Abstract:
A thickened cleaning composition for laundry products incorporates low levels of a fluorescent whitening agent or dye, a surfactant, an acidic pH adjusting agent and an insoluble peracid precursor. At the acidic pH, the fluorescent whitening agent precipitates as a colloidal particle, and is stabilized by associating with the surfactant, resulting in thickening. The precursor is stably suspended in its inactive form in the thickener, and provides oxidizing power as the corresponding peracid is formed when added to an alkaline wash or rinse solution. The composition preferably is formulated with an acidic soluble bleach source and most preferably with a peroxygen bleach.

Description:
This is a continuation-in-part of co-pending Ser. No. 928,281, filed on 10/21/86, now U.S. Pat. No. 4,764,302, and a continuation-in-part of Ser. No. 838,148, filed on 3/10/86, now U.S. Pat. No. 4,772,290. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to a thickened laundry composition comprising a surfactant, a fluorescent whitening agent or dye, a pH adjusting agent and a peracid precursor, and more particularly to a liquid laundry composition, thickened with such a system, and having a peracid precursor stably suspended therein. 
     2. Description of the Relevant Art 
     Much prior art has addressed the development of thickened household laundry products such as detergents or bleaches. Consumer preference for such thickened products is well documented, and applications include prewash products or hard surface cleaners which require concentrating the active ingredients and/or the capability to cling to surfaces. Typical thickeners of the prior art include surfactants, polymers, or combinations of polymers and surfactants. Various disadvantages are associated with such prior art thickening systems. To the extent that a thickened laundry product requires the addition of components solely for thickening, the cost of the product is increased. Many prior art thickeners are incompatible with oxidizing species, e.g., bleaches. 
     Liquid bleaches have been known and used in a variety of household applications for a great many years. 
     Chlorine bleaches are used extensively since they are highly effective, inexpensive, and simple to produce. In certain applications, however, non-chlorine, e.g. peroxygen or peracid bleaches are preferred. For maximum effect, non-chlorine bleaches should contain surfactants for detergency, fluorescent whiteners or optical brighteners to increase fabric reflectance, and dyes for producing a pleasing color. 
     Prior art efforts to develop peroxide laundry products include compositions described in U.S. Pat. No. 4,430,236 issued to Franks, which describes peroxide combined with a detergent-effective amount of a nonionic surfactant, and a fluorescent whitening agent. Franks also discloses the use of a chelating agent in an effort to stabilize the hydrogen peroxide bleach, and the use of a solvent to reduce the viscosity of the composition. U.S. Pat. No. 4,448,705 issued to Grey describes a peroxy bleach with a chelating agent, a bleach activator such as a polyacylated amine, anionic, nonionic, zwitterionic, or cationic surfactants, and may include optical brighteners. Barrett, Jr. U.S. Pat. No. 3,970,575 describes a peroxide bleach with a nonionic surfactant and phthalocyanine blue dye. Krezanoski, U.S. Pat. No. 3,852,210 describes a peroxygen-containing concentrate formulated with a polyoxypropylene copolymer, a betaine surfactant, and an acid or base to adjust the pH. The formulation may also include a chelating agent, and is primarily intended for germicidal use, although fabric bleaching is mentioned. U.S. Pat. No. 4,347,149 issued to Smith et al describes a detergent composition of hydrogen peroxide, ethanol plus amino compounds as stabilizers, phosphonate compounds, and anionic, nonionic, or amphoteric surfactants. U.S. Pat. No. 4,525,291 also issued to Smith et al describes peroxide-containing compounds including a builder, anionic or nonionic surfactants and alkyl metal aryl hydrotropes for phase stability, and can include optical brighteners. Goffinet et al, U.S. Pat. No. 4,470,919 discloses a hydrogen peroxide bleach composition incorporating a surfactant and a fatty acid. Lutz et al, U.S. Pat. No. 4,130,501 describes a viscous peroxide bleach containing from 0.5 to 4% of an anionic or nonionic surfactant and thickened with a copolymer of carboxylic acid with a polyol. No optical brighteners are included in the formulations of Lutz et al. Chung et al, U.S. Pat. No. 4,412,934, apparently describes a dry bleaching composition containing peracid activators and a source of hydrogen peroxide in a specified molar ratio. U.S. Pat. No. 4,526,700 issued to Hensley et al discloses an unthickened formulation having a fluorescent whitening agent of the stilbene type formed into fibrous particles by coprecipitating the whitener with a sulfonate surfactant in aqueous hypochlorite at a basic pH. Neiditch et al, U.S. Pat. Nos. 4,497,718, and 4,562,002 describe a viscous fabric softening composition containing a cationic surfactant, a stilbene fluorescent whitening agent and a non-ionizable base. Robinson et al, U.S. Pat. No. 3,655,566 describes a nonthickened bleaching composition including fluorescent whitening agents and anionic or nonionic surfactants, and having a pH above about 10. Claussen et al, U.S. Pat. No. 3,767,587 shows a nonthickened aqueous dispersion of fluorescent whitening agents and anionic, cationic or amphoteric surfactants. Eckhardt et al, U.S. Pat. No. 4,311,605 discloses an unthickened laundry composition including fluorescent whitening agents and surfactants. Thompson, U.S. Pat. No. 4,216,111 shows a colloidal suspension of high levels of fluorescent whitening agent by flocculating the fluorescent whitening agent with an acid, then deflocculating by basification. Becker, U.S. Pat. No. 4,265,631 describes a stable aqueous suspension of high levels of fluorescent whitening agent or dye with an aminoplast precondensate and a nonionic copolymer. Clark et al, U.S. Pat. Nos. 3,904,544 and 3,912,115 are exemplary of art teaching thickened suspensions of fluorescent whitening agents. These references both teach preparation of a thixotropic slurry containing high levels of a fluorescent whitening agent with a surfactant. Thickening appears to occur due to the high solids content. 
     Generally, the art showing thickened compositions including fluorescent whitening agents teaches thickening by a high solids (fluorescent whitening agent) content, or by including additional components, e.g., polymers, to achieve the thickening. Aqueous suspensions of fluorescent whitening agents of the art are generally not at acidic pHs. 
     SUMMARY OF THE PRESENT INVENTION 
     It is therefore an object of the present invention to provide a stable thickening system incorporating low levels of a fluorescent whitening agent as part of the thickening system. 
     It is another object of the present invention to provide a stable, thickened bleach composition containing a fluorescent whitening agent. 
     It is yet another object of the invention to provide a composition which can be formulated to be sufficiently thick to be used as a hard surface cleaner, or to suspend abrasives. 
     It is another object of the present invention to provide a viscous formulation of fluorescent whitening agents. 
