The field of the disclosure relates generally to a container formed from a sheet of material, and more particularly to a container that includes at least one venting assembly having an upper and lower vent panel that extends along at least a portion of at least one edge of a top panel of the container.
It is well known in the food industry, including the pizza industry, to provide a food product to a consumer that is packaged in film, foil, paperwrap, a box, or a container. Such containers provide a convenient package to carry the food product from the producer of the food product to a table or other location for consumption by the consumer of the food product. However, if the container is sealed and unventilated and the food product contained within the container is hot, moisture captured within the container may make the drier parts of the food product soggy. Conversely, if the container is too ventilated, there will be excessive heat loss during product transfer. It is also convenient to place multiple containers in a heated bag so a customer and/or delivery person is able to carry those containers from the restaurant for consumption elsewhere. At least some of these containers may be time-consuming to form. Moreover, at least some such known containers do not include easily formed features that facilitate securing a lid to a base of the container when the container is closed.
In one aspect, a blank of foldable sheet material for forming a container is provided. The blank includes a top portion including a top panel. The top panel includes a front edge, a rear edge, a first side edge, and a second side edge. The blank further includes at least one venting assembly including a first vent panel and a second vent panel extending from the first vent panel. The first and second vent panels have at least partially free side edges. The partially free side edges at least partially define an opening at each end of the venting assembly. The at least one venting assembly is positioned along one or more of the front edge, the rear edge, the first side edge, and the second side edge.
In another aspect, a container formed from a blank of foldable sheet material is provided. The container includes a top portion including a top panel. The top panel includes a front edge, rear edge, a first side edge, and a second side edge. The container further includes at least one venting assembly including a first vent panel and a second vent panel hingedly connected to the first vent panel. The first and second vent panels have at least partially free side edges. The partially free side edges at least partially defining an opening at each end of the venting assembly. The at least one venting assembly is positioned along one or more of the front edge, the rear edge, the first side edge, and the second side edge.
In another aspect, a method of constructing a container from a blank of sheet material is provided. The method includes rotating two opposing bottom side panels of the blank about a bottom panel toward an interior surface of the blank to form a base. The method also includes rotating two opposing top side panels of the blank about a top panel toward an interior surface of the blank to form a lid. The method further includes rotating the lid toward the base such that a first vent panel and a second vent panel form openings at side edges of the vent panels.
The following detailed description illustrates the disclosure by way of example and not by way of limitation. The description clearly enables one skilled in the art to make and use the disclosure, describes several embodiments, adaptations, variations, alternatives, and use of the disclosure, including what is presently believed to be the best mode of carrying out the disclosure.
The present disclosure provides a stackable, collapsible container that includes a top panel and at least one venting assembly located along at least a portion of at least one edge of the top panel. The at least one venting assembly provides enhanced ventilation for a food product contained within the container. The enhanced ventilated container is constructed from a blank of sheet material. The blank is formed by a machine that imparts fold lines, cut lines, and other lines of weakness to the blank. In one embodiment, the ventilated container is fabricated from a paperboard material. The ventilated container, however, may be fabricated using any suitable material, and therefore is not limited to a specific type of material. In alternative embodiments, the container is fabricated using cardboard, plastic, fiberboard, paperboard, foamboard, corrugated paper, and/or any suitable material known to those skilled in the art and guided by the teachings herein provided.
In the example embodiment, the ventilated container includes at least one marking thereon including, without limitation, indicia that communicates the product, a manufacturer of the product and/or a seller of the product. For example, the marking may include printed text that indicates a product's name and briefly describes the product, logos and/or trademarks that indicate a manufacturer and/or seller of the product, and/or designs and/or ornamentation that attract attention. “Printing,” “printed,” and/or any other form of “print” as used herein may include, but is not limited to including, ink jet printing, laser printing, screen printing, giclee, pen and ink, painting, offset lithography, flexography, relief print, rotogravure, dye transfer, and/or any suitable printing technique known to those skilled in the art and guided by the teachings herein provided. In another embodiment, the container is void of markings, such as, without limitation, indicia that communicates the product, a manufacturer of the product and/or a seller of the product. Furthermore, the container may have any suitable size, shape and/or configuration, i.e., any suitable number of sides having any suitable size, shape and/or configuration as described and/or illustrated herein. In one embodiment, the container includes a shape that provides functionality, such as a shape that facilitates packaging a food item, a shape that facilitates transporting the container, and/or a shape that facilitates stacking and/or arrangement of a plurality of containers.
