This invention pertains generally to storage containers and more particularly to flexible storage bags designed to be sealed and evacuated. The invention finds particular applicability in the field of food storage.
Flexible plastic bags are widely used for a variety of purposes such as storing food items, either temporarily as in the case of packaging snacks or long term as in the case of freezer storage. Plastic bags of this style typically include flexible sidewalls made from, for example, polyethylene, that define an opening and an internal volume accessible through the opening. To seal the bag, interlocking closure strips may be provided about the rim of the opening.
One common problem which occurs with such bags is that, after the opening has been sealed, latent air may remain trapped in the internal volume. In addition to undesirably increasing the overall size of the sealed bag, the trapped air can cause spoilation of food items stored in the internal volume. Therefore, to remedy this problem, it is known to provide a one-way valve element attached to a flexible sidewall and communicating with the internal volume. The one-way valve element allows for the evacuation of the trapped air from the internal volume while also preventing the ingress of air from the surrounding environment into the internal volume. The one-way valve element may be activated in various ways such as, for example, by applying compressive pressure to the flexible sidewalls to force air from the internal volume or by engaging a nozzle of a vacuum source to the one-way valve element to draw air from the internal volume. An example of a one-way valve element that operates in conjunction with a vacuum source is provided in U.S. Pat. No. 6,581,641, issued to Skeens et al. and assigned to Illinois Tool Works Inc.
A problem that may arise with such bags that include one-way valve elements is that the flexible sidewall opposing the valve element and the sidewall to which the valve element is attached can actually clog the valve element preventing further evacuation. For example, it will be appreciated that placing the opposing sidewall against a solid surface and pressing the sidewall with the attached valve element toward the surface evacuates the internal volume by collapsing the sidewalls together. This also necessarily brings the opposing sidewall into contact with the valve element which can result in clogging. Likewise, where a vacuum source is used to evacuate the flexible bag, the opposing sidewall may be drawn under vacuum pressure into the valve element. A related problem is that collapsing the opposing sidewalls themselves together may trap air in other portions of the internal volume. These and other problems are remedied by the invention described herein.
The invention provides a clearance member for preventing the opposing second sidewall from clogging the one-way valve element while maintaining communication between the valve element and the internal volume. The clearance member additionally hinders the collapsing together of the first and second sidewalls that results in trapping of air in other portions of the internal volume.
In one aspect, the clearance member is provided as a textured portion on an inner surface of the sidewall that is opposite the valve element. The textured portion provides various evacuation passages that are recessed into the opposing sidewall. Accordingly, even when the second sidewall and the valve element collapse adjacent to each other, the evacuation passages communicate with an inlet to the valve element allowing for continued evacuation. In another aspect, the clearance member can be a permeable element attached to the inner surface of the first sidewall to cover the valve element. Accordingly, the second sidewall is prevented from collapsing adjacent to the valve element by the permeable element. The permeable element, however, is comprised of a material that demonstrates high air permeability so that air can continue to access the covered valve element.
In another aspect, the clearance member is provided as a rigid structure attached to the valve element or to the sidewalls proximate to the valve element. The rigid structure spaces the opposing sidewalls apart from each other thereby allowing for continued evacuation. In yet another aspect, the clearance member may be a compressible structure attached to the valve element or sidewalls. While the compressible structure continues to prevent the complete collapsing together of the sidewalls, it also compresses to minimize the space between the sidewalls and, accordingly, minimizes the air remaining in the internal volume.
Thus, an advantage of the invention is that it assists in preventing a one-way valve element from becoming clogged with an opposing flexible sidewall. Another advantage is that it hinders the opposing sidewalls from collapsing together and thereby prevents the trapping of air within the internal volume. A related advantage is that the invention facilitates evacuation of air from the internal volume to, for example, preserve food items. These and other advantages and features of the invention will become apparent from the detailed description and the accompanying drawings.
Now referring to the drawings, wherein like reference numbers refer to like elements, there is illustrated in
To releasably close the opened top end 116 after insertion of an item for storage, there is attached to first and second sidewalls 102, 104 and parallel to the open top edge respective first and second fastening strips 120, 122. The first and second fastening strips 120, 122 can be formed from extruded, flexible thermoplastic and extend between the first and second side edges 110, 112. As will be appreciated by those of skill in the art, the first and second fastening strips 120, 122 can engage to form a seal which closes the normally open top edge 116. Of course, in other embodiments or in combination with the interlocking strips, other methods such as the use of pressure sensitive or cold seal adhesives such as those disclosed in U.S. Pat. No. 6,149,304, herein incorporated by reference in its entirety, heat-sealing, or cling can be employed to seal the open top edge.
