The system is provided with: a first heat exchanger which is interposed at an intersection between a rich solution supply line and a lean solution supply line, which has absorbed CO.sub.2 and H.sub.2S extracted from a bottom portion of an absorber, and a regenerated absorbent; a second heat exchanger which is interposed at an intersection between a semi-rich solution supply line and a branch line branched at the branch portion C from the lean solution supply line, and the lean solution; a merging portion which merges a branch line configured to supply the lean solution after heat exchange with the lean solution supply line; and a flow rate adjusting valve which is interposed in the lean solution supply line to adjust the distribution amount of the lean solution.

A system and process for selectively separating H.sub.2S from a gas mixture which also comprises CO.sub.2 is disclosed. A water recycle stream is fed to the absorber in order to create a higher concentration absorbent above the recycle feed and having a greater H.sub.2S selectivity at lower acid gas loadings, and a more dilute absorbent below the recycle feed and having a greater H.sub.2S selectivity at higher acid gas loadings. Also disclosed is a system and process for selectively separating H.sub.2S by utilizing two different absorbents, one absorbent for the upper section of the absorber, tailored to have a greater H.sub.2S selectivity at lower acid gas loadings, and a second absorbent for the lower section of the absorber, tailored to have a greater H.sub.2S selectivity at higher acid gas loadings.

A two-stage electrodialysis system and a method for recovering waste CO.sub.2-lean amine solvent are provided. The system includes an amine solution pretreatment filtering system, a C-A homogeneous membrane electrodialysis device, a BP-A bipolar membrane electrodialysis system, and a CO.sub.2 recovery and capture system. The C-A homogeneous membrane electrodialysis system includes a material chamber, a C-A homogeneous membrane electrodialysis device, a concentrated HSSs waste solution chamber, an electrode solution chamber, and corresponding pipelines and peristaltic pumps. The BP-A bipolar membrane electrodialysis system includes a secondary feed chamber, a BP-A bipolar membrane electrodialysis device, an acid liquor chamber, an electrode solution chamber, and corresponding pipelines and peristaltic pumps. The waste CO.sub.2-lean amine solvent enters the material chamber after passing through the amine solution pretreatment filtering system. The concentrated HSSs waste solution chamber is connected to the secondary feed chamber by a buffer tank.

Systems and methods are provided for performing hydrodeoxygenation of bio-derived feeds while maintaining the hydrodeoxygenation catalyst in a sulfided state. During hydrodeoxygenation, a hydrogen-containing stream is provided to the hydrodeoxygenation reactor as a hydrogen treat gas to provide hydrogen for the reaction. In some aspects, the hydrogen treat gas used for hydrodeoxygenation can be formed at least in part from hydrogen that has been used as a stripping gas for removing H.sub.2S from a rich amine stream. In other aspects, H.sub.2S can be stripped using water vapor, and a resulting overhead HS stream can be compressed prior to incorporation of the H.sub.2S into a hydrogen-containing stream. The resulting hydrogen-containing stream can include sufficient H.sub.2S to substantially maintain the catalyst in the hydrodeoxygenation stage in a sulfided state.

A wet desulfurization apparatus which removes sulfur oxides in flue gas from a boiler 11 includes a mist collection/agglomeration apparatus which is provided on a downstream side of the desulfurization apparatus and forms agglomerated SO.sub.3 mist by causing particles of SO.sub.3 mist contained in flue gas 12B from the wet desulfurization apparatus to be bonded together and have bloated particle sizes; a CO.sub.2 recovery apparatus constituted by a CO.sub.2 absorption tower having a CO.sub.2 absorption unit which removes CO.sub.2 contained in flue gas by being brought into contact with a CO.sub.2 absorbent and an absorbent regeneration tower which recovers CO.sub.2 by releasing CO.sub.2 from the CO.sub.2 absorbent having absorbed CO.sub.2 and regenerates the CO.sub.2 absorbent; and a mist collection unit which collects CO.sub.2 absorbent bloated mist bloated by the CO.sub.2 absorbent being absorbed by the agglomerated SO.sub.3 mist in the CO.sub.2 absorption unit.

The invention generally relates to processes for reducing fouling in amine systems and to equipment useful in such processes. Such amine systems are useful for removing one or more acidic gases such as CO.sub.2 or H.sub.2S from olefin containing hydrocarbon streams. The invention generally relates to minimizing residence time of foulant and foulant precursors at the relatively high temperature found in the amine regenerator and/or to purging the foulant and foulant precursors from the regenerator system. This is accomplished by operating the regenerator column as a stripper (no reflux) and re-routing reflux liquid containing foulant or foulant precursors to a processing location that is less prone to fouling or, optionally, by replacing the reflux liquid with fresh make-up amine or water.

In a hydrocarbon-fed steam methane reformer hydrogen-production process and system, carbon dioxide is recovered in a pre-combustion context, and optionally additional amounts of carbon dioxide are recovered in a post-combustion carbon dioxide removal, to provide the improved carbon dioxide recovery or capture disclosed herein.

The invention relates to a plant for production of hydrogen, and to a method for operating this plant, comprising a steam reforming reactor having a furnace, in which reactor water and at least one carbonaceous energy carrier are reacted to form a hydrogen-containing crude synthesis gas, and at least one cleaning device for purifying the crude synthesis gas, to which the crude synthesis gas is fed from the steam reforming via at least one feed line. According to the invention, upstream of one of the at least one cleaning devices at least one return line branches off from the feed line, through which the crude synthesis gas is at least in part recirculated into the furnace of the steam reforming reactor.

According to embodiment, a carbon dioxide capturing system cools a regenerator discharge gas discharged from a regenerator 5 containing carbon dioxide by a cooling unit 8, and then sends the gas to a cleaner 9. The cleaner 9 receives condensed water generated from the regenerator discharge gas cooled by the cooler 9, and a gaseous cooled regenerator discharge gas, and cleans the cooled regenerator discharge gas by a cleaning liquid. The cleaner 9 has a first liquid reservoir 9b configured to store the condensed water, and a second liquid reservoir 9c configured to store the cleaning liquid having cleaned the cooled regenerator discharge gas.

A carbon dioxide capture process system includes an absorber vessel, a stripper, a first group of sensors and a second group[ of sensors. The first group of sensors is adapted for collecting real-time temperature, pH, density and viscosity data for a lean carbon capture solvent used for carbon capture from an acid gas adjacent the lean carbon capture solvent inlet. The second group of sensors is adapted for collecting real-time temperature, pH, density and viscosity data for a rich carbon capture solvent following carbon capture from the acid gas adjacent the rich carbon capture solvent inlet. A control system and related method are also described.