Abstract:
A multiple ply freight shipping bag having multiple side gussets. The bag being of the type having pinch closeable upper and lower ends. The side gussets and the bag plies all being stepped in incremental distances to form an elongated sealable stepping pattern for efficient closure of the bag to prevent outward sifting or channeling of products filling the bag. The upper and lower corners of the gusset walls are spot bonded together to maintain a locked position, hold ply alignment, and achieve increased bag strength during and after filling, and wherein the gussets are freely expandable therebetween from the bottom of the bag to the top.

Description:
FIELD OF THE INVENTION 
     The invention is directed to gusseted large pinch-closure type multi-wall bags requiring side gussets from 5½-6″ and larger. 
     BACKGROUND OF THE INVENTION 
     Gusseted bags, having top and bottom pinch closeable ends, are typically made in a multi-wall construction having a plurality of paper plies formed as a tube and laterally offset to provide seams for bonding. The top and bottom ends are usually stepped to provide opposing adhesive “laddered” bonding surfaces. These bags are generally called freight shipping bags in the industry. 
     In regard to such bags, there has begun a market demand for large side gussets of 5½-6″ and greater. It is recognized that bags having single gusset sizes of 5½″ or less work extremely well for small bags, such as for coffee, popcorn, vacuum cleaners, etc., because they are not highly load-stressed and may be manufactured on standard bag formers and filled on known bag spouting machinery. 
     The needs for larger gusset pinch closeable bags involve manufacturers who fill and ship the bags with higher bulk density products and that require greater bag volumes and pallet stackability, thus demanding a larger package. Such bulk products include pet foods, granulated food materials, flake-form materials, powdered and granular chemicals, agricultural products, such as potting soil bark, mulch, and the like. Accordingly, bag customers are requiring a wider range of capacity for a range of bulk densities. It is a goal in the industry to replace other bags that are limited in their capability for handling greater weights and volumes. 
     The industry has also found it beneficial to utilize large gusset bags in order to eliminate overhang when a shipment of bags is palletized. 
     The freight shipping packing and handling industries have found multi-wall bags with pinch closeable ends widely acceptable because of their relative ease in sealing and compatibility with well known bag closure equipment. 
     As the industry has sought to increase the size of gussetted pinch closeable bags, two major factors have arisen that compound the problem in producing the larger or wider side gussets required. As would be understood to those skilled in the art, the larger the gusset becomes, the more free board is needed to close the bag at the open end where the filling spout introduces the product. This means that extra paper is needed to close the top of the bag with paper covering the product so the bag has to be made bigger to accommodate this closure. The larger the gusset becomes the deeper the gusset ribs extend into the gusset of the end tuck and more room is required because these large ribs are difficult to push outwardly when the bag is being filled. This can cause irregular bag expansion that might lead to tearing and ripping. Heretofore, the multi-wall bag industry has not successfully developed or accepted large gusseted pinch closeable bags. Alternate ways have been attempted, such as by using other styles of bags. In great measure, larger gussets, i.e. those that would be generally about 6″ or more in width, are difficult to make in single standard fold gussets. Large percentages of the bags manufactured must be discarded as inferior. The bag-making production lines using the larger gussets also have to be run at slower speeds than non-gusseted pinch closeable bag line speeds. As the industry has experienced, urging these large gussets to form in the tuber, due to the bulkiness in size, creates difficulty in handling and machining during the bag making process. The standard guideline in the multi-wall freight shipping bag has been to not specify gussets that are over 5½″ wide. While certain manufacturers occasionally have provided these larger gussets, there is an inherent weakness at the gussets in large bags. 
     Antecedent to the present invention, bag manufacturers have not produced multiple gusseted pinch closeable bags. Instead, the industry has chosen to focus its effort in producing small-sized pinch bags having a standard single gusset, such as used for popcorn bags, small coffee bags, microwaveable bags, vacuum cleaner bags, and the like. Accordingly, smaller bags have become the norm with respect to utilizing side or lateral gussets. This is because the large gusseted bags have been found to require more timely machinery set-up for the tuber, former, and flattener, plus the impractical end result that they develop a higher waste at a lower production rate. When large gusset bags have been made in this fashion, the bag manufacturer simply accepts the inherent inefficiency and loss to meet an order of a customer. 
