Molecular sieve abstract
Inorganic composite membrane containing molecular sieve crystals,
comprising a macroporous support to which molecular sieve crystals
and modifications thereof have been applied substantially as a monolayer,
said crystals and modifications thereof having been oriented so
that, toa substantial extent, the pores of the sieve crystals form
a significant included angle with the support surface, there being
present between the crystals a gastight matrix, at least gastight
to a degree sufficient under practical conditions.
Molecular sieve claims
We claim:
1. An inorganic composite membrane comprising:
(a) a macroporous support member,
(b) a monolayer of molecular sieve crystals applied upon the support
membrane, said crystals having pores forming a significant included
angle with said support member; and
(c) a substantially gastight matrix selectively deposited upon
said support member in the area between the molecular sieve crystals.
2. Membrane in accordance with claim 1 wherein the molecular sieve
crystals have a one dimensional pore structure and are selected
from the group consisting of AlPO.sub.4 -5 VPI-5 mordenite, Nu-10
crystals and mixtures thereof.
3. Membrane in accordance with claim 1 wherein the molecular sieve
crystals have a two dimensional pore structure and are selected
from the group consisting of ZSM-5 silicalite and mixtures thereof.
4. Membrane in accordance with claim 1 wherein the molecular sieve
crystals have a three dimensional pore structure selected from the
group consisting of crystals of zeolite A, zeolite X, zeolite Y,
and mixtures thereof.
5. Membrane in accordance with claim 1 wherein the crystals are
of a thickness of at least 2 mm and a length and width of at least
10 mm.
6. Membrane in accordance with claim 1 wherein the crystals are
applied upon the matrix substantially with the same orientation.
7. Membrane in accordance with claim 1 wherein the molecular sieve
crystals are at least 10 mm in dimension.
8. Membrane in accordance with claim 1 wherein a porous fixing
layer is applied between the support member and the crystals prior
to deposition of the gastight matrix.
9. Membrane in accordance with claim 8 wherein the fixing layer
is formed from a clay selected from the group consisting of kaolin
and baked-out silicone paste.
10. Membrane in accordance with claim 1 wherein the gastight matrix
is formed from a glaze, a borosilicate glass, an oxide or a ceramic
material.
11. Membrane in accordance with claim 1 wherein catalytic centers
are provided in the pores of the membrane and/or on the surface
thereof.
12. Method for the preparation of a membrane in accordance with
claim 1 which comprises the steps of
(a) applying a monolayer of molecular sieve crystals upon the surface
of a macroporous inorganic support member, said crystals being oriented
such that the pores of the crystals form a significant included
angle with the surface of the support, and
(b) applying a gastight matrix between said crystals.
13. Method in accordance with claim 12 wherein a fixing layer is
applied upon the surface of the support member prior to the application
of said monolayer upon the support member.
14. Method in accordance with claim 13 wherein the fixing layer
is derived from kaolin or baked-out silicone paste.
15. Method in accordance with claim 13 wherein catalytic centers
are provided in the pores and/or on the surfaces of said crystals.
16. Method in accordance with claim 12 wherein the gastight matrix
is selected from the group consisting of a glaze, a borosilicate
glass, an oxide or a ceramic material.
17. Method in accordance with claim 12 wherein any matrix material
applied upon the molecular sieve crystals is removed by polishing
or etching techniques.
18. Method in accordance with claim 12 wherein the porous support
member is removed to obtain a self-supporting membrane film.
19. A method for producing the inorganic composite membrane recited
in claim 1 comprising:
(a) applying molecular sieve crystals to a macroporous support
such that said molecular sieve crystals applied on said support
form a monolayer which comprises crystals which are oriented such
that the pores of said crystals form a significant included angle
with the surface of said support; and,
(b) applying a substantially gastight matrix between the crystals.
20. The method recited in claim 19 wherein a fixing layer build
up from clay or baked-out silicone paste is applied to the support
surface.
21. The method recited in claim 20 wherein the gastight matrix
comprises a glaze, borosilicate glass, an oxide, or a ceramic material.
22. The method recited in claim 20 wherein matrix material which
has been formed on the particles is removed by polishing or etching.
23. The method recited in claim 19 wherein said support is removed
to obtain a membrane film.
24. The method recited in claim 17 wherein catalytic centres are
present or have been provided in the pores and/or the surface of
said crystals.
25. An inorganic composite membrane comprising a macroporous support,
molecular sieve crystals, and a matrix between said crystals, wherein
said crystals are present as a monolayer and are oriented on said
support so that the pores of said crystals have a significant included
angle with the surface of said macroporous support, said matrix
between said crystals being substantially gastight and wherein said
crystals have a one-dimensional or two-dimensional pore structure.
26. The membrane recited in claim 25 wherein said crystals are
AIPO.sub.4 -5 VPI-5 mordenite, Nu-10 or mixtures thereof when
said crystals have a onedimensional pore structure and ZSM-5 silicalite,
or mixtures thereof when said crystals have a two-dimensional pore
structure.
27. The membrane recited in claim 26 wherein said crystals have
the same orientation.
28. The membrane recited in claim 26 wherein said molecular sieve
crystals have a thickness of at least 2 .mu.m and a length and width
of at least 10 .mu.m.
29. The membrane recited in claim 26 wherein said molecular sieve
crystals have dimensions of at least 10 .mu.m.
30. The membrane recited in claim 26 wherein said membrane further
comprises a porous fixing layer which is present between the support
and the crystals.
31. The membrane recited in claim 30 wherein said fixing layer
is formed from clay or baked-out silicone paste.
32. The membrane recited in claim 26 wherein said gastight matrix
is formed from a glaze, borosilicate glass, an oxide, or a ceramic
material.
33. The membrane recited in claim 26 wherein catalytic centres
are present or are provided in the pores of said crystals.
Molecular sieve description
This invention relates to an inorganic composite membrane containing
molecular sieve crystals and to methods for producing such a membrane.
For separation on a molecular level, such as gas separation, vapor
permeation and pervaporation, mainly membranes on the basis of organic
polymers have been proposed so far for use on an industrial scale.
A wide variety of macromolecular (almost exclusively organic) materials
have been found to be suitable for use as a membrane material. Reasonable
separation factors can be achieved, and the throughput of such membranes
is sufficiently large.
However, these polymer membranes have the disadvantage of a relatively
short service life. Owing to the sensitivity of the materials to
solvents (swelling) and the low stability at high temperatures,
the range of application is limited. Moreover, regeneration by oxidative
removal of impurities is not possible.
Also known are so-called ceramic membranes composed substantially
of inorganic materials, which, compared with polymer membranes,
have the advantage that they are resistant to high temperatures,
so that regeneration is possible, and moreover are relatively inert.
Such membranes are usually produced starting from multi-layered
systems, in which a relatively thick macroporous layer serves as
a support for a microporous top layer which is much thinner relative
to the supporting layer and exhibits the separation properties.
