Thermoplastic films and bags

The present invention relates to a thermoplastic film having improved tear and puncture resistance. The thermoplastic film has a plurality of embossed regions that are comprised of a plurality of parallel, linear embosses. The plurality of embossed regions is arranged so that a straight line cannot traverse the thermoplastic film without intersecting at least one of the plurality of embossed regions. Certain embodiments further disclose an unembossed arrangement having at least three distinct segments that extend in three distinct directions.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to improvements for thermoplastic films, particularly thermoplastic films used in the manufacture of bags including trash bags. In particular, the present invention relates to improvements to trash bags and embossed patterns for such bags.

2. Description of the Related Art

Thermoplastic films are used in a variety of applications. For example, thermoplastic films are used in sheet form for applications such as drop cloths, vapor barriers, and protective covers. Thermoplastic films can also be converted into plastic bags, which may be used in a myriad of applications. The present invention is particularly useful to trash bags constructed from thermoplastic film, but the concept and ideas described herein may be applied to other types of thermoplastic films and bags as well.

Plastic bags are manufactured from thermoplastic film produced using one of several manufacturing techniques well-known in the art. The two most common methods for manufacture of thermoplastic films are blown-film extrusion and cast-film extrusion. In blown-film extrusion, the resulting film is tubular while cast-film extrusion produces a generally planar film.

In blown film extrusion, thermoplastic resin is fed into an extruder where an extrusion screw pushes the resin through the extruder. The extrusion screw compresses the resin, heating the resin into a molten state under high pressure. The molten, pressurized resin is fed through a blown film extrusion die having an annular opening. As the molten material is pushed into and through the extrusion die, a thermoplastic film tube emerges from the outlet of the extrusion die. The direction that the thermoplastic film tube is extruded from the extrusion die is commonly referred to as the machine direction. The direction perpendicular to the machine direction is commonly referred to as the cross direction.

Depending on the application, the use of thermoplastic film presents technical challenges since thermoplastic film is inherently soft and flexible. Specifically, all thermoplastic films are susceptible to puncture and tear propagation. In some instances, it may be possible to increase the thickness of the film or select better polymers to enhance the physical properties of the film. However, these measures increase both the weight and cost of the thermoplastic film and may not be practicable. In light of the technical challenges of thermoplastic film, techniques and solutions have been developed to address the need for improved shock absorption to reduce the likelihood of puncture. For example, it is known to impart stretched areas into thermoplastic films as a means of inducing shock absorption properties into the film.

U.S. Pat. No. 5,205,650, issued to Rasmussen and entitled Tubular Bag with Shock Absorber Band Tube for Making Such Bag, and Method for its Production, discloses using thermoplastic film material with stretchable zones wherein the film material has been stretched in a particular direction with adjacent un-stretched zones that extend in substantially the same direction. The combination of the stretched zones and adjacent un-stretched zones provides a shock absorber band intended to absorb energy when the bag is dropped. Specifically, when a bag is dropped or moved, the contents inside the bag exert additional forces that would otherwise puncture or penetrate the thermoplastic film. However, the shock absorber bands absorb some of the energy and may prevent puncture of the film.

Another example of a thermoplastic film material designed to resist puncture is disclosed in U.S. Pat. No. 5,518,801, issued to Chappell and entitled Web Materials Exhibiting Elastic-Like Behavior. Chappell, in the aforementioned patent and other related patents, discloses using a plurality of ribs to provide stretchable areas in the film much like Rasmussen. Chappell also discloses methods of manufacturing such thermoplastic film with such ribs.

Another example of shock absorption to prevent puncture is disclosed in U.S. Pat. No. 5,650,214 issued to Anderson and entitled Web Materials Exhibiting Elastic-Like Behavior and Soft Cloth-Like Texture. Anderson discloses using a plurality of embossed ribs defining diamond-shaped areas with a network of unembossed material between the diamond-shaped areas. Thus, the unembossed area comprises a network of straight, linear unembossed material extending in two perpendicular directions.

The foregoing disclosures specifically address the desire to increase the shock absorption of thermoplastic film to reduce the likelihood of punctures occurring in the film. However, none of the foregoing disclosures address the problem of reducing tear propagation in a thermoplastic bag.

