The present invention relates to conveyorized packaging apparatuses. More particularly, it relates to packaging apparatuses for intermittently conveying a generally horizontal web of interconnected bags and loading and sealing one or more stacks of items into the bags, and/or loading and sealing items side-by-side in the bags, followed by applying a dividing seal to divide the bags into two subcompartments, each containing part of the items, and optionally cutting or perforating along the dividing seal to separate the two subcompartments, thus forming two smaller sealed bags.
Packaging apparatuses exist for loading and sealing food items into bags in a web of interconnected bags. One type of apparatus provides for inserting items into a bag having one open end, and then applying a seal to the open end to seal the items into the bag. Often, for efficient loading, it is desired to seal multiple items in a single bag. However, disadvantages include that more items in a bag means more time required to consume the contents once opened, as well as in some cases an undesirably large area footprint of the sealed bag.
A need therefore exists for a packaging apparatus that facilitates sealing multiple food items within one bag, while limiting the area footprint of the sealed bag and/or providing a way to maintain the freshness of food items that are not the first to be consumed when the sealed bag is opened.
According to an aspect of the invention, a packaging apparatus including a station for dividing bags (“dividing sealing station”) filled and sealed by the apparatus into subcompartments, and optionally cutting or perforating along a dividing seal to form smaller separate or separable bags from the two subcompartments, is provided. The apparatus includes a web conveyor and a pair of opposed belts that cooperate to convey a web of flexible material (such as a suitable polymer film) including interconnected bags to be filled and sealed, the web having generally parallel proximal and distal edges extending along a longitudinal conveying direction. A pair of opposed belts is configured to grip a portion of a proximal longitudinal strip of the web between the opposed belts, the interconnected bags being joined together by the proximal longitudinal strip, and each bag comprising a continuous closure meeting the proximal longitudinal strip at an upline end and a downline end of the closure, said closure ends being spaced apart longitudinally to define an opening of the bag extending between the closure ends and upline and downline sides of the bag extending transversely across the web of film from the respective upline and downline closure ends. For example, the closure may be a continuous, generally U-shaped seal, or it may comprise two transverse side seals and a C-folded edge of the web extending between the side seals, to define upline, downline, and distal closed sides of the bag. A bag-loading mechanism of the apparatus is configured to insert a product load into one of the bags through the bag opening and deposit the material inside the bag. The web conveyor is typically a generally horizontal belt conveyor, configured to support a portion of the web located to one side of the gripped portion in a generally horizontal orientation, and to advance said portion of the web downline as the opposed belts advance the longitudinal strip of the web downline. A closure sealing station located downline of the bag loading mechanism is configured to seal said bag opening to form a sealed bag containing the inserted product load. The dividing seal station is disposed downline of the closure sealing station and comprises a heat seal bar and a lower seal support. The lower seal support is configured to move from a lowered position disposed below the web conveyor to a raised position in which the lower seal support lifts a central portion of the bag above the upline and downline sides of the bag, so that the bag is essentially draped over the lower seal support. This causes an upline portion of the inserted product load to fall away from the central portion of the bag towards the upline side of the bag and a downline portion of the inserted product load to fall away from the central portion of the bag towards the downline side of the bag. In addition, when the lower seal support is fully raised, the heat seal bar and lower seal support grip the central portion of the bag between them to create a center seal in the bag which divides the bag into two sealed subcompartments, namely, a sealed upline subcompartment containing said upline product portion and a sealed downline subcompartment containing said downline product portion.
The lower seal support may be further configured to oscillate vertically to promote separation of said upline and downline product load portions before engaging the heat seal bar to seal said bag central portion.
Typically, the heat seal bar comprises longitudinally spaced apart, parallel, transverse elongate heat seal bands, disposed to form longitudinally spaced apart, parallel, transverse elongate heat seals in the bag central portion.
Further, the apparatus may comprise a bag splitting knife mounted for vertical movement between a lowered position and a raised cutting position extending between the heat seal bands, so that when the bag is retained between the heat seal bar and the lower seal support and the bag splitting knife is moved to the raised cutting position, the bag splitting knife forms a continuous transverse cut in an unsealed strip of the bag extending between the heat seals across a transverse dimension of the bag. This separates the downline subcompartment from the upline subcompartment, to form two separate, smaller sealed bags from one larger sealed bag. The cutting movement of the bag splitting knife may be driven by a pneumatic cylinder, so that the bag splitting knife can be discharged from the lowered position to the cutting position by a pneumatic impulse delivered to the pneumatic cylinder. The bag splitting knife comprising a linear array of generally V-shaped teeth, each tooth of the array comprising a tip and a cutting edge tapering from the tip to a base wider than the tip, the cutting edges of the teeth meeting end-to-end at the bases of the teeth to form a continuous cutting edge of the bag splitting knife.
