WO2014016524A1 - Composite membranes, the preparation method and uses thereof - Google Patents

Abstract

The present invention relates to a composite membrane comprising: a porous support structure (2), and a separating layer (1), said separating layer consisting of a porous host layer of which the pores are filled with at least one polymer (4), consisting of oligomers, and covalently grafted to the interior of said pores, on the surface thereof, the ratio between the "size of the pores of said host layer" and the "length of said oligomers, calculated on the assumption that the chain is unfolded" being in a range of approximately 0.2 to approximately 3, particularly approximately 0.3 to approximately 1, particularly approximately 0.2 to approximately 0.9 and particularly approximately 0.5 to approximately 1.

Description

 COMPOSITE MEMBRANES, PROCESS FOR THEIR PREPARATION AND THEIR

 USES

The invention relates to composite membranes, their method of preparation and their use in particular for enriching a medium in at least one substance contained in a fluid mixture.

Filtration devices, such as polymeric or composite membranes, are known for enriching media in one or more permeable substances through said devices. These membranes, depending on the characteristics of the elements that constitute them, allow to pass only certain compounds.

 Over the past decades, tremendous progress has been made in the design, microstructure and formulation of polymer membranes to improve their performance. Improvements have been made in the separation factor, permeability, stability and cost of membrane production and use.

A first type of membrane corresponds to asymmetric polymer membranes for the gas separation, they consist of a thin layer of 0.1 to 0.5 micrometer thickness of polymer on a very thick porous support structure of 100 at 200 micrometers of polymer. However, the flow of gas through such membranes are generally low and high pressures are often required to achieve acceptable permeance, greater than about 10 ^"8 mol / (m ² s Pa).

Another type of asymmetric membrane comprises a ceramic support (alumina) surmounted by a polymer surface layer, wherein the ceramic is alumina and the polymer is a polydimethylsiloxane (PDMS). These membranes make it possible to couple the mechanical, thermal and chemical stability of the ceramic support with the separation properties of the PDMS coating (SM Dutczak et al., "Composite capillary membrane for solvent resistant nanofiltration SRNF", Journal of Membrane Science 372 (2011) 182 -190). Studies of the effects of the molecular weight of PDMS on the characteristics of a PDMS / ceramic membrane have demonstrated the value of using PDMS with a high molecular weight (average molecular weight greater than 70 000 g / mol) to obtain a flawless polymer coating (Wang Wei et al., "Effects of polydimethylsiloxane (PDMS) molecular weight on the performance of PDMS / ceramic composite membranes" Journal of Membrane Science 375 (2011) 334-344). In these membranes, the polymer is mechanically fixed to the support by infiltration of the polymer into the ceramic, which is allowed by the roughness of the surface. ceramic. A potential disadvantage of such membranes lies in the rapid degradation, in particular by decohesion or mechanical erosion of the polymer layer due to the conditions of use of the membrane.

 Another type of recently developed membranes relates to pervaporation membranes whose polymer layers are polymerized directly on the ceramic support by the condensation of oligomers "A" polymer directly on oligomers "B" grafted beforehand on the ceramic membrane ( Yoram Cohen, "Ceramic supported polymer pervaporation membrane", US Patent No. 6,440,309). This technique makes it possible to obtain a polymer phase covalently bonded to the support, thus presenting a greater resistance to the conditions of use of the membrane. However, in view of the size of the oligomers and the surface-polymerized layer, the membranes may have permeability, heat resistance and erosion resistance limited by the intrinsic properties of the polymer.

One of the aims of the invention is to propose composite membranes whose permeability and selectivity properties are reproducible and durable.

 Another object of the invention is a simple and robust process for the preparation of composite membranes whose permeability and selectivity properties are reproducible and durable.

The invention consists of a composite membrane comprising:

 a porous support structure, and

 a separating layer,

 said separator layer being constituted by a porous host layer whose pores are filled with at least one polymer, consisting of oligomers, and grafted covalently onto the surface of said pores,

 the ratio of "pore size of said host layer" to "length of said oligomers, calculated assuming unfolded chain," in a range of about 0.2 to about 3.

The invention consists of a composite membrane comprising:

 a porous support structure, and

a separating layer, said separator layer being constituted by a porous host layer whose pores are filled with at least one polymer, consisting of oligomers, and covalently grafted inside said pores, on the surface thereof,

 the ratio of "pore size of said host layer" to "length of said oligomers, calculated assuming unfolded chain," in a range of about 0.2 to about 3.

The inventors have found that the ratio between the "size of the pores of the host layer" and the "length of the trace elements, calculated by assuming the unfolded chain" is important insofar as it allows a filling of only the pores of the the host layer, without filling pores of the support structure. This selective filling makes it possible to reduce the thickness of the polymer material by avoiding filling the pores of the support structure with the polymer and avoiding or minimizing the creation of a thick layer of polymer on the surface of the separating layer. Thus, thanks to this ratio, the composite membrane has qualities of permeability and selectivity. If this ratio is less than about 0.2, the filling of the pores of the host layer by the polymer is not complete because the oligomers are too large to penetrate easily into the pores, if this ratio is greater than about 3 pore filling of the host layer by the polymer is also not complete because the oligomers are too small to completely fill the pore volume using the embodiment of the invention.

The ratio between the "pore size of the host layer" and the "length of said oligomers, calculated by assuming the unfolded chain, is in particular in a range from about 0.3 to about 1, and in particular about 0, 2 to about 0.9, and especially about 0.5 to about 1.

The composite membrane is capable of being permeable to one or more gases to allow their diffusion or to be permeable to fluids to allow their diffusion through the membrane. The evolution of the permeability to one or more gases as a function of the temperature corresponds to a thermal activation of the transport. The coefficient of permeability (Pe) of the membrane is obtained by experiments for measuring the flow of a pure gas given through the membrane. It is obtained by multiplying the measured permeance (Π) by the thickness (e) of the membrane.

P _e = nxe

Permeance (Π) is used to evaluate the fluid permeability level of a homogeneous material for a given thickness. It is related to the permeability coefficient P _e (Π = P _e / e), where "e" is the thickness, in meters, of the membrane material. It characterizes the quantity of fluid passing through a square meter of material in one second for a pressure difference of one Pascal between the two faces; permeance is expressed in mol / (m ² .s.Pa). It is a normalized flow per unit of pressure. It is determined by measuring the gas flow at the membrane outlet (permeate) using a gas flow meter.

 Quantity (Permeate)

 Π Amont

 Surface (Membrane) x Time x ΔΡ

Selectivity describes the ability of a membrane to separate the constituents of a mixture. The simple ratio of permeances (or permeabilities) of two pure gases a and b gives access to an so-called ideal selectivity (α * _α ¾ = Π _α / Ι¾ = P _a / Pb). For gas mixtures a / b, selectivity has _a / b is also called separation factor. It corresponds to the ratio of the molar fractions x _a and Xb of the two gases a and b, in the permeate and in the feed:

 alim

The term "porous support structure" refers to a pore structure serving as a support for a separating layer and which gives the composite membrane mechanical stability.

The term "splitter layer" refers to a porous host layer whose pores are filled with a polymer. "Separator" means that the layer has properties allowing an enrichment of a medium in one or more substances, that is to say it allows the separation of the medium to be filtered named "feed" in a filtered medium called "permeate" and retained medium called "retentate". Membranes considered efficient have sufficient permeances and selectivities, ie in general values greater than 10 ^{~ 8} mol / (m ² .s.Pa) for permeance and greater than 10 for the selectivity. However, depending on the type of mixing and targeted application, the selectivity and permeance values may vary. By way of example, for the CH ₄ / N ₂ mixture, a selectivity (CH ₄ / N ₂ ) greater than or equal to 5 is sufficient.

According to a particular embodiment of the invention, the separating layer of the composite membrane has a surface in partial or total contact with said porous support structure and an outer surface.

The term "outer surface" refers to the surface of the separator layer in contact with the feed. The other surface of the separating layer is in contact with the support structure. The term "total contact" refers to a continuous contact between the separator layer and the porous support structure. The term "partial contact" denotes a discontinuous contact between the separating layer and the porous support structure, for example due to a free space. The contact minimum according to a partial contact is equal to 65% of the geometric area of the interface between layer and support.

The term "filled" means that the internal volume of the pores of the host layer, accessible by the polymer, is occupied by said polymer with a degree of occupation such that the gas can not pass freely through the entire thickness of the polymer. separation layer by spaces left empty, including an occupancy rate of about 100%.

The term "covalently grafted" means that a covalent chemical bond is established between the polymer and the pore surface within said pores.

The expression "inside the pores of the host layer, on the surface thereof" refers to the surface of the material constituting the host layer that physically forms the pores. This expression does not refer to the space above the outer surface of the separator layer.

The "length of the above oligomers, calculated by assuming their unfolded chain" is determined by considering the lengths of the chemical bonds defined in the literature and the hybridization of the atoms constituting the main chain of the oligomers.

The term "pore size" refers to the average pore diameter assuming a cylindrical shape. "Pore size" can be measured in particular by nitrogen adsorption / desorption measurements at 77K (e.g. with Micromeritics ASAP 2020 commercial equipment).

According to a particular embodiment of the invention, the pores of said support structure and / or the outer surface of said separating layer of the composite membrane are substantially free of graft polymer.

The term "substantially free of graft polymer" refers to an absence or presence in an amount of graft polymer less than 10% by volume for the support and a thickness of less than 10 nm for the outer surface.

Advantageously, the graft polymer of the composite membrane is:

 a polymer consisting of oligomers of the same nature and of the same molecular mass, the oligomers being functionalized, or

 a polymer consisting of oligomers of different nature, at least one of the oligomers being functionalized, or

 a polymer consisting of oligomers of the same nature having different molecular weights, at least one of the oligomers being functionalized.

