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Publication numberUS2791471 A
Publication typeGrant
Publication dateMay 7, 1957
Filing dateOct 26, 1953
Priority dateOct 26, 1953
Publication numberUS 2791471 A, US 2791471A, US-A-2791471, US2791471 A, US2791471A
InventorsClancey James T, Phinney John A, Regan Thomas J, Wasp Edward J
Original AssigneeConsolidation Coal Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Transportation of coal by pipeline
US 2791471 A
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Description  (OCR text may contain errors)

May 7, 1957 Filed OCb. 26. 1953 S LU RBY www@ 158m WATER- J. T. cLANcEY Er Ax. 2,791,471


IPUMP-l l S l U RRY DEWATERING T LLI E mvENToRs .1.1. cLANcl-:Y g .1.A. PHINNEY D T. J. REGAN (7,' E. .1. wAsP ATTORNEY May 7, 1957 .1. T. cLANcEY ETAL 2,791,471

TRANSPORTATION OF COAL BY PIPELINE Filed CGT.. 26, 1953 5 Sheets-Sheet 2 J Lu l! m N '2- n l 1 3 U- L O (D u] :l E

(r E 4 a O X 12 2 /Q 2 v .E z (D U3 N y y D mvENToRs O JAMES 'non mcfv JOHN A. P HINNEY Q lq Q 'o THoMAs'J-REGAN N N EDWARD J. wAsP ATTORNEY May 7, 1957 Filed Oct. 26, 1955 WE|GHT% MINUS 325 MESH PARTICLES IN SLURRY J. T. CLANCEY TAL TRANSPORTATION OF COAL BY PIPELINE sheets-sheet 3 4MXO 24 BMXO le B /T' l2 o 2o 4o. eo 8o |00 M|LES 0F PIPELINE TRAVEL FIG. 3


FIG. 4

ATTORNEY May 7, 1957 J. T. cLANcEY rs1-AL TRANSPORTATION OF COAL BY PIPELINE 5 Sheets-Sheet 5 Filed Oct. 26. 1955 IOO MILES OF PIPELINE TRAVEL N YYAP MN5 ANRw LI CTJ O .SU MNAAR EENWM VMHHD N A 0 IJJTE 5 ATTORNEY TRANSPRTATION F COAL BY PIPELINE James T. Clancey, John A. Phinney, and Thomas J. Regan, Pittsburgh, and Edward J. Wasp, Library, Pa., assignors to `Pittsburgh Consolidation Coni Company, Pittsburgh, Pa., a corporation of Pennsylvania Application October 26, 1953, Serial No. 388,399

Claims. (Cl. 302-66) tive delivered cost of coal per B. t. u. considered in relation tosuch incidental factors as dust nuisance, handling properties, moisture content, et cetera, determines what he will pay for tonnage coal. With a bulk tonnage product such as coal, freight is a very considerable part of the delivered fuel cost. Hence any appreciable reduction in the transportation cost will decrease vsubstantially the delivered B. t. u. cost to the coal consumer.

Coal traditionally is shipped from mine to market by railroad, although for years less expensive means have been envisioned. As early as 1891, W. C. Andrews obtained U. S. Patent 449,102 broadly outlining the technique of'pumping coal in mixture with water through pipelines. Since Andrews, many schemes have been proposed or implementing the Andrews patent, although no coal pipeline has been operated commercially for long distances, e. g., 50 miles or more. See, for example, U. S. Bureau of Mines Report of Investigation 4799, A Survey of the'Hydraulic Transportation of Coal, by R. W. Dougherty, July 1951.

Any coal pipeline installation comprises three basic and separable stages: (l) a preparation stage comprising treatment of the coal and mixing it with water to form a slurry; (2) a transportation stage comprising the pipeline proper together with pumping apparatus for moving the slurry through the long distance pipeline; and (3) a recovery stage at the pipeline-terminal in which water is removed from the delivered slurry .to permit recovery of marketable or usable coal.

