CS263618B1 - Enzyme agent for washing,degreasing,cleaning and water regeneration - Google Patents

Abstract

The detergent is based on an enzyme complex, and particularly on lipases and oxidoreductases. A substantially lower contents of surfactants and chelatizing components positively influences the effects of enzyme constituents on all of the basic dirt types, except for pigments, and promotes the environmental protection. Apart from this, the washing ability of this detergent even if used at low temperatures has its significance in power econonmy.

Description

The invention relates to an enzyme composition for washing, degreasing, washing, cleaning, regeneration of waste and polluted waters degrading hydrophobic chains with a carbon number of 5 to 35 C.

The current level of detergents, detergents and cleaning agents is virtually equal throughout the world. High efficacy is achieved by a composition that has stabilized with little variation in the use of a combination of anionic active and nonionic surfactants, chelating agents and special additives, of which proteinases and amylases, sodium perborate, carboxymethylcellulose, optical brighteners are of the greatest detergency.

In most cases, the use of a mechanical heating effect is necessary to achieve the desired performance properties. In particular, the removal of high levels of hydrophobic substances is energy intensive, surfactant and alkaline. During washing, failure to comply with these requirements may cause greasy dirt to precipitate in hardly removable particles. The detergent process generates a large volume of waste water, the regeneration of which places considerable demands on the removal of surfactants and buildrens. .

Also, the demulsification of hydrophobes is often very demanding, requiring the addition of other substances. special equipment, and in general it causes an increase in wastewater recovery costs.

Of the current raw materials used in detergents, cleaners and similar products, proteases and amylases, they do not impose energy and investment requirements to maintain environmental cleanliness. These are highly active ingredients which generally reduce the energy requirement for removing proteinaceous apolysaccharide dirt components. However, their use is very narrow and does not cover all dirt components, especially their hydrophobic part, which can still be removed by applying surfactants. After completion of the washing process, the disposal of used surfactants and released hydrophobes must be addressed.

These disadvantages are overcome by the enzyme composition for washing, degreasing, washing, cleaning and regeneration of waste and polluted waters, containing activating, softening, surface-active, filling, fragrance, coloring, proteolytic, amylolytic, buffering agents or mixtures thereof according to the invention characterized in that it contains 0.01 to 50% by weight, preferably 0.5 to 10% by weight, of a multienzyme lipase-oxidoreductase complex having a minimum lipase activity of 2 units / mg protein and an alkanohydroxylase oxidoreductase activity of at least 0, 5 nkat / mg protein and alcohol dehydrogenase 0.5 units / mg protein, 2 to 45% by weight, non-ionic and / or anionic surfactants, and the remainder to 100% by weight are chelating, filling, coloring, scenting, brightening and other additives.

The composition according to the invention solves the removal of hydrophobic substances with or without substantially less surfactants, which is of ecological importance. Furthermore, it makes it possible to increase the efficiency of existing detergents and degreasing agents for use at lower temperatures, which will bring considerable energy savings.

The composition according to the invention successfully dissolves dirt, the hydrophobic portion of which contains hydrocarbon, alcohol, organic acid and derivative chains having a carbon number of 5 to 35.

Conversion of all of these to shorter, water-soluble and biodegradable substances, such as acetic and propionic acids, provides an enzyme complex with Upas, alkanoxidase and alcohol dehydrogenase activity. In the sequence of enzymatic reactions, lipases are first employed which, in the presence of higher fatty acid esters with alcohols, cleave the ester bond; for example, fatty acids and alcohols are degraded by a system of oxidation reactions, in particular beta-oxidation. Also aliphatic hydrocarbons are degraded by multistep oxidation, which is usually initiated by hydroxylation of the atom to form the alcohol and the next step of the acid. This stage is followed by beta-oxidation. Metabolites formed by beta-oxidation, i.e. acetyl- or propionyl-CoA, are degraded in the citrate or methyl-nitrate cycle to form CCl2 and l2O.

Use of enzyme system in washing, washing, cleaning and degreasing agents. it will increase the detergency efficiency with existing but also substantially lower surfactants and chelating components, extend the enzyme activity complex to all impurity constituents except pigments, while facilitating environmental protection.

The composition of the invention and its effects are illustrated by the following examples.

