WO2000027255A2

WO2000027255A2 - Food container having cut resistance surface

Info

Publication number: WO2000027255A2
Application number: PCT/US1999/025933
Authority: WO
Inventors: John William Toussant; Bruce Neil Hall
Original assignee: The Procter & Gamble Company
Priority date: 1998-11-09
Filing date: 1999-11-03
Publication date: 2000-05-18
Also published as: EP1128751A2; AU1340800A; JP2002529128A; CA2348950A1; HK1041797A1; KR20010086000A; TW442426B; ZA200103018B; CN1342051A; WO2000027255A3; BR9915172A; AU755081B2

Abstract

A food container (10) having a first user-facing surface (11) and an opposed second surface (12). A cut-resistant external facing (32) is juxtaposed with and preferably coincident the first surface (11). The external facing (32) comprises a single stratum of a particulate material (34). The particulate material (34) comprises particles having a particle size of at least 5 microns and preferably ranging from 50 to 200 microns. Preferably the particles have a Mohs hardness of at least 3.

Description

FOOD CONTAINER HAVING CUT RESISTANCE SURFACE

FIELD OF THE INVENTION

The present invention relates to food containers, and more particularly to food containers having a user facing surface which provides improved cut resistance.

BACKGROUND OF THE INVENTION Disposable food containers are well known in the art. Disposable food containers include common paper plates, bowls, clam shells, trays, etc. The art has paid considerable attention to making, molding, and deforming these food containers out of a single plane. In this latter process a blank is provided. The blank is inserted between mating platens and pressed. The periphery of the blank may have radial grooves. The radial grooves provide for accumulation of the material deformed by the platens. Exemplary art includes U.S. Patents 3,033,434, issued May 8, 1962 to Carson; 4,026,458, issued May 31 , 1977 to Morris et al., the disclosures of which are incorporated herein by reference; 4,606,496, issued August 19. 1986 to Marx et al.; 4,609,140, issued September 2, 1986 to van Handel et al.; 4,721.500, issued Jan. 26, 1988 to van Handel et al.; 5.230.939, issued July 27, 1993 to Baum; and 5,326.020, issued July 5, 1994 to Cheshire et al.

However, these attempts in the art suffer from several drawbacks. As illustrated by the plethora of attempts to improve the rigidity and stability of the food containers, the prior art attempts do not provide food containers of sufficient strength. This lack of strength leads to spillage of food when the food container becomes overloaded, or, alternatively, unduly constrains the amount of foods which can be placed on the food container at a given time. There have been several attempts in the art to improve the rigidity of such food containers. For example, food containers having a bottom wall, a side wall disposed radially outwardly of and circumjacent the bottom wall, and a rim disposed radially outwardly of and circumjacent the side wall are known in the art. Food containers with densified regions in the side wall have been attempted in the art. Likewise, containers having densified circumferentially spaced regions extending radially through annular portions of the rim are known. Such attempts in the art are alleged to provide resistance to bending throughout the entire structure. Illustrative of such attempts are U.S. Pat. nos. 4,606,496 issued Aug. 19, 1986 to Marx et al. and 4,609,140 issued Sept. 2, 1986 to Van Handel et al.

Food containers according to the prior art have been coated to improve resistance to penetration by liquids, such as grease, etc. Coatings have also been used to attempt to provide cut resistance in the finished product, gloss, ink receptivity, etc. An example of such attempts is U.S. 5,776,619 issued July 7, 1998 to Shanton. Shanton teaches a coated paper board having two coatings, a base coat and a top coat. Each coating consists of a polymer latex and a particulate pigment. The top coat has a blend of about 90 parts kaolin clay, having approximately 80% of the particles less than two microns in size. Furthermore, U.S. 5,709,913 issued Jan. 20, 1998 to Andersen et al. discloses, in Example 112, inorganically filled paper plates which are allegedly more rigid than conventional paper plates.

