Compressible and moldable toy sand composition

Abstract

A sand-based molding composition which can be compressed using hand pressure, and which starts as a free-flowing sand mixture, is formed by combining a solvent with a waxy binder and blending this with sand and subsequently stripping off the solvent. The molding composition includes the particulate material, preferably sand, coated with a thin coating of the waxy binder which is preferably a paraffin wax. A pigment can be added which will remain held by the binder and will not tend to stain. The molding composition can be compressed with the hand to form a molded article, and can be easily crushed to form a flowable, sandy product.

Description

BACKGROUND OF THE INVENTION

Children of all ages love to play with sand. One of the most enjoyable things to do with sand is to make a sand castle or other building out of sand. Sand mixed with the right amount of water can be compressed together to form a self-sustaining structure. Of course, when the sand dries it crumbles apart. Unfortunately, sand does not make a good plaything for inside the house. It is simply too messy.

There are many molding compositions that can be used inside the house such as putty-type molding compositions and Play Doh.RTM. brand molding composition, but these do not have the overall feeling of sand. They frequently tend to dry out and are too expensive to make larger items.

SUMMARY OF THE INVENTION

The present invention is premised upon the realization that a low-cost, compressible molding composition can be formed by coating inert particulate material with an inert wax-like material. Preferably, according to the present invention, the compressible molding composition comprises sand or other particulate material coated with a thin coating of wax, preferably a paraffin wax or similar composition. The formed product requires no water for compression molding and is very clean, leaving little or no residue on the hands. It is tactilely pleasant, non-toxic and safe. Further, it can be combined with food-grade or other inert pigment compositions to provide a colored molding composition. Further, the pigments can be fluorescent or phosphorescent, which in turn provides for a wide variety of different aesthetic appearances which further enhances the product.

The objects and advantages of the present invention will be further appreciated in light of the following detailed description.

DETAILED DESCRIPTION

According to the present invention, a compressible molding composition includes a particulate material coated with a wax-like binder. This composition can be pressed together with one's hands to form a self supporting article.

The particulate material employed in this composition can be any inert particulate material. Preferably, it will be a non-porous inert material. The preferred particulate material is an inorganic material such as sand, crushed stone, silica particles or other crushed minerals. Silicaceous materials are particularly suitable. Such particles are inert, non-hazardous. The preferred particulate material is sand, due to its overall size, porosity, inertness and cost.

The particle sizes of the particulate material can vary widely, generally from 1000 down to 50 microns. Preferred particle sizes would be from about 500 down to about 100 microns. Sand or ground stone or other siliceous material can be purchased having such a particle size.

The particulate material is coated with a film of a binder. The binder is an inert, wax-like material which will bind to the particulate material and will not dry out. Preferably, the binder is a wax. The term "wax" is used as a generic classification of many materials that are either natural or synthetic and of petroleum, mineral, vegetable, or animal origin. Generally, these materials are considered wax-like because of their functional characteristics and physical properties. They are solid at ambient temperatures with a relatively low melting point, and capable of softening when heated and hardening when cooled. The material is self-adherent and thus functions as a binder. Further, it is deformable under moderate pressure. Compositions generally included within the definition of wax include waxes of vegetable and animal origin such waxes include beeswax. Also included within the term "wax" is paraffin wax which is a distillate taken from petroleum after the cracking process. Other wax-like materials include low molecular weight polyethylenes and polymethylenes, as well as wax-like polyethylene glycol. However, paraffin wax which is obtained from petroleum distillation is preferred.

Preferably, the binder is one which has a melting point significantly above room temperature and generally greater than 100.degree. F. or more. Microcrystalline wax and Borneo wax have relatively high melting points--145.degree.-165.degree. F. Other waxes that have particularly high melting points include Montan wax which melts at 80.degree.-90.degree. C.

In order to formulate the molding composition of the present invention, the binder or wax is dissolved or suspended in a solvent, preferably an inert, organic solvent. Suitable solvents would include isopropyl alcohol, hexane, heptane, nonane, chloroform and toluene. With water-emulsified waxes, of course, water can be used. But this is more difficult to remove from the end product and therefore is less preferred. Generally, the hydrocarbon solvents are preferred. The wax or binder is combined with the solvent to form a nearly saturated solution of the wax. This is then combined with the particulate material and mixed. The solvent is then stripped, leaving the molding composition remaining.

