US3006816A - Oil shale retort and method - Google Patents

Oil shale retort and method Download PDF

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US3006816A
US3006816A US702571A US70257157A US3006816A US 3006816 A US3006816 A US 3006816A US 702571 A US702571 A US 702571A US 70257157 A US70257157 A US 70257157A US 3006816 A US3006816 A US 3006816A
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shale
bed
raw
oil
combustion
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John H V Finney
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Union Oil Company of California
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    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10GCRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
    • C10G1/00Production of liquid hydrocarbon mixtures from oil-shale, oil-sand, or non-melting solid carbonaceous or similar materials, e.g. wood, coal
    • C10G1/02Production of liquid hydrocarbon mixtures from oil-shale, oil-sand, or non-melting solid carbonaceous or similar materials, e.g. wood, coal by distillation

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  • oil shale there are vast deposits of a raw material called oil shale in the western part of the United States, principally in the States of Colorado, Wyoming and Utah.
  • This raw material which is not a shale but a marl stone, contains organic material in amounts from a trace to over 30% by weight, and generally a commercial deposit should average between 10.5 to 80 gallons of derived shale oil per ton of ore.
  • the organic matter in Colorado oil shale is sometimes called kerogen, which is a high molecular weight substance of largely unknown structure. It is from this complex organic substance that a liquid hydrocarbon mixture, called shale oil, is formed by a pyrolysis.
  • a retort which includes essentialy three zones, that is, a combustion zone, a distillation or retort zone, and a preheating zone for combustion air which also cools the ash from the combustion zone.
  • the retort includes the desirable feature of having an upward flow of shale and downward flow of gas and oil in the retort zone, but in the burning and ash cooling zone there is the desirable downward flow of shale and ash and an upward flow of air.
  • the retort includes a lower combustion zone, and an upper retort zone subject to the gases of combustion from the lower combustion zone to perform the pyrolysis and the distillation of shale oil.
  • the retort of the invention includes a simplified design wherein the interior walls of the retort may be made of fire brick in those parts which are subjected to high heat, and which may be constructed so that the depth of the beds of shale in the previous parts are not controlled by the size of the device but may be determined by the optimum operation of the retort.
  • the simplified design of the present invention provides means for distributing the weight of contained shale so that it is easily supported, and so that there is no substantial increase of friction of the shale on the supporting walls of the vessel or an increase of size of the retort.
  • a simplified retort design which may be constructed of various sizes and utilize fire brick in the high heat and other desired portions of the retort.
  • the weight of the shale in the various beds of the retort is distributed so that it may be adequately supported.
  • the design of the retort of the present invention permits the distribution of shale beds in the retort to provide optimum depth determined by the process and not by the size of the unit.
  • the retort of the invention is very effective and provides a highly eflicient process for economically performing destructive pyrolysis of shale.
  • the retort design permits the use of fire brick or equivalent for economic construction.
  • FIGURE 1 is a side elevational view in partial section showing the main elements of the retort of the invention
  • FIGURE 2 is a front elevational view of the raw shale feed mechanism and bed support for the shale retorting;
  • FIGURE 3 is a top plan view of the shale feeders and retor-t bed.
  • the retort of the invention may be described as an inverted U having one short inclined leg and one longer vertical leg.
  • the short inclined leg is arranged to hold a bed of shale for the retort zone, while the longer leg is utilized for the combustion zone and the ash cooling zone.
  • the retort zone which includes a bed of raw shale, provides an outer pyrolysis zone on the surface of the raw shale and a cooling zone through the mass of the raw shale which condenses and cools the oil produced by the pyrolysis.
  • the combustion zone likewise, includes several distinct subzones, one of which is combustion space above a mass of spent shale and one of which is on the surface of the spent shale mass which is a combustion zone for residual carbon remaining on the shale after pyrolysis, and another is a cooling zone in the spent shale mass below the combustion zone where air for the combustion is heated and the ash or remaining shale is cooled.
  • An oil lock is provided in the raw shale feeding zone to prevent blow back of the hot gases through the feed system and to prevent entrance of air into the retorting zone.
  • a retort is housed in a suitable building I mounted on suitable foundations or the like 2.
  • the retort which may be of any cross section or shape, but is preferably generally rectangular, includes an upright or combustion leg 3.
  • the leg 3 includes a lower conical section 4 and an upper arcuate roof 5 leaving a combustion space therebetween.
  • the walls of the upright leg 3 are preferably made of a refractory or fire brick, as is the roof 5. Inspection doors 6 may be provided in a retort wall for observing the operation of the device.
  • a pair of rotary ash crushers 7 are mounted in the throat 8 of the conical section 4, discharging through a chute 9 onto a pan conveyor 10, or other suitable ash removal means.
  • a plurality of screw feeders 14 arranged in tiers extend through the sloped wall 11, and provide shale feed from one side to the other of the Wall 11 and from top to bottom thereof. Such screw feeders are well known and detailed description is not believed necessary. As shown in FIGURE 2, there are three horizontal banks of the screw feeders 14 and six vertical banks providing a total of eighteen screw feeders.
  • the Wall 11 is perforated between the several chutes 35 to permit oil and gas flow through and into the gas chambers 15 and to effectively prevent passage of shale.
  • Gas chambers 15 interconnect the perforated wall and communicate with a manifold 16.
  • the manifold 16 collects gas and liquid passing through the Wall 11, and the mixture may then be passed through a gas and oil separator 17.
  • the treatment provides a countercurrent flow of gas and shale.
