The present invention relates to a bottle such as a sports bottle for selectively dispensing a liquid beverage and a second substance such as an energy gel.
People often drink when exercising to keep hydrated. Many different types of sports bottles or bladders are available for this purpose. The drink is often water, including water with an additive such as a flavour, an electrolyte and/or a stimulant such as caffeine.
In addition, people sometimes take energy supplements when exercising to provide energy boosts. For example, energy gels are a convenient way to provide fast-acting carbohydrates. Energy gels are usually provided in sealed packs that are usually carried in a pocket or in a backpack. The packs typically hold 40 ml or 60 ml of gel.
U.S. Pat. No. 9,457,927 describes a sports bottle having a larger outer container that holds water, and a smaller inner container that holds a liquid supplement shot, for example a nutritional supplement. The bottle's mouthpiece may be pushed and pulled, or rotated clockwise and anticlockwise, to select the first chamber only, the second chamber only or neither chamber, thereby allowing access to both liquids.
US Patent Publication No. 2017/0066640 describes another sports bottle having two chambers which may hold different liquids. An outer container holds water, and an inner container holds an energy or flavour supplement. When the supplement is dispensed, it is dispensed at the same time as the water. A piston forces the supplement from the inner container to join the flow of water from the outer container. A mechanism is provided to allow delivery of the water only or delivery of the water with supplement. This mechanism requires two different movements to access the water only and then to access both the water and the energy or flavour supplement.
Against this background, and from a first aspect, the present invention resides in a bottle comprising an open-topped outer container having a resilient body for holding a liquid beverage such as water (including water with additives such as flavouring, stimulants or hydration supplements). The bottle also comprises an inner container comprising a flexible pouch for holding a gel, such as an energy gel. The bottle includes a closure adapted to fix to the top of the outer container thereby forming an enclosure for containing the liquid beverage. The closure may be a screw-top lid. The bottle also comprises a fixing configured to allow the inner container to be suspended from the closure.
The bottle comprises an outlet in fluid communication with both the outer container and the inner container, thereby allowing the outlet to dispense the liquid beverage and the gel. A switch mechanism is provided that includes a switch moveable to select between placing the outlet in fluid communication with the outer container and placing the outlet in fluid communication with the inner container. Hence, the switch may allow a user to select between consuming the liquid beverage or the gel.
The bottle also comprises an air inlet and a one-way valve configured to allow air to flow into the outer container.
Such a bottle allows a user to drink liquid beverage in the outer container by setting the switch to the corresponding position and squeezing the resilient body of the bottle to force the liquid beverage out of the outlet. Also, the user may consume gel in the flexible pouch by setting the switch to the corresponding position and also squeezing the resilient body of the bottle. The flexible pouch is suspended from the closure and hence resides within the outer container. Squeezing the resilient body applies pressure to the contents of the outer container, including the flexible pouch and the gel it may contain. Hence, squeezing the bottle forces the gel out of the outlet. Advantageously, the air inlet and one-way valve allow air to enter the outer container to replace the gel that has been forced from the outlet. Thus, the pressure in the outer container does not drop below ambient pressure and maintains a compressive force on the partially-emptied flexible pouch to stop the flexible pouch filling with air. Hence, at each successive use of the bottle to consume gel, squeezing the bottle delivers gel to the outlet without any delay that would otherwise be caused by air first being expelled from the flexible pouch.
The one-way valve is also beneficial in that it stops the liquid beverage leaking from the bottle. Optionally, the one-way valve is an umbrella valve. The closure may comprise the air inlet. For example, the air inlet may extend through a wall of the closure to connect directly the internal volume of the outer container to the ambient environment outside the bottle. Where an umbrella valve is used, this may be seated on the underside of the closure, within the outer container.
