US2980291A - Method and apparatus for compounding sinter feed - Google Patents
Method and apparatus for compounding sinter feed Download PDFInfo
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- US2980291A US2980291A US810508A US81050859A US2980291A US 2980291 A US2980291 A US 2980291A US 810508 A US810508 A US 810508A US 81050859 A US81050859 A US 81050859A US 2980291 A US2980291 A US 2980291A
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- ore
- hot recycle
- feed
- conveyor
- rate
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22B—PRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
- C22B1/00—Preliminary treatment of ores or scrap
- C22B1/14—Agglomerating; Briquetting; Binding; Granulating
- C22B1/16—Sintering; Agglomerating
- C22B1/20—Sintering; Agglomerating in sintering machines with movable grates
- C22B1/205—Sintering; Agglomerating in sintering machines with movable grates regulation of the sintering process
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01G—WEIGHING
- G01G19/00—Weighing apparatus or methods adapted for special purposes not provided for in the preceding groups
- G01G19/22—Weighing apparatus or methods adapted for special purposes not provided for in the preceding groups for apportioning materials by weighing prior to mixing them
Definitions
- An iron-bearing sinter feed commonly consists of a mixture of ore fines, scale, ue dust, sinter returns, filter cake and solid fuel particles (e.g. coke or anthracite fines).
- sinter returns are separated into sized returns added to the feed to control the bed porosity and hot recycle, which is dust or unburned sinter not suitable as a sintered product.
- Belt scales are available commercially for automatically registering lthe weight of material carried by a moving conveyor.
- weigh-feeders are available which are table feeders combined with and controlled by belt scales.
- Part of the difficulty in keeping a sinter mix constant can be overcome by installing a belt scale on the main feed conveyor and weigh-feeders on the bins which deliver such additives as fuel and sized returns.
- the ore reaches the main conveyor before the additives and the belt scale is located between the ore and additive bins, where it registers the actual weight of ore on the conveyor before the additives are introduced.
- a suitable transmitter connects this belt scale with the weigh-feeders to pace the latter and insure that they deliver additives in proper proportion to the weight of ore actually on the conveyor.
- hot recycle should be considered as an equivalent to ore, and the additives should be proportioned in accordance with the combined weight of ore and hot recycle.
- the hot recycle bin often is situated after the additive bins, and even after the mixing device, and feeds hot recycle to the main conveyor after the additives already have been proportioned according to the weight of ore alone plus some constant factor. Conse- Patented Apr. 18, 1961 quently there is no controlled compensation for variations in the hot recycle.
- An object of the present invention is to provide an mproved sinter feed compounding apparatus and method which take into account variations in hot recycle in proportioning the other ingredients, regardless of the location of the hot recycle bin.
- a further object is to provide an improved sinter feed compounding apparatus and method which combine the weight of ore and hot recycle in determining the Weight of additives to be included in sinter feed, even though the hot recycle bin follows the additive bins and may follow the mixing device.
- a more specific object is to provide a sinter feed compounding apparatus which includes belt scales and Weighfeeders arranged as hereinbefore described, plus additional belt scales for determining the weight of hot recycle fed to the main conveyor and means automatically combining this weight with that of the ore, the weighfeeders being paced by the resulting combined weights.
- Figure l is a diagrammatic side elevational View of a sinter feed compounding apparatus constructed in accordance with my invention.
- Figure 2 is a diagrammatic showing of a weigh-feeder embodied in my apparatus
- Figure 3 is a View similar to Figure 1, but showing a modification
- Figure 4 is another view similar to Figure 1, but showing a further modification.
- Figure l shows a conventional main feed conveyor 21 and its associated series of bins for compounding a sinter feed.
- conveyor 21 is shown as a single belt, but more often in actual installations it is formed of a series of belts.
- the first six bins 22 contain ore, and the next two 23 and 24 scale and scrap, which in sinter feed are equivalent to ore.
- Each bin 22, 23 and 24 is equipped with its individual table feeder 25, which feeds material therefrom to the main conveyor 21.
- conveyor 21 traverses a conventional belt scale 26 which continuously weighs material fed thus far.
- the next four bins 27, 28, 29 and 30 contain coke, anthracite, flue dust and sized returns, each of which is added in a predetermined proportion with respect to ore and its equivalents.
- Each bin 27 to 30 is equipped with its indiw'dual weigh-feeder 31, which feeds the respective ingredient to the main conveyor 21, as hereinafter eX- plained.
- eX- plained For simplicity I refer hereinafter to ore, scrap and scalecombined as ore, and coke, anthracite, flue dust and sized returns generically as additives
- the last bin 32 contains hot recycle and is equipped with a table feeder 33 which feeds this material to the main conveyor 21.
- a mixing device 34 is situated to receive material from the main conveyor, lilter cake from a conveyor 35 and water from an adjustable source 36.
- the mixing device can be a pug mill or a balling disk or drum, and it 'discharges mixed sinter feed to a conveyor 37 which carries it lto a sintering machine not shown.
- the belt scale 26 transmits a signal to a summator 38, which signal'is proportionate to the weight of ore on conveyor 21. Another signal proportionate to the-hot recycle is also transmitted to this summator, as hereinafter explained.
- the summator transmits a signal proportionate to the sum of its two input signals to a series of ratio devices 39 to 43.
- the ratiodevices 39 to 42 control the proportion of each additive which the weighfeeders 31 feed to conveyor 21 from bins 27 to 3l).
- 'I'he ratio device 43 controls the proportion of water delivered from the water source 36. Actually the proportion of this sum.
- a The belt lscale-26, Ysummator 38-and -ratiolV devices 39 to water is a function of the total solids in the mix, but
- Unit B of the summator is left uncoupled so that the force thereon is effectively zero.
