LINER FOR A VESSEL

Abstract

A beverage containment assembly may include a disposable liner assembly for dispensing fluids with a vessel. The liner assembly may comprise a flexible liner configured for the vessel, a flexible tube; and a cuff having an interlock surface. The cuff may be received in at least a portion of the tube thereby securing the liner and the tube. The interlock surface may be configured to provide a seal between at least the cuff and the liner. A method of manufacturing same is further provided.

Description

FIELD OF TECHNOLOGY

A fluid dispensing assembly, and more particular, a flexible, disposable, and tamper-resistant liner assembly for dispensing fluids with a vessel, and methods of manufacturing and assembling the same.

BACKGROUND

A containment assembly such as urns or vessels may be used for holding and serving liquid or beverages. Typical assemblies may be constructed of metal and thus require cleaning after usage. In a restaurant environment, it is generally preferred to clean such vessels at the end of each shift so as to maintain cleanliness. However such a cleaning task requires increased man power and other resources and such is not preferred.

Another containment assembly uses a plastic bag assembly that is positioned within a containment vessel having a dispensing valve, which in turn is used to deliver beverages to consumers. These bag assemblies may be formed of a two-layer plastic sheet that is heat sealed on three sides with a spout that is heat sealed to an outer surface and over an aperture in one side of the plastic sheet. To fluidly connect with the dispensing value, the typical spout is releasably received into a filament connected to an elongated dispensing tube. As a result, the traditional spout may be physically separated from the elongated dispensing tube by the filament. To dispense beverages, the elongated dispensing tube is passed into the dispensing valve of the containment vessel to be selectively operated by customers. Thus, typical plastic bag assemblies may include excess components thereby unnecessarily increasing material costs and complexity of installation.

Further, typical bag assemblies are not tamper-resistant. After beverages have been dispensed or at the end of a work shift, the containment assembly should be cleaned by throwing away the plastic bag assembly. However, traditional bag assemblies include a releasable connection between the spout and filament. This releasable connection may be utilized to reuse portions or all of the bag assembly, which may lead to unsanitary conditions. As a result, there is a need for a tamper-resistant liner assembly.

Moreover, typical bag assemblies made of two-layer plastic sheet are not configured for the shape of the containment vessel. The concern with such designs is that the plastic bag does not uniformly fit within the containment vessel and as such, crevices are created at the base and elsewhere in the bag which tends to trap useful beverages that in turn cannot be released to the consumer for consumption. Thus, beverage product is wasted and such is not very efficient in the restaurant industry.

Other containment assembly designs employ expensive plastic bags that employ complex valves and dispensing systems that in turn may be used with a vessel. It would be helpful to provide an improved disposable container assembly that has improved functionality, a reduction in the number of working components, yet is more cost competitive for the beverage industry.

BRIEF DESCRIPTION OF THE DRAWINGS

While the claims are not limited to a specific illustration, an appreciation of the various aspects is best gained through a discussion of various examples thereof. Referring now to the drawings, exemplary illustrations are shown in detail. Although the drawings represent the illustrations, the drawings are not necessarily to scale and certain features may be exaggerated to better illustrate and explain an innovative aspect of an example. Further, the exemplary illustrations described herein are not intended to be exhaustive or otherwise limiting or restricted to the precise form and configuration shown in the drawings and disclosed in the following detailed description. Exemplary illustrations are described in detail by referring to the drawings as follows:

FIG. 1 illustrates a perspective view of an improved containment assembly;

FIG. 2 illustrates an enlarged perspective view of the FIG. 1, for example, including a liner assembly having with a tube, a liner, and a cuff with a flange;

FIG. 3 illustrates an enlarged side view of FIG. 2, for example, showing the liner assembly of FIG. 2;

FIG. 4 illustrates an enlarged perspective view of a friction cuff, for example, with a flange;

FIG. 5 illustrates an enlarged side view of another liner assembly having a tube, a liner, and a cuff, for example, without a flange.

