DE2314449A1 - ALKALINE DETERGENT PREPARATION - Google Patents

Description

Alkaline detergent preparation

The invention relates to an alkaline detergent composition, the working solutions having a pH value of 10 or supplies higher and by means of which it is possible the formation lu hard-of s loan to prevent calcium and magnesium salts and low corrosive, effect on Glass, porcelain and. Metals.

In many cleaning processes, for example metal degreasing, Machine dishwashing and washing of certain fiber materials are used as the main detergents aqueous alkaline detergent solutions are used. These develop either sodium hydroxide or alkaline as alkali

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Salts such as metasilicate, trisodium phosphate or soda, regardless of the type of alkali used, must be taken into account that the calcium and magnesium ions present in the water are more or less completely in the form of sparingly soluble Carbonates or phosphates, in certain cases also in the form of silicates, are precipitated as soon as the pH value of the water exceeds the value of 10 "In order to now To prevent lungs, either softened water or the cleaning agent was used for alkaline cleaning a suitable complexing agent. for the calcium r and magnesium ions added.

When using softened water, there are relatively high investment costs, especially for the water for household use. In addition, with softened water, the corrosion on glass decreases with mechanical Dishwashing too. That is why alkaline cleaning agents are usually used as complexing agents, such as sodium triphosphate, sodium biphosphate, the sodium salt of nitrilotriacetic acid, the sodium salt of ethylenediaminetetraacetic acid and - at pH. of 13 or more - the sodium salt: of gluconic acid, added. All of the complexing agents mentioned have certain disadvantages when they are used. So are under certain conditions Triphosphate and bisphosphate themselves cause the formation of poorly soluble calcium and magnesium salts. Also in regarding the nutritional effect in large water pools, in where the wastewater is discharged, extensive use of phosphates in cleaning agents is not recommended.

The sodium salts of nitrilotriacetic acid and ethylenediaminetetraacetic acid In contrast to the above-mentioned phosphates, they do not lead to poorly soluble calcium or calcium under any circumstances Magnesium complexon, but instead they have a highly corrosive one Effect on the glass and porcelain decor and on many ' Metals such as copper, zinc, iron and nickel. The corrosive effect on metals is particularly noticeable when the same

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early an oxidant is present, which is the case with most dishwasher detergents, also has shown that the ethylenediaminetetraacetic acid "in the" biochemical Water purification is bad for me to decompose. As for the sodium gluconates and the related complexing agents are concerned, these are only at a pH of 13 or more active so that their practical use is very limited.

It has now been found that when a complexing agent is used in the above-mentioned alkaline detergent preparations Iminodiacetic acid substituted on the nitrogen atom is used, a detergent preparation is obtained which on the one hand does not lead to the formation of calcium or magnesium precipitates and on the other hand only shows insignificant corrosion Glass that wields porcelain decor and metals. The iminodiacetic acid is quickly decomposable even with normal biochemical water purification. The present invention relates to consequently an alkaline detergent preparation which gives a ready-to-use solution a pH value of Ί0 or more and is characterized in that it contains an iminodiacetic acid of the general formula as complexing agent

ECH (OH) CH ₂ Ii (GH ₂ GOOLI) ₂

in which R is hydrogen or a methyl or ethyl group and M is a monovalent cation, such as a sodium, potassium, lithium, ammonium or ethanolammonium ion. The alkali-reacting substances contained in the preparation according to the invention are primarily alkali metal carbonates, alkali metal silicates, alkali metal phosphates, alkali metal hydroxides, ammonia, ethanolamines or mixtures thereof. Sodium hydroxide, ca-

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lium hydroxide, ammonia, metasilicates, NaO (SiOo) _n , where η is an integer from 2 to 4 ·, and the corresponding potassium silicate, trisodium and tripotassium phosphate, sodium and potassium carbonate and mono-, di- and triethanolamine. The amount of alkali varies according to the alkalizing substance (s) contained in the preparation, as already stated above, but the amount must be adjusted so that the ready-to-use solution of the preparation has a pH of 10 or more. With the normal dosage amounts, this means that an addition of 10 g of the detergent preparation, based on its dry weight, to 1 liter of distilled water results in the latter having a pH of at least 10.

