Patent Publication Number: US-2023151554-A1

Title: Thermoformable dual ovenable recyclable coated cellulosic board, dual ovenable recyclable coated cellulosic board food vessels thermoformed therefrom, and methods for manufacturing and using thereof

Description:
PRIORITY 
     This application claims priority from U.S. Ser. No. 63/279,719 filed on Nov. 16, 2021, the entire contents of which are incorporated herein by reference. 
    
    
     FIELD 
     The present disclosure relates to the field of thermoformable ovenable and microwavable coated cellulosic board, thermoformed ovenable and microwavable coated cellulosic board food vessels, and methods for manufacturing and using thereof. 
     BACKGROUND 
     Some thermoformed ovenable coated paperboard bowls and trays of the related art have layers of heat resistant crystalized polyester terephthalate (PET) extruded thereon that prevent the underlying paperboard from absorbing grease and moisture. However, the PET extrudate makes the containers of the related art difficult to repulp at paper recycling mills, thus inhibiting recyclability. 
     To improve repulpability, there have been attempts to replace the PET extrudate with aqueous-based coatings. In some cases, aqueous-based coated paperboard has been provided for manufacturing of folded ovenable paperboard bowls. In other cases, aqueous-based coated paperboard has been provided for manufacturing of thermoformed ovenable paperboard containers. 
     However, there remains need for a coating system solution to provide for a dual ovenable, repulpable, coated paperboard for thermoforming into a coated paperboard container that is suitable for heating of prepared food products and being aesthetically pleasing to the senses. 
     Accordingly, those skilled in the art continue with research and development in the field of thermoformable ovenable coated cellulosic board, thermoformed ovenable coated cellulosic board food vessels, and methods for manufacturing and using thereof. 
     SUMMARY 
     In one embodiment, a method for manufacturing a thermoformable dual ovenable coated cellulosic board includes rod or press-applied coating of an aqueous-based polyester acrylate copolymer dispersion basecoat on a first major side of a cellulosic board substrate and rod or press-applied coating of an aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the aqueous-based polyester acrylate copolymer dispersion basecoat. 
     In another embodiment, a thermoformable dual ovenable coated cellulosic board includes a cellulosic board substrate having a first major side and a second major side and a multilayer thermoformable dual ovenable coating. The multilayer thermoformable dual ovenable coating includes an aqueous-based polyester acrylate copolymer dispersion basecoat on the first major side of the cellulosic board substrate and an aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the aqueous-based polyester acrylate copolymer dispersion basecoat. 
     In yet another embodiment, a method for manufacturing a thermoformed dual ovenable coated cellulosic board food vessel includes thermoforming the coated cellulosic board into the form of a thermoformed dual ovenable coated cellulosic board food vessel. 
     In yet another embodiment, a thermoformed dual ovenable coated cellulosic board food vessel includes the thermoformed dual ovenable coated cellulosic board in the thermoformed condition. 
     In yet another embodiment, a method for using the thermoformed dual ovenable coated cellulosic board food vessel includes placing a food product on the thermoformed dual ovenable coated cellulosic board food vessel and sealing the food product within the thermoformed dual ovenable coated cellulosic board food vessel. 
     Other embodiments of the disclosed coated cellulosic board, thermoformed dual ovenable coated cellulosic board food vessel, and methods for manufacturing and using thereof, will become apparent from the following detailed description, the accompanying drawings, and the appended claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG.  1    is a side view representation of a coated cellulosic board (e.g., coated paperboard) according to the present description. 
         FIG.  2    is a schematic illustration of an apparatus for producing rolls or sheets of coated cellulosic board (e.g., coated paperboard) of the present description. A preferred method for coating the cellulosic board is by rod applicators. 
         FIG.  3    is a top view of a coated cellulosic board according to the present description in the form of a blank having radial score lines. 
         FIG.  4    is a pictorial view of a thermoformed paperboard food vessel (e.g., tray) having been coated on the inside panels according to the present description. 
         FIG.  5    is an alternate pictorial view of the same thermoformed paperboard food vessel of  FIG.  4   . 
         FIG.  6    is a pictorial view of a thermoformed paperboard food vessel with multiple cavities having been coated on the inside panels according to the present invention. 
         FIG.  7    is a side view representation of a paperboard thermoforming process of the present description. 
