NO763509L - - Google Patents

Description

The invention relates to detergent mixtures which are suitable for washing clothes, and in particular such mixtures which contain phosphate detergent builders.

The detergent builders most commonly used are condensed phosphates, especially sodium tripolyphosphate, but it has been suggested that the use of these phostat detergent builders may contribute to eutrophication problems. Many proposals have been made for alternative, mainly organic, materials for use as detergency builders instead of the condensed phosphates, but most of these materials tend to

be unsatisfactory for one reason or another. For example, they are less effective or biologically unacceptable, or they are simply too expensive.

It has also been proposed to mitigate the eutrophication problems by using smaller amounts of detergent builders of condensed phosphates, with or without the presence of other detergent builders, but few of these proposals have been acceptable. Thus, when reduced amounts of sodium tripolyphosphate are used without supplemental builders, considerable problems can arise when the compositions are used in hard water if there is insufficient phosphate to sequester all the calcium ions present,

as these cause the precipitation of insoluble calcium phosphate salts which can accumulate on the washed laundry. When a condensed phosphate builder is used together with other types of detergency builders, they tend to influence each other, and often the former prevents the latter from working effectively, especially when it comes to other detergency builders that work by precipitation of the calcium salt, for example, sodium carbonate.

We have now discovered that certain mixtures of sodium tripolyphosphate and soap act as effective detergency builders and that these materials, when combined with a non-ionic surfactant, form a heavy-duty washing powder that has good detergency and produces a comfortable grip on the laundry after washing.

According to the present invention, a washing powder for large-scale laundry is provided which comprises a non-soap-containing detergent, a water-soluble soap and sodium tripolyphosphate, in which (a) the non-soap-containing detergent is essentially treated with an alkylated alcohol non-ionic surfactant agent present in an amount of from 5 to 50% by weight,

(b) the water-soluble soap is present in an amount of

10-30% by weight, and

(c) the sodium tripolyphosphate is present in an amount of 10-40% by weight;

the rest being conventional components in laundry detergents. By selecting the amounts of the sodium tripolyphosphate and the soap within the indicated ranges, it is possible to form effective detergent compositions containing lower amounts of phosphorus than conventional detergent compositions of comparable performance. To that extent. these two materials usually work in different ways, i.e. sodium tripolyphosphate acts as a sequestering detergency builder and the soap acts as a precipitation builder, it is somewhat surprising that a mixture of the materials works so effectively. In particular, the tendency of sodium tripolyphosphate to cause inorganic deposits on laundry when used in small amounts in detergent compositions is reduced in the presence of the soap. Also, sodium tripolyphosphate does not seem to inhibit the detergency building effect of the soap, as it does with many other detergency builders, and all soaps that do not precipitate as calcium salts, e.g. when the mixtures are used in soft water or at higher product concentrations, can act as a detergent-active compound, and thus increase the washing ability of the mixtures.

The soaps used are sodium, or less desirable potassium, salts of Cq-C^-^acetic acids, especially natural fatty acids derived from nut oils, such as coconut oil or palm kernel oil, or fats of the tallow class, such as tallow from beef or mutton, palm oil, lard, some vegetable butter and castor oil. The fat of the tallow class can, if desired, be hardened, to reduce the content of unsaturated acids such as oleic acid and linolenic acid, and this is particularly useful if it is desired to use some stronger polyunsaturated oils, such as soybean oil, as fat of the tallow class in significant amounts.

It is preferred to use mixtures of soaps derived from fats of the tallow class (ci4-C2o-'^ove(3sa^-el:'-'? cis~fatty acids) and soaps from nut oils, which are soaps of predominantly C^q-C^ -, mainly c±2~^acetic acids, of which usually least

about. 75% are saturated fatty acids, and again the nut oils can be hardened if desired. Such mixtures tend to be more soluble than tallow soap alone, and this, coupled with sufficiently low calcium soap solubilities for satisfactory wash eye build-up and sufficiently low critical micelle concentrations approaching those of tallow soap alone, enables any excess of the soap to act as a additional detergent-active component. The preferred mixtures contain from approx. 9:1 to 1:9, for example approx. 5:1

to 1:5, and especially approx. 3:1 to 1:2, parts by weight of soap from the tallow class in relation to parts by weight of soap from the nut oil class. Generally, higher proportions of soaps from the tallow class in such mixtures give better properties as detergent builders, while larger proportions of soaps from the nut oil class give better solubility properties.

