The present invention relates to methods and apparatus for placing a product in a flexible, recloseable container, and methods and apparatus for manufacturing a flexible, recloseable container. More specifically, the present invention relates to the use of sliders on profiles used with flexible recloseable containers.
Flexible, recloseable containers such as zipper-type plastic bags are a significant advancement in the field of prepackaged items both for industrial and retail uses. The packaging industry recognizes the importance of using interlocking fastener profile strips to provide the ability to reclose the container after first use. It is also important that it be easy for the user to reliably close the interlocking strips. For instance, some containers utilize multi-colored interlocking strips to make it easier for the consumer to determine if a container is closed. Another way in which to provide for reliable interlocking is by the use of a slider that opens the interlocks when moved in one direction, and closes the interlocks when moved in the other direction. Sliders have not been applied to flexible, recloseable containers being filled with a product on a form, fill, and seal machine. What is needed is a method for incorporating a slider on a flexible, recloseable container that is formed, automatically filled with a product, and sealed. The present invention provides this in a novel and unobvious way.
One aspect of the present invention provides a method for placing the product in a flexible recloseable container. The method includes feeding a web of flexible film with interlockable fastener strips. A slider is oriented to a pre-determined orientation, and placed over the fastener strips. The slider is moved relative to the fastener strips such that the fastener strips are generally closed. A transverse seal is generally formed across the film and a product is placed within the web.
Another aspect of the present invention provides a method for making a flexible recloseable container. The method includes providing a pair of interlockable fastener strips, a web of flexible film, and a slider, placing the slider on the pair of interlockable fastener strips, and then attaching the interlockable fastener strips with attached sliders to the web of flexible film.
This and other objects of the present invention will be found in the claims, description, and drawings of the embodiments of the present invention to follow.
a is a partial cross-sectional view of the container of
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiment illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations and further modifications in the illustrated device, and such further applications of the principles of the invention as illustrated therein being contemplated as would normally occur to one skilled in the art to which the invention relates.
Slider 48 is slidable upon fastener strips 32 and 34. Movement of slider 48 along the fastener profiles results in either an interlocking of profiles 50 and 52, or an unlocking of profiles 50 and 52. In some embodiments of the present invention profiles 50 and 52 are comprised of uppermost and bottommost closure elements. In one embodiment there is an uppermost closure element 50a that interlocks with uppermost closure element 52a, and a bottommost closure element 50b that interlocks with bottommost closure element 52b. In a more preferable embodiment of the present invention separator 60 has a length sufficient to separate elements 50a and 52a, and its length is otherwise kept to a minimum. In this manner, separator 60 is kept from interfering with any spreading devices of slider application machine 114. It is preferable that slider 48 be cast or molded as a single piece, such that subsequent spreading of slider 48 by slider application machine 114 does not unduly stress a joint between separate slider components.
a is a partial cross-sectional view of the container of
Interlocking strips 32 and 34 of fastener profile are provided from a supply 106. Alternatively, some embodiments of the present invention include interlocking strips 32 and 34 which have previously been made integral with web 102. Strips 32 and 34 are substantially interlocked as provided, and pass over one or more guiding and tensioning rollers, and then between free edges 107a and 107b of web 102. Sealing mechanism 108 forms a continuous seal along edge 107a of web 102 and fastener strip 32, including a portion of inner flange 44. Sealing mechanism 108 is preferably of a type that utilizes any of hot air, heated metal bars, electrical impulse sealing bars, or ultrasonics. It is preferable that edge 107a seal against and overlap flange 44 and not shoulder 45. Likewise, free edge 107b is sealed along inner flange 46 of fastener strip 34, and preferably does not overlap shoulder 47, although there may be overlapping of the free edge and the shoulder in some embodiments of the present invention. In a more preferable embodiment of the present invention, strips 32 and 34 are oriented relative to edges 107a and 107b, respectively, such that free edges 107a and 107b are not between feet 54 and 56, respectively, so as to facilitate placement of slider 48 on strips 32 and 34 by slider application machine 114.