     
    
    
     DETAILED DESCRIPTION 
     The present disclosure relates to coated cellulosic board substrates, particularly coated paperboard substrates. A suitable cellulosic board substrate (e.g., paperboard substrate) would preferably be selected to be microwavable and ovenable to at least 400° F. and thermoformable at temperatures of approximately 200-425° F. The suitable cellulosic substrate (e.g., paperboard substrate) should be selected to be recyclable and repulpable. The cellulosic board structure (e.g., paperboard substrate) may take the form of a sheet of material of a suitable size and thickness for the intended application. Hereinafter, the present disclosure will refer to paperboard substrates, but it is understood that any cellulosic board substrate suitable for the intended application may be employed. 
     The paperboard substrate takes the form of a web of paper-based material having a first major side and a second major side. The paperboard substrate may be formed from virgin fibers, recycled fibers, or combinations thereof. The paperboard substrate may be bleached or unbleached. 
     The paperboard substrate may be formed from various grades of hardwood, softwood, or combinations thereof. Preferably the paperboard substrate includes softwood fibers, which have a higher length than hardwood fibers. The long softwood fibers are more conducive to thermoforming. In an example, the paperboard substrate includes at least 1%, by weight, softwood fibers. In another example, the paperboard substrate includes at least 10%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 20%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 30%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 40%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 50%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 60%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 70%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 80%, by weight, softwood fibers. In yet another example, the paperboard substrate includes at least 90%, by weight, softwood fibers. 
     The paperboard substrate may have any suitable thickness for the intended application. In an aspect, a paperboard substrate may have a caliper thickness in a range from about 7 point to about 30 point. In an example, the paperboard substrate has a caliper thickness in a range from about 16 point to about 24 point. A typical paperboard substrate of the present invention may be constructed from about 20 point solid bleached sulphate (SBS) sheet. 
     In an aspect of the present disclosure, the paperboard substrate is preferably not clay-coated on one or both of the first and second major sides. It has been found that the presence of a clay-coating on paperboard substrate, when used for thermoforming, is not ideal, as the clay-coating is prone to cracking or sticking to heated matched metal tools used in the paperboard thermoforming process, for which the temperature of these matched metal tools can range from 200-450° F. Instead, non-clay-coated paperboard substrates have been found to be a more desirable option. The non-clay-coated paperboard substrate may be, for example, a solid bleached sulfate (SBS) substrate or an uncoated natural kraft (UNC) substrate. Typically, the paperboard substrate is most commonly a solid bleached sulfate (SBS) substrate. A suitable paperboard substrate is 20 point WestRock TruServ Pressed Tray, which is an SBS-based resilient paperboard containing softwood fibers that maintains compliance with strict global food safety standards. While uncoated paperboard substrates are suitable for the thermoforming of containers (e.g., bowls or trays), such uncoated paperboard substrates cannot by themselves contain liquids or oils and are unsuitable for use in the distribution of frozen or refrigerated foods. Therefore, the present description provides coatings suitable for thermoformable dual ovenable paperboard substrates. 
     The present disclosure relates to multilayer thermoformable dual ovenable coatings, which include an aqueous-based polyester acrylate copolymer dispersion basecoat and an aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the aqueous-based polyester acrylate copolymer dispersion basecoat. 
     Properties of the aqueous-based polyester acrylate copolymer dispersion basecoat include that the aqueous-based polyester acrylate copolymer dispersion coating serves the function of a basecoat, which is to seal the underlying surface of the paperboard substrate, and that the aqueous-based polyester acrylate copolymer dispersion coating provides for flexibility characteristics at thermoforming temperatures. Thus, the aqueous-based polyester acrylate copolymer dispersion basecoat functions to seal the paperboard surface, provide a flexible base for maintaining topcoat adherence during thermoforming, and provide grease resistance. 
     The aqueous-based polyester acrylate copolymer dispersion basecoat is selected from available aqueous-based polyester acrylate copolymer dispersion coating compositions having sufficient flexibility properties. Preferably, the aqueous-based polyester acrylate copolymer dispersion basecoat does not contain styrene butadiene. Although aqueous-based polyester acrylate copolymer dispersion basecoats containing styrene butadiene can provide for sufficient flexibility properties to function as a basecoat, the presence of styrene butadiene creates an unpleasant odor when heating food in an oven or microwave, thereby causing unpleasant aesthetics so as to be unsuitable for the heating of prepared food products. More preferably, the aqueous-based polyester acrylate copolymer dispersion basecoat is selected from available aqueous-based polyester acrylate copolymer dispersion coating compositions having sufficient flexibility properties without containing styrene butadiene. In an aspect, the aqueous-based polyester acrylate copolymer dispersion basecoat is less than 50% by weight of total polymer units of the aqueous-based polyester acrylate copolymer dispersion basecoat derived from polyester. An exemplary available coating is Jainchem 301. This polyester acrylate copolymer coating composition provides a functional backbone for flexibility and offers a degree of grease resistance. 