In each case, a series of experiments were carried out to document the effect of the concentration used and the differently active multienzyme complexes on enhancing the anti-control performance, see Examples 5 and 6, or the effect of temperature on the anti-control performance enhancement (Example 4). A series of examples 1, 2 and 3 illustrates the higher washing performance of surfactant and multienzyme complex detergent compositions over surfactants alone and further demonstrates that the increase in washing performance due to the use of multienzyme complexes over control is not affected by the use of different surfactant types or by changing their concentration. Since the series of experiments were performed in time, different types of canvases were applied to each series, which in some way affects the absolute values of the resulting washing ability.

Example 1 g of detergent composed of 25% by weight, tripolyphosphate, 2% by weight, lauryl polyglycol ether containing 12 moles of ethyloxide, 4% by weight, multienzyme preparation with enhanced lipase activity of the complex of 20 j / mg protein, alkanhydroxylase activity 0.6 nkat / mg protein and an alcohol dehydrogenase activity of 1.5 J / mg protein and a variable amount of sodium dodecylbenzene sulfonate, supplemented with water to 100% by weight, was dissolved and made up to 1 L with water 2+ containing 5.34 mmol Ca / L. The resulting solution was used for a wash test of standard dirt soaked cotton cloths at 40 ° C for 15 minutes in a Limitest laboratory washing machine. The washing performance results are given in dependence on the dodecylbenzene sulfonate (DBS) weight content in Table 1 below:

Dodecylbenzene Washing ability Washing ability DBS sulfonate (%) without enzymes with a multienzyme complex 0 40.6 47.3 3 53.1 60.4 6 57.6 64.2 9 58.8 66.0 . 12 69.2 80.0

Example 2 g of detergent composed of 6% by weight, sodium alkylbenzene sulfonate, 2% by weight, lauryl polyglycol ether containing 12 moles of ethyloxide, 3% by weight, multienzyme complex with lipase activity of 10 J / mg protein and enhanced oxidoreductase activity with alkanhydroxylase activity 1.5 / mg protein and an alcohol dehydrogenase activity of 1.5 U / mg, with varying amounts of sodium tripolyphosphate, supplemented with water to 100% by weight, were dissolved 2 + 1 and made up to 1 L with water containing 5.34 mmol Ca / L. The resulting solution was used for a laundering test of standard cloth dirt at 40 ° C for 15 minutes in a laboratory washing machine. The washing performance results are shown in Table 2 according to the sodium tripolyphosphate (TPF) content:

TPF Washing ability (% by weight) No enzymes With multienzyme complex 0 5.0 12.5 5 56.4 65.7 10 58.9 66.9 15 Dec 61.7 67.2 20 May 62.4 69.1 25 63.2 70.1

Example 3 g of a detergent composed of 2 wt%, lauryl polyglycol ether containing 12 moles of ethyloxide, 3 wt%, a multienzyme complex with enhanced oxidoreductase and Upas activity as in Example 2, in varying amounts of sodium tripolyphosphate supplemented with water up to 110 wt%.

was dissolved and made up to 1 L with water containing 5.34 mmol Ca / L. The resulting solution was used for washing test of cotton cloths soiled by standard MS. dirt at 40 ° C for 15 minutes in a Limitest laboratory washing machine. The washing performance results are shown in Table 3, depending on the sodium tripolyphosphate content:

TPF Washing ability (% by weight) No enzymes With multienzyme complex 0 1.0 3.9 5 33.9 41.9 10 34.2 41.9 15 Dec 39.8 45.7 20 May 38.9 46.7 25 40.3 47.0

Example 4

To 1000 ml of phosphate buffer, 5 g of a detergent consisting of only 100% by weight of a multienzyme complex with enhanced oxidoreductase activity as in Example 2 was added as described in Example 2. The resulting solution was used to wash cotton cloths soiled with standard paraffin dirt for 15 minutes under laboratory conditions with variable temperature. The washing performance results are shown in Table 4:

Temperature (° C). . .. Washing ability No enzyme With multienzyme complex 30 12.4 18.0 37 17.9 .26,9 50 30.1 45.9

Example 5

To 1000 ml of phosphate buffer solution pH 8 was added 0.2-5 g of detergent containing only 100% by weight of a multienzyme complex with lipase and enhanced oxidoreductase activity as in Example 2. The resulting solution was used to wash cotton soiled cloths standard MS. dirt under laboratory conditions at 50 ° C for 15 minutes. The results of the washing ability as a function of the amount of the multienzyme complex are given in Table 5;