     It is another object of the present invention to provide a thickened peroxygen bleaching composition in which insoluble bleach activators may be stably suspended for storage. 
     It is another object of the present invention to provide a stable, thickened peroxygen bleach composition incorporating surfactants, and fluorescent whitening agents for a commercially acceptable product. 
     Briefly, in one embodiment the present invention comprises the essential components of, in aqueous solution: 
     a surfactant; 
     a fluorescent whitening agent; 
     a pH adjusting agent to adjust the composition pH to about two to six; and 
     an insoluble peracid precursor. 
     Optionally, a C 6-18  soap can be included to synergistically increase viscosity. 
     The thickened composition can be formulated as a high viscosity gel or paste, and typically, will be an intermediate viscosity (200-500 centipoise) for products such as hard surface cleaners which need sufficient residence time for use on nonhorizontal surfaces. More typically, the composition may be formulated to have a viscosity on the order of 100-300 centipoise (cP) for use with a laundry product to enhance pourability and allow concentration of the product on heavily stained areas of fabric. 
     In a second embodiment, the present invention is formulated as a thickened bleaching product and includes the essential components of, in aqueous solution: 
     a bleach; 
     a bleach activator; and 
     the thickening system comprising the surfactant, the fluorescent whitening agent and the pH adjusting agent. 
     A formulation of the second embodiment includes an oxidant bleach, and the thickening system comprising the fluorescent whitening agent, surfactant and optionally, the C 6-18  soap. The bleach would preferably be a peroxygen or peracid bleach, although virtually any oxidant compatible with an acidic composition could be used. The formulation would have utility as a bleach with improved pourability, or as a prewash. 
     In a third embodiment, the invention is formulated as a stable, thickened hydrogen peroxide bleaching product and includes the essential components of, in aqueous solution: 
     a hydrogen peroxide bleach; 
     a bleach activator; 
     a stabilizing system comprising a chelating agent and an antioxidant; 
     the thickening system comprising the surfactant, fluorescent whitening agent, and the pH adjusting agent. 
     The thickened peroxide bleach is advantageously formulated as a consumer acceptable product, thus a stabilizing system is present to ensure shelf and storage longevity, a whitener is included to increase fabric reflectance and the user&#39;s perception of brightness, a bleach activator is present to increase bleaching action, a dye may be present to produce a pleasing color and the ternary thickening system provides a viscous solution. The fluorescent whitening agent functions as one component of the thickening system, reducing the total level of organic components needed. Optionally, the C 6-18  soap may be included to enhance viscosity. 
     It is therefore an advantage of the present invention that a viscous stable composition of a fluorescent whitening agent is provided. 
     It is another advantage of the present invention that a cleaning product can be formulated to achieve a viscosity sufficient to enable its use as a hard surface cleaner with efficacy on nonhorizontal surfaces, or to suspend abrasives therein. 
     It is a further advantage of the present invention to provide a thickening system for laundry products with low levels of a fluorescent whitening agent wherein the whitening agent is one component of the thickening system. 
     It is a further advantage of the present invention that a consumer acceptable, stabilized, thickened peroxide bleach composition can be formulated. 
     It is yet another advantage of the present invention to provide a thickened peroxide bleaching composition which remains stable throughout a typical storage life. 
     It is another advantage of the present invention that bleach activators may be stably suspended in the composition, thus minimizing interactions between the activators and the peroxygen compounds during storage. 
     These and other objects and advantages of the present invention will become apparent from a review of the following Detailed Description of the Preferred Embodiment. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     In a first embodiment, the composition of the present invention comprises the essential ingredients of, in aqueous solution: 
     a surfactant 
     a pH adjusting agent; 
     a fluorescent whitening agent; and 
     a bleach activator. 
     The above ingredients will be described in greater detail in the following sections. 
     Surfactant 
     The surfactant functions as one component of the thickening system, also including the pH adjusting agent and fluorescent whitening agent. In addition to thickening, the surfactant advantageously also performs its normal soil removal function. The thickening effect of the surfactant and the fluorescent whitening agent is thought to be due to stabilization of a colloid of the fluorescent whitening agent by the surfactant. The surfactant must be compatible with an acidic pH and, in embodiments of the invention incorporating a bleach, must be resistant to oxidation by the bleach. The most preferred surfactants are the nonionics, for example, polyethoxylated alcohols, ethoxylated akyl phenols, anhydrosorbitol, and alkoxylated anhydrosorbitol esters. An example of a preferred nonionic surfactant is a polyethoxylated alcohol manufactured and marketed by the Shell Chemical Company under the trademark &#34;Neodol&#34;. Examples of preferred Neodols are Neodol 25-7 which is a mixture of 12 to 15 carbon chain length alcohols with about 7 ethylene oxide groups per molecule; Neodol 23-65, a C 12-13  mixture with about 6.5 moles of ethylene oxide; Neodol 25-9, a C 12-15  mixture with about 9 moles of ethylene oxide; and Neodol 45-7, a C 14-15  mixture with about seven moles of ethylene oxide. 
     Other nonionic surfactants useful in the present invention include a trimethyl nonyl polyethylene glycol ether, manufactured and marketed by Union Carbide Corporation under the Trademark Tergitol TMN-6, and an octyl phenoxy polyethoxy ethanol sold by Rohm and Haas under the Trademark Triton X-114. Brij 76 and Brij 97, trademarked products of Atlas Chemical Co., also thicken. The Brij products are polyoxyethylene alcohols, with Brij 76 being a stearyl alcohol with 10 moles of ethylene oxide per molecule and Brij 97 being an oleyl alcohol with 10 moles of ethylene oxide per molecule. While the exact nature of the thickening-effective association of surfactant with fluorescent whitening agent is not fully understood, it has been empirically determined that thickening-effective nonionic surfactants have a hydrophobic -lipophobic balance (HLB) of between about 11-13. 
     Certain amphoteric surfactants will thicken, most notably betaines and in particular a lauryl/myristyl amido propyl betaine sold by Miranol Chemical Company Inc. under the trademark Mirataine BB. 
     Limited anionics, principally alkyl aryl sulfonates, and in particular Calsoft F-90, a trademarked product of Pilot Chemical Co. will thicken in combination with the fluorescent whitening agents of the invention. 
