Dispensing Lid

This application claims the benefit under 35 U.S.C. § 120 and is a continuation-in-part of U.S. patent application Ser. No. 18/736,369, filed on Jun. 6, 2024 and entitled “Dispensing Lid”, which claims the benefit and is a continuation of U.S. patent application Ser. No. 18/735,089, filed on Jun. 5, 2024 and entitled “Dispensing Lid”, each of which is incorporated herein by reference.

Various personal, dispensing containers and related covers or lids have been fabricated and sold over many decades. In the present day, such devices designed to contain liquids are often referred to generically as “water bottles,” though they frequently contain liquids other than water, or simply “bottles.” For many years, these personal, liquid-dispensing containers and their associated covers or lids, or water bottles, have been designed to meet the particular needs of users during their various events and activities.

For example, many prior art dispensing containers include a complex arrangement of separate components individually assembled and serving separate functions. The separate components might include a spout to dispense liquid, a vent to exchange air, a cap or other mechanism to close the spout, and a fastener to retain the cap or other mechanism. Some dispensing containers may use multiple parts to provide the spout, to provide the vent, to provide the closing mechanism, or to provide the fastener, making the arrangement even more complex. Accordingly, dispensing containers with fewer components would be beneficial.

One dispensing container described in U.S. Pat. No. 8,550,269 includes a bottom-mounted drink spout closed by an outer cap, which is retained by a release button. The outer cap fastening mechanism alone includes at least four separate components: a release button that fits within a tunnel in an inner cap and is biased with a spring and held in place by pin.

Accordingly, designs that increase the simplicity of function and assembly would be beneficial.

The example implementations described herein refer to the accompanying drawings. The same reference numerals in the various drawings may identify the same or similar features.

In some instances, multitude components provide multitude features that may be attractive to dispensing container users. However, multitude components may also increase manufacturing complexity and yield difficulty in user cleaning and parts replacement. More components may also create more points of potential mechanical failure.

Some examples described herein provide an integration unit that combines and integrates multiple mechanical elements and functions into a unified and cohesive whole. The integration units herein may simplify complex systems, improve efficiency, enhance overall functionality, or accomplish more than one of these benefits. The integration units may incorporate two or more elements selected from among a fastener button, a fastener spring, a spout, a vent, and a cap spring into a single module made of a uniform material.

Therefore, some implementations described herein simplify by consolidating multiple components into a single integration unit. The overall design becomes simpler, reducing the number of parts and connections required. Some implementations increase space efficiency with an integration unit by optimizing the use of space within a dispensing container, allowing for more compact and streamlined designs. Some implementations improve performance with an integration unit by integrating mechanical elements within a single unit that can reduce friction and enhance overall mechanical efficiency and performance. Some implementations increase ease of assembly with an integration unit by simplifying the assembly process, making it easier and faster to build the dispensing container. Some implementations enhance reliability with an integration unit by using fewer components and connections, often resulting in higher reliability and reduced chances of mechanical failure. Some implementations reduce cost with an integration unit by integrating multiple functions into a single unit potentially yielding savings in manufacturing, materials, and/or assembly.

In some instances, known spouts (e.g., U.S. Pat. No. 8,550,269) do not provide a secure sealing surface between the spout and a body of a dispensing lid or require a large flange to adequately seal. Some examples described herein provide an integration unit including a spout and a gasket with a concave profile. A body of a dispensing lid has a gasket seat complementary to the concave profile of the gasket and circumscribing a body conduit in which the integration unit is inserted. Therefore, some implementations described herein include a gasket in tension when the integration unit is engaged with the body, thus pulling upper and lower surfaces of the concave profile of the gasket into contact with the gasket seat. As described herein, the concave profile then increases the sealing ability of the integrated unit.

In some instances, dispensing containers include a bottom-mounted drink spout (e.g., U.S. Pat. No. 8,550,269) that engages with the body of the dispensing lid by insertion through the body conduit that passes through the body. Insertion occurs from the bottom of the dispensing lid while removed from its associated container. Unfortunately, pressure applied to the drink spout from the top of the dispensing lid could push the drink spout back through the body conduit, disengaging it from the body. Since the user frequently contacts the dispensing lid when drinking, when closing the lid, or during other activities, some risk of unintentional disengagement exists. Also, the dispensing lid must be removed from the container in order to obtain the drink spout after or before intentional disengagement for cleaning.

Some examples described herein provide a top-mounted drink spout. In two of the examples, a tube projects outward from a bottom of a well recessed into an outside surface of the body. The integration unit includes a spout and a socket. The tube seats inside the integration unit socket when engaged with the body into the well. In other examples, the top-mounted drink spout is inserted through the body conduit that passes through the body, but insertion may only occur from the top of the dispensing lid. Therefore, some implementations described herein reduce the risk of a drink spout unintentionally disengaging from the body by top-mounting the drink spout. Also, the drink spout may be intentionally disengaged for cleaning without removing the dispensing lid from the container.