     Previous attempts at pinch closeable bags having gussets 6″ and over also have had several other problems. For example, when considering a standard 17″ by 33″ by 8″ bag, wherein the 8″ is the gusset and bag width dimension, the gussets are formed in the bag sides lengthwise of the bag creating two gusset walls having a v-shape arrangement. Thus, the gusset is indented 4″ deep on either side of the bag. When the bag lies empty ready to be filled, there are two 4″ tucks at either side wall for a total of 8″, thus leaving 9″ between the inner folds of the v-shapes for a 17″ wide bag. The room for spouting, filling and forming is thus lessened by 8″ compared to a non-gussetted construction. It has been found that single large gussets of this type have difficulty in being outwardly expanded during the filling process because all of the gusset is facing inwardly and the product mass has to push the gusset in the outward direction. The inherent weakness in forcing paper plies outwardly and at localized pressure zones can lead to bag rupture. There is a particular inherent weakness at the inside apex area of the v-shapes at the “manufactured end” (pre-sealed) of the bag. This can result in tearing and upward fracturing of the bag. The large gusset is difficult to fill out and square properly. The resulting gussets of a filled bag are often a little bit less than the intended bag width of 7 or 8″ because the product in the bag does not fully push out the v-shaped gusset. This reduction in bag depth can also affect the presentation of advertising or printing on the bag sides. As would also be clear, because of this inability to shape or “square out,” the filled bag may actually offer a diminished volume capacity inside the bag, which otherwise could be filled with the product. 
     Therefore, the major goals of the invention are (1) to provide more lateral or inboard room between gussets for forming, filling and spouting; (2) to create easier gusset-shaping during the filling step which allows the gussets to fill outwardly with less localized stress and less product pressure that would otherwise cause rupture in the previously known bags; (3) in providing larger gusseted (deeper) pinch-closeable bags, while maintaining sidewall strength, and (4) allowing the large gussets to be configured in a way so that the filled bags can subsequently be evenly stacked on a pallet without pallet overhang. 
     SUMMARY OF THE INVENTION 
     The present invention provides a multiple gusset for large freight shipping bags of the pinch closeable style wherein the manufactured end is pinch closed and the opposite open end is later sealed by the customer after filling the bag. The invention includes a unique step pattern and folded construction that when seal closed, satisfies industry wide drop testing strength, machine-ability, moisture barrier requirements, and seal closeability on standard pinch closure equipment. The invention may be summarized as providing a multiple gusset bag of greater than 5½-6″ depth utilizing an improved seal-closeable stepping pattern, upper and lower end gusset bonds, and a maximized space between inward folds of the gussets to satisfy fill spouting requirements. 
     Standard pinch closeable three-ply bags with bag widths from about 14-20″ have stepped multi-paper plies with a step pattern length about of 2¼″ or less. For an equivalently sized bag, the present invention provides for a stepping pattern length of 2⅜-2½″ having steps between adjacent ply edges of from {fraction (1/16)}″ up to about {fraction (5/16)}″, which in a preferred embodiment offers a double gusset in a three-ply paper bag. This creates 18 layers of ply thickness at the folded gusset, which when folded to form the pinch closure can create a thickness of over 30 plies at the pinch closed end. Another popular bag size is made of two plies having double-gussets creating a thickness of 12 plies at the gussets. 
     The inventive multi-gusset bag secures the ends of the gussets in a bonded or tacked arrangement, which does not separate during spouting, but yet allows the gusset portions for the full length of the bag therebetween to expand outwardly during filling. 
     On each side of the multi-wall bag, the gussets unfold outwardly taking a rectangular shape forming the squared sides of the bag. The multiple gussets extend from end-to-end, i.e., from the manufactured closed end to the upper open end for receipt of the fill spouting. Both ends of the pinch style bag are folded through the gussets. The invention allows the option of making a flush cut for a top sewn closure or otherwise creating a pinch closure at the open end. Space between gusset infolds is maximized for filling and spouting. As compared to an 8″ gusset in the prior art, wherein only a 9″ gap between in-folds is achieved for a 17″ wide bag, the present invention allows for 13″ between the in-folds of the gussets. Increasing the spout entry space is a significant advantage over present standard single gussets in large freight shipping bags. 