AND

Amount of multienzyme complex (g / l) Washing ability sample control (no enzyme) 0.2 45 32 0.5 48 34 1.0 48 32.5 2,0 51 34 3.0 53 33.5 4.0 53 35 5.0 55 . ³⁵ ' ⁹

Example 6

To 1000 ml of phosphate buffer pH 8 was added a variable amount of 0.2-5 g of detergent containing only 100 wt.%, Multienzyme complex with oxidoreductase and enhanced Upas activity as in Example 1. The resulting solution was used for a cotton wash test dirty standard MS. dirt under laboratory conditions at 50 ° C for 15 minutes. The results of the washing ability depending on the amount of multienzyme complex are given in Table 6:

Amount of multienzyme complex (g / l) Washing ability sample control (no enzyme) 0.2 32.5 23.8 0.5 31.8 24.5 1.0 33.5 23.5 2,0 37.3 27.3 3.0 35.5 25.3 4.0 34.3 21.3 5.0 31.6 18.0

Example 7

In a conventional powder formulation, a blend of 7 wt.%, Dodecylbenzene sulfonate, 3 wt.%, Nonyl polyglycol ether, 20 wt.%, Tripolyphosphate, 1.5 wt.%, Carboxymethylcellulose, 3 wt.%, Sodium silicate, 0.2 wt. an optical brightener, 3% by weight, amorphous silica, 0.2% by weight, perfume, 2% by weight, a multi-enzyme complex degrading hydrophobic chains of 5 to 35 carbons showing enhanced lipase activity as in Example 1, in encapsulated form, 60.1 % sodium sulfate. Compared to the control sample without the multienzyme complex, an increase in remission of 7 units was achieved over the entire range of concentrations evaluated, depending on the temperature in the range of 30 to 50 ° C.

Example 8

Detergent and degreaser containing 20% surfactants; ammonium alkylbenzonate, sodium alkyl polyglycol ester and ammonium lauryl sulfate in a weight ratio of 3: 1: 1 was compared to a solution of a multienzyme complex degrading hydrophobic chains of up to 0.02 g / l in a phosphate buffer solution of pH 8. The multienzyme complex exhibited a lipase activity of 2 J mg protein, alkane hydroxylase 0.5 nkat / mg and alcohol dehydrogenase 0.5 j / mg protein. Degreasing test on glass cloths containing paraffins and triglycerides. The values obtained at 40-50 ° C in 30-60 minutes at Limitest showed consistent results.

Example 9

Degreasing liquid composition comprising by weight%, ^C iq_i4 etoxylovených alcohols ^with 12 epoxy groups,% by weight, multi-enzyme complex with lipase activity of 2 units / mg of protein and the content of alcohol dehydrogenase 0.5 U / mg protein and 0.5 nkat / mg alkanhydroxylasy,% by weight, % sodium humensulfonate wt. water.

Example 10

Detergent and degreaser comprising% by weight, multienzyme complex of Example 9,% by weight, sodium alkylbenzene sulfonate,% by weight, sodium soap,% by weight, ethylene oxide / propylene oxide copolymer% by weight, synthetic zeolite,% by weight, sodium tripolyphosphate,

1.4% by weight of sodium sulfate

0.3% by weight of an optical brightener,

0.3% by weight, perfume,

1.0 wt.%, Carboxymethylcellulose.

Example 11

A laundry detergent composition containing% wt, sodium alkylbenzene sulfonate, wt%, sodium soap wt, ethylene oxide-propylene oxide copolymer wt, proteinase wt, amylase wt, multienzyme complex as in Example 2, wt%, zeolite wt, tripolyphosphate

0.3% by weight of an optical brightener

0.3% by weight of perfume

1.0 wt.%, Carboxymethylcellulose

1.4 wt%, sodium sulfate, wt%, sodium sulfate.

Claims (1)

Enzyme composition for the washing, degreasing, washing, purification and regeneration of waste and polluted waters, characterized in that it contains 0.1 to 50% by weight of a multienzyme lipase-oxidoreductase complex with a minimum Upas activity of 2 units / mg protein and the oxidoreductase activity of the alkane hydroxylase is at least 0.5 nkat / mg protein and alcohol dehydrogenase 0.5 units / mg protein, 2 to 45% by weight, nonionic and / or anionic surfactants, and the remainder to 100% by weight are chelating, filling, coloring, fragrance, brightener and other ingredients.