To evacuate air trapped in the flexible bag 100 after sealing the open top edge 116, the bag includes a one-way valve element 130 that is attached to the first sidewall 102 and communicates with the internal volume 106. The one-way valve element 130 is capable of opening to allow entrapped air from the internal volume 106 to escape and closing to prevent to the ingress of environmental air into the internal volume. Communication with the internal volume 106 can be accomplished by disposing an opening through the first sidewall 102 and then attaching the valve element 130 over the opening.
Referring to
Disposed concentrically into the valve body 132 is a counter-bore 148. The counter-bore extends from the first flange face 140 part way towards the boss face 144. The counter-bore 148 defines a cylindrical bore wall 150. Because it extends only part way toward the boss face 144, the counter-bore 148 forms within the valve body 132 a preferably planar valve seat 152. To establish fluid communication across the valve body, there is disposed through the valve seat 152 at least one aperture 154. In fact, in the illustrated embodiment, a plurality of apertures 154 are arranged concentrically and spaced inwardly from the cylindrical bore wall 150.
To cooperatively accommodate the movable disk 134, the disk is inserted into the counter-bore 148. Accordingly, the disk 134 is preferably smaller in diameter than the counter-bore 148 and has a thickness as measured between a first disk face 156 and a second disk face 158 that is substantially less than the length of the counter-bore 148 between the first flange face 140 and the valve seat 152. To retain the disk 134 within the counter-bore 148, there is formed proximate to the first flange face 140 a plurality of radially inward extending fingers 160. The disk 134 can be made from any suitable material such, as for example, a resilient elastomer.
Referring to
Referring to
To attach the valve element 130 to the first sidewall, referring to
In other embodiments, the one-way valve element can have a different construction. For example, as illustrated in
As will be appreciated by those of skill in the art, when the sidewalls 102, 104 of the bag 100 are forcibly compressed together, air from the internal volume 106 will pass through the hole 180 and the aperture 176 thereby partially displacing the top layer 174 from the base layer 172. The air can then pass along the channel formed between the adhesive strips 178 and escape to the environment. When the force on the sidewalls 102, 104 is released, the resilient top layer 174 will return to its stretched configuration covering and sealing the aperture 176. The valve element 170 may also contain a viscous material such as an oil, grease, or lubricant between the two layers in order to prevent air from reentering the bag. In an embodiment, base layer 172 may also be a rigid sheet material.
Illustrated in
Referring to
Referring to
The vacuum source connected to the nozzle 196 in
In the embodiment illustrated in
Referring to
Of course, in other embodiments, the textured portion need not be provided over substantially the entire inner surface. For example, in the embodiment illustrated in
In another embodiment illustrated in
To produce a flexible bag having a textured portion, webs of flexible thermoplastic material can be manipulated through a high speed manufacturing process such as that illustrated in
A second web 250 of thermoplastic material is provided wound onto a second roll 252 located below the first roll. Embossed into the material of the second web 250 are pluralities of peaks and recesses that form the textured portion of the finished flexible bag. The second web 250 is continuously unwound from the second roll 252 and aligned with the machine direction 244 where it is attached to the second surface 248 of the advancing first web 240 by web attachment rollers 254. As will be appreciated, the attached first and second webs 240, 250 will form the second sidewall of the finished flexible bag.
To provide the first sidewall, a third web 260 of thermoplastic material is provided wound onto roll 262. The third web 260 is continuously unwound and aligned with the first and second webs 240, 250 in the machine direction 244. After alignment, the third web 260 is attached to the first and second webs 240, 250 at a second set of web attachment rollers 264. In order to form the open top edge of the finished bag, the third web 260 is only attached to the first and second webs 240, 250 along a first edge 268 of the combined webs while the parallel second edge 269 remains unattached.