FIG. 6 illustrates an enlarged perspective view of another cuff, for example, without a flange;

FIG. 7 illustrates a perspective view of a containment assembly having an alternative liner assembly;

FIG. 8 illustrates an enlarged perspective view of the liner assembly of FIG. 7;

FIG. 9 illustrates another enlarged perspective view of the liner assembly of FIG. 7;

FIG. 10 illustrates another enlarged perspective view of the liner assembly of FIG. 7;

FIG. 11 illustrates a perspective view of an alternative containment assembly; and

FIG. 12 illustrates a side view of an alternative containment assembly.

DETAILED DESCRIPTION

The exemplary assembly may include a rigid vessel such as an urn, a liner such as a flexible fitted liner, a cuff such as a friction cuff configured to be positionable on an inner wall of the liner, a tube such as a flexible tube positionable on an outer wall of the liner, and a spigot that allows for the flexible tubing to be inserted therethrough. The vessel may further include a flow operator that pinches the tube to allow controlled dispensing.

The assembly may be configured to allow for sanitary dispensing of beverages for human consumption. The assembly may be configured such that the beverage may bypass the urn or the spigot for easy cleaning. Instead, the assembly may be configured such that the liquid is handled by the liner, cuff, and tube thereby minimizing or preventing contact between the liquid from the vessel.

With reference to FIGS. 1-2, a containment assembly 100 may include a vessel 110 and a liner assembly 120. The vessel 110 may include any liquid or beverage dispenser such as a beverage or tea urn. As shown in FIG. 2, the liner assembly 120 may include a tube 130, a liner 140 such as a flexible liner, and a cuff 160 such as a rigid cuff with or without a flange. The liner 140 may be specially dimensioned and configured to match an internal cavity of the vessel 110 and the liner 140 and vessel 110 may include a tapered bottom portion to facilitate flow of liquid therefrom, as discussed in more detail below.

The liner assembly 120 may be configured to provide a seal between the liner 140 and the tube 130, for example, using cuff 160. Cuff 160 may include a unitary or one piece component configured to secure the liner 140 and tube 130 together. The liner assembly 120, using the cuff 160, may utilize an interlock such as a friction interlock. The interlock may provide a permanent or tamper-resistant connection between any portions of liner assembly 120, for example, being destroyed in response to disassembly. For example, the liner 140 and the tube 130 may be connected with the interlock. To provide this seal, the cuff 160, such as a circular spacer with or without a flange, may be positioned inside the tube 130 thereby outwardly expanding a diameter of an inner surface of the tube 130. The liner 140 may be positioned between the tube 130 and liner 140. Thus, the cuff 160 may outwardly push the liner 140 against an inside surface of the tube 130 thereby providing a seal such as a liquid tight seal. As a result, the cuff 160 provides a unitary or one piece component that secures the liner 140 relative to the tube 130 thereby eliminating unnecessary components. Accordingly, the interlock may provide a fluid tight structure or seal thereby reducing leakage of liquid along the liner assembly 120 and may provide a permanent or tamper-resistant connection between the cuff 160, liner 140, and tube 130 that may not be removed without at least partially destroying at least a portion of the liner 140.

Referring to FIGS. 3 and 5, the liner assembly 120 may include the liner 140 interposed between the tube 130 and the cuff 160. The cuff 160 may include an inner surface having a passage for receipt of liquid from the liner 140 and an outer surface that is dimensioned and configured to be received in and outwardly stretch an inner surface of the tube 130. The cuff 160 may be configured to be positioned with an axial force along the tube 130 and may be configured to expand the tube 130 thereby placing an outward force against the liner 140 and toward the inner surface of tube 130. In reaction, the tube 130 may place an inward force against the liner 140 and toward the outer surface of the cuff 160. Thus, the liner assembly 120 may be cold-formed with the axial force, outward force, inward force, or a combination thereof, thereby creating an interlock between the tube 130, liner 140, and cuff 160. Accordingly, the liner 140 may be held between the tube 130 and the cuff 160 thereby providing a permanent or tamper-resistant connection between the cuff 160, liner 140, and tube 130 that may not be removed without at least partially destroying at least a portion of the liner 140.