In addition to the alkali and the complexing agents, the preparation according to the invention should also contain a surface-active component. In principle, it can be any surface-active substance, regardless of whether it is anionic, cationic, non-ionic or ampholytic. In general, a surface-active substance from the two last-mentioned classes is preferred, since it is then possible to select substances with a low foaming power and a good cleaning effect. Examples of suitable ampholytic detergents are in particular those of the betaine type, ie surface-active agents which have the characteristic group ^ Jf-R-OOCP, where R is a hydrocarbon group with 1 to 22 carbon atoms and the distance between COO and Ir * eight Does not exceed carbon atoms, in which Hegel is not more than two carbon atoms, contain. It is also possible to use the sulfobetaines, which are closely related to the betaines and form the characteristic group

^ JSr-R-SQ ₇ T , where R has the meaning given in the above formula for the betaines, contain * Other suitable ampholytic surfactants are. Aminomonocarboxylic acids and aminodicarboxylic acids of the general formula

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y E ₁ COOH y R ₁ COOH

b N

R-N or R-N

'where R is a hydrophobic group with 10 to 22 carbon atoms and R ₁ and Rp are smaller groups with not more than
8 mean carbon atoms. Another type of ampholytic surfactant that can be used in accordance with the invention are the various imidazoline derivatives.Detergent preparations of the invention which contain an ampholytic detergent have proven to be excellent means for degreasing metals.

Examples of non-ionic surfactants
are ethylene oxide adducts of alkylphenols, fatty alcohols,
secondary alcohols, alkylamines and alkyl mercaptans as well as adducts between ethylene oxide and propylene oxide. Ethylene oxide adducts of alkylphenols, fatty alcohols and synthetic primary and secondary alcohols with 9 to 20 carbon atoms in the hydrophobic part and an ethylene oxide chain with 5 to 30 ethylene oxide units are particularly suitable according to the invention. In cases in which foaming is not a disadvantage, customary anionic surface-active substances, such as alkyl sulfonates or sulfates with 12
up to 18 carbon atoms in the alkyl group, mono- or bialkylbenzene sulfonates or sulfates with a total of 15 to 21
Carbon atoms. A special type of anionic surface-active compounds are alkyl phosphates or alkyl ether phosphates of the general formula

R ₂ -O- (A ₂ ) _n 2 "OH
in de j: H _{1 is} an alkyl or alkylphenyl group with 8 to 20

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Carbon atoms in the alkyl chain, H ₂ hydrogen, an alkyl or alkylphenyl group with 8l> to 20 carbon atoms in the alkyl chain, A ^ and Ag independently of one another a GoBLO or C, BL.O group and. iu and up represent numbers from 0 to 15, or salts thereof. These phosphates combine a low degree of foaming with good corrosion-inhibiting properties, making them very suitable for use, for example, in dishwasher detergents, for example in combination with other surface-active compounds, such as non-ionic compounds.

As already stated above, cleaning agents which contain the substituted iminodiacetic acid according to the invention contain, a low corrosive effect on glass, porcelain decor and metals. An additional event may be optional Reduction in corrosion can be achieved that one known per se corrosion inhibitors added. Excellent Corrosion inhibitors in this context are alkyl ether phosphates, e.g. of the type defined in the above formula, benzotriazoles, fatty acid soaps, sodium aluminate and Sodium zincate · In detergent preparations can be used with advantage a mixture can be used consisting of a substituted Iminodiacetic acid and a smaller amount of sodium polyphosphate exists as a complexing agent. It has been shown that the preparations produced in this way have a high detergent effect and only have a low residue content on the Lead laundry.

The ratio of the amounts of the components contained in the detergent preparation according to the invention can vary within wide limits, but in Hegel the substituted iminodiacetic acid makes up 5 to 50 % of the dry weight of the preparation. A typical preparation can consist of 2 to 95 parts by weight of alkali, 5 to 50 parts by weight of a substituted iminodiacetic acid and 0.1 to 30 parts by weight of a surface-active compound.