According to a particular embodiment of the invention, the porous support structure of the composite membrane is macroporous and / or mesoporous, preferably macroporous. According to a particular embodiment of the invention, the host layer of the composite membrane consists of mesopores and / or micropores, preferably mesopores. The term "macropores" corresponds to pores larger than 50 nanometers and less than 1 millimeter.

The term "mesopores" corresponds to pores of size between 2 nanometers and 50 nanometers.

The term "micropores" corresponds to pores smaller than 2 nanometers and greater than 0.2 nanometers.

According to a particular embodiment of the invention, the pores of the host layer of the composite membrane have a homogeneous or inhomogeneous distribution and a size of about 0.5 nanometers to about 50 nanometers, in particular of about 0.5 nanometers at about 10 nanometers, and especially from about 2 nanometers to about 10 nanometers.

 According to another particular embodiment of the invention, the pores of the host layer of the composite membrane have a size of about 2 nanometers to about 5 nanometers, preferably about 3 nanometers to about 5 nanometers.

 According to another particular embodiment of the invention, the pores of the host layer of the composite membrane have a size of about 5 nanometers to about 10 nanometers, preferably about 5 nanometers to about 8 nanometers.

The term "homogeneous distribution" refers to a distribution in which, for a given plane, only pores of the same size are found, the plane being parallel to the surface of the host layer.

The term "inhomogeneous distribution" refers to a distribution in which, for a given plane, there are pore sizes.

According to a particular embodiment of the invention, the pores of the porous support structure of the composite membrane have

- a single size in a homogeneous distribution, or multiple sizes, either in a homogeneous distribution, especially in a gradient of increasing size from the mesoporous layer, or in an inhomogeneous distribution. The term "size gradient" refers to a homogeneous distribution of pore size in a plane parallel to the surface of the host layer and a gradient evolution of the pore size in the plane perpendicular to the surface of the host layer.

According to a particular embodiment of the invention, the pores of the support structure of the composite membrane which are in contact with the separating layer have a size greater than or equal to two or three times the pore size of the host layer, and in particular the size of said pores of the support structure which are in contact with the separating layer does not exceed about 100 micrometers. If the pores of the support in contact with the separating layer are of a size greater than 100 microns, then the separating layer and / or the membrane are weakened.

According to a particular embodiment of the invention, the thickness of the porous support structure of the composite membrane is from about 1 micrometer to about 1 centimeter thick, preferably from about 0.1 millimeter to about 1 millimeter.

If the thickness of the porous support structure of the composite membrane is less than 1 micrometer, then the support structure and / or the membrane are weakened. Beyond a thickness of 1 centimeter of the porous support structure of the composite membrane, there is no functional utility for the composite membrane.

According to a particular embodiment of the invention, the thickness of the host layer of the composite membrane is:

 equal to or greater than two or five times the pore size of said support structure which is in contact with said host layer, and

- less than or equal to 100 micrometers. If the thickness of the host layer of the composite membrane is less than twice the pore size of the support, then the host layer and / or the composite membrane are weakened and there is an increased risk of defects within the host layer. If the thickness of the host layer of the composite membrane is greater than 100 micrometers, then an increase in the pressure drop of the composite membrane occurs.

According to a particular embodiment of the invention, said porous host layer and said porous support structure of the composite membrane are made of inorganic material.

According to a particular more advantageous embodiment of the invention, the inorganic material of the composite membrane is based on alumina, zirconia, titanium dioxide or silicon compounds. According to an even more advantageous embodiment of the invention, the alumina of the composite membrane is an alpha alumina (α-Α1 ₂ 0 ₃ ) or a gamma alumina (γ-Α1 ₂ 0 ₃ ) or a transition alumina.

By "transition alumina" is meant a chi, kappa, gamma, theta, delta or eta alumina.

According to a particular embodiment of the invention, the length of the oligomers, calculated by assuming the unfolded chain, forming part of the polymer composition of the composite membrane is from about 0.2 nanometer to about 150 nanometers, in particular about 0.5 nanometer to about 8 nanometers, especially about 0.5 nanometer to about 5 nanometers, and especially about 0.5 nanometer to about 2 nanometers.

According to a particular embodiment of the invention, the oligomers of the composite membrane carry functional groups for grafting the polymer having a physicochemical reactivity, in particular post-crosslinkable functional groups such as photo-crosslinkable, heat-crosslinkable, or chemo-crosslinkable, and / or reversibly reactive in the presence of an external stimulus such as pH, temperature, light, or pressure, including amide, acid, amino, phenone functional groups. The term "physico-chemical reactivity" refers to the ability to react chemically within the pores, on the surface thereof, or with another oligomer to form covalent bonds under the effect of an external stimulus.

According to a particular embodiment of the invention, the oligomers of the composite membrane carry functional groups having a chemical reactivity, in particular functional groups such as alkoxysilane, carboxylic acid, phosphonic acid, amide, amine, imine, maleimide or fluorinated .

The term "chemical reactivity" refers to the ability to spontaneously react chemically within the pores, on the surface thereof, or with another oligomer to form covalent bonds (without the effect of a stimulus external).

The alkoxysilane functional groups can be ethoxysilane groups (Si (OC ₂ H ₅ )).

According to an advantageous embodiment of the invention, functional groups of the oligomers of the composite membrane are intended for grafting the polymer, in particular the functional groups such as alkoxysilane, carboxylic acid, phosphonic acid, amine and maleimide.

The functional groups of the oligomers for grafting the polymer correspond to the functional groups involved in establishing covalent bonds between the polymer and the material constituting the host layer.

According to an advantageous embodiment of the invention, functional groups of the oligomers of the composite membrane are intended for filtration, in particular the functional groups such as amine and fluoro group. The functional groups of the oligo-mothers intended for filtration correspond to the functional groups which are present on the polymer during filtration. According to a particular embodiment of the invention, the functional groups of the graft polymers of the composite membrane are intended for filtration, in particular the functional groups such as amine and fluoro group.

The functional groups of the graft polymers for filtration are:

 present on the structure of the grafted polymer, and

 in contact with the food (medium to be filtered).

According to a particular embodiment of the invention, the oligomers of the composite membrane comprise at least one alkoxysilane function, in particular at least one ethoxysilane or methoxysilane function.

According to a particular embodiment of the invention, the oligomers of the composite membrane are of general formula:

with RI of formula:

H ₃ C-H ₃ C-O- (H ₅ C ₂ O) Si-, H-

and R2 of formula:

or of formula:

 "N" ranging from 1 to 100, and

oligomers having a calculated length assuming the unfolded chain of from about 0.2 nanometers to about 150 nanometers, especially from about 0.5 nanometers to about 8 nanometers and a molecular weight from about 100 grams / mol to about 2500 g / mol.

According to a particular embodiment of the invention, the oligomers of the composite membrane are chosen from the following products:

 - I: PEO Triethoxysilane (Trade name); CAS NUMBER [97969-60-3]; with a molecular weight of 300 to 20,000 g / mol,

 II: PEO Bis Triethoxysilane (Trade name); CAS NUMBER

 [666829-33-0]; with a molecular weight of 300 to 20,000 g / mol,

 III: PPO 19 Bis Triethoxysilane (Trade name); CAS NUMBER

 [1017971-44-6]; with a molecular weight of 300 to 20,000 g / mol,

 IV: PMMA Triethoxysilane End group (Trade name); with a molecular weight of 300 to 20,000 g / mol,

 V: MMA co Triethoxysilane methacrylate (Trade name); CAS NUMBER [75944-16-0]; with a molecular weight of 300 to 20,000 g / mol,

Some of these oligomers are found, for example, in the catalog of SPECIFIC POLYMERS under the following references:

 - I: "SP-1P-2-001"

 II: "SP-1P-2-006"

 - III: "SP-1P-2-026"

 - IV: "SP-4P-2-004"

- V: "SP-4P-2-002" According to a particular embodiment of the invention, the pore size of the host layer of the composite membrane is from about 0.5 nanometers to about 50 nanometers and the molecular weight of the oligomers is about 100 g / mol to about 10,000 g / mol,

 preferably the size of said pores is from about 0.5 nanometers to about 10 nanometers and the molecular weight of the oligomers is from about 100 g / mol to about 3000 g / mol,

 and in particular the size of said pores is from about 3 nanometers to about 5 nanometers and the molecular weight of the oligomers is from about 350 g / mol to about 1000 g / mol,

 and in particular the size of said pores is from about 5 nanometers to about 8 nanometers and the molecular weight of the oligomers is from about 1000 g / mol to about 2500 g / mol. According to a particular embodiment of the invention, the composite membrane is gas-tight, especially to nitrogen, especially at about 2 bar, especially at a temperature greater than or equal to 0 ° C. and less than 50 ° C.

The term "sealed" corresponds to a permeance of less than 10 ^"11 mol / (m ² .s.Pa), as measured according to the technique of gas permeation and permeate flow measurement with a gas flow meter.

According to a particular embodiment of the invention, the composite membrane is impervious, in particular at a temperature of about 0 ° C. to about 40 ° C., in particular at a temperature of about 10 ° C. to about 40 ° C., in particular a temperature of about 20 ° C to about 30 ° C, and especially at a temperature of about 25 ° C.

According to a particular embodiment of the invention, the composite membrane is selective for at least one substance contained in gases, vapors or liquids at a temperature of about 50 ° C to about 300 ° C.

Selectively means that the composite membrane is selectively selective and is capable of separating at least one substance from a set of substances. According to a particular embodiment of the invention, the composite membrane is selective especially at a temperature of about 50 ° C. to about 200 ° C., in particular from about 70 ° C. to about 180 ° C., in particular about 85 ° C. At about 165 ° C, and especially from about 100 ° C to about 150 ° C.