The liner assembly 120 may be configured for a permanent or tamper-resistant connection between tube 130, liner 140, and cuff 160, for example, being at least partially destroyed in response to disassembly. For example, the liner assembly 120 (e.g., liner 140 and/or tube 130) may be configured to at least partially destruct, rip or tear in the event of disassembly thereby providing a permanent or tamper-resistant liner assembly 120 in response to disassembly. Alternatively, the tube 130, liner 140, and cuff 160 may be connected using an adhesive or heat seal thereby providing a permanent or tamper-resistant liner assembly 120, for example, being at least partially destroyed in response to disassembly. In addition, liner assembly 120 may utilize any other destructive interlock between the tube 130, liner 140, and cuff 160 that results in at least partial destruction of at least one of the tube 130, liner 140, and cuff 160 during disassembly. Thus, the liner assembly 120 may be configured to provide a permanent or tamper-resistant connection, for example, being at least partially destroyed in response to disassembly.

The liner assembly 120 may include the cuff 160 with a flange 164 as shown in FIG. 4 or without a flange 164 as shown in FIG. 6. The cuff 160 may include a rigid cuff, for example, configured to resist bending of the flange 164 and maintain a passage therethrough. Further, the flange 164 may be configured to maintain the liner 140 in an outward position relative to the tube 130, for example, to resist blockage of the passage of the cuff 160. To maintain the outward position, the flange 164 may be configured to releasably contact or push against the liner 140 or may be adhered or heat sealed thereto. Alternatively, the cuff 160 may be without a flange 164, for example, to allow relative inward movement of the liner 140.

As mentioned above, the liner 140 may be affixed (e.g., permanently) relative to the cuff 160 and tube 130. As shown in FIG. 5, the liner assembly 120 may include an optional adhesive 150 (e.g., a food grade adhesive) thereby permanently adhering the tube 130, liner 140, and cuff 160 together. Alternatively, the liner 140 may be affixed relative to the cuff 160 and tube 130 using a heat seal thereby permanently fusing the tube 130, liner 140, and cuff 160 together.

As shown in FIGS. 4 and 6, the cuff 160 may include an interlock surface 162. The interlock surface 162 may be configured to provide or facilitate the interlock between the cuff 160, liner 140, and tube 130. The interlock surface 162 may include a plurality of protrusions interposed by a plurality of recesses, thereby resulting in an increased surface area and a higher coefficient of friction. For example, this may create a plurality of ridges with alternating valleys as shown in FIG. 4. As another example, the interlock surface 162 may include a plurality of pores as shown in FIG. 5. Alternatively, the interlock surface 162 may be smooth. Thus, the interlock surface 162 may facilitate the interlock and resulting seal between the cuff 160, liner 140, and tube 130.

Referring to FIG. 7, the dimensions of the liner 140 are configured to allow for a minimum amount of liner material to be used for the specific vessel 110 that is being lined. This reduces the number of folds created when the liner is installed into the vessel and filled, thus improving drainage of the liquid product. The liner 140 may be constructed from a tube of flexible material having one end sealed closed. The tube 130 is attached to the liner 140, which may occur proximal to the sealed end of the liner 140 at a point configured to assist in draining the beverage product in its entirety from the liner 140. Further, the liner 140 may be dimensioned and configured to provide an optimum size to reduce material usage and improve draining with respect to the vessel 110. In addition, the liner 140 may be optimized or dimensioned according to a vessel length, a vessel height, a vessel opening perimeter or circumference, and a spigot location relative to a length and a width of the vessel 110.

The liner 140 may be made from flat tubing, gusseted tubing, or a flexible pouch having opposed sidewalls that may be optionally connected at peripheral edges. The liner 140 may be any shape configured to form-fit to the vessel 110. The liner 140 may be configure to be stretched over the top edge of the vessel 110, for example, to keep the liner 140 from sliding down inside of the vessel 110 upon being filled.

