DRY BLEACH COMPOSITION
WITH IMPROVED DISPERSIBILITY
Background of the Invention
1. Field of the Invention
This invention relates to dry fabric bleaching products for household use, and more particularly to such dry bleach products based upon peroxygen bleaches, which are formulated to exhibit improved dispersibility/solubility in cold water. 2. Description of Related Art
Bleaching compositions have long been used in households for the bleaching and cleaning of fabrics. Liquid bleaches based upon hypochlorite chemical species have been used extensively, as they are inexpensive, highly effective, easy to produce, and stable. However, the advent of modern synthetic dyes and the use of modern automatic laundering machines have introduced new requirements in bleaching
techniques, and have created a need for other types of bleaching compositions. In order to satisfy this need, and to broaden and extend the utility of bleaches in household use, other bleach systems have been introduced in recent years, most notable are the peroxygen bleaches which generate
hydroperoxide ion as the oxidizing species. A particularly preferred peroxygen bleach is sodium perborate which is suitable for a dry granular formulation. Preferably sodium perborate is combined with an alkalinity booster/builder such as sodium carbonate and is used as a laundry additive. Such a
laundry additive composition is more fully described in US 3,697,271 to Maddox, incorporated by reference herein.
While these compositions have a demonstrated effectiveness, changes in laundering procedures often dictated by
environmental concerns, can reduce their effectiveness. Cold water washes, for example, coupled with shortened wash cycles may hamper solubility/dispersion of sodium perborate/sodium carbonate formulations. Detergents or additives having high sodium carbonate levels readily form bridged hydrated product lumps when placed in piles and submerged in cold water. In a washing machine, these lumps can not be broken apart by agitation and leave residual product known as cold water residue (CWR). When the bulk solution temperature is low enough to cool the internal structure of the submerged pile below the melting points of the carbonate hydrates,
precipitation of hydrates occurs in the saturated internal pile spaces and a bridged CWR mass is formed. CWR has been observed in the washer at temperatures as high as 75°F.
Approximately 25% of all U.S. washloads are conducted at or below this temperature.
Several references have addressed the question of improving cold water dissolution of laundry detergent compositions, however, these limit themselves to compositions containing detersive levels (above about 5%) of surfactant. Cala et al, US 4,196,095, describes and claims a dry blended,
carbonate-based detergent comprising 30 to 90% of a builder salt, at least one third of which is sodium carbonate; sodium silicate; 5 to 30% of a surfactant, and 0.1 to 2% of magnesium stearate. The magnesium stearate is employed to reduce insoluble lumps formed when a detergent composition contacts cold water. Nakamura et al, US 4,970,017, claims a process
for producing a granular detergent composition having high density and wherein one step of the claimed process comprises coating a disintegrated granular detergent composition with 0.5 to 5% by weight of a water-insoluble finely divided powder.
JP 60-96698 (Hara et al), describes a method for manufacturing a granular detergent composition wherein 0.5 to 5 weight percent of calcium stearate or other water insoluble powder is added to a granulated detergent product specifically to improve solubility in cold water. JP 62-228000 Saito et al, describes and claims a high density granular detergent
composition, also employing a hydrophobic powder such as calcium stearate, as a means of improving cold water
solubility. JP 64-20298 to Nakamura et al also describes and claims a high density granular detergent composition having as its object the attainment of a better cold water dissolution rate. This application points out one of the disadvantages in the use of hydrophobic fine powders to attain satisfactory dissolution rates, that is, while the hydrophobicity of the powder may aid dispersion, it can also impede dissolution.
Summary of the Invention
It is therefore an object of the invention to provide a dry peroxygen bleach formulation which exhibits minimal cold water residue and retains good flowability and pour qualities,
It is also an object of the invention to provide a dry peroxygen bleach formulation which is highly soluble in aqueous media at low temperature.
Other objects and advantages of the invention will become apparent from a review of the following description and the claims appended hereto.