     The multilayer thermoformable dual ovenable coatings may incorporate a pigment into the aqueous-based polyester acrylate copolymer dispersion basecoat. When present, the pigment is preferably included in a sufficient amount to provide for substantial opacity to provide for aesthetic appeal. In another aspect of the present disclosure, the pigment is preferably a microwave-safe pigment. The pigment may have any color. For example, the pigment may typically be a black pigment, a brown pigment, or combinations thereof. The pigment may be selected from any known pigment suitable for the intended application. 
     The aqueous-based polyester acrylate copolymer dispersion basecoat may be coated on one or both of the first and second major sides of the paperboard substrate. 
     Preferably, the aqueous-based polyester acrylate copolymer dispersion basecoat is coated directly on, i.e., with no intervening layers, one or both of the first and the second major sides of the paperboard substrate. 
     The aqueous-based polyester acrylate copolymer dispersion basecoat may preferably have a basis weight of about 4 to about 20 dry grams per m 2 . If the basis weight is significantly lower than about 4 dry grams per m 2 , then the aqueous-based polyester acrylate copolymer dispersion basecoat may provide insufficient coverage of the paperboard substrate or may provide insufficient flexibility for topcoat adherence during thermoforming. If the basis weight is significantly greater than about 20 dry grams per m 2 , then the cost of the multilayer thermoformable dual ovenable coating may increase and the repulpability of the multilayer thermoformable dual ovenable coating may be inhibited. In an aspect, the aqueous-based polyester acrylate copolymer dispersion basecoat may have a surface tension in a range of 43 dyne/cm to 60+ dyne/cm. Thus, the defined surface tension is favorable to improve adhesion of the topcoat and provide for a high basis weight of the topcoat. The basecoat may be treated to provide for the desired surface tension, chemically or such as by corona treatment. 
     The topcoat is an aqueous-based polyester acrylate copolymer dispersion barrier topcoat. Thus, the aqueous-based polyester acrylate copolymer dispersion serves as a topcoat to have resistance to blocking after thermoforming and suitability for direct contact with food during heating. The combination of the topcoat with the basecoat provides for improved blocking prevention. Two coatings, i.e., basecoat plus topcoat, are better than one single coating to prevent blocking. Additionally, the aqueous-based polyester acrylate copolymer dispersion barrier topcoat serves a barrier layer, providing for moisture and additional grease barrier properties. Finally, the topcoat also acts as a slip-agent to release the food vessel from the thermoforming tooling. 
     The aqueous-based polyester acrylate copolymer dispersion barrier topcoat is preferably selected from available aqueous-based polyester acrylate copolymer dispersion coating compositions having the desired barrier properties. Preferably, the aqueous-based polyester acrylate copolymer dispersion barrier topcoat does not contain styrene butadiene. The presence of styrene butadiene creates an unpleasant odor when heating food in an oven or microwave, thereby causing unpleasant aesthetics so as to be unsuitable for the heating of prepared food products. More preferably, the aqueous-based polyester acrylate copolymer dispersion barrier topcoat is selected from available aqueous-based polyester acrylate copolymer dispersion coating compositions having the desired barrier properties without containing styrene butadiene. An exemplary available coating composition is Jainchem 820, which is an aqueous-based polyester acrylate copolymer dispersion having the desired barrier properties. 
     The aqueous-based polyester acrylate copolymer dispersion barrier topcoat may be coated on one or both of the first and second major sides of the paperboard substrate. Providing the coatings on both sides of the paperboard substrate acts as a high-heat slip agent for tooling release during thermoforming as well as providing the desired grease and moisture barrier. 
     Preferably, the aqueous-based polyester acrylate copolymer dispersion barrier topcoat is coated directly on, i.e., with no intervening layers, the aqueous-based polyester acrylate copolymer dispersion basecoat. A preferred method for coating the cellulosic board is by rod applicators. 
