FIELD OF TEH INVENTION

This invention is related to catalytic cracking of hydrocarbons. It more particularly refers to a novel cracking catalyst that, when regenerated, produces a flue gas with ecologically acceptable concentration of carbon monoxide and noxious nitrogen oxides. It further refers to a novel catalytic cracking process which produces a flue gas with little or no content of noxious nitrogen oxides and CO.

BACKGROUND OF THE INVENTION

In recent years there has been an increased concern in the United States and elsewhere about air pollution from industrial emissions of noxious oxides of nitrogen, sulfur and carbon. Government agencies, in response to such concerns, have in some cases already placed limits on allowable emissions of one or more of the pollutants, and the trend is clearly in the direction of increasingly stringent restrictions. Petroleum fuel refineries are particularly affected by present and anticipated restrictions on emissions, particularly emissions of nitrogen oxides and carbon monoxide. Catalytic cracking, a major petroleum refinery process, is the largest single source of nitrogen oxides in such refineries.

Fluid catalytic cracking of petroleum hydrocarbons to lower molecular weight products is a well known process. This process is practiced industrially in a cyclic mode wherein hydrocarbon feedstock is contacted with hot, active, solid particulate catalyst and without added hydrogen at rather low pressures of up to about 50 psig and temperatures sufficient to support the desired cracking. As the hydrocarbon feed is cracked to more valuable and desirable products, "coke" is deposited on the catalyst particles. It should be noted that substantially all of the organic nitrogen in the feedstock to the cracker is incorporated with the coke deposit. The coked catalyst particles are disengaged from the hydrocarbon products and contacted with an oxygen containing gas in a regenerator whereupon coke is burned away from the particles to regenerate their catalytic activity. The heated, regenerated catalyst particles are then returned to the cracking zone and contacted with additional hydrocarbon feed and the cycle is repeated. The phrase "circulating inventory of cracking catalyst" as used herein includes the total catalyst contained in the cracking and regenerator sections of the cracking plant, including transfer lines, standpipe, etc.

In general, when coke is burned with a deficiency of oxygen, the regenerator flue gas has a high CO/CO.sub.2 ratio and a low level of nitrogen oxides, but when burned with excess oxygen, the flue gas has a high level of such nitrogen oxides and a reduced CO content. Thus, catalytic cracking regenerators emit CO, or nitrogen oxides, or mixtures of these pollutants with the flue gas in varying quantities, depending on feed quality, mode of operation of the regenerator, etc.

Although several nitrogen oxides are known which are relatively stable at ambient conditions, it is generally recognized that two of these, viz. nitric oxide (NO) and nitrogen dioxide (NO.sub.2), are the principal contributors to smog and other undesirable environmental effects when they are discharged into the atmosphere. These effects will not be discussed further here since they are well recognized.

Nitric oxide and nitrogen dioxide, under appropriate conditions, are interconvertible according to the equation

2NO+O.sub.2 =2NO.sub.2.

For purposes of the present invention, NO.sub.x will be used herein to represent nitric oxide, nitrogen dioxide (the principal noxious oxides of nitrogen), and/or mixtures thereof.

U.S. Pat. No. 3,900,554 to Lyon describes a homogeneous gas phase thermal reaction to remove NO.sub.x from combustion effluent by adding 0.4 to 10 moles (preferably 0.5 to 1.5 moles) of ammonia followed by heating to 1600.degree. C. to 2000.degree. C. The NO.sub.x content is lowered as a result of its being reduced to nitrogen by reaction with ammonia. The so-called "selective catalytic reduction" type process which operates at a much lower temperature, 200.degree. to 600.degree. C., is exemplified by U.S. Pat. No. 4,220,632 to Pence et al., which describes a process for reducing NO.sub.x from a fossil fuel fired power generation plant, or from other industrial plant off-gas stream, to elemental nitrogen and/or innocuous nitrogen oxides by employing ammonia as reductant and, as catalyst, the hydrogen or sodium form of a zeolite having pore openings of about 3 to 10 Angstroms.