Briefly, the present invention is a dry, fabric bleaching composition comprising
(a) a bleaching-effective amount of a peroxygen
bleach;
(b) an alkaline builder material in an amount sufficient to provide an alkaline pH and building capacity;
(c) about 0.05-0.5% of a calcium stearate powder; and
(d) 0 to about 5% of a surfactant.
The laundry additive composition of the present invention exhibits a dramatic reduction in cold water residue compared with similar compositions of the art having no calcium
stearate powder. Surprisingly, the improvement in cold water residue does not result in a reduction in pour qualities or flowability of the composition, nor are the dissolution properties adversely affected.
A method of making the composition of the present invention is also disclosed, and comprises dry blending the peroxygen bleach and alkaline builder, as well as any other dry
ingredients. To this is added the calcium stearate powder which is further blended until completely dispersed, uniformly coating the other dry ingredients. Generally about 5-10 minutes in a tumble style mixer is required. Last, any liquids, particularly nonaqueous liquids such as surfactant, are applied using a coarse spray, while continuing to mix, to result in a uniformly coated dry mixture. Optimally, the initial dry blending step may be replaced by an agglomeration step wherein the oxidant and builder are coagglomerated with an agglomerating agent.
If the agglomeration step option is utilized, it is preferred that the builder be preloaded with a low level (less than about 5%) surfactant prior to agglomerating with the oxidant.
Description of the Drawings
Figures 1 and 2 are graphs showing the effect on bulk solution dissolution of various levels of calcium stearate powder (as calcium stearate). The data were obtained using a sodium perborate/sodium carbonate laundry additive matrix, and wash conditions were a water temperature of 4.5°C, 100 ppm hardness and five pounds of ballast. Results were obtained as
conductance (in millisiemens/cm).
Fig. 1 is a graph showing the effect of 0.25 weight percent of calcium stearate on bulk solution dissolution compared to a control having no calcium stearate; and
Fig. 2 is a graph showing the effect of 0.5 weight percent of calcium stearate on bulk solution dissolution compared to the same control.
Detailed Description of the Invention
Briefly, the present invention is a dry, fabric bleaching composition comprising
(a) a bleaching-effective amount of a peroxygen bleach;
(b) an alkaline builder material in an amount sufficient to provide an alkaline pH and building capacity;
(c) about 0.05-0.5% of a calcium stearate powder; and
(d) 0 to about 5% of a surfactant.
A first method of making the composition of the present invention is also disclosed, and comprises dry blending the peroxygen bleach and alkaline builder, as well as any other dry ingredients. To this is added the calcium stearate powder
which is further blended until completely dispersed, uniformly coating the other dry ingredients. Generally about 5-10 minutes in a tumble style mixer is required. Last, any liquids, particularly nonaqueous liquids such as surfactant, are applied using a coarse spray, which continuing to mix, to result in a uniformly coated dry mixture.
A second method of making the composition of the present invention is an agglomeration process wherein the oxidant material and alkaline builder are agglomerated prior to addition of the calcium stearate powder. In this method, the alkaline builder is first preloaded with surfactant, and any additional liquid additives. Thus surfactant is applied to the builder in a mixer, preferably, a tumble-style or falling curtain rotary mixer, and mixed sufficiently for the builder to substantially absorb the surfactant. Sufficient surfactant is applied to the builder to result in a final product (after agglomeration) surfactant content of 0 to about 5 wt. %, preferably about 0.1 - 3 wt.%. Generally on a surfactant to builder weight basis about 0-20 wt. % surfactant is applied to the builder, more preferably about 1- 15 wt. %. The preloaded builder and oxidant are then charged to the agglomerator. Any agglomerating apparatus known to the art may be employed and preferred are rotary or vertical turbo agglomerators.
Similarly, any agglomerating agent may be used, with sodium silicate and polyacrylates preferred. The agglomerate is then mixed with the calcium stearate powder and any additional dry ingredients in a mixing means, especially a rotary or tumble mixer.
In both processes, care must be taken to minimize physical contact between the calcium stearate and the surfactant, in order to ensure the efficacy of each component.
