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Publication numberUS3360470 A
Publication typeGrant
Publication dateDec 26, 1967
Filing dateAug 2, 1966
Priority dateMay 28, 1963
Publication numberUS 3360470 A, US 3360470A, US-A-3360470, US3360470 A, US3360470A
InventorsHarald Eugene Wixon
Original AssigneeColgate Palmolive Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Laundering compositions
US 3360470 A
Abstract  available in
Images(6)
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Claims  available in
Description  (OCR text may contain errors)

- theory of reaction or action;

United States Patent 3,360,470 LAUNDERING COMPOSITIONS Harold Eugene Wixon, New Brunswick, NJ mignor to Colgate-Palmolive Company, New York, N. a corporation of Delaware No Drawing. Filed Aug. 2, 1966, Ser. No. 576,493 11 Claims. (Cl. 252-99) ABSTRACT OF THE DISCLOSURE A composition comprising a quaternary ammonium textile softener tending to yellow textiles and an alkali metal carboxymethyl cellulose as an anti-yellowing agent.

This is a continuation-in-part of application Ser. No. 283,702, filed May 28, 1963, now abandoned.

This invention relates to laundering compositions and more particularly to additives for detergent compositions and as components of such compositions.

In recent years there has been a growing need for softening agents for use in laundering, particularly in automatic washing machines where they are used primarily in a rinse cycle, rather than in the wash cycle. Softening agents are used to render fabrics or textiles soft and the term softening refers to the handle, hand, touch or feel; this is the tactile impression given by textiles to the hand or body and is of aesthetic and commercial importance. Softening realized with such agents varies with a number of factors including: laundry load weight and composition, types of bleach used, detergents used, the initial degree of harshness, type of washing machine, water temperature, etc. To date, therefore, it is generally necessary that a detergent be used in the wash cycle and, thereafter, a fabric softener is used in the rinse cycle. This is an expensive and inconvenient procedure; the use of the softener almost doubles the cost of doing a wash and a waiting period is involved for the launderer.

While softening agents used in the rinse cycle alone have been effective in rendering textiles soft, a problem has arisen because of the wide variety of water supplies containing colored colloidal particles. A number of water supplies in the United States have color values above 5 (Lumetrin colorimeter; cobalt-platinum standard). For example Jersey City, NJ., tap water varies seasonally from about to about in color value. Some well waters have color values of greater than 50. Color imparted to textiles laundered with cationic softening agents has been found to be related to the amount of softening given to the textiles. That is, with highly colored water supplies, laundered textiles have a greater degree of yellowness or yellow color when a substantial and effective amount of softening agent is used herewith.

There is no intent herein to limit this invention to a however, the most probable action is the following. In a system of water, clothes and cationic softener, fabric surfaces tend to be electroncgative and therefore attract a positively charged cationic agent, resulting in deposition of a cationic layer. If the concentration of cationic agent is greater than that needed to balance the fiber charge, a thicker layer accumulates on the fabric by means of adhesion, and a surplus electro-positive charge is produced thereon. This surplus charge then attracts electro-negatively charged colloidal particles in the water. At the same time, the cationic agent dispersed in the water is reducing the zeta potential of the suspended material in the water to zero (or, if enough cationic agent is present, the particles acquire a positive zeta potential). The neutralized particles then agglomerate and are deposited upon the fabric EXAM l NER 3,360,470 Patented Dec. 26, 1967 It has been found, therefore, that the softer the fabric, the yellower it is. This is particularly true in the rinse cycle of automatic laundering.

Since cationic agents are used for softening, it is desirable to find agents compatible therewith in an effort to counter the yellowing phenomenon. This phenomenon has been minimized by using one or more of a group of compounds with the cationic softeners used in the compositions of this invention. Surprisingly, the effective compounds include materials tending to be incompatible with the said softeners.

It is an object of this invention, therefore, to provide compositions containing in combination a cationic softening agent of certain character and an anti-yellowing agent for laundering textiles. It is a further object of the invention to provide such compositions for use in a wash or a rinse cycle of automatic laundering operations, and for use in conventional non-automatic operations. Still another object of the invention is to provide an additive composition to be used in conjunction with a detergent in laundering textiles. Still another object of the invention is to provide softener-detergent compositions. A further object is the provision of laundry compositions having detergent, softening and bleaching capabilities, such that they are total laundry care compositions. Other objects of the invention will become apparent from the following descripition.

