Abstract:
A bag and dispensing system system wherein the thermoplastic bag to be dispensed may be retained in an open position, to allow for the loading thereof with contents for carrying, such as purchased goods or the like. The system is further configured such that the loaded bag, when dispensed, draws the next bag in the stack forward into an open loading position such that it is ready to be loaded with goods without further manipulation by the attendant. The preferred embodiment of the present invention teaches the utilization multi-edged penetration punch applied to the handle area of the bags to hold said handles together for handling of the bag pack, and for facilitating opening of the next bag in the stack on the rack, when a loaded bag is removed. The preferred embodiment of the present invention utilizes co-extruded film, wherein there is provided a high density film having bonded thereto a lower density film of lesser density than said high density film, such that said lower density film forms the exterior side of said co-extruded film. The co-extruded film is then corona treated at a higher energy level than that recommended for facilitating a printing surface on said film. Said film is then die-cut to form bag stacks, and simultaneously punched with the multi-faceted punch in the area of the handles. This punch penetrates the film forming the bag walls, melding the adjacent walls together in a releasable fashion, allowing self opening of said bags.

Description:
STATEMENT OF CONTINUING APPLICATIONS 
     The present invention is a continuation-in-part of U.S. patent application Ser. No. 09/189,854, filed Nov. 10, 1998, pending, and a continuation-in-part of Ser. No. 08/717,083, U.S. Pat. No. 5,863,130, issued Jan. 26, 1999, filed Oct. 7, 1996, which is a continuation-in-part of Ser. No. 08/337,167, U.S. Pat. No. 5,561,967, issued Oct. 8, 1996 and filed Nov. 10, 1994, which is a continuation-in-part of Ser. No. 08/124,278 U.S. Pat. No. 5,363,965, issued Nov. 15, 1994 and filed Sep. 20, 1993. 
    
    
     INVENTION FIELD 
     The present invention relates to bag dispensing systems, and particularly to a bag and system for dispensing self-opening thermoplastic bags or the like from a stack of bags. The present system is configured such that it may be utilized with a variety of off-the-shelf rack configurations, and to provide optimal characteristics for dispensing bags one at a time, while further providing a system wherein the bag to be dispensed may be retained in an open position, to allow for the loading thereof with contents for carrying, such as purchased goods or the like. The system is further configured such that the loaded bag, when dispensed, draws the next bag in the stack forward into an open loading position such that it is ready to be loaded with goods without further manipulation by the attendant. 
     The preferred embodiment of the present invention teaches the utilization of a star, X, cross-configured, or other multi-edged penetration punch applied to the handle area of the bags as a pack in such a manner as provide a punched region in the pack, to hold said handles together for handling of the bag pack, and for facilitating opening of the next bag in the stack on the rack, when a loaded bag is removed. 
     The self-opening characteristics of the present invention have been found to be greatly improved via the utilization of a co-extruded film, wherein there is provided a mostly high density film having bonded thereto a mostly low density, or even in some formulations a medium density film of substantially lesser thickness than said high density film, such that said low density film forms the exterior, exposed side of the tube of said co-extruded film. 
     The co-extruded film is then corona treated at a higher energy level than that recommended for facilitating a printing surface on said film. Said film is then die-cut to form bag stacks, and simultaneously punched with the multi-faceted punch in the area of the handles. This punch penetrates the film forming the bag walls, melding the adjacent walls together in a releasable fashion, facilitating holding of the bag handles in the bag pack for transport and loading on to a bag dispenser, and providing a means for opening the next bag to be dispensed upon removal of a bag from the dispenser. 
     GENERAL BACKGROUND DISCUSSION 
     Although the prior art has contemplated literally hundreds of various designs for bags and bag dispensing systems, relatively few have proved easily implemented and few yet have proved consistent in performance. 
