Abrégé

A homogeneous charge continuous oxidation system for generating heat can include a fuel gas source, an oxygen source, and a carbon dioxide source. The oxygen source can include oxygen gas that is substantially free of nitrogen or that contains nitrogen in an amount less than 10 vol %. The system can also include an oxidation chamber including an oxidation product outlet and at least one inlet connected to the fuel gas source, the oxygen source, and the carbon dioxide source to receive a gas mixture of fuel gas, oxygen, and carbon dioxide. A body of porous material can be within the oxidation chamber and positioned in a flow path of the gas mixture between the at least one inlet and the oxidation product outlet such that oxidation occurs within the body of porous material.

Classes IPC  ?

• F23C 99/00 - Matière non prévue dans les autres groupes de la présente sous-classe

Abrégé

A homogeneous charge continuous oxidation system (100) for generating heat can include a fuel gas source (110), an oxygen source (120), and a carbon dioxide source (130). The oxygen source (120) can include oxygen gas that is substantially free of nitrogen or that contains nitrogen in an amount less than 10 vol%. The system (100) can also include an oxidation chamber (140) including an oxidation product outlet (142) and at least one inlet (144,146,148) connected to the fuel gas source, the oxygen source, and the carbon dioxide source to receive a gas mixture of fuel gas, oxygen, and carbon dioxide. A body of porous material (150) can be within the oxidation chamber (140) and positioned in a flow path of the gas mixture between the at least one inlet (144,146,148) and the oxidation product outlet (142) such that oxidation occurs within the body of porous material (150).

Classes IPC  ?

• B01J 6/00 - CalcinationCuisson
• B01J 19/00 - Procédés chimiques, physiques ou physico-chimiques en généralAppareils appropriés
• C10B 49/02 - Distillation destructive des matières carbonées solides par chauffage direct au moyen d'agents porteurs de chaleur, y compris la combustion partielle de la matière à traiter avec des gaz ou des vapeurs à haute température, p. ex. les gaz chauds obtenus par la combustion partielle de la charge

Abrégé

A method (100) of producing commercially pure carbon dioxide can include providing (110) a body of rubblized carbon based ore. The body of rubblized carbon based ore can be heated (120) at an elevated temperature under an oxygen deficient atmosphere to produce water, carbon dioxide, a residual mineral ore, and optionally hydrocarbon products. The carbon dioxide can be separated (130) from the water and optional hydrocarbon products. The carbon based ore can include oil shale, coal, tar sands, peat, tasmanite, or a combination thereof.

Classes IPC  ?

• C01B 32/50 - Anhydride carbonique
• B01D 53/62 - Oxydes de carbone
• B01D 53/34 - Épuration chimique ou biologique des gaz résiduaires
• B01D 53/14 - Séparation de gaz ou de vapeursRécupération de vapeurs de solvants volatils dans les gazÉpuration chimique ou biologique des gaz résiduaires, p. ex. gaz d'échappement des moteurs à combustion, fumées, vapeurs, gaz de combustion ou aérosols par absorption

Abrégé

A method of recovering rare earth elements and other trace metals from based ores can include providing a body of rubblized carbon-based ore. The rubblized carbon-based ore can include carbonates and rare earth elements. The carbonates in the ore can be decomposed at an elevated decomposition temperature and an oxygen deficient atmosphere to form an enriched spent ore and carbon dioxide.

Classes IPC  ?

• C22B 3/42 - Traitement ou purification de solutions, p. ex. de solutions obtenues par lixiviation par extraction utilisant l'échange d'ions
• C22B 3/04 - Extraction de composés métalliques par voie humide à partir de minerais ou de concentrés par lixiviation
• C22B 5/04 - Procédés généraux de réduction appliqués aux métaux par voie sèche par l'aluminium, d'autres métaux ou le silicium
• C22B 5/12 - Procédés généraux de réduction appliqués aux métaux par voie sèche par des gaz
• C22B 9/16 - Refusion des métaux
• C22B 3/22 - Traitement ou purification de solutions, p. ex. de solutions obtenues par lixiviation par des procédés physiques, p. ex. par filtration, par des moyens magnétiques
• C22B 59/00 - Obtention des métaux des terres rares

Abrégé

A method of continuously recovering hydrocarbons from carbon ores, comprising: providing a first vessel and a second vessel containing rubblized carbon ore; introducing a cooling fuel gas into the first vessel; consuming the oxygen through oxidation in an oxidation zone at an oxidation temperature in the first vessel; controlling the oxidation temperature of the oxidation zone; heating rubblized carbon ore in a pyrolysis zone using the hot oxidation product gas, producing gaseous and vapor hydrocarbon pyrolysis products and a heated pyrolyze carbon ore; condensing the vapor hydrocarbon pyrolysis products on rubblized carbon ore in a condensing zone downstream of the pyrolysis zone; collecting the condensed hydrocarbon pyrolysis products; and recycling remaining gaseous hydrocarbons and oxidation products from the gas outlet of the second vessel as the recycle gas; wherein the oxidation zone and pyrolysis zone continuously move through the rubblized carbon ore in a downstream direction.

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• B01D 3/14 - Distillation fractionnée
• C10G 9/36 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures par contact direct avec des fluides inertes préchauffés, p. ex. avec des métaux ou sels fondus avec des gaz ou vapeurs chauds
• E21B 43/247 - Combustion sur place en association avec des procédés de fracturation

Abrégé

A method of continuously recovering hydrocarbons from carbon ores can include providing first and second vessels containing rubblized carbon ore. A cooling fuel gas can be introduced into the first vessel. The cooling fuel gas can include oxygen and a recycle gas from the second vessel, which includes hydrocarbons and oxidation products. The oxygen can be consumed through oxidation in an oxidation zone in the first vessel. The temperature of the oxidation zone can be controlled by limiting the oxygen concentration in the cooling fuel gas. This can produce a hot oxidation product gas that heats rubblized carbon ore in a pyrolysis zone downstream of the oxidation zone. Gaseous and vapor hydrocarbons can be produced in the pyrolysis zone. The vapor hydrocarbons can be condensed in a condensing zone downstream of the pyrolysis zone and then collected. The remaining gaseous hydrocarbons and oxidation products can be recycled as the recycle gas. The oxidation zone and the pyrolysis zone can continuously move through the rubblized carbon ore in a downstream direction. Optionally, by using nitrogen free oxygen for the oxidation, a nitrogen free stream of carbon dioxide is produced suitable for carbon dioxide capture and management. This can also eliminate the production of NOx in the oxidation process.

Classes IPC  ?

• C10B 57/04 - Autres procédés de carbonisation ou de cokéfactionCaractéristiques générales des procédés de distillation destructive utilisant des charges de composition spéciale
• B01J 19/00 - Procédés chimiques, physiques ou physico-chimiques en généralAppareils appropriés
• C10B 57/14 - Caractéristiques des procédés de carbonisation à basse température

Abrégé

Recovering hydrocarbons from oil shale can include injecting a heated working fluid into a first vessel containing particulate oil shale in a pyrolysis mode. The heated working fluid can have a temperature above a production temperature to pyrolyze kerogen in a stationary bed of the oil shale at or above the production temperature. An effluent can concurrently flow out of the first vessel to be injected into a second vessel in preheating mode. The second vessel containing particulate oil shale has an average temperature below the production temperature so as to capture heat from the effluent sufficient to increase the average temperature of the particulate oil shale and to condense condensable hydrocarbon product while also removing entrained mineral fines mists of condensed hydrocarbons from the effluent. Liquid hydrocarbons can concurrently be collected from the first vessel and/or the second vessel.