In some instances, dispensing containers provide a carrying handle attached to or integral with the lid. The handle may be fixed or may be in rotatable engagement with the lid. In either circumstance, the handle is readily apparent and an obtrusive feature of the dispensing container profile. Short of removing a rotatable handle, no option exists for stowing the handle in a concealed location. The handle may add bulk to the dispensing container profile or otherwise form a loop that may catch or snag on objects.

Some examples described herein provide a selectively extendable and retractable carrying mechanism. Therefore, for some implementations described herein, the handle may be stowed in the lid when not in use, providing a sleeker profile without an obtrusive loop.

In some instances, dispensing containers with a handle also include a cap that rotates into an open position to access the dispensing spout. Some dispensing containers are inverted to pour out the contents. Unfortunately, a user drinking from the spout may find that the cap rotates toward a closed position into contact with the user's face.

Some examples described herein provide a cap that engages the handle when extended, which restricts rotation of the cap when inverting the lid. Therefore, some implementations described herein retain the cap when pouring out contents.

As indicated above, the FIGURES are provided merely as examples of the described solutions. Other examples are possible and may differ from what is described with regard to the FIGURES, but nonetheless provide the solutions to the problems described above that yield the enumerated technical benefits.

are respective side, top, and sectional views of an integration unit. Integration unitis included as part of a dispensing lidshown in. Dispensing lidis designed for use with a container (not shown) that may contain liquids. Dispensing lidmay be selectively engageable with and disengageable from the container, such as by a threaded connection or other known type of connection. Alternatively, dispensing lidmay be permanently affixed to the container. As will be appreciated from the discussion herein, dispensing lidincreases the simplicity of function and assembly. Also, dispensing lidprovides a gasket in tension that increases the sealing ability. Further, dispensing lidincludes a handle that may be stowed in the lid and retains the cap when pouring out contents.

Lidincludes a body, a capin rotatable engagement with body, and integration unitselectively engageable with and disengageable from body. Integration unitis formed of a continuous material in common amongst integration unitcomponents, which include a spoutand a fastener. Spouthas a spout conduitpassing through the continuous material in common and allowing dispensing through lidvia spout conduit.

Fasteneris formed of the continuous material in common and has a fastener button, a fastener lever, and a fastener spring. Fastener leverconnects fastener buttonto integration unitand the fastener spring applies a force to fastener leverwhen pressing fastener button.

In the example shown for integration unit, the continuous material is resilient and the resilience of the continuous material that forms fastener leverprovides the fastener spring integrally. Accordingly, the fastener spring is not labeled with a reference numeral separately from fastener lever. In other examples, the fastener spring conceivably could be provided separately, but a benefit exists with providing the fastener spring integrally, as described above in the discussion of benefits associated with integration units.

For lid, capcloses spoutwhen retained in a closed position by fastener, as shown in. Also, capopens spoutwhen pressing fastener buttonovercomes the applied force of the fastener spring and moves fastener lever, releasing capfrom the closed position, such as shown in.

Integration unitfurther includes a ventseparate from spoutand including a vent ductpassing through the continuous material in common and allowing air exchange through lidvia vent duct. Capcloses spoutand ventwhen retained in the closed position by fastener. Also, capopens spoutand ventwhen pressing fastener buttonovercomes the applied force of the fastener spring and moves fastener lever, releasing capfrom the closed position.

Notably, respective portions of the continuous material that form spoutand fastenerlack material interfaces within the continuous material between spout, fastener, fastener button, fastener lever, and the fastener spring. As the term is used herein, in addition to the description given above, an integration unit is considered to be unitary, that is, not divided nor discontinuous. By way of example, integration unitmay be manufactured in a single molding process containing all of the continuous material in common sufficient to form the components included therewith. Other manufacturing processes are conceivable, such as subtractive manufacturing to remove portions from a block of the continuous material, etc. Silicone may be a suitable continuous material for many implementations with a hardness, such as a Shore A durometer value, sufficient to yield the physical and mechanical properties described herein. For example, the Shore A value may be from 40 to 60, but other values are conceivable.

In other implementations, integration unitformed of a continuous material in common could conceivably have material interfaces between components. For example, if components are formed of the continuous material, though at different times, then material interfaces could exist. Also, in additive manufacturing, such as 3-D printing and other methods, some techniques may leave macroscopic interfaces between successively formed layers of a continuous material in common unless measures are taken to reduce or eliminate such interfaces. Likewise, if components containing the continuous material are welded together in some manner without adding different material, then material interfaces would likely exist. Components joined using a different interface material, such as adhesive, would not include a “continuous” material in common among components.