To provide the fastening strips on the finished bag, the first and second fastening strips 270, 272 can be provided as elongated thermoplastic extrusions wound onto first and second strip rolls 274, 276. The first fastening strip 270 is unwound and aligned with the third web 260 to which the first fastening strip is attached by strip attachment rollers 278. The second fastening strip 272 is unwound and aligned in the machine direction 244 with the first and second webs to which the second fastening strip is continuously attached by strip rollers 280. As illustrated in
As the attached webs and strips are advanced in the machine direction 244, the side edges of the finished bag may be produced by an edging machine 282. Specifically, the edging machine 282 forms a seal 284 across the width of the attached webs and then cuts perforations 286 along the seal. The perforated webs can then be folded by a folding machine 288 and wound into a roll 290 for distribution. Later, individual bags can be unwound and detached from the roll 290 along the perforated seals.
In another embodiment, instead of providing the textured portion in the form of a separate web of material, the textured portion can be formed directly onto the first web 240 of advancing material. For example, the second roll 252 and second web 250 of material can be eliminated and the first web attachment rollers 254 can be replaced with an embossing machine that forms the peaks and recesses directly onto the first web 240.
In another aspect of the invention, as illustrated in
The permeable element 308 can be provided as a thickened planar sheet outlined by a peripheral edge 309 that defines the shape of the permeable element. The permeable element can be attached by, for example, adhesive to an inner surface 324 of the first sidewall 302 such that the permeable element overlays and covers the one-way valve element 330. In another embodiment, the permeable element 308 can be attached to the second sidewall 304 opposite the valve element 330. The permeable element 308 is characterized in that it comprises a material that demonstrates a high degree of air permeability.
As illustrated in
Examples of various permeable materials suitable for the permeable element include any of various nonwoven materials such as, but not limited to, melt blown, spun bond, hydroentangled, needle punched, batting, dry-laid or wet-laid. Preferably, the selected nonwoven material demonstrates a hydrophobic property that permits air to permeate through but retains liquids. As will be appreciated, such a hydrophobic permeable material would prevent fluids from leaking through the one-way valve element or from drying out within the valve element. A preferred material is polypropylene but the nonwoven material could also be made from polyester, nylon, or polyethylene. Other examples of suitable permeable materials include porous materials such as open celled foams such as sponges, porous substrates, and sintered materials.
In another aspect of the invention, the clearance member can be provided as a rigid structure that functions to space the sidewalls apart from each other in the proximity of the valve element during evacuation. The rigid clearance member may include slots or notches disposed into it that permit air from the internal volume to access the valve element. Because of the combined effect of the rigid clearance member in spacing the sidewalls apart and providing access to the valve element, clogging of the valve element is prevented. Preferably, the rigid clearance member is engaged to the valve element itself but in some embodiments the rigid clearance member can be attached to the opposing sidewall.
An embodiment of the rigid clearance member in the form of a band 460 engaged to a valve element 430 attached to a flexible bag 400 is illustrated in
Referring to
Preferably, the inner diameter of the band 460 is sized to slidably fit about the circular, projecting boss portion 438. Accordingly, when the boss portion 438 and band 460 are fit together, the first sidewall 402 is sandwiched between the valve element 430 and band. So that the second face 464 of the band 460 projects into the internal volume, the length of the band between the first and second faces 462, 464 is greater than the length of the projecting portion 438 between the second flange face 442 and the boss face 444. In various embodiments, the band and the boss portion can be secured by adhesive, friction fit, or can be an integral portion of the valve.
As illustrated in
The vacuum source connected to the nozzle 496 in
In
Referring to
As illustrated in
Illustrated in
The elongated sleeve 660 is formed as a cylindrical structure that extends between a first face 662 and a second face 664. Disposed through the sleeve 660 about the periphery are a plurality of slots 666. The cylindrical sleeve 660 can be sized to slideably engage with the circular valve element 630 in the above described manner with the second face 664 projecting into the internal volume 606 towards the second sidewall 604. Referring to
Illustrated in
It will be appreciated that when the nozzle 780 is pressed against the valve element 730, the second sidewall 704 can collapse against and clog the valve element. To prevent this from occurring, an embodiment of the clearance member 760 is attached to the valve element 730. The clearance member 760 is formed as a circular wall extending between a first end 764 and a second end 766. The first end 764 is attached to the valve base 734 such that the second end 766 is directed towards the second sidewall 704. Disposed through the circular wall 762 are a plurality of apertures 770 through which air, indicated by arrow 768, can pass. Accordingly, when the vacuum nozzle 780 is pressed against the cap 732, the clearance member 760 prevents the second sidewall 704 from entering and clogging the valve element 730.