Unless indicated to the contrary, all percentages, ratios, or parts are determined by weight.
Bleach
Preferred as bleaches are peroxygen or peracid bleaches in solid form. Preferred peroxygen bleaches include sodium percarbonate, sodium perborate, sodium phosphate
peroxyhydrate, potassium permonosulfates and metal peroxides. Sodium perborate is most preferred and may be in the form of tetrahydrate or monohydrate. Bleach activators, also known as peracid precursors, can be included with the peroxygen
compounds. Examples of activators include tetraacetyl
ethylenediamine (TAED), nonanoyloxy benzene-sulfonate (NOBS), and nonanoylglycoylphenol sulfonate (NOGPS). NOGPS is
disclosed, for example, in US patent 4,778,618 issued to Fong et al and in EP 373743 to Bolkan et al, the disclosures of which are incorporated herein by reference. If added, the peracid percursor is added in an amount effective to provide oxidizing power, and generally in a mole ratio to oxidant bleach of about 0.1:1 to 10:1. Peracid bleaches (including monoperacids and diperacids) may be advantageous in terms of bleaching performance. Examples include perazelaic and diperazelaic acids, diperoxydodecanedioic acid (DPBDA) and alkyl monoperoxysuccinic acid. Peracid bleaching species, and a method for their production, are described in U. S. patent 4,337,213 to Marynowski et al, the disclosure of which is incorporated herein by reference. The bleach is present in an amount sufficient to provide effective bleaching, e.g., from about 5 to 50% by weight active, preferably from about 8-25% by weight active, most preferably from about 10 to 13% by weight active depending on the bleaching species chosen.
Alkaline Builder An alkaline builder material is added to provide to a pH of between about 8-12. The builder also has the capacity to sequester or precipitate hardness ions (e.g. Ca2+ and
Mg2+) Alkali-metal carbonates, sesquicarbonates and
bicarbonates are suitable builders, and preferred are sodium and/or potassium carbonates. The carbonate acts as the
builder to remove divalent metal ions such as calcium, and additionally provides alkalinity and aids in soil removal.
Generally, in terms of weight percent of the composition, at least about 25%, Preferably 50%, most preferably 80% carbonate is employed. Higher levels can be employed, however, at levels greater than about 90% there is insufficient room for the other ingredients which contribute to the overall
effectiveness of the composition. Calcium stearate Powder
Very low levels of a calcium stearate powder are important to significantly reduce the levels of CWR in the dry peroxygen bleaching matrix. Preferred are calcium stearates, available, for example, from The Synthetic Products Company (Synpro), of Cleveland, Ohio. Examples of particularly preferred calcium stearate are Synpro's finely-sized grades, especially grades 1 5, 12B, 24-46, 114-36, NF and Food Grade. Preferably, the calcium stearate powder has a particle size distribution such that at least 95 percent is smaller than a US 200 mesh screen, and has a bulk density of about 0.1-0.4 g/cm . More
preferably the calcium stearate powder has a particle size distribution such that at least 99% i s smaller than a US 200 resh screen, and 95* is smaller than a 400 mesh screen A fine particle size is important to ensure effective coating of
the other dry ingredients to result in a hydrophobic
environment, thus mitigating cold water residue.
Granulometer measurements reveal that the most preferred calcium stearate fine powder has a median grain size of less than about 25 microns, preferably less than about 10 microns.
Liquid Additives
A surfactant may be provided to prevent "dusting" of the dry ingredients, particularly sodium carbonate, sodium perborate, and fluorescent whitening agents. It is most preferred to use at least one nonionic surfactant, especially C1-4
alkoxylated aliphatic alcohols and C1-4 alkoxylated alkyl phenols. Particularly preferred are ethoxylated/propoxylated c8-14 alcohols. There should be at least about three alkoxy groups per alcohol, preferably at least about nine. Examples of preferred ethoxylated/propoxylated aliphatic alcohols are BASF Corporation's traderoarked INDUSTROL, and PLURAFAC.