We have discovered that by properly selecting, within narrowly defined limitations, the coal to be transported through pipelines, the signilicant operating costs in each of the three stages can be minimized. In addition, the coal delivered from a pipeline operated in accordance with this invention is more acceptable to the customer because of its minimum content of fines.

The primary object of this invention is to reduce the overall energy required for transporting coal from mine to market through pipelines by minimizing the energy requirements for coal preparation, Yslurry pumping and slurry dewatering.

Another object of this invention is to Vtransport coal with water through pipelines to deliver at distant points a coal ,slurry which has a minimum weight fraction `of Aundesirable ltine-sized coal particles, thereby minimizing storage and handling problems of pipeline coals.

:The inventionis best described with reference to the accompanying drawings in which:

YFigure :1 is a schematic illustration of a coal :pipeline `transpor-tationlsystenax;

.ligurel is -ia .graphical illustration .showing the effect vpipes Whichare commercially feasible.

522,791,471 Patented May 7, 1.957

2 ofpumping distance on the pressure drop of coal slurries throughout a commercial scale pipeline;

Figure 3 is a .graphical illustration-shoWing-the particlefattrition which results from transporting coal slurries AthrOllgll yCommercial scale pipelines;

`Figure 4 isa graphical illustration showing the eiiect of one factor in the initial particle Vsize distribution of a coal slurry on therparticle attrition resulting from transporting. coal through a commercial V.scale pipeline; and

-toform a slurry. It necessary, the coal may `be-crushed and Screened prior to being mixed with water.

The resulting slurry should contain about 35 to 55 percent coal by weight. Slurry from the preparation stage is introduced into the transportation pipeline and pumped at pressures up to about 1200 pounds per square inch through the pipeline for long distances, e. g., 5-0 or 100 milesor more to a slurry dewatering terminal wherek dry, marketable coal is recoveredfrom the slurry for ydeliveryV to.customers. The preferred linear velocity of the slurry through the pipeline is in the range of about 4to 7 feet ,per second. With linear velocities in this range, 5500V to 8000 tons of coal can be delivered daily by a commercialgpipeline having an internal diameter o f about l2 inches.

Economic radvantages of coalpipelines cannot be ob- .tained in pipelines less .than about 8 inches in internal .diameter becauseof the limited throughput in smaller pipes. In general, pipelines of about 8 to 15 inches in diameter are preferred, although larger pipes are feasible provided the coal demand is suicient to vconsumetheir delivery.

The present invention, moreover, is applicable only to .these ylarger diameter pipelines which are of commercial interest. We have found that the size consist of the pipeline-coal is a critical factor in the economics of coal pipeline operation only in rthose large diameter Small diameter experimental Ycoal slurry pipelines indicatedthe pressure drop exhibited by coal'slurries tobe independent cf coal size consist in a ,3-inch diameter pipe, and also to'have a diameter of 12 inches, however, we discovered that surprisingly the operation of commercial pipelines is Ysensitive'to the coal size consist and also the pumping ditance. -We found that the size consist of the coal affects costs of operation and costs of equipment at all three stages of Aa commercial pipeline.

In the preparation stage, the crushing Yenergy required as well as the equipment costs can be minimizedby using as pipeline feed a coal size consist which can be prepared readily with relatively simple equipment.

Even more important, however, is the effect of coal size on the energy required for pumping slurry through the transportation pipeline itself. We have found that pumping energy, a d irect cost `factor, can be minimized by selecting certainnarrowly defined coal size fractions for pipeline transportation.

Moreover the size distribution of the coal inthe slurry also atectsfthe relative diiiculty of recovering dry, marketable coal in the dewatering stage at the pipelinedelivery terminal.

' Finally `the size consist of ,the recovered coal' is a ysignificant Aactorfin its marketability because of its effect upon 1 the handling iand storage ,characteristics of the ,dce

economic loss of potential fuel.

'bridging in coal hoppers and handling equipment, resulting in erratic feeding of such coals to continuously fed boilers. Furthermore extremely ne coals, when stored in open stockpiles are readily blown away by winds and air currents resulting in dust nuisances as well as an Coal having excessive fines is quite susceptible in storage piles to spontaneous combustion. To resolve these problems, the purchaser of extremely ne coal must resort to elaborate and costly stockpiling techniques.

