NO742450L - - Google Patents

Description

The present invention relates to concentrated and liquid coarse detergent compositions. Such compositions contain a nonionic surfactant component, an anionic surfactant component, and an alkanolamine component.

Liquid rough-cleaning agent compositions are well known in professional circles. Typically, such compositions (see, e.g., US Patents 2,908,651$2,920,045-, 3,272,753; 3,393,154 and Belgian Patents 613,165 and 665,532) contain a synthetic organic detergent component, which is usually of anionic, nonionic or mixed anionic-nonionic nature; an inorganic additive salt, and a solvent, which is usually water and/or alcohol. These compositions often contain a hydrotropic or solubilizing agent to permit the addition of sufficient amounts of surfactant and additive salt to thereby provide a suitable ratio of application volume to consumption. Although such liquid detergent compositions have been found to be effective for certain types of home washing, the presence of inorganic additive salts in such compositions may be undesirable from an ecological point of view as they affect the waste water in an unfavorable direction.

Many attempts have been made to formulate additive-free, hydrotrope-free liquid detergent compositions. E.g. describes the U.S. patent No. 3,528,925 essentially anhydrous liquid detergent compositions, which consist of an alkylarylsulfonic acid, a nonionic surfactant and an alkanolamine component. US Patent No. 2,875,153 describes liquid detergent compositions containing a nonionic surfactant component and a sodium soap component. U.S. patent no. 2,543,744 describes a low-foaming detergent composition, which consists of a non-ionic, water-soluble, synthetic detergent and a water-soluble soap in the form of an alkali metal, ammonium or amine salt. All these cleaning agent compositions are effective for certain types of washing operations, but none of the commercially available compositions of this type are particularly effective either for pre-treatment or for bulk washing agents for cleaning both natural and synthetic substances.

U.S. patent No. 3,663,445 relates to liquid cleaning and degreasing compositions containing a nonionic surfactant, an alkanolamine-neutralized anionic surfactant, and alkanolamine.

U.S. patent application no. 222,363, filed on 31/1/1972, which is under processing, and which has the title "Liquid Detergent Compositions" relates to detergent mixtures which consist of a greater ratio of non-ionic to anionic surfactant and alkanolamine.

U.S. Patents No. 3,709,838; 3,697,451; 3,554,916; 3,239,468;

2,947,702; 2,551,634; British Patent No. 900,000; 842,813;

759,877, and Canadian Patent No. 615,583 describe various detergent compositions containing mixed non-ionic

spoon-anionic surfactants, both with and without alkanolamines.

As can be seen from the above, "substantial work has been done to develop liquid cleaning agent compositions with little additives as well as additive-free ones. There are, however, many problems in connection with the compositions described within professional circles, and then problems in connection with that the aforementioned compositions do not exhibit optimal effects across the entire spectrum of use.

Firstly, many previously known compositions contain phosphorus-based additives. Such additives and compositions containing such compounds may '.

be of little use in areas of a country where there is insufficient treatment of waste water.

Second, many previously known compositions are formulated with too low a ratio of nonionic:anionic surfactant to achieve optimal oil sol removal from the fabrics.

Thirdly, many previously known compositions are formulated to provide a satisfactory cleaning throughout the washed fabric, but do not provide optimal pre-wash treatment of oil dirt located on the collars and cuffs of the fabric.

Most users of liquid detergent compositions expect that good toy cleaning is obtained by applying the liquid product directly at full strength to the heavily soiled areas of the toy for washing. Consequently, it is desirable to provide a liquid cleaning agent which has an optimal cleaning effect during pretreatment as well as optimal cleaning during "through-washing".

However, it is known from the past (see U.S. Patent No. 3,663,445) that surfactant compositions containing high concentrations of ethylene oxide-based nonionic surfactants and alkanolamines must contain fatty acid salts to provide the desired product stability and/or performance .

Due to delivery problems with fatty acids, it is undesirable

to provide stable, high-cleansing, non-ionic - anionic cleaning agent compositions with a high concentration of ethylene oxide-based non-ionic surfactants without the need for additives which are derivatives of fatty acids.

