Title of Invention

AN ADDITIVE COMPOSITION SUITABLE FOR REDUCING CO EMISSIONS DURING CATALYST REGENERATION IN A FLUID CATALYTIC CRACKING PROCESS

Abstract A composition for controlling CO and NOx emissions during FCC processes comprises (i) acidic oxide support, (ii) cerium oxide (iii) lanthanide oxide other than ceria such as praseodymium oxide (iv) optionally, oxide of a metal from Groups Ib and IIb such a s copper, silver and zinc and (v) precious metal such s Pt and Pd.
Full Text CO OXIDATION PROMOTERS
FOR USE IN FCC PROCESSES
BACKGROUND OF THE INVENTION
A major industrial problem involves the development of efficient
methods for reducing the concentration of air pollutants, such as carbon
monoxide, sulfur oxides and nitrogen oxides in waste gas streams which
result from the processing and combustion of sulfur, carbon and nitrogen
containing fuels. The discharge of these waste gas streams into the
atmosphere is environmentally undesirable at the sulfur oxide, carbon
monoxide and nitrogen oxide concentrations that are frequently
encountered in conventional operations. The regeneration of cracking
catalyst, which has been deactivated by coke deposits in the catalytic
cracking of sulfur and nitrogen containing hydrocarbon feedstocks, is a
typical example of a process which can result in a waste gas stream
containing relatively high levels of carbon monoxide, sulfur and nitrogen
oxides.
Catalytic cracking of heavy petroleum fractions is one of the major
refining operations employed in the conversion of crude petroleum oils to
useful products such as the fuels utilized by internal combustion engines.
In fiuidized catalytic cracking (FCC) processes, high molecular weight
hydrocarbon liquids and vapors are contacted with hot, finely-divided, solid
catalyst particles, either in a fiuidized bed reactor or in an elongated
transfer line reactor, and maintained at an elevated temperature in a
fiuidized or dispersed state for a period of time sufficient to effect the
desired degree of cracking to lower molecular weight hydrocarbons of the
kind typically present in motor gasoline and distillate fuels.
In the catalytic cracking of hydrocarbons, some nonvolatile
carbonaceous material or coke is deposited on the catalyst particles. Coke
comprises highly condensed aromatic hydrocarbons and generally
contains from about 4 to about 10 weight percent hydrogen. When the
hydrocarbon feedstock contains organic sulfur and nitrogen compounds,
the coke also contains sulfur and nitrogen. As coke accumulates on the
cracking catalyst, the activity of the catalyst for cracking and the selectivity
of the catalyst for producing gasoline blending stocks diminishes.
Catalyst which has become substantially deactivated through the deposit
of coke is continuously withdrawn from the reaction zone. This deactivated
catalyst is conveyed to a stripping zone where volatile deposits are
removed with an inert gas at elevated temperatures. The catalyst particles
are then reactivated to essentially their original capabilities by substantial
removal of the coke deposits in a suitable regeneration process.
Regenerated catalyst is then continuously returned to the reaction zone to
repeat the cycle.
Catalyst regeneration is accomplished by burning the coke deposits
from the catalyst surfaces with an oxygen containing gas such as air. The
combustion of these coke deposits can be regarded, in a simplified
manner, as the oxidation of carbon and the products are carbon monoxide
and carbon dioxide.
High residual concentrations of carbon monoxide in flue gases from
regenerators have been a problem since the inception of catalytic cracking
processes. The evolution of FCC has resulted in the use of increasingly
high temperatures in FCC regenerators in order to achieve the required
low carbon levels in the regenerated crystalline aluminosilicate catalysts.
Typically, present day regenerators now operate at temperatures in the
range of about 1100° F. to 1350° F. when no promoter is used and result
in flue gases having a CO2/CO ratio in the range of 1.5 to 0.8. The
oxidation of carbon monoxide is highly exothermic and can result in so-
called "carbon monoxide afterburning" which can take place in the dilute
catalyst phase, in the cyclones or in the flue gas lines. Afterburning has
caused significant damage to plant equipment. On the other hand,
unburned carbon monoxide in atmosphere-vented flue gases represents a
loss of flue value and is ecologically undesirable.
Restrictions on the amount of carbon monoxide, which can be
exhausted into the atmosphere and the process advantages resulting from
more complete oxidation of carbon monoxide, have stimulated several
approaches to the provision of means for achieving complete combustion
of carbon monoxide in the regenerator.
The use of precious metals to catalyze oxidation of carbon
monoxide in the regenerators of FCC units has gained broad commercial
acceptance. Some of the history of this development is set forth in U.S.
Pat. No. 4,171,286 and U.S. Pat. No. 4,222,856. In the earlier stages of
the development, the precious metal was deposited on the particles of