Certain C1_ 4 alkylene oxide copolymers such as ethylene oxide/propylene oxide copolymers are also preferred as
surfactants. These are exemplified by BASF's trademarked PLURONIC series. Other suitable nonionic surfactants are polyethoxylated alcohols manufactured and marketed by the Shell Chemical Company under the trademark "NEODOL". 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 C12_13 mixture with about 6.5 moles of ethylene oxide, and NEODOL 25-9, a Cl2-15 mixture with about 9 moles of ethylene oxide. Also useful are 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. Total
surfactant content may range from 0 to about 5%, preferably from about 0.1 to 3%, more preferably from 0.2 to 1% and most preferably from about 0.2 to 0.3%. It is to be noted that higher levels of surfactant, and/or its application as an overly fine spray, tends to cause agglomeration of the calcium stearate powder, thus severely reducing its effectiveness. It is also preferred to a ratio of surfactant to calcium stearate powder be from about 3:1 to 1:5.
Adjuncts
Adjuncts may be added in an amount of from 0 to about 5% and are useful to improve or enhance efficacy, aesthetics and/or consumer acceptance of the overall formulation. Enzymes are a particularly preferred adjunct, and may be selected from amylases, proteases, cellulases, and lipases. The hydrolytic enzyme should be present in an amount of about 0.01-2%, more preferably about 0.5-1%, by weight of the detergent. Mixtures of any of the foregoing hydrolases are desirable, especially protease/amylase blends.
Dyes, such as Monastral blue and anthraquinone dyes (such as those described in Zielske, U.S. 4,661,293, and
U.S. 4,746,461), and pigments, e.g. titanium dioxide and ultramarine blue which are also suitable colorants, can be selected. Anti-redeposition agents, such as
carboxymethylcellulose, are potentially desirable.
Seguestrants, such as EDTA, citric acid, polyphosphonates, aminopolyphosphonates, and the like, may also be desirable to complex transition metal ions which can destabilize bleaches.
Fluorescent whitening agents (FWAs) are desirable
components for inclusion in bleaching formulations, as they
counteract the yellowing of cotton and synthetic fibers. FWAs are absorbed on fabrics during the washing and/or bleaching process. FWAs function by absorbing ultraviolet light, which is then emitted as visible light, generally in the blue wavelength ranges. The resultant light emission yields a brightening and whitening effect, which counteracts yellowing or dulling of the bleached fabric. Such FWAs are available commercially from sources such as Ciba Geigy Corp. of Basel, Switzerland, under the trade name "Tinopal". Incorporation of the FWAs may be afforded by mixing a binding agent and bulking agents e.g., Na2SO4, and colorants. The mixture is then compacted to form particles, which are admixed into the bleach product. If added, the FWA particles may comprise from about 0.1% to 1% by weight of the composition.
A fragrance which imparts a pleasant odor to the bleaching composition is generally included. As fragrances are subject to oxidation by bleaches, they may be protected by
encapsulation in polymeric materials such as polyvinyl
alcohol, or by absorbing them into starch or sugar and forming them into beads. These fragrance beads are soluble in water, so that fragrance is released when the bleach composition is dissolved in water, but the fragrance is protected from oxidation by the bleach during storage.
Buffering, building, and/or bulking agents may also be present. Boric acid and/or sodium borate are preferred agents to buffer the pH of the composition. Other buffering agents and cobuilders such as sodium and potassium silicate, sodium phosphate, sodium tripolyphosphate, sodium tetraphosphate, aluminosilicates (zeolites), and organic builders such as sodium sulfosuccinate may be added. Optionally, fillers such as sodium sulfate are added. Buffer, builder, and bulking agents are included in the product in particulate form such
that the entire composition forms a free-flowing dry product. Buffers and cobuilders and/or bulking agents may range from 0 to about 80%, preferably 10-50% by the weight of composition.
