Typical beverage cups with an open top and open rim designed for standard gravity applications lose their functionality when employed in zero gravity or microgravity environments such as those found on spacecraft and space stations. A beverage placed inside such a cup will adhere to the base of the cup interior due to capillary forces. The adherence is maintained regardless of the orientation of the cup, making it impossible for a user to tilt the beverage towards the rim, and thus preventing the user from imbibing in the typical fashion. Further, any inertial forces applied to the cup that are greater than the capillary forces will cause the beverage to dissociate from the cup.
The current, widely accepted method for imbibing liquids in space utilizes completely sealed vesicles, such as a bag. Liquids may be withdrawn from the bag via a user sucking through a straw, or by squeezing the bag by hand, forcing liquid out of the bag and into the mouth of a user. By completely containing the liquids in a sealed vesicle, clean delivery is ensured. However, flavor is reduced, as aromatics are nearly completely eliminated. Further, the experience of sipping or drinking a beverage is lost, and the user may feel unsophisticated by being limited to sucking liquids from a bag. Especially for individuals who spend extended periods of time at a space station, even modest comforts of home may improve their mental health and well-being. For extended missions, it may also prove effective to rely on reusable cups rather than disposable bags.
U.S. Pat. No. 8,074,827 describes one approach for providing an open-topped beverage cup for use in low gravity environments. The beverage cup described therein uses a corner channel to exploit capillary forces and allow a beverage contained therein to be directed to the rim of the cup. However, the design has limitations, as recognized by the inventors herein. For example, the capillary pressure gradient dissipates as the liquid level decreases, thereby making it difficult to completely drain a beverage from the cup in a reasonable amount of time. This problem is aggravated by the fact that no capillary gradient is established along the interior corner to promote a more conducive drinking rate. As another example, the corner channel extends to the rim of the cup, forcing the user to drink from a tapered point, making the experience less like drinking at standard gravity. Further, the stability of the beverage within the cup is limited, reducing the amount of liquid that may be held therein while maintain capillary forces in excess of potential inertial forces.
A capillary beverage cup may be used to provide a liquid for drinking in a low-gravity environment. The capillary beverage cup may comprise an open top, allowing for aromatics to be experienced by a user while drinking. The capillary beverage cup may provide a continuous capillary force on the liquid contained by the cup, utilizing a continuous interior corner extending from a lip interface into an inner cavity of the capillary beverage cup that is activated as fluid is removed from the lip interface. The continuous interior corner may comprise an acute included angle which tapers continuously as the interior corner approaches the lip interface, allowing the cup to provide continuous increased capillary under-pressure (e.g. suction) on liquids with a contact angle less than 70°. The lip interface may comprise a cusp-shaped channel that is continuous with the continuous interior corner and extends to an edge of the lip interface. In this way, a rivulet of liquid may be presented at the lip interface for imbibing, the upper lip providing a capillary connection with the liquid in the cusp and thus the entire liquid contents within the cup. A user may withdraw the liquid by applying a sucking force, or with small quantities of liquid wicked into the mouth without applying a sucking force, but by merely coupling the user's lip to the lip interface of the cup. The capillary beverage cup may include a rounded, low-curvature region assuring that the vessel is completely drained by the continuous interior corner, though the interior corner may not extend into the rounded, low curvature region.
It should be understood that the summary above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined uniquely by the claims that follow the detailed description. Furthermore, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure.
Note: Figures are drawn approximately to scale, but other dimensions may be used.
This detailed description relates to cups for drinking beverages in low-gravity environments, for example lower than standard gravity on earth. In one example, this description relates to cups that leverage capillary action to passively pump fluid from the interior of the cup to a lip interface, where the beverage may be imbibed by a user. Such cups may be expected to function effectively provided the impacts of surface tension and cup geometry are significantly greater than the impact of gravity, allowing for use in standard gravity (e.g. on Earth), sub-standard gravity (e.g. on the Moon, on Mars, on asteroids and/or other fractional bodies), or low to near zero gravity (e.g. free flying in outer space).
Capillary beverage cup 100 may be constructed from any suitable material provided the material establishes the necessary wetting characteristics between the liquid and the cup. For example, capillary beverage cup 100 may be constructed from rigid and/or flexible materials, such as metal, etc. Capillary beverage cup 100 may comprise a single, molded piece of material, or may comprise a plurality of pieces of material connected into a single structure. In the description herein, reference will be made to numerous faces and portions of the cup. It should be understood that a single piece of material may form two or more faces or portions, and/or that adjacent faces or portions may be seamlessly connected. As described herein, capillary beverage cup 100 may be constructed out of relatively thin material, allowing for the outer geometry of the cup to have similar shapes, curves, and angles as the inner geometry. However, the described inner geometries may be placed within any suitable outer casing that gives the cup improved aesthetics or ergonomics without compromising the liquid holding properties of the cup interior. For capillary beverage cup 100, the advancing contact angle for the interior corner(s) must be less than the critical geometric wetting angle (i.e., Concus-Finn angle). Such a favorable wetting condition may be achieved by selection of material, material surface finish, cup fill method, or by applying a hydrophilic coating to at least the interior surfaces of the cup.