According to a particular embodiment of the invention, the composite membrane is selective especially at a temperature of about 50 ° C, or about 60 ° C, or about 70 ° C, or about 80 ° C or about 90 ° C, or about 100 ° C, or about 110 ° C, or about 120 ° C, or about 130 ° C, or about 140 ° C, or at about 150 ° C, or about 160 ° C, or about 170 ° C, or about 180 ° C, or about 190 ° C, or about 200 ° C.

According to a particular embodiment of the invention, the composite membrane is selective for at least one substance contained in gases, vapors or liquids, at a pressure of about 10 ^-10 bar to about 70 bar.

According to a particular embodiment of the invention, the composite membrane is selective, in particular at a pressure of approximately 1 bar to approximately 10 bar, in particular from approximately 1 bar to approximately 9 bar, in particular from approximately 1 bar to approximately 9 bar. bar, in particular from about 1 bar to about 8 bar, in particular from about 1 bar to about 7 bar, in particular from about 1 bar to about 6 bar, in particular from about 1 bar to about 5 bar, and especially from about 1 bar at about 4 bar.

According to a particular embodiment of the invention, in the composite membrane:

 the porous support structure:

^■ is in alpha alumina,

^■ has multiple sizes macropores distributed homogeneously in a gradient of increasing size from the mesoporous layer and having respective sizes of 200 nm, 800 nm and 1 000 nm,

^■ is 1 to 2 mm thick,

 - the host layer:

^■ is of gamma alumina or transition alumina, ^■ has multiple sizes mesopores in the range of about 3 nanometers to about 5 nanometers,

^■ has a thickness from about 1 to about 5 μιη μιη, in particular approximately 3 μιη,

 the polymer grafted inside the mesopores of the host layer, on the surface thereof:

^■ is a polymer consisting of one of the following oligomers:

 I: PEO Triethoxysilane; CAS NUMBER [97969-60-3]; having a molecular weight of 632 g / mol, or

 I: PEO Triethoxysilane; CAS NUMBER [97969-60-3]; with a molecular weight of 1161 g / mol.

According to another particular embodiment of the invention, in the composite membrane:

 the porous support structure:

^■ is in alpha alumina,

^■ has multiple sizes of macropores distributed homogeneously in a gradient of increasing size from the mesoporous layer and having respective sizes of 200 nm, 800 nm and 1 000 nm, ■ has a thickness of 1 at 2 mm,

 - the host layer:

^■ is of gamma alumina or transition alumina,

^■ has mesopores of multiple sizes in the range of about 5 nanometers to about 8 nanometers, ■ is of a thickness of about 1 μιη to about 5 μιη, including about 3 μιη,

 the polymer grafted inside the mesopores of the host layer, on the surface thereof:

^■ is a polymer consisting of one of the following oligomers:

 I: PEO Triethoxysilane; CAS NUMBER [97969-60-3]; having a molecular weight of 1161 g / mol, or

IV: PMMA Triethoxysilane End group; with a molecular weight of 1250 g / mol, or II: PEO Bis Triethoxysilane; CAS NUMBER

 [666829-33-0] with a molecular weight of 928 g / mol, or ■ is a polymer consisting of oligomers of the same nature having molecular weights of 1,300 to 1,800 g / mol "II: PEO Bis Triethoxysilane; CAS NUMBER [666829-33-0] ".

The invention also consists of a process for preparing a composite membrane which comprises:

 a step of contacting a porous support structure surmounted by a porous host layer with oligomers, to impregnate said porous host layer of oligomers,

 the ratio of "pore size of said host layer" to "length of said oligomers, calculated assuming unfolded chain," being in the range of about 0.2 to about 3,

 a step of condensing said oligomers in at least one functionalized polymer, impregnating said porous host layer, and covalently grafting said functionalized polymer onto reactive groups present inside the pores of said host layer, on the surface thereof for filling the pores of the host layer with said graft polymer,

to obtain a porous support structure surmounted by a separating layer consisting of a porous host layer whose pores are filled with the aforesaid polymer grafted covalently inside said pores, on the surface thereof.

The term "porous host layer" refers to the separator layer prior to grafting the polymer; it overcomes the porous support structure. The pores of this porous host layer are empty prior to grafting of the polymer.

The term "impregnation of the porous host layer of oligomers" refers to the penetration of the oligomers within at least 30% of the accessible pores of the host layer.

The term "accessible pores" refers to the pores in which the trace minerals can physically access during the contacting step. The term condensation refers to the formation:

 MO-Si bridges from an M-OH hydroxyl group present inside the pores, on the surface thereof, (where M is a metal or silicon atom) and a silanol or alkoxysilane group; oligomers, or

Si-O-Si siloxane bridges between two silanol groups or a silanol group and an alkoxysilane oligomers.

The term "covalent grafting" refers to an attachment by means of a covalent chemical bond.

The expression "fill the pores" denotes an occupation of the volume of the pores concerned.

The ratio between the "pore size of the host layer" and the "length of said oligomers, calculated by assuming the unfolded chain," is in particular in a range from about 0.3 to about 1, especially about 0, 2 to about 0.9, and especially about 0.5 to about 1.

According to a particular embodiment of the invention, the porous host layer has a surface in partial or total contact with the porous support structure and an outer surface and in which the pores of said support structure and / or the outer surface of said layer porous host are substantially free of graft polymer.

According to a particular embodiment of the invention, the reactive groups present inside the pores of said host layer, on the surface thereof, are:

 present by the nature of the material used to form said porous host layer, or

 present by the nature of the material used to form said porous host layer and their number is increased by means of pretreatments, or

 - generated through pre-processing.

An example of pretreatment is an immersion in an aqueous solution whose pH is higher or lower than the zero charge point of the material forming the porous host layer. According to an advantageous embodiment of the invention, the reactive groups present inside the pores of the host layer, on the surface thereof, are hydroxyl groups. According to one particular embodiment of the invention, the oligomers comprise at least one alxoxysilane function, in particular an ethoxysilane or methoxysilane function.

According to a particular embodiment of the invention, said covalent grafting is an oxidation reaction.

The oxidation reaction of the covalent grafting is a chemical condensation reaction as defined above between the reactive groups present inside the pores of the host layer, on the surface thereof, and the reactive groups present on the polymer. .

According to a particular embodiment of the invention, said oligomers are prehydrolysed in acidic water and, if the water is not a good solvent for the oligomer, an organic solvent is also used, chosen in particular from the polar protic solvents such as methanol, ethanol, thiols, amines, carboxylic acids and, to a lesser extent, enolizable ketones, or among polar aprotic solvents such as, acetonitrile, dimethylsulfoxide, dimethylformamide, tetrahydrofuran and pyridine.

The term "acidic water" refers to water in which acid, particularly nitric acid, has been added to obtain a pH of about 2, this water is intended to ensure the hydrolysis of all the reactive groups of the oligomers.

"PH" refers to the pH of the hydrolysis water added to the oligomer solvent or the pH of the hydrolysis water if the water is a good solvent for the oligomer.

The "pH" does not match the pH of the oligomer solution.

The term "good solvent for the oligomer" refers to the ability of the solvent to dissolve the oligomer. According to a particular embodiment of the invention, is added to the pre-hydrolyzed oligomer a product resulting in an increase of pH in the case of an aqueous solution or an increase in the OH ion concentration ^"in the case of an organic solution, following a physical or chemical treatment to form a prehydrolysed soil.

The increase in pH or in the concentration of OH ^" ions consists in the evolution of the pH up to a value greater than 6, or in the evolution of the concentration of OH ions ^" up to a value greater than 10 ^"8 mol / L" Prehydrolysed soil "means the solution used to impregnate the porous host layer and contains:

 oligomers,

 water, which can be used for Poligomer dissolution,

 an organic solvent if the water is not a good solvent for the oligomer,

acid, in particular nitric or hydrochloric acid, for raising the pH of the hydrolysis water to 2,

 the product capable of causing an increase in pH following a physical or chemical treatment. The term "physical treatment" refers to a modification of the environmental parameters of the prehydrolysed soil, such as, for example, a change in temperature or pressure.

The term "chemical treatment" refers to a modification of the prehydrolysed soil by means of a chemical reaction.

According to an advantageous embodiment of the invention, said product resulting in the increase of pH in the case of an aqueous solution or an increase in the OH ion concentration ^"in the case of an organic solution, is the urea and said physical treatment is a heat treatment.

The term "heat treatment" refers to the physical treatment of thermal type.

The term "heat treatment" refers to a change in temperature. According to another advantageous embodiment of the invention, said product resulting in the increase of pH in the case of an aqueous solution or an increase in the OH ion concentration ^"in the case of an organic solution, is formamide and said physical treatment is a heat treatment.

According to a particular embodiment of the invention, the step of contacting said prehydrolysed sol and said porous host layer is carried out under vacuum.

This vacuum contacting step facilitates the deaeration of the porosity of the host layer and thus a faster and more complete impregnation of the host layer.

According to a particular embodiment of the invention, the step of contacting said prehydrolysed sol and said porous host layer is carried out selectively on the side of said porous host layer.

This step of bringing into contact selectively makes it possible to limit unnecessary impregnation of the porous support.

 The term "selective manner" refers to contacting the prehydrolyzed soil with the porous host layer in which the soil is prevented from contact with the outer face of the porous support structure.

According to a particular embodiment of the invention, the step of contacting said prehydrolyzed soil with said porous host layer is followed by a step of removing the surplus of said soil.

