This disclosure relates to bottles or other similar rigid containers. More particularly, the disclosure relates to a bottle feeding system that includes a nipple having an enlarged opening suitably sized for semi-solid foods and either a liner or an integrated piston to hold the liquids or semi solids.
Bottles provide a simple and convenient method for feeding both adults and babies. However, bottles are not well suited for semi-solid foods. Accordingly, there is a need for a feeding system that provides a simple and convenient way for eating semi-solid foods.
The present disclosure relates to a bottle-feeding system having an enlarged opening that is well suited for semi-solid foods. The system generally includes a rigid container or housing having an upper opening defined by an upper rim that provides access to an interior of the container. A volume compensator is inserted into the interior to assist in storing liquids or semisolids poured into the container. For example, in certain embodiments, the volume compensator may be a food grade bottle liner. The liner has a container portion configured for insertion in to the interior and a lip portion configured to engage the upper rim.
The spout has an enlarged outlet that is sized for semi-solid food. The spout includes a one-way valve having a lower ring portion that surrounds a plurality of flaps that form an opening and are configured to move between an open position and a closed position. The spout also includes a first lid portion removably engaging a top surface of the lower ring portion and having a first orifice in concentric alignment with the valve opening. The flaps extend through the first orifice. Additionally, a retainer ring having an inwardly extending retainer portion is configured to directly contact the lid portion. A first connection member and a second clamping member disposed on the container are configured to mate together to clamp the container, bottle liner and spout together.
In an alternative embodiment, the volume compensator includes a piston having a deformable body that is configured for insertion into the container. The piston contacts and forms a leak resistant seal with an inside surface of the container such that liquids and semi solids may be poured directly onto the piston. A frictional force between the body and the inside surface may be fitted to hold the piston in place. At other times, the piston may be configured to slide upwards and downwards within the container. For example, the piston may slide upwards within the container when suction is applied and then slide downwards when suction is removed. However, preferably a one way valve prevents the piston from sliding downwards once suction is removed. Applying a suction force to a top surface of the piston reduces the frictional force such that the piston is permitted to move within the container.
In addition to infants and small children, this bottle system could be used by adults with special needs. For example, adults having diminished fine motor skills or who are otherwise prevented from feeding themselves normally could use this bottle system.
Further advantages of the disclosure are apparent by reference to the detailed description when considered in conjunction with the figures, which are not to scale so as to more clearly show the details, wherein like reference numbers indicate like elements throughout the several views, and wherein:
The present disclosure relates to a bottle system that can accommodate liquids and semi-solid foods. With reference now to the figures, in which like reference characters designate like or corresponding parts throughout the several views and, in particular, to
The container 102 has an upper opening that is defined by an upper rim 112 that provides access to an interior of the container 102. The bottom of the container 102 may be closed or may be open. Having an open bottom and an open top would facilitate access and cleaning. However, a recurring problem in feeding children from a bottle having an open bottom container is that the child may tamper with the filled liner and cause food or liquids to spew from the bottle's spout. Therefore, in alternative embodiments, the bottom of the container 102 may be enclosed to assist in preventing spills and waste since the liner would be inaccessible.
The bottle liner 104 has a container portion 114 and a lip portion 116. The container portion 114 of the bottle liner 104 is inserted into the container 102 via the upper rim 112. When the container portion 114 is inserted into the interior of the container 102, the lip portion 116 is designed to rest on the upper rim 112 in order to maintain the liner 104 in place.
The precise size and configuration of the container 102 may change according to the size and type of bottle liner 104 being used. For example, the liner 104 shown in
In other embodiments, a separate liner spreader may be used to prevent the aforementioned problems associated with liner collapse. As with the reinforced liner sections 120 described above, the liner spreader assists in preventing the spout 106 from becoming clogged by holding the collapsing liner 104 away from the spout. The liner spreader preferably includes a cylindrical tube having an open top and bottom and, in certain embodiments, may include a lip that surrounds the top edge of the cylindrical tube. Referring again to
Once the liner 104 has been inserted into the container 102, the food spout 106 is also placed on the upper rim 112 so that it covers the liner and the upper opening of the container. The spout 106 may be formed from one or more components using a combination of pliable or rigid materials, including, for example, silicone, rubber, plastic or other similar materials. Preferably, these materials are food grade materials. In certain embodiments, the spout includes a one-way valve 128 that works cooperatively with a lid portion 130, including a first lid portion 130A and a second lid portion 130B. The lid portion 130 encircles the one-way valve 128 and is sized to cover the upper opening of the bottle 100 and preferably provides a leak resistant seal with the container 102 and liner 104. The lid portion 130 may be constructed entirely from a rigid material such as a hard plastic. In other embodiments, at least a bottom surface of the lid portion 130 is constructed from food grade rubber or silicone or similar material. In yet other embodiments, the entire lid portion 130 may be constructed from food grade rubber or silicone or similar material.