Previously known solutions to limiting tear propagation are based on two primary concepts. First, longer and more tortuous tear paths consume more energy as the tear propagates and can help in limiting the impact of the tear in a bag or thermoplastic film. Second, many thermoplastic films, particularly thermoplastic films made using a blown-film extrusion process, have different physical properties along different axes of the film. In particular, blown films are known to have higher tear strength in the cross-direction versus the corresponding tear strength in the machine direction. Certain prior art solutions take advantage of the differential properties of thermoplastic films by redirecting tears into a different direction. This redirecting of tears can offer greater resistance to a tear propagating. For example, some solutions redirect a tear propagating in the weaker machine direction of blown film into the stronger cross-direction.

One solution for reducing tear propagation is based on the idea that longer, tortuous tear paths are preferable and is described in U.S. Pat. No. 6,824,856, issued to Jones and entitled Protective Packaging Sheet. Jones discloses materials suitable for packaging heavy loads by providing an embossed packaging sheet with improved mechanical properties. Specifically, a protective packaging sheet is disclosed where surfaces of the sheet material are provided with protuberances disposed therein with gaps between protuberances. The protuberances are arranged such that straight lines necessarily intersect one or more of the protuberances. The resulting protective packaging sheet provides mechanical properties where tears propagating across the thermoplastic sheet are subject to a tortuous path. The tortuous path is longer, and more complex, than a straight-line tear, and a tear propagating along such a path would require markedly more energy for continued propagation across the film compared to a tear along a similar non-tortuous path in the same direction. Thus, due to the increased energy required for tear propagation, the tortuous path ultimately reduces the impact of any tears that do propagate across the film.

Another example of a tear resistant plastic film is disclosed in U.S. Pat. No. 8,357,440, issued to Hall and entitled Apparatus and Method for Enhanced Tear Resistance Plastic Sheets. Hall discloses an alternative tortuous path solution and further relies on the fact discussed above that certain polymer films, particularly thermoplastic films made in a blown-film extrusion process, are known to have a stronger resistance to tear in the cross direction when compared to the machine direction.

Hall discloses a solution that contemplates using preferably shaped embosses, particularly convex shaped embosses with a curved outer boundary, to provide maximum resistance to tear propagation. In most thermoplastic films, a tear will have a tendency to propagate along the path of least resistance or in the machine direction. Hall contemplates redirecting propagating tears in a tortuous path with the additional intent of redirecting the machine direction tears along the curved edges of the embossed regions and into a cross direction orientation. The redirected tears in the cross direction will be subject to additional resistance and, preferably, will propagate to a lesser degree than a tear propagating in the machine direction in an unembossed film.

Unlike the references described earlier, Jones and Hall are primarily focused on resistance to tear propagation after a puncture has occurred, rather than attempting to prevent the puncture from occurring in the first place. It would be desirable to balance both of these properties, shock absorption and tortuous tear paths in the cross direction, into a single, practicable thermoplastic film. Specifically, it would be desirable to provide a thermoplastic film with a shock-absorbing feature to prevent punctures in a film while also providing increased resistance to tear propagation. It would also be desirable to balance these features so that one feature does not degrade the performance of another. The present invention addresses these needs.

SUMMARY OF THE PRESENT INVENTION

In at least one embodiment of the present invention, an embossed pattern of thermoplastic film may have a plurality of embossed regions embossed into the thermoplastic film. Each of the plurality of embossed regions may comprise a set of parallel, linear embosses. In at least one embodiment, each of the plurality of embossed regions may comprise six or more parallel linear embosses. The plurality of embossed regions may be separated by a continuous, unembossed arrangement. Each embossed region may be defined by a boundary with the continuous, unembossed arrangement. The continuous, unembossed arrangement may comprise at least a plurality of first segments, a plurality of second segments, and a plurality of third segments. The plurality of first segments may extend in a first direction and the first direction may be vertical. The plurality of second segments may extend in a second direction. The plurality of third segments may extend in a third direction. The first, second, and third directions may each be distinct from each other. Additionally, the first, second and third directions may each be oblique to each other. The first, second, and third segments may intersect each other. The first, second, and third segments may also intersect each other at two opposing vertices of each embossed region.

In some embodiments of the present invention, each emboss of each set of parallel, linear embosses of an embossed region may be parallel with every other emboss of parallel linear embosses of other embossed regions. Furthermore, in some embodiments, a majority of the plurality of embossed regions may be irregularly shape. In the alternative, a majority of the plurality of embossed regions may be hexagon-shaped.