In addition to soap from the tallow class and any possible nut oil soap, certain soaps with . longer carbon chain length, especially C20-C24 soaps, e.g. rapeseed soaps, which are useful in providing antifoam properties. A particularly preferred mixture of soaps is one comprising 45-60% by weight tallow fat grade soap, 20-30% by weight coconut oil soap and 15-25% by weight hardened rapeseed oil soap. When this is incorporated into a powder in an amount of 15% by weight, it has been found that it enables the production of a powder with desirable powder properties. Soaps made from synthetic fatty acids can also be used. Unlike naturally occurring or derived fatty acids which have linear carbon chain lengths with equal numbers, synthetic fatty acids can have both different and equal ones. numbers and they can have both linear and branched chains. Synthetic fatty acids with carbon chain lengths of mainly C14-C20 which are preferably at least approx. 40% saturated and at least approx. 75% linear, can be used as a partial or full replacement for soaps of the natural tallow class, and synthetic fatty acids with carbon chain lengths of mainly C^0-C-^g, which are preferably at least approx. 75% saturated and at least approx. 50% linear, can be used as a partial or full replacement for natural nut oil soaps. If some fatty acids with a branched chain are used, they are preferably !Y-alkyl-, e.g. Q<i-methyl~ branched, rather than being more strongly branched.

In recent years, there have been many proposals for the use of sodium tripolyphosphate as a detergency builder in detergent mixtures that include soap as a detergent active material. In so-called ternary mixtures for use in low-foaming mixtures, it is for example common for some soap to be present, in a small amount of up to approx. 8% by weight, together with very small amounts of anionic and non-ionic surfactants. Such soaps are usually tallow soaps or soaps of fatty acids with longer chain lengths. Soap-based detergent mixtures have also contained small amounts of sodium tripolyphosphate. The applicant, however, is not aware that it has been proposed to use the specific detergency builder mixtures of sodium tripolyphosphate and soap in the conditions stated above for use in laundry detergent mixtures according to the present invention.

The ratio between the sodium tripolyphosphate and the soap in the detergent mixture is usually from approx. 4:1 to 1:3 parts by weight, preferably approx. 3:1 to approx. 1:3 parts by weight, and especially from approx. 2:1 to approx. 4:3 parts by weight. The total amount of sodium tripolyphosphate plus soap is usually from approx. 20 to approx. 70% by weight, preferably approx. 25 to approx. 60% by weight, and sold approx. 25 to approx. 45% by weight of the mixture. Smaller amounts of sodium tripolyphosphate and soap are found to be more desirable for compositions intended for use either at higher product concentrations or in soft water.

It will be understood that the amount of sodium tripolyphosphate is chosen according to the total amount of phosphate builder desired in detergent mixtures, or according to the maximum permissible phosphorus content. One usually uses an amount of sodium tripolyphosphate that is in the range from approx.

15 to approx. 35% by weight of the mixture. If, however, the mixtures according to the invention are intended for use with smaller amounts of phosphate for environmental reasons, lower amounts of approx. 10 to approx. 25% or preferably approx. 10 to approx. 20%. An amount of 20% by weight of sodium tripolyphosphate relative to the mixture is equivalent to only approx. 5% by weight of phosphorus, and it is a feature of this invention that it is possible to prepare detergent mixtures with these low phosphate contents which nevertheless have particularly good washing

properties.

The minimum amount of soap that should be present is 10% by weight of the mixture, and the maximum amount is 40% by weight, preferably less than about 25% by weight of the mixture, and especially approx.

10. to approx. 20% by weight.

The amounts of sodium tripolyphosphate and soap for use in a particular detergent mixture are selected according to the expected washing conditions. We have found that, for example, amounts of 20 and 15% respectively give optimal performance (with a 5% phosphorus amount) for mixtures that are intended for use at relatively high product concentrations, i.e. about. 0.3 to approx. 0.8% by weight which is common practice in Europe, especially in automatic washing machines with front loading. But in mixtures intended for use at relatively low product concentrations, i.e. about. 0.1 to 0.3%

which is common practice under North American washing conditions, especially in automatic top load washing machines, we have found that quantities of approx. 24% sodium tripolyphosphate and approx. 15% soap gives optimum performance at a phosphorus content of 6%, or as little as 16% sodium tripolyphosphate and as much as 30% soap if a lower phosphorus content of 4% is necessary.

