Valve apparatus and container including the same

What is claimed is: 1. A container comprising: a chamber containing a viscous fluidic material; a dispensing passageway for discharging the viscous fluidic material from the chamber; a resilient valve operably coupled to the dispensing passageway, the resilient valve comprising: a valve head; and an orifice in the valve head, the orifice defined by an orifice edge of the valve head; and a nozzle comprising at least a portion of the dispensing passageway, the nozzle terminating in an annular distal-most surface that defines a dispensing opening of the dispensing passageway; the resilient valve configured to: (1) transition from a normal state to a dispensing state upon a discharge pressure being applied to the chamber to allow the viscous fluidic material to be passed through the orifice of the resilient valve and be dispensed from the dispensing passageway as a string of the viscous fluidic material, the orifice being open in the normal state; and (2) return from the dispensing state to the normal state upon cessation of the discharge pressure, the resilient valve assuming a pinching state while returning from the dispensing state to the normal state in which the string of the viscous fluidic material is pinched off by the orifice edge; the resilient valve comprising an annular ring defining a central opening, the valve head supported by the annular ring within the central opening, the annular ring comprising an upper-most surface; and the resilient valve mounted within the nozzle so that the upper-most surface of the annular ring of the resilient valve is substantially flush with and surrounded by the annular distal-most surface of the nozzle. 2. The container according to claim 1 wherein the resilient valve is self-biased into the normal state to assist with the return of the resilient valve from the dispensing state to the normal state. 3. The container according to claim 1 wherein, in the normal state, the orifice is opened a first amount; and wherein, in the dispensing state, the orifice is open a second amount, the second amount being greater than the first amount. 4. The container according to claim 1 wherein, in the pinching state, opposite portions of the orifice edge contact one another and the orifice is substantially closed. 5. The container according to claim 1 wherein the orifice comprises a plurality of slits that intersect one another, thereby forming a plurality of flaps. 6. The container according to claim 1 wherein, in the normal state, the valve head comprises a convex inner surface and a convex outer surface. 7. The container according to claim 1 wherein, in the normal state, at least a portion of the valve head is located below a bottom-most surface of the annular ring. 8. The container according to claim 1 wherein: the nozzle is formed of a hard plastic; and the resilient valve is overmolded to the nozzle within the portion of the dispensing passageway, wherein the orifice of the resilient valve is formed during the overmolding process. 9. The container according to claim 1 further comprising a collapsible tube comprising the chamber, wherein the collapsible tube comprises a wall formed of a multi-layer sheet comprising a flavor barrier layer formed of a copolymer, wherein the collapsible tube generates a negative pressure upon cessation of the discharge pressure, the negative pressure assisting with the return of the resilient valve from the dispensing state to the normal state. 10. The container according to claim 1 further comprising: a nozzle component comprising the nozzle, the nozzle comprising an outer side surface extending downward from the annular distal-most surface; a closure component comprising a sealing element comprising an annular wall, the closure component alterable between: (1) a sealed state in which the sealing element seals the dispensing opening via engagement of the annular wall with the outer side surface of the nozzle; and (2) a dispensing state in which the dispensing opening is unobstructed by the sealing element. 11. The container according to claim 10 wherein, in the sealed state, the annular distal-most surface of the nozzle and the upper-most surface of the annular ring of the resilient element are free of contact with the sealing element. 12. The container according to claim 10 wherein the annular wall of the sealing element terminates in a distal edge surface that is inclined relative to a central axis of the annular wall; and wherein the outer side surface of the nozzle is inclined relative to a nozzle axis of the nozzle. 13. The container according to claim 10 wherein the closure component further comprises an annular skirt wall spaced from and circumscribing the annular wall; and wherein the annular skirt wall engages an upper surface of the nozzle component, the nozzle protruding from the upper surface, wherein a perimeter edge of the upper surface defines a perimeter having a center when viewed from above, the nozzle axis spaced a distance from the center of the perimeter in a first direction, and further comprising a hinge coupling the nozzle component to the closure component; and wherein the hinge is located a distance from the center of the perimeter in a second direction opposite the first direction. 14. A method of dispensing a viscous fluidic material from a container comprising: a) upon a discharge pressure being applied to a chamber of the container, a resilient valve positioned in a dispensing passageway transitioning from a normal state to a dispensing state, thereby allowing the viscous fluidic material to pass through an orifice of the resilient valve, the orifice being open in the normal state, the resilient valve comprising an annular ring defining a central opening, a valve head of the resilient valve being supported by the annular ring within the central opening, the annular ring comprising an upper-most surface, the resilient valve mounted within a nozzle of the container so that the upper-most surface of the annular ring of the resilient valve is substantially flush with and surrounded by the annular distal-most surface of the nozzle; and b) upon cessation of the discharge pressure, the resilient valve returning from the dispensing state to the normal state, the resilient valve assuming a pinching state while returning from the dispensing state to the normal state in which the string of the viscous fluidic material is pinched off by the orifice edge.