Examples of at least some useful benefits of the ventilated container described herein include the at least one vent (or venting assembly) of the container serving to release steam generated by a heated food product contained within the container to prevent the food product from becoming soggy and undesirable, while retaining heat to prevent the food product from becoming cold too quickly. As described herein, testing of the enhanced ventilated container with pizza contained in the ventilated container showed that the ventilated container improved heat retention and moisture control, resulting in a more user desirable pizza for a longer period of time (e.g., from a moisture standpoint and heat retention standpoint) as compared to other containers containing similar pizza. For example, in at least one test of the ventilated container, a heated pizza contained within the enhanced ventilated container measured temperatures of 30% to 67% hotter than a similar heated pizza contained within a non-ventilated container at about 33 minutes of elapsed time.
In addition, the at least one venting assembly is also configured to provide a better gripping surface such that a consumer is better able to hold the ventilated container when transporting it. The ventilated container may also include at least one tab extending through and below a bottom edge of the bottom panel. The at least one tab is configured to contact a top panel of another ventilated container located underneath the first ventilated container to improve stability and provide a more secure structure for stacking and transporting containers. This allows for multiple ventilated containers to be stacked on one another without making the stack unstable and without crushing the venting assemblies. Additionally, the at least one venting assembly together with the least one tab provides spacing between stacked ventilated containers, further improving heat retention within the ventilated container when compared to other stacked containers without spacing. Furthermore, in one embodiment, the at least one venting assembly includes partially free side edges that angle outwardly to an apex in order to increase structural stability, enabling the at least one venting assembly to support greater weight when containers are stacked and providing improved airflow.
Referring now to the drawings, and more specifically to
Referring to
More specifically, top panel 120 extends from front tuck flap 134 along fold line 126, back panel 122 extends from top panel 120 along fold line 128, bottom panel 124 extends from back panel 122 along fold line 130, first front panel 142 extends from bottom panel 124 along fold line 132, and second front panel 136 extends from first front panel 142 along fold line 148. Side flaps 138 exist on each side of front panel 142 and 136, with each side flap 138 separated from front panel 142 and 136 by a cut line 152.
In the example embodiment, front tuck flap 134 has a length L1 that is equal to or less than a length L2 of top panel 120. Front tuck flap 134 and fold line 126 cooperate to form a front edge of top panel 120, and fold line 128 defines a back edge of top panel 120.
Top panel 120 includes a first top side panel 162 and a second top side panel 164 extending therefrom along respective opposing fold lines 166 and 168. More specifically, first top side panel 162 extends from top panel 120 along fold line 166, and second top side panel 164 extends from top panel 120 along fold line 168. Fold lines 166 and 168 define side edges of top panel 120. Additionally, in the example embodiment, a finger tab 140 is located in a center of a front edge defined by fold line 126.
In the example embodiment, top panel 120 further includes vent 156 located along at least a portion of fold line 128. Vent 156 includes a lower vent panel 194 and an upper vent panel 196 extending therefrom along respective fold lines 158, 160, and 170. Fold lines 158 and 170 define edges of vent 156. More specifically, lower vent panel 194 extends from back panel 122 along fold line 158, upper vent panel 196 extends from lower vent panel 194 along fold line 160, and top panel 120 extends from upper vent panel 196 along fold line 170. Fold line 160 is offset from fold line 128, such that fold line 160 is closer to a center of top panel 120. Each end of vent 156 includes a cut line 198 made through top panel 120 and back panel 122. In the example embodiment, lower vent panel 194 has a width W3 that is greater than a width W4 of upper vent panel 196. Furthermore, vent 156 has a length L3 that is one-thirds to two-thirds the length L2 of top panel 120.