     A list of prior patents which may be of interest is presented below 
     
         ______________________________________U.S. Pat. No.        Inventor(s)  Issue Date______________________________________5,335,788    Beasley et al                     August 09, 19945,123,145    Huang et al  May 25, 19935,183,158    Boyd et al   Feb 02, 19935,014,852    Herrington et al                     May 14, 19915,013,290    DeMatteis    May 07, 19914,989,732    Smith        Feb 05, 19914,676,378    Baxley et al Jun 30, 19874,562,925    Pistner      Jan 07, 19863,869,065    Wang         Mar 04, 1975______________________________________ 
    
     U.S. Pat. Nos. 4,989,732 and 5,183,158 to Mobil Oil Corporation teaches a self opening bag system wherein there is contemplated a thermoplastic bag pack having handles emanating from opposing sides of a bag mouth, wherein there is provided a pressure bonded area of the pack, such that the plastic film of the bags are in &#34;face to face&#34; engagement between the top and base of the handles, and beneath the medial area of the bag mouth. 
     The Mobil patents are distinguishable from the present invention, as they contemplate a non-permeating engagement of the film in the various layers of plastic forming the bag pack. Further, unlike the Mobil patents, the present invention does not require pressure-bonding below the mouth of the bags, as is specifically contemplated, and believed required, for the Mobil system to work. 
     Unlike Mobil, the present systems punch configuration for providing a permeated, releasible pressure bond provides sufficient releasable binding of the film layers, via melding of the severed film, to draw the next bag open for dispensing, with the removal of the full bag from the rack, without the necessity of the medial pressure bond below the bag mouth as in &#39;732, as well as a separate pressure bond at the base of the bag and pack, as contemplated and claimed in &#39;158. 
     U.S. Pat. No. 5,013,290 to DeMatteis contemplates a t-shirt bag pack formed of co-extruded plastic film, wherein the inner layer comprises a relatively low friction coefficient, the outer layer comprises a generally high friction coefficient, said t-shirt bag pack having formed in the handles a handle aperture having a flap designed to rest upon the rods of a dispenser rack in such a manner such that the flaps are oriented so that they are disposed away from the mass of the bags to pass the weight of the bag pack of said bundle downward through the flaps and onto said rods. The patent refers to the high friction, outer layer of the co-extrusion being formed of low density polyethylene resin (LDPE), the inner layer formed of high density polyethylene resin (HDPE). 
     U.S. Pat. No. 5,335,788 to Sonoco Products Company teaches a &#34;Self-Opening Polyethylene Bag Stack and Process for Producing Same&#34;, teaching a mono-extruded bag formed from HDPE film, said film having a corona treatment applied thereto. Quoting this patent (Col 1, Ln 67-Col2 Ln45): 
     &#34;In general, the phenomenon of corona-induced self-adhesion of polyethylene film is not a new development as far as film processors are concerned. On the contrary, processors continually fought this problem, more commonly known as &#34;blocking&#34; for many years. In fact, most LDPE and LLDPE contain specific amounts of slip and anti-block additives to counteract the &#34;blocking&#34; effect. However, high molecular weight, high density polyethylene (HDPE) which has substantially greater crystallinity and is a more substantially linear polymer does not tend to block, and is more often than not does not contain any slip or antiblock additives. 
     The mechanism of hydrogen bonding in polyethylene films a result of corona treating is reported by Owens in J. Appl. Polym. Sci. 19, 256-271 (1975). The polyethylene films treated by Owens were LLDPE (the material was reported to have a density of 0.926). However, the conditions of heat and pressure which readily caused blocking in corona treated LDPE and LLDPE seem to have little or no effect on HDPE. 
     Apparently for similar reasons, although the process disclosed in Prader U.S. Pat. No. 5,087,234 can be successfully employed on low density polyethylene materials to form self-opening bag stacks, this process is generally ineffective when used for high molecular weight, high density polyethylene (HDPE) bag stacks. Thus, this process is not successful even when the degree of corona discharge treatment is applied to the surfaces of the tubular film is increased in order to induce self-adhesion of the outer surfaces of adjacent bags during the mouth and handle cutting process. Similarly, even when the cutting blade edges are dulled in order to increase the degree of pressure exerted on the bags during the cutting process, self-adhesion of adjacent bags for self opening is not achieved with HDPE. 