cracking catalyst. Present practice is generally to supply a promoter in the
form of solid fluidizable particles containing a precious metal, such
particles being physically separate from the particles of cracking catalyst.
The precious metal or compound thereof, is supported on particles of
suitable carrier material and the promoter particles are usually introduced
into the regenerator separately from the particles of cracking catalyst. The
particles of promoter are not removed from the system as fines and are
cocirculated with" cracking catalyst particles during the
cracking/stripping/regeneration cycles. Judgement of the CO combustion
efficiency of a promoter is done by measuring the difference in
temperature, delta T, between the (hotter) dilute phase and the dense
phase.
Promoter products used on a commercial basis in FCC units
include calcined spray dried porous microspheres of kaolin clay
impregnated with a small amount (e.g., 100 or 500 ppm) of platinum.
Reference is made to U.S. Pat. No. 4,171,286 (supra). Most commercially
used promoters are obtained by impregnating a source of platinum on
microspheres of high purity porous alumina, typically gamma alumina. The
selection of platinum as the precious metal in various commercial products
appears to reflect a preference for this metal that is consistent with prior
art disclosures that platinum is the most effective group VIII metal for
carbon monoxide oxidation promotion in FCC regenerators. See, for
example, FIG. 3 in U.S. Pat. No. 4,107,032 and the same figure in U.S.
Pat. No. 4,350,614. The figure illustrates the effect of increasing the
concentration of various species of precious metal promoters from 0.5 to
10 ppmon CO2/CO ratio.
U.S. Pat. No. 4,608,357 teaches that palladium is unusually
effective in promoting the oxidation of carbon monoxide to carbon dioxide
under conditions such as those that prevail in the regenerators of FCC
units when the palladium is supported on particles of a specific form of
silica-alumina, namely leached mullite. The palladium may be the sole
catalytically active metal component of the promoter or it may be mixed
with other metals such as platinum.
U.S. Pat. Nos. 5,164,072 and 5,110,780, relate to an FCC CO
promoter having Pt on La-stabilized alumina, preferably about 4-8 weight
percent La2 O3. It is disclosed that ceria "must be excluded." At col. 3, it is
disclosed that "In the presence of an adequate amount of La2 O3, say
about 6-8 percent, 2 percent Ce is useless. It is actually harmful if the La2
O3 is less." In an"illustrative example "072 and "780 demonstrates an
adverse effect of 8% Ce on CO promotion of platinum supported on a
gamma alumina and a positive effect of La.
When sulfur and nitrogen containing feedstocks are utilized in
catalytic cracking process, the coke deposited on the catalyst contains
sulfur and nitrogen. During regeneration of coked deactivated catalyst, the
coke is burned from the catalyst surface that then results in the conversion
of sulfur to sulfur oxides and nitrogen to nitrogen oxides.
Unfortunately, the more active combustion promoters such as
platinum and palladium also serve to promote the formation of nitrogen
oxides in the regeneration zone. Since the discharge of nitrogen oxides
into the atmosphere is environmentally undesirable, the use of these
promoters has the effect of substituting one undesirable emission for
another. It has been reported that the use of prior art CO promoters can
cause a dramatic increase (e.g. >300%) in NOX.
Various approaches have been used to either reduce the formation
of noxious gases or treat them after they are formed. Most typically,
additives have been used either as an integral part of the FCC catalyst
particles or as separate particles in admixture with the FCC catalyst.
Various additives have been developed that will carry out CO
promotion while controlling NOx emissions.
U.S. Pat. Nos. 4,350,614, 4,072,600 and 4,088,568 mention rare
earth addition to Pt based CO promoters. An example is 4% REO that
shows some advantage. There is no teaching of any effect of REO on
decreasing NOx emissions from the FCCU.
US 4,199,435 teaches a combustion promoter selected from the Pt,
Pd, Ir, Os, Ru, Rh, Re and copper on an inorganic support.
US 4,290,878 teaches a Pt-lr and Pt-Rh bimetallic promoter that
reduces NOx compared to conventional Pt promoter.
US 4,300,997 patent teaches the use of a Pd-Ru promoter for
oxidation of CO that does not cause excessive NOx formation.
US 4,544,645 describes a bimetallic of Pd with every other Group
VIII metal but Ru.
US 6,165,933 and 6,358,881 describe compositions comprising a
component containing (i) an acidic oxide support, (ii) an alkali metal and/or
alkaline earth metal or mixtures thereof, (iii) a transition metal oxide having
oxygen storage capability, and (iv) palladium; to promote CO combustion
in FCC processes while minimizing the formation of NOx.
US 6,117,813 teaches a CO promoter consisting of a Group VIII
transition metal oxide, Group IIIB transition metal oxide and Group MA
metal oxide.
There is still a need, however, for improved CO oxidation promoters
having NOX emission control in FCC processes.
SUMMARY OF THE INVENTION