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation

Abrégé

Recovering hydrocarbons (100) from oil shale can include injecting (110) a heated working fluid into a first vessel containing particulate oil shale in a pyrolysis mode. The heated working fluid can have a temperature above a production temperature to pyrolyze kerogen in a stationary bed of the oil shale at or above the production temperature. An effluent can concurrently flow (120) out of the first vessel to be injected into a second vessel in preheating mode. The second vessel containing particulate oil shale has an average temperature below the production temperature so as to capture heat from the effluent sufficient to increase the average temperature of the particulate oil shale and to condense condensable hydrocarbon product while also removing entrained mineral fines mists of condensed hydrocarbons from the effluent. Liquid hydrocarbons can be concurrently collected (130) from the first vessel and/or the second vessel.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• C10G 9/26 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures avec des matériaux solides fixes préchauffés en discontinu, p. ex. vent et tirage
• C10G 9/02 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures dans des cornues
• C10G 9/36 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures par contact direct avec des fluides inertes préchauffés, p. ex. avec des métaux ou sels fondus avec des gaz ou vapeurs chauds
• C10G 9/38 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures par contact direct avec des fluides inertes préchauffés, p. ex. avec des métaux ou sels fondus avec des gaz ou vapeurs chauds produits par la combustion partielle de la matière à craquer ou par la combustion d'un autre hydrocarbure

Produits et services

Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, carbon capture for others using in-ground sequestration and sequestration in spent shale Mining extraction services for the recovery of oil and related products from hydrocarbon deposits, namely, oil shale, tar sands, coal, peat, plastics, and biomass; Land reclamation; Mining extraction for the production of crude oil, kerogen hydrocarbon residues, plastics, and biomass; Mining extraction for the production of crude oil, kerogen and hydrocarbon residues Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, transmission of captured carbon dioxide by means of trucking and pipeline for others; Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, physical storage of captured carbon dioxide for others Engineering, namely, mining engineering using clean technology to produce oil from oil shale and CO2 produced from oil production sequestered with enhanced oil recovery (EOR) in nearby conventional oil fields; Engineering, namely, mining engineering services for simultaneous recovery of rare earth elements from oil shale projects

Produits et services

Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, carbon capture for others using in-ground sequestration and sequestration in spent shale Mining extraction services for the recovery of oil and related products from hydrocarbon deposits, namely, oil shale, tar sands, coal, peat, plastics, and biomass; Land reclamation; Mining extraction for the production of crude oil, kerogen hydrocarbon residues, plastics, and biomass; Mining extraction for the production of crude oil, kerogen and hydrocarbon residues Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, transmission of captured carbon dioxide by means of trucking and pipeline for others; Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, physical storage of captured carbon dioxide for others Engineering, namely, mining engineering using clean technology to produce oil from oil shale and CO2 produced from oil production sequestered with enhanced oil recovery (EOR) in nearby conventional oil fields; Engineering, namely, mining engineering services for simultaneous recovery of rare earth elements from oil shale projects

Produits et services

Mining extraction services for the recovery of oil and related products from hydrocarbon deposits, namely, oil shale, tar sands, coal, peat, plastics, and biomass; Land reclamation; Mining extraction for the production of crude oil, kerogen hydrocarbon residues, plastics, and biomass; Mining extraction for the production of crude oil, kerogen and hydrocarbon residues Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, transmission of captured carbon dioxide by means of trucking and pipeline for others; Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, physical storage of captured carbon dioxide for others Carbon sequestration services using technologies to sequester carbon produced from oil shale projects, namely, carbon capture for others using in-ground sequestration and sequestration in spent shale Engineering, namely, mining engineering using clean technology to produce oil from oil shale and CO2 produced from oil production sequestered with enhanced oil recovery (EOR) in nearby conventional oil fields; Engineering, namely, mining engineering services for simultaneous recovery of rare earth elements from oil shale projects

Abrégé

A radial flow oil shale retort (100) can include a central heating fluid conduit (118) having a permeable outer wall (132) and an outer heating fluid annulus (116) positioned about the central heating fluid conduit (118), the outer heating fluid annulus (116) having a permeable inner wall (130). An annular body (114) of comminuted oil shale can be between the permeable outer wall (132) of the central heating fluid conduit (118) and the permeable inner wall (130) of the outer heating fluid annulus (116). A heating fluid supply (122) can be connected to either the central heating fluid conduit (118) or the outer heating fluid annulus (116) to flow a heating fluid in a radial direction through the annular body (114) of the comminuted oil shale.

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E21B 43/24 - Procédés de récupération assistée pour l'extraction d'hydrocarbures utilisant la chaleur, p. ex. injection de vapeur

Abrégé

Systems and methods for heating material through cogeneration of thermal and electrical energy can include a heat source and an electric generator configured to produce hot exhaust gas and electricity. One or more heating conduits can carry the hot exhaust gas to one or more bodies of material. The electric generator can at least partially power one or more electric heaters configured to reheat the hot exhaust gas after a portion of heat has been transferred from the hot exhaust gas to the one or more bodies of material.

Classes IPC  ?

• C10G 1/06 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par hydrogénation destructive
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• F01L 15/10 - Systèmes de distribution à soupapes, p. ex. comportant des tiroirs à mouvement alternatif, autres que ceux couverts par les groupes comportant un tiroir en guise de soupape principale auxiliaire entraînée par ce tiroir
• F02C 6/04 - Ensembles fonctionnels de turbines à gaz délivrant un fluide de travail chauffé ou pressurisé à d'autres appareils, p. ex. sans sortie de puissance mécanique
• C10B 53/06 - Distillation destructive spécialement conçue pour des matières premières solides particulières ou sous forme spéciale de schistes ou roches bitumineux
• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• C10B 49/02 - Distillation destructive des matières carbonées solides par chauffage direct au moyen d'agents porteurs de chaleur, y compris la combustion partielle de la matière à traiter avec des gaz ou des vapeurs à haute température, p. ex. les gaz chauds obtenus par la combustion partielle de la charge
• C10B 47/06 - Distillation destructive des matières carbonées solides avec chauffage indirect, p. ex. par combustion externe avec charge immobile dans des cornues

Abrégé

Systems (100) and methods for heating material through cogeneration of thermal and electrical energy can include a heat source (105) and an electric generator (110) configured to produce hot exhaust gas and electricity. One or more heating conduits (115) can carry the hot exhaust gas to one or more bodies of material (120). The electric generator (110) can at least partially power one or more electric heaters (125) configured to reheat the hot exhaust gas after a portion of heat has been transferred from the hot exhaust gas to the one or more bodies of material (120).

