Molecular sieve abstract
Molecular sieve agglomerates exhibiting reduced pore mouth blockage
and decreased diffusivity resistance to the internal sieve pores
result from coating, prior to addition of a binding agent to the
sieve, the molecular sieve particles with an organic polymer, fixing
the polymer to the sieve surface so that it exhibits no migratory
tendencies and subsequently removing the coating by combustion during
calcination of the formed agglomerate. Such agglomerates showed
enhanced activity and selectivity in typical refining processes
such as dewaxing and fluid catalytic cracking.
Molecular sieve claims
What is claimed is:
1. In the method of forming molecular sieve agglomerates from molecular
sieve particles comprising mixing the molecular sieve particles
with a binding agent which is at least one inorganic oxide, forming
the mixture of molecular sieve particles and inorganic oxide, and
heating the formed mixture to set the binding agent and to calcine
the formed agglomerate, the improvement comprising depositing a
fixed, nonmigratory coating of an organic polymer on the surface
of said molecular sieve particles prior to mixing with the binding
agent and subsequently volatilizing the organic polymeric coating
during heating of the formed mixture.
2. The method of claim 1 where the binding agent is selected from
the group consisting of silica, silica-alumina, alumina, titania,
silica-zirconia, silica-magnesia, alumina-boria, alumina-titania,
clays, and combinations thereof.
3. The method of claim 2 where the inorganic oxide is silica.
4. The method of claim 3 where the inorganic oxide is alumina.
5. The method of claim 1 where said coating is volatilized during
calcination of the formed agglomerate.
6. The method of claim 1 where said organic polymer is an organic
anionic polymer.
7. The method of claim 6 where the polymer is selected from the
group consisting of polymeric carboxylic acids, polymeric sulfonic
acids, and water soluble salts thereof.
8. The method of claim 1 where said organic polymer is an organic
cationic polymer.
9. The method of claim 8 where the polymer is selected from the
group consisting of polymeric quaternary ammonium salts.
10. The method of claim 1 where the organic polymer is selected
from the group consisting of polystyrenes, polyesters, and polyolefins.
11. A method of reducing pore mouth blockage in the binding of
small molecular sieve particles and the forming of molecular sieve
agglomerates therefrom comprising coating the molecular sieve particles
with an organic polymer fixing the organic polymeric coating to
the surface of the molecular sieve particles so as to produce a
nonmigratory coating thereon, binding the coated molecular sieve
particle with a binding agent which is at least one inorganic oxide,
forming the agglomerate of molecular sieve particles, and removing
the organic polymeric coating by calcination.
12. The method of claim 11 wherein the binding agent is selected
from the group consisting of silica, silica-alumina, alumina, titania,
silica-zirconia, silica-magnesia, alumina-boria, alumina-titania,
clays, and combinations thereof.
13. The method of claim 12 where the inorganic oxide is silica.
14. The method of claim 12 where the inorganic oxide is alumina.
15. The method of claim 11 where the organic polymer is an organic
anionic polymer.
16. The method of claim 15 where the polymer is selected from the
group consisting of polymeric carboxylic acids, polymeric sulfonic
acids, and water soluble salts thereof.
17. The method of claim 11 where the organic polymer is an organic
cationic polymer.
18. The method of claim 17 where the polymer is selected from the
group consisting of polymeric quaternary ammonium salts.
19. The method of claim 11 where the polymer is selected from the
group consisting of polystyrenes, polyesters, and polyolefins.
20. The method of claim 11 where coating is performed prior to
binding.
21. A molecular sieve agglomerate having improved transport properties
which results from the method of claim 1.
Molecular sieve description
BACKGROUND OF THE INVENTION
This application relates to agglomerates of fine particles of molecular
sieve material. For the purpose of this application, "agglomerates"
are formed catalyst or adsorbent such as extrudates, pills, tablets,
beads, spheres, and so on. More particularly, this application relates
to agglomeration of individual particles of molecular sieves where
the individual particles are held together by binding agents, especially
where at least the major component of the binding agent is an inorganic
oxide such as alumina or silica. The invention within provides a
solution to the problem of pore blockage of molecular sieves by
the aforesaid binding agents.