- the Sorteberg force bridge is set up for multiplication, and theoutput line from the'unit Def the summator is connected A thereto to provide the force A on the bridge.
- V The force B on the bridge is set manuallyV to provide the desired'ratio of the particular additive.
- - The force' Dv is .maintained constant.
- the force C whichisY the product,
- Y t Y Figure 2 is a diagrammatic showing of asuitable weighfeeder 31 Vfor the coke bin 27, showing also its relation to the'ratio device 39.
- the otherweigh-feeders are simi- -lar; ⁇ ;hence'the showing is not repeated.
- The'weigh-feeder includes Va conventional table'feeder ⁇ 44 and V'a conveyor belt 45.
- the table feeder has a variable speed drive 46 and delivers cokefrom bin 27 to the belt, which has a Y constant speeddrive 47 and deliversthis coke to the main conveyor 21.
- Belt 45 traversesja belt scale 48, which can rbeV similar to 26, and transmits a signal to a controller 49.
- the ratio device 39 transmits another signal to this controller.
- YYTheoutput signal from the controller is proportionate to the difference between its two input signals and is transmitted to the variable speed drive 46 to control the speed of the table feederV 44.
- the belt scale determines the actual weight of material fed and transmits this weight to the controller, which changesthe table feeder speedY to correct forV any difference between the weight set by the ratio devicefand'the actual weight.
- the apparatus includes 'a control lpanel 50 whichV carriesseven panel set controls 51 to SI.
- the controlv51 ⁇ is connected to the table feeders 25 for bins 22, 23 and 24.
- This control can be any suitable known device for varying the speed of an electric motor, and its manual Vadjus'trnent'varies the table feeder speed Vand ths varies the weight of ore fed to the main con- Y and its action is explained hereinafter.
- Vl() Y thereof, whereby manual adjustment of controls 52 to 56 varies the proportion of the respective additives andwater.
- these controls can be pressure regulating valves that permit manual 'regulation of the pressure on the input B of the Sorteberg force bridge. If the Donaldson ratio relay isused, the relay itself is mounted in the control panel and its knob 20 becomes the panel set control.
- the control 57 governs hot recycle The mechanism thus far described controls the proportion of 'additives with respect to the ore by pacing the weigh-feeders 31 in accordance with theweight registered on belt scale 26, although it has been mentioned that the invention embodies afurther control based on hot recycle.
- The'panel control 57 is connected to a controller 58 through a Atime delay device 59.
- the controller 58. can be of similar construction to .49 ( Figure f2) and is connected to the table feeder33 for the hot recycle'bin to control the feed rate thereof.
- control 57 can be apressure regulating yvalve forY adjusting the pressure-on'the input 16 of the Moore controller, and the time'delay device conveniently can be a simple coil oftubing-ofalength sufficient to delay impulses transmitted therethrough;
- the main conveyor 21 traverses another pair of belt scales 60 and 61 located at opposite sides of the table feederf33, and both transmitV signals to an algebraic summator 62 which can be similar to k38 butconnectedto subtract and whose output signal is Vproportionalto the dierence between the weights registered by these two scales, thatris, Vto the actual weight of hot recycle Yfed to the main conveyor.
- the output signal frornsummator'62 is continuously transmitted to controller 58,.wh'ose own output signal controls the table feeder 33 so that it feeds hot recycle accuratelyY at the rate set'by the control 57.. Itis seen that the arrangement is the .equivalent of the weigh-feeder showny in Figure 2,
- a .weighfeeder can be substituted if VYthe recycle .suchthat the 'table feeder 33 feeds hot recycle at approximately the rate itis currently received. He also adjusts the control V51 to VVmake an inverse 'change in the rate of Yore feed .to Vkeep the'total weight of ore and hot recycle ⁇ substantially. constant, and thus keep the equipment operating Vat substantially a constant'rate, preferably its rated capacity.
- the purpose of the time delay device 5S is to retard changes Vin hot recycle feed YrateV until the section of conveyor' 21V on which Vthefore feed rate vhas, been changed reaches feeder 33.
- the controls 52 to 56 areconnectedltothe ratio devices 39 to 43 respectively to adjust the settings
- the control panel 51 also carries additional indicators 64 to 67.
- Thertirst two are connected respectively to the summator- 38'and .controller ⁇ 5,8, and register the weight of ore plus hot recycle fed to the conveyor and the weight of hot recycle alone.
- lIndicator 66 is connected to a belt scale 68 which the filter cake conveyor 35 traverses to indicate the weight of filter cake added to the sinter feed. This weight is not taken into account in the control system, since the material is used irregularly and in relatively small quantities
- Indicator 67 is connected to a belt scale 69 which conveyor 137 traverses to indicate the total output of sinter feed from the installation.
- Figure 3 shows a modification in which changed settings inthe hot recycle feed rate automatically change the ore feed rate. Except for the parts and connections which accomplish this function, the apparatus is similar to Figure 1; hence this description is not repeated.
- the panel set control 51 is connected to a controller 7 0 (which can be similar to 49 and 5S) to regulate the total feed of ore and hot recycle, rather than ore alone, ⁇ as in Figure 1.
- controller 7 0 which can be similar to 49 and 5S
- control 51 is a valve for regulating the pressure on Moores line 16.
- the apparatus of Figure 3 embodies an additional ratio device 71 which receives signals from the summator 38 similar to the ratio devices 39 to 43.
- the panel set control 57 is connected to the ratio device 71 to set it to the desired ratio of hot recycle with respect to ore.
- the output signal from the ratio device 71 goes to the controller SS via the time delay device 59, and also feeds back t the summator 38.
- indicator 63 shows a change is needed in the rate of hot recycle feed
- the panel set control 57 is adjusted as in Figure l, but now it adjusts the setting of the ratio device 7l to change the ratio of hot recycle to ore without changing the total.
