by suspension
US2713945A (en) * 1951-05-15 1955-07-26 Stamicarbon Separation of mixtures of solid particles differing in specific gravity
US2753998A (en) * 1950-05-03 1956-07-10 Hardinge Co Inc Method and apparatus for heavy-media separation
US2764290A (en) * 1952-12-02 1956-09-25 Wilmot Eng Co Hindered settling separation apparatus
US2771994A (en) * 1952-11-13 1956-11-27 United Eng & Constructors Inc Apparatus for separating materials of different specific gravities
DE959811C (en) * 1951-09-25 1957-03-14 Hardinge Company Inc Separation of substances with different settling rates in liquids, e.g. in water
DE1152371B (en) * 1960-01-02 1963-08-08 Schuechtermann & Kremer Feeding device for the even distribution of black beetroot in sink separators
US3393876A (en) * 1966-11-21 1968-07-23 Bunker Hill Company Recovery of lead from waste storage batteries

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2486682A (en) * 1942-11-14 1949-11-01 Ridley Frank Frost Gravity liquid separation of solids
US2460802A (en) * 1945-01-09 1949-02-08 Colorado Iron Works Co Method of starting a fine heavy media separation plant
US2474774A (en) * 1945-06-01 1949-06-28 American Cyanamid Co Heavy-media separation apparatus
US2678727A (en) * 1949-08-17 1954-05-18 Jaruza A G Chur Soc Separating solid materials by suspension
US2753998A (en) * 1950-05-03 1956-07-10 Hardinge Co Inc Method and apparatus for heavy-media separation
US2713945A (en) * 1951-05-15 1955-07-26 Stamicarbon Separation of mixtures of solid particles differing in specific gravity
DE959811C (en) * 1951-09-25 1957-03-14 Hardinge Company Inc Separation of substances with different settling rates in liquids, e.g. in water
US2771994A (en) * 1952-11-13 1956-11-27 United Eng & Constructors Inc Apparatus for separating materials of different specific gravities
US2764290A (en) * 1952-12-02 1956-09-25 Wilmot Eng Co Hindered settling separation apparatus
DE1152371B (en) * 1960-01-02 1963-08-08 Schuechtermann & Kremer Feeding device for the even distribution of black beetroot in sink separators
US3393876A (en) * 1966-11-21 1968-07-23 Bunker Hill Company Recovery of lead from waste storage batteries

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