  • Oil or liquid which is separated out of the mixture drops through a feed nozzle 18 into a settling tank 19.
  • An oil production outlet 20 adjacent the top of the tank provides a discharge for the clarified oil produced.
  • Sludge, which settles out of the oil in tank 20 is conveyed by a screw conveyor 21 into an elevator shaft 22.
  • the elevator shaft 22 is connected to the tank 19 by conveyor 21 so that an oil level 23 may be maintained in the elevator at the same height as the oil level in the tank 19.
  • This oil in the shaft provides a seal through which raw shale must pass before being charged into the retort, thus efiectively 3 preventing the passing of air into the retort with the raw shale feed.
  • the wall 11 with its bottom support wall 12 is placed at an angle which is substantially equivalent to the angle of repose of crushed shale.
  • the width of wall 12 generally controls the thickness of the shale bed.
  • the angle of repose is that angle at which the shale particles on the surface of a pile of such shale slide down the pile. As shale is forced into the bed, the surface of the shale extends beyond the repose surface and so the surface particles must slide down the pile.
  • the angle of repose of the shale surface after pyrolysis is about 45
  • a bed of shale 38 of relatively uniform thickness may be maintained. Optimum efliciency of the operation is achieved by maintaining the bed 38 at a uniform thickness determined by the width of wall 12, and by feeding shale substantially uniformly across the extent of the under surface of the raw shale bed.
  • Crushed ore in a minus four inch size that is all to pass a'four inch opening, is fed from a crusher (not shown) into a hopper 30.
  • the hopper or ore bin 30 feeds onto an apron or other suitable feeder 31, which is provided with a variable speed drive for varying the feed rate into a chute 32 discharging into the elevator shaft 22.
  • the top of the chute 32 is above the oil level 23, but passage tothe elevator shaft is well below the oil level thus effecting an air seal.
  • the oil shale drops into the oil in the bottom of the elevator shaft 22, and an elevator, not shown but which may be any suitable type conveyor such as a bucket conveyor or the like, picks up the oil shale in the elevator shaft.
  • the shale is moved upwardly in the shaft, while preferably the shale is drained of excess oil, to the top where it drops over the top into a chute 33.
  • the chute 33 discharges into a shale distributor 34 which is a screw conveyor for uniformly distributing the shale from the elevator into feeder chutes 35 leading to the individual feed conveyors 14.
  • the elevator shaft 22, the distributors, and the feeders should be air-tight to prevent introducing air with shale.
  • Air for combustion is drawn into the retort by an induction fan, not shown, which draws the air through a pile of spent shale 41 in zone four.
  • the air, heated as it passes through the shale bed 41, is the air for burning carbon or the like on the shale in bed 41.
  • the products of combustion then pass through the shale bed 3 8, resting on walls 11 and 12, thus pyrolyzing the shale.
  • the fluid materials passing through raw shale bed 38 are drawn through the foraminous wall 11 into themanifold, and gases are separated from the oil and are ultimately discharged through an exhaust pipe 39 which leads to the fan (not shown).
  • the air must be heated to cause combustion, and an effective design requires the air to be heated to about 1390 F. before it enters the top layer of bed 41 for combustion.
  • Hot gases resulting from the combustion pass upwardly through chamber 3 and are directed through the raw shale bed 38.
  • the gases of combustion which are at a temperature of about 1650 F., heat the raw shale bed which in turn cools the gases and products of pyrolysis. This heating is sufficient to cause an efiiclent pyrolysis of the kerogen to form shale oil.
  • the resultant shale oil and gases pass through the bile of raw shale, thereby being cooled and condensing 4 the shale oil.
  • the cooled products are recovered at a temperature of 150 P. which is cool enough to insure optimum recovery of oil.
  • Spent shale slides from the surface of the bed 3 8 (being pushed by incoming shale) and falls on the bed 41.
  • a retort should preferably be able to retort about 1000 tons of shale per twentyfour hours.
  • the retort has a width of about 15 feet and a length of about 24 feet, with a height of about 36 feet from ash crusher to roof.
  • the shale throughout rate ranges from about to 300 pounds per hour per square foot of retort cross section, depending on the size of the raw shale fed to the retort.
  • oil shale contains about 2% surface moisture and the shale contains about 15% organic material in the form of kerogen, the following table shows the operational rates on an hourly basis.
  • Weight of mositure 1,670 (3) Weight of dry feed 81,730 (4) Weight of kerogerl in feed 15% of (3) 12,260 (5) Weight of inorganics feed (3)(4) 69,470 (6) Weight of CaO in feed 28% of (5 19,450 (7) Weight of CaCO equivalent to (6) 34,700
  • Retort yield (8) Shale oil 85% of (4) 7,970 (9) Shale gas 10% of (4) 1,225 (10) Carbonaceous residue 25% of (4) 3,065 Passing into combustion zone (11) CaCO (7) 34,700 (12) Silicious and metallics (5)(7) 34,770 (13) Total inorganics (5) 69,470 (14) Oarbouaceous resin (10) 3,065 (15) Total passing into combustion zone 72,535
  • the marlstone contains carbonates which decompose at the temperature of the burning zone, and the decomposition is endothermic so that in fully considering the material and heat balance of the retort, the decomposition of the carbonates must be taken into consideration.
  • average temperatures are considered in the operation of the retort, that is, the ambient temperature of air is taken at an average of 60 F., the shale feed temperature is taken at 60 F., and the temperature of the combustion zone is 1650" F.