Another attempt in the art is illustrated by U.S. 5,635,279 issued June 3, 1997 to Ma et al. Ma et al. discloses paperboard having a polymer matrix/wax/pigment mixture applied as an aqueous formation and suited for corrugated box constructions. The coating consists of pigments, including natural and synthetic silicates, bentonite, kaolin and other clays, etc. U.S. 5,494,716 issued Feb. 27, 1996 to Seung et al. discloses a food tray having an aqueous coating with a styrene/acrylic latex and other agents. U.S. 5,334,449 issued Aug. 2, 1994 to Bergmann discloses a paper having a prime coat and a mixture of kaolin, calcium carbonate, casien and butadiene-styrene latex. U.S. 5,100,472 issued Mar. 31 , 1992 to Fugitt et al. discloses a paper coating containing dionized clay or calcium carbonate. Similar attempts have been made in nonanalogous art to utilize particulates for abrasion resistance. For example, U.S. 5,558,906 issued Sept. 24, 1996 to

Albrinck et al. discloses a decorative laminate having an abrasion resistant material including alumina particles having particle sizes of about 25 microns and at about 3 microns in a 2-1 ratio.

Additionally, mineral pigments such as titanium dioxide, and water and particulate fillers such as kaolin clay have been used as opacifying agents in nonanalogous arts, such as tissue. Examples include commonly assigned U.S. 4,952,278 issued Aug. 28, 1990 to Gregory et al.; U.S. 5,611 ,890 issued Mar. 18, 1997 to Vinson et al.; and 5,672,249 issued Sept. 30, 1997 to Vinson et al., the disclosures of which are incorporated herein by reference. Additionally, fillers and cationic starch have been taught in nonanalogous arts such as the production of news print as found in U.S. 5,670,021 issued Sept. 23, 1997 to Owens. Accordingly, this invention provides a food container having a cut resistance surface which is simpler in execution and consumer preferred over the surfaces provided by the attempts in the prior art. Particularly, this invention provides a food container having a cut resistance surface which not only improves resistance to inadvertent cutting and to penetration by liquid such as grease, but also provides a preferred tactile feel, when using common eating utensils such as silverware.

SUMMARY OF THE INVENTION This invention comprises a food container. The food container has a first user-facing surface and a second surface opposed to the first surface. The food container has a cut-resistant particle containing external facing juxtaposed with, and preferably coincident, the first surface. The external facing consists of a single stratum of a particulate material. The particulate material has a Mohs hardness of at least 3 and preferably at least 7. The particulate material has a particle size of at least 5 microns, and preferably at least 10 microns. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a food container according to the present invention. Fig. 2 is a fragmentary sectional view taken along the lines 2-2 of Fig. 1.

DETAILED DESCRIPTION OF THE INVENTION Referring to Figs 1-2, the food container 10 according to the present invention may comprise a plate, bowl, tray, clam shell, or any other configuration known in the art.

Typically the food container 10 according to the present invention has a concave first surface 11 and a convex second surface 12. The concave first surface 11 of the food container 10 is that side which typically faces the user while in use. The convex side of the food container 10 typically faces away from the user in use and may rest upon a horizontal surface such as a table.

The food container 10 thus comprises a first user-facing surface and a second surface 12 opposed to the first surface 11. The food container 10 further has a cut-resistant external facing 32 juxtaposed with, and preferably coincident, the first surface 11. The cut-resistant external facing 32 comprises particulate material 34 disposed in a single stratum. Particulate material 34 of the cut- resistant external facing 32 is disposed on and carried by a substrate 30.

The food container 10 comprises a central region 14 and a circumjacent periphery 16. The central region 14 and periphery 16 are preferably disposed in two different planes, although a flat food container 10 is contemplated as a less preferred embodiment. A flat food container 10, may, for example, have utility as a food tray or cutting board.

The central region 14 defines the XY plane of the food container 10. The Z- direction of the food container 10 lies perpendicular to the XY plane. The food container 10 has a transition region 20 from the central region 14 to the periphery 16. The periphery 16 may be spaced apart in the Z-direction from the central region 14, or the food container 10 may be flat, as described above. In normal use, the periphery 16 is raised relative to the central region 14. The central region 14 of the food container 10 defines a first portion of the food container 10. Likewise, the periphery 16 of the food container 10 defines a second portion of the food container 10.