The detergent mixtures according to the invention necessarily contain a quantity of a non-ionic surfactant. Many such detergent active compounds are commercially available and are fully described in the literature, for example in "Surface Active Agents and Detergents", Volumes I and II, by Schwartz, Perry and Berch.

The non-ionic surfactants used in the mixtures according to the present invention are alkoxylated alcohols.

The alcohols can be primary or secondary alcohols containing straight or branched carbon chains. The number of carbon atoms will usually be from approx. 7 to approx. 24, preferably from approx. 8 to 18 and most preferably from approx. 12 to 15. These alcohols can be the so-called synthetic alcohols formed by the well-known Ziegler or Oxo processes, or so-called "natural alcohols".

The alkylation reaction can be carried out by conventional means, usually using ethylene oxide or propylene oxide. The degree of ethoxylation can vary greatly, both from one hydrophobic part to another and even when a single hydrophobic part is used. Thus, ethylene oxide chains containing as little as 1 or more than 20 ethylene oxide units can often be found in nonionic surfactants, and such can be used herein.

The choice of carbon chain length on the hydrophobic alkoxy chain is largely determined by the washing properties required of the molecule. The ratio between the chain length in the hydrophobic part of the molecule and the chain length in the hydrophilic part can be expressed numerically as the hydrophilic/lipophilic balance (HLB).

A simple and easy way to determine HLB is to use the expression HLB= weight percent ethylene oxide

5

Nonionic surfactants suitable for use in heavy-duty washing powders generally have an HLB in the range of 9 to 13, although HLB values outside this range are not excluded.

A further factor in the selection of nonionic surfactant is that alcohols containing both short carbon chain lengths and short ethoxylate chain lengths are relatively low-boiling and can evaporate under the conditions prevailing in a spray drying tower. Consequently, one will not usually choose alcohols that contain less than approx. 8 carbon atoms if their ethoxy chains do not contain at least approx. 8 ethylene oxide units for fear of excessive emission regulations, if it is not proposed to incorporate these materials into the powder in a different way than by spray drying.

Preferred alcohol ethoxylates for use in this invention are derived from the following series.

"Tergitols" which are a series of ethoxylates of secondary alcohols obtained from Union Carbide Corporation, particularly "Tergitol" 15-S-7, 15-S-9, 15-S-12 and 15-S-15, which are ethoxylates of a mixture of C11_15 alcohols, and "Tergitol" 45-S-7, 45-S-9, 45-S-12 and 45-S-15, which are ethoxylates of a mixture of C^- and C^g- alcohols, the degree of ethoxylation being shown in the postscript.

Ethoxylates of primary alcohols formed by the Oxo process and the contents approx. 20% branched material, obtained from Shell Chemicals Ltd. (trade name "Dobanol") and Shell Chemicals Inc.

(trade name "Neodol"), especially "Dobanol" and "Neodol" 25-7, 25-9, 25-12 and 25-15, which are ethoxylates of a mixture of c^2~ C15 alcohols, and "Dobanol" 45-7, 45-9, 25-12 and 25-15, which are

ethoxylates of a mixture of C14_^,_-alcohols..

"Lutensols" are a series of C12_^5-a^co'llols of ethoxylates prepared by the '0X0' process from an olefin formed by the polymerization of ethylene, manufactured by Badische Anilin und Soda Fabrik GmbH, in particular "Lutensol" AO 8 and 12.

"Ukanils" which are a series of ethoxylates of Oxo-alcohols containing approx. 25% with (Y-methyl-branched and approx. 10% with ethyl-branched material.

"Acropol", manufactured by Ugine Kuhlman et Cie, especially "Acropol" 35-7, 35-9 35-11 and 35-15, which originate from a mixture of C^2-C]_5-alk°h0ler •

"Synperonic", a series of ethoxylates of alcohols containing 45-55% of alkyl branching, mostly methyl branching, are available from Imperial Chemical Industries Limited, particularly those based on a C^3_-^ mixture of alcohols and which are ethylated to 7, 9, 11 and 15 ethylene oxide units.