The remarkable properties of molecular sieves have been successfully
utilized for several decades. For most industrial applications the
discrete particles of molecular sieve materials are too small to
be used directly, hence are agglomerated into larger particles which
may be more efficaciously used as, for example, adsorbents, catalysts,
and so forth. These agglomerates are formed by mixing small particles
of molecular sieves with a binding agent (binder) where alumina
and silica are examples of commonly used binders. The agglomerates
consist of a multiplicity of small particles dispersed in a binder
and often containing adjuncts, such as plasticizers, burnout agents,
and extrusion agents, for example.
Molecular sieves are characterized by an internal pore structure
which is responsible for their ability to perform size and shape
separations and which also serves as a microreactor of molecular
size. For optimum separation properties it is apparent that access
to these pores needs to be unimpeded. In many cases optimum catalytic
properties also require unimpeded access to these pores. Ingress
to and egress from the pores are certainly a necessary prerequisite
for reactions to occur in the pores; there can be no catalytic activity
arising from the pore structure as a reaction zone when the reactant
has no access to the reaction zone, and there will be no measurable
reaction unless the product can leave the reaction zone so as to
permit access to further reactant molecules. In the context of catalytic
properties, the reaction rate and selectivity (where more than one
reaction may occur) will be influenced by the transport of reactant
into and product out of the reaction zone within the pores of a
molecular sieve.
It should be clear from the foregoing that the transport properties
of resulting molecular sieve agglomerates are a major concern when
binding small particles of molecular sieves. Unfortunately, commonly
used binders tend to reduce pore access to varying degrees by blocking
the mouth of pores, and such pore blockage may significantly adversely
affect adsorbent and/or catalytic activity of the resulting agglomerate
by impeding the transport of substances between the pore interior
and the external medium.
We have found a means of reducing pore mouth blockage while not
adversely affecting the binding of small particles by coating the
latter with certain organic polymers prior to the binding stage.
Molecular sieves have been coated with organic polymers previously
but for the distinctly different purpose of reducing attrition.
For example, the patentee in U.S. Pat. No. 4319928 faced the problem
of the disintegration of zeolitic adsorbents upon their continued
use in aqueous streams with attendant silicon contamination of the
product stream. The patentee solved this problem by coating the
agglomerates with cellulose esters. It may be mentioned in passing
that the patentee coated the dispersion of the molecular sieves
in the binder, i.e., what the patentee coated was previously used
as the finished bound adsorbent whereas in the invention to be described
it is the individual particles of the molecular sieve which are
coated prior to forming agglomerates with the binder. The scope
of protective coatings for zeolites was reviewed by the patentees
of U.S. Pat. No. 4822492 who substituted latexes for inorganic
oxides as a binder for crystalline molecular sieves in order to
alleviate problems of deterioration of zeolitic agglomerates through
attrition when used in an aqueous medium. The patentees believed
their protective coating minimized additional pore blockage of molecular
sieves.
Since coating molecular sieves previously has been recognized to
contribute to pore blockage, it is paradoxical that we have alleviated
pore blockage in our invention by deliberately coating small particles
of molecular sieve. However, we coat molecular sieves for a different
purpose, at a different stage of product manufacture, and with different
materials than are used in the prior art. Conceptually, the method
of our invention coats the surface of a molecular sieve via a multiplicity
of mechanisms. When the coated molecular sieve particles are mixed
with a binder and subsequently agglomerated, the coating prevents
(or more properly, reduces) the interaction between the binder and
molecular sieve surface which causes pore blockage, although the
coating itself at this stage results in substantial additional pore
blockage. After the agglomerate is formed the surface coating is
then removed by calcination leaving voids immediately around the
molecular sieve particle. The resulting formed agglomerates have
substantially less pore blockage than agglomerates formed without
the interim coating, and since air calcination effectively removes
the organic coating there remains no vestige of a "foreign"
material which might influence the properties of the molecular sieve.
This procedures and the resulting material is portrayed, albeit
somewhat fancifully, in FIG. 1.
SUMMARY OF THE INVENTION
The purpose of this invention is to improve diffusivity at the
molecular sieve-binder interface in agglomerates and to reduce molecular
sieve pore mouth blockage during the binding process. An embodiment
comprises coating small particles of molecular sieve with organic
polymers, mixing the fine coated molecular sieve particles with
a binder to form agglomerates, and thereafter removing the organic
coating by heating the agglomerates so as to volatilize the coating
or to combust it with the formation of volatile materials. In one
embodiment the molecular sieve has a positively charged surface
and the organic coating is an anionic polymer or oligomer. In a
more specific embodiment the oligomer is a salt of a polyacrylic
acid. In another embodiment the surface of the molecular sieve is
negatively charged and the coating arises from a cationic polymer
or oligomer. Other embodiments will be apparent from the ensuing
description.