- the feedback connection to summator 38 transmits an immediate signal thereto that the hot recycle ratio is changed.
- the output signal from the summator to the controller 70 changes correspondingly. This controller changes the rate of ore feed inversely to the change in hot recycle feed to maintain the total constant, that is, to maintain constant the sum of the signals from the belt scale 216 and the feedback signal from the ratio device 71.
- Figure 4 shows another modification in which the main conveyor includes two belts 21a and 2lb in series, and the mixing device 34 is situated between these belts.
- Bin 32 feeds hot recycle to an apron-type conveyor 75, which in turn feeds this material to belt 2lb.
- scale 61 now registers the total weight of sinter feed7 it furnishes the signal transmitted to indicator 67; conveyor 37 and scale 69 shown in Figure 1 can be eliminated.
- this modification is similar to that shown in Figure l; hence the description is not repeated.
- lt is apparent also that the main conveyor and mixing device of the embodiment shown in Figure 3 could be arranged las shown in Figure 4.
- the present invention affords a simple apparatus and method for positively proportioning the composition of a sinter feed. Variations in the quantity of hot recycle are easily compensated, irrespective of the location of the hot recycle bin.
- the invention is readily applied to existing installations. Sometimes recycle is cooled beforehand to facilitate handling and screening, but such cooling does not affect the operation of my invention. Therefore I do not intend my terminology to exclude this obviously equivalent variation.
- an apparatus for compounding sinter feed which apparatus includes a main conveyor, and individually controllable means for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeding means of a proportioning mechanism comprising a scale for determining the Weight of ore fed to the conveyor, means for ladjusting said hot recycle feeding means to feed this material substantially at the rate received, a summator connected to said scale and to said adjusting means for combining the weights of ore and hot recycle, and ratio devices connected to said summator and to said additive feeding means for proportioning the rate of feeding additives as definite ratios of the combined weights of ore and hot recycle.
- a combination as defined in claim 1 further comprising a time delay device in the adjusting means for said hot recycle feeding means to delay adjustments in the rate of feeding hot recycle until compensated for by adjustments in the rate of feeding ore.
- an apparatus for compounding sinter feed which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeders of a proportioning mechanism comprising means for adjusting the rate of ore feed, a belt scale traversed by said conveyor between said ore and additive feeders for determining the weight of ore fed thereto, means for adjusting said hot recycle feeder to feed this material substantially at the rate received, a summator connected to said belt scale and to said second named adjusting means for continuously combining the Weight registered on said scale with the setting of said second named adjusting means, and ratio devices connected with said summator and the respective additive feeders for proportioning the rate of feeding additives as definite ratios of the combined weights of ore and hot recycle.
- an apparatus for compounding sinter feed which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeders of a proportioning mechanism comprising means for adjusting said hot recycle feeder to feed this material substantially at the rate received, means for adjusting said ore feeders inversely to said hot recycle feeder to maintain the combined feed of hot recycle and ore substantially constant, means for computing the combined weight of ore and hot recycle fed to said conveyor, and control means for said additive feeder operatively connected with said computing means for proportioning the additives in ⁇ accordance with the combined feed of hot recycle and ore.
- a combination as dened in claim 4 further comprising a feedback connection between the adjusting means for said hot recycle feeder and the adjusting means for said ore feeder via said computing means to adjust the ore feed rate automaticallywith adjustments in hot recycle feed rate.
- an apparatus for compounding sinter feed which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeders of a proportioning mechanism comprising means for adjusting said hot recycle feeder to feed this material substantially at the rate received, means for adjusting said ore feeders inversely to said hot recycle feeder to maintain the combined feed of hot recycle and ore substantially constant, a time delay device in the adjusting means for said hot recycle feeder to delay adjustments in the rate of feeder hot recycle until the portion of said conveyor on which the rate of feeding ore has changed reaches said hot recycle feeder, and control means for said additive feeder for proportioning the additives in accordance with the combined feed of hot recycle and ore.
- an apparatus for compounding sinter feed which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle in theorder named to said convey0r,.the com- ⁇ bination with said feeders of a proportioning mechanism comprising meansV for maintaining the combined feeding rate of ore and hot recycle substantially constant, means Y for continuously summating the actual combined feeding rate thereof, and ratio devices connecting said summating means andsaid additive feeders for maintaining the additive feeding rate as a definite ratio of the combined feeding rate of ore and hot recycle.
- Van apparatus for compounding sinter feed which apparatus includes a main conveyor and individually controllable feeders for vfeeding ore,”additives and hot re- 'cycle successively to .said conveyor, the combination therewith of a'mechanism for regulatingsaid yore feeders comprising means for transmitting a signal proportionate to the desired sum of thel ore and hot recycle feed rates,
- an apparatus for compounding sinter feed which apparatus includes a mainrconveyor and individually con- Vtrollable feeders for feeding ore, additives andjhot recycle successively to said conveyor, theV combination therewith of a mechanism for regulating-said ore feeders comprising means for transmitting a first signal proportionate to the desired sum of the ore and hot recycle feed rates, means for transmitting a second signal proportionate to the actual ore feed rate, means for transmitting a third signal proportionate to the setting of said hot recycle feeder, means ⁇ for computing the sum of said second and third signals operatively connected to the transmitting means therefor, and control-means opera- Y Y tively connected with said ore feeders, with the transmitting means for said rst signal Yand with said computing means for adjusting the ore feed rate to maintain the sum Y of the ore and hot recycle feedrrates at the constant desired level.