It has now been found that certain ethylene oxide-based nonionic surfactants can be used at high concentrations in liquid detergent compositions, in combination with alkanolamines and certain anionic surfactants, and then without the necessity of using fatty acid-based stabilizers.

It is an aim of the present invention to provide additive-free and liquid cleaning agent compositions, which provide both good pre-washing and re-washing during fabric cleaning.

Another object of the invention is to provide stable and liquid cleaning agent compositions, which are free of fatty acid-based stabilizers, and which exhibit optimal cleaning and foaming characteristics.

Another object of the invention is to provide fatty acid-free liquid cleaning agent compositions, which contain high concentrations of non-ionic surfactants and free alkanolamines.

These and other purposes have been achieved by the present invention, which will be further illustrated in the description.

The present invention relates to liquid cleaning agent compositions, which consist of: (a) from approx. 20 to approx. 90% by weight of a non-ionic surfactant produced by condensation of from approx. 5 moles to approx. 11 mol of ethylene oxide with a mol

of a C, . to C, c alcohol, whereby said non-ionic over-

14 16'

Surfactants are further characterized by a hydrophilic-lipophilic equilibrium of from approx. 10 to 14, preferably 11 to 13, or mixtures thereof; (b) an anionic surfactant of the type described below, and then in an amount

which is sufficient to provide a weight ratio between nonionic surfactant and anionic surfactant that lies within the range from about 1.8:1 to about 3.5:1, based on the free acid form of the anionic surfactant, and (c) an alkanolamine in an amount sufficient to provide at least 1% by weight of free alkanolamine based on the composition.

Hoyt's preferred nonionic surfactants for use here are alcohol-ethylene oxide condensates, where the alcohol contains from 14 to 15 carbon atoms, and where the condensate contains from 6 to 9 moles of ethylene oxide (hydrophilic) per moles of alcohol (lipophilic). Such materials are usually abbreviated to ci4_i5E05_9'

The attached curve diagram shows three separate product parameters, which indicate the optimum of non-ionic surface-active agents for use in a liquid detergent composition, which contains a non-ionic-anionic mixture of the type described here. Each of the parameters is dependent on both the degree of ethoxylation of the non-ionic surfactant (x-axis) and the carbon content in the lipophilic alkyl part of the non-ionic surfactant molecule (y-axis). Non-ionic, ethoxylated surfactants selected from the border areas of curve A in the figure exhibit excellent cleaning action when used as pre-treatment of a substance for an aqueous washing process. Non-ionic surfactants selected from the border areas within curve B in the figure show excellent cleaning effects when washing through a substance. Consequently, selection of a non-ionic surfactant from the area bounded within curves A and B, and where these intersect, will provide the optimum non-ionic agents, from an overall cleaning effect point of view.

Line C in the figure indicates the lower limit (c^^) of the carbon content in the hydrocarbyl part of the non-ionic surfactants, which is used as a main component of the compositions described here. As mentioned above, selection of the non-ionic surfactant from the area above line C gives stable compositions, which have high concentrations of non-ionic substances without the need for fatty acid additions.

Consequently, selection of the non-ionic surface active agent from the area limited by intersection areas between curves A and B as well as C (shaded area in the figure) gives the formulation of stable non-ionic surfactant mixtures with optimal pre-treatment and wash-through purification.

In the following, the individual components of the present cleaning agent compositions shall be described. The compositions in question contain as an essential ingredient approx. 20 to approx. 90% by weight, preferably from approx. 25 to approx. 40% by weight, of a non-ionic surfactant, which is obtained by the condensation of ethylene oxide with an alcohol having a content of carbon atoms from to approx. C-^. As can be seen from the figure, ethylene oxide condensates, which have more than approx. 16 carbon atoms in the alkyl chain in the alcohol part of the molecule, not suitable either for cleaning the substance by washing through or pre-treatment. As mentioned above, alcohols which have a hydrocarbon content of C, . or more preferably due to the stability of the product.