In another aspect of the present invention, the clearance element can be provided as compressible structure comprised from a compressible material. The compressible clearance member can be attached to either the valve element or to an inner surface of a sidewall proximate the valve element. Accordingly, the compressible clearance member will prevent the sidewalls from completely collapsing together proximate the valve element. An advantage of utilizing the compressible clearance member is that while the sidewalls remain spaced-apart, the compressible clearance member compresses to minimize the air remaining in the internal volume. Another advantage of utilizing a compressible clearance member is that the compressible clearance member urges back against the sidewalls. Therefore, if the valve element were to become clogged by the sidewalls, the compressible structure could unclog the valve element by urging the first and second sidewalls apart.
Referring to
The spring 860 is formed as helical spring comprised of a plurality of hoops 866 that extends between a first end 862 and a second end 864. The first end 862 engages the valve element 830 by, for example, adhesive attachment such that the second end 864 projects into the internal volume 806 toward the second sidewall 804. In other embodiments, the spring can be secured to the valve element by a friction fit, a snap-lock engagement, or adhesive. During evacuation, as the first and second sidewalls 802, 804 collapse together, the second sidewall 804 will contact the second end 864 of the spring 860 and begin to compress the spring towards the first sidewall. Conversely, the spring 860 will urge the second sidewall 804 away from the valve element 830 preventing the valve element from becoming clogged. Moreover, because of the substantial space between the alternating hoops 866 of the spring 860, air will continue to access to the valve element 830. Preferably, the spring is made from any suitable resilient material such as spring steel or a resilient thermoplastic. In another embodiment, a structure comprising a tube with axially-spaced, collapsible, accordion pleats and holes disposed therethrough can be employed as the compressible clearance member.
Illustrated in
The compressible foam elements 960 are shaped as rectangular blocks of porous foam attached to the inner surface of the first sidewall 902 on either side of valve element 930. However, in other embodiments, the foam elements can be attached to the second sidewall in a manner to align with the valve element. Additionally, in other embodiments, the foam element can have other shapes, such as circular, square, annular, or polygon. The foam elements 960 extend into the internal volume 906 and terminate at respective foam top surfaces 962 that are located closer toward the second sidewall 904 than the valve element 930. During evacuation, as the first and second sidewalls 902, 904 collapse towards each other, the second sidewall will contact the foam top surfaces 962 and begin to compress the foam blocks 960 towards the first sidewall 902. Conversely, the foam blocks 960 will urge the second sidewall 904 away from the valve element 930 preventing the valve element from clogging. Because of the porous character of the foam blocks 960, air will continue to have access to the valve element. Preferably, the foam blocks are formed from foamed rubber.
In another aspect of the invention, the flexible bag having a one-way valve element and clearance member can be provided with fastening strips activated by a slider. For example, referring to
As shown in
The second closure element 1034 includes a base portion 1038 having a pair of spaced-apart parallely disposed webs 1040, 1041, extending from the base portion 1038. The base and the webs form a U-channel closure element. The webs 1040, include hook closure portions 1042, 1044 extending from the webs 1040, 1041 respectively, and facing towards each other. The hook closure portions 1042, 1044 include guide surfaces 1046, 1047 which serve to guide the hook closure portions 1042, 1044 for occluding with the hook closure portions 1052, 1054 of the first closure element 1036.
The first closure element 1036 includes a base portion 1048 including a pair of spaced-apart, parallely disposed webs 1050, 1051 extending from the base portion 1048. The base and the webs form a U-channel closure element. The webs 1050, 1051 include hook closure portions 1052, 1054 extending from the webs 1050, 1051 respectively and facing away from each other. The hook closure portions 1052, 1054 include guide surfaces 1045, 1055, which generally serve to guide the hook closure portions 1052, 1054 for occlusion with the hook closure portions 1042, 1044 of the second closure element 1034. The guide surfaces 1045, 1055 may also have a rounded crown surface.
