A polygonal bottle, and mouth, shoulder, drum, and bottom sections are formed in a bottle axial direction, the drum section including main wall sections connected via connecting sections in a circumferential direction about a bottle axis, in a lateral cross sectional view perpendicular thereto, a polygonal shape is formed, in which a panel section recessed inward in a radial direction, extending in the bottle axial direction and arriving at an upper portion of the mouth section side of the main wall section formed at the main wall sections of the drum section. A reinforcement protrusion protruding outward in the radial direction is formed at shoulder section connecting portions, a top surface directed outward in the radial direction is continued to an outer circumferential surface of the drum section with no step difference, and an upper surface directed upward is formed in a curved surface shape protruding upward.

A plastic container that is adapted for adjustment to internal volumetric changes such as those that occur during the hot-fill process includes a container body defining an internal space and having a sidewall. The container body has a maximum lateral dimension and a plurality of flexible panels and posts defined in the sidewall. The posts are respectively interposed between the flexible panels around the outer circumference of the sidewall. Each of the plurality of posts has a minimum width and a maximum width, and a ratio of the minimum width to maximum width is preferably within a range of about 0.3 to about 0.7. A ratio of the minimum width to the maximum lateral dimension is preferably within a range of about 0.05 to about 0.30. In addition, a ratio of the maximum width to the maximum lateral dimension is preferably within a range of about 0.15 to about 0.45.

A container includes a base, a neck defining an outlet, and a body positioned between the base and the neck. The body includes a plurality of ribs extending around a periphery of the body and along at least a portion of a height of the body, a plurality of channels extending around the periphery and positioned between the plurality of ribs, and a plurality of support columns spaced about the periphery and extending along at least a portion of the height of the body. Each of the plurality of support columns includes a plurality of protrusions that are vertically aligned. Each of the plurality of protrusions is disposed within a respective one of the plurality of channels. The plurality of protrusions include a first plurality of protrusions having a first size and a second plurality of protrusions having a second size different from the first size.

A container includes a base, a neck portion, and a body positioned between the base and the neck portion. The base includes a plurality of feet with a plurality of recesses positioned between the plurality of feet. The body includes a plurality of ribs, a plurality of channels, and a plurality of support columns. The plurality of ribs extend around a periphery of the body and along at least a portion of a height of the body. The plurality of channels extend around the periphery and are positioned between the plurality of ribs. The plurality of support columns are spaced about the periphery and extend along at least a portion of the height of the body. Each of the plurality of support columns includes a plurality of protrusions that are vertically aligned. Each of the plurality of protrusions is disposed within a respective one of the plurality of channels.

A volume expansion feature for a fluid reservoir is provided, the volume expansion feature comprising a central recess, a plurality of channels extending from the central recess, where the central recess and the channels are positioned at least in part in a recessed surface profile. The recessed surface profile is reversibly moveable from a first inwardly directed configuration, to a second outwardly directed configuration. The central recess and the channels are configured to impart an inward bias to maintain the recessed surface profile in the first inwardly directed configuration under standard loading of the fluid reservoir. Upon increased pressure within the fluid reservoir, the recessed surface profile extends to the second outwardly directed configuration, thereby increasing the volume of the fluid reservoir.

Provided is a synthetic resin container that effectively absorbs the reduced pressure generated inside the container as a result of hot filling and that also prevents deterioration in appearance of a label applied to an outer circumferential surface of a trunk portion of the container. A synthetic resin container according to the present disclosure includes a mouth portion, a trunk portion, and a bottom portion. The trunk portion is provided with a plurality of reduced pressure absorbing panels extending in the vertical direction while twisting in the circumferential direction and being arranged side by side in the circumferential direction. Each reduced pressure absorbing panel has a narrow-width portion located in a region between the panel upper end and the panel lower end. A width of each reduced pressure absorbing panel is reduced in the narrow-width portion than in the panel upper end and the panel lower end.

A semi-rigid collapsible container has a side-wall with an upper portion, a central portion, a lower portion and a base. The central portion includes a vacuum panel portion having a control portion and an initiator portion. The control portion is inclined more steeply in a vertical direction, i.e. has a more acute angle relative to the longitudinal axis of the container, than the initiator portion. On low vacuum force being present within the container panel following the cooling of a hot liquid in the container the initiator portion will flex inwardly to cause the control portion to invert and flex further inwardly into the container and the central portion to collapse. Raised ribs provide an additional support for the container in its collapsed state. In another embodiment the telescoping of the container back to its original position occurs when the vacuum force is released following removal of the container cap.

A bottle is provided for storing an associated fluid product when filled. The bottle includes a first wall having an opening therein that is selectively opened and closed to allow the associated fluid product to be dispensed therethrough or stored in the bottle, respectively. A second wall is spaced from the first wall, and a third wall extending between the first and second walls. A compliant pleat extends along substantially an entirety of the first wall, second wall, and third wall and divides the bottle into first and second portions. The compliant pleat allows the first and second portions to move toward one another in response to a predetermined force and thereby increase pressure in the closed bottle.

A polygonal bottle, and mouth, shoulder, drum, and bottom sections are formed in a bottle axial direction, the drum section including main wall sections connected via connecting sections in a circumferential direction about a bottle axis, in a lateral cross sectional view perpendicular thereto, a polygonal shape is formed, in which a panel section recessed inward in a radial direction, extending in the bottle axial direction and arriving at an upper portion of the mouth section side of the main wall section formed at the main wall sections of the drum section. A reinforcement protrusion protruding outward in the radial direction is formed at shoulder section connecting portions, a top surface directed outward in the radial direction is continued to an outer circumferential surface of the drum section with no step difference, and an upper surface directed upward is formed in a curved surface shape protruding upward.

The intermediate stretched-blow molded container (1) comprises a biaxially stretched-blow molded hollow body (10) that comprises a container side wall (10a), at least one recess (101) that is formed in said container side wall (10a), that is off-center from the second vertical central plane (P2), and at least one convex and outwardly protruding deformable region (102) that is formed in the container side wall (10a). The maximum gripping dimension (DR) of the stretched-blow molded hollow body (10) measured next to and on one side of the convex and outwardly protruding deformable region (102) is smaller than the maximum dimension (DL) of the stretched-blow molded hollow body (10) measured next to and on the other side of convex and outwardly protruding deformable region (102). Said convex and outwardly protruding deformable region (102) comprises an outwardly protruding invertable lateral wall (1020) that is an extension of a second lateral wall (1011) of the recess (101) and that extends beyond a first lateral wall (1010) of the recess (101), and a front wall (1021) that is an extension of this outwardly protruding invertable lateral wall (1020). The junction (H) between the bottom portion (1012) and the second lateral wall (1011) of said recess (101) forms an hinge on the whole periphery of the outwardly protruding convex deformable region (102) for inverting the said outwardly protruding convex deformable region ((102) and the second lateral wall (1011) of the recess (101) by pushing them inwardly in order to form a concave grip (G).