DE19945188C2 - Method and device for removing aqueous phases from mixtures of non-aqueous liquids and aqueous phases - Google Patents

Description

The present invention relates to a method and an apparatus for Removal of aqueous phases from mixtures of non-aqueous liquids and aqueous phases.

Because water is omnipresent in the environment, for example in form of liquid phase or gaseous in the form of humidity, it is often an undesirable companion of non-aqueous liquids. So it can be z. B. accumulate in hydraulic fluids due to Ventilate the hydraulic system with air containing water vapor or through System leak. Also in gas pipelines or other pipelines systems can occur, for example due to the accumulation of condensate. It can be used as a water-in-oil emulsion or as an aqueous sediment occur.

As a rule, such water contains admixtures that are from the air or come from the contact of the water with other components of the system. In an aqueous environment and with the participation of such admixtures reactivities develop which cause corrosion of walls, Valves etc. can lead or what functionally important system can damage components. In the example of hydraulic fluids additives that affect the hydraulic fluid can be affected are added to improve environmental sustainability.

It has been difficult to add water from non-aqueous liquids  remove. In general, inorganic salts were used for this, which have a water-attracting effect, such as calcium chloride or calcium oxide. Also Alkali metals, such as potassium or sodium, are used to remove water from non-aqueous liquids.

The disadvantage of these substances is that their water absorption capacity is limited is and that they often have undesirable side effects, such as. B. the Alkali metals.

From "Staub-Reinhalt-Luft 36 (1976), No. 7, pp. 288-292" it is known that Adsorbents, such as. B. activated carbon, have certain properties to which u. a. the specific surface, the porosity and the grain size counting. A large specific surface is the prerequisite for the usability as a technical adsorbent. This knowledge The surface effects during adsorption are not transferable on the incorporation of water into the gel matrix of gel-forming poly saccharides.

DE 43 12 279 C2 describes an agent in granular form for adsorbing and absorbing tion of fluids known, which consists of at least one highly swellable Clay mineral and a granular carrier material. This as Material used in animal litter forms lumps, the removal of which is easy is. For a lump-free water-absorbing material, this gives Publication no suggestion.  

In "Ullmann's Encyclopedia of Industrial Chemistry, 4th Edition, Vol. 23 (1983), Pp. 311-326 "there is an indication that bentonite suspensions are caused by organic polyelectrolytes, e.g. B. alginates or carboxymethyl cellulose, be stabilized; in higher concentrations envelop the poly electrolytes the bentonite particles and give them their hydrophilic Character. Hydrophilic nonionic polymers have the same effects, such as B. Polysaccharides. The uptake of water is in this pressure Scripture not discussed, there is no question of adsorption.

The object of the present invention is a method for removal of water from non-aqueous phases that is more effective than the previously used method, which has no side effects and which also makes it possible, in addition to the water, in the water phase together with the water from the non-water to remove the remaining phases. The object of the invention is also to create a device for removing such aqueous phases.

Gel-forming polysaccharides can bind large amounts of water, often more than a hundred times. Those that form when water is absorbed However, gels can form water-impermeable layers (DE 199 09 975.8), that can be used for barrier layer materials that one Can prevent the passage of water.

It has been found that the formation of waterproof Layers can be prevented if the gel-forming polysaccharides coarse-grained materials that have a large surface area exhibit. Such coarse-grained materials must have at least the two times the surface area, which is a massive ball of the same Material that fulfills the same space as a part of the has coarse-grained material, the volume of which therefore corresponds.

The coarse-grained materials are preferably in the form of granules used.  

Coarse-grained materials are all materials, one have a large surface area. Materials are preferably used that contain open pores or capillaries.

The coarse-grained materials can consist of inorganic material, for example from broken bricks, expanded clay, clay granules, slag granules or pearls, pressed ash granules, granules from sandstone, pumice, tuff or Lime sandstone, or from organic materials, for example open-pore Plastics, rubber or cork granules. They are said to be from microorganisms not to be vulnerable, d. that is, they are not or only from microorganisms are reduced to an insignificant extent.

The surface of the coarse-grained materials must be at least as large as that they are twice the surface of a sphere with the same Volume corresponds. Fulfill substances that have pores or capillaries this condition. The surface is preferably at least that Five times a sphere of the same volume.

The pores or capillaries of the coarse-grained materials can open widths in the range from 0.05 to 2 mm, preferably in the range from 0.1 to 1.2 mm. The resulting increase in surface area has proved to be particularly advantageous.