DESCRIPTION OF THE FIGURES
FIG. 1 is a pictorial representation of the coating process and
a particle within the agglomerate as formed by the process of this
invention.
FIG. 2 compares the effect of the coated vs. non-coated molecular
sieves of Example 1 on the pour point of a hydrocarbon feed in catalytic
dewaxing at various temperatures.
FIG. 3 shows the relation between pour point and conversion to
products of boiling point under 500.degree. F. in catalytic dewaxing
using the coated and uncoated molecular sieve of Example 1.
FIG. 4 shows the effect of polymer coating the sieve of Example
2 on its activity in FCC catalysts.
FIG. 5 shows the effect of polymer coating the sieve of Example
2 on its selectivity in FCC catalysts.
DESCRIPTION OF THE INVENTION
The invention within provides a means of reducing pore mouth blockage
and improving diffusivity at the molecular sieve-binder interface
in agglomerates formed by binding small particles of molecular sieves
with in organic oxides, especially silica and alumina. The invention
is perhaps most readily understood by reference to FIG. 1. A small
particle of a molecular sieve is coated with an organic polymer
or oligomer to afford a molecular sieve particle which is encased
in the shell of organic material. It needs to be stated that the
representation of the figure is an exaggeration; it is not that
every molecular sieve particle is encased within an organic shell,
and it is better to think of the small particles of molecular sieve
having a multiplicity of patches of organic coating on its surface.
What this coating does is to prevent interaction between the surface
of the molecular sieve particle and the binders which are added
to agglomerate the various small particles of molecular sieve into
a larger, industrially more desirable particle such as an extrudate,
sphere, bead, pill or tablet. After formation of the agglomerate
induced by the inorganic binder, the material is calcined not only
to set the inorganic binder but also to volatilize or otherwise
remove the organic coating around the individual molecular sieve
particles. The result, which is the right-most representation in
FIG. 1 is a molecular sieve which has a substantial portion of
its surface unattached to the binder. Since the entrance to the
internal pores of the molecular sieve are at the surface of the
molecular sieve particles, this results in decreased pore mouth
blockage and increased diffusivity at the molecular sieve-binder
interface.
Prior to the detailed description of our invention, an overview
seems desirable. A key aspect of the present invention is the coating
of molecular sieve particles, especially prior to binding, then
removing the coating subsequent to binding and forming. The net
effect of this process is the production of void spaces following
the forming step at the molecular sieve-binder interface by combustion
and volatilization of the coating agent, resulting in enhanced diffusion
across that interface.
Although the use of burnout agents to increase porosity in bound
systems is not new, both the manner of their use as disclosed within
and the consequences of our particular manner of use are previously
unknown. Burnout agents typically are added to the molecular sieve-binder
mixture prior to extrusion or forming and are combusted during the
calcination step to volatile products to leave void spaces at the
locations the burnout agents originally occupied, which are randomly
distributed throughout the molecular sieve-binder composite. That
is, the prior art production of voids is at non-specific locations,
and the prior art contains no realization of the added benefits
which flow by specifically designing those void spaces at the molecular
sieve-binder interface. In stark contrast to the prior art, the
burnout agent of this invention, which is a polymer coating agent,
is specifically directed and attached to the molecular sieve, especially
prior to binding, to ensure that the void spaces crated upon combustion
will be at the molecular sieve-binder interface. A key aspect of
the current invention is that the coating agent is chosen so that
it will remain fixed to the molecular sieve surface during subsequent
treatments encountered during the binding and forming steps. In
general, a polymer is impregnated onto the molecular sieve surface
from an appropriate solution. During this impregnation and subsequent
drying, the initially soluble polymeric coating agent is rendered
insoluble at least under the conditions of the steps of binding,
forming, and setting, by one of several mechanisms. The actual mode
by which this insolubilization or fixation is achieved is not as
important as the requirement that the polymer must not migrate through
the binder in subsequent processing steps; once attached to the
molecular sieve the polymer must remain fixed, i.e., firmly attached
to the molecular sieve surface, through the subsequent steps until
volatilized during combustion. Coatings manifesting such properties
will be subsequently referred to as nonmigratory coatings.
