The present disclosure is directed to a bag wicketer processing line, and more in particular, the set-up of such a processing line prior to normal production operation.
A bag wicketer processing line may utilize pressurized air to aid in the delivery of bag blanks to an exit conveyor. In one aspect, the pressurized air may facilitate the transition of bag blanks from the sideweld seal head to an exit conveyor and a wicket arm portion of the exit conveyor at an exit of the sideweld seal head. In another aspect, the pressurized air may facilitate the transition of bag blanks through processing equipment on the processing line, including a conveyor. In the example of a processing line with a sideweld seal head, the pressurized air may be delivered adjacent the exit of the sideweld seal head via one or more pneumatic blow down bars. The pneumatic blow down bars may be mounted on the sideweld seal head. Pressurized air may be exhausted from nozzles formed on the pneumatic blow down bar and directed toward the advancing film plies or bag blank as it moves onto the exit conveyor. The pressurized air flow from the nozzles of the pneumatic blow down bar forces the advancing film plies or bag blank downward on the exit conveyor and/or wicket arm portion of the exit conveyor to prevent the leading edge of the plies or bag blank from lifting off the exit conveyor and folding backward. The pressurized air also helps eliminate wrinkles near the seal roll, which may compromise seal quality. Finally, the pressurized air helps the plies or bag blanks transition from the exit of the sideweld seal head to the exit conveyor and to the vacuum arms of the wicket arm portion in a straight manner without skewing.
As disclosed in greater detail below, a laser may be used to align the direction of flow of the pressurized air from one or more of the pneumatic the blow down bars at the exit of the sideweld seal head to facilitate set-up prior to normal production operation of the bag wicketer processing line. The laser may be a Class 1 laser, or another directional light generating device may be used. The beam emanating from the laser may be a point or a line. The laser or directional light generating device may be mounted directly to one or more of the pneumatic blow down bars or may be removably attached to a nozzle of the pneumatic blow down bar. Accordingly, each laser or direction light generating device may be pointed in the same direction as the discharge from the nozzles on the respective pneumatic blow down bar and provide a visual aid to the operator in adjusting the pneumatic blow down bar so that the pressurized air is directed to a desired location on the plies or bag blank to force the plies or bag blank into engagement with the exit conveyor and the wicket arm portion. The timing for when the laser is energized, and duration the laser is energized may be directly tied to the timing of the discharge of pressurized air from the nozzles of the pneumatic blow down bars via a control of the processing line, and may be based upon at least one of the speed of advancement of the plies or bag blanks, the size of the bag blanks, the overall cycle time of the sideweld seal head, the exit conveyor speed, and/or the wicket arm portion speed. The visual aid provided by the laser is intended to illustrate to machine operators how the discharge of pressurized air from the nozzles of the pneumatic blow down bars are affecting bag delivery. The visual aid provided by the laser is intended to facilitate set up of the processing line prior to normal production operations and may be used during normal production operations as a visual inspection means to ensure proper operation of the processing line.
Pressurized air from nozzles 30 of one or more pneumatic blow down bars 32 may be directed toward the bag blank BB entering the exit conveyor 22, for instance, from the exit of the sideweld seal head 18. Making reference to
A laser 40 operatively mounted on the pneumatic blow down bar 32 may be energized to produce a beam 42 emanating from the laser. The laser 40 may removably attached to a nozzle 30 of the pneumatic blow down bar 32 or removably attached to the pneumatic blow down bar itself, so the laser may be removed after set-up of the processing line to reduce repeated vibration during normal production operations. The laser 40 may also be a more permanent structure of the pneumatic blowdown bar 32 and may be energized as needed during normal production operations so the operator may perform a visual inspection during operation. In each case, the laser 40 is aligned with the nozzles 30 of the pneumatic blow down bar 32 so that the beam 42 emanating from the laser indicates a direction of flow of the pressurized air from the nozzles 30 of the pneumatic blow down bar 32. The laser 40 may have a casing 44 with an bore 46 sized to fit over a nozzle 30 of the pneumatic blowdown bar 32. The laser 40 may be held in place on the nozzle 30 with a set screw 48. The laser 40 may be energized with a power source controlled from a control 50 associated with the processing line. The lasers may be stored in a storage magazine 52 located near the exit of the sideweld seal head.
With the laser 40 energized, the operator may adjust the position of the pneumatic blow down bar 32 relative to the bag blank BB, the exit of the sideweld seal head 18, and/or the entrance of the exit conveyor 22 in a manner such that the beam emanating 42 from the laser 40 is positioned against the bag blank at a desired location where pressurized air from the nozzles 30 of the pneumatic blow down bar(s) 32 is directed against the bag blank and forces the bag blank into engagement with the belts 26 of the exit conveyor 22 at the entrance of the exit conveyor. In addition, with the laser 40 energized, the operator may adjust the position of the pneumatic blow down bar 32 relative to the bag blank BB, the exit of the sideweld seal head 18, and/or the entrance of the exit conveyor 22 in a manner such that the beam emanating 42 from the laser 40 is positioned against the bag blank at a desired location where pressurized air from the nozzles 30 of the pneumatic blow down bar(s) 32 is directed against the bag blank with the bag blank in engagement with the wicket arm portion 24 of the exit conveyor.