This surplus soil removal step avoids the systematic formation of an outer polymer surface layer which is detrimental to the permeability of the final membrane.

According to one particular embodiment of the invention, the heat treatment is carried out in at least one step, in an oven at a relative humidity of 80 to 95%, at a temperature of 80 to 100.degree. duration of several hours, especially 2 hours. This step can also be performed in other types of speakers such as vacuum bell with integrated heating plate, or in an autoclave under steam pressure.

The heat treatment has the effect of decomposing the urea or formamide contained in the prehydrolysed soil impregnated in the porous host layer. The degradation of these compounds causes an increase in pH or the OH ion concentration ^"soil prehydrolyzed impregnated, causing condensation reactive groups hydrolyzed, and thus the condensation of the oligomers in a polymer and the grafting of said polymer inside pores of the porous host layer, on the surface thereof.

According to another particular embodiment of the invention, the heat treatment is carried out under steam in an autoclave heated by microwave at 90 ° C (400W) for 2 hours and then at 150 ° C for 3 hours in a classic oven. According to a particular embodiment of the invention, said condensation step is followed by a step of drying the porous support structure surmounted by the oligomer-impregnated host layer, a step which stabilizes said polymer in the pores of the host layer. to form the separator layer. The drying step promotes the condensation of prehydrolysed oligo-mothers by removing the solvent and thus confining the reactive functions of the polymer in the pores of the host layer.

According to a particular embodiment of the invention,

 the process steps are performed in one go to perform a simple graft polymer deposit or

 at least one step is repeated at least once to perform a graft polymer multiple deposition, preferably all the steps are repeated at least once, in particular, the contacting and condensing steps are repeated at least once.

The term "simple deposition" refers to an embodiment of the membrane preparation process by performing the steps evoked once to fill the pores of the host layer. The term "multiple deposition" denotes an embodiment of the membrane preparation process by repeating at least one step at least once to fill the pores of the host layer, and in particular the expression multiple deposition denotes the realization of the method of preparing the membrane. preparing the membrane by repeating the deposition several times, in particular twice.

A double deposit makes it possible to obtain the desired sealing of the membrane at room temperature in the case where a simple deposit is not sufficient. The double deposit also makes it possible to fill in defects or larger pores present on the porous host layer.

According to a particular embodiment of the invention:

 the porous host layer has pores ranging in size from about 3 nanometers to about 5 nanometers, and

 the process steps are performed once to perform a simple graft polymer deposition.

According to a particular embodiment of the invention:

 the porous host layer has pores ranging in size from about 5 nanometers to about 8 nanometers, and

 each of the process steps is repeated once to perform a double deposit of graft polymer. According to a particular embodiment of the invention, the process for preparing a composite membrane comprises:

 a step of contacting a support surmounted by a porous host layer having a surface in partial or total contact with a porous support structure and an external surface, with oligomers which:

i. comprise at least one alkoxysilane function, in particular at least one ethoxysilane or methoxysilane function, ii. are prehydrolysed in a solvent, for example ethanol, iii. are integrated in a prehydrolysed soil containing urea, for impregnating said porous host layer of oligomers, the ratio of "pore size of said host layer" to "calculated length assuming the unfolded chain of said oligomers" being in the range of about 0.2 to about 3, especially about 0.3 to about 1, and especially from about 0.2 to about 0.9, and especially from about 0.5 to about 1,

 a step, by heat treatment, of condensation of said functionalized polymer oligomers, impregnating said porous host layer, and of covalent grafting by oxidation of said functionalized polymer onto hydroxyl groups present inside the pores of the host layer, on the surface of these, to fill the pores of graft polymer, followed by a drying step of the porous structure surmounted by the separating layer.

The drying step serves in particular to stabilize said polymer in the pores of the porous host layer.

According to another particular embodiment of the invention, the method for preparing a composite membrane comprises:

 a step of contacting a support surmounted by a porous host layer having a surface in partial or total contact with a porous support structure and an external surface, with oligomers which:

 i. comprise at least one alkoxysilane function, in particular at least one ethoxysilane function,

 ii. are prehydrolysed in a solvent, for example ethanol, iii. are integrated in a prehydrolysed soil containing formamide,

 for impregnating said porous host layer with oligomers,

the ratio of "pore size of said host layer" to "calculated length assuming unfolded chain of said oligomers" being in the range of about 0.2 to about 3, especially about 0.3 to about about 1, especially about 0.2 to about 0.9, and especially about 0.5 to about 1,

a step, by heat treatment, of condensation of said functionalized polymer oligomers, impregnating said porous host layer, and covalent grafting by oxidation of said functionalized polymer onto hydroxyl groups present within the pores of the host layer, on the surface thereof, for filling the pores of graft polymer, followed by a step of drying the porous structure surmounted by the separating layer.

The invention also consists in the use of the composite membranes described in the present application for the enrichment of a medium in at least one substance contained in gases, vapors or liquids, by contacting said composite membrane with said gases, said vapors or said liquids.

The term "enrichment" refers to the preferential filtration through the membrane of at least one substance contained in the medium to be filtered (feed) to enrich said substance (s) with the filtered medium (permeate).

 The enrichment of a medium in at least one or more substances is allowed by the selective permeation of the substance or substances with respect to other substances. Selective permeation is allowed through a combination of mechanisms such as solubility, diffusion or molecular sieving.

According to a particular embodiment of the invention, the enrichment is carried out at a temperature of about 50 ° C to about 300 ° C.

According to a particular embodiment of the invention, the enrichment is carried out in particular at a temperature of about 50 ° C. to about 200 ° C., in particular from about 70 ° C. to about 180 ° C., in particular about 85 ° C. At about 165 ° C, and especially from about 100 ° C to about 150 ° C.

According to a particular embodiment of the invention, the enrichment is carried out at a pressure of about 10 ^-10 bar to about 70 bar According to a particular embodiment of the invention, the enrichment is carried out in particular at a temperature of about 10 bar. pressure of about 1 bar to about 10 bar, in particular from about 1 bar to about 8 bar, and in particular from about 1 bar to about 6 bar. According to an advantageous embodiment of the invention, the enrichment of a medium in at least one substance consists in the enrichment of a medium in at least one gas.

According to an even more advantageous embodiment of the invention, the gas enrichment of a medium is chosen in particular from He, H ₂ , CO ₂ , CO, C¾ and N ₂ .

Typical applications of the composite membranes of the present application are:

 enrichment in gaseous hydrocarbons C1-C4, or

 - the extraction of water vapor or volatile organic compounds (VOCs),

 the separation of nitrogen or oxygen from the air,

 the separation of hydrogen from gases such as nitrogen and methane,

 - the recovery of hydrogen from the production flows of ammonia production plants,

 - recovery of hydrogen in petroleum refining processes,

 the separation of methane from other biogas components,

 the oxygen enrichment of the air in the medical or metallurgical field,

- Nitrogen enrichment of cavities in inerting systems to prevent the explosion of fuel tanks,

 - the extraction of water vapor from natural gas and other gases,

- extraction of C0 ₂ from natural gases,

- the extraction of H ₂ S from natural gases,

 - extraction of volatile organic compounds (VOCs) from the exhaust air stream,

 - desiccation or dehumidification of the air.

1. FIGURES

1.1. Figures la, lb, le, ld and

Figures la to show schematically the morphologies of the composite membranes obtained when a polymer is impregnated or grafted onto / in a ceramic membrane. The different locations of the polymer on / in the porous support are observed. Figures la and lb show typical membranes described in the prior art, Figures 1a, 1d and 1 correspond to the invention. More precisely,

 la) represents the case where the host layer (of the separator layer) and the support structure are completely filled by the polymer and a polymer layer is present at the surface; the numbers 1 to 6 represent:

 1 separating layer (porous host layer whose pores are filled with the polymer),

 2- porous support structure,

 3- polymer,

 4-pore of the porous host layer filled with the polymer (delimited by the dotted lines),

 Ceramic material constituting the porous host layer and the porous support structure,

 6- pore of the porous support structure (delimited by the dotted lines),

 lb) represents the case where the host layer (of the separator layer) and the support structure are completely filled with the polymer and there is no polymer layer on the surface; the numbers 1 to 6 represent:

 1 separating layer (porous host layer whose pores are filled with the polymer),

 2- porous support structure,

 3- polymer,

 4-pore of the porous host layer filled with the polymer (delimited by the dotted lines),

 Ceramic material constituting the porous host layer and the porous support structure

 6- pore of the porous support structure (delimited by the dotted lines),

 the) represents the case where only the host layer (of the separating layer) is filled by the polymer, the pores of the support structure do not contain any polymeric material; presence of a polymer layer on the surface; the numbers 1 to 6 represent:

 1 separating layer (porous host layer whose pores are filled with the polymer),

2- porous support structure, 3- polymer,

 4-pore of the porous host layer filled with the polymer (delimited by the dotted lines),

 Ceramic material constituting the porous host layer and the porous support structure,

 6- pore of the porous support structure (delimited by the dotted lines),

ld) it is an advantageous embodiment, corresponding to the case where only the host layer of the separator layer is filled by the polymer, the pores of the support structure do not contain polymeric material; absence of polymer layer on the surface; the numbers 1 to 6 represent:

 1 separating layer (porous host layer whose pores are filled with the polymer),

 2- porous support structure,

 3- polymer,

 4-pore of the porous host layer filled with the polymer (delimited by the dotted lines),

 Ceramic material constituting the porous host layer and the porous support structure,

 6- pore of the porous support structure (delimited by the dotted lines),

1c) represents the case where the only pores of the host layer of the separating layer, here mesoporous, are selectively filled with crosslinked oligomers, chemically grafted covalently on the ceramic grains; the pores of the support structure contain only a little polymer material, they are not filled; the numbers 1 to 6 represent:

 1 separating layer (porous host layer whose pores are filled with the polymer),

 2- porous support structure,

 3'- representation of a chain of an oligomer constituting the polymer,

4-pore of the porous host layer filled with the polymer (delimited by the dotted lines), Ceramic material constituting the porous host layer and the porous support structure,

 6- pore of the porous support structure (delimited by the dotted lines).