Integration unitmay be associated with an additional component (not shown) that is not formed of the continuous material in common amongst integration unit components. The additional component could impart additional mechanical properties to the integration unit. For example, integration unitcould be co-molded with an internal feature that stiffens the flexion of fastener buttonat fastener tabinstead of using a stiffer continuous material. Despite the presence of the internal feature, integration unitmay nonetheless be formed of a continuous material in common amongst spout, fastener, fastener button, fastener lever, and the fastener spring.

In lid, the resilience of the continuous material that forms ventprovides a cap spring integrally. Accordingly, the cap spring is not labeled with a reference numeral separately from vent. In other examples, the cap spring conceivably could be provided separately, but a benefit exists with providing the cap spring integrally, as described above in the discussion of benefits associated with integration units. The cap spring applies a force to capwhen capis retained in the closed position of. The cap spring rotates capwhen capis released from the closed position, opening spoutand vent.

To facilitate the ease of opening and closing cap, fastenerincludes a taband capincludes a slot. Fastener tabengages cap slotwhen capis in the closed position. Fastener tabretains capin the closed position by the force of the fastener spring applied to fastener lever.

Lidprovides a hinge mechanism that is not completely described herein. A few of its various components appear in the FIGURES, but are not individually numbered and are instead noted generically as hinge mechanism components. The hinge mechanism may use a known configuration and provides for the opening and closing of cap.

Similarly, lidprovides a lock mechanism that is not completely described herein. A few of its various components appear in the FIGURES, but are not individually numbered and are instead noted generically as lock mechanism components. The lock mechanism may use a known configuration and provides for retaining capin the closed position in a manner that reduces the likelihood of opening capby unintentionally pressing fastener button.

Integration unitfurther includes a spout rimand a vent rim. Spout rimcircumscribes a top inletinto spout conduitand is formed of the continuous material in common. Vent rimcircumscribes a top inletinto vent ductand is also formed of the continuous material in common. Spout rimand/or vent rimcould conceivably be formed of a material different from the continuous material.

Additionally, capincludes an interior seal surfacethat contacts spout rimand vent rimwhen capapproaches the closed position. Interior seal surfacecloses spoutand ventwhen capis retained in the closed position by fastener. Interior seal surfacemay simply press on spout rimand vent rimto accomplish sealing. Alternatively, when ventis taller, interior seal surfacemay bend ventover such that vent rimcompresses and folds, with opposing sides of vent rimtouching and accomplishing the seal.

Bodyincludes a body conduitpassing through body, as shown in. Spout conduitaligns with body conduitwhen integration unitis engaged with body, allowing dispensing through lidvia both body conduitand spout conduit. Also, vent ductaligns with body conduitwhen integration unitis engaged with body, allowing air exchange through lidvia both body conduitand vent duct.

With vent ductand spout conduitsharing body conduit, the continuous material of integration unitforms an outside surface of the lidand an opposing inside surface of the lid. Lid inside surfacefaces inside the container when lidis attached to the container. Lid inside surfaceis other than a surface of vent ductand other than a surface of spout conduit.

Vent ductis placed through lid inside surface. Such placement permits entry of air into the container through integration unitwhen withdrawing contents from the container through a straw (not shown) engaged with spout conduit. As an alternative, contents of the container may be withdrawn through spout conduitby tilting the container to drink instead of reliance on a straw (seeand corresponding discussion herein).

Integration unitfurther includes a gasketwith a concave profile. Gasketis formed of the continuous material in common. Integration unitmay lack material interfaces within the continuous material between gasketand other components. Body conduithas a gasket seatcomplementary to concave profileof gasketand circumscribing body conduit. Gasketseals with gasket seatwhen integration unitis engaged with body, thus aligning spout conduitand vent ductwith body conduit. Although integration unitincludes gasketwith a concave profile, other sealing associations are conceivable between integration unitand body, such as known sealing associations.

Lidincludes an integration of spoutand fastener. The integration is shown incombined with gasketwith concave profileand combined with a selectively extendable and retractable carrying mechanism (discussed below). Even so, such integration is contemplated for use independently with other dispensing lids instead of that appearing in. More specifically, the integration of a spout and a fastener may be used in combination with other dispensing lids herein, as well as other dispensing lids not disclosed herein.

In the example of lid, integration unitextends through body conduitwhen engaged with body. As stated, the continuous material of integration unitforms lid inside surface. Consequently, lid inside surfacefaces inside the container as exposed through body conduitwhen lidis attached to the container.

Lidincludes the selectively extendable and retractable carrying mechanism. The carrying mechanism is shown incombined with the integration of spoutand fastenerand combined with gasketwith concave profile. Even so, such carrying mechanism is contemplated for use independently with other dispensing lids instead of that appearing in. More specifically, the selectively extendable and retractable carrying mechanism may be used in combination with other dispensing lids herein, as well as other dispensing lids not disclosed herein.