The switch may be rotatable to allow selection between placing the outlet in fluid communication with the outer container and placing the outlet in fluid communication with the inner container. Optionally, the switch mechanism further comprises a core piece, and the switch is part of the core piece that is fixed to a central part of the closure to allow the switch to rotate about a central longitudinal axis of the bottle. The outlet may comprise a mouthpiece slidably mounted to a post of the core piece. The mouthpiece may slide between a closed position where the post fills an exit aperture of the mouthpiece and an open position where the exit aperture is displaced from the post. In the closed position, neither the liquid beverage nor the gel may flow from the outlet. In the open position, either the liquid beverage or the gel may flow from the outlet.
Optionally, the core piece is received within a recess formed in the top of the closure by a downwardly extending stub.
The stub may comprise at least a portion of the fixing that is configured to allow the inner container to be suspended from the closure. For example, the stub may comprise a screw thread and the inner container may comprise a complementary screw thread. Hence, the inner container may be screwed onto the stub to secure the inner container in place. Use of screw threads allows easy disassembly to allow the inner container to be removed for cleaning and refilling. The screw thread on the inner container may be formed around an aperture provided in a top part of the inner container, for example the flexible pouch may include a relatively rigid top part to allow it to be connected to the rest of the bottle. The aperture may be large to allow easy filling with gel. For example, the aperture may occupy 50% or more of the cross- sectional area of the top of the inner container.
Optionally, the core piece comprises a collar that extends over the recess and resilient members that extend through a central aperture in the base wall of the stub such that the closure is sandwiched between the collar and resilient members. This arrangement retains the core piece on the closure. The resilient members may be arranged diametrically opposite each other across the central aperture. For example, a pair or a ring of resilient members may be provided that extend through the central aperture around the edge of the central aperture. The resilient members may be prongs provided with enlarged distal ends having a tapering side and backward-facing shoulder. The tapering sides are arranged to ease deflection of the prongs as they are pushed through the central aperture until the enlarged distal ends clear the central aperture, at which time the prongs snap back such that the backward-facing shoulders engage with the underside of the stub around the central aperture.
The bottle may further comprise a disassembly tool that bends the resilient members so that they may pass back through the central aperture of the stub. For example, the tool may attach to the stub in the same way as the inner container. Where the core piece comprises the prongs described above, the tool may contain a sloping surface or sloping surfaces that act(s) on the tapering sides of the prongs to force the prongs to deflect until the shoulders are clear of the central aperture. The core piece may then be removed from the bottle for cleaning.
Optionally, the core piece is provided with a first hole and a second hole, and the stub is provided with a first hole and a second hole. The switch may be rotatable between a first position and a second position. In the first position, the first holes are aligned such that the outlet is in fluid communication with the outer container. In the second position, the outlet in which the second holes are aligned such that the outlet is in fluid communication with the inner container. The first holes may be provided in a side wall of the stub and a side wall of the core piece. The second holes may be provided in a base wall of the stub and a base wall of the core piece.
The switch mechanism may further comprise a cup member located in the recess between the stub and the core piece. The cup member may have a side wall provided with a first hole aligned with the first hole of the core piece and a base wall provided with a second hole aligned with the second hole of the core piece. The core piece and cup member may have indexing means to ensure the cup member rotates with the core piece thereby keeping the first and second holes of the cup member and the core piece in alignment. The indexing means may comprise complementary splines provided in the core piece and the cup member.
Optionally, the switch is located within a notch provided in the closure. The notch may comprise end walls defining the limits of movement of the switch such that the limits of movement correspond to the first and second positions of the switch. This provides ease of operation: in use, the switch need only be moved to a limit of movement to set the bottle to provide the liquid beverage or the gel. Further tactile feedback may be provided to confirm that the switch has been set to a correct position. For example, the switch may be provided with an indentation and the closure may be provided with a protrusion such that the protrusion is received within the indentation when the switch is in the first and/or second position. The locations of the indentation and protrusion may be reversed such that the protrusion is provided on the switch and the indentation is provided on the closure.