     The surfactant is present in the composition in an amount sufficient to stabilize the fluorescent whitening agent, generally about 1 to 20% by weight, more preferred is 1 to 10% by weight, and the most preferred range is about 2 to 5%. Because of co-surfactant thickening effects, high levels of surfactants, e.g. above 30%, tend to increase solution viscosity regardless of the fluorescent whitening agent concentration. It is within the scope of the invention to use mixtures of any of the above surfactants. 
     pH Adjusting Agent 
     It is essential that the pH range of the composition be compatible with the pH range of insolubility of the fluorescent whitening agents. Because acid-insoluble fluorescent whitening agents are used, the composition pH must also be acidic in order to maintain the fluorescent whitening agents in an undissolved state. Preferably, the pH adjusting agent is added in an amount sufficient to adjust the pH range to between about 2 and 6, and more preferably to between about 3 and 5. Resulting composition viscosities vary slightly depending on the type of acid used, and the final pH. 
     The composition of the present invention is an aqueous colloidal mixture having a high percentage of water. In the absence of the pH adjusting agent, the pH will normally be in a neutral to slightly basic range. It is to be understood that any agent added to the composition which results in the insolubilizing, thickening-effective pH is considered to be a pH adjusting agent even if pH adjustment is not its sole or primary function. Further, order of addition of other composition ingredients relative to the pH adjusting agent is not critical, although it is preferred to have the surfactant present when the fluorescent whitening agents are precipitated by the pH adjusting agent. For this reason, it is preferred that the pH adjusting agent be added to a mixture of the desired composition ingredients, i.e., surfactant and fluorescent whitening agent plus any optional components. Inorganic acids such as sulfuric acid (H 2  SO 4 ), phosphoric acid (H 3  PO 4 ), and hydrochloric acid (HCl) are preferred for pH adjustment. Organic acids, such as acetic acid, will also function. It is noted that depending on the composition, the addition of a separate acid may not be necessary to adjust the pH to the correct level. Many chelating agents are acidic and compositions utilizing such chelating agents may not need further added acid. 
     Fluorescent Whitening Agent 
     A fluorescent whitening agent (FWA), also referred to as an optical brightener, is an essential component of the thickening system of the invention, and associates with the surfactant to achieve the thickening. Such products are fluorescent materials, often substituted stilbenes and biphenyls, and have the ability to fluoresce by absorbing ultraviolet wave-lengths of light and re-emitting visible light. A preferred fluorescent whitening agent is sold by the Ciba Geigy Corporation under the tradename &#34;Tinopal&#34;, which are substituted stilbene 2,2&#39;-disulfonic acid products. Preferred Tinopal products are Tinopal 5BM-XC, a 4,4&#39;-Bis[[4-anilino-6 [N-2-hydroxyethyl-N-methylamino]-1,3,5-triazin-2-yl]amino]- 2,2&#39;-stilbene disulfonic acid disodium salt; Tinopal UNPA, a 4,4&#39;-Bis[[4-anilino-6-[Bis(2-hydroxyethyl)amino]-1,3,5-triazin-2-yl]amino]-2,2&#39;-stilbene disulfonic acid; and Tinopal AMS, a 4,4&#39;-Bis[(4-anilino-6-morpholino-1,3,5-triazin-2-yl)amino]-2,2&#39;-stilbene disulfonic acid. The fluorescent whitening agent is present in an amount necessary to thicken to the desired viscosity. Typically the amount of fluorescent whitening agent is from about 0.1 to about 10% by weight. More preferred is about 0.1-5% by weight, and most preferred is about 0.2-0.5%. Also suitable as fluorescent whitening agents are stilbene-type FWAs sold commercially by Mobay Chemical Corp. under the trademarks Phorwite RKH and Phorwite HRS. 
     Generally, thickening-effective FWAs comprise those having a molecular weight of between about 500-1500 grams/mole, a potential for a zwitterionic charge distribution (i.e., both positive and negative charge on the same molecule), are insoluble at a pH of below about seven and which will precipitate as a colloidal-sized particle. More preferably the FWA should have a molecular weight of between about 700-1000 grams/mole, a zwitterionic charge distribution wherein equal numbers of positive and negative charges are developed, should precipitate as a colloidal particle of under about 10 microns in size and should also be soluble at a basic pH. Most preferred as FWA are those possessing the stilbene structure, with the potential for a negative charge supplied by sulfonic acid groups, and the potential for a positive charge supplied by protonated amine groups. 
     An example of a class of thickening effective FWAs are those which fall within the American Society for Testing Materials (ASTM) class &#34;DASC&#34; (diamino stilbene disulfonic acid-cyanuric chloride) including DASC subclasses 1 through 5. Examples of DASC FWAs are published in ASTM&#39;s List of Fluorescent Whitening Agents for the Soap and Detergent Industry, ASTM Data Series DS53A, the disclosure of which is incorporated herein by reference. DASC whiteners all possess the 2,2&#39;-stilbene disulfonic acid structure illustrated by the following figure: ##STR1## Specific examples of DASC whiteners, include Ciba Geigy&#39;s trademarked Tinopal UNPA, UNPS, AMS, 4BM and 5BM, as well as 
     Mobay Chemicals&#39; trademarked Phorwite BBH, RKH, HRS and MBBH. For the purposes of the present invention, &#34;fluorescent whitening agent&#34; (FWA) is deemed to include dyes having structure and/or physical characteristics similar to the thickening-effective fluorescent whitening agent&#39;s and which are also thickening effective. Such dyes should also be insoluble at acidic pHs, have a potential for zwitterionic charge distribution, a molecular weight range of between about 500-1500 grams/mole and precipitate as colloidal particles. A preferred class of dyes fitting the above general description of thickening-effective FWAs are the substituted biphenyl diazo dyes. A preferred example of this type of dye is a 3,3&#39;-[[biphenyl]-4,4&#39;-diylbis-(azo)]bis[4-amino-1-naphthalene-sulfonic acid]disodium salt, sold commercially as Congo Red. Mixtures of any of the above FWAs can also be employed. 
     In order for the fluorescent whitening agent, in association with the surfactant, to thicken, it is necessary that the fluorescent whitening agent be precipitated out as a colloid. This is accomplished by formulating the thickening system with a low pH, on the order of 2-6 and preferably 3-5. The thickening system advantageously does not consume or remove the fluorescent whitening agents in achieving the thickening. The fluorescent whitening agents are thus fully available to perform their nominal function, e.g., whitening. It is also within the scope of the invention to mill FWA particles down to a size range of about 10 microns and add the milled particles to a preacidified surfactant mixture to attain the desired thickening effective colloidal association. 
     Table 1 illustrates viscosities resulting from formulations using four structurally different Tinopals: 5BM-XC, RBS 200, CBS-X and SWN. The remainder of the formulations included the following: 
     