     In providing multiple gussets, by having additional folds at the pinch closeable upper and lower corners, there is difficulty in feeding and gathering these numerous thicknesses, which as stated can be 18 ply thicknesses in a three-ply bag with a double gusset. This creates a problem in holding the bag in proper alignment while it is being filled and after letting it go from the filler to move through the folder and sealer. It is important to hold the gussets in position for an even sealing. Accordingly, the invention includes the aforementioned gusset bonding or tacking at least at the upper open end of the bag in order to hold the gusset in control and to strengthen the bag after it is filled and stacked on a pallet. Thus, the upper ends of the gussets are held together for evenly placing the bag into the sealer after bag filling. This maintains the bag in proper registry so that as it is going through the pinch closure sealer, not only is the gusset prevented from coming open at the top, it also does not allow the gusset to “belly down.” The upper gusset bonding also provides for a straighter feed into the sealing line and creates a cleaner fold at the pinch closeable fold line. Upper gusset bonding also allows the bag to shape up properly as it is filled and does not let the gussets wander or crimp and become uneven to be sealed in an uneven position. 
     The gusset tacking is also preferably included at both ends of the bag just beyond the fold line. The tacking thereby offers strength also at the bottom manufactured end as the product is charged into the bag to forcefully impact the bottom of a bag. The gusset bonding increases strength and holds the gusset securely together as they are being shaped and pushed outwardly from the bottom to the top. 
     The added strength achieved by gusset bonding prevents the ends of the bag from being pushed out at any of the four corners as the bag is going through typical bag flatteners and conventional palletizing systems, and then placed upon a pallet. 
     The unique stepping pattern at both ends of the bag requires that each ply and its adjacent ply are spaced at a minimum of about {fraction (1/16)}-⅛th inch measured longitudinally. This full stepping avoids product sifting or channeling through the plies by providing for at least the same overlap as in conventional pinch bottom bags, but using less paper by stepping more. This configuration also eliminates the need for mitered inside corners required to open the bag up for filling, which is used in prior art configurations. 
     In the disclosed preferred embodiment, the multiple gusset bag has double gussets. However, three or more gussets, i.e., each a v-shaped pair of walls, can be provided. The number is mainly limited to the extent that all the thicknesses of the multi-paper plies must be accommodated in bag tubing, forming and, ultimately, bag folding and sealing machinery. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective view looking downwardly at the open end of a multi-gusset pinch closeable bag made in accordance with the invention wherein at the right side of the bag the gussets are shown bonded together at their top ends and at the left side are separated to show the locations of the gusset bonding for securing the gussets together; 
     FIG. 2 is a front elevational view of the bag as in FIG. 1 showing the stepping pattern of the front and back bag walls and across the left and right multiple gussets; 
     FIG. 3 illustrates the knife bar cutting configurations used to provide a three ply double gusset stepping pattern having a longitudinal span of about 2⅜″, and further showing the location of the fold line relative to the knife cuts at each of the plies; 
     FIG. 4 schematically illustrates the three ply knife cuts of FIG. 3 superimposed to form the bag and showing how each ply is stepped or shingled individually throughout the gussets and the relation of the ply cut upper stepped edges; 
     FIG. 5 is similar to FIG. 4 but, wherein at right side of the bag, the bag is shown in the completed gusset-folded arrangement, wherein the three paper plies are folded together to create  18  thicknesses and stepped at the double gusseted sides of the bag; 
     FIG. 6 is a perspective view of the bag as in FIG. 1 wherein a bag filling spout is shown inserted between the bonded ends of the folded gussets and wherein the upper gusset bonding maintains the gussets in place at the upper corners but allows the gussets to expand therebelow upon introduction of the product through the fill spout; 
     FIG. 7 is a vertical sectional view showing the folding over pinch closure of the bag following the filling step in FIG. 6, whereby the bag is illustrated being folded along the fold line as denoted in FIG. 2 to ultimately effectuate a pinch closure and the overlapping of the multiple ply thicknesses at the side gussets, which are doubled over on themselves at closure; 
     FIG. 8 is a front elevational view of the bag similar to FIG. 2 but showing an alternate embodiment having a two-ply bag; and 
     FIG. 9 illustrates the knife bar cutting configurations used to provide a two-ply double gusset stepping pattern having a longitudinal span of about 2¼″, and further showing the location of the fold line relative to the knife cuts at each of the plies similar to FIG.  3 . 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In the following discussion of FIGS. 1-7, like reference numerals are used throughout to denote the same elements. 