When incomplete combustion of coke in the regenerator of a fluid catalytic cracking plant leaves a significant amount of carbon monoxide (CO) in the flue gas, such flue gas not only emits CO to the atmosphere, but also tends to sporadically burn (by reaction of CO with residual oxygen) in ducts and flues of the plant (afterburning), damaging these structures by excessive temperatures. It is now known that trace amounts of a platinum group metal, such as 1.0 parts per million of platinum incorporated with the cracking catalyst, effectively catalyzes the complete burning of carbon monoxide to carbon dioxide in the regenerator without detriment to the cracking reaction. This development simultaneously eliminated the environmental problem and the problem of sporadic afterburning, and has been very widely accepted by refiners. Such catalysts and their use are described in U.S. Pat. Nos. 4,251,395, 4,265,787, 4,088,568, 4,072,600, 4,093,535 and 4,159,239, all to Schwartz, and are incorporated herein by reference for further details on composition and use. As described therein, such promoted catalysts may be used to completely burn CO (referred to hereinbelow as "full CO-combustion") or to only partially burn the CO (referred to hereinbelow as "partial CO-combustion") by the simple expedient of limiting the oxygen supplied to the regenerator. The term "Pt group metal CO-oxidation promoter" as used herein means those metals and their mode of use as taught by the Schwartz patents cited above. Operation with CO-combustion promoters, which solves the CO emissions problem, can in some instances increase the NO.sub.x emissions.

Although most petroleum cracking is conducted with fluid beds, non-fluid catalyst beds also may be used. Such processes also are operated continuously and in cyclic fashion, with movement of the catalyst against gravity being effected, as needed, pneumatically or mechanically. One typical example of industrially practiced moving bed hydrocarbon catalytic cracking is known as Thermofor Catalytic Cracking (TCC). In this process the catalyst is in the shape of beads or pellets having an average particle size of about 1/64 to 1/4 inch, preferably about 1/8 inch. In contrast with these particles, in fluid catalytic cracking (FCC) the catalyst is a fine powder of about 10 to 200 microns, preferably about 70 micron size. The problems encountered with NO.sub.x and CO emissions in fluid catalytic cracking exist also with the moving bed type processes. Although the description herein, for simplicity, is couched in terms of fluid catalytic cracking, it is contemplated that the invention encompasses both fluid and moving-bed type processes.

The catalysts used in endothermic nonhydrogenative cracking are to be distinguished from catalysts used in exothermic hydrocracking. Operating conditions also are different. While the catalytic cracking processes to which this invention is directed operate at low pressures near atmospheric and in the absence of added hydrogen, hydrocracking is operated with added hydrogen at pressures of up to about 1000 to 3000 psig. Further, nonhydrogenative catalytic cracking is a reflexive process with catalyst cycling between cracking and regeneration (coke burn off) over a very short period of time, such as seconds or minutes. In hydrocracking, on the other hand, a fixed bed of catalyst usually remains in cracking service for months between regeneration. Another important difference is in the product. Nonhydrogenative catalytic cracking produces a highly unsaturated product with substantial quantities of olefins and aromatics, and a high octane gasoline fraction. Hydrocracking, in contrast, produces an essentially olefin-free product and a relatively low octane gasoline. The present invention is not directed to hydrocracking nor is it within the scope of this invention to use hydrocracking catalysts.

We have now found that NO.sub.x emissions formed in cracking catalyst regeneration can be dramatically reduced or eliminated without resorting to the very high temperatures required for the gas phase thermal reaction with NH.sub.3, and without adding ammonia at all, and without providing expensive downstream facilities to clean up the flue gas.

It is an object of this invention to provide a novel cracking catalyst composition which reduces emissions of NO.sub.x and/or CO from the regenerator of a fluid catalytic cracking plant.

It is a further object to provide an improved fluid catalytic cracking process that utilizes such catalyst.

It is a further object of this invention to provide a means for reducing NO.sub.x emissions when operating a fluid catalytic cracking plant in the full CO-burning mode.

These and other objects of this invention will become apparent from this entire specification including the appended claims.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1(A), 1(B). Effluent Species Profiles, Regeneration of Coked FCC Catalyst Without Additive.

FIG. 2. Illustrates NO.sub.x reduction, Example 8.