The invention provides novel compositions suitable for use in FCC
processes that are capable of providing improved CO oxidation promotion
activity along with NOx emission control.
In one aspect, the invention provides compositions for reducing CO
emissions in FCC processes, the compositions containing (i) an acidic
oxide support, (ii) ceria (iii) at least one oxide of a lanthanide series
element other than ceria, (iv), optionally, at least one oxide of a transition
metal selected from Groups Ib and lib of the Periodic Table and (v) at least
one precious metal. The acidic oxide support preferably contains alumina.
Praseodymium oxide is the preferred lanthanide oxide other than ceria.
Cu and Ag are preferred Group Ib transition metals and Zn is the preferred
Group lib transition metal.
In another aspect, the invention encompasses FCC processes
using the CO emission reduction and NO* control compositions of this
invention either as an integral part of the FCC catalyst particles or as
separate particles admixed with the FCC catalyst.
These and other aspects of the invention are described in further
detail below.
DETAILED DESCRIPTION OF THE INVENTION
The invention encompasses the discovery that certain classes of
compositions are very effective for both the reduction of CO and control of
NOx gas emissions in FCC processes. The CO reduction compositions of
the inventions are characterized in that they comprise (i) an acidic oxide
support, (ii) cerium oxide (iii) at least one oxide of a lanthanide series
element other than ceria, (iv), optionally, at least one oxide of a transition
metal selected from Groups Ib and llb of the Periodic Table and mixtures
thereof and (v) at least one precious metal.
The acidic oxide support should be of sufficient acidity for the
composition to act as an effective additive for CO oxidation promotion and
NOX control. Acidic oxide catalyst supports are well know to those of
ordinary skill in the art and include, for example, transitional aluminas such
as gamma and eta alumina, silica-stabilized versions of said aluminas,
including the silica-stabilized alumina spinel formed by leaching silica from
kaolin calcined through its characteristic exotherm to form the spinel, or
mullite. The support may be crystalline or amorphous. Preferably, the
acidic oxide support contains at least some alumina. More preferably, the
oxide support contains at least 50 wt. % alumina. The oxide support is
preferably an oxide selected from the group consisting of alumina and
silica-alumina. Where an amorphous silica-alumina support is used, the
support preferably has an alumina to silica molar ratio of from about 1:1 up
to about 50:1. Examples of commercially available acidic oxide alumina
supports are available under tradenames such as PURALOX, CATAPAL
and VERSAL. Examples of commercially available acidic silica-alumina
supports are available under the tradenames such as SIRAL and
SIRALOX.
The silica-alumina support can optionally be created by the caustic
leaching of silica from preformed kaolin microspheres as described in US
Patents 4,847,225 and 4,628,042, which are hereby incorporated by
reference for their teachings in this regard. Preferably, the kaolin that is
subject to caustic leaching is calcined substantially through its
characteristic exotherm to form spinel and/or mullite. More preferably, the
caustic leached kaolin support is a microsphere whereby the caustic
leached kaolin is bound with aluminum chlorohydroxide before calcination
through the exotherm.
The acidic oxide support further preferably has sufficient surface
area to facilitate CO oxidation promotion and control. Preferably, the oxide
support has a surface area of at least about 20 m2/g, more preferably from
about 50 up to about 300 m2/g. The acidic oxide support may be a powder
which is preferable when used as an integral part of the FCC catalyst or a
microsphere or particle, preferably when used as an admixture with FCC
catalysts.
The amount of the cerium oxide (ceria) present in the additive
composition of the present invention may be varied considerably relative to
the amount of acidic oxide support. Preferably, the additive composition
contains at least about 0.5 part by weight of cerium oxide per 100 parts by
weight of the acidic oxide support material, more preferably from at least
about 1 part by weight up to about 25 parts by weight of cerium oxide per
100 parts of the acidic oxide support material.
The lanthanide oxides other than ceria include at least one metal
oxide from the lanthanide series other than ceria. Preferably, the
lanthanide oxide other than ceria is praseodymium oxide. The amount of
the lanthanide oxide other than ceria present in the additive composition
may be varied considerably relative to the amount of acidic oxide support.
Preferably, the additive composition contains from at least about 0.05 part
by weight of oxide per 100 parts by weight of the acidic oxide support
material, more preferably from at least about 1 part by weight up to about
25 parts by weight of lanthanide oxide other than ceria mixture per 1 (30
parts of the acidic oxide support material. The amount of ceria to the