Generally, the particulate material will form the bulk of the product by weight. Generally, the binder will be from about 1.5% to about 15% of the molding composition (with the solvent stripped), and preferably will be about 2.5% to 7.5% of the overall composition. Thus, for example, 20 gm of paraffin may be combined with 375 gm of sand to form the composition.

Generally, the solvent will form 25% to 50% by weight or more of the total combined weight of the wax, sand and solvent. Basically, as little solvent should be used as possible to provide a coating. In forming the coating, the solvent is simply combined with the wax and heated to ensure complete dissolution. Optimally a non-saturated solution is obtained. This is then added to the sand and combined in an appropriate blender such as a rotary blender, ribbon blender or the like.

In addition, any pigment can be combined with the sand composition. Generally, these should be pigments considered safe for toys such as those certified by the Art and Creative Materials Institute. The pigment can be a visible color pigment or a fluorescent pigment, a phosphorescent pigment or even a thermochromic pigment, depending upon the desired aesthetic appearance of the final product. The amount of pigment will vary, depending on the pigment and the desired color, but will generally be 0.1% to 50% based on sand or inert material. In addition to pigment, other colorants such as glitter or mica particles can be added.

The blending is continued until there is even mixing, and then the solvent is removed using a rotary evaporator. Care must be taken that the rotary evaporator does not increase the temperature of the molding composition above the melting point of the binder or an agglomerated semi-solid product will be formed.

The product is then ready for use. It can be held in the hand and compressed by applying only hand pressure, which would be about 0.5 or greater lbs/inch.sup.2, to form a self-sustaining molded article. Open molds can also be used to form molded products. The products can also be run through a toy extruder, providing for a variety of different play activities. After it has been molded, it can be broken up by light hand pressure and reused.

If desired, the molded article or object can be made semi-permanent by heating it, in a conventional oven, to the melting point of the wax. This temperature is simply held until the wax throughout the molded object becomes molten, generally about 1-30 minutes. When cooled, the object hardens and becomes less friable. It can then be painted, if desired, to enhance the aesthetics of the object.

The invention will be further appreciated in light of the following detailed examples which demonstrate the formulation of the product, as well as various modifications.

EXAMPLE 1

A moldable sand composition is formed by first making a sand/wax solution according to Step 1.0 and then removing the solvent as per Step 2.0.

Step 1.0 Make Wax/Sand Solution 1.1 Add 400 mls of Hexane to 1000 ml round bottom flask 1.2 Add 20 grams of paraffin wax (prepared by grating through cheese grater) 1.3 Drop in magnetic stirbar and turn on magnetic stirrer 1.4 If wax dissolves slowly, heat gently with heating mantle (40.degree. to 50.degree. C.) 1.5 Add 1.5 grams of pigment through funnel while stirring 1.6 Turn off magentic stirrer and remove magnetic stirbar 1.7 Add 375 grams of white play sand through a funnel, vortexing solution by hand 1.8 Cap and shake to ensure sand is completely coated with solution Step 2.0 Solvent Removal 2.1 Attach flask to Rotavap, bath temperature -56.degree. C., RPM=40, water aspirator for vacuum 2.2 Remove solvent for about 30 minutes. Continue under same conditions another 30 minutes to dry sand as much as possible and remove residual solvent 2.3 Remove flask from Rotavap and place contents into Pyrex dish in fume hood to allow trace solvent to evaporate 2.4 After contents are completely dry, break up any clumps by hand and store in a polyethylene bottle

Following the procedure disclosed in Example 1, various ratios of paraffin to particulate matter loadings were evaluated. The components, volumes and percent ratios are provided in Table 1. The data in Table 1 would indicate that the optimum ratio of wax to sand+wax on a percent basis is 2.5 to about 5.0%.

A variety of different solvents were evaluated and the results of these evaluations are shown in Table 2. As can be seen from the data in Table 2, althougth isopropyl alcohol and chloroform both work well with paraffin as a binder, heptane and hexane are more desirable.

