A cap for a container including a dispensing opening operable to be selectively sealed and a housing configured for sealing engagement with a container opening, said housing defining a passage along a longitudinal axis thereof, the passage having a plurality of ribs disposed in the passage defining a plurality of channels which, when the container is in a sufficiently tilted state, cause liquid in the container to exit through the dispensing opening, wherein at least one channel is a liquid-flow channel through which liquid flows out of the dispensing opening when unsealed.

A combination of a container made out of rolled laminated plastic or rolled laminated metal, combined with a child-resistant locking assembly between the container and a cap removably affixed to the container. The container includes a closed rear end, a front wall and a flexible sidewall between the closed rear end and the front. The cap includes a central post inserted into a dispensing opening in a dispensing nozzle of the contain to reduce the possibility of contents in the container seeping out of the dispensing nozzle after the sealing cap is affixed to the nozzle.

The present invention may comprise a container, with a container body, a closed base, an open top, an exterior, and a cap assembly designed to couple to the container body for closing the container. A cap assembly may include an inner cap configured to couple to a container body and an outer cap coupled to the inner cap. A first coupler may be coupled to the inner cap and a second coupler may be coupled to the outer cap and designed to optionally engage the first coupler. An outer cap may be designed to rotate relative to an inner cap if the outer cap is in one or more positions and to engage the inner cap when the outer cap is in one or more other positions.

Systems, methods, and apparatuses for sealing bottles with a Roll-on Pilfer Proof (ROPP) closure and a childproof overcap are provided. More specifically, the present disclosure relates to an overcap that can be placed onto or formed onto the ROPP closure. The overcap has a retainer that secures the overcap to the ROPP closure and allows the overcap to move relative to the ROPP closure in a longitudinal axis. The overcap moves between a first position or mode of operation where the overcap can rotate about the ROPP closure and a second position or mode of operation where the overcap engages the ROPP closure to transmit a twisting or torque force to the ROPP closure and open the bottle.

A child resistant closure with twin locking comprising a container including a body portion defining a chamber, and a hollow neck extending from the body portion, an inner cap (2) formed to fit around the hollow neck of the container, an outer cap (1) operably disposed over the inner cap (2) adapted to impart an axial rotational force on the inner cap, plurality of locking ratchet (C) positioned on the circumferential inner sidewall surface (D) of the outer cap (1) and on the circumferential outer sidewall surface (02) of the inner cap (2), plurality of locking teeth (E) positioned on the inner top surface (10) of the outer cap (1) and on the top surface (9) of the inner cap (2) wherein by pressing the outer cap (1) downward on the inner cap (2), the plurality of locking ratchet (C) positioned on the circumferential inner sidewall surface (D) of the outer cap (1) and the plurality of locking ratchets (04) positioned on the circumferential outer sidewall surface (02) of the inner cap (2) gets engaged with each other to impart rotation to the inner cap (2) in anticlockwise direction to remove the closure from the container. Further, it also discloses the use plurality of locking teeth to provide additional force to remove the closure from the container.

A closure is configured to mount on a container to close an open mouth formed in the container. The closure includes a lid and an outer layer coupled to the lid.

A liquid dispensing nozzle includes a liquid dispensing opening and a removable cap configured to cover the liquid dispensing opening. The removable cap includes an outer casing and an inner casing that are coaxial and configured to move relative to each other in an axial direction of the nozzle between an unscrewing configuration wherein a pressing force applied to the removable cap is greater than a predetermined threshold, and a safety configuration wherein a pressing force applied to the cap is lower than the predetermined threshold, wherein the outer casing is configured to freewheel relative the inner casing in the first direction. A rotation of the outer casing in a first direction drives by friction a rotation of the inner casing in the same first direction to unscrew the cap, wherein the pressing force is different from a force required to rotate the cap in the first direction.

A container with a security lock is provided. The container may have a lid (or “top”) portion and a bottom portion. The lid portion may have an exterior cover, a first disc, a second disc and a third disc. The first disc may have a plurality of indented downward partial trapezoids. The second disc may also have a plurality of nearly identical, upwardly extending partial trapezoids wherein the plurality of indented partial trapezoids of the first disc may be temporarily and selectively located between the plurality of partial trapezoids of the second disc in order to allow the lid to be rotated and the container therein opened. The third disc may be made of a thin material that allows the container to remain substantially airtight.

Disclosed is a process for manufacturing a safety closure, wherein in a first step, a monolithic injection-molded part is made having, one behind the other in the direction of a longitudinal axis (L), a rotary closure with a closure cap, a plurality of break-off points and an actuation piece, and in a second step, a force acting in the direction of the longitudinal axis (L) is applied to the injection-molded part such that the closure cap and the actuation piece move against each other in the direction of the longitudinal axis (L) and the closure cap slides at least partially into the actuation piece, the actuation piece being elastically deformed by the first engagement piece during the sliding-in movement so as to take an oval shape and then regaining its original shape once the sliding-in movement has been completed.