From the foregoing it should be clear that "fixing" in
this application means firmly attaching an organic polymer to the
surface of a molecular sieve. A few mechanisms of fixation can be
described here for the purpose of illustrating the foregoing but
these examples in no way limit the overall scope of the invention.
In one method of fixing the polymer to the molecular sieve surface,
a water insoluble polymer dissolved in an organic solvent is contacted
with the molecular sieve powder. The solvent is then evaporated,
leaving the polymer deposited on the surface of the molecular sieve
crystals since the polymer is too large to enter the molecular sieve
pore structure. All subsequent steps of binding and forming are
performed in an aqueous environment in which the polymer is insoluble
and where the polymer on the sieve surface is left undisturbed.
In a final step the polymer is combusted leaving a void at the surface
of the molecular sieve.
In another method of fixing the polymer coating agent to the surface
of the molecular sieve crystal a polymer is selected with a water
solubility that changes with pH. Thus, a polycarboxylic acid is
soluble in water at high pH where it is predominantly in the dissociated
or anionic carboxylate form. For example, after coating a molecular
sieve with ammonium polycaroboxlate in aqueous solution at a pH
greater than 8 where it is soluble, the solvent can be evaporated
and subsequent processing can be conducted in an aqueous environment
but a lower pH as is commonly done with acid peptized binders. At
such lower pH the polymer will remain in the water insoluble carboxylic
acid form and adhere to the molecular sieve surface during the binding
steps.
In yet another illustration an ionic polymer can be selected for
attachment to a sieve with a charged surface. Thus, a sieve with
a positively charged surface could be contacted with a solution
containing a polymeric anion such as the polycarboxylate described
above. In this example the charge difference between the crystal
and the polymer causes the polymer to become securely attached to
the crystal surface due to coulombic attractions. Alternatively,
a sieve with a negatively charged surface might be effectively coated
with a polymeric cation.
In summary, the method by which the polymer is fixed to the sieve
surface is not critical. The more critical aspect is that the polymer,
however fixed to the sieve surface, must remain so fixed throughout
the subsequent binding and forming steps to be removed only in the
final calcination step. This will ensure that the porosity created
by the combustion of the polymer is associated with the molecular
sieve-binder interface and that diffusion restriction due to excessive
interaction of the binder with the sieve is reduced resulting in
enhanced access by reactants and egress by products. The desirable
result of this enhanced diffusivity will be increased activity for
the primary reactions and increased selectivity for the desired
primary products.
The molecular sieves which may be used in the practice of this
invention may be any crystalline inorganic molecular sieve such
as aluminosilicates, aluminophosphates, silicaluminophosphates,
borosilicates, silicates, and silicalite. Representative of such
molecular sieves are the aluminophosphates of U.S. Pat. No. 4310440
the silicaluminophosphates of U.S. Pat. N. 4440871 transition
metal-containing silicaaluminophosphates (MeAPSO's), zeolite X,
zeolite Y, LZ-210 zeolite A, zeolite F, zeolite L, zeolite P, zeolite
Q, zeolite W, clinoptilolite, mordenite, chabazite, errionite, ZSM-type
zeolites, NU-type zeolites, faujasite, phillipsite, and so forth.
It is to be clearly understood that the foregoing is not an exhaustive
list of molecular sieves which can be used in the practice of this
invention, but the members are merely illustrative and representative
of this class of materials.
Typically the molecular sieve particles are less than about 20
microns in diameter, and the small size often precludes their direct
use in commercial processes. For example, when used as a packed
bed such a small particle size would lead to far larger pressure
drops than could be economically accommodated. Consequently the
small particles are dispersed in an inorganic matrix acting as a
binder which forms agglomerates consisting of a multitude of small
particles of molecular sieves. The molecular sieve typically will
be present in the inorganic matrix in such portions that the resulting
product contains from 1 to 95 weight percent of the molecular sieve,
although more normally the agglomerate contains between about 10
to about 90 weight percent of molecular sieve in the final product.
The binders which are of interest in this invention are inorganic
oxides such as silicas, silica-aluminas, aluminas, titania, silica-zirconia,
silica-magnesia, alumina-boria, alumina-titania, clays such as kaolin,
and mixtures thereof. The usual purpose of the binder is to aid
in forming or agglomerating the small particles of the molecular
sieve into larger, commercially more useful ones. The mixture of
molecular sieves and binder is then formed into particles of suitable
size and shape and subsequently calcined to "set" the
particles. It should be mentioned that the inorganic oxides when
used as binders also may contain other materials as additives, such
as plasticizers, extrusion acids, and burnout agents.