  • the temperature of the gas leaving the retort through wall 11 is maintained at F. which is suflioient to condense the shale oil.
  • the optimum temperature of the ash discharge is about 800 E, which is controlled by the rate of ash discharge and the throughput rate of air through the bed 41.
  • the spent shale ffrorn the bed 38 onto the bed 41 is approximately 7
  • the wall 11 of FIGURE 1 for a 1000 ton per day retort, is about 13.7 feet wide by 23 feet long between the sidewalls, and wall 12 is about 5 feet so that the v j depth of the bed 38 may be maintained about 5 feet with a slope of about 45.
  • the approximate area of wall 11 is 300 square feet providing approximately 1500 cubic feet of retort bed.
  • a gas separator such as a cyclone separator
  • a gas separator may be installed in'the gas line leading from the manifold 16 so as to provide an eflicient separation of oil from the' oil-gas mixture passing from the bed 38.
  • a standard thickener may be used for separating sludge from oil.
  • an elevating device is shown having an oil seal to' prevent from entering the feeders, other types of devices for conveying shale to the feeders may be used, especially such devices in which it is possible to seal from the raw shale bed.
  • the screw feeders as illustrated provide a simple and economical means for feeding the bed 38,
  • ram feeders may also be used for feeding the bed.
  • the stream of gas through the beds is described as air induced draft from a suction fan, however, it may be a forced draft from the air inlet side.
  • a shale oil retort comprising an upright combustion chamber having means for supporting a bed of spent shale in its lower portion and having an air inlet at its bottom, means in the upper portion of said chamber for supporting a relatively shallow biased bed of raw shale of substantially uniform thickness, said shale bed supporting means comprising (1) a sloped foraminous rear wall defining the under surface of said raw shale bed and forming a common outlet for oil and eduction gases and (2) an intersecting support wall extending forwardly therefrom, said support wall being juxtaposed above the combustion chamber in position to permit shale to fall from the raw shale bed substantially centrally of said spent shale bed, means for feeding raw shale substantially uniformly into the entire under surface of said biased shale bed so as to push shale from the upper biased surface thereof, means for directing air through said inlet and through said spent shale bed for burning contained residual carbon and then directing the hot gases of combustion substantially uniformly through said biased raw shal
  • a shale oil retort comprising an upright combustion chamber of substantial vertical extent having means in its lower portion for supporting bed of spent shale and tion to permit shale to fall from'the raw shale bed substantially centrally of said spent shale bed, means for feeding raw shale into said raw shale bed substantially uniformly across the extent of said foraminous wall, means for sealing said raw shale feed to prevent the passage of air with fed shale into said bed of r-awshale on said foraminous Wall, means inclusive of at least one chamber below said foraminous Wall for inducing a draft of air through said bed of spent shale for combustion of contained residual carbon and then directing the re-- sultant gases of combustion substantially uniformly through said bed of raw shale from the upper to the lower surface thereof to cause a pyrolysis of the shale for oil recovery, and means for separately removing ash and oil from said chamber.
  • a shale oil retort comprising an upright combustion chamber of substantial vertical extent, having a combustion grate in the lower portion of said chamber arranged to support a substantial bed of spent shale and arranged to admit air for combustion through such a bed of spent shale, a biased foraminous Wall mounted in the upper portion of said chamber arranged to support a relatively shallow bed of raw shale of generally uniform thickness and arranged with the surface of such a bed dis bustion chamber, means for feeding raw shale substan-' tially uniformly across said foraminous wall into the lower surface of said raw shale bed, so as to'push shale through the bed and to cause shale to fall by gravity from the upper surface of said raw shale bed to substantially the middle of said spent shale bed, means for sealing said feed means to prevent entrance of air with raw shale feed, means for inducing a draft of air through said grate and said bed of spent shale for combustion of contained residual carbon
  • a shale oil retort as defined in claim 5 including means for mixing a portion of the eduction gases with the gases of combustion prior to directing said gases of combustion through said raw shale bed.