Various waxes and other binders were further evaluated. The results of these evaluations are shown in Table 3. Paraffin and microcrystalline paraffin work nearly equally as well. Other waxes tested also worked to varying degrees, but tend to produce a less desirable product. Other animal, mineral, vegetable and synthetic waxes should provide similar efficacy. In these tests, the Vanwax-H is a blend of paraffin wax and microcrystalline paraffin wax, petroleum based, with an average molecular weight of 600-800 and 30-75 carbon atoms per molecule. The paraffin is a semi-microcrystalline paraffin, normal paraffin having a molecular weight of 280-560 with 20-40 carbon atoms per molecule.

In order to determine the optimal solvent concentration, various solvent concentrations were used employing hexane as the solvent. Sufficient solvent is present when it solubilizes the wax. Ideally, processing performed utilizing the least volume of solvent per batch minimizes fire hazards and processing costs. The results of these tests are shown in Table 4. The preferred solvent weight percent is between about 27% and 50%, based on the combined solvent, wax and particulate matter where the particulate matter was sand.

Pigmentation of the system was investigated using combinations of various binders, solvents and pigments. The different components are shown in Table 5. The product incorporating the binder and the pigment surprisingly retained its pigmentation and did not bleed off into other products.

Further, to evaluate the particle size requisites for practicing the present invention, various compositions were employed. These are shown in Table 6. In the first experiment, the sand particles had a size greater than 425 microns. In the second experiment, the sand particles were about 250 microns, and in the third experiment, the sand particles were 150 microns. All worked well. Thus, significantly larger and smaller particles can function in the present invention.

Finally, Table 7 shows a variety of different specialty formulations. This shows the use of thermochromic pigments in one formulation, phosphorescent pigments in another, and the incorporation of glitter in the third. These are just variations of formulations which demonstrate the variety of effects that can be achieved using the present invention.