We have discovered that surprisingly all of these problems, as well as the magnitude of the energy required to deliver dry coal can be minimized if the coal selected for pipeline transportation has a nominal top size of from 6 mesh to 28 mesh Tyler Standard Screen Series, and in addition not more than 25 percent of the coal by weight is retained on a 14mesh Tyler Standard Screen.

It is evident that only limited crushing is required to prepare a coal feed for commercial pipelines in the critical size consist range. Since crushing energy requirements 'increase rapidly with desired product tlneness, a substantial savings results from the limited size comminution required to produce the critical feed material of this invention. Conventional hammer mills in general can be used for size reduction to about a 28 mesh nominal top size; more elaborate crushing apparatus Would have to be provided to comminute feed coal to any smaller size. Furthermore screens having openings of less than 28 mesh are generally impractical for commercial use because of the tendency of ne coal particles to become -caught in the openings resulting in a blinding of the screen. To etfect size grading of coals to a top size of less than about 28 mesh requires apparatus other than relatively inexpensive screens. Hence conventional hammer milling and screening is adequate to provide the critical coal size consist required for pipeline transportation.

Thus, through its effect on the costs of the preparation stages, the size consist of the feed coal is a substantial factor in the overall costs of coal pipeline transportation.

To illustrate the effect of coal size on pumping power requirements, Figure 2 shows the pressure drop exhibited by several typical coal slurries of differing size consists. All the data for the relationships of Figure 2 were obtained from slurry pumping operations'at about 6 feet per second through a pipeline having an internal diameter of l2 inches. Each of the slurries shown had a solids concentration of about 50 percent by weight.

The pressure drop of water alone is shown in line A and is assigned a value of 1.0 for comparison; the value is seen to be unvarying with pumping distance. Each of the curves B, C, D and E shows the phenomenon of high initial pressure drop which is characteristic of raw coal slurries being pumped through commercial pipelines. Curve B shows 4 mesh X 0 coal; curve C shows 8 mesh x coal; curve D shows 14 mesh x 0 coal; and curve E shows 28 mesh X 0 coal. All mesh sizes are Tyler Standard Screen Series. The term raw coal as used herein applies to any coal which has not previously passed through a long distance coal slurry transportation pipeline.

Figure 2 shows that after about 50 miles of travel in a commercial scale pipeline, coal slurries regardless of their particle size distribution, require about the same pumping energy. The disparity of the pumping energy requirement for various slurries exists to a pronounced degree only in the initial portion of the pipeline, e. g., the first 50 miles. The initial pressure drop for 4 mesh x 0 coal slurries has been shown to be 1.5 and more times Vgreater than that of 14 mesh X 0 slurries. YIt' is further evident that coals having a size composition of about 14 mesh x 0 exhibit a minimum initial pressure drop. Coals having a nominal top size larger than about 6 mesh -exhibit an excessive initial pressure drop in a commercial scale pipeline. Similarly coals having a nominal top size less than about 28 mesh result in excessive initial pressure drop.

The phenomenon of high initial pressure drop exhibited by coal slurries occurs only in pipelines having relatively large diameters, i. e., those which are economically feasible for long distance commercial transportation of coal.

In Table I pressure drop characteristics of various coal slurries are compared at the initial point of a pipeline and also after 10() miles of travel through a pipeline for both a 3-inch diameter pipe and a 12-inch diameter pipe.

TABLE I 1 50 wt. percent coal in water.