The production of such membranes, in which the so-called sol-gel
or dip-coating techniques can be used successfully for providing
the separating layer, is described inter alia in the following publications:
A. Larbot, A. Julbe, C. Guizard, L. Cot, J.Membr.Sci., 93 (1989),
289-303; A. Larbot, J.P. Fabre, C. Guizard, L. Cot, J.Am.Ceram.Soc.,
72 (1989), 257-261; W.A. Zeltner, M.A. Anderson, "Chemical
Control over Ceramic Membrane Processing: Promises, Problems and
Prospects", in: Proc. 1st Int.Conf.Inorg.Membr., (eds. J. Charpin,
L. Cot), Montpellier, France, Jul. 3-6 1989 213-223; A. Leenaars,
Preparation, Structure and Separation Characteristics of Ceramic
Alumina Membranes, PhD thesis, University of Twente, Netherlands,
(1984); H.M. van Veen, R.A. Terpstra, J.P.B.M. Tol, H.J. Veringa,
"Three-Layer Ceramic Alumina Membrane for High Temperature
Gas Separation Applications", in: Proc. 1st Int.Conf.Inorg.Membr.,
(eds. J. Charpin, L. Cot), Montpellier, France, Jul. 3-6 1989
329-335.
A disadvantage of such ceramic membranes is that the separation
efficiency is low. In most ceramic membranes developed so far, separation
takes place on the basis of Knudsen diffusion. In that case, the
rate of transport is inversely proportional to the square root of
the molecular weight. The selectivity of the separation process
is sufficient only if molecules having widely divergent molecular
weights are to be separated from each other.
Improved insights have led to separation processes on the basis
of ceramic membranes exhibiting material transport mechanisms other
than Knudsen diffusion, such as surface diffusion or capillary condensation:
R.J.R. Uhlhorn, "Ceramic Membranes for Gas Separation; Synthesis
and Transport Properties", PhD thesis, University of Twente,
Netherlands, (1990). In the case of surface diffusion, use is made
of differences in chemical and/or physical properties of the molecules
to be separated. The surface of the separating (or active) part
of the membrane is modified in such a manner that one type of molecule
is transported much more rapidly than the other as a result of a
difference in surface diffusion. However, the insight into the mechanism
of surface diffusion is still poor, so that it is difficult to make
appropriate use of differences in chemical and/or physical properties.
In capillary condensation and multilayer diffusion, use is made
of the formation of a liquid phase in the separating part of the
membrane. Here, too, it may be advantageous to modify the surface
of the membrane. Although the separation efficiency can be high,
the implementation of the separation process is strongly bound by
specific values of process parameters such as temperature and pressure,
as a result of the vapor tension of the condensing material.
Another drawback of the known ceramic membranes is that the pore
size distribution is hard to control. Because the pores of the active
layer are not uniform in size and shape, it is not possible to have
such a membrane function as a molecular sieve. It has moreover been
found to be very difficult to prepare a microporous layer that is
stable under process conditions.
The use of crystalline microporous materials renders it possible
in principle to exactly adjust the pore size distribution on a molecular
level. There is a wide variety of such materials, of which particularly
the zeolites (microporous aluminosilicates) are frequently used
on an industrial scale. Zeolites are now being used as adsorbent,
ion exchanger and catalyst. Due to the molecular sieve properties,
processes with a high selectivity can be carried out. However, the
molecular sieve properties are optimally used only if these materials
are arranged in a membrane configuration.
In the development and use of such membranes, it is of essential
importance that information be available on mass transport by the
zeolite crystals (cf R.M. Barrer, J.Chem.Soc. Faraday Trans., 86
(7), (1990), 1123-1130. Hayhurst and Paravar studied the diffusion
of alkanes, using a zeolite membrane configuration (A.R. Paravar,
D.T. Hayhurst. "Direct Measurement of Diffusivity for Butane
Across a Single Large Silicalite Crystal", 6th Int.Zeol.Conf.,
(Eds. D. Olson, A. Bisio), Reno, USA, Jul. 10-15 (1983), 217-224;
D.T. Hayhurst, A.R. Paravar, Zeolites 8 (1988), 27-29). In this
study, use was made of a twin silicalite crystal in an organic matrix
and a low feed gas pressure.
Werner and Osterhuber studied the permeation through a faujasite
type (NaX) single crystal, using a substantially higher feed gas
pressure. (D.L. Wernick, E.J. Osterhuber, "Diffusional Transition
in Zeolite NaX: 1. Single Crystal Gas Permeation Studies",
6th Int.Zeol.Conf., (Eds. D. Olson, A. Bisio), Reno, USA, Jul. 10-15
(1983), 122-130; D.L. Wernick, E.J. Osterhuber, J.Membr.Sci. 22
(1985), 137-146).
The most favorable configuration for a membrane having 10 molecular
sieve properties is realized if the molecular sieve crystals form
the only separation between two fluids. In that case, molecules
can pass directly from the first (retentate) phase to the second
(permeate) phase only via the micropores of the molecular sieve
crystals.
It is difficult, however, to arrange molecular sieve crystals in
a membrane configuration. Proposals are known where the molecular
sieve crystals are included in a polymer phase (cf Dutch patent
application 8800889; European patent application 0 254 758 and
U.S. Pat. No. 4740219).
Further known are various ceramic membranes produced using molecular
sieve crystals. Different methods have been proposed for including
molecular sieve crystals in a macroporous support which either have
initially been hydrothermally synthesized or are crystallized in
situ in or on the support. Further, membranes have been prepared
in which on a macroporous ceramic support an ultrathin layer of
molecular sieve crystals in a ceramic matrix is dispersed. This
has also been done without using a macroporous support (cf. European
patent applications 0 180 200 0 135 069 and 30 0 265 018; U.S.
Pat. Nos. 4699892 and 4800187; Canadian patent 1235684 and
Japanese patents 63291809 and 60129119).
The above-mentioned ways of preparing membranes start from very
small sizes of the molecular sieve crystals.
Material transport through micropores proceeds very slowly and
is inversely proportional to the thickness of the membrane. In general,
therefore, active layers of a few micrometers or less are used.
In many cases, the molecular sieve crystals are selected more than
one order smaller than the thickness of the active layer.
A great disadvantage of using very small crystals is that it is
virtually impossible to realize the optimum configuration of the
molecular sieve crystals in the membrane. This is caused by the
poor manageability of such small particles. The passage through
the separating top layer requires that the pores of the crystals
be in proper alignment in the direction of the material transport
through the membrane. The possibility exists that this is the case
only to a limited extent, so that large parts of the membrane surface
are not permeable. Moreover,,in practice, material transport along
the molecular sieve crystals cannot be precluded completely, which
causes a strong reduction of the selectivity.