Figure 1d shows the case which makes it possible to obtain the best fluxes while preserving the selectivity of the polymer. Reproduction of this ideal case is not possible by conventional methods of impregnating polymers described in the prior art because the polymerization starts prior to impregnation. Indeed, these methods, unlike that of the invention, do not allow or little to promote both the selective filling of the pores of the separating layer, while avoiding the important filling of the pores of the porous support structure but also the formation of a polymer layer on the surface of the separator layer.

1.2. Figure 2

 FIG. 2 shows the schematic diagram of the synthesis of the prehydrolysed soil containing the oligomers, used to transform the porous host layer into a separating layer, that is to say to covalently graft the polymer inside the pores of the layer porous host, on the surface of these.

1.3. Figure 3

 Figure 3 shows the sectional views of the composite membranes of the present invention.

These membranes were obtained with a porous host layer of γ-Α1 ₂ 0 ₃ with pores of a size of about 3 nm to about 5 nm, after a deposition (line 1) or two deposits (line 2) of the soils Oligomers (I: "SP-1P-2-001"; II: "SP-1P-2-006"; III: "SP-1P-2- 026"; IV: "SP-4P-2-004 V: "SP-4P-2-002") in water, isopropanol or acetone. The cross-sectional views of the composite membranes of the present invention can be compared to the diagrams of Figures 1a, 1b, 1d, 1d and 1c.

A. Oligomers "I", M _w = 2250 g / mol, (solvent: H ₂ O)

 first + second deposit: type the.

B. Oligomers "II", M _w = 1550 g / mol, (solvent: H ₂ O) first + second deposit: type le

C. Oligomers "III", M _w = 1750 g / mol, (solvent: isopropanol)

 first deposit: type E, second deposit: type

D. Oligomers "I", M _w = 632 g / mol, (solvent: H ₂ O)

 first + second deposit: type le

E. Oligomers "I", M _w = 632 g / mol, (solvent: isopropanol)

 first + second deposit: type le

F. Oligomers "I", M _w = 1161 g / mol, (solvent: H ₂ O)

 first + second deposit: type le

G. Oligomers "IV", M _w = 1250 g / mol, (solvent: acetone)

 first + second deposit: type le

H. Oligomers "II", M _w = 928 g / mol, (solvent: acetone)

 first deposit: type the second deposit: type When Mw = 1690 g / mol for Poligomer IV, the first + second deposit is of the type or.

1.4. Figure 4

 FIG. 4 shows in graph form the separation of gas mixtures with the D0 membrane which is the subject of example 33.

 On the abscissa is represented the temperature and on the ordinate the separation factor.

2. PREPARATION OF THE COMPOSITE MEMBRANES OF THE INVENTION 2.1. Porous substrates and porous host layers

 Membranes ΓΑ0 to A81; ΓΒ0 to B81; fCO to C81

A tubular alumina structure (Al ₂ O ₃ ) was used. The structure is asymmetric with a host layer (3 to 5 micrometers thick) inside the gamma alumina tube and three support layers (a total thickness of 1.5 millimeters) in size alpha alumina increasing pores: 200, 800 and 1000 nm. Depending on the pore size of the host layer, two support / host layer structures have been distinguished, in the first, the pores of the host layer have a size of about 3 nanometers to about 5 nanometers, in the second, the pores of the host layer have a size of about 5 nanometers to about 8 nanometers. Membrane [DOl

 A second type of support was also used. It is a single-channel alumina tubular support provided by "CTI SA" with a so-called "15 kiloDaltons" zirconia host layer (5-10 microns thick). The pores of the host layer have a size of about 5 nm to 10 nm, and the pores of the support layer have a size of 150 to 200 nm. The length of the support is 150 mm. Said tubular single-channel support comprises at least one support layer, preferably three.

 2.2. Prehydrolysed soil

 The soil formulation is defined to obtain a constant concentration of trialkoxysilane groups in the soil equal to 0.1 M. The concentrations of urea and nitric acid are 0.01 M. For a fixed mass of each oligomer (3 grams), the amounts of solvent, urea, acid and optionally added water are indicated in the following table. 10 prehydrolysed soils were obtained.

Preparation of prehydrolysed soils:

3 grams of oligomer were inserted into a vial containing the corresponding solvent in an amount specified in the table. The solution was stirred for 1 to 10 minutes at room temperature (from about 20 ° C to about 25 ° C) until complete dissolution of the oligomer. If the water is not a good solvent for dissolving the oligomer, a minimum amount of water equal to three times the molar amount of trialkoxysilane in the solution was added to ensure the hydrolysis of all the alkoxysilane groups of the oligomer. The nitric acid, in the amount specified in the table, was previously added with stirring in water to activate the hydrolysis, as well as urea to activate the condensation by increasing the pH / the concentration of OH ^" The soil was stirred for 10 minutes, then the amount of urea specified in the table was added The final soil thus obtained was further stirred at room temperature for 1.5 hours to complete the hydrolysis. oligomers and ensure complete dissolution of the urea 2.3 Impregnation and deposit

The pre-hydrolysed soils (2.2) were impregnated into the pores of the host layer of the porous structures with a porous support structure and a porous host layer (2.1.).

The impregnation was carried out by dipping the porous support surmounted by the porous host layer in the prehydrolysed sol, optionally under vacuum for 10 minutes for better impregnation of the pores of the porous host layer, then by vertically drawing the support out of the soil.

 Then, for the heat treatment, the impregnated support was placed in an oven at 80 ° C with a relative humidity of 80% for 17 h, then at 90 ° C with a relative humidity of 70% for 1 hour. , 5h.

 Finally, drying was carried out at a temperature of 150 ° C. for 3 hours.

The thermal treatment has the particularity of decomposing the urea of the pre-hydrolysed soil impregnated in the pores of the host layer, causing an increase in pH, activating the condensation of the silanol functions and thus the polymerization / grafting of the oligo-mothers in the pores of the the porous host layer.

 The purpose of the drying step is to stabilize the membrane material in the pores. A second deposit can be performed according to the same protocol to ensure a filling of all the pores of the host layer.

The covalent grafting can be controlled by infrared spectroscopic analysis or solid ²⁹ Si NMR of the powder obtained by scraping the separating layer. We found a very small separating layer in which the proportion of Si-O-Al bridges is itself very low.

3. Procedures for measuring membrane performance

The performance of the membranes is measured by permeation of pure gases with permeate flow measurement using a gas flow meter.

To evaluate the results, they are compared with reference values previously defined.

In general, selectivity is considered as:

 low if it is lower than the Knudsen selectivity (square root of the inverse ratio of the molar masses of the 2 pure gases considered),

 - good if it is superior to the selectivity of Knudsen, and

 - excellent if it is very superior to the selectivity of Knudsen.

 1/2

For example, the Knudsen selectivity for the He / N ₂ pair is equal to (28/4) or 2.64)

It is considered that the membrane is impermeable if permeance is unmeasurable with the gas flow meter, i.e. less than 10 ^"11 mol / (m ² .s.Pa).

Permeance is considered as:

low if between 10 ^"11 and 10 ^-9 mol / (m ² .s.Pa)

good if between 10 ^{~ 9} and 10 ^{~ 7} mol / (m ² .s / Pa),

excellent if greater than 10 ^{~ 7} mol / (m ² .s.Pa).

A membrane is considered efficient if its permeance and selectivity values correspond to values judged to be good or excellent, as defined above.

However, these values are relative and dependent on the gases considered as well as targeted applications. By way of example, a CH ₄ / N ₂ selectivity of about 5-7 can be considered excellent and the membrane considered economically viable.

Also, an H ₂ / N ₂ selectivity of the order of 100 with a permeance of at least 10 ^{~ 7} mol / (m ² .s.Pa) make it possible to constitute a viable membrane. Examples 1 to 28 - Composite membranes obtained

 The membranes which were obtained after the preparation of the membranes are listed in the following table:

Typical Floor Sizes

 Number

Reference Pore of the Oligomer

 Example No. of

 Host layer membrane Reference Solvent

soil M _w (g / mol) deposits (nanometers) oligomer

1 A0 [~ 3 to ~ 5] 1 SP-1P-2-001 2,250 H ₂ 0 ¹

2 Al [~ 3 to ~ 5] 2 SP-1P-2-006 1 550 H ₂ 0 ¹

3 A2 [~ 3 to ~ 5] 3 SP-1P-2-006 1 550 Isopropanol ¹

4 A3 [~ 3 to ~ 5] 4 SP-1P-2-026 1,750 Isopropanol ¹

5 A4 [~ 3 ~ 5] 5H ₂ 0

SP-1P-2-001 ¹

 632

6 A5 [~ 3 to ~ 5] 6 Isopropanol ¹

7 A6 [~ 3 to ~ 5] 7 SP-1P-2-001 1 161 H ₂ 0 ¹

8 A7 [~ 3 to ~ 5] 8 SP-4P-2-004 1,250 Acetone ¹

9 A8 [~ 3 to ~ 5] 9 SP-1P-2-006 928 Acetone ¹

10 B0 [~ 5 to ~ 8] 1 SP-1P-2-001 2,250 H ₂ 0 ¹

11 Bl [~ 5 to ~ 8] 2 SP-1P-2-006 1 550 H ₂ 0 ¹

12 B2 [~ 5 to ~ 8] 3 SP-1P-2-006 1 550 Isopropanol ¹

13 B3 [~ 5 to ~ 8] 4 SP-1P-2-026 1 750 Isopropanol ¹

14 B4 [~ 5 to ~ 8] 5 H ₂ 0

SP-1P-2-001 ¹

 632

15 B5 [~ 5 to ~ 8] 6 Isopropanol ¹

16 B6 [~ 5 to ~ 8] 7 SP-1P-2-001 1 161 H ₂ 0 ¹

17 B7 [~ 5 to ~ 8] 8 SP-4P-2-004 1,250 Acetone ¹

18 B8 [~ 5 to ~ 8] 9 SP-1P-2-006 928 Acetone ¹

19 CO [~ 5 to ~ 8] 1 SP-1P-2-001 2,250 H ₂ O 2

20 Cl [~ 5 to ~ 8] 2 SP-1P-2-006 1 550H ₂ O 2

21 C2 [~ 5 to ~ 8] 3 SP-1P-2-006 1 550 Isopropanol 2

22 C3 [~ 5 to ~ 8] 4 SP-1P-2-026 1,750 Isopropanol 2

23 C4 [~ 5 to ~ 8] 5 H ₂ 0 2

 SP-1P-2-001 632

 24 C5 [~ 5 to ~ 8] 6 Isopropanol 2

25 C6 [~ 5 to ~ 8] 7 SP-1P-2-001 1 161 H ₂ O 2

26 l [~ 5 to ~ 8] 8 SP-4P-2-004 1 250 Acetone 2

27 C8 [~ 5 to ~ 8] 9 SP-1P-2-006 928 Acetone 2

28 DO [~ 5 to ~ 10] 10 SP-4P-2-004 1690 Acetone 2 The ratios between the "pore size of the host layer" and the "oligomer length, calculated assuming their unfolded chain" of the oligomeric / pore-tested pairs of the host layer are listed in the following table:

Example 29 - Performance of membranes A0, A1, A2, A3, A4, A5, A6, A7 and A8

The membranes A0 to A8 are obtained from host layers having pores ranging in size from about 3 nanometers to about 5 nanometers. These Membranes were made by a polymerization step of the oligomers in a single deposit.

The ideal selectivities (He permeance / N2 permeability) were measured at 25 ° C and at ΔΡ = 4 bar for the above-mentioned series of membranes, the results are grouped in the following table:

When a host layer with small mesopore sizes (about 3 to about 5 nm) is used, pore filling can be obtained from the first in-situ polymerization deposition of the smaller trace minerals. This is observed since the membrane A5 obtained with the smallest oligomers having a molecular mass ranging from 500 to 1000 g / mol (soil No. 6, SP-1P-2-001, M _w = 632 g / mol), is watertight to He and N ₂ at 25 ° C.

Then, the ideal selectivities (Π [Ηε] / Π [Ν ₂ ], II [He] / n [C0 ₂ ], n [He] / II [SF ₆ ]) were measured at 100 ° C and 150 ° C and at ΔΡ = 4 bar for the above-mentioned series of membranes, the results are summarized in the following table. 100 ° C to 150 ° C

Membrane

a He / N ₂ a He / C0 ₂ He / SFg He / N ₂ a He / C0 ₂ He / SFg

A0 2 2 6 3 2 10

Al 2 1, 2 8 3 1.3 9

 A2 - - - - - -

A3 3.5 2> 10 3.6 2 6

 A4 - - - 8 1, 4 »10

A5 - - -> 10 2.6 »10

A6 3 2 5 5 2.5 7

 A7 4.6 3, 1 6 3 1, 5 5

 A8 9 1, 5> 10> 10 0.8> 10

For low selectivities at 25 ° C., an increase in this selectivity is observed with the increase in temperature, especially for helium. This increase in temperature causes a thermal activation of the transport. The best selectivities with the host layers having pore sizes of about 3 to 5 nm, are observed with the membranes A5 (sol. No. 6, SP-1P-2-001, 632 g / mol), and A8 (sol. 9, SP-1P-2-006, 928 g / mol) thermally activated at 100 ° C and 150 ° C. These membranes were sealed at 25 ° C.

Example 30 - Performance of membranes BP to B8 and C0 to C8.

 Membranes B0 to B8 and C0 to C8 are obtained from structures whose host layer pores are from about 5 nanometers to about 8 nanometers in size. The polymerization stage of the oligomers was carried out in a single deposit for the membranes B0 to B8 and in two deposits for the membranes C0 to C8.

The ideal selectivities (He permeance / N ₂ permeance) were measured at 25 ° C and at ΔΡ = 4 bar for the above-mentioned membrane series, the results are summarized in the following table. Performance after ^1st deposit Performance after 2 ^cmc deposit

Membrane Membrane

IIHe ΠΝ ₂ a * = IIHe ΠΝ ₂ a * =

B0 4.7. If) ^-8 2.3.10 ^-8 ~ 2 CO 4.0.10 ^-10 2.1.1ο ^-10 ~ 2

Bl 9.7.1 (r ⁸ 4.9.10 ^"8 ~ 2 Cl 2.8.10 ^-10 1.2.1ο ^-10 ~ 2

B2 NM (<10 ^-11 ) NM (<10 ^-11 ) - C2 -

B3 9.4. If) ^-8 4.4.10 ^-8 ~ 2 C3 23.0.10 ^-10 10.9.10 ^"10 ~ 2

B4 56.8.10 ^-8 28.2.10 ^-8 ~ 2 C4 1 460.10 ^"10 797.0.10 ^-10 ~ 2

B5 8.5.10 ^"8 4.1.10 ^-8 ~ 2 C5 374.10 ^{" 10} 229.10 ^-10 ~ 2

B6 0.1.10 ^-8 0.02.10 ^-8 ~ 2 C6 NM (<10 ^-11 ) NM (<10 ^-11 ) -

B7 NM (<10 ^-11 ) NM (<10 ^-11 ) - C7 -

B8 2.3.10 ^-8 1.52.10 ^-8 ~ 2 C8 NM (<10 ^-11 ) NM (<10 ^-11 ) -

Π in [mol / (m ² .s.Pa)] NM: Not Measurable

α * = ΠΗε / ΠΝ ₂

The membranes obtained are N ₂ and He-tight at 25 ° C. and ΔΡ = 4 bars, after a simple deposition of SP-1P-2-006 (sol.3, M _w = 1550 g / mol; isopropanol as a solvent) or SP-4P-2-004 (sol no. 8, M _w = 1250 g / mol), corresponding respectively to the membranes B2 and B7, ie with oligomers with a mass of typically from 1250 to 1800 g / mol. For smaller oligomers (such as oligomers SP-1P-2-001 and SP-1P-2-006 with respective weights of 1,161 g / mol and 928 g / mol, ie C6 and C8 membranes), a double deposit is required. The membrane remains highly permeable (permences greater than 200 × ^{10 -10} mol / (m ² .s.Pa)) after two deposits for oligomers that are too small (M _w = 632 g / mol, C4 and C5 membranes).

Example 30 bis - Performance of C0, Cl, C2, C3, C4, C5, C6, C7 and C8 Membranes

The ideal selectivities (Π [Ηε] / Π [Ν ₂ ], II [He] / n [C0 ₂ ], n [He] / II [SF ₆ ]) were measured at 100 ° C and 150 ° C and at ΔΡ = 4 bar for the above-mentioned series of membranes, the results are grouped in the following table: 100 ° C to 150 ° C

 Reference

Membrane aHe / N ₂ aHe / C0 ₂ aHe / SF ₆ aHe / N ₂ aHe / C0 ₂ aHe / SF ₆

CO 4 -1.2> 10 6 -1.2> 10

Cl 5 ~ 1.2> 10 9 -1.2 "10

 C2 7 ~ 1> 10 10 1.2 "10

 C3 3 -1.5 6 3 -1.5 7

C4 2 ~ 1 3 2 ~ 1 3

C5 2 ~ 1 3 2 ~ 1 3

C6 3 ~ 3> 10 7 7> 10

Cl - - -> 10 3.5 "10

 C8 10 1.2> 10> 10 1.2 "10

For the membranes tested, it is observed that the ideal selectivity He / N ₂ , low at 25 ° C (see Example 30), the rest at higher temperature (100 ° C and 150 ° C). The highest selectivities (greater than 10) are obtained with the membranes C1, C2, C6, C7 and C8 which are prepared from larger oligomers (respectively SP-1P-2-006 with a molecular weight of 1 550 g / mol, SP-1P-2-001 with a molecular weight of 1,161 g / mol, SP-4P-2-004 with a molecular weight of 1,250 g / mol and SP-1P-2-006 with an equal molecular weight at 928 g / mol). The membranes C4 and C5, prepared with the small oligomers SP-1P-2-001 of molecular weight equal to 632 g / mol, have a lower selectivity (at most equal to 3 for the gases considered).

Example 31 - Summary of Performance of Membranes A5, A8, Cl, C6 and C7

 In the following table are grouped the results of the membranes, obtained from the host layers whose pores are of a size ranging from about 3 nanometers to about 5 nanometers, which have the best performance.

In the following table are grouped the results of the membranes, obtained from the host layers whose pores are of a size ranging from about 5 nanometers to about 8 nanometers and a double deposition process oligomers, which have the best performance.