A vibrating bowl or hopper 110 provides sliders 48 to channel 112 in an orientation appropriate for insertion of slider 48 onto fastener strips 32 and 34. Slider 48 is preferably oriented on fastener strips 32 and 34 such that the more narrow, interlocking end 58 of slider 48 faces in direction of the movement 101 of film web 102. The wider, unlocking end 59 of slider 48 is thus oriented opposite to direction of motion 101. Channel 112 provides sliders 34 to slider application machine 114. The present invention also contemplates those embodiments in which unlocking end 59 is oriented to face in the direction of movement 101.
Slider application machine 114 includes a motor-driven rotating selector wheel 115 which rotates within a semi-circular pocket of mounting block 302. Selector 115 rotates in a direction indicated by arrow 304 about axis of rotation 306. Sidewalls 22 and 24 of web 102, with fastener strips 32 and 34 attached, move in direction 101. A stationary probe 309 spreads apart fastener strips 32 and 34 as the strips move toward slider application machine 114. Probe 309 is shown extending from channel 112 and preferably passing between both sets of closure elements 50a and 52a, and 50b and 52b. However, it is also acceptable in some embodiments of the present invention that probe 309 extend only between top closure elements 50a and 52a. In this manner the bottom closure elements remain interlocked, and slider 48 need not be spread apart as much to pass over the bottom closure elements 50b and 52b. This partial opening by probe 309 would be useful in those embodiments of the present invention that utilize sliders 48 that cannot be spread apart far enough to extend over the bottom closure elements.
Web 102 traverses along filling tube 104, with strips 32 and 34 passing through a guiding slot within mounting block 302. The guide ensures proper orientation of the fastener strips 32 and 34 prior to placement of slider 48 on the strips. It is preferable that web 102 momentarily stop as selector 115 is rotated about 90 degrees. The positional movements of selector 115 and web 102 are synchronized such that a single slider 48 is placed on each container 20. In one embodiment of the present invention this synchronization is achieved by controlling both the rotational actuation of selector 115 and the flow of web 102. This control may be achieved by an analog controller that senses the stoppage of web 102, such as, by way of example only, a positional sensor on a gear train driving rotating sealing mechanism 108, or by an optical sensor that stops web 102 when a particular visual feature of web 102 passes in front of the sensor. As another example, synchronization may be achieved by a digital electronic controller that actuates selector 115 after determining from an encoder that a portion of web 102 equivalent to the width of container 20 as gone past machine 114 since the last slider 48 was placed over strips 32 and 34.
A pocket 310a with a slider 48 located therein is rotated to position slider 48 on web 102. Slider 48 moves over the spreading ridge and is spread open. Selector 115 then places slider 48 over fastener strips 32 and 34 at a first location before feet 54 and 56 have had sufficient time to return to their normal unspread configuration. Slider 48 returns to its unspread configuration under the influence of elastic forces within slider 48. Selector 115 stops rotation at a position with the pocket leading edge pulled away from contact with interlocking end 58 of slider 48. Web 102 is free to continue moving along filling tube 104 without interference from pocket 310a. Edge 318 of mounting block 302 is cut back a sufficient amount to permit slider 48 to freely pass thereby. By momentarily stopping web 102 as selector 115 is rotated, and also by moving the pocket leading edge away from contact with slider 48, it becomes unnecessary to coordinate the rotational speed of selector 115 with the linear speed of web 102. Web 102 is preferably static when slider 48 is applied. The present invention also contemplates those embodiments in which either or both selector 115 and web 102 move in a generally continuous fashion.
After placing a slider 48 over fastener strips 32 and 34 at the first location, slider 48 is then held in a static position by positioning arm 116 and slider receiver 118 as film web 102 continues to be pulled down filling tube 104. Arm 116 may be a pocket or hand located at the end of a pneumatic cylinder, the pocket or hand having a shape complementary to a portion of slider 48. Actuation of the cylinder places the pocket or hand near slider 48 and constrains slider 48 to a position. Receiver 118 may be a pocketed plate or a flat plate that helps constrain motion of slider 48 when arm 116 is actuated.
