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 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 method of mounting a bottle involves attaching, to a support body, an interface body attached to a portion of the bottle, such that at least a portion of the interface body and the portion of the bottle are positioned within an aperture defined by the support body. Bottle mounting systems are also disclosed.

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 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 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.

A container system includes a first container including a bottom wall, at least one sidewall, and an open top, with a plurality of indented recesses formed in the bottom wall. A first lid closes the open top of the first container. A second container includes a bottom wall, at least one sidewall, and an open top. A second lid closes the open top of the second container, with a push indicator structure formed at a center portion of the second lid, and with a plurality of registration bumps formed about the push indicator structure. The first container is stackable on the second lid such that (i) each of the registration bumps in the second lid is aligned with an adjacent one of the recesses in the bottom wall of the first container and (ii) surfaces of the registration bumps are spaced from surfaces of the adjacent recesses.

A plastic formed body having a pouring port 110 for pouring out highly wetting liquid that wets plastics to a high degree, wherein at least either a surface 110b that becomes a liquid-drip flow passage when said liquid drips at the pouring port 110 or a surface 110a that becomes a flow passage when said liquid is poured out, is coated with a fluorine-contained resin, and a surface of the fluorine-contained resin coating has an arithmetic mean roughness (Ra) in a range of 0.4 to 200 m in the surface roughness measurement and an element mean height (Rh) in a range of 0.04 to 10 as defined by mean height (Rc)/element mean length (RSm) in the linear roughness measurement. The formed body effectively prevents said highly wetting liquid from dripping at the pouring port 110.

A drip stopper for preventing the undesired falling of drops during pouring includes a substantially cylindrical wall having an insertion part for inserting into a bottleneck, and a pouring-out part. The wall has an axially parallel set-back in the form of a recess which extends over the axial length of the wall and makes is possible to adapt the drip stopper to bottlenecks of different widths.