EP0074998A1 - Metallized film-paper - Google Patents

Abstract

Laminated paper covered with a metallic plastic film intended for use as decorative wrapping paper as well as for reflective insulation. The metal laminate comprises a base layer of paper sheet, a film of thermoplastic polymer extruded on one surface of the paper layer, and a thin metal layer deposited on the free surface of the plastic film in such a way that the plastic film is sandwiched between the metal layer and the sheet of paper. The resulting lamin has high strength and a metallic sheen with very low weight of the base paper and can be used as decorative wrapping paper either as it is or by printing symbols or drawings thereon.

Description

METALLIZED FILM PAPER

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to metallized paper and more particularly to metallized paper having a thermoplastic film sandwiched between the metallic layer and the paper.

2. Description of the Prior Art

The prior art discloses methods of depositing a metallic layer onto paper.

Direct metallization of paper in a high vacuum metalli¬ zation chamber is known. However, direct metallization has been found to have significant disadvantages. Particularly when one of the more useful metals, such as aluminum, is used in direct metallization of paper, the resulting product has a dull gray lustre instead of the desired metallic appearance. Also in direct metallization of paper, the resulting product has very poor barrier properties; namely, the product tends to be porous and permeable to water vapor, oxygen, and other gases. It has also been found necessary to degas the paper prior to the high vacuum metallization in order to release gases and water vapor which have been absorbed into the paper and which would adversely affect the metallization process if not removed.

In view of these disadvantages in direct metallization of paper, improvements such as coating the paper sheet with a solvent-based polymer coating or aqueous dispersion of resi¬ nous polymer prior to the metallization step have been de¬ scribed in the prior art. For example, an aqueous dispersion of resinous polymer used to coat a paper sheet is discussed in U.S. Patent 3₉H3_S888. The aqueous dispersion of.polymer is claimed to enhance the brilliance of the metallized surface and eliminate the need for degassing prior to metallization. How¬ ever, coating by aqueous or solvent dispersion of high polymer requires that the coating and/or drying steps be carried out at specific temperatures and under stringent process control, adding significantly to the cost of the finished product. A metallized laminate having high tensile strength cannot be manufactured effectively by aqueous or solvent-based coating methods for thin paperj e.g. paper having a basis weight less than 28 g/m . Furthermore, in order to obtain a suitable de¬ gree of brightness on paper, it has been necessary to apply one or more coatings to the surface of the paper, to obtain a glossy, smooth, non-porous surface. While it is theoretically possible to apply these coatings on a paper machine at the papermill level, in practice, these coatings are generally applied as a separate coating operation, adding additional cost to this substrate. Further, it has been difficult to apply suitable coatings to very lightweight porous tissues, these light tissues being weak and difficult to run through multistage converting operations without breaking. Vacuum metallizing is most often a batch process, and a web break during the metallizing process will cause delay ti-r.es of 15-60 minutes to repair the break and bring the ^"chamber down to the desired vacuum.

Applicants have determined that the disadvantages of direct metallization of paper or of metallization of aqueous polymer dispersion or. solvent-coated paper can be overcome by extruding a thermoplastic film onto a fibrous material such as tissue, paper or cardboard prior to the vacuum metallizing step. Although processes for extruding a thermoplastic film onto a paper sheet, per se, are known, a substrate composed of thermoplastic film extruded onto paper has not been used heretofore as a substrate for metallizing to produce a laminate product having the desirable, physical characteristics which applicants have achieved.

The extrusion of thermoplastic film onto the paper sheet prior to metallization is believed to be more economical than the water-based polymer dispersion method described in U.S. Patent 3_SH3₃888 and can be more readily controlled than con¬ ventional solvent or water-based-polymer coating techniques.

The product. of the present •invention exhibits excellent resistance to moisture vapor transmission, resistance to oxygen, grease and oil absorption, and has been found to have exceptional qualities of metallic smoothness and gloss. Surprisingly, the product of the present invention ex- ^■ hibits significantly improved bursting strength, tensile strength, and high metallic brilliance heretofore unachiev¬ able for tissue thin paper; e.g., for paper having a basis weight less than about 28 g/m and is a low-cost substitute for paper foil laminates such as gift wrap, labels, food wraps, decorative trims, and reflective insulating.

