The apparatus and method of the invention will be described in further detail below and with reference to the attached drawings where the same or similar elements are referred to by the same numerals, and in which:
As indicated above, the method and apparatus of the present invention can be employed with any number of FCC process units known to the prior art. With reference to
In this continuous process, the mixture of catalyst and FCC reactor feedstream proceed upward through the riser into a reaction zone in which the temperature, pressure and residence time are controlled within ranges that are conventional and related to the operating characteristics of the one or more catalysts used in the process, the configuration of the apparatus, the type and characteristics of the feedstock and a variety of other parameters that are well known to those of ordinary skill in the art and which form no part of the present invention. The reaction product is withdrawn through conduit (16) for recovery and/or further processing in the refinery.
The spent catalyst from the FCC unit is withdrawn via transfer line (18) for delivery to the lower portion of regeneration vessel (20), most conveniently located in relatively close proximity to FCC unit (10). The spent catalyst entering through transfer line (18) is contacted by at least a stream of air admitted through conduit (24) for controlled combustion of accumulated coke. The flue gases are removed from the regenerator (20) via conduit (26), and the temperature of the regenerated catalyst is raised by the combustion of the coke to provide heat for the endothermic cracking reaction.
Referring now to
Although a variety of catalysts can be utilized in the process, it will be understood that the same catalyst used in the main FCC unit is also employed in the catalytic cracking of the heavy oil feedstream in the ancillary downflow reactor (30). Typical FCC units utilize zeolites, silica-alumina, carbon monoxide burning promoter additives, bottom cracking additives and light olefin promoting additives. In the practice of the invention it is preferred that zeolite catalysts of the Y, REY, USY and RE-USY types be used alone or in combination with a ZSM-5 catalyst additive. As will be understood by those of ordinary skill in this art, the catalysts and additives are preferably selected to maximize and optimize the production of light olefins and gasoline. The choice of the catalyst(s) system does not form a part of the present invention.
With continuing reference to
Stripping steam is admitted through line (36) to drive off any removable hydrocarbons from the spent catalyst. The product gases are discharged from the reaction zone (33) of the downflow reactor (30) and introduced into the upper portion of the stripper vessel (37) where they combine with the stripping steam and other gases and vapors and pass through cyclone separators (39) and out of the stripper vessel via product line (34) for product recovery in accordance with methods known to the art.
The spent catalyst recovered from the downflow reactor (30) is discharged through transfer line (40) and admitted to the lower end of the diptube, or lift riser, (29) which extends from the catalyst regenerator (20) that has been modified in accordance with the method of this invention. In this embodiment, air is introduced below the spent catalyst transfer line (40) at the end of diptube or lift riser (29) via pressurized air line (25). A more detailed description of the functioning of the secondary downflow reactor is provided below.
The configuration and selection of materials for the downflow reactor (30), as well as the specific operating characteristics and parameters will be dependent upon the specific qualities and flow rate of the heavy oil feed introduced at the feedstock line (32), which in turn will be dependent upon the source of the feedstock. More detailed operating conditions are set forth below.
With continuing reference to
The reaction temperature, i.e., the outlet temperature of the downflow reactor, is controlled by opening and closing a catalyst slide valve (not shown) that controls the flow of regenerated catalyst from the withdrawal well (31) and into the mix zone. The heat required for the endothermic cracking reaction is supplied by the regenerated catalyst. By changing the flow rate of the hot regenerated catalyst, the operating severity or cracking conditions can be controlled to produce the desired yields of light olefinic hydrocarbons and gasoline.
The heavy oil feedstock (32) is injected into the mixing zone through feed injection nozzles (32a) placed in the immediate vicinity of the point of introduction of the regenerated catalyst into the downflow reactor (30). These multiple injection nozzles (32a) result in the catalyst and oil being mixed thoroughly and uniformly. Once the feedstock contacts the hot catalyst the cracking reactions occur. The reaction vapor of hydrocarbon cracked products and unreacted heavy oil feed and catalyst mixture quickly flows through the remainder of the downflow reactor and into a rapid separation section (35) at the bottom portion of the reactor. The residence time of the mixture in the reaction zone is controlled in accordance with apparatus and procedures known to the art.
If necessary for temperature control, a quench injection (50) is provided near the bottom of the reaction zone (33) immediately before the separator. This quench injection quickly reduces or stops the cracking reactions and can be utilized for controlling cracking severity and allows for added process flexibility.