Broadly stated, according to the present invention, the foregoing objects are realized with compositions comprising:

(a) A quaternary ammonium salt having two higher alkyl groups and normally tending to soften textile materials and preferably a quaternary ammonium salt represented by the general formula 4 wherein R and R are alkyl groups each containing from 1 to 3 carbon atoms, R and R are aliphatic groups each containing from 12 to 22 carbon atoms, and X is selected from halogen and methyl sulfate; and

(b) An alkali metal carboxymethyl cellulose, said alkali metal being selected from the group consisting of sodium and potassium.

The compositions containing (a) and (b) are preferably used in powder form.

As indicated above, the cationic agents of this invention are represented by the general formula given in connection with (a). These compounds are quaternary ammonium compounds. They are characterized by dispersibility in water. Representative of such compounds are: distearyl dimethyl quaternary ammonium chloride; distearyl dimethyl quaternary ammonium bromide; distearyl dimethyl quaternary ammonium methylsulfate; dicoco dimethyl quaternary ammonium chloride; dimethyl arachidyl, behenyl quaternary ammonium c oride; dialkyl dimethyl quaternary ammonium ghloride the alkyl groups of which comprise a mixture consisting essentially of 24 parts of hexadecyl, parts of octadecyl and 1 part of octadecenyl, the latter ammonium chloride is also known as dihydrogenated ditallow dimethyl ammonium chloride and is particularly preferred herein. It is to be understood that mixtures of two or more cationic agents can be employed if desired.

The term coco refers to fatty acid groups formed in cononut oil fatty acids. Such acids contain from about 8 to about 18 carbon atoms per molecule, predominating in C -C acids.

The alkali metal carboxymethylcellulose generally contains 0.4 to 1.5, and preferably 0.5 to 0.8, carboxymethyl groups per cellulose unit.

An important factor herein is the ratio, by weight, of the cationic agent to the anti-yellowing agent: (a)/ (b). The ratio ranges from about 1.5/1 to about 4/1, with optimum results being obtained with a ratio of about 3/1. For example, when the ratio exceeds about 3/1, excellent softness is retained but yellowness is not materially reduced. At the 3/1 ratio whiteness is apparent or, expressed otherwise, yellowness is significantly reduced with only a slight loss of softness.

hi aem -muemm isns (a) and (5 can be used in the formiofaddltivesior iddition to launderingammpositinmisa ddifinn ageng, "thenithabggdded ither in a wash cycle or in a rlnsecycle,.or in both cyclgwhefde'sired. with respect to rinse cycle application, th'e'nature'of the detergent-activeingredientnsed iniheprecedingwas'h cycle is of little moment.l n spell lieatiomihe said ingredient c ionic, cationic, nQncombiu of the same. However, wen an additive comsi- -tien-of1ltimntion is used in the wash cycle, maximum effectiveness is realized withnou-innie detergents. Substantial quantities of anionic detergents in the wash cycle reduce the efl'ectiveness of the additive composition used in the same cycle.

It is also contemplated that the combination oisoftening agent (a) m'rdanti-ye'lloyizingagent (b) can be used together with adetergent in a softener-detergent composition. In t he latter, a non-ionicdetergent 'is used. And it is to be understood that one or several of such detergents can be used in the compositions.

A wide variety of non-ionic detergents are available in the art and, broadly, all such detergents are contemplated herein. In general, such detergents have a hydrophobic group of at least 8 carbons, preferably 8-30 carbons, and an hydrophilic group attached to confer detersive properties in water. One particular class of such detergents is that formed by oxyalkylation of fatty acids, alcohols, phenols, mercaptans, thiophenols, amines and amides with ethylene oxide, propylene oxide and related oxides. Such materials usually have at least 5 mols of alkylene oxide, preferably 5-30 mols depending upon the particular hydrophobic group. Representative of such materials are those formed by condensation of ethylene oxide and alkyl phenols or alcohols. Particularly preferred herein are condensates formed by reaction of one mol of a nonyl phenol or a mixture of C -C saturated, straightchain, aliphatic alcohols with 8-10 mols of ethylene oxide, the condensates containing an average of about 8-10 ethylene oxide groups per molecule.

In addition to use of a non-ionic detergent in the softener-detergent compositions of this invention, it is also contemplated that a relatively small amount of such a detergent can be used as a dispersing aid with an additive combination of (a) and (b). Generally, from about 5 to about 25% by weight of nonionic is used in this type of combination.