The invention will be more readily understood by reference to the
following detailed description taken in conjunction with the accompanying
drawing wherein:
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a photograph of a porous clay layer suitable for embedding
of crystals deposited upon a two layer support member;
FIG. 2 is a photograph of a silicalite crystal embedded in a deposited
clay layer;
FIGS. 3-5 are photographs of an alumina support member having deposited
thereon a clay suspension containing embedded zeolite crystals and
a homogeneous gastight glaze film;
FIG. 6 is a photograph of a silicalite crystal incorporated in
a clay layer on a support member with a glaze applied thereto;
FIG. 7 is a photograph of four (4) juxtaposed silicalite crystals
embedded in a layer of clay and disposed upon an alumina support
member to which a thin glaze film has been applied;
FIG. 8 is a more detailed photograph of the structure shown in
FIG. 7;
FIGS. 9-12 are photographs of small holes present in a continuous
glaze films prepared in accordance with the present invention;
FIG. 13 is a photograph of a wide crack in the top layer of a membrane
prepared in accordance with the present invention, the crack being
attributed to forced clamping in a measuring cell;
FIGS. 14 and 15 are photographs of bonding effected between a glaze
layer and an alumina layer used in the practice of the present invention;
FIG. 16 is a photograph of the membrane of FIGS. 14 and 15 after
the deposition thereon of a thin glaze film;
FIG. 17 is a photograph of a membrane in accordance with the present
invention showing that the deposition of a glaze powder under zeolite
crystals is avoided by appropriate disposition of crystals and support
member; and
FIG. 18 is a photograph of a crystal embedded in a glaze matrix
which was polished until the crystal surface was reached.
Therefore, according to the invention, a membrane with molecular
sieve properties is proposed, in which the abovementioned disadvantages
do not occur. The membrane according to the invention comprises
a macroporous support to which molecular sieve crystals have been
applied substantially as a monolayer, between which crystals is
present a matrix gastight at least to a degree sufficient under
practical conditions.
In the membranes according to the invention, the orientation of
the molecular sieve crystals on the support is important. In nature,
a wide variety of molecular sieves are known, while intensive research
has led to a much larger number of synthetic molecular sieves. Each
type has a specific pore structure, and often the chemical composition
is also fixed to a certain degree. The morphology may be different
for each molecular sieve, although it can generally be influenced.
Finally, the particle size for each molecular sieve is also adjustable
to a certain maximum size.
In the membranes according to the invention, the morphology, the
particle size and the pore structure of the molecular sieve crystals
are important parameters. Molecular sieves may have a one-, two-
or three-dimensional pore structure. In the case of a three-dimensional
pore structure, in which the pores are equal in all three main directions
(e.g., zeolites A, X and Y), the particle size is important. Since
the crystals having a regular morphology crystallize out (cubic:
zeolite A, or octahedral: zeolites X and Y), orientation on the
support is of minor importance. To properly arrange such crystals
in a membrane configuration, the crystal size is preferably at least
10 .mu.m.
If, however, the pores of a type of molecular sieve extend only
in two or even one main direction (for instance, AlPO.sub.4 -5
VPI-5 mordenite and Nu-10), the crystals must be oriented on the
support in such a manner that to a substantial extent the pores
of the crystals form a significant included angle with the support
surface. If such a type of molecular sieve is arranged in the membrane
configuration according to the invention, the crystal morphology
is of great importance. It has been found that many molecular sieves
preferably crystallize out in the form of needles, the pores being
oriented exactly in the direction of the long axis. In that case,
incorporation in a membrane according to the invention becomes virtually
impossible. In many cases, however, it is quite possible to influence
crystallization in such a manner that the molecular sieve crystallizes
out in a flat form, with the pores oriented exactly in the direction
of the minimal size. It is preferred to use molecular sieves of
such a morphology, because then a relatively large surface is covered
with each crystal. Moreover, the thickness of the active layer is
thus reduced as much as possible.
For such types of molecular sieves, the thickness of the crystals
is preferably not less than 2 .mu.m. The width and length of the
crystals is preferably at least 10 .mu.m, so that the orientation
on the support in the desired direction can be properly realized.
Although crystals in the form of sheets or tiles are preferred,
this is not a prerequisite.
In the membrane according to the invention, therefore, in principle
any type of molecular sieve can be used. It is to be expected that
for most types of molecular sieves, crystals having a suitable morphology
can be obtained. For different types of molecular sieves, the preparation
of large crystals has already been extensively studied and described
in the literature. In this connection, reference may be made to,
for instance, the following publications: J.F. Charnell, J. Crystal
Growth 8 (1971), 291. This publication describes the preparation
of large crystals of the molecular sieve types A and X, the crystals
of the A-type being cubic and of the X-type octahedral.
The preparation of a molecular sieve of the AlPO.sub.4 -5 type
(AFI; a porous aluminum phosphate) is described in U.S. Pat. No.
4310440 and in the publication by S. T. Wilson et al. in J.Am.Chem.Soc.
104 (1982), 1146. The preparation of this type of molecular sieve
is also described by S. Qiu et al in Zeolites 9 (1989), 440-444
according to which also very large single crystals can be formed.
It is a disadvantage of this synthesis, however, that the pores
are in the longitudinal direction of the crystals. The preparation
of an AlPO-type molecular sieve having very wide pores (VPI-5) is
described by M. E. Davis et al. in Zeolites 8 (1988), 362.
A special example is zeolite ZSM-5 (MFI) . This type of molecular
sieve has been extensively studied, and different morphologies of
this type are known. Although this zeolite exhibits a three-dimensional
pore structure, a pore direction can actually be indicated in two
main directions only: the socalled straight and sinusoidal channels.
There are different publications indicating that the transport through
the straight and sinusoidal channels is not completely identical
(for instance, E. R. Geus et al. in "Zeolites for the Nineties",
Recent Research Report, Book of Abstracts of 8th Int.Conf. on Zeolites,
Amsterdam, (1989), No. 135 293-295).
The two most frequent morphologies of ZSM-5--the prismatic and
cube or tile morphology--can be prepared in different ways. When
crystals having the prismatic morphology are arranged in a membrane
configuration according to the invention, there is a random distribution
of straight and sinusoidal channels. When cubical crystals are used,
a membrane with mainly straight channels can be produced, because
there is one clear preferred orientation. Therefore, with these
two different morphologies of ZSM-5 type crystals, membranes of
dissimilar properties can be prepared.
U.S. Pat. No. 3702886 discloses the preparation of a molecular
sieve of the ZSM-5 type. The preparation of an aluminium-deficient
variant of ZSM-5 (silicalite) has been described by E.M. Flanigen
et al. in Nature 271 (1978), 512. The preparation of large cubical
single crystals of ZSM-5 is dscribed by H. Lermer et al. in Zeolites
5 (1985), 131. For the so-called Sand synthesis for the preparation
of prismatic crystals of ZSM-5 reference may be made to the publication
by M. Ghamani et al. in Zeolites 3 (1983), 155-162. The fluoride
synthesis for the preparation of prismatic crystals of ZSM-5 is
described by J.L. Guth et al. in: "New Developments in Zeolite
Science and Technology", Y. Murakami, A. Iyima, J.W. Ward (Eds),
Proc. 7th Int.Conf. on Zeolites, Tokyo, Japan, Aug. 17-22 (1986),
Kodansha, Tokyo and Elsevier, Amsterdam, 121-128. It has recently
been found that by adding other elements (for instance, boron) crystals
of the ZSM-5 type can be formed with the tile morphology (for instance,
J. C. Jansen et al. "Isomorphous Substitution of Si by B, Al,
Ga, and Be during Crystallization of Large Single Crystals of Zeolite.