  • a process for the continuous retorting of oil shale for the pyrolysis of organic material contained therein which comprises maintaining a spent shale bed of substantial thickness in the lower portion of a combustion zone, maintaining a biased relatively shallow uniform depth raw shale bed in the upper portion of said combustion zone, the angle of the surface of said raw shale bed being maintained at the angle of repose of the shale under treatment, continuously feeding raw shale into the under surface of said raw shale bed uniformly throughout the extent thereof to thereby maintain a relatively uniform depth raw shale bed and to progressively move upper layers of said raw shale bed beyond the angle of repose whereby surface shale of said raw shale bed falls residual'carbon in the spent shale bed, drawing hot gases of combustion from said combustion zone substantially uniformly through said raw shale bed generally countercurrently to the raw shale feed to said raw shale bed to pyrolyze the organic material contained therein for oil recovery, removing oil and
  • a process for the continuous retorting of. oil shale for the pyrolysis of organic material contained therein which comprises maintaining a spent shale bed of substantial thickness in a lower portion of a combustion zone, maintaining a biased relatively shallow uniform depth raw shale bed in the upper portion of said combustion zone, the angle of the upper surface of said raw shale bed being maintained at the angle of repose of the shale under treatment, continuously'feeding raw shale substantially uniformly into the under surface of said raw shale bed throughout the extent thereof to thereby maintain a relatively uniform depth raw shale bed and to progressively move upper layers, of said raw shale bed beyond the angle of repose whereby exhausted shale slides along the raw shale bed surface and falls by gravity onto said spent shale bed, directing a stream of air through said spent shale bed to simultaneously cool the spent shale and to heat air for the combustion of residual carbon in said spent shale bed, drawing hot gases of combustion from said
  • a process for the continuous retorting of oil shale for the pyrolysis of organic material contained therein which comprises maintaining a relatively shallow biased uniform depth raw shale bed in the upper portion of the chamber subject to continuous feed throughout the extent of the lower surface thereof so as to push shale from the upper biased surface of said raw shale bed, the bed of raw'shale being maintained at a relatively uniform thickness and its upper surface being maintained at substantially the angle of repose of the shale under treatment, maintaining a spent shale bed in the lower portion of the chamber in position to receive shale falling from said raw shale bed, discharging ash from said spent shale bed at a rate to maintain -a uniform thickness thereof, directing a draft of air through said spent shale bed for combustion of residual carbon therein, whereby the air for combustion is heated on its passage through the spent shale, directing the gases from combustion and a portion of the hereinafter defined product gases substantially countercurrently to the raw shale

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  • Engineering & Computer Science (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
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  • Wood Science & Technology (AREA)
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Description

Oct. 31, 1961 J. H. v. FINNEY on. SHALE RETORT AND METHOD 2 Sheets-Sheet 1 Filed Dec. 13. 1957 ATTORN EYS Oct. 31, 1961 J. H. v. FINNEY OIL SHALE RETORT AND METHOD 2 Sheets-Sheet 2 Filed Dec. 13. 1957 INVENTOR. 1 JOHN HMFlNNEY F|G.3. BY
vATTORNEYS United States Patent Office I 3,006,816 Patented Oct. 31, 1961 3,006,816 OIL SHALE RETORT AND METHOD John H. V. Finney, Longmont, Colo., assignor to Union 011 Company of California, Los Angeles, Calif., a corporation of California Filed Dec. 13, 1957, Ser. No. 702,571 Claims. (Cl. 202-7) This invention relates to apparatus and methods for the destruction pyrolysis of oil bearing shale.
There are vast deposits of a raw material called oil shale in the western part of the United States, principally in the States of Colorado, Wyoming and Utah. This raw material, which is not a shale but a marl stone, contains organic material in amounts from a trace to over 30% by weight, and generally a commercial deposit should average between 10.5 to 80 gallons of derived shale oil per ton of ore. The organic matter in Colorado oil shale is sometimes called kerogen, which is a high molecular weight substance of largely unknown structure. It is from this complex organic substance that a liquid hydrocarbon mixture, called shale oil, is formed by a pyrolysis. While the shale oil industry antedates production from oil wells by about twenty years, it has not become a commercial process in recent years due to the economy involved. Many designs have been suggested for retorts for performing the pyrolysis of shale oil, but to date none have been commercialized.
According to the present invention, there is provided a retort which includes essentialy three zones, that is, a combustion zone, a distillation or retort zone, and a preheating zone for combustion air which also cools the ash from the combustion zone. The retort includes the desirable feature of having an upward flow of shale and downward flow of gas and oil in the retort zone, but in the burning and ash cooling zone there is the desirable downward flow of shale and ash and an upward flow of air. The retort includes a lower combustion zone, and an upper retort zone subject to the gases of combustion from the lower combustion zone to perform the pyrolysis and the distillation of shale oil. The retort of the invention includes a simplified design wherein the interior walls of the retort may be made of fire brick in those parts which are subjected to high heat, and which may be constructed so that the depth of the beds of shale in the previous parts are not controlled by the size of the device but may be determined by the optimum operation of the retort. The simplified design of the present invention provides means for distributing the weight of contained shale so that it is easily supported, and so that there is no substantial increase of friction of the shale on the supporting walls of the vessel or an increase of size of the retort.
Included among the objects and advantages of the present invention is a simplified retort design which may be constructed of various sizes and utilize fire brick in the high heat and other desired portions of the retort. The weight of the shale in the various beds of the retort is distributed so that it may be adequately supported. The design of the retort of the present invention permits the distribution of shale beds in the retort to provide optimum depth determined by the process and not by the size of the unit. Further, the retort of the invention is very effective and provides a highly eflicient process for economically performing destructive pyrolysis of shale.
The retort design permits the use of fire brick or equivalent for economic construction.
These and other objects and advantages of the invention may be readily ascertained by referring to the following description and appended illustration, in which:
FIGURE 1 is a side elevational view in partial section showing the main elements of the retort of the invention;
FIGURE 2 is a front elevational view of the raw shale feed mechanism and bed support for the shale retorting; and
FIGURE 3 is a top plan view of the shale feeders and retor-t bed.
Generally, the retort of the invention may be described as an inverted U having one short inclined leg and one longer vertical leg. The short inclined leg is arranged to hold a bed of shale for the retort zone, while the longer leg is utilized for the combustion zone and the ash cooling zone. The retort zone, which includes a bed of raw shale, provides an outer pyrolysis zone on the surface of the raw shale and a cooling zone through the mass of the raw shale which condenses and cools the oil produced by the pyrolysis. The combustion zone, likewise, includes several distinct subzones, one of which is combustion space above a mass of spent shale and one of which is on the surface of the spent shale mass which is a combustion zone for residual carbon remaining on the shale after pyrolysis, and another is a cooling zone in the spent shale mass below the combustion zone where air for the combustion is heated and the ash or remaining shale is cooled. An oil lock is provided in the raw shale feeding zone to prevent blow back of the hot gases through the feed system and to prevent entrance of air into the retorting zone.