FIG. 3. Illustrates CO reduction, Example 8.

FIG. 4. Illustrates effect of additive concentration on peak NO.sub.x reduction, Example 8.

FIG. 5. Illustrates effect of additive concentration on integrated NO.sub.x reduction, Example 8.

FIG. 6. Illustrates effect of additive concentration on continuous regeneration.

FIG. 7. Exemplifies a fluid catalytic cracking apparatus.

FIG. 8. Illustrates a swirl regenerator.

BRIEF SUMMARY OF THE INVENTION

This invention provides a novel means for reducing or eliminating the emission of NO.sub.x with a flue gas from the regenerator of a catalytic cracking plant. This is accomplished by incorporating into the circulating catalyst inventory of a catalytic cracking unit an amount of additive particles comprising a highly siliceous crystalline zeolite, said zeolite preferably having the crystal structure of ZSM-5, ZSM-11, ZSM-12, ZSM-22, ZSM-23, ZSM-35, ZSM-38, ZSM-48, mordenite, dealuminated Y or Zeolite Beta and a silica to alumina ratio of 20 to 100, said zeolite containing copper metal or ions preferably equivalent to at least one half mole of CuO for each mole of Al.sub.2 O.sub.3 in said zeolite, with said amount of additive particles constituting 0.1 to 30 wt %, and preferably 0.1 to 10 wt % of said circulating inventory including additive.

The advantage of the method of this invention is its simplicity: no modification of the catalytic cracking equipment is required, nor is there any necessity for expensive downstream facility such as would be required in the downstream treatment of the flue gas to reduce its NO.sub.x content. As will be shown hereinbelow, the invention also is effective to reduce carbon monoxide emissions. It is also contemplated that gasoline octane will also be somewhat improved by the use of a preferred embodiment of this invention.

This invention also provides a novel cracking catalyst which may be prepared in situ as described above; or, alternatively, as a preformed mixture of conventional cracking catalyst and the additive comprising the highly siliceous zeolite that contains copper or copper ion.

DESCRIPTION AND PREFERRED EMBODIMENTS

The cracking catalyst composition of this invention consists of 99.9 to 70.0 wt % of a solid acidic cracking catalyst, herein referred to as the host catalyst, and 0.1 to 30.0 wt % of additive particles. A preferred range for the host catalyst is 99.9 to 90.0 wt % with 0.1 to 10.0 wt % of additive particles.

As host catalyst, any solid acidic cracking catalyst free of added copper may be used, including amorphous catalysts such as those based on silica alumina and silica magnesia, for example. The term "added copper" means copper deliberately added by impregnation or ion-exchange, and excludes copper which may be acquired from trace amounts in the feed, for example.

The preferred host catalyst is one prepared, for example, by compositing a major portion of amorphous catalyst with a minor portion of an active crystalline aluminosilicate zeolite. Catalysts of this type for FCC and TCC are described in U.S. Pat. Nos. 3,140,249 and 3,140,253, the disclosures of which are hereby incorporated by reference. The active crystalline aluminosilicate component of such catalysts, usually a large pore zeolite of the faujasite crystal type, imparts high activity with very good selectivity to the cracking catalyst. Such catalysts have become very widely used in fluid catalytic cracking, supplanting the older amorphous synthetic silica-alumina catalysts almost completely. The term "zeolite cracking catalyst" as used herein means a catalyst essentially of the type described in U.S. Pat. Nos. 3,140,249 and 3,140,253, and variants thereof, such as those which also include a ZSM-5 type zeolite, exemplified by U.S. Pat. Nos. 3,758,403; 4,309,279; and 4,309,280, all of which are included herein by reference.

The additive employed with the host catalyst is prepared from a highly siliceous crystalline zeolite having a silica to alumina ratio of 20:1 to 100:1 and a pore size of about 5 to 13 Angstroms. The preferred highly siliceous zeolites useful for this purpose include ZSM-5, ZSM-11, ZSM-12, ZSM-22, ZSM-23, ZSM-35, ZSM-38, ZSM-48, mordenite, dealuminated Y and Zeolite Beta, all of which are known.