lanthanide oxides other than ceria present in the additive composition of
this invention ranges from 1:20 to20:1 by weight, preferably 1:10 to 10:1.
The Group Ib and/or lib transition metals may be any metal or
combination of metals selected from those groups of the Periodic Table.
Preferably, the transition metal is selected from the group consisting of Cu,
Ag, Zn and mixtures thereof. The amount of transition metal present is
preferably at least about 100 parts by weight (measured as metal oxide)
per million parts of the oxide support material, more preferably from about
0.1 up to about 5 parts by weight per 100 parts of the oxide support
material.
The amount of precious metal can be varied considerably
depending the level of CO combustion promotion desired. Typical levels of
precious metal will be in the range of 50 to 1500 ppm of total additive
and/or catalyst. As used herein the precious metals include those
selected from a group consisting of Pt, Pd, Ir, Os, Ru, Rh, Re and their
precursors such as salts and amine complexes and mixtures thereof,
preferably the precious metal is Pt, Pd or mixtures thereof.
The additive composition may contain minor amounts of other
materials, which preferably do not adversely affect the CO oxidation or
NOX control function in a significant way. Reference herein to NOX control
typically refers to the reduction of NOX emissions from the FCC process,
although other types of control are contemplated by this invention
including, for example, the maintenance of the NOX emission levels in the
FCC unit where increased emissions of NOX are expected. The additive
composition may consist essentially of items (i)-(v) mentioned above, item
(iv) being optional. Where the composition of the invention is used as an
additive particle for an FCC process (as opposed to being integrated into
the FCC catalyst particles themselves), the additive composition may be
combined with fillers (e.g. clay, silica-alumina, silica and/or alumina
particles) and/or binders (e.g. silica sol, alumina sol, silica alumina sol,
etc.) to form particles suitable for use in an FCC process, preferably-by
spray drying before the calcination of step. More preferably, porous
particles, also known as microspheres, are formed from acidic oxide
support typically by spray drying powdered oxide support material
combined with a binder/filler before or after impregnation with the
individual constituents. Preferably, any added binders or fillers used do not
significantly adversely affect the performance of the additive component.
Where the additive composition is used as an additive particulate
(as opposed to being integrated into the FCC catalyst particles
themselves), the amount of additive component in the additive particles is
preferably at least 50 wt %, more preferably at least 75 wt. %. Most
preferably, the additive particles consist entirely of the additive component.
The additive particles are preferably of a size suitable for circulation with
the catalyst inventory in an FCC process. The additive particles preferably
have an average particle size of about 20-200 µm. The additive particles
preferably have attrition characteristics such that they can withstand the
severe environment of an FCCU.
As previously mentioned the additive composition of the invention
may be integrated into the FCC catalyst particles themselves. In such
case, any conventional FCC catalyst particle components may be used in
combination with the additive composition of the invention. If integrated
into the FCC catalyst particles the additive composition of the invention
preferably represents at least about 0.02 wt. % the FCC catalyst particle.
While the invention is not limited to any particular method of
manufacture, the additive composition of the invention is preferably made
by the following procedures:
(a) co-impregnate the acidic oxide support particles with a
cerium oxide source, at least one lanthanide oxide source
other than ceria, and, optionally, at least one source of a
Group 1b/llb element.
(b) calcine the impregnated support of step (a)
(c) impregnate the formed material in step (b) with the desired
level and choice of precious metal or precursor salt or
complex,
(d) optionally, recalcine the impregnated additive from step (c).
The sources of oxides are preferably slurries, sols and/or solutions
of the metal oxides themselves or salts of the respective metals, which
decompose to oxides on calcination, or combinations of oxides and salts.
If desired, the individual constituents may be separately added to the
support particles with a calcination step in between each addition. The
calcination steps are preferably performed at about 450-750° C.
The additive composition may be used as a separate additive
particle or as an integral part of an FCC catalyst particle. If used as an
additive, the additive component may itself be formed into particles
suitable for use in a FCC process. Alternatively, the additive component
may be combined with binders, fillers, etc. by any conventional technique.
See for example, the process described in U.S. Pat. No. 5,194,413, the
disclosure of which is incorporated herein by reference.