Arm 116 and receiver 118 thus position slider 48 such that it does not interfere with the formation of corner seals 40 and 42. Because of the orientation of interlocking end 58 to face in the direction of the flow of web 102, holding slider 48 stationary as web 102 continues to move ensures that interlocking strips 32 and 34 are interlocked downstream of each slider 48. For those embodiments of the present invention in which unlocking end 59 faces in the direction of the flow of web 102, the present invention contemplates moving slider 48 relative to web 102 such that strips 32 and 34 are interlocked downstream of each slider 48.
A portion of this interlocked length of strips 32 and 34 is presented between sealing horn 120 and sealing plate 122. A pneumatic cylinder places horn 120 at a second location along fastener strips 32 and 34 and free ends 107a and 107b, and against sealing plate 122. By means of heat, ultrasonic energy, or similar process horn 120 fuses the portions of fastener strips and sidewall between horn 120 and sealing plate 122 and simultaneously forms a corner seal 40 and endstop 36 of a first container 20, and a corner seal 42 and endstop 38 of an adjacent, second container 20. It is preferable that horn 120 and sealing plate 122 not alter shoulders 45 and 47, such that there remains shoulders 45 and 47 generally across the width of container 20 to restrain slider 48.
As the assembly of web 102, fastener strips 32 and 34, and slider 48 move down along filling tube 104, there is a second repositioning of slider 48. Slider 48 is positioned adjacent the second location fused by horn 120 and sealing plate 122 by positioning arm 124 which holds slider 48 stationary against slider receiver 126, in a manner similar to the positioning by arm 116 and receiver 118. It is preferable, but not necessary, that slider 48 be moved in a manner which interlocks strips 32 and 34 and positioned adjacent endstop 36 before endstop 36 is fully hardened. The softened area of strips 32 and 34 adjacent endstop 36 is thereby permanently deformed by slider 48. This movement of slider 48 into the previously fused area has been observed to reduce leakage from container 20. This permanently deformed area is docking station 39.
In some embodiments of the present invention, a tamper evident seal 127 is provided over guiding and tensioning rollers and into a second sealing mechanism 128. Mechanism 128 fuses a tamper evidence exterior seal 127 near free ends 107a and 107b of web 102, and over the exterior of slider 48 and fastener strips 32 and 34. In other embodiments of the present invention, a tamper evident interior seal 43 is located inside and between fastener strips 32 and 34, as indicated by dotted line 43 of
As web 102 flows off of filling tube 104, a cutting and sealing mechanism 130 places a seal transversely across sidewalls 22 and 24. Having thus formed the first transverse seal of container 20, a product may be placed into the vertically extending filling tube 104 to thus fall within container 20. When container 20 is full and flows off of tube 104, sealing and cutting mechanism 130 forms the other transverse seal of container 20, and severs container 20 from web 102. The sealing and cutting mechanism 130 simultaneously forms the lower seal of the next container 20.
A web 102 of film is fed over rollers and along a folding guide 202 in a horizontal direction as indicated by arrow 201. Guide 202 folds web 102 in half, with fold 203 preferably located above free edges 107a and 107b. It is also acceptable that fold 203 be located laterally to edges 107a and 107b, such that web 102 is generally placed in a horizontal plane. A supply of interlocking fastener strips 32 and 34 are guided into alignment with free edges 107a and 107b, and sealed thereto by sealer 108. Feeding mechanisms 204 generally guide and feed web 102. Rollers, belts, and similar devices are suitable as feeding mechanisms 204.
Sliders 48 are placed along fastener strips 32 and 34 by machine 114 in a manner previously described. Sliders 48 are positioned by arm 116 and receiver 118, a fused spot is created by horn 120 and sealing plate 122, and slider 48 is repositioned by arm 124 and receiver 126, all in a manner as previously described. A tamper evident seal 127, if desired, may be applied to container 20 by sealer 128 in a manner as previously described.