In the device illustrated in the drawings, a retort is housed in a suitable building I mounted on suitable foundations or the like 2. The retort, which may be of any cross section or shape, but is preferably generally rectangular, includes an upright or combustion leg 3. The leg 3 includes a lower conical section 4 and an upper arcuate roof 5 leaving a combustion space therebetween. The walls of the upright leg 3 are preferably made of a refractory or fire brick, as is the roof 5. Inspection doors 6 may be provided in a retort wall for observing the operation of the device. A pair of rotary ash crushers 7 are mounted in the throat 8 of the conical section 4, discharging through a chute 9 onto a pan conveyor 10, or other suitable ash removal means. A sloping, foraminous wall 11, having a bottom support Wall 12 mounted substantialy at right angles or at a slight angle thereto, interconnects the left side of the roof 5 with the left upright wall of the chamber 3. End walls 27 complete the retort.
A plurality of screw feeders 14 arranged in tiers extend through the sloped wall 11, and provide shale feed from one side to the other of the Wall 11 and from top to bottom thereof. Such screw feeders are well known and detailed description is not believed necessary. As shown in FIGURE 2, there are three horizontal banks of the screw feeders 14 and six vertical banks providing a total of eighteen screw feeders. The Wall 11 is perforated between the several chutes 35 to permit oil and gas flow through and into the gas chambers 15 and to effectively prevent passage of shale. Gas chambers 15 interconnect the perforated wall and communicate with a manifold 16. The manifold 16 collects gas and liquid passing through the Wall 11, and the mixture may then be passed through a gas and oil separator 17. The treatment provides a countercurrent flow of gas and shale. Oil or liquid which is separated out of the mixture drops through a feed nozzle 18 into a settling tank 19. An oil production outlet 20 adjacent the top of the tank provides a discharge for the clarified oil produced. Sludge, which settles out of the oil in tank 20, is conveyed by a screw conveyor 21 into an elevator shaft 22. The elevator shaft 22 is connected to the tank 19 by conveyor 21 so that an oil level 23 may be maintained in the elevator at the same height as the oil level in the tank 19. This oil in the shaft provides a seal through which raw shale must pass before being charged into the retort, thus efiectively 3 preventing the passing of air into the retort with the raw shale feed.
The wall 11 with its bottom support wall 12 is placed at an angle which is substantially equivalent to the angle of repose of crushed shale. The width of wall 12 generally controls the thickness of the shale bed. The angle of repose, for purposes of this specification, is that angle at which the shale particles on the surface of a pile of such shale slide down the pile. As shale is forced into the bed, the surface of the shale extends beyond the repose surface and so the surface particles must slide down the pile. The angle of repose of the shale surface after pyrolysis is about 45 By sloping the wall 11 at about'45, a bed of shale 38 of relatively uniform thickness may be maintained. Optimum efliciency of the operation is achieved by maintaining the bed 38 at a uniform thickness determined by the width of wall 12, and by feeding shale substantially uniformly across the extent of the under surface of the raw shale bed.
Crushed ore in a minus four inch size, that is all to pass a'four inch opening, is fed from a crusher (not shown) into a hopper 30. The hopper or ore bin 30 feeds onto an apron or other suitable feeder 31, which is provided with a variable speed drive for varying the feed rate into a chute 32 discharging into the elevator shaft 22. The top of the chute 32 is above the oil level 23, but passage tothe elevator shaft is well below the oil level thus effecting an air seal. The oil shale drops into the oil in the bottom of the elevator shaft 22, and an elevator, not shown but which may be any suitable type conveyor such as a bucket conveyor or the like, picks up the oil shale in the elevator shaft. The shale is moved upwardly in the shaft, while preferably the shale is drained of excess oil, to the top where it drops over the top into a chute 33. The chute 33 discharges into a shale distributor 34 which is a screw conveyor for uniformly distributing the shale from the elevator into feeder chutes 35 leading to the individual feed conveyors 14. The elevator shaft 22, the distributors, and the feeders should be air-tight to prevent introducing air with shale.
Air for combustion is drawn into the retort by an induction fan, not shown, which draws the air through a pile of spent shale 41 in zone four. The air, heated as it passes through the shale bed 41, is the air for burning carbon or the like on the shale in bed 41. The products of combustion then pass through the shale bed 3 8, resting on walls 11 and 12, thus pyrolyzing the shale. The fluid materials passing through raw shale bed 38 are drawn through the foraminous wall 11 into themanifold, and gases are separated from the oil and are ultimately discharged through an exhaust pipe 39 which leads to the fan (not shown). As air is drawn into the bottom of the retort, which may be through a chamber 40 or through the grate 7, it. passes up through the ash 41 (the residue after burning residual carbon on the shale). The pile of ash not only heats the air but the air cools the ash. The air coolsthe ash sufiiciently so that it is discharged at a temperature of about 800 F. The incoming air is simultaneously heated sufiiciently to cause burning of the residual carbon or organic matter remaining on the spent shale falling from bed 38. The spent shale from the pyrolysis is low grade fuel on the order of 500600 B.t.u. per pound. The air must be heated to cause combustion, and an effective design requires the air to be heated to about 1390 F. before it enters the top layer of bed 41 for combustion. Hot gases resulting from the combustion pass upwardly through chamber 3 and are directed through the raw shale bed 38. The gases of combustion, which are at a temperature of about 1650 F., heat the raw shale bed which in turn cools the gases and products of pyrolysis. This heating is sufficient to cause an efiiclent pyrolysis of the kerogen to form shale oil. The resultant shale oil and gases pass through the bile of raw shale, thereby being cooled and condensing 4 the shale oil. The cooled products are recovered at a temperature of 150 P. which is cool enough to insure optimum recovery of oil. Spent shale slides from the surface of the bed 3 8 (being pushed by incoming shale) and falls on the bed 41.