Bottom panel 124 has a first bottom side panel 176 and a second bottom side panel 178 extending therefrom along respective opposing fold lines 180 and 182. More specifically, first bottom side panel 176 extends from bottom panel 124 along fold line 180, and second bottom side panel 178 extends from bottom panel 124 along fold line 182. Fold lines 180 and 182 define side edges of bottom panel 124. Fold line 132 defines a front edge of bottom panel 124, and fold line 130 defines a back edge of bottom panel 124. Side flaps 138 further extend from first bottom side panel 176 and second bottom side panel 178 along respective opposing fold line 146. Furthermore, each bottom side panel 176 and 178 includes a back tab 184 extending from a respective back edge 186 of bottom side panel 176 or 178. Each back edge 186 is defined by a fold line. Each back tab 184 is separated from back panel 122 by a cut line 190, and further separated from an adjacent one of top side panels 162 and 164 by a cut line 192. In an alternative embodiment (not shown), each back tab 184 extends from one of top side panels 162 and 164 such that a fold line couples back tab 184 to top side panel 162 or 164, and a cut line separates each back tab 184 from bottom side panel 176 or 178.
With reference to
First front panel 142 and second front panel 136, which are a same approximate width and length, are rotated interiorly along respective fold lines 132 and 148, causing second front panel 136 to be adjacent to first front panel 142 (in a face-to-face relationship), with side flaps 138 located in between first front panel 142 and second front panel 136. First front panel 142 forms an exterior of front wall (not shown) and second front panel 136 forms an interior portion of front wall (not shown).
In the example embodiment, first front panel 142 includes tabs 150 along fold line 132 directed towards top panel 124. Tabs 150 include at least partially free edges between top panel 124 and first front panel 142. Second front panel 136 includes tabs 144 along trailing edge 118 directed away from top panel 124. Tabs 150 and 144 have a same approximate width and length and are located opposite to each other. When first front panel 142 and second front panel 136 are rotated interiorly along respective fold lines 132 and 148, tabs 144 insert into a slot opening created when tabs 150 are rotated outwardly, such that tabs 144 and 150 extend downwardly past a bottom edge of front panels 142 and 136 when the container is constructed. Tabs 144 and 150 extend below bottom panel 124. In one embodiment, tabs 144 extend less than or further than tabs 150.
Bottom side panels 176 and 178 cooperate with front panels 136 and 142 to define a cavity of base 202. Bottom side panels 176 and 178 are configured to form a portion of respective first side wall 216 and second side walls (not shown), and front panels 136 and 142 are configured to form a portion of a front wall (not shown). After rotation, bottom side panels 176 and 178 and front panel 142 are substantially perpendicular to bottom panel 124.
Back tabs 184 are rotated about respective fold lines 186 toward interior surface 112 to form a portion of a back wall 236 that at least partially defines cavity. It should be understood that back tabs 184 may be rotated into position before or after side flaps 138 are rotated toward interior surface 112.
To construct lid 206 of container 200, top side panels 162 and 164 are rotated about respective fold lines 166 and 168 toward interior surface 112, and front tuck flap 134 is rotated about fold line 126 toward interior surface 112, such that top side panels 162 and 164 and front tuck flap 134 are perpendicular to top panel 120. It should be understood that lid 206 may be formed before base 202 is formed.
To close container 200, lid 206 is rotated toward base 202 along fold lines 128 and 130. As lid 206 is rotated toward base 202, back panel 122 is rotated about fold line 130 to form back wall 236. More specifically, back wall 236 is formed when back panel 122 is adjacent to back tabs 184. Additionally, when container 200 is closed, top panel 120 forms a top wall 204 of container 200, and front tuck flap 134 contacts second front panel 136 to form, along with first front panel 142, front wall (not shown) of container 200 and at least partially defines a releasably secure closure of lid 206 and base 202.
In the example embodiment when container 200 is in a closed position, a venting assembly 240 is formed on top wall 204 along at least a portion of fold line 128. In the example embodiment, venting assembly 240 is a raised triangular cross-sectional shape. In the example embodiment, vent 240 is similar to vent 156 shown in
In certain embodiments, top side panels 162 and 164 are so received in a friction fit, defining a releasably secure closure of lid 206 and base 202. More specifically, when container 200 is closed, exterior of top side panel 162 forms a friction fit with interior of bottom side panel 176 to form first side wall 216 of container 200, exterior of top side panel 164 forms a friction fit with interior of bottom side panel 178 to form second side wall (not shown) of container 200, and exterior of front tuck flap 134 forms a friction fit with second front panel 136 to, along with first front panel 142, form front wall (not shown) of container 200. More specifically, exterior surface of each top side panel 162 and 164 and front tuck flap 134 contact interior surface of each respective bottom side panel 176 and 178 and second front panel 136. In alternative embodiments, one or more of top side panel 162 and 164 and front tuck flap 134 are so received in a clearance fit and/or a non-contact fit.