The carrying mechanism inincludes a handle, two arm tracks, and two post channels. Handleincludes two parallel arms, a bridgeconnecting two armsnear a first end of each arm, and two posts, each projecting from a respective one of two armsnear a second end of its respective arm. Arm tracksare formed into bodyand two armsslide through arm trackswhen extending and retracting handle. Post channelsare inside arm tracksand postsslide through post channelswhen extending and retracting handle.

show postsas laterally elongated columns with opposing flat sides and rounded ends. The width of postsat the flat sides is complementary to the width of post channels. Postsmay be formed in other shapes, such as a circular column, etc., though the shape shown inprovides unique benefits further described below.

While a variety of additional features are contemplated for the carrying mechanism, the example of dispensing lidherein is shown to include the following additional features. Other features or different combinations of the features than shown are contemplated for the carrying mechanism. Two postseach project from an outward facing surfaceof its respective arm. Two post channelsare each formed in an inward facing surfaceof a respective one of two arm tracks. Inward facing surfacesoppose outward facing surfaceswith handleretracted. As the term is used herein, “outward facing” refers to facing outward in a direction oriented from the center of bodytoward the perimeter of body. As the term is used herein, “inward facing” refers to facing inward in a direction oriented from the perimeter of bodytoward the center of body.

Handleis selectively rotatable about posts, such as shown in, upon fully extending handleso that postsreach two respective endsof post channels. Handleis not selective rotatable unless fully extended. This feature is enabled by the complementary size of post channelsand flat-sided posts. Since postsare elongated and sized complementary to post channels, they cannot rotate within post channelsuntil extended to reach channel ends. Channel endsare shaped and sized complementary to the rotational profile of posts. Accordingly, in dispensing lid, channel endsare circular, receiving the rotational profile of posts.

Additionally, postsnear the second end of their respective armare offset from the second end such that a tipof each armprojects past its respective post. Two tip recessesare formed in bodyproximate the respective ends of post channels. Upon fully extending and then rotating handle, tip recessesreceive arm tipsas handlerotates in the manner shown in. Arm tipsadditionally restrict handlefrom rotating except when fully extended. This feature is enabled by the distance that arm tipsproject that exceeds the distance between post channelsand a bottom of arm tracks.

With capin the closed position, as shown in, each of two opposing side wallsof capdefine part of a respective one of two arm tracksshown in. With handleretracted, as shown in, each of armsis between a respective one of two side wallsof capand a respective one of two post channels.

With capin a fully open position and handlefully extended, as shown in, a topof caprests between armsand engages bridgewhen inverting lid. Such engagement restricts rotation of cap. In such manner, a user may avoid caprotating toward the closed position into contact with the user's face when inverting the dispensing container to drink from the spout. Notably, pivot points for handleand capare not aligned. Also, cap tophas a radius of motion when caprotates that differs from a radius of motion for bridgewhen handlerotates. Accordingly, with the offset pivot points and different radii of motion, cap topengages bridgeand restricts rotation of cap.

The configuration shown also permits simple removal of handlefrom lid. With handleretracted and capin an open position, as shown in, cap side wallsare moved away from arm tracks. Handlemay be removed from bodyby flexing arm tipstoward each other and disengaging postsfrom post channels. With postsdisengaged from post channels, arm tipsmay be lifted from arm tracksand separated from body.

Lidincludes gasketwith concave profile. The gasket is shown incombined with the integration of spoutand fastenerand combined with the selectively extendable and retractable carrying mechanism. Even so, such gasket is contemplated for use independently with other dispensing lids instead of that appearing in. More specifically, a gasket with a concave profile may be used in combination with other dispensing lids herein, as well as other dispensing lids not disclosed herein.

In further discussion of gasket, concave profileincludes an upper sloped surface, a lower sloped surface, and a neckjoining upper sloped surfaceand lower sloped surface. Upperand lowersloped surfaces decrease in diameter toward neckand spout conduitpasses within neck. Bodyincludes body conduitpassing through bodyand body conduithas gasket seatcomplementary to concave profileof gasketand circumscribing body conduit. Gasketseals with gasket seatwhen integration unitis engaged with body, thus aligning spout conduitwith body conduit. A variety of structures are possible for gasket seat. In the example of dispensing lid, gasket seatis formed on an extension wallof body.

Spout conduitand vent ductare aligned with body conduit. Gasketseals with gasket seatcircumscribing body conduit. It follows that spout conduitand vent ductpass within neckof gasket.show that gasketlaterally surrounds at least a portion of spout conduitand vent duct. Integration unitincludes a bottom inletinto spout conduitand a bottom inletinto vent duct. Gasket, as defined by the portion of integration unitthat seals with body, laterally surrounds vent bottom inlet. Gasketdoes not laterally surround spout bottom inletsince it is positioned below gasket.