Chemical apparatus and process disinfecting – deodorizing – preser – Chemical reactor – Fluidized bed
Reexamination Certificate
1999-03-17
2003-01-07
Johnson, Jerry D. (Department: 1764)
Chemical apparatus and process disinfecting, deodorizing, preser
Chemical reactor
Fluidized bed
C422S139000, C422S141000, C422S142000, C422S144000, C422S145000, C432S058000
Reexamination Certificate
active
06503460
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to catalyst regeneration in fluidized catalytic cracking units, more particularly to a regenerator system employing a baffled fluidized bed for two-stage catalyst regeneration.
BACKGROUND OF THE INVENTION
Improvements in fluid catalytic cracking (FCC) technology have continued to make this conventional workhorse process more reliable and productive. In recent years, much of the activity in FCC development has focused on the reaction side of the process. However, the importance of improving regenerator design has increased as more refiners process resid-containing feedstocks and as environmental restrictions on emissions become tighter.
Continuous catalyst regeneration is a key element of the FCC process. It continuously restores catalytic activity by combusting the coke deposited on the catalyst and it provides the heat required for the process. In FCC units processing high-resid feedstocks, the re-generator must also remove excess heat generated by the high coke make caused by contaminants in the feed.
Ideally, the regeneration system accomplishes these goals in an environment that preserves catalyst activity and selectivity so that catalyst makeup is minimized and reactor yields are optimized. Environmental regulations on particulate and NO
x
emissions impose additional constraints. The ideal regeneration system would regenerate catalyst uniformly to low carbon levels, minimize catalyst deactivation, reduce vanadium mobility and limit catalyst poisoning, reduce particulate emissions, provide operational flexibility, offer high mechanical reliability, and minimize complexity and capital cost. An important principle in regenerator design is to minimize the size and mechanical complexity of the regenerator and its internals, consistent with meeting the process performance criteria.
FCC units processing high-resid feedstocks need to deal effectively with heavy feed components rich in nickel, vanadium, and Conradson Carbon Residue (CCR). While each of these contaminants affects the performance of the unit in different ways, the latter two present significant challenges to the design of the regenerator. CCR in the feed increases the coke make and can lead to excessively high regenerator temperatures. Heat must be removed from the system to achieve acceptably high catalyst-to-oil ratios and avoid exceeding regenerator metallurgy temperature limits. One option is to limit the heat release in the regenerator by operating in a partial CO combustion mode. The heat of CO combustion is released in a downstream CO boiler. Another option is to install a catalyst cooler. The excess heat is directly removed from the catalyst and is used to generate high-pressure steam.
Although nickel and vanadium both deposit quantitatively on the catalyst, nickel forms stable compounds which remain on the outer surface of the catalyst. The oldest catalyst particles contain the highest levels of nickel. Vanadium is much more destructive than nickel. In the presence of high temperatures, excess oxygen, and steam, it redistributes over the entire catalyst inventory, contaminating both new and old catalyst and destroying catalyst activity. This phenomenon reduces the equilibrium activity of the unit inventory because most of the catalytic activity is derived from the newest catalyst particles. The reactions characterizing vanadium mobility are as follows:
V
2
O
5
generated in oxidative environment:
4 V+5O
2
→2V
2
O
5
Migration to other particles via volatile vanadic acid:
V
2
O
5
+3H
2
O →2VO(OH)
3
To mitigate these effects, it is wise to design for partial combustion of CO in the regenerator when processing feedstocks with high vanadium and CCR contents. By restricting vanadium mobility, premature deactivation of the fresh catalyst is prevented and the catalyst equilibrates at a higher activity for a given metal level.
Operating the regenerator in partial CO combustion mode is an attractive option because it (1) reduces catalyst makeup rate by limiting vanadium mobility in the regenerator and vanadium-induced deactivation of the catalyst; (2) can eliminate the need for a catalyst cooler when processing moderately contaminated feeds, or it can reduce the size of the catalyst cooler required for heavily contaminated feeds; (3) reduces the size of the regenerator vessel and air blower; and (4) reduces NOx emissions.
Unfortunately, there are drawbacks as well. In a partial combustion operation, it is difficult to burn all of the carbon off the catalyst. Residual carbon can have a negative effect on catalyst activity. (For the purposes of the present specification and claims, we will define “cleanly burned catalyst” as containing≦0.1 wt % carbon.) At a CO
2
/CO ratio of about 3.5:1, the regenerated catalyst from a conventional single-stage regenerator may contain 0.15-0.25% carbon.
FIG. 1
shows the relationship between catalyst activity and carbon-on-regenerated-catalyst. In this example, dropping the carbon level from 0.25% to 0.10% increases the MAT activity by about 3-4 vol % (per ASTM D-3907).
One way to achieve the goal of burning the catalyst clean in partial combustion operation is to utilize what is referred to in the art as two-stage regeneration. In this type of design, multiple regenerator vessels are operated in series with either cascading or separate flue gas trains. The first stage operates in partial combustion and the second stage operates in complete combustion. While they can achieve low levels of carbon-on-catalyst, these two-stage designs are more mechanically complex, more expensive, and more difficult to operate than a single-stage regenerator.
U.S. Pat. No. 4,615,992 to Murphy discloses a horizontal baffle device or subway grating 2 to 4 feet below the catalyst bed level in a regenerator operating in complete combustion mode. The baffle device is said to eliminate the need for catalyst distribution troughs and aerators.
Other U.S. Patents of interest include U.S. Pat. No. 3,785,620 to Huber; U.S. Pat. No. 4,051,069 to Bunn, Jr. et al.; U.S. Pat. No. 4,150,090 to Murphy et al.; U.S. Pat. No. 4,888,156 to Johnson; U.S. Pat. No. 5,156,817 to Luckenbach; U.S. Pat. No. 5,635,140 to Miller et al.; and U.S. Pat. No. 5,773,378 to Busey et al. EPA 94-201,077 discloses radial distribution of fluid into a catalyst bed in a regenerator vessel.
SUMMARY OF THE INVENTION
We have invented a regeneration system which achieves complete removal of carbonaceous deposits from spent fluid catalytic cracking catalyst in a single regeneration vessel while operating in an environment of incomplete combustion which could only be accomplished in the prior art by using multiple regenerator vessels. Furthermore, our system reduces entrainment of catalyst into the dilute phase of the regenerator, thus reducing particulate emissions and mechanical wear on the regenerator cyclones. These benefits are achieved by placing a baffle in the regenerator to reduce backmixing between the upper and lower sections of the fluidized bed. A spent catalyst distributor, which evenly distributes catalyst across the top of the upper bed is also an important part of the invention.
In one aspect, the present invention provides a catalyst regenerator for removing carbon from fluid catalytic cracking (FCC) catalyst circulated in a FCC unit. The regenerator includes a vessel comprising a dilute phase and a dense phase fluidized catalyst bed disposed in respective upper and lower regions of the vessel. A spent catalyst distributor is provided for distributing spent catalyst feed preferably radially outwardly from a central pipe or well, into the vessel adjacent a top of the dense phase fluidized catalyst bed. An air grid is disposed adjacent a bottom of the dense phase fluidized catalyst bed for introducing oxygen-containing aeration fluid into the vessel. A baffle is disposed between the spent catalyst distributor and the air grid. The baffle can divide the dense phase bed into upper and lower stages, wherein aeration fluid leaving the upper stage contains CO and
Miller Richard B.
Yang Yong-Lin
Doroshenk Alexa A.
Johnson Jerry D.
Kellogg Brown & Root Inc.
Kellogg Brown & Root, Inc.
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