U.S. Pat. No. 3,702,886 describing and claiming ZSM-5 is incorporated herein by reference.

ZSM-11 is more particularly described in U.S. Pat. 3,709,979, the entire content of which is incorporated herein by reference.

ZSM-12 is more particularly described in U.S. Pat. 3,832,449, the entire content of which is incorporated herein by reference.

ZSM-22 is more particularly described in U.S. Pat. 4,481,177, the entire content of which is incorporated herein by reference.

ZSM-23 is more particularly described in U.S. Pat. 4,076,842, the entire content of which is incorporated herein by reference.

ZSM-35 is more particularly described in U.S. Pat. 4,016,245, the entire content of which is incorporated herein by reference.

ZSM-38 is more particularly described in U.S. Pat. 4,046,859, the entire content of which is incorporated herein by reference.

ZSM-48 is more particularly described in U.S. Pat. 4,397,827 of which is incorporated herein by reference.

Zeolite Beta is more particularly described in U.S. Pat. 3,308,069, the entire content of which is incorporated herein by reference.

For purposes of this invention, any of the described zeolites may be used as such as the starting material. Alternatively, the zeolite may be incorporated in a binder (matrix) such as silica, silica alumina, alumina, clay or other known inorganic binder, and used in this form as the starting material. Regardless of whether the zeolite is in pure form or incorporated in a matrix, it is preferred that it be in the hydrogen, ammonium, or sodium form prior to loading with metals as described hereinbelow. If in a matrix, it is bound and shaped to match the particle size and approximate density of the host catalyst.

Copper may be introduced into the zeolite by the use of any soluble copper salt, preferably one which provides cupric ions. We have found cupric acetate and cupric nitrate to be useful for purposes of this invention, but cupric-chloride and cupric sulfate also may be used. Ion-exchange techniques, as shown in the examples, provide catalytically effective copper. However, as will be illustrated by example, effective loading is also obtained when the copper is introduced by impregnation of the zeolite with an aqueous solution of the copper salt.

In a preferred embodiment and best mode for making this invention, a steam stabilizing amount of titanium or zirconium or a mixture thereof is included in the additive by treatment of the zeolite with any titanium or zirconium compound that can be brought into intimate association with the zeolite. We have found that highly effective results are obtained with the use of aqueous solutions of titanium tetramethoxide and zirconium acetate, and, such materials being readily available, are preferred. As will be illustrated by example, the introduction of titanium or zirconium compound is effective when done by impregnation of the zeolite. The introduction of titanium or zirconium may follow ion-exchange by cupric ion, but it also may be done concurrently therewith with an aqueous solution containing, for example, both divalent copper cations and a soluble titanium or soluble zirconium compound. It is also contemplated to load the zeolite with titanium or zirconium compound prior to introduction of copper. An amount of the stabilizing metal equal to 1 to 20 wt % of the total additive is effective.

As a final step in preparation of the zeolitic copper additive of this invention, the dried catalyst is calcined in air for about 1-4 hours to decompose organic matter and fix the titanium and/or zirconium in the composition as an inorganic compound. Suitable calcination temperatures are 500.degree. to about 600.degree. C.

The catalyst composition of this invention may be prepared as a preformed mixture of host catalyst and additive and the mixture added to the cracking unit as initial fill or as makeup catalyst. It also may be prepared in situ by introduction of the additive to the circulating inventory of host catalyst in the cracking unit, this latter method being preferred. The point of introduction into the system may be the same as used for adding makeup host catalyst, but it may be at some other place.

The improved process of this invention is provided by incorporating into the circulating catalyst inventory of an FCC unit an amount of additive particles described above, said amount of additive particles constituting 0.1 to 30 wt %, and preferably 0.1 to 10 wt % of said circulating inventory including additive.

FIG. 7 and the sectional element thereof shown in FIG. 8 are representative of a commercial fluid catalytic cracking unit. Referring now to FIG. 7, a hydrocarbon feed 2 such as a gas oil boiling from about 600 degrees F. up to 1000 degrees F. is passed after preheating thereof to the bottom portion of riser 4 for admixture with hot regenerated catalyst introduced by standpipe 6 provided with flow control valve 8. A suspension of catalyst in hydrocarbon vapors at a temperature of at least about 950 degrees F. but more usually at least 1000 degrees F. is thus formed in the lower portion of riser 4 for flow upwardly therethrough under hydrocarbon conversion conditions. The suspension initially formed in the riser may be retained during flow through the riser for a hydrocarbon residence time in the range of 1 to 10 seconds.

