The present specification generally relates to composite containers and, more specifically, to composite containers for storing perishable products.
Closed containers may be utilized for the storage of perishable products such as, for example, humidity and/or oxygen sensitive solid food products. Such closed containers may be formed from a tubular body having an outwardly rolled top rim and an open bottom end. The open bottom end may be sealed with a bottom made of metal or a composite material. Specifically, the bottom of the tubular body may be sealed by crimping a metal bottom end using seaming techniques such as a double seaming technique. Alternatively, the bottom of the tubular body may be sealed by adhering a composite bottom end to a tubular body.
However, metal bottoms may increase the overall weight of the closed container, which may result in increased energy usage and increased emissions during manufacture of the closed container. Closed containers having composite bottoms are commonly produced using inefficient manufacturing process having less than optimal production rates. Furthermore, closed containers having composite bottoms are prone to manufacturing flaws such as pin holes, pleats, cuts or cracking.
Accordingly, a need exists for alternative composite containers for storing perishable products.
In one example, a composite container for storing perishable products may include a composite body and a composite bottom. The composite body may be formed into a partial enclosure having an interior surface and an exterior surface. The interior surface and the exterior surface may extend from a bottom end of the composite body to a top end of the composite body and the bottom end of the composite body may terminate at a bottom edge of the composite body. The composite bottom may include a bottom fiber layer, a bottom oxygen bather layer, and a bottom sealant layer, such that the composite bottom has an upper surface and a lower surface. The composite bottom may include a platen portion connected to a sealing portion. A hermetic seal may be formed between the sealing portion of the composite bottom and the interior surface of the composite body. When an internal pressure is applied to the interior surface of the composite body and the upper surface of the platen portion of the composite bottom, an external pressure is applied to the exterior surface of the composite body and the lower surface of the composite bottom, and the internal pressure is about 20 kPa greater than the external pressure, the platen portion of the composite bottom may not extend beyond the bottom edge of the composite body.
In another example, a composite container for storing perishable products may include a composite body and a composite bottom. The composite body may be formed into a partial enclosure having an interior surface and an exterior surface. The interior surface and the exterior surface may extend from a bottom end of the composite body to a top end of the composite body and the bottom end of the composite body may terminate at a bottom edge of the composite body. The composite bottom may include a platen portion, a radius portion, and a sealing portion. The platen portion may extend to the radius portion and the radius portion may extend to the sealing portion such that the radius portion forms a radius angle between the platen portion and the sealing portion. The composite bottom may include a bottom fiber layer, a bottom oxygen bather layer, and a bottom sealant layer. The composite bottom can have an upper surface and a lower surface. The upper surface of the composite bottom and the lower surface of the composite bottom may terminate at a lower edge of the composite bottom. At least a portion of the composite bottom may be recessed inside the composite body such that the lower edge of the composite bottom is spaced an edge distance away from the bottom edge of the composite body. A hermetic seal may be formed between the sealing portion of the composite bottom and the interior surface of the composite body.
In yet another example, a composite container for storing perishable products may include a composite body, a closure seal and a composite bottom. The composite body may be formed into a partial enclosure having an interior surface and an exterior surface. The interior surface and the exterior surface may extend from a bottom end of the composite body to a top end of the composite body. The composite body may include a body sealant layer that forms at least a portion of the interior surface of the composite body. The closure seal may be hermetically sealed to the body sealant layer at the top end of the composite body. The composite bottom may include a bottom fiber layer, a bottom oxygen barrier layer, and a bottom sealant layer, such that the composite bottom has an upper surface and a lower surface. The bottom sealant layer of the composite bottom may be hermetically sealed to the body sealant layer at the bottom end of the composite body. An internal volume may be enclosed by the interior surface of the composite body, the closure seal, and the upper surface of the composite bottom. A solid food product stored within the internal volume may be shelf stable for 15 months such that a moisture gain of the solid food product is less than 1% per gram of the solid food product.
These and additional features provided by the examples described herein will be more fully understood in view of the following detailed description, in conjunction with the drawings.