In one embodiment, the apparatus further comprises a bag splitting knife stop member movable between a disengaged position and an engaged position obstructing movement of the bag splitting knife past a raised perforating position. In the perforating position, an upper portion of each tooth penetrates the unsealed strip to form a perforation comprising a plurality of discontinuous cuts spaced apart along the unsealed strip. The raised perforating position is disposed at an elevation between the lowered position and the raised cutting position. Thus, when the bag splitting knife stop member is in the engaged position, the bag splitting knife can be discharged from the lowered position to the perforating position by a pneumatic impulse delivered to the pneumatic cylinder and is restrained from passing the perforating position by the bag splitting knife stop member.
The packaging apparatus may also comprise a bag separation tool configured to press (typically upwardly or downwardly) against a portion of said longitudinal strip connecting the bag gripped between the seal bars to an adjacent upline bag to separate the adjacent bags. A preformed perforation extending transversely across the longitudinal strip may facilitate separation by the separation tool. For example, the apparatus may comprise a pre-perforation knife adapted to form such a perforation, extending across the proximal longitudinal strip to a proximal end of each pair of adjacent free side edges of adjacent bags. The perforation may, for example, be formed before the proximal longitudinal strip is fed between the opposed belts.
According to another aspect of the invention, a stacked loading packaging apparatus is provided. Similarly to the apparatus described above, the stacked loading apparatus comprises a web conveyor cooperating with a pair of opposed belts to support and advance a web of flexible material comprising interconnected bags. A bag loader of the apparatus is configured to insert a generally horizontally oriented first item into one of the bags between the opposed belts through an opening of the bag at a loading height and deposit the first item inside said bag. The loading height is generally fixed, and a lift mechanism is provided to lower the web conveyor to permit the bag loader to insert again without impinging the previously deposited item. Thus, the lift mechanism may index downward in stepwise increments equal to approximately the thickness of a deposited item, in between successive insertions of the loader. These movements may be programmed into and coordinated by an electronic controller of the packaging apparatus. To facilitate insertion of the loader, the opposed belts may guide top and bottom plies of the web around a spreader bracket at a product infeed station, the spreader bracket being configured to expand to spread apart the plies of the web, typically at or near the proximal longitudinal strip, to form a vertical gap for insertion of the bag loader and supported item.
With reference to the accompanying drawings, the structure and function of an automatic packaging apparatus 10 according to the present invention will now be described. Apparatus 10 embodies aspects of the present invention providing for loading stacked layers of products into bags on a conveyor and for forming a dividing seal in a bag on a conveyor to divide the bag into separately sealed subcompartments, which may be permanently connected, manually separable, or separated as desired. The illustrated packaging apparatus 10 also includes in-line bag making and modified atmosphere gas evacuation and replacement functions, described briefly herein. A more detailed description of such aspects of a packaging apparatus is provided in U.S. Pat. No. 8,689,529 and in U.S. patent application Ser. No. 14/202,952, the entire contents of which are hereby incorporated by reference. However, the present invention is not so limited. For example, the stacked loading and bag splitting/dividing aspects of the invention may be advantageously incorporated more generally in machines that load and seal products into bags of an interconnected, conveyorized web, regardless of whether the bags are formed in-line by the apparatus of the invention, formed in-line by a separate machine which feeds the web of bags to the apparatus of the invention, preformed on a roll, or otherwise fed into the inventive apparatus. Also, the invention is advantageously employed for loading, sealing, and forming compartments from bags in an interconnected web, regardless of whether they are evacuated and refilled with a replacement gas or gas mixture, evacuated only, or simply sealed without manipulating the gaseous environment to be sealed within the bags.