The hydrocarbon vapor-catalyst suspension formed in the riser reactor is passed upwardly through riser 4 under hydrocarbon conversion conditions of at least 900 degrees F. and more usually at least 1000 degrees F. before discharge into one or more cyclonic separation zones above the riser discharge, represented by cyclone separator 14. There may be a plurality of such cyclone separator combinations comprising first and second cyclonic separation means attached to or spaced apart from the riser discharge for separating catalyst particles from hydrocarbon vapors. Separated hydrocarbon vapors are passed from separator 14 to a plenum chamber 16 for withdrawal therefrom by conduit 18. These hydrocarbon vapors together with gasiform material separated by stripping gas as defined below are passed by conduit 18 to fractionation equipment not shown. Catalyst separated from hydrocarbon vapors in the cyclonic separation means is passed by diplegs represented by dipleg 20 to a dense fluid bed of separated catalyst 22 retained abort an upper portion of riser conversion zone 4. Catalyst bed 22 is maintained as downwardly moving fluid bed of catalyst countercurrent to rising gasiform material. The catalyst passes downwardly through a stripping zone 24 immediately below and counter-current to rising stripping gas introduced to a lower portion thereof by conduit 26. Baffles 28 are provided in the stripping zone to improve the stripping operation.

The catalyst is maintained in stripping zone 24 for a period of time sufficient to effect a higher temperature desorption of feed deposited compounds which are then carried overhead by the stripping gas. The stripping gas with desorbed hydrocarbons pass through one or more cyclonic separating means 32 wherein entrained catalyst fines are separated and returned to the catalyst bed 22 by dipleg 34. The hydrocarbon conversion zone comprising riser 4 may terminate in an upper enlarged portion of the catalyst collecting vessel with the commonly known bird cage discharge device, or an open end "T" connection may be fastened to the riser discharge which is not directly connected to the cyclonic catalyst separation means. The cyclonic separation means may be spaced apart from the riser discharge so that an initial catalyst separation is effected by a change in velocity and direction of the discharged suspension. Vapors less encumbered with catalyst fines may then pass through one or more cyclonic separation means before passing to a product separation step. In any of these arrangements, gasiform materials comprising stripping gas hydrocarbon vapors and desorbed sulfur compounds are passed from the cyclonic separation means represented by separator 32 to a plenum chamber 16 for removal with hydrocarbon products of the cracking operation by conduit 18. Gasiform material comprising hydrocarbon vapors is passed by conduit 18 to a product fractionation step not shown. Hot stripped catalyst at an elevated temperature is withdrawn from a lower portion of the stripping zone by conduit 36 for transfer to a fluid bed of catalyst being regenerated in a catalyst regeneration zone. Flow control valve 38 is provided in transfer conduit 36.