From a second aspect, the present invention also resides in an alternative version of the bottle according to the first aspect of the invention. Specifically, the alternative sports bottle need not include the air inlet and the one-way valve configured to allow air to flow into the outer container. According to the second aspect, the bottle is provided with a switch mechanism that is adapted for easy disassembly.
The switch mechanism may comprise a core piece, and the switch may be part of the core piece that is fixed to a central part of the closure to allow the switch to rotate about a central longitudinal axis of the bottle. The outlet may comprise a mouthpiece removably mounted to the core piece. The mouthpiece may comprise a pair of opposed shoulders that engage with apertures provided in the corepiece. The shoulders may be forced inwardly to release the mouthpiece and allow it to be removed from the core piece. The mouthpiece may be slidably mounted to a post of the core piece. The mouthpiece may slide between a closed position where the post fills an exit aperture of the mouthpiece and an open position where the exit aperture is displaced from the post. In the closed position, neither the liquid beverage nor the gel may flow from the outlet. In the open position, either the liquid beverage or the gel may flow from the outlet.
The core piece may be received within a recess formed in the top of the closure by a downwardly extending stub. The core piece may comprise a collar that extends over the recess and resilient members that extend through a central aperture in the base wall of the stub such that the closure is sandwiched between the collar and resilient members. This arrangement retains the switch mechanism comprising the core piece and mouthpiece on the closure. Moreover, the resilient members may be pushed inwardly so that they may pass back through the central aperture in the base wall of the stub such that the switch mechanism comprising core piece and mouthpiece may be removed from the closure.
The resilient members may be arranged diametrically opposite each other across the central aperture. For example, a pair or a ring of resilient members may be provided that extend through the central aperture around the edge of the central aperture. The resilient members may be prongs provided with enlarged distal ends having a tapering side and backward-facing shoulder. The tapering sides are arranged to ease deflection of the prongs as they are pushed through the central aperture until the enlarged distal ends clear the central aperture, at which time the prongs snap back such that the backward-facing shoulders engage with the underside of the stub around the central aperture.
The inner container may be supported by the stub of the closure. For example, the stub may comprise at least a portion of the fixing that is configured to allow the inner container to be suspended from the closure. The stub may comprise a screw thread and the inner container may comprise a complementary screw thread. Hence, the inner container may be screwed onto the stub to secure the inner container in place. Use of screw threads allows easy disassembly to allow the inner container to be removed for cleaning and refilling. The screw thread on the inner container may be formed around an aperture provided in a top part of the inner container, for example the flexible pouch may include a relatively rigid top part to allow it to be connected to the rest of the bottle. The bottle may further comprise a disassembly tool that bends the resilient members inwardly so that they may pass back through the central aperture of the stub. Conventiently, the tool may attach to the stub in the same way as the inner container. Where the core piece comprises the prongs described above, the tool may contain a sloping surface or sloping surfaces that act(s) on the tapering sides of the prongs. As the tool is screwed onto the stub, the sloping surface(s) acts as ramp that deflects the prongs inwardly until the shoulders are clear of the central aperture. The switch mechanism comprising the core piece and mouthpiece may then be removed from the bottle for cleaning.
The switch mechanism may further comprise a cup member located in the recess between the stub and the core piece. The cup member may also be held in place when the switch mechanism is attached to the closure as it too is sandwiched in place between the collar of the core piece and the base of the recess. If the core piece and mouthpiece are removed from the closure, the cup member may be simply lifted from the recess for cleaning. The cup member may have seals extending around it sides that seal against the sides of the recess in the closure.
The bottle according to the second aspect of the invention may further comprise any of the optional features described with respect to the bottle according to the first aspect of the invention.
The present invention also extends to any of the bottles above when containing a liquid beverage in the outer container and a gel in the inner container. The liquid beverage may be water (including water with additives such as flavouring, stimulants or hydration supplements). The gel may be an energy gel.
Further optional features will become evident to the person skilled in the art upon reading the following detailed description of the invention.