     As explained above, the invention is directed toward multi-wall pinch closeable freight shipping bags. In the embodiment illustrated, the bag is constructed of three paper plies as shown in FIG. 1, however, two-ply and four-ply bags are also commonly used in the industry and are adaptable to the present invention. The invention is not limited to two-four multiple plies and more plies may be provided depending upon the ply thicknesses chosen and machinery capabilities for handling increased thickness. In that regard, the present invention is directed toward using paper plies made of natural Kraft paper in the range of from about 40 lbs. to 70 lbs. This industry-wide standard refers to the number of pounds per a 3,000 square foot ream of paper. The invention is not limited to natural Kraft paper and other suitable paper materials, or useable alternatives, such as metal foils, polyethylene/paper laminate combinations, other foil/plastic/paper laminates, and plastic extrusions, are all within the penumbra of the invention. 
     In greater detailed reference to FIG. 1, a three ply multi-wall paper bag  1  is shown in a perspective view. The bag  1  is made up of one 40 lb. natural Kraft paper ply and two 55 lb. Kraft paper plies as will be described below. The bag  1  of the disclosed embodiment has a width of 17″, a length of 33″, and depth, upon fully expanding side gussets  2  and  3 , of about 8″. The bag  1  has a front wall  4  and a back wall  5 . The front wall  4  and back wall  5  will be seen to be comprised of front and back expanses of bag plies  6 ,  7  and  8 , wherein the bag ply  6  is an outer ply which typically receives printed indicia and may be coated, the ply  7  is an intermediate or middle ply, and the ply  8  is an innermost ply, which would have contact with any product filling the bag  1 . 
     In the preferred embodiment shown, the intermediate ply  7  and inner ply  8  are comprised of 55 lb. Kraft paper plies and the outer ply  6  comprises the 40 lb. Kraft paper. Depending upon the properties of the product to fill the bag, such as product density, physical configurations of granulated or crystalline materials, the bag  1  in the embodiment shown, could be made of three plies of 40 lb. weight each up to three plies of 70 lb. weight. For a two ply construction, the preferred embodiment would utilize two 70 lb. plies to provide sufficient rigidity and strength for most products. However, two plies of 40 lb. each could be used depending on the nature of the material to be filled. 
     In all embodiments of the invention, it is envisioned that the side gussets  2  and  3  have at least two gussets, or v-shaped infolds. However, depending upon ply thicknesses and the ability of tube forming and handling equipment to handle increased thicknesses, a larger number of gussets are envisioned within the scope of the invention. In the disclosed embodiment for the bag  1 , the side gussets  2  and  3  have substantially identical constructions and like reference numerals will be used for both of their corresponding constituent elements hereinafter. A description of one of the side gussets is therefore applicable to the other. As shown in FIG. 1 the side gusset  2  is shown unfolded for purposes of explanation and includes two v-shape folds V 1 , V 2  having infold edges  9  and  11 , respectively, formed at the apices of the gusset walls  10 ,  12 , and  13 ,  14 , respectively. It is envisioned that the depth of the v-shapes V 1 , V 2  will be from about 2″ for smaller bags up to about 4″ for larger width bags. At the right side of FIG.  1 . the side gusset  3  is shown in the flattened prefilled condition ready to expand between ends of the bag as shown in FIG. 6 to ultimately provide a filled-bag width of 8″. Because the bag  1  has an overall width of 17″, it will therefore be seen that the distance between opposing apices  9  and  11  at opposite side gussets  2  and  3  of the bag creates a spacing of 13″ therebetween for receipt of a fill spout therein. 
     In FIG. 2, the side gussets  2  and  3  are shown in a front elevational view in a flattened manufactured stage. The bag  1  is constructed of fully stepped paper plies  6 ,  7  and  8 , which create the ladder-like appearance at the folded upper portions of side gussets  2  and  3  in FIG.  2 . The ends of the side gussets  2  and  3  at both the upper and lower ends of the bag  1  are maintained in the flattened condition, as shown for gusset  3  at the right side of FIG. 1, by means of gusset bonding or tacking at spot adhesive points  15  best shown in FIG. 1 at the expanded left side gusset  2 . The adhesive tack points  15  bond the walls  10  and  12  together and  13  and  14  together at v-shapes V 1  and V 2 , respectively, whereby the side gussets  2  and  3  are clamped together at these bag end locations. The side gusset  2  in FIG. 1 is expanded (untacked) for illustrative purposes, but would otherwise be maintained as shown for the right side gusset  3  during filling. 