OMPI --21-

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a decorative wrapping product having a layer on one side and a smooth, glossy metallic appearance on the other side.

It is an important object of the present invention that the wrapping product exhibit improved bursting strength and tensile strength for a broad range of paper weights including very thin paper base layers.

It is a further object of the invention to provide a wrapping product that is flexible, yet strong, and which ex¬ hibits superior resistance to moisture vapor transmission, grease, oil and oxygen even for very thin paper base layers.

It has been determined that, when a thermoplastic mater¬ ial, preferably polyethylene or polypropylene, particularly low density polyethylene, is extruded onto one side of a paper sheet (base layer) thus forming a plastic paper substrate, the substrate may be exposed directly to conventional high vacuum metallization process to coat the exposed thermoplastic sur¬ face of the substrate with a thin metallic surface, prefer¬ ably aluminum. The resulting product is a decorative wrap having a smooth, metallic lustre on one side and improved physical property characteristics.

Particularly the finished product exhibits the handling and flexibility of paper but yet has significantly improved bursting and tensile strength and a high metallic brilliance. The finished product also exhibits barrier properties; i.e., resistance to moisture vapor transmission, grease, and oxygen even for very thin paper base layers.

The significant increase in the bursting, tensile strengths and metallic brilliance achieved for a finished metallised paper product of very low basis weight was surpris¬ ing and was not anticipated prior to applying the process of the invention.

The present invention thus results in a wrapping product which exhibits significantly improved strength and flexibil¬ ity and high metallic brilliance for a broad range of thin paper thicknesses; e.g., for paper base layers typically be-

2 2 tween 17 g/m and 32 g/m basis weight including very thin paper such as paper having a basis weight of less than about

28 g/m².

In the present invention, the reason for the high metal¬ lic brilliance achieved when depositing the metallic layer directly onto the exposed surface of the extruded plastic film is not fully understood. It is theorized that the high brilliance may be due to surface reaction occuring between the metal surface and the thin polymer film layer which may be en¬ hancing the reflective properties of the film. Applicants also theorize that the surprising high metallic brilliance may be caused by microscopic craters or irregularities in the polymer surface which may result when using a highly polished chill roller after the extrusion step for very thin polymer layers, particularly between about 5-»β g/m 2 to 11 g/m2.

Development of such microscopic irregularities in the polymer surface when exposing very.thin polymer layers to a highly polished chill roller followed by metallization was surprising. It is theorized that the irregularities in the polymer surface, contribute to the enhanced reflective properties of the polymer and consequently to that of the metallic layer thus markedly increasing the saleability of the product.

The product also exhibits barrier properties, such as re¬ sistance to moisture vapor transmission, oil, grease and oxygen absorption even at paper sheets having a basis weight as low as

2 about 17 g/m and for finished metallized products having a

2 basis weight as low as 22.6 g/m .

The finished metallized product exhibits barrier proper¬ ties at high, glossy metallic lustre and high tensile strength

2 for paper sheets tissue thin; e.g., as low as even 17 g/m basis weight paper. The process of the invention can also be practically utilized to achieve the above-enumerated desirable physical characteristics for heavier paper, for example, paper having a basis weight between about 17 g/m 2 to 50 g/m2 and as

2 high as 80 g/m or even higher. The polymer film itself can have a basis weight as low as about 5-6 g/m 2 to 11 g/m2 and

2 _2 2 up to 25 g/m and the metallic layer about 5 x 10 g/m when

2 thin, lightweight paper of about 24 g/m basis weight is used. The base layer may be composed of fibrous material such as tissue, paper, cardboard or woven or nonwoven fabric. In addition to use as a gift wrap, the finished metallized pro¬ duct may be used as a packaging wrap or as a backing material, label or reflective insulator. The metallic layer may also be overprinted with indicia or designs or may be selectively re¬ moved to create such designs or indicia. The metallized pro¬ duct can also be laminated to heavier board or coated with pressure sensitive adhesive to form pressure sensitive labels.