For a dry-blend process, liquid ingredients, including liquid adjuncts, are preferably sprayed onto the dry
ingredients after application of the calcium stearate powder, and more preferably, as a final step. It is important in the application of liquids, particularly nonaqueous liquids such as nonionic surfactants, that the application be carried out in such a way as to prevent agglomeration of the calcium stearate. For the preferred method of applying liquids last, the liquid application apparatus should be selected to deliver a relatively coarse spray, and mixing should be gentle to moderate. A desired coarse spray may be obtained by a pump-fed non-atomizing nozzle, having a fan-shaped spray pattern. An example is a nozzle sold under the name T-Jet 11002. It is within the scope of the dry-blending-process of the present invention, however, to preload surfactant or other liquids onto sodium carbonate prior to blending in the remaining dry ingredients, and prior to adding any remaining liquid
ingredients. If preloading is undertaken, the spray density of surfactant is less important as long as the carbonate is sufficiently mixed during and after spraying to assure maximum absorption of surfactant. It is preferred to employ a
tumble-style or falling curtain rotary mixer for the
preloading, and the surfactant may be applied using an air-fed atomizing spray apparatus.
Dry adjuncts may be added at any time during the process, for example with the sodium perborate and carbonate or after the addition of all liquid ingredients.
FORMULATION EXAMPLES Ingredient Weight Percentage
Na2CO3 60-90
Sodium Perborate 2-30
Calcium Stearate 0.05-0.5
Surfactant 0-5
Enzyme 0-2.0
Brightener 0-0.5
UMB 0-0.2
Fragrance 0-0.3
Experimental
Table I below shows the importance of particle size
distribution of the calcium stearate powder on CWR. The measurement of CWR is accomplished by placing a measured quantity of laundry composition, as a single pile, in the bottom of a washing machine. Ballast (10 lbs. of polycotton pillow cases) is piled on top of the composition. The washing machine is set to run a gentle eight minute cycle with 4.5°C incoming wash water. At the end of a complete wash cycle the ballast is removed and undissolved composition collected and weighed.
The data of Table I was obtained by placing 110 g of a sodium perborate/sodium carbonate - based additive formulation, containing 0.25 weight percent calcium stearate as the calcium stearate powder, in a pile in a washing machine. Ten pounds of ballast, in the form of polycotton pillowcases were added, and the wash was conducted at a water temperature of 4.5°c, with the results shown in the table. All mesh sizes are US mesh.
Table I
Hydrophobic Powder
Grade Size Distribution CWR (g)
A 60% through 40 83.3
B 80% through 200 35.4
C 99% through 200 0.0
D 95% through 200 0.1
E 99% through 200 2.3
F 99% through 200 1.7
Control(1) 86.4
(1) No calcium stearate
The results show that grades A and B were insufficiently finely sized to achieve an acceptable reduction in CWR.
Grades C-F, however, yielded an acceptable level of CWR. The results of Table I are accurate to within 5.0 g, thus C-F should be considered equal to each other. Generally, less than about 30 g, preferably less than about 10 g and most preferably less than about 5 g is acceptable. Alternatively, CWR is expressed as a percentage by comparing final weight of laundry product with the initial weight. Expressed as a percentage of additive remaining after a wash cycle, less than about 30% more preferably, less than about 10% and most preferably less than about 5% CWR is acceptable.
Table II shows the minimum amount of calcium stearate powder (as calcium stearate) necessary to achieve acceptable CWR levels. The calcium stearate was added to a sodium
carbonate/sodium perborate formulation as in the Example, and had a size distribution of 99% through a 200 mesh screen.
Experimental conditions were as given for Table I above, except more vigorous agitation was employed in the wash cycle.
Table II shows that for a sodium carbonate/perborate
composition, at least about 0.05 wt. %, preferably at least about 0.15 wt. % calcium stearate is important to reduce CWR to acceptable levels.