Classes IPC  ?

• E21B 43/24 - Procédés de récupération assistée pour l'extraction d'hydrocarbures utilisant la chaleur, p. ex. injection de vapeur
• E21B 43/243 - Combustion sur place
• E21B 43/247 - Combustion sur place en association avec des procédés de fracturation

Abrégé

Systems for heating a body of crushed hydrocarbonaceous material to produce hydrocarbons therefrom can involve heating multiple zones of the body of material sequentially. An exemplary system can include a body of crushed hydrocarbonaceous material having a lower zone and an upper zone. A lower heating conduit can be embedded in the lower zone, while an upper heating conduit is embedded in the upper zone. A collection conduit is embedded in the upper zone at a location above the upper heating conduit. A lower heating valve is also operatively associated with the lower heating conduit and is capable of switchably flowing a heat transfer fluid through the lower heating conduit. An upper heating valve is operatively associated with the upper heating conduit and capable of switchably flowing the heat transfer fluid through the upper heating conduit. The lower heating valve and upper heating valve are also configured to sequentially flow the heat transfer fluid through the lower heating conduit and then through the upper heating conduit or through the upper heating conduit and then through the lower heating conduit.

Classes IPC  ?

• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• C10B 1/00 - Cornues
• C10B 5/06 - Fours à coke à chambres horizontales à conduits de chaleur horizontaux
• C10B 49/02 - Distillation destructive des matières carbonées solides par chauffage direct au moyen d'agents porteurs de chaleur, y compris la combustion partielle de la matière à traiter avec des gaz ou des vapeurs à haute température, p. ex. les gaz chauds obtenus par la combustion partielle de la charge

Abrégé

Methods and systems of heating a body of crushed hydrocarbonaceous material to produce hydrocarbons therefrom can involve heating multiple zones of the body of material sequentially. An exemplary method (100A) can include forming a body of crushed hydrocarbonaceous material having a first zone and a second zone (110A). The first zone can be heated in a first heating stage to form a dynamic high temperature production region in the first zone (120A). A cooling fluid can then be injected into the first zone after the high temperature production region forms (130A). The high temperature production region can move into the second zone in a second heating stage. Hydrocarbons can be collected from the body of crushed hydrocarbonaceous material during both the first and second heating stages (140 A).

Classes IPC  ?

• E21B 43/24 - Procédés de récupération assistée pour l'extraction d'hydrocarbures utilisant la chaleur, p. ex. injection de vapeur
• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits
• E21B 43/16 - Procédés de récupération assistée pour l'extraction d'hydrocarbures

Abrégé

Methods and systems of heating a body of crushed hydrocarbonaceous material to produce hydrocarbons therefrom can involve heating multiple zones of the body of material sequentially. An exemplary method can include forming a body of crushed hydrocarbonaceous material having a first zone and a second zone. The first zone can be heated in a first heating stage to form a dynamic high temperature production region in the first zone. A cooling fluid can then be injected into the first zone after the high temperature production region forms. The high temperature production region can move into the second zone in a second heating stage. Hydrocarbons can be collected from the body of crushed hydrocarbonaceous material during both the first and second heating stages.

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation

Abrégé

A fluid seal system for a hydrocarbon recovery capsule includes a plurality of interconnected fluid seals each comprising an elongated sealing member clamped to a bulkhead plate and biasing a geomembrane to the bulkhead plate. A compression plate is positioned between each elongated sealing member and the bulkhead plate, thereby clamping the geomembrane to the bulkhead plate. An enclosed channel of each elongated sealing member receives a slurry. Clay amended soil surrounds and compresses the plurality of interconnected seals to provide a fluid seal that is capable of withstanding high temperatures while sealing off fluid and gas from the environment. A method of sealing a hydrocarbon recovery capsule is disclosed and described.

Classes IPC  ?

• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• F16J 15/02 - Joints d'étanchéité entre surfaces immobiles entre elles
• F16J 15/14 - Joints d'étanchéité entre surfaces immobiles entre elles au moyen d'un matériau en grains ou en matière plastique ou d'un fluide

Abrégé

A gas containment system can include a gas barrier layer forming a capsule. The gas barrier layer can be made up of a particulate swelling clay, a non-swelling particulate material mixed with the particulate swelling clay, water, and a water-soluble polyol. The water can hydrate the particulate swelling clay and form a continuous liquid phase in the gas barrier layer. The water-soluble polyol can be dissolved in the water. The gas containment system can further include a gas retained inside the capsule.

Classes IPC  ?

• B65G 5/00 - Emmagasinage des fluides dans des excavations ou cavités naturelles ou artificielles souterraines
• E21D 11/00 - Revêtement de tunnels, galeries ou autres cavités souterraines, p. ex. de vastes chambres souterrainesRevêtements à cet effetLeur exécution sur place, p. ex. par assemblage
• E21D 11/38 - Imperméabilisation à l'eauCalorifugeageImperméabilisation acoustiqueIsolation électrique
• E21D 13/00 - Vastes chambres souterrainesProcédés ou appareils pour leur exécution

Abrégé

A gas containment system (100) can include a gas barrier layer (110) forming a capsule. The gas barrier layer can be made up of a particulate swelling clay, a non-swelling particulate material mixed with the particulate swelling clay, water, and a water-soluble polyol. The water can hydrate the particulate swelling clay and form a continuous liquid phase in the gas barrier layer. The water-soluble polyol can be dissolved in the water. The gas containment system can further include a gas retained inside the capsule.

Classes IPC  ?

• F17D 5/02 - Prévention, interception ou localisation des pertes

Abrégé

A thermal insulation system can include a body of heated material at an elevated temperature. A layer of porous insulating material can be placed adjacent to and in fluid communication with the body of heated material. The insulating layer can contain distributed liquid water in an amount sufficient to cool the insulating layer through evaporative vapor flow toward the body of heated material. The amount of water can be sufficient to provide water vapor for inhibiting the diffusion and adsorption of hydrocarbons from the heated material. The insulating layer can include a continuous vapor phase. A heat sink material at a lower temperature can be placed adjacent to the insulating layer and opposite from the body of heated material.

Classes IPC  ?

• F28F 13/00 - Dispositions pour modifier le transfert de chaleur, p. ex. accroissement, diminution
• F16L 59/02 - Forme ou configuration de matériaux isolants, avec ou sans revêtement formant un tout avec les matériaux isolants
• E21B 43/24 - Procédés de récupération assistée pour l'extraction d'hydrocarbures utilisant la chaleur, p. ex. injection de vapeur

Abrégé

A thermal insulation system (100) can include a body of heated material (110) at an elevated temperature. A layer of porous insulating material (120) can be placed adjacent to and in fluid communication with the body of heated material (110). The insulating layer (120) can contain distributed liquid water in an amount sufficient to cool the insulating layer (120) through evaporative vapor flow toward the body of heated material (110). The amount of water can be sufficient to provide water vapor for inhibiting the diffusion and adsorption of hydrocarbons from the body of heated material (110). The insulating layer (120) can include a continuous vapor phase. A heat sink material (130) at a lower temperature can be placed adjacent to the insulating layer (120) and opposite from the body of heated material (110).