In another embodiment of the present invention, a thermoplastic bag may have a first panel and a second panel. The first panel and second panel may be joined along a first side edge, a second side edge, and a bottom edge. A top edge of the first panel and the second panel may define an upper opening of the bag. A plurality of embossed regions may be embossed into the first panel and the second panel. A majority of the plurality of embossed regions may be irregularly shape. In the alternative, a majority of the plurality of embossed regions may be hexagon-shaped. The plurality of embossed regions may be separated by a continuous, unembossed arrangement. Each of the plurality of embossed regions may comprise a plurality of parallel, linear embosses. In at least one embodiment, each of the plurality of embossed regions may comprise six or more parallel, linear embosses. Each emboss of each set of parallel, linear embosses of an embossed region may be parallel with every other emboss of parallel linear embosses of other embossed regions. Each embossed region may be defined by the continuous, unembossed arrangement. The continuous, unembossed arrangement may comprise at least a plurality of first segments, a plurality of second segments, and a plurality of third segments. The plurality of first segments may extend in a first direction. The plurality of second segments may extend in a second direction. The plurality of third segments may extend in a third direction. The first, second, and third directions may be distinct from each other. Additionally, the first, second and third directions may each be oblique to each other. The first, second, and third segments may intersect each other. The first, second, and third segments may also intersect each other at two opposing vertices of each embossed region.

In a further embodiment of the present invention, an embossed pattern of thermoplastic film includes a plurality of embossed regions embossed into thermoplastic film. Each of the plurality of embossed regions may include a set of parallel, linear embosses. The plurality of embossed regions may be separated by a continuous, unembossed arrangement. Each of the plurality of embossed regions may also have a serpentine shape. The continuous, unembossed arrangement may only bound each embossed region at a perimeter of the embossed pattern. Each embossed region may be defined by a boundary with the continuous, unembossed arrangement. The continuous, unembossed arrangement may include a plurality of first segments, a plurality of second segments, a plurality of third segments, and a plurality of fourth segments. The plurality of first segments may extend in a first direction. The plurality of second segments may extend in a second direction. The plurality of third segments may extend in a third direction. The plurality of fourth segments may extend in a fourth direction. The first, second, third and fourth directions may be distinct from each other. The first direction may be generally vertical and the fourth direction may be generally horizontal.

DETAILED DESCRIPTION OF THE INVENTION

The present disclosure illustrates several embodiments of the present invention. It is not intended to provide an illustration or encompass all embodiments contemplated by the present invention. In view of the disclosure of the present invention contained herein, a person having ordinary skill in the art will recognize that innumerable modifications and insubstantial changes may be incorporated or otherwise included within the present invention without diverging from the spirit of the invention. Therefore, it is understood that the present invention is not limited to those embodiments disclosed herein. The appended claims are intended to more fully and accurately encompass the invention to the fullest extent possible, but it is fully appreciated that certain limitations on the use of particular terms are not intended to conclusively limit the scope of protection.

Referring initially toFIG. 1, a plan view of a first embodiment of the present invention is shown. In particular, an embossed pattern100may be defined on a thermoplastic film. The embossed pattern100comprises a plurality of embossed regions110, where each of the plurality of embossed regions110is separated by a continuous, unembossed arrangement120. Each of the embossed regions110comprises a plurality of parallel linear embosses130. The parallel, linear embosses130are all arranged in a parallel fashion throughout the embossed pattern100to facilitate expansion of the film in a particular direction. Furthermore, the parallel, linear embosses130extend across each embossed region110. For ease of reference, a horizontal direction may be defined that is parallel with the linear embosses130and a vertical direction that is perpendicular to the linear embosses130.

FIG. 1further shows that the unembossed arrangement120includes a plurality of first segments120a, and a plurality of second segments120b. Each first segment120aextends in a first direction. Each second segment120bextends in a second direction that is generally perpendicular to the first direction. Due to the rectangular shape of each embossed region110, each first segment120aextends uninterrupted through the entire embossed pattern100while each second segment120bis interrupted by adjacent embossed regions110and fails to extend through the embossed pattern100.

In certain preferred embodiments of the present invention, the embossed regions110are provided with rounded corners, rather than sharp corners. As discussed with respect to the prior art, it is known that tears have a tendency to propagate along the edges of the embossed regions. Embossed regions with continuously curved borders, i.e. without sharp corners, encourage propagating tears to follow the edge of the embossed region. In contrast, when an embossed region is provided with sharp corners, the tear is more likely to diverge from the edge of the embossed region and will no longer be guided by the embossed region. Typically, such tears will continue propagating in the same direction, which may provide less resistance along a less tortuous path.

