The present disclosure relates to a cutting system for providing holes in a core material layer. The cutting system has a cutting tool having a cutting knife configured to cut through the core material layer, and an anvil having a rigid support surface for receiving the cutting knife of the cutting tool. The cutting system further has an elastic member that is positioned to absorb at least a part of a force applied when the cutting tool is pressed against said anvil.

A cutting unit for cutting preparation features in a web of sheetlike material is provided. The cutting unit has a first part with a rigid base portion, at least one first cutting tool configured to cut a first preparation feature in the web of sheetlike material, and at least one second cutting tool configured to cut a second preparation feature in the web of sheetlike material. The at least one first and second cutting tools are attached to the base portion and located at a distance from each other, wherein at least one of the at least one first or second cutting tools is supported by a flexible support that is located in the rigid base portion of the first part.

A perforating apparatus has a first roll and a second roll, each being operatively engageable with a support. The first roll has a first longitudinal axis about which the first roll rotates and a first anvil disposed on the first roll and having a first design. The second roll has a second longitudinal axis about which the second roll rotates. A second anvil is disposed on the second roll. The second anvil has a second design. At least one blade is disposed on the support so as to cooperate in interacting relationship with one of the first anvil and the second anvil when the support is operatively engaged with the one of the first anvil and the second anvil. The apparatus comprises two alternative paths for the web material.

A perforating apparatus has a first roll and a second roll, each being operatively engageable with a support. The first roll has a first longitudinal axis about which the first roll rotates and a first anvil disposed on the first roll and having a first design. The second roll has a second longitudinal axis about which the second roll rotates. A second anvil is disposed on the second roll. The second anvil has a second design. At least one blade is disposed on the support so as to cooperate in interacting relationship with one of the first anvil and the second anvil when the support is operatively engaged with the one of the first anvil and the second anvil. The apparatus comprises two alternative paths for the web material.

A perforating apparatus has a base having at least one counter component. The counter component has a length, L.sub.CC, and a nonlinear shape having a shape width, W. A support is operatively engaged with the base. A blade having a length, L.sub.B, is disposed on the support so as to cooperate in interacting relationship with the counter component. The blade has a plurality of teeth. A web material is perforated as it passes between the base and the support and the blade cooperates with the counter component. A driving means is associated with one of the support and the base to reciprocally shift the one of the support or the base for a distance, D, in a shifting direction. The distance, D, is at least the translational distance that one tooth travels to cover the shape width, W.

A perforating apparatus has a base having at least one counter component. The counter component has a length, L.sub.CC, and a nonlinear shape having a shape width, W. A support is operatively engaged with the base. A blade having a length, L.sub.B, is disposed on the support so as to cooperate in interacting relationship with the counter component. The blade has a plurality of teeth. A web material is perforated as it passes between the base and the support and the blade cooperates with the counter component. A driving means is associated with one of the support and the base to reciprocally shift the one of the support or the base for a distance, D, in a shifting direction. The distance, D, is at least the translational distance that one tooth travels to cover the shape width, W.

A label dispensing machine includes a label curving cover, and arched label output mechanism for outputting a continuous series of label strip to an inner side of the label curving cover where the lead end of the continuous series of label strip is curved by the label curving cover into an integral arch-shaped label. The label dispensing machine is disposed at one side of a film roll/bags-on-a-roll on a reel so that the arch-shaped label can be cut off and adhered to a cut-off lead end of the film roll/bags-on-a-roll and partially exposed to the outside of the tear line of the film roll/bags-on-a-roll easily for allowing the user to quickly find and lift the cut-off lead end of the film roll/bags-on-a-roll.

A label dispensing machine includes a label curving cover, and arched label output mechanism for outputting a continuous series of label strip to an inner side of the label curving cover where the lead end of the continuous series of label strip is curved by the label curving cover into an integral arch-shaped label. The label dispensing machine is disposed at one side of a film roll/bags-on-a-roll on a reel so that the arch-shaped label can be cut off and adhered to a cut-off lead end of the film roll/bags-on-a-roll and partially exposed to the outside of the tear line of the film roll/bags-on-a-roll easily for allowing the user to quickly find and lift the cut-off lead end of the film roll/bags-on-a-roll.

A method and an apparatus for producing a microporous metal foil by forming fine pores in a metal foil passing through a gap between a pattern roll having high