From the figure it appears that the non-ionic surfactants used here contain from approx. 5.0 mol of ethylene oxide to approx. 10.7 mol of ethylene oxide per moles of alcohol in the condensate. However, it is not sufficient to describe the nonionic surfactants only with respect to their alkyl carbon content and ethylene oxide content, as a part of the nonionic surfactants, which are covered by this broad definition, lie outside the preferred range which is indicated by the curves A, B and C (see here the shaded area in the figure). Consequently, the nonionic surfactants here must also be defined by means of their hydrophilic-lipophilic equilibrium.

The individual non-ionic surfactants used here in the compositions are often considered to contain a hydrocarbyl chain (derived from the alcohol) which is condensed with an alkylene oxide chain. The hydrocarbyl part of such materials gives rise to their lipophilic character, while the ethylene oxide part is decisive for their hydrophilic character. The overall hydrophilic-lipophilic characteristic of a particular hydrocarbyl-ethylene oxide condensate is reflected in the balance between these two factors, i.e. the hydrophilic-lipophilic equilibrium (HLB). HLB

to the ethoxylated nonionic compounds can be experimentally determined in a well-known manner, or it can be calculated in the manner indicated in Decker, "Emulsions Theory and Practice" Reinhold 1965, pp. 233 and 248.. .E.g. HLB in the non-ionic surface-active agents can be approximately simply stated with the help of the expression

HLB = E/5,

where E is the weight percent ethylene oxide content in the molecule. Naturally, the HLB will vary for a particular hydrocarbyl content with the amount of ethylene oxide.

Consequently, the non-ionic materials, which here lie within the preferred range shown in the figure, can be described as condensates of an alcohol with a carbon content of from C, ^ to approx. C^g, which is condensed with from approx. 5.0 mol to approx. 10.7: moles of ethylene oxide per moles of alcohol, and which further characterizes the wood HLB in the area from approx. 10 to approx. 14, preferably from approx. 11 to approx. 13. Non-ionic surfactants, which lie within these ranges, are highly preferred due to optimal pre-treatment cleaning, optimal wash-through cleaning and product stability, and then without the need to add fatty acid-based additives.

The non-ionic surface-active agents, which are used in present compositions, can be prepared using various well-known methods. In general, such nonionic surfactants are prepared by condensing ethylene oxide with an alcohol under acidic or basic catalyst conditions.

The non-ionic surfactants here include the ethylene oxide condensates of both primary and secondary alcohols, with the condensates of primary alcohols being preferred. Non-limiting and specific examples of non-ionic surfactants, which have the required carbon content in the hydrocarbyl part of the molecule, the required ethylene oxide content and the required HLB are as follows: N-C14H2g(EO)5$ n_ci4<H >29 ^<E>0^6'n-Cl4~H29^E0^7'

n<-C>14<H>29(<EO>)10' , n-C15H31(EO)6' n-C15H31(EO) 75<2-C>15<H>31 (<EO>) 7; , n~C15H31(EO)8'2-C15H31(EO)8'n-C15H31(EO)9; 2-C15H31 (EO) g5 n-<C>16<H>33(EO)95°9 2-C16H33(EO)9-

It has been observed that mixtures of the aforementioned nonionic surfactants can also be used and are readily available from commercial alcohol mixtures. Moreover, the degree of ethoxylation can vary somewhat, as the average degree of fractionation for ethoxylation is obtained. E.g. may n-C^ j-H31 (EO) ^ contain small amounts of n-C-^H.^(E0)Q and n-C^^H^ (EO) Such commercial mixtures are within the limits indicated here and are usable in the present cleaning agent compositions.

The preferred nonionic surfactants are the 15^E0^6 9 materials which constitute the above-mentioned materials, and these are commercially available as mixtures under the names "Neodol 45-7" and "Neodol 45-9" from Shell Chemical Co. "Neodol 45-7"

is a liquid at room temperature and is preferred. "Neodol 45-9"

is a solid at room temperature, but can be used in the liquid cleaning agent compositions according to the present invention, as it is easily dissolved.

The presence of the non-ionic surface-active agent in the liquid detergent compositions in the essentially specified concentrations and mixtures provides the necessary removal of oil stains during both pre-treatment and thorough washing. The selected non-ionic surfactants here also contribute to the physical stability of the liquid cleaning agent compositions.