Ethoxylates of primary Ziegler alcohols are sold under the trade name "Alfol" and are derived from the oxidative polymerization of ethylene, and are produced by Conoco-Condea, specifically "Alfol" 12/14-7, 12/14-9, 12/14-12, 12 /14-15 and "Alfol" 14/12-7, 14/12-9, 14/12-12, 14/12-15, which are ethoxylates of mixtures of C^2-C14<-a>alcohols.

Ethoxylates of primary oxo alcohols which are approx. 50% branched, mainly Cx!-methyl, sometimes called "Lial", prepared from olefins and produced by Liquichemica.

The required HLB cannot be achieved simply by choosing the carbon chain length of the hydrophobic part and the length of the ethylene chain in a single or substantially single material (due to the nature of their manufacturing process, all nonionic surfactants referred to as single substances, in reality mixtures). It can also be achieved by deliberately taking two "substances" with vastly different HLB values and mixing them. This method is described in our British Patent Application 16641/76, in Dutch Patent Application No. 7,413,522

and in Dutch Patent Application No. 7,406,003. It is also possible to achieve the required HLB by "stripping" some chain lengths from a nonionic surfactant mixture, as described in patent applications based on U.S. Pat. application 453,464 and U.S. Patent Document No. 3,682,849.

It has been found that non-ionic detersive compounds exhibit good detergency, especially in combination with large amounts of sodium tripolyphosphate, i.e. over approx. 20% by weight, and they are useful in facilitating limescale soap dispersion and inhibiting its deposition on washing machine parts.

Amphoteric or zwitterionic detergent-active compounds can also be used in the mixtures according to the invention, but this is usually not desired, as they are relatively expensive. If any amphoteric or zwitterionic detergent compounds are used, they will usually be present in only small amounts. However, some such zwitterionic or amphoteric compounds, particularly sulfobetaines such as hexadecyldimethylammoniopropanesulfonate, have useful cabbage soap dispersing properties.

The amount of non-soap detergent-active compound or compounds used is usually in the range from approx. 5 to approx. 50% by weight, preferably approx. 7 to approx. 25% by weight, of the mixtures, depending on the desired properties. Some of the soap that is added can also act as a washing-active compound in so-called "overbuilding" circumstances, i.e. at higher product concentrations or when soft water is used, but the soap is not included in the amount of non-soap detergent compound. The ratio of all non-soap detergent compounds to the total amount of sodium tripolyphosphate and soap should generally be in the range of approx. 10:1 to 1:10 parts by weight, especially approx. 3:1 to 1:5 parts by weight.

Apart from the non-soap-containing detergent and washability builders, a laundry powder according to the invention may contain any of the conventional additives in such quantities that such additives are usually used in such mixtures. Examples of these additives include foam enhancers such as alkanolamides, especially the monoethane amides derived from palm kernel fatty acids and coconut fatty acids, powder flow aids such as silicon oxides and aluminum silicates, foam suppressants such as phosphate esters, especially C^2_]^~monoalkyl esters, dirt carriers agents such as sodium carboxymethyl cellulose, oxygen-releasing bleaches such as sodium perborate and sodium percarbonate, penic acid bleach precursors, chlorine-releasing bleaches such as trichloroisocyanuric acid and alkali metal salts of dichloroisocyanuric acid, fabric softeners such as clays of the smectite and illite types, anti-ash - auxiliaries, starches, lime soap dispersants, inorganic salts such as sodium sulfate, larger amounts of which lead to improved powder properties, and usually present in very small amounts, fluorescent agents, perfumes, enzymes such as proteases and amylases, germicides and dyes. In addition, it may be desirable to add slurry stabilizers such as copolyethylene maleic anhydride and copolyvinyl methyl ether maleic anhydride, usually in salt form.

It is also possible in the detergent mixtures according to the invention to include small amounts, e.g. no more than 25% by weight, of other detergency builders, which can be either so-called precipitating builders or sequestering builders. This can be particularly useful where it is desirable to increase the washing ability at the same time as particularly small amounts of sodium tripolyphosphate are used, so that a particularly low phosphorus content is achieved in the detergent mixtures. Examples of such other detergency builders are amine carboxylates

such as sodium nitrile triacetate, sodium carbonate and aluminum silicate builders as described in German Patent Applications Nos. 2,412,837 and 2,422,655. It may also be noted that small amounts of sodium pyrophosphate and sodium orthophosphate are usually formed by the hydrolysis of sodium tripolyphosphate during the spray drying processes to form detergent powders, so there may be small amounts of these other phosphate builders present in the detergent compositions.