- apparatus includes a main conveyor composed of at :least one power driven belt, a mixing device adapted to receive material from said conveyor, and individually Y controllable means for feeding ore, additives and hot recycle successively to said conveyor, the combination with sa1d feeding means of a proportioning mechanism comprising a scale for determining the weight of ore fedto the conveyor, means for adjusting said hot recycle feeding means to feed this material substantially at the rate received, a summator connected tosaid scale and to-saidradjusting means for combining the weights of ore Y and hot recycle, and ratio devices connected to said summator and to said additive feeding means for proportioning the rate of feeding additives as definite ratios of the Y combined Weights of ore and hot recycle.
- a combination as dened in claim 10 in which the feeding means for ore, additives and Yh'otrec'ycle are situated to Vfeed these materials to a belt ahead of ⁇ said Vmixing device, whereby said mixing device receives hot recycle as well as ore and additives.
- a combination as defined in c1air ⁇ n-10 in which the feeding means for ore and additives aresituated to feed these Vmaterials to a belt ahead of said mixing device, and the feeding means for hot recycleV is situated to feed the latterVV material to a belt beyond said mixing device, whereby said mixing device receives orewand additives, but hot recycle is excluded therefrom.
- a method of compounding sinter feed comprising ⁇ feedin Isuccessivel to a traveling conve or ore, additives, and hot recycle ⁇ at va predetermined respective rate for each, continuously and separately Yobtaining measurements of the feeding rates of loreand hot recycle, continuously obtaining a summation of said measurements, and continuously controlling the feeding rate of additives to a rate proportional to this summation. .Y
- a method of compounding sinter feed comprising receiving hot recycle at a variable r-ate'from a'sintering operation, feeding successivelyto a traveling conveyor ore, additives and hot recycle at a predetermined respective rate for each, adjusting the feeding rate of hot recycle toY substantially the rate received, inversely adjusting the feeding rate of ore to maintain the combined feeding rateY of ore and hot recycle substantially constant, continuously obtaining measurements of the. actual feeding rates of ore and hot recycle, continuously obtaining a summation of these measurements, and continuously controlling the feeding rate of additives to a rate proportional to this summation.
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Description
April 18, 1961 T. R. scHuERGE-.R
METHOD AND APPARATUS FOR COMPOUNDING SINTER FEED Filed May l, 1959 3 Sheets-Sheet 1 April 18, 1961 T. R. scHUERGER 2,980,291
METHOD AND APPARATUS FOR COMPOUNDING SINTER FEED Filed May l, 1959 3 Sheets-Sheet 2 AAA INVENTOR. Q
BY 7 HOM/15 Q. SCI/02H65? H/.s ArronA/Ey T. R. SCHUERGER April 18, 1.961
METHOD AND APPARATUS FOR COMPOUNDING SINTER FEED 3 Sheets-Sheet 3 Filed May l, 1959 Mnl xml
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METHGD AND APPARATUS FOR CQMPOUND- ING SIWER FEED Filed lWay 1, 1959, Ser. No. 819,508
Claims. (Cl. 222-1) This invention relates to an improved apparatus and method for compounding sinter feed and proportioning the ingredients thereof. The present application is a continuation-in-part of my earlier application Serial No. 579,326, tiled April 19, 1956, and of common ownership (now abandoned).
Although my invention has general application to sinltering operations in which hot fines recovered from a sintered product are recycle, it is particularly useful in sinter-ing iron-bearing materials. An iron-bearing sinter feed commonly consists of a mixture of ore fines, scale, ue dust, sinter returns, filter cake and solid fuel particles (e.g. coke or anthracite fines). In modern plants sinter returns are separated into sized returns added to the feed to control the bed porosity and hot recycle, which is dust or unburned sinter not suitable as a sintered product. Conventionally the various ingredients discharge from individual bins to table feeders and thence to a main feed conveyor of the belt-type, which carries them to a mixing device Where moisture also is added. This conveyor vcan be formed of only a single belt, but more commonly is formed of several belts in series. Usually the only control of proportions is obtained by adjusting the discharge areas of the bins or speed of the table feeders, but this control is uncertain, since both bulk density of the materials and their ability to ow from a bin continually vary. Therefore a constant composition is difficult to maintain, and frequent pan sampling of material on the main conveyor is necessary.
Belt scales are available commercially for automatically registering lthe weight of material carried by a moving conveyor. Likewise weigh-feeders are available which are table feeders combined with and controlled by belt scales. Part of the difficulty in keeping a sinter mix constant can be overcome by installing a belt scale on the main feed conveyor and weigh-feeders on the bins which deliver such additives as fuel and sized returns. The ore reaches the main conveyor before the additives and the belt scale is located between the ore and additive bins, where it registers the actual weight of ore on the conveyor before the additives are introduced. A suitable transmitter connects this belt scale with the weigh-feeders to pace the latter and insure that they deliver additives in proper proportion to the weight of ore actually on the conveyor.
However, in many installations an arrangement as described neglects one significant variable. To a large extent hot recycle must be fed to the main conveyor in whatever quantities it is returned from the sintering machine, despite considerable variation. In proportioning the ingredients, hot recycle should be considered as an equivalent to ore, and the additives should be proportioned in accordance with the combined weight of ore and hot recycle. The hot recycle bin often is situated after the additive bins, and even after the mixing device, and feeds hot recycle to the main conveyor after the additives already have been proportioned according to the weight of ore alone plus some constant factor. Conse- Patented Apr. 18, 1961 quently there is no controlled compensation for variations in the hot recycle.
An object of the present invention is to provide an mproved sinter feed compounding apparatus and method which take into account variations in hot recycle in proportioning the other ingredients, regardless of the location of the hot recycle bin.
A further object is to provide an improved sinter feed compounding apparatus and method which combine the weight of ore and hot recycle in determining the Weight of additives to be included in sinter feed, even though the hot recycle bin follows the additive bins and may follow the mixing device.