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The preparation according to the invention can of course also contain other components in addition to these three main components contain, e.g. "common complexing agents, corrosion inhibitors, Fillers, agents to prevent reprecipitation, Additives to prevent foam formation, oxidants, optical brighteners, bacterial oids, dyes and fragrances. In addition, the preparations can be in the form of a powder or in the form of aqueous solutions, the latter normally being have a dry content of 10 to 40%.

The invention is illustrated in more detail by the following examples, but without being limited to it.

example 1

In a household dishwasher were at 70 C with Water with a hardness of 20 ° dH 6 drinking glasses, three of which were crystal glasses and three soda glasses, rinsed · The Glasses were rinsed three times with one of the detergents given below and on between washes Let air dry. The rinse water contained no detergent added. After the third wash, the dry glasses placed on a dark surface and rated. The series of experiments given above was carried out with each of the carried out below three dishwasher detergents of the composition given below.

Dishwasherdetj2rgens_jNr .__ 1 j_ This consisted of a commercially available Dishwasher detergent containing metasilicate, sodium triphosphate, a non-ionic surfactant Product of propylene oxide and ethylene oxide with a molecular weight of 5000 and an oxidizing organic chlorine compound. 3 ^ 10 g of this dishwasher detergent were used per washing process, which corresponded to a dishwasher detergent. agent concentration in the dishwashing water of 3 »88 g per 1,

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since the amount of water in a dishwashing process was 8 liters.

Ge £ chirrj3pülj5rdeterg £ ns No. _-1 2: _ This consisted of a preparation according to the invention which contained the following components in the amounts specified for each rinsing process:

Sodium salt of N- (2-hydroxyethyl) iminodiacetic acid 7 ₅ O7 S

,. 0.88 g / l

Na ₂ SiO _{3 t} . ^v '9.60 g

1.20 g / l Na dichloroisocyanurate 0.35 g

0.04-4 g / l

Fatty alcohol / ethylene oxide adduct (mixtures of

Cetyl and stearyl alcohol + 8 moles of ethylene oxide) 0.35 g

O ₁ OMA- g / l

Dishwasher detergent No ^ 3,: '_ This dishwasher detergent containing the same components in the same amounts as the dishwasher detergent # 2, but also it still contained sodium triphosphate in an amount of 1,94- 6 P ^ro rinsing or 0.24 g per. 1 Rinse water.

Assessing the amount of debris on the rinsed Glasses were made by five people, who were completely independent were from each other and didn't know what dishwashing detergent had been used. The following results were obtained:

Crystal glasses

Dishwasher detergent - Number of people who rated Dishwasher Detergent No. detergent as

the. best the second best the worst

1 0 0 5

2 5 0 0

3 0 5.0

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Lime soda glasses

G-es-dishwashing detergent- Number of people using the dishwasher gene JJr. detergents rated as

the best the second best the worst

1 0 0 5

2 5 0 0

3 0 5 0

From the above results it can be seen that all persons use the preparations according to the invention * i.e. the dishwasher detergents Mr. 2 and ITr. 3, as clearly better than the usual dishwasher detergent Mr. 1. From the Results can also be seen that by adding a small amount of sodium triphosphate to the dishwasher detergent ITr. 2 no part of the gate was achieved, but that instead the The amount of deposits increased.

Example 2

An artificially soiled cotton fabric was washed for 15 minutes in a laboratory washing machine of the Terg-O-Tometer type with an aqueous wash liquor containing a preparation according to the invention. The washing temperature was 60 ° C and the water hardness was 17 dH. The detergent composition comprised 10% dodecylbenzene sulfonate, 30% ÜT- (2-hydroxyethyl) iminodiacetic acid, 20 ° / o sodium perborate 10% sodium carbonate, 10% dicarbonate, 5% water glass (as active substance), and consisted of 1% carboxymethylcellulose, was in added in an amount of 7.5 g per liter of water. For comparison, a washing test was also carried out with 5 * 3 of the same preparation per liter of water, but this time the iminodiacetic acid was missing. The reflectance (luster) of the cotton fabric before and after washing was measured, and based on this measurement, the washing effect was calculated using the Kubelka-Munlcs equation. When using the detergent preparation according to the invention, a

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A washing effect of 77 % of the dirt washed out is achieved, while Yrarden removes only 23% of the dirt with the preparation without the N- (hydroxyethyl) iminodiacetic acid. This shows that the complex-forming ability of N- (2-hydroxyethyl) iminodiacetic acid is good and that it can be used with advantage in detergent preparations.

