A packaged redeemable code system is disclosed. The packaged redeemable code system includes a paper insert having a front surface with a removable item, and a rear surface with redeemable code. The packaged redeemable code system further includes a paper sleeve having an interior that encloses the paper insert and conceals the redeemable code. The paper sleeve also having a ripcord configured to open an edge of the paper sleeve to provide an access point for removal of the paper insert. The paper sleeve further having a front surface with a cutout extending therethrough. The cutout aligns with and provides visual access to the removable item. The removable item is a different color than or provides contrast with the front surface of the paper sleeve. The paper sleeve further having a rear surface with an activation code that is associated with the redeemable code.

Machinery for packaging articles (15, 15′) in preformed cartons (18), having a conveyor (19) for making cartons travel with an article resting on top of the carton, partially enclosed by the carton, comprising a closing station, in particular having first folding means (24) designed to lift a first side wall of the said carton arranged transversely to the carton progress direction (A) so that it is positioned against the article, in particular towards the rear of the article with respect to the carton progress direction, characterised by the fact that said closing station may be moved parallel to the carton progress direction, wherein the closing station is integral to a sliding surface (20) which is parallel to the surface (26) of the machine on top of which the cartons travel. Packaging method using a machine as described above.

Machinery for packaging articles (15, 15′) in preformed cartons (18), having a conveyor (19) for making cartons travel with an article resting on top of the carton, partially enclosed by the carton, comprising a closing station, in particular having first folding means (24) designed to lift a first side wall of the said carton arranged transversely to the carton progress direction (A) so that it is positioned against the article, in particular towards the rear of the article with respect to the carton progress direction, characterised by the fact that said closing station may be moved parallel to the carton progress direction, wherein the closing station is integral to a sliding surface (20) which is parallel to the surface (26) of the machine on top of which the cartons travel. Packaging method using a machine as described above.

The present invention relates to the forming of a container by folding a cardboard sheet with at least vertical flaps, using a forming device and a forming method. Such a device comprises an upstream conveyor driving said cardboard sheet in a direction of travel, a downstream conveyor, means for folding the vertical flaps, said folding means being situated symmetrically about said upstream conveyor, and is characterized in that, on each side, said folding means comprise a pair of downstream and upstream pushers forming a gripper, said pushers being actuated jointly from an open position toward a closed position of folding said corresponding vertical flaps, a support for each gripper, said support being mobile in said direction of travel.

The present invention relates to the forming of a container by folding a cardboard sheet with at least vertical flaps, using a forming device and a forming method. Such a device comprises an upstream conveyor driving said cardboard sheet in a direction of travel, a downstream conveyor, means for folding the vertical flaps, said folding means being situated symmetrically about said upstream conveyor, and is characterized in that, on each side, said folding means comprise a pair of downstream and upstream pushers forming a gripper, said pushers being actuated jointly from an open position toward a closed position of folding said corresponding vertical flaps, a support for each gripper, said support being mobile in said direction of travel.

This box assembling and packing system is provided: a first jig which is fixed at a predetermined position and against which a side part of a body of a packing box is thrust; a second jig which is fixed at a predetermined position and against which a flap part and a tuck part of the packing box are thrust; and a robot having two articulated arms. A first articulated arm of the two articulated arms holds and moves the packing box in a flatly collapsed form by a packing box holding mechanism, folds and raises the body of the flatly collapsed packing box into a rectangular tubular shape in cooperation with the first jig, and maintains the folded and raised body of the packing box in the rectangular tubular shape by a packing box rectangular tubular shape maintaining mechanism. The second articulated arm moves a folding member into contact with the flap part and the tuck part of the packing box being held by the packing box holding mechanism of the first articulated arm, forms each of a bottom and a lid of the packing box in cooperation with the second jig, and moves an object-to-be-packed being grasped by an object-to-be-packed grasping mechanism and inserts it into the body from an end portion at a timing between forming the bottom and forming the lid.

A non-transitory computer readable recording medium has an estimation model according to one aspect of the present invention recorded thereon, and the estimation model is included in a program to be executed by a computer and outputs output data estimated based on input data received. In response to receiving, as the input data, a change over time in an intensity of energy emitted from a sealing part of an object subjected to a sealing process through bonding, the estimation model estimates at least one of whether sealing of the object is good or whether the sealing of the object is defective and outputs an estimation result as the output data, the change over time being calculated based on an intensity of energy emitted at each of a first time point and a second time point that is later than the first time point.

A non-transitory computer readable recording medium has an estimation model according to one aspect of the present invention recorded thereon, and the estimation model is included in a program to be executed by a computer and outputs output data estimated based on input data received. In response to receiving, as the input data, a change over time in an intensity of energy emitted from a sealing part of an object subjected to a sealing process through bonding, the estimation model estimates at least one of whether sealing of the object is good or whether the sealing of the object is defective and outputs an estimation result as the output data, the change over time being calculated based on an intensity of energy emitted at each of a first time point and a second time point that is later than the first time point.

The invention relates to a method for automatically creasing a folded box having inserted packaged goods, wherein the side walls of the folded box are creased by means of a creasing station which comprises a creasing tool having a rotatably mounted creasing roller for creasing a planar workpiece and a rotatably mounted counter-pressure roller which are retained at one end on a common support, wherein the distance between the two rollers can be varied, wherein the creasing tool is fastened to a movement system for three-dimensional displaceability, and wherein the following steps are carried out: a) providing the folded box, which is open at the top in the vertical direction and has inserted packaged goods; b) determining the dimensions of the folded box and the filling height of the packaged goods; c) creasing the side walls of the folded box, a first side wall being creased at a first creasing height associated with the filling height determined in step b). The counter-pressure roller is mounted parallel to the creasing roller; the counter-pressure roller and the creasing roller can be displaced relative to one another in order to set a distance from one another; and, during the creasing process, when the creasing tool reaches a vertical edge of the folded box, the roller located outside the folded box is pivoted through 90° about the roller located inside the folded box, the distance between the creasing roller and the counter-pressure roller being changed.

The invention relates to a method for automatically creasing a folded box having inserted packaged goods, wherein the side walls of the folded box are creased by means of a creasing station which comprises a creasing tool having a rotatably mounted creasing roller for creasing a planar workpiece and a rotatably mounted counter-pressure roller which are retained at one end on a common support, wherein the distance between the two rollers can be varied, wherein the creasing tool is fastened to a movement system for three-dimensional displaceability, and wherein the following steps are carried out: a) providing the folded box, which is open at the top in the vertical direction and has inserted packaged goods; b) determining the dimensions of the folded box and the filling height of the packaged goods; c) creasing the side walls of the folded box, a first side wall being creased at a first creasing height associated with the filling height determined in step b). The counter-pressure roller is mounted parallel to the creasing roller; the counter-pressure roller and the creasing roller can be displaced relative to one another in order to set a distance from one another; and, during the creasing process, when the creasing tool reaches a vertical edge of the folded box, the roller located outside the folded box is pivoted through 90° about the roller located inside the folded box, the distance between the creasing roller and the counter-pressure roller being changed.