Prior to the formation of transverse seals, it is necessary to open the bottom edge 203 of container 20 for subsequent introduction of the product. A slitter 210 cuts through the fold. Slitter 210 is preferably a static mechanism that cuts bottom edge 203 as web 102 is pulled past slitter 210. Bottom edge 203 is cut into bottom free edges 222 and 224. Shortened rollers 212 continue to guide and feed web 102.
A pre-sealing mechanism 206 applies sufficient heat and pressure to web 102 to substantially flatten web 102 thereat, but not so much heat or pressure as to fuse the web sidewalls. This pre-sealing mechanism 206 substantially removes wrinkles that may exist in web 102. A sealing mechanism 208 creates partial transverse seals for container 20 at the flattened web position. Sealing mechanism 208 is preferably of a type that utilizes either heated metal bars or electrical impulse sealing bars. Sealing mechanism 208 creates partial transverse seals 28′ and 30′ that extend substantially but not completely across sidewalls 22 and 24. Mechanism 208 fuses a partial transverse seal from free edges 107a and 107b across sidewalls 22 and 24 to a point about one-half inch away from bottom free edges 222 and 224. By not forming transverse seals completely across sidewalls 22 and 24, there remains a portion along bottom free edges 222 and 224 which is useful for guiding and feeding web 102 and also for subsequent opening and filling of container 20.
After forming partial transverse seals, a product is placed within container 20. Container 20 is useful for containing products that are generally flowing in nature, such as small pieces of candy, granular products, and liquids. For example, with products of the type which have a flowing nature it is preferable that container 20 be oriented in a substantially vertical manner as it continues to move horizontally.
After introduction of the product into container 20, free edges 222 and 224 are fused together by bottom sealing mechanism 218. Mechanism 218 places a wide sealing area on container 20, such that a seal is formed that overlaps with partial transverse side seals 28′ and 30′. In this way, the approximate one-half inch not sealed by sealing mechanism 208 is instead sealed by mechanism 218. Following the placement of a bottom seal, a cutting mechanism 230 severs adjacent containers 20 through the full transverse side seal 28 and 30. It may also be necessary to trim some of the sealed bottom edge of container 20.
Container 20 is also useful for larger products with a well defined shape, such as cheese and large candy bars. Web 102 may require reorientation based upon the type of product to be inserted within container 20. For placement within container 20 of those products that are large and have a definite shape it is preferable that web 102 be in a substantially horizontal plane, such that free edges 222 and 224 are at about the same elevation as fastening strips 32 and 34.
In those embodiments in which web 102 is pulled by rollers 204 in a vertical orientation, there is a subsequent reorientation of web 102 to a horizontal plane. As web 102 passes through second roller set 204b there is a twist 402 of 90 degrees before web 102 passes through third set of rollers 204c. It is preferable to support the underside of the horizontal portion of web 102 so that the product placed between the sidewalls is supported. This support may be in the form of a belt or roller conveyor, for example.
A spreading mechanism 216′ holds free edge 224 and lifts it vertically, creating opening 404 within web 102. In some embodiments it may be helpful to permit that portion of web 102 downstream of mechanism 216′ to return toward mechanism 216′, such that the lifting of free edge 224 does not unduly stress sidewall 22. A product is placed within sidewalls 22 and 24 of web 102 by placement mechanism 225 and free edge 224 is brought back into contact with edge 222. Transverse side seals 28 and 30 across web 102 are formed by sealing machine 208′. Sealing machine 208 places a full transverse seal across web 102. Sealing machine 208′ must also separate sufficiently such that the product within container 20 may pass therebetween. Free edges 224 and 222 are then fused together by heat, ultrasonic energy, or other method by bottom sealer 218′. Bottom sealer 218′ applies a slightly narrower seal than bottom sealer 218, because of the full transverse seal applied by sealing mechanism 208′. A cutting mechanism 230 then severs container 20 from web 102 through the transverse seals.