Methods of manufacturing the liner 140 are contemplated. Methods may include converting raw material into roll stock and converting the roll stock into individual liners 140. The raw material may be in the form of roll stock, for example, dimensioned according to a vessel length and a vessel width of the vessel 110. The roll stock may then be converted by cutting (e.g., using heat or a cutter) the liner 140 to an optimum liner length (e.g., a vessel height of vessel 110) thereby resulting in an end open at the top of the liner 140 and a bottom of the liner 140 that is sealed.

Furthermore, methods of assembling the liner assembly 120 are contemplated. A method may include positioning the cuff 160 (e.g., a friction cuff) over a locating stud of an assembly tool or platform, positioning the liner 140 over at least a portion of the cuff 160 and locating stud, and pushing tubing 130 over at least a portion of the liner 140, cuff 160, and locating stud, thereby outwardly expanding the tube 130 and puncturing the liner 140. In use, puncturing the liner 140 allows fluid to flow from the liner 140 through the cuff 160, and into the tube 130. As such, the tube 130, liner 140, and cuff 160 may be held together (e.g., permanently) by an inward force from the elasticity of the tube 130 and a friction force between the tube 130, liner 140, and cuff 160. Alternatively or in addition, any or all of tube 130, liner 140, and cuff 160 may be held together (e.g., permanently) using an adhesive or a heat seal therebetween. Accordingly, the liner assembly 120 may be configured with layers having an order from inside to outside as follows: the cuff 160 (e.g., a friction cuff), the liner 140, and the tubing 130 (e.g., flexible tube). In addition, a method may further include removing the liner assembly 120 from the assembly tool or platform and packing the liner assembly 120 for distribution.

Referring to FIGS. 7-10, an assembly 200 may include a vessel 110 and a liner assembly 120. The vessel 110 may include a support surface 170. The liner assembly 120 may include a liner 210 (e.g., a fitted flexible liner), a tube 220 (e.g., a flexible tubing), and a heat seal 230. The liner 210 may include a single piece heat sealed liner dimensioned and figured for the vessel 110. The liner 210 may be directly attached to a tube 220 with the heat seal 230. The heat seal 230 may provide a permanent or tamper-resistant connection, for example, being at least partially destroyed in response to disassembly. The heat seal 230 may be created by using a heat probe. The heated probe may push the liner 210 into an inner surface of the tube 220 thereby sealing an outer surface of the liner 210 at the point at which the liner 210 contacts the inner surface and end of the tube 220.

The liner 210 may be dimensioned and configured to allow for a minimum amount of liner material to be used for the specific vessel 110 being lined. This may reduce the number of folds created when the liner 210 is installed into the vessel 110 and filled, thus improving drainage of the liquid or product. The liner 210 may be constructed from a tube 220 of flexible material having one end sealed closed. The tube 220 and liner 210 may be permanently attached, which may occur proximal to the sealed end of the liner 210 at a point configured to assist in draining the product in its entirety from the liner 210. The liner 210 may then placed over a locating board with heat probe for sealing. The tube 220 may then be placed above the heat probe and a foot operated pedal may then pushes the heat probe through a hole in the locating board thereby forming the heat seal 230. Accordingly, the liner assembly 120 may include the layers from inside to outside as follows: liner 210, heat seal 230, and tube 220.

Referring to FIGS. 11 and 12, an assembly 300 may include the vessel 110 and the liner assembly 120 The liner 140, the vessel 110, or both the liner 140 and vessel 110 may be configured with a tapered structure, for example as a bottom of the liner 140 and/or the support surface 170 of the vessel 110. For example, the tapered structure may optimize utilization of fluid in the liner 140 by urging fluid toward the tube 130. The tapered structure may include any structure configured to urge liquid toward the tube 130 of the liner assembly 120 and/or spigot of the vessel 110. The tapered structure may include any number of tapered surfaces as part of the vessel 110 or liner 140 that are configured to angle or slope liquid toward the spigot of the vessel 110. The tapered structure may include two tapered surfaces forming a v-shape (e.g., along a lengthwise, central axis of the vessel 110) as shown in FIG. 11, may be tapered downwards from a first end (e.g., a backend) to a second end (e.g., a front end) of the vessel 110 as shown in FIG. 12, or may be a combination thereof. For example, the bottom of liner 140 or the support surface 170 of vessel 110 may include the tapered structure. Moreover, the liner 140 may have any number of gussets or may be heat sealed to form a tapered structure as shown in FIGS. 11 and 12. As such, the vessel 110 and liner 140 may be configured to taper fluid out of the liner 140 and toward the tube 130 thereby optimizing usage of the fluid.

