WO1998005414A1

WO1998005414A1 - Composite membrane comprising a polyether-polyester block copolymer coating for separating polar gases from gaseous mixtures

Info

Publication number: WO1998005414A1
Application number: PCT/DE1997/001618
Authority: WO
Inventors: Klaus-Viktor Peinemann; Yanwei Cen
Original assignee: Gkss-Forschungszentrum Geesthacht Gmbh
Priority date: 1996-08-07
Filing date: 1997-07-30
Publication date: 1998-02-12
Also published as: EP0946271A1; DE19631841A1; DE19631841C2

Abstract

The invention concerns a composite membrane consisting of a microporous carrier membrane and a separation layer applied thereto. The composite membrane is characterized in that the separating layer comprises a block copolyetherester and is ≤ 3 νm thick. The composite membrane enables polar gases (water vapour, hydrogen sulphide) to be separated selectively from gaseous mixtures, and can be used, for example, to dry natural gas before it is fed into a central supply system.

Description

Composite membrane with a coating of polyether-polyester block copolymers for the separation of polar gases from gas mixtures

Describe bunq

The invention relates to a composite membrane consisting of a microporous carrier membrane and a separating layer applied thereon, and to the use thereof for separating polar gases from gas mixtures.

The separation of water vapor from process gas mixtures is currently carried out on an industrial scale with the aid of absorption processes (for example drying glycol), with the aid of adsorption processes (for example molecular sieves, activated aluminum oxide or silica gel) or with the aid of refrigeration dryers. Membrane processes are already used for gas drying. However, the latter are due to the low flux densities and high production losses are only used for low and medium volume flows.

Absorption processes, such as gas drying using glycol scrubbers (TEG, DEG), are used on an industrial scale to process natural gas. The loaded

Absorbent is regenerated in a second process step. This known method leads to high

Degrees of abrasion and is therefore particularly in the

Drying of natural gases used.

A disadvantage of these known absorption processes is the complex process control, which entails a high level of personnel and high investment costs. In addition, corrosion and fouling, especially in the heat exchangers, lead to problems in the operation of these known processes. Glycol also causes losses and the necessary additives, such as defoamers and chemicals for pH adjustment, cause additional costs.

In the known adsorption drying, adsorbents, for example molecular sieves or silica gel, are cyclically loaded and unloaded with moisture. The adsorbent is loaded with water in the first step and regenerated in a second step using heat, pressure changes or a dry gas flow. This known method is particularly suitable for drying low-load streams. In addition, particularly low residual moisture levels can be achieved.

A disadvantage of this known method is the fact that the adsorbent has to be regenerated cyclically, so that the process control is discontinuous is. In addition, this known method for the separation of high water loads is too complex.

Refrigeration dryers are used for the continuous separation of water vapor from gas mixtures. The dew points that can be achieved are around 2 ° C, since below this temperature the cooling coils start to freeze. However, lower dew points can be achieved with two devices connected in parallel, one of which is automatically defrosted. However, this mode of operation requires a high investment cost and an additional energy requirement. The limits of use of this known method are therefore close to the freezing point.

Hydrogen sulfide is currently mainly separated from natural gases by absorption processes using amine scrubbers. The loaded absorbent is regenerated in a second process step. The disadvantage of this known method is the high cost.

The membrane processes known to date can in principle also be used for dehumidifying and desulphurizing large amounts of gas. However, the membrane separation always produces two outlet streams, namely the purified product stream and the water-laden permeate stream. Depending on the application, these currents can be fed back into the process or else discarded. In any case, a high permeate flow leads to increased operating costs.

The object of the present invention is to provide a new membrane which has high separation factors for polar gases, in particular for hydrogen and hydrogen sulfide, and which has a good mechanical and has chemical stability.

This task is solved by teaching the claims.

The composite membrane according to the invention is made up of a microporous carrier membrane and a polymeric separating layer applied thereon. This separating layer consists of block copolyetherester or polyether-polyester block copoly eren. The polyether block copolymer is preferably a polyalkylene glycol block. The Al yl enei nhei t, which may be straight or branched, preferably has up to 6 carbon atoms. Polyethylene glycol blocks are particularly preferably used.