The anionic surfactant.

The anionic component in the cleaning agent compositions is an alkanolamine salt of an alkylbenzene sulfonic acid (an alkanolamine alkylbenzene sulfonate). The alkanolamine alkylbenzene sulfonate salts are prepared by neutralizing an alkylbenzene sulfonic acid with an alkanolamine selected from the group consisting of monoethanolamine, diethanolamine and triethanolamine. The triethanolamine salts are hereby preferred. The anionic surfactant salt is used here in an amount which is sufficient to give a weight ratio between non-ionic surfactant and anionic surfactant from approx. 1.8:1 to approx. 3.5:1, preferably at a ratio of 2.0:1 to 3.0:1, calculated on the free acid form of the anionic surfactant.

In particular, the anionic surfactant consists of a mono-, di- or tri-ethanolamine salt of a straight-chain or branched alkylbenzenesulfonic acid, where the alkyl group contains from approx. 9 to approx. 15 carbon atoms. Preferred surfactants of this type are those where the alkyl chain is straight chain and on average approx. 12 carbon atoms long. Examples of alkanolamine-■ alkyl-benzenesulfonates, which can be used according to the present invention, include monoethanolamine-decylbenzenesulfonate, diethanolamine-undecylbenzenesulfonate, triethanolamine-dodecylbenzenesulfonate, monoethanolamine-tridecylbenzenesulfonate, triethanolamine-tetradecylbenzenesulfonate and diethanolamine-tetrapropylenebenzenesulfonate and mixtures thereof. Examples of commercially available alkylbenzenesulfonic acids useful in the preparation of the alkanolamine sulfonates of the present invention include "Conoco SA 515", "SA 597" and "SA 697", all of which are marketed by Continental Oil Company, and "Calsoft LAS 99" , which is marketed by Pilot Chemical Company.

The alkanolamine

A third important component in the liquid cleaning agent composition according to the present invention is the alkanolamine compound. The alkanolamine used here is selected from the group consisting of monoethanolamine, diethanolamine, triethanolamine and mixtures thereof. Mixtures of these three alkanolamine compounds are produced by the reaction between ethylene oxide and ammonia. The pure compounds can be separated from this mixture

using conventional distillation techniques.

The alkanolamine component of the present invention serves two purposes. As will be explained later, the alkanolamine in the preferred method for producing the present compositions neutralizes the free acid form of the anionic surfactant, thereby resulting in the corresponding alkanolamine salt, which is an important component in the present cleaning agent compositions. In addition, an excess of alkanolamine beyond what is necessary to form the anionic surface-active salt will contribute to cleaning performance, and serve as a buffering agent that keeps the pH of the wash water from the present compositions within the range of approx. 7 to approx. 9. It is important that the compositions according to the present invention contain at least 1% by weight of the total composition of free alkanol-

amine, i.e. an excess over that required to neutralize the alkylbenzenesulfonic acid as anionic surfactant.

Stable liquid cleaning agent compositions, which contain non-ionic, anionic and alkanolamine-containing components, can be formulated by preparing each component separately and carefully mixing them in one order or another. In a preferred method for producing the present compositions, the anionic and alkanolamine-containing components were formulated simultaneously by superneutralizing the alkylbenzenesulfonic acid with alkanolamine. This method forms the desired alkanolamine alkylbenzene sulfonate and provides the free alkanolamine component of the present composition. Preferably, the compositions contain from approx. 2.0 to approx. 10.0% by weight of free alkanolamine, preferably triethanolamine.

Optional Components.

Although the liquid cleaning agent compositions according to the present invention only need to contain the three components described above (i.e. thick and water-free compositions), then

preferred compositions will contain, in addition to the three active components, a solvent, which is selected from the group

consisting of water and water-alcohol mixtures. Such solvents can be used to an extent from approx. 1 to 45% by weight calculated on the total detergent composition. In preferred compositions, the solvent comprises from approx. 25 to 45% by weight of the total composition. The use of such solvents in the compositions has many advantages. Firstly, the physical stability of the cleaning agent compositions can be improved by dilution with such solvents, whereby the clearing points will thereby be lowered. The diluted compositions will not become cloudy at low temperatures,

which is common during shipment or storage of commercially marketed cleaning agent compositions.