     Accordingly, although easy-open bag stacks of LLDPE and LDPE film bags can be readily provided without the necessity of a separate adhesive layer between the bags, a separate adhesive layer is still required between HDPE bags when these bags are prepared by prior art manufacturing process. Moreover, with low density polyethylene materials, the known process for forming self-opening bags such as described in U.S. Pat. No. 5,087,234 to Prader to not allow for substantial adjustment of the degree of bonding between adjacent bags or variation of bonding locations.&#34; 
     Unlike the present invention, the &#39;788 patent not only appears to contemplate a film of at least 50% HDPE in the compression area, but also teaches a compression means utilizing a blunt end punch, wherein the compressed film is not severed, the blunt punch apparently compressing the bag walls together resulting in decreased thickness. Further, the above quote teaches that the novelty &#39;788 rests in the ability to corona treat and punch HDPE bags in order to provide an HDPE bag stack having self-opening characteristics, the quote apparently indicating that corona treating LDPE is not particularly new. Unlike &#39;788, the present invention contemplates a system utilizing co-extruded film, wherein the outer layer comprises mostly, if not all, LDPE or LLDPE product. Further &#39;788 does not contemplate the utilization of a punch formed of a multi-faceted cutting blades, as is shown and claimed in the present invention, which punch penetrates and severs the bag walls, melding the cut edges together, as opposed to compressing them together, as is taught in &#39;788. 
     SUMMARY DISCUSSION OF THE INVENTION 
     Unlike the prior art, the present invention provides a self opening bag and dispenser system which is consistent in performance, and comparatively strong and reliable, while being inexpensive to manufacture, requiring little in the way of custom manufacturing equipment. 
     The present invention is taught in the preferred embodiment of the present invention is to be utilized in conjunction with a pack of T-shirt thermoplastic bags or the like, which are dispensed from a rack having first and second elongated, somewhat horizontally displaced bag handle holding members, and a central tab piece emanating from the bag mouth. 
     As taught, the present invention teaches the application of two punches in the same general vicinity in the handle area of a bag pack, said punches having multi-facted cutting edges in the configuration of, for example, star, X, or cross configurations. 
     It has been found that this configuration punch, which not only applies a pressure bond to the plastic film forming the bags and bag pack, but also permeates said walls, provides sufficient bonding between the walls to allow for the consistent dispensing of a bag from the pack with the removal from the rack of a previously dispensed bag. Other configured punches have failed to perform in such a manner. 
     The preferred embodiment of the present invention further contemplates the utilization of a co-extruded film comprising a first ply of mostly HDPE (up to 75-80%+HDPE), and a second ply of LDPE or LLDPE (linear low density polyethylene), said co-extruded film formed into a bag pack such that the first ply forms the inner walls of the bag, and the second ply forms the outer wall of the bag. The coextruded film is then corona treated at an intensity which exceeds that of traditional corona treatment for providing a printable surface, in order to treat the low density outer layer to facilitate a better bonding surface, further enhancing the bond, providing a higher bonding between adjacent exterior, low density outer walls of adjacent bags via the punch of the present invention. 
     The coextrusion of the present invention provides a more economical, stronger, better self-opening bag than prior art systems. In the present invention, the first ply, formed of HDPE, may have a thickness comprising up to, for example, 80+% of the co-extruded, two ply film, while the second ply, formed of the LDPE or LLDPE, may only comprise 20% or less of the density of the co-extruded, two ply film. Occidental Chemical Company of Texas has indicated that Polyethylene resins having a density above 0.94 are referred to as High Density. Medium, Low, and Linear Low density have a density of less than 0.94. As HDPE is a stronger film than MDPE, LDPE, or LLDPE, it is advantageous to have as high an HDPE content as possible. However, HDPE does not print so well, and, in mono-extruded, single ply systems, it is often necessary to blend HDPE with MDPE, LDPE or LLDPE in order to provide a printable surface, which may have to be corona treated to allow for retention of the ink. This blending, which can be 20%, 30%, and even 40%+, can result in significant weakening of the film. Further, blending may be necessary for providing a pack which will self open when punched, as contemplated in the &#39;788 patent, resulting in a weakened film for the sake of making the system self opening. Lastly, low density resin may be expensive compared to high density, so it behooves one to utilize as little low density resin as possible. 