         ______________________________________           Wt. %______________________________________Surfactant        4.0Antioxidant       .01Fragrance         .01Base              .18Fatty Acid Soap   .45Chelating Agent   .12Bleach            10.00Distilled Water   BalancepH Adjusting Agent             to pH 4.0______________________________________ 
    
     
                       TABLE 1______________________________________A. Viscosity - Brookfield RVT, Spindle #1, 4 speeds5BM-XC.45%        RBS 200 .26%                   CBS-X .22% SWN .12%______________________________________10 rpm 302      22           5       1020 rpm 189      24           8       1550 rpm 110      34          10       23100 rpm   87      48          14       31______________________________________ 
    
     Only Tinopal 5BM-XC is a DASC type FWA and it can be seen from the resulting viscosities that only the 5BM-XC resulted in significant thickening. The Tinopal RBS, CBS-X and SWN products are not DASC fluorescent whitening agents, and proved to be ineffective at thickening. 
     Bleach Activator 
     A useful addition to the thickened peroxygen bleaching compositions disclosed herein are insoluble bleach activators, especially peracid activators, also known as peracid precursors. The activators employed in the bleaching compositions of the invention may be characterized as being insoluble at pHs of about 7 or less used for storage (neutral or acidic pH&#39;s) and also being about 10-1000 times, preferably 50-1000 times, most preferably 100-1000 times as soluble at pHs of greater than about 7 (alkaline pHs) used in bleaching. Activators which can exhibit this pH-dependent solubility are activators containing weakly acidic groups such as free carboxylic acid groups, sulfonamide groups, thiocarboxylic acid groups, aromatic hydroxyls, aromatic thiols, aromatic anhydrides, cyclic amide groups, and phosphite groups as solubilizers. At acidic pHs such groups are not ionized and contribute to insolubility. At basic pHs these groups become increasingly ionized and solubilize the activator. These groups appear to be uniquely suited as solubilizers in this setting. Sulfonate or phosphonate groups are not acceptable because they are extensively ionized, and lead to extensive activator solubilization at the acidic pH&#39;s where nonionization and insolubilization are sought. Quaternary ammonium groups are inappropriate as well as they will tend to form ion pairs with anions present in the wash mixture. Thus, the activators employed herein can be classified as containing ionizable solubilizing groups that are substantially unionized at conditions of storage and substantially ionized at conditions of use, and contain no sulfonate, phosphonate or quaternary ammonium groups. Representative suitable solubilizing groups are aromatic and aliphatic carboxylic acids and thioacids and their alkali metal and alkaline earth metal salts, as well as aromatic alcohols and aromatic thiols, aromatic anhydrides, maleimides and sulfonamides. 
     The peracid precursors used herein may be represented structurally as: ##STR2## That is, they contain a carbonyl group attached to a leaving group &#34;LG&#34; which is displaced when the peracid forms and an &#34;R 1  &#34; group which is an organic residue of 1 to 20 carbon atoms. The weakly acidic solubilizer group or groups &#34;SG&#34; can be attached to either the R 1  or the LG portion of the molecule. 
     The SG group may be selected from groups such as an aromatic --COOM, a --CSOH, an aromatic --OH, an aromatic --SH, or following structures (a), (b) or (c): ##STR3## In these typical SG group structures, R 2  is an organic linking or bridging group typically having less than about 8 carbon atoms. Representative R 2  groups are alkylenes of from 1 to about 4 carbon atoms, and 6 to 8 carbon arylenes and alkarylenes, such as methylene, ethylene, propylene, butylene, phenylene, phenylenemethylene, and the like. Also in these structures, M is hydrogen, an alkali metal ion or an alkaline earth metal ion such as sodium, potassium, calcium or magnesium. When aromatic groups are present in the SG groups, they can be substituted with alkyls of from 1 to 6 carbon atoms, halogens, e.g., chloros or bromos, acyls of 1 to 4 carbon atoms, other aryls of up to 6 carbon atoms, either pendent or fused, or alkoxies of from 1 to 6 carbon atoms, if desired. Multiple substitution is possible, as well, if desired. 
     R 1 , the C 1-20  organic residue, can be a hydrocarbon such as a branched or straight chain alkyl or alkenyl, an aryl, an alkaryl or the like, or a substituted hydrocarbon such as an ether or an amine. Typically, R 1  may be selected from alkyls and alkenyls of from 1 to about 20 carbon atoms, aryls and aralkyls of from about 6 to 12 carbon atoms, ethers of from about 4 to 8 carbon atoms with 1 to 3 oxygen atoms, and alkyl amines of from about 3 to 8 carbon atoms and 1 amine nitrogen atom. An SG group can be attached to this R 1  group, if desired. 
     LG, the leaving group, is generally an aromatic moiety, in particular, often an aryloxy group of from about 6 to about 12 carbon atoms. Representative LG groups include structures (d) and (e): ##STR4## (wherein n equals from 1 to about 4) and the like. In such LG groups, the aromatic ring may be substituted with one or more SG groups and/or with one or more alkyl, halogen, acyl, aryl, or alkoxy groups, if desired. 
     The activators used in accord with this invention will always include at least one SG group. It is possible for them to contain more than one SG group, for example two, three or four such groups so long as the activators have the required solubility properties. If two or more SG groups are present, they can be the same or different and located in the same region of the activator or in different regions. 
     Typical activators which would be useful herein because of their insolubility in storage and solubility in use are as shown in structures (f), (g), (h), (i), and (j): ##STR5## wherein X is hydrogen, C 1-4  alkyl, acyl, or alkoxy, an aryl of about 6 carbon atoms, or a chloro, bromo or iodo; n is 1 to 20; and SG is as defined above; ##STR6## wherein n is 1 to 20, m is 1, 2 or 3, R 1  and R 2  each are H or C z  H 2z+1 , and z is 1 to 20 and SG is an defined above; ##STR7## wherein n and z are each 1 to 20, m is 1, 2 or 3, and SG is as defined above; ##STR8## wherein n is 1 to 20, and SG&#39; is a COOM or a COSH, m is 1, 2 or 3; and ##STR9## wherein n is 1 to 20, and m is 1, 2 or 3. 
     One preferred group of activators can be described structurally as having the formula: ##STR10## wherein R is an alkyl of 1 to 12 carbon atoms and R&#39; is an arylene group of 6 carbon atoms, optionally with an &#34;X&#34; substituent as above described, which will exert an electron withdrawing effect in the central: ##STR11## group to promote substitution by perhydroxyl ions (OOH - ). M is hydrogen, an alkali metal ion, or an alkaline earth metal ion--usually either K +  or Na + . (If M is a metal ion, when the activator is placed in an acidic medium, the metal ion will immediately be substantially replaced by hydrogen.) Such an activator can undergo the following reactions in pH 7 or greater aqueous media: ##STR12## Preferred R groups have from 3 to 10 carbon atoms, more preferred is 5 to 9 carbon atoms, and normal C 7  alkyls being the most preferred. R&#39; can preferably be selected from 6 to 10 carbon atom arylenes which optionally contain up to two alkyl substituents totalling up to 8 carbon atoms. Phenylene is the most preferred R&#39; group in this class of activator. 
     Taking the above-defined preferences into account one can define a more preferred group of activators as having the following formula (k): ##STR13## wherein n is an integer from 2 to 8, especially 4 to 8 and more preferably about 6, and M is hydrogen, Na +  or K + . The COOM group can be at various positions on the aromatic ring, with the position para to the --O-- link being preferred. 
     The above described activators can be produced by methods known in the art. One generally applicable process for forming the: ##STR14## activators involves first, forming an anhydride of the formula: ##STR15## by condensing two molecules of: ##STR16## acid in the presence of excess acetic anhydride under dehydration conditions, and then, reacting the anhydride so formed with a hydroxy-substituted acid of the formula: 
     