The present invention builds on the concepts of tortuous path and redirecting tears in a direction that provides more resistance to continued propagation of the tear by preferably utilizing rounded corners on the embossed regions. Preferably, the embossed regions110have generally rounded corners rather than sharp corners to facilitate redirection of tears propagating along the perimeter of said embossed region and into a more tortuous path that may offer increased tear resistance.

FIG. 2shows a second embodiment of the present invention. In this embodiment, the embossed pattern200has a plurality of embossed regions210that are generally hexagonal in shape, preferably with rounded corners to facilitate tear redirection. Like the previous embodiment, the embossed regions210have a plurality of parallel linear embosses230. Moreover, due to the hexagonal geometry, the continuous, unembossed arrangement220does not provide any location where a continuous, straight line can be drawn across the arrangement220, unlike the first embossed pattern100shown inFIG. 1. This is important because a tear propagating in the unembossed arrangement220cannot follow a continuous path in the machine direction, where the film is inherently weaker. Instead, assuming the tear follows the edges of the embossed regions210, the tear will follow a longer path that will be, at least partially, in the cross direction.

Due to the hexagonal shape of the second embodiment,FIG. 2further shows that the unembossed arrangement220includes a plurality of first segments220a, a plurality of second segments220b, and a plurality of third segments220c. Dashed lines are provided inFIG. 2, as well in many of the following figures, to indicate the direction that each segment extends. These dashed lines are provided for reference only and do not form any structure of the invention. Each first segment220aextends in a first direction that is generally horizontal. Each second segment220bextends in a second direction that is oblique (i.e. neither parallel nor at a right angle) to the first direction. Each third segment220cextends in a third direction that is oblique to both the first direction and the second direction. Due to the hexagonal shape and nesting of adjacent embossed regions210, none of the unembossed arrangement220segments220a,220b, or220cextends through the embossed pattern200; rather each segment is interrupted by an adjacent embossed region210, extending only a fraction of one of the embossed regions210.

FIG. 3shows a third embodiment of the present invention. In this third embodiment, an embossed pattern300, which may be applied to thermoplastic film, has a variety of circular embossed regions310arranged along a series of parallel sinusoidal paths separated by a continuous, unembossed arrangement320. This continuous unembossed arrangement320offers unique advantages in that a continuous straight-line path is generally not possible, assuming the size of the embossed regions310are properly sized, the amplitude of the sinusoidal path is sufficiently large, and there is sufficient frequency of the embossed regions310along the sinusoidal path. Thus, as a tear propagates across the film, it will necessarily intersect with one of the embossed regions310. Such tears will have a tendency to propagate around the edges of the embossed regions310and into varying directions.

In the embodiment disclosed inFIG. 3, the embossed regions310are preferably arranged along a series of parallel, sinusoidal paths extending in a first direction. The peak amplitude, measured from the center of the sinusoidal wave to the peak of the sinusoidal wave is typically at least ½ of the diameter of the embossed regions310. In some embodiments of the present invention, the embossed regions310are also arranged along a sinusoidal path extending in a second direction. The second direction may be perpendicular to the first direction of the sinusoidal path.

In a preferred embodiment, the embossed regions310will all be substantially the same size. However, in other embodiments, the size of the embossed regions310may vary. For example, depending on the spacing between nearby embossed regions310, the size, or even the shapes, of the embossed regions may be modified to provide that spacing between the embossed regions is more uniform.

FIG. 4discloses a fourth embodiment of the present invention. In this embodiment, an embossed pattern400has a plurality of circular embossed regions410much like the embodiment depicted inFIG. 3. However, in this embodiment, some of the circular embosses are connected to form connecting embossed regions412to block some, or even all, of the sinusoidal paths between the circular embosses.

Looking back atFIG. 3, it is apparent that, depending on the size of the embossed regions412and the amplitude of the sinusoidal path of embossed regions412, a tear may propagate along a sinusoidal path between the sinusoidal paths of the embossed regions412. Properly selecting the amplitude of the sinusoidal waves, adjusting the location of the embossed regions412along the sinusoidal path, and modifying the sizes of the various embossed regions may be used, individually or in combination with one another, to prevent tears from propagating along the sinusoidal paths by forcing tears to continually encounter embossed regions412and propagate around the perimeter of said embossed regions412

Looking now atFIG. 5, a fifth embodiment of the present invention is depicted wherein the embossed regions are random shapes with substantially curved edges. The embossed pattern500is shown with a plurality of embossed regions510, an unembossed arrangement520, and each embossed region510comprised of a plurality of parallel linear embosses530. The embossed pattern is structured so that a continuous, linear path cannot be drawn across the unembossed arrangement, which is desirable to prevent the propagation of tears across the thermoplastic film.