The pressure drop for water is taken as a reference point and assigned a value of 1.0. The pressure drop of 50 wt. percent coal slurries in a pipe having a diameter of 3 inches is 1.3 times that of water in the same pipe at the same velocity. This pressure drop does not vary with size consist of the coal (in the range of 4 mesh x 0 to 28 mesh x 0) and furthermore does not vary with thc length of travel through the small pipe. Pressure drop of all the coal slurries for a 3-inches diameter pipe in Table I is 1.3 times that of water throughout the pipe. Nevertheless in the pipe having a diameter of 12 inches, the size consist of the coal is seen to exert a substantial elect on the pressure drop of the coal slurry. The 4 mesh X 0 slurry exhibits initially a pressure drop 2.8 times that of water whereas the 14 mesh x O slurry has a pressure drop of only 1.52 times that of water. Moreover the pressure drop of coal slurries in the large pipeline is not uniform throughout its length. lIhe pressure drop of 14 mesh X 0 slurry, for example, is seen to diminish from 1.52 times that of water initially to only 1.38 times that of water after traveling through miles of the 12 inches diameter pipeline. Even after 100 miles of travel, however, the 14 mesh x 0 slurry in the 12 inches diameter pipe exceeds that of water by a factor of 1.38 whereas at any point in the 3 inches diameter pipe the 14 mesh x 0 coal slurry pressure drop is only 1.3 times that of water.

Thus, it is seen that pressure drop phenomenon (which controls the pumping energy requirements for coal slurries and hence the cost of transporting coals through pipelines) occurs only in those large diameter pipes which are of interest commercially, i. e., larger than about 8 inches in diameter.

Accordingly we have discovered that the pumping energy requirements for transporting coal slurries through commercial pipelines can be minimized where the coal has a nominal top size in the range of about 28 mesh to about 6 mesh.

One of the most troublesome problems associated with transporting coal by pipeline is that of separating the coal from the slurry in the slurry dewatering stage at the pipeline delivery terminal. Dewatering dilhculties in general arise from the presence of very line size attrited particles in the delivered slurry.

In passing through a slurry pipeline, the coal particles experienced attrition which causes a rounding olf of their sharp edges to produce what are termed minus 325 mesh attrited particles. These minus 325 mesh attrited particles are the most diicult to recover and also render diiicult the dewatering of the balance of the coal particles. coal slurry are not nearly so troublesome as the minus 325 mesh attrited particles.

The minus 325 mesh attrited coal lls the interstices between larger particles and obstructs drying by natural drainage of the coal. The minus 325 attrited coal also tends to clog the interstices of a filter septem in conventional iiltration equipment and frequently passes through the equipment into the liquid filtrate. Both the rate and ethciency of filtration are reduced by the presence of minus 325 mesh attrited coal. Centrifugal and cyclonetype separators are generally ineffective for separating these minus 325 mesh attrited solids from their liquid medium. The only really satisfactory technique for,

separating thewater medium from the delivered slurry containing appreciable minus 325 mesh attrited coal is thermal drying which is costly, cumbersome and ineicient with respect to solids recovery.

Hence it is desirable to deliver through commercial pipelines to a slurry dewatering stage a minimum quantity of attrited particles which will pass through a 325 mesh screenf Coals which have Vbeen ground to' nominal top sizes of less than 28 mesh normally'will contain a substantial quantity of initial minus 325 mesh particles after the grinding operation. In passing through a slurry pipeline, these finely ground coalsV undergo only slight attrition to yield additional minus 325 mesh particles in the form of attrited coal.

On the other hand, coals which have been ground to a nominal top size larger than about 6 mesh will undergo excessive attrition'in passing through a slurry pipeline to yield large fractions of minus 325 mesh attrited particles in the delivered slurry. Whereas these coarser fractions initially contain only small quantities;

We have thus discovered that coal can be delivered by means of slurries `through pipelines with a minimum of minus 325 mesh attrited particles Where the initial coal has a nominal top size of from about 6 mesh to about 28 mesh. When the pipeline is operated with such coal, the dewatering diliiculties are minimized, land, in addition, the recovered dried coal is more readily store and handled.

