This invention generally relates to flexible containers, such as pouches, bags or other packages, having a reclosable plastic zipper. In particular, the invention relates to reclosable bags, pouches or other packages for containing vacuum, pressure or liquid.
To ensure hermeticity or airtightness, packagers have typically sealed their flexible containers to an extent that they are not reclosable after the seal is broken. Many flexible containers that were reclosable typically did not retain the desired vacuum, pressure or liquid containment feature that existed prior to the container being opened for the first time.
In many different applications, it is desirable to provide a reclosable container that, under normal or expected conditions of usage, will not leak fluid when the zipper is closed. Such a container should maintain a leakproof condition even when there is a large differential in pressure between the interior and exterior of the container. As used herein, the term “leakproof” does not mean free of leaks under all temperature/pressure conditions, but rather free of leaks over a range of temperatures and pressures expected to occur during normal usage of the reclosable container.
In the case of known collapsible, evacuable, zippered storage bags, the zipper is opened; an article is placed inside the bag; the zipper is closed, and then the bag is evacuated using a fixture that penetrates a bag wall. With the bag thus evacuated, a compressible article contained therein may be significantly compressed so that it is easier to transport and requires substantially less storage space. It is highly desirable that ambient air not leak into the evacuated interior space of the bag. Such leakage would cause a loss of vacuum. Also it is highly desirable that the zipper not open unintentionally due to mechanical forces that occur during bag manipulation.
Collapsible, evacuable storage bags are beneficial for reasons in addition to those associated with compression of the stored article. For example, removal of the air from the storage bag inhibits the growth of destructive organisms, such as moths, silverfish, and bacteria, which require oxygen to survive and propagate. Moreover, such bags, if properly sealed, are impervious to moisture, as a consequence of which the growth of mildew is inhibited.
Not only large, compressible items such as clothing may be stored in a collapsible, evacuable and reclosable storage bag. For example, it may be desirable to store bulk items made of small particles, such as powders or granulated resins, in an evacuated reclosable bag. The stored material may be of a type that, when exposed to air during storage, is rendered unsuitable for its intended purpose. If the reclosable bag were made leakproof, then the bulk contents inside the bag would not be exposed to air.
In accordance with another application, a reclosable storage bag may be filled at ambient atmosphere instead of being evacuated. If such a bag were placed under extremely low pressure, e.g., while being air-lifted via a cargo plane having a depressurized cargo bay, then a large differential in pressure would exist between the interior and exterior of the bag. In this situation, the internal pressure may be about 15 psi, while the external pressure is negligible. It is desirable that the bag not develop a leak and that the zipper not pop open under such conditions.
Another use for evacuable reclosable packages is in the field of food product packaging. After a package of food has been opened and a portion of the food product removed, the remaining food product can be stored by closing the reclosable feature and then evacuating the interior space of the package via a fixture that penetrates a package wall. It is highly desirable that such packages, containing perishable food product in a vacuum, be leakproof, i.e., hermetic. By preventing exposure to air, the life span of the perishable food product can be extended.
In other situations, it is desirable to provide a reclosable package capable of holding liquid without leaking during normal usage when the zipper is reclosed. Preferably such a package would be able to withstand a predetermined pressure differential (interior/exterior) without liquid leaking out of the package.
In a typical construction, a reclosable pouch, bag or other package has a plastic zipper comprising two extruded zipper strips, the ends of the zipper strips extending into the side seals of a flexible receptacle. Frequently, each zipper strip comprises a closure profile and a flange or fin portion (hereinafter “flange”). The zipper strips are joined to the web of web material by heat sealing the web to the zipper flanges. In order to facilitate the formation of a tight side seal, typically the ends of the zipper strips are crushed. During the crushing operation, heat and pressure are applied in sufficient amounts (e.g., by means of mutually opposing heated sealing bars) that the ends of the zipper strips soften or melt and then deform. The flattened ends of the zipper strips then fuse during cooling. This thermal crushing operation is typically done at a separate thermal crush station or as part of the formation of a side seal of the receptacle at a cross sealing station. This “thermal crushing” of the plastic zipper creates a transition between “as is” (i.e., not crushed) zipper and crushed zipper that is susceptible to the presence of leaks.
