NO141443B - PROCEDURE FOR THE MANUFACTURE OF A PRODUCT WHICH ENCOURAGES THE BIOLOGICAL DECOMPOSITION OF HYDROCARBONS - Google Patents

Description

The present invention relates to a method for producing a product which accelerates the biological breakdown of hydrocarbons, in particular hydrocarbons in mineral oil products.

It is known that the sulphite liquors which occur during the processing of wood according to the sulphite method mainly contain lignosulfonic acid as a water-soluble conversion product of lignin and with SO^H groups.

There are a large number of proposals regarding the use of this ligninsulfonic acid, and some of these have also been implemented in practice. One achieves e.g. binders for briquettes, adhesives for glue and paper, fertilizers when converted into humic substances, additives for plastic pressing compounds, emulsifiers for road construction materials, auxiliaries and anti-corrosive agents for textile processing, fire protection agents, tanning extracts, flocculating agents for egg white precipitation as well as condensation products for the rubber industry. Furthermore, it is known that lignin sulphonic acid is used for gel formation by oxidation of chromium IV salts.

Calcium-containing sulphite liquors with a content of 50-60% dry matter also contain sugar and carbohydrates. For such substances, it is known to transfer them with the help of microorganisms, e.g. by means of yeasts, to usable fats and egg whites and also to use them as ion exchangers (Rompp, Chemielexikon, section lignin; Fiedler, F. Mat. Dies. Univ. Greifswald 1957; Chemiker-Zeitung 1954, page 508).

Regarding cerium, it is known that this as well as salts

of praseodymium and neodymium in an order of magnitude for the concentration of 1:10,000 can increase the fermentation power of yeast, as well as that the coagulation of milk due to lape can be accelerated by the addition of these salts and that blood clotting in vitro is inhibited or prevented

is prevented (Hara p: Arch. f. exper. pathol. 100, 224; Drossbach:

ZBL, Bakt. I, 21, 57).

Special colloidal systems of rare earth salts

in addition to this, it is known that, as trace elements, they are able to activate the growth development of plants, which can be seen in a shorter germination time, earlier cotyledon formation, better root formation and denser growth. In experimental field tests, it can be shown that the yield of crops can be increased by the use of such trace element colloids by 24.6%, whereby the plants also become more resistant to diseases and other pests and plants (H.A. Schweigart: Pflanzenernahrung durch Anreicherung der Saat mit The trace element contact colloid, Vitalstoffe, Heft 20, 1960). In further publications, it is demonstrated that special catalase-free bacteria, such as BAC. Delbruggi, can carry out its oxidative metabolism with the help of cerium peroxide, which means that oxidative metabolism processes under special conditions can be influenced or created with the help of cerium compounds. Hereby, cerium's properties with regard to valence change possibilities and the voltage difference of 1.57 volts, the redox potential, certainly play a role. Reference must also be made to the fact that cerium alloys have found use by exploiting the oxygen affinity properties in e.g. gas glow stockings (Evens: Peroc. Soc. exper. Biol. a. Med. 73, 1955, 19, 198; Dipl.-Chem. E. Potratz, Zeitschrift fur diagnostiche und therapeutische Sondermethoden, volume IV, 1957) .

Oily waste, especially no longer usable mineral oil, is stored e.g. with a view to composting in watertight oil dykes, whereby the composting takes place as normal biological decomposition very slowly.

The present invention is based on the knowledge regarding the influence of the microbacterial breakdown of hydrocarbons and the transfer to egg white of small concentrations of salts of rare earth species to potentiate the oxidative metabolism of microorganisms; and the invention has the task of producing a method for producing a mixture which is added to used mineral oil products, whereby the biological breakdown of these products is accelerated.

This task is solved according to the invention by dissolving 50-150 g of calcium lignin sulphonate with a standardized iron content of 0.05-0.15% in water and adding a pre-determined amount of a rare earth salt, preferably 30-50 g of cerium-IV -sulphate, and that an absorptive substance is added to this solution comprising either a mixture of 25-100 g of stearic acid and 4-12 g of triethanolamine or a 10-30% aluminum sulphate solution, which product contributes to a natural biological breakdown of said hydrocarbons whereby these undergo a complex transformation into fat and egg white.

It has been found that calcium-containing lignin sulfonates with the following composition can serve as the preferred starting product:

pH in the aqueous solution = 4.6.

It has been assumed that according to the laws of oximetry

determination of iron can be carried out using cerium-IV-sulphate in 0.1N solution.

This is based on the following: 1 cm 3 consumed of 0.1N cerium-IV-sulphate corresponds to 5.585 mg of iron. The provision is carried out by adding approx. 5 cm 3 of concentrated sulfuric acid at an iron quantity of 0.1-0.2 g of iron in 100 cm 3 of liquid to be tested.

