CA1127326A - Method for increasing fine coal filtration efficiency - Google Patents
Method for increasing fine coal filtration efficiencyInfo
- Publication number
- CA1127326A CA1127326A CA321,522A CA321522A CA1127326A CA 1127326 A CA1127326 A CA 1127326A CA 321522 A CA321522 A CA 321522A CA 1127326 A CA1127326 A CA 1127326A
- Authority
- CA
- Canada
- Prior art keywords
- froth
- coal
- product
- flotation
- aqueous liquid
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
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Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION 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
- B03B—SEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
- B03B9/00—General arrangement of separating plant, e.g. flow sheets
- B03B9/005—General arrangement of separating plant, e.g. flow sheets specially adapted for coal
Abstract
METHOD FOR INCREASING FINE COAL FILTRATION EFFICIENCY
Abstract of the Invention Fine coals suspended in a coal flotation froth are more efficiently filtered when the flotation froth is subjected to a thickening operation prior to filtration.
The thickening operation is accomplished by the use of a clarifier or thickener.
Abstract of the Invention Fine coals suspended in a coal flotation froth are more efficiently filtered when the flotation froth is subjected to a thickening operation prior to filtration.
The thickening operation is accomplished by the use of a clarifier or thickener.
Description
l~Z~7326 Back~round of the Inventlon Raw coal, as it ls taken from a mine, conslst3 of lumpq and partlcles of coal which difrer both ln ~lze and degree of purity. Be~ore ~quch coal may be shipped to a consumer it mu~t be crushed and sl3ed and must meet ~pecl~led ~tandard~ o~ purlty in order that it be fit both ~or shipplng and for lt lntended u~e. Specifically, the coal must often be separated both from refu~e, l.e. pyrites, ~late, clay, etc., and ~rom water, and other llquld~, used to separate such re~u~e.
To effect ~uch separation3 the raw coal i3 ~requently sub~ected to a crushlng operation and then to a 3eries of screenlng operations which pass the over~lzes, i.e. the coal that does not pass through the screens, to .~igs, heavy medium cyclone~ or hydrocyclones or other approprlate apparatus where refuse ls removed.
The coal partlcle~ which pas~ through all screening operatlon~, i.e. the coal undersize3, are designated ~Ifines~
and are typically on the order o~ minus ~ixty-five mesh.
These fine~ represent a ~i~nificant percentage of ~he coal mlned and, there~ore, the overall economics o~ the mining operatlon are dependent upon an ef~lcient separatlon and recovery of the3e fines from their impuritle~.
Conventlonal methods for the purification and recovery of ~lne~ comprl~e routing an aqueous slurry of theRe fines to a flotation cell in which the slurry is treated with an organlc reagent such aq, for exæ~.ple, methyl i~obutyl carblnol or 2-ethylisohexanol. These rea~ents, by
To effect ~uch separation3 the raw coal i3 ~requently sub~ected to a crushlng operation and then to a 3eries of screenlng operations which pass the over~lzes, i.e. the coal that does not pass through the screens, to .~igs, heavy medium cyclone~ or hydrocyclones or other approprlate apparatus where refuse ls removed.
The coal partlcle~ which pas~ through all screening operatlon~, i.e. the coal undersize3, are designated ~Ifines~
and are typically on the order o~ minus ~ixty-five mesh.
These fine~ represent a ~i~nificant percentage of ~he coal mlned and, there~ore, the overall economics o~ the mining operatlon are dependent upon an ef~lcient separatlon and recovery of the3e fines from their impuritle~.
Conventlonal methods for the purification and recovery of ~lne~ comprl~e routing an aqueous slurry of theRe fines to a flotation cell in which the slurry is treated with an organlc reagent such aq, for exæ~.ple, methyl i~obutyl carblnol or 2-ethylisohexanol. These rea~ents, by
-2-1~2~326 virtue of thelr afflnlty ~or carbonaceous surfaces, coat the coal partlcles, while leavlng the non-carbonaceous particles of re~use unchanged. The ~lotation bath in whlch such coatlng i8 ef~ected ls vigorously agitated by conventlonal stirring mean~ and by constant aeratlon. As a result of thls agitation and aeratlon, the alcohol-coated coal fines tend to adhere to the air bubbles and rl~e to the sur~ace of the bath, ~ormlng a so-called flotation froth. At the same time, the uncoated re~u~e partlcle~ tend to remain ln suspen310n ln the flotatlon bath and are wlthdrawn therefrom and di3carded. Wlth slxty-five mesh coal, the flotation ~roth may typlcally contaln perhaps 15% coal partlcles and as much as 20~ o~ coal particles by welght, the exact percentage belng dependent on particle size~ shape and denslty, type of ~lotatlon machlne and manner o~ operation.
This flotation froth iB continuou~ly removed from the ~urface of the bath and vacuum flltered ln order to dewater the coal. The flne coal 1~ then remo~ed from the filter and either used as 1~ or recombined wlth the larger coal 3iz~s separated by prlor ~creening and processln~
step~.
The u~e of these conventlonal techniques re~ults ln acceptable purl~lcatlon o~ the flne coal in the ~lotatlon step ltsel~. Xowever, the ~iltration step has been less than sati~factory due to at least two limlting factors dlrectly re3ulting from the sheer amount of wa~er contained ln the flotatlon froth.
The flrst limlting factor arises from the ~act that virtually all ~llters are limited ln the gro~s volume ~Z7326 of filterable solution they can handle 3er unit tlme by t~e size of the ~llter. Thus one con~equence of the hi~h water to coal welght ratlo in conventlonal flotation froth3 1~
that the qheer volum~ o~ ~roth containlng a given amount of water may exceed the rllter's physical capacl~y or volume and thereby liml~ the hourly volume of froth which can be ~iltered. In other words, although a gi~en filter may be capable o~ handling the amount o~ water contained ln a glven amount Or flotatlon ~roth, the ~heer volume of froth con-talnlng water may be too great for the ~llter to handleefflciently, or even at all. As a result, the overall rate of coal processing may be ~eriously limited by the ~lltration step.
The second limlting ~actor ln the conventional proce~s i~ the low yields o~ coal per unlt time. This low i~olation rate (expressedj ~or example, in pounds o~ coal i~olated per hour) ls directly attributable to the rela-tlvely low percentage Or coal present in any ~lven volume of con~entlonal flotation ~roth.
It i~ important ln many ~ilters, furthermore, partlcularly in drum or dlsk type ~acuum ~ilters, ~or the medlum belng filtered to contain su~ficient solid~ to initlally coat the filter element in order to establi3h a differentlal ~ressure between the down~tream 3ide of the ~llter and the upstream side. I~, for example, a drum or disk type fllter i~ presented wlth a froth contaln~r.g only a little particulate material such as ~lne coal, the sur~ace of the fllter ln the absence of a coatln~ of partlcula~e 1~2~73~
wlll remain ~o porous that lnsuf~icient pres~ure difference between one ~ide o~ the ~ilter medium and the other wlll be established to conduct any sub3tantial flltering at all.
Thus in those cases in which the froth volume compared to the sollds content of the froth ls very large initiatlon of filterlng may be delayed ~or a flnlte period a~ the solld3 build up on the filter sur~ace thus delaying the lnitlation of e~flcient ~lltering and posstbly allowing more fine solids than usual to pa ~ through the ~llterlng medium or ~llter cloth.
In order to avold these di~flculties a ¢oarser ¢oal product from a previous separatlon ~tep has often been combined with the froth, or flotation product, prior to fllterlng to lncrea~e the percentage o~ coal in the ~lotation product and lncrease the ef~iclency of ~lltering. The combination o~ the prior coar~er coal, ~or example, coal havlng a partlcle slze greater than 65 mesh, with the ~lotation coal product of 65 mesh or le~ naturally provides a mlxed coal slze whlch may, or may not, be deslrable d~pendin~ upon circumstances. A more ~erious problem arises, however, when the ~lotation product must be thermally dried after ~llterlng~ but prlor to u~e. Flne coal particles of about 65 mesh or less haYe a large aggregate surface area and tend to retaln a large amount of moisture. A fairly large amount of ~uel is nece~sary to generate the heat values ~o remo~e thls moi~ture. Under these clrcum tances it i3 ine~ficient to mix a coar~er coal product ~ith the ~lne coal ~lotatlon product and thermally dry the mixed coal ~27~Z~ii product. The coarse coal doe~ not normally retain sufflcient moi~ture to require thermal drying and thus adds a slgnlficant amount of bulk to the mixed product, all of whlch must be heated, without addlng molsture which requlres removal. The efficlency of the dryln~ operation is thus substantlally decreased.
It ha~ been customary under somewhat ~imilar clr-cumstance~ in the fllterln~ of mlneral flotatlon products, ~or example, mineral ores and the like~ to thlcken the flotatlon product by the u~e of a thickener or clarifier.
In these ~ystem~ the flotatlon product is conveyed to a thlckener where it i8 retained on the surface o~ the liquid body ln the thickener until ~he ~ro~h break~ down and the mineral particles settle to the bottom of the thlckener.
The underflow 1~ then conveyed to a sultable filter. Some-times sprays are used to accelerate decomposition of the flotation ~oam or froth on the ur~ace of the thickener.
While flotation followed by thickenlng in a thickener, or settllng apparatus, has been successfully used in the treatment of mineral ores, it has not proven satlsfactory in the treatment o~ coal. The mlneral particles in an ore flotation froth product have a higher speclfic gravity than coal partlcle~ and are less resi~tant to wetting than coal froth solids. Consequently, while mineral particles are readily rel~aRed ~rom a ~lotation froth, coal sollds in a flotation froth product are not readlly released from the froth in a conventlonal thlckener even with auxillary spraying. The froth persi3t3 and only a portlon of the fine ~L~732~
coal product wlll ~ettle to the bottom of the thickener ln a condltlon for ~llterlng. In the case of coal, once ~he coal has been floated lt 19 almost totally imposRlble wlthout chemical treatment to su~iciently wet all the floated coal particles to release the coal ~rom the froth 80 that a conventional thickener can be u~ed to prepare the flotatlon product ~or efflclent ~lltering. Some amount of coal wlll always remain attached to the air bubbles and remaln on the ~urface o~ the thickening vessel.