In order that the invention can be more readily understood, reference will now be made by way of example only, to the accompanying drawings in which:
A sports bottle 20 according to an embodiment of the present invention is shown in the accompanying figures.
The body 22 of the bottle 10 forms an outer container 31 that holds a liquid beverage such as water 32, as well as containing the pouch 28. The water 32 may be flavoured, for example using a squash or cordial. The water 32 may contain a supplement, for example a hydration supplement that may provide electrolytes, and also a stimulant like caffeine and/or flavour. For the sake of brevity, the outer container 31 is assumed to hold water 32 in the following.
The pouch 28 provides an inner container 33 in which a gel 34 such as an energy gel or similar may be stored. For the sake of brevity, the inner container 33 is assumed to hold an energy gel 34 in the following.
A user may consume either the water 32 or the energy gel 34 through the mouthpiece 26, and the tab 30 functions as a switch that allows the user to switch between delivery of the water 32 and the energy gel 34.
The threaded aperture 38 cooperates with threads 42 provided on a stub 40 projecting from the underside of the lid 24, as shown in
The lid 24 has a multipart construction, and includes a cap 56 with a threaded rim 64 that allows the cap 56 to be screwed into place on the body 22 of the bottle 20, via a cooperating thread 66 provided around the top of the body 20. The cap 56 also comprises the stub 40 to which the pouch 28 attaches. The stub 40 extends downwardly from the cap 56 and has a hollow interior which forms a recess 68 in the top of the cap 56. The recess 68 receives a switch assembly 41 that provides delivery of the water 32 and gel 34. The switch assembly 41 comprises the mouthpiece 26, a core piece 46, and a valve piece 54. The lid 24 also includes an air inlet 62 provided with an umbrella valve 58, as can best be seen in the exploded views of
The cup-shaped valve piece 54 is seated in the recess 68, the core piece 46 extends through the valve piece 54, and the mouthpiece 26 pushes down onto the core piece 46 from above. The core piece 46 fixes the switch assembly 41 to the lid 24, as will now be explained.
The core piece 46 comprises a barrel-shaped body 52 that is open-topped and provided with a base, a post 48 extends upwardly from the base of the barrel 52, a collar 50 that extends from the body 52 over and around the top of the recess 68, and a pair of opposed resilient prongs 70 that extend downwardly from base of the core piece 46. The mouthpiece 26 is seated on the post 48. The core piece 46 is fixed to the cap 56 by sandwiching the stub 40 between the collar 50 and the ends of the prongs 70. The core piece 46 is pushed into the recess 68 so that the prongs 70 extend through aligned central apertures 51a,b provided in the bases of the valve piece 54 and recess 68. Each prong 70 has an enlarged distal end with a tapering side 71 and a backward-facing shoulder 72. The tapering sides 71 push against the edges of the central apertures 51a,b as the core piece 46 is pushed into the recess 68 which causes the prongs 70 to deflect inwardly. Then, the prongs 70 snap back as the shoulders 72 clear the bottom of the stub 40. The shoulders 72 then abut against the bottom of the stub 40. In this position, the collar 50 is level with the top of the cap 56, thereby attaching the core piece 46 to the cap 56 and preventing the core piece 46 from being pulled back out of the recess 68. However, the core piece 46 may be rotated about its vertical axis, and the tab 30 is provided to allow a user to cause such rotation.
The valve piece 54 is also held in the recess 68, between the bottom of the recess 68 and the collar 50 of the cap 56, and the valve piece 54 may also rotate about a vertical axis. Rotation of the valve piece 54 is driven by rotation of the core piece 46 with the tab 30 via upwardly extending splines 74a,b provided on the inside of the valve piece 54 and the outside of the barrel 52 of the core piece 46.