In general, the membranes are non-permeable (non-measurable permeability, <10 ^{~ n} mol / (m ² .s.Pa)) at room temperature and the best compromises of permeance and selectivity are obtained between 100 ° C and 150 ° C, for the two host layers studied. For the A1 ₂ 0 ₃ host layers with a pore size of about 3 nanometers to about 5 nanometers, a simple deposit of the smaller polymers, ie low molecular weight, (sol No. 6, SP-1P-2- 001, Mw = 632 g / mol), containing a maximum of triethoxysilane groups (0.158 mol / 100 g of polymer) ("maximum" insofar as the hydrocarbon chain is very short and there are 3 silicon-bonded alkoxysilane functions) allows to generate the most efficient membranes, ie the most selective (ideal selectivity greater than 10) and the most permeable ones. This is attributed to optimized infiltration and crosslinking (the "optimized cross-linking" corresponds to a high level of condensation, ie less than 10% of the silanol groups are not condensed) of these small oligomers (molecular weight of about 600 g / mol) in the pores of the host layer, pores whose size is from about 3 nm to about 5 nm.

For the pore size A1 ₂ 0 ₃ host layers of about 5 nanometers to about 8 nanometers, two successive depositions are required to fill the pores of the host layer with the small oligomers considered. The efficiency of the pore filling of the host layer is evaluated by measuring the permeance of N ₂ after the condensation / polymerization of the oligomers.

For host layers with pores of about 5 nanometers to about 8 nanometers, the best results are obtained with SP-1P-2-006 (M _w = 1550 g / mol) and with a double deposit (membrane C1, soil n ° 2). Polymers SP-1P-2-001 (M _w = 1161 g / mol) and SP-4P-2-004 (1250 g / mol) have attractive selectivities based on the gases to be separated (C6 and C7 membranes; respectively soil No. 7 and No. 8). The polymers SP-1P-2-006 (M _w = 1550 g / mol) and SP-1P-2-001 (M _w = 1161 g / mol) are bi- and mono-functional PEGs having molecular weights in the range 1 161 - 1 550 g / mol. For this type of host layer, the small oligomers (SP-1P-2-001, M _w = 632 g / mol) (PEG, M _w = 632 g / mol) do not make it possible to obtain selective membranes under the conditions studied.

On the other hand, for the host layers with small pores of about 3 nanometers to about 5 nanometers, the best ideal selectivities are obtained at 150 ° C., with these same small polymers SP-1P-2-001 (M _w = 632 g / mol) and SP-1P-2-001 (M _w = 1161 g / mol).

Example 32 - Performance of the A5 membrane

 The following table shows the application of the membrane A5 for the separation of a gas mixture:

These results show that the CO ₂ / H ₂ selectivity can exceed 25 at 150 ° C. with a permeance of the order of 10 ^-9 mol / (m ² .s.Pa).

Example 33 - Performance of the D0 Membrane

 Several gas mixtures of equivolum composition were tested for a transmembrane pressure DP of 3.7 bar and at three different temperatures (100, 130 and 150 ° C).

The results obtained are reported in the following table:

The results are also reported as a graph in Figure 4.

 These results show that the selectivity of hydrogen relative to another gas increases with temperature which is consistent with a thermally activated transport.

A demonstration of the separation capabilities of this membrane was also carried out for a mixture of 4 molar composition gases 10% CH ₄ /20% CO ₂ /30% CO / 40% H ₂ . These measurements were carried out at 150 ° C. and at 2 bar DP (transmembrane pressure). This mixture and its composition are close to those obtained by certain processes for producing gas from biomass. Permeation Flow

 Permeate membrane

(10 ^E- 10 mol / (pa.sm ² ))

PolyCer (lh '.m ² )

 CH4 C02 CO H2

DO 0.01 9 0.5 0.2 2.9

The separation factors found in these interesting mixing conditions.

Against example 1 - Study of the applicability of the process for the preparation of composite membranes from methyltriethoxysilane

I Methyltriethoxysilan I

M = 178 g / mol

 Triethoxysilane = 0.5617 mol / 100g

 Molecular dimension calculated ~ 8,

In an Erlenmeyer flask, 0.16 g of Methyltriethoxysilane (liquid compound) was weighed and 22.36 g of acetone (synthesis solvent) was added. The solution was stirred a few minutes, especially 5 minutes. 38 mg of nitric acid (HN0 ₃ ) were added using a pasteur pipette and 17 mg of urea, the pH of the solution is then about 2. The solution was stirred again to homogenize. Finally 0.12 g of distilled water was added to hydrolyze the 3 ethoxysilane functions. The beaker was then stirred for about 2 hours at room temperature (covered with a film to limit evaporation).

 Subsequently, the solution was contacted for one minute with the tubular ceramic support 5 cm long enameled at both ends (Pall Exekia-Gamma alumina host support treated at 920 ° C-pore distribution in the range 5 cm. -8 nm). The solution was then evacuated from the bottom of the support. This step was performed twice.

 The impregnated supports were placed in the oven for 17H at 80 ° C. + 80% humidity and then 90 ° C. at 90 ° C. + 70% humidity and finally 3 hours at 150 ° C. in a conventional study.

Using this protocol and even after several deposits, the membranes are not gas-tight (N ₂ ) at room temperature (from about 20 ° C to about 25 ° C). According to this criterion, the precursor used (Methyltriethoxysilane) therefore does not allow, following this protocol, to fill the size pores in the range 5-8 nm.

After an initial deposition, the permeabilities measured at 25 ° C are very high and higher than 10 ^"5 mol / (m ² .s.Pa) for all tested gases (He, N _2, C0 _2, SF _6).

After a second deposit, the permeance helium reached 1.4 10 ^"7 mol / (m ² .s.Pa). The pore size ratio / alkoxide size here is strictly greater than 5 (50 / 8.8 = 5 6).

Claims

1. Composite membrane comprising

 a porous support structure, and

 a separating layer,

 said separator layer being constituted by a porous host layer whose pores are filled with at least one polymer, consisting of oligomers, and covalently grafted inside said pores, on the surface thereof,

the ratio between the "pore size of said host layer" and the "length of said oligomers, calculated assuming unfolded chain," being in the range of about 0.2 to about 3, especially about 0, 3 to about 1, especially about 0.2 to about 0.9, and especially about 0.5 to about 1.

The composite membrane of claim 1, wherein the graft polymer is:

 a polymer consisting of oligomers of the same nature and of the same molecular mass, the oligomers being functionalized, or

 a polymer consisting of oligomers of different nature, at least one of the oligomers being functionalized, or

 a polymer consisting of oligomers of the same nature having different molecular weights, at least one of the oligomers being functionalized.

Composite membrane according to any one of claims 1 to 2, in which the porous support structure is macroporous and / or mesoporous, preferably macroporous, and in which the host layer consists of mesopores and / or micropores, preferably mesopores,

and especially :

In which the pores of the host layer have a homogeneous or inhomogeneous distribution and a size ranging from about 0.5 nanometers to about 50 nanometers, in particular from about 0.5 nanometers to about 10 nanometers, and in particular about 2 nanometers. nanometers to about 10 nanometers, and in particular or in which:

^■ the pores of the host layer of the composite membrane have a size of about 2 nanometers to about 5 nanometers, preferably from about 3 nanometers to about 5 nanometers, or

^■ the pores of the host layer of the composite membrane have a size of about 5 nanometers to about 10 nanometers, preferably from about 5 nanometers to about 8 nanometers,

 or in which the pores of the support structure which are in contact with the separating layer have a size greater than or equal to two or three times the pore size of the separating layer and in particular the size of said pores of the support structure which are in contact with the separating layer do not exceed about 100 micrometers.

Composite membrane according to any one of claims 1 to 3, wherein the thickness of the porous support structure is from about 1 micrometer to about 1 centimeter thick, preferably about 0.1 millimeter thick. at about 1 millimeter,

and especially :

 In which the thickness of the host layer is:

 equal to or greater than two or five times the pore size of said support structure which is in contact with said host layer, and

 - less than or equal to 100 micrometers,

 Or wherein said porous host layer and said porous support structure are made of inorganic material, in particular based on alumina, zirconia, titanium dioxide or silicon compounds, the alumina being in particular an alpha-alumina

(α-Α1 ₂ 0 ₃ ) or a gamma alumina (γ-Α1 ₂ 0 ₃ ) or a transition alumina.

Composite membrane according to any one of claims 1 to 4, wherein the separating layer has a surface in partial or total contact with said porous support structure and an outer surface, and in particular in which the pores of said support structure and / or the outer surface of said separator layer is substantially free of graft polymer.

The composite membrane according to any one of claims 1 to 5, wherein the length of the oligomers, calculated assuming the unfolded chain, forming part of the polymer is from about 0.2 nanometers to about 150 nanometers, especially from about 0.5 nanometers to about 8 nanometers, especially about 0.5 nanometers to about 5 nanometers, and especially about 0.5 nanometers to about 2 nanometers.