Secondly, the addition of solvents, and in particular water-alcohol mixtures, will serve to regulate the gelling tendency, which liquid cleaning agent compositions according to the present invention exhibit when diluted with water.

When an alcohol-water mixture is used as a solvent,

then the weight ratio between water and alcohol will preferably be kept above approx. 3:1, preferably from approx. 4:1 to approx. 7:1. High alcohol (especially ethanol) concentrations in the water-alcohol mixtures, which are used according to the present invention, are preferably avoided because of flammability problems that can occur with such high alcohol concentrations.

Any alcohol containing from 1 to approx. 5 carbon atoms can be used in the water-alcohol dilution, which is used to produce the present cleaning agent compositions. Examples of useful alcohols include methanol, ethanol, propanol, isopropanol, isopropanol, butanol, isobutanol and pentanol; whereby ethanol is usually preferred.

Another optional component that can be added to the cleaning agent compositions according to the present invention is a salt electrolyte. As emphasized in the U.S. patents Nos. 2,580,173 and 3,440,171, the electrolyte salts reduce the gelation that tends to occur with alkanolamine-neutralized surfactants. Such electrolytes will, when used here in combination with a water-alcohol solvent in a percentage by weight of the total composition of from approx. 0.5 to 5% of the electrolyte salt, completely eliminate the gel formation of the anionic surfactant without the need to use an excess of high alcohol concentrations.

Useful electrolyte salts include the alkali metal chlorides,

-sulfates and -carbonates, and the salts formed by the reaction of alkanolamines with inorganic acids, such as HCl, H^O^ and organic acids, such as formic acid, acetic acid, propionic acid, butyric acid and citric acid. Specific examples of such salts include sodium chloride, potassium chloride, sodium carbonate, potassium carbonate, potassium sulfate, sodium sulfate, triethanolamine sulfate, triethanolamine citrate, triethanolamine acetate, triethanolamine formate, monoethanolamine propionate and diethanolamine butyrate. Of all the possible electrolyte salts, which can be used to avoid gel formation of the compositions here, potassium chloride is very effective and preferred. Potassium chloride is preferably added to the present compositions in an amount of from approx. 1 to 3% by weight

to provide anti-gelling effects.

As mentioned, the use of a solvent and electrolyte serves to regulate and control gel formation in the present liquid detergent compositions. If, however, gel formation is desired, then it is possible to select particular concentrations of a water solution which give gel compositions in the absence of alcohol and electrolyte salt. These compositions, which contain the three active components in the concentrations specified above and a water solution, which contains from approx. 15 to 35% by weight, will become thick or gel-like provided no alcohol or electrolyte is present.

Other optional components, which are not important and do not affect the compositions, can be added to the compositions to give a good aesthetic impression. Preferred compositions according to the invention are those to which a color stabilizing agent, such as citric acid, has been added. These compositions exhibit surprising stability against the tendency of such compositions to develop a reddish color on storage. Moreover, the presence of citric acid in the compositions according to the inventions can have a beneficial effect with regard to preventing the development of stains, which can be observed on the outer surface of plastic jugs, and which occur when spills, leaks or handling bottles with hands that has previously been in contact with the compositions according to the present invention. As regards the anionic surface-active acids, citric acid forms alkanolamine citrate when the acid is added to present compositions containing alkanolamine in excess. Usually, meanwhile, this alkanolamine citrate concentration in the compositions is expressed as a percentage by weight of the free acid form of the citrate, i.e. citric acid, added to the compositions. A quantity of the citric acid and up to approx. 1% by weight calculated on the composition is usually added to achieve the aforementioned advantages with regard to color. A very preferred range for added amount of citric acid is from approx. 0.05 to approx. 0.10% by weight calculated on the composition. Naturally, the composition must still be formulated to maintain a minimum of approx. 1% by weight of free alkanolamine.