Prior to closing container 200, a product, such as a food product, may be placed within base 202. As such, when lid 206 engages base 202, the product is secured within the cavity by lid 206 and base 202.
As such, the following steps are performed to form container 200 from blank 100: (1) rotate side flaps 138 about respective fold lines toward interior surface 112; (2) rotate bottom side panels 176 and 178 about respective fold lines toward interior surface 112 to form a portion of side walls; (3) rotate first front panel 142 and second front panel 136 about respective fold lines towards interior surface 112, such that, after the rotating, second front panel 136 contacts first front panel 142, with side flaps 138 located in between first front panel 142 and second front panel 136, tabs 144 on second front panel 136 are inserted into partially free edges of tabs 150, and front panels 136 and 142 are substantially perpendicular to bottom wall 203, to form a portion of front wall (not shown); (4) rotate front tuck flap 134 and top side panels 162 and 164 toward interior surface 112 to form lid 206; and (5) rotate lid 206 toward base 202 to form first side wall 216, second side wall (not shown) and front wall (not shown). In an alternative embodiment, step (4) is performed before steps (1), (2), and (3).
Vent 356, located along at least a portion of fold line 366, includes a lower vent panel 394 and an upper vent panel 396. Lower vent panel 394 extends from top side panel 362 along fold line 358. Upper vent panel 396 extends from lower vent panel 394 along fold line 360. Top panel 320 extends from upper vent panel 396 along fold line 370. Cut lines 398 through top panel 320 and top side panel 362 are located at each end of vent panel 394 and 396. In one embodiment, lower vent panel 394 has a greater width than upper vent panel 396.
Vent 350, located along at least a portion of fold line 368, includes a lower vent panel 394 and an upper vent panel 396. Lower vent panel 394 extends from top side panel 364 along fold line 358. Upper vent panel 396 extends from lower vent panel 394 along fold line 360. Top panel 320 extends from upper vent panel 396 along fold line 370. Cut lines 398 through top panel 320 and top side panel 364 are located at each end of vent panel 394 and 396. In one embodiment, lower vent panel 394 has a greater width than upper vent panel 396.
Referring to
More specifically, top panel 520 extends from front tuck flap 534 along fold line 526, back panel 522 extends from top panel 520 along fold line 528, bottom panel 524 extends from back panel 522 along fold line 530, and front panel 542 extends from bottom panel 524 along fold line 532. In the example embodiment, front tuck flap 534 includes a pair of offset edges 531 disposed at opposite ends of front tuck flap 534. More specifically, offset edges 531 are offset from leading edge 516 of blank 500. In alternative embodiments, front tuck flap 534 does not include offset edges 531.
In the example embodiment, front tuck flap 534 has a length L1 that is less than a length L2 of top panel 520, such that a pair of free edges 560 of top panel 520 are defined on opposing sides of, and substantially co-linear with, fold line 526. Free edges 560 and fold line 526 cooperate to form a front edge of top panel 520, and fold line 528 defines a back edge of top panel 520. In alternative embodiments, length L1 is equal to or greater than length L2, such that top panel 520 does not include free edges 560.
Top panel 520 includes a first top side panel 562 and a second top side panel 564 extending therefrom along respective opposing fold lines 566 and 568. More specifically, first top side panel 562 extends from top panel 520 along fold line 566, and second top side panel 564 extends from top panel 520 along fold line 568. Fold lines 566 and 568 define side edges of top panel 520. Each of first top side panel 562 and second top side panel 564 includes a front edge 574 that is configured to engage one of minor diagonal panels 536 to at least partially define the second releasably secure closure of container 600 in a closed position 660. For example, in the illustrated embodiment, each of first top side panel 562 and second top side panel 564 includes a front portion 571 proximate front edge 574, and a locking tab 572 that extends from front edge 574. More specifically, in the example embodiment, each locking tab 572 is configured to be received in a locking aperture 650 defined in a minor diagonal wall 610 of container 600 to at least partially define the second releasably secure closure of container 600 in closed position 660, as shown in
In the example embodiment, top panel 520 includes a pair of rounded front corner edges 570. Each rounded front corner edge 570 extends between a free edge 560 and a respective side edge of top panel 520. Alternatively, top panel 520 does not include rounded front corner edges 570.