The cationic agent (a) and anti-yellowing agent (b) can also be used in conjunction with materials referred to in the detergent art as builders. These are generally alkali metal salts of weak inorganic acids. However, some strong bases and even neutral salts can be used, and are within the broad category builders. Representative of such materials are: trisodium phosphate; tetrasodium pyrophosphate; sodium acid pyrophosphate; sodium nipolyphosphate; sodium monobasic phosphate; sodium dibasic phosphate; sodium metasilicate; sodium ilicates, Nap/s0, of 1.6/1 to 3.2/1; sodium carbonate; mum sulfate, and borax. The potassium cation can be substitinterbfor the sodium cation where desired and mixtures of the sodium and potassium salts are contemplated.

In addition to the components of compositions contemplated herein and recited above, still other materials can be present in the compositions. For example, brighteners can be present and are typified by stilbene, triazole and benzidine sulfone compositions. Representative of such compositions are: sulfonated substituted triazinyl stilbene, sulfonated naphthotriazole stilbene, benzidine sulfone, etc. Preferred are stilbene and triazole combinations.

Bluing agents such as ultramarine blue can be used herein. This is a well known blue pigment occurring naturally as the mineral lapis lazuli. It can be made, for example, by igniting a mixture of kaolin, sodium carbonate or sulfate, sulfur, and carbon. It is insoluble in water, and is stable when in contact with bleaching agents, alkali and light. Details for synthetic ultramarines are given in the text: Ultramarines, Their History and Characteristics; Reckitts (Colours) Ltd., Hull, England. Preferred are micropulverized, synthetic ultramarine blues, particularly grades RS4-RS8 provided by Reckitts. The proportion of quaternary ammonium salt to ultramarine blue can range from about 10/1 to about 100/1.

The combination of ultramarine blue and alkali metal carboxymethyl cellulose provides an exceptionally fine anti-yellowing effect. This effect appears to be more pronounced than the anti-yellowing effect of either material alone.

Coloring agents and perfumes conventionally used in detergent and toiletry compositions can also be included. It is to be understood that other detergents can be present provided that the amounts are not sufficient to substantially adversely affect the desired properties. As indicated hereinafter in several of the examples, water can also be present in the compositions.

. 'Total laundry care compositions are prepared by combining the softeners (a), anti-yellowing agents (b), and detergents with or without other components described above, and bleaching agents. The iast-mentioned agents are classified broadly, for convenience, as chlorine bleaches and oxygen bleaches. Chlorine bleaches are typified by sodium hypochlorite (NaOCl), potassium dichloroisocyanurate (59% available chlorine), and trichloroisocyanuric acid available chlorine). Oxygen bleaches are represented by sodium and potassium perborates and H te.

The proportions of components which can be present in the final product in percent by weight based on the total weight of the final product are as followsanabout 5% to about 15% and preferably abou 6 .5% to about 12.5%; nonionic detergent-about 5% about 30% and preferably about 7% to about 12%; quaternary ammonium salt-about 2% to about 8% and preferably about 4% to about 6%; alkali metal builder saltsabout 30% to about 87.5% and preferably about 65% to about 85%; and alkali metal carboxymethyl cellulose-about 0.5% to about 5.33% and preferably about 1% to about 3.5%; colorants, perfumes, brighteners and bluing agents-total weight 0% to about 2% and preferably 0% to about 1%; bleaching agent0% to about 10% and preferably 0% to about 5%.

The present invention is more fully described and exemplified in the following examples. Parts and percentages are by weight unless otherwise indicated.

Example 1 Dry blends of a softener (a) and of an anti-yellowing agent (b) were tested in a One-Towel Test. The softener was dimethyl dihydrogenated tallow quaternary ammonium chloride activity) and the anti-yellowing age)nt was sodium carboxymethyl cellulose (74% activity In this One-Towel Test, one Martex brand terry cloth hand towel, size 16 inches by 26 inches, previously washed in .066% concentration of a composition containing 20% sodium dodecylbenzene sulfonate and 80% penta-sodium tripolyphosphate, rinsed and dried, is softened using the following procedure. The previously laundered terry cloth towel is placed in the bottom of a top-loading, agitator-type General Electric automatic washing machine, and 20 gallons of tap water are added at F. The particular softener composition to be tested is then added to the washing machine and the machine agitator is turned on for a ten-minute period. At the end of the ten-minute agitation period, the softening solution is automatically pumped out of the machine while the towel is spun to a damp-dry condition. The towel is subsequently subjected to a two-minute deep rinse in tap water at 80 F. and again spun to a dampdry condition after the rinsing solution has been pumped from the machine. The towel is then line-dried at room temperature and evaluated for softness and yellowness.

