Certain types of edible films are presently being used as a delivery system for mints and oral care products. Typically, the film is precut into rectangular pieces and packaged in a flat pack-shaped primary package. The edible film is stacked in the package. One problem that may be encountered with the present package is the difficulty of removing one piece of film from the stack. Another problem that may be encountered with the present package is the film pieces, at times, tend to curl during use life (when the film is exposed to moisture).
In another application, there is a belief that edible films can be used as a delivery system for ethical drugs. The edible film would comprise a carrier made of an edible film and a regulated amount of the desired drug. In one such application, the user would insert the edible film in their mouth and the edible film would dissolve—immediately dispensing the drug into the body. However, in this application, one desires to assure that a unit dose (a single piece of film) is delivered during use.
The present invention relates to an edible film dispenser that presents a single strip of film during each index cycle. In a further embodiment, the edible film dispenser provides a moisture tight environment during shelf life and during use life.
The film dispenser of the present invention is illustrated by showing two edible film dispenser designs: (1) a continuous film dispenser where a unit dose of film is cut during the index cycle and (2) a design that dispenses precut film pieces. However, it is understood that these designs are merely illustrative and are not meant to limit the scope of the present invention.
Among those benefits and improvements that have been disclosed, other objects and advantages of this invention will become apparent from the following description taken in conjunction with the accompanying figures. The figures constitute a part of this specification and include illustrative embodiments of the present invention and illustrate various objects and features thereof.
Detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely illustrative of the invention that may be embodied in various forms. In addition, each of the examples given in connection with the various embodiments of the invention are intended to be illustrative, and not restrictive. Further, the figures are not necessarily to scale, some features may be exaggerated to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
In one embodiment, the film dispenser of the present invention is illustrated by showing an edible film dispenser designs that dispenses precut film pieces. However, it is understood that this design is merely illustrative and are not meant to limit the scope of the present invention.
In one example, precut pieces of film are packaged in the container (e.g. continuous bandoleer). For example, the bandoleer is composed of 2-pieces of plastic film (e.g. PP, PET, etc) that is die cut and welded together to form pockets that each piece of film is placed. A set of regularly spaced tractor guide holes are placed in the bandoleer. These guide holes are used to precisely index the bandoleer in the dispenser.
In one embodiment, the precut film dispenser is composed of the following components (see
In one embodiment, the precut film dispenser is composed of the following components (see e.g.,
1. Lid and Main Housing—an injection molded part that interfaces with the Body. This component has a Main Housing and a hinged Lid. When closed, the Lid creates a moisture tight seal with the main housing. There is a “T” shaped opening in the Main Housing. In this opening a feature acts as a hinge point for the Flexible Arm as the Arm slides underneath the hinge point. The Lid and Main Housing are bonded to the Body in a manner that creates a moisture tight seal.
2. Body—An injection molded part that, for example, is made by two shot molding a material such as polypropylene and, at least a portion of, desiccant plastic. The desiccant plastic absorbs moisture that enters the package during the Shelf Life and Use Life. In one example, the desiccant plastic holds the film pieces and is shaped in the form of a ramp or slope so that the film strip is forced up and out of the package when being indexed. In a further embodiment, a Child Resistant (CR) feature is incorporated into this component as well. By pressing in on CR feature, the Lid can be opened which will cause the film to be dispensed.
3. Indexing Finger—An injection molded part that is made, for example, by two shot molding an elastomer and a material such as polypropylene. The Indexing finger is bonded to the hinged Lid during the assembly process. The end of the Indexing Finger that is not bonded to the Lid is made of elastomer and when closed is in contact with the film strip. It fits through the “T” shaped slot in the Main Housing.
In one example of the operation of the present invention, the package is sealed when it is closed. The Lid seals to the Main Housing (e.g. by snapping over a sealing feature). The result is a moisture tight seal. The desiccant plastic absorbs moisture that may come into the package, from the opening and closing of the Dispenser, or that penetrates through the materials. In one example, the absorbing material is used because the Film Strips themselves contain moisture, which may be driven off by changes in temperature that the package goes through. Thus the present invention maintains the Film Strips in a dry environment throughout the Shelf Life and the Use Life.