     The present system allows one to utilize, proportionally, a lesser percentage of low density or linear low density polyethylene in a two ply, coextruded context, than would be implemented in a typical monoextrusion context, resulting in superior strength, better bonding, and at a perceived lesser overall cost. 
     It is therefore an object of the present invention to provide a self opening bag system which may be utilized with a variety of configurations of bag packs to be dispensed from a rack. 
     It is another object of the present invention to provide a self opening bag system which utilizes significantly less LDPE or LLDPE than other systems, while capitalizing on the benefits of LDPE or LLDPE, without the weaknesses or costs associated with other systems. 
     It is another object of the present invention to provide a self opening bag system which is relatively easily implemented, cost effective, and reliable. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     For a further understanding of the nature and objects of the present invention, reference should be had to the following detailed description, taken in conjunction with the accompanying drawings, in which like parts are given like reference numerals, and wherein: 
     FIG. 1 is a frontal view of the bag of the preferred, exemplary embodiment of the present invention, illustrating the self-opening punch configuration and placement thereof. 
     FIG. 2a is an isometric view of the bag pack of bags of FIG. 1, as it is placed upon an exemplary rack, illustrating the communication of the support cuts with the various rack support members, and the relation of the self-opening punches thereto. 
     FIG. 2b is an isometric view of the bag pack of bags of FIG. 2a, illustrating a user opening a first bag on a rack, allowing the loading thereof. 
     FIG. 2c is an isometric view of the bag pack of bags of FIG. 2a, illustrating a user removing the first bag of FIG. 2B, wherein the next bag on the rack has been opened by the removal of said first bag, via handle punches. 
     FIG. 2d is an isometric view of the bag pack of bags of FIG. 2a, illustrating the next bag has been fully opened by the removal of the first bag 
     FIG. 3a is a side view of the preferred embodiment of the self-opening punch, illustrating the multi-faceted cutting blade configuration in the general form of a &#34;+&#34; or &#34;x&#34;. 
     FIG. 3b is an end view of the punch of FIG. 3a, illustrating an end view. 
     FIG. 3c is an isometric view of the punch of FIG. 3a, illustrating the overall configuration of said punch. 
     FIG. 4 is a flow chart illustrating the basic steps in forming the bag pack of the present invention. 
     FIG. 5 is a cross-sectional view of an exemplary co-extrusion of thermoplastic film, illustrating a base extrusion of primarily HDPE, and a top extrusion of primarily LDPE. 
     FIG. 6 is a top view of an exemplary die for forming the bag pack of the present invention, including cutting blades for fonning the handle, handle apertures and mouth area of each bag and the bag pack, as well as exemplary placement of the self opening die punches. 
     FIG. 7 is an isometric view of corona treatment of the film tube of the present invention following co-extrusion. 
     FIG. 8 illustrates an alternative placement of the self opening punches of the present invention. 
     FIG. 9 illustrates a best mode, &#34;tab free&#34; design of the present invention, illustrating a medial bag mouth retaining member which is configured to dispense with each individual bag, such that no tab piece is left on the dispensing rack after the bag pack is dispensed. 