The examples set forth in the drawings are illustrative and exemplary in nature and not intended to limit the subject matter defined by the claims. The following detailed description of the illustrative examples can be understood when read in conjunction with the following drawings, where like structure is indicated with like reference numerals and in which:
The examples described herein relate to high barrier packages for perishable products such as hermetically closed containers for packaging humidity and oxygen sensitive solid food products. The hermetically closed containers described herein may be capable of sustaining a variety of atmospheric conditions. More specifically, the hermetically closed containers may be suitable for maintaining the freshness of crisp food products such as, for example, potato chips, processed potato snacks, nuts, and the like. As used herein, the term “hermetic” refers to the property of sustaining an oxygen (O2) level with a barrier such as, for example, a seal, a surface or a container.
Hermetically closed containers formed according to the examples described herein may include a composite bottom which is shaped and sealed (e.g., via a heated pressing tool) without causing pin holes, pleats, cuts or cracking of the closed container. Thus, when solid crisp food products, which can deteriorate when exposed to humidity or oxygen, are sealed within a hermetically closed container that has a lower probability of having pin holes, pleats, cuts or cracking of the barrier layers, the probability of product deterioration can be reduced. Accordingly, such hermetically closed containers may be capable of enclosing a substantially stable environment (i.e., oxygen, humidity and/or pressure) without bulging and/or leaking.
Furthermore it is noted, that such hermetically closed containers may be transported worldwide via, for example, shipping, air transport or rail. Thus, the containers may be subjected to varying atmospheric conditions (e.g., caused by variations in temperature, variations in humidity, and variations in altitude). For example, such conditions may cause a significant pressure difference between the interior and the exterior of the hermetically closed container. Moreover, the atmospheric conditions may cycle between relatively high and relatively low values, which may exacerbate existing manufacturing defects. Specifically, the hermetically closed container may be subject to strains that lead to defect growth, i.e., the dimensions of for example, pin holes, pleats, cuts or cracks resulting from the manufacturing process may be increased. The hermetically closed containers, described herein, may be transported and/or stored under widely differing climate conditions (i.e., temperature, humidity and/or pressure) without defect growth.
Moreover, in some examples, the hermetically closed container may be formed of material having sufficient rigidity to resist deformation while subjected to varying atmospheric conditions. Specifically, when a hermetically closed container containing a high internal pressure is subjected to ambient conditions at a relatively high altitude (e.g., about 1,524 meters above sea level, about 3,048 meters above sea level, or about 4,572 meters above sea level), the pressure differential between the interior and the exterior of the hermetically closed container may exert a force upon the hermetically closed container (e.g., acting to cause the hermetically closed container to bulge out). Depending upon the shape of the hermetically closed container, any bulging may cause the hermetically closed container to deform, which may lead to unstable behavior on the shelf (e.g., wobbling and rocking) and may negatively influence purchase behavior. In further examples, the hermetically closed containers described herein may be formed from material having sufficient strength, surface friction, and heat stability for rapid manufacturing (i.e., high cycle output machine types and/or manufacturing lines).
The hermetically closed containers described herein may include a metal bottom or a composite bottom. Hermetically closed containers including a metal bottom may be recycled (e.g., in a range of countries, the metal may be separated from the hermetically closed containers prior to being recycled). While, hermetically closed containers including a composite bottom may also be recycled. For example, when the composite bottom is made from similar material as the remainder of the hermetically closed container, the entire container may be recycled without separation. Moreover, such hermetically closed containers may be manufactured according to the methods described herein, which may provide environmental benefits through a reduction in the environmental impact of the container manufacturing process.
Referring still to
The composite body 10 may be any shape suitable for storing a perishable product, for example, tube shaped. It is noted that, while the composite body 10 is depicted as having a substantially cylindrical shape with a substantially circular cross-section, the composite body 10 may have any cross-section suitable to contain a perishable product such as, for example, the cross-sectional shape of the composite body may be substantially triangular, quadrangular, pentagonal, hexagonal or elliptical. Furthermore, the composite body 10 may be formed by any forming process capable of generating the desired shape such as, for example, spiral winding or longitudinal winding.