Composite membrane according to any one of claims 1 to 6, in which the oligomers carry functional groups intended for grafting of the polymer having a physicochemical reactivity, in particular post-crosslinkable functional groups such as photo-crosslinkable, crosslinkable, or chemically crosslinkable, and / or reversibly reactive in the presence of an external stimulus such as pH, temperature, light, or pressure, including amide, acid, amino, phenone,

and especially :

 In which the oligomers carry functional groups having a chemical reactivity, in particular functional groups such as alkoxysilane, carboxylic acid, phosphonic acid, amide, amine, imine, maleimide or fluoro,

Or in which functional groups of the oligomers are intended for grafting the polymer, in particular the functional groups such as alkoxysilane, carboxylic acid, phosphonic acid, amine and maleimide,

 Or in which functional groups of the oligomers are intended for filtration, in particular the functional groups such as amine and fluorinated group,

Or in which the functional groups of the graft polymers are intended for filtration, in particular the functional groups such as amine and fluorinated group,

Or in which the oligomers comprise at least one alkoxysilane function, in particular at least one ethoxysilane or methoxysilane function,

Or in which the oligomers are of general formula:

with RI of formula:

H ₃ C-, H ₃ C-O-, (H ₅ C ₂ O) Si-, (H ₅ C ₂ O) ₃ Si-

(H ₅ C ₂ 0), Si ^' Ό

and R2 of formula:

or formula

"N" ranging from 1 to 100, and

oligomers having a calculated length assuming the unfolded chain of from about 0.5 nanometers to about 8 nanometers and a molecular weight of from about 100 grams / mol to about 2500 grams / mol,

 Or in which the oligomers are chosen from the following products:

 - I: PEO Triethoxysilane (Trade name); CAS NUMBER [97969-60-3]; with a molecular weight of 300 to 20000 g / mol,

 II: PEO Bis Triethoxysilane (Trade name); CAS NUMBER

 [666829-33-0]; with a molecular weight of 300 to 20,000 g / mol,

 III: PPO 19 Bis Triethoxysilane (Trade name); CAS NUMBER

 [1017971-44-6]; with a molecular weight of 300 to 20,000 g / mol,

 IV: PMMA Triethoxysilane End group (Trade name); with a molecular weight of 300 to 20,000 g / mol,

V: MMA co Triethoxysilane methacrylate (Trade name); CAS NUMBER [75944-16-0]; with a molecular weight of 300 to 20,000 g / mol,

The composite membrane of any one of claims 1 to 7, wherein the pore size of the host layer is from about 0.5 nanometers to about 50 nanometers and the molecular weight of the oligomers is about 100 g / mol at about 10,000 g / mol,

 preferably wherein the size of said pores is from about 0.5 nanometers to about 10 nanometers and the molecular weight of the oligomers is from about 100 g / mol to about 3000 g / mol,

and especially :

 Wherein the size of said pores is from about 3 nanometers to about 5 nanometers and the molecular weight of the oligomers is from about 350 g / mol to about 1000 g / mol,

 Or wherein the size of said pores is from about 5 nanometers to about 8 nanometers and the molecular weight of the oligomers is from about 1000 g / mol to about 2500 g / mol.

9. Composite membrane according to any one of claims 1 to 8, which is gas-tight including nitrogen, especially at about 2 bar, especially at a temperature greater than or equal to 0 ° C and less than 50 ° C, in particular at a temperature of about 0 ° C. to about 40 ° C., in particular at a temperature of about 10 ° C. to about 40 ° C., in particular a temperature of about 20 ° C. to about 30 ° C., and in particular a temperature of about 25 ° C,

and especially :

 • Which is selective for at least one substance contained in gases, vapors or liquids:

 "at a temperature:

 from about 50 ° C to about 300 ° C, especially from about 50 ° C to about 200 ° C, especially 70 ° C to about 180 ° C including from about 85 ° C to about 165 ° C, and especially from about 100 ° C to about 150 ° C,

or about 50 ° C, or about 60 ° C, or about 70 ° C, or about 80 ° C, or about 90 ° C, or about 100 ° C, or about 110 ° C, or about 120 ° C, or about 130 ° C, or about 140 ° C, or about 150 ° C, or about 160 ° C, or about 170 ° C, or about 180 ° C, or about 190 ° C, or about 200 ° C,

and / or at a pressure of approximately 10 ^{~ 10} bar at approximately 70 bar, in particular from approximately 1 bar to approximately 10 bar, in particular from approximately 1 bar to approximately 9 bar, in particular from approximately 1 bar to approximately 8 bar , in particular from about 1 bar to about 7 bar, in particular from about 1 bar to about 6 bar, in particular from about 1 bar to about 5 bar, and in particular from about 1 bar to about 4 bar.

Composite membrane according to any one of Claims 1 to 9, in the porous support structure:

^■ is in alpha alumina,

^■ has multiple sizes macropores distributed homogeneously in a gradient of increasing size from the mesoporous layer and having respective sizes of 200 nm, 800 nm and 1 000 nm,

^■ is 1 to 2 mm thick,

 the host layer:

^■ is of gamma alumina or transition alumina,

^■ has multiple sizes mesopores in the range of about 3 nanometers to about 5 nanometers,

^■ has a thickness from about 1 to about 5 μιη μιη, in particular approximately 3 μιη,

 the polymer grafted inside the mesopores of the host layer, on the surface thereof:

^■ is a polymer consisting of the oligomers

 I: PEO Triethoxysilane; CAS NUMBER [97969-60-3]; having a molecular weight of 632 g / mol, or

 I: PEO Triethoxysilane; CAS NUMBER [97969-60-3]; with a molecular weight of 1161 g / mol.

The composite membrane of any one of claims 1 to 10, wherein

the porous support structure: ^■ is in alpha alumina,

^■ has multiple sizes macropores distributed homogeneously in a gradient of increasing size from the mesoporous layer and having respective sizes of 200 nm, 800 nm and 1 000 nm,

^■ is 1 to 2 mm thick,

 the host layer:

^■ is of gamma alumina or transition alumina,

^■ has multiple sizes mesopores in the range from about 5 nanometers to about 8 nanometers,

^■ has a thickness from about 1 to about 5 μιη μιη, in particular approximately 3 μιη,

 the polymer grafted inside the mesopores of the host layer, on the surface thereof:

^■ is a polymer consisting of the oligomers

 I: PEO Triethoxysilane; CAS NUMBER [97969-60-3]; having a molecular weight of 1161 g / mol, or

 IV: PMMA Triethoxysilane End group; with a molecular weight of 1250 g / mol, or

 II: PEO Bis Triethoxysilane; CAS NUMBER [666829-33-0] with a molecular weight of 928 g / mol, or

^■ is a polymer consisting of the same nature of oligomers having molecular weights from 1 300-1 800 g / mol "II: PEO Bis triethoxysilane; CAS NUMBER [666829-33-0] ". 12. Process for the preparation of a composite membrane according to any one of claims 1 to 11, comprising:

 a step of contacting a porous support structure surmounted by a porous host layer with oligomers, to impregnate said porous host layer of oligomers,

the ratio between the "pore size of said host layer" and the "length of said oligomers, calculated assuming unfolded chain," being in a range of about 0.2 to about 3, especially about 0.3 at about 1, especially from about 0.2 to about 0.9, and especially from about 0.5 to about 1, a step of condensing said oligomers in at least one functionalized polymer, impregnating said porous host layer, and covalently grafting said functionalized polymer onto reactive groups present inside the pores of said host layer, on the surface thereof, for filling the pores of the host layer with said graft polymer to obtain a porous support structure surmounted by a separating layer consisting of a porous host layer whose pores are filled with the aforesaid polymer covalently grafted inside said pores, on the surface of these,

and especially :

 Wherein the condensation step is optionally followed by a step of drying the porous support structure surmounted by the oligomer-impregnated host layer, which step stabilizes said polymer in the pores of the host layer to form the separator layer,

 Or wherein the reactive groups present within the pores of the host layer, on the surface thereof, are hydroxyl groups,

 Or wherein the oligomers comprise at least one alxoxysilane function, in particular an ethoxysilane or methoxysilane function.

The process for preparing a composite membrane according to claim 12, wherein said oligomers are prehydrolysed in acidic water and, if the water is not a good solvent for the oligomer, a solvent is also used. organic, especially selected from polar protic solvents such as methanol, ethanol, thiols, amines, carboxylic acids and, to a lesser extent, enolizable ketones, or from polar aprotic solvents such as, acetonitrile, dimethylsulfoxide, dimethylformamide, tetrahydrofuran and pyridine,

and especially :

• wherein there is added to the pre-hydrolyzed oligomer a product resulting in an increase of pH in the case of an aqueous solution or an increase in the OH ion concentration ^"in the case of an organic solution, due to physical or chemical treatment for form a prehydrolysed soil,

in particular wherein said product resulting in the increase of pH in the case of an aqueous solution or an increase in the OH ion concentration ^"in the case of an organic solution, is urea and said physical treatment is a heat treatment.

The process for preparing a composite membrane according to any one of claims 12 and 13, which comprises:

 a step of contacting a support surmounted by a porous host layer having a surface in partial or total contact with a porous support structure and an external surface, with oligomers which:

 i. comprise at least one alkoxysilane function, in particular at least one ethoxysilane or methoxysilane function, ii. are prehydrolysed in a solvent, for example ethanol, iii. are integrated in a prehydrolysed soil containing urea, for impregnating said porous host layer of oligomers,

the ratio of "pore size of said host layer" to "calculated length assuming unfolded chain of said oligomers" being in the range of about 0.2 to about 3, especially about 0.3 to about about 1, especially about 0.2 to about 0.9, and especially about 0.5 to about 1 ".

 a step, by a heat treatment, of condensation of said functionalized polymer oligomers, impregnating said porous host layer, and of covalent grafting by oxidation of said functionalized polymer onto hydroxyl groups present inside the pores of the host layer, on the surface thereof, for filling the pores of graft polymer, followed by a drying step of the porous structure surmounted by the separating layer.

15. Use of a composite membrane according to any one of claims 1 to 11, for the enrichment of a medium in at least one substance contained in gases, vapors or liquids, by contacting said membrane composite with said gases, said vapors or said liquids,

and especially :

 • in which the enrichment is carried out:

 at a temperature of about 50 ° C. to about 300 ° C.,

50 ° C to about 200 ° C, especially about 70 ° C to about 180 ° C, especially about 85 ° C to about 165 ° C, and especially about 100 ° C to about 150 ° C, and / or at a pressure of approximately 10 ^{~ 10} bar at approximately 70 bar, in particular from approximately 1 bar to approximately 10 bar, in particular from approximately 1 bar to approximately 8 bar, and in particular from approximately 1 bar to approximately 6 bar bar.