A pourer includes a pour spout, wherein the pour spout is configured to serve as a spout for a content liquid stored in a container main body, and is configured to be attached to a mouth part of the container main body, wherein the pour spout includes a surplus resin part provided on a part of a top surface of the pour spout through which the content liquid passes, and wherein the surplus resin part protrudes outwardly in the radial direction from an outer peripheral edge of the top surface of the pour spout.

A retaining member for use with a vacuum-insulated vessel is described. The retaining member includes a frustoconical body, a cylindrical skirt extending from the frustoconical body, and a deformable member extending along an inner surface of the frustoconical body. The deformable member may have multiple layers. An opening extends through the frustonical body, so that the neck of a bottle may pass through the opening. The vacuum-insulated vessel, in combination with the retaining member, may receive and secure bottles having different heights and widths. The retaining member and vacuum-insulated vessel also eliminates condensation from external surfaces of a bottle positioned therein, maintains the initial temperature of the bottle, and allows a user to pour from the bottle without having to remove the bottle from the vessel.

A package includes a container and a closure cap for mounting on the container. The closure cap is coupled to a neck of the container to block selectively removal of product stored within the container at the selection of a user.

A package includes a container and a closure cap for mounting on the container. The closure cap is coupled to a neck of the container to block selectively removal of product stored within the container at the selection of a user.

A liquid bottle or container, such as for liquid detergent, and corresponding cap and cup is disclosed for operation in a horizontal position with the cap and cup side wall substantially parallel to the ground, the cap and cup shape providing a built-in drip collector cavity positioned around a portion of the circumference or perimeter of the cap and cup rim on the open end of the cap. The cap and cup may be used to cover a nozzle or other valve dispenser during storage. The drip collector cavity has a volume sufficient to collect liquid residue remaining after normal use of the cap as a measuring and dispensing cup, and any post-use drops from the dispenser nozzle. Thus, the cap and cup of the present disclosure is dripless or nearly drip less. In an embodiment, at least a portion of the cap rim perimeter around which no built-in drip collector cavity is positioned is shaped as a pouring spout. In another embodiment, the area of the liquid container body which receives the cap is shaped to have an indent to accept the pouring spout, thus acting as an orientation key. In yet another embodiment, the drip collector cavity includes one or more radial partitions providing additional rigidity and support to the rim. In another alternative embodiment, the cap and cup shape provides a built-in drip collector cavity at the closed end of the cap. The side wall along the lowest elevation has a negative slope such that when the cap and cup is in the generally horizontal storage position covering the nozzle dispenser, the lowest point of elevation of the rim of the cap and cup is a higher elevation than the lowest point of elevation of the closed end of the cap and cup, thus resulting in collection of liquid residue at and/or near the closed end of the cap and cup.

A liquid bottle or container, such as for liquid detergent, and corresponding cap and cup is disclosed for operation in a horizontal position with the cap and cup side wall substantially parallel to the ground, the cap and cup shape providing a built-in drip collector cavity positioned around a portion of the circumference or perimeter of the cap and cup rim on the open end of the cap. The cap and cup may be used to cover a nozzle or other valve dispenser during storage. The drip collector cavity has a volume sufficient to collect liquid residue remaining after normal use of the cap as a measuring and dispensing cup, and any post-use drops from the dispenser nozzle. Thus, the cap and cup of the present disclosure is dripless or nearly drip less. In an embodiment, at least a portion of the cap rim perimeter around which no built-in drip collector cavity is positioned is shaped as a pouring spout. In another embodiment, the area of the liquid container body which receives the cap is shaped to have an indent to accept the pouring spout, thus acting as an orientation key. In yet another embodiment, the drip collector cavity includes one or more radial partitions providing additional rigidity and support to the rim. In another alternative embodiment, the cap and cup shape provides a built-in drip collector cavity at the closed end of the cap. The side wall along the lowest elevation has a negative slope such that when the cap and cup is in the generally horizontal storage position covering the nozzle dispenser, the lowest point of elevation of the rim of the cap and cup is a higher elevation than the lowest point of elevation of the closed end of the cap and cup, thus resulting in collection of liquid residue at and/or near the closed end of the cap and cup.

A micro-spill prevention trough and method for use in with intermediate bulk container (IBC) totes is disclosed herein. The micro-spill prevention trough includes an attachment portion rotationally coupled to fluid retention portion. The attachment portion is configured to be secured under a spout of an intermediate bulk container (IBC) tote. The attachment portion includes a bucket portion defining a fluid retention space. The fluid retaining portion defines a second fluid retention space, wherein the fluid retaining portion pivots between an open position and a closed position. In the closed position a front wall of the fluid retaining portion pivots into the bucket portion of the attachment portion to define a fluid retention container.

A micro-spill prevention trough and method for use in with intermediate bulk container (IBC) totes is disclosed herein. The micro-spill prevention trough includes an attachment portion rotationally coupled to fluid retention portion. The attachment portion is configured to be secured under a spout of an intermediate bulk container (IBC) tote. The attachment portion includes a bucket portion defining a fluid retention space. The fluid retaining portion defines a second fluid retention space, wherein the fluid retaining portion pivots between an open position and a closed position. In the closed position a front wall of the fluid retaining portion pivots into the bucket portion of the attachment portion to define a fluid retention container.

A capsule for covering the top of a bottle includes a lower portion configured to wrap about a neck of the bottle, an upper portion connected to the lower portion and configured to be removed from the lower portion to expose a top of the neck, and a trench formed about a periphery of an upper edge of the lower portion. An assembly used to form the trench in the capsule includes a housing, and a blade extending outwardly from the housing.