The rapid separator (35) along with the end portion of the downflow reactor (30) is housed in the upper section of a large vessel referred to as the catalyst stripper (37). The rapid separator directs the reaction vapor and catalyst directly into the top part the stripper vessel (37).
The reaction vapors move upwardly from the rapid separator outlet into the stripper, combine with stripped hydrocarbon product vapors and stripping gas from the catalyst stripping section of this vessel and pass through conventional separating means such as one or more cyclones (39), which further separate any entrained catalyst particles from the vapors. The catalyst from the separator that is captured in the cyclones is directed to the bottom of the stripper vessel (37) through a cyclone dipleg for discharge into the bed of catalyst that was recovered from the rapid separator in the stripping section.
After the combined vapor stream passes through the cyclones and out of the stripper vessel, it is directed through a conduit or pipe commonly referred to as a reactor vapor line (34) to a conventional product recovery section known in the FCC art.
The catalyst from the rapid separator and cyclone diplegs flows to the lower section of the stripper vessel that includes a catalyst stripping section into which a suitable stripping gas, such as steam, is introduced through line (36). The stripping section is provided with several baffles or structured packing (not shown) over which the downwardly flowing catalyst passes counter-currently to the flowing stripping gas. The upwardly flowing stripping gas, which is typically steam, is used to remove any additional hydrocarbons that remain in the catalyst pores or between catalyst particles.
The stripped catalyst is transported by the combustion air stream (25) through a lift riser (29) that terminates in the existing, but modified, regenerator (20) in a typical FCC process to burn off any coke that is a by-product of the cracking process. In the regenerator, the heat produced from the combustion of the by-product coke produced in the first reaction zone (10 and 14) of a typical FCC process from cracking heavy hydrocarbons and from the heavy oil cracking in zone (33) of the downflow reactor (30) is transferred to the catalyst.
The regenerator vessel (20) can be of any conventional previously known design and can be used with the enhanced process and downflow reaction zone of this invention. When modified for the practice of the invention, the placement of the regenerator-to-reactor conduit (28) or regenerated catalyst transfer line for the regenerator will be such that it insures a steady and continuous flow of a substantial quantity of regenerated catalyst that is needed to meet the maximum design requirements of the downflow reactor.
The catalyst requirements for the process of the invention can be determined in conjunction with any catalyst conventionally used in FCC processes, e.g., zeolites, silica-alumina, carbon monoxide burning promoter additives, bottoms cracking additives, light olefin-producing additives and any other catalyst additives routinely used in the FCC process. The preferred cracking zeolites in the FCC process are zeolites Y, REY, USY, and RE-USY. For the entranced production of light olefins, a preferred shaped selective catalyst additive typically used in the FCC process to produce light olefins and increase FCC gasoline octane is ZSM-5 zeolite crystal or other pentasil type catalyst structure. This ZSM-5 additive is mixed with the cracking catalyst zeolites and matrix structures in the conventional FCC catalyst and is preferably used in the method of the invention to maximize and optimize light olefin production in the ancillary downflow reactor.
A particular advantage of the present invention as an enhancement to existing FCC processes for co-processing heavy oils is that separate recovery of the products from each reactor for further downstream processing can be provided. The method and apparatus of the invention provides enhanced product recovery in conjunction with the existing FCC reactor thereby effectively increasing the overall capacity of the FCC unit process to produce more light olefins to meet the growing commercial demands described above. In addition, the process has the advantage that the products can be recovered in the existing section of the FCC unit without the need for additional facilities and capital expenditures.
The following comparative example illustrates the improvement in product yield when an existing convention FCC unit is provided with the enhancement of the down flow reactor of the present invention to increase the yield of light olefins. The product yields are typical for an FCC unit operating on unhydrotreated Middle East vacuum gasoil (VGO) feedstock. The downflow reactor yields are based on a bench scale pilot plant results representing the cracking conditions in the downflow reactor using hydrotreated Middle East vacuum gasoil. In this example the catalyst systems are similar and use USY zeolite.
The following Table summarizes the yield improvement in the production of light olefins when utilizing the downflow enhancement with a feedstock that is different than the feedstock provided to the conventional FCC unit.
As reported in the table, the total weight percent of the light olefins (C2′, C3 and C4) produced in the conventional FCC unit was 10.41, while the method of the invention increased the yield of these compounds to 39.86 weight percent.
These comparative examples also indicate that two different feedstocks can be introduced and the processes operated at different severities in order to produce these yields.
It will be understood that the embodiments described above are illustrative of the invention and that various modifications can be made by those of ordinary skill in the art that will be within the scope of the invention, which is to be determined by the claims that follow.