     Preferably, the aqueous-based polyester acrylate copolymer dispersion barrier topcoat is clear. Thus, the optionally pigmented aqueous-based polyester acrylate copolymer dispersion basecoat can be seen through the aqueous-based polyester acrylate copolymer dispersion barrier topcoat. 
     The aqueous-based polyester acrylate copolymer dispersion barrier topcoat may preferably have a basis weight of about 3 to about 20 dry grams per m 2 . If the basis weight is significantly lower than about 3 dry grams per m 2 , then the aqueous-based polyester acrylate copolymer dispersion barrier topcoat may provide insufficient barrier properties. If the basis weight is significantly greater than about 20 dry grams per m 2 , then the cost of the multilayer thermoformable dual ovenable coating may increase and the repulpability of the multilayer thermoformable dual ovenable coating may be inhibited. 
     Preferably, the aqueous-based polyester acrylate copolymer dispersion basecoat and the aqueous-based polyester acrylate copolymer dispersion barrier topcoat have a combined basis weight of about 7 to about 40 dry grams per m 2 . If the combined basis weight is significantly greater than about 40 dry grams per m 2 , then the cost of the multilayer thermoformable dual ovenable coating may increase and the repulpability of the multilayer thermoformable dual ovenable coating may be inhibited. 
     By combining the basecoat and the topcoat of the present disclosure into a multilayer thermoformable dual ovenable coating, the present disclosure provides for a thermoformable, dual ovenable, repulpable, coated paperboard suitable for thermoforming into a thermoformed, dual ovenable, repulpable, coated paperboard container suitable for heating of prepared food products and being aesthetically pleasing to the senses. 
     Properties of the multilayer thermoformable dual ovenable coating include: (a) mass stability at temperatures below about 400° F., i.e., below 400° F. the coatings will not melt, degrade or otherwise lose mass (for instance, by a solvent outgassing); (b) capable of being tack bonded at temperatures of about 250° F. or greater; (c) chloroform-soluble extractives levels do not exceed about 0.5 mg/in 2  of food contact surface when exposed to a food simulating solvent, for example, N-Heptane at 150° F. for two hours; and (d) is flexible enough to withstand conventional creasing in a cross direction with a 2 point male rule and 0.62 inch channel while sustaining a crack length ratio, defined as total length of cracks per total length of score, of no greater than about 0.1; and (e) exhibits resistance to blocking when stacked at ambient conditions under a load of about 0.5 lbs/sq in or greater; and (f) is resilient enough for thermoforming at temperatures about 200 to about 425° F. without degradation or damage. These properties are important because they assure that the multilayer coating will not crack during thermoforming, contaminate the food in contact with the coating during storage and use of the food vessel, and the blanks or food vessel can be separated by conventional feed systems. 
     Mass stability may be determined by a Thermal Gravimetric Analysis (TGA) plot, which is a measure of the weight of a coating sample plotted against temperature. Any significant weight loss indicates product outgassing. By way of the term “dual ovenable”, it is understood that the coatings of the present description are ovenable and microwavable. By way of the term “ovenable,” it is understood that the coatings of the present description have mass stability at temperatures below about 400° F., i.e., below about 400° F. the coatings will not melt, degrade, or otherwise lose mass (for instance, by a solvent outgassing). By way of the term “microwaveable” means the coating can be placed together with food into a microwave oven and microwaved so as to heat the food without the melting of the coating or otherwise causing transferring of the coating to the food. 
     As further mentioned below, a film (e.g., a PET lidstock film) may be tack bonded at temperatures of 250° F. or greater to the multilayer thermoformable dual ovenable coating to seal a food vessel thermoformed therefrom. One of the aspects of the multilayer thermoformable dual ovenable coating is capability of being tack bonding at temperatures of 250° F. or greater to the aqueous-based polyester acrylate copolymer dispersion barrier topcoat. 