Table II
Wt. % Calcium Stearate CWR (g)
0. 0 78. 6
0. 025 74 . 4
0.050 28 . 6
0. 150 0. 3
0. 250 0 . 2
0.500 0. 1
For perborate/carbonate laundry additive formulations, a level of calcium stearate powder above 0.5 wt %, the product bridges or clumps slightly as it is poured with the degree of clumping becoming worse with increasing calcium stearate powder level. This phenomenon is seen in the results of Table III which presents angle of repose data for compacted and uncompacted sodium carbonate/perborate samples containing calcium
stearate, poured in a tilt plate apparatus. The tilt plate is a twelve inch long smooth surfaced-plate, upon which is placed about 100 g of sample, in a single pile. The plate is tilted to various angles and the angle at which the sample begins to flow is noted.
At a 0.25 weight percent calcium stearate level, the
pourability of the formulation does not change. The 0.5 weight percent level produces a slight change relative to a stearate-free sample, thus may be considered a maximum level with respect to product pour/flow characteristics.
Table III
Angle of Repose
Weight % Calcium Uncompacted ComDacted
Stearate Sample Sample
0.00 20° 21°
0.25 20° 21°
0.50 22° 22°
1.00 24° 26°
3.00 25° 28°
5.00 25° 28º
10.00 26° 30°
Once dispersed from the bottom of the washer by the agitator the individual granules of additive composition must dissolve in the bulk solution. Owing to the hydrophobic nature of the calcium stearate powder, an excess (above about 0.5%) can interfere with bulk solution dissolution of the additive, as the additive particles become sufficiently coated to prevent them from dissolving. Japanese patent application 62-22800 teaches that while stearate alone is effective for reducing CWR, it also inhibits bulk solution dissolution.
Figures 1 and 2 illustrate bulk solution conductivity
profiles for a mixture of sodium carbonate/sodium perborate and calcium stearate at 4.5°C. Bulk solution dissolution is measured by first filling a washing machine with water at the desired temperature. A 100 g sample was added to the water in the washer tub, and conductance was measured using a
Radiometer America Conductivity Meter, Model CDM-83.
Conductance is expressed in millisiemens/cm, and increases with dissolution of the sample.
All materials were added to bulk solution (5 lbs ballast, 100 ppm hardness). At the 0.25 weight percent calcium stearate level, the bulk solution dissolution is equivalent to the
stearate-free control after eight minutes (both were 84% dissolved). A reduction in solution conductivity is seen for the 0.5 wt % stearate level. Based on a conductance vs.
sodium carbonate level calibration curve (not shown) the pure sodium carbonate is 84% dissolved after eight minutes while the sodium carbonate with 0.5 wt. % stearate is 79%
dissolved. Therefore, the 0.5 wt. % calcium stearate
prevents approximately 5 grams (5%) of sodium carbonate from dissolving after eight minutes. The 0.5% level thus is a maximal level (for a sodium perborate/sodium carbonate additive formulation) above which the beneficial effects of the stearate on additive dissolution is reduced.
Cleaning Performance
To verify that calcium stearate does not reduce performance when a dry bleach composition (containing sodium perborate) is added directly to solution, standard condition (20, 35, and 50°C; 100 ppm hardness) performance and multi-cycle whitening studies were conducted. A leading
commercially-available phosphate detergent served as the detergent matrix, and a leading commercially-available sodium perborate/sodium carbonate laundry additive, to which was added 0.0 and 0.5 weight percent calcium stearate, was tested. The treatments were added directly to solution to prevent lumping. Soil removal, whitening and redeposition were each measured colorimetrically by comparing reflectance measurements on swatches of fabric before and after washing. Whitening was measured after one, three and five cycles while redeposition was measured once after five cycles. Soil removal was measured after one cycle. As seen in the stain and soil averages presented in Table IV, the calcium stearate does not reduce performance. All results are shown for the average of the three wash temperatures. No reduction was
found on any of the individual performance attributes as well (such as grass stains on cotton fabric or clay soil on polycotton fabric) .