         HO--R&#39;--COOM 
    
     generally in the presence of strong acid. An alternative process proceeds through acid chlorides. Other synthetic processes can be found in published European Application No. 105,673 dated 4/18/84 (Hardy et al.); Kirk-Othmer Encyclopedia of Chemical Technology, 3d. Ed., Vol. 22, p 348; and Rabjohn, Organic Syntheses, Vol. 4, pp 635-38 (1963). The activators can be recovered as solids and are used as particulate solids in the compositions of this invention. They are generally ground or otherwise divided to a size of about 140 mesh or smaller, preferably to a size of 500 microns or less to facilitate their dispersal and suspension in the bleach composition. 
     The solid activator is added in amounts of from about 0.1 to about 10.0 moles per mole of hydrogen peroxide. Since the activator is more expensive than hydrogen peroxide it is preferred for economic reasons not to use large excesses of activator so that amounts of from 0.2 to 2 moles of activator per mole of hydrogen peroxide, and especially 0.3 to 1 mole of activator per mole of hydrogen peroxide are preferred. 
     A particularly preferred bleach activator for the thickened peroxygen bleaching compositions herein is a p-(n-octanoyloxy) benzoic acid (OBA) having the following structure (1): ##STR17## To ensure stable suspension of the precursor, it should have a particle size range on the order of about 0.01-100 microns, most preferably 0.01-10 microns. This can be accomplished by any means known in the art such as mechanical means including milling or grinding. When placed in an alkaline wash (or rinse) medium, the peracid precursor becomes soluble, and forms its corresponding peracid. 
     Soap 
     While significant thickening occurs with only the surfactant and fluorescent whitening agent, it has been found that viscosities can be synergistically increased by the inclusion of a fatty acid or esterfied fatty acid soap. Generally C 6-18  soaps provide the synergistic increase in thickening. Preferred are saturated, alkyl C 6-18  soaps, although varying degrees of unsaturation, branching, or esterification will not eliminate the viscosity enhancing effects of the soap. Most preferred are capric acid, lauric acid, myristic acid, and coconut fatty acid (having a chain length distribution of ten to eighteen carbons, and about 55% C 12 ) soaps, as well as methyl laurate, or mixtures of any of the foregoing. Because the solubility of the acid form is generally not very good, it is preferred to neutralize the fatty acid soap in situ using a base such as an alkaline-earth-metal or alkali-metal hydroxide. KOH and NaOH are the most preferred bases. Of course, addition of the salt form of the soap also gives acceptable results. A preferred amount of soap is that sufficient to improve viscosity, and typically is about 0.05 to 5.0 weight %, more preferred is 0.1 to 1.0 weight % and most preferred is 0.3 to 0.5 weight percent. When soap is incorporated into the composition of the invention, it is preferred to make an aqueous solution of the desired surfactant, add thereto an amount of base, most preferably NaOH, calculated to neutralize the amount of fatty acid to be added, then add the fatty acid. The FWA is added to this solution and the pH is adjusted to precipitate the FWA. Addition of the peracid precursor is typically the final step. 
     In a second embodiment the present invention is formulated as a thickened bleaching composition and includes, in aqueous solution: 
     a bleach; 
     a bleach activator; and 
     the thickening system comprising the surfactant, fluorescent whitening agent and pH adjusting agent. 
     The thickening system and bleach activator are as described in the first embodiment of the invention. The remaining component, e.g., the bleach is further described below. 
     Bleach 
     A bleach source may be selected from various types of bleaches such as halogen, peroxygen and peracid bleaches. The thickened composition is compatible with any oxidant bleach which can tolerate the acid pH necessary to precipitate the fluorescent whitening agent. The bleach must be able to supply oxidizing species at the acid pH, and should be resistant to degradation thereby. Halogen bleaches are ordinarily ineffective at acid pHs and are therefore not preferred. It is noted that ionic strength associated with halogen bleaches is neither a prerequisite nor a hindrance to the thickening system; thickening will occur in the presence or absence of ionic strength. 
     Preferred as bleaches are the peroxygen or peracid bleaches. Peroxygen bleaches are preferred in terms of manufacturing cost, and preferably are added as an aqueous solution. The aqueous bleach is present in an amount sufficient to provide effective bleaching, e.g., from about 0.05 to 50% by weight active, more preferably from about 0.1 to 35% by weight active and most preferably from about 0.5 to 15% by weight active depending on the bleaching species chosen. Peracid bleaches (including monoperacids and diperacids) may be advantageous in terms of bleaching performance. Peracid bleaches, however, must be added in an insoluble form, due to their greater reactivity. Suitable peracid bleaching species include C 8-12  alkyl peracids especially perazelaic and diperazelaic acids, diperoxydodecanedioic acid (DPDDA), and alkyl monoperoxysuccinic acid. Peracid bleaching species, and a method for their production, are described in U.S. Pat. No. 4,337,213 issued June 29, 1982 to Marynowski et al, the disclosure of which is incorporated herein by reference. DPDDA is particularly preferred for use in the composition of the present invention as it is relatively storage stable and produces desirable bleaching results. Other potential suitable peracids are identified in U.S. Pat. No. 4,391,725 issued to Bossu, the disclosure of which is incorporated herein by reference. If added, the total peracid may range from about 0.1 to 50, preferably about 0.1-15, most preferably about 2-10 weight percent, and total oxidant present should generally not exceed about 50 weight percent. The peracid may be added in its active form or by means of the previously mentioned peracid precursors. Combinations of any of the foregoing are also useful, and it is particularly advantageous to include the insoluble peracid precursor with the soluble peroxygen bleach. Suspension of the precursor and/or the peracid in the composition herein maximizes the storage stability thereof by minimizing the potential for interaction between the peracid precursor and nucleophilic species which may activate the precursor. Suspension of peracid or peracid precursor also aids in preventing oxidation thereby of any oxidizable components in the composition. 
     In a third embodiment, the invention is formulated as a stabilized, thickened peroxide bleach, and includes, in aqueous solution: 
     a peroxide bleach; 
     a bleach activator; 
     the thickening system comprising the surfactant, fluorescent whitening agent, and pH adjusting agent; and 
     a stabilizing system including a chelating agent and antioxidant. 
     The thickening system and bleach activator again are as described for the first and second embodiments. The remaining components are described in further detail below. 
     Peroxide 
     A hydrogen peroxide source is present as the principal active ingredient and functions as the bleaching agent. The hydrogen peroxide is normally supplied as liquid hydrogen peroxide, although other hydrogen peroxide sources may also function satisfactorily. For example perborate and percarbonate also supply H 2  O 2  in solution. The peroxide is present in the range of about 0.05-50% by weight active, more preferred is 0.1-35% by weight active, and most preferred is 0.5-15% by weight active. Numerous sources manufacture and/or market hydrogen peroxide on a commercial basis, and one example of a commercial source is the FMC Company of Philadelphia, Pennsylvania. Ordinarily the peroxide is purchased as a concentrated aqueous solution, for example a 70% solution, and is diluted with the deionized water to the desired strength. 
     Stabilizing System 
     Stabilization of the bleaching composition of the present invention, including the hydrogen peroxide, fluorescent whitening agent, surfactants and any optional dyes and fragrances relies upon the presence of a metal chelating agent. Stabilization is accomplished as fully described in copending U.S. patent application Ser. No. 144,616, filed Jan. 11, 1988, which is a continuation-in-part of Ser. No. 745,617, filed June 17, 1985, now abandoned, assigned to the same assignee as the present invention and incorporated by reference herein. The following briefly describes the essential components of the stabilizing system. More detailed information may be obtained from the above-referenced application. 
     The stabilizing system comprises an antioxidant and a chelating agent. It is thought that the chelating agent acts to sequester heavy metal cations, especially polyvalent metals such as copper and iron which are always present in small amounts among the mineral components in water. These heavy metal cations normally have the ability to catalyze peroxide homolysis and to mediate free-radical generation. These capabilities are inhibited by the chelating agent. The stabilizing system also includes an antioxidant which appears to work by tying up free-radicals initially formed in the solution, removing the ability of free-radicals to degrade organic components and also stopping the self-propagating free-radical cascade reaction. By such a mechanism, destruction of the surfactants, fluorescent whitener and optional oxidizable components (e.g., fragrance and dye) is arrested or reduced. Both the chelating agent and antioxidant should be present to attain the desired stability of the peroxide bleaching composition. However, less preferred embodiments of the invention can omit either the chelating agent or antioxidant. 
     The chelating agent maybe selected from a number of known agents which are effective in chelating heavy metal cations. The chelating agent should be resistant to hydrolysis and oxidation by oxidants. Preferably it should have an acid dissociation constant (pKa) of about 1-9, indicating that it dissociates at low pH&#39;s to enhance bonding to metal cations. The most preferred chelating agent is an amino polyphosphonate which is commercially available under the trademark &#34;Dequest&#34; and sold by the Monsanto Company. Specific examples of effective Dequest products include Dequest 2000, Dequest 2010, Dequest 2041 and Dequest 2060. Other related chelating agents such as pyrophosphates may also be utilized. Polycarboxylic acid-type chelating agents, e.g. EDTA, will also perform well. Mixtures of the foregoing are also suitable. The chelating agent should be present in an amount sufficient to tie up any heavy metal cations present in the solution. The preferred range is 0.02 to 5% by weight, more preferred 0.04 to 3% by weight, and most preferred is 0.06 to 1.0% by weight. 
     The second component of the stabilizing system is the antioxidant which functions as a free-radical scavenger. Preferred for this purpose are substituted phenols, or more broadly, hydroxy benzenes. Of this class of compounds, butylated hydroxy toluene (BHT) and mono-t-butyl hydroquinone (MTBHQ) have been found to be especially effective. The antioxidant must resist oxidation by H 2  O 2  and therefore cannot be too strong a reducing agent. It is also desirable that the antioxidant hydroxy benzenes be partially hindered, i.e., have a substituent alkyl or similar group attached to some of the reactive sites on the ring structure. It is necessary to block some of the reactive sites so that reactions with multiple available free-radicals resulting in polymerization and possible phase separation do not occur. BHT and MTBHQ satisfy all of the above criteria and are therefore preferred as antioxidants. BHT is commercially available from the Uniroyal Chemical Company, while MTBHQ is commercially available from the Eastman Chemical Company. Other suitable antioxidants are aromatic amines such as alkylated diphenyl amines and naphthylamines. Only very small amounts of antioxidant are necessary in the bleach composition. A preferred range is about 0.005-0.1% by weight, more preferred is 0.007-0.04% by weight, and most preferred is 0.01-0.02 by weight. 
     Optional Ingredients 
     Optionally, the thickened peracid activator composition may include small amounts of components such as fragrances, commerically available from, for example, International Flavors and Fragrances, and dyes such as acid blue. It is also contemplated that fluorescent whitening agents or dyes which do not fall within the thickening-effective classification could be added to perform only their whitening or dying function. Thickening-effective fluorescent whitening agents would, of course be present to both thicken and whiten, and the extra fluorescent whitening agents would serve to increase brightening without increasing thickening. Detergents and fabric softening compounds may also be included. Preferred detergents include anionic, cationic, nonionic and amphoteric detersive surfactants, such as alkyl benzene sulphonates, ethoxylated alcohols, ethoxylated alkyl phenols, fatty acid esters and amine oxides. Preferred fabric softeners include quaternary and diquaternary ammonium compounds, imidazolinium compounds, fatty alcohols and esters thereof, and the like. 
     The balance of the formulation is, of course, water. It is preferred for stability purposes to use deionized or distilled water to reduce metal ion contaminates to as low a level possible. It may be noted however, that even with metal ion contamination of 2-10 ppm or more, the stabilizing system of the present invention remains effective. 
     Examples of typical thickened stabilized peroxide bleach formulations are set forth below: 
     