It will be appreciated that the aforementioned method and devices may be modified to have some components and steps removed, or may have additional components and steps added, all of which are deemed to be within the spirit of the present disclosure. Even though the present disclosure has been described in detail with reference to specific embodiments, it will be appreciated that the various modifications and changes can be made to these embodiments without departing from the scope of the present disclosure as set forth in the claims. The specification and the drawings are to be regarded as an illustrative thought instead of merely restrictive thought.

Claims

1. A beverage containment assembly for use with a liner assembly, the beverage containment assembly comprising: a vessel;a flexible liner disposed within the vessel;a flexible tube; anda cuff having an interlock surface,wherein the cuff is received in at least a portion of the tube thereby securing the liner and the tube, andwherein the interlock surface provides a seal between at least the cuff and the liner.

2. The assembly of claim 1, wherein the cuff is configured to apply an outward force to the liner and the flexible tube is configured to apply an inward force to the liner.

3. The assembly of claim 1, wherein the interlock surface is configured to provide a permanent connection between the cuff, liner, and tube that is at least partially destroyed in response to disassembly.

4. The assembly of claim 1, wherein the cuff includes a flange configured to maintain the liner in an outward position.

5. The assembly of claim 1, wherein the interlock surface includes a plurality of ridges.

6. The assembly of claim 1, wherein the interlock service is secured relative to the liner with at least one of an adhesive and a heat seal.

7. The assembly of claim 1, wherein at least one of the vessel and the liner includes a tapered structure configured to urge fluid toward the tube.

8. A liner assembly comprising: positioning a cuff having an interlock surface over a locating stud of an assembly tool;positioning a flexible liner over at least a portion of the cuff thereby puncturing the liner;positioning at least a portion of a tube over at least a portion of the liner and cuff thereby outwardly expanding at least a portion of tube;a flexible liner;a flexible tube; andwherein the cuff is received in at least a portion of the tube thereby securing the liner and the tube, andwherein the interlock surface provides a seal between at least the cuff and the liner.

9. The assembly of claim 1, wherein the cuff is configured to apply an outward force to the liner and the flexible tube is configured to apply an inward force to the liner.

10. The assembly of claim 1, wherein the interlock surface is configured to provide a permanent connection between the cuff, liner, and tube that is at least partially destroyed in response to disassembly.

11. The assembly of claim 1, wherein the cuff includes a flange configured to maintain the liner in an outward position.

12. The assembly of claim 1, wherein the interlock surface includes at least a smooth portion.

13. The assembly of claim 1, wherein the interlock surface includes a plurality of ridges.

14. The assembly of claim 1, wherein the interlock service is secured relative to the liner with at least one of an adhesive and a heat seal.

15. A method of assembling a liner assembly comprising: positioning a cuff over a locating stud of an assembly tool, the cuff having an interlock surface;positioning a flexible liner over at least a portion of the cuff;pushing a tube over at least a portion of the liner and cuff, thereby outwardly stretching at least a portion of tube and puncturing the liner;wherein the cuff is received in at least a portion of the tube thereby securing the liner and the tube, andwherein the interlock surface provides a seal between at least the cuff and the liner.

16. The method of claim 15, wherein the cuff is configured to apply an outward force to the liner and the flexible tube is configured to apply an inward force to the liner.

17. The method of claim 15, wherein the interlock surface is configured to provide a permanent connection between the cuff, liner, and tube that is at least partially destroyed in response to disassembly.

18. The method of claim 15, wherein the cuff includes a flange configured to maintain the liner in an outward position.

19. The method of claim 15, wherein the interlock surface includes at least a smooth portion.

20. The method of claim 15, wherein the interlock surface includes at least one of a plurality of ridges.