Packaging apparatuses for loading and sealing products into a web of interconnected bags, and methods of using them, are provided. In one aspect, the packaging apparatus includes an intermittently advancing web conveyor that also indexes vertically to facilitate stacked loading of products into the bags. In another aspect, the packaging apparatus includes a dividing seal station that applies a center seal dividing the bag into separate sealed subcompartments, some of the bag contents being distributed to each compartment, such as one of two trays to each subcompartment. To facilitate distribution of contents and even sealing, the dividing seal station may include a dividing sealer lower support that oscillates vertically to promote settling of contents and gases in the bag before applying a dividing seal.

Packaging apparatuses for loading and sealing products into a web of interconnected bags, and methods of using them, are provided. In one aspect, the packaging apparatus includes an intermittently advancing web conveyor that also indexes vertically to facilitate stacked loading of products into the bags. In another aspect, the packaging apparatus includes a dividing seal station that applies a center seal dividing the bag into separate sealed subcompartments, some of the bag contents being distributed to each compartment, such as one of two trays to each subcompartment. To facilitate distribution of contents and even sealing, the dividing seal station may include a dividing sealer lower support that oscillates vertically to promote settling of contents and gases in the bag before applying a dividing seal.

A head for a horizontal flow wrapper packaging machine for forming a bandolier of product packages. The head includes a rotatable first shaft having a plurality of knife elements each including a blade and first and second upper crimping elements. The head also includes a rotatable second shaft having a plurality of anvil elements. A rotation speed of the second shaft is independent of the rotation speed of the first shaft. Each anvil element includes perforation and cutting surfaces and first and second lower crimping elements. A rotation speed of either the first shaft or second shaft is changed to move either a knife element or an anvil element, respectively, between a perforation position and a cutting position. The first upper and first lower crimping elements and the second upper and second lower crimping elements also mate to crimp the packaging material in either the perforating or cutting positions.

A head for a horizontal flow wrapper packaging machine for forming a bandolier of product packages. The head includes a rotatable first shaft having a plurality of knife elements each including a blade and first and second upper crimping elements. The head also includes a rotatable second shaft having a plurality of anvil elements. A rotation speed of the second shaft is independent of the rotation speed of the first shaft. Each anvil element includes perforation and cutting surfaces and first and second lower crimping elements. A rotation speed of either the first shaft or second shaft is changed to move either a knife element or an anvil element, respectively, between a perforation position and a cutting position. The first upper and first lower crimping elements and the second upper and second lower crimping elements also mate to crimp the packaging material in either the perforating or cutting positions.

A mechanism is described herein to drive slitter and cutter waste in a direction that allows for a more advantageous use of the waste collection bin's volume. The waste drive mechanism allows for at least one armature that drives the waste in a desired direction. The armature is made from a material that is flexible, with a curved shape to allow a pre-loaded force against a contact surface of the waste collection bin. The pre-loaded flexible armature against a contact surface of the collection bin provides sufficient force to drive the waste it in a desired direction, allowing for a more consistent use of the waste collection bin spatial volume.

A machining data generation apparatus 4 is used in a sheet process system, which executes a plurality of times of processes by using one or more sheet process apparatuses processing a sheet by performing one or more times of machining and obtains a product in a desired form from the sheet, and generates machining data for operating the sheet process apparatus, and the machining data generation apparatus 4 includes a machining condition input unit 51 that inputs a machining condition for obtaining the product in a desired form from the sheet; a data generation unit 8 that generates the machining data including each machining data piece for operating the sheet process apparatus in order to execute each process in the plurality of times of processes, on the basis of the input machining condition; and a data output unit 71 that outputs the generated machining data to the sheet process apparatus that executes each process.

An opening station for facilitating box opening may include a scanning station, an edge opening station, and a conveyor assembly. The scanning station is configured to measure a length “L”, height “H”, and/or width “W” of a substantially square box having a top, a bottom, two sides, and two edge portions. The edge opening station is configured to perform perforation operations on at least one of the two edge portions. A complete box opening system may include the scanning station, edge opening station, conveyor, and at least one of a top opening station and a side opening station.

A sheet processing machine has a stationary frame and includes a transport table for transporting and supporting a sheet material. The transport table includes a roller conveyor including a plurality of rollers and a gap between two of the plurality of rollers. The machine further includes a processing tool for processing the sheet material at a first side of the sheet material, as well as a marking tool for marking the sheet material at a second side of the sheet material, opposite the first side. The machine additionally has an XY-guide assembly arranged in or at the gap and connecting the marking tool to the stationary frame and enabling a movement of the marking tool with respect to the stationary frame. The movement of the marking tool with respect to the stationary frame is independently controllable relative to a movement of the processing tool with respect to the stationary frame.

Punched and incised portions can be formed properly, in which it is not necessary to replace an anvil depending on a type of a sheet material. A punching unit 51 comprises: a punching blade 50 for punching a first panel material 11, a second panel material 12, an open tape and a mounting base portion so as to form a punching portion; a incising portion 51 for incising the second panel material 12 and the mounting base portion disposed on the open tape so as to form a incising portion; and an adjusting portion 54 for adjusting a first gap 56 in a punching direction 5Z between edges 50A and 51A of the punching and incising blades 50 and 51.

An avocado cutting method discloses feeding, orientation and traveling along multi-lanes of avocados (A), a pre-cutting stage to create an incision in the upper and lower portions of each avocado (A) while the avocado (A) is held with its axis stem-blossom vertically oriented, and a cutting stage for cutting each avocado (A) in the sides thereof in order to divide the avocado (A) into two halves with simultaneous hit on its pit. A multi-lane machine is also disclosed having a cutting section (54) with a plurality of pairs of separate cutting blades (55). The cutting section (54) has a plurality of plungers (56) in the form of rods, each plunger (56) being movable between the separate cutting blades (55) with respect to an upper head (43) to strike the pit (N) and move it inside the avocado (A) in order to detach it from the pulp (P).