A synthetic resin container that is formed in a bottle shape having a mouth and a trunk and that is provided in the trunk with at least one reduced pressure absorbing panel. The trunk has a density of 1.3695 g/cm.sup.3 or more, and a ratio of a crystal orientation in a transverse direction with respect to a total value of a crystal orientation in a machine direction and the crystal orientation in the transverse direction in the trunk is less than 44%.

A bottomed tubular-shaped preform is molded into a liquid-containing container holding a content liquid, by supplying, through a first supply path, a first liquid at a predetermined pressure into the preform that has been heated to a predetermined temperature to liquid blow mold the preform and by supplying, through a second supply path that is different from the first supply path, a second liquid into the preform after or simultaneously with the supply of the first liquid.

A bottomed tubular-shaped preform is molded into a liquid-containing container holding a content liquid, by supplying, through a first supply path, a first liquid at a predetermined pressure into the preform that has been heated to a predetermined temperature to liquid blow mold the preform and by supplying, through a second supply path that is different from the first supply path, a second liquid into the preform after or simultaneously with the supply of the first liquid.

A decorative multilayered extrusion-blow-formed bottle having an inner layer of a polyethylene (A) and a metallic layer of a polyethylene (B) in which a metal pigment having an average thickness of not more than 600 nm is dispersed on the outer side of the inner layer. If the shear viscosities (Pa.Math.s) of the resin forming the layer neighboring the metallic layer on the inner side thereof are denoted by V.sub.6 and V.sub.30 as measured at the shear rates 6 s.sup.1 and 30 s.sup.1 thereof at a temperature of 210 C., then the shear viscosities (Pa.Math.s) .sub.6 and .sub.30 of the polyethylene (B) measured at the shear rates 6 s.sup.1 and 30 s.sup.1 thereof at a temperature of 210 C. satisfy the following viscosity condition formulas (1) and (2):
.sub.6V.sub.62000(1)
.sub.30V.sub.302000(2)

A decorative multilayered extrusion-blow-formed bottle having an inner layer of a polyethylene (A) and a metallic layer of a polyethylene (B) in which a metal pigment having an average thickness of not more than 600 nm is dispersed on the outer side of the inner layer. If the shear viscosities (Pa.Math.s) of the resin forming the layer neighboring the metallic layer on the inner side thereof are denoted by V.sub.6 and V.sub.30 as measured at the shear rates 6 s.sup.1 and 30 s.sup.1 thereof at a temperature of 210 C., then the shear viscosities (Pa.Math.s) .sub.6 and .sub.30 of the polyethylene (B) measured at the shear rates 6 s.sup.1 and 30 s.sup.1 thereof at a temperature of 210 C. satisfy the following viscosity condition formulas (1) and (2):
.sub.6V.sub.62000(1)
.sub.30V.sub.302000(2)

The present disclosure is directed to the packaging of metal thin films deposited on polymeric substrates. The packaging method prevents deleterious change of surface energy/water contact angle as a function of time for metal thin films such as rolls, coils, sheets or strips of sputtered or vacuum deposited metal thin films. Methods and kits directed toward a unique packaging and storage scheme are also disclosed. This results in maintenance of the metal film's hydrophilicity and surface energy for extended periods of time.

The present disclosure is directed to the packaging of metal thin films deposited on polymeric substrates. The packaging method prevents deleterious change of surface energy/water contact angle as a function of time for metal thin films such as rolls, coils, sheets or strips of sputtered or vacuum deposited metal thin films. Methods and kits directed toward a unique packaging and storage scheme are also disclosed. This results in maintenance of the metal film's hydrophilicity and surface energy for extended periods of time.

A package including a container body (1) containing a fluid content (3) with leaving a head space (7), wherein the container body (1) has an inner surface (1a) on which ruggedness is formed entirely, the inner surface (1a) with the ruggedness of the container body (1) is coated with a lubricating liquid (30) immiscible with the fluid content (3), and the lubricating liquid (30) is present as a coating layer interposed between the inner surface (1a) and the fluid content (3), and the lubricating liquid (30) for forming the coating layer forms a liquid pool (31) at a periphery of an upper end face of the fluid content (3) contained in the container body (1) in a state of being held upright.

A fuel torch display assembly including a base member, an inner canister member coupled to the base member and with a can channel having the fuel canister disposed therein. The assembly includes an outer canister member of a transparent material defined on a portion thereon and an inner surface with a radial retention flange having an upper wall and a sidewall defining an inner canister member retention zone with an enclosed sidewall of the inner canister member disposed therein and the outer surface of the enclosed sidewall of the inner canister member and the inner surface of the enclosed sidewall of the outer canister member defining and flanking an indicia medium placement zone with an indicia medium selectively removably disposed therein adjacent to the transparent material to display an indicia disposed on the indicia medium to an outside ambient environment of the fuel torch assembly.