Thus, the food container 10 is preferably multi-planar. By multi-planar, it is meant that the different portions of the food container 10 lie in different planes. An example of the multi-planarity of the food container 10 of the present invention is illustrated by the central region 14 and periphery 16 of the food container 10. The central region 14 and periphery 16 of the food container 10 are spaced apart in the Z-direction, thus rendering the food container 10 multi- planar.

It may be necessary to accommodate the accumulation of material which occurs when the food container 10 is formed. Pleats or gathers are often used for this purpose, as is known in the art. Pleats and gathers, particularly accumulation pleats having a radial orientation, are contemplated. It is not necessary that either the central region 14 or the periphery 16 be parallel to the XY plane or generally planar. For example, bowls having a generally concave shaped bottom will be suitable for use with the present invention. The Z-direction distance from the bottom surface of the central region 14 (taken while the food container 10 is in its normal in use and generally horizontal position) to the top surface of the periphery 16 as referred to as the Z- direction depth 19 of the food container 10. If there are different depths at different portions of the food container 10, the Z-direction depth is taken as that greatest Z-direction distance.

The boundary and shape of the periphery 16 are defined by the edge 18 of the food container 10. It is to be recognized that the dimensions and relative proportions of the periphery 16 and central region 14 of the food container 10 will vary according to the exact size and intended use of the food container 10. While a round food container 10 is contemplated, one of ordinary skill will recognize that any suitable shape and depth of food container 10 may be selected for use with the present invention and the invention is not so limited. Other suitable shapes include squares, rectangles, ovals, various polygons, etc. The substrate 30 of the food container 10 may be comprised of at least two plies, a first ply and a second ply. The second ply may be smaller that the first ply, so that at least part of the food container 10 is free from the second ply. The second ply and the first ply may be concentric. It is to be recognized that an alternative embodiment (not shown) of the food container 10 may comprise three or more plies.

In a particularly preferred embodiment, the food container 10 comprises a single ply of a rigid material, particularly a material which provides for carrying the cut-resistant external facing 32 in juxtaposition and preferably coincident with the user-facing surface of the food container 10. Suitable rigid materials include foam, plastic and various other synthetic materials. The food container 10 is preferably made of cellulose and may be made of kraft, solid bleached sulfite (SBS), or layers of various paper fibers including recycled cellulose. The food container 10 may be molded from a pulp slurry or pressed from a blank between mating platens. Both methods of manufacture are well known in the art.

The external facing 32 provides resistance to penetration of hot greasy foods into the substrate 30 of the food container 10. Also, the external facing 32 provides a tactile sensation which is not unpleasant when the user touches the first surface 11 of the food container 10, or cuts food thereon with an eating utensil such as a knife.

One of ordinary skill will recognize that a particulate material 34 is particularly preferred for the external facing 32. A material having discrete and separate particles allows the facing to be hard and cut resistant without being brittle. This combination allows the food container 10 to be handled, shipped, etc., during normal transportation and use - without breaking, spalling, delamination or chipping of the external facing 32 surface.

It is important that the first surface 11 of the food container 10 be hard yet flexible - rather than hard and brittle. This arrangement further allows the first surface 11 of the food container 10 to be cut-resistant. As used herein, a surface is considered to be "cut-resistant" if the surface allows the user to exert normal pressures while eating cooked and other prepared foods without ordinarily penetrating through the substrate 30 of the food container 10. It is further important that the first surface 11 provides the proper tactile sensation directly to the fingertips and as transmitted through various eating utensils.