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A fluid seal system for a hydrocarbon recovery capsule includes a plurality of interconnected fluid seals (30) each comprising an elongated sealing member (32) clamped to a bulkhead plate (34) and biasing a geomembrane (36) to the bulkhead plate (34). A compression plate (42a, 42b) is positioned between each elongated sealing member (32) and the bulkhead plate (34), thereby clamping the geomembrane (36) to the bulkhead plate (34). An enclosed channel (38) of each elongated sealing member (32) receives a slurry (40). Clay amended soil surrounds and compresses the plurality of interconnected seals (30) to provide a fluid seal that is capable of withstanding high temperatures while sealing off fluid and gas from the environment. A method of sealing a hydrocarbon recovery capsule is disclosed and described.

Classes IPC  ?

• E02B 3/16 - Étanchement ou joints

Abrégé

A system and method for long term storage of waste can include a comminuted material (100) having a high surface area. The comminuted material (100) can include particles of processed hydro carbonaceous materials from which hydrocarbon products have been derived. The comminuted material (100) can be contacted with a flowable waste material so that the flowable waste material is retained in the comminuted material (100). This flowable waste material is some material other than hydrocarbon products that have been derived from the hydro carbonaceous materials. An encapsulation barrier (105) can envelope the comminuted material (100) and provide a secondary means of preventing escape of the flowable waste material.

Classes IPC  ?

• B03B 9/02 - Disposition générale d'un atelier de séparation, p. ex. schéma opératoire spécialement adapté aux séparations pétrole/sable, pétrole/craie, pétrole/schistes, ozokérite, bitume ou similaires
• B09B 1/00 - Mise à la décharge des déchets solides
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E02D 31/00 - Dispositions de protection pour les fondations ou ouvrages réalisés par des techniques de fondationMesures dans le cadre des techniques de fondation pour protéger le sol ou l'eau du sous-sol, p. ex. prévention ou neutralisation de la pollution par le pétrole

Abrégé

A system and method for long term storage of waste can include a comminuted material having a high surface area. The comminuted material can include particles of processed hydrocarbonaceous materials from which hydrocarbon products have been derived. The comminuted material can be contacted with a flowable waste material so that the flowable waste material is retained in the comminuted material. This flowable waste material is some material other than hydrocarbon products that have been derived from the hydrocarbonaceous materials. An encapsulation barrier can envelope the comminuted material and provide a secondary means of preventing escape of the flowable waste material.

Classes IPC  ?

• B09B 1/00 - Mise à la décharge des déchets solides
• B09B 3/00 - Destruction de déchets solides ou transformation de déchets solides en quelque chose d'utile ou d'inoffensif

Abrégé

A method for removal and condensation of vapors from within an enclosed space is disclosed. An enclosed space containing hydrocarbonaceous material is surrounded by an insulative permeable layer having a lowering temperature gradient between the inner surface and the outer surfaces. The insulative layer may also be covered by an impermeable layer. Heating the material in the enclosed space causes the formation of vapors at a positive pressure within the enclosed space. Vapors pass through the inner surface of the insulative permeable layer and contact the permeable materials and are condensed by the lowering temperature within the insulative layer. The condensate liquid passes downwardly through the insulative layer and is then collected. The positive pressure within the heated enclosed space and the condensation and lowering of pressure and temperature within the insulative layer serves to draw additional vapors from within the enclosed space into the insulative layer which facilitates condensation and subsequent collection.

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 31/06 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par des méthodes non prévues ailleurs par chauffage, refroidissement ou traitement par la pression
• F26B 25/00 - Parties constitutives d'application générale non couvertes par un des groupes ou

Abrégé

A method (10) of minimizing vapor transmission from a constructed permeability control infrastructure can comprise forming (12) a heterogeneous hydrated matrix within the constructed permeability control infrastructure, the constructed permeability control infrastructure comprising a permeability control impoundment defining a substantially encapsulated volume. The heterogeneous hydrated matrix includes a particulate solid phase and a continuous liquid phase which is penetrable by a vapor having a permeation rate. The constructed permeability control infrastructure is operated (14) to control the permeation rate by manipulating (16) an operational parameter of the constructed permeability control infrastructure. Additionally, the vapor can be impeded during operating sufficient to contain the vapor within the constructed permeability control infrastructure.

Classes IPC  ?

• B01D 19/00 - Dégazage de liquides
• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 31/00 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par des méthodes non prévues ailleurs

Abrégé

A method of minimizing vapor transmission from a constructed permeability control infrastructure can comprise forming a heterogeneous hydrated matrix within the constructed permeability control infrastructure, the constructed permeability control infrastructure comprising a permeability control impoundment defining a substantially encapsulated volume. The heterogeneous hydrated matrix includes a particulate solid phase and a continuous liquid phase which is penetrable by a vapor having a permeation rate. The constructed permeability control infrastructure is operated to control the permeation rate by manipulating an operational parameter of the constructed permeability control infrastructure. Additionally, the vapor can be impeded during operating sufficient to contain the vapor within the constructed permeability control infrastructure.

Classes IPC  ?

• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• F17D 5/02 - Prévention, interception ou localisation des pertes

Abrégé

A method of reducing settling of residual comminuted hydrocarbonaceous material during processing (10) can comprise forming a constructed permeability control infrastructure (12) which defines a substantially encapsulated volume. The method can also include introducing a composite comminuted hydrocarbonaceous material into the control infrastructure to form a permeable body (14), where the composite hydrocarbonaceous material includes a comminuted hydrocarbonaceous material and a structural material. The method can further include heating the permeable body sufficient to remove hydrocarbons therefrom (16). The hydrocarbonaceous material is substantially stationary during heating, exclusive of subsidence and settling. The structural material can provide structural integrity to the permeable body sufficient to maintain convective flow of fluids throughout the permeable body during heating.

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon

Abrégé

A system (100) for disrupting convective heat flow within a body of hydro carbonaceous material (108) includes a body of hydro carbonaceous material (108) which is sufficiently porous that convective currents can form in void spaces of the material (108). A bulk fluid occupies these void spaces and the bulk fluid is heated by a heat source (112), causing the bulk fluid to flow through the void spaces in convective currents. A convective barrier (116) is placed in an upper portion of the body of hydro carbonaceous material (108). This convective barrier (116) is configured to disrupt convective flow of the bulk fluid.

Classes IPC  ?

• C10G 31/06 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par des méthodes non prévues ailleurs par chauffage, refroidissement ou traitement par la pression

Abrégé

A system for disrupting convective heat flow within a body of hydrocarbonaceous material includes a body of hydrocarbonaceous material which is sufficiently porous that convective currents can form in void spaces of the material. A bulk fluid occupies these void spaces and the bulk fluid is heated by a heat source, causing the bulk fluid to flow through the void spaces in convective currents. A convective barrier is placed in an upper portion of the body of hydrocarbonaceous material. This convective barrier is configured to disrupt convective flow of the bulk fluid.

Classes IPC  ?