     FIG. 10 illustrates the alternative bag design of FIG. 9, wherein a pack of the &#34;tab free&#34; bags are mounted upon a rack, and a bag is shown being dispensed therefrom. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     As can be seen in FIG. 1, the bag B of the preferred, exemplary embodiment of the present invention, includes first 1 and second 2 sides, a bottom 3 and top 4 ends, and a mouth 5. Emanating from opposing ends of the mouth 5 are first 7 and second 6 handles, each handle having an inner side edge 8, 9, respectively. Further included in the handles 7, 6, are first and second handle support cuts 10, 11, respectively. Each handle support cut 10, 11, as shown has formed therein first 12 and second 13 tabs, respectively, connectively affixed to the handle via uncut portion forming tab connections 14, 15, respectively, at the bottom of said tabs 12, 13. The handle support cuts may be formed via cutting die or the like pressed upon and through the bag or bag pack, as shown in FIG. 6. 
     Emanating from the bag mouth 5 is dispensing tab 22, having a neck 24, and an upper, bulbous portion 23 having an end 25. Formed and situated in the bulbous portion 23 of tab 22 is the tab support cut 26 having first 27 and second 28 ends. 
     As shown in FIG. 2A of the drawings, the bag pack P of the present invention may be dispensed upon a rack R having first and second, somewhat horizontally situated handle support members H&#39;, H&#34;, and a tab support member T, configured to communicate with handle support cuts 10, 11 and tab support cut 26, respectively. 
     The individual bags of the present invention are held together in a bag pack P via the utilization of a heated or cold punch 29, fusing the dispensing tabs 22 together. The multi-faceted linear punches 30&#39;,31&#39; and 30&#34;, 31&#34; are formed in the first and second handles, respectively, in the general area ofthe tabs 12, 13. As shown, both first 30&#39;, 30&#34;, and second 31&#39;, 31&#34; punches may be positioned between the tops 8, 9 of the bag handles 7, 6 and the respective tab areas 12, 13; the second punches 31&#39;, 31&#34; may be positioned generally near the inner edges 16, 17 of their respective bag handles 7, 6, with the first punches 30&#39;, 30&#34; positioned more towards the medial area of the handles, between the inner edges and distal, outer edges of the bag handles. Further, the first and second punches may be of varying sizes, for example, the first punches may comprise a larger punch, for example, 10-50% larger than the second punches, in order to prevent weakening of the bag due to the second punches being closer to the inner edge than the first punches, which are further from either the inner or outer edges of the bag handles. 
     As illustrated in FIG. 2B, the present invention is utilized in much the same manner as conventional T-shirt bags, with the lead bag first placed in the loading position by grasping and directing the first wall of the bag forward by pulling same P, thereby separating the first 32 and second 33 walls of the bag, and opening said bag into a separated, supported (via the handle support racks), loading position. 
     FIGS. 2B-2C illustrate the self-opening properties of the present system, utilizing the multi-facet punch design, which has been found to work as well with a star or cross punch configuration. 
     As shown, the user U pulls P the first wall 32 of the lead bag L loaded bag from the rack. In doing so, the bag handle support cuts 10, 11 ride along the handle support rods H, H&#34; away from the bag pack. However, the punches 30&#39;, 30&#34;, 31&#39;, 31&#34; formed in the rear wall 33 of the lead bag cause the handle area of the rear wall of the lead bag to adhere to the front wall 35 of the next bag N sufficient to break 36 the bond between the upper bag wall and the tab 5, allowing said front wall 35 to be directed into an open position O on the rack. Once the lead bag L is removed from the rack, as shown in FIG. 2D, the next bag, now in the open position, becomes the lead bag L&#39;, and the process repeats itself with the loading and removal of said bag, dispensing the next bag N&#39;, and so on. 
     Referring to FIGS. 2C-2D, the punches taught in the present invention permeate the walls of the bags such that the rear wall of the next bag N remains with the pack, and supported by tab 5, and hold the opened bag in place on the rack, as the lead bag is removed from the rack, the rear wall of the next bag holding said bag firm as the joined, punched area on the lead and next bag separates, as the lead bag is removed from the rack, before the rear wall 33 is removed from the support rods H&#39;, H&#34;, but after the next bag is placed in an open, ready to be loaded position. 
     FIGS. 3A&#34;3C illustrate the cross-configured punch 42 of the present invention, whereby there is provided a tip having first 39 and second 40 linear, longitudinal linear punch members perpendicularly intersecting with first 43 and second 44 linear, lateral punch members, forming a multi faceted, or multiple edged punch. 