The softness of the towel subjected to the foregoing test is reported in terms of values from 1 to 10 based on a tactile rating by an experienced individual. A value of 1 is assigned to a control towel which is subjected to the foregoing test in the absence of a softener composition; whereas, a value of 10 is assigned to the towel treated with softener composition A, and softness ratings of 5 to are considered to be desirable. The higher the number, the greater the degree of softness. whiteness values are determined with a Gardner color difference meter, model No. AC-l, purchased from Gardner Laboratories Inc. at Bethesda, Md., using the +b scale as a measure of the yellow chromaticity. However, higher -|-b values or whiteness numbers indicate a high amount of yellowness and poor results; whereas low +b values or whiteness numbers denote less yellowness or greater whiteness and excellent results. A difl'erence of 0.5 +b unit in the test represents a difference which is visible to the eye.

Results of the tests, illustrating the use of the new additive compositions in a rinse cycle, are set forth in Table I.

TABLE I whiteness Value Grams of Active Material Soitness Run. No. (a)/(b) Rating I Excellent. 1 Poor.

As indicated in the tabulation, ratios of (a)/ (b) from about 1.5/1 to about 4/1 are suitable for effectively minimizing yellowness while retaining good softening properties. In this series of tests, a ratio of 3.2/1 provided maximum whiteness gain while retaining desirable softness.

Example 2 In this illustration, softener granules and detergent granules were prepared independently and were then admixed to form a finished composition of distinctive character.

Parts 6 Detergent granules: Parts Alcohol -ethylene oxide condensate 11 Sodium silicate 3 Sodium carboxymethyl cellulose (dry) 1.6 Brighteners 0.25 Ultramarine blue 0.13 Pentasodium tripolyphosphate 37.9 Sodium sulfate, anhydrous 35.9 Perfume 0.22

Water 10 A mixture of saturated, straight chain aliphatic alcohols with an approximate distribution (weight) of C12 percent 3 Cu d0 37 Cu do 37 C d0 21 C d 2 I) 2 Average of 9 ethylene oxide groups per molecule.

cipally 16 to 60 mesh (US. Standard Sieve).

Detergent 'g'r'anule's'were formed as follows. In the order given, the components were added to a crutcher: water, sodium sulfate, sodium silicate, condensate, ultramarine blue, cellulose compound, brighteners, and phosphate. Initially, the crutcher was operated at 150 r.p.m.; however, before addition of the phosphate, it was operrated at 300 r.p.m. Temperature is of the order of from 500-600 F. (260-316 C.). The resulting granules have a moisture content of about 10 percent. Perfume was then mixed with the granules.- v

'gran'ilesTzblfiparts, were blended with detergent granules, 73.7 parts, in a twin-shell blender. The resulting product is speckled in appearance, predominantly blue with pink randomly distributed therewith. Properties of the product include: cup weight, -120 grams; flowability, 70-80%; particle size, 16-60 mesh.

Since the softener granules and the detergent granules are approximately of the same particle size distribution and flowability, segregation is minimized, and the product is non-caking and free-flowing. Also, since the softener granules are substantially dry, bleeding of the non-ionic detergent and/or of the softening agent upon aging is minimized.

When this product was used in a washing machine, it dispersed rapidly. ,At F. (49 C.), complete solubility occurred within about 1 minute.

Example 3 Tablets of a softener-detergent composition were formed according to the following procedure.

Softener granules: Parts Dimethyl dihydrogenated tallow quaternary 7 Detergent granules: Parts Nonyl phenol-ethylene oxide condensate 1 12 Pentasodium tripolyphosphate 37 Sodium silicate, Na O/SiO =l/2.35, solids 1 Average of 9.5 ethylene oxide groups per molecule.

Softener granules were formed by dry blending the phosphate and cellulose compound in a blender. The cationic agent, non-ionic detergent and color were mixed, heated to dissolve the cationic agent, and the resulting molten mixture was stirred into the dry blend. Granules of softener were formed and were screened to particle size predominantly 16 to 60 mesh.