It is possible to include in the mixtures an amount of an alkali metal silicate, especially sodium ortho-, -meta- or preferably neutral or alkali silicate. The presence of such alkali metal silicate in amounts of, for example, approx. 5 to approx. 15% by weight is usually beneficial for reducing the corrosion of metal parts in washing machines and also gives advantages in processing and usually improved powder properties. In addition, the amount of silicate can to a certain extent be used to regulate the pH value in the mixtures, as this should usually be within the range from approx. 9 to approx. 11, preferably from approx. 9.5 to approx. 10.5, in aqueous solution of the mixtures at the recommended concentrations. A high pH value, i.e. over approx. 10.5, tends to be more effective in terms of detergency, but may be less desirable in terms of domestic safety.

The mixtures can be prepared by any of

the techniques commonly used in the manufacture of laundry detergent mixtures, particularly included the formation of slurry and spray drying processes for the manufacture of washing powders. However, it has been found that the presence of appreciable amounts of soap in detergent slurries tends to cause problems in

spray drying, especially when producing powders with a low mass density and a high proportion of small particles (fines).

In a further aspect of the invention, it has been found useful to prepare the detergent mixtures by a process comprising the formation of a slurry and spray drying, in which none or only part of the soap, preferably no more than approx. 8% by weight, is added to the slurry, and where all or the rest of the soap is then added afterwards to the spray-dried powder in particulate form, e.g. such as noodles, granules, pellets, ribbons, threads, flakes, smaller balls or jets. The. in this case it may be useful to add less important ingredients, for example perfumes, to the detergent mixtures in the subsequently added soap particles. Such soap particles can be formed by ordinary processes depending on the desired final shape and size, and it is preferred to carefully grind the soap before the particles are formed, as this tends to improve their solubility, and this is especially true of particles with a high tallow soap content .

Alternatively, it is possible to spray-dry two separate slurries, either in the same or in different spray-drying towers, and then mix them to form the final mixture. In this case, preferably one slurry contains all the main ingredients but no more than approx. 8% soap by weight, and the second slurry contains the main amount of soap together with other less significant ingredients. Extracted "spray drying" includes, when used above, processes by which detergent slurries are injected into relatively hot gas, usually air, either by countercurrent or cocurrent processes, or by processes by which warmer slurries are injected into relatively cool air, i.e. by so-called trickle-cooling or flash-drying processes. Conventional temperatures are used in slurry and drying gas in such spray-drying processes for the production of the detergent mixtures according to the invention.

It is further possible to prepare the powders by a method which comprises forming a slurry containing parts of the non-ionic surfactant, spray drying it, and then afterwards adding the rest of the non-ionic surfactant. Such a method is particularly suitable when a mixture of two non-ionic surfactants is used in the composition, since it is then possible to incorporate the component that is least volatile into the slurry, and for example to spray the more volatile component (which will probably be a liquid) into the resulting spray-dried powder. The volatile component can alternatively be incorporated in an additional additive, e.g. in noodles or granules, and then added afterwards to the spray-dried part of the powder. Methods of the general type described above are also described in U.S. Pat. Patents Nos. 3,838,072 and 3,886,098 and in Dutch Patent Applications Nos. 7,504,264 and 7,509,797.

The invention is illustrated by the following examples in which parts and percentages are by weight unless otherwise stated.

EXAMPLE 1

A spray-dried detergent mixture was prepared so that it contained the following composition:

This was then mixed with 45 parts by weight of a separate spray-dried mixture of the following composition:

The resulting compositions were found to be advantageous in washing properties compared to commercially available non-ionic and anionic-based detergent compositions containing 33% sodium tripolyphosphate, respectively.

EXAMPLE 2

The procedure from Example 1 was repeated, except that instead of the 45 parts of soap-based spray-dried mixture, 30 parts of potassium tallow soap in zero form were added to the spray-dried base powder.