; 10 It ~ould thu~ be desirable to decrease the volume of coal flotatlon froth product prior to filtratlon. It would, furthermore, be de~lrable to dec-rease such volume while lncrea~lng the percenta~e o~ coal particles per unlt volume of froth product in order that ~ine coals may be more rapldly i301ated therefrom.
Summary of the Invention I have dis~overed that both of these desirable goals may be accompli~hed by sub~ecting ~lne coal flotation froths to a pre-riltration thickening ~tep wherein the weight ratio of coal to water ln the products is increased.
Speclficallyg my proce~s treats fine coal flotat~on froths ln a modlfled con~entional thlckener whereby a portion of the froth is physlcally decomposed, i.e., a portion of the bubbles contalned in the froth are caused to burst or coalesce.
ThiR decompo3ition results in the drainlng o~ a significant portlon of the water contained ln the orlglnal froth, thereby lncrea~lng the coal to water weight percent, l.e. thickening the froth.
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In addltion to decreasing the water content of the froth, the thickenlng operation cause~ a portlon of the suspended coal particles to separate from the froth. The ma~or portlon of this ~eparated coal settles to the bottom 5 ~ o~ the thlckening apparatus where it may be collected and recombined with the thickened fro~h prlor to ~iltratlon to ~ield a ~roth product wlth an even hlgher sollds content.
I have found that a froth thlckened ln accordance with my ln~ention re~ults in both an lncrease ln the overall filtration rate and ln an lncrea~e in the rate of recovery of coal solid~ from the flne coal flotation froth product per unik time. Furthermore, where the volume of the non-thickened foam or flo~ation product compared to the solids ~ content o~ ~ine coal which ls contained ln the foam is very large, u~e of the ~hickening operation also lncreases the efficlency of ~ilterln~, i.e. the solids recovery9 itsel~, due to accelerated coa~ing of the ~ilter ~urface with fine particles which increase the filter se~aration e~iciency.
In a pre~erred arrangement the flotation froth is passed from the flotatlon tanks to a thlckener where the froth floats upon the sur~ace o~ a body of fluid contained ln the thlckener. The residence tlme in ~he thickener is ~uf~icient ~o that signlficant ~ater contained in the ~roth drain~ from the ~roth lnto the underlying llquid and a portlon o~ the coal flne~ in the froth settle to the bottom o~ the thickener. The remaining thickened froth is then pushed from the surface of the liquld over the ed~e of the thickener, preferably combined with underflow sollds, and . -3~
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transported to the filter. Water as an effluent is drawn off at an intermediate point and can be returned to process.
More particularly the invention involves a method for recovering coal particles from a froth-product containing water obtained in a froth-flotation type coal fine treat-ment system, comprising: (a) charging said froth-product containing coal fines attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) removing the thickened froth-product from said thickener apparatus, (d) filtering said thickened froth-product to yield said fines.
Brief Descri~tion of the Drawings FIGURE l is a block type flow diagram depicting the various steps in a typical raw coal treatment process utilizing the present in~ention.
FIGURE 2 is a schematic type diagram showing the treatment of coal fines in a circui~ including a flotation chamber, thickener and filter in accordance with the invention.
FIGURE 3 is a vertical cross-section of the thickener preferably used in the process of the invention.
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FIGURE 4 is a second vertlcal cross-section of the thickener used in the process along the line B-B
of FIGURE 3 taken at approximate right angles to FIGURE 3.
FIGURE 5 is a top view of the thickener used in my process.
Description of the Preferred Embodiment -A complete understanding of the invention may be gained by those skilled in the art from the ~ollowing discussion with reference to the drawings.
Referring to FIGURE l there is shown a block flow diagram of a coal treatment operation or plant wherein raw coal 11 received from the mine or from crushers, not shown, passes to a screening station or operation 13, which may use a l/4 inch screen, where the coarse fines 15 are removed and passed to a second screening station 17.
The coarse coal -9a-732~
screen product 19 from the screening operat~on 13 may be paæsed to a heav~J medlum ~eparation bath 21 for ~eparatlon into a coar~e coal product 23 and a re~use product 25 con-taining slate, rock, clay and other gangue materlal which i9 discarded. The coarse coal product 23 can be used as is, or reground and u~ed, or retreated. Both the coarse coal Z3 and the re.use 25 are 3hown treated in screen drain and wash statlon~ 21a and 21~ a~ shown a~ter pas~a~e through the heavy medium bath 21 in order to separate the hea~y medlum 10 ~rom the two products.
The coarse fine~ 15 are screened in the second screening ætation 17, wh~ch mag use a 28 mesh screen, to produce a second coarse coal screen product 27 which may likewlse be pa~sed to hea~y medlu~ cyclones 29 which ~n turn produce a coarse or medium coarse coal product 31 and a re~u~e product 33. The two products 31 and 33 are separated ~rom the medium used ln cyclone~ 29 by the use of dra~n and ~a3h screens 2qa and 29b.
~he ~lne3 35 from the screenln~ operation 17 are passed to hydrocyclones 37 where the fine coal particles are ~eparated lnto an over~low strea~ 39 which ls passed to a conventlonal 31evebend 41 and an under~low stream 43 which ls pasæed to reruse 45. The overflow stream 39 which contains most of the coal iæ æeparated on the slevebend 41 into a medium coal product 47 and a flne coal product 49.
The medium coal product 47 is shown combined with the medlum coar~e coal product 31 and passed to a centr~uge operation 51 where the final medium coal product 53 is dewatered.
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The fine coal product 49, which contain~ con-taminating subst~nce~, is passed to a flotation oper~tion 55 where a fine coal froth product ~7, which may contain coal particles of minus 65 mesh size, is floated from a denser refuse product ~9 ln ~ conventional manner and the float or froth product i passed in accordance ~lth the present ; invention to a thickening operation in a thickener 61 which ls ~ho~n in more detall ln FIGURES 3, 4 an~ ~ hereln. In accordance with the invention the flotation or froth product ~7 ls thickened in the thickener 61 by allowing a residence time ln the thlckener 61 suf~iclent to allow water to draln from the froth into the body of liquid held in the thickener 61. The t~ickened froth or de~ified foam product 62 is then passed to a filter 63 by ~weeping the densifled foam ~rom the surface of the body o~ llquld ln the thickener with sultable ~weep arms and conveying the thlGkened or denslfled foam to the filter. As the water drain~ ~rom the foam product ln the thickaner some of the floated coal i5 released from the foam and drop~ to the bottom of the thic~ener.
: 20 Thls coal i~ removed from the bottom of the thickener in a normal fashion as a slurry 6~ and is also passed to the fllter 63 and a~ter filtration enters the flltered fine coal product 65. More preferably the coal product from the bottom of the thickener 61 ls mixed unlformly wlth the froth floatlon product prior to filtration as shown ~y the dotted llne 67 to ~urther ~hlc~en or increase ~he percen~age of flne coal in the froth prlor to pas~age of the .~roth product onto the fllter thereby increa~ing the efflciency or capaclty .......
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of the filterin~ opera-tion. ~his ~s ~ho~n more clearly ln FI~URE 2. The heavy refuse ma-terial 59 is discharged ~rom the ~ottom of the flota~ion apparatu~ and passed to ~laste.
he flltered coal product 65 i~ passed to a ;,ilermal dryer ~pparatus 6g for removal of resldual rnoi~ture from the flnal fine coal product 71. Alternatively the filtered fine coal product 65 can be used i~ desired without drylng. How-ever~ the fine coal has a considerable ~mount o~ sur~ace area and e~en af~er flltering tends to have a considerable amount of water assoclated ~lth it. ~hermal drying i3 thu~
usually necessary to obtain a satl~factory flnal fine coal product. Pri~r to the pre~ent invention it ha~ usually been necessary in order to effect satisfactory fil~erin~ of tne flotatlon product to mix 30me of the medium to coarse coal product 31 or medium coal product 47 ~ith the flotatlon product or flne coal froth product 57 in or~er to den~l~y the froth product ~uficiently to attain an ef~icient ~ilterin~ operatlon. The medium coal product, however, is mor~ effectively dewatere~ by centrilu~ing and the medium coal pro~uct me~el~ adds bulk in the thermal drying cycle i4 added to the flotatlon ~roth product ~lthout a commensurate amount o~ water which mi~ht require thermal drying.
~ IC-URE 2 shows schematlcally the combination o~
the flotation, thickening an~ filterln~ steps of the lnventlon ln more detall. In FI~'uRE 2 i3 shown a conventional flotation apparatus 71 into whlch "raw coal'! in the form of 2 fine coal product ~rom a prlor scre~nlng operatlon such a3 shQ~,rn in FIG-~P;h 1~ or ~rom some other treatment apparatu3~ i~
passed. The fine coal is deposited into the top o~ the flotatlon apparatus ln any ~ultable manner and mixe~ wlth a body of liquid ln the flotatlon chamber 73. A ~erie~ of spinnlng blade~ or agitators 75 at the bottom of the apparatus 5 ~l are dri~en through a central shart 77 by a motor 79 and drlve belt 81 at a hlgh rate of speed. Air i~ drawn down the central well 83 o~ the apparatus and ls intimately mixed with the liquld within the apparatus as fine bubble~ which ¦ float to the ~urface of the llquid body 73 attachlng to ~ine lO ,I coal particles as the bubble rl3e. A suitable flotation Il agent i8 added to the liquld ~o enhance the attraction ; I between the bubbles and the coal partlcles or to cause the bubble~ to adhere more strongly to the coal whlle re~ectlng ~ the remainin~ refuse material9 all as well known in the art of flotatlon treatment. The bubble~ and attached flne coal partlcles collect on the surface o~ the ~lotation chamber as a ~roth product and overflow the baffle 85 lnto the resldence chamber 87 where ~ome densificatlon or thickening of the froth product 89 occur~ be~ore the ~roth product i~ forced ,, , 20 l from the residence chamber 87 by the rotatlng paddle arrange-ment 93 and passed along the chute 95 to the cen~ral feed chamber 97 of a thickener 99. Water dralning from the froth product 89 passes back lnto the main body of liquid 73 ln the ~lotation apparatus through the opening 91 between the 25 , ba~fle 85 and the side of the flotation chamber 73.
i The froth product 89 which enter~ the central feed chamber 97 of the thickenlng apparatus o~ thickener 99 overflows out the bottom of the feed chamber 97 lnto the ... , 13 maln body of the thickener where lt ~loats on ~he sur~ace of the body o~ liquld 101 contained ln the thickening apparatus.