     Chloroform-soluble extractives levels may be determined by an extraction test, which measures non-transfer of substances from the package to the food product. Coated paperboard may be tested by use of an extraction cell described in the “Official Methods of Analysis of the Association of Official Analytical Chemists,” 13th Ed. (1980) sections 21.010-21.015, under “Exposing Flexible Barrier Materials for Extraction.” A suitable food simulating solvent for tray applications described would be N-Heptane. The N-Heptane should be a reagent grade, freshly redistilled before use, using only material boiling at 208° F. The extraction methodology consists of, first, cutting the lid sample to be extracted to a size compatible with the clamping device chosen. Next, the sample to be extracted is placed in the device so that the solvent only contacts the food contact surface. The solvent is then added to the sample holder and placed in an oven for two hours at 150° F. At the end of the exposure period, the test cell is removed from the oven and the solvent is poured into a clean Pyrex® flask or beaker being sure to rinse the test cell with a small quantity of clean solvent. The food-simulating solvent is evaporated to about 100 millimeters in the container, and transferred to a clean, tared evaporating dish. The flask is washed three times with small portions of the Heptane solvent and the solvent is evaporated to a few millimeters on a hot plate. The last few millimeters should be evaporated in an oven maintained at a temperature of approximately 221° F. The evaporating dish is cooled in a desiccator for 30 minutes. A chloroform extraction is then performed by adding 50 milliliters of reagent grade chloroform to the residue. The mix is warmed, filtered through a Whatman No. 41 filter paper in a Pyrex® funnel and the filtrate is collected in a clean, tared evaporating dish. The chloroform extraction is then repeated by washing the filter paper with a second portion of chloroform. This filtrate is added to the original filtrate and the total is evaporated down to a few millimeters on a low temperature hot plate. The last few millimeters should be evaporated in an oven maintained at approximately 221° F. The evaporating dish is cooled in a desiccator for 30 minutes and weighed to the nearest 0.1 milligram to get the chloroform-soluble extractives residue. To be assured that there is no appreciable coating transfer to the food product, the chloroform-soluble extractives should not exceed about 0.5 mg/in 2 . 
     Flexibility of the multilayer thermoformable dual ovenable coating may be determined by using iodine to stain scored areas. The coated paperboard is subjected to conventional creasing in a cross direction with a 2 point male rule and 0.62 inch channel. Iodine is applied to stain scored areas. The iodine technique makes any cracks in the applied coating extremely visible. Cracking on each score is then evaluated as to average crack size and coverage (lengthwise) over a one-inch score area. The crack length ratio, defined as total length of cracks per total length of score, of no greater than about 0.1 is measured. 
     Block resistance of the multilayer thermoformable dual ovenable coating is important when blanks or trays are stacked at ambient temperatures under a load of about 0.5 lbs./sq. in. or greater. Blanks or food vessels of the present disclosure may be stacked after manufacture of the blanks or food vessels. Typically, blanks may be cased (approximately 1000/case) or palletized. The pallets are then stacked creating fairly high (0.5 lbs/sq. in.) loads on the bottom layers of blanks. Food vessels may be “nested” and delivered and shipped in a similar manner. When the food vessels or blanks are unpacked by an end user, they are typically loaded into a mechanical devise which separates the articles and transfers them to a conveyer or sealing device. If the blanks or food vessels have any attraction to one another, the aqueous-based polyester acrylate copolymer dispersion barrier topcoat must have the necessary properties which allows for easy separation. 
     The resiliency of the multilayer thermoformable dual ovenable coating for thermoforming at temperatures about 200° F. to about 425° F. without degradation or damage as a result of the thermoforming processes. It was found that the aqueous-based polyester acrylate copolymer dispersion basecoat alone, i.e., without a topcoat, does not provide resiliency of the multilayer thermoformable dual ovenable coating for thermoforming at temperatures about 200° F. to about 425° F. without degradation or damage. To the contrary, the aqueous-based polyester acrylate copolymer dispersion basecoat alone, i.e., without a topcoat, would result in sticking of the food during cooking. 
     With reference to  FIG.  1   , there is illustrated a side view of an exemplary coated cellulosic board (e.g., coated paperboard). The coated paperboard  1  includes a thermoformable ovenable uncoated paperboard substrate  2  having a first major side  3  and a second major side  4 , a continuous coating of a dried aqueous-based polyester acrylate copolymer dispersion basecoat  5  directly on the first major side  3  of the paperboard substrate  2 , and a continuous coating of a dried aqueous-based polyester acrylate copolymer dispersion barrier topcoat  6  directly on the dried aqueous-based polyester acrylate copolymer dispersion basecoat  5 . The second major side  4  may or may not have its own inks or various aqueous based coatings. For example, the outside surface may include one or both of the aqueous-based polyester acrylate copolymer dispersion basecoat and the aqueous-based polyester acrylate copolymer dispersion barrier topcoat. 