Where the additive component of the invention is integrated into an
FCC catalyst particle, preferably the component is first formed and then
combined with the other constituents which make up the FCC catalyst
particle. Incorporation of the additive composition directly into FCC
catalyst particles may be accomplished by any known technique.
Examples of suitable techniques for this purpose are disclosed in U.S. Pat.
Nos. 3,957,689; 4,499,197; 4,542,188 and 4,458,623, the disclosures of
which are incorporated herein by reference.
Preferably, the compositions of this invention do not contain alkali
and/or alkaline earth metals. The absence of alkali and/or alkaline earth
metals in the additive compositions of this invention is intended to mean
that they are substantially absent from such compositions so as not to
which preferably do not adversely affect the CO oxidation or NOX control
function of such compositions in a significant way. Typically, the absence
of the amount of alkali and/or alkaline earth metals shall mean less than
about 1%, preferably, less than about 0.5% and, more preferably, less
than about 0.1 % alkali and alkaline earth metal present in the additive
compositions of this invention.
The compositions of the invention may be used in any conventional
FCC process. Typical FCC processes are conducted at reaction
temperatures of 450 to 650° C. with catalyst regeneration temperatures of
600 to 850° C. The compositions of the invention may be used in FCC
processing of any typical hydrocarbon feedstocks. Preferably, the
compositions of the invention are used in FCC processes involving the
cracking of hydrocarbon feedstocks which contain above average amounts
of nitrogen, especially residual feedstocks or feedstocks having a nitrogen
content of at least 0.1 wt. %. The amount of the additive component of the
invention used may vary depending on the specific FCC process.
Preferably, the amount of additive component used (in the circulating
inventory) is about 0.05-15 wt. % based on the weight of the FCC catalyst
in the circulating catalyst inventory. The presence of the compositions of
the invention during the FCC process catalyst regeneration step
dramatically reduces the level of CO emitted during regeneration and
controls NOX emissions as well.
The following examples are illustrative of embodiments of the
invention and are not intended to limit the invention as encompassed by
the claims forming part of the application.
Example 1
2% Prg6O11/10% CeO2/2% CuO/Alumina
Alumina support particles are coimpregnated with a solution of cerium and
praseodymium nitrate by incipient wetness, dried and calcined at 1200°F
for 2 hours to achieve a 10% CeO2 and 2 wt% Pr6On level. On the
microsphere, copper nitrate is impregnated, dried and calcined at 1200° F
for 2 hours to achieve a 2 wt% CuO level.
Example 2
3% Pr6On/18% CeO2/0.5% CuO/Alumina
Alumina support particles are coimpregnated with a solution of cerium and
praseodymium nitrate by incipient wetness, dried and calcined at 1200°F
for 2 hours to achieve a 18% CeO2 and 3 wt% Pr6On level. To achieve
these levels of Ce and Pr the impregnation and calcination steps were
conducted twice. On the resulting microsphere, copper nitrate is
impregnated, dried and calcined at 1200° F for 2 hours to achieve a 0.5
wt% CuO level.
Example 3
2% Pr6O11/10% CeO2/Alumina
Alumina support particles are coimpregnated with a solution of cerium and
praseodymium nitrate by incipient wetness, dried and calcined at 1200°F
for 2 hours to achieve a 10% CeO2 and 2 wt% Pr6On level.
Example 4
Platinum is impregnated on the product made in Example 1 to a level of
500 ppm from a water solution of monoethanol amine complex. The dried
material is calcined at 1200°F for 2 h.
Example 5
Platinum is impregnated on product made in Example 2 to a level of 500
ppm from a water solution of monoethanol amine complex. The dried
material is calcined at 1200°F for 2 h.
Example 6
Platinum is impregnated on product made in Example 2 to a level of 200
ppm from a water solution of monoethanol amine complex. The dried
material is calcined at 1200°F for 2 h.
Example 7
Platinum is impregnated on product made in Example 3 to a level of 500
ppm from a water solution of monoethanol amine complex. The dried
material is calcined at 1200°F for 2 h.
Example 8
Palladium is impregnated on product made in Example 2 to a level of 500
ppm from a water solution of nitrate salt. The dried material is calcined at
1200oF for 2 h.
Example 9
Palladium is impregnated on product made in Example 3 to a level of 500
ppm from a water solution of nitrate salt. The dried material is calcined at
1200°F for 2 h.
COMPARATIVE EXAMPLES
Example A
500 ppm Pt on Alumina
Platinum is impregnated on alumina microspheres to a level of 500 ppm
from a water solution of ethanol amine salt. The dried material is calcined
at 1200°F for 2 h.
Example B
500 ppm Pd on Alumina
Palladium is impregnated on alumina microspheres to a level of 500 ppm
from a water solution of nitrate salt. The dried material is calcined at
1200° F for 2h.
CO Oxidation Testing
The additives tested are deactivated by steaming a 50/50 blend of additive