The rroth product 89 ~loats on the sur~ace of the llquid 101 for a perlod de~igned to be suf~lclent to allow a signlflcant 5l amount of water to drain ~rom the roam product 89 80 that the ~oam is thlckened.
The water whlch draln~ from the ~oam product is removed from the thickenlng apparatus ~hrough drawo~f tube 102 and returned to the process, i.e. usually the ~lotatlon ; 10 chamber 71, ~or reuse. A suitable recycle llne for the water ls lndicated as llne 104 ln FIGURE 2. TAe ~lne coal particl~s suspended in the recycled water are largely removed during the next pasaage through the ~lotation-thlckenlng process 80 that the quantlty of ~ine coal particles ln the re¢ycle water doe~ not signlflcantly increa~e wlth tlme.
:The ~oam 1~ pushed ~rom the sur~ace of the liquid ; ~ 101 by a serie~ o~ splral blades 103, more clearly ~hown ln subaequen~ Yiews in FIGURES 3, 4 and 5. The ~piral blades ~ are ~upported ~rom and rotated by sha~t 105 which 1~ ln turn rotated by a motor 107 and drive belt 109. The sha~t 105 al~o support~ and rotates scraper bladss 111 at the bottom o~ the thlckener 99 whlch serve to scrape coal ~olid~ whlch drop to the bottom o~ the th1ckener and urge them toward the ~- aump 113 ~rom whlch they are pumped as a slurry vla condult 115 and pump 117 to mlxing chamber 119 where the coal slurry i~ pre~erably mlxed evenly with ~roth product. ~he ~roth : product i8 expelled over alde baf~le 121 by the splral rotatl~g blades 103 lnto peripheral trough or launder 123 ~rom whlch the froth product ~low~ through condult 125 to the mlxlng chamber 119. The combined mixture Or coal slurry and thickened ~roth, or den~iried ~oam, product then passes ~ rrom the mixlng chamber 119 through condult 127 to the rotating fllter 129.
The mlxing ¢hamber 119 may con~ist o~ a ~mall enclosed space into which both coal underflow and denRified ~roth overflow are passed. Mlxing occur~ e~sentially upon contact and retention within the mixing chamber may be a matter of seconds. Alternatively, the coal slurry may be merely pas~ed into the conduit along or through which the froth produot 18 conducted.
The froth productl whlch has been thlckened, or den~irie~, ln the thickener 99 by allowlng a re~idence time sufficient to allow ~ome of the moisture of the froth product to drain from the rroth ~o that the percentage of aoal to volume of frotb bubbles ls lncrea~ed~ and which pre~erably has al~o been mixed wlth coal slurry ~rom the ~ bottom of the thickener to rurthsr increase the relatlve percentage Or coal to rroth Yolume, ~ilter~ er~iciently upon the fllter wlth an lncreased filter rate a~ compared to the : ~ilter rate o~ unthickened ~roth product. Whlle lt i~
prererred to mlx the coal slurry rrom the bottom of the thlckener with the already thickened9 or densi~led3 ~roth product in order to further lncr~aRe the percentage of coal rlnes ln the ~roth product prlor to rlltering, it i8 al80 possible to elther pa~s the coal slurry directly to the filter 129 or alternatiYely ts pass lt to a second ~llter or even to merely allow it to drain and dry naturally. In either case the thickened froth product, which must, as a practical matter, be filtered somewhere along the way, is filtered more efficiently and at an increased rate than would otherwise be the case. The filtered fine coal product is discharged from the filter into container 131.
The flotation foam derived from the flotation apparatus 71 will usually contain not more than about 18 to 20% solids by weight while after densification or thickening the flotation froth will perferably contain more than about 30% solids by weight, although it may contain from 25 to 30%
solids. Naturally any significant amount of thickening is benficial to filtering efficienty. The foam which initially has a consistency of stiff soap suds, after densification becomes essentially self supporting and very stiff and heavy, although it will still flow.
A preferred construction of a flotation thickener for use in the present invention is shown in FIGURES 3, 4 and 5 and described below.
Referring to FIGURES 3, 4 and 5, thickener, 201, is comprises of an upright cylindrical tank, 202, having an outer wall, 203, which wall has an outer surface and an inner surface, a generally open top 204 and a bottom 205.
The bottom 205 tapers toward the central axis of the tank and forms an underflow discharge port 207. A cylindrical ship to, the outer wall, 203, is provided in the upper end of the tank and is attached to the tank by a concentic ~truc~ural plate, 217. The annular space between said baf~le and said wall has an open lower end, 211, and an open upper end, 213. The upper end of the baffle 209 ls positloned below the upper end of the outer wall 203 of the tank 202.
5 1 A qulescent zone, 210, is derined by the lower portlon of the ba~fle~ the structural plate, 217, and the opposlng sur~ace of the wall, 203. A peripheral trough or launder, 215, is ~ormed by the upper portion o~ baf~le plate 209, the ~ lnner 3urface o~ the upper end Or the tank wall 203, and 10 I structural plate, 217. This peripheral launder, 215, ext~nd~ 360 around the lnner surface of the wall, 203, and is charackerized by a descendlng pltch ln the ~tructural plate 217 from a high pointg 218, to a low polnt~ 220, 180 i away. See FIGURE 4. At the low polnt 220, a froth launder .
dlscharge outlet, 222, i~ connected to ~-uitable ~roth pumpin~ mean~, not shown. Alternatively, a plurallty o~
indivldual perlpheral launders may be formed by ba~le 209, wall 203 and ind~vldual structural plates 217 together wlth sultable end plates. In this al~ernatlve con~tructlon each 20 i indlvidual launder i3 equlpped wlth a froth launder di~charge ~ -outlet analogous to outlet 222 w~ichg in turn, communicates with ~umplng mean~, not shown ln FIGURES 3, 4 and 5.
See FI~URE 2.
Waste water boxe~, 219, are attached to the outer ~urface o~ wall 203 at regularly spaced intervals. Effluent ports, 221, whlch connect the lnterior of thickener tank qulescent zone 210, ~rlth the interior of waste water boxes, 219, are equipped with ad~ustable sleeves3 223. Each waste -17~
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water box is, in additlon, equipped wlth a drainage mean~, not shown, whereb~ ~Yater leaving tank 202 throu~h effluent ~port 221, overflowing ad~ustable slee~e 223 and enterln~
l wa3te water box 219 may be drained there~rom and dlsposed of 1 or furt~er treated as discussed below.
i A cyli~.drical feed well, 225, concentrlc with both the outer wall, 203, and the ba~fle, 209, and inside the baffle 1 pru~ided ln the tank, 202. A rotatable shaft, ~ 227, which ~erves as both ~ mounting and driving mean3 for 1 rakes and scrapers in the thlckener 202, i~ axlally posltioned and connected ~la suitable connecting means at the top to drlve means, not shown. Cylindrical ~eed well 225 1~ spaced from and ~upported by rotatable shaft 227 through attachment strut3 228. In the upper end of the tank, splral 3kimming 15 llblades or 3k~mmers, 229, are mounted on feed well, 225, and are stabili3ed b~ stlf~eners 230 and sklmmer support3, 231, which, ln turn, are att2&hed to mountlng and driving shaft, 227. In the lower end o~ the tank, rake3, 2333 are mounted on the rake mountlngs 234 secured to shaft 227, and are stablllzed by ra~e support means, 235, al~o mounted on ~haft 1 227. Both $he spiral sklmmer~, 229, and rake mountings, ; 233, e;~tend radially outwardly ~ro~ the mountin~ and dri~l~g sha t, 227.
n operation~ a froth ~roduct, containln~ particles 25 ,. of fl ne coal rrom ~roth floation cells in a coal preparation plant, ls char~ed into ~eed rell, 225~ o~ the tank. The ~roth tend~ t,o float on the water ln the ~ank, and ~hile it doe~ 30~ a portlon of the w~ter ln the froth product drains downwardl~ ~rom the froth lnto the water ln the tank carr~ln~
,rlth it a portion of the coal in the ~roth, whlch coal Z~
subsequently settles to 'he bottom 205 o~ the tank 202. ~
such action, the ~roth remainin~ atop the bath i9 thlckened.
ThlcXening can be de~ined as a decr~ase in the volume and ~ater content of the ~oam with an accompanying lncrease ln the percenta~e o~ solids contalned in the remalnlng foam, Thickening re~ults essen~ia}ly ~rom a decrease in the liquid contained in the walls of the bubbles of the foam. The llquid content may be decreased either through eYaporation o~ the liquid from the surface of the lQ foam or by draining of llquid from the bubble walls due to the downward pull o~ gravlty. In either case the individual bubbles tend to become smaller or to bur~t wnen the wall~
contain lnsu~fici~nt liquid for the surface tension to malntain a coheslve bubble wall. Coalescence o~ bubbles due to rupture of the walls between bubbles leads to the formation of larger ~ubble6 with an effectively sm.aller surface area per unlt ~olume of gas enclosed. Thus, re~ardless of whether the lndiYldual bubbles become sm~ller as llquid 19 re~oved from t~elr walls~ or bl~er as a resulc o~ consolidation or co~lescence between kubbles as separating b~bble ~7alls rupture, the Jf~ectlve are~ o~ the ~ubble walls in the froth decreasas. ~lnce the coal partlcles adhere to the bubble wails, the decrease ln the wall area e~ectively increases the concentratlon o~ coal particles per unit o~ wall arel~
This process eff~cti~Jely increases the solids content o~ the froth ~nd thlckens t;.e froth. As th~ area of the ~alls d~crsases and khe concentration c~ coal particies ~ecomes greater som~ o~ the coal particles are crowded o~ an~ crop _ 7 ~ _ ....
from the foam. Other coal particles are released as lndlvidual bubble wall~ are ruptured partlcularly around the periphery of the ~oam mass. The maintenance o~ a liquid body in contact wlth the lower perlphery o~ the ~roth or foam encourages the dralnage of llquid of slmilar composltlon ~rom the bubble walls in the froth. Approxlmately one-thlrd to one-half or even more of the coal particle3 remain attached to the den~ified foam at the ~urface of the thlckener. The thlckened or den~ifled foam material ha~ a con~istency such that lf cut or cleaved lt will maintain its shape in a self supportlng ma~s but is still not so stiff that lt will not ~low alon~ or through a condult of reasonable dlmen~lon~
~; such a~, ~or example, a ~our to six lnch diameter condult.