     The present disclosure relates to methods for manufacturing thermoformable dual ovenable coated cellulosic boards (e.g., coated paperboards), including steps of rod or press-applied coating the aqueous-based polyester acrylate copolymer dispersion basecoat on the first major side of the cellulosic board substrate (e.g., paperboard substrate) and rod or press-applied coating an aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the aqueous-based polyester acrylate copolymer dispersion basecoat. 
     In an aspect, the methods for manufacturing thermoformable dual ovenable coated cellulosic boards may include treating the aqueous-based polyester acrylate copolymer dispersion basecoat to have a surface tension in a range of 43 dyne/cm to 60 dyne/cm, such as by corona treatment, followed by the step of rod or press-applied coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the aqueous-based polyester acrylate copolymer dispersion basecoat. 
     The coating steps may be performed by any suitable methods, such as by use of a gravure roll, a flex-coater, a rod coater, an air knife, or a screen blade. A preferred method for coating the cellulosic board is by rod applicators. The step of coating the aqueous-based polyester acrylate copolymer dispersion basecoat and the step of coating an aqueous-based polyester acrylate copolymer dispersion barrier topcoat may employ the same coating method or may employ different coating methods. Rod coating is a preferred embodiment of the present disclosure for both the step of coating the aqueous-based polyester acrylate copolymer dispersion basecoat and the step of coating an aqueous-based polyester acrylate copolymer dispersion barrier topcoat. 
     In an aspect, the step of coating the aqueous-based polyester acrylate copolymer dispersion basecoat comprises coating the aqueous-based polyester acrylate copolymer dispersion basecoat to a basis weight of about 4 to about 20 dry grams per m 2 . In another aspect, the step of coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat comprising coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat to a basis weight of about 3 to about 20 dry grams per m 2 . In yet another aspect, the aqueous-based polyester acrylate copolymer dispersion basecoat and the aqueous-based polyester acrylate copolymer dispersion barrier topcoat have a combined basis weight of about 7 to about 40 dry grams per m 2 . 
     The step of coating the aqueous-based polyester acrylate copolymer dispersion basecoat may include-dispersion coating the aqueous-based polyester acrylate copolymer dispersion basecoat on the second major side of the cellulosic board substrate (e.g., paperboard substrate). 
     The step of coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat may include coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat on a second major side of the cellulosic board substrate (e.g., paperboard substrate). For example, the step of coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat may include dispersion coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the aqueous-based polyester acrylate copolymer dispersion basecoat on the second major side of the cellulosic board substrate. 
     In an aspect, the step of dispersion coating aqueous-based polyester acrylate copolymer dispersion basecoat on the second major side of the cellulosic board substrate may include coating the aqueous-based polyester acrylate copolymer dispersion basecoat to a basis weight of about 4 to about 20 dry grams per m 2 . In another aspect, the step of coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the second major side of the cellulosic board substrate may include coating the aqueous-based polyester acrylate copolymer dispersion barrier topcoat to a basis weight of about 3 to about 20 dry grams per m 2 . In yet another aspect, the aqueous-based polyester acrylate copolymer dispersion basecoat and the aqueous-based polyester acrylate copolymer dispersion barrier topcoat on the second major side of the cellulosic board substrate may have a combined basis weight of about 7 to about 40 dry grams per m 2 . 
       FIG.  2    illustrates a schematic illustration of an exemplary apparatus  10  for producing rolls or sheets of coated cellulosic board (e.g., coated paperboard) of the present description, in particular a reel handling system  10 . This illustration depicts production of coated paperboard blanks. In particular, the apparatus  10  may include a paper roll  12 , a paperboard substrate  2  in the form of a paperboard roll web  14 , a first coating station  16 , a first coating dryer  18 , printing station  20 , curing station  22 , a second coating station  24 , a second coating dryer  26 , cutters  28 , resulting in coated paperboard blanks. A preferred method for coating the cellulosic board is by rod applicators. 