     As further shown, each of the linear punch members are tapered T&#39;to a generally linear end 45, forming the leading edge of the punch. It has been found that this multiple edged approach, which have tended to comprise generally linear edges, provides not only a penetrating and cutting of the bags forming the bag pack, but has also been found to meld the cut edges together of the adjacent, mostly low density outer walls of the adjacent bags, providing a releasable adhesive means which facilitates the self-opening operation of the present bag system. 
     Accordingly, other punches having similar characteristics may also work in the fashion described in the present invention, as long as they comprise a plurality of punch members forming a multi-edged or multi-faceted punch. The punch, when applied, should partially meld the outer bag walls such that the rear, outer wall of the lead bag in a bag pack is releasably melded with the front, outer wall of the next bag in the pack. Although the preferred embodiment of the present invention contemplates the utilization of a linear cutting edge forming the leading edge of the punch, it is anticipated that non-linear, or radial leading cutting edges may also be implemented with favorable results. 
     FIG. 4 sets forth a flow chart illustrating the basic steps in forming the bag pack of the present invention. As shown, the first step in the process is the formation of the film tube utilized in the manufacture of the bags in the bag stack. Referring to FIG. 5, the present system utilizes a co-extruded extrusion process, wherein the co-extruded film 60 comprises a first ply 61 of mostly HDPE (up to 70%+HDPE, the remainder comprising, for example, color concentrate, and/or recycled resin), and a second ply 62 of MDPE, LDPE or LLDPE (linear low density polyethylene), said co-extruded film formed into a bag pack such that the HDPE forms the inner walls of the bag, and the LDPE or LLDPE forms the outer wall of the bag. An exemplary co-extruder machine is manufactured by Alpine Gb of Germany. 
     In the present invention, the first ply, formed of HDPE, may have a density 63 comprising up to, for example, 70+% of the co-extruded, two ply film, while the second ply, formed of the LDPE or LLDPE, may only comprise 30-% of the density 64 of the co-extruded, two ply film. It is noted that the relative thicknesses of the plies in the figure is not particularly to scale, and is for illustrative purposes only. As earlier discussed, HDPE is a stronger film than LDPE, MDPE, or LLDPE, and it is therefore advantageous to have as high an HDPE content as possible. An exemplary film thickness for the overall co-extruded, two ply film would be, for example, 0.53 mils, with the first ply comprising, for example, 0.371 mils and the second ply comprising 0.159 mils. 
     As earlier discussed, the present system allows one to utilize, proportionally, a lesser percentage of low density or linear low density polyethylene in a two ply, coextruded context, than would be implemented in a typical monoextrusion context , and providing a first ply comprising mostly HDPE, resulting in superior strength, better bonding, and at a perceived lesser overall material cost. 
     Returning to FIG. 4, the next step in the fabrication process is to flatten the film tube, then exposure of the co-extruded film tube to a corona field. As shown in FIG. 7, the extruded film tube 66, formed from the co-extruded film 60, is situated such that the outer surface 65 of the tube comprises the LDPE or LLDPE second ply 62, and the inner surface of the tube comprises the HDPE first ply 61, is passed through a corona field facilitated by a corona field generator 67, corona treating 68 the outer, second ply of the co-extruded film. 
     In the exemplary embodiment of the present system, the film tube is progressing through the corona field at a speed of about 50-80 meters per minute, and the corona field has a strength of about, for example, 40-48 dynes (or even 49 or 50 dynes)depending upon the quality of the resin and film thickness. This setting is higher than traditional corona treatment settings for treatment of the film for providing a printing surface. 
     It is perceived that the corona treated, LDPE or LLDPE outer surface of the film further enhances the self-opening properties of the present system, providing better melding of the punched, cut edges of the punched handle areas of the bag stack. 