This type of catalyst regeneration operation is referred to as a swirl type of catalyst regeneration due to the fact that the catalyst bed tends to rotate or circumferentially circulate about the vessel's vertical axis and this motion is promoted by the tangential spent catalyst inlet to the circulating catalyst bed. Thus, the tangentially introduced catalyst at an elevated temperature is further mixed with hot regenerated catalyst or catalyst undergoing regeneration at an elevated temperature and is caused to move in a circular or swirl pattern about the regenerator's vertical axis as it also moves generally downward to a catalyst withdrawal funnel 40 (sometimes called the "bathtub") adjacent the regeneration gas distributor grid. In this catalyst regeneration environment, it has been found that the regeneration gases comprising flue gas products of carbonaceous material combustion tend to move generally vertically upwardly through the generally horizontally moving circulating catalyst to cyclone separators positioned above the bed of catalyst in any given vertical segment. As shown by FIG. 2, the catalyst tangentially introduced to the regenerator by conduit 36 causes the catalyst to circulate in a clockwise direction in this specific embodiment. As the bed of catalyst continues its circular motion some catalyst particles move from an upper portion of the mass of catalyst particles suspended in regeneration gas downwardly therethrough to a catalyst withdrawal funnel 40 in a segment of the vessel adjacent to the catalyst inlet segment. In the regeneration zone 42 housing a mass of the circulating suspended catalyst particles 44 in upflowing oxygen containing regeneration gas introduced to the lower portion thereof by conduit distributor means 46, the density of the mass of suspended catalyst particles may be varied by the volume of regeneration gas used in any given segment or segments of the distributor grid. Generally speaking, the circulating suspended mass of catalyst particles 44 undergoing regeneration with oxygen containing gas to remove carbonaceous deposits by burning will be retained as a suspended mass of swirling catalyst particles varying in density in the direction of catalyst flow and a much less dense phase of suspended catalyst particles 48 will exist above 44 in the upper portion of the regeneration zone. Under carefully selected relatively low regeneration gas velocity conditions, a rather distinct line of demarcation may be made to exist between a dense fluid bed of suspended catalyst particles and a more dispersed suspended phase (dilute phase) of catalyst above it. However, as the regeneration gas velocity conditions are increased there is less of a demarcation line and the suspended catalyst passes through regions of catalyst particle density generally less than about 30 lbs. per cu. ft. A lower catalyst bed density of at least 20 lb/cu. ft. is preferred.

A segmented regeneration gas distributor grid 50 positioned in the lower cross-sectional area of the regeneration vessel 42 is provided as shown in FIG. 7 and is adapted to control the flow of regeneration gas passed to any given vertical segment of the catalyst bed above it. In this arrangement, it has been found that even with the generally horizontally circulating mass of catalyst, the flow of regeneration gas is generally vertically upwardly through the mass of catalyst particles so that regeneration gas introduced to the catalyst bed by any given grid segment or portion thereof may be controlled by grid openings made available and the air flow rate thereto. Thus, oxygen containing combustion gases after contact with catalyst in the regeneration zone are separated from entrained catalyst particles by the cyclonic means provided and vertically spaced above the bed. The cyclone combinations diagrammatically represented in FIG. 1 are intended to correspond to that represented in FIG. 2. Catalyst particles separated from the flue gases passing through the cyclones are returned to the mass of catalyst below by the plurality of provided catalyst diplegs.

As mentioned above, regenerated catalyst withdrawn by funnel 40 is conveyed by standpipe 6 to the hydrocarbon conversion riser 4.

The regenerator system shown in FIGS. 7 and 8 is of a type originally designed for producing a flue gas that contains a substantial concentration of carbon monoxide along with carbon dioxide. In fact, a typical CO.sub.2 /CO ratio is about 1.2 (i.e., in the absence of a CO-oxidation promoter).

Other regenerator designs for FCC units have been proposed. A number of these utilize more than one regeneration zone. It is contemplated that the present invention will have a salutary effect on emissions with most, if not with all regenerators.

EXAMPLES

This invention will now be illustrated by example, which illustration is not to be construed as limiting the scope of the invention, said scope being determined by this entire specification including appended claims.

Examples 1-7, inclusive, illustrate preparation of a catalyst additive according to this invention.

EXAMPLE 1

Catalyst Additive 1 (CA1) was prepared by aqueous ion exchange of a NH.sub.4 -ZSM-5 extrudate having a SiO.sub.2 /Al.sub.2 O.sub.3 ratio of about 70/1. The zeolite was exchanged at 85.degree. C. using a 0.1 N copper acetate solution at a ratio of 1 g zeolite per 10 ml solution; the pH of the exchange solution was 5. After two hours with occasional stirring, the zeolite was filtered and thoroughly washed with distilled water. The exchange, filter, and wash procedure was repeated two additional times. The catalyst was then air-dried at 150.degree. C. Prior to testing, it was ground and sized to 120/140 mesh. An elemental analysis showed 4.6 wt % Cu.