     During the operation of apparatus  10 , paper roll  12  is unrolled such that paperboard roll web  14  is formed. Paperboard roll web  14  is traversed along apparatus  10  by conventional techniques to first coating station  16 . At the first coating station  16 , paperboard roll web  14  is coated with the aqueous-based polyester acrylate copolymer dispersion basecoat  5  of the present description on the first major side  3  of the paperboard roll web  14 . The aqueous-based polyester acrylate copolymer dispersion basecoat  5  may be continuously applied or patterned applied at the first coating station  16  on the first major side  3  of the paperboard roll web  14  by any conventional coating technique (e.g., a gravure roll, a flex-coater, a rod coater, an air knife, a screen blade) mentioned earlier at a deposition rate of, preferably, about 4 to about 20 dry grams per m 2  for the basecoat  5 . Rod coating is a preferred embodiment of the present disclosure. Following the application of the aqueous-based polyester acrylate copolymer dispersion basecoat  5  upon paperboard roll web  14 , paperboard roll web  14  is traversed to a first coating dryer  18  where the aqueous-based polyester acrylate copolymer dispersion basecoat is dried. After drying, the paperboard roll web  14  may be cooled through contact with conventional drum chillers (not shown). The paperboard roll web  14  is traversed to graphics printing station  20  where graphics such as sales and information graphics as well as other inks or coatings may be applied upon paperboard roll web  14 . Inks may then be cured at curing station  22 . For example, radiation curable inks may be applied at graphics printing station  20  and cured at curing station  22 . After curing the inks, the paperboard roll web  14  is traversed along apparatus  10  by conventional techniques to second coating station  24 . At the second coating station  24 , paperboard roll web  14  is coated with the aqueous-based polyester acrylate copolymer dispersion barrier topcoat  6  of the present description on the aqueous-based polyester acrylate copolymer dispersion basecoat  5 . The aqueous-based polyester acrylate copolymer dispersion barrier topcoat  6  may be continuously applied or patterned applied at the second coating station  24  by any conventional coating technique (e.g., a gravure roll, a flex-coater, a rod coater, an air knife, a screen blade) mentioned earlier at a deposition rate of, preferably, about 3 to about 20 dry grams per m 2  for the topcoat. Rod coating is a preferred embodiment of the present disclosure. Following the application of the aqueous-based polyester acrylate copolymer dispersion barrier topcoat  6  upon paperboard roll web  14 , paperboard roll web  14  is traversed to a second coating dryer  26  where the aqueous-based polyester acrylate copolymer dispersion barrier topcoat  6  is dried. The process depicted in  FIG.  2    is illustrated as continuous, but the process can be broken into steps at the same or different facilities.  FIG.  2    is only one exemplary sequence as related to the application of the basecoat  5 , topcoat  6 , and optional graphics of the present description. Following the application of basecoat  5  and topcoat  6 , paperboard roll web  14  is traversed to cutting mechanism (e.g., cutters  28 ) which cuts the paperboard roll web  14  into the desired blank size and scores the blank to provide desired score lines (e.g., radial score lines) for subsequent thermoforming. For example, the cutting mechanism may be a rotary cutting system. Alternatively, one may choose to wind the paperboard roll web  14  in roll form or sheet the web for cutting and scoring at a later time. 
     The present disclosure relates to coated cellulosic board substrates in the form of a blank.  FIG.  3    is a top view of an exemplary coated cellulosic board according to the present description in the form of a blank  35  having radial score lines  36  suitable for thermoforming. The blank  35  has multiple score lines  36  that are close together at each corner of the blank  35 . The score lines  36  enable for the formation of pleats that result when the blank  35  is thermoformed. The coating of the present description do not crack or otherwise get damaged when the score lines  36  become pleats to ensure for the desired barrier properties. The illustrated score lines  36  are one exemplary representation of radial score lines. Actual scoring may be more or less. 
     The present disclosure relates to methods for manufacturing a thermoformed dual ovenable coated cellulosic board food vessel, in which the coated cellulosic board as previously described is thermoformed into the form of a thermoformed dual ovenable coated cellulosic board food vessel. 
     The thermoforming may be performed in any conventional manner. For example, thermoforming may be performed using thermoforming machines manufactured by Peerless Machine or Gralex Industries. A specific exemplary thermoforming process is described as follows. 
     Typically, a web of coated paperboard to be thermoformed into a paperboard food vessel are blanked and scored and delivered to a thermoforming press  70  as a stack of blanks.  FIG.  6    is schematic representation of a cross-section of a male die  72  and a female die  74  of the thermoforming press  70  used for thermoforming the blank  35  into a paperboard food vessel (e.g., tray or bowl). It will be understood that the male die  72  and the female die  74  as illustrated in  FIG.  6    are merely exemplary, and that thermoforming systems may include a variety of modifications and alternatives including but not limited dividers and cavities. 
     At the thermoforming press  70 , the blank  35  is thermoformed with the male die  72  and the female die  74  using heat and pressure to form a paperboard food vessel. 