         ______________________________________Formulation #1               Wt. %______________________________________Water                     84.68Surfactant                4.0Fragrance                 .01Antioxidant               .01Base                      .12Soap                      .45FWA                       .45Chelating Agent           .12Bleach                    10.0pH Adjusting Agent        .1-.14pH                 5.0Viscosity (cP)     255______________________________________Formulation #2               Wt. %______________________________________Water                     84.92Surfactant                4.0Fragrance                 .05Antioxidant               .05Base                      .18Soap                      .34FWA                       .23Chelating Agent           .12Bleach                    10.0pH Adjusting Agent        .1-.14pH                 4.0Viscosity (cP)     225______________________________________ 
    
     Highly thickened, transparent gel or paste compositions were made using relatively high levels of FWA and surfactant in accordance with the following formulation: 
     
         ______________________________________Formulation #3              Wt. %______________________________________Water                    81.9Surfactant               12.3FWA                      2.5pH Adjusting Agent       3.3pH                 4.0______________________________________ 
    
     A preferred process for making the formulations of the present invention begins by preparing an aqueous solution of the desired type and amount of surfactant. If the composition is to include only the surfactant, FWA, peracid precursor and pH adjusting agent, the FWA is added next to the surfactant solution and the pH adjusting agent is added to precipitate the FWA, resulting in a generally homogenous dispersion. The ph adjusting agent can precede the FWA; it is important only that the surfactant precede at least FWA or pH adjusting agent. The peracid precursor is typically added last, and must be added after the pH has been adjusted to the acidic range so that the precursor will not become activated. When a soap is incorporated, it is preferred to add to the aqueous surfactant solution an amount of base calculated to neutralize the amount of fatty acid, then add the fatty acid. The FWA, pH adjusting agent and precursor are then added as above. The bleach, stabilizing system and/or any optional ingredients may be added at any point prior to addition of FWA or pH adjusting agent, and preferably prior to both. 
     Experimental 
     Viscosity of the thickening system, comprising the major components of water, surfactant, FWA and soap was evaluated, as was phase stability of the thickening system with each of the major components omitted. The specific materials included in the composition were: 
     Surfactant - Neodol 25-7, 4% by weight; 
     FWA - Tinopal 5BM-XC, 0.45% by weight; 
     Soap - lauric acid, neutralized in situ to sodium laurate, 0.5% by weight; 
     and the balance was water. 
     The control (composition 1) included water, Neodol, FWA and soap. Three additional compositions were made up, identical to the control minus one of the thickening system components. Thus composition two contained water, Neodol and the FWA; composition three contained water, FWA and soap; and composition four contained water, soap and Neodol. Viscosity was checked immediately after sample preparation and results are shown in Table 2. Samples 2, 3 and 4 exhibited varying degrees of instability during 72 hours of storage at 70° F. 
     
                       TABLE 2______________________________________A. Viscosity (cP) - Brookfield RVT, Spindle #1, 4 speeds1             2         3          4Control       No Soap   No Surfactant                              No FWA______________________________________10 rpm  300       121       6         720 rpm  175       69        7        1050 rpm  103       43        9        14100 rpm  82       44        12       19______________________________________ 
    
     Table 3 shows the effect of variations in soap on the viscosity and phase stability of the composition of the present invention. The following soaps were tested: 
     capric acid, lauric acid, methyl laurate, myristic acid, and coconut fatty acid. 
     Each fatty acid material was blended into the hydrogen peroxide formula of formulation 1, at a molar equivalent of 0.0225M (between about 0.4 to 1.0% by weight depending on the fatty acid). Sodium hydroxide was first added to neutralize the fatty acid in situ. Viscosities were checked at four different spindle RPMs, and were tested at four times: initially at completion of the batch, after 24 hours at 70° F., after three days of 70° F., and after two weeks at 120° F. Table 3 illustrates the viscosities of the formulations incorporating each of the fatty acid soaps at the four times tested. 
     
