A container is provided with a body portion. The body portion includes a first vacuum panel, a second vacuum panel, a third vacuum panel, a first diagonal column between the first vacuum panel and the second vacuum panel, and a second diagonal column between the second vacuum panel and the third vacuum panel. The second vacuum panel and the third vacuum panel are oriented in opposite directions. In response to a change in an internal container pressure, the body portion flexes at the first vacuum panel such that a surface of the first vacuum panel increases in concavity in response to an increasing pressure change.

A beverage container includes a base, a sidewall extending from and integrally formed with the base, and an upper region extending from the sidewall and defining an upper opening. The beverage container includes a longitudinal axis extending in a direction from the base to the upper opening. The beverage container further includes a continuous channel formed in and extending continuously around a circumference of the sidewall, wherein the continuous channel includes peaks and troughs connected by diagonal regions. The continuous channel is configured to resist paneling and elongation of the beverage container. The beverage container further includes a central channel formed in and extending continuously around a circumference of the sidewall at a central portion of the sidewall, wherein the central channel is configured to resist paneling of the beverage container.

A beverage container includes a base, a sidewall extending from and integrally formed with the base, and an upper region extending from the sidewall and defining an upper opening. The beverage container includes a longitudinal axis extending in a direction from the base to the upper opening. The beverage container further includes a continuous channel formed in and extending continuously around a circumference of the sidewall, wherein the continuous channel includes peaks and troughs connected by diagonal regions. The continuous channel is configured to resist paneling and elongation of the beverage container. The beverage container further includes a central channel formed in and extending continuously around a circumference of the sidewall at a central portion of the sidewall, wherein the central channel is configured to resist paneling of the beverage container.

The disclosure provides a packaging system to store a beneficial agent including a primary package with a molded component. The molded component may have a compartment with a flexible wall enclosing a storage volume and a rigid section configured to connect to a secondary package such that the compartment is contained therewithin. The flexible wall may collapse to deplete a beneficial agent from the storage volume through a dispensing port. The flexible wall may be a web material including a monolayer web or multilayer web, and may incorporate a film, a foil, an adhesive, a polymer layer, a metallic layer, and/or a metal oxide layer. The molded component may be a co-molded component formed of a first material and a second material, the first material being molded into a form and joined to a second material. The molded component may be a unitary molded component which consists of one material.

A synthetic resin container, the container including: a parting line; and a plurality of reduced pressure absorbing panels each formed as a groove extending in the vertical direction while twisting in the circumferential direction, the reduced pressure absorbing panels being disposed in the trunk, in which: when the parting line passes through an upper part of a first reduced pressure absorbing panel and through a lower part of a second reduced pressure absorbing panel, the first reduced pressure absorbing panel is shallower in depth at the upper part thereof than at a central part thereof in the vertical direction, and the second reduced pressure absorbing panel is shallower in depth at the lower part thereof than at a central part thereof in the vertical direction.

A double container has an outer layer body and an inner layer body mainly made of a polyester resin and is formed by biaxial stretch blow molding, and includes: a mouth portion; a shoulder portion, gradually increasing in diameter in a downward direction, and having an outward protruding curved shape over a length in a vertical direction in a longitudinal section; a barrel portion; and a bottom portion, wherein the mouth portion has an outside air introduction port for introducing outside air between the outer layer body and the inner layer body, and the double container includes a shoulder rib that is concave or convex as seen from outside and at least extends from an upper end of the shoulder portion to the lower end of the shoulder portion.

A polymeric container including a finish defining an opening. A base is configured to support the container upright. A grip area is between the opening and the base. A plurality of grip panels are at the grip area. Each one of the grip panels has a depth, a height, and a width. The depth is at least 17% of the height, and the depth is at least 10% of the width.

A plastic container has a base portion adapted for vacuum absorption, the container including a base and a body extending up from the base along a central axis to a finish portion defining a mouth. The base includes an outside wall, a chime connecting the outside wall to an annular contact ring, an inside wall extending upward from the contact ring to a hinge, and a diaphragm connected to the hinge. The diaphragm can move between first and second positions in response to pressure change within the container. The diaphragm includes a central region and a flexible wall having a curved profile in cross section. The flexible wall curves downward from the hinge to the central region. In some embodiments, the flexible wall is asymmetric and includes a first portion having a curved profile and a second portion having a linear profile. A container wall structure is also disclosed.

Synthetic resin bottle (1) including tube-shaped body section (3) comprises eight decompression absorbing panels (8) disposed at equal intervals in body section (3) and pillar sections (9) respectively disposed between said decompression absorbing panels (8) and formed by arcuate wall surfaces (9a). Arcuate wall surfaces (9a) of pillar sections (9) in a cross section of body section (3) configure parts of one imaginary perfect circle (10). A total of circumferential lengths of arcuate wall surfaces (9a) of pillar sections (9) is 20 to 50% of a total circumferential length of perfect circle (10). Consequently, it is possible to realize the synthetic resin bottle having decompression absorbing performance in order to absorb a decrease in internal pressure, the exterior of the body section of the synthetic resin bottle being seen as a cylindrical shape whose shape is almost the same as that of a perfect circle.

An extrusion blow-molded plastic container, for example, a plastic bottle, is described which has a container body having a longitudinal axis, a longitudinal end sealed by a container bottom, another longitudinal end adjoining a container neck provided with a pour opening, and a container shoulder. The container body has at least one deformable section which is made flat and which extends over a large part of an axial length of the container body and in the peripheral direction. The deformable section which has been made flat has two longitudinal sides which run essentially in the axial direction and which border regions of the container body which have a greater stiffness than the deformable section.