Capillary beverage cup 100 comprises an upper right face 101 and an upper left face 102. Upper right face 101 and upper left face 102 are convex surfaces, intersecting at both the front and rear of the cup. At the rear of the cup, the upper left and right faces form an upper portion of rear face 103. Upper right face 101 and upper left face 102 intersect at the front of the cup at tapered front face 104. An upper portion 100a of capillary beverage cup 100 is formed by faces 101, 102, 103, and an upper portion of tapered front face 104. As shown in
A lower portion 100b of capillary beverage cup 100 comprises rear bottom faces 105a and 105b as well as front bottom faces 105c and 105d. Rear bottom faces 105a and 105b form a rounded, low-curvature region comprising generally spherical geometry, intersecting at a lower portion of rear face 103, as well as at the underside of cup 100, as shown in
Tapered front face 104 extends from base 106, connecting front bottom faces 105c and 105d as well as upper right face 101 and upper left face 102. As will be described further herein and with regards to
The upper portion of interior corner 120 formed by upper right face 101, upper left face 102, and tapered front face 104 directs liquid to lip interface 109. Interior corner 120 extends into an inner cavity of cup 100. Lip interface 109 forms a cusp-shaped channel 109a (referred to herein as cusp 109a for simplicity) that is continuous with interior corner 120. Liquid flow will stop at cusp 109a when the liquid meets a free surface that defines a capillary force equilibrium. Cusp 109a thus allows for liquid to be delivered from cup 100 to the lips of a user by providing a natural capillary connection between the cup and the user's lips during drinking. By gently applying a light sucking pressure, the user may withdraw liquid from the cup into the user's mouth. The measure of fluid at cusp 109a creates a capillary pressure gradient that acts throughout the cup to passively pump all of the remaining liquid in the cup to the mouth. In this example, lip interface 109 comprises right lip interface 109b and left lip interface 109c. Right lip interface 109b and left lip interface 109c form an ergonomic interface for a user's lips. Right lip interface 109b and left lip interface 109c each have a rounded, concave shape, roughly coinciding to the profile of the top lip of a prospective user. In this way, lip interface 109 naturally positions the user's upper lip above cusp 109a, allowing for any sucking pressure to be directed directly to cusp 109a and thus directly applied to liquid located at the cusp. However, right lip interface 109b and left lip interface 109c are not required for the function of cup 100. Other lip interface designs may be used, such as those shown in
In this example, base 106 has a circular shape with a flat surface that has a significantly smaller area than does the lower portion 100b, though other dimensions and shapes may be used. Base 106 may be configured to tether capillary beverage cup 100 to a surface in low gravity. For example, base 106 may be formed of a magnetic material or VELCRO® material that would allow capillary beverage cup 100 to be affixed to a surface. In some examples, base 106 may comprise a male part of a male-female docking station.
Although not shown, capillary beverage cup 100 may include a fill port or other interface to allow liquid to be delivered to the interior of the cup without undue spillage. For example, a duck-bill valve may be used as a fill port. A fill port may be located within base 106 or elsewhere tangential to the outer surface of cup 100, provided the fill port does not disrupt the interior walls that form interior corner 120. Further, the fill port must be configured to deliver liquid to interior corner 120, in order to establish the capillary gradient. Any suitable device may be used to deliver liquid to cup 100, either through a dedicated fill port, or through open top 108, provided the liquid is provided to interior corner 120. The corner wetting phenomena provides a passive means of fluid pumping, effectively trading the forces of surface tensions with those of gravity in the drinking process. Once liquid is delivered into the cup, fluid preferentially distributes within the interior of the cup based on the interior dimensions. In a scenario where the fluid is not delivered in a manner that engages the primary interior corner, the cup may be lightly sloshed by hand as a means of connecting the bulk fluid with interior corner 120.
Additional perspective views of the example capillary beverage cup depicted in
Section H-H, as shown in
Section F-F, as shown in
For a time-efficient uptake of liquid, the wetting conditions of the liquid and solid interior surface should satisfy the practical geometric interior corner wetting condition, where θadv<(π/2−α); a modification of the Concus-Finn condition [1969] θeq<(π/2−α), where θadv and θeq are the respective advancing and equilibrium contact angles and a is the half-angle of the interior corner with all angles measure in radians. The vessel will function if θeq replaces θadv, but the time required for such function is so large as to be impractical. For relatively rapid capillary delivery of liquid, it is desirable to establish θadv that is sufficiently smaller than λ/2−α. For a fixed θadv, this is accomplished in capillary beverage cup 100 by methodically decreasing a towards the lip, eventually forming a cusp where satisfaction of θadv<π/2−α is certain for most aqueous liquids.