The polyester block copolymer is preferably polyalkyl enterephthalate blocks and in particular polyethylenterephthalate blocks and polybutyl 1 entherephthalate blocks.

A further preferred polymer block copolymer are poly allyl phthalate and in particular polydimethyltherephthalate.

However, the invention is not limited to the polymers mentioned, which are only preferred embodiments. Rather, all polymers suitable for membranes can be used which have several ether bonds and several ester bonds and give block copolymers.

The mechanical stability of the membrane according to the invention is achieved by the construction of different materials (composite membrane). The composite membrane according to the invention can be produced inexpensively, since commercially available polymers can be used. In addition, production is simple since the composite membrane according to the invention can be obtained by a dipping process or by pouring or spraying on the polymers that make up the separating layer. There is therefore no need for complex interfacial polymerization. In this way, particularly thin selective layers <3 μm are obtained. Due to the thin layers and the polymers used, high separation factors and a high flow rate can be achieved.

The thickness of the separating layer is preferably chosen such that the water vapor / gas selectivity is 100 to 30000.

The composite membrane according to the invention enables water vapor and / or hydrogen sulfide to be separated from gas mixtures. Furthermore, the composite membrane according to the invention can be used to separate carbon dioxide, ammonia and ethylene oxide from gas mixtures. However, it has a low flux density for other gases, for example N _? , 0 «and CH .. This leads to a particularly high selectivity, which results in only minor product losses. In addition, the membrane area required is small or small.

The membrane according to the invention thus enables the selective separation of polar gases from gas mixtures. It can thus be used, for example, for drying natural gas before it is fed into a central pipeline network and for processing compressed air. In contrast to the known gas drying membranes, the inventive Membrane, if used for natural gas cleaning, in addition to the water vapor, hydrogen sulfide and carbon dioxide are simultaneously separated. This means that the known glycol and amine scrubbers can be replaced by a single membrane stage when cleaning natural gas. The membrane according to the invention can also be used to dehumidify inert gases which are used to dry sensitive products. By using a circuit, the inert gas consumption can be significantly reduced.

The membrane according to the invention also has a high ammonia / nitrogen selectivity.

Another advantage of the membrane according to the invention is that it is stable against condensates. The known Cel 1 ul oseacetatmembranen show, for example, an irreversible change in flow performance after contact in liquid water.

Any known material suitable for such purposes can be used as the microporous support membrane for the support membrane according to the invention. However, the support membrane preferably consists of polyether iid, polyethyl vinyl idene fluoride or polyacrylic nitrite 1.

The composite membrane according to the invention is explained in more detail below with reference to the examples describing preferred embodiments.

EXAMPLE 1

0.5 g of a block copolymer ester, which consists of 70 wt. -7. Polyethylene terephthalate and 30% by weight polyethylene glycol (commercially available as Sympatex (R) (Akzo)), 49.5 g of 1, 1, 2-trichloroethane were added and the mixture was heated under reflux at the boiling point for 12 h. After cooling to 45 ° C., a microporous polyacrylic nitri 1 membrane (manufacturer GKSS) was coated with this solution using the immersion method. After the solvent had been evaporated off at room temperature, a composite membrane was obtained, the selective separation layer of which consisted of an approx. 1 μm thin sypatex layer. The following gas permeabilities were measured with this membrane.

Nitrogen Oxygen Methane Coal Sulfur Water Hydrogen Hydrogen

1.07 2.41 2.2 50.8 185 20,000

Permeabi 1 i at 10 m / m h bar

In comparison, a commercial showed 10 μm thicker

Sympatex film a water vapor permeabi 1 i tat of approx. 2

3 2 m / m h bar. This flow of the known membrane is too low for a technical gas drying membrane.

