FI75861C - COL / VATTENDISPERSION. - Google Patents

Abstract

Dispersion which comprises water, pulverized coal and additives and is stable in storage, can be pumped and can be burned by conventional technique. The coal content of the dispersion ranges from 60 to 80% by weight and the dispersion contains at least one amphiphile substance adsorbed to the surfaces of the coal particles, which provides repulsion between the coal particles by hydration forces, and also polymers cooperating with said substance, at least one of said polymers containing segments of hydrophobic as well as hydrophilic character.

Description

1 75861

The carbon / water dispersion

The present invention relates to a carbon / water dispersion which is very stable in storage and suitable for transport and energy production. More specifically, the invention relates to a dispersion containing water, powdered carbon and additives having a carbon content in the range of 60 to 80% by weight.

The carbon dispersion pollutes the environment considerably 10 less and can be handled more easily than solid carbon and avoids some of the hazards associated with transportation and storage. Such a dispersion is also advantageous from an economic point of view.

The reason for the use of carbon dispersions is the planned increase in the use of coal as a primary energy source in both large and small plants for the production of electricity and heat. The use of solid carbon in this context is difficult for several reasons and thus the conversion of carbon to liquid form is generally considered to be an interesting method. Chemical transformation of carbon into a liquid product, the so-called liquefaction, cannot yet compete with oil and it is assumed that this method will affect global energy production only marginally before 2000. The chemical conversion of coal into a gaseous product, the so-called gasification appears to be a more productive method of utilizing coal. However, this method also has significant technical difficulties, even though large sums of money have been spent on technical development.

Physical conversion is another way to convert hii-30 to a liquid form, and the invention is directed to this method. It applies the dispersion of carbon in a liquid, which may be an organic fuel such as heating oil, methanol, etc., or water.

The difficulty with aqueous dispersions of powdered carbon is mainly to make the dispersions stable at low viscosity. Carbon particles must not settle during storage or transport of carbon dispersions. In addition, the pumpability of the carbon dispersion must be good and its theological properties must be suitable for combustion using a conventional method, possibly with some modification.

Of the previous proposals for stabilizing carbon / water dispersions, the one presented in the Russian publication Khim. Perab. Topi. 1975 30 (2) 19-29 and summarized in Chemical 10 Abstracts 87: 55532b. In this case, salts and polyphosphates of the polycarboxylic acid are used, inter alia, as stabilizers. The optimum mixture has a viscosity of about 0.5 Pas at a coal content of 57-63% and it follows that this dispersion does not meet the requirements. In addition, the stability against landing is insufficient.

SE-A-7805632-2 discloses a carbon / water dispersion in which a stability effect against settling is achieved with conventional polyelectrolytes, e.g. polyphosphate according to the same principles as set out in the above-mentioned publication. Again, the stability against landing is unsatisfactory.

U.S. Patent 4,242,098 discloses a carbon / water dispersion in which stabilization is achieved by the addition of various water-soluble polymers (polyethylene oxide, polacrylamides, etc.). This dispersion represents an improvement over the above dispersions.

The theory of the stability of dispersions has recently been considerably refined. The theory has been developed to understand more concentrated systems, but above all, a new type of interaction has been demonstrated. In addition to the previously discussed modes of action, such as electrostatic stabilization by means of surfactants and polyelectrolytes and etheric stabilization by means of polymers, the so-called The hydration. The existence of these forces has recently been demonstrated and they are 3 75861 explained theoretically. Hydration forces, possibly in combination with other types of interactions, form the main basis of the present invention to provide long-lived stable carbon / water dispersions of the type described above, which are well suited for direct combustion using available methods, possibly with minor modifications. Such dispersions are obtained by the present invention.

The invention relates to a dispersion consisting of water, powdered carbon and additives, the carbon content being 60 to 80% by weight. The process is characterized in that the dispersion contains lecithin or another zwitterionic surfactant absorbed on the surface of the carbon particles, and in addition polymers co-operating with it, at least one of which contains segments of both hydrophobic and hydrophilic nature.

Dispersion The theological properties allow the dispersion to be pumped and transferred through pipelines with significantly reduced friction and, above all, its sta-20 stability against flocculation and settling has been significantly improved.

If carbon / water dispersions, which by definition are thermodynamically unstable, are stabilized, the deposition and aggregation rates decrease due to the formation of a barrier layer that resists interparticle attraction. This repulsive effect can be achieved by three basic principles: electrostatic stabilization, etheric stabilization, and stabilization by hydration forces. Stabilization alters the energy of the particles 30 and / or forms a stronger barrier layer that resists the attraction between the particles. Based on these principles, it is possible to stabilize high concentrations of carbon particles in aqueous solution by adding small amounts of organic additives.

35 In order to form new colloidal systems, it is necessary to give the systems such properties that the interparticle attraction is minimized and a barrier layer is formed against flocculation and subsequent settling. Some forms of steric stabilization with hydrophilic polymers provide favorable conditions for long-term stabilization of carbon / water dispersions.