     Returning to FIG. 4, the corona treated film tube is then gusseted, as is traditionally done in the industry, forming gussets longitudinally along the length of the flattened film tube. The tube is then cut and sealed to form bag blanks, as they are known, and the bag blanks are assembled into a stack for die cutting, to form a bag pack. 
     A die D such as that shown in FIG. 6 is employed to form the stack into a bag pack. As shown, the die includes a main blade 70 which forms the handles and mouth of the bag pack, further including the tab area, further formed by a tab support blade 76, and a tab breakaway blade 77. The handle tabs, as earlier discussed, area formed by first and second tab blades 72, 72&#39;, respectively. Each of the blades of the die is mounted to a base 71 which may be formed, for example, of wood, the blades in the present invention emanating in generally lateral fashion from the base, having sharp edges distal the base. 
     Also emanating from the base 71 of the die is the self opening punches, comprising first 73 and second 74 punches, forming self opening punch 30&#39;, 31&#39; areas as set forth on FIG. 2A, respectively, and back to FIG. 6, third 73&#39; and forth 74&#39; punches, forming self opening punch 30&#34;, 31&#34;, respectively. Also provided is tab punches 75, 75&#39; for permanently fusing the tabs together. 
     The die engages and cuts the bag blank stack as is traditionally done in the industry. For exemplary purposes, the hydraulic driver driving the die of the present invention is set at 80-90 barr for driving the die blades and punches into a bag pack of, for example, 50 high density thermoplastic bags. The die may be heated as is done in the industry, or may be cold, depending upon the resin formulation, speed, number of bags in the bag stack, and other criteria. 
     The invention embodiments herein described are done so in detail for exemplary purposes only, and may be subject to many different variations in design, structure, application and operation methodology. Thus, the detailed disclosures therein should be interpreted in an illustrative, exemplary manner, and not in a limited sense. 
     FIG. 9 and FIG. 10 illustrates a best mode of the present invention as applied to a new and unique tab-less bag design, configured to allow a user to dispense a pack of bags without the necessity of having to dispose of, as a separate step, a tab left upon the dispenser. 
     As shown in FIGS. 9 and 10, the bag 100 is similar in construction to the bag of FIG. 1, except that the dispensing tab (22) of FIG. 1 is replaced with a releasable tab 101 (FIG. 9) configured to dispense with each bag individually upon dispensing. 
     As shown, bag 100 includes a medial area 102 between the handles, forming the bag mouth, which has the releasable tab 101 emanating upwardly therefrom, generally centrally disposed between handles 103, 104. 
     Formed within the releasable tab 101 is dispense cut 105 having first 109 and second 109&#39; ends with a medial area 106 therebetween, the medial area 106 of the entire dispense cut being situated generally above the lower edge of the bag mouth, with each end 107, 107&#39; of said medial area curving in radial fashion towards the bottom of the bag, then curving 108, 108&#39; upwardly, such that each end 109, 109&#39; of the dispense cut is situated generally adjacent to opposing sides 111, 112 of the releasable tab 101, respectively forming a rupture zone 124, 124&#39; in FIG. 10, which will be discussed further infra. 
     In use, a plurality of aligned, stacked bags is formed and retained in place via handle punches a taught in the invention of FIG. 1; in addition, continuing with FIG. 9, linear punches 113, 114 formed by the device of FIGS. 3A-3C may be utilized to facilitate further securement of the bag pack for handling purposes, while providing self-opening characteristics, which may be further enhanced by the corona process of FIG. 4, all of which were discussed supra. 
     Continuing with FIG. 10, the pack 120 of bags is loaded upon a rack 121 as shown, with the dispense cut 105 placed about the medial support member 122 or the rack to support the mouth area of the bags forming the pack, with the handles mounted as previously discussed. The first to be dispensed bag is then pulled by the front wall by the user, removing the bag wall from the pack with the bag in an open, loading position. Once loaded, as the bag is removed from the rack; as shown, with the user pulling the bag from the rack, the pressure upon the dispense cut causes one of the ends to rupture 123, freeing 124 the releasable tab.