The invention relates to a machine for forming a flexible pouch, More particularly, the invention relates to a machine for forming flexible pouches from a roll of continuous web of film.
It is well known in the art to provide flexible pouches with a reclosable closure such as a zipper type, press to seal, or slide fastener closure. The flexible pouches are typically formed from a roll of continuous web of flexible film that is sealed along the side edges prior to the separation of the flexible film into individual separate pouches. The flexible film is preprinted with images and text describing the product to be contained therein. As such, it is important that the flexible film be accurately positioned with respect to the side seals that delineate the film into separate pouches.
Moreover, as the side seals extending across height of the pouch, the side seals pass through opposite ends of the closure. However, as the side seals typically utilize heat, pressure, ultrasonic, or any combination thereof, the seals must extend through or melt the plastic closure in order to bond the side edges of the pouch. As the closure has a thickness substantially more than the thickness of the walls of the pouch panel and it is required that the entire plastic fastener be heated in order to melt the plastic so as to fuse together and form a non-leaking side edge, substantial heat and time is required.
It has been previously known to provide the closure with a plurality of apertures prior to the connection with the flexible film. An example of such an apparatus is disclosed in U.S. Pat. No. 5,906,438 issued May 25, 1999, which is herein incorporated by reference in the entirety. The apertures are spaced so as to be along the side edges where the seals will made in order to reduce the amount of mass of the closure at the side seal edges so that the time required to form the seal, the size of the seal across the closure at the side edges, and the occurrences of faulty seals will be reduced.
With respect to
Further, during the formation process the flexible film has a tendency to stretch which distorts the images preprinted on the flexible film. In addition, the stretching of the film can potentially cause the images on the film to become misaligned with the sealing and separation station. If the images are not properly aligned with the sealing station and the separation station, the separated pouches will be defective as the placement of the images are disfigured.
Accordingly, there exists a need for an apparatus capable of accurately aligning the continuous web of film so that the images and apertures are properly placed with respect to the side seals by relieving the tension in the flexible film.
The present invention provides an apparatus for forming a flexible pouch from a continuous web of flexible film, which overcomes the above-mentioned disadvantages of the previously known machines by adjusting the tension in the film so as to accurately align the film as the film is sealed and separated.
In brief, the apparatus is provided for forming a plurality of flexible pouches from a continuous web of film having an interior surface, an opposite exterior surface, a plurality of registration marks spaced a predetermined distance apart. The apparatus includes a film displacement mechanism, a registration mark sensor, and a controller. The film displacement mechanism includes at least one vertically oriented roller that rollingly engages with the continuous web of film. The film displacement mechanism adjusts the tension in the film by horizontally displacing the vertically oriented roller.
The registration mark sensor is positioned upstream from the film displacement mechanism. The registration mark sensor is configured to detect one of the plurality of registration marks. The controller in communication with the film displacement mechanism and the registration mark sensor. The controller receives a signal from the registration mark sensor and controls the film displacement mechanism to adjust the tension in the film. The controller controls the web displacement mechanism to horizontally displace the film.
The apparatus optionally includes a film driver and a plow. The film driver feeds the continuous web of film into the apparatus. The plow is positioned between the film displacement mechanism and the web feeder. The plow contacts the continuous web of film to fold the film along a longitudinal axis so as to form a front panel and a rear panel in which the interior surface of the front panel faces the interior surface of the rear panel. The registration mark sensor is positioned downstream of the plow.
Advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings wherein:
The present invention has utility as an apparatus for forming flexible pouches from a continuous web of flexible film, which compensates for the stretching of the film during pouch formation and closure insertion. By providing the apparatus with a film displacement mechanism, having at least one vertically oriented roller that horizontally displaces the film, the tension in the film can be reduced.