EXAMPLE 2

In accordance with the instructions in Example 1, a 0.5% by weight Sympatex solution in 1, 1, 2-trichloroethane was prepared. This solution was used to coat a microporous PVDF membrane on a polypropylene base (manufacturer GKSS) with a solution that was 50 ° C. After evaporation of the solvent, an approximately 1 μm thin Sympatex film with very good adhesion to PVDF was formed ° C Measurements carried out with nitrogen / water vapor mixtures, resulting in a water vapor permeability which was dependent on the partial pressure of the water vapor at 8 mbar Water vapor partial pressure a permeability of 22 m ³ / m ² h bar was measured, at 22 mbar water vapor part i al -

3 2 pressure this value rose to 40 m / m h bar. The middle

Water vapor / nitrogen selectivity was 25,000.

Figures 1 and 2 show the nitrogen and water vapor permeabilities against the water vapor part i al pressure. Figure 3 shows the corresponding selectivity. For comparison, the three figures also contain the values obtained with a commercial Sympatex film.

EXAMPLE 3

0.5 g of a block copolymer consisting of 84.5% polyethylene glycol and 15.5% by weight polydimethyl therephthalate was mixed with 99.5 g of a solution which had the following composition:

Aceteon 16 wt .-% iso-propanol, 77 wt .-% water 7 wt ¹ /.

After refluxing for 3 hours, the solution was cooled and filtered. A microporous polyetherimide membrane on a polyester base (manufacturer GKSS) was then coated with this solution. After evaporation of the solvent, an approximately 0.7 μm thin layer of the block copolymer on polyether i id was obtained. The following gas flows were determined with this composite membrane.

Nitrogen Carbon Dioxide Sulfur Oxygen Water vapor 5 124 495 21000 Permeabilities in 10 ^{~ 3} xm / h bar The resulting water vapor / nitrogen selectivity is 4200.

EXAMPLE 4

With a 0.5% by weight Sympatex! Solution in 1,1,2-trichloroethane was coated on a microporous polypropylene hollow thread (manufacturer Akzo) by pumping the solution through the lumen of the hollow thread. The solvent was then evaporated using a stream of nitrogen. An approximately 1 μm thin Sympatex layer was formed in the interior of the hollow fibers. The following gas permeabilities were determined:

C0 ₂ methane ammonia sulfur water hydrogen vapor

2.59 5.08 80 4.53 280 148 38000

-3 3 2 permeabilities in 10 x m / m h bar

The resulting water vapor / nitrogen selectivity was 14,700.

Claims

1. composite membrane of a microporous support membrane and a separating layer applied thereon, characterized in that the separating layer consists of a block copolyether ester and has a thickness of <3 μm.

2. Composite membrane according to claim 1, characterized in that it is in the block copolyetherester is a polymer having polyal kyl englykol blocks, in particular polyethyl englykol blocks.

3. composite membrane according to claim 2, characterized in that it is the block copolyetherester a polymer of polydimethyl theraphtha and polyethyl englykol blocks.

4. Composite membrane according to claim 1 or 2, characterized in that it is in the block copolyetherester is a polymer having polyal enthalphthalate blocks.

5. Composite membrane according to claim 4, characterized in that the block copolyether ester is a polymer of polybutyl enterephthalate and polyethyl kyol blocks.

6. Composite membrane according to one of the preceding claims, characterized in that the thickness of the separating layer is selected such that the water vapor / gas selectivity is 100 to 30000.

7. Composite membrane according to one of the preceding claims, characterized in that the microporous carrier membrane consists of polyether mid, polyvi nyl idenf1 uoride or polyacrylic nitri 1.

8. Composite membrane according to one of the preceding claims, characterized in that an additional coating of a polyalkyl silicone, in particular polydimethyl si 1 i kon, is applied to the separating layer.

9. Use of a composite membrane according to one of claims 1 to 8 for the separation of polar gases from Gasgemi see.

10. Use according to claim 9 for the separation of water vapor, hydrogen sulfide, carbon dioxide, ammonia and / or ethylene oxide from gas mixtures.

11. Use according to claim 10 for the simultaneous separation of water vapor and hydrogen sulfide from gas mixtures, in particular natural gas.