A more specific object is to provide a sinter feed compounding apparatus which includes belt scales and Weighfeeders arranged as hereinbefore described, plus additional belt scales for determining the weight of hot recycle fed to the main conveyor and means automatically combining this weight with that of the ore, the weighfeeders being paced by the resulting combined weights.
In accomplishing these and other objects of the invention, I have provided improved details of structure, preferred forms of which are shown in the accompanying drawings, in which:
Figure l is a diagrammatic side elevational View of a sinter feed compounding apparatus constructed in accordance with my invention;
Figure 2 is a diagrammatic showing of a weigh-feeder embodied in my apparatus;
Figure 3 is a View similar to Figure 1, but showing a modification; and
Figure 4 is another view similar to Figure 1, but showing a further modification.
Figure l shows a conventional main feed conveyor 21 and its associated series of bins for compounding a sinter feed. For simplicity conveyor 21 is shown as a single belt, but more often in actual installations it is formed of a series of belts. The first six bins 22 contain ore, and the next two 23 and 24 scale and scrap, which in sinter feed are equivalent to ore. Each bin 22, 23 and 24 is equipped with its individual table feeder 25, which feeds material therefrom to the main conveyor 21. Immediately beyond bin 24, conveyor 21 traverses a conventional belt scale 26 which continuously weighs material fed thus far. The next four bins 27, 28, 29 and 30 contain coke, anthracite, flue dust and sized returns, each of which is added in a predetermined proportion with respect to ore and its equivalents. Each bin 27 to 30 is equipped with its indiw'dual weigh-feeder 31, which feeds the respective ingredient to the main conveyor 21, as hereinafter eX- plained. For simplicity I refer hereinafter to ore, scrap and scalecombined as ore, and coke, anthracite, flue dust and sized returns generically as additives The last bin 32 contains hot recycle and is equipped with a table feeder 33 which feeds this material to the main conveyor 21. A mixing device 34 is situated to receive material from the main conveyor, lilter cake from a conveyor 35 and water from an adjustable source 36. The mixing device can be a pug mill or a balling disk or drum, and it 'discharges mixed sinter feed to a conveyor 37 which carries it lto a sintering machine not shown.
The belt scale 26 transmits a signal to a summator 38, which signal'is proportionate to the weight of ore on conveyor 21. Another signal proportionate to the-hot recycle is also transmitted to this summator, as hereinafter explained. The summator transmits a signal proportionate to the sum of its two input signals to a series of ratio devices 39 to 43. The ratiodevices 39 to 42 control the proportion of each additive which the weighfeeders 31 feed to conveyor 21 from bins 27 to 3l). 'I'he ratio device 43 controls the proportion of water delivered from the water source 36. Actually the proportion of this sum. A The belt lscale-26, Ysummator 38-and -ratiolV devices 39 to water is a function of the total solids in the mix, but
accordance with ore plus hot recycle, for convenience the wateralso can be apportioned in` accordance'with 43 per se are conventional instruments and not part of my inventionrhencef-they arenot disclosed in detail inthe vpreserltlspe'cification. Neverthelessrfor exemplary showings of a suitable belt scale, summator vand ratio device,
reference can be made toFrazel Patent No. 2,664,286,
Y Markson Patent No; 2,631,599 and Sorteberg Patent No. 2,643,055 respectively, although obviouslymy invention is -not limitedto the specicj devices shown in these patents. VThesev particular instruments Vare Y pneumatically operated and the connections therebetween are air conduits,'jrbutitris also apparent that equivalentelectric devices could be substituted. When the devices shownV in Athese patents are usedthe tube V17 of the Frazel scale-is connected to one of the units A or C of Vthe YMarkson *summator and the yline 'from'the hot recycle is connected Y Vto the other of these units.
Unit B of the summator is left uncoupled so that the force thereon is effectively zero. The Sorteberg force bridge is set up for multiplication, and theoutput line from the'unit Def the summator is connected A thereto to provide the force A on the bridge.
VThe force B on the bridge is set manuallyV to provide the desired'ratio of the particular additive. -The force' Dv is .maintained constant. The force C, whichisY the product,
is transmitted to the weigh-feeder.V *Another example of a suitable ratio device is shown in' Donaldson Patent No. 2,304,783, whose'input 6 can receive the signal from the summator and whose line 9 can carry a signal'to the weigh-feeder. Y t Y Figure 2 is a diagrammatic showing of asuitable weighfeeder 31 Vfor the coke bin 27, showing also its relation to the'ratio device 39. The otherweigh-feeders are simi- -lar;`;hence'the showing is not repeated. The'weigh-feeder includes Va conventional table'feeder`44 and V'a conveyor belt 45. The table feeder has a variable speed drive 46 and delivers cokefrom bin 27 to the belt, which has a Y constant speeddrive 47 and deliversthis coke to the main conveyor 21. Belt 45 traversesja belt scale 48, which can rbeV similar to 26, and transmits a signal to a controller 49. The ratio device 39 transmits another signal to this controller. YYTheoutput signal from the controller is proportionate to the difference between its two input signals and is transmitted to the variable speed drive 46 to control the speed of the table feederV 44. The belt scale determines the actual weight of material fed and transmits this weight to the controller, which changesthe table feeder speedY to correct forV any difference between the weight set by the ratio devicefand'the actual weight. Per
se the controller isa conventional instrument notpart of my invention and henceis not shown in detail. For an Y.exemplary'showing of a suitable controllenreference can be madeV to Moore Patent No. 2,520,468, although obvi-Y ously'my invention is not limited to the specific device shown in this patent. When the Moore controller is used with the patent devices previously discussed, the product signal 'from the Sorteberg force bridge (force C) or from the Donaldson 'ratio relay (line 9) is applied as thecontrol setting pressure to' Moores line'16,'and the signal from the belt scale is applied to Moores lineV ll. 'Moores `valve 13 controls my Variable speed drive 46 through any v suitable speed regulator. Y
Referring to Figure l, the apparatus includes 'a control lpanel 50 whichV carriesseven panel set controls 51 to SI.