     The adhesive envisioned for the adhesive tacking at points  15  is a starch based glue, which is applied as the bag tube is formed and folded to create the side gussets  2  and  3  and is longitudinally seamed in a well known bag tube making process as would be understood by those in the art. The tacking points  15  between the gusset walls are shown as single dots, but multiple tack points are optional. 
     Upon filling the bag, the upper ends of the side gussets  2  and  3  would be folded over along the fold line indicated in FIG. 2 to create a pinch closure at the top of the bag  1 . The invention is therefore characterized by the adhesive tacking at points  14  at the upper ends of the side gussets  2  and  3  and also by the unique stepped arrangement of the plies  6 ,  7  and  8  as will be further understood in connection with FIGS. 3-5. 
     With reference to FIG. 3, three knife bar ply cuts are schematically shown at reference numerals  60 ,  70  and  80  which, respectively, are the cuts made for stepping the plies  6 ,  7  and  8  shown in FIGS. 1 and 2. The ply fold lines for each of the knife bar cuts are indicated, which correspond to the common fold line shown in FIG. 2 whereby the stepped plies are overlain and registered along match lines by tubing and forming equipment for the production of the bag  1 . It will be seen that the knife bar cut  60  drawn in small dashed lines creates five steps  61 - 65 , as noted. The knife bar cut  60  is also known as the print ply knife cut because it is used to cut the outer ply  6  which may include a printable surface for advertising and labeling indicia. The central lowest edge, labeled  66 , up to the highest edge  67  represents the maximum longitudinal step distance labeled D. For a conventional bag having a width in the range of from 14-17″, this distance D would normally be, for a single gusset bag, 2¼″ or less. In the preferred embodiment of the invention, the dimension D is 2⅜″ and may be from about 2¼″ to about 2½″ providing an increase of up to about 15% in length for the stepping pattern. In the disclosed embodiment the first step  61  provides a step up of {fraction (5/16)}ths; step  62  steps up {fraction (1/16)}th inch; step  63  steps up ⅜ths inches; step  64  steps up {fraction (1/16)}th inch; and, step  65  steps up {fraction (15/16)} inches to reach the upper edge  67  as labeled in FIG.  1 . Accordingly, the lowest edge  66  is the lowest stepped edge portion of the ply  6  and extras across the front wall  4 . This is also illustrated in the front elevational view in FIG.  2 . 
     The middle ply  7 , having knife bar cut  70  is shown in the center of FIG.  3  and is distinguished from the cutting line of knife bar  60  in that it is shown in solid lines wherein the cut line for the knife bar  60  is shown in said small dashed lines. Like knife bar cut  60 , knife bar cut  70  provides five steps up numbered  71 - 75  as noted. They rise from the lowest edge  76  to the upper edge  77 . For the knife bar cut  70 , the distance D′ between the lowest edge  76  to the upper edge  77  is 1¾″. The upper and lower edges  76  and  77  are also referenced in FIGS. 1 and 2. The steps  71 - 77  provide incremental rises therebetween to form the stepping pattern for the middle ply  70 , wherein step  71  steps up from edge  76  a distance of {fraction (9/16)}ths inches; step  72  steps up {fraction (3/16)}ths inches; step  73  steps up ¼ inch; step  74  steps up {fraction (3/16)}th inches; and, step  75  steps up {fraction (9/16)}th inches to the upper edge  77 . 
     The knife bar cut  80  is the inside ply knife cut for the inner ply  8  and is shown in long dashed lines. The inner ply  8  is cut to have six steps up  81 - 86  as illustrated. These steps up rise a distance D″ which is 1⅜″ from a lowest edge  87  up to an upper edge  88 , as shown and also as noted in FIGS. 1 and 2, which are the respective front and back edges of the ply  8  extending between the side gussets  2  and  3 . Accordingly, the inner ply  8  has an additional step provided which is needed to achieve the first inward steps  81 , as shown in FIG.  1 . The knife bar cut  80  creates six steps up labeled  81 - 86 , wherein step  81  provides a step up of {fraction (3/16)}ths inches; step  82  steps up ⅛th inch; step  83  steps up {fraction (5/16)}ths inches; step  84  steps up ⅛th inch; step  85  steps up {fraction (5/16)}th inches; and, step  86  steps us {fraction (5/16)}th inches to the upper edge  88  as shown. 