     Thus, the blank  35  is heated, drawn into the temperature-controlled female die  74  by the temperature-controlled male die  72 , and then held against the surfaces of the male die  72  and female die  74  until cooled. 
     The temperature of the female-die  74  is controlled to be at a higher temperature than the male die  72 . The first major side  3  of the paperboard substrate  2  is arranged to face the male die  72  and the second major side  4  of the paperboard substrate  2  is arranged to face the female die  74 . 
     If the temperature of the male die  72  is too low, then the basecoat  5  and topcoat  6  as well as the paperboard substrate  2  may be insufficiently heated and the resulting paperboard food vessel may not be strongly formed to the desired shape. If the temperature of the male die  72  is too high, then the basecoat  5  and/or topcoat  6  may stick to the male die  72 . Accordingly, in an aspect, the male die  72  preferably has a temperature of approximately 80-220° F. If the paperboard substrate  2  were to have clay coating that substrate may stick in the thermoform tooling. In an aspect, the female die may have a temperature of approximately 200-425° F. 
     In an aspect, a moisture content of the coated paperboard  1  is controlled during the thermoforming process. The moisture content may be controlled by, for example, using a humidifier to control an atmospheric humidity or addition of moisture directly to the coated paperboard. 
     If the moisture content of the coated paperboard  1  is too high, then blistering of the basecoat  5  and/or topcoat  6  may occur. If the moisture content of the coated paperboard  1  is too low, then corner cracking of the paperboard substrate  2  and the basecoat  5  and/or topcoat  6  may occur. In an aspect, the moisture of the coated paperboard  1  is controlled between 9 and 14% by weight. In another aspect, the moisture of the coated paperboard  1  is controlled between 10 and 13% by weight. 
     The present disclosure relates to coated cellulosic board food vessels. The coated cellulosic board food vessels are thermoformed from the previously described coated cellulosic board. The thermoforming may be performed in any manner, such by way of the thermoforming methods described above. 
     The structure of the coated cellulosic board food vessels are not limited. In an aspect, the coated cellulosic board food vessel may include a coated bottom panel and a coated sidewall panel. In another aspect, the coated cellulosic board food vessel may include a coated bottom panel, a coated sidewall panel, and a coated flange panel. 
     An exemplary food vessel in the form of a food tray is illustrated in  FIGS.  3  and  4   . With reference to  FIG.  3   , there is illustrated a thermoformed paperboard food tray  30 . Food tray  30  may include in part, a coated bottom panel  31 , coated sidewall panel  32 , and a coated flange panel  33 . The coated panels may be comprised of the coated paperboard  1  of  FIG.  1   . The coated flange panel  33  can be tack bonded to PET lidstock film, heat-seal coated cellulosic board or similar at temperatures of 250° F. or greater.  FIG.  4    is an alternate view of the same food tray  30  and constituent panels  31 ,  32 ,  33 . 
     An exemplary food vessel in the form of a food tray is illustrated in  FIG.  5   . With reference to  FIG.  5   , food tray  40  may include in part, tray compartments  44 , flange  46  and top surface  48 . The top surface  48  may correspond to the first major side  3  (having basecoat  5  and topcoat  6 ) in  FIG.  1   . The coated flange  46  can be tack bonded to PET lidstock film, heat-seal coated cellulosic board or similar at temperatures of 250° F. or greater. The food tray  40  in  FIG.  5    may be cut from a paperboard sheet or web of a great length. 
     The present disclosure relates to methods of using coated cellulosic board food vessels. In an aspect, a method of using the coated cellulosic board food vessels as previously describe may include placing a food product on the thermoformed dual ovenable coated cellulosic board food vessel and sealing the food product within the thermoformed dual ovenable coated cellulosic board food vessel. 
     The sealing of the food product within the thermoformed dual ovenable coated cellulosic board food vessel may be performed by any suitable conventional method. In an exemplary aspect, the sealing of the thermoformed dual ovenable coated cellulosic board food vessel may include tack bonding a film to the thermoformed dual ovenable coated cellulosic board food vessel, particularly a flange of the thermoformed dual ovenable coated cellulosic board food vessel. 
     Although various embodiments of the disclosed coated cellulosic board, thermoformed dual ovenable coated cellulosic board food vessel, and methods for manufacturing and using thereof, have been shown and described, modifications may occur to those skilled in the art upon reading the specification. The present application includes such modifications and is limited only by the scope of the claims.