EXAMPLE 2

Catalyst Additive 2 (CA2) was prepared by aqueous ion exchange of a silica-alumina bound ZSM-5 having a SiO.sub.2 /Al.sub.2 O.sub.3 ratio of about 26/1. The bound ZSM-5 was obtained in a spray dried form, suitable for direct use in FCC applications, and consisted of 75% binder/25% ZSM-5. The ion exchange procedure was carried out using copper acetate solution as described for CA1, as was the drying. An elemental analysis showed 2.2 wt % Cu.

EXAMPLE 3

Catalyst Additive 3 (CA3) was prepared by treating CA2 with an aqueous solution of zirconium acetate by the method of incipient wetness. The additive was then dried at 150.degree. C. for 2 hours, followed by air calcination at 538.degree. C. for 4 hours. An elemental analysis showed 2.2 wt % Cu and 12 wt % Zr.

Catalyst Additive 4 (CA4) was prepared by treating CA2 with an acidified aqueous solution cf titanium tetramethoxide by the method of incipient wetness. The additive was dried and calcined as for CA3. An elemental analysis showed 2.2 wt % Cu and 8 wt % Ti.

EXAMPLE 5

Catalyst Additive 5 (CA5) was prepared by treating a spray dried, silica-alumina bound ZSM-5 material (that described as the precursor material in preparing CA2) with an aqueous co-solution of both copper nitrate and titanium tetramethoxide by the method of incipient wetness. The additive was then dried and calcined as for CA3. An elemental analysis showed 3.3 wt % Cu and 4.6 wt % Ti.

EXAMPLE 6

Catalyst Additive 6 (CA6) was prepared by treating a spray dried, silica alumina binder (analogous to that used in the precursor material for CA2 except that no ZSM-5 was present) with a solution of copper nitrate by the method of incipient wetness, followed by drying at 150.degree. C. for 2 hours and air calcination at 538.degree. C. for 4 hours. An elemental analysis showed 3.4 wt % Cu.

EXAMPLE 7

Catalyst Additive 7 (CA7) was prepared by treating CA6 with an acidified aqueous solution rf titanium tetramethoxide by the method of incipient wetness. The additive was dried and calcined as for CA6. An elemental analysis showed 3.4 wt % Cu and 5.5 wt % Ti.

EXAMPLE 8

10 g of coked commercial FCC catalyst (0.71% C, 320 ppm N) from a refinery was regenerated in a semi-batch mode in a fluidized bed unit at 700.degree. C using 400 cc/min of a N.sub.2 O.sub.2 mixture to achieve a final O.sub.2 concentration of 3 vol. %. Effluent NO.sub.x, CO/CO.sub.2, and O.sub.2 levels were continuously monitored using a chemiluminescent analyzer, non-dispersive infrared analyzers, and a solid state electrochemical sensor, respectively. The effluent stream was dried with a membrane drier prior to entering the analytical train. The effluent species profiles observed during the coked FCC regeneration, in the absence of additive particles, are shown in FIGS. 1(A) and 1(B) of the drawing. The peak NO.sub.x and CO emissions are given in Table I.

Identical experiments to that above were then repeated with fresh batches of coked FCC catalyst to which was added CA.sub.1 at loadings of from 0.125 to 28 wt % based on the total FCC catalyst bed. Both NO.sub.x and CO emissions were significantly reduced during these catalyst regenerations, as shown graphically in FIGS. 2 and 3 for CA1 additive loadings of 0.125 and 1.1 wt % and as tabulated in Table I. Both the peak and integrated NO.sub.x emissions were reduced across the entire range of CA1 loading; however, the primary benefit is achieved once the additive loading reaches about 1 to 2 wt %, as shown in FIGS. 4 and 5. The efficacy of CA1 for NO.sub.x and CO removal was found to be retained after undergoing additional regeneration cycles.

                  TABLE I
    ______________________________________
    EFFECT OF Cu-ZSM-5 ON NO.sub.x AND CO EMISSIONS
    Run           Peak NO.sub.x (ppm)
                               Peak CO (vol %)
    ______________________________________
    Coked FCC Catalyst
                  301          2.1
    with no Additive
    Coked FCC Catalyst
                  128          1.2
    with 0.125 wt % CA1
    Coked FCC Catalyst
                   92          0.2
    with 1.1 wt % CA1
    ______________________________________