It ha~ been round to be ~ery dir~lcult 1~ not impo~slble to release the remaining flne coal solids from the den~l~led foam without the addition of special and expenslve wetting a~ent~.
The mountlng and dri~ing shaft, 227~ is contlnuously rotated by the drive mean~ to contlnuously rotate both the 20 spiral sklmmers~ 229, and the rakes, 233. The rotatlon of the spiral skimmers pushes the thickened froth product from atop the water in the tank, over the top of the ba~fle~ 21 -~ and into peripheral launder 215. The froth product then flows do~n the peripheral launder lncllne to an outlet, 222~
2~ at the low polnt of the launder ~rom which it may be removed and routed either to the filter or to any sultable appara~us for prelimlnary recomblnation with the coal solid~ separated and collected as further described below.
~2732 ,1 . . .
As previously stated, durin~ the thlckening operation both water and particles of coal separate from the ~roth and mix wlth the underlylng water layer. The water l~level in the thickener ls stabilized by effluent port 221 5 1l and ad~u~table sleeve 223. By vertlcal ad~ustment of sleeve 223, the level of the llquld ln the thlckener may be varled over a llmited range to accommodate di~erent ~roth depths. Water in exce~s o~ thi3 deslred volume e~it~ over I the top o~ ~leeve 223 into waste water boxe~ 21g and ls l~removed therefrom. The water ~rom the boxes may contain Isignl~lcant amounts of suspended ~ine coal partlcles, and it l~ i8 there~ore preferable ~rom an e~ficlency vlew-polnt that ; llsuch ef~luent water be returned to a prior ~tep ln the coal ; lpurlflcatlon operation in order that thls coal may be recovered. To thi end, water may be u~ed either as a carrier ln the ~creenlng operations or may be returned to the prior ~lotation operatlon. I -The heavier coal particles which have separated ~rom the froth product slnk to the bottom of the thickener 20 ~ tank where khe rotatlon o~ rakes 233 moves the particles down the incllned bottom 205 toward underflow discharge 207, I ~
from which polnt pumping means, not shown, may route these olids to the prevlously mentioned apparatus for recom-bination with the thickened ~roth prlor to filtratlon.
Alternatlvely the collected ~olid~ may be pas~ed to a dryer or the llke prlor to Deing used a~ a ~ine coal.
The use of a thickening operatlon as described result3 in the 3eparation of three coal-containing components ~rom a ~lotatlon froth product: (1) a thickened froth, (2) a water Atream and (3) an under~low dlscharge. The coal partlcles contained ln water stream (2) are smaller than the under~low dl3charge coal particle~ (3) which ~lnk to the bottom o~ the thickener and the water can be recycled in the proce~s~
":
;~ In order to compare the ~iltration ef~lciency of froths as a function of the amount o~ coal solids per ltnit volume, comparatlve experlments were run in which approxlmately ~ ;, equal volumes o~ froth product3 containing increasing coal concèntratlon~ were ~ub~ected to a conventlonal ~iltration , operatlon. Table I gives the results of ~uch experlments.
TA~LE I
COMPARATIVE FILTRA~ION TEST RESULTS*
15 Te~t No. 1 2 3 4 Feed - Volume - cc2000 2000 2000 2000 Feed - % Sollds (By Weight) 9.5 14.0 18,4 31.3 Formqng Time ~ Mln. 1.30 1.30 1.25 1.10 Drylng Time - Min.2.60 2.60 2.50 2.20 Filtrate Volume - cc 1690 1550 1460 920 Wet Cake - Wt. - Gms. 337 453.8 608.7 994 Dry Cake - Wt. - Gms. 192.3 280.6 382.4 600 % Mol~ture in Cake 42~8 38.2 37.2 39.6 Total Cycle - ~ln.* 5.20 5.20 5.00 4.40 Lbs. Dry Cake~
Sq. Ft./Cycle 0.85 1.23 1.68 2.64 Lbs~ ~ry Cake/
Sq. Ft./~r. 9.8 14.1 20.2 3~.0 ~All te~ts were mads usln~ a 0.5 8q. ~ . Denver filter at room temperature under a vacuum of 22-23 ln. o~ mercury.
.
~273~;
.
As shown by Table I, increasing the percentage of coal ~olids ~rom 9.5 to 31.3 resulted in only a 15~ decrease in formlng time ~0.20 min.) ~or a 2000 c.c. feed volume.
However the wel~ht of dry coal i~olated from the thickened feed durlng that shortened time was over three tlme~ that l~olated from the lowest solids feed. As a re~ult of these two co-operating improvements ln ef~iciency, the overall ef~iciency of the flltration ~tep (expressed in weight of dry coal per ~quare ~oot of fllter per hour) was increased by approximately 370%.
It may thu~ be recognized by tho~e skilled in the art that treatlng coal flotatlon froth products in accordance wlth the present invention wlll result in a ~ignificant increase ln e~iciency o~ the coal filtration proce~.
Whlle a preferred arrangement and con~truction of thlckening tank has been shown and de~cribed for u~e in the method of the inYention, it ~hould be understood ~hat an~y comparable thlckening apparatu~ may be used in whlch water can drain ~rom the froth lnto a body of wa~er below and a separation between the ~hlckened froth, the water, and the underflow can be made prior to directing the thickened froth to a filtra~lon step or other method o~ final dewatering.
This flotation froth iB continuou~ly removed from the ~urface of the bath and vacuum flltered ln order to dewater the coal. The flne coal 1~ then remo~ed from the filter and either used as 1~ or recombined wlth the larger coal 3iz~s separated by prlor ~creening and processln~
step~.
The u~e of these conventlonal techniques re~ults ln acceptable purl~lcatlon o~ the flne coal in the ~lotatlon step ltsel~. Xowever, the ~iltration step has been less than sati~factory due to at least two limlting factors dlrectly re3ulting from the sheer amount of wa~er contained ln the flotatlon froth.
The flrst limlting factor arises from the ~act that virtually all ~llters are limited ln the gro~s volume ~Z7326 of filterable solution they can handle 3er unit tlme by t~e size of the ~llter. Thus one con~equence of the hi~h water to coal welght ratlo in conventlonal flotation froth3 1~
that the qheer volum~ o~ ~roth containlng a given amount of water may exceed the rllter's physical capacl~y or volume and thereby liml~ the hourly volume of froth which can be ~iltered. In other words, although a gi~en filter may be capable o~ handling the amount o~ water contained ln a glven amount Or flotatlon ~roth, the ~heer volume of froth con-talnlng water may be too great for the ~llter to handleefflciently, or even at all. As a result, the overall rate of coal processing may be ~eriously limited by the ~lltration step.
The second limlting ~actor ln the conventional proce~s i~ the low yields o~ coal per unlt time. This low i~olation rate (expressedj ~or example, in pounds o~ coal i~olated per hour) ls directly attributable to the rela-tlvely low percentage Or coal present in any ~lven volume of con~entlonal flotation ~roth.
It i~ important ln many ~ilters, furthermore, partlcularly in drum or dlsk type ~acuum ~ilters, ~or the medlum belng filtered to contain su~ficient solid~ to initlally coat the filter element in order to establi3h a differentlal ~ressure between the down~tream 3ide of the ~llter and the upstream side. I~, for example, a drum or disk type fllter i~ presented wlth a froth contaln~r.g only a little particulate material such as ~lne coal, the sur~ace of the fllter ln the absence of a coatln~ of partlcula~e 1~2~73~
wlll remain ~o porous that lnsuf~icient pres~ure difference between one ~ide o~ the ~ilter medium and the other wlll be established to conduct any sub3tantial flltering at all.
Thus in those cases in which the froth volume compared to the sollds content of the froth ls very large initiatlon of filterlng may be delayed ~or a flnlte period a~ the solld3 build up on the filter sur~ace thus delaying the lnitlation of e~flcient ~lltering and posstbly allowing more fine solids than usual to pa ~ through the ~llterlng medium or ~llter cloth.
In order to avold these di~flculties a ¢oarser ¢oal product from a previous separatlon ~tep has often been combined with the froth, or flotation product, prior to fllterlng to lncrea~e the percentage o~ coal in the ~lotation product and lncrease the ef~iclency of ~lltering. The combination o~ the prior coar~er coal, ~or example, coal havlng a partlcle slze greater than 65 mesh, with the ~lotation coal product of 65 mesh or le~ naturally provides a mlxed coal slze whlch may, or may not, be deslrable d~pendin~ upon circumstances. A more ~erious problem arises, however, when the ~lotation product must be thermally dried after ~llterlng~ but prlor to u~e. Flne coal particles of about 65 mesh or less haYe a large aggregate surface area and tend to retaln a large amount of moisture. A fairly large amount of ~uel is nece~sary to generate the heat values ~o remo~e thls moi~ture. Under these clrcum tances it i3 ine~ficient to mix a coar~er coal product ~ith the ~lne coal ~lotatlon product and thermally dry the mixed coal ~27~Z~ii product. The coarse coal doe~ not normally retain sufflcient moi~ture to require thermal drying and thus adds a slgnlficant amount of bulk to the mixed product, all of whlch must be heated, without addlng molsture which requlres removal. The efficlency of the dryln~ operation is thus substantlally decreased.
