The present invention is a pressure reduction-absorbing bottle having a cylindrical shape with a bottom made of a synthetic resin material in which a bottom wall portion of a bottom portion of the bottle includes a grounding portion, a rising circumferential wall portion, a movable wall portion, and a central wall portion, the movable wall portion includes a curved portion having a curved surface shape protruding downward, the curved portion is connected to an outer end portion of the central wall portion in a bottle radial direction, and a lowest portion of the curved portion positioned at a lowest position thereof is located at a portion of the curved portion further outward in the bottle radial direction than a central position of the curved portion in the bottle radial direction.

A synthetic resin container includes a mouth portion and body, the body being squeezed to discharge contents. The body has a flattened shape with a width larger than a thickness. An end on one side in an axial direction along a center axis line of the body is connected to the mouth portion, and an end on another side is closed and formed in a curved shape protruding toward the other side in the axial direction. Each widthwise ends of the body is provided with a bent portion extending in parallel with the axial direction. When the body is squeezed in the thickness direction to discharge the contents, the bent portion is configured to be a starting point when one of a front side wall and a rear side wall opposed to each other in the thickness direction of the body is inverted and deformed toward the other.

A controlled release container including a base. The base has a flexible diaphragm movable between a relaxed position and a depressed position. In the depressed position the flexible diaphragm reduces an interior volume of the container to dispense a dosage amount of material stored within the container. The dosage amount directly corresponds to an internal volume of the container displaced by moving the flexible diaphragm to the depressed position.

A container assembly including a removable closure and a container which includes a chamber wall and a bottom attached to the chamber wall to form a cavity in which product is contained. An outer surface of the chamber wall includes a first attachment connector near the upper end of the chamber wall and which removably engages with a mating second attachment connector formed on the closure. A shoulder extends radially outward from the chamber wall at a point below the first attachment connector, and an outer support skirt extends downward from a distal end of the shoulder. The outer support skirt surrounds at least a substantial portion of the outer surface of the chamber wall and, when placed on a surface, the support skirt rests on the surface and the bottom of the cavity rests on or is spaced apart from the surface.

A displacement device for moving a truncated cone at a base of a container from an as-blown position to a displaced position. The base includes a deep base ring between a standing surface and the truncated cone. The displacement device includes a collar sized and shaped to be received within the deep base ring. A plunger includes a head at an end of a shaft extending through the collar. The head is sized and shaped to be received within the receptacle of the collar. The plunger is movable from a retracted position, at which the head is seated within the receptacle, to an extended position at which the head extends out from within the receptacle to allow the head to contact the truncated cone and move the truncated cone from the as-blown position to the displaced position.

Base includes an outer support wall, a support surface extending inwardly from the outer support wall and defining a reference plane, an inner support wall extending upwardly from the support surface, a first radiused portion extending radially inward from the inner support wall and concave relative to the reference plane, a second radiused portion extending radially inward from the first radiused portion and convex relative to the reference plane, an intermediate surface extending radially inward from the second radiused portion, the intermediate surface including a linear portion and an intermediate radiused portion, a third radiused portion extending radially inward from the intermediate surface and convex relative to the reference plane, and a central portion disposed proximate the third radiused portion.

The present invention relates to a container cap and, more specifically, to: a container cap which is coupled to the mouth of a container in which contents are contained; and a container having same coupled thereto. The present invention provides a container cap comprising: a body part coupled to the mouth of a container in which contents are contained, and having an opening at the top thereof; a cover part coupled to the body part so as to open and close the top opening of the body part; and a separation part integrally connected to a first member, which is one of the body part and the cover part, by a first connection part, and integrally but detachably connected to a second member, which is the other of the body part and the cover part, by a second connection part, wherein the second connection part is detached by a user's manipulation so as to allow the cover part to be separated from the body part.

A protective bottle enclosure includes a container having a neck, a shoulder, and a body, wherein the neck includes a plurality of threaded portions and a plurality of planar portions located intermediate the plurality of threaded portions. The enclosure further includes a removable cap from which extends a first threaded portion and a second threaded portion, the first and second threaded portions being located along opposing sides of the sidewall, and a first planar portion and a second planar portion disposed adjacent and between the first and second threaded portions. The first and second threaded portions of the cap are aligned with the plurality of planar portions along the neck when the cap is axially inserted into the container.

Plastic container that is to be filled with a hot product includes a threaded neck portion, a base portion including a standing surface and a moveable element, and a body portion including a dome portion, first and second label stop portions, a supplemental vacuum panel and a sidewall relatively free of structural geometry that surrounds an interior of the body portion. During cooling, the hot product is contracted so as to create an induced vacuum. The supplemental vacuum panel is configured and operative to remove a first portion of an induced vacuum, and the moveable element is configured and operative to move from a first position to a second position to remove a second portion of the vacuum, wherein the first portion of the vacuum and the second portion of the vacuum constitute substantially the entire vacuum.

Exemplary hot-fillable plastic containers are disclosed. In some embodiments, the containers may include a threaded neck portion, a body portion, and a base portion including a standing surface and a movable element. In some embodiments, the moveable element may be arranged to be recessed either substantially above, or substantially below, the standing surface in an initial pre-filling position.