Referring now to
Referring back to
In the example depicted in
Furthermore, as depicted in
The composite bottom 40 may comprise a plurality of layers that are delineated by the upper surface 42 of the composite bottom 40 and the lower surface 44 of the composite bottom 40. In one example, the composite bottom 40 may comprise a bottom fiber layer 52, a bottom oxygen barrier layer 54, and a bottom sealant layer 56. The bottom fiber layer 52 may form at least a portion of the lower surface 44 of the composite bottom 40. The bottom sealant layer 56 may form at least a portion of upper surface 42 of the composite bottom 40. The bottom oxygen barrier layer 54 may be disposed between the bottom fiber layer 52 and the bottom sealant layer 56. Each of the bottom fiber layer 52, the bottom oxygen bather layer 54, and the bottom sealant layer 56 may be coupled to one another directly or via an adhesive. Optionally, an additional coating may be applied to the outside of the bottom fiber layer 52, which may include printing, coating, or lacquer resistant to discoloration and dislocation under the heat sealing conditions. Accordingly, the composite bottom 40 may have a density of less than about 2.5 g/m3 such as less than about 1.5 g/m3 or less than about 1.0 g/m3. Moreover, the composite bottom 40 may have a modulus of elasticity of less than about 35 GPa such as less than about 30 GPa or less than about 10 GPa.
The body sealant layer 30 and/or the bottom sealant layer 56 may comprise a thermoplastic material suitable for forming a heat seal. The thermoplastic material may be heat-sealable from about 90° C. to about 200° C. such as from about 120° C. to about 170° C. Moreover, the thermoplastic material may have a thermal conductivity from 0.3 W/(mK) to about 0.6 W/(mK) such as from about 0.4 W/(mK) to about 0.5 W/(mK). The thermoplastic material may comprise, for example, an ionomer-type resin, or be selected from the group comprising salts, preferably sodium or zinc salts, of ethylene/methacrylic acid copolymers, ethylene/acrylic acid copolymers, ethylene/vinyl acetate copolymers, ethylene/methylacrylate copolymers, ethylene based graft copolymers and blends thereof. In addition, for example, a polyolefin. Exemplary and non-limiting compounds and polyolefins that can be used as thermoplastic material may include polycarbonate, linear low-density polyethylene, low-density polyethylene, high-density polyethylene, polyethylene terephthalate, polypropylene, polystyrene, polyvinyl chloride, co-polymers thereof, and combinations thereof.
The body oxygen barrier layer 32 and/or the bottom oxygen bather layer 54 may comprise an oxygen inhibiting material. The oxygen inhibiting material may be a metallized film comprising, for example, aluminum. In further examples, oxygen inhibiting material may comprise an aluminum foil. The body oxygen bather layer 32 may have a thickness ranging from about 6 μm to about 15 μm such as from about 9 μm to about 15 μm, from about 6 μm to about 12 μm, or from about 7 μm to about 9 μm. The bottom oxygen bather layer 54 may have a thickness ranging from about 6 μm to about 15 μm such as from about 9 μm to about 15 μm, from about 6 μm to about 12 μm, or from about 7 μm to about 9 μm. Accordingly, the body oxygen bather layer 32 and the bottom oxygen barrier layer 54 may each have a thermal conductivity from about 200 W/(mK) to about 300 W/(mK) such as from about 225 W/(mK) to about 275 W/(mK).
The body fiber layer 34 and/or the bottom fiber layer 52 may comprise a fiber material such as, for example, cardboard or litho paper. The fiber material can comprise a single layer or multiple layers joined by means of one or more adhesive layers. The fiber material can have a thermal conductivity from about 0.04 W/(mK) to about 0.3 W/(mK) such as 0.1 W/(mK) to about 0.25 W/(mK) or about 0.18 W/(mK). The body fiber layer 34 may have a total area weight from about 200 g/m2 to about 600 g/m2 such as from about 360 g/m2 to about 480 g/m2. The bottom fiber layer 52 may have a total area weight from about 130 g/m2 to about 450 g/m2 such as from about 150 g/m2 to about 250 g/m2, or about 170 g/m2.