Foam modifiers may be present in the present compositions in smaller amounts to provide high foaming or low foaming products as desired. As the compositions according to the present invention naturally provide adequate suds levels, certain consumers desire detergent products to provide abundant suds. Consequently, the compositions according to the present invention can optionally contain up to approx. 10% by weight of foaming enhancers. Nonionic surfactants in the C10 i4E04_9 range are well applicable for such foam enhancing purposes. A preferred foam enhancer is hexa-ethoxylate of mixed coconut fat alcohols (abbreviated CNE^). The compositions according to the present invention, which contain from 1 to 10% by weight of CNE6, are preferred. Naturally, smaller amounts of CNEg, which are added because of the foam-enhancing properties, cannot in any way affect other desired properties of

the compositions.

Other optional components include gloss additives, fluorescent agents, enzymes, bleaching agents, anti-microbial agents, corrosion inhibitors and colorants. Such components preferably do not amount to more than approx. 3% by weight of the total composition.

Application of the quantity ratio between non-ionic surfactant and anionic surfactant (free acid base) from approx. 1.8:1 to approx. 3.5:1 in combination with the use of an excess of free alkanolamine is critical in the formulation of the cleaning agent compositions, which have the unexpected cleaning effect and stability characteristics according to the present invention. The formation of mixed surface-active micelles, which is a result of using the special non-ionic-anionic surfactant ratio according to the present invention provides an unexpected cleaning effect, which is insensitive to the hardness of the water.

Use of alkanolamine salts and an excess of alkanolamine also contribute to making the present cleaning agent compositions effective. E.g. are these compositions, which contain the alkanolamine motion in combination with an excess of free alkanolamine, better for cleaning polyester/cotton than corresponding compositions, which contain the more conventional sodium or potassium salts of the anionic surface-active acids and no free alkanolamine. Of the alkanolamines, tri-ethanolamine is preferred because of its availability and cleaning effect.

The compositions according to the present invention are particularly intended to provide an optimal cleaning effect when they are used in the two ways that are common in connection with liquid cleaning agent compositions. Firstly, the compositions can be used as pre-treatment agents, whereby they are used in concentrated form directly on the fabric's stains for washing the fabric. Secondly, the present compositions are also usable as cleaning agents for conventional fabric washing. One achieves

o

excellent removal of stains and grease when the present compositions are dissolved in an aqueous washing solution at a concentration of at least approx. 0.10% by weight (approx. 1/4 cup per 77-86 1 wash water). For thorough washing of the toy, a concentration of present compositions within the range from 0.08 to approx. 0.20% by weight calculated on the washing liquid. Naturally, this can be adjusted depending on the degree of dirtiness and the user's wishes.

With regard to pre-treatment effect, the present compositions, which contain the components and proportions specified here, provide removal of oil stains from polyester or polyester/cotton fabrics, and this removal is superior to similar pre-treatment effects achieved by using conventionally formulated anionic cleaning agents - compositions. In reality, this effect is comparable to the removal of oil stains achieved with pure non-ionic surfactants, which are particularly known for their effect in such pretreatment and removal of stains. On the other hand is

the special compositions according to the present invention are far superior to the conventional non-ionic products which are based on surfactants, and which are used for washing and removing grease (and especially from cotton) under normal conditions in homes. - The cleaning agent effect during normal washing with the present compositions is in fact comparable to that achieved with conventional formulated, powdered anionic cleaning agent compositions.

The following examples illustrate the liquid cleaning agent compositions according to the present invention. The abbreviations for the nonionic surfactants used, e.g. C14(EO)6, is the standard for such materials and describes the carbon content in the alcoholic and lipophilic part of the molecule as well as the ethylene oxide content in the hydrophilic part of the molecule.

EXAMPLE 1

100 g of liquid detergent composition is formulated, whereby it has the following composition:

The weight ratio between nonionic surfactant and anionic surfactant (based on free acid) in the above composition is 2.00:1.

The above composition is a stable; (i.e. does not separate or otherwise degrade on storage and is satisfactory for use after being subjected to a freeze-thaw cycle) clear and liquid detergent, which does not gel when diluted with water. The composition gives a medium high level of foaming in washing water at different temperatures and hardness. The aforementioned composition provides an excellent cleaning effect on substances both during pre-treatment and through washing.