Figure 3 indicates the manner in which the content of minus 325 mesh particles increases with the length of -travel of the coal slurry through a pipeline. The weight percentage of minus 325 mesh coal is plotted against the length of pipeline travel for a slurry containing about 50 weight percent coal being moved at a linear velocity of about 6 feet per second. Curve A shows the minus 325 mesh coal content of a typical slurry containing 28 mesh x 0 coal; curve B is for 14 mesh x 0 coal; curve C is for 8 mesh x O coal; and curve D is for 4 mesh x 0 coal. It is seen from Figure 3 that the initial content of minus 325 mesh particles is high for the generally less coarse coals, but is low for the generally coarse coals. At pipeline distances of commercial interest, i. e., 50 miles and more, the problem of attrition becomes acute. The curves indicate that coal delivered by pipelines over long distances of about 50 miles or more have a minimum total content of minus 325 mesh particles when the starting coal has a size composition ranging from about 6 mesh x 0 to about 28 mesh x 0.

In addition we have discovered that the weight of particles larger than 14 mesh size (hereinafter referred to as plus 14 mesh particles) should not exceed 25 percent of the feed coal in order to avoid the production of excessive minus 325 mesh coal by attrition.

The curve of Figure 4 shows the increase of minus 325 The minus 325 mesh` particles initially in the` mesh coal in slurries which have been pumped for miles through a commercial scale pipeline. It is seen that the quantity of minus 325 mesh coal resulting from attrition increases sharply as the quantity of plus 14 mesh particles in the feed coal increases.

To summarize our invention, we have found that by properly selecting the size of coals to be transported in slurry form through long distance pipelines, it is possible to minimize the capital investment, operating costs and energy requirements at all stages in a commercial long distance coal transportation pipeline system. Where` the consumer is more acceptable for storage and handling because of its minimum quantity of total minus 325 mesh particles (see Figures 3 and 4).

In the following Table lII, some experimental results obtained by transporting various coal slurries through long distances in commercial scale pipelines are tabulated to indicate quantitatively some of the advantages which attend the operation of coal slurry pipelines in accordance with the present invention.

TABLE Il Run No 55 61 59 v 11 Nominal Feed Size 28m x 0 14m x 0 8m x 0 4m x 0 Feed Composition (Weight percent oi feed solids): Y 0.0 0.0 0.0 0. 8 0.0 0.0 0.8 12.6 0.3 0.3 24. 7 18.6 0.4 28. 1 26.1 22. 2 87. 8 30.9 20. 2 18. 4 on 100 mcsh. 31.6 19. 0 13.1 11.8 on 200 mesh 13. 5 8.1 6.2 5. 9 on 325 mesh 6. 8 3. 9 3. 3 3.6 Through 325 mesh.. 9. 6 9.6 5. 6 6.1 Slurry Concentration- 60. 0 50. 0 60. 0 48. 1 kLinear Velocity, ft./sec. 6. 0 6. 0 6. 2 6.0

Delivered Slurry Composition at 100 miles (Weight percent of feed solids):

on 4 mesh l 0. 0 0.0 0.0 0.3 l 0.0 0.0 0.2 6. 4 l 0. l 0.3 18. 9 14. 7 1 0.2 21. 6 24.1 17. 3 1 36. 6 29. 7 17. 1 13.1 1 29. 3 18. 1 8.7 9. 4 1 12.3 G. 4 3. 8 5. 6 on 325 mesh 1 6.8 3. 5 2.8 3. 5 Through 325 mesh 1 14. 7 20.4 24. 4 29. 2 Increase in minus 325 mesh coal weight percent 5.1 10. 8 17. 8 23. 1 Filtration rate of Slurry (dry lbs. per hr. per sq. ft.) 37 72 50 (2) 1 80 miles. 2 4 mesh x 0 slurry was untilterable.

The experimental runs are arranged in Table II from left to right in order of increasing coarseness of the feed material. The increase in the content of minus 325 mesh coal (i. e. attrition coal) after 100 miles (80 miles in the case of run 55) is shown to be greater as the coal feed becomes generally coarser. The effect of slurry transportation on the tiltration characteristics of the delivered slurry is demonstrated by the filtration rates which are low for the 28 mesh x 0 slurry, reach a maximum with 14 mesh x 0 slurry, and again diminish with 8 mesh x 0 slurries. The 4 mesh x O slurry proved to be untilterable in the drum-type filter employed in these tests, because of its excess of large coal particles. Although unfilterable in the particular equipment available, nevertheless the 4 mesh x 0 slurry could be satisfactorily separated into a coarse and a line fraction with centrifuging equipment;` .the yslurry eiuent from the centrifuge thereupon was iilterable, although its filtration rate Was 10W.