The process of the invention has particular advantages over prior art methods as discussed in the foregoing descrip¬ tion of the prior art. Furthermore, since thin lightweight paper can be used in applicants' process, an important addi¬ tional advantage is realized in that more paper can be pro-^' cessed per batch run through conventional high vacuum metal- lizers resulting in increased productivity and considerable cost savings in time and labor. Also the use of very thin

2 lightweight paper; e.g. basis weight as low as about 17 g/m in addition to increasing productivity permits applicants to reduce material costs and realize additional savings in storage and shipping costs.

The present invention also has the advantage of not only obviating the need to apply solvent-based or aqueous disper¬ sion coating to the paper prior to metallization but also a smooth, high metallic brilliance is obtained without applica¬ tion of a lacquer or other coating to the metallic surface after metallization as taught in conventional methods.

In sum, a finished wrapping or reflective insulator product having a high, metallic brilliance, excellent resist¬ ance to moisture, grease, oil and oxygen, and significantly improved bursting strength, tensile strength and flexibility surprisingly even for very thin tissue light paper, is achieved. The resulting product is an improved saleable pro¬ duct manufactured at considerable cost savings. DESCRIPTION OF THE PREFERRED EMBODIMENT

A preferred metallized laminate sheet of the invention is comprised of a paper base layer sheet, a thermoplastic polymer film extruded onto the paper base layer, and a metallic layer deposited onto the free surface of the polymer film so that the polymer film is sandwiched between the metallic layer and the paper base layer. The base layer is preferably a paper or fibrous sheet but may also be of a woven or nonwoven fabric. The thermoplastic film preferably is polyethylene film, more preferably low density polyethylene film. Polypro¬ pylene film is also a preferred film but other extrudable thermoplastics are within the scope of the invention. For-ex¬ ample, suitable thermoplastics may include pol olefins; vinyls such as polyvinyl chloride and polyyinylidene chloride; poly¬ esters such as polyethylene terephthalate; styrenes such as polystyrene; and acrylates such as polymethylmethacrylate and nylon. The base layer may typically have a basis weight in the range between about 17 g/m 2 to 50 g/m2 for thin to heavier weight paper or even cardboard having a basis weight of about

2 80 g/m may be used. The base layer may have a. basis weight

2 of between about 17 to 32 g/m for thin, light-weight paper.

The polymer film may have a basis weight as low as about

5.6 g/m 2 to 11 g/m2 and typically may be as high as about 25 g/m 2, and the metallic layer about 5 x 10—2 g/m2 or having a

2 resistance typically of about 2-4 ohm/cm .

In addition to use as a decorative wrapping paper, the product of the invention may be used as a packaging wrap, backing paper or to form labels or reflective sheets and rolls for insulation; for example, in building construction. The metallic layer may serve a number of functions. Principally, it has a decorative purpose, since it creates a brilliant metallic surface. Print coats may be applied to the surface of the metallic layer to enhance its printabilit , and the metallic layer may also be overprinted with indicia or designs.

Alternatively, the metallic layer may be selectively removed in order to create such designs or indicia.

OMPI Test analysis of the physical property characteristics of the metallized laminate of the invention for a tissue thin paper base layer is presented in the example. As may be noted from inspection of the example, the metallized laminate exhibits significantly improved bursting strength, tensile strength and barrier properties and exhibits a high metallic brilliance.

The process of manufacture employs simply the steps of extruding the thermoplastic film uniformly onto a side of the paper base layer by use of conventional extrusion techniques to form a polymer film coated paper substrate; subjecting the poisoner film coated paper substrate preferably to a chill rolling step employing highly polished chill rollers; and then passing the substrate to conventional high vacuum paper metallization equipment wherein a thin, metallic layer, preferably aluminum is deposited onto the free surface of the polymer film.