The controlv51` is connected to the table feeders 25 for bins 22, 23 and 24. :This control can be any suitable known device for varying the speed of an electric motor, and its manual Vadjus'trnent'varies the table feeder speed Vand ths varies the weight of ore fed to the main con- Y and its action is explained hereinafter. Y
Vl() Y thereof, whereby manual adjustment of controls 52 to 56 varies the proportion of the respective additives andwater. In a pneumatic system these controls can be pressure regulating valves that permit manual 'regulation of the pressure on the input B of the Sorteberg force bridge. If the Donaldson ratio relay isused, the relay itself is mounted in the control panel and its knob 20 becomes the panel set control. The control 57 governs hot recycle The mechanism thus far described controls the proportion of 'additives with respect to the ore by pacing the weigh-feeders 31 in accordance with theweight registered on belt scale 26, although it has been mentioned that the invention embodies afurther control based on hot recycle. This material arrives in variable amounts from the sintering machine and must be used approximately at the rate received, although bin 32 affords sullicient surge capacity tolenableV hot-recycle to feed at constantrates for extended periods. The'panel control 57 is connected toa controller 58 through a Atime delay device 59. The controller 58. can be of similar construction to .49 (Figure f2) and is connected to the table feeder33 for the hot recycle'bin to control the feed rate thereof. Ina pneumatic system the control 57 can be apressure regulating yvalve forY adjusting the pressure-on'the input 16 of the Moore controller, and the time'delay device conveniently can be a simple coil oftubing-ofalength sufficient to delay impulses transmitted therethrough;v The main conveyor 21.traverses another pair of belt scales 60 and 61 located at opposite sides of the table feederf33, and both transmitV signals to an algebraic summator 62 which can be similar to k38 butconnectedto subtract and whose output signal is Vproportionalto the dierence between the weights registered by these two scales, thatris, Vto the actual weight of hot recycle Yfed to the main conveyor.` The output signal frornsummator'62 is continuously transmitted to controller 58,.wh'ose own output signal controls the table feeder 33 so that it feeds hot recycle accuratelyY at the rate set'by the control 57.. Itis seen that the arrangement is the .equivalent of the weigh-feeder showny in Figure 2,
Y and in fact. a .weighfeeder can be substituted if VYthe recycle .suchthat the 'table feeder 33 feeds hot recycle at approximately the rate itis currently received. He also adjusts the control V51 to VVmake an inverse 'change in the rate of Yore feed .to Vkeep the'total weight of ore and hot recycle `substantially. constant, and thus keep the equipment operating Vat substantially a constant'rate, preferably its rated capacity. The purpose of the time delay device 5S is to retard changes Vin hot recycle feed YrateV until the section of conveyor' 21V on which Vthefore feed rate vhas, been changed reaches feeder 33. YFor example, if indicator` 63 shows hot recycle is building up in bin`32, the operator adjusts both controls 57 and 51,' to increasethe hotv recycle feed rate and decrease the ore feed'rate. Immediately the '.table feeders'25 feed less ore to conveyor 21 and the increase inthe hot recycle feed ratersetting is immediately transmitted to summator 38 to offset the lower weight registered on the belt scale 2,6. Consequently no appreciable variation occurs in the output signal from the surnmatortransmitted to the ratio devices nor in the additive feed rate. The time delay device assures that the increase in hot recycle feed rate occurs when the section of the conveyor belt which received less ore actually reaches "feeder 33. v
Figure 3 shows a modification in which changed settings inthe hot recycle feed rate automatically change the ore feed rate. Except for the parts and connections which accomplish this function, the apparatus is similar to Figure 1; hence this description is not repeated. -In Figure 3 the panel set control 51 is connected to a controller 7 0 (which can be similar to 49 and 5S) to regulate the total feed of ore and hot recycle, rather than ore alone, `as in Figure 1. In the example of a controller constructed as shown in the aforementioned Moore patent, control 51 is a valve for regulating the pressure on Moores line 16. The apparatus of Figure 3 embodies an additional ratio device 71 which receives signals from the summator 38 similar to the ratio devices 39 to 43. The panel set control 57 is connected to the ratio device 71 to set it to the desired ratio of hot recycle with respect to ore. The output signal from the ratio device 71 goes to the controller SS via the time delay device 59, and also feeds back t the summator 38. When indicator 63 shows a change is needed in the rate of hot recycle feed, the panel set control 57 is adjusted as in Figure l, but now it adjusts the setting of the ratio device 7l to change the ratio of hot recycle to ore without changing the total. The feedback connection to summator 38 transmits an immediate signal thereto that the hot recycle ratio is changed. The output signal from the summator to the controller 70 changes correspondingly. This controller changes the rate of ore feed inversely to the change in hot recycle feed to maintain the total constant, that is, to maintain constant the sum of the signals from the belt scale 216 and the feedback signal from the ratio device 71.
Figure 4 shows another modification in which the main conveyor includes two belts 21a and 2lb in series, and the mixing device 34 is situated between these belts. Bin 32 feeds hot recycle to an apron-type conveyor 75, which in turn feeds this material to belt 2lb. Thus the ore, additives, filter cake and Water mix before hot recycle is added. Since scale 61 now registers the total weight of sinter feed7 it furnishes the signal transmitted to indicator 67; conveyor 37 and scale 69 shown in Figure 1 can be eliminated. In all other respects this modification is similar to that shown in Figure l; hence the description is not repeated. lt is apparent also that the main conveyor and mixing device of the embodiment shown in Figure 3 could be arranged las shown in Figure 4.