When studying laminar liquid / crystal phases in ionic surfactant systems, it has been shown that these phases can swell and contain large amounts of water. This is explained by repulsion through the aqueous layer between adjacent surfactant layers and can be considered as part of the electrostatic double layer forces. With zwitterionic agents such as phospholipidilecithin, swelling is less noticeable, but still very clear. This shows that even without a net charge, there is considerable repulsion. This repulsive force, the so-called hydration force, changes approximately exponentially with distance with a declination of 2-3 nm. The nature of the force is general and does not vary with the length of the alkyl chain or the physical state of the chains (liquid or solid) and is also present if some amount of charged surfactants is added to the system. Hydration forces have also been demonstrated by directly measuring the forces between a few 1/10 nm distances between 25 surfaces. Recently, a theoretical model for hydration forces has been developed and thus it has been possible to bring these forces into line with the so-called the presence of mirror charges at interfaces where the effective dielectric constant changes. These mirror charges with zwitterionic groups are common in micro- and macroheterogeneous systems.

They are utilized in accordance with the present invention to provide the desired properties to a suspension of a substance having a high dielectric constant. Thus, a zwitterionic surfactant such as lecithin can be adsorbed on the surfaces of solid particles. In this case, strong repulsive forces occur between the particles at short distances. The principle is thus particularly useful against concentrated dispersions.

The invention is illustrated in more detail by the following example.

Example 1. A non-micellar zwitterionic active substance such as lecithin or alkyl betaine, which is thus relatively sparingly soluble in water, is first dissolved in an organic solvent. The solvent may be, for example, octanol, hexadecene or methanol and may be recovered in a suitable manner or may form an insignificant proportion by weight of the dispersion.

2. The surfactant preparation is added to the dispersion of powdered carbon and water. Suitable carbon fractions range from 1 to 200 micrometers (preferably 150 microns) and have a wide size distribution (polydispersed carbon powder). The size and size distribution of the particles can be selected according to the desired stability. The smaller the particle size, the better the stability, but grinding the carbon to a micrometer-smaller particle-20 size is expensive. The concentration of the particles can vary over a wide range. From an economic and technical point of view, the concentration of particles should be optimized from case to case. Carbon / water dispersions with a dry matter content of between 65 and 75% by weight are of particular interest because of the good rheological properties of these dispersions, for example for transfer in pipelines. In order to obtain the highest possible carbon content (70-80% by weight), special consideration must be given to the particle size distribution. Normally, this can be done according to simple geometric considerations, such as minimizing free space when packing particles of different sizes.

After the adsorption step, at least one anionic or non-anionic polymer is added to the dispersion which interacts with the surfactant and contains 45 segments of both hydrophobic and hydrophilic nature to provide some degree of steric barrier layer 675861 and to reduce interparticle friction. The choice can be made, for example, between polyethers, polysaccharides such as xanthan gum or guar gum, polyalcohols and polyacrylates. Particularly suitable according to the invention are polyethylene oxide, copolymers of polypropylene oxide and polyethylene oxide in which the amount of polyethylene oxide predominates. The copolymer preferably has a molecular weight of 5,000 to 50,000, and most preferably, the copolymer contains at least 70% by weight of polyethylene oxide, with a molecular weight of 8,000 to 15,000. The content by weight of the polymers, based on the total weight, can be varied between 0.1 and 5%, but the economic optimum is about 0.5%. The total amount of additives is preferably less than 2% by weight.

To make the dispersion more comfortable as a substitute for uncontaminated oil, some salts of alkali metals or alkaline earth metals may be added to the dispersion. Preferably the salt is calcium hydroxide or dolomite powder. The salt neutralizes the acidic gaseous components formed by the oxidation of the fuel 20 and can be recovered in the particle precipitator.

To prevent evaporation of water from the carbon / water dispersion, a substance can be added to form a monomolecular layer at the interface. Such a substance is cetyl-35 alcohol or hexadecanol.

The invention provides considerable advantages over previous methods for stabilizing coal particles in aqueous solution. The dispersion obtained due to its excellent landing stability and pumpability, which has excellent theological properties, is suitable for the proper transfer of carbon in pipelines and pipelines for use in, for example, the chemical industry or directly in energy production.

Combustion tests in boilers designed for ras-35 dipping oil have shown that the dispersion is very well suited to replace all or part of the oil.

Claims (7)

7 75861 Dispersion consisting of water, powdered carbon and additives having a carbon content of 60 to 80% by weight, characterized in that the dispersion contains lecithin or another zwitterionic surfactant adsorbed on the surface of the carbon particles, and in addition together with it active polymers, at least one of which contains segments of both hydrophobic and hydrophilic nature. Dispersion according to Claim 1, characterized in that one of the polymers is a copolymer of polypropylene oxide and polyethylene oxide, the amount of polyethylene oxide being predominant. Dispersion according to Claim 2, characterized in that the copolymer has a molecular weight of 5,000 to 50,000. Dispersion according to Claim 3, characterized in that the copolymer contains at least 70% by weight of polyethylene oxide and has a molecular weight of 8,000 to 15,000. Dispersion according to Claim 1, characterized in that one of the polymers is a polysaccharide. Dispersion according to Claim 5, characterized in that the polysaccharide is xanthan gum or guar gum. Dispersion according to Claim 1, characterized in that the total amount of additives is less than 2% by weight.