For a commercial operation a retort should preferably be able to retort about 1000 tons of shale per twentyfour hours. For such an operation, the retort has a width of about 15 feet and a length of about 24 feet, with a height of about 36 feet from ash crusher to roof. Using shale which produces not less than about 25 gallons of oil per ton, the shale throughout rate ranges from about to 300 pounds per hour per square foot of retort cross section, depending on the size of the raw shale fed to the retort. Estimating that oil shale contains about 2% surface moisture and the shale contains about 15% organic material in the form of kerogen, the following table shows the operational rates on an hourly basis.
Quantities-hourly rates Lbs/hr. (1) Weight of wet feed 1,000 tons/day 83,400
(2) Weight of mositure 1,670 (3) Weight of dry feed 81,730 (4) Weight of kerogerl in feed 15% of (3) 12,260 (5) Weight of inorganics feed (3)(4) 69,470 (6) Weight of CaO in feed 28% of (5 19,450 (7) Weight of CaCO equivalent to (6) 34,700
Retort yield (8) Shale oil 85% of (4) 7,970 (9) Shale gas 10% of (4) 1,225 (10) Carbonaceous residue 25% of (4) 3,065 Passing into combustion zone (11) CaCO (7) 34,700 (12) Silicious and metallics (5)(7) 34,770 (13) Total inorganics (5) 69,470 (14) Oarbouaceous resin (10) 3,065 (15) Total passing into combustion zone 72,535
Combustion (16) Carbon burnedassume 85% of (14) 2,600 (17) Carbon unburned-15% of (14) 465 Carbon burns as per chemical reastion:
C+O :CO
-Mol Wts.: 12+32 =44. (-18) Wts. reacting: 2,600+6,930=9,530 lbs./hr.
But air is used for oxygen: Air-=23% O+77% N. (19) Air required=30,l30 lbs./hr.; air-=6,930
oxygen-[43,200 nitrogen. Note.Item (8) is equivalent to 587 barrels/2'4 hr. day.
The marlstone contains carbonates which decompose at the temperature of the burning zone, and the decomposition is endothermic so that in fully considering the material and heat balance of the retort, the decomposition of the carbonates must be taken into consideration.
In providing a typical operation as shown in the table, average temperatures are considered in the operation of the retort, that is, the ambient temperature of air is taken at an average of 60 F., the shale feed temperature is taken at 60 F., and the temperature of the combustion zone is 1650" F. The temperature of the gas leaving the retort through wall 11 is maintained at F. which is suflioient to condense the shale oil. The optimum temperature of the ash discharge is about 800 E, which is controlled by the rate of ash discharge and the throughput rate of air through the bed 41. The spent shale ffrorn the bed 38 onto the bed 41 is approximately 7 The wall 11 of FIGURE 1, for a 1000 ton per day retort, is about 13.7 feet wide by 23 feet long between the sidewalls, and wall 12 is about 5 feet so that the v j depth of the bed 38 may be maintained about 5 feet with a slope of about 45. The approximate area of wall 11 is 300 square feet providing approximately 1500 cubic feet of retort bed.
Since the shale is crushed to about four inch lumps, a twenty inch diameter screw is required for effective feeding. The feeders 14, mounted in three banks of six, effectively cover the area, and these eighteen screw feeders satisfy the requirement of uniformly feeding the entire area of the bed 38. Each of the screw feeders requires about a one horsepower motor. Other types of feeders may require different power consumption. The size of the burning zone on bed .41, assuming that the carbon residue on the spent shale may be burnt at the rate vof about twenty pounds of carbon per hour per square foot, requires about 153 square feet of area, taking into account the slope of the bed. 1
Where desired, a gas separator,'such as a cyclone separator, may be installed in'the gas line leading from the manifold 16 so as to provide an eflicient separation of oil from the' oil-gas mixture passing from the bed 38. Also, place of settling tank 19, a standard thickener may be used for separating sludge from oil. While an elevating device is shown having an oil seal to' prevent from entering the feeders, other types of devices for conveying shale to the feeders may be used, especially such devices in which it is possible to seal from the raw shale bed. The screw feeders as illustrated provide a simple and economical means for feeding the bed 38,
however, ram feeders may also be used for feeding the bed. In certain instances, it may be desirable to recycle some of the separated gases into the combustion zone, and this may be easily accomplished by passing a portion of the gas into the duct 40. In the operation of the retort the stream of gas through the beds is described as air induced draft from a suction fan, however, it may be a forced draft from the air inlet side.
- While the invention has been illustrated by reference to a specific device, there is no intent to limit the spirit and scope of the invent-ion to the precise details so set forth, except insofar as defined in the appended claims.
. I claim:
1. A shale oil retort comprising an upright combustion chamber having means for supporting a bed of spent shale in its lower portion and having an air inlet at its bottom, means in the upper portion of said chamber for supporting a relatively shallow biased bed of raw shale of substantially uniform thickness, said shale bed supporting means comprising (1) a sloped foraminous rear wall defining the under surface of said raw shale bed and forming a common outlet for oil and eduction gases and (2) an intersecting support wall extending forwardly therefrom, said support wall being juxtaposed above the combustion chamber in position to permit shale to fall from the raw shale bed substantially centrally of said spent shale bed, means for feeding raw shale substantially uniformly into the entire under surface of said biased shale bed so as to push shale from the upper biased surface thereof, means for directing air through said inlet and through said spent shale bed for burning contained residual carbon and then directing the hot gases of combustion substantially uniformly through said biased raw shale bed generally countercurrently to the shale feed so as to cause a pyrolysis of the shale for oil recovery, and means for discharging ash and oil separately from said chamber.