It ha~ been customary under somewhat ~imilar clr-cumstance~ in the fllterln~ of mlneral flotatlon products, ~or example, mineral ores and the like~ to thlcken the flotatlon product by the u~e of a thickener or clarifier.
In these ~ystem~ the flotatlon product is conveyed to a thlckener where it i8 retained on the surface o~ the liquid body ln the thickener until ~he ~ro~h break~ down and the mineral particles settle to the bottom of the thlckener.
The underflow 1~ then conveyed to a sultable filter. Some-times sprays are used to accelerate decomposition of the flotation ~oam or froth on the ur~ace of the thickener.
While flotation followed by thickenlng in a thickener, or settllng apparatus, has been successfully used in the treatment of mineral ores, it has not proven satlsfactory in the treatment o~ coal. The mlneral particles in an ore flotation froth product have a higher speclfic gravity than coal partlcle~ and are less resi~tant to wetting than coal froth solids. Consequently, while mineral particles are readily rel~aRed ~rom a ~lotation froth, coal sollds in a flotation froth product are not readlly released from the froth in a conventlonal thlckener even with auxillary spraying. The froth persi3t3 and only a portlon of the fine ~L~732~
coal product wlll ~ettle to the bottom of the thickener ln a condltlon for ~llterlng. In the case of coal, once ~he coal has been floated lt 19 almost totally imposRlble wlthout chemical treatment to su~iciently wet all the floated coal particles to release the coal ~rom the froth 80 that a conventional thickener can be u~ed to prepare the flotatlon product ~or efflclent ~lltering. Some amount of coal wlll always remain attached to the air bubbles and remaln on the ~urface o~ the thickening vessel.
; 10 It ~ould thu~ be desirable to decrease the volume of coal flotatlon froth product prior to filtratlon. It would, furthermore, be de~lrable to dec-rease such volume while lncrea~lng the percenta~e o~ coal particles per unlt volume of froth product in order that ~ine coals may be more rapldly i301ated therefrom.
Summary of the Invention I have dis~overed that both of these desirable goals may be accompli~hed by sub~ecting ~lne coal flotation froths to a pre-riltration thickening ~tep wherein the weight ratio of coal to water ln the products is increased.
Speclficallyg my proce~s treats fine coal flotat~on froths ln a modlfled con~entional thlckener whereby a portion of the froth is physlcally decomposed, i.e., a portion of the bubbles contalned in the froth are caused to burst or coalesce.
ThiR decompo3ition results in the drainlng o~ a significant portlon of the water contained ln the orlglnal froth, thereby lncrea~lng the coal to water weight percent, l.e. thickening the froth.
~27~
In addltion to decreasing the water content of the froth, the thickenlng operation cause~ a portlon of the suspended coal particles to separate from the froth. The ma~or portlon of this ~eparated coal settles to the bottom 5 ~ o~ the thlckening apparatus where it may be collected and recombined with the thickened fro~h prlor to ~iltratlon to ~ield a ~roth product wlth an even hlgher sollds content.
I have found that a froth thlckened ln accordance with my ln~ention re~ults in both an lncrease ln the overall filtration rate and ln an lncrea~e in the rate of recovery of coal solid~ from the flne coal flotation froth product per unik time. Furthermore, where the volume of the non-thickened foam or flo~ation product compared to the solids ~ content o~ ~ine coal which ls contained ln the foam is very large, u~e of the ~hickening operation also lncreases the efficlency of ~ilterln~, i.e. the solids recovery9 itsel~, due to accelerated coa~ing of the ~ilter ~urface with fine particles which increase the filter se~aration e~iciency.
In a pre~erred arrangement the flotation froth is passed from the flotatlon tanks to a thlckener where the froth floats upon the sur~ace o~ a body of fluid contained ln the thlckener. The residence tlme in ~he thickener is ~uf~icient ~o that signlficant ~ater contained in the ~roth drain~ from the ~roth lnto the underlying llquid and a portlon o~ the coal flne~ in the froth settle to the bottom o~ the thickener. The remaining thickened froth is then pushed from the surface of the liquld over the ed~e of the thickener, preferably combined with underflow sollds, and . -3~
'`` q1.Z7~Z~
transported to the filter. Water as an effluent is drawn off at an intermediate point and can be returned to process.
More particularly the invention involves a method for recovering coal particles from a froth-product containing water obtained in a froth-flotation type coal fine treat-ment system, comprising: (a) charging said froth-product containing coal fines attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) removing the thickened froth-product from said thickener apparatus, (d) filtering said thickened froth-product to yield said fines.
Brief Descri~tion of the Drawings FIGURE l is a block type flow diagram depicting the various steps in a typical raw coal treatment process utilizing the present in~ention.
FIGURE 2 is a schematic type diagram showing the treatment of coal fines in a circui~ including a flotation chamber, thickener and filter in accordance with the invention.
FIGURE 3 is a vertical cross-section of the thickener preferably used in the process of the invention.
,.! f ~L~273Z~
FIGURE 4 is a second vertlcal cross-section of the thickener used in the process along the line B-B
of FIGURE 3 taken at approximate right angles to FIGURE 3.
FIGURE 5 is a top view of the thickener used in my process.
Description of the Preferred Embodiment -A complete understanding of the invention may be gained by those skilled in the art from the ~ollowing discussion with reference to the drawings.
Referring to FIGURE l there is shown a block flow diagram of a coal treatment operation or plant wherein raw coal 11 received from the mine or from crushers, not shown, passes to a screening station or operation 13, which may use a l/4 inch screen, where the coarse fines 15 are removed and passed to a second screening station 17.
The coarse coal -9a-732~
screen product 19 from the screening operat~on 13 may be paæsed to a heav~J medlum ~eparation bath 21 for ~eparatlon into a coar~e coal product 23 and a re~use product 25 con-taining slate, rock, clay and other gangue materlal which i9 discarded. The coarse coal product 23 can be used as is, or reground and u~ed, or retreated. Both the coarse coal Z3 and the re.use 25 are 3hown treated in screen drain and wash statlon~ 21a and 21~ a~ shown a~ter pas~a~e through the heavy medium bath 21 in order to separate the hea~y medlum 10 ~rom the two products.
The coarse fine~ 15 are screened in the second screening ætation 17, wh~ch mag use a 28 mesh screen, to produce a second coarse coal screen product 27 which may likewlse be pa~sed to hea~y medlu~ cyclones 29 which ~n turn produce a coarse or medium coarse coal product 31 and a re~u~e product 33. The two products 31 and 33 are separated ~rom the medium used ln cyclone~ 29 by the use of dra~n and ~a3h screens 2qa and 29b.
~he ~lne3 35 from the screenln~ operation 17 are passed to hydrocyclones 37 where the fine coal particles are ~eparated lnto an over~low strea~ 39 which ls passed to a conventlonal 31evebend 41 and an under~low stream 43 which ls pasæed to reruse 45. The overflow stream 39 which contains most of the coal iæ æeparated on the slevebend 41 into a medium coal product 47 and a flne coal product 49.
The medium coal product 47 is shown combined with the medlum coar~e coal product 31 and passed to a centr~uge operation 51 where the final medium coal product 53 is dewatered.
~12732~
The fine coal product 49, which contain~ con-taminating subst~nce~, is passed to a flotation oper~tion 55 where a fine coal froth product ~7, which may contain coal particles of minus 65 mesh size, is floated from a denser refuse product ~9 ln ~ conventional manner and the float or froth product i passed in accordance ~lth the present ; invention to a thickening operation in a thickener 61 which ls ~ho~n in more detall ln FIGURES 3, 4 an~ ~ hereln. In accordance with the invention the flotation or froth product ~7 ls thickened in the thickener 61 by allowing a residence time ln the thlckener 61 suf~iclent to allow water to draln from the froth into the body of liquid held in the thickener 61. The t~ickened froth or de~ified foam product 62 is then passed to a filter 63 by ~weeping the densifled foam ~rom the surface of the body o~ llquld ln the thickener with sultable ~weep arms and conveying the thlGkened or denslfled foam to the filter. As the water drain~ ~rom the foam product ln the thickaner some of the floated coal i5 released from the foam and drop~ to the bottom of the thic~ener.
: 20 Thls coal i~ removed from the bottom of the thickener in a normal fashion as a slurry 6~ and is also passed to the fllter 63 and a~ter filtration enters the flltered fine coal product 65. More preferably the coal product from the bottom of the thickener 61 ls mixed unlformly wlth the froth floatlon product prior to filtration as shown ~y the dotted llne 67 to ~urther ~hlc~en or increase ~he percen~age of flne coal in the froth prlor to pas~age of the .~roth product onto the fllter thereby increa~ing the efflciency or capaclty .......
-~Z73~;
of the filterin~ opera-tion. ~his ~s ~ho~n more clearly ln FI~URE 2. The heavy refuse ma-terial 59 is discharged ~rom the ~ottom of the flota~ion apparatu~ and passed to ~laste.
he flltered coal product 65 i~ passed to a ;,ilermal dryer ~pparatus 6g for removal of resldual rnoi~ture from the flnal fine coal product 71. Alternatively the filtered fine coal product 65 can be used i~ desired without drylng. How-ever~ the fine coal has a considerable ~mount o~ sur~ace area and e~en af~er flltering tends to have a considerable amount of water assoclated ~lth it. ~hermal drying i3 thu~
usually necessary to obtain a satl~factory flnal fine coal product. Pri~r to the pre~ent invention it ha~ usually been necessary in order to effect satisfactory fil~erin~ of tne flotatlon product to mix 30me of the medium to coarse coal product 31 or medium coal product 47 ~ith the flotatlon product or flne coal froth product 57 in or~er to den~l~y the froth product ~uficiently to attain an ef~icient ~ilterin~ operatlon. The medium coal product, however, is mor~ effectively dewatere~ by centrilu~ing and the medium coal pro~uct me~el~ adds bulk in the thermal drying cycle i4 added to the flotatlon ~roth product ~lthout a commensurate amount o~ water which mi~ht require thermal drying.