     With respect to the location of the fold line relative to the knife bar cuts  60 ,  70  and  80 , it will be seen that the edges  66  and  76  are below the fold line and accordingly would not be folded to make a pinch closure, but the edge  87  is shown to be above the fold line for the inner ply  8 . Accordingly, the edge  87  is folded over for a small overlap dimension which in the preferred embodiment is about {fraction (1/16)}th inch, as will be further discussed in connection with FIG.  7 . 
     In FIG. 4, the knife bar cuts  60 ,  70  and  80  for the plies  6 ,  7  and  8  are shown schematically superimposed for purposes of illustration. It will be understood that the plies  6 ,  7  and  8  extend to the left and to the right of the front wall  4 , shown in FIG. 4, and would be joined by the tuber to form the back wall  5 , shown in FIG. 1 as would be clear to one skilled in the art. The seaming lines for the tube forming of the plies  6 ,  7  and  8  would be laterally offset as in a typical tubular bag construction and are not illustrated, but would be understood by those in the bag making art. 
     The knife bar cuts  60 ,  70  and  80  of FIG. 3 are superimposed in FIG. 4 in the assembled vertical relation to each other during manufacturing just before the gusset infold v-shapes V 1 , V 2  for side gussets  2  and  3  are made. FIG. 4 is a schematic illustration wherein the solid line of middle ply  7 , and the dashed lines for plies  6  and  8 , are not intended to shown phantom or hidden lines, but instead to illustrate the stepped relationships of the edges of the plies ( 61 - 67 ;  71 - 77 ;  81 - 88 ), as they are stepped upwardly from the lower edges  66 ,  76  and  87  up through the stepping to the upper edges  67 ,  77  and  88 , respectively. 
     Each of the steps shown in FIG. 3 for the plies  6 ,  7  and  8  are labeled in FIG.  4 . They are cut to equal lateral widths between corresponding stepped edges, and wherein the inner ply  8  has the inward most first steps  81 , and the plies are stepped sequentially upward therefrom at the overlying triple sets of steps up  61 ,  71  and  82 ;  62 ,  72  and  83 ;  63 ,  73  and  84 ;  64 ,  74  and  85 ; and  65 ,  75  and  86 . In this regard it will be seen that side gusset  3 , as well as side gusset  2 , is formed by the folding of their respective walls  10 ,  12  at apex  9 , and walls  13 ,  14  at apex  11 , after the knife cut steppings up are aligned and registered. 
     With reference to FIGS. 2 and 4. it will be seen that the steps of the plies  6 ,  7  and  8  at walls  10 ,  12 ,  13  and  14  have smaller incremental steps up between adjacent ply edges than do the front wall  4  between the gussets and the back wall  5  of the bag  1 . In the preferred embodiment, the overall stepping distance D, as noted in regard to FIG. 3, is 2⅜ths inches, wherein the steps of the ply edges forming the gusset walls  10 ,  12 ,  13  and  14  are the smallest and in the range of from about {fraction (1/16)}th-⅛th inch between adjacent sequential ply edges. Whereas, the stepping distances between the ply edges  88 ,  77  and  67  and  66 ,  76  and  87  are larger and in the range of from about {fraction (3/16)}th-{fraction (5/16)}th inches between adjacent sequential ply edges of the stepped bag walls. 
     FIG. 5 is another schematic illustration which shows at the left half thereof the same schematic relationship of the stepped bag plies as in FIG. 4, but wherein the right half illustrates the relationship of the bag edges when the side gusset  3  is formed by folding the bag (a) at the “V” apices  9  and  11 , and (b) between the gusset walls  10  and bag front wall  4 , and (c) between the gusset walls  14  and bag back wall  5 . The dimension D is denoted for the 2⅜th inch stepping length between the front wall lowest edge  66  and back wall upper edge  67  of the outer ply  6 . 
     With reference to FIG. 6, a fully formed bag I is shown wherein the bottom end, which is the so called “manufactured end” is denoted at reference numeral  16 , has a pinch closure made across the bag bottom and the opposite open upper bag end denoted at reference numeral  17  receives a filling spout  18 . The adhesive tacking locations  15  shown in FIG. 1 at the upper ends of the gussets  2  and  3  have counterparts  15 ′ at the lower ends, noted in dashed lines, for purposes of holding the gussets  2  and  3  together at the bottom of the bag for strength and allowing the side gussets  2  and  3  therebetween to “square out” to fully fill the bag  1  between the bottom pinch closure  16  and upper open end  17 . The V-shapes V 1  and V 2  are thus clamped tightly and tacked together at the upper tacking locations  15 , wherein the front wall  4  and back wall  5  are allowed to flare open from the gusset walls  10 ,  14 , respectively, in order to have product fill the bag  1  entering through the spout  18  as indicated by the arrow. 