There is a continuing need for improvements in the construction of reclosable containers having a hermetic interior volume when the zipper is reclosed. In particular, there is a need for an improved reclosable container wherein leakage is eliminated in those areas of the zipper near the container side seals.
Flexible containers that are hermetically resealable are disclosed herein. Each resealable container comprises a receptacle and a pair of plastic zipper strips. The zipper strips are flattened at the ends within the side seal regions and are joined to each other, without substantial deformation of the closure profiles, in respective transition areas substantially contiguous with the side seals. These transition areas of zipper strip joinder assist in providing a leakproof transition from the openable section of the zipper to the side seals, where the closure profiles are fused and flattened (i.e., crushed). The present invention is directed to methods of manufacturing reclosable containers having the foregoing features.
One aspect of the invention is a method of manufacture comprising the following steps: (a) joining first and second zipper strips of a plastic zipper to web material, the first zipper strip comprising a first closure profile and a first flange extending from the first closure profile, the second zipper strip comprising a second closure profile and a second flange extending from the second closure profile, the first and second closure profiles in combination comprising at least three projecting elements, and the first zipper strip further comprising a third flange extending from the first closure profile in a direction opposite to that of the first flange, the first through third flanges being joined to the web material; (b) before or after step (a) has been performed, arranging the web material such that first and second sections are mutually opposed; (c) after steps (a) and (b) have been performed, applying heat and pressure along first and second band-shaped zones that are substantially orthogonal to the joined zipper strips and extend at least from the zipper strips to the portions of the first and second sections of the web material that are furthest away from the zipper strips, the heat and pressure being sufficient to melt the portions of the web material that lie within the first and second band-shaped zones, and to melt and flatten the portions of the zipper that lie within the first and second band-shaped zones; (d) before step (c) is performed, applying heat and pressure or ultrasonic vibrations and pressure in first and second transition regions having intermediate portions that will be respectively overlapped by the first and second zones in step (c), heat and pressure or ultrasonic vibrations and pressure being applied to an extent that upon completion of step (d), the projecting elements of the closure profiles that are furthest apart from each other will become fused to respective portions of the other zipper strip in the first and second transition regions, and the first and second closure profiles will be heated but not flattened in the first and second transition regions, wherein upon completion of steps (c) and (d), the unflattened portions of the first and second closure profiles in the first transition region form first and second transition areas on opposite sides of a first flattened section of the first and second closure profiles, and the unflattened portions of the first and second closure profiles in the second transition region form third and fourth transition areas on opposite sides of a second flattened section of the first and second closure profiles; (e) after step (c) has been performed, applying pressure in the first and second transition regions to an extent that surface irregularities formed on the first through third flanges during step (c) are flattened without flattening the first through fourth transition areas; and (f) cutting the web material and the first and second zipper strips along first and second lines that respectively intersect the first and second zones and extend the full height of the web material.
Another aspect of the invention is a method of manufacture comprising the following steps: (a) joining a first flange of a length of a first zipper strip made of thermoplastic material to a first portion of a web material, the first zipper strip further comprising a first closure profile, the first flange extending from the first closure profile; (b) joining a second flange of an equal length of a second zipper strip made of thermoplastic material to a second portion of the web material, the second zipper strip further comprising a second closure profile, the second flange extending from the second closure profile; (c) after steps (a) and (b) have been performed and while the first and second closure profiles are interlocked along the length of the first and second zipper strips, pressing respective first sections of the first and second flanges between a first pair of bars having mutually opposed flat surfaces on each side of a pair of mutually opposed straight grooves, the first pair of bars being energized and applying pressure to the extent that upon completion of step (c), the first sections of the first and second flanges are melted while the first sections of the first and second closure profiles are softened and not flattened; (d) after step (c) has been performed, pressing intermediate portions of the first sections of the first and second closure profiles and of the first and second flanges and mutually confronting third and fourth portions of the web material between mutually opposing flat surfaces of a second pair of bars, wherein the third and fourth portions of the web material do not overlap any portions of and extend substantially orthogonal to the first and second zipper strips, the second pair of bars being energized and applying pressure to the extent that upon completion of step (d), the third and fourth portions of the web material are melted, and the intermediate portions of the first sections of the first and second closure profiles are melted and flattened; (e) after step (d) has been performed, pressing the respective first sections of the first and second flanges and the respective first sections of the first and second closure profiles between a third pair of bars having mutually opposed flat surfaces on each side of a pair of mutually opposed straight grooves, the third pair of bars applying pressure to an extent that upon completion of step (e), surface irregularities on the joined first sections of the first and second flanges are flattened without flattening any further portion of the first sections of the first and second closure profiles; and (f) after step (e) has been performed, cutting the web material and the first and second zipper strips along a first line that intersects and extends the full height of the web material.