• E21B 43/24 - Procédés de récupération assistée pour l'extraction d'hydrocarbures utilisant la chaleur, p. ex. injection de vapeur
• E21B 43/241 - Procédés de récupération assistée pour l'extraction d'hydrocarbures utilisant la chaleur, p. ex. injection de vapeur combinés avec une exploitation au moyen de solvants de matières minérales autres que des hydrocarbures, p. ex. pyrolyse de schistes bitumineux au moyen de solvants

Abrégé

A method of reducing settling of residual comminuted hydrocarbonaceous material during processing can comprise forming a constructed permeability control infrastructure which defines a substantially encapsulated volume; introducing a composite comminuted hydrocarbonaceous material into the control infrastructure to form a permeable body, said composite hydrocarbonaceous material comprising a comminuted hydrocarbonaceous material and a structural material; and heating the permeable body sufficient to remove hydrocarbons therefrom such that the hydrocarbonaceous material is substantially stationary during heating, exclusive of subsidence and settling. The structural material can provide structural integrity to the permeable body sufficient to maintain convective flow of fluids throughout the permeable body during heating.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• C10G 31/06 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par des méthodes non prévues ailleurs par chauffage, refroidissement ou traitement par la pression
• C10B 53/06 - Distillation destructive spécialement conçue pour des matières premières solides particulières ou sous forme spéciale de schistes ou roches bitumineux
• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 53/06 - Traitement des huiles d'hydrocarbures, en l'absence d'hydrogène, par plusieurs procédés de raffinage uniquement par plusieurs étapes en série comprenant au moins une étape d'extraction ne comprenant que des étapes d'extraction, p. ex. désasphaltage par un solvant suivi d'une extraction des composés aromatiques

Abrégé

An access system (100) for a pressure controlled environment is disclosed and described. The system (100) can include a pressurized region (110) having a first fluid (104). The pressurized region (110) can be defined, at least partially, by a barrier (112) separating the pressurized region (110) from a lower pressure region (111 ). The system (100) can also include a trap (140) fluidly coupling the pressurized region (110) and the lower pressure region (111 ) through at least a portion of the barrier (112). The trap (140) can have a second fluid (142) forming a seal to prevent the first fluid (104) from escaping the pressurized region (110). Additionally, the system (100) can include at least one cable (132) extending through the trap (140) and the barrier (112) into the pressurized region (110).

Classes IPC  ?

• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon
• C10G 11/00 - Craquage catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures

Abrégé

An access system for a pressure controlled environment is disclosed and described. The system can include a pressurized region having a first fluid. The pressurized region can be defined, at least partially, by a barrier separating the pressurized region from a lower pressure region. The system can also include a trap fluidly coupling the pressurized region and the lower pressure region through at least a portion of the barrier. The trap can have a second fluid forming a seal to prevent the first fluid from escaping the pressurized region. Additionally, the system can include at least one cable extending through the trap and the barrier into the pressurized region.

Classes IPC  ?

• E21B 43/12 - Procédés ou appareils pour commander l'écoulement du fluide extrait vers ou dans les puits
• C10G 1/02 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par distillation
• G05D 27/00 - Commande simultanée des variables entrant dans plusieurs des groupes principaux

Abrégé

A method of reducing residual hydrocarbon accumulation during processing can comprise forming a permeable body (608) of a comminuted hydro carbonaceous material within an enclosure (602). A primary liquid collection system (610) is located in a lower portion of the permeable body. The primary liquid collection system (610) has an upper surface for collecting and removing liquids. Comminuted hydro carbonaceous material below the primary liquid collection system (610) forms a non-production zone (616). At least a portion of the permeable body (608) is heated to a bulk temperature above a production temperature sufficient to remove hydrocarbons therefrom within a production zone (614), where conditions in the non-production zone (616) are maintained below the production temperature.

Classes IPC  ?

• E21B 43/30 - Disposition particulière des puits, p. ex. disposition rendant optimum l'espacement des puits
• E21B 43/16 - Procédés de récupération assistée pour l'extraction d'hydrocarbures
• E21B 43/34 - Aménagements pour séparer les matériaux produits par le puits

Abrégé

A vertically compactable fluid transfer device (10) can include a lateral fluid transfer conduit (12) to convey a fluid transfer fluid therethrough and to be supported by particles (16) packed to a first density. Additionally, the device (10) can include a riser (14) coupled to, and in fluid communication with, the lateral fluid transfer conduit (12). The riser (14) can be vertically compactable by at least 20% while maintaining structural integrity when the lateral fluid transfer conduit lowers as the supporting particles (16) pack to a second density, which is higher than the first density.

Classes IPC  ?

• F16L 11/00 - Manches, c.-à-d. tuyaux flexibles

Abrégé

A vertically compactable fluid transfer device (10) can include a lateral fluid transfer conduit (12) to convey a fluid transfer fluid therethrough and to be supported by particles (16) packed to a first density. Additionally, the device (10) can include a riser (14) coupled to, and in fluid communication with, the lateral fluid transfer conduit (12). The riser (14) can be vertically compactable by at least 20% while maintaining structural integrity when the lateral fluid transfer conduit lowers as the supporting particles (16) pack to a second density, which is higher than the first density.

Classes IPC  ?

• E21B 43/12 - Procédés ou appareils pour commander l'écoulement du fluide extrait vers ou dans les puits
• E21B 43/08 - Tubes filtres ou crépines

Abrégé

A method of maintaining structural integrity of a subsiding earthen fluid containment structure is disclosed and comprises forming a lined containment infrastructure (100) including a convex bulged crown portion (120), floor portion (110) and sidewall portions (115) which enclose a comminuted earthen material (126) within an enclosed volume (125) such that fluid flow from the lined containment compound is restricted. The bulged crown flattens, thickens and diminishes in surface area during subsidence of the comminuted earthen material as fluid is removed. The bulged crown is shaped to avoid tensile stresses which may otherwise result in breach or failure of lined containment during subsidence. Further, the lined containment structure can include an inner insulative layer and an outer impermeable seal layer having unique contributions as described in more detail herein.

Classes IPC  ?

• B65D 88/02 - Grands réceptacles rigides
• B65G 5/00 - Emmagasinage des fluides dans des excavations ou cavités naturelles ou artificielles souterraines
• F17C 1/00 - Récipients sous pression, p. ex. bouteilles de gaz, réservoirs de gaz, cartouches échangeables

Abrégé

A method of removing fines from a hydrocarbon-containing fluid can include preparing a bed media of particulate earthen material (12). The hydrocarbon-containing fluid having fines therein can be passed through the bed media (12) at a flow rate such that a portion of the fines are retained in the bed media (12) to form a filtered hydrocarbon-containing fluid. The flow rate is sufficient to maintain a wetting film of the hydrocarbon-containing fluid across at least a majority portion of the particulate earthen material which is contacted by the hydrocarbon-containing fluid. The filtered hydrocarbon-containing fluid can be recovered from the bed media (12) via a suitable outlet (16) having substantially reduced or eliminated fines content.

Classes IPC  ?