     The dimensions of the bag I for the disclosed embodiment as noted above are 17″ wide by 33″ long and wherein the side gussets  2  and  3  expand to create a bag depth or side of 8″. This is one standard bag dimension and other common sizes are 15″ by 31¾″ by 7″; 15½″ by 31″ by 7″; 15″ by 30″ by 7¾″; 14¾″ by 31″ by 7″. However, it is envisioned that variously-sized freight shipping bags can be employed for the present invention and having a wide range of dimensions, such as a width from about 12″ to about 24″ and a length from about 18″ to about 36″. In this regard the gusset dimension may range from about 5½″ up to 12″ deep from the front wall  4  to the back wall  5 . Typically, smaller bags would not be used for heavy weight commodity materials used in industry, wherein freight shipping bags are typically large sized and offer strength and tear resistance, versus a popcorn, vacuum cleaner or coffee bag, where filling dynamics and weights are not remotely as demanding. In the disclosed embodiment, the fill spout  18  has a space to fit between the V-shapes V 1  and V 2  of about 13″, since the V-shapes extend 2″ bag inwardly at each side of the 17″ wide bag. It is envisioned that the disclosed ranges for freight shipping bag dimensions are those that would be typically useful for the application of the present invention, wherein the V-shapes would extend inwardly from the bag sides a dimension in the range of from about 2″ to about 4″, which range would facilitate an efficient filling out of the bag when charged with a product. Efficiently and non-tearingly filling out gussets that extend bag inwardly greater than about 4″ is not impossible, but creates weakened points subject to rupture. As noted above, a minimum gusset depth of about 5½″ front wall-to-back wall is envisioned as a practical minimum. Gussets less than that would not have the criticality for filling out and strength because of the smaller dimension. While the invention can be used for smaller depth gussets, there is greater application for gusset depths of greater than 5½″ to fulfill the industry&#39;s needs for large gussetted bags. 
     Other practical limitations involve the thicknesses that bag tubing and forming equipment can handle. It will be appreciated in connection with the cross sectional view of FIG. 7 that when the stepped gussets of a double gusseted bag, as for the bag  1  disclosed, are formed there results  18  thicknesses through the side gussets  2  and  3 . This is because the three plies are double folded at the V-shapes creating six walls, each having three plies ( 6 ,  7  and  8 ). Then, when folded over around the fold line to complete the pinch closure noted at reference numeral  19  at the upper end  18  of the bag  1  shown in FIG. 7, the number of thicknesses to be sealed closed would have 34 ply (18+16) thicknesses. This is because the bottom edges  66  and  76  are not folded over. Thus leaving two less thicknesses to be overlapped. When using 40-70 lb. natural Kraft paper, the bag forming and sealing equipment must be able to handle these thick overlaps. To facilitate the sealing of the bag to close the upper end  18  and form the pinch closure  19 , similar to pinch closure  16 , the stepped plies are coated during the bag making process with a hot melt adhesive which is heat activated to seal the pinch closure  19 . The hot melt adhesive is provided across the face of these stepped portions of the bag  1  in a region having a length H (see FIGS. 2 and 7) from the edges  67 ,  77 ,  88  downwardly to slightly above the inner ply edge  86 , which dimension H in the preferred embodiment is approximately 1¾″ long and fully across the face of the bag, across the side gusset  2 , the back wall  5 , and the side gusset  3 . Thus, the bag  1  when filled is fed to bag sealing equipment wherein the adhesive bonding locations  15  maintain the upper ends of the side gussets  2  and  3  together thereat, which keeps the bag in shape for (a) an even feeding into standard pinch closure sealing equipment, (b) holding the bag in even alignment with the equipment to facilitate even folding around the fold line  19 , (c) activating the hot melt adhesive, and (d) pinching close the bag to complete a bag closure in a similar final condition to the manufactured pinched closed end  16  illustrated in FIG.  6 . 