From the foregoing description it is seen the present invention affords a simple apparatus and method for positively proportioning the composition of a sinter feed. Variations in the quantity of hot recycle are easily compensated, irrespective of the location of the hot recycle bin. The invention is readily applied to existing installations. Sometimes recycle is cooled beforehand to facilitate handling and screening, but such cooling does not affect the operation of my invention. Therefore I do not intend my terminology to exclude this obviously equivalent variation.
While I have shown and described only certain preferred embodiments of my invention, it is apparent that other modilications may arise. Therefore, I do not wish to be limited to the disclosure set forth but only by the scope of the appended claims.
I claim:
1. In an apparatus for compounding sinter feed, which apparatus includes a main conveyor, and individually controllable means for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeding means of a proportioning mechanism comprising a scale for determining the Weight of ore fed to the conveyor, means for ladjusting said hot recycle feeding means to feed this material substantially at the rate received, a summator connected to said scale and to said adjusting means for combining the weights of ore and hot recycle, and ratio devices connected to said summator and to said additive feeding means for proportioning the rate of feeding additives as definite ratios of the combined weights of ore and hot recycle.
2. .A combination as defined in claim 1 further comprising a time delay device in the adjusting means for said hot recycle feeding means to delay adjustments in the rate of feeding hot recycle until compensated for by adjustments in the rate of feeding ore.
3. In an apparatus for compounding sinter feed, which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeders of a proportioning mechanism comprising means for adjusting the rate of ore feed, a belt scale traversed by said conveyor between said ore and additive feeders for determining the weight of ore fed thereto, means for adjusting said hot recycle feeder to feed this material substantially at the rate received, a summator connected to said belt scale and to said second named adjusting means for continuously combining the Weight registered on said scale with the setting of said second named adjusting means, and ratio devices connected with said summator and the respective additive feeders for proportioning the rate of feeding additives as definite ratios of the combined weights of ore and hot recycle.
4. In an apparatus for compounding sinter feed, which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeders of a proportioning mechanism comprising means for adjusting said hot recycle feeder to feed this material substantially at the rate received, means for adjusting said ore feeders inversely to said hot recycle feeder to maintain the combined feed of hot recycle and ore substantially constant, means for computing the combined weight of ore and hot recycle fed to said conveyor, and control means for said additive feeder operatively connected with said computing means for proportioning the additives in `accordance with the combined feed of hot recycle and ore.
5. A combination as dened in claim 4 further comprising a feedback connection between the adjusting means for said hot recycle feeder and the adjusting means for said ore feeder via said computing means to adjust the ore feed rate automaticallywith adjustments in hot recycle feed rate.
6. In an apparatus for compounding sinter feed, which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle successively to said conveyor, the combination with said feeders of a proportioning mechanism comprising means for adjusting said hot recycle feeder to feed this material substantially at the rate received, means for adjusting said ore feeders inversely to said hot recycle feeder to maintain the combined feed of hot recycle and ore substantially constant, a time delay device in the adjusting means for said hot recycle feeder to delay adjustments in the rate of feeder hot recycle until the portion of said conveyor on which the rate of feeding ore has changed reaches said hot recycle feeder, and control means for said additive feeder for proportioning the additives in accordance with the combined feed of hot recycle and ore.
7. In an apparatus for compounding sinter feed, which apparatus includes a main conveyor and individually controllable feeders for feeding ore, additives and hot recycle in theorder named to said convey0r,.the com-` bination with said feeders of a proportioning mechanism comprising meansV for maintaining the combined feeding rate of ore and hot recycle substantially constant, means Y for continuously summating the actual combined feeding rate thereof, and ratio devices connecting said summating means andsaid additive feeders for maintaining the additive feeding rate as a definite ratio of the combined feeding rate of ore and hot recycle.
8. In Van apparatus for compounding sinter feed, which apparatus includes a main conveyor and individually controllable feeders for vfeeding ore,"additives and hot re- 'cycle successively to .said conveyor, the combination therewith of a'mechanism for regulatingsaid yore feeders comprising means for transmitting a signal proportionate to the desired sum of thel ore and hot recycle feed rates,
lmeans for transmitting another'signal proportionate to the actual ore feed rate, means for transmitting a third signal proportionate tothe setting of said hot recycle feeder, and control means operatively connected with said ore feeders and said transmitting means for adjusting the ore feed rate to maintain the sum of the ore and hot recycle feed rates'at the constant desired level.
9. In an apparatus for compounding sinter feed, which apparatus includes a mainrconveyor and individually con- Vtrollable feeders for feeding ore, additives andjhot recycle successively to said conveyor, theV combination therewith of a mechanism for regulating-said ore feeders comprising means for transmitting a first signal proportionate to the desired sum of the ore and hot recycle feed rates, means for transmitting a second signal proportionate to the actual ore feed rate, means for transmitting a third signal proportionate to the setting of said hot recycle feeder, means `for computing the sum of said second and third signals operatively connected to the transmitting means therefor, and control-means opera- Y Y tively connected with said ore feeders, with the transmitting means for said rst signal Yand with said computing means for adjusting the ore feed rate to maintain the sum Y of the ore and hot recycle feedrrates at the constant desired level. i
10. In an apparatus for compounding sinter feed,
which apparatus includes a main conveyor composed of at :least one power driven belt, a mixing device adapted to receive material from said conveyor, and individually Y controllable means for feeding ore, additives and hot recycle successively to said conveyor, the combination with sa1d feeding means of a proportioning mechanism comprising a scale for determining the weight of ore fedto the conveyor, means for adjusting said hot recycle feeding means to feed this material substantially at the rate received, a summator connected tosaid scale and to-saidradjusting means for combining the weights of ore Y and hot recycle, and ratio devices connected to said summator and to said additive feeding means for proportioning the rate of feeding additives as definite ratios of the Y combined Weights of ore and hot recycle.