~ IC-URE 2 shows schematlcally the combination o~
the flotation, thickening an~ filterln~ steps of the lnventlon ln more detall. In FI~'uRE 2 i3 shown a conventional flotation apparatus 71 into whlch "raw coal'! in the form of 2 fine coal product ~rom a prlor scre~nlng operatlon such a3 shQ~,rn in FIG-~P;h 1~ or ~rom some other treatment apparatu3~ i~
passed. The fine coal is deposited into the top o~ the flotatlon apparatus ln any ~ultable manner and mixe~ wlth a body of liquid ln the flotatlon chamber 73. A ~erie~ of spinnlng blade~ or agitators 75 at the bottom of the apparatus 5 ~l are dri~en through a central shart 77 by a motor 79 and drlve belt 81 at a hlgh rate of speed. Air i~ drawn down the central well 83 o~ the apparatus and ls intimately mixed with the liquld within the apparatus as fine bubble~ which ¦ float to the ~urface of the llquid body 73 attachlng to ~ine lO ,I coal particles as the bubble rl3e. A suitable flotation Il agent i8 added to the liquld ~o enhance the attraction ; I between the bubbles and the coal partlcles or to cause the bubble~ to adhere more strongly to the coal whlle re~ectlng ~ the remainin~ refuse material9 all as well known in the art of flotatlon treatment. The bubble~ and attached flne coal partlcles collect on the surface o~ the ~lotation chamber as a ~roth product and overflow the baffle 85 lnto the resldence chamber 87 where ~ome densificatlon or thickening of the froth product 89 occur~ be~ore the ~roth product i~ forced ,, , 20 l from the residence chamber 87 by the rotatlng paddle arrange-ment 93 and passed along the chute 95 to the cen~ral feed chamber 97 of a thickener 99. Water dralning from the froth product 89 passes back lnto the main body of liquid 73 ln the ~lotation apparatus through the opening 91 between the 25 , ba~fle 85 and the side of the flotation chamber 73.
i The froth product 89 which enter~ the central feed chamber 97 of the thickenlng apparatus o~ thickener 99 overflows out the bottom of the feed chamber 97 lnto the ... , 13 maln body of the thickener where lt ~loats on ~he sur~ace of the body o~ liquld 101 contained ln the thickening apparatus.
The rroth product 89 ~loats on the sur~ace of the llquid 101 for a perlod de~igned to be suf~lclent to allow a signlflcant 5l amount of water to drain ~rom the roam product 89 80 that the ~oam is thlckened.
The water whlch draln~ from the ~oam product is removed from the thickenlng apparatus ~hrough drawo~f tube 102 and returned to the process, i.e. usually the ~lotatlon ; 10 chamber 71, ~or reuse. A suitable recycle llne for the water ls lndicated as llne 104 ln FIGURE 2. TAe ~lne coal particl~s suspended in the recycled water are largely removed during the next pasaage through the ~lotation-thlckenlng process 80 that the quantlty of ~ine coal particles ln the re¢ycle water doe~ not signlflcantly increa~e wlth tlme.
:The ~oam 1~ pushed ~rom the sur~ace of the liquid ; ~ 101 by a serie~ o~ splral blades 103, more clearly ~hown ln subaequen~ Yiews in FIGURES 3, 4 and 5. The ~piral blades ~ are ~upported ~rom and rotated by sha~t 105 which 1~ ln turn rotated by a motor 107 and drive belt 109. The sha~t 105 al~o support~ and rotates scraper bladss 111 at the bottom o~ the thlckener 99 whlch serve to scrape coal ~olid~ whlch drop to the bottom o~ the th1ckener and urge them toward the ~- aump 113 ~rom whlch they are pumped as a slurry vla condult 115 and pump 117 to mlxing chamber 119 where the coal slurry i~ pre~erably mlxed evenly with ~roth product. ~he ~roth : product i8 expelled over alde baf~le 121 by the splral rotatl~g blades 103 lnto peripheral trough or launder 123 ~rom whlch the froth product ~low~ through condult 125 to the mlxlng chamber 119. The combined mixture Or coal slurry and thickened ~roth, or den~iried ~oam, product then passes ~ rrom the mixlng chamber 119 through condult 127 to the rotating fllter 129.
The mlxing ¢hamber 119 may con~ist o~ a ~mall enclosed space into which both coal underflow and denRified ~roth overflow are passed. Mlxing occur~ e~sentially upon contact and retention within the mixing chamber may be a matter of seconds. Alternatively, the coal slurry may be merely pas~ed into the conduit along or through which the froth produot 18 conducted.
The froth productl whlch has been thlckened, or den~irie~, ln the thickener 99 by allowlng a re~idence time sufficient to allow ~ome of the moisture of the froth product to drain from the rroth ~o that the percentage of aoal to volume of frotb bubbles ls lncrea~ed~ and which pre~erably has al~o been mixed wlth coal slurry ~rom the ~ bottom of the thickener to rurthsr increase the relatlve percentage Or coal to rroth Yolume, ~ilter~ er~iciently upon the fllter wlth an lncreased filter rate a~ compared to the : ~ilter rate o~ unthickened ~roth product. Whlle lt i~
prererred to mlx the coal slurry rrom the bottom of the thlckener with the already thickened9 or densi~led3 ~roth product in order to further lncr~aRe the percentage of coal rlnes ln the ~roth product prlor to rlltering, it i8 al80 possible to elther pa~s the coal slurry directly to the filter 129 or alternatiYely ts pass lt to a second ~llter or even to merely allow it to drain and dry naturally. In either case the thickened froth product, which must, as a practical matter, be filtered somewhere along the way, is filtered more efficiently and at an increased rate than would otherwise be the case. The filtered fine coal product is discharged from the filter into container 131.
The flotation foam derived from the flotation apparatus 71 will usually contain not more than about 18 to 20% solids by weight while after densification or thickening the flotation froth will perferably contain more than about 30% solids by weight, although it may contain from 25 to 30%
solids. Naturally any significant amount of thickening is benficial to filtering efficienty. The foam which initially has a consistency of stiff soap suds, after densification becomes essentially self supporting and very stiff and heavy, although it will still flow.
A preferred construction of a flotation thickener for use in the present invention is shown in FIGURES 3, 4 and 5 and described below.
Referring to FIGURES 3, 4 and 5, thickener, 201, is comprises of an upright cylindrical tank, 202, having an outer wall, 203, which wall has an outer surface and an inner surface, a generally open top 204 and a bottom 205.
The bottom 205 tapers toward the central axis of the tank and forms an underflow discharge port 207. A cylindrical ship to, the outer wall, 203, is provided in the upper end of the tank and is attached to the tank by a concentic ~truc~ural plate, 217. The annular space between said baf~le and said wall has an open lower end, 211, and an open upper end, 213. The upper end of the baffle 209 ls positloned below the upper end of the outer wall 203 of the tank 202.
5 1 A qulescent zone, 210, is derined by the lower portlon of the ba~fle~ the structural plate, 217, and the opposlng sur~ace of the wall, 203. A peripheral trough or launder, 215, is ~ormed by the upper portion o~ baf~le plate 209, the ~ lnner 3urface o~ the upper end Or the tank wall 203, and 10 I structural plate, 217. This peripheral launder, 215, ext~nd~ 360 around the lnner surface of the wall, 203, and is charackerized by a descendlng pltch ln the ~tructural plate 217 from a high pointg 218, to a low polnt~ 220, 180 i away. See FIGURE 4. At the low polnt 220, a froth launder .
dlscharge outlet, 222, i~ connected to ~-uitable ~roth pumpin~ mean~, not shown. Alternatively, a plurallty o~
indivldual perlpheral launders may be formed by ba~le 209, wall 203 and ind~vldual structural plates 217 together wlth sultable end plates. In this al~ernatlve con~tructlon each 20 i indlvidual launder i3 equlpped wlth a froth launder di~charge ~ -outlet analogous to outlet 222 w~ichg in turn, communicates with ~umplng mean~, not shown ln FIGURES 3, 4 and 5.
See FI~URE 2.
Waste water boxe~, 219, are attached to the outer ~urface o~ wall 203 at regularly spaced intervals. Effluent ports, 221, whlch connect the lnterior of thickener tank qulescent zone 210, ~rlth the interior of waste water boxes, 219, are equipped with ad~ustable sleeves3 223. Each waste -17~
~273Z~
water box is, in additlon, equipped wlth a drainage mean~, not shown, whereb~ ~Yater leaving tank 202 throu~h effluent ~port 221, overflowing ad~ustable slee~e 223 and enterln~
l wa3te water box 219 may be drained there~rom and dlsposed of 1 or furt~er treated as discussed below.
i A cyli~.drical feed well, 225, concentrlc with both the outer wall, 203, and the ba~fle, 209, and inside the baffle 1 pru~ided ln the tank, 202. A rotatable shaft, ~ 227, which ~erves as both ~ mounting and driving mean3 for 1 rakes and scrapers in the thlckener 202, i~ axlally posltioned and connected ~la suitable connecting means at the top to drlve means, not shown. Cylindrical ~eed well 225 1~ spaced from and ~upported by rotatable shaft 227 through attachment strut3 228. In the upper end of the tank, splral 3kimming 15 llblades or 3k~mmers, 229, are mounted on feed well, 225, and are stabili3ed b~ stlf~eners 230 and sklmmer support3, 231, which, ln turn, are att2&hed to mountlng and driving shaft, 227. In the lower end o~ the tank, rake3, 2333 are mounted on the rake mountlngs 234 secured to shaft 227, and are stablllzed by ra~e support means, 235, al~o mounted on ~haft 1 227. Both $he spiral sklmmer~, 229, and rake mountings, ; 233, e;~tend radially outwardly ~ro~ the mountin~ and dri~l~g sha t, 227.
n operation~ a froth ~roduct, containln~ particles 25 ,. of fl ne coal rrom ~roth floation cells in a coal preparation plant, ls char~ed into ~eed rell, 225~ o~ the tank. The ~roth tend~ t,o float on the water ln the ~ank, and ~hile it doe~ 30~ a portlon of the w~ter ln the froth product drains downwardl~ ~rom the froth lnto the water ln the tank carr~ln~
,rlth it a portion of the coal in the ~roth, whlch coal Z~
subsequently settles to 'he bottom 205 o~ the tank 202. ~
such action, the ~roth remainin~ atop the bath i9 thlckened.