The present invention also incorporates methods and apparatus which can improve the operation of apparatus 100, 200, and 400 described herein for forming, filling, and sealing a flexible recloseable container. Further, the methods and apparatus to be described can also improve the operation of other methods and apparatus for forming, filling, and sealing a flexible recloseable container, and also for forming a flexible recloseable container, as those of ordinary skill in the art will readily appreciate. The use of the same element numbers refers to elements the same as previously described, but with any adaptations and changes being noted. Further, the present invention includes methods and apparatus for manufacturing flexible, recloseable containers that do not contain a product and which are sold in an empty state to a consumer.
The sliders and other features are preferably applied to the pair of fastener strips prior to attaching the fastener strips to film web 102. The apparatus thus described may be suitably packaged, such as being wound on a supply roll, or used directly without packaging, and used subsequently in a forming, filling, and sealing (FFS) process, or in a process to manufacture empty containers. The use of this novel apparatus is believed to simplify, make more reliable, and make less costly those forming, filling, and sealing applications which include a flexible recloseable container with a slider. For example, an existing machine for forming, filling, and sealing a flexible recloseable container without sliders can use the pair of fastener strips with pre-applied sliders as described. With only slight modifications, such as for accommodating the thickness of the slider through the material path, an existing FFS machine utilizing the present invention can produce a recloseable container that incorporates a slider. In contrast, the adaptation of an existing FFS machine to apply sliders after the profiles have been attached to the web of plastic film may require repositioning of several process stations of the FFS machine and the introduction of new process stations, along with adapting the material path to accommodate the thickness of the slider. On newly designed FFS it is believed that the use of fastener profiles with a plurality of sliders applied thereto prior to adhering the profiles to the web results in an FFS machine that is simpler and therefore cheaper, more reliable, and less expensive to operate. Further, since the application of the slider to the fastener profiles is one of the more complicated and troublesome aspects of forming, filling, and sealing, the separation of slider application away from the forming, filling, and sealing process permits the slider to be applied more reliably and repeatably since portions of the process need not be compromised for the forming, filling, and sealing processes.
Apparatus 500 also includes a plurality of docking stations 39′ as previously described created along the length of fastener strips 510 and 520, docking stations 39′ being substantially the same as docking station 39 described herein, except that docking station 39′ is created on the fastener strips before the strips are attached to the sidewalls of the container. Docking station 39′ is created by positioning slider 530 into the heat affected zone created when fusing a portion of fastener strips 510 and 520 to create fused endstop 540. Moving the closure element separating portion of slider 530 into the heat affected zone proximate to fused endstop causes the heat affected material of the fastener strips to set in a position that reduces mechanical pressure exerted on the separating portion of slider 530 by fastener 510 and 520
In one embodiment, apparatus 500 preferably includes a plurality of position marks 560 arranged along the length of at least one of fastener strips 510 and 520. Position marks 560 are reference marks which cooperate with a sensor and controller by which the repetitive features of apparatus 500, such as endstops 540, sliders 530, docking stations 39′, or other repetitive features may be spaced apart along the length of the fastener strips in a spacing corresponding to the length of the recloseable container. Also, position marks 560 cooperate with a sensor and controller in a process for forming, filling, and sealing to establish the size of the final recloseable container, as will be described later. The present invention contemplates a variety of different types of position marks 560, depending upon the type of sensor chosen. For example, position marks 560 may be substantially opaque for cooperating with an optical sensor, or may be substantially transparent on a substantially opaque background for cooperating with an optical sensor, or could be electrically conductive for cooperating with an electrical continuity sensor.
Although what has been described is creating a docking station by cutting a plurality of notches from each of the fastener strips, the present invention also contemplates creating a docking station by cutting a plurality of notches from only one of the fastener strips. The cutting and removal of a notch from a single fastener strip also relieves pressure exerted on the closure element spreading portion of the slider, and thus lessens the force required to move the slider when the slider is placed within docking station.