It is preferred that the particulate material 34 comprising the external facing 32 have a Mohs hardness of at least 3, preferably at least 7, and even approaching or greater than 9. A Mohs hardness between 6.5 and 7.5 has been found suitable for use with the food container 10 of the claimed invention. The Mohs hardness (scale measured on a 1 to 10 talc to diamond scale) of the particulate materials 34 of the external facing 32 are well documented in reference handbooks such as pages 4-132 to 4-139, 12-93 to 12-97, and 12-205 to 12-206 of The Handbook of Chemistry and Physics, 78^th Edition, 1997-1998 incorporated herein by reference. Of course, the hardness of the particulate material 34 comprising the external facing 32 is determined prior to incorporating the particulate material 34 into or disposing the particulate material 34 on the substrate 30 of the food container 10. By providing a particulate material 34 of the aforementioned hardness, a food container 10 having the proper and preferred tactile sensation is attainable. Such a hardness allows the user to cut foods on the food container 10 with a sharp knife, without experiencing the unpleasant occurrence when the knife cuts through the food container 10, allowing gravy, au jus, etc., to leak through the food container 10.

Furthermore, it has been unexpectedly found that the particulate material 34 has a preferred particle size. The preferred particle size is necessary to impart the tactile sensation of toughness without being unpleasant to the touch. The, user will not be afraid to cut food disposed on such a food container 10 with a sharp knife or other eating utensil.

The particulate material 34 comprising external the facing 32 has a particle size of at least 5 microns, and preferably 10 microns. The particulate material 34 may range in size from 20 to 200 microns, and possibly range from 50 to 200 microns. Particle size is measured using an L3P Sonic Sifter Separator, ATM available from VWR Scientific Products Corp., catalog number 57353-035.

The particulate material 34 comprising the external facing 32 may be a mixture of or several mixtures of mineral and other types of particulates known in the art and commercially available. For example, various particulates comprising alumina, silica, carbonate, oxides, carbides, nitrides, bromides, hard metals, hard alloys, hard elements. If carbides are selected, suitable carbides include tantalum carbide, tungsten carbide, zirconium carbide, beryllium carbide or silicone carbide (carborundum). If a boride is selected, suitable borides include aluminum boride, tantalum boride, zirconium boride, and titanium boride. Boron may also be used. If a nitride is selected, suitable nitrides include aluminum nitride, zirconium nitride and titanium nitride. Metals, including hard metal alloys, such as iron, steel and chromium may be used for the particulate material 34. Ceramics, such as stoneware and particularly porcelain type ceramic particulate materials 34 have been found suitable. More particularly, aluminum oxide (corundum), silicone dioxide (quartz), calcium carbonate, potassium aluminum silicate and feldspar are suitable. Silicone dioxide, calcium carbonate, and aluminum oxide are available from the J.T. Baker Company, a division of Mallincroft Baker, Inc., of Phillipsburg, NJ, under catalog numbers JT3405, JT1301 , and JT0536, respectively.

The particulate material 34 may further comprise clay. A kaolin clay has been found particularly well suited. Suitable kaolin clay is available from the J.T. Baker Company of Phillipsburg, NJ under catalog number JT2242. A suitable mixture for the external facing 32 has been found to be 80% kaolin clay and 20% aluminum oxide. Another suitable mixture has been found to be 80% kaolin clay and 20% calcium carbonate. All percentages described herein are weight percentages, unless otherwise specified.

The particulate material 34, including any optional clay, may be added to a water-based resin to form a coating. An acrylic resin is particularly preferred. A suitable coating may have 50 to 90% resin with 10 to 50% particulate material 34 mixed therein.

A suitable add-on level for the particulate material 34 comprising the external facing 32 of first surface 11 of the food container 10 is from about 0.5 to 100 grams per square meter, and preferably from about 1 to 50 grams per square meter. A round food container 10 having a finished diameter of about 22.9 centimeters and 0.1 to 2 grams of particulate material 34 comprising the external facing 32 has been found suitable.

It is desired that the particulate material 34, including any resin or other carrier used therewith, be applied to the substrate 30 of the food container 10 as a single stratum. The single stratum provides the benefits over the dual strata teachings of the prior art of more precise control of the add-on levels, a single application operation, and is accommodated by a commercial drying operation. In contrast, the dual strata teachings of the prior art require double the inventory of raw materials and double the machinery to apply the particulate material 34 to the substrate 30.