TABLE 1__________________________________________________________________________OPTIMIZATION OF PARAFFIN TO WAX LOADING % Ratio Extrac. Time Air Wt./Vol. (wax/sand + Bath temp Time Dried Free Compress- ShapeIngredient (grams/mL) wax) (C) (minutes) (hours) Flowing bility Sustainability Tactility Comments__________________________________________________________________________Paraffin 10 2.5 68 60 24 yes good good pleasant/softHexane 400Sand 372Paraffin 20 5 58-60 60 24 yes good good pleasant/softHexane 400Sand 375Paraffin 30 7.5 59 60 24 yes good good slightly Tends to clumpHexane 400 best too muchSand 375__________________________________________________________________________ TABLE 2__________________________________________________________________________EVALUATION OF SOLVENTS % Ratio Extrac. Time Air Wt./Vol. (wax/sand + Bath temp Time Dried Free Compress- ShapeIngredient (grams/mL) wax) (C) (minutes) (hours) Flowing bility Sustainability Tactility Comments__________________________________________________________________________Paraffin 20 2.6 70 60 24 yes slight marginal- poor leaves residualIPA 200 unacceptable wax feel onSand 375 handsParaffin 20 5 56-60 60 24 yes good-with acceptable poor leaves residualIPA 200 more force wax feel onSand 375 handsParaffin 14 7 61 60 24 yes good fair good does not bindChloro- 350 as well asform othersSand 186Paraffin 20 5 56 60 24 yes excellent good very soft one of the bestHeptane 400 with littleSand 375 pressureParaffin 20 5 48-60 60 24 yes good good pleasant/softHexane 400Sand 375__________________________________________________________________________ TABLE 3__________________________________________________________________________EVALUATION OF WAXES % Ratio Time (wax/ Bath Extrac. Air Wt./Vol. sand + Temp Time Dried Free Sustain-Ingredient (grams/mL) wax) (C) (minutes) (hours) Flowing Compressiblity ability Tactility Comments__________________________________________________________________________Sand 15 7.69 35 60 1 yes good good pleasant/soft initial experimentEther 100Vanwax-H 1.25(micro-crystalline)Paraffin 10 2.5 68 60 24 good good good pleasant/soft goodHexane 400Sand 375Vanwax-H 10 2.5 68 60 1 yes good dry hard slumps more than(micro- paraffin initially,crystalline) but breaks upHexane 400 readily; seems toSand 375 work/feel better at lower temp W/etherEpolene Wax 20 5 69 45 24 yes no none/ dry may work out of(C-10) slight higher boilingHexane 400 solvent, waxSand 375 softens at 74- 84.degree. C., has odorCarbowax (poly- 20 5 55 60 24 yes somewhat marginal does not feel has an odor,ethylene glycol good as attempted set8000) paraffin structure inWater 400 microwave; noSand 0 chg. after 5-6 min. of heatingCarbowax (poly- 20 5 80 120 24 yes, but no none unpleasant bottom 1/4 hardethylene glycol water clumpy clumpy, and clumpy; this8000) difficult to coarse and is area of greatestWater 400 strip hard heat; above MPSand 375 of wax (-63.degree. C.)110 MPX8-Wax 66 9.6 not not 72 @ yes yes, but weak, but acceptable, bulk mix dumped(60% wax in stripped acceptable 40.degree. C. requires works has odor in Pyrex dish,emulsion) by greater hand placed at 45 toAdditional water 133 Rotovap pressure, remove excessSand 375 would not wax and water work for kids and oven dried to remove remaining water-could work if wax doubledBeeswax 20 5 56 60 24 yes, but yes good slightly honey-like odor,Hexane 400 a little reduced waxSand 375 clumpy loading would improve product performance__________________________________________________________________________ TABLE 4__________________________________________________________________________EVALUATION OF WAXES % Ratio Extrac. Time Air Wt./Vol. (wax/sand + Bath temp Time Dried Free Compress- ShapeIngredient (grams/mL) wax) (C) (minutes) (hours) Flowing bility Sustainability Tactility Comments__________________________________________________________________________Paraffin 20 5 58-60 60 24 yes good good pleasant/softHexane 400Sand 375Paraffin 20 5 55-57 50 24 yes, but yes better than not as appearanceHexane 125 a little IPA coarse slightly whiteSand 375 clumpyParaffin 20 5 55-57 66 24 yes good good pleasant/softHexane 150 crunchySand 375 initially__________________________________________________________________________ TABLE 5__________________________________________________________________________COLORING/PIGMENTING OF PARAFFIN SYSTEM WITH FLUORESCENT PIGMENTS % Ratio Time (wax/ Bath Extrac. Air Shape Wt./Vol. sand + Temp Time Dried Free Compress- Sustain-Ingredient (grams/mL) wax) (C) (minutes) (hours) Flowing ibility ability Tactility Comments__________________________________________________________________________Vanwax-H 4.95 6.2 58 60 24 yes yes yes a little coarse, agglomerated initially,Chloroform 75 more like coarse but broke up to decentSand 70 sand instead product, colorfastF5-605 purple 0.05 fine fluorescentParaffin 20 N/A 58-60 60 24 yes good good pleasant/softHexane 400FB-205 yellow 1.5pigmentSand 375Paraffin 20 5 58 60 24 yes yes, yes good nice vivid color,Hexane 400 compresses colorfast, fluorescentSand 375 easilyFB-605 violet 1.5No Paraffin 0 0 58 60 24 yes no none sharp, sand-like appears to be colorfast,Hexane 100 but some pigment comesSand 93.75 off on hands,FB-605 violet 0.375 fluorescentParaffin 20 5 58 60 24 yes yes good soft, pleasant colorfast, nice color,Hexane 400 fluorescentSand 375FB-805 blue 1.5Paraffin 20 5 58 60 24 yes yes good soft, pleasant colorfast, vivid color,Hexane 300 looks good, fluorescentSand 375FB-905 green 1.5Paraffin 20 5 58 60 at 24 yes yes good soft, pleasant colorfast, vivid color,Hexane 400 20-23" fluorescent, reducedSand 375 Hg. pigment may be betterFB-805 blue 1.5__________________________________________________________________________ TABLE 6__________________________________________________________________________EVALAUTION OF VARIOUS PARTICLE SIZES % Ratio Extrac. Time Air Wt./Vol. (wax/sand + Bath Time Dried Free ShapeIngredient (grams/mL) wax) Temp (C) (minutes) (hours) Flowing Compressibility Sustainability Tactility Comments__________________________________________________________________________>425 micron large sand:Paraffin 20 5 56 55 24 yes good good like beach sand,Hexane 400 slightly coarseSand 375 and sharp<250 microns medium sand similar to white play sand:Paraffin 20 5 58 60 24 yes good good soft, pleasantHexane 400Sand 375<150 microns fine sand:Paraffin 6.75 5 56 56 24 yes good good soft, pleasantHexane 133Sand 125__________________________________________________________________________ TABLE 7__________________________________________________________________________PREPARATION OF SPECIALTY FORMULATIONS % Ratio Bath Extrac. Time Air Wt./Vol. (wax/sand + Temp Time Dried Free Compress- ShapeIngredient (grams/mL) wax) (C) (minutes) (hours) Flowing ibility Sustainability Tactility Comments__________________________________________________________________________Paraffin 10 56 45 24 yes yes yes soft/pleasant colorfast,Hexane 150 thermo-Sand 187.5 chromicType 22 10thermochromicpigmentParaffin 20 57 40 24 yes yes yes soft, butHexane 350 slightlySand 375 clumpy6SSU phosphor- 10escent pigmentParaffin 10 68 60 24 yes yes yes soft/pleasant glitter doesHexane 400 not hinderSand 375 performance,Glitter 8.4 works__________________________________________________________________________ well

