A system includes a heat exchange system and a power generation system. The heat exchange system includes first, second, and third heat exchangers each operable as a continuous source of heat from a delayed coking plant. The first and second heat exchangers heat first and second fluid streams to produce heated first and second fluid streams, respectively. The heated second fluid stream has a lower temperature and a greater quantity of heat than the heated first fluid stream. The third heat exchanger heats a third fluid stream to produce a heated third fluid stream that includes the heated first fluid stream and a hot fluid stream. The heated third fluid stream has a lower temperature than the heated first fluid stream. The power generation system generates power using heat from the heated second and third fluid streams.

A system includes a heat exchange system and a power generation system. The heat exchange system includes first, second, and third heat exchangers each operable as a continuous source of heat from a delayed coking plant. The first and second heat exchangers heat first and second fluid streams to produce heated first and second fluid streams, respectively. The heated second fluid stream has a lower temperature and a greater quantity of heat than the heated first fluid stream. The third heat exchanger heats a third fluid stream to produce a heated third fluid stream that includes the heated first fluid stream and a hot fluid stream. The heated third fluid stream has a lower temperature than the heated first fluid stream. The power generation system generates power using heat from the heated second and third fluid streams.

A system includes a heat exchange system and a power generation system. The heat exchange system includes first, second, and third heat exchangers each operable as a continuous source of heat from a delayed coking plant. The first and second heat exchangers heat first and second fluid streams to produce heated first and second fluid streams, respectively. The heated second fluid stream has a lower temperature and a greater quantity of heat than the heated first fluid stream. The third heat exchanger heats a third fluid stream to produce a heated third fluid stream that includes the heated first fluid stream and a hot fluid stream. The heated third fluid stream has a lower temperature than the heated first fluid stream. The power generation system generates power using heat from the heated second and third fluid streams.

Systems and methods for safe on-line pigging decoking of a coker furnace tubes and which also permits on-line spalling operations.

A distillation apparatus for use in microwave-assisted pyrolysis includes a microwave, a pyrolysis reactor, a microwave-absorbent bed, and a condenser. The pyrolysis reactor is located within the microwave and configured to receive a liquid input stream and to output a vapor. The microwave-absorbent bed is located within the pyrolysis reactor that converts microwave energy provided by the microwave to thermal energy to initiate pyrolysis within the pyrolysis reactor, wherein the pyrolysis reactor provides a vapor output. The condenser is configured to receive the vapor output of the pyrolysis reactor and to cool and condense the vapor into a recoverable product.

A distillation apparatus for use in microwave-assisted pyrolysis includes a microwave, a pyrolysis reactor, a microwave-absorbent bed, and a condenser. The pyrolysis reactor is located within the microwave and configured to receive a liquid input stream and to output a vapor. The microwave-absorbent bed is located within the pyrolysis reactor that converts microwave energy provided by the microwave to thermal energy to initiate pyrolysis within the pyrolysis reactor, wherein the pyrolysis reactor provides a vapor output. The condenser is configured to receive the vapor output of the pyrolysis reactor and to cool and condense the vapor into a recoverable product.

An insulated pressure vessel, such as a coke drum, having an insulation system installed thereon. The insulation system includes an insulation support system comprising either a floating ring type support system, or a cage type support system including a plurality of vertically spaced insulation support rings each having a diameter greater than the external diameter of the coke drum. A plurality of insulation panels are secured to the support rings, each panel including insulation material and an exterior metal jacket. The panels are secured to horizontally adjacent insulation panels with standing seams. Weather shields may be provided over the top of the seams. Tensioned insulation securing cables, corresponding in number to the insulation support rings, are routed through horizontally aligned eyelets in each standing seam.

An insulated pressure vessel, such as a coke drum, having an insulation system installed thereon. The insulation system includes an insulation support system comprising either a floating ring type support system, or a cage type support system including a plurality of vertically spaced insulation support rings each having a diameter greater than the external diameter of the coke drum. A plurality of insulation panels are secured to the support rings, each panel including insulation material and an exterior metal jacket. The panels are secured to horizontally adjacent insulation panels with standing seams. Weather shields may be provided over the top of the seams. Tensioned insulation securing cables, corresponding in number to the insulation support rings, are routed through horizontally aligned eyelets in each standing seam.

The present invention pertains to the recovery, separation and the unique product mixtures obtained by recovery and separation of coal-tar oils produced from low-rank-coal by a novel mild-temperature pyrolysis [MTP] process originating at the point where the vapor phase exits the pyrolysis reactor. Mild-temperature pyrolysis [MTP] takes place below 1200 F. in contrast to the high-temperature pyrolysis [HTP] that is operated at 1600-2000 F. for coke oven processing of metallurgical coke. The yield and composition of coal-tar-oil recovered from MTP are quite different from HTP coal-tar. In order to optimize the oil recovery process, the most appropriate recovery and separation processes therefore also will be different. The MTP process produces coal-tar containing a major fraction of strongly polar compounds mixed with non-polar compounds that separates into several liquid phases and overlap in their distillation ranges. This invention addresses the distinct product fractions obtained from MTP and the integrated multi step oil recovery and product separation process, which is designed with the objective to improve and facilitate the product separation, decrease the required amount of energy for separation and equipment cost for downstream processing.

Systems and methods are provided for pretreatment and upgrading of crude bio oils for further processing and/or use as fuel products. Crude bio oils can be treated by one or more of flash fractionation and thermal cracking to generate fractions suitable for further processing, such as further hydroprocessing. Blending of crude bio oil fractions with mineral feeds can also be used to reduce metals contents to levels suitable for refinery processing.