Detergent granules were formed according to the procedure given in Example 2. Granules so obtained had a moisture content of about percent.

Softener granules, 22 parts, were blended with detergent granules, 65 parts. The blend was then added to a rotary drum wherein it was sprayed with a sodium silicate (Na- O/SiO- =1/2.35) solution, 13 parts. The silicate solution contains 44 percent solids. The resulting mixture was pressed to tablets of 0.75 inch thickness, 2.5 inches diameter. Tablet weight was about 1.5 ounces. The tablets were sprayed with water and dried to improve their strength.

The tablets have excellent strength, disperse and dissolve quickly in use. They have excellent detergent and softening activity.

TOTAL LAUNDRY CARE COMPOSITION Example 4 Compositions having detergent, softening and bleaching capabilities, are illustrated by the following composition.

A softener-detergent combination is formed of:

The bleaching agent was then sealed in a water-soluble polyvinyl alcohol packet, such that the agent comprised 98.3 parts of the sealed packet and the alcohol film comprised 1.7 parts thereof.

The sealed packet was then packed in a polyvinyl alcohol container with the softener-detergent combination. The weight relationships of the finished product were:

Parts Softener-detergent 73.7 Bleach packet 25 Polyvinyl alcohol film 1.3

This product combines the advantageous functions of low sudsing detergent, fabric softener and heavy duty bleach, as well as substantial freedom from the yellowing phenomenon described above.

In a series of home-soiled laundry tests, it was determined that sodium hypochlorite was advantageous in that yellowness was reduced without sacrifice in softness. In contrast, potassium dichloroisocyanurate reduces yellowness, but causes some reduction in softness. However, the latter is advantageous because of its excellent aging stability and its availability in powdered form.

CATIONIC SOPTENER Example 5 This illustrates the effectiveness of cationic softeners used in the compositions of this invention, and the ineffectiveness of other cationic materials.

Using a softener-detergent composition of the character described above as a base, the cationic agent was varied. Approximately the same quantity of such an agent was used in each run given below. The test used was the One-Towel Test. Results are given in Table II, following.

=42 parts of alkyl' dimethyl benzyl q.a.c., 8 parts of dialkyl' methyl benzyl q.a.c., 50 arts oi inert.

'=00% Clv 30 a Cu, u,

Example 6 The softening and whitening properties of a number of softener compositions containing various known soil-suspending agents were evaluated as described herein:

(a) Softener comp0siti0ns.The softener compositions evaluated are listed in Table III:

TABLE III Materials Parts Composition:

A Softener 4 B iii "13 "tH'Viitii i o umcar oxyme ee ose (NaCMC)". y c {Softene m 4 Polyvinyl alcohol (PVA) 2 D ottener 4 Polyvinylpyrrolidone (PVP) 2 Softener 4 E Copolymer of vinyl yrrolidone and vinyl- 2 acetate (PVP/VAR i Dmethyl dihydrogenated tallow quaternary ammonium c On e.

1 Sodium carboxymethyl cellulose containing 74% active material.

Polyvinyl alcohol having a viscosity of 1.8-3 centipoises in 4% aqueous solution and a polyvinyl acetate content within a. range of 10 to 30%.

Polyvinylpyrrolidone having an average molecular weight of agproximately 40 000.

opolymer of vinylpyrrolidone and vinyl acetate having a 60/40 ratio of vinylpyrrolidone to vinyl acetate and an agar-3.58 molecular weight within the range or about 40,000 to The compositions were prepared by admixing the solid ingredients in the stated proportions.

(b) Test pr0cedures.The softening and whitening properties of compositions A through B were evaluated using the One-Towel Test described above.

(c) Test results-The results of the tests are presented in Table IV below. The column percent Reduction in Yellowing is determined by subtracting the +b value for the composition containing an anti-yellowing ingredient from the +b value for composition A and dividing by 9 the difference in +b value between composition A and the control; e.g., based on compositions B Example 7 The softening and whitening properties of a number of softener compositions were evaluated as described herein:

(a) Softener compositions- 111c softener compositions evaluated are listed in Table V:

TABLE V Materials Parts Composition:

1 Dimethyl dihydrogentated tallow quaternary ammonium chloride (Softener A). 4 n {Softener A 4 Sodium carboxymethyleellulose (NaCMC) 2 Softener A 4 NaCMC 2 I11 Condensation product of Cir-Cir alcohol 6 with 9 moles of ethylene oxide (Non- 4 2 40 4 2 6 40 4 VI NaTPP 40 Potassium dichloroisocyanuratc bleach 10 4 {Softener 4 IX i im th 1 2 coco e y uaternary ammonium 4 chloride (Softener B) X Softener B NaCMO--.-...-..- 2.67 XI Dihydrogenated tallow dimethyl quternary ammonium methyl sulfate (Softener C). XII {Softener C NaCMC 2. 67 X111 Dihydrogenatod tallow dimethyl quater- 4 ammonium bromide (Softener D). 4 2 Softener D 4 XV Potasg ilm carboxymethyl cellulose 2 4 2 The compositions were prepared by admixing the solid ingredients in the stated proportions.

(b) Test procedures.The softening and whitening properties of compositions I through XVI were evaluated using the One-Towel Test described above.

(c) Test results-The results of the tests are presented in Tables VI and VII below. The column percent Reduction in Yellowing is determined by substracting the +b value for the composition containing an anti-yellowing ingredient from the +b value for the same composition containing softener alone and dividing by the differ- 10 ence in +b value between the composition containing softener only and the control run in water alone; e.g., based on composition II TABLE VI Softnes Percent Ingredients Rating Reduction in Yellowing Composition:

1.. Softener A 10 II. Softener A plus NaCMC 9 64 III Softener A plus NaCMO 9 58 plus nonionic. IV Softener A lus NaCMC 8 41 plus Na PP. V Softener A plus NeCMC 9 72 lus nonionie plus aTPP. VI Softener A plus NaCMC 0 84 plus noniomc plus aTPP plus bleach.

TABLE VII Softness Percent Ingredients Rating Reduction in Yellowing Com sition:

Fi Softener A l0 Softener A plus NaCMC g 64 9 32 7 8 63 nor D 10 Softener D plus NaCMC-. 9 67 Softener D plus KCMC--. 9 59 Softener A plus KOMC.-- 9 29 The new compositions can be packaged in paper, plastic, or any other suitable packaging medium. For example, an additive composition of a cationic agent (a) and an antiyellowing agent (b) can be packaged in a water-soluble plastic material such as polyvinyl alcohol, for use either in a wash or a rinse cycle, or in both cycles. It has been found that total laundry care compositions containing a bleach are most effective when the bleach is segregated from other ingredients. In this way decomposition is avoided and greater shelf life of a product is realized. Thus, the bleach can be contained in a water-soluble polyvinyl alcohol packet and all other ingredients can be combined in the container which also includes the bleach packet. Another technique contemplated for insuring long shelf life of a total laundry care involves coating of a bleaching agent with a fatty alcohol such as stearyl alcohol; the coated bleaching agent can then be mixed with all other ingredients without necessity for separated compartments in a container.

It is to be understood, in keeping with the illustrations given above, that the additive compositions, etc. of this invention can be in solid form in the character of freefiowing powders, granules, tablets and solution. By the term solids used herein, it is intended to include sizes and shapes of material having at least one dimension of relatively low order, such as grains, chips, flakes and other forms having proportionately large surface areas.

Performance of the compositions of this invention is excellent. Advantages realized therewith include: softer, flufiier towels and diapers-whether dryer-dried or linedried; smoother, silkier sheets and pillow cases; easier-to. iron shirts and sheets reduced static cling on nylon and other synthetics; longer garment life; less wrinkling.

The new compositions can be used to launder a variety of fabrics, which can be made from natural animal fibers, natural vegetable fibers, mineral fibers and synthetic fibers.

11 These include wool, silk, cotton, linen, glass, acetate, rayon, and nylon. The fabrics can be those classified as outer garments, under garments and diapers.

I claim: 1. A composition consisting essentially of (a) a quaternary ammonium textile softener tending to yellow textile materials upon treatment in water containing colored colloidal particles, and represented by the general formula wherein R and R; are alkyl groups each containing from 1 to 3 carbon atoms, R; and R are alkyl groups each containing from 12 to 22 carbon atoms, and X is selected from the group consisting of chlorine, bromine, and methyl sulfate; and

(b) an alkali metal carboxymethyl cellulose wherein the alkali metal is selected from the group consisting of sodium and potassium; the weight ratio of (a)/(b) being from about 1.5/1 to about 4/1 and sufficient to inhibit said yellowing effect.