Referring back to
In some examples, the composite body 10 and the closure seal 72 may be hermetically sealed prior to filling the composite container 100 with a perishable product. Specifically, the closure seal 72 and the composite container 100 may be prefabricated and hermetically sealed to one another. The container may be filled with a perishable product from the open end of the container, i.e, the bottom end 18. Once filled, the composite container may be closed hermetically by hermetically sealing the composite bottom 40 to the bottom end 18 of the composite body 10 and enclosing an internal volume 24 (
Referring again to
As is noted above, a hermetic seal 60 may be formed between the sealing portion 48 of the composite bottom 40 and the interior surface 14 of the composite body 10. The hermetic seal 60 may have a leakage rate equivalent to a hole diameter of less than about 300 μm such as, for example, less than about 75 μm, less than about 25 μm or less than about 15 μm, when measured by the vacuum decay method as described by ASTM test method F2338. The vacuum decay method may be utilized to determine the equivalent hole diameter of the hermetic seal 60 directly, i.e., by coating the non-sealed portions of the composite container 100 with a substance that inhibits leakage. The vacuum decay method may be utilized to derive the equivalent hole diameter of the hermetic seal 60 from multiple measurements. The vacuum decay method may also be utilized to determine the upper bounds of the equivalent hole diameter of the hermetic seal 60 by measuring the leakage of the composite container 100, i.e., the equivalent hole diameter of the hermetic seal 60 may be assumed to be less than or equal to the equivalent hole diameter of a composite container 100 that includes the hermetic seal 60.
The thickness X1 of the hermetic seal 60 can be measured from the exterior surface 16 of the composite body 10 to the lower surface 44 of the composite bottom 40. The thickness X1 of the hermetic seal 60 may be any distance suitable to maintain the hermeticity of the hermetic seal 60 seal and the structural integrity of the composite container 100. The thickness X1 may be from about 0.0635 cm to about 0.16 cm or any distance less than about 0.16 cm such as from about 0.0635 cm to about 0.1092 cm. Furthermore, the thickness X2 of the composite bottom 40 measured between the upper surface 42 and the lower surface 44 may be from about 0.011 cm to about 0.06 cm and the thickness X3 of the composite body 10 measured between the interior surface 14 and the exterior surface 16 may be from about 0.05 cm to about 0.11 cm.
Referring collectively to
The composite container 100 is hermetic when the oxygen transmission rate of the composite container 100 is less than about 50 cm3 of O2 per m2 of the interior surface area of the composite container 100 per day such as, for example, less than about 25 cm3 of O2 per m2 per day or less than about 14.32 cm3 of O2 per m2 per day, as measured by ASTM test method F1307 when subjected to ambient conditions of air at 22.7° C. and 50% relative humidity. The interior surface area of the composite container 100 includes the interior surface 14 of the composite container 100 and the upper surface 42 of the composite bottom 40. The interior surface area of the composite container 100 may also include any top closure.
As is noted above, the composite container 100 may be subjected to a pressure differential between the interior and the exterior of the composite container 100 that acts to cause the composite container 100 to bulge out. Examples of the composite container 100 may be structurally resistant to bulging when measured by a pressure differential method as described by ASTM test method D6653. In one example, the platen portion 46 of the composite bottom 40 may not extend beyond the bottom edge 22 of the composite body 10 when: an internal pressure is applied to the interior surface 14 of the composite body 10 and the upper surface 42 of the platen portion 46 of the composite bottom 46; an external pressure is applied to the exterior surface 16 of the composite body 10 and the lower surface 44 of the composite bottom 40; and the internal pressure is about 20 kPa or more (e.g., about 30 kPa, about 35 kPa, or about 38 kPa) greater than the external pressure. In another example, the composite bottom 40 may not extend beyond the bottom edge 22 of the composite body 10 when: an internal pressure is applied to the interior surface 14 of the composite body 10 and the upper surface 42 of the composite bottom 40; an external pressure is applied to the exterior surface 16 of the composite body 10 and the lower surface 44 of the composite bottom 40; and the internal pressure is about 20 kPa or more (e.g., about 30 kPa, about 35 kPa, or about 38 kPa) greater than the external pressure.