Part I. on the Maximum Boron Content of ZSM-5", in "Innovation
in Zeolite Materials Science", F. J. Grobet et al. (Eds), Elsevier,
Amsterdam, (1988), 133-141; J.C. Jansen et al. "Isomorphous
Substitution of Si in Zeolite Single Crystals. Part II. on the Boron
Distribution and Coordination in [B]-ZSM-5", in "Zeolites:
Facts, Figures, Future", P. A. Jacobs and R.A. van Santen (Eds),
Elsevier, Amsterdam, (1989), 679-688). In addition to the advantage
of one preferred orientation, the particle size distribution is
very narrow and can be optimally adjusted. The yield of the synthesis
is high, and a pure product is formed. Finally, a pure silicon dioxide
lattice can be formed by means of a socalled postsynthesis, which
strongly reduces the sensitivity to clogging.
An example of a molecular sieve which, in the first instance, yielded
predominantly crystals in the form of needles is mordenite. By means
of adaptation of the synthesis, however, it has been found possible
to strongly inhibit the crystal growth in the direction of the channels,
so that crystals having a suitable shape were obtained (cf P. Bodart
et al. "Study of Mordenite Crystallization III: Factors Governing
Mordenite Synthesis", in "Structure and Reactivity of
Modified Zeolites", P.A. Jacobs et al. (Eds), (1984), Elsevier,
Amsterdam, 125-132).
In this connection, it is observed that German Offenlegungsschrift
38 27 049 describes the preparation of zeolitic membranes, in which
a fully continuous layer, which is not a monolayer, of zeolite crystals
is formed on a porous support. According to the process described,
this layer is obtained by first making the surface of the support
seedactive and then dipping the support in a solution containing
the components for forming the zeolitic material. The thus applied
layer is then brought to crystallization. This must be carried out
several times. Apart from the fact that by using this method only
a few types of zeolite layers can be applied (only zeolite A is
discussed in an example), it is difficult to carry out the crystallization
in a controlled manner such that a well defined crystal film is
obtained at the surface. For this reason, it is hardly possible
to fully avoid material transport along the crystals, which adversely
affects the separation selectivity. Moreover, for molecular sieves
having an asymmetric pore structure, crystallization must be thoroughly
controlled so that the crystals are correctly oriented on the support.
In the membrane according to the invention, as stated before, a
collection of molecular sieve crystals was spread as a monolayer
over the surface of a macroporous, in particular an inorganic, support.
The support must be sufficiently flat to orient the molecular sieve
crystals in one plane. Different materials are suitable as a coarse-porous,
inorganic support. Thus, a metal support starting from sintered
metal powder can be used, but so can oxidic (ceramic) supports.
Different types of supports are commercially available. As a support,
a two-layered system is preferred. In that case, the coarse-porous
part of the support gives the necessary support, and the flat orientation
of the molecular sieve crystals can be properly realized on the
relatively thin top layer.
A gastight ceramic matrix, at least sufficiently gastight for practical
use, must be disposed between the molecular sieve crystals on the
support, so that material transport is only possible via the micropores
of the molecular sieve crystals. Requirements are further imposed
on the chemical and mechanical properties of this matrix. Thus,
the material must be inert under process conditions. Further, the
matrix material must have a correct combination of properties (modulus
of elasticity and thermal expansion coefficient), so that during
the process conduct the membrane remains intact.
This invention also relates to a method of producing an inorganic
composite membrane having molecular sieve properties. According
to this process, a layer, substantially a monolayer, of relatively
large molecular sieve crystals is applied to a macroporous support,
between which crystals a gastight matrix is provided.
The object of the methods according to the invention is to obtain
the highest possible degree of coverage of molecular sieve crystals
on the support. In this way, the maximum effective membrane surface
is realized. The form of the crystals plays an important part in
their application to the support. The sheet-like crystals of zeolite
ZSM-5 referred to above will be applied to the support with the
correct orientation almost without an exception. In addition to
the form of the crystals, the uniformity of the particle size is
also important. In that case, it appears that a very high degree
of coverage can be realized. Moreover, in that case the diffusion
path is equal in the whole membrane, so that a membrane having very
constant properties can be produced. The particle size distribution
can be properly controlled by means of the crystallization process.
In addition, there is the possibility of fractionation, for instance,
by using sieves. Particularly in the case of single crystals, the
use of sieves will be advantageous, as has been demonstrated in
the fractionation of silicalite crystals. It appears that due to
the prismatic form of this molecular sieve only the single crystals
can pass through the smallest sieve openings (<38 .mu.m) . Material
grown together will generally be too broad.
According to one method, an amount of molecular sieve crystals
which is sufficient and not too large to form a monolayer is scattered
on the support. When subsequently, for instance by means of low-frequency
vibrations, a monolayer is formed, it appears that a degree of coverage
of about 80% can be realized. An even higher degree of coverage
can be realized by means of a liquid flow over a porous support
saturated with the same liquid, which support pushes up the molecular
sieve crystals to form an almost continuous layer on the support.
It is also possible to treat the molecular sieve crystals, in the
first instance, with a surfactant, so that the crystals obtain a
surface having a hydrophobic character. Thus treated molecular sieve
crystals remain afloat on water and are found to assume substantially
a juxtaposed position. A macroporous support can be disposed under
the thus formed monolayer of molecular sieve crystals, after which
the water level is lowered to the upper side of the support. The
crystals are thus applied to the support in a high coverage.
In the preparation of the membranes according to the invention,
it is generally advantageous to attach the molecular sieve crystals
to the support to a certain degree before applying the matrix material.
This attachment may be effected in different ways. When starting
from a monolayer of loose molecular sieve crystals on an inorganic
support, an attachment that is sufficient in many cases can be realized
through absorption of water or a colloidal suspension of an oxide
by the support and then drying (optionally at elevated temperatures)
of the entire system. The attachment, however, can be improved by
applying to the macroporous support an ultrathin coating of an oxide
or a mixture of oxides which already liquefies at relatively low
temperatures. A layer of, for instance, borosilicate glass (BSG)
can be deposited on the surface of an inorganic macroporous support
by means of CVD (chemical vapor deposition) techniques. Here, clogging
of the macroporous support does not occur, because the deposited
layer is too thin for that. Subsequently, a monolayer of molecular
sieve crystals is applied to the thus modified support in an otherwise
similar manner, after which the temperature is increased to the
liquefying temperature of the mixing oxide. Upon cooling, a glass
phase is formed again, fixing the molecular sieve crystals to the
support.