It has been observed that certain features of embossed regions are desirable to maximize the amount an embossed film expands due to an applied force. For instance, to maximize film expansion along a vertical axis, embossed regions having a polygonal shape with vertices at the bottom and top of the polygon is desirable. To also maximize expansion, a major axis of each of the plurality of linear embosses should be arranged perpendicular to the vertical axis.

Shown inFIG. 6is an embossed pattern600with the plurality of embossed regions610having a generally hexagonal shape. One of the hexagonal shapes is indicated by dashed lines A inFIG. 6, which is shown for reference only and forms no structure of the disclosed invention. Each embossed region610is defined by nine parallel and adjacent linear embosses630. The two opposing vertically extending sides of each embossed region610are defined by three middle adjacent parallel linear embosses630with equal length; each vertical side of the hexagon formed by adjacent ends of the three linear embosses630. Each of the other four diagonal sides of the hexagon are defined by an end point of an outer emboss of the three middle adjacent linear embosses630and adjacent end points of three other outer adjacent linear embosses630with each of the three other adjacent linear embosses630decreasing in length the same amount as the adjacent linear emboss630.

Unlike the hexagonal shaped regions ofFIG. 2, the hexagonal shaped embossed regions610ofFIG. 6are oriented such that vertices of each hexagon are at a bottom and top of each hexagon. As shown inFIG. 6, adjacent to the upper and lower vertices are two short opposing, linear embosses630at each end of each embossed region610. Although it would be advantageous for these two embossments to have a shorter length that approaches a singular point, so as to maximize stretch, it has been observed that very short linear embosses creates a force concentration on the film and may significantly degrade properties of the film, such as impact resistance. Hence, these lower and upper embossments630have a certain amount of length to prevent a substantial degradation in impact resistance.

The orientation of the hexagonal shaped embossed regions610ofFIG. 6allows the thermoplastic film to expand in the vertical direction to a greater extent than the hexagonal shaped embossed regions210ofFIG. 2. Nonetheless, due to the hexagonal shape of its embossed regions610, the depicted embodiment maintains features to prevent tear propagation, as previously discussed regarding the hexagonal shape ofFIG. 2.

Due to the hexagonal shape of the sixth embodiment,FIG. 6further depicts the unembossed arrangement620having a plurality of first segments620a, a plurality of second segments620b, and a plurality of third segments620c. Each embossed region610is bounded by two first segments620a, two second segments620b, and two third segments620c. Each first segment620aextends in a first direction that is generally vertical. Each second segment620bextends in a second direction that is oblique to the first direction. Each third segment620cextends in a third direction that is oblique to both the first direction and the second direction. The first, second, and third directions are all distinct from each other. As shown inFIG. 6, each of the segments620a,620b, or620care interrupted by an adjacent embossed region610, failing to extend past more than one embossed region610.

As further shown inFIG. 6, the first segments620aintersect both the second segments620band third segments620c. Furthermore, a first segment620a, a second segment620b, and a third segment620call intersect each other adjacent to both the upper and lower vertices of each embossed region610. In a particular embodiment, the angle formed by each intersection by a first segment620awith a second segment620bor third segment620ccan be approximately 54 degrees or the supplementary angle of 126 degrees. In the same embodiment, the angle formed by each intersection of a second segment620bwith a third segment620ccan be approximately 108 degrees.

Shown inFIG. 7is another view of the embossed film pattern600as it may generally be formed on a web of thermoplastic film, showing in more detail the shape of each linear emboss630, in a preferred embodiment. As previously discussed, the corners of each linear emboss630is rounded so that each embossed region610has rounded corners, in general. Also illustrated is the unembossed arrangement620.

