An in-line process for reusing printed cans is disclosed. The process includes positioning a printed can in front of a laser, the printed can having existing-print on an outer surface of the printed can. And, irradiating the outer surface of the printed can with laser radiation to remove 10% to 90% of the existing-print from the printed can and thereby form a lightened-printed can. And further, coating the outer surface of the lightened-printed can with a masking agent to form a blank-reprintable can. Finally, optionally, printing a new print-pattern on the outer surface of the blank-reprintable can to form a newly-printed can.

The invention provides an amorphous copolymerized polyester raw material for a film. The raw material contains ethylene terephthalate as a main constituent component, and contains from 18% by mol to 30% by mol of neopentyl glycol when a total amount of a glycol component in a total polyester resin component is taken as 100% by mol. The raw material contains from 8% by mol to 16% by mol of a constituent unit derived from diethylene glycol in the total amount (100% by mol) of the glycol component in the total polyester resin component. The raw material has an intrinsic viscosity of from 0.70 dl/g to 0.86 dl/g. The raw material has a melt viscosity of 200 Pa.Math.S or less, when measured at a shear rate of 6080/S at 250° C.

The invention provides an amorphous copolymerized polyester raw material for a film. The raw material contains ethylene terephthalate as a main constituent component, and contains from 18% by mol to 30% by mol of neopentyl glycol when a total amount of a glycol component in a total polyester resin component is taken as 100% by mol. The raw material contains from 8% by mol to 16% by mol of a constituent unit derived from diethylene glycol in the total amount (100% by mol) of the glycol component in the total polyester resin component. The raw material has an intrinsic viscosity of from 0.70 dl/g to 0.86 dl/g. The raw material has a melt viscosity of 200 Pa.Math.S or less, when measured at a shear rate of 6080/S at 250° C.

Briefly, a portable leak-proof container for liquid and/or solid materials is disclosed. In particular embodiments, the container may include a substantially planar base that is circular in shape and a plurality of panels abutting the substantially planar base, in which the plurality of panels are encased within a wall having a truncated cone shape. The wall having the truncated cone shape may be fused with the substantially planar base.

Briefly, a portable leak-proof container for liquid and/or solid materials is disclosed. In particular embodiments, the container may include a substantially planar base that is circular in shape and a plurality of panels abutting the substantially planar base, in which the plurality of panels are encased within a wall having a truncated cone shape. The wall having the truncated cone shape may be fused with the substantially planar base.

Systems and methods for printing a plurality of images on a substrate include, for each of the plurality of images: determining whether that image is a removable image or a permanent image, identifying, based on the determination, at least one layer to be used for printing that image in addition to a marking material layer that forms the image. The at least one layer may be a pre-coat layer applied under the marking material layer and/or a post-coat layer applied over the marking material layer. The marking material layer and the at least one layer are then printed on the object.

Systems and methods for printing a plurality of images on a substrate include, for each of the plurality of images: determining whether that image is a removable image or a permanent image, identifying, based on the determination, at least one layer to be used for printing that image in addition to a marking material layer that forms the image. The at least one layer may be a pre-coat layer applied under the marking material layer and/or a post-coat layer applied over the marking material layer. The marking material layer and the at least one layer are then printed on the object.

A container for holding a fluid is disclosed. The container comprises an inner sleeve having a first opening and a second opening opposite the first opening, and an outer sleeve having a third opening and a fourth opening opposite the third opening. The inner sleeve and the outer sleeve are made of paper. The first opening has a first reinforcing element which extends into the first opening, and the third opening has a second reinforcing element which extends into the third opening. Further, the container comprises a functional insert. The outer sleeve has a larger diameter than the inner sleeve so that the inner sleeve is insertable into the outer sleeve through the fourth opening such that the insert is fastened between the first reinforcing element and the second reinforcing element.

A container for holding a fluid is disclosed. The container comprises an inner sleeve having a first opening and a second opening opposite the first opening, and an outer sleeve having a third opening and a fourth opening opposite the third opening. The inner sleeve and the outer sleeve are made of paper. The first opening has a first reinforcing element which extends into the first opening, and the third opening has a second reinforcing element which extends into the third opening. Further, the container comprises a functional insert. The outer sleeve has a larger diameter than the inner sleeve so that the inner sleeve is insertable into the outer sleeve through the fourth opening such that the insert is fastened between the first reinforcing element and the second reinforcing element.

A cup holder that includes a sleeve, which is expandable from a flat position to an open position, in which the sleeve is configured to receive a cup; and a handle having first and second ends coupled to the sleeve to form a loop, wherein at least one perforation associated with at least one of the first and second ends of the handle provides for adjustability of the loop relative to the sleeve.