The agglomeration of small particles results from a strong interaction
between the surface of the molecular sieve particles and the binder.
Such strong interactions not only lead to agglomeration of the particles
but also lead to pore mouth blockage. The remainder of this discussion
will be directed toward the means discovered to improve diffusivity
at the molecular sieve-binder interface and to reduce the pore mouth
blockage with arises during the binding and forming processes.
Our solution to pore mouth blockage which arises during the binding
and forming stages of agglomerate production is to coat the individual
small particles of molecular sieves with organic material which
will physically adhere to the molecular sieve rather than migrate
through the binder. This coating acts as a protective layer for
the surface and itself covers many of the pore entrances at the
sieve surface. But in doing so such a coating also prevents interaction
of the binder with the molecular sieve surface at the entry to the
pore channels. After binding and forming of the agglomerates the
coating is then removed, and in doing so the pore entrances previously
covered by the coating are opened and become more freely accessible
to species such as reactants.
The materials desired for use as a molecular sieve surface coating
are organic oligomers or polymers which are initially soluble in
some suitable solvent for ease of application, which either become
water insoluble upon coating the sieve surface or can be so insolubilized,
and which can be completely removed after agglomerate formation,
preferably via calcination. For the purposes of this application
no distinction will be made between an "oligomer" and
a "polymer"; the practical distinction between the two
rests on their molecular weight and the line separating oligomers
and polymers often is quite indistinct. For the purposes of this
application the phrase "polymer" will include both organic
oligomers and polymers which can be used in the practice of this
invention.
The surfaces of molecular sieve particles often are charged. As
a consequence one broad class of organic polymers which is quite
useful in the practice of our invention is the class of charged
polymers, that is, either cationic or anionic polymers. Where a
solution of a polymer with a charge type opposite to that found
on the molecular sieve surface is used, the organic polymer will
adhere very strongly to the surface of the molecular sieve through
electrostatic interactions, that is, the organic polymer will become
insolubilized at the molecular sieve surface, remaining there when
the coating sieve is subsequently bound with an inorganic oxide
rather than migrating through the binder. Because most molecular
sieve surfaces are positively charged, anionic polymers are particularly
preferred in the practice of this invention. Examples of such polymers
include the polymeric carboxylic acids and polymeric sulfonic acids
generally and their water soluble salts. Exemplary of the aforegoing
classes are poly(acrylic acid), poly(crotonic acid), poly(maleic
acid), poly(methacrylic acid), poly(itaconic acid), copolymers of
maleic anhydride with olefins (such as butadiene, styrene, acrylates,
and vinyl ethers) which have been hydrolyzed to the carboxylic acids,
poly(styrenesulfonic acid), poly(vinylsulfonic acid), and poly(acrylamidomethylpropanesulfonic
acid), but the aforegoing is illustrative only and not intended
to be exhaustive.
Where the molecular sieve surfaces are negatively charged, which
is a less frequent situation, cationic organic polymers may be successfully
used. Such polymers encompass for the most part polymeric quaternary
ammonium ion species, especially the trialkylammonium salts of polymeric
amines. Illustrative of the latter are poly(vinylbenzylamine), .alpha.-aminopolystyrene,
ring-aminated polystyrene, poly(allylamine), poly(ethyleneimine),
and poly(vinylamine). The aforegoing are only exemplary and not
exhaustive.
Since it is only necessary that the organic polymer which is used
as the coating be initially soluble and become insolubilized at
the surface of the molecular sieve particle prior to subsequent
binding, any polymer which has these properties and which does not
migrate through the binder is suitable in our invention. Insolubilization
often implies a strong surface attraction between the molecular
sieve and the polymer, which may arise from van der Waal's forces,
charge attraction, covalent bonding, or some combination of the
above. In appropriate cases it may be desirable to modify the surface
charge of the molecular sieve in order to coat it with an anionic
or cationic organic polymer. In those situations where the sieve
exterior surface bears a negative charge or no charge at all and
where it is desirable to coat the sieve with an anionic polymer,
such as a polycarboxylate, it is necessary to first treat the sieve
surface with cationic species to develop the appropriate electrostatic
attraction between the polymer and the sieve surface. For example,
silicalite, a silica molecular sieve isostructural with MFI (pentasil
structure) has very little surface cation content. Attempts to coat
silicalite with a polycarboxylic acid were unsuccessful unless the
silicalite was first treated with a poly(aluminumhydroxy) cation
such as aluminumchlorohydrate (ACH; aluminumchlorohydrol; aluminumchlorohydroxide).