A further aspect of the invention is a method of manufacture comprising the following steps: (a) interlocking a first closure profile of a length of a first zipper strip made of thermoplastic material with a second closure profile of an equal length of a second zipper strip made of thermoplastic material, the first and second zipper strips respectively further comprising first and second flanges respectively extending in the same direction from the first and second closure profiles, and the first zipper strip further comprising a third flange extending in a direction opposite to the direction in which the first flange extends; (b) joining the first through third flanges of the lengths of the first and second zipper strips to first through third portions respectively of a web material along first through third band-shaped zones of joinder respectively; (c) after steps (a) and (b) have been performed, supplying energy into first, second and third volumes forming a first section of the lengths of the first and second zipper strips, the third volume being disposed between the first and second volumes, the third volume being occupied by respective first sections of the first and second closure profiles, the first volume being occupied by respective first sections of the first and second flanges, and the second volume being occupied by a first section of the third flange, wherein the respective first sections of the first and second closure profiles are heated without being flattened during step (c) and the respective first sections of the first and second flanges will become joined upon completion of step (c); (d) after step (c) has been performed, applying pressure to and supplying energy over a first side seal region that intersects intermediate portions of the first sections of the first and second closure profiles and the first through third flanges and that intersects mutually confronting fourth and fifth portions of the web material, whereby the fourth and fifth portions of the web material will become joined to each other and to the intermediate portion of the first section of the third flange, and the intermediate portions of the first sections of the first and second closure profiles are flattened; (e) after step (d) has been performed, applying pressure on the respective first sections of the first and second flanges without flattening any unflattened portions of the first sections of the first and second closure profiles; and (f) after step (e) has been performed, cutting the web material and the first and second zipper strips along a first line that intersects and extends the full height of the first side seal region.
Yet another aspect of the invention is a method of leakproofing an end of a plastic zipper comprising first and second zipper strips joined to respective portions of a web material, the first zipper strip comprising a first closure profile and a first flange extending from the first closure profile, the second zipper strip comprising a second closure profile and a second flange extending from the second closure profile, the first and second closure profiles in combination comprising at least three projecting elements, and the first zipper strip further comprising a third flange extending from the first closure profile in a direction opposite to that of the first flange, the method comprising the following steps: (a) applying heat and pressure or ultrasonic vibrations and pressure to a section of the zipper, heat and pressure or ultrasonic vibrations and pressure being applied to an extent that upon completion of step (a), the projecting elements of the zipper that are furthest apart from each other will become fused to respective confronting portions of the zipper in the zipper section, and the first and second closure profiles will be heated but not flattened in the zipper section; (b) after step (a) has been performed, thermally crushing a portion of the zipper section, the crush area extending the full height of the zipper from flange edge to flange edge, the first and second closure profiles being flattened in the crushed portion of the zipper section; and (c) after step (b), applying pressure on the zipper section to an extent that surface irregularities formed on the first through third flanges during step (b) are flattened without flattening any further portion of the first and second closure profiles in the zipper section.
Other aspects of the invention are disclosed and claimed below.
Reference will now be made to the drawings in which similar elements in different drawings bear the same reference numerals.
The receptacle 4 typically comprises front and rear walls or panels (typically made of thermoplastic film material) that are joined together at the bottom and two sides by conduction heat sealing to form a receptacle having an interior volume and a mouth in which the zipper 8 is installed. Alternatively, the receptacle 4 may be made from a web of film that is folded, the fold forming the bottom of the receptacle. One wall of receptacle 4 has a hole (not shown in
During use, one or more discrete articles or a bulk material (not shown) may be placed inside the receptacle 4 while the zipper 8 is open, i.e., while the closure profiles of the interlockable zipper strips are disengaged from each other. After the article or material to be stored has been placed inside the receptacle, the mouth of the receptacle 4 can be sealed by pressing the zipper strips together to cause their respective closure profiles to interlock with each other. Although the zipper closure profiles may have many different designs, the design must be one that ensures that an airtight seal can be formed at the mouth of the receptacle.
