In some embodiments, a container includes a cover placed on the container. Shrinkable material that is placed on the container where the shrinkable material is shrunk around the container and the cover. The shrinkable material includes a tamper indicator. A cap is placed over the shrinkable material where the cap covers the shrinkable material such that the shrinkable material is not shown below the cap.

A resin coated metal sheet for container includes a polyester resin coating layer in which 90 mol % or more of structural units are ethylene terephthalate units. A half-value width of a peak attributable to C═O stretching vibration around 1,730 cm.sup.−1 determined from laser Raman spectroscopic analysis measured by making a plane of polarization of linearly polarized laser light incident on a thickness direction section of the polyester resin coating layer perpendicularly to a thickness direction is 18.5 cm.sup.−1 to 22.0 cm.sup.−1 at a position with a thickness of 1.0 μm from a metal sheet side of the polyester resin coating layer and is greater than 17.0 cm.sup.−1 and 18.5 cm.sup.−1 or less at a position with a thickness of 1.0 μm from a surface side of the polyester resin coating layer.

A resin coated metal sheet for container includes a polyester resin coating layer in which 90 mol % or more of structural units are ethylene terephthalate units. A half-value width of a peak attributable to C═O stretching vibration around 1,730 cm.sup.−1 determined from laser Raman spectroscopic analysis measured by making a plane of polarization of linearly polarized laser light incident on a thickness direction section of the polyester resin coating layer perpendicularly to a thickness direction is 18.5 cm.sup.−1 to 22.0 cm.sup.−1 at a position with a thickness of 1.0 μm from a metal sheet side of the polyester resin coating layer and is greater than 17.0 cm.sup.−1 and 18.5 cm.sup.−1 or less at a position with a thickness of 1.0 μm from a surface side of the polyester resin coating layer.

A method of reducing static charge of a plastic container is provided. The method includes providing a PECVD coating of SiCOH, SiO.sub.x or SiOH to an external support surface of the container. The PECVD coating reduces static charge of the container compared to a reference container that is essentially identical to the container except that the reference container is uncoated.

Provided are a preform for manufacturing a synthetic resin container, in which a decorative layer (60) having three-dimensional design different from the conventional one is formed on the surface of a container main body (10a), and a synthetic resin container. In a preform (1) including a preform main body (1a) of a bottomed cylindrical shape that is opened to have a mouth portion (2) on one end side thereof, and a covering layer (6) configured to cover the preform main body (1a) except for a part thereof on a mouth portion (2) side, and a container (10) obtained by subjecting the preform to blow molding, a distal end side of the covering layer (6) (decorative layer (60)) is formed so as to reach a peripheral end edge of a neck ring (22) while covering a lower surface of the neck ring (22) that is provided on a lower end side of the mouth portion (2) and protrudes annularly along a circumferential direction.

A bottle decorated with a removable wrap includes a bottle and a removable wrap. The wrap includes a thin resilient planar body that is curved such that the body forms a structure resembling a portion of a cylinder. A decorative treatment is applied to the body. In a first state, the wrap is separated from the bottle, and the cylindrical structure is in a natural/default state and has a first radius. In a second state, the wrap is separated from the bottle, and the cylindrical structure is in a spread state and has a second radius. In a third state, the wrap is mounted around the bottle, the cylindrical structure is in a partially-spread mounting state and has a third radius such that bias in the partially-spread body is applied to the bottle. The second radius is larger than the third radius which is larger than the first radius.

Multi-compartment containers in accordance with embodiments of the invention are disclosed. In one embodiment, a device for storing multiple fluids in multiple compartments comprises a first compartment for storing a first fluid, a second compartment for storing a second fluid, wherein the second compartment is within the first compartment, a lid of the first compartment comprising a first aperture and a second aperture; and a holding lattice for holding the second compartment against the lid of the first compartment, wherein the second compartment is aligned with the second aperture of the lid.

A protective cover apparatus designed to couple to a container to minimize abrasions, deformation and damage to the container due to impact forces generated from contact with an object is provided. The container includes a top open end continuously connected to a closed bottom end by a side wall. The protective cover apparatus includes an upper bumper disposed around the container proximate the top open end, and a lower bumper coupled to the bottom closed end of the container. The lower bumper has a base continuously connected to a side wall. The base of the lower bumper has a plurality of internal ridges in contact with the bottom closed end of the container. The internal ridges of the lower bumper are designed to deform to absorb and redirect the impact forces from contact with the object away from the container.

A method for manufacturing a composite preform is provided, including preparing a preform that is formed from a plastic material, preparing a tubular heat shrinkable plastic member that is longer than the preform and has a margin for thermocompression bonding at one end, inserting the preform into the plastic member having the plastic member undergo thermal shrinkage by heating the preform and the plastic member, and bonding the margin of the plastic member by thermocompression.

An improved method for molding a plastic container within a mold including an RFID tag to generate a container which leaves a mold having an RFID tag bonded between the container and a label. This method provides for an improved integrally, extrusion blow molded container, label and RFID tag combination.