                       TABLE 3______________________________________A. Viscosity (cP) - Brookfield RVT, Spindle #1, 4 speedsCapric      Lauric   Methyl   Myristic                                CoconutAcid        Acid     Laurate  Acid   Fatty Acid______________________________________1. Initial10 rpm 598      253      213    196    16820 rpm 368      152      116    116    9650 rpm 200      102       62     65    6600 rpm 100       89       54     60    662. 24 Hours10 rpm 520      152      92     19420 rpm 342      102      61     12850 rpm 200       69      46      82    N/A100 rpm  100       60      47      733. 3 Days2.5 rpm  2260     --       --     --     --5 rpm  1400     --       --     848    --10 rpm 860      416      266    521    42220 rpm 500      263      157    318    26650 rpm 200      146       88    174    153100 rpm  100      100       71    100    100 4. 2 Weeks@ 120° F.2.5 rpm   22605 rpm  165010 rpm 1000     --       Unstable    --______________________________________ 
    
     Table 4 illustrates the effects of various acids and pHs on viscosities and phase stability. Again, viscosity was measured initially, at one week, and at ten days, all at room temperature (70° F.). While initial viscosities were slightly higher at pH 3, the one week and ten day sample exhibited significantly higher viscosities at pH 5. The phosphoric acid samples also generally resulted in somewhat higher viscosities then samples adjusted with hydrochloric acid. Phase stability of samples at one week was good for all but the HCL, pH 3 sample which had separated into two layers. After ten days, the hydrochloric acid samples showed some signs of flocculation, evidencing phase instability. The phosphoric acid samples at pH 3 and 4 were homogeneous with smooth consistencies and no signs of phase instability. The phosphoric acid sample at pH 5 was homogeneous but had a slightly lumpy texture. 
     
                       TABLE 4______________________________________A. Viscosity (cP) - Brookfield RVT, Spindle #1, 4 speeds        pH 3     pH 4   pH 5______________________________________1. InitialH.sub.3 PO.sub.4      5 rpm   428        474  416      10 rpm  237        263  255      20 rpm  133        149  160      50 rpm   72         79   97HCL         5 rpm  584        484  292      10 rpm  320        268  182      20 rpm  178        130  117      50 rpm   88         74   722. 1 WeekH.sub.3 PO.sub.4       5 rpm  350        864  1570      10 rpm  197        502  928      20 rpm  118        306  500      50 rpm   68        173  200HCL         5 rpm  --         694  1220      10 rpm  --         396  773      20 rpm  --         237  446      50 rpm  --         127  2003. 10 DaysH.sub.3 PO.sub.4       5 rpm  260        910  1840      10 rpm  153        533  1000      20 rpm   94        326   500      50 rpm   59        182   200HCL         5 rpm  --         764  1420      10 rpm  --         436  877      20 rpm  --         268  500      50 rpm  --         153  200______________________________________ 
    
     Stability 
     Chemical stability of the peroxide, dye and FWA, was tested using the following formulation: 
     
         ______________________________________Ingredient        Wt %______________________________________Peroxide          10.0FWA               0.32Dye               0.0043Surfactant        4.0Base              0.24Fragrance         0.05Antioxidant       0.01Chelating Agent   0.12pH Adjusting Agent             1.61Soap              0.39Deionized Water   83.26______________________________________ 
    
     Samples were made up and innoculated with the following metals: 0.3 ppm copper; 0.2 ppm iron; 0.1 ppm manganese; 0.2 ppm nickel; and 0.2 ppm chronium. 
     After storage for two weeks at 120° F. the samples were tested for percentage remaining peroxide, FWA and dye, and the viscosity was measured. Test results are illustrated in table 5 and show that 98.5% of the peroxide remained, 104% of the FWA was found, and 108% of the dye was found. In addition to the excellent chemical stability of the components, no settling of FWA was observed. This was confirmed by measuring FWA levels at the top, middle and bottom of the container used to store the formulation. All measurements showed about 104% of FWA remaining. Final viscosity of the formulation was 248 cP, a decrease of only about 10%. 
     
                       TABLE 5______________________________________   Initial   Final   % remaining______________________________________H.sub.2 O.sub.2.sup.(1)     3.47        3.42    98.5FWA.sup.(2)     0.3189      0.3308  104Dye.sup.(2)     0.1254      0.1361  109pH        4.0         3.73    93Viscosity.sup.(3)     276         248     90______________________________________ .sup.(1) Measured via Iodometric Titration. .sup.(2) Measured as absorbance units via a PerkinElmer spectrophotometer .sup.(3) Measured on a Brookfield RVT, No. 1 Spindle at 5 rpm. 
    
     More extensive chemical stability studies were conducted on formulations which were similar, but without the thickening-effective FWAs. The following formulation was used: 
     
         ______________________________________Ingredient             Wt %______________________________________Peroxide               3.5FWA                    0.16Dye                    0.0005Surfactant             3.5Fragrance              0.01Antioxidant            0.01Chelating Agent        0.12pH Adjusting Agent     0.1Water                  balance______________________________________ 
    
     The following examples in Table 6 were made and tested: 
     
                       TABLE 6______________________________________CHELATING AGENT WT. %   ANTIOXIDANT  WT. %______________________________________1.  0               0       0          02.  Dequest 2010.sup.1               0.12    0          03.  Dequest 2060.sup.2               0.12    0          04.  Dequest 2041.sup.3               0.12    0          05.  0               0       Butyl Hydroxy                                  0.01                       Toluene.sup.4 (BHT)6.  0               0       Ethyl 754.sup.5                                  0.017.  0               0       Cyanox 2246.sup.6                                  0.018.  0               0       Ethyl 733.sup.7                                  0.019.  0               0       Anox NSM.sup.8                                  0.0110. 0               0       Santoflex AW.sup.9                                  0.0111. 0               0       Naphthlamine.sup.10                                  0.0112. Dequest 2010    0.12    BHT        0.0113. Dequest 2010    0.12    Ethyl 754  0.0114. Dequest 2010    0.12    Cyanox 2246                                  0.0115. Dequest 2010    0.12    Ethyl 733  0.0116. Dequest 2010    0.12    Anox NSM   0.0117. Dequest 2010    0.12    Santoflex AW                                  0.0118. Dequest 2010    0.12    Naphthlamine                                  0.0119. Dequest 2060    0.12    BHT        0.0120. Dequest 2060    0.12    Ethyl 754  0.0121. Dequest 2060    0.12    Cyanox 2246                                  0.0122. Dequest 2060    0.12    Ethyl 733  0.0123. Dequest 2060    0.12    Anox NSM   0.0124. Dequest 2060    0.12    Santoflex AW                                  0.0125. Dequest 2060    0.12    Naphthlamine                                  0.0126. Dequest 2041    0.12    BHT        0.0127. Dequest 2041    0.12    Ethyl 754  0.0128. Dequest 2041    0.12    Cyanox 2246                                  0.0129. Dequest 2041    0.12    Ethyl 733  0.0130. Dequest 2041    0.12    Anox NSM   0.0131. Dequest 2041    0.12    Santoflex AW                                  0.0132. Dequest 2041    0.12    Naphthlamine                                  0.01______________________________________ .sup.1 Dequest 2010 (60% active) is an amino polyphosphonate available from the Monsanto Co. .sup.2 Dequest 2060 (50% active) is an amino polyphosphonate available from the Monsanto Co. .sup.3 Dequest 2041 (90% active) is an amino polyphosphonate available from the Monsanto Co. .sup.4 (Shell Ionol) BHT (100% active) available from the Shell Chemical Co. .sup.5 Ethyl 754 (100% active) available from the Ethyl Corporation, is 4hydroxymethyl 2, 6di-T-butyl phenol. .sup.6 Cyanox 2246 (100% active) available from the American Cyanamid, is a 2, 2&#39;methylenebis-(6- Tbutyl-p-cresol). .sup.7 Ethyl 733 (100% active) available, from Ethyl Corporation, is an alkylated phenol. .sup.8 Anox NSM (Pennox A, etc.) (100% active) available from the Bozzett Industrie Chimiche, is a alkylated diphenyl amine. .sup.9 Santoflex AW (100% active), available from the Monsanto Co., is a dihydroquinoline. .sup.10 Naphthylamine (98% active) available from the Aldrich Chemical Co., is an N--phenylalpha naphthylamine. 
    