With reference to
The apparatus 100 includes a web driver 102 that feeds a roll 103 of a continuous web of flexible film material 104 that forms the pouch 10, best seen in
With reference to
The apparatus 100 includes a dancer system 110 positioned downstream of the web driver 102. The dancer system 110 accumulates the film 104 feed by the film driver 102, and maintains a constant tension on the film 104 until a secondary driver 112 drives the film 104 forward. The dancer system 110 permits the apparatus 100 to run intermittently.
After exiting the dancer system 110, the film 104 passes through a punch hole device 114, such as disclosed in U.S. Pat. No. 6,217,497 issued Apr. 17, 2001, which is herein incorporated by reference in the entirety. The hole punch device 114 includes a sensor 118 that detects a plurality of registration marks 116 formed on the film 104. The sensor 118 senses registration mark 116 and issues a signal for the hole punch device 114 to punch a pair of holes 107 into the film 104. The holes 107 allow for heat from the heat sealers, described in greater detail below to pass through the holes 107 and seal the bottom portion of the pouch 10.
The plurality of registration marks 116 are spaced a predetermined distance apart on an edge 105 of the film 104. The registration marks 116 are spaced apart by a distance of one pitch P, which is equivalent to a width of the pouch 10. The registration marks 116 are a printed or imbedded into the exterior surface 106, the interior surface 108 or on both sides of the film 104. As best seen in
The secondary driver 112, positioned downstream from the hole punch device 114, drives the film 104 into a folding and closure insertion section 120. In folding and closure insertion section 120, the previously horizontally oriented film 104 is folded by a plow 122 provided in the path of the film 104. The plow 122 folds the film along a longitudinal axis L1 so as to form a front panel 14 and a rear panel 16, as best seen in
Specifically, the film 104 is drawn over the plow 122 which is in contact with the interior surface 108 of the film 104. In addition, the plow 122 includes a gusset forming portion 123 provided underneath the film 104, as best seen in
The folding and closure insertion section 120 further includes a closure installation device 124 that inserts a continuous strand of a reclosable closure 126 between the front panel 14 and the rear panel 16 of the pouch 10. Specifically, the closure 126 is placed between the interior surface 108 of the folded film 104 a predetermined distance from the edges 105 of the film 104, as best seen in
The closure installation device 124 includes a closure feed device 128 which unwinds a length of the zipper fastener 10 from a roll 130. The closure feed device 128 includes an electronically controlled servo motor that feeds the closure 126 through the closure installation device 124. A plurality 132 of rollers defines a closure path that the closure 126 follows from the roll 130 into the film 104. The closure feed device 128, specifically the motor, operates to unwind a length of closure 126 from the roll 130 and feed the closure 126 through the closure installation device 124. Accordingly, the closure 126 is fed by the closure feed device 128 rather than pulled through the closure installation device 124 and into the flexible film 104. The rollers 132 in conjunction with the motor of the closure installation device 126 are configured so as to gently draw out the closure 126 form the roll 130 thereby reducing any slack in the closure installation device 124.
The closure installation device 124 also includes a punch device 134 which forms apertures 136 in the closure 126 prior to the closure 126 being inserted into the film 104. As best seen in
As disclosed in U.S. Pat. No. 5,906,438 issued May 25, 1999, apertures 136 in the continuous stand of closure 126 are provided in order to reduce the amount of plastic material present at the side edge lines 26 of separation in order to reduce the occurrence of a bulbous mass upon separation of the panels into individual pouches 10. The closure insertion device 124 secures the closure 126 to the interior surfaces 108 of the front panel 14 and the rear panel 106 through the operation of heat, pressure, adhesive, ultrasonics, or any combination thereof. It is appreciated, of course, that the means for attaching the closure 126 to the interior surfaces 108 of the front panel 14 and the rear panel 16 at a predetermined distance from the edge 105 of the film 104 is not limited in the methods described thereof.