In the example embodiment, top panel 520 further includes vent (or venting assembly) 556 located along at least a portion of fold line 528. Vent 556 includes a lower vent panel 594 and an upper vent panel 596 extending therefrom along respective fold lines 558, 560, and 570. Fold lines 558 and 570 define the edges of vent 556. More specifically, lower vent panel 594 extends from back panel 522 along fold line 558, upper vent panel 596 extends from lower vent panel 594 along fold line 560, and top panel 520 extends from upper vent panel 596 along fold line 570. Each end of vent 556 includes a cut line 598 made through top panel 520 and back panel 522. In the example embodiment, lower vent panel 594 has a width greater than a width of upper vent panel 596, such that lower vent panel 594 has a width W3 that is greater than a width W4 of upper vent panel 596. Furthermore, vent 556 has a length L3 that is between one-thirds to two-thirds the length L2 of top panel 520.
Bottom panel 524 has a first bottom side panel 576 and a second bottom side panel 578 extending therefrom along respective opposing fold lines 580 and 582. More specifically, first bottom side panel 576 extends from bottom panel 524 along fold line 580, and second bottom side panel 578 extends from bottom panel 524 along fold line 582. Fold lines 580 and 582 define side edges of bottom panel 524. Furthermore, each bottom side panel 576 and 578 includes a back tab 584 extending from a respective back edge 586 of bottom side panel 576 or 578. Each back edge 586 is defined by a fold line. Each back tab 584 is separated from back panel 522 by a cut line 590, and further separated from an adjacent one of top side panels 562 and 564 by a cut line 592. In an alternative embodiment (not shown), each back tab 584 extends from one of top side panels 562 and 564 such that a fold line couples back tab 584 to top side panel 562 or 564, and a cut line separates each back tab 584 from bottom side panel 576 or 578.
In the example embodiment, each bottom side panel 576 and 578 also has a minor diagonal panel 536 extending from a respective front edge 588 of the bottom side panel. Each bottom side panel front edge 588 is partially defined by a cut line 587 that defines a slot-forming tab 544 on bottom side panel front edge 588, and further at least partially defined by at least one fold line 589 extending from an end of cut line 587. In the example embodiment, the at least one fold line 589 is a pair of fold lines 589 that extend from opposing edges of cut line 587. Each slot forming tab 544 is configured to form one of locking apertures 650 of container 600, as shown in
Front panel 542 includes a pair of oppositely disposed side edges 543. Each side edge 543 is defined by a fold line. A major diagonal panel 545 extends from each side edge 543. Each major diagonal panel 545 has a length greater than a length of each minor diagonal panel 536, wherein the length of major diagonal panel 545 is measured between a respective fold line 543 and a respective side edge 547 of major diagonal panel 545, and the length of minor diagonal panel 536 is measured between a respective fold line 588 and a front edge 548 of minor diagonal panel 536.
Fold line 532 defines a front edge of bottom panel 524, and fold line 530 defines a back edge of bottom panel 524. In addition, bottom panel 524 includes a pair of oppositely disposed angled edges 546 that extend from opposing ends of fold line 532 to bottom panel side edges 580 and 582, respectively. Each angled edge 546 is defined by a respective fold line. A corner panel 538 extends from each angled edge 546. Moreover, each corner panel 538 is separated from an adjacent minor diagonal panel 536 by a fold line 549, and is separated from an adjacent major diagonal panel 545 by a respective fold line 550. In addition, each minor diagonal panel 536 is separated from an adjacent major diagonal panel 545 by a respective cut line 551.