The minus 325 mesh screen analysis of the delivered slurries indicates that the 4 mesh x 0 slurry has an excessive quantity of minus 325 mesh coal fines, most of which result from attrition during transit in the pipeline. Hence 4 mesh x 0 slurries are both diicult to dewater and troublesome for consumer handling and storage. The particular 8 mesh x 0 slurry shown in Table II also has an excessive quantity of fines; however its initial composition is slightly beyond the critical limitations of this invention, namely, the plus 14 mesh content exceeds 25 Weight percent of the feed coal.

Pressure drop profiles for each of the coal slurries tabulated in Table II are presented in Figure 5 where the pressure drop of each slurry is plotted against the length of travel by the slurry through the pipeline. The two slurries exhibiting the high initial pressure drop are the 4 mesh x 0 slurry and the 2S mesh x 0 slurry. Minimum pressure drop is indicated for the 14 mesh x (l slurry.

Thus, it is seen, that by using a coal feed selected as herein provided, crushing costs can be maintained at a low value since the required size reduction is not excessive; pumping costs as reliected by the pressure drop curves of Figure 5 are minimized; dewatering costs indicated by the filtration rate data of Table II are minimized; and handling and storage characteristics of the delivered product (a substantial factor in its marketability) are improved as shown by the delivered screen analysis of Table II.

An additional implication of our discovery is applicable to the transportation of coals to commercial steam generating plants, most of which have burners adapted to operate with pulverized coals, for example, coals of which 100 percent will pass through a 100 mesh screen and at least 50 percent will pass through a 200 mesh screen. Because of the excessive pumping energy which would be required for such pulverized coals, their transportation through commercial pipelines is prohibitive. In order to convert mined coal into thermal energy at distant boiler plants, therefore, we have found that it is uneconomical to grind the coal to a pulverized state before it is shipped by pipeline. Instead, the mined coal should be comminuted to a size from about 6 mesh x 0 to about 28 mesh x 0 as previously set forth herein and pumped as a slurry through a long distance pipeline to the distant boiler plant. Attritionv resulting `from the movement of the coal through the pipeline is itself an effective factor in increasing the neness of the delivered coal, thereby reducing the duty of any further mechanical crushing apparatus.

As a further consequence of our discovery that the pressure drop of coal slurry decreases with distance of travel through a commercial pipeline, we have found that the pumping stations should be placed along the pipeline at successively increasing intervals.

lf, for example, five equal capacity pumping units will supply the energy required to move coal slurry at the desired rate through a commercial pipeline, these tive pumping stations should not be placed along the pipeline at uniform intervals` One fifth of the total energy required to move coal slurry through the entire pipeline under stated conditions will not move the slurry through the first fth of the pipeline at the stated conditions. Hence, in order to obtain maximum advantage from equal capacity pumping stations for coal slurry pipelines, it is necessary that they be placed at successively increasing intervals, with proper allowance for differences in elevation of the terrain which exert an independent effect on the pumping requirements.

Y According to the provisions of the Vpatent statutes, We have explained the principle, .preferred construction, and

' mode of operation of our invention and have illustrated and described what we now consider to represent its best embodiment. However, we desire to have it understood that, within the scope of the appended claims, the invention may be practiced otherwise than as specically illustrated and described.

We claim:

l. A method for moving coal from mines to distant markets which comprises obtaining coal having a nominal top size in the range of 28 mesh to 6 mesh Tyler Screen Series and having less than 25 percent by Weight of plus 14 mesh particles, preparing a water slurry comprising 35 to 55 percent by weight of said coal in water, pumping said slurry through a long distance pipeline at linear velocities of 4 to 7 feet per second, recovering slurry from the delivery end of said pipeline and recovering marketable coal from said slurry.