With reference to
The flaps 134 provide a one-way seal, allowing liquids and semi-solids to pass through in only one direction. The flaps 134 move back and forth between an open position, when liquids and semi-solids flow out through the valve, and a closed position, where the flow ceases. In one example, the valve 128 shown in
The first lid portion 130A consists of a flat disc-shaped first flange 136A and a spout tip 138 having an enlarged outlet 140 at the top that is sized for semi-solids. The spout tip 138 is sized for insertion into a mouth of a user. The second lid portion 130B consists of a flat disc-shaped second flange 136B that is configured to rest on the upper rim 112 of the container 102. The second flange 136B has a shallow circular indentation 142 located in its center. The height and outside diameter of lower ring portion 132 of the one-way valve 128 are sized so that it fits into the circular indentation 142 and the top of the lower ring portion is flush with the top surface of the second flange 136B and only the flaps 134 extend above the second flange. Additionally, an orifice 144 is located within the circular indentation 142.
The orifice 144 is approximately the same size as the opening formed when the flaps 134 of the one-way valve 128 is in the open position. Preferably, the bottom of the spout tip 138 is slightly larger than the orifice 144, which provides a small amount of space where the flaps 134 are located when the valve 128 is the open position. In certain embodiments, the outlet 140 is substantially the same size as the orifice 144. In certain embodiments, the spout tip 138 is tapered so that the orifice 144 is larger than the outlet 140. Tapering the spout tip 138 in this manner allows the user to easily insert the spout tip 138 into its mouth, whereas a larger spout might be too large to fit comfortably into the user's mouth. A second advantage is that tapering the spout tip 138 causes pressure to build as semi-solid food flows through, which assists in forcing the food through the spout and into the user's mouth. This design is particularly beneficial for thicker foods, such as oatmeal, which might otherwise become lodged or stuck in a non-tapered spout tip 138.
Returning to
With reference to
With reference to
The cover 110 preferably includes first connection members, which are configured to removably mount to corresponding second connection members formed on the bottom of the container 102 or third connection members formed on the top of the container. The snap connection may be achieved, for example, by providing a ridge located on a lower inside or outside surface of the cover 110 that mates with a corresponding ridge located on the outer or inside edge of the retention member 108 and on a lower outer edge of the container 102. Alternatively, the cover 110 may be connected to the top or bottom of the bottle via a threaded connection. For example, threads may be placed along the inside or outside surface of the cover 110 and corresponding threads may be placed on the outside or inside surface of the retention member 108 and an outside lower surface of the container 102. An advantage of a threaded connection is that it may provide a more secure, tamper-proof connection and may also prevent accidentally disconnecting the cover from the bottle.
With reference now to
The storage tray 160 includes a tray body and one or more cutouts 162 that are sized to receive one liner 104 each. The outwardly extending lip of the liner 104 rests on the edge of the cutout 162 and the container portion extends downwards into the tray 160. Next, a tray cover 164 may be placed over the entire tray 160 covering all of the cutouts 160 and liners 104. The tray cover 164 preferably forms a leak-proof seal such that no food or liquids can leak from the storage tray 160. In an alternate embodiment, separate tray covers 164 may cover each cutout 162. The tray covers 164 may also include a handle 166 that allows for easy placement and removal of the covers into the cutouts 160. In certain embodiments, each cutout 160 has a corresponding well 168, including at least one wall and a bottom, which extends into the storage tray 160 and is configured to surround the inserted liners 104. In other embodiments, no well is provided and the liner 104 is simply suspended within the tray 160.
In a second major embodiment, as shown in
A sealed volume, where liquid or semi-solids may be stored, is formed in the bottle 100 between the tops of the piston 170, the container 102 walls and the bottom of the spout 106. As the user sucks food through the spout, a vacuum is created in this sealed volume and a suction force is applied to the top of the piston 170. In certain embodiments, this suction force causes the top portion of the piston 170 to be deformed and to stretch towards the spout 106, which causes the piston to become slightly narrowed and relieves some of the pressure between sidewalls of the container 102 and the piston 170. Alternatively, the piston may be more rigid such that deformation does not occur. In either case, once the suction force acting on top of the piston is greater than the frictional force between the piston and the walls of the container, the piston 170 moves freely within the container 102. It is then drawn towards the spout 106 through continued suction. When suction is released, the deformable piston 170 returns to its original shape, the frictional force increases, and movement of the piston stops. When the piston 170 returns to its original shape (i.e., from a stretched condition to an un-stretched condition), a slight vacuum pressure is created inside the bottle due to the retraction of the piston. This may cause any food or liquid that is near the outlet to be drawn back down the spout tip.
As shown in
Referring again to
By providing an inlet for air to enter the lower volume such that no vacuum is created in the lower volume when suction is applied to upper volume, the piston 170 could again move freely within the container 102. If the air inlet were a one-way inlet so that air entering the lower volume is trapped, the piston 170 would be unlikely to move downwards in the container 102. Accordingly, in certain embodiments, the one-way air valve 128 in the spout 106 may be eliminated and the bottle may include a cover 110 that forms an airtight seal when placed on the bottom portion of the container 102. As shown in
The foregoing description of preferred embodiments for this disclosure has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure to the precise form disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiments are chosen and described in an effort to provide the best illustrations of the principles of the disclosure and its practical application, and to thereby enable one of ordinary skill in the art to utilize the disclosure in various embodiments and with various modifications as are suited to the particular use contemplated.
This application claims the benefit of U.S. Provisional Application No. 61/858,392, filed Jul. 25, 2013, entitled “Baby Bottle Feeding System,” which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US14/47737 | 7/23/2014 | WO | 00 |
Number | Date | Country | |
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61858392 | Jul 2013 | US |