Such pressure differentials can be applied as described by ASTM test method D6653. Any suitable chamber capable of withstanding about one atmosphere pressure differential fitted with a flat-vacuum-tight cover or equivalent chamber providing the same functional capabilities can be utilized. Moreover, it may be desirable to utilize a vacuum chamber that provides visual access to observe test samples. When the desired pressure differential is applied to a composite container 100 supported at the bottom end 18, the composite bottom 100 can be visually inspected. For example, when the platen portion 46 of the composite bottom 40 extends beyond the bottom edge 22 of the composite body 10 tilting, slanting and/or rocking can be observed.
A composite container 100 including a composite bottom 40 hermetically sealed to the bottom end 18 of the composite body 10 can be subjected to implosion testing. Implosion testing is analogous to ASTM D6653 where a pressure differential between the interior and the exterior of the composite container 100 is applied. Rather than subjecting the composite container 100 to a surrounding vacuum environment, implosion testing pulls a vacuum within the composite container 100. Any vacuum device suitable for measuring the vacuum resistance strength of a container in units of pressure (e.g., in-Hg) can be utilized for implosion testing. One suitable vacuum device is the VacTest VT1100, available from AGR TopWave of Butler, Pa., U.S.A.
The implosion test can be applied by securing the top end 20 of a composite container 100 to the vacuum device (e.g., forming a continuous seal with a rubber coated test cone and/or with a plug having a hose for pulling a vacuum). Successive test cycles can be applied to the composite container 100 at ambient conditions of air at about 22° C. and about 50% relative humidity. Each successive cycle may increment the amount of vacuum pressure applied to the composite container 100. When the composite container 100 implodes, the peak vacuum pressure applied during the test cycle can be indicative of the implosion strength of the composite container 100. Implosion testing can be applied to composite containers 100 from about 30 minutes to about 1 hour after manufacture (i.e., “green cans”) and/or greater than about 24 hours after manufacture (i.e., “cured cans”). Composite containers 100 having a substantially cylindrical shape may have an implosion strength of greater than about 3 in-Hg (10.2 kPa) such as for example, greater than about 5 in-Hg (16.9 kPa) or greater than about 7 in-Hg (23.7 kPa).
It is noted that the implosion strengths described above were determined using a composite container 100 having a diameter of about 3 in (about 7.6 cm) and a height of about 10.5 in (about 26.7 cm). The implosion strengths can be scaled to containers having other dimensions and/or shapes. Specifically, a decrease in height results in an increase in implosion strength and an increase in height results in a decrease in implosion strength. A decrease in diameter results in an increase in implosion strength and an increase in diameter results in a decrease in implosion strength. The loading of the container is analogous to a beam in beam theory, with the length of the composite container 100 correlated to the length of a beam and the diameter length of the composite container 100 correlated to the area moment of inertia of a beam. Accordingly, the implosion strengths described herein may be scaled to different dimensions based upon beam theory.
Referring collectively to
Referring collectively to
A mandrel heater 226 may be configured to conductively heat the first mandrel surface 222 and the second mandrel surface 224 of the inner mandrel 220. Specifically, the mandrel heater 226 may be disposed within the inner mandrel 220. The inner mandrel 220 may further comprise an insulated portion 228 formed from a heat insulating material that is configured to mitigate heat transfer. Specifically, the first mandrel surface 222 may be partially formed by an insulated portion 228 that is recessed within the inner mandrel 220 such that the shaped portion 230 and the second mandrel surface 224 is preferentially heated.