Turning to
In the illustrated embodiment, each interconnected flexible bag 22 formed in web 20 has a distal folded edge 26 and side seals 25, as shown in
To permit separation of adjacent flexible bags 22, the side edges of flexible bags 22 are cut along a side edge cut 30 that meets pre-perforation 27, pre-perforation 27 extending across a proximal longitudinal strip 31 of web 20 from a proximal end of side edge cut 30 to proximal edge 23 of web 20. Side edge cut 30 is preferably a complete cut rather than a perforation, thus eliminating the need for subsequent tearing along cut 30 to separate bags 22, while also permitting the edges of bags 22 to be displaced longitudinally inwardly and away from neighboring bags 22 when bags 22 are expanded vertically to accommodate trays T, thus avoiding undue stresses on web 20. Pre-perforation 27, on the other hand, is advantageously a discontinuous perforation rather than a complete cut, permitting proximal longitudinal strip 31 of web 20 to remain intact as it passes through apparatus 10, to facilitate simultaneous alignment of each bag 22 at its respective station of apparatus 10.
As shown in
A product infeed station 34 is configured to separate the layers of web 20 at an open proximal edge 23 of web 20 and bag 22 and insert a product to be packaged into bag 22. Products to be inserted into bag 22 are illustrated herein for simplicity as contained in trays T, but they could be provided with any other suitable form of pre-packaging, such as a wrapper or separator sheet, or no pre-packaging at all. Product infeed station 34 comprises a product infeed conveyor 33 for inserting trays T into flexible bag 22. As illustrated schematically in
Product infeed station 34 preferably comprises a conventional spreader bracket 55, shown in
Turning again to
Once flexible bag 22 is supplied with a load, a controller is used to advance main web conveyor 12 in a downline direction. Flexible bag 22 is thus moved downline to a gas flushing station 38 where substantially all of the gas, typically primarily air, is drawn out of bag 22 by any appropriate suction implement, such as a snorkel 44 in fluid communication with a vacuum source, and a replacement gas supplying a desired modified atmosphere is injected by an appropriate implement, which may also be snorkel 44 in fluid communication with a pressurized gas source. Typical replacement gas mixtures may, for example, comprise about 0.4% carbon monoxide, about 30% carbon dioxide, and about 69.6% nitrogen, to provide a low- to no-oxygen modified environment in bag 22; or 80% oxygen and 20% carbon dioxide, to provide a high-oxygen modified environment in bag 22. The apparatus may include a plurality of pressurized tanks containing different desired gas mixtures, and programmable valves or throttles configured for supplying gas from a selected tank to a particular bag 22.
After the completion of gas flushing, flexible bag 22 is moved downline by main web conveyor 12 to proximal sealing station 39 where proximal edge 23 is sealed to form a proximal seal 54 (see
After proximal seal 54 has been formed, bag 22 is advanced downline to a dividing seal station 58 including a dividing sealer 65. Dividing seal station 58 is configured to seal bag 22 across its transverse width at a position between its side seals to divide bag 22 into separately sealed subcompartments 63. Dividing seal station 58 includes a dividing seal bar 60, disposed above main web conveyor 12 just beyond its downline end 62; and a dividing sealer lower support 64, disposed below main web conveyor 12 just beyond its downline end 62. When bag 22 is at dividing seal station 58, dividing seal bar 60 is positioned between side seals 25 of bag 22, so that the downline side seal 25 and a downline portion 66 of bag 22 is located beyond downline end 62 of main web conveyor 12. Downline portion 66 is preferably supported on a takeaway conveyor 68 that indexes forward in synchronization with main web conveyor 12 and timing belts 35. In alternative embodiments, the positioning of dividing sealer 65 may vary depending on whether subcompartments of equal or differing sizes are desired.
In operation, dividing sealer lower support 64 is raised by pneumatic cylinders 69 (or other equivalent linear motive device, not shown) into engagement with dividing seal bar 60 to grip a central portion of bag 22 between dividing sealer lower support 64 and dividing seal bar 60 as depicted in
In still another mode, when it is desired to form a separable dual-compartment bag 22″′ comprising connected but manually separable smaller bags 22′, as shown in
Alternatively, a transverse perforating knife 94 as shown in
Certain features and methods pertaining to dividing seal station 58 are provided to promote consistent compartment attributes and dividing seal quality. For instance, when bag 22 reaches dividing seal station 58, a gas bulge B may initially be present, due to inertia of the gas in bag 22 and the intermittent advancing movement of web 20. Thus, the raising of dividing sealer lower support 64 is preferably delayed by a dwell time predetermined to be sufficient to permit the gas inside bag 22 to settle evenly, promoting an even distribution of gas between subcompartments 63, as well as inhibiting ripples or misalignment the film material that could be caused by sealing when the web film material is being pulled in the direction of bulge B.