The apparatus 100 further includes a controller 138 having memory and a processor which is used to control the operation of the apparatus 100, and at least one registration mark sensor 145, which detect the registration marks 116 on the film 104 that is connected to the controller 138. The registration mark sensor 145 is provided downstream of the folding and closure insertion section 120 so as to detect the registration marks 116 the distance between may have varied due to the stress of the folding and closure insertion section 120. The registration mark sensor 145 is optionally a plurality of sensors, and is an optical sensor, bar reader, data matrix reader, or the like which is operable to sense/detect the registration mark 116.
The operation of the closure feed device 124 and hole punch 132 and punch hole device 114 is controlled by the controller 138. The controller 138 receives a signal from a sensor positioned adjacent to the folding and closure insertion section 120 and actuates the servo motor of the closure feed device 128 to advance the feed of a predetermined length of the closure 126 through the closure installation device 124 including the punch device 134. The sensor is optionally a registration mark sensor 145 discussed below.
As the apparatus 100 advances the film 104 through the pouch formation process intermediately, the closure feed device 128 in coordination advances only the required amount of the closure 126 into the intermediately advancing film 104. The closure feed device 128 reduces the stress on the film 104, as the film 104 is no longer required to bear the stress of unwinding the closure 126 from the roll 130 and pulling the closure 126 through punch device 134, thus allowing the closure installation device 124 to be used on thinner gauged continuous webs if films formed of thinner gauged flexible material that would have ripped or torn if required to bear the stress of pulling the closure 126.
Positioned at least one pitch P downstream from the registration mark sensor 145 is a gusset seal station 172. The gusset seal station 172 is controlled by the controller 138 based on a signal from the registration mark sensor 145. The gusset seal station 172 includes a pair of seal bars 174 positioned on either side of the film 104. Each of the pair of seal bars 174 is provided on a rod 175 attached to an actuation member 176 which are controlled by the controller 138. The actuation member 176 moves the rod 175 and the seal bars 174 between a first position and a second position. As best seen in
In operation, a registration mark 116 on the film 104 is detected by the registration mark sensor 145 and a signal indicating such is sent to the controller 138. As the seal bars 174 are positioned at least one pitch P downstream of the registration mark sensor 145, the controller 138 actuates the actuation members 176 to move the seal bars 174 from the first position to the second position to provide a preliminary seal 28 at the correct position where the holes 107 are formed on the film 104.
The preliminary seal 28 prevents the portion of the film 104 that forms the gusset 24 from dropping down between the front panel 14 and the rear panel 16 during pouch formation. At the seal station 200, the preliminary seal 28 will be fully sealed. The seal bars 174 use heat, ultrasonics, pressure or a combination thereof to preliminary seal the gusset 24 in place.
The seal bars 174 are positioned so as to align with the holes 107 formed by the hole punch device 114. The holes 107 allow for the interior surfaces 108 of the front panel 14 and the rear panel 16 to contact the gussets 24 which is the portion of the film 104 tucked between the front panel 14 and the rear panel 16. The holes 107 allow for a quicker sealing as the seal bars 174, and those of the seal station 200, are not required to melt through two layers of the film 104 that forms the gusset 24 to result in a standup type pouch 10 which is formed of a flexible material. Heat, pressure, ultrasonics, or any combination thereof from the seal bars 174, and the sealing bars of the sealing station 200, can quickly to pass through the holes 107 and seal the gusset 24 to form the stand up pouch 10.
After the closure 126 has been securely attached to the interior surfaces 108 of the film 104 by the closure installation device 124, and the gusset 24 receives the preliminary seal 28, the folded film 104 passes through a film displacement mechanism 140. The film displacement mechanism 140 is connected to and controlled by the controller 138.