ThlcXening can be de~ined as a decr~ase in the volume and ~ater content of the ~oam with an accompanying lncrease ln the percenta~e o~ solids contalned in the remalnlng foam, Thickening re~ults essen~ia}ly ~rom a decrease in the liquid contained in the walls of the bubbles of the foam. The llquid content may be decreased either through eYaporation o~ the liquid from the surface of the lQ foam or by draining of llquid from the bubble walls due to the downward pull o~ gravlty. In either case the individual bubbles tend to become smaller or to bur~t wnen the wall~
contain lnsu~fici~nt liquid for the surface tension to malntain a coheslve bubble wall. Coalescence o~ bubbles due to rupture of the walls between bubbles leads to the formation of larger ~ubble6 with an effectively sm.aller surface area per unlt ~olume of gas enclosed. Thus, re~ardless of whether the lndiYldual bubbles become sm~ller as llquid 19 re~oved from t~elr walls~ or bl~er as a resulc o~ consolidation or co~lescence between kubbles as separating b~bble ~7alls rupture, the Jf~ectlve are~ o~ the ~ubble walls in the froth decreasas. ~lnce the coal partlcles adhere to the bubble wails, the decrease ln the wall area e~ectively increases the concentratlon o~ coal particles per unit o~ wall arel~
This process eff~cti~Jely increases the solids content o~ the froth ~nd thlckens t;.e froth. As th~ area of the ~alls d~crsases and khe concentration c~ coal particies ~ecomes greater som~ o~ the coal particles are crowded o~ an~ crop _ 7 ~ _ ....
from the foam. Other coal particles are released as lndlvidual bubble wall~ are ruptured partlcularly around the periphery of the ~oam mass. The maintenance o~ a liquid body in contact wlth the lower perlphery o~ the ~roth or foam encourages the dralnage of llquid of slmilar composltlon ~rom the bubble walls in the froth. Approxlmately one-thlrd to one-half or even more of the coal particle3 remain attached to the den~ified foam at the ~urface of the thlckener. The thlckened or den~ifled foam material ha~ a con~istency such that lf cut or cleaved lt will maintain its shape in a self supportlng ma~s but is still not so stiff that lt will not ~low alon~ or through a condult of reasonable dlmen~lon~
~; such a~, ~or example, a ~our to six lnch diameter condult.
It ha~ been round to be ~ery dir~lcult 1~ not impo~slble to release the remaining flne coal solids from the den~l~led foam without the addition of special and expenslve wetting a~ent~.
The mountlng and dri~ing shaft, 227~ is contlnuously rotated by the drive mean~ to contlnuously rotate both the 20 spiral sklmmers~ 229, and the rakes, 233. The rotatlon of the spiral skimmers pushes the thickened froth product from atop the water in the tank, over the top of the ba~fle~ 21 -~ and into peripheral launder 215. The froth product then flows do~n the peripheral launder lncllne to an outlet, 222~
2~ at the low polnt of the launder ~rom which it may be removed and routed either to the filter or to any sultable appara~us for prelimlnary recomblnation with the coal solid~ separated and collected as further described below.
~2732 ,1 . . .
As previously stated, durin~ the thlckening operation both water and particles of coal separate from the ~roth and mix wlth the underlylng water layer. The water l~level in the thickener ls stabilized by effluent port 221 5 1l and ad~u~table sleeve 223. By vertlcal ad~ustment of sleeve 223, the level of the llquld ln the thlckener may be varled over a llmited range to accommodate di~erent ~roth depths. Water in exce~s o~ thi3 deslred volume e~it~ over I the top o~ ~leeve 223 into waste water boxe~ 21g and ls l~removed therefrom. The water ~rom the boxes may contain Isignl~lcant amounts of suspended ~ine coal partlcles, and it l~ i8 there~ore preferable ~rom an e~ficlency vlew-polnt that ; llsuch ef~luent water be returned to a prior ~tep ln the coal ; lpurlflcatlon operation in order that thls coal may be recovered. To thi end, water may be u~ed either as a carrier ln the ~creenlng operations or may be returned to the prior ~lotation operatlon. I -The heavier coal particles which have separated ~rom the froth product slnk to the bottom of the thickener 20 ~ tank where khe rotatlon o~ rakes 233 moves the particles down the incllned bottom 205 toward underflow discharge 207, I ~
from which polnt pumping means, not shown, may route these olids to the prevlously mentioned apparatus for recom-bination with the thickened ~roth prlor to filtratlon.
Alternatlvely the collected ~olid~ may be pas~ed to a dryer or the llke prlor to Deing used a~ a ~ine coal.
The use of a thickening operatlon as described result3 in the 3eparation of three coal-containing components ~rom a ~lotatlon froth product: (1) a thickened froth, (2) a water Atream and (3) an under~low dlscharge. The coal partlcles contained ln water stream (2) are smaller than the under~low dl3charge coal particle~ (3) which ~lnk to the bottom o~ the thickener and the water can be recycled in the proce~s~
":
;~ In order to compare the ~iltration ef~lciency of froths as a function of the amount o~ coal solids per ltnit volume, comparatlve experlments were run in which approxlmately ~ ;, equal volumes o~ froth product3 containing increasing coal concèntratlon~ were ~ub~ected to a conventlonal ~iltration , operatlon. Table I gives the results of ~uch experlments.
TA~LE I
COMPARATIVE FILTRA~ION TEST RESULTS*
15 Te~t No. 1 2 3 4 Feed - Volume - cc2000 2000 2000 2000 Feed - % Sollds (By Weight) 9.5 14.0 18,4 31.3 Formqng Time ~ Mln. 1.30 1.30 1.25 1.10 Drylng Time - Min.2.60 2.60 2.50 2.20 Filtrate Volume - cc 1690 1550 1460 920 Wet Cake - Wt. - Gms. 337 453.8 608.7 994 Dry Cake - Wt. - Gms. 192.3 280.6 382.4 600 % Mol~ture in Cake 42~8 38.2 37.2 39.6 Total Cycle - ~ln.* 5.20 5.20 5.00 4.40 Lbs. Dry Cake~
Sq. Ft./Cycle 0.85 1.23 1.68 2.64 Lbs~ ~ry Cake/
Sq. Ft./~r. 9.8 14.1 20.2 3~.0 ~All te~ts were mads usln~ a 0.5 8q. ~ . Denver filter at room temperature under a vacuum of 22-23 ln. o~ mercury.
.
~273~;
.
As shown by Table I, increasing the percentage of coal ~olids ~rom 9.5 to 31.3 resulted in only a 15~ decrease in formlng time ~0.20 min.) ~or a 2000 c.c. feed volume.
However the wel~ht of dry coal i~olated from the thickened feed durlng that shortened time was over three tlme~ that l~olated from the lowest solids feed. As a re~ult of these two co-operating improvements ln ef~iciency, the overall ef~iciency of the flltration ~tep (expressed in weight of dry coal per ~quare ~oot of fllter per hour) was increased by approximately 370%.
It may thu~ be recognized by tho~e skilled in the art that treatlng coal flotatlon froth products in accordance wlth the present invention wlll result in a ~ignificant increase ln e~iciency o~ the coal filtration proce~.
Whlle a preferred arrangement and con~truction of thlckening tank has been shown and de~cribed for u~e in the method of the inYention, it ~hould be understood ~hat an~y comparable thlckening apparatu~ may be used in whlch water can drain ~rom the froth lnto a body of wa~er below and a separation between the ~hlckened froth, the water, and the underflow can be made prior to directing the thickened froth to a filtra~lon step or other method o~ final dewatering.
Claims (9)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. In a coal treatment process wherein coal fines are treated in a flotation process followed by filtration of the resultant flotation froth product containing water, coal particles and froth bubbles to isolate coal fines, the improvement comprising:
(a) collecting the flotation froth product prior to filtration, (b) treating the collected flotation froth product in a thickening apparatus containing a sufficient body of aqueous liquid to physically decompose a portion of the froth and yield (1) a thickened froth which floats upon the surface of the body of aqueous liquid, (2) a coal containing aqueous liquid stream removed from a point between the surface of the aqueous liquid and the bottom of the thickener apparatus and (3) an underflow of a slurry of coal particles which sink to and are removed from the bottom of the thickener apparatus, (c) removing the thickened flotation froth from the thickener apparatus, and (d) filtering the thickened flotation froth to yield said coal fines.
(a) collecting the flotation froth product prior to filtration, (b) treating the collected flotation froth product in a thickening apparatus containing a sufficient body of aqueous liquid to physically decompose a portion of the froth and yield (1) a thickened froth which floats upon the surface of the body of aqueous liquid, (2) a coal containing aqueous liquid stream removed from a point between the surface of the aqueous liquid and the bottom of the thickener apparatus and (3) an underflow of a slurry of coal particles which sink to and are removed from the bottom of the thickener apparatus, (c) removing the thickened flotation froth from the thickener apparatus, and (d) filtering the thickened flotation froth to yield said coal fines.
2. The coal treatment process of claim 1 additionally comprising:
(a) collecting the underflow of slurried coal particles which are removed from the bottom of the thickener apparatus, and (b) combining said collected coal particles with said thickened flotation froth prior to filtration in step (d).
(a) collecting the underflow of slurried coal particles which are removed from the bottom of the thickener apparatus, and (b) combining said collected coal particles with said thickened flotation froth prior to filtration in step (d).
3. The coal treatment process of claim 2 further comprising:
(a) removing the coal containing aqueous liquid stream taken from the thickener apparatus at a point beneath the flotation froth floating on the surface of the aqueous liquid and above the bottom of the thickener apparatus, and (b) returning said aqueous liquid stream to the prior flotation process for removal of coal particles suspended in the aqueous liquid.
