Processes and systems are provided for converting a carbonaceous feedstock into a reaction gas and a syngas, involving a step of pyrolysing and methanating the feedstock in a pyrolysis chamber to produce the reaction gas and a step of gasifying unconverted feedstock in the presence of a reactant to produce a syngas.

Disclosed is an improved system and method for carrying out the petroleum coking process. The improvements provide for recovery of gaseous hydrocarbons from operational units and use of the recovered gaseous hydrocarbons in place of steam during the coking process and during the stripping of volatile compounds from the coke drums.

Disclosed is an improved system and method for carrying out the petroleum coking process. The improvements provide for recovery of gaseous hydrocarbons from operational units and use of the recovered gaseous hydrocarbons in place of steam during the coking process and during the stripping of volatile compounds from the coke drums.

Processes for quenching coke in a coke drum of a delayed coker unit that more thoroughly cool the coke, eliminate hot spots in the coke bed, and remove residual hydrocarbons from the coke prior to venting the coke drum may comprise a ramp quench phase and a pressure quench phase after the ramp quench phase. During the ramp quench phase, the coke drum internal pressure may rise to a maximum pressure level and then fall to a transitional pressure level. At least one control valve may be actuated at the transitional pressure level to increase the coke drum internal pressure from the transitional pressure level to a pulsed pressure level of the pressure quench phase.

Processes for quenching coke in a coke drum of a delayed coker unit that more thoroughly cool the coke, eliminate hot spots in the coke bed, and remove residual hydrocarbons from the coke prior to venting the coke drum may comprise a ramp quench phase and a pressure quench phase after the ramp quench phase. During the ramp quench phase, the coke drum internal pressure may rise to a maximum pressure level and then fall to a transitional pressure level. At least one control valve may be actuated at the transitional pressure level to increase the coke drum internal pressure from the transitional pressure level to a pulsed pressure level of the pressure quench phase.

In one aspect, the present invention relates to a coke drum module, the coke drum module includes a support frame. A coke drum is disposed within the support frame. A strut is removably connected to the support frame and the coke drum. The strut becomes unloaded responsive to the coke drum contacting a support pad. The coke drum module further includes a compression member removably connected to the support frame and the coke drum. The compression member is oriented generally perpendicularly to the strut. A rigid connection is present between the coke drum and the support frame during transportation of the coke drum module. Upon removal of the strut and the compression member, the rigid connection is not present.

A method for preparing needle coke for ultra-high power (UHP) electrodes from heavy oil is provided. In this method, heavy oil is used as a raw material. The size exclusion chromatography (SEC) is conducted with polystyrene (PS) as a packing material to separate out specific components with a relative molecular weight of 400 to 1,000. The ion-exchange chromatography (IEC) is conducted to remove acidic and alkaline components to obtain a neutral raw material. The neutral raw material is subjected to two-stage consecutive carbonization to obtain green coke, and the green coke is subjected to high-temperature calcination to obtain the needle coke for UHP electrodes. The needle coke has a true density of more than 2.13 g/cm.sup.3 and a coefficient of thermal expansion (CTE) of ≤1.15×10.sup.−6/° C. at 25° C. to 600° C.

A method for preparing needle coke for ultra-high power (UHP) electrodes from heavy oil is provided. In this method, heavy oil is used as a raw material. The size exclusion chromatography (SEC) is conducted with polystyrene (PS) as a packing material to separate out specific components with a relative molecular weight of 400 to 1,000. The ion-exchange chromatography (IEC) is conducted to remove acidic and alkaline components to obtain a neutral raw material. The neutral raw material is subjected to two-stage consecutive carbonization to obtain green coke, and the green coke is subjected to high-temperature calcination to obtain the needle coke for UHP electrodes. The needle coke has a true density of more than 2.13 g/cm.sup.3 and a coefficient of thermal expansion (CTE) of ≤1.15×10.sup.−6/° C. at 25° C. to 600° C.

A method of oxidative pyrolysis involves heating hydrocarbon feedstock, heating a steam-oxygen mixture, combusting hydrocarbon feedstock in vapors of a steam-oxygen mixture in a special reactor, rapidly cooling the obtained products of incomplete combustion of chemical reactions in two steps, after which the cooled steam-gas mixture is directed to the fractionation unit. A hydrocarbons pyrolysis device has a steam-oxygen mixture and feedstock mixing chamber, a pyrolysis chamber and a coking reactor, a device for heating hydrocarbon feedstock, a device for heating steam-oxygen mixture coupled to a mixing chamber, a coking reactor having a device for supplying coolant to the pyrogas flow, a separation unit coupled to the coking reactor, a fractionation unit with an additional coolant supply device. Disposal of heavy oil residues by rapid coking with high economic efficiency and environmental safely while obtaining high-quality coke and producing aromatic compounds occurs without construction or additional installations.

A method of oxidative pyrolysis involves heating hydrocarbon feedstock, heating a steam-oxygen mixture, combusting hydrocarbon feedstock in vapors of a steam-oxygen mixture in a special reactor, rapidly cooling the obtained products of incomplete combustion of chemical reactions in two steps, after which the cooled steam-gas mixture is directed to the fractionation unit. A hydrocarbons pyrolysis device has a steam-oxygen mixture and feedstock mixing chamber, a pyrolysis chamber and a coking reactor, a device for heating hydrocarbon feedstock, a device for heating steam-oxygen mixture coupled to a mixing chamber, a coking reactor having a device for supplying coolant to the pyrogas flow, a separation unit coupled to the coking reactor, a fractionation unit with an additional coolant supply device. Disposal of heavy oil residues by rapid coking with high economic efficiency and environmental safely while obtaining high-quality coke and producing aromatic compounds occurs without construction or additional installations.