A one piece plastic container for beverages, has a base region, a main body extending in the longitudinal direction of the plastic container to the base region and a mouth region with a container mouth, with the mouth region adjoining the main body in the longitudinal direction at least indirectly, wherein the base region has at least three standing feet, wherein at least one groove having a groove base extending in the circumferential direction over a circumferential angle is arranged between two, in particular adjacent feet. The wall of the container is curved inwards at least in sections in the region of the groove base of a groove.

A container may comprise a tubular body having a longitudinal axis and a rounded sidewall; a base portion; a rim portion; a vertical portion defined, in part, by the rounded sidewall, aligned along the longitudinal axis, and extending between the base portion and the rim portion; a plurality of grooves defined within the vertical portion, each of the grooves comprising a width defining opposing sides of each of the plurality of grooves, wherein: each of the plurality of grooves is aligned parallel with the longitudinal axis; the valley of each of the plurality of grooves is radially inset a distance from the vertical portion perimeter; and opposing sides of adjacently positioned ones of the plurality of grooves define a peak that is radially aligned with the vertical portion perimeter. The container may also comprise a set of base transition grooves extending between the base portion and the vertical portion and aligned parallel with the longitudinal axis.

A blow-molded lamination container includes an outer layer and an inner layer. The outer layer has a bottom and an air-inletting seam. The air-inletting seam is disposed through the bottom of the outer layer, and is formed from a tapering opening by cooling shrinkage. The inner layer is disposed in the outer layer, is capable of being filled with a content and contracts with respect to the outer layer, and is not nipped within the air-inletting seam by the outer layer. A width of a widest portion of the air-inletting seam is at least twice greater than a width of a narrowest portion of the air-inletting seam. A manufacturing method for the blow-molded lamination container is also provided.

The invention provides for a dispenser package comprising a generally cylindrical container body and a cap removably mounted to the container body. The cap comprises a generally cylindrical cap body securable to an upper end of the container body. The cap body comprises a generally circular projecting portion having an outer circumferential surface and an upper surface that includes plural dispensing openings. A generally circular flip-up lid is connected to the cap body by a living hinge and being movable between a covering position and an open position.

A conveying system, comprising a modular conveyor belt supported on a conveyor track so that top surfaces of the modules of the conveyor belt present a conveying face that in use moves along the track in a conveying direction, and at least one plastic bottle supported at its bottom on the conveying face via one or more textured surfaces at a bottom of the bottle. The disclosure also includes a method of conveying bottles, wherein plastic bottles are supported with their bottoms on a moving conveying face of a conveyor, and wherein the conveying face and the bottom of the bottle are conveyed via one or more textured surfaces at a bottom of the bottle. The disclosure further includes use of at least one textured bottom surface of a plastic bottle for conveying, and a blow mold for blow molding a plastic bottle.

The invention concerns a bottle (1) molded from at least one thermoplastic polymer of at least one Furan Dicarboxylic Acid (FDCA) monomer, preferably 2,5-Furan Dicarboxylic Acid (2,5-FDCA) monomer, and at least one diol monomer, preferably Monoethyleneglycol (MEG) monomer, said bottle, having a main axis (X), being provided with a body (5) and a bottom base (6) extending from a lower end of the body (5). The bottom base (6) comprises:a peripheral seat (7) defining a laying plane (8);a concave arch (10) which extends from the periphery of a central zone (11) of the bottom base (6) to the peripheral seat (7), said concave arch (10) having a rounded general shape with a concavity turned towards the outside of the container (1) and the middle point of the central zone (11) being named push-up (11a);a series of reinforcing grooves (13) which extend radially from the central zone (11) to at least the peripheral seat (7);base feet (14) located between two adjacent reinforcing grooves (13); According to the invention, the bottle bottom base (6) comprises an offset sitting radius, defined as the distance between the maximum bottle diameter and the contact point of the base feet with the laying plan (8) that is in the range of 5 to 10 mm for a bottle having a diameter (D) between 40 and 150 mm.

The invention concerns a bottle (1) molded from at least one thermoplastic polymer of at least one Furan Dicarboxylic Acid (FDCA) monomer, preferably 2,5-Furan Dicarboxylic Acid (2,5-FDCA) monomer, and at least one diol monomer, preferably Monoethyleneglycol (MEG) monomer, said bottle, having a main axis (X), being provided with a body (5) and a bottom base (6) extending from a lower end of the body (5), The bottom base (6) comprises: a peripheral seat (7) defining a laying plane (8); a concave arch (10) which extends from the periphery of a central zone (11) of the bottom base (6) to the peripheral seat (7), said concave arch (10) having a rounded general shape with a concavity turned towards the outside of the container (1) and the middle point of the central zone (11) being named push-up (11a); a series of reinforcing grooves (13) which extend radially from the central zone (11) to at least the peripheral seat (7); base feet (14) located between two adjacent reinforcing grooves (13); According to the invention, the bottle bottom base (6) comprises a push-up height, defined as the height between the push-up (11a) and the laying plan (8), that is in the range of 7 to 10 mm for a bottle having a diameter (D) between 40 and 150 mm.

This disclosure provides new carbonated beverage bottle design, particularly carbonated soft drink bottle bases, that can afford improvements in various structural and functional features of the blow molded bottles. The bottle base design can be generated by providing a spherical bottle end cap and extruding at least three (3) feet from the spherical end cap, wherein the center portion of each valley cross section between the extruded feet is convex.

A beverage container for a carbonated beverage may include a base with a plurality of feet extending therefrom. The feet may act to reinforce a punt in the base of the beverage container to prevent deformation of the base of the beverage container when a carbonated or other pressurized beverage is added to the beverage container.