Table IV
% Soil Removal
Sebum/
3-stain ( 1 ) 2-soil (2) 3-Fabric ( 3 )
Additive 75.7 81.9 86.0
Additive + 0.5 wt. % stearate 76.7 83.6 87.7
LSD, 95% t-test 1.7 3.4 1.4
Whitening Redeposition Cycle 1 Cycle 3 Cycle 5 Cycle 5 Additive 17 7 19.5 21.0 -2.9
Additive + 0.5 wt. % stearate 17.2 18.8 20.8 -3.1 LSD,95% t-test 0.8 1.1 0.6 1.4
(1) three different proteinaceous stains
(2) two particulate soils
(3) cotton, polycotton and polyester
Table V lists the laundry performance improvements achieved when the additive containing 0.5 wt. % calcium stearate is placed at the bottom of a washer for a cold water wash.
Because the control formula lumps, it provides less
alkalinity and brighteners to the wash resulting in the significantly reduced sebum and whitening performance.
Given the CWR results for the 0.15 wt. % and 0.25 wt. % stearate levels presented in Table II, it is expected that the Table III results would be achieved by the additive plus 0.25 wt. % stearate formula as well.
Table V
Wash Condition Treatment %SR (E)
Sebum/cotton with stearate 72.6
21ºC, regular without stearate 67.9 agitation LSD, 95% t-test 2.5
Sebum/polyester with stearate 95.9
21ºC, regular without stearate 91.8 agitation LSD, 95% t-test 3.0
Sebum/3-fabric with stearate 82.8 average without stearate 79.6
21ºC, regular LSD, 95% t-test 1.4
agitation
Whitening with stearate 10.7 12.8ºC, regular without stearate 9.1 agitation LSD, 95% t-test 1.0
Whitening with stearate 8.9 4.5°C, regular without stearate 6.8 agitation LSD, 95% t-test 0.8
Tables VI and VII illustrates the importance of the method of the present invention. Mixing time of dry ingredients and order of addition of surfactant and/or any liquids (e.g., fragrance) can impact stearate dispersion, thereby affecting CWR. The product of Table VI was made as a 10 lb.
dry-blended batch in a tumble mixer.
Table VI
Sample Mixing Time (Min) CWR(g)
A 5 51.5
A 10 4.8
B 5 52.9
B 10 50.8
B 15 23.0
A = perborate plus 0.25 wt. % calcium stearate
B = A plus 0.40 wt. % nonionic surfactant/fragrance
Table VI shows that a minimum of ten minutes of mixing (in a small tumble mixer with gentle-moderate mixing) the dry ingredients is necessary to attain an acceptable CWR value. Table VI also illustrates the disadvantages of using a fine surfactant spray, as this tends to cause agglomeration of the calcium stearate particles and increase CWR unless mixing is continued for a long time. The spray apparatus used to obtain the mixture of Table VI was an atomizing sprayer embodying a pressure of about 25 psi at 2 g/min delivery. These spray conditions are accordingly not preferred where surfactant is added last.
A scale up was run in a 100 lb. batch Pelligrini mixer (a baffled, tumble mixer) set to provide vigorous mixing. A surfactant/fragrance mixture was applied as a coarse spray using a T-Jet 11002 Nozzle at 40 psi and 300 g/min delivery. A substantial decrease in CWR was evidenced by these process parameters, as shown in Table VII.
Table VII
Sample Mixing Time (Min) CWR(g)
A 5 0.49
A 10 0.45
B 5 3.51
B 10 1.05
B 15 1.41
A = perborate plus 0.25 wt. % calcium stearate
B = A plus 0.40 wt. % nonionic surfactant/fragrance
Both Tables VI and VII show that dispersion of stearate into the dry ingredients is important in achieving good CWR. The five minute value of Sample A of Table VII is sharply
improved owing to the more rapid dispersion of stearate in the larger, more vigorous Pelligrini mixing apparatus. The
coarser spray also improved CWR of the B samples, apparently by sharply reducing the tendency of the fine powder to agglomerate. Generally, only five minutes of mixing the dry ingredients, followed by another five minutes after
surfactant addition, is needed to achieve acceptable CWR values.
While 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 occur 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.