An example illustrative of the method of manufacture and physical property characteristicsof the metallized laminate product is set forth as follows:

EXAMPLE I A.M.G. bleached Kraft tissue having the following typical physical properties was used as the base layer:

Basis Weight: 21.4 g/m

Caliper: 1.3 mils

Tensile Strength:

M.D. lbs./inch width 7

(Machine Direction)

CD. lbs./inch width 4

(Cross Direction)

Moisture Vapor Transmission Rate Negligible resistance to moisture vapor transmission EXAMPLE I (CONTINUED) Mullen Burst Strength 7 lbs./In.² (ASTM D774-67(197D) Brightness (MgO = 100%) Negligible

A polyethylene film was extruded onto this base layer tissue by use of extrusion coating methods for extruding a thermoplastic film onto a paper sheet to form a film coated paper substrate. The substrate was passed preferably through highly polished chrome chill rollers immediately after the extrusion of the film onto the paper sheet. The extruded polyethylene film layer had a basis weight of 5.8 g/m² and a density of 0.917 g /cm-- with a melt index of 12.0. The polyethylene-coated tissue was then subjected to a conventional high vacuum metallization, resulting in the deposition of enough aluminum to give a surface resistance of 2-4 ohms per square centimeter.

After completion of the metallizing step, the metallized laminate product had the following typical physical properties: Basis Weight: 27-2 g/m²

Caliper: 1.4 mils

Tensile Strength:

M.D. lbs.inch width 8.4 (Machine Direction)

CD. lbs./inch width 6.2 (Cross Direction) Mullen Burst Strength 9-0 lbs./In² (ASTM D 774-67 (197D Moisture Vapor Transmission Rate (Gms/100 In ² /24 hours) 2.8 Brightness: (MgO = 100%) 61.5 Although a tissue thin paper base layer was used, the metallized laminate had the handling properties and flexibility of paper but yet significantly improved bursting strength and tensile strength for its low basis weight. The

-^REA metallized laminate also exhibited exceptionally high metallic brilliance. After the metallization step, the laminate product is suitable for use directly as a decorative or packaging wrap or as a reflective insulator. However, the laminate product may be subjected to additional processing wherein print coats, commonly available from ink manufacturers, may be applied to the surface of the aluminum to enhance its printability.

The metallized laminate can be subjected to other processing, depending on the desired end use; for example, the metallized product can be laminated to heavier board, or coated with pressure sensitive adhesive to form pressure sensitive labels.

While the present invention has been described with reference to specific preferred embodiments, it should be appreciated that variations are possible without departing from the scope of the invention. Therefore, the invention is not intended to be limited by the description in the specification but only by the language of the claims and equivalents thereof.

O PI

Claims

CLAIMS-11-

1. A laminate comprising a base member, a thermoplastic polymer layer extruded upon said base member, and a metallized layer deposited upon the extruded thermoplastic polymer.

2. A laminate as defined in claim 1 wherein said thermo¬ plastic polymer layer constitutes a single continuous film.

3. A laminate as defined in claim 2 wherein said poly¬ mer film has a basis weight in the range between about

4. A laminate as defined in claim 1 wherein said polymer is polyethylene.

5. A laminate as defined in claim 4 wherein said poly¬ ethylene has a density less than high density polyethylene.

6. A laminate as defined in claim 1 wherein the thermo¬ plastic polymer film is selected from the group consisting of polyethylene, polypropylene, polyvinylchloride, polyvinyl- idene chloride, polyethylene terephthalate, polystyrene, and polymethylmethacrylate.

7- A laminate as defined in claim 1 wherein the base member is a sheet having a basis weight of between about 17 g/m² to about 80 g/m².

8. A laminate as defined in claim 1 wherein the metal¬ lized layer is vapor deposited upon the extruded thermoplastic polymer.

9. A process of manufacturing the product of claim 1, comprising the steps of extruding a thermoplastic polymer layer upon a base member, and vapor depositing a metallized layer upon the thermoplastic polymer layer.

10 . The process of claim 9 further including the step of impressing the thermoplastic polymer layer with a chilled roller before metallization .