When silicalite is first impregnated with an ACH slurry, dried,
and contacted with an aqueous solution of a polyacrylate, the polymer
coating procedure described within is successful. Because it is
important that the coating remain at the molecular sieve surface
and not migrate through the binder it also is important that there
should not be a strong attraction between the coating and the binder.
Until the coating is removed at a later stage in agglomerate formation,
it is highly desirable that it be strongly associated only with
the molecular sieve surface.
The amount of organic polymeric coating which must be used to effectively
utilize the favorable consequences of reduced pore mouth blockage
varies with the intended use of the agglomerate, and the optimum
needs to be determined on a case-by-case basis. In general, the
coating may be from about 0.1 to about 5 weight percent of the molecular
sieve, although a range from about 0.5 to about 3 weight percent
is more often suitable.
After the small particles are coated as described above, they are
agglomerated using the binding and forming procedures well known
to those in the art. Agglomeration consists of adding a binder,
often containing other materials such as plasticizers, so as to
form agglomerates of a multiplicity of smaller particles. After
the addition of binder and formation of large particles the agglomerate
is generally calcined to set the binder. It is during this stage
of agglomerate production that the molecular sieve surface coating
is removed, either by direct volatilization or by volatilization
via combustion. Thus, calcination generally is conducted at temperatures
between about 300.degree. and about 700.degree. C. and may be conducted
in the presence of air or oxygen, whereever necessary, to induce
volatilization of the organic coating. Removal of the organic coating
then presents fresh surfaces of molecular sieve particles which
are not associated with the binder used in agglomerate formation
and thus makes freely available pore entrances unimpeded by particles
of the binder.
The prior description of our preparation of molecular sieve agglomerates
with improved transport properties is one where the organic polymer
coating is deposited on the surface of the molecular sieve prior
to mixing with a binding agent. Although this is the most preferred
variant of our invention it is not the only procedure possible.
In particular, we have found that often it is not necessary for
the zeolite to be coated prior to binding and that coating may be
effected during the binding procedure. Evidently, particularly with
a charged polymer to be used as a coating, there is sufficient attraction
between the organic polymer and the molecular sieve surface that
the polymer migrates preferentially to the sieve's surface even
in the presence of a binder so that a slurry of the molecular sieve,
binder, organic polymer, and so on may be formed and spray dried
to afford a molecular sieve agglomerate with improved transport
properties.
Molecular sieves have been used as catalysts or as catalyst supports
in a large number of processes, especially those of interest o the
petrochemical industry, including reforming, hydrocracking, dewaxing,
isomerization, fluid cataltic cracking (FCC), partial oxidation,
alkylation and disproportionation of aromatics. Specific reaction
conditions and the types of feeds which can be used in these processes
are set forth in U.S. Pat. Nos. 4310440 and 4440871 which are
incorporated by reference. The molecular sieves of this invention
also may present advantages when used as adsorbents in separation
processes since diffusion of materials into and out of the pores
should be greatly facilitated and size selectivity should be determined
more strictly by pore size rather than availability of pore entrances.
The present molecular sieve agglomerates having improved transport
properties also exhibit surface selectivity characteristics which
render them useful as catalyst or catalyst bases in a number of
hydrocarbon conversion and oxidative combustion reactions. They
can be impregnated or otherwise loaded with catalytically active
metals by methods well known in the art and used, for example, in
fabricating catalyst compositions having silica or alumina bases.
Of the general class, those species having pores larger than about
4 .ANG. are preferred for catalytic applications.
Among the hydrocarbon conversion reactions catalyzed by molecular
sieve agglomerates having improved transport properties are cracking,
hydrocracking, alkylation for both the aromatic and isoparaffin
types, isomerization including oxylene isomerization, polymerization,
reforming, hyrogenation, dehydrogenation, transalkylation, dealkylation,
hydrodecyclization and dehydrocyclization.