The film displacement mechanism 140 includes an entrance guide roller 142 that guides the film 104 into the film displacement mechanism 140, and an exit guide roller 144 that guides the film out of the film displacement mechanism 140. The film displacement mechanism 140 includes a pair of vertically oriented rollers 146 that are in rollingly engagement with the film 104. As best seen in
Each of the upper and lower roller support members 148A and 148B are connected to a frame or base portion 156 by a drive rod 158 and a driven rod 160. Each of the drive rods 158 includes a distal end 162 and a proximate end 164. The distal ends 162 of the drive rods 158 are pivotally connected to one of the ends 152 of each of the roller support members 148A and 148B and the proximate ends 164 of the drive rods 158 are secured to a rotating device 166 attached to the frame portion 156. Each of the driven rods 160 includes a distal end 168 and a proximate end 170. The distal ends 168 of the driven rods 160 are pivotally connected to one of the ends 152 of each of the roller support members 148A and 148B and the proximate ends 170 of the driven rods 160 are pivotally mounted to the frame portion 156. The drive rods 158 and the driven rods 160 acts as a connection member between the upper and lower roller support members 148A and 148B and the frame portion 156. A shaft connects the proximate ends 166 of both drive rods 158 to the rotating device 166.
After exiting the plow 122 and being folded from a horizontally oriented single thickness position to a vertically oriented double thickness, with a gusset 24, position, the film 104 is traveling at an elevated speed and therefore under tension. The speed and the tension could cause the film 104 to enter the sealing station 200 in an unaligned manner thereby causing defects in the sealing operation. In order remove the tension in the film 104, the film displacement mechanism 140 horizontally displaces the film 104 so as to reduce the elevated speed to a reduced speed that is slower than the elevated speed. The reduction in the travel speed of the film 104 after traveling through the film displacement mechanism 140 reduces the tension in the film 104.
Specifically, as the film 104 exits the folding and closure insertion section 120, the registration mark sensor 145 detects the registration mark 116 provided on the edge 105 of the film 104. The registration mark sensor 145 sends a signal to the controller 138 which actuates the film displacement mechanism 140 to horizontally displace the film 104. The controller 138 controls the rotating device 166 to rotate in the direction of arrow Al thereby driving the drive rod 158 to horizontally displace the pair of rollers 146 in the direction of arrow B1, as best seen in
The horizontal displacement of the film 104 by the film displacement mechanism 140 increases the length of the path that the film 104 must travel thereby reducing the film speed from the elevated speed exiting the folding and closure insertion section 120 to the reduced speed after exiting the film displacement mechanism 140. The reduction in speed and horizontal displacement provides a very low film pulling force which reduces the tension in the film 104 and provides a more precise film feed through the apparatus.
The rotating device 166 includes a servo motor that is electronically controlled by the controller 138 for rotation in the directions of arrows A1 and A2. In the alternative, the rotating device 166 includes a cam actuated reciprocating mechanism that is mechanically controlled or electronically controlled by the controller 138 and which rotates in the direction of arrows A1 and A2. The alternative rotating device further includes a biasing member to biasing the rotating device 166 in the direction of either arrows A1 or A2.
After the film 104 exits the film displacement mechanism 140, at the reduced speed which is lower than the elevated speed that the film 104 had entering the film displacement mechanism 140, the film 104 enters into the sealing station 200, as best seen in
Once the film 104 has received the sealed edges 26 at the sealing station 200, the film 104 travels to a separation station 220 that separates the film 104 into individual pouches 104 by cutting the film 104 along the sealed edges 26. After being separated the individual pouches 10 are transferred into a fill-seal machine 230 or packaged for storage. In the illustrated embodiment, the apparatus 100 is formed together with a rotary fill-seal machine 230; however, the apparatus is not limited to such a configuration. Specifically, the fill-seal machine 230 is optionally connected to or separate from the apparatus, and is optionally a linear fill-seal machine.
It is appreciated, of course, that the various registration mark sensors 118 and 145 are optionally a single sensor positioned either downstream of the plow 122 or upstream of the hole punch device 114.
Having described the invention, however, many modifications thereto will become apparent to those skilled in the art to which it pertains without deviation from the spirit of the invention as defined by the scope of the appended claims.
This application claims priority of U.S. Provisional Patent Application Ser. No. 61/485,537 filed May 12, 2011, which is incorporated herein by reference in the entirety.
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