111. A combination as dened in claim 10 in which the feeding means for ore, additives and Yh'otrec'ycle are situated to Vfeed these materials to a belt ahead of` said Vmixing device, whereby said mixing device receives hot recycle as well as ore and additives.
12. A combination as defined in c1air`n-10 in which the feeding means for ore and additives aresituated to feed these Vmaterials to a belt ahead of said mixing device, and the feeding means for hot recycleV is situated to feed the latterVV material to a belt beyond said mixing device, whereby said mixing device receives orewand additives, but hot recycle is excluded therefrom.
13. A method of compounding sinter feed comprising `feedin Isuccessivel to a traveling conve or ore, additives, and hot recycle` at va predetermined respective rate for each, continuously and separately Yobtaining measurements of the feeding rates of loreand hot recycle, continuously obtaining a summation of said measurements, and continuously controlling the feeding rate of additives to a rate proportional to this summation. .Y
14. A method of compoundingsnter feed-comprising f feeding successively to a Ytraveling conveyor ore, additives, and hot recycle at a predetermined respective rate for each, maintaining the combined feeding rate of ore and hot recycle Vsubstantially constant, continuously and separately obtaining measurements of the actual feeding Yrates of ore and hot recycle, continuously obtaining a summation of said measurements, and continuously controlling the feeding rate of additives to arate proportional to this summation. g f,
' 15. A method of compounding sinter feed comprising receiving hot recycle at a variable r-ate'from a'sintering operation, feeding successivelyto a traveling conveyor ore, additives and hot recycle at a predetermined respective rate for each, adjusting the feeding rate of hot recycle toY substantially the rate received, inversely adjusting the feeding rate of ore to maintain the combined feeding rateY of ore and hot recycle substantially constant, continuously obtaining measurements of the. actual feeding rates of ore and hot recycle, continuously obtaining a summation of these measurements, and continuously controlling the feeding rate of additives to a rate proportional to this summation.
References Cited in the tile of this patent UNITED STATES PATENTS Davies Nov. 24, 1959
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US810508A US2980291A (en) | 1959-05-01 | 1959-05-01 | Method and apparatus for compounding sinter feed |
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US810508A US2980291A (en) | 1959-05-01 | 1959-05-01 | Method and apparatus for compounding sinter feed |
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US2980291A true US2980291A (en) | 1961-04-18 |
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US810508A Expired - Lifetime US2980291A (en) | 1959-05-01 | 1959-05-01 | Method and apparatus for compounding sinter feed |
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US3078012A (en) * | 1960-10-03 | 1963-02-19 | New York Air Brake Co | Automatic control device |
US3190743A (en) * | 1962-03-01 | 1965-06-22 | Mckee & Co Arthur G | Method and apparatus for manufacture of pellets or the like |
US3262770A (en) * | 1962-05-11 | 1966-07-26 | Yawata Iron & Steel Co | Method of controlling the thickness of a charged raw material layer in dwight-lloyd sintering machine |
US3615344A (en) * | 1967-12-01 | 1971-10-26 | Centre Nat Rech Metall | Methods of controlling the process of agglomeration |
US3632018A (en) * | 1968-05-17 | 1972-01-04 | Leeds & Northrup Co | Feed rate control in a cement kiln incorporating dust return |
US3822056A (en) * | 1972-03-31 | 1974-07-02 | R Hawes | Method and means for adding small measured quantities of selected materials to a large capacity material-mixing plant |
US4202466A (en) * | 1973-07-19 | 1980-05-13 | Henry Simon Limited | Method of and apparatus for dispensing predetermined proportions of two or more materials |
US20070125543A1 (en) * | 2005-12-01 | 2007-06-07 | Halliburton Energy Services, Inc. | Method and apparatus for centralized well treatment |
US20070125544A1 (en) * | 2005-12-01 | 2007-06-07 | Halliburton Energy Services, Inc. | Method and apparatus for providing pressure for well treatment operations |
US20070201305A1 (en) * | 2006-02-27 | 2007-08-30 | Halliburton Energy Services, Inc. | Method and apparatus for centralized proppant storage and metering |
US20080083531A1 (en) * | 2006-10-10 | 2008-04-10 | Halliburton Energy Services, Inc. | Methods and systems for well stimulation using multiple angled fracturing |
US20080083532A1 (en) * | 2006-10-10 | 2008-04-10 | Surjaatmadja Jim B | Methods for Maximizing Second Fracture Length |
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US7946340B2 (en) | 2005-12-01 | 2011-05-24 | Halliburton Energy Services, Inc. | Method and apparatus for orchestration of fracture placement from a centralized well fluid treatment center |
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US20090194273A1 (en) * | 2005-12-01 | 2009-08-06 | Surjaatmadja Jim B | Method and Apparatus for Orchestration of Fracture Placement From a Centralized Well Fluid Treatment Center |
US20070201305A1 (en) * | 2006-02-27 | 2007-08-30 | Halliburton Energy Services, Inc. | Method and apparatus for centralized proppant storage and metering |
US20080083531A1 (en) * | 2006-10-10 | 2008-04-10 | Halliburton Energy Services, Inc. | Methods and systems for well stimulation using multiple angled fracturing |
US7740072B2 (en) | 2006-10-10 | 2010-06-22 | Halliburton Energy Services, Inc. | Methods and systems for well stimulation using multiple angled fracturing |
US7711487B2 (en) | 2006-10-10 | 2010-05-04 | Halliburton Energy Services, Inc. | Methods for maximizing second fracture length |
US20080083532A1 (en) * | 2006-10-10 | 2008-04-10 | Surjaatmadja Jim B | Methods for Maximizing Second Fracture Length |
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