Front panel 542 is configured to engage front tuck flap 534 to at least partially define a first releasably secure closure of container 600 in closed position 660. For example, in the illustrated embodiment, a notch 540 is defined in trailing edge 518 along each side edge 543 of front panel 542. Each notch 540 is configured to receive at least a portion of front tuck flap 534 to at least partially define the first releasably secure closure of container 600 in closed position 660, as shown in
With reference to
When corner panels 538 are rotated toward interior surface 512, major diagonal panels 545, minor diagonal panels 536, and front panel 542 are also rotated about respective fold lines 546, 543, 550, 549, and 532 toward interior surface 512 because of the interconnectivity of each of major diagonal panels 545, minor diagonal panels 536, and front panel 542 with corner panels 538. In addition, bottom side panels 576 and 578 are also rotated about respective fold lines 580 and 582 toward interior surface 512 because of the interconnectivity of bottom side panels 576 and 578 with respective minor diagonal panels 536. As such, major diagonal panels 545, minor diagonal panels 536, bottom side panels 576 and 578, and front panel 542 are rotated into position concurrently with corner panels 538 in one motion. Major diagonal panels 545 form respective major diagonal walls 608, and minor diagonal panels 536 form respective minor diagonal walls 610. Bottom side panels 576 and 578 are configured to form a portion of respective first and second side walls 616 and 618, and front panel 542 is configured to form a portion of a front wall 620. After rotation, bottom side panels 576 and 578, front panel 542, major diagonal walls 608, and minor diagonal walls 610 are substantially perpendicular to bottom wall 606.
In the example embodiment, when minor diagonal panels 536 are rotated, slot-forming tabs 544 separate from minor diagonal panels 536, forming locking apertures 650 in each minor diagonal wall 610 adjacent first and second side walls 616 and 618. Further, when corner panels 538 are rotated into position, front edges 548 of each minor diagonal panel 536 contact an adjacent major diagonal panel 545, and side edges 547 of each major diagonal panel 545 are adjacent to, but spaced from, a respective adjacent bottom side panel 576 and 578. Each minor diagonal wall 610 extends from front edge 588 of the respective bottom side panel 576 and 578 at an acute angle relative to the bottom side panel, and each major diagonal wall 608 extends from one of side edges 543 of front panel 542 at an obtuse angle relative to front panel 542. A recess 626 is defined by each major diagonal wall 608, minor diagonal wall 610, and corner panel 538. Further, each of bottom side panels 576 and 578 cooperates with an adjacent minor diagonal wall 610 and an adjacent major diagonal wall 608 to define a respective chamber 630 within a cavity 632 of base 602. Each chamber 630 is separated from one of recesses 626 by a corresponding minor diagonal wall 610.
Back tabs 584 are rotated about respective fold lines 586 toward interior surface 512 to form a portion of a back wall 636 that at least partially defines cavity 632. It should be understood that back tabs 584 may be rotated into position before or after corner panels 538 are rotated toward interior surface 512.
To construct lid 606 of container 600, top side panels 562 and 564 are rotated about respective fold lines 566 and 568 toward interior surface 512, and front tuck flap 534 is rotated about fold line 526 toward interior surface 512, such that top side panels 562 and 564 and front tuck flap 534 are perpendicular to top panel 520. It should be understood that lid 606 may be formed before base 602 is formed.
To close container 600, lid 606 is rotated toward base 602 along fold lines 528 and 530. As lid 606 is rotated toward base 602, back panel 522 is rotated about fold line 530 to form back wall 636. More specifically, back wall 636 is formed when back panel 522 is adjacent to back tabs 584. Additionally, when container 600 is closed, top panel 520 forms a top wall 604 of container 600, and front tuck flap 534 engages front panel 542 to form front wall 620 of container 600 and at least partially define the first releasably secure closure of lid 606 and base 602. In the example embodiment, each notch 540 receives at least a portion of front tuck flap 534 to at least partially define the first releasably secure closure of lid 606 and base 602. More specifically, each notch 540 receives one of pair of offset edges 531 of front tuck flap 534 to at least partially define the first releasably secure closure of lid 606 and base 602. In alternative embodiment, each notch 540 receives any suitable portion of front tuck flap 534.
In the example embodiment when container 600 is in the closed position, vent 640 is formed on top wall 604 along at least a portion of fold line 528. In the example embodiment, vent 640 has a raised triangular cross-sectional shape. More specifically, upper vent panel 596 and lower vent panel 594 are configured to form vent 640 on top wall 604 along at least a portion of fold line 528, thereby creating an opening into cavity 632 at cut lines 598 on each side of vent 640. As lid 606 is rotated toward base 602 along fold lines 528 and 530, lower vent panel 594, which in the example embodiment has a greater length than upper vent panel 596, rotates along fold line 558 into an upwards slope position, upper vent panel 596 rotates along fold lines 560 and 570 into a downwards slope position, creating triangular-shaped vent 640, with fold line 560 being an apex of triangular-shape vent 640.