In an alternative method of bonding molecular sieve crystals to
the support, use is made of a silicone paste. Such material is viscoelastic
for a limited period of time. By pressing the molecular sieve crystals
into the layer of silicone paste within this period, a proper attachment
is realized. During baking out of the silicone paste, a porous silica
film is formed in which the molecular sieve crystals are properly
attached. This method is also suitable if a solution of a silicone
rubber or a highly viscous silicone oil is spread as a blanket over
molecular sieve crystals and support. The polymer solution is prevented
from penetrating into the pores of the macroporous support by filling
the support with, for instance, water. The solvent is evaporated,
and, after baking out, a similar silica film results. In principle,
in this manner other polymers can also be applied as a film, which
are completely burned during baking out. In that case, any polymer
film (e.g., polychloropropene or polybutadiene) may be applied.
Such an attachment method may be useful if the actual matrix material
can be applied at low temperatures. An additional advantage is that
the pores of the support are temporarily clogged, so that no matrix
material can be deposited between the molecular sieve crystals and
the support.
According to a preferred method, the molecular sieve crystals are
attached to the support using a highly diluted clay suspension.
Molecular sieve crystals to some extent attached to the support
are incorporated in a clay suspension by pouring an extremely diluted
clay suspension over the support. After baking out, a ceramic layer
is obtained which is thinner than the molecular sieve crystals,
so that these protrude. It is also possible to apply the clay layer
by means of a dipping technique. Then, too, the starting material
may be molecular sieve crystals that are already attached to some
extent. In an alternative method, the starting material is a clay
suspension in which the molecular sieve crystals are already dispersed.
In this case, the suspension is spread over the surface of the macroporous
support. The degree of coverage of the membrane surface is then
properly adjustable by setting a high concentration of molecular
sieve crystals. If a sufficiently homogeneous layer cannot be obtained
in one step, a homogeneous layer can still be obtained by means
of a clay suspension applied according to the first-mentioned method.
In another preferred method, the starting material is a commercial
alumina support (coarse-porous) which is provided with a thin clay
layer according to one of the above methods.
The thus modified support is baked out, and a two-layered support
is obtained, on which the molecular sieve crystals can be excellently
oriented, for instance, by means of directed low-frequency vibrations.
Subsequently, the whole pore volume of the support is filled with
water, followed by a mild heat treatment. The molecular sieve crystals
are thus sufficiently attached to the support to properly carry
out the subsequent steps in the membrane synthesis.
After the molecular sieve crystals have been applied to the support
as a monolayer and have optionally been attached thereto, the gastight
matrix is applied to the support between the molecular sieve crystals.
According to the invention, different known techniques are suitable
for applying the matrix. A distinction is made between methods by
which matrix material is applied as a blanket over both the support
and the crystals and methods by which it is selectively deposited
between the crystals. Preferably, deposition methods are used by
which matrix material is selectively applied between the crystals,
because it is not necessary, then, to remove part of the matrix
material on the crystals.
By using generally known sol-gel techniques, also discussed in
the above literature, a thin layer of matrix material can be reproducibly
deposited. A great advantage of the sol-gel technique is the good
homogeneity of the deposited material. The composition of the gel
is determined during the preparation of the sol, in which the different
components can be simply mixed on a molecular scale. Thus, sols
of mixing oxides can be simply prepared by mixing the corresponding
metal alkoxides with a solvent and water. Similarly, collodial suspensions
can be prepared very homogeneously. Binders may be added to give
the sol the desired physical properties. In addition, so-called
DCCAs (Drying Controlling Chemical Agents) may be added. Thus, the
drying process is better controlled, so that no cracks are formed
in the film.
The sols may be applied in different manners to the support provided
with a monolayer of molecular sieve crystals. The simplest method
is to pour out the sol over the support surface. Because the viscosity
of the sol has been set high by means of additives, the sol does
not penetrate into the support.
According to another suitable method, use is made of the so-called
spin-on technique (cf T. Bein et al. in Stud.Surf.Sci.Catal. 49
(1989), 887-896), in which a flat support is rotated very rapidly.
By using this method, a very homogeneous layer of matrix material
can be deposited on a support.
According to yet another method, use is made of the known dip-coating
technique referred to above (cf A. Leenaars, "Preparation,
Structure and Separation Characteristics of Ceramic Alumina Membranes",
PhD thesis, University of Twente, Netherlands, (1984); H.M. van
Veen, R.A. Terpstra, J.P.B.M. Tol, H.J. Veringa, "Three-Layer
Ceramic Alumina Membrane for High Temperature Gas Separation Applications",
in: Proc. 1st Int.Conf.Inorg.Membr., (Eds. J. Charpin, L. Cot),
Montpellier, France, Jul. 3-6 1989 329-335). According to this
technique, a suitable sol is contacted with the dry substrate for
a period of time to be controlled very accurately. At the surface
of the substrate, a phase separation of the sol takes place, comprising
absorption of the liquid into the porous support and deposition
of the sol particles as a layer on the support. In the last-mentioned
technique, there will be almost exclusive deposition beside the
molecular sieve crystals, because the phase separation will only
take place on the surface of the macroporous support.
After drying the gel, a xerogel is formed having a very high surface
if the sol composition is appropriately chosen. As a result, the
gel is very sintering active, so that during a heat treatment an
irreversible transition of the gel occurs and a dense film results.
By properly adjusting the composition of the gel and the heat treatment
to each other, a gastight layer of a metal oxide can already be
obtained at relatively low temperatures (400-500.degree. C.) . By
an appropriate selection of the composition of a mixing oxide, the
sintering properties can be improved, because such materials are
usually sintering active already at lower temperatures.
By employing a method utilizing the above-mentioned CVD technique
(Chemical Vapor Deposition), a matrix can be deposited from the
gaseous phase at elevated temperatures. With this method, too, it
is possible to deposit layers of one metal oxide or a mixture of
oxides. For nearly every metal, precursor molecules for carrying
out the CVD process are available. Silicon dioxide films can be
deposited, for instance, by means of the oxidation of silane or
the pyrolysis of alkoxy silicates (for instance, the decomposition
of tetraethyl orthosilicate; B. Delperier et al., "Silica CVD
from TEOS on Fe/Cr/Ni Alloy", Proc. 10th Int.Conf. on CVD,
The Electrochem.Soc., Pennington, N.J., (1987), 1139-1146). However,
for the production of a membrane according to the invention, the
deposition of borosilicate glasses will be preferred, because in
that case the deposition temperature can be considerably lower.
The process by means of the oxidation of hydride compounds (silane
and borane) has long since been known (e.g., W. Kern, R.C. Heim,
J.Electrochem.Soc. 117 (1970), 562-567). The decomposition of alkoxides
as the above-mentioned tetraethyl orthosilicate and trimethyl borate
is advantageous, however, not in the last place because of the fact
that such compounds are much less explosion-sensitive. Such processes
have long since been known too (for instance, P. Eppenga, et al.,
Journal de Physique, Colloque C5 (1989), 575-584).
Because of the simple process conduct, the CVD process is preferably
carried out under atmospheric pressure. In alternative methods,
for instance, a plasma is used, so that these methods can be carried
out at much lower temperature and, in many cases, at reduced pressure,
because the reactant supply is limiting due to the low vapor tension
of the reactants. The deposited layer may not yet be gastight after
deposition. By means of a thermal posttreatment (optionally a hot
pressing technique), however, a gastight layer can be formed in
a simple manner.