2. A composition defined by claim 1 wherein R and R are methyl.

3. A composition defined by claim 1 wherein R and R are hydrogenated tallow groups.

4. A composition defined by claim 1 wherein X is chlorine.

5. A composition defined by claim 1 wherein (a) is dimethyl dihydrogenated ditallow quaternary ammonium chloride.

6. A composition defined by claim 1 wherein (b) is sodium carboxymethyl cellulose.

7. A composition defined by claim 1 which contains ultramarine blue, the proportion of (a) to ultramarine blue being about /1 to about 100/1.

8. A detergent composition consisting essentially of:

(a) about 2% to about 8% of a quaternary ammonium salt as defined in claim 1;

(b) about 0.5% to about 5.33% of an alkali metal carboxymethyl cellulose wherein the alkali metal is selected from the group consisting of sodium and potassium, the weight ratio of (a) to (b) being from about 1.5/1 to about 4/ l and sufiicient to inhibit the yellowing effect resulting from the tendency of the quaternary ammonium softener to yellow textile materials upon treatment in water containing colored colloidal particles;

(c) about 5% to about 30% of a water soluble nonionic detergent having a hydrophobic group of 8 to 30 carbon atoms condensed with 5 to 30 mols of ethylene oxide;

((1) about 30% to about 87.5% of at least one alkali metal inorganic builder salt wherein the alkali metal is selected from the group consisting of sodium and potassium; and

(e) about 5% to about 15% of water; wherein said percentages are by weight based on the total weight of the detergent composition.

9. The detergent composition as defined in claim 8 3 wherein the quaternary ammonium salt is present in an "amount of about 4.0% to about 6%; the alkali metal carboxymethyl cellulose is present in an amount of about 1% to about 3.5%; the nonionic detergent is present in an amount of about 7% to about 12%; the alkali metal inorganic builder salt is present in an amount of about to about and water is present in an amount of about 6.5% to about 12.5%.

10. The detergent composition as defined in claim 8 wherein a bleaching agent selected from the group consisting of chlorine bleaches and oxygen bleaches is present in an amount of 0% to about 10%.

11. The detergent composition as defined in claim 10 wherein the bleaching agent is present in an amount of no more than 5%.

References Cited UNITED STATES PATENTS 2,708,157 5/1955 Houser 252109 X 2,995,523 8/1961 Germann 252137 3,033,704 5/1962 Sherrill et a1. 252-106 X 3,044,962 7/1962 Brunt et a1. 252-106 X 3,058,916 10/1962 Sinner et a1. 252--99 3,122,502 2/1964 Waldman et a1. 252--8.8 3,186,869 6/1965 Friedman 252 X 3,213,028 40/1965 Wood 252-152 X LEON D. ROSDOL, Primary Examiner.

A. T. MYERS, M. WEIZNBLATT, Assistant Examiners.

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Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3454494 *Aug 3, 1965Jul 8, 1969Standard Chem Products IncTextile softener compositions
US3505221 *Jun 9, 1967Apr 7, 1970Armour Ind Chem CoFabric softener
US3537993 *Jun 21, 1966Nov 3, 1970Procter & GambleDetergent compositions
US3546115 *Feb 28, 1967Dec 8, 1970Cargill IncFabric softener
US3609075 *Jun 25, 1968Sep 28, 1971Procter & GambleCleaning and softening detergent compositions
US3644203 *Dec 9, 1968Feb 22, 1972Lever Brothers LtdFabric softener
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US3959157 *Jun 4, 1973May 25, 1976Colgate-Palmolive CompanyNon-phosphate detergent-softening compositions
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Classifications
U.S. Classification510/308, 510/331, 510/298, 510/443, 510/515, 510/277, 510/501, 510/444, 510/324
International ClassificationD06M13/463, C11D3/42, C11D3/37, C11D3/395, C11D17/00, C11D3/00, C11D3/39, C11D1/62
Cooperative ClassificationC11D3/3757, C11D3/3953, C11D3/001, C11D3/42, C11D3/3958, C11D3/3942, C11D3/3955, D06M13/463, C11D1/62, C11D17/0086
European ClassificationC11D3/395J, D06M13/463, C11D3/00B3, C11D17/00H8T6, C11D3/42, C11D3/37C6, C11D3/395F, C11D3/395D, C11D1/62, C11D3/39D