In addition, trays T may have a tendency to settle unevenly toward opposite ends of bag 22 when a central portion of bag 22 is lifted. This may be due to one or more of a number of factors. For example, initial asymmetry in the respective positions of trays T may cause them to settle asymmetrically; that is, one or the other of trays T may be initially farther displaced from its respective end of bag 22, closer to proximal seal 54 or distal folded edge 26, or rotated to a different orientation than the other tray T when in the horizontal position, before dividing sealer lower support 64 is raised or linear and/or rotational sliding of trays T on the lower film layer of bag 22, for example, due to trays T sliding in different ways during the intermittent starts and stops of web 20 between product infeed station 34 and dividing seal station 58. In addition, some part of one or both trays T may snag or hang up on a portion of film, or the web film material may have a steeper and/or more even incline from the central portion toward the downline side seal 25 than from the central portion toward the upline side seal 25 of bag 22, due to the upline side seal 25 being closer to the part of proximal longitudinal strip 31 of web 20 that is gripped between timing belts 35 at a position elevated above the top surface of main web conveyor 12. In accordance with the present invention, such tendencies of trays T to settle unevenly to their respective ends of bag 22 are overcome by dividing sealer lower support 64 oscillating up and down through a range of vertical positions elevated above the surfaces of main web conveyor 12 and takeaway conveyor 68, tending to free trays T from possible snags and allow them, as well as the gases in bag 22, to settle fully and evenly. In this way, the formation of a straight, uniform dividing seal 73 is promoted, limiting the appearance of kinks, bends, or anomalies that may weaken or appear to weaken dividing seal 73. For a particular configuration of bag 22, the inventors have found that vertically oscillating a central portion of bag 22, by moving the top of dividing sealer lower support 64 between 2 inches and 5 inches above the support surfaces of main web conveyor 12 and takeaway conveyor 68 for 3 cycles at 5 Hz, consistently provides even settling of trays T to promote a substantially uniform dividing seal 73. Specifically, these results were achieved for a bag 22 formed of 0.002-in thick polynylon film having a 26.4-inch length L along the direction of web travel and a 30-inch width/bag depth w perpendicular to web travel (as indicated in
With reference to
One example of a gripping and pulling type of perforation breaker is illustrated in
Turning now to
In one embodiment, an electronic controller (not shown) is operatively connected to unwind motor 16, main web conveyor 12, timing belt pulleys 36, pre-perforation assembly 24, edge perforator-sealer 28, product infeed station 34 (including product infeed conveyor 33 and spreader bracket 55), gas flushing station 38 (including, for example, any linear actuators for extending and retracting snorkels or other hose attachments, and any gas supply and vacuum valves), proximal sealing station 39 (including heating and linear actuation of proximal sealer 40), dividing seal station 58 (including actuation of pneumatic cylinders 69, knife cylinders 84, and stop yoke cylinders 92 and heating of dividing seal bar 60), and takeaway conveyor 68. The control system causes unwind motor 16, main web conveyor 12, timing belt pulleys 36, and takeaway conveyor 68 to intermittently advance web 20 and bags 22 by an incremental distance approximately equal to a width (i.e., longitudinal dimension) of bag 22, and while web 20 is stationary, causes the foregoing components to operate simultaneously on the corresponding portions of web 20 and the corresponding bags 22 that are positioned at their respective stations. Preferably, the control system includes a servo mechanism (not shown) by which main web conveyor 12, timing belt pulleys 36, and takeaway conveyor 68 are mechanically powered by a single motor and thus inherently synchronized.
While the invention has been described with respect to certain embodiments, as will be appreciated by those skilled in the art, it is to be understood that the invention is capable of numerous changes, modifications and rearrangements, and such changes, modifications and rearrangements are intended to be covered by the following claims.
This application is a continuation of U.S. Nonprovisional application Ser. No. 14/838,815, filed on Aug. 28, 2015, which issued as U.S. Pat. No. 10,407,199 on Sep. 10, 2019, the entirety of which is hereby fully incorporated by reference herein.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 14838815 | Aug 2015 | US |
Child | 16566535 | US |