The determination option provides an opportunity to standardize the content of iron in the starting product for the ligninsulfonates in order to achieve the same starting conditions and, on the other hand, by introducing specific amounts of the cerium sulfate, to achieve optimal cerium content in the final product by calculating the cerium content in the mixture according to the invention. Hereby, the oxidative properties of cerium, respectively its valence change, are taken into account.

Due to the above, according to the invention, it is assumed that the amounts of lignin sulphonate used, taking into account the iron content of 0.1% with an amount of 0.5 g after previous cerimetry, and taking into account the conversion factor contain 1.4 mg cerium. This dosage was recognized as optimal during the later use of the product obtained.

If, according to a further development of the mixture according to the invention, an absorptive-acting solution of stearic acid and triethanolamine is added, a mass is formed with which one e.g. can line out waste oil ditches, before oil is filled in. The filled ditch can also be covered with this emulsion.

By mixing this construction mass with water in a ratio of 1:1, a substance that absorbs oil but is water-repellent is flocculated from the construction mass. This flocculated material settles in the edge area, e.g. along the walls of the oil dike. The penetrating oil is then biologically broken down very quickly as this breakdown is potentiated due to the cerium salt in the flocculated mass. The oil is thereby converted into substances that can be utilized by plants. The breakdown, i.e. of the oil's hydrocarbons, is also achieved by oxidation. The oxygen required for this is obtained by the bacteria in the mixture according to the invention from water, e.g. the groundwater, and also from the oil emulsion from the water that becomes free during the flocculation.

In field tests, it has been possible to demonstrate that when constructing dike systems for composting oily waste and by placing binding material or filter material using the above-mentioned substance in the above-mentioned quantity, can be achieved

a demonstrable aerobic breakdown with potentiated effect of hydrocarbons by oxidation, and that at the same time improved plant growth can be achieved on such depots due to improved oxygen utilization and chelation.

It can be demonstrated that the biological degradation is potentiated by mineral oil of the substance produced according to the invention, further that the oxidation rate for hydrocarbons is doubled, whereby the stimulating effect is achieved above cerium's redox potential.

Such a process was checked over two years, during which a temperature of 30°C was noted and where the following data was obtained:

Examples:

1) 100 g of a calcium lignin sulphonate with a standardized iron content of 0.1 g is dissolved in 1 liter of water. 40.4 g of cerium-IV-sulphate are added to the solution heated to 75°C with constant stirring. The solution thus obtained serves as starting material for the further examples. 2) The substance crystallized in example 1 is added in an amount of 0.5 g to an absorptive-acting mixture and emulsion of approx. 50 g of stearic acid and 8 g of triethanolamine in 1,000 cm 3 of water in a quantity of 2.0 g with constant stirring and heating to 85°C. The product thus obtained is used as filter material for the removal and covering of constructed depots for groundwater protection when introducing oily waste. 3) To the solution obtained under example 1, a quantity of 0.5 cm 3 of an equally absorbent 20% aluminum sulphate solution is added at a maximum temperature of 35°C. This product serves to demulsify oily emulsions of anionic, cationic or non-ionic character.

The quantities of the components present in the mixture as well as the temperatures specified in the description apply to preferred embodiments and can be varied within certain limits without going outside the scope of the invention. The aforementioned limits are specified in the requirements.

Claims (4)

1. Process for the production of a product which accelerates the biological breakdown of hydrocarbons, preferably hydrocarbons in mineral oil products, characterized in that 50-150 g of calcium lignin sulphonate with a standardized iron content of 0.05-0.15% is dissolved in water and added in advance certain amount of a rare earth salt, preferably 30-50 g of cerium-IV-sulphate, and that this solution is added to an absorptive agent comprising either a mixture of 25-100 g of stearic acid and 4-12 g of triethanolamine or 10-30% -ig aluminum sulphate solution, which product contributes to a natural biological breakdown of the aforementioned hydrocarbons, whereby these undergo a complex transformation into fat and egg white. 2. Method according to claim 1, characterized in that calcium lignin sulphonate is used in an amount of 100 g with a standardized iron content of 0.1%, dissolved in 1 liter of water, and that this solution is heated to a temperature between 50 and 100°C , preferably 75°C, and with constant stirring, said cerium-IV-sulphate is added in an amount of 40.4 g, and said absorptive substance, which here consists of said amounts of stearic acid and triethanolamine, is added in dissolved form. 3. Method according to claim 1 or 2, characterized in that the cerium-enriched calcium lignin-sulfonate solution in an amount of 0.5 g is added to 2.0 g of the absorptive-acting substance which here consists of a solution containing said stearic acid in an amount of 50 g and said triethanolamine in an amount of 8 g/1000 cm 3 of water and under constant stirring and heating to 75-95°C, preferably 85°C. 4. Method according to claim 1, characterized in that the cerium-enriched calcium lignin sulfonate solution is used in an amount of 100 g, and that a 20% aluminum sulfate solution is used as absorptive active substance which is added at a temperature of 25-45° C and in an amount of preferably 0.5 cm.