Rotation of the valve piece 54 opens and shuts a pair of passages 76 from the outer container 31 to the mouthpiece 26. The passages 76 are formed by two sets of three aligned water holes 76a,b,c provided in the stub 40 of the cap 56, the valve piece 54 and the barrel 52 of the core piece 46. The water holes 76a,b of the barrel 52 and the valve piece 54 rotate together and are always aligned in their pairs by virtue of the splines 74a,b. The water hole 76c of the stub 40 does not rotate. The tab 30 is used to rotate the water holes 76a,b of the valve piece 54 and the barrel 52 into and out of alignment with the water hole 76c of the stub 40. When all the waterholes 76a,b,c are aligned, water 32 may flow from the outer container 31 into the centre of the core piece 46 and then to the mouthpiece 26.
The core piece 46 is provided with the post 48 that is upstanding from the base of the barrel 52, thereby creating an annular space between the post 48 and the outer wall of the barrel 52. The mouthpiece 26 is of a conventional design and is generally mushroom-shaped with an enlarged head 25 and a hollow stem 27. A channel 44 extends through the mouthpiece 26 from top to bottom. The mouthpiece 26 pushes onto the post 48 of the core piece 46 such that the post 48 is received within the channel 44. The bottom of the stem 27 is provided with a pair of opposed shoulders 78 that locate within the water hole 76a provided in the barrel 52 of the core piece 46 and a second, matching hole 79 provided in the barrel 52. The mouthpiece 26 may slide up and down on the post 48 as guided by the outer wall of the barrel 52. The shoulders 78 fouling on an upper edge of the holes 76a and 79 prevents the mouthpiece 26 from being pulled off the core piece 46 (see
The mouthpiece 26 is slid up and down the post 48 to open up and shut off flow of water 32 or gel 34.
To switch to delivery of the gel 34 from the pouch 28, the user rotates the tab 30. This rotates the core piece 46 and the valve piece 54 that are joined by the splines 74a,b. This sees the water holes 76a,b of the core piece 46 and the valve piece 54 move out of alignment from the water holes 76c of the stub 40 of the cap 56. Thus, water 32 can no longer flow from the outer container 31 to the exit orifice 45 at the mouthpiece 26.
In addition to moving the water holes 76a,b,c out of alignment, rotation of the tab 30 brings two sets of three gel holes 84a,b,c into alignment, as shown in
When not in use, the mouthpiece 26 will be kept in the closed position shown in
With the tab 30 set to the water delivery position of
Air is admitted into the outer container 31 through the air inlet 62 via the umbrella valve 58. As the user sucks on the mouthpiece 26, a volume of water 32 flows from the outer container 31 creating a pressure drop in the outer container 31. The pressure drop causes the umbrella valve 58 to open and air rushes into the outer container 31 to replace the volume of water 32 lost from the outer container 31. This maintains the shape of the bottle 20. Alternatively, if the user squeezes the bottle 20 to force water 32 out of the mouthpiece 26, the bottle 20 will return to its undeformed shape when the user releases his or her grip on the bottle 26. Once the grip on the bottle 20 is released, air may rush back into the outer container 31 through the air inlet 62. When not in use, the outer container 31 is at ambient pressure such that the umbrella valve 58 seals around the air inlet 62. This prevents water 32 leaking from the air inlet 62.
When the user wants to consume gel 34, the user sets the tab 30 to the gel delivery position shown in
To ensure quick delivery of gel 34 to the user, the pouch 28 should be empty of air. Otherwise, the initial squeezing effort merely forces air out of the pouch 28. This is achieved by the air inlet 62 and the umbrella valve 58. When the user stops squeezing the bottle 20 to force gel 34 from the mouthpiece 26, the bottle 20 returns to its undeformed shape due to the resilient body 22. This causes a pressure drop in the outer container 31 which activates the umbrella valve 58 to allow air to rush back into the outer container 31 through the air inlet 62 to equalize the pressure in the outer container 31 with ambient pressure. Consequently, a constant pressure is maintained in the outer container 31 that is exerted on the pouch 28 thereby preventing the pouch 28 from filling with air.