To complete setup of the processing line, the machine operator may then set an interval for energizing the laser 40 and directing pressurized air from the nozzles 30 of the pneumatic blow down bar 32 against the bag blank BB based at least in part upon a speed of advancement of the web, plies or bag blanks, the size of the bag blanks, the overall cycle time of the sideweld seal head, the exit conveyor speed, and/or the wicket arm portion speed. The machine operator may set the interval for energizing the laser 40 and directing pressurized air from the nozzles 30 of the pneumatic blow down bar 32 against the bag blank by energizing the laser and directing pressurized air from the nozzles of the pneumatic blow down bar at the same time and/or the same duration. In doing so, the light emanating from the laser 40 simulates the flow of pressurized air from the nozzles 30 of the pneumatic blow down bar 32.
The processing line may be operated intermittently to allow the machine operator to make adjustments to the pneumatic blow down bar 32 to align the directional flow of pressurized air. The operator may concurrently make other adjustments to the processing line in terms of the speed of advancement of the plies or folded over web, the overall cycle time of the sideweld seal head, a speed of the belts 26 of the exit conveyor 22, and a speed of the wicket arm portion 24 of the exit conveyor. The operator may energize the laser 40 as necessary to simulate the effect of the pressurized air and the location of the pressurized air relative to the bag blank BB.
Depending upon the number of pneumatic blow down bars 32 on processing line 10 at the entrance of the exit conveyor 22 or as the case may be the sideweld seal head 18, the machine operator may align a direction of pressurized air from the nozzles 30 of other pneumatic blow down bars 32 by energizing one or more lasers 40,60 operatively mounted on the other pneumatic blow down bar 32 of the sideweld seal head (for instance, a second laser on a second pneumatic blow down bar, or moving the first laser to the other pneumatic blow down bar). The lasers 40,60 may be similarly configured to be removably attached to the nozzle of the one or more pneumatic blow down bars. The other laser 60 may be aligned with the nozzles 30 of the respective pneumatic blow down bar 32 so that the beam 62 emanating from the other laser 60 indicates a direction of flow of the pressurized air from the nozzles of the other pneumatic blow down bar. With the other laser 60 energized, the machine operator may adjust the position of the other pneumatic blow down bar 32 relative to the bag blank BB and the exit of the sideweld seal head such that the beam 62 emanating from the respective laser 60 is positioned against the bag blank BB at another desired location where pressurized air from the nozzles 30 of the respective pneumatic blow down bar 32 is directed against the bag blank BB and forces the bag blank BB into engagement with the belts 26 of the exit conveyor 22 at the entrance of the conveyor. In connection with the adjustment of the other pneumatic blowdown bar 32, the machine operator may also adjusting the position of the respective pneumatic blow down bar relative to the bag blank BB with the other 60 energized so that the beam 42,62 emanating from the respective laser is positioned against the bag blank at a desired location where pressurized air from the nozzles 30 of the respective pneumatic blow down bar 32 is directed against the bag blank with the bag blank in engagement with the wicket arm portion 24 of the exit conveyor 22.
In connection with the other pneumatic blow down bar 32, the machine operator may complete the set-up for the processing line by setting an interval for energizing the other laser 60 and directing the pressurized air from the other pneumatic blow down bar against the bag blank BB at least in part upon a speed of advancement of the plies through the side weld seal head, the size of the bag blanks, the overall cycle time of the sideweld seal head, the exit conveyor speed, and/or the wicket arm portion speed. The other laser 60 and air pulse from the other pneumatic blow down bar may be interfaced with the control 50. The machine operator may set the interval for energizing the other laser 60 and directing pressurized air from the nozzles 30 of the other pneumatic blow down bar(s) 32 against the bag blank BB by energizing the other laser and directing pressurized air from the nozzles of the other pneumatic blow down bar(s) at the same time and/or the same duration. The light emanating from the other laser simulates the flow of pressurized air from the nozzles of the other pneumatic blow down bar.
With the air pulse and laser associated with the one or more pneumatic blow down bars, the operator may ensure that the bag blank BB is sufficiently flat and unwrinkled so that the bag blank transitions properly from the exit of the sideweld seal head to the exit conveyor, and as applicable, the wicket arm portion 24 of the exit conveyor 22. The vacuum arms of the wicket arm portion 24 of the exit conveyor 22 may engage with the bag blank to keep it smooth and flat as the arms lift the bag blank from the belts 26 of the exit conveyor and move the bag blanks to the downstream conveyor 28. The vacuum arms may have one or more rows of vacuum holes depending upon the format of the bag blank. For instance, in
Depending upon the mounting configuration of the lasers and the pneumatic blowdown bar, during normal production operations, the machine operator may also energize the lasers to provide a periodic visual inspection means of the direction of pressurized air flow from the pneumatic blow down bar as many desired
The embodiments were chosen and described in order to best explain the principles of the disclosure and their practical application to thereby enable others skilled in the art to best utilize said principles in various embodiments and with various modifications as are suited to the particular use contemplated. As various other modifications could be made in the constructions and methods herein described and illustrated without departing from the scope of the invention, it is intended that all matter contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative rather than limiting. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims appended hereto and their equivalents.
This application claims priority benefit of U.S. provisional application Ser. No. 63/308,301, filed Feb. 9, 2022, the disclosure of which is incorporated by reference herein.
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