Referring back to
Referring back to
Referring again to
Referring back to
The sealing member 320 may be utilized to compress and heat a work piece in order to perform a heat sealing operation. Each sealing member 320 may provide conductive heating to a work piece of up to about 300° C. Moreover, the sealing member 320 may apply a pressure of up to about 30 MPa to a work piece. As is noted above, a plurality of sealing members 320 may be utilized to heat seal (e.g., by applying heat and pressure) the bottom end 18 of the composite body 10 to a composite bottom 40. As depicted in
The tube support assembly 400 may be configured to retrieve a composite body 10 and hold the composite body 10 in a desired location. The tube support assembly 400 may comprise a tube support member 402 that is shaped to accept the composite body 10. In one example, the mandrel assembly 200, the die assembly 300, and the tube support assembly 400 may be aligned along the Y-axis such that a composite sheet 140 may be urged through the die opening 310 by the inner mandrel 220 and inserted into the bottom end 18 of a composite body 10 held by the tube support member 402.
Referring again to
The deformed sheet 240 may have a first deformed surface 242 and a second deformed surface 244 that define a deformed sheet thickness 258. The deformed sheet 240 may comprise the layered structure of the composite bottom 40 described hereinabove, i.e., a fiber layer, an oxygen barrier layer and a sealant layer. The deformed sheet 240 may further comprise an inner portion 246 and an outer portion 248. The inner portion 246 of the deformed sheet 240 may be substantially straight. A radius portion 250 may be disposed between the inner portion 246 and the outer portion 248 of the deformed sheet 240. The radius portion 250 may be shaped to define a radius angle θ2 as measured between the second deformed surface 244 of the inner portion 246 and the second deformed surface 244 of a first section 254 of the outer portion 248. The radius angle θ2 may be from about 1.31 radians to about 1.83 radians such as, for example, from about 1.48 radians to about 1.66 radians or about 1.57 radians. The outer portion 248 of the deformed sheet 240 may comprise an elastic radius 252 between the first section 254 and a second section 256 of the outer portion 248. The elastic radius 252 may be shaped to define an elastic angle α as measured between the first deformed surface 242 of the first section 254 and the first deformed surface 242 of the second section 256. The elastic angle α may be from any angle greater than or equal to about 1.57 radians such as, for example, from about 1.66 radians to about 2.0 radians.
In one example, the composite sheet 140 may be positioned adjacent to the die opening 310 of the die assembly 300 in order to allow for deformation into a deformed sheet 240. Specifically, the locating portion 304 may interact with the composite sheet 140 and position the outer portion 148 of the composite sheet 140 between the first forming surface 214 and the second forming surface 314. Once aligned, a portion (e.g., the outer portion 148) of the composite sheet 140 may be constrained between the first forming surface 214 and the second forming surface 314. The first forming surface 214 can be spaced a gap distance 110 from the second forming surface 314. As is noted above, the gap distance 110 may be controlled by the interaction between the gap gauge 212 and the gauge support surface 302. For example, the gap gauge 212 and the gauge support surface 302 may remain in contact throughout the forming process such that the gap distance 110 is held substantially constant.
While the outer portion 148 of the composite sheet 140 is constrained by the first forming surface 214 and the second forming surface 314, the motion of the outer portion 148 of the composite sheet 140 along the Y-axis may be limited by the gap distance 110. When the gap distance 110 is relatively large, the outer portion 148 of the composite sheet 140 may move a greater distance along the Y-axis. Conversely, when the gap distance 110 is relatively small, the outer portion 148 of the composite sheet 140 may move a shorter distance along the Y-axis. Moreover, as the gap distance 110 increased the elastic angle α may be increased. Accordingly, the gap distance 110 may be any distance that is substantially equal to or greater than the sheet thickness 150 of the composite sheet 140. For example, the gap distance 110 may be from about 1 times the sheet thickness 150 of the composite sheet 140 to about 5 times the sheet thickness 150 of the composite sheet 140.