2. A shale oil retort as defined in claim I wherein said means for feeding raw shale comprises a plurality of feeders.
3. A shale oil retort as defined in claim 1 wherein said means for feeding raw shale includes an air seal to prevent the induction of air with the raw shale feed.
4. A shale oil retort comprising an upright combustion chamber of substantial vertical extent having means in its lower portion for supporting bed of spent shale and tion to permit shale to fall from'the raw shale bed substantially centrally of said spent shale bed, means for feeding raw shale into said raw shale bed substantially uniformly across the extent of said foraminous wall, means for sealing said raw shale feed to prevent the passage of air with fed shale into said bed of r-awshale on said foraminous Wall, means inclusive of at least one chamber below said foraminous Wall for inducing a draft of air through said bed of spent shale for combustion of contained residual carbon and then directing the re-- sultant gases of combustion substantially uniformly through said bed of raw shale from the upper to the lower surface thereof to cause a pyrolysis of the shale for oil recovery, and means for separately removing ash and oil from said chamber.
5. A shale oil retort comprising an upright combustion chamber of substantial vertical extent, having a combustion grate in the lower portion of said chamber arranged to support a substantial bed of spent shale and arranged to admit air for combustion through such a bed of spent shale, a biased foraminous Wall mounted in the upper portion of said chamber arranged to support a relatively shallow bed of raw shale of generally uniform thickness and arranged with the surface of such a bed dis bustion chamber, means for feeding raw shale substan-' tially uniformly across said foraminous wall into the lower surface of said raw shale bed, so as to'push shale through the bed and to cause shale to fall by gravity from the upper surface of said raw shale bed to substantially the middle of said spent shale bed, means for sealing said feed means to prevent entrance of air with raw shale feed, means for inducing a draft of air through said grate and said bed of spent shale for combustion of contained residual carbon and then directing the resultant gases of combustion substantially uniformly counter-currently through said bed of raw shale from the upper to the lower surface thereof, means associated with said draft inducing means for separating oil and eduction gas, means for recovery of separated oil, and means for removing ash from said bed of spent shale.
6. A shale oil retort as defined in claim 5 wherein said means for feeding raw shale comprises a plurality of feeders.
7. A shale oil retort as defined in claim 5 including means for mixing a portion of the eduction gases with the gases of combustion prior to directing said gases of combustion through said raw shale bed.
8. A process for the continuous retorting of oil shale for the pyrolysis of organic material contained therein which comprises maintaining a spent shale bed of substantial thickness in the lower portion of a combustion zone, maintaining a biased relatively shallow uniform depth raw shale bed in the upper portion of said combustion zone, the angle of the surface of said raw shale bed being maintained at the angle of repose of the shale under treatment, continuously feeding raw shale into the under surface of said raw shale bed uniformly throughout the extent thereof to thereby maintain a relatively uniform depth raw shale bed and to progressively move upper layers of said raw shale bed beyond the angle of repose whereby surface shale of said raw shale bed falls residual'carbon in the spent shale bed, drawing hot gases of combustion from said combustion zone substantially uniformly through said raw shale bed generally countercurrently to the raw shale feed to said raw shale bed to pyrolyze the organic material contained therein for oil recovery, removing oil and eduction gases from said raw shale bed through the same outlets, said outlets distributed substantially coextensively over the under surface of said raw shale bed, removing the recovered oil from the treatment, and removing ash from the bottom of said spent shale bed at a rate sufiicient to maintain a desired depth therein.
V 9. A process for the continuous retorting of. oil shale for the pyrolysis of organic material contained therein which comprises maintaining a spent shale bed of substantial thickness in a lower portion of a combustion zone, maintaining a biased relatively shallow uniform depth raw shale bed in the upper portion of said combustion zone, the angle of the upper surface of said raw shale bed being maintained at the angle of repose of the shale under treatment, continuously'feeding raw shale substantially uniformly into the under surface of said raw shale bed throughout the extent thereof to thereby maintain a relatively uniform depth raw shale bed and to progressively move upper layers, of said raw shale bed beyond the angle of repose whereby exhausted shale slides along the raw shale bed surface and falls by gravity onto said spent shale bed, directing a stream of air through said spent shale bed to simultaneously cool the spent shale and to heat air for the combustion of residual carbon in said spent shale bed, drawing hot gases of combustion from said combustion zone generaly countercurrently to the feed thereto to pyrolyze the organic material contained therein for oil recovery, removing oil and,
eduction gases from said raw shale bed through the same outlets, said outlets distributed substantially coextensively over the under surface of said raw shale bed, separating resulting oil from the gas, and continuously removing ash from the bottom of said spent shale bed at a rate suificient to maintain a desired depth therein.