The aforementioned composition is modified by the addition of 0.05 g of citric acid. The color stability of the composition, which contains citric acid, is markedly improved compared to

similar compositions that do not contain citric acid.

In the above composition, the triethanolamine-neutralized anionic surfactant is replaced with monoethanolamine- and diethanolamine-neutralized anionic surfactant, and you get an overall good cleaning effect.

In the above composition, the free triethanolamine is replaced with henh. free monoethanolamine and free diethanolamine, and you get a good overall cleaning effect.

EXAMPLE 2

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent during pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 3

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 4

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 5

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 6

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 7

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 8

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent during pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water. In addition, the composition has a desired foaming property.

EXAMPLE 9

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water. In addition, the composition has a desired foaming property.

EXAMPLE 10

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

EXAMPLE 11

The above composition is stable and provides excellent cleaning of substances when used either at full strength as a cleaning agent for pre-treatment or through washing, and then in a quantity of 1/4 cup per 77 1 washing water.

Claims (15)

1. A liquid cleaning agent composition, characterized in that it consists of: (a) from approx. 20 to approx. 90% by weight non-ionic surfactant, which is produced by condensation of from approx. 5 moles to approx. 11 mol of ethylene oxide with 1 mol of an alcohol with 14-16 carbon atoms, whereby the non-ionic surfactant is characterized by an HLB from approx. 10 to approx. 14, or mixtures thereof; (b) an anionic surfactant, which is an alkanolamine salt of an alkylbenzenesulfonic acid, wherein the alkyl group contains from about 9 to approx. 15 carbon atoms, whereby the weight ratio between non-ionic surfactant and anionic surfactant is from approx. 1.8: 1 to approx. 3.5:1 , calculated on the free acid form of the anionic surfactant; and (c) at least 1% by weight of free alkanolamine calculated on the composition. 2. Composition according to claim 1, characterized in that the non-ionic surfactant is the condensation product of from approx. 6 to 9 moles of ethylene oxide with a C14 15 alcohol, and that the HLB is in the range from 11 to 13. 3. Composition according to claim 1, characterized in that the alkanolamine salt of the anionic surfactant is the triethanolamine salt. 4. Composition according to claim 1, characterized in that the alkylbenzene sulphonate contains on average 12 carbon atoms in the alkyl group. 5. Composition according to claim 1, characterized in that the weight ratio between non-ionic and anionic surfactant is in the range from 2.0:1 to 3.0:1. 6. Composition according to claim 1, characterized in that the free alkanolamine is triethanolamine. 7. Composition according to claim 6, characterized in that the triethanolamine is present in the composition in a concentration of from approx. 2.0 to approx. 10.0% by weight. 8. Composition according to claim 1, characterized in that the non-ionic surfactant is a condensation product of 6 to 9 mol of ethylene oxide with an alcohol, and that the HLB is from 11 to 13, whereby the anionic surfactant is a triethanolamine salt of an alkylbenzenesulphonic acid with an average of 12 carbon atoms in the alkyl group, and that the free alkanolamine is triethanolamine. 9. Composition according to claim 1, characterized in that it additionally contains from approx. 1 to approx. 45% by weight of a solvent selected from the group consisting of water and water and C-^-C^ alcohol. 10. Composition according to claim 9, characterized in that the alcohol is ethanol. 11. Composition according to claim 10, characterized in that the solvent consists of from approx. 25 to approx. 45% by weight, calculated on the total composition, and that the weight ratio between water and ethanol is above approx. 3:1. 12. Composition according to claim 10, characterized in that it further contains up to approx. 10% by weight of a Cl0 i4.(E°)4_9 foam booster. 13. Composition according to claim 12, characterized in that the foam enhancer is hexaethoxylate of mixed coconut fat alcohols. 14. Composition according to claim 13, characterized in that it further contains from approx. 0.5 to approx. 5% by weight potassium chloride. 15. Composition according to claim 13, characterized in that - it further contains from approx. 0.5 to approx. 1 wt% citric acid, calculated on the free acid form.