Proximate to each endstop 540 is a docking station 554. One embodiment of docking station 554 comprises a plurality of slits 553 which extend through a portion of fastener strip 512 and fastener strip 522. As best seen in
Although what has been described is creating a docking station by cutting one or more slits from each of the fastener strips, the present invention also contemplates creating a docking station by cutting one or more slits from only one of the fastener strips. The cutting of one or more slits from a single fastener strip also relieves pressure exerted on the closure element spreading portion of the slider, and thus lessens the force required to move the slider when the slider is placed within docking station.
As fastener strips 510 and 520 progress past slider application machine 114 in direction 101, a plurality of sliders 530 are coupled to fastener strips 510 and 520 in a manner as previously described. Interlocked profiles 510 and 520 then progress past and between a positioning arm 116 and slider receiver 118 for repositioning sliders 530. In a preferred embodiment, fastener profiles 510 and 520 then progress past and between a sealing horn 120 and sealing plate 122 which cooperate to form a plurality of endstops 540 (
Apparatus 900 (
It is understood that the present invention is not limited to the fastener strips, sliders, endstops, docking stations, or position marks illustrated herein, and that other fastener strips, sliders, endstops, docking stations, and position marks may be utilized in connection with the present invention. Various examples of these features are presented herein, but those of ordinary skill in the art will recognize other configurations for these features applicable to the present invention.
In a preferred embodiment, apparatus 600 includes a sensor 610 for detecting a target on fastener strip 510 or 520, such as position mark 560 (
Upon sensing a position mark 560, a controller (not shown) controls apparatus 600 to perform the various container related processes, such as one or more repositionings of the slider, detection of the presence of the slider, forming seals, and cutting the bag in spatial relationship to the position marks. For example, the slider may be placed at a position along the fastener strip in reference to the position mark. Having so placed the slider, the other features of the recloseable container, such as the transverse seals or additional endstop sealing for those interlocked strips incorporating fused endstops 541, are also incorporated on the webbing in spatial relationship to the position marks. However, the present invention also contemplates interlocking fastener strips without position marks, in which case positioning of sliders, creation of docking stations, forming of transverse seals, and other spatially-related tasks are performed, for example, by measurement of the length of the interlocked strips and/or webbing of film.
For those fastener profiles that incorporate a docking station 550 (
Apparatus 600 (
Although various embodiments of the present invention have been shown and described in conjunction with form, fill, and seal apparatus and methods, those of ordinary skill in the art will recognize that the present invention also contemplates embodiments used in conjunction with apparatus and methods for manufacturing an empty, flexible, recloseable container. As examples of such apparatus and methods, the manufacture of such empty containers would not necessarily use the various machines described for slitting the web, placing a product in the web, or resealing the web after placing the product in the web.
It is intended that embodiments of the present container with tamper-evident seals be used in situations where the bag is filled at the factory with a product and then marketed to the consumer. The consumer buys the bag and is reassured that it has not been tampered with because the tamper-evident seal is in place and needs to be ruptured before the consumer can use the contents of the bag. If the consumer does not wholly consume the contents he can then reclose the bag and use it further to contain the partially filled bag. The present invention also contemplates those embodiments which do not include a tamper-evident seal, including both those embodiments sold with a product in the bag and those embodiments in which the bag is sold in the empty state.
Referring now to
Referring to
Referring to
In the embodiment shown in
In forming seal 1100, each of the pair of side walls 1112 and 1113 folds over itself as seen at upper regions 1090 and 1091. Seal 1100 typically extends along planes parallel to a plane passing between inner face 1082 and outer face 1080 of fastener strip 1122 and a plane passing between inner face 1083 and outer face 1081 of fastener strip 1125. However, seal 1100 may also extend along planes oblique or a plane perpendicular to a plane passing between inner face 1082 and outer face 1080 of fastener strip 1122 and a plane passing between inner face 1083 and outer face 1081 of fastener strip 1125 in this and the other embodiments discussed. Seal 1100 preferably has at least one curved region 1101. The length of side walls 1112 and 1113 that form seal 1100 is typically that which allows the fastener strips to separate from each other a greater distance when the profile elements 1126, 1127, 1130 and 1131 are in a non-interlocked configuration and can be determined by one skilled in the art. In this way, seal 1100 acts as a gusset, thus allowing easier access to the film of plastic film bag 1111.