When the Lid is opened, an Arm, which is attached to the Lid, pushes or pulls the film strip off the stack and out of the package. When the Lid is closed, the Arm returns to a home position, ready for the next dispense cycle.
The following is an illustration of the present invention (as shown in
The Flexible Arm is returned to the home position, ready to index the next strip, by pushing the Lid back down sealing it to the Main Housing. Alternatively, the user could continue to open the package so the Flexible Arm clears the Hinging Point, which allows it to come out of the “T” slot. The package is closed, which pushes the Flexible Arm back through the “T” slot and under the hinging point ready for the next index.
In one embodiment, the continuous film dispenser is composed of the following components (see
1. Flip-Top Main Housing (1)—an injection molded part (e.g. made via 2-shot molding of polypropylene and a thermoplastic elastomer (TPE) i.e., Santoprene). In one embodiment, the Santoprene forms a moisture tight reusable seal.
2. Tractor Guide (2)—an injection molded part (e.g. made of polypropylene) that has a base with, for example, 2-caterpillar tractor guides attached. The tractor guide is assembled to the lid of the main housing via posts in the main housing lid. In one example, the assembly may be accomplished by ultrasonic welding.
3. Drive Assembly (Magazine) (3)—(e.g. can be made of polypropylene or 3-phase desiccant plastic). In one example, the drive and support rollers are assembled into the magazine, via a snap fit. The magazine also holds a supply of edible film in a single, continuous arrangement. In one example, the drive assembly is placed into the main housing and assembled via spot welding using a heat source or ultrasonic welding.
4. Drive Roller. (4)—e.g. can be made via 2-shot molding—polypropylene inner shaft and drive sprockets with a TPE (Santoprene) coating the inner shaft). In one embodiment, the TPE serves as the edible film contact surface. For example, the sprockets of the drive roller are assembled into the tractor guide caterpillars.
5. Support Roller (5)—(e.g. can be made via 2-shot molding—polypropylene inner shaft with a TPE (Santoprene) coating the inner shaft). For example, the TPE serves as the edible film contact surface.
In one embodiment, the continuous film dispenser holds a supply of film to support 50-100 dispense cycles.
In this example, the edible film is dispensed while the main housing lid is opened by a user. When the lid is opened, the tractor guide, which is attached to the lid, also rotates upward. During this motion, the drive roller sprockets rotate as the tractor guide caterpillars are displaced by the lid motion (see
When the lid is closed, the film is cut, via a knife-like feature on the underside of the flip-top lid in the main housing (see
In a further embodiment, during lid closing, the tractor guide caterpillars return to the home position. The caterpillar teeth ride over the drive roller sprockets. The drive roller only rotates in 1-direction—the sprocket teeth do not engage the caterpillar and cause the sprockets to rotate during lid closing.
In yet another embodiment, a ‘brake feature’ is included to prevent a user from pulling an excessive amount of film out of the dispenser before cutting. In another example, the features of the lid are designed so that it must be opened some minimum amount to ensure that a full dose of film is indexed out of the dispenser.
In an example of an embodiment relating to precut film strips, precut pieces of film are packaged in a container (e.g. continuous bandoleer). For example, the bandoleer is composed of 2-pieces of plastic film (e.g. PP, PET, etc) that is die cut and welded together to form pockets that each piece of film is placed. A set of regularly spaced tractor guide holes are placed in the bandoleer. These guide holes are used to precisely index the bandoleer in the dispenser.
In one embodiment, the precut film dispenser is composed of the following components (see
1. Flip-Top Main Housing (6)—an injection molded part (e.g. made via 2-shot molding of polypropylene and a thermoplastic elastomer (TPE) i.e., Santoprene). In one example, the Santoprene forms a moisture tight reusable seal. There are a set of through holes in the side walls of the main housing. These holes each have TPE gaskets—the drive shaft & thumb wheel are assembled through these holes.
3. Film Indexing Magazine (7)—(e.g. can be made of polypropylene or 3-phase desiccant plastic). The drive sprocket is assembled into the magazine (e.g. via a snap fit). The magazine has 2-compartments that hold the continuous bandoleer. One compartment is the supply side (bandoleer filled with edible film pieces) and a take-up compartment (empty bandoleer). The drive assembly is placed into the main housing (e.g. assembled via spot welding using a heat source or ultrasonic welding).