In a special embodiment, use is made of the possibility of supplying
the reactants separately. In that case, the process can be carried
out in the membrane module itself. This is sometimes referred to
as Chemical Vapor Infiltration (CVI). By properly adjusting the
pressure on both sides of the substrate, it is possible to realize
a very local deposition. Such a process has already been studied
for a long time in connection with the development of solid fuel
cells (SOFC) . A thin film of yttrium-stabilized zirconia is deposited
on a macroporous support as a top layer, the chlorides of yttrium
and zirconium being presented on one side of the substrate and a
mixture of oxygen and water on the other side. In the first instance,
the deposition proceeds according to above-discussed CVD process.
After the pores of the substrate have become clogged owing to the
deposited layer, further growth takes place, because oxygen ions
can diffuse through the deposited layer. Thus, layers having a thickness
of 20 to 50 .mu.m can be formed (cf U.B. Pal, S.C. Singhal, "Electrochemical
Vapor Deposition of Yttria-Stabilized Zirconia Films", in Proc.1st
Int.Symp. on Solid Oxide Fuel Cells, The Electrochemical Society,
Vol. 89-11 (1989), 41-56; J.P. Dekker, N.J. Kiwiet, J. Schoonman,
"Electrochemical Vapor Deposition of SOFC Components",
in Proc.1st Int.Symp. on Solid Oxide Fuel Cells, The Electrochemical
Society, Vol. 89-11 (1989), 57-66; Y. S. Lin et al., in Proc.1st
Int.Symp. on Solid Oxide Fuel Cells, The Electrochemical Society,
Vol. 89-11 (1989), 67-70; and N. J. Kiwiet, J. Schoonman, "Electrochemical
Vapor Deposition: Theory and Experiment", in Proc. 25th Intersociety
Energy Conversion Engineering Conference, Vol. 3 Paul A. Nelson,
William W. Schertz and Russel H. Till (Eds), (1990), American Institute
of Chemical Engineers, New York, 240-245.
In each of the above-mentioned CVD processes, very advantageous
use can be made of an applied porous intermediate layer which partly
fills the space between the molecular sieve crystals. Thus, the
deposition of matrix material under the crystals can be avoided.
This applies to the normal CVD processes but especially also to
the above-descrihed CVI process. In the CVD process, deposition
on the molecular sieve crystals is hard to avoid. In the CVI process,
this largely depends on the process conditions. Selective removal
of matrix material on the molecular sieve crystals is quite possible,
however, by means of polishing or etching techniques, which will
hereinafter be explained.
In a preferred method of applying the matrix, glaze powders are
used that melt at low temperatures. An advantage of using such glazes
is the great freedom of composition of the matrix material, so that
an optimum combination of material properties can be obtained. The
glaze must liquefy sufficiently to result in a gastight and properly
adhering layer during the heat treatment. The viscosity of the glass
during the heat treatment must be sufficiently high, so that the
glaze is only applied to the macroporous support. Because eventually
the membrane will also be used at high temperatures, the temperature
during preparation must be significantly higher than the process
temperature. It is also necessary that the regeneration can be carried
out at a considerably lower temperature than the preparation temperature.
Suitable glazes are often commercially available.
The application of the glaze can be realized in many ways. For
instance, a suspension of glaze powder can be applied over a monolayer
of molecular sieve crystals on a macroporous support. Use can also
be made of "spray" techniques, while glaze powder can
also be applied to the support in dry form. If the molecular sieve
crystals are attached to the support sufficiently firmly, the glaze
can be selectively applied beside the molecular sieve crystals.
In that case, a fine powder is applied over the entire support in
dry form, whereafter powder located on the molecular sieve crystals
is swept off. In such a method, it is desirable that the molecular
sieve crystals be much larger than the powder particles of the glaze.
Preferably, the glaze is applied using a strongly diluted glaze
suspension. This method can be carried out directly in a macroporous
support in module form, for instance a tubular module. The molecular
sieve crystals may already have been bonded to the support in one
of the manners mentioned. However, it is also possible to apply
the crystals to the support in situ from a suspension. In that case,
the support is completely enclosed by a fluid phase. By allowing
fluid to flow through the support continuously, the molecular sieve
crystals are attached to the support surface. The glaze suspension
is then added to the fluid flow and the glaze particles are retained
as a filter cake on the free surface of the support. The fluid flow
also fixes the glaze powder. By the accumulation of particles on
the support, the pressure drop across the module increases over
time. This pressure drop can serve as a measure for the thickness
of the layer deposited. As soon as the layer has a sufficient thickness,
the addition of the glaze suspension is discontinued. The powder
particles present on the molecular sieve crystals are removed by
the still ongoing fluid flow, while in the glaze powder layer further
densification occurs. The fluid is then absorbed by the support,
followed by a heat treatment.
According to a particularly suitable embodiment of the above-described
method, use is made of the specific advantages offered by the dip
process. The molecular sieve crystals are first attached to the
macroporous support, preferably using the above-mentioned clay suspension.
Then a glaze suspension of very fine powder is prepared. The homogeneous
dispersion of powder particles is obtained through ultrasonic vibration
of the suspension and subsequently allowing the larger particles
to sink. The support, flat in this case, provided with molecular
sieve crystals, is dipped into the glaze suspension for a few seconds
by the side thereof on which the layer of glaze is to be deposited.
This so-called dipping must be carried out carefully so as to prevent
complete submersion of the support. Through phase separation, discussed
above, glaze powder is selectively deposited beside the molecular
sieve crystals on the support. A thin layer of extremely thin powder
is formed, in which larger pores are clearly observable. During
the temperature treatment, sufficient liquefaction occurs for a
proper continuous glaze to be formed. The dip process can optionally
be carried out several times in succession with intermediate drying
of the substrate. Even after baking out, it is possible to carry
out the dip process once more, which can be used with great advantage
as an in situ repair technique.
As explained hereinabove, in a number of methods of applying the
matrix material, this material is deposited as a blanket over both
the support and the molecular sieve crystals. In that case, by means
of etching or polishing, for instance, the matrix material is selectively
removed from the molecular sieve crystals. These techniques are
known per se. Depending on the flatness of the macroporous support
and the particle size distribution of the molecular sieve crystals,
either the polishing or the etching method is chosen. During the
polishing procedure, the crystals are preferably additionally supported,
for instance using a resin. A resin layer is applied to the top
layer of the membrane, whereafter both the resin and the matrix
material on the crystals are ground off gradually. The remaining
resin is removed through oxidation or dissolution.