• B01D 15/00 - Procédés de séparation comportant le traitement de liquides par des adsorbants ou des absorbants solidesAppareillages pour ces procédés
• B01J 20/02 - Compositions absorbantes ou adsorbantes solides ou compositions facilitant la filtrationAbsorbants ou adsorbants pour la chromatographieProcédés pour leur préparation, régénération ou réactivation contenant une substance inorganique
• B01J 20/22 - Compositions absorbantes ou adsorbantes solides ou compositions facilitant la filtrationAbsorbants ou adsorbants pour la chromatographieProcédés pour leur préparation, régénération ou réactivation contenant une substance organique

Abrégé

A method of maintaining structural integrity of a subsiding earthen fluid containment structure is disclosed and comprises forming a lined containment infrastructure (100) including a convex bulged crown portion (120), floor portion (110) and sidewall portions (115) which enclose a comminuted earthen material (126) within an enclosed volume (125) such that fluid flow from the lined containment compound is restricted. The bulged crown flattens, thickens and diminishes in surface area during subsidence of the comminuted earthen material as fluid is removed. The bulged crown is shaped to avoid tensile stresses which may otherwise result in breach or failure of lined containment during subsidence. Further, the lined containment structure can include an inner insulative layer and an outer impermeable seal layer having unique contributions as described in more detail herein.

Classes IPC  ?

• B65G 5/00 - Emmagasinage des fluides dans des excavations ou cavités naturelles ou artificielles souterraines
• E02D 31/00 - Dispositions de protection pour les fondations ou ouvrages réalisés par des techniques de fondationMesures dans le cadre des techniques de fondation pour protéger le sol ou l'eau du sous-sol, p. ex. prévention ou neutralisation de la pollution par le pétrole

Abrégé

A method for removal and condensation of vapors from within an enclosed space (120) is disclosed. An enclosed space (120) containing material (110) is surrounded by an insulative permeable layer (130) having a lowering temperature gradient (230) between the inner surface (220) and the outer surfaces (240). The insulative layer (130) may also be covered by an impermeable layer (140). Heating the material (110) in the enclosed space (120) causes the formation of vapors at a positive pressure within the enclosed space (120). Vapors pass through the inner surface (220) of the insulative permeable layer (130) and contact the permeable materials and are condensed by the lowering temperature within the insulative layer (130). The condensate liquid passes downwardly through the insulative layer (130) for collection. The positive pressure within the heated enclosed space (120) and the condensation and lowering of pressure and temperature within the insulative layer (130) serves to draw additional vapors from within the enclosed space (120) into the insulative layer (130) for condensation and collection.

Classes IPC  ?

• B01D 53/02 - Séparation de gaz ou de vapeursRécupération de vapeurs de solvants volatils dans les gazÉpuration chimique ou biologique des gaz résiduaires, p. ex. gaz d'échappement des moteurs à combustion, fumées, vapeurs, gaz de combustion ou aérosols par adsorption, p. ex. chromatographie préparatoire en phase gazeuse
• B01D 53/26 - Séchage des gaz ou vapeurs

Abrégé

A method for removal and condensation of vapors from within an enclosed space (120) is disclosed. An enclosed space (120) containing material (110) is surrounded by an insulative permeable layer (130) having a lowering temperature gradient (230) between the inner surface (220) and the outer surfaces (240). The insulative layer (130) may also be covered by an impermeable layer (140). Heating the material (110) in the enclosed space (120) causes the formation of vapors at a positive pressure within the enclosed space (120). Vapors pass through the inner surface (220) of the insulative permeable layer (130) and contact the permeable materials and are condensed by the lowering temperature within the insulative layer (130). The condensate liquid passes downwardly through the insulative layer (130) for collection. The positive pressure within the heated enclosed space (120) and the condensation and lowering of pressure and temperature within the insulative layer (130) serves to draw additional vapors from within the enclosed space (120) into the insulative layer (130) for condensation and collection.

Classes IPC  ?

• F26B 23/00 - Chauffage
• C10G 31/06 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par des méthodes non prévues ailleurs par chauffage, refroidissement ou traitement par la pression
• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon

Abrégé

A method of removing fines from a hydrocarbon-containing fluid can include preparing a bed media of particulate earthen material (12). The hydrocarbon-containing fluid having fines therein can be passed through the bed media (12) at a flow rate such that a portion of the fines are retained in the bed media (12) to form a filtered hydrocarbon-containing fluid. The flow rate is sufficient to maintain a wetting film of the hydrocarbon-containing fluid across at least a majority portion of the particulate earthen material which is contacted by the hydrocarbon-containing fluid. The filtered hydrocarbon-containing fluid can be recovered from the bed media (12) via a suitable outlet (16) having substantially reduced or eliminated fines content.

Classes IPC  ?

• B01D 24/10 - Filtres à substance filtrante non agglomérée, c.-à-d. à substance filtrante sans aucun liant entre les particules ou les fibres individuelles qui la composent avec le lit filtrant stationnaire pendant la filtration la substance filtrante étant retenue dans un récipient fermé
• B01D 53/02 - Séparation de gaz ou de vapeursRécupération de vapeurs de solvants volatils dans les gazÉpuration chimique ou biologique des gaz résiduaires, p. ex. gaz d'échappement des moteurs à combustion, fumées, vapeurs, gaz de combustion ou aérosols par adsorption, p. ex. chromatographie préparatoire en phase gazeuse

Abrégé

A method of preventing egress of a vapor from an encapsulated volume can include forming a substantially impermeable vapor barrier (20) along an inner surface of the encapsulated volume. The encapsulated volume includes a permeable body (120) of comminuted hydrocarbonaceous material. Further, the vapor barrier (20) can include an insulating layer (24) capable of maintaining a temperature gradient of at least 400° F across the insulating layer (24). The permeable body (120) can be heated sufficient to liberate hydrocarbons therefrom and the hydrocarbons can be collected from the permeable body (120). The vapor barrier layer (20) can be a single or multiple layer construction, depending on the specific materials chosen.

Classes IPC  ?

• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits
• C10G 99/00 - Matière non prévue dans les autres groupes de la présente sous-classe

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure (600). This constructed infrastructure (600) defines a substantially encapsulated volume. A mined hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body (605) of hydrocarbonaceous material. The permeable body (605) can be heated sufficient to remove hydrocarbons therefrom. Hydrocarbon products can be collected from intermediate locations (620, 630) within the permeable body (605). Advantageously, an intermediate fluid collection system (610) can be used to draw a hydrocarbon product from the permeable body (605) at preselected locations. Such intermediate collection can provide hydrocarbon product fractions which can reduce or eliminate the need for full-scale distillation of a hydrocarbon product having a full range of products such as that typically found in crude oil. In addition, product quality can be tailored by monitoring such intermediate draws and adjusting operating parameters accordingly.

Classes IPC  ?

• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits

Abrégé

A method of sequestering carbon dioxide emissions during recovery of hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure (100). This constructed infrastructure (100) defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure (100) to form a permeable body (120) of hydrocarbonaceous material. The permeable body (120) can be heated sufficient to remove hydrocarbons therefrom. During heating, the hydrocarbonaceous material is substantially stationary as the constructed infrastructure (100) is a fixed structure. Additionally, during heating, any carbon dioxide that is produced can be sequestered. Removed hydrocarbons can be collected for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 29/04 - Métaux ou métaux déposés sur un support
• C10G 29/16 - Oxydes métalliques
• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits

Abrégé

A method of maintaining the structural integrity of heating conduit used to heat a permeable body of hydrocarbonaceous material enclosed within a constructed permeability control infrastructure. The method includes obtaining a heating conduit with corrugated walls and configured for transporting a heat transfer fluid, burying the heating conduit at a depth within the permeable body of hydrocarbonaceous material and with an inlet end extending from the boundary of the constructed permeability control infrastructure, operably coupling the inlet end of the heating conduit to a heat source of the heat transfer fluid, and passing the heat transfer fluid through the heating conduit to transfer heat from the heat transfer fluid to the permeable body, with the corrugations in the corrugated walls mitigating longitudinal axis thermal expansion of the heating conduit and allowing the heating conduit to conformably bend in response to subsidence of the permeable body.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering minerals from hydro carbonaceous materials can include forming a constructed permeability control infrastructure (100). This constructed infrastructure (100) defines a substantially encapsulated volume. A comminuted hydro carbonaceous material can be introduced into the control infrastructure to form a permeable body (120) of hydro carbonaceous material. The permeable body (120) can be contacted with an agent sufficient to remove minerals therefrom. The agent is typically a solution containing a solvent, leachant, chelating agent and the like via which minerals can be removed having value, toxic minerals, radioactive minerals and the like.

Classes IPC  ?

• C10G 21/00 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par extraction au moyen de solvants sélectifs
• C10G 29/00 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, au moyen d'autres produits chimiques
• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure (100). This constructed infrastructure (100) defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body (120) of hydrocarbonaceous material. The permeable body (120) can be heated sufficient to remove hydrocarbons therefrom. During heating and removal of hydrocarbons and subsequent thereto a positive pressure can be maintained within the encapsulated volume by means of a non-oxidizing gas to expedite flushing of hydrocarbonaceous material, inhibit unwanted entry of oxygen into the encapsulated volume and remove recoverable hydrocarbons following the heating process.

Classes IPC  ?

• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits

Abrégé

An articulating conduit linkage system (80) for maintaining a fluid connection between a fluid source and displaceable conduit that has been buried in a subsiding permeable body (30). A fluid source can supply a working fluid through a source outlet (72), and which is located outside of the boundaries of the permeable body (30). A displaceable conduit can receive the working fluid through a conduit inlet (74), and be buried at a depth within a subsiding permeable body (30) that is contained within a permeability control infrastructure (12). A plurality of articulating conduit segments (82,84,86) can comprise: an outer conduit segment (82) that is operably coupled to the source outlet (72) with a first single-axis swivel joint, an inner conduit segment (84) that is operably coupled to the conduit inlet (74) with a second single-axis swivel joint, and at least one middle conduit segment (86) that operably connects the outer (82) and inner segments (84), respectively, with at least one single-axis swivel joint to establish a working fluid connection between the fluid source and the displaceable conduit (70). In the event of a subsidence of the permeable body which causes a relative displacement between the source outlet (72) and the conduit inlet (74) that is perpendicular to the longitudinal axes of both the outlet and the inlet, the plurality of articulating conduit segments (82,84,86) are configured so the outer (82) and inner (84) conduit segments rotate in opposite directions to extend the conduit linkage system while maintaining a working fluid connection between the source outlet (72) and the conduit inlet (74).

Classes IPC  ?

• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits
• C10G 31/09 - Raffinage des huiles d'hydrocarbures, en l'absence d'hydrogène, par des méthodes non prévues ailleurs par filtration
• C02F 1/44 - Traitement de l'eau, des eaux résiduaires ou des eaux d'égout par dialyse, osmose ou osmose inverse
• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/00 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon

Abrégé

A method of maintaining the structural integrity of heating conduit used to heat a permeable body of hydro carbonaceous material enclosed within a constructed permeability control infrastructure. The method (200) includes obtaining (202) a heating conduit with corrugated walls and configured for transporting a heat transfer fluid, burying (204) the heating conduit at a depth within the permeable body of hydro carbonaceous material and with an inlet end extending from the boundary of the constructed permeability control infrastructure, (206) operably coupling the inlet end of the heating conduit to a heat source of the heat transfer fluid, and (208) passing the heat transfer fluid through the heating conduit to transfer heat from the heat transfer fluid to the permeable body, with the corrugations in the corrugated walls mitigating longitudinal axis thermal expansion of the heating conduit and allowing the heating conduit to conformably bend in response to subsidence of the permeable body.

Classes IPC  ?

• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits
• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A constructed permeability control infrastructure (100) can include a permeability control impoundment, which defines a substantially encapsulated volume. The infrastructure (100) can also include a comminuted hydrocarbonaceous material within the encapsulated volume. The comminuted hydrocarbonaceous material can form a permeable body (120) of hydrocarbonaceous material. The infrastructure (100) can further include at least one convection driving conduit oriented in a lower portion of the permeable body (120) to generate bulk convective flow patterns throughout the permeable body (120). An associated method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure (100), which defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure (100) to form a permeable body (120) of hydrocarbonaceous material. A heated fluid can be passed throughout the permeable body (120) in bulk convective flow patterns to remove hydrocarbons from the permeable body (120). Removed hydrocarbons can be collected for further processing and/or use.

Classes IPC  ?

• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• E21B 43/00 - Procédés ou dispositifs pour l'extraction de pétrole, de gaz, d'eau ou de matériaux solubles ou fusibles ou d'une suspension de matières minérales à partir de puits