The coating, which ultimately comprises the external facing 32, may be applied to the substrate 30 of the food container 10 after it is formed. The coating comprising the particulate material 34 may be applied by blade coating, printing, or spraying as are known in the art. If blade coating is used, the hardness of the blade must be at least as hard as the particulate material 34. Preferably, an air knife coating process is used to apply the particulate mixture to the substrate 30. Preferably, the substrate 30 of the food container 10 is not dipped into the coating - so that the second surface 12 of the food container 10 remains uncoated. One of ordinary skill will recognize that many variations are feasible. For example, the particulate material 34 may be applied in a gradient. The gradient preferably has a greater add-on level near the center of the food container 10 where more cutting typically occurs in use. Less of the particulate material 34 may be applied to the exposed sides and periphery 16 of the food, which typically function to hold the food within the periphery 16 of food container 10. This allows for conservation of the particulate material 34 as well as concentrating the particulate material 34 in the area which typically receives the greatest wear in use. Such an arrangement provides a Z-direction gradient, with concentration increasing as the center of the food container 10 is approached and decreasing as the edge of the food container 10 is approached.

Alternatively, the particulate material 34 may vary in an XY pattern between regions of the first surface 11 having the particulate material 34 and regions free of the particulate material 34. The particulate material 34 may, for example, be applied in a checkerboard pattern or in stripes. Suitable patterns of stripes include concentric rings, radial lines (either straight or spiral), parallel lines, etc. This arrangement provided the benefit that the food container 10 is flexible in the regions not having the particulate material 34 and yet hard in the regions having the particulate material 34. Thus a food container 10 which has a cut resistant external facing 32 will still result.

Optionally, the external facing 32 may be provided with at least one overcoat (not shown). The overcoat serves to protect the particulate material 34 and the external facing 32 from becoming dislodged from the substrate of the food container 10. Additionally, the overcoat defines and provides a relatively smoother first surface 11. Preferably, the overcoat does not provide a first surface 11 which is too smooth, otherwise the proper tactile sensation may not result. The overcoat(s) may comprise an acrylic resin. Preferably, the acrylic resin is relatively transparent or translucent, so that an aesthetically pleasing first surface 11 will result. The overcoat may be applied by printing, spraying, dipping, blade coating, air knife coating, etc. as known in the art.

Claims

WHAT IS CLAIMED IS :

1. A food container, said food container having a first user facing surface and a second surface opposed thereto, said food container having an external facing juxtaposed with said first surface, characterized in that said external facing consists of a single stratum of a particulate material.

2. A food container according to Claim 1 wherein said particulate material has a Mohs hardness of at least about 3.

3. A food container according to Claims 1 and 2 wherein said external facing further comprises a resin.

4. A food container according to Claims 1 , 2, and 3 wherein said external facing further comprises clay.

5. A food container, said food container having a first user facing surface and a second surface opposed thereto, said food container having an external facing juxtaposed with said first surface, characterized in that said external facing comprises a particulate material having a particle size of at least 5 microns.

6. A food container according to Claim 5 wherein said particulate material ranges in size from 20 to 200 microns.

7. A food container according to Claims 1 , 2, 3, 4, 5, and 6 wherein said particulate material is selected from the group consisting of alumina, silica, carbonates, oxides, silicates, carbides, nitrides, borides, hard metals, hard alloys, and mixtures thereof.

8. A food container, said food container having a first user facing surface and a second surface opposed thereto, said food container further having a central region bounded by a periphery, said food container having an external facing juxtaposed with said first surface, said external facing comprised a particulate material, characterized in that said particulate material is disposed in a gradient, whereby said more particulate material is disposed near the center of the food container than the periphery of the food container.

9. A food container according to Claim 8 comprising a central region and a circumjacent periphery, said circumjacent periphery and said central region being disposed in two different planes and connected by a transition region.

10. A food container, said food container having a first user facing surface and a second surface opposed thereto, said food container having an external facing juxtaposed with said first surface and comprising particulate material, characterized in that said first surface has regions containing said particulate material and regions free of said particulate material.