A process allows the extraction of heavy hydrocarbon compounds from solid substrates in an economical and efficient fashion. Materials containing heavy hydrocarbons (i.e. oil sands or roofing shingles) are broken up into an auger and then mixed with light hydrocarbons. Subsequently, the resulting slurry is shaken to separate fluids from solids, and the fluids are subjected to one or more filtering processes to remove waste sediment. These filtering processes may include a series of one or more of centrifuges and nozzle purifier machines. Filtered fluids are distilled to separate heavy hydrocarbons from light hydrocarbons. Simultaneously, the solids are heated to remove the remaining light hydrocarbons as vapors. Light hydrocarbons are cooled in a condenser and coalesced in a holding tank, wherefrom they may be recirculated into the process and used repeatedly. The now-isolated heavy hydrocarbons resulting from the distillation process may be removed as a purified product.

A process allows the extraction of heavy hydrocarbon compounds from solid substrates in an economical and efficient fashion. Materials containing heavy hydrocarbons (i.e. oil sands or roofing shingles) are broken up into an auger and then mixed with light hydrocarbons. Subsequently, the resulting slurry is shaken to separate fluids from solids, and the fluids are subjected to one or more filtering processes to remove waste sediment. These filtering processes may include a series of one or more of centrifuges and nozzle purifier machines. Filtered fluids are distilled to separate heavy hydrocarbons from light hydrocarbons. Simultaneously, the solids are heated to remove the remaining light hydrocarbons as vapors. Light hydrocarbons are cooled in a condenser and coalesced in a holding tank, wherefrom they may be recirculated into the process and used repeatedly. The now-isolated heavy hydrocarbons resulting from the distillation process may be removed as a purified product.

An example system for co-liquefying feedstock and yellow grease includes: a feedstock container to contain a feedstock; a yellow grease container to contain a yellow grease; a hydrothermal liquefaction system configured to receive feedstock from the feedstock container and to receive yellow grease from the yellow grease container; the feedstock received by the hydrothermal liquefaction system and the yellow grease received by the hydrothermal liquefaction system to become a mixture; a controller connected to the feedstock container and the yellow grease container, the controller configured to control the amount of the feedstock supplied from the feedstock container to the hydrothermal liquefaction system, the controller further configured to control the amount of the yellow grease supplied from the yellow grease container to the hydrothermal liquefaction system to be between 10% to 50% of the mixture; and a collector configured to receive a bio-crude from the hydrothermal liquefaction system.

A fast pyrolysis heat exchanger system for economically and efficiently converting biomass and other combustible materials into bio-oil. The system employs multiple closed loop tubes situated inside the heat exchanger. As a granular solid heat carrier is deposited at the top of the heat exchanger and caused to move downwardly therethrough, heat is transferred from the tubes to the heat carrier which is then transferred to a reactor where it is placed in contact with the combustible materials.

A system is provided that enables a continuous process that involves the introduction of particles into a reactor drum having a low oxygen environment. Heavy hydrocarbons are boiled off of the particles during the heating of the particles. The boiled off heavy hydrocarbons mix with a heated gas stream that heats the particles within the reactor drum. The heated gas stream (with the boiled off heavy hydrocarbons) exit the drum and are recirculated back to a heat source for reheating the gas stream prior to reentering the reactor drum. Repeated exposure to the elevated temperatures within the reactor drum cracks the heavy hydrocarbons into lighter hydrocarbons. The lighter hydrocarbons may then be separated out of the heated gas stream and collected for sale or use.

A system is provided that enables a continuous process that involves the introduction of particles into a reactor drum having a low oxygen environment. Heavy hydrocarbons are boiled off of the particles during the heating of the particles. The boiled off heavy hydrocarbons mix with a heated gas stream that heats the particles within the reactor drum. The heated gas stream (with the boiled off heavy hydrocarbons) exit the drum and are recirculated back to a heat source for reheating the gas stream prior to reentering the reactor drum. Repeated exposure to the elevated temperatures within the reactor drum cracks the heavy hydrocarbons into lighter hydrocarbons. The lighter hydrocarbons may then be separated out of the heated gas stream and collected for sale or use.

A process for the production of a fractionated product is disclosed, comprising providing a solid hydrocarbonaceous material, wherein the material is in particulate form, and wherein at least about 90% by volume (% v) of the particles are no greater than about 500 μm in diameter. The solid hydrocarbonaceous material is combined with an unrefined liquid hydrocarbonaceous material, such as crude oil, in order to create a combined solid-liquid blend; and the combined solid-liquid blend is subjected to fractionation in order to generate one or more fractionation products. Typically the solid hydrocarbonaceous material comprises coal, optionally the coal is ultrafine coal, and suitably the coal is comprised of microfine coal. The coal may be dewatered and deashed prior to combination with unrefined liquid hydrocarbonaceous material. Compositions and products of the process are further provided.

A process for the production of a fractionated product is disclosed, comprising providing a solid hydrocarbonaceous material, wherein the material is in particulate form, and wherein at least about 90% by volume (% v) of the particles are no greater than about 500 μm in diameter. The solid hydrocarbonaceous material is combined with an unrefined liquid hydrocarbonaceous material, such as crude oil, in order to create a combined solid-liquid blend; and the combined solid-liquid blend is subjected to fractionation in order to generate one or more fractionation products. Typically the solid hydrocarbonaceous material comprises coal, optionally the coal is ultrafine coal, and suitably the coal is comprised of microfine coal. The coal may be dewatered and deashed prior to combination with unrefined liquid hydrocarbonaceous material. Compositions and products of the process are further provided.

A process for the production of a fractionated product is disclosed, comprising providing a solid hydrocarbonaceous material, wherein the material is in particulate form, and wherein at least about 90% by volume (% v) of the particles are no greater than about 500 μm in diameter. The solid hydrocarbonaceous material is combined with an unrefined liquid hydrocarbonaceous material, such as crude oil, in order to create a combined solid-liquid blend; and the combined solid-liquid blend is subjected to fractionation in order to generate one or more fractionation products. Typically the solid hydrocarbonaceous material comprises coal, optionally the coal is ultrafine coal, and suitably the coal is comprised of microfine coal. The coal may be dewatered and deashed prior to combination with unrefined liquid hydrocarbonaceous material. Compositions and products of the process are further provided.

A process for the production of a fractionated product is disclosed, comprising providing a solid hydrocarbonaceous material, wherein the material is in particulate form, and wherein at least about 90% by volume (% v) of the particles are no greater than about 500 μm in diameter. The solid hydrocarbonaceous material is combined with an unrefined liquid hydrocarbonaceous material, such as crude oil, in order to create a combined solid-liquid blend; and the combined solid-liquid blend is subjected to fractionation in order to generate one or more fractionation products. Typically the solid hydrocarbonaceous material comprises coal, optionally the coal is ultrafine coal, and suitably the coal is comprised of microfine coal. The coal may be dewatered and deashed prior to combination with unrefined liquid hydrocarbonaceous material. Compositions and products of the process are further provided.