Using molecular sieve agglomerates having improved transport properties
which contain a hydrogenation promoter such as platinum or palladium,
heavy petroleum residual stocks, cyclic stocks and other hydrocrackable
charge stocks can be hydrocracked at temperatures in the range of
400.degree. F. to 825.degree. F. using molar ratios of hydrogen
to hydrocarbon in the range of between 2 and 80 pressures between
10 and 3500 psig., and a liquid hourly space velocity (LHSV) of
from 0.1 to 20 preferably 1.0 to 10.
The molecular sieve agglomerates having improved transport properties
employed in hydrocracking are also suitable for use in reforming
processes in which the hydrocarbon feedstocks contact the catalyst
at temperatures of from about 700.degree. F. to 1000.degree. F.,
hydrogen pressures of from 100 to 500 psig, hydrocarbon molar ratios
in the range of 1 to 20 preferably between 4 and 12.
These same catalysts, i.e., those containing hydrogenation promoters,
are also useful in hydroisomerization processes in which feedstocks
such as normal paraffins are converted to saturated branched chain
isomers. Hydroisomerization is carried out at a temperature of from
about 200.degree. F. to 600.degree. F., preferably 300.degree. F.
to 550.degree. F. with an LHSV value of from about 0.2 to 1.0. Hydrogen
is supplied to the reactor in admixture with the hydrocarbon feedstock
in molar proportions (hydrogen to hydrocarbon) of between 1 to 5.
At somewhat higher temperatures, i.e., from about 650.degree. F.
to 1000.degree. F., preferably 850.degree. F. to 950.degree. F.
and usually at somewhat lower pressures within the range of about
15 to 50 psig, the same catalyst compositions are used to hydroisomerize
normal paraffins. Preferably the paraffin feedstock comprises normal
paraffins having a carbon number range of C.sub.7 -C.sub.20. Contact
time between the feedstock and the catalyst is generally relatively
short to avoid undesirable side reactions such as olefin polymerization
and paraffin cracking. LHSV values in the range of 0.1 to 10 preferably
1.0 to 6.0 are suitable.
Catalysts containing the molecular sieve agglomerates having improved
transport properties find use in the conversion of alkylaromatic
compounds, particularly the catalytic disproportionation of toluene,
ethylene, trimethyl benzenes, tetramethyl benzenes and the like.
In the disproportionation process, isomerization and transalkylation
can also occur. Group VIII noble metal adjuvants alone or in conjunction
with Group VI-B metals such as tungsten, molybdenum and chromium
are preferably included in the catalyst composition in amounts of
from about 3 to 15 weight percent of the overall composition. Extraneous
hydrogen can, but need not, be present in the reaction zone which
is maintained at a temperature of from about 400.degree. to about
750.degree. F., pressures in the range of 100 to 2000 psig and LHSV
values in the range of 0.1 to 15.
Catalytic cracking processes are preferably carried out with molecular
sieve agglomerates having improved transport properties using feedstocks
such as gas oils, heavy naphthas, deasphalted crude oil resudua,
etc., with gasoline being the principal desired product. Temperature
conditions of 850.degree. to 1100.degree. F., LHSV values of 0.5
to 10 and pressure conditions of from about 0 to 50 psig are suitable.
Dehydrocyclization reactions employing paraffinic hydrocarbon feedstocks,
preferably normal paraffins having more than 6 carbon atoms, to
form benzene, xylenes, toluene and the like are carried out using
essentially the same reaction conditions as for catalytic cracking.
For these reactions it is preferred to use the molecular sieve agglomerates
having improved transport properties in conjunction with a Group
VIII non-noble metal cation such as titanium and nickel.
In catalytic dealkylation wherein it is desired to cleave paraffinic
side chains from aromatic nuclei without substantially hydrogenating
the ring structure, relatively high temperatures in the range of
about 800.degree.-1000.degree. F. are employed at moderate hydrogen
pressures of about 300-1000 psig, other conditions being similar
to those described above for catalytic hydrocracking. Preferred
catalysts are of the same type described above in connection with
catalytic dehydrocyclization. Particularly desirable dealkylation
reactions contemplated herein include the conversion of methylnaphthalene
to naphthalene and toluene and/or xylenes to benzene.