     To assess the stabilizing effect of the added chelating agents and antioxidants, the samples were initially measured for available oxygen (via Iodometric titration) and amounts of dye (without dilution) and brightener (dilution factor: 3 mls. formulation/1,000 mls. water). Amounts of dye and brightener were measured as absorbance units via a Beckman Spectrophotometer set at wavelengths 598 nm and 344 nm, respectively. Next, each sample was innoculated with 6 ppm heavy metal ions (3 ppm Fe (III); 3 ppm Cu (II)) and stored at 100° C. for three hours. The available oxygen for the hydrogen peroxide and the absorbance values for the dye and the brightener were then read again. Storage at 100° C. for three hours approximates long term storage of about 5 months at room temperature. The data observed were collected and tabulated in Table 7 below: 
     
                                           TABLE 7__________________________________________________________________________EXAMPLE  AO.sub.I.sup.1      AO.sub.F          % AO              DYE.sub.I.sup.2                  DYE.sub.F                      % DYE                           FWA.sub.I.sup.3                               FWA.sub.F                                   % FWA__________________________________________________________________________1      17920      10080          56  0.171                  0   0    0.443                               0   02      17920      16160          90  0.172                  0   0    0.437                               0.1 233      17280      15680          91  0.168                  0   0    0.441                               0.12                                   274      15840      12640          80  0.18                  0   0    0.477                               0   05      17760      14240          80  0.173                  0   0    0.448                               0.02                                   46      17600      11360          65  0.168                  0   0    0.461                               0   07      17760      17280          97  0.17                  0   0    0.47                               0.21                                   458      17680      17440          99  0.169                  0   0    0.468                               0.28                                   609      18080      13280          73  0.199                  0   0    0.466                               0   010     17600      12000          68  0.21                  0   0    0.466                               0   011     17920      17280          96  0.172                  0   0    0.475                               0.311                                   6512     17760      18240          103 0.173                  0.157                      91   0.443                               0.458                                   10313     17280      17600          102 0.169                  0.16                      95   0.478                               0.445                                   9314     17280      17120          99  0.17                  0.162                      95   0.472                               0.452                                   9615     17280      17600          102 0.169                  0.153                      91   0.456                               0.446                                   9816     17360      16960          98  0.166                  0.16                      96   0.468                               0.444                                   9517     17360      17280          100 0.207                  0   0    0.473                               0.344                                   7318     17440      17440          100 0.17                  0.195                      115  0.483                               0.454                                   9419     17120      16960          99  0.176                  0.163                      93   0.467                               0.429                                   9220     17120      16640          97  0.178                  0.163                      92   0.469                               0.428                                   9121     16960      17360          102 0.178                  0.168                      94   0.463                               0.432                                   9322     17440      17280          99  0.177                  0.167                      94   0.465                               0.417                                   9023     17120      16800          98  0.216                  0.155                      72   0.461                               0.382                                   8324     17360      16960          98  0.208                  0   0    0.465                               0.36                                   7725     17600      17120          97  0.181                  0.167                      92   0.48                               0.436                                   9126     17760      17200          97  0.181                  0.164                      91   0.48                               0.428                                   8927     18160      17920          99  0.184                  0.169                      92   0.498                               0.449                                   9028     17440      17200          99  0.181                  0.165                      91   0.481                               0.428                                   8929     17440      17280          99  0.181                  0   0    0.479                               0.303                                   6330     17440      16480          94  0.209                  0   0    0.483                               0.296                                   6131     17280      15680          91  0.207                  0   0    0.483                               0.133                                   2832     17600      16720          95  0.183                  0   0    0.491                               0.397                                   81__________________________________________________________________________ .sup.1 AO.sub.I = Initial reading of available oxygen; AO.sub.F = Final reading. .sup.2 DYE.sub.I = Initial reading of dye; DYE.sub. F = Final reading. .sup.3 FWA.sub.I = Initial reading of brightener; FWA.sub.F = Final reading. 
    
     The above results show that surprising and dramatically improved stability results when the inventive stabilizing system of an antioxidant and a metal chelating agent are used. 
     Example 1, which uses neither chelating agent nor antioxidant, has no stabilizing effects on dyes or brighteners. Examples 2-4, containing only metal chelating agents, have no stabilizing effect on dyes, and minimal to no effect on brighteners. Examples 5-11, containing only antioxidants, have no stabilizing effect on dyes, and minimal to no effect on brighteners. Examples 12-32, on the other hand, in which both metal chelating agent and antioxidant are present, show dramatic improvement in stability. Occasionally, some examples (17, 24, 29-32) show lack of stabilizing effect on dyes, but overall, increased chemical stability above and beyond that of any of examples 1, 2-4 and 5-11, is demonstrated. 
     Formulation #4 
     8.15 g of OBA was ground using a mortar and pestle, then mixed with 120 g of a thickened peroxide composition substantially as described in formulation of Table 1, with the brightener being 0.32% of PHORWITE RKH. The peroxide and peracid concentrations were monitored over time at 70° F. and 120° F. and results are reported in Table 8. 
     
                       TABLE 8______________________________________       Time       2 weeks       12 weeks      70° F.                120° F.                         70° F.______________________________________Percent OBA  95 ± 4%  81 ± 4%                             98 ± 4%RemainingPercent Peroxide        100 ± 2% 98 ± 2%                             96 ± 2%Remaining______________________________________ 
    
     No syneresis was exhibited by the formulations of Table 8. The results confirm that the peracid activator can be successfully suspended in the thickened peroxide matrix, and reaction of OBA with the peroxide is slowed considerably by the suspension. 
     Although described in terms of the presently preferred embodiments, it is to be understood that such disclosure is not to be interpreted as limiting. Various modifications and alterations will no doubt become apparent to one skilled in the art after having read the above disclosure. Accordingly, it is intended that the appended claims be interpreted as covering all such modifications and alterations as fall within the true spirit and scope of the invention.