When an etching method is used for the removal of the matrix material
from the molecular sieve crystals, this method may be a wet (chemical)
or dry (via a plasma) etching method, depending on the compostion
of the matrix material. Thus, for instance silicon dioxide can be
removed in a very well controlled manner using an aqueous solution
of hydrogen fluoride or using a plasma of a fluorocarbon compound
such as CF.sub.4 (Ch. Steinbruchel et al., "Mechanism of Dry
Etching of Silicon Dioxide", J.Electrochem. Soc. 132 (1), (1985),
180-186), C.sub.2 F.sub.6 (T.M. Mayer, "Chemical Conversion
of C.sub.2 F.sub.6 and Uniformity of Etching SiO.sub.2 in a Radial
Flow Plasma Reactor", J.Electronic Soc. 9 (3), (1980), 513-523),
or CHF.sub.3 (H. Toyoda et al., "Etching Characteristics of
SiO.sub.2 in CHF.sub.3 Gas Plasma", J.Electronic Mat. 9 (3),
(1980), 569-584). As will be clear, when the support is finished,
the support can be removed using a suitable method depending on
the support used, so that a membrane film is obtained.
The membranes according to the invention can be used for any application
for which at present thermostable membrane configurations are proposed,
and in particular for separations at molecular level. Because molecular
sieves and in particular zeolites such as ZSM-5 and zeolite Y are
used in catalysis, the invention also relates to a catalytically
active membrane having molecular sieve properties.
For some decades now, research has been done into the use of catalytically
active membranes. For an extensive review, reference is made to
V. T. Zaspalis, Catalytically Active Ceramic Membranes; Synthesis,
Properties and Reactor Applications, PhD thesis, University of Twente,
Netherlands, (1990).
Such a membrane with catalytic properties can be obtained according
to the invention by providing catalytic centres in the pores of
the membrane and/or on the surface thereof prior to, during or after
production, using a technique which is known per se.
Here, the thermal stability of a membrane thus obtained is essential
because a great many catalytic processes take place at elevated
temperatures (higher than permissible for organic polymers). In
addition, it is often necessary to reactivate the catalyst (molecular
sieve) in an oxidizing environment at elevated temperatures.
The catalytically active membranes according to the invention may
contain the conventional catalytically active molecular sieves as
well as molecular sieves modified, for instance, by isomorphous
substitution, ion exchange or satellite formation.
The various stages of the production of the membrane according
to the invention will now be further explained in and by the following
examples and with reference to the accompanying photographs.
EXAMPLE 1
a) Preparation of uniform single crystals of ZSM-5/-silicalite.
Silicalite crystals were prepared using the Sand method (Zeolites
3 (1985), 155-162). The synthesis mixture consisting of 27.2 tetrapropyl
ammonium bromide (TPABr, CFZ), 207.2 g sodium hydroxide (NaOH, Baker),
167.4 g colloidal silicon dioxide (Ludox AS40 E. I. du Pont de
Nemours) and 125.8 g water was heated for 162 h at 180.degree. C.
in a teflon-coated autoclave. In the last phase of the synthesis,
the crystals were in a gel phase, which, using a caustic soda solution
(0.5 M) was removed at approx. 70.degree. C. The crystals were calcined
at 450.degree. C. (temperature increase 1.degree. C./min) . Then
the crystals were fractionated by means of sieves. The fraction
smaller than 38 .mu.n consisted exclusively of prismatic single
crystals.
b) Applying a monolayer of silicalite crystals to an .alpha.-alumina
support.
Silicalite crystals were applied to an .alpha.-Al.sub.2 O.sub.3
two-layer support (NKA, Petten) of a diameter of 25 mm and a thickness
of 2.5 mm. The supports used consisted of a coarse-porous support
layer (pore diameter 2-8 .mu.m) of pressed .alpha.-alumina granules,
to which a thin layer of .alpha.-alumina had been applied via a
slibcasting process (pore diameter 0.15 .mu.m) . Single crystals
of silicalite (prismatic; length about 200 .mu.m, thickness and
width about 30 .mu.m) were applied in dry form to the top layer
of the support, whereafter through vibration at low frquency (1-4
Hz) virtually all crystals were positioned side by side on the support.
In this manner, silicalite cyrstals with two orientations were obtained
on the support.
Both the straight and the sinusoidal channels serve as pores for
the membrane, without a preference for either of the two channels.
Then water was absorbed by the support, in such a manner that both
the crystals and the support were completely moistened. The support
was dried at about 50.degree. C. The zeolite crystals were now weakly
bonded to the alumina support.
c) Embedding the crystals in a porous clay layer.
A very strongly diluted clay suspension was prepared by mixing
3.75 g clay suspension (kaolin; Porceleine Fles, Delft), 0.08 g
quartz flour and 30 g water. The suspension was well homogenized
using an ultrasonic vibrating bath. Of this suspension, 0.5 ml was
applied to the dry alumina support, provided with zeolite crystals.
The suspension spread over the entire surface before the water penetrated
into the support. The clay layer remained on the top of the support
and as such embedded the zeolite crystals. The support was baked
out in the following manner: 1.degree. C./min: 20.degree.-95.degree.
C.; for 30 min at 95.degree. C.; 3.degree. C./min: 95.degree.-350.degree.
C./min; 2.degree. C./min; 350.degree.-900.degree. C./min; for 60
min at 900.degree. C.; 3.degree. C.
Photograph 1 shows a picture of the clay layer on the two-layer
support. Photograph 2 shows a silicalite crystal embedded in the
deposited clay layer.
d) Applying the glaze film.
A suspension of 1.35 g glaze (lead borosilicate, melting point
800-900.degree. C; Ferro B.V., Rotterdam) and 8.1 ml water was prepared.
The suspension was homogenized for 5 min in an ultrasonic vibrating
bath. The support was held in the suspension for 5 seconds and then
dried in the air. In order to obtain a homogeneous, gastight glaze
film, the following temperature programme was carried out: 5.degree.
C./min: 20.degree.-95.degree. C.; for 30 min at 95.degree. C.; 1.degree.
C./min: .degree.95-550.degree. C./min; for 300 min at 550.degree.
C.; 3.degree. C./min: 550-20.degree. C.
Photographs 3-5 show the structure of the four-layer system formed
in this manner. Photograph 6 shows a silicalite crystal which has
been incorporated in the clay layer, whereafter a glaze film has
been applied to the support.
EXAMPLE 2
Silicalite crystals were synthesized in the same manner as in Example
1. The crystals were applied to the alumina support in the same
manner and weakly bonded.
A similar clay suspension was used to apply a clay layer between
the crystals on the support. In this case, however, the clay layer
was also applied by the dip process by dipping for 5 seconds. The
clay layer was baked out in an otherwise similar manner.
The glaze film was applied and treated thermally in the same manner
as in Example 1.
Photograph 7 shows a section of four juxtaposed silicalite crystals
on the alumina support, embedded in a clay layer to which a thin
glaze film has been applied. Photograph 8 shows the structure of
the membrane in more detail.
EXAMPLE 3
In this example it is demonstrated that it is also possible, as
a first step in the production of the membrane, first to modify
the alumina support using the clay suspension. In that case it is
not necessary to use a two-layer support.