The tapering interior corner also narrows the open portion of cup 100. This enhances the stability of liquid within cup 100 per unit volume, allowing for greater volumes to be stored within the cup, allowing for larger lateral and upward disturbances to the cup with a reduced concern of spilling. The stability is further promoted by the spherical geometry of the lower, rear portion of the cup. In this example, the ratio of the height of the lower, spherical portion of the cup 100b to the upper, tapered portion of the cup 100a is approximately 1:1. This ratio provides stability to liquid stored in the cup despite small inertial perturbations, while allowing the capillary action of the interior corner to drain all or nearly all of the contents to the lip interface. As liquid is drained, the tapered interior shape shifts the bulk liquid ever forward towards the lip interface, eventually draining the contents of the cup.
As shown in
Section C-C, as shown in
Although capillary beverage cup 100 may be used in low-gravity environments, the beverage cup may also be used in standard-gravity environments. Base 106 may be used to balance cup 100 on a level surface on Earth, an artificial gravity environment, or reduced gravity environments (e.g. Lunar, Martian, asteroid, etc.) without the use of additional adherents. Further, liquid may be poured or imbibed from either the lip interface 109 or the rear portion of rim 107 in scenarios where the force of gravity is greater than the capillary force applied by interior corner 120.
Similarly to capillary beverage cup 100, capillary beverage cup 300 comprises an upper right face 301 and an upper left face 302. Upper right face 301 and upper left face 302 intersect at both the front and rear of the cup. At the rear of the cup, the upper left and right faces form upper rear face 303. Upper right face 301 and upper left face 302 intersect at the front of the cup at tapered front face 304. An upper portion 300a of capillary beverage cup 300 is formed by faces 301, 302, 303, and an upper portion of tapered front face 304. As viewed from the front (
Upper right face 301, upper left face 302, rear face 303, and tapered front face 304 form a tear drop profile at the intersection of right bottom face 305a and left bottom face 305b, as shown in
Right bottom face 305a and left bottom face 305b form an egg-shaped profile at the intersection of base 306. The egg-shaped profile is maintained from the base to the intersection with upper portion 300a. However, the area of the base is smaller than the area at the intersection of upper portion 300a and lower portion 300b. As shown in
Handle 310 is shown attached to upper right face 301 and right bottom face 305a, but may be attached to any part the exterior of upper portion 300a and/or lower portion 300b, provided it does not interfere with the internal geometry or the lip interface of the cup. For example, a handle may be placed on the left side of the cup for left handed drinkers, or on the rear face of the cup for universal use. Handle 310 protrudes away from cup 101, attaching below lip 307 and at the interface of the upper and lower portions of the cup. Handle 310 includes an opening which may allow a user to insert a finger (See
As shown in
In this example, the combined height of upper portion 300a and lower portion 300b (from base 306 to rim 307) is 2.56 inches, and lip interface 309 extends 0.59 inches above rim 307. Lip interface 309a includes cusp 309a that is continuous with interior corner 320. In this example, lip interface 309 comprises right lip interface 309b and left lip interface 309c, which form an ergonomic interface for a user's lips. Right lip interface 109b and left lip interface 109c each have a rounded, concave shape, allowing for placement of a user's upper lip above cusp 309a. In this example, lip interface 309 is connected to upper portion 300a via interface support 309d, which may be used to reinforce lip interface 309.
As capillary cup 300 comprises a flat base 306, low-curvature region may be defined by base fill region 323. In this example, the outer profile of cup 300 does not precisely extend the interior profile of the cup. Rather, the base allows for a more traditional looking cup, while enabling the interior geometry that allows for beverage imbibing in low-gravity environments. The base fill region extending from interior base mid-point 321 may define the wide-angle portion of interior corner 321, transitioning into the large interior corner defined by upper right face 301, upper left face 302, and tapered front face 304.
Capillary beverage cup 403 is distinguishable from capillary beverage cup 300 primarily based on the design of handle 410 and lip interface 409. Handle 410 extends from the upper portion of capillary beverage cup 403, with the top surface of the handle situated close to the rim of the cup. Handle 410 has a round opening, allowing for the insertion of a finger, as shown in
Lip interface 409 includes a cusp 409a, clearly visible in
The following claims particularly point out certain combinations and sub-combinations regarded as novel and non-obvious. These claims may refer to “an” element or “a first” element or the equivalent thereof. Such claims should be understood to include incorporation of one or more such elements, neither requiring nor excluding two or more such elements. Other combinations and sub-combinations of the disclosed features, functions, elements, and/or properties may be claimed through amendment of the present claims or through presentation of new claims in this or a related application. Such claims, whether broader, narrower, equal, or different in scope to the original claims, also are regarded as included within the subject matter of the present disclosure.
This application claims priority to U.S. provisional patent application, Ser. No. 62/057,161, entitled “CAPILLARY BEVERAGE CUP,” and filed on Sep. 29, 2014, the entire contents of which are hereby incorporated by reference for all purposes.
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