Example 3

A cotton fabric was 90 minutes of the type Terg-0-Tometer at a temperature of 90 ⁰ C and a water hardness of 20 ° dH measured in a laboratory washing machine. The washing liquor was 11. After the washing process was complete, 0.15 liters of the washing liquor were obtained and 1 liter of rinsing water with a water hardness of 20 ° dH was added. The water was completely changed in three successive rinsing processes 20 ° dH. This washing process was repeated 5 times. The detergent preparation used, which had been added in an amount of 9 »5 6, contained, inter alia, the following ingredients:

10 % ot-olefin sulfonate (with 14 to 20 carbon atoms)

20 % N- (2-hydroxyethyl) -iminodiacetic acid (calculated as sodium salt) -

10% sodium tripolyphosphate

20 % sodium perborate

10 % soda

10% bicarbonate

5 % water glass (as active substance)

1 % carboxymethyl cellulose.

For comparison, tests were carried out with the corresponding preparation in which the N- (2-hydroxyethyl) iminodiacetic acid completely replaced by sodium tripolyphosphate.

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After washing for 5 hours, the residue content of the cotton fabric was determined measured. It was found that the fabric washed with the detergent preparation according to the invention w.orden had a residue content of 0.10%, while the fabric made with the comparison preparation had been washed, had a residue content of 0.11%. This example shows that N- (2-hydroxyethyl) iminodiacetic acid can be used with advantage in detergent preparations without the risk of a high Residue content arises.

Example 4

In the same manner as in Example 1, dishwashing tests were carried out carried out, but this time in the dishwasher detergents ITr. 2 and no. 3 the sodium salt of N- (2-hydroxyethyl) iminodiacetic acid was replaced by an equal amount of the sodium salt of N- (2-hydroxypropyl) iminodiacetic acid. When evaluating the cleaning effect of the various dishwasher detergents, the same results as obtained in Example 1, i.e. dishwasher detergent # 2 was the best, dishwasher detergent # 3 was second best and dishwasher detergent # 1 was the worst,

Patent claims:

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Claims (1)

Pat ent claims (V). Alkaline detergent preparation which supplies ready-to-use solutions with a pH of 1ü or higher, characterized in that it contains an iminodiacetic acid of the general formula as a complexing agent ^ß - in which E is hydrogen, a methyl or iithyl group and M is a monovalent cation mean » 2. Preparation according to claim 1, characterized in that it contains (a) 5 to 50 parts by weight of iminodiacetic acid, (b) 2 to 95 parts by weight of an alkali metal carbonate, alkali metal silicate, Alkali metal phosphate, alkali metal hydroxide, Ammonia or ethanolamine or mixtures thereof and (c) 0.1 to JO parts by weight of a surfactant. 3. Preparation according to claim 1 and / or 2, characterized in that that they, as component (a), the sodium or potassium salt of 2-hydroxyethyliminodiacetic acid, as component (b) an alkali metal silicate and, as component (c), a nonionic or an ampholytic surfactant compound. . ¹ T. Preparation according to at least one of claims 1 to ^ i, characterized in that it contains as component (c) a non-ionic compound from the group of iithyleno.:,7dadducts of a fatty alcohol, a synthetic primary or secondary alcohol or a , AIIq *! Phenols with a total of 9 to 309840/1128 Contains 20 carbon atoms in the hydrophobic part and an ethylene chain with 5 to 30 ethylene oxide units » 5. Preparation according to at least one of claims 1 to 3 » characterized in that it ε-ls component (c) an ampholytic contains betaine-type surfactant. 6ο preparation according to at least one of claims 1 to 4, characterized in that, in addition to the nonionic surface-active compound, it is an anionic surface-active compound Contains alkyl phosphate or alkyl ether phosphate. 7ο preparation according to at least one of claims 1 to 6, characterized in that it is an iminodiessif as a complexing agent : contains acid / liatric polyphosphate mixture. 309840/1128