In catalytic hydrofining, the primary objective is to promote the
selective hydrodecomposition or organic sulfur and/or nitrogen compounds
in the feed, without substantially affecting hydrocarbon molecules
therein. For this purpose it is preferred to employ the same general
conditions described above for catalytic hydrocracking, and catalysts
of the same general nature described in connection with dehydrocyclization
operations. Feedstocks include gasoline fractions, kerosenes, jet
fuel fractions, diesel fractions, light and heavy gas oils, deasphalted
crude oil residua and the like any of which may contain up to about
5 weight percent of sulfur and up to about 3 weight percent of nitrogen.
Similar conditions can be employed to effect hydrofining, i.e.,
denitrogenation and desulfurization, of hydrocarbon feeds containing
substantial proportions of organonitrogen and organosulfur, compounds.
It is generally recognized that the presence of substantial amounts
of such constituents markedly inhibits the activity of catalysts
of hydrocracking. Consequently, it is necessary to operate at more
extreme conditions when it is desired to obtain the same degree
of hydrocracking conversion per pass on a relatively nitrogenous
feed than are required with a feed containing less organonitrogen
compounds. Consequently, the conditions under which denitrogenation,
desulfurization and/or hydrocracking can be most expeditiously accomplished
in any given situation are necessarily determined in view of the
characteristics of the feedstocks, in particular the convention
of organonitrogen compounds in the feedstock. As a result of the
effect of organonitrogen compounds on the hydrocracking activity
of these compositions it is not at all unlikely that the conditions
most suitable for denitrogenation of a given feedstock having a
relatively high organonitrogen content with minimal hydrocracking,
e.g., less than 20 volume percent of fresh feed per pass, might
be the same as those preferred for hydrocracking another feedstock
having a lower concentration of hydrocracking inhibiting constituents,
e.g., organonitrogen compounds. Consequently, it has become the
practice in this art to establish the conditions under which a certain
feed is to be contacted on the basis of preliminary screening tests
with the specific catalyst and feedstock.
Isomerization reactions are carried out under conditions similar
to those described above for reforming, using somewhat more acidic
catalysts. Olefins are preferably isomerized at temperatures of
500.degree.-900.degree. F., while paraffins, naphthenes and alkyl
aromatics are isomerized at temperatures of 700.degree.-1000.degree.
F. Particularly desirable isomerization reactions contemplated herein
include the conversion of n-heptene and/or n-octane to isoheptanes,
iso-octanes, butane to iso-butane, methylcyclopentane to cyclohexane,
meta-xylene and/or ortho-xylene to paraxylene, 1-butene to 2-butene
and/or isobutene, n-hexene to isohexene, cyclohexene to methylcyclopentene,
etc. The preferred form of the catalyst is a combination of the
molecular sieve agglomerates having improved transport properties
with polyvalent metal compounds such as sulfides) of metals of Group
II-A, Group II-B and rare earth metals. For alkylation and dealkylation
processes the molecular sieve agglomerates having improved transport
properties and having pores of at least 5 .ANG. are preferred. When
employed for dealkylation of alkyl aromatics, the temperature is
usually at least 350.degree. F., and ranges up to a temperature
at which substantial cracking of the feedstock or conversion products
occurs, generally up to about 700.degree. F. The temperature is
preferably at least 450.degree. F. and not greater than the critical
temperature of the compound undergoing dealkylation. Pressure conditions
are applied to retain at least the aromatic feed in the liquid state.
For alkylation the temperature can be as low as 250.degree. F. but
is preferably at least 350.degree. F. In the alkylation of benzene,
toluene and xylene, the preferred alkylating agents are olefins
such as ethylene and propylene.
The molecular sieve agglomerates of our invention also may be used
in a process for catalytically dewaxing a hydrocarbon feedstock.
Normally such feedstocks contain higher molecular weight straight
chain paraffins and slightly branched paraffins which are waves,
causes high pour and cloud points in oils. Catalytic dewaxing selectively
cracks these waxy paraffins to lower molecular weight products,
and to some extent may isomerize the paraffins to non-waxy products.
The hydrocarbon oil feedstocks normally have a boiling point at
least about 350.degree. F. Catalytic dewaxing is performed in the
presence of hydrogen, at a total pressure as low as about 15 psig
up to about 3000 psig, at temperatures between about 200.degree.
C. and 475.degree. C., and at a liquid hourly space velocity of
from 0.1 to about 20; cf. U.S. Pat. No. 4859311. The molecular
sieves are used in conjunction with at least one Group VIII metal,
such as platinum and palladium, often with adjuncts such as molybdenum,
vanadium, zinc, and so on. |