As shown by the various formulations tested, the present invention has a wide variety of potential aesthetic characteristics. The invention can retain the coloration of natural sand, it can be pigmented with a variety of different pigments. Glitter can be added to provide shiny or flaky particles. Mica particles can be employed to provide a shiny appearance. The particle size can be modified to affect the tactile characteristics of the present invention. And the present invention can be made phosphorescent, fluorescent, or even thermochromic. The product initially begins as a flowable, sandy product which can be easily compressed into a self-sustaining shape such as a sand castle, broken apart and reused. This makes for limited mess and easy clean-up.

Further, since the pigment remains in the product and does not migrate to the hands of the user, it does not cause staining or discoloration problems.

The preceding has been a description of the present invention along with preferred methods of practicing the present invention.

Claims

1. A toy molding composition comprising an inert particulate material coated with a thin layer of a binder, said thin layer of binder comprising a wax material effective to permit said composition to be compressed from a free-flowing particulate form to a free-standing compressed form wherein said composition has a percent wax ratio of wax to wax-plus-sand on a per weight basis of from about 1.5% to about 15%.

2. The toy molding composition claimed in claim 1 wherein said particulate matter is a siliceous material.

3. The toy molding composition claimed in claim 1 wherein said particulate material is sand.

4. The toy molding composition claimed in claim 3 wherein said wax material is selected from the group consisting of vegetable wax, animal wax, polyethylene wax, polymethylene wax polyethylene glycol wax and petroleum paraffin wax.

5. The toy molding composition claimed in claim 4 wherein said wax material is microcrystalline wax.

6. The toy molding composition claimed in claim 4 wherein said binder has a melting point of at least about 100.degree. F.

7. The toy molding composition claimed in claim 1 further comprising a pigment.

8. The toy molding composition claimed in claim 7 wherein said pigment is selected from the group consisting of phosphorescent pigments, fluorescent pigments, and thermochromic pigments.

9. The method of forming a molding composition comprising dissolving a wax binder in a solvent to form a binder solution, and blending said binder solution with an inert particulate material to thereby coat said inert particulate material with said waxy binder solution, and stripping off said solvent at a temperature greater than the melting point of said wax, wherein said composition has a percent wax ratio of wax to wax-plus-sand on a per weight basis of from about 1.5% to about 15%.

10. The method claimed in claim 9 wherein said wax binder is selected from the group consisting of paraffin wax, animal wax, polyethylene wax, polymethylene wax, polyethylene glycol wax and vegetable wax.

11. The method claimed in claim 10 further comprising heating said binder solution.

12. The method claimed in claim 9 wherein said solvent comprises an organic solvent.

13. The method claimed in claim 12 wherein said organic solvent comprises a hydrocarbon solvent.

14. The method claimed in claim 13 wherein said hydrocarbon solvent is selected from the group consisting of hexane, heptane, octane and nonane.

15. The method claimed in claim 14 comprising 27 to 50% solvent based on total weight of sand, wax and solvent.

16. The method claimed in claim 14 wherein said solvent is blended with said binder and said sand at a temperature above the softening point of said wax and below the melting point of said wax.

17. The method claimed in claim 9 wherein said particulate matter is sand.