In addition, when container 600 is closed, top side panel 562 cooperates with bottom side panel 576 to form first side wall 616 of container 600, and top side panel 564 cooperates with bottom side panel 578 to form second side wall 618 of container 600. More specifically, exterior surface 514 of each top side panel 562 and 564 contacts interior surface 512 of respective bottom side panel 576 and 578, and front portion 571 of each top side panel 562 and 564 is at least partially disposed within one of chambers 630. Moreover, each front edge 574 of top side panels 562 and 564 engages one of minor diagonal panels 536 to at least partially define the second releasably secure closure of container 600 in closed position 660. For example, in the illustrated embodiment, locking tab 572 of each front edge 574 is received in a respective locking aperture 650 of minor diagonal walls 610, at least partially defining the second releasably secure closure of lid 606 and base 602.
Additionally, front portion 571 of top side panel 562 is received between bottom side panel 576 and side edge 547 of adjacent major diagonal panel 545, and front portion 571 of top side panel 564 is received between bottom side panel 578 and side edge 547 of adjacent major diagonal panel 545. In certain embodiments, each front portion 571 is so received in a friction fit, defining a third releasably secure closure of lid 606 and base 602. In alternative embodiments, each front portion 571 is so received in a clearance fit and/or a non-contact fit.
Prior to closing container 600, a product, such as a food product, may be placed within base 602. As such, when lid 606 engages base 602, the product is secured within cavity 632 by lid 606 and base 602.
As such, the following steps are performed to form container 600 from blank 500: (1) rotate corner panels 536 toward bottom panel 524 to form base 602; (2) rotate back tabs 584 toward interior surface 512 to form a portion of back wall 636; (3) rotate front tuck flap 534 and top side panels 562 and 564 toward interior surface 512 to form lid 606; and (4) rotate lid 606 toward base 602 to form side walls 616 and 618 and front wall 620. In an alternative embodiment, steps (1) and (2) are interchanged. In another alternative embodiment, step (3) is performed before steps (1) and (2).
In the example embodiment, top panel 720 includes vents (or venting assemblies) 756 on top wall 720 along at least a portion of respective fold lines 766. Each vent 756 includes a lower vent panel 794 and an upper vent panel 796 extending therefrom along respective fold lines 758, 760, and 770. More specifically, lower vent panel 794 extends from top side panels 776 along fold line 758, upper vent panel 796 extends from lower vent panel 794 along fold line 760, and top panel 720 extends from upper vent panel 796 along fold line 770. Each end of vent 756 includes an at least partially free side edge 798. In the example embodiment, lower vent panel 794 includes an apex 730 on each of side edges 798 that is spaced a distance from fold line 758 that is approximately a half to two-thirds of the distance between fold line 758 and fold line 760, where side edges 798 extend at an oblique angle from apex 730 and relative to fold line 760. More specifically, the side edges 798 extend at an angle ranging between 30 and 60 degrees relative to fold line 760.
Embodiments of the above-described container are easily constructed from a flexible unitary blank of paperboard. Further, embodiments of the above-described container include an easily formed first releasably secure closure of a lid and a base, at least partially defined by engagement of a front tuck flap on the lid and a front panel of the base, and an easily formed second releasably secure closure of the lid and the base, at least partially defined by engagement of the side panels of the lid with the side panels of the base.
Exemplary embodiments of a container have been described above in detail. The container is not limited to the specific embodiments described herein, but rather, components of the container and/or steps of the method may be utilized independently and separately from other components and/or steps described herein. Further, the described components and/or method steps can also be defined in, or used in combination with, other apparatus and/or methods, and are not limited to practice with only the apparatus and method as described herein.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
This application claims the benefit of priority under 35 U.S.C. § 119(e) of U.S. provisional application Ser. No. 62/214,035 filed on Sep. 3, 2015 which is hereby incorporated by reference in its entirety.
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