Abrégé

A method of preventing egress of a vapor from an encapsulated volume can include forming a substantially impermeable vapor barrier along an inner surface of the encapsulated volume. The encapsulated volume includes a permeable body of comminuted hydro carbonaceous material. Further, the vapor barrier can include an insulating layer capable of maintaining a temperature gradient of at least 400° F. across the insulating layer. The permeable body can be heated sufficient to liberate hydrocarbons therefrom and the hydrocarbons can be collected from the permeable body. The vapor barrier layer can be a single or multiple layer construction, depending on the specific materials chosen.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of sequestering carbon dioxide emissions during recovery of hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to remove hydrocarbons therefrom. During heating, the hydrocarbonaceous material is substantially stationary as the constructed infrastructure is a fixed structure. Additionally, during heating, any carbon dioxide that is produced can be sequestered. Removed hydrocarbons can be collected for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to remove hydrocarbons therefrom. During heating and removal of hydrocarbons and subsequent thereto a positive pressure can be maintained within the encapsulated volume by means of a non-oxidizing gas to expedite flushing of hydrocarbonaceous material, inhibit unwanted entry of oxygen into the encapsulated volume and remove recoverable hydrocarbons following the heating process.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A constructed permeability control infrastructure can include a permeability control impoundment, which defines a substantially encapsulated volume. The infrastructure can also include a comminuted hydrocarbonaceous material within the encapsulated volume. The comminuted hydrocarbonaceous material can form a permeable body of hydrocarbonaceous material. The infrastructure can further include at least one convection driving conduit oriented in a lower portion of the permeable body to generate bulk convective flow patterns throughout the permeable body. An associated method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure, which defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. A heated fluid can be passed throughout the permeable body in bulk convective flow patterns to remove hydrocarbons from the permeable body. Removed hydrocarbons can be collected for further processing and/or use.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A mined hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to remove hydrocarbons therefrom. Hydrocarbon products can be collected from intermediate locations within the permeable body. Advantageously, an intermediate fluid collection system can be used to draw a hydrocarbon product from the permeable body at preselected locations. Such intermediate collection can provide hydrocarbon product fractions which can reduce or eliminate the need for full-scale distillation of a hydrocarbon product having a full range of products such as that typically found in crude oil. In addition, product quality can be tailored by monitoring such intermediate draws and adjusting operating parameters accordingly.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering minerals from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be contacted with an agent sufficient to remove minerals therefrom. The agent is typically a solution containing a solvent, leachant, chelating agent and the like via which minerals can be removed having value, toxic minerals, radioactive minerals and the like.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to remove hydrocarbons therefrom. During heating the hydrocarbonaceous material is substantially stationary as the constructed infrastructure is a fixed structure. Removed hydrocarbons can be collected for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering hydrocarbons from hydro carbonaceous materials can include forming a constructed permeability control infrastructure (100). This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydro carbonaceous material can be introduced into the control infrastructure to form a permeable body (120) of hydro carbonaceous material. The permeable body (120) can be heated sufficient to remove hydrocarbons therefrom such as by using heating conduits (118,126). During heating the hydro carbonaceous material is substantially stationary as the constructed infrastructure (100) is a fixed structure. Removed hydrocarbons can be collected as liquid products (136) and gaseous products (140) for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 9/00 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures
• C10G 11/00 - Craquage catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume having substantially permeable side walls and a substantially impermeable cap. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to remove hydrocarbons therefrom without contamination or substantial leaching of materials outside of the impoundment. During heating the hydrocarbonaceous material is substantially stationary as the constructed infrastructure is a fixed structure. Removed hydrocarbons can be collected for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering hydrocarbons from water-containing hydrocarbonaceous materials can include forming a constructed permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A mined or separately collected water-containing hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to initially remove water therefrom as a water vapor. The water vapor can be removed from the infrastructure via an outlet which can be controlled or shut off when the permeable body is sufficiently dewatered. The dewatered permeable body can be heated sufficient to remove hydrocarbons therefrom. During heating the hydrocarbonaceous material is substantially stationary as the constructed infrastructure is a fixed structure. Removed hydrocarbons can be collected for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of recovering hydrocarbons from hydrocarbonaceous materials can include forming a stationary permeability control infrastructure. This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydrocarbonaceous material can be introduced into the control infrastructure to form a permeable body of hydrocarbonaceous material. The permeable body can be heated sufficient to remove hydrocarbons therefrom within a temperature range which is sufficient to substantially avoid formation of carbon dioxide or non-hydrocarbon leachates. During heating the hydrocarbonaceous material is substantially stationary as the constructed infrastructure is a fixed structure. Removed hydrocarbons can be collected for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Produits et services

Mining extraction services for the recovery of oil and related products from hydrocarbon deposits, namely, oil shale, tar sands, coal, and peat; Land reclamation

Produits et services

Mining extraction for the production of crude oil, kerogen and hydrocarbon residues [ Fuel refining; oil refining ] Mining engineering

Abrégé

Recovering hydrocarbons (100) from oil shale can include injecting (110) a heated working fluid into a first vessel containing particulate oil shale in a pyrolysis mode. The heated working fluid can have a temperature above a production temperature to pyrolyze kerogen in a stationary bed of the oil shale at or above the production temperature. An effluent can concurrently flow (120) out of the first vessel to be injected into a second vessel in preheating mode. The second vessel containing particulate oil shale has an average temperature below the production temperature so as to capture heat from the effluent sufficient to increase the average temperature of the particulate oil shale and to condense condensable hydrocarbon product while also removing entrained mineral fines mists of condensed hydrocarbons from the effluent. Liquid hydrocarbons can be concurrently collected (130) from the first vessel and/or the second vessel.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction
• C10G 9/02 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures dans des cornues
• C10G 9/26 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures avec des matériaux solides fixes préchauffés en discontinu, p. ex. vent et tirage
• C10G 9/36 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures par contact direct avec des fluides inertes préchauffés, p. ex. avec des métaux ou sels fondus avec des gaz ou vapeurs chauds
• C10G 9/38 - Craquage thermique non catalytique, en l'absence d'hydrogène, des huiles d'hydrocarbures par contact direct avec des fluides inertes préchauffés, p. ex. avec des métaux ou sels fondus avec des gaz ou vapeurs chauds produits par la combustion partielle de la matière à craquer ou par la combustion d'un autre hydrocarbure

Abrégé

A method of recovering hydrocarbons from hydro carbonaceous materials can include forming a constructed permeability control infrastructure (100). This constructed infrastructure defines a substantially encapsulated volume. A comminuted hydro carbonaceous material can be introduced into the control infrastructure to form a permeable body (120) of hydro carbonaceous material. The permeable body (120) can be heated sufficient to remove hydrocarbons therefrom such as by using heating conduits (118,126). During heating the hydro carbonaceous material is substantially stationary as the constructed infrastructure (100) is a fixed structure. Removed hydrocarbons can be collected as liquid products (136) and gaseous products (140) for further processing, use in the process, and/or use as recovered.

Classes IPC  ?

• C10G 1/04 - Production de mélanges liquides d'hydrocarbures à partir de schiste bitumineux, de sable pétrolifère ou de matières carbonées solides non fusibles ou similaires, p. ex. bois, charbon par extraction

Abrégé

A method of removing fines from a hydrocarbon-containing fluid can include preparing a bed media of particulate earthen material (12). The hydrocarbon-containing fluid having fines therein can be passed through the bed media (12) at a flow rate such that a portion of the fines are retained in the bed media (12) to form a filtered hydrocarbon-containing fluid. The flow rate is sufficient to maintain a wetting film of the hydrocarbon-containing fluid across at least a majority portion of the particulate earthen material which is contacted by the hydrocarbon-containing fluid. The filtered hydrocarbon-containing fluid can be recovered from the bed media (12) via a suitable outlet (16) having substantially reduced or eliminated fines content.

Classes IPC  ?

• B01D 24/10 - Filtres à substance filtrante non agglomérée, c.-à-d. à substance filtrante sans aucun liant entre les particules ou les fibres individuelles qui la composent avec le lit filtrant stationnaire pendant la filtration la substance filtrante étant retenue dans un récipient fermé
• B01D 53/02 - Séparation de gaz ou de vapeursRécupération de vapeurs de solvants volatils dans les gazÉpuration chimique ou biologique des gaz résiduaires, p. ex. gaz d'échappement des moteurs à combustion, fumées, vapeurs, gaz de combustion ou aérosols par adsorption, p. ex. chromatographie préparatoire en phase gazeuse