The slider 1032 includes a top portion 1072. The top portion provides a separator 1043 having a first end and a second end wherein the first end may be wider than the second end. In addition, the separator 1043 may be triangular in shape. When the slider is moved in the occlusion direction, the separator 1043 deoccludes the fastening strips 1030, 1031 as shown in
The interlocking fastening strips may comprise “arrowhead-type” or “rib and groove” fastening strips as shown in
The slider 1119 includes a flat back plate 1120 adapted to run along free edges 1121 on the upper ends of the sections of the flange portions 1108 and 1109 as shown in the drawing. (U.S. Pat. No. 3,806,998, Col. 2, lines 41-46). Integrally formed with the back plate 1120 and extending in the same direction (downwardly as shown) therefrom are respective coextensive sidewalls 1122 with an intermediate spreader finger 1123 extending in the same direction as the sidewalls at one end of the slider. (U.S. Pat. No. 3,806,998, Col. 2, lines 46-51). The sidewalls 1122 are in the form of panels which are laterally divergent from a narrower end of the slider. (U.S. Pat. No. 3,806,998, Col. 2, lines 51-55). The slider walls 1122 are each provided with an inwardly projecting shoulder structure 1124 flange adapted to engage respective shoulder ribs 1125 and 1127 on respectively outer sides of the lower section of the flange portions 1108 and 1109. (U.S. Pat. No. 3,806,998, Col. 2, line 66 to Col. 3, line 3).
Additionally, the interlocking fastening strips may comprise “profile” fastening strips, as shown in
The straddling slider 1210 comprises an inverted U-shaped member having a top 1220 for moving along the top edges of the strips 1214 and 1215. (U.S. Pat. No. 5,664,299, Col. 4, lines 1-3). The slider 1210 has sidewalls 1221 and 1222 depending from the top 1220. (U.S. Pat. No. 5,664,299, Col. 4, lines 3-4). A separating leg 1223 depends from the top 1220 between the sidewalls 1221 and 1222 and is located between the uppermost closure elements 1216a and 1217a of profiles 1216 and 1217. (U.S. Pat. No. 5,664,299, Col. 4, lines 26-30). The fastening assembly includes ridges 1225 on the outer surfaces of the fastening strips 1214 and 1215, and shoulders 1221b and 1222b on the sidewalls of the slider. (U.S. Pat. No. 5,664,299, Col. 4, lines 62-65). The shoulders act as means for maintaining the slider in straddling relation with the fastening strips by grasping the lower surfaces of the ridges 1225. (U.S. Pat. No. 5,664,299, Col. 5, lines 4-7).
Also, the interlocking fastening strips may be “rolling action” fastening strips as shown in
The straddling slider 1310 comprises an inverted U-shaped plastic member having a back 1320 for moving along the top edges of the tracks 1318 and 1319 with sidewalls 1321 and 1322 depending therefrom for cooperating with the tracks and extending from an opening end of the slider to a closing end. (U.S. Pat. No. 5,007,143, Col. 5, lines 26-31). A separator finger 1323 depends from the back 1320 between the sidewalls 1321 and 1322 and is inserted between the inclined tracks 1318 and 1319. (U.S. Pat. No. 5,007,143, Col. 5, lines 34-36). The slider 1310 has shoulders 1321a and 1322a projecting inwardly from the depending sidewalls 1321 and 1322 which are shaped throughout the length thereof for cooperation with the depending separator finger 1323 in creating the rolling action in opening and closing the reclosable interlocking rib and groove profile elements 1316 and 1317. (U.S. Pat. No. 5,007,143, Col. 5, lines 43-49).
In other embodiments, the fastening strips noted above may also be used without the slider.
All references, including publications, patent applications, and patents, cited herein are hereby incorporated by reference to the same extent as if each reference were individually and specifically indicated to be incorporated by reference and were set forth in its entirety herein.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”) provided herein, is intended merely to better illuminate the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
Preferred embodiments of this invention are described herein, including the best mode known to the inventors for carrying out the invention. Variations of those preferred embodiments may become apparent to those of ordinary skill in the art upon reading the foregoing description. The inventors expect skilled artisans to employ such variations as appropriate, and the inventors intend for the invention to be practiced otherwise than as specifically described herein. Accordingly, this invention includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the invention unless otherwise indicated herein or otherwise clearly contradicted by context.
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