4. Drive Sprocket—(e.g. made of polypropylene). The drive sprockets are driven by an external thumb wheel. As the drive sprocket is rotated, the bandoleer is indexed forward. The sprocket moves in 1-direction.
5. Thumb Wheel & Drive Shaft—(e.g. made of polypropylene). The sprockets are assembled onto the drive shaft. The drive shaft is fitted into the main housing, through the film indexing magazine. A set of thumb wheels are attached to the ends of the drive shaft.
2. Rotate thumb wheel to index a piece of film.
3. Remove film.
2. Pusher indexing slider forward to index a piece of film.
3. Remove film.
1. Open half portion of the Flip-top lid.
2. Pusher indexing slider forward to index a piece of film.
3. Remove film.
4. Close half portion of the lid.
1. Open half portion of the Flip-top lid.
2. Squeeze the dispenser together to index a piece of film (dispenser uses a rack and pinion design to index the bandoleer).
3. Remove film.
4. Close half portion of the lid.
In yet another embodiment, the present invention may also include a dispenser that is either disposable or reusable. For example, the entire dispenser is discarded after one emptying out the edible film. In the reusable case, in one example, the spent bandoleer is disposable so that a new bandoleer filled with film piece may be reloaded into the re-usable dispenser. In another embodiment, part of the dispenser may be made of a desiccant plastic such as, but not limited to, disclosed in U.S. Pat. Nos. 5,911,937 and 6,214,255, which are incorporated by reference herein. For example, the film indexing magazine may be made of a desiccant plastic. In another example, the dispenser may hold a desired quantity of edible film—such as 25, 50, 75, and/or 100 units.
In one embodiment, the dispenser of the present invention is designed to maintain a moisture tight seal during shelf and use life of less than about 300 micro-g/day. For purposes of the present invention, in another embodiment, the dispenser of the present invention is “moisture tight” in accordance with the test protocols set forth in USP 671. In one-embodiment, the dispenser is considered “moisture tight” where not more than one of the 10 test dispenser exceeds 100 mg per day, per liter, in moisture permeability. Testing for USP 671 is conducted on sealed containers and on containers that have been opened and then resealed. The testing consists of a desiccant of set quantity 4-8 mesh, anhydrous calcium chloride being first dried at 110 degrees for one hour then cooled in a desiccator. Then 12 containers of uniform size are selected and opened and closed 30 times each. Torque is applied to the closures as specified in the USP monograph. Desiccant is then added to 10 of the packages labeled test containers. These are then filled to within 13 mm of the opening on containers larger than 20 ml and to two-thirds full on containers smaller than 20 ml. The closures are then applied to the torque specified in the monograph. Weight is recorded to the nearest 0.1 mg for containers smaller than 20 ml, to the nearest mg for 20 ml to 200 ml, or to the nearest centigram if the container is larger than 200 ml. The containers are stored at 75 percent, plus or minus three percent, relative humidity at a temperature of 23 degrees, plus or minus two degrees. After 36 hours, plus or minus one hour, the weight is recorded, with the moisture permeability calculated in mg per day, per liter.
The following is an illustrative example that tests breath strips in the container of the present invention compared with a non-desiccated breath strip pack at 25C 80% RH to determine the effectiveness of these packs in protecting the strips during use life. Watson Spearmint Breath strips, Wrigley's Spearmint Breath strips and strips from Pfizer were tested at 25C 80% Rh to determine the variation in strip chemistry stability for this use life condition in their own primary packaging.
Whereas particular embodiments of the present invention have been described above as examples, it will be appreciated that variations of the details may be made without departing from the scope of the invention. One skilled in the art will appreciate that the present invention can be practiced by other than the disclosed embodiments, all of which are presented in this description for purposes of illustration and not of limitation. It is noted that equivalents of the particular embodiments discussed in this description may practice the invention as well. Therefore, reference should be made to the appended claims rather than the foregoing discussion of examples when assessing the scope of the invention in which exclusive rights are claimed.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US04/39582 | 11/24/2004 | WO | 00 | 4/20/2009 |
Number | Date | Country | |
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60524495 | Nov 2003 | US | |
60533362 | Dec 2003 | US |