     It will be appreciated that the bag  1  can be made in a second preferred embodiment having two plies. Reference is now made to FIGS. 8 and 9 wherein a two-ply bag construction is shown having an outer print ply  6 ′ and an inner ply  8 ′ for a bag  1 ′. For the two-ply construction a somewhat different knife bar cutting arrangement is utilized. In regard to FIG. 9, knife bar cuts  160  are shown for the outer print ply  6 ′ having five steps up  161 - 165  which rise a distance D from a lowest front edge  166  up to an upper back wall edge  167 . The distance D in this embodiment for a bag having the length and width dimensions as set out for bag  1  is 2¼. 
     The inside ply  8 ′ is formed by knife bar cuts  180  having six steps up shown at steps up  181 - 186 . The stepping cuts for the ply  8 ′ extend upwardly from a lowest front wall edge  187  up to an upper back wall edge  188  a distance D″ of 1⅝″. 
     In FIG. 9, a match line is provided to show the distance above and below where the knife bar cuts  161 - 165  and  181 - 186  are made. The match line is the line over which the plies are to be superimposed for bag forming. Also in FIG. 9, the fold line, as in FIGS. 2-4, is shown. In FIG. 8, the plies  6 ′ and  8 ′ are overlain in a schematic arrangement to show the relative positions of the steps and wherein the fold line is shown slightly below the edge  187  and above the edge  166 , whereby the edge  166  is not folded over. 
     Similar to the bag  1 , a band or zone of hot melt adhesive H extends for about 1¾″ downwardly from the upper most bag edge  167  of the print ply  6 ′ down toward, but stopping short of, the lowermost edge  187  of the inside ply  8 ′. 
     To the left and right of FIG. 8, the corresponding gussets  2 ′ and  3 ′ are made similar to the gussets  2  and  3 . Similar to the bag  1 , the bag  1 ′ is stepped whereby the smaller incremental steps of sequentially vertically adjacent edges are made through the gussets  2 ′ and  3 ′ and a greater stepping of vertical incremental distances are made between the front and back wall edges that do not make up part of the gussets. In the disclosed embodiment for the bag  1 ′, two v-shape folds are made at either side to form the gussets  2 ′ and  3 ′ similar to v-shapes V 1  and V 2  of FIG.  1 . Thereby, the alternate preferred embodiment in FIGS. 8 and 9 is also a double gusset bag. As noted above, the bag  1 ′ is disclosed as having two 70 lb. Kraft paper plies for the plies  6 ′ and  8 ′, but for lighterweight materials having less stress creating dynamics, two 40 lb. paper plies might be used. 
     At the gussets  2 ′ and  3 ′ there would be 12 ply thicknesses and upon folding the upper open end of the bag for a pinch closure, the bag would have a maximum of 23-ply thicknesses, since the lowest edge  166  of the print ply  6 ′ is not folded upon itself. 
     The knife bar cuts  160  of the print ply  6 ′ provide that the step up  161  is ⅞″; the step up  162  steps up ⅛″; the step up  163  steps up ¼″; the step up  164  steps up ⅛″; and, the step up  165  steps up ⅞″. For the knife bar cuts  180  of the inside ply  8 ′, from the lowest edge  187  the step up  181  steps up ⅝″; the step up  182  steps up {fraction (3/16)}″; the step up  183  steps up ¼″; the step up  184  steps up ⅛″; the step up  185  steps up ¼″; and, the step up  186  steps up ½″. 
     The filling and pinch closure of the bag  1 ′ is substantially identical to the bag  1  except for the reduction by one-ply thickness, which thinner profile is more easily accommodated in bag handling, filling and sealing equipment. The gussets  2 ′ and  3 ′ are similarly provided with bonding locations substantially identical to the bonding locations  15  and  15 ′ of bag  1 . 
     Greater than three ply construction is also envisioned, for example, a four ply multi-gusseted bag may be provided in accord with the invention and formed of, for example, three 40 lb. Kraft paper plies and one 55 lb. Kraft paper ply. The gusset ply thicknesses would then have 24 plies at the gussets and, when folded over to create a pinch closure, would have greater than 40 thicknesses to be hot melt adhesively sealed. The invention can be practiced with these increased thicknesses, but depends upon the capacity of tubing, forming, handling, sealing and filling equipment, and their ability to accommodate these multiple plies. 
     The foregoing is a description of preferred and alternate embodiments of the invention, but the claims appended hereto are not limited thereby, and encompass a broader scope.