Pouches 28 of different sizes may be provided. The pouch shown in
When the pouch 28 is partially filled, it is better for the user to remove air from the pouch 28. This may be done by squeezing the pouch 28 as it is reattached to the lid 24, and by sucking out any remaining air through the mouthpiece 26 before the lid 24 is screwed back onto the body 22.
The body 24 may be provided with marks to indicate how much water 32 should be added to the body 22 depending on the amount of gel 34 in the pouch 28. This assists in not overfilling water 32 such that water 32 is displaced from the bottle 20 when the lid 24 is placed back onto the body 22 and the pouch 28 enters the water 32.
The tool 94 is also provided with a sloping ring 100 that faces upwardly as the tool 94 is screwed onto the stub 40. As the tool 94 moves closer to the core piece 46, the ring 100 contacts the tapering sides 71 of the prongs 70 of the core piece 46. The sloping surface of the ring 100 deflects the prongs 70 inwardly such that the shoulders 72 of the prongs 70 disengage from the underside of the central aperture 51a provided in the bottom of the stub 40. This allows the core piece 46 and mouthpiece 26 to be lifted from the bottle 20 by grasping the mouthpiece 26. The mouthpiece 26 and core piece 46 lift off the cap 56 together as the prongs pass through the apertures in the cap 56 and valve piece 54. The mouthpiece 26 may be freed from the core piece 46 by the user pressing the shoulders 78 at the base of the stem 27 of the mouthpiece 26 inwardly through the holes 76a and 79 provided in the core piece 46. Once the shoulders 78 are clear of the holes 76a and 79, the mouthpiece 26 may be slid off the post 44 of the core piece 46. The valve piece 54 may be lifted out of the recess 68 in the cap 56.
The disassembled parts of the lid 24 may be cleaned thoroughly. To reassemble the lid 24, the tool 94 is removed from the cap 56, the valve piece 54 is returned to the recess 68 in the cap 56, the mouthpiece 26 is slid back down the post 44 of the core piece 46, and the mouthpiece 26 and core piece 46 are pushed back into the valve piece 54 with the splines 74a,b aligned and such that the prongs 70 pass through the central apertures 51a,b in the cap 56 and valve piece 54, and snap open to hold the core piece 46 in place. The splines 74a,b have a non-symmetric arrangement such that the core piece 46 fits into the valve piece 54 in a unique orientation that aligns the water holes 76a,b
A person skilled in the art will appreciate that the above embodiments may be varied in many different respects without departing from the scope of the present invention that is defined by the appended claims.
For example, the body 22 may have one of a number of different sizes to accommodate different amounts of water 32 or other liquid beverage. For example, the body 22 may form an outer container 31 that holds 500 ml, 600 ml, 750 ml of 1 l of water. Also, the pouch 28 may be of different sizes to accommodate different amounts of gel 34. The bottle 20 may be supplied with pouches of different sizes, but having a common size of threaded aperture 38 to allow them all to be attached to the stub 40.
The bottle 20 need not be used with water 32 and/or gel 34. Any liquid beverage may be used in the outer container 31, and any gel 34, liquid or flowable substance may be used in the inner container 33.
Although the figures show a bottle 20 with a single air inlet 62, further air inlets 62 connecting the outer container 31 to the ambient atmosphere may be provided. Advantageously, the air inlet(s) 62 is (are) provided at the top of the bottle 20, for example in the lid 24, but could be provided in the body 22 of the bottle 20. An umbrella valve 58 is but one example of a one-way valve that regulates air admittance into the outer chamber 31. Other forms of one-way valve may be used in the place of the umbrella valve 58. Where multiple air inlets 62 are provided, each air inlet 62 should be provided with a one-way valve such as an umbrella valve 58.
Number | Date | Country | Kind |
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2017711.9 | Nov 2020 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2021/081202 | 11/10/2021 | WO |