with FCC catalyst at 1500°F for 4 hours in 100% steam. Chemical markers
are used to ensure that the blend composition is retained after steaming.
CO oxidation testing is done in a fluid bed with a gas stream that has 5%
CO/3% O2/5% CO2/balance N2 at 1100°F. Different CO conversions are
achieved by varying the additive charged to the fluid bed reactor. Activity is
defined as the slope of-ln(1-x) vs. space time where x is the conversion of
CO. Data from the CO oxidation activity testing is shown in Table 1.
Results from Table 1 show that additive compositions from the present
invention having comparable precious metal loadings have better CO
promotion activity than prior art materials.
NOx Reduction
A fixed fluid bed laboratory reactor is used. The additives are deactivated
by steaming at 1500°F for 4 hours in 100% steam. A blend containing 0.2
wt% of the additive with a low metal ECAT is used for testing. Coke is
deposited on the blend by cracking gas oil. The spent catalyst is
regenerated at 1300°F in air. NOx emissions from the resulting flue gas
are determined via chemiluminescence. The NOx emissions are reported
at constant coke. Typical results for NOx reduction are shown in Table 2.
Results from Table 2 show that additive compositions from the present
invention reduce NOx emissions when compared with additives from prior
art.
We Claim:
1. An additive composition suitable for reducing CO emissions
during catalyst regeneration in a fluid catalytic cracking process;
said composition comprising (i) an acidic oxide support, (ii)
cerium oxide, (iii) at least one oxide of a lanthanide series element
other than cerium oxide, wherein the weight ratio of (ii) to (iii) is
from about 5:1 to about 20:1, (iv) optionally, at least one oxide of a
transition metal selected from Groups Ib and Iib of the Periodic
Table and mixtures thereof and (v) at least one precious metal.
2. The composition as claimed in claim 1 wherein said acidic oxide
support is selected from the group consisting of alumina and silica-
alumina.
3. The composition as claimed in claim 1 wherein said Group Ib and
Iib transition metals are present in said composition and are
selected from the group consisting of copper, silver, zinc and
mixtures thereof,
4. The composition as claimed in claim 1 wherein the precious metal
is at least one of the group consisting of Pt and Pd and the amount
of precious metal in said composition is at least about 50 and less
than about 1500 ppm.
5. The composition as claimed in claim 1 wherein said oxide of a
lanthanide series element other than cerium oxide is praseodymium
oxide.
6. A fluid cracking catalyst composition comprising (a) a cracking
component suitable for catalyzing the cracking of hydrocarbons,
and (b) an additive composition comprising (i) an acidic oxide
support, (ii) cerium oxide, (iii) at least one oxide of a lanthanide
series element other than ceria, the weight ratio of (ii) to (iii) being
from about 5:1 to about 20:1, (iv) optionally, at least one oxide of a
transition metal selected from Groups Ib and Iib of the Periodic
Table and (v) at least one precious metal, said additive
composition being an integral component of the catalyst
composition particles, being separate particles from the catalyst
component or mixtures thereof and being present in the cracking
catalyst in a sufficient CO emission reducing amount.
7. The cracking catalyst as claimed in claim 6 wherein said cracking
catalyst comprises an admixture of component (a) and component
(b).
8. The cracking catalyst as claimed in claim 6 wherein said oxide of a
lanthanide series element other than ceria is praseodymium oxide.
9. The composition as claimed in claim 6 wherein the precious metal
is at least one of the group consisting of Pt and Pd and the amount
of precious metal in said composition is at least about 50 and less
than about 1500 ppm.
10. A method of reducing CO emission during fluid catalytic cracking
of a hydrocarbon feedstock into lower molecular weight
components, said method comprising contacting a hydrocarbon
feedstock with a cracking catalyst suitable for catalyzing the
cracking of hydrocarbons at elevated temperature whereby lower
molecular weight hydrocarbon components are formed in the
presence of a CO emission reduction composition, wherein said
composition comprises (i) an acidic oxide support, (ii) at least 0.5
part by weight of cerium oxide per 100 parts by weight of acidic
oxide support, (iii) at least one oxide of a lanthanide series element
other than ceria, the weight ratio of (ii) to (iii) being from about 5:1
to about 20:1, (iv) optionally, an oxide of a transition metal
selected from Groups Ib and Iib of the Periodic Table and (v) at
least one precious metal, said CO reduction composition being
present in an amount sufficient to reduce said CO emissions.
A composition for controlling CO and NOX emissions during FCC processes
comprises (i) acidic oxide support, (ii) cerium oxide (iii) lanthanide oxide
other than ceria such a s praseodymium oxide (iv) optionally, oxide of a
metal from Groups Ib and Iib such as copper, silver and zinc and (v)
precious metal such s Pt and Pd.