The composite sheet 140 may be urged through the die opening 310 and along the third forming surface 312 to shape the composite sheet 140 (
Referring again to
The shape of the deformed sheet 240 may further be defined by a wall distance 234. When the inner mandrel 220 extends past the die opening 310 (
Referring collectively to
Referring collectively to
The composite bottom 40 may be sealed to the composite body 10 such that the composite bottom 40 is hermetically sealed to the composite body 10. Specifically, compression and heat may be applied to the composite bottom 40 and/or the composite body 10 such that their respective sealant layers form a hermetic seal. Referring collectively to
Hermetic seals, according to the present disclosure, may be formed by sealing members at a temperature greater than about 90° C. such as, for example, 120° C. to about 280° C. or from about 140° C. to about 260° C. Suitable hermetic seals may be formed by keeping the sealing member in contact with the bottom end 18 of the composite body 10 for any dwell time sufficient to heat a sealant layer to a temperature suitable for forming a hermetic seal such as, for example, less than about 4 seconds, from about 0.7 seconds to about 4.0 seconds or from about 1 second to about 3 seconds. The composite bottom 40 and the bottom end 18 of the composite body 10 may be compressed between the sealing members 320 and the inner mandrel 220 with any pressure less than about 30 MPa such as a pressure from about 1 MPa to about 22 MPa.
In further examples, a plurality of composite containers may be formed by a system or device suitable for processing multiple composite sheets, composite bottoms and composite containers in a synchronized manner. For example, a manufacturing system may include a plurality of mandrel assemblies, a plurality of die assemblies, and a plurality of tube support assemblies operating in a coordinated manner. Specifically, a turreted device with a plurality of sub assemblies wherein each sub assembly comprises a mandrel assembly, a die assembly, and a tube assembly may accept composite sheets and process the composite sheets simultaneously or synchronously. Depending upon the complexity of the turreted device up to many hundreds of separate composite containers may be manufactured per cycle in a coordinated manner. Thus, any of the processes described herein may be performed contemporaneously. For example, when each sub assembly operates in a synchronous manner each of the following may be performed contemporaneously: a first composite sheet may be positioned above a die opening; a second composite sheet may be constrained between a mandrel assembly and a die assembly; a third composite sheet may be formed into a first composite bottom; a second composite bottom may be inserted into a first composite body; and a third composite bottom may be hermetically sealed to a second composite body. Alternatively, any of the operations described herein may be performed simultaneously such as, for example, by a device having a plurality of sub assemblies.
It should now be understood that the present disclosure provides for hermetically closed containers for packaging humidity sensitive and/or oxygen sensitive solid food products such as, for example, crisp carbohydrate based food products, salted food products, crisp food products, potato chips, processed potato snacks, nuts, and the like. Such hermetically closed containers may provide a hermetic closure under widely varying climate conditions of high and low temperature, high and low humidity, and high and low pressure. Moreover, the hermetically closed containers can be manufactured according to the methods described herein via processes involving conductive heating technology with relatively low environmental pollution. The hermetically closed containers described herein may have high structural stability at low weight and be suitable for recycling.
It is noted that the terms “substantially” and “about” may be utilized herein to represent the inherent degree of uncertainty that may be attributed to any quantitative comparison, value, measurement, or other representation. These terms are also utilized herein to represent the degree by which a quantitative representation may vary from a stated reference without resulting in a change in the basic function of the subject matter at issue.
Furthermore, it is noted that directional references such as, for example, upper, lower, top, bottom, inner, outer, X-direction, Y-direction, X-axis, Y-axis, and the like have been provided for clarity and without limitation. Specifically, it is noted such directional references are made with respect to the coordinate system depicted in
While particular examples have been illustrated and described herein, it should be understood that various other changes and modifications may be made without departing from the spirit and scope of the claimed subject matter. Moreover, although various aspects of the claimed subject matter have been described herein, such aspects need not be utilized in combination. It is therefore intended that the appended claims cover all such changes and modifications that are within the scope of the claimed subject matter.
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