2. A method for preparing coal to be transported in the form of a Water slurry through long distance cornmercial pipelines which comprises comminuting coal to a nominal top size in the range of 28 mesh to 6 mesh Tyler Screen Series in such manner that less than 25 percent'by Weight of said coal comprises plus 14 mesh particles, and preparing a water slurry comprising 35 to 55 percent by weight of said coal.

3. A method for ,delivering coal through commercial pipelines vexceeding 50 miles in length which comprises obtaining coal having a nominal top size in the range of 28 mesh to 6 mesh Tyler Screen Series and having less than 2-5 percent of its weight as plus 14 mesh particles, mixing said coal -with Water to `form a slurry containing a 35 to 55 percent solids concentration by weight, pumping said mixture at high pressures through a pipeline having an internal diameter exceeding 8 inches, at a linear velocity of 4 to 7 feet per second, removing the bulk of the water from the delivered slurry, and recovering marketable coal.

4. A -method for delivering coal over distances exceeding 50 miles which comprises obtaining coal having a nominal top size in the range of 28 mesh to 6 mesh Tyler Screen Series, and having less than 25 percent by weight as plus 14 mesh particles, mixing said coal with water to form -a slurry having 35 to 55 Weight percent solids concentration, introducing said slurry into a pipeline having an internal diameter of at least 8 inches, introducing substantially equal quantities of energy into the pipeline at increasing intervals of length :by means of pumping apparatus, recovering coal slurry at the delivery terminal of said pipeline, and recovering marketable coal from the delivered slurry.

5. A method for moving coal 4between two distant locations Vwhich comprises obtaining coal having a nominal top size in the range of 28 mesh to 6 mesh Tyler Screen Series and having less than 25 percent by weight of plus 14 mesh particles, ypreparing a water yslurry comprising 35 to 55 percent by Weight of said coal in water, pumping said slurry through a pipeline connecting said two distant locations, recovering slurry from the delivery end ot Vsaid pipeline vand recovering marketable coal from said slurry.

Y References Cited inthe file of this patent UNITED STATES PATENTS 449,102 Andrews Mar. 31, 1891

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
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Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3012826 *Apr 28, 1960Dec 12, 1961Ruhrgas AgHydraulic conveying method
US3093419 *Mar 2, 1960Jun 11, 1963Bowers William EMortar spreading apparatus and method of conveying
US3168350 *Aug 29, 1961Feb 2, 1965Consolidation Coal CoTransportation of coal by pipeline
US3517969 *Apr 10, 1968Jun 30, 1970Shell Oil CoTransportation of particles by pipeline
US3637263 *Mar 3, 1970Jan 25, 1972Bechtel Int CorpTransportation of coal by pipeline
US3931999 *Nov 4, 1974Jan 13, 1976Continental Oil CompanyApparatus for hydraulically transporting solids
US3940184 *May 21, 1974Feb 24, 1976Continental Oil CompanyMethods and systems for hydraulically transporting solids
US3982789 *Jul 16, 1974Sep 28, 1976Kamyr, Inc.Process and apparatus for conveying large particle mined coal, oil shale, ore, etc. from underground mines or from strip mines via a pipeline
US4008924 *Apr 18, 1975Feb 22, 1977Marathon Oil CompanyProcess for reducing the settling rate of comminuted porous solids in a water-solids slurry
US4245664 *Oct 16, 1978Jan 20, 1981Johnson Johnny TControlled pressure sewer system
US4265737 *Apr 23, 1980May 5, 1981Otisca Industries, Ltd.Methods and apparatus for transporting and processing solids
US4282006 *Oct 26, 1979Aug 4, 1981Alfred University Research Foundation Inc.Heat energy
U.S. Classification406/197, 110/263, 110/267
International ClassificationB65G53/30, B65G53/00
Cooperative ClassificationB65G53/30
European ClassificationB65G53/30