10. A process for the continuous retorting of oil shale for the pyrolysis of organic material contained therein which comprises maintaining a relatively shallow biased uniform depth raw shale bed in the upper portion of the chamber subject to continuous feed throughout the extent of the lower surface thereof so as to push shale from the upper biased surface of said raw shale bed, the bed of raw'shale being maintained at a relatively uniform thickness and its upper surface being maintained at substantially the angle of repose of the shale under treatment, maintaining a spent shale bed in the lower portion of the chamber in position to receive shale falling from said raw shale bed, discharging ash from said spent shale bed at a rate to maintain -a uniform thickness thereof, directing a draft of air through said spent shale bed for combustion of residual carbon therein, whereby the air for combustion is heated on its passage through the spent shale, directing the gases from combustion and a portion of the hereinafter defined product gases substantially countercurrently to the raw shale feed to said raw shale bed so, as to pyrolyze the organic material in said raw shale bed and to simultaneously cool resultant product gases and condense resultant oil products on passage through said raw shale bed, removing said condensed oil products and said cool gasm from said raw shale bed through the same outlets, said outlets distributed substantially coextensively over the under surface of said raw shale bed, and separating oil from the gas-oil mixture passing through said raw shale bed.
References Cited in the file of this patent UNITED STATES PATENTS Petroleum Processing, Shale and Air Counter-Flow in New Continuous Retort, December 1948, page 1188.

Claims (1)

  1. 8. A PROCESS FOR THE CONTINUOUS RETORTING OF OIL SHALE FOR THE PYROLYSIS OF ORGANIC MATERIAL CONTAINED THEREIN WHICH COMPRISES MAINTAINING A SPENT SHALE BED OF SUBSTANTIAL THICKNESS IN THE LOWER PORTION OF A COMBUSTION ZONE, MAINTAINING A BIASED RELATIVELY SHALLOW UNIFORM DEPTH RAW SHALE BED IN THE UPPER PORTION OF SAID COMBUSTION ZONE, THE ANGLE OF THE SURFACE OF SAID RAW SHALE BED BEING MAINTAINED AT THE ANGLE OF REPOSE OF THE SHALE UNDER TREATMENT, CONTINUOUSLY FEEDING RAW SHALE INTO THE UNDER SURFACE OF SAID RAW SHALE BED UNIFORMLY THROUGHOUT THE EXTENT THEREOF TO THEREBY MAINTAIN A RELATIVELY UNIFORM DEPTH RAW SHALE BED AND TO PROGRESSIVELY MOVE UPPER LAYERS OF SAID RAW SHALE BED BEYOND THE ANGLE OF REPOSE WHEREBY SURFACE SHALE OF SAID RAW SHALE BED FALLS BY GRAVITY ONTO SAID SPENT SHALE BED, DIRECTING A STREAM OF AIR THROUGH SAID SPENT SHALE BED TO SIMULTANEOUSLY COOL THE SPENT SHALE AND TO HEAT AIR FOR THE COMBUSTION OF RESIDUAL CARBON IN THE SPENT SHALE BED, DRAWING HOT GASES OF COMBUSTION FROM SAID COMBUSTION ZONE SUBSTANTIALLY UNIFORMLY THROUGH SAID RAW SHALE BED GENERALLY COUNTERCURRENTLY TO THE RAW SHALE FEED TO SAID RAW SHALE BED TO PYROLYZE THE ORGANIC MATERIAL CONTAINED THEREIN FOR OIL
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3536590A (en) * 1965-03-15 1970-10-27 Nippon Steel Corp Annular coke oven chamber with rotatable top charging hood and rotatable and movable coke discharge conveyor means
US4003797A (en) * 1976-05-05 1977-01-18 Union Oil Company Of California Superatmospheric pressure shale retorting process
US4004982A (en) * 1976-05-05 1977-01-25 Union Oil Company Of California Superatmospheric pressure shale retorting process
US20110065057A1 (en) * 2009-09-17 2011-03-17 Petrocoque S/A Industria E Comercio Supply means of a rotating furnace used for calcination of oil green coke

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1639390A (en) * 1925-05-18 1927-08-16 George W Wallace Carbonizing apparatus
US2531998A (en) * 1945-09-20 1950-11-28 George W Wallace Carbonization apparatus
US2536365A (en) * 1948-07-31 1951-01-02 New Jersey Zinc Co Autogenous coking of agglomerates of zinciferous and carbonaceous materials
US2689787A (en) * 1948-12-18 1954-09-21 Standard Oil Dev Co Volatile fuel production and apparatus therefor

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1639390A (en) * 1925-05-18 1927-08-16 George W Wallace Carbonizing apparatus
US2531998A (en) * 1945-09-20 1950-11-28 George W Wallace Carbonization apparatus
US2536365A (en) * 1948-07-31 1951-01-02 New Jersey Zinc Co Autogenous coking of agglomerates of zinciferous and carbonaceous materials
US2689787A (en) * 1948-12-18 1954-09-21 Standard Oil Dev Co Volatile fuel production and apparatus therefor

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3536590A (en) * 1965-03-15 1970-10-27 Nippon Steel Corp Annular coke oven chamber with rotatable top charging hood and rotatable and movable coke discharge conveyor means
US4003797A (en) * 1976-05-05 1977-01-18 Union Oil Company Of California Superatmospheric pressure shale retorting process
US4004982A (en) * 1976-05-05 1977-01-25 Union Oil Company Of California Superatmospheric pressure shale retorting process
US20110065057A1 (en) * 2009-09-17 2011-03-17 Petrocoque S/A Industria E Comercio Supply means of a rotating furnace used for calcination of oil green coke
US8932050B2 (en) * 2009-09-17 2015-01-13 Petrocoque S/A Indústria e Comércio Supply means of a rotating furnace used for calcination of oil green coke

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