The zipper strips can be pressed together using a device (not shown in
The zipper 8 is designed to form a hermetic seal at the mouth of the receptacle 4 when the zipper 8 closed. After the zipper has been closed, the interior volume of the receptacle can be evacuated by sucking air out via the one-way valve assembly 6. Air can be drawn out of receptacle 4 through valve assembly 6 using a conventional vacuum source, such as a household or industrial vacuum cleaner. The valve assembly 6 and the zipper 8 maintain the vacuum inside receptacle 4 after the vacuum source is removed.
The front and rear wall panels of the receptacle 4 are respectively sealed to the zipper strip by lengthwise conduction heat sealing in conventional manner. Alternatively, the interlockable zipper strips can be attached to the wall panels by adhesive or bonding strips or the zipper profiles can be extruded integrally with the web material. The walls of the receptacle may be formed of various types of gas-impermeable thermoplastic web material. The preferred gas-impermeable thermoplastics are nylon, polyester, polyvinyl dichloride and ethylene vinyl alcohol. The web material may be either transparent or opaque.
In many reclosable bags, the zipper comprises a pair of mutually interlockable zipper strips, each zipper strip having a respective generally constant profile along the interlockable portion of the zipper. Each zipper strip further comprises upper and lower flanges that extend from the respective closure profile in opposite direction. Each flange is a thin web of the same material used to make the closure profiles. The upper flanges serve as pull flanges that can be gripped and pulled apart to open the zipper. Typically, the ends of the zipper strips are joined together at the sides of the bag. A representative zipper joint is shown in
Thermal crushing of the interlockable profiled closure elements in region 10 of the zipper 8 creates a transition 15 between uncrushed zipper and crushed zipper that is susceptible to the presence of leaks through which fluid (gas or liquid) can enter or exit an evacuated container. Such leakage is indicated by the dashed arrow in
During manufacture, the cross seals are made wide enough so that respective halves of the heat sealed area 14 can be incorporated into two bags, as seen in
An evacuable storage bag may be constructed from two panels of film joined together (e.g., by conduction heat sealing) along three sides of a rectangle. Alternatively, the bag may be constructed by folding a web of film and heat sealing the confronting sides of the folded web in side seal regions. To maintain a vacuum inside the storage bag, the zipper in a closed state must provide a hermetic seal at the mouth (i.e., fourth side) of the bag. Also the thermally crushed ends of the zipper must be leakproof under the temperature/pressure conditions to be expected during normal usage.
In U.S. patent application Ser. No. 10/896,769, it was proposed to eliminate air leakage into an evacuated storage bag at the zipper joints by providing a transition area between the crushed and uncrushed closure profiles wherein the closure profiles have been fused together without flattening. Above and below the transition area, the zipper flanges are fused together. This was accomplished first by applying pressure and supplying ultrasonic energy in a section of the zipper indicated by cross hatching in
Still referring to
As disclosed in U.S. patent application Ser. No. 10/896,769, the foregoing was accomplished by ultrasonically welding the zipper strips together in the cross-hatched region seen in
After respective sections of the zipper strips have been joined by ultrasonically welding in zones 18, 20 and 22 (shown in
As seen in
In accordance with the teaching of U.S. patent application Ser. No. 10/896,769, the uncut web/zipper assembly comprises three distinct structures: (a) respective thermally crushed zipper sections 70, 72 (that will be severed at the cut line 16) in which the zipper strips are fused together and the closure profiles are deformed; (b) respective ultrasonically welded zipper sections 74, 76 substantially contiguous with the thermally crushed zipper sections 70, 72, in which the zipper strips are fused together and the closure profiles are fused without substantial deformation, thus forming the aforementioned transition areas 22a and 22b); and (c) the remaining zipper sections 78 (having one end substantially contiguous with a corresponding ultrasonically welded section) in which the zipper strips are interlockable and disengageable (i.e., the closure profiles are neither deformed nor fused together).