(a) removing the coal containing aqueous liquid stream taken from the thickener apparatus at a point beneath the flotation froth floating on the surface of the aqueous liquid and above the bottom of the thickener apparatus, and (b) returning said aqueous liquid stream to the prior flotation process for removal of coal particles suspended in the aqueous liquid.
4. A method for recovering coal particles from a froth-product containing water obtained in a froth-flotation type coal fine treatment systems, comprising:
(a) charging said froth-product containing coal fines attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) skimming the thickened froth-product from atop said aqueous liquid in said thickener into a peripheral launder associated with said thickener, (d) passing said thickened froth-product from said launder to a filtration step, (e) filtering said thickened froth-product to separate said particles of coal from said water, (f) removing said particles of coal as a filter cake and recycling said water to the froth-flotation treatment system.
(a) charging said froth-product containing coal fines attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) skimming the thickened froth-product from atop said aqueous liquid in said thickener into a peripheral launder associated with said thickener, (d) passing said thickened froth-product from said launder to a filtration step, (e) filtering said thickened froth-product to separate said particles of coal from said water, (f) removing said particles of coal as a filter cake and recycling said water to the froth-flotation treatment system.
5. In a coal treatment process wherein raw coal fines of minus 65 mesh size are treated in a flotation process followed by filtration of the resultant flotation froth product containing water, coal particles and froth bubbles to isolate a fine coal product, the improvement comprising:
(a) collecting the flotation froth product prior to filtration, (b) treating the collected flotation froth product in a thickener apparatus containing a sufficient body of aqueous liquid to physically decompose a portion of the froth and yield (1) a thickened froth which floats upon the surface of the body of aqueous liquid,(2) a coal containing aqueous liquid stream removed from a point between the surface of the aqueous liquid and the bottom of the thickener apparatus and (3) an underflow of a slurry of minus 65 mesh coal particles which sink to and are removed from the bottom of the thickener apparatus, (c) removing the thickened flotation froth from the thickener apparatus, and (d) filtering the thickened flotation froth to yield minus 65 mesh coal fines.
(a) collecting the flotation froth product prior to filtration, (b) treating the collected flotation froth product in a thickener apparatus containing a sufficient body of aqueous liquid to physically decompose a portion of the froth and yield (1) a thickened froth which floats upon the surface of the body of aqueous liquid,(2) a coal containing aqueous liquid stream removed from a point between the surface of the aqueous liquid and the bottom of the thickener apparatus and (3) an underflow of a slurry of minus 65 mesh coal particles which sink to and are removed from the bottom of the thickener apparatus, (c) removing the thickened flotation froth from the thickener apparatus, and (d) filtering the thickened flotation froth to yield minus 65 mesh coal fines.
6. The coal treatment process of claim 5 additionally comprising:
(a) collecting the underflow of a slurried minus 65 mesh coal particles which are removed from the bottom of the thickener apparatus, and (b) combining said collected coal particles with said thickened flotation froth prior to filtration in step (d).
(a) collecting the underflow of a slurried minus 65 mesh coal particles which are removed from the bottom of the thickener apparatus, and (b) combining said collected coal particles with said thickened flotation froth prior to filtration in step (d).
7. The coal treatment process of claim 6 further comprising:
(a) removing the coal containing aqueous liquid stream taken from the thickener apparatus at a point beneath the flotation froth floating on the surface of the aqueous liquid and above the bottom of the thickener apparatus, and (b) returning said aqueous liquid stream to the prior flotation process for removal of minus 65 mesh coal particles suspended in the aqueous liquid.
(a) removing the coal containing aqueous liquid stream taken from the thickener apparatus at a point beneath the flotation froth floating on the surface of the aqueous liquid and above the bottom of the thickener apparatus, and (b) returning said aqueous liquid stream to the prior flotation process for removal of minus 65 mesh coal particles suspended in the aqueous liquid.
8. A method for recovering fine coal particles of minus 65 mesh and less from a froth-product containing water obtained in a froth-flotation type fine coal treatment system, comprising:
(a) charging a froth-product containing coal fines of 65 mesh and less attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) skimming the thickened froth-product from atop said aqueous liquid in said thickener into a peripheral launder associated with said thickener, (d) passing said thickened froth-product from said launder to a filtration step, (e) filtering said thickened froth-product to separate said particles of coal from said water, and (f) removing said particles of minus 65 mesh coal as a filter cake and recycling said water to the froth-flotation treatment system.
(a) charging a froth-product containing coal fines of 65 mesh and less attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) skimming the thickened froth-product from atop said aqueous liquid in said thickener into a peripheral launder associated with said thickener, (d) passing said thickened froth-product from said launder to a filtration step, (e) filtering said thickened froth-product to separate said particles of coal from said water, and (f) removing said particles of minus 65 mesh coal as a filter cake and recycling said water to the froth-flotation treatment system.
9. A method for recovering coal particles from a froth-product containing water obtained in a froth-flotation type coal fine treatment system, comprising:
(a) charging said froth-product containing coal fines attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) removing the thickened froth-product from said thickener apparatus, (d) filtering said thickened froth-product to yield said fines.
(a) charging said froth-product containing coal fines attached to bubbles within the froth into a thickener apparatus which uses an aqueous liquid body contained within the apparatus as a treatment and separation medium, (b) floating said froth-product upon the surface of said aqueous liquid for a time sufficient to dewater the froth-product and increase the solids content to thereby form a thickened froth-product, (c) removing the thickened froth-product from said thickener apparatus, (d) filtering said thickened froth-product to yield said fines.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US05/881,977 US4175035A (en) | 1978-02-27 | 1978-02-27 | Method for increasing fine coal filtration efficiency |
| US881,977 | 1978-02-27 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1127326A true CA1127326A (en) | 1982-07-06 |
Family
ID=25379624
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA321,522A Expired CA1127326A (en) | 1978-02-27 | 1979-02-14 | Method for increasing fine coal filtration efficiency |
Country Status (2)
| Country | Link |
|---|---|
| US (1) | US4175035A (en) |
| CA (1) | CA1127326A (en) |
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| US4244813A (en) * | 1979-08-08 | 1981-01-13 | Bethlehem Steel Corporation | Method of increasing fine coal filtration efficiency |
| US4326855A (en) * | 1979-11-08 | 1982-04-27 | Cottell Eric Charles | Process for beneficiating and stabilizing coal/oil/water fuels |
| US4544490A (en) * | 1984-01-09 | 1985-10-01 | Rexnord Inc. | Method and system for recovering coal fines from pipe line coal slurry |
| JPS6133285A (en) * | 1984-07-24 | 1986-02-17 | Rasa Shoji Kk | Treatment of sewage |
| CA1327342C (en) * | 1987-11-30 | 1994-03-01 | James Kelly Kindig | Process for beneficiating particulate solids |
| US5169004A (en) * | 1991-08-29 | 1992-12-08 | K-Pack Systems International | Method of and apparatus for treating building rubble |
| WO1993007967A1 (en) * | 1991-10-15 | 1993-04-29 | Genesis Research Corporation | Coal cleaning process |
| US5522510A (en) * | 1993-06-14 | 1996-06-04 | Virginia Tech Intellectual Properties, Inc. | Apparatus for improved ash and sulfur rejection |
| US5333952A (en) * | 1993-08-17 | 1994-08-02 | Perdue John L | Chemical mixing chamber |
| US5843315A (en) * | 1996-05-10 | 1998-12-01 | Vulcan Materials Company | System and method for recovering aggregate fine size particles |
| US6085912A (en) * | 1999-07-13 | 2000-07-11 | Hacking, Jr.; Earl L. | Apparatus for sorting and recombining minerals background of the invention |
| CA2595723C (en) | 2005-10-14 | 2009-01-27 | Aquero Company, Llc | Amino acid, carbohydrate and acrylamide polymers useful as flocculants in agricultural and industrial settings |
| US9914136B2 (en) * | 2012-07-24 | 2018-03-13 | Aquero Company, Llc | Process for reducing soluble organic content in produced waters associated with the recovery of oil and gas |
| CN109794349B (en) * | 2019-03-08 | 2020-03-17 | 中国矿业大学 | Underground coal dressing process |
| US20210394195A1 (en) * | 2020-06-18 | 2021-12-23 | Peijing YANG | Clean coal production system and method |
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|---|---|---|---|---|
| US1938894A (en) * | 1931-05-07 | 1933-12-12 | Dorr Co Inc | Thickener |
| US2317139A (en) * | 1939-07-20 | 1943-04-20 | Colorado Fuel & Iron Corp | Froth breaking |
| US2411288A (en) * | 1945-03-26 | 1946-11-19 | Morse Albert Reynolds | Froth flotation with simultaneous filtration and collection of froth |
| US2656118A (en) * | 1951-03-24 | 1953-10-20 | Knowles Associates | Disposal of slime-bearing water |
| US2713026A (en) * | 1951-07-21 | 1955-07-12 | Process Engineers Inc | Flotator-clarifier |
| US2876863A (en) * | 1954-07-26 | 1959-03-10 | Process Engineers Inc | Treatment of aqueous wastes containing hydrocarbons |
| US2970689A (en) * | 1958-03-27 | 1961-02-07 | Crucible Steel Co America | Coal treating process |
| US3043426A (en) * | 1960-04-05 | 1962-07-10 | Allied Chem | Black water clarification |
| US3233731A (en) * | 1960-12-27 | 1966-02-08 | Consolidation Coal Co | Method of separating coal |
| US3579442A (en) * | 1970-07-09 | 1971-05-18 | Bird Machine Co | Coal converting process |
| US3696923A (en) * | 1970-07-28 | 1972-10-10 | Bethlehem Steel Corp | Method for recovering fine coal and coal-containing particles in a coal recovery circuit |
| CA1069623A (en) * | 1976-01-07 | 1980-01-08 | Michael O. Holowaty | Apparatus and method for separating a mixture of liquid and coal fines |
-
1978
- 1978-02-27 US US05/881,977 patent/US4175035A/en not_active Expired - Lifetime
-
1979
- 1979-02-14 CA CA321,522A patent/CA1127326A/en not_active Expired
Also Published As
| Publication number | Publication date |
|---|---|
| US4175035A (en) | 1979-11-20 |
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