Tamper evident seal 1100 preferably has a plurality of perforations for facilitating its rupture. The plurality of perforations is preferably located in curved region 1101 but may be located at other places on seal 1100 as one skilled in the art would appreciate. Alternately, seal 1100 may be ruptured by cutting by the consumer.
The embodiment depicted in
In the embodiment shown in
The sheet of plastic seal 1200 preferably has a plurality of perforations for facilitating its rupture. The plurality of perforations is preferably located in any of the curved regions 1201a-1201c but may be located at other places on seal 1200 as one skilled in the art would appreciate. Alternately, seal 1200 may be ruptured by cutting.
The embodiment shown in
Tamper-evident seal 1300 preferably has a plurality of perforations for facilitating its rupture. The plurality of perforations is preferably located at curved region 1301 but may be located at other places on seal 1300 as one skilled in the art would appreciate. Alternately, seal 1300 may be ruptured by cutting.
Base 1431 of joint 1430 may be weakened as a result of formation of the joint and may allow one to grasp and tear the seal to open bag 1211. Alternatively, a plurality of perforations may be placed along base 1431 of seal 1400 to aid in rupturing the film. Seal 1400 may also be ruptured by cutting.
It is to be noted that the sheet of flexible plastic film disposed between the side walls can have regions other than curved regions, including pleats and other forms of folds that will act as a gusset.
Although what has been shown and described are various apparatus 500, 502, 502′, 504, 506, 508, 508′, and 509 with particular combinations of fastener strips, sliders, endstops, docking stations, tamper evident seals, and position marks as specifically described, those of ordinary skill in the art will recognize that these features of the various apparatus may be combined differently. As but one example, fastener strips 510 and 520 could include any of the various endstops shown herein, and their equivalents.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiment has been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected.
This application is a continuation of U.S. patent application Ser. No. 10/325,483 filed Dec. 19, 2002, now U.S. Pat No. 6,918,230, which is a continuation of U.S. patent application Ser. No. 10/232,844, filed Aug. 30, 2002, now U.S. Pat. No. 6,962,034, which is a continuation of U.S. patent application Ser. No. 09/794,592, filed Feb. 27, 2001, now U.S. Pat No. 6,499,272, which is a continuation of U.S. patent application Ser. No. 09/493,718, filed Jan. 28, 2000, now U.S. Pat. No. 6,216,423; which claims priority to U.S. Provisional Patent Application Ser. No. 60/148,495, filed Aug. 12, 1999, and which is a continuation-in-part of U.S. patent application Ser. No. 09/370,053, filed Aug. 6, 1999, now U.S. Pat. No. 6,209,287, which is a continuation of U.S. patent application Ser. No. 08/965,722, filed Nov. 7, 1997, now U.S. Pat. No. 5,956,924. All of these documents are incorporated herein by reference.
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Number | Date | Country |
---|---|---|
0 098 392 | Apr 1999 | EP |
0 689 993 | Apr 1999 | EP |
2 085 519 | Apr 1982 | GB |
WO 9857863 | Dec 1998 | WO |
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Number | Date | Country | |
---|---|---|---|
20040074058 A1 | Apr 2004 | US |
Number | Date | Country | |
---|---|---|---|
60148495 | Aug 1999 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10325483 | Dec 2002 | US |
Child | 10405052 | US | |
Parent | 10232844 | Aug 2002 | US |
Child | 10325483 | US | |
Parent | 09794592 | Feb 2001 | US |
Child | 10232844 | US | |
Parent | 09493718 | Jan 2000 | US |
Child | 09794592 | US | |
Parent | 08965722 | Nov 1997 | US |
Child | 09370053 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 09370053 | Aug 1999 | US |
Child | 09493718 | US |