In order to produce a reclosable pouch, bag or package that will contain vacuum, pressure and/or liquids, it was determined that there should be hard and intimate contact between the closure profiles when the zipper is closed. More specifically, it was determined that, in order to ensure that the zipper performs its containment function in an acceptable manner, the percentage of the area of intimate contact between closure profiles should lie within a predetermined range. As used herein, the term “intimate contact”, in the context of a closed zipper, means those portions of the area at the interface of the interlocked closure profiles that do not show any clearance between the respective closure profile elements, such as hooked elements and posts or backup elements, when viewed under a microscope. The areas without clearance can be displayed by cutting the zipper with a razor blade and placing the cross section under magnification. A magnified image of the closure profiles (i.e., a so-called “shadowgraph”) is produced, and then the portions of the profiles that display intimate contact can be marked on the image.
The minimum and maximum intimate contact area may be expressed as percentage, whereby the area of lineal contact is divided by the total available lineal surface of one profile. It was determined that the minimum percentage of intimate contact area that would still enable the zipper to perform satisfactorily as a containment zipper was 33%, whereas the maximum percentage of intimate contact area that would still enable the zipper to open and reclose was 76%. It is believed that any zipper having an intimate contact area percentage in the range of 33 to 76% can be effectively placed in a reclosable package that will contain vacuum, pressure and/or liquid during normal usage. Once a containment zipper has been selected, the package designer must then select a proper film strength and film seal integrity for the specific application.
Furthermore, the respective closure profiles of the zipper should have the same shape and configuration of elements, so that thermoplastic zipper material is substantially symmetrically and evenly distributed across the interlocked profiles. This will facilitate the formation of zipper end stomps or joints having flat surfaces and constant thickness.
If the minimum design criteria for the closure profiles are met, the reclosable package will only be limited by the material strength of the package components, i.e., the web material, the web-to-web and web-to-zipper seals, and the zipper material.
Many different types of zippers are suitable for use as containment zippers. In accordance with various embodiments disclosed hereinafter, a containment zipper is incorporated into a pouch or bag in such a way that the pouch or bag is able to withstand a large pressure differential between the interior and the exterior of the pouch or bag without leaking or popping open. Alternatively, the pouch or bag is suitable for containing liquid without leaking or popping open under the expected conditions of normal usage.
A reclosable pouch or bag in accordance with one embodiment of the invention is schematically represented in cross section in
The upper flanges 24 and 30 can be gripped by the user and pulled apart to open the closed zipper. The opened zipper can be reclosed by manually pressing the zipper strips together along the entire length of the zipper with sufficient force to cause the closure profiles to interlock. Alternatively, a slider (not shown) can be used to close the zipper. Typically, such a slider takes the form of a U-shaped clip that fits over the zipper with clearance for the upper flanges, while the legs of the clip cam the zipper profiles of the incoming zipper section into engagement when the slider is moved along the zipper in either direction.
The structure of the containment zipper is only schematically represented in
The three-flange zipper seen in
To ensure that a reclosable bag of the type shown in
The present invention also envisions the formation of a transition area that separates crushed closure profiles from uncrushed closure profiles. One method for accomplishing the foregoing will now be described.
In accordance with one method of manufacture, the web is intermittently advanced in a machine direction and guided into a configuration whereby sides 4a and 4b of the web will be disposed between dual sealing bar assemblies 116 and 118 when web advancement ceases, i.e., during a dwell time. Concurrently with web advancement, the interlocked zipper strips 8a and 8b are also fed in the machine direction and guided by zipper guide blades 112 and 114 into the position seen in
The structure and operation of such sealing bars is well known. Typically, the sealing bar comprises a seal bar core having a pair of longitudinal channels that respectively house a thermocouple and an electric heater, both of which are electrically connected to a programmable heat controller by electrical wiring. The thermocouple produces electrical signals representing the temperature of the seal bar core, which signals are received by the heat controller. The heat controller controls the level of electrical current supplied to the heater in accordance with a heat control program that is designed to maintain the sealing bar temperature within limits preset by the system operator.
In accordance with the method of manufacture being described, first the sealing bars 142, 144 and 150 are heated to the desired temperatures. Then the mounting plates 146 and 152 are extended toward each in unison.
