A condiment distribution apparatus is provided. The apparatus may include a condiment delivery fitment including a condiment delivery base comprising two curved exterior surfaces formed adjacent to a flat top surface, a curved condiment delivery tube having a remote end and a near end, the near end affixed to the flat top surface of the condiment delivery base, and product valve distribution means positioned within the condiment delivery base and attached to the curved condiment delivery tube enabling rotation of the curved condiment delivery tube relative to the condiment delivery base, wherein rotation of the product valve distribution means selectively inhibits or enables condiment product delivery via the curved condiment delivery tube.

A condiment distribution apparatus is provided. The apparatus may include a condiment delivery fitment including a condiment delivery base comprising two curved exterior surfaces formed adjacent to a flat top surface, a curved condiment delivery tube having a remote end and a near end, the near end affixed to the flat top surface of the condiment delivery base, and product valve distribution means positioned within the condiment delivery base and attached to the curved condiment delivery tube enabling rotation of the curved condiment delivery tube relative to the condiment delivery base, wherein rotation of the product valve distribution means selectively inhibits or enables condiment product delivery via the curved condiment delivery tube.

A container (100) is provided that includes a chamber (102), a dispensing passageway and a resilient valve (120). The chamber contains a viscous fluidic material. The valve (120) is configured to transition from a normal state to a dispensing state upon a discharge pressure being applied to the chamber (102) to allow the viscous fluidic material to pass through the orifice (131) of the resilient valve and to be dispensed from the dispensing passageway as a string of the viscous fluidic material. The orifice (131) is open in the normal state. The valve is also configured to return from the dispensing state to the normal state upon cessation of the discharge pressure, whereby the resilient valve (120) assumes 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.

A container (100) is provided that includes a chamber (102), a dispensing passageway and a resilient valve (120). The chamber contains a viscous fluidic material. The valve (120) is configured to transition from a normal state to a dispensing state upon a discharge pressure being applied to the chamber (102) to allow the viscous fluidic material to pass through the orifice (131) of the resilient valve and to be dispensed from the dispensing passageway as a string of the viscous fluidic material. The orifice (131) is open in the normal state. The valve is also configured to return from the dispensing state to the normal state upon cessation of the discharge pressure, whereby the resilient valve (120) assumes 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.

A liquid-dispensing container may include a vessel, lid body, valve assembly, selector and/or straw. The selector may be movable between a first position that allows fluid disposed within the container to be discharged through a straw, and a second position that allows fluid within the container to be discharged by inverting and/or squeezing the container. The selector may be movable into a closed position that restricts fluid from being discharged from the container. The selector may be movable into a detachment position that allows for detachment of the selector from a remainder of the container, disassembly of the valve assembly, or both.

A liquid-dispensing container may include a vessel, lid body, valve assembly, selector and/or straw. The selector may be movable between a first position that allows fluid disposed within the container to be discharged through a straw, and a second position that allows fluid within the container to be discharged by inverting and/or squeezing the container. The selector may be movable into a closed position that restricts fluid from being discharged from the container. The selector may be movable into a detachment position that allows for detachment of the selector from a remainder of the container, disassembly of the valve assembly, or both.

The disclosure provides an anti-pollution bottle cap comprising a cap body, a liquid drainage one-way valve and an air intake one-way valve. A liquid drainage hole and an air intake hole are disposed in the cap body and both communicated with an inside of the cap body. The liquid drainage one-way valve is disposed in a space enclosed by the cap body. The liquid drainage hole is blocked by the liquid drainage one-way valve in one way so as to be opened during toppling operation. The air intake one-way valve is disposed in the space enclosed by the cap body. The air intake hole is blocked by the air intake one-way valve in one way so as to be closed during toppling operation. In application, the anti-pollution bottle cap will be installed on a bottle for matched use, so that a user can normally drain liquid through the liquid drainage hole only by squeezing the bottle. When use is stopped, through blockage of the liquid drainage one-way valve to the liquid drainage hole, adherends on the body surface of the user are prevented from entering the bottle, contents will not be polluted, and the problem that an existing bottle cap is likely to pollute contents is practically solved.

The disclosure provides an anti-pollution bottle cap comprising a cap body, a liquid drainage one-way valve and an air intake one-way valve. A liquid drainage hole and an air intake hole are disposed in the cap body and both communicated with an inside of the cap body. The liquid drainage one-way valve is disposed in a space enclosed by the cap body. The liquid drainage hole is blocked by the liquid drainage one-way valve in one way so as to be opened during toppling operation. The air intake one-way valve is disposed in the space enclosed by the cap body. The air intake hole is blocked by the air intake one-way valve in one way so as to be closed during toppling operation. In application, the anti-pollution bottle cap will be installed on a bottle for matched use, so that a user can normally drain liquid through the liquid drainage hole only by squeezing the bottle. When use is stopped, through blockage of the liquid drainage one-way valve to the liquid drainage hole, adherends on the body surface of the user are prevented from entering the bottle, contents will not be polluted, and the problem that an existing bottle cap is likely to pollute contents is practically solved.

A sealing closure for dispensing fluid includes a closure body. The closure body has an attachment portion configured to attach to a container containing fluid, a dispensing portion, and a conduit connecting the attachment portion and dispensing portion and configured to direct fluid from the attachment portion to the dispensing portion. The sealing closure further includes a spring lid attached to the dispensing portion. The spring lid has a first portion coupled to the closure body, a second portion not attached to the closure body. The second portion is configured to contact the closure body when a pressure of the fluid is below a threshold, and flex to separate from the closure body when the pressure of the fluid meets or exceeds the threshold to create an opening for dispensing the fluid.

Cream dispenser for topically dispensing liquid onto the skin of a user including a liquid store, a discharge head that has a discharge opening and a hinged lid to protect the discharge opening. The dispenser has a multi-part design of the discharge head in order to limit, in a haptically satisfactory way, the movability of a release button of the discharge head and a special relative arrangement of the locking edges on the discharge head and on the hinged lid opposite a joint of the hinged lid in order to prevent the sharp-edged locking edges from coming into contact with the skin while cream is being discharged onto the skin.