EXAMPLE 3

A detergent mixture was prepared which had the following composition: Ingredients %

Condensate of linear c12-15~OXO alcohol - 12 EO 8.0 Sodium tripolyphosphate 31.8 Sodium tallow soap 8.0 Sodium coconut soap 4.0 Hardened sodium rapeseed soap 3.0 Alkaline sodium silicate 6.0 Sodium carboxymethylcellulose 0.8 Water and minor additives ( fluorescent agents, perfume, preservatives, enzymes, stabilizers, etc.) 12.2 Sodium perborate 27.0

100.0

The mixture was prepared by such techniques as slurry formation and spray drying, except that 5% of the non-ionic component, i.e. the condensate of linear 2.5 0X0 alcohol - 12 EO, and the perfume (0.2%) was sprayed onto the powder after spray drying, and the perborate and enzyme granules (0.5%) were dry mixed with the powder. It was found that the detergent composition had good washing properties compared to commercially available detergent compositions with similar phosphate content.

EXAMPLE 4

The procedure from example 3 was repeated with the following modifications.

The condensate of linear C12_15-0X0 alcohol - 12 EO was replaced by an 8 EO condensate of the same alcohol. There was complete absence of non-ionic surfactant in the spray-dried slurry. Half (4% by weight of the final mixture) was sprayed onto the spray-dried powder prepared from the slurry, and the other half was added as an excipient. The additive was formed by mixing the nonionic surfactant with sodium perborate monohydrate.

The resulting powder was equivalent in detergency performance to the powder of Example 3 and had satisfactory powder properties.

EXAMPLE 5

The procedure from example 4 was repeated with the following modifications.

One fourth of the condensate of linear C^2-15"0x0~aik°lloi

- 8 EO (2% by weight of the final mixture) was replaced by the 12 E0 condensate of the same alcohol. This 12 EO condensate was incorporated into the slurry, as in Example 3, and spray-dried with the rest of the components. 2% by weight of the final mixture of the 8 EO condensate was sprayed onto the spray-dried powder, and the remainder was added as an excipient as in Example 4.

EXAMPLE 6

The procedure of Example 3 was repeated except that only 2% (based on the weight of other final components) of the alcohol-ethylene oxide condensate was incorporated into the slurry, while the remaining 6% was formed into an admixture with sodium perborate monohydrate and added to the spray-dried powder, so

as in example 4.

The powders produced in examples 5 and 6 had equivalent performances and properties to the powder produced in example 4.

EXAMPLE 7

EXAMPLE 8

Claims (8)

1. Washing powder for large-scale washing, comprising a non-soap-containing detergent, a water-soluble soap and sodium tripolyphosphate as a detergency builder, characterized in that (a) the non-soap detergent consists essentially of an ethoxylated alcohol non-ionic surfactant present in an amount of from 5 to 50% by weight, (b) the water-soluble soap is present in an amount of 10-30% by weight, and (c) the sodium tripolyphosphate is present in an amount of 10-40% by weight; the rest being conventional components in laundry detergents. 2. Washing powder as stated in claim 1, characterized in that the sodium tripolyphosphate is present in an amount of 15-30% by weight. 3. Washing powder as stated in any of the preceding claims, characterized in that the water-soluble soap is present in an amount of 15-25% by weight. 4. Ash powder as stated in any of the preceding claims, characterized in that the ethoxylated alcohol non-ionic surfactant is present in an amount of 7-25% by weight. 5. Washing powder as set forth in any of the preceding claims, characterized in that the alkylated alcohol non-ionic surfactant is a C,~ alcohol LZ .— XD ethoxylated with 4-25 mol of ethylene oxide per moles of alcohol. 6. Washing powder as stated in claim 5, characterized in that the alkoxylated alcohol non-ionic surfactant is a C,„ ..-alcohol ethoxylated with from 4 to 12 mol 12-15 ethylene oxide per moles of alcohol. 7. Washing powder as stated in claim 6, characterized in that the alkoxylated alcohol-nonionic surfactant consists of a mixture of long-chain and short-chain ethoxylates in which the average degree of ethoxylation is 6-9 mol ethylene oxide per moles of alcohol. 8. Washing powder as set forth in any of the preceding claims, characterized in that the water-soluble soap is a mixture comprising: 45-60% unhardened tallow soap 20-30% coconut oil soap 15-25% hardened rapeseed oil soap.