If the web material is a solitary web of packaging film, then that web is folded before the zipper is attached. Alternatively, if the web material comprises two webs of packaging film, then the additional operation of heat sealing the bottoms of the receptacles can be performed before or after zipper attachment. A person skilled in the art will recognize, however, that the zipper strips could be separately attached to the web material and then brought into interlocking relationship while joined to the web material, in which case the arrangement shown in
After each zipper sealing operation is performed, the joined web and zipper are advanced by one package length. Each length of joined web and zipper must pass in succession through the stages depicted in
At station 130, a short section of zipper having a small rectangular area is pressed between a first set of mutually opposing heated grooved bars (only one of which is visible in
When two heated grooved bars of the type shown in
At station 130, the temperature of the grooved bars is high, while the applied pressure is low. Under these conditions, the portions of the flanges trapped between the grooved bars are heated and softened, while the portions of the closure profiles trapped between the opposing grooves of the grooved bars are heated and softened without flattening. The area contacted by the grooved bars is similar to the cross-hatched area consisting of zones 18, 20, 22 seen in
At the start of the next work cycle, the web and zipper are indexed forward until the same zipper section that was pressed at station 130 arrives at station 132, where it is pressed between a second set of mutually opposing heated grooved bars (only one of which is visible in
At the start of the next work cycle, the web and zipper are again indexed forward until the same zipper section that was pressed at station 132 arrives at side sealing station 134. Station 134 comprises a pair of mutually opposing heated side sealing bars (only one of which is visible in
At station 134, the bag side seals are formed by extending the heated side sealing bars so that the zipper/web assembly is pressed therebetween. The side sealing bars at station 134 will melt intervening portions of the web and zipper material. Since the zipper section has been preheated at stations 130 and 132, the side sealing bars will readily crush, i.e., flatten, the intervening zipper portions, including the intervening portions of the closure profiles. More precisely, the side sealing bars flatten an intermediate portion of the zipper area previously contacted by the grooved bars at stations 130 and 132. The side seal region will be similar to the cross-hatched region 14 seen in
At the start of the next work cycle, the web and zipper are again indexed forward until the same zipper section that was partially flattened at station 134 arrives at station 136, where it is pressed between a third set of mutually opposing heated grooved bars (only one of which is visible in
In accordance with the preferred method of manufacture, all of the heated areas are then cooled by being placed in contact with surface of chilled or unheated bars. This can be done in two separate operations or in a single operation given a properly designed cooling bar.
At the start of the next work cycle, the web and zipper are again indexed forward until the same zipper section that was pressed at station 136 arrives at the first cooling station 138, where it is pressed between a fourth set of mutually opposing chilled or unheated grooved bars (only one of which is visible in
At the start of the next work cycle, the web and zipper are again indexed forward until the same zipper section that was cooled at station 138 arrives at the second cooling station 140. Station 140 comprises a pair of mutually opposing chilled or unheated side cooling bars (only one of which is visible in
The cooling stations achieve the desired final formation of the transition area and adjacent areas. Thereafter, the zipper/web assembly is again indexed forward. During the next work cycle, the zipper and web material are cut along a line generally bisecting the side seal region formed at station 134.
Alternatively, a set of cooling bars could be designed to contact all of the foregoing areas (i.e., the areas contacted by the grooved bars as well as the area contacted by the side sealing bars) in one operation. In this case, each cooling bar would have a flat surface comprising a first area in the shape of an H on its side and a second area, substantially contiguous with the first area and extending downward from the side of the H. The H-shaped surface area would be defined by respective recesses that provide clearance for the transition areas and has a width equal to the width of the heat-treated zipper section, while the second area has a width equal to the width of the side seal region.
The result of the foregoing operations is seen in
In accordance with one methodology, the temperature and pressure of the grooved bars at stations 130, 132, 136 and 138 are such that the transition area 62 has a cross section as shown in
However, the transition area 62 may be formed in a manner such that the hooks of the monohook elements are fused together and there are no channels like those depicted in
One of the problems in producing an acceptable containment package occurs with mismatched packaging elements. If the zipper is massive compared to the film, or the zipper requires a high amount of energy relative to the film to produce a seal, the transition area of the zipper crush must be formed with care to avoid leakage. In accordance with alternative embodiments, the contact area in the section of the closure profiles wherein the transition areas will be formed may be coated with a lower-melting-point material that allows for the adhesion of the zipper to itself in the transition areas using a lower heat setting. Consequently, film damage is reduced while still creating a leakproof zipper end seal and eliminating or reducing the possibility of cross-channel leakers. The coating can be made of a material that is activated by thermal, ultrasonic, radiofrequency or ultraviolet energy, which would be applied at the point in the zipper profile where it is desired to fuse and weld the profiles to create an acceptable containment seal. The advantage of this is that the heat used can be lowered in the stomp area, thereby helping to minimize or eliminate film damage while still creating a hermetic side seal. This allows for the combination of mismatched packaging elements with the introduction of the coating material onto the zipper profiles. By adding a lower-energy material to the profile, one can effectively circumvent the problems associated with the combination of massive (high-energy) zippers and thin (low-energy) films. The coating would have a lower energy requirement than the base zipper material, thereby more closely matching to a lower-energy film substrate.
A reclosable pouch or bag in accordance with another embodiment of the invention is schematically represented in cross section in
Still referring to
The structure of the containment zipper attached to front panel 4a is only schematically represented in
The zipper shown in
In accordance with one method of manufacturing reclosable bags or pouches of the type depicted in
After the cross seals and zipper end seals have been formed, the bag or pouch shown in
The result of the foregoing process is a reclosable bag or pouch having a zipper attached to the front panel and extending the full width of the bag or pouch. A line of weakness, e.g., a line of spaced perforations, is formed in the front panel 4a at a point between the zones of web-zipper joinder 92 and 96, as indicated by the short line seen intersecting front panel 4a in
With the ends of the zipper sealed using the techniques disclosed herein, the bag or pouch shown in
The transition area between crushed and non-crushed closure profiles needs to be correctly formed for containment applications. To successfully form a tight transition area, the pouch or bag machine can be set up with grooved bars that are specially designed for the particular zipper being employed. Although
Alternatively, tight transition zones can be formed using ultrasonic energy instead of conductive heat. In that case, each set of heated grooved bars would be replaced by a respective horn/anvil pair, in which the horn emits ultrasonic energy, and both the horn and anvil have grooves that provide clearance for the sections of closure profiles disposed between the horn and anvil. Welding and sealing of thermoplastic material by ultrasonic vibrations is an established process and has been used for forming slider end stops on the ends of a slider-operated zipper in a reclosable bag and for forming zipper joints generally. A typical ultrasonic welding apparatus in which a workpiece is fed through an ultrasonic weld station comprises an anvil and an oppositely disposed resonant horn. The frontal surface of the horn and the anvil are urged toward mutual engagement, for coupling the ultrasonic vibrations from the activated horn into the thermoplastic material of the workpiece, thereby effecting ultrasonic welding. The horn is energized from a power supply that provides electrical high-frequency power at a predetermined ultrasonic frequency to an electro-acoustic transducer, which, in turn, provides mechanical vibrations at that frequency to a booster or coupling horn for coupling these vibrations to the horn.
Although not shown in
While the invention has been described with reference to various embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation to the teachings of the invention without departing from the essential scope thereof. Therefore it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
As used in the claims, the term “joined” means that distinct surfaces of respective portions of thermoplastic material have been brought into contact and softened or melted to an extent that those surfaces are no longer distinct and the portions of material have or will become integral with each other after sufficient cooling. As used in the claims, the term “web material” means one or more webs of flexible material suitable for making a package. As used in the claims, the term “melted”, in the context of material of either a zipper flange or a closure profile “melting”, means some or all of the material of the particular flange or closure profile has melted. As substantially used in the claims, the concept of “a volume occupied by a structural element” should not be construed to require that the volume contain no empty space or that the volume contain no other structural element. Further, in the absence of explicit language in any method claim setting forth the order in which certain steps should be performed, the method claims should not be construed to require that steps be performed in the order in which they are recited.
This application is a continuation-in-part of and claims priority from U.S. patent application Ser. No. 10/896,769 filed on Jul. 21, 2004 and entitled “Leakproof Zipper End Crush for Reclosable Bag and Related Method of Manufacture”.
Number | Date | Country | |
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Parent | 10895769 | Jul 2004 | US |
Child | 11257682 | Oct 2005 | US |