Shown inFIG. 8is a seventh embodiment of the present invention. The seventh embodiment has embossed regions810in the shape of a hexagon forming an embossed pattern800. In a similar fashion toFIG. 4, some of the embossed regions810are connected to adjacent embossed regions. As shown inFIG. 8, each embossed region has six parallel linear embosses830that define each embossed region810. Located at a midpoint of each embossed region are two adjacent linear embosses830of equal length that define opposing vertical sides of each embossed region810. For certain horizontally adjacent embossed regions810, these two adjacent linear embosses830extend to a horizontally adjacent embossed region to connect the two adjacent embossed regions810together. These connected adjacent embossed regions810may provide further assistance in preventing the propagation of tears in the film as previously discussed.

The unembossed arrangement820of the seventh embodiment includes a plurality of first segments820a, a plurality of second segments820b, and a plurality of third segments820c. Each first segment820aextends in a first direction that is generally vertical. Each second segment820bextends in a second direction that is oblique to the first direction820a. Each third segment820cextends in a third direction that is oblique to both the first direction820aand the second direction820b. Additionally, the seventh embodiment has a plurality of fourth segments820dthat extend in a fourth direction. The fourth direction is generally horizontal and intersects the second and third segments820b,820cat oblique angles.

Shown inFIG. 9is an eighth embodiment of the present invention with an embossed pattern900. The eighth embodiment has embossed regions910in the shape of a hexagon. Rather than only certain adjacent embossed regions being connected, each embossed region is connected to an adjacent embossed region, except at the boundaries of the embossed pattern900. Each embossed region is shown with eight parallel linear embosses930that define each embossed region910. Located in a vertical midpoint of each embossed region are two adjacent linear embosses930of equal length that define opposing vertical sides of each embossed region. For each adjacent embossed region910, these two adjacent linear embosses extend to a horizontally adjacent embossed region910to connect the two adjacent embossed regions together. These connected adjacent embossed regions may provide further assistance in preventing the propagation of tears in the film by interrupting any straight-line paths between adjacent embossed regions910.

The unembossed arrangement920of the eighth embodiment includes a plurality of first segments920a, a plurality of second segments920b, a plurality of third segments920c, and a plurality of fourth segments920d. Each first segment920aextends in a first direction that is generally vertical. Each second segment920bextends in a second direction that is oblique to the first direction920a. Each third segment920cextends in a third direction that is oblique to both the first direction920aand the second direction920b. The plurality of fourth segments920dextend in a horizontal fourth direction and intersects the second and third segments920b,920cat an oblique angle. The first, second, third, and fourth directions are all distinct from each other.

Shown inFIG. 10is a ninth embodiment of the present invention. Unlike the previous embodiments,FIG. 10shows, in general, a plurality of vertically connected hexagonal shapes, forming a plurality of serpentine or bead shaped embossed regions1010. Each embossed region1010extends an entire vertical distance of the embossed pattern1000. The unembossed arrangement1020must extend to the perimeter of the embossed pattern1000to completely bound each embossed region1010. As in the previous embodiments, the continuous, unembossed arrangement1020does not provide any location where a continuous, straight line can be drawn across the arrangement1020.

The unembossed arrangement1020of the ninth embodiment includes a plurality of first segments1020a, a plurality of second segments1020b, a plurality of third segments1020c, and a plurality of fourth segments1020d. Each first segment1020aextends vertically in a first direction. Each second segment1020bextends in a second direction that is oblique to the first direction1020a. Each third segment1020cextends in a third direction that is oblique to both the first direction1020aand the second direction1020b. The plurality of fourth segments1020dextends horizontally in a fourth direction. The plurality of fourth sections is defined only about the perimeter of the pattern, intersecting the second segments1020band third segments1020cat oblique angles or the first segments1020aat right angles. As shown, first segments1020aintersect both second segments1020band third segments1020c. In a particular example, each of these intersections can form an angle of approximately 37 degrees, or the supplementary angle of approximately 143 degrees. The fourth segments1020dalso intersect both the second and third segments1020b,1020cat an angle of approximately 37 degrees and the first segments1020aat ninety degrees.

In at least one embodiment, the bead pattern ofFIG. 10can extend in a cross direction of a blown film. Hence, any tear propagating in the weaker machine direction of the film would expect to be interrupted by the bead pattern. In alternative embodiment, the bead pattern may extend in the machine direction. If a tear then propagates in the film, it is expected that one of the linear embosses will interrupt the tear before it propagates and redirect it into the cross direction.

As previously noted, the specific embodiments depicted herein are not intended to limit the scope of the present invention. Indeed, it is contemplated that any number of different embodiments may be utilized without diverging from the spirit of the invention. Therefore, the appended claims are intended to more fully encompass the full scope of the present invention.