In the same manner as described in Example 1 an accurately measured
amount of clay suspension was applied over an .alpha.-Al.sub.2 O.sub.3
support consisting of one layer. The support modified in this manner
was baked out in the same manner as described in Example 1 C) at
900.degree. C. Then a monolayer of silicalite crystals was applied
to the support in the same manner as described in Example 1. The
bonding of the silicalite crystals was improved by baking out the
still humid support according to the following temperature programme:
1.degree. C./min: 20.degree.-95.degree. C.; for 30 min at 95.degree.
C.; 1.degree. C./min: 95-550.degree. C./min; for 120 min at 550.degree.
C.; 2.degree. C./min: 550-20.degree. C.
The dip process with a glaze suspension and the thermal posttreatment
were carried out in the same manner as in Example 1.
The advantage of the use of glaze powders appeared to be that the
drying step--unlike the sol-gel process--is not in the least critical.
The powder particles do not form a continuous layer but during the
subsequent temperature treatment liquefaction occurred to a sufficient
degree for a covering layer to be formed. The dip process in the
case of a glaze suspension appears to be little time-dependent as
regards the amount of deposited material, which is an advantage
over the dip coating process using colloidal soles.
Thus, a smooth, continuous glaze film was formed, which properly
conformed to the irregularities of the support. In some supports
the irregularities appeared to be too large, so that a few small
holes were visible in the glaze coating (photographs 9 10 11 and
12). It appeared to be quite possible to further close these holes
with the same dip coating process. Because the glaze suspension
of water poorly moistens the glaze surface, it becomes possible
to deposit virtually exclusively glaze powder on the holes still
present. The redundant glaze powder can be removed using a water
flow.
Using the dip coating technique, it also appeared to be possible
to repair a composite membrane. Photograph 13 shows a wide crack
(about 15 .mu.m wide) in the top layer of the membrane, which was
the result of forced clamping in a measuring cell. The crack, which
extended centrally throughout the preparation, was completely filled
with glaze powder. The preparation was baked out in the same manner
as in Example 1 and appeared to close the crack completely.
Normally, the thin coating of glaze obtained exhibited no cracks,
not even during repeated heating and cooling. Indentation tests
demonstrated the much better mechanical strength of the thin glaze
film relative to the thicker glaze film which was obtained by pouring
an amount of glaze suspension over the support. The thin glaze film
which has been formed using the dip coating technique appears to
be much more homogeneous than the thicker glaze film formed through
pouring of a suspension. This is partly due to the fact that in
the dip process exclusively very small glaze powder particles are
deposited.
EXAMPLE 4
The above experiments could also be carried out without using an
intermediate layer. In that case, crystals were only weakly bonded
to the .alpha.-alumina support in the manner described in Example
1. Then a layer of glaze was applied by the dip process, whereafter
the layer of glaze was melted by heating in an analogous manner
to that in Example 1. It is possible that in this manner glaze also
penetrates between the crystals and the support. The photographs
14 and 15 show the eminent bonding between the glaze film and the
.alpha.-alumina top layer. It appears a very thin glaze film can
be applied uniformly over the entire support surface (photo 16).
Photograph 17 demonstrates that deposition of glaze powder under
the zeolite crystals can be prevented, provided crystals and support
are sufficiently continuous relative to each other.
EXAMPLE 5
Silicilate crystals were obtained in the same manner as described
in Example 1 and applied to a stainless steel support (Krebsoge),
which had been provided with a thin layer of silicone paste (Bizon).
The support was baked out at 400.degree. C. (temperature increase
1.degree. C./min) . Then the support was placed in a bath and, using
a level, arranged entirely horizontally. As much 111-trichloroethane
was added as was necessary to precisely fill up the support. Then
50 .mu.m of a tetraethyl orthosilicate (TEOS) sol (TEOS : water
: ethanol=1 : 2 : 4) was poured out over the support. By removal
of the solvent (ethanol) from the sol through evaporation and dissolution
in the trichloroethane phase, gelation took place. The assembly
so obtained was dried overnight and then baked out at 500.degree.
C. (temperature increase 1.degree. C./min).
EXAMPLE 6
Silicalite crystals were obtained and applied to an .alpha.-alumina
support in the same manner as in Example 1. The support was introduced
into a CVD reactor (horizontal hot-wall reactor). Trimethyl borate
(TMB) and tetraethyl orthosilicate (TEOS) were introduced into the
reactor via evaporators. The reactant flows were 50 sccm (TMB) and
200 sccm (TEOS), respectively. The unit sccm stands for cm.sup.3
/min at 25.degree. C. and 1 bar. The deposition was carried out
at 700.degree. C. and 0.6 torr.
Deposition was performed for 6 hours, which yielded a borosilicate
glass layer of a thickness of about 4.8 .mu.m.
In this manner a homogeneous glass layer was obtained which had
been deposited adjacent to and on top of the crystals. Some deposition
had also taken place under the crystals.
Using inter alia polishing techniques which are known per se, matrix
material could be selectively removed from the top of the crystals.
This is demonstrated by photograph 18 where a crystal which had
been embedded in a glaze matrix was polished until the crystal surface
had been reached. In this case polishing was done using a very fine
alumina powder (.beta.-Al.sub.2 O.sub.3 0.3 .mu.m diameter; Union
Carbide). In the case of borosilicate films, etching techniques
also proved eminently useful.
EXAMPLE 7
In the production of a membrane, substantially the method according
to Example 1 was used, but now no clay layer was used, in view of
the good compatibility of .alpha.-alumina and borosilicate glass
(pyrex).
Again, the process started from a monolayer of silicalite crystals
on a macroporous support. In this case, in an analogous manner to
that used with the clay suspension, a suspension of pyrex glass
powder (P5; mesh 250) which had first been properly homogenized
by ultrasonic vibration, was poured over the support (1 g pyrex
P5 powder, 10 g demineralized water). On the support a powder layer
was selectively formed beside the silicalite crystals. The borosilicate
film (melting point about 800.degree. C.) was baked out at about
825.degree. C. (heating rate 1.degree. C./min).
EXAMPLE 8
A composite membrane was prepared in a manner as described in Example
4 with incorporation of an amount of crystals of the zeolite A
type. Zeolites of the type A were synthesized according to Charnell
(J. F. Charnell, "Gel Growth of Large Crystals of Sodium A
and Sodium X Zeolites", J.Cryst. Growth 8 (1971), 291-294).
A mixture of sodium silicate (25.0 g), triethanolamine (56.0 g),
sodium aluminate (20.0 g) and 360.1 g water was heated for one week
at 75.degree. C. Both single crystals and twined crystals of zeolite
A proved to have been formed with a maximum size (cube-shaped) of
about 15 .mu.m. Without further processing, these crystals were
applied to a two-layer support (alumina; NKA, Petten) by spreading
a suspension of crystals over the water-saturated support using
a nylon thread.The support was dried at 50.degree. C., whereafter
a glaze suspension (see Example 1) was applied by the dip process.
The following temperature programme was then carried out: 1.degree.
C./min: 20-95.degree. C.; for 30 min at 95.degree. C.; 1.degree.
C./min: 95-550.degree. C; for 60 min at 550.degree. C.; 2.degree.
C./min: 550-20.degree. C. |