Documents:

848-kolnp-2005-granted-abstract.pdf

848-kolnp-2005-granted-assignment.pdf

848-kolnp-2005-granted-claims.pdf

848-kolnp-2005-granted-correspondence.pdf

848-kolnp-2005-granted-description (complete).pdf

848-kolnp-2005-granted-examination report.pdf

848-kolnp-2005-granted-form 1.pdf

848-kolnp-2005-granted-form 18.pdf

848-kolnp-2005-granted-form 2.pdf

848-kolnp-2005-granted-form 3.pdf

848-kolnp-2005-granted-form 5.pdf

848-kolnp-2005-granted-gpa.pdf

848-kolnp-2005-granted-letter patent.pdf

848-kolnp-2005-granted-reply to examination report.pdf

848-kolnp-2005-granted-specification.pdf


Patent Number 215550
Indian Patent Application Number 848/KOLNP/2005
PG Journal Number 09/2008
Publication Date 29-Feb-2008
Grant Date 27-Feb-2008
Date of Filing 10-May-2005
Name of Patentee ENGELHARD CORPORATION
Applicant Address 101 WOOD AVENUE, P.O. BOX 707, ISELIN, NJ 08830-0770
Inventors:
# Inventor's Name Inventor's Address
1 KELKAR, C.P. 32 SHAFFER ROAD, BRIDGEWATER, NJ 08807
2 LI, YUEJIN 8 EAST DRIVE, EDISON, NJ 08820
3 MADON, ROSTAM, J. 17 HENDRICK ROAD, FLEMINGTON, NJ 08820
4 VAARMAMP, MARIUS 14-411 ST. PIERRE LANE, CYPRESS, 77429
PCT International Classification Number B 01 J 23/89
PCT International Application Number PCT/US02/035387
PCT International Filing date 2002-11-05
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/268,256 2002-10-10 U.S.A.