The grain size of the coarse-grained materials is generally in the Range from 1 to 20 mm, preferably from 2 to 10 mm. For larger ones or smaller grain sizes, the manageability of the coarse-grained Materials worse, although such materials can also be used.

It has proven to be useful to coat coarse-grained materials to mix with uncoated. This is particularly recommended if the coated materials are used in the form of a filter bed to avoid clogging.  

All polysaccharides are suitable for the process (derivative) s that can form gels with water. these are for example natural and / or biosynthetic poly saccharide, also expolysaccharide, from bacteria, fungi, Algae, and / or higher organisms, partially or fully synthetic polymers with polysaccharide content, such as. B. glycosylated polypeptides or glycosylated polyhydroxy alkanoates, or natural copolymers with sugar or other components.

These include gel-forming polysaccharides (derivatives) for example natural and / or biosynthetic poly saccharides, e.g. B. may be of marine origin, such as Alginates, carrageenans, agar, or vegetable polysaccha ride, such as karya, tragacanth, gum arabic, carob; or of microorganisms, e.g. B. the genus Xanthomonas, Azotobacter, Leuconostoc, or from Fungi, e.g. B. Sclerotium and Schizophyllum excreted polysaccharides.

The above-mentioned polysaccharides (derivatives) include, among others, homo- or heteropolysaccharides, such as, for example, glucose polymers (glucans), such as:
Dextran: 1,6-α-homoglucan (1,6-glucan)
Schizophyllan: 1,3-β-homoglucan and curdlan (1,3-β-homoglucan)
Scleroglucan: 1,3-β-glucopyranose backbone with 1,6-β-glucopyranoses as side chains
Xanthan: 1,4-β-glucose base chain plus side chains (mannose, glucuronic acid, acetate, pyruvate)
Fructose polymers: Levane (2,6-β-homopolysaccharides)
Galactose polymers and copolymers
Agarose: 1,3-β-galactopyranose plus 1,4-α- (and 1,4-β-) 3,6-anhydro-galactopyranose, alternately
Agar: agarose plus agaropectin (agaropectin is a non-swelling polysaccharide made from 1,3-β-linked galactose plus 3,6-anhydro-galactose plus uronic acids)
Guar gum: polygalactomannon copolymers: can contain very different saccharides and can have different side groups
Uronic acids: alginates (1,4-glycosidically linked mannuronic and glucuronic acids)
this also includes xanthan and agaropectin (see above) because of their side groups, karaya gum, tragacanth, mucopolysaccharides.

Polysaccharide derivatives include u. a. modified Saccharides, celluloses or starches, such as Hydroxyethyl cellulose, hydroxypropyl cellulose, carboxy methyl cellulose, polyvinyl saccharides, o-carboxycytosans u. a.

All of these polysaccharide (derivative) s have the Ability to gel multiple times their own volume bind to water. So binds the contained in the alginates Alginic acid 200 to 300 times the amount of water.  

The gel-forming polysaccharides are made by conventional coating techniques applied to the coarse-grained materials. To do this, the Polysaccharides dissolved in water, forming a polysaccharide gel. Then the coarse-grained materials are added to the gel solution, where they wrap themselves with the gel. For porous or capillary ones Materials can penetrate into the pores or capillaries applying a vacuum can be improved. The materia coated in this way Lien can be dried, but the temperature should not be higher allowed as the temperature at which the polysaccharide swells deteriorated. Temperatures are well below 100 ° C in general advised.

The inventive method can be carried out so that the with the polysaccharide coated materials with the non-aqueous Liquid to be mixed. By stirring or shaking the Effect of binding the aqueous phase can be accelerated. To The product swollen with water ends when the water is removed removed from the non-aqueous phase.

The coated coarse-grained material can also be placed in a filter vessel be filled, for example in a tubular container, which is provided with an inlet and an outlet. When passing through the aqueous phase is removed from the non-aqueous liquid. Such a device has proven to be optimal for carrying out the proven method according to the invention. If the absorption capacity of the polysaccharide is exhausted for water, the coated coarse-grained materials can be easily removed from the pipe.  

When using the method according to the invention, the in the non-aqueous liquids contain amounts of water from which itself forming or already formed polysaccharide gel. Not only is the water stored in the gel, but also substances dissolved in water. This is ent in the known water pulling substances not the case, so that the inventive method considerable compared to conventional water removal processes Offers advantages.

The invention is explained in more detail below with the aid of the examples.  

EXAMPLE 1

1 kg of sodium alginate was dissolved in 10 l of water. In a vacuum vessel were 9 kg expanded clay pellets, grain size about 3 to 8 mm, with the alginate solution treated with the application of a vacuum. The so produced coated expanded clay pellets were air dried at 90 ° C.

The coated granulate was coated with 15 kg of uncoated expanded clay pellets mixed, so that a mixing ratio of 1: 1.5 resulted.

EXAMPLE 2

The hydraulic system shown in Fig. 1 with a pressure cylinder 10 and a working cylinder 12 contains about 10 l of hydraulic fluid Shell Vitrea Oil 150. In the connecting line 14 between the working cylinder 12 and the pressure cylinder 10 , a tubular main flow filter 16 with a pressure-tight sealable cover 28 is arranged, which was filled with 1 kg of the expanded clay mixture from Example 1. Both on the pressure cylinder 10 and on the working cylinder 12 each bypass filters 20 , 22 were arranged, which were connected via valves 24 to the respective cylinder. The bypass filters 20 , 22 which can be closed by cover 28 were each filled with 5 kg of the expanded clay mixture from Example 1. The expanded clay mixture was filled in sacks, which consisted of a fine-mesh plastic network.

The bypass filters 20 , 22 are used during breaks in the hydraulic system.

With an initial water content of the hydraulic oil of approx. 0.5%, they have coated expanded clay mixtures have a service life of at least 6 weeks, before they need to be replaced.  

EXAMPLE 3 Separation of water from a natural gas pipeline

Both water and oil condense in natural gas pipelines. When on Feeding the gas into the line will contaminate oil from the pumps by condensed water, introduced into the pipe system. Also from the Gas content is condensed.

The oil-water mixture is deposited in an oil water sump 30 , the volume of which is approximately 3 m ³ . From the oil water sump 30 , it is pumped by a pump 32 via a line 34 into a cleaning basin 36 which contains about 200 kg of alginate granules, produced according to Example 1. The alginate granulate is filled in a close-meshed plastic net, for example in plastic fly screens. By a Umpump- or Rührvorrich device 38 , the liquid in the cleaning basin 36 is kept in a steady slow flow.

After a contact time of 24 hours, the oil is in the cleaning basin completely water-free and clear. It can easily be a technical Be used.

Claims (11)

1. A process for removing aqueous phases from mixtures of non-aqueous liquids and aqueous phases, characterized in that the mixtures are brought into contact with coarse-grained materials which are not susceptible to attack by microorganisms, the surface of which is at least twice the surface of a sphere of the same volume is, the surface of the coarse-grained material has been coated with a gel-forming polysaccharide. 2. The method according to claim 1, characterized in that the surface of the coarse-grained material is at least five times that Surface of a solid sphere made of the same material. 3. The method according to claims 1 or 2, characterized in that the coarse-grained materials have a grain size of 2 to 20 mm, preferably have from 1 to 10 mm. 4. The method according to one or more of the preceding claims, characterized in that the coarse-grained materials have pores and / or capillaries. 5. The method according to claim 4, characterized in that the opening width of the pores or capillaries 0.05 to 2 mm, is preferably 0.1 to 1.2 mm. 6. The method according to one or more of the preceding claims, characterized characterized in that the coated coarse-grained materials with non-coated coarse-grained materials are mixed.   7. The method according to claim 1 or 2, characterized in net that the gel-forming polysaccharide (derivative) e natural or biosynthetic polysaccharides or natural mixed polymers with sugar or other compo are. 8. The method according to one or more of the preceding claims, characterized in that the gel-forming polysaccharides are natural or biosynthetic polysaccharides. 9. The method according to one or more of the preceding claims, characterized in that the gel-forming polysaccharides belong to the following groups:
Homo- or hetero-polysaccharides and polysaccharide derivatives. 10. An apparatus for performing the method according to claims 1 to 9, characterized by a cleaning basin ( 36 ) into the container with the coated coarse-grained materials can be introduced, and a pumping or stirring device ( 38 ) and a feed line ( 34 ) with pump ( 32 ). 11. An apparatus for performing the method according to claims 1 to 9, characterized by a main flow filter ( 16 ) in a flow of the non-aqueous liquid speed, and by one or more secondary flow filters ( 20 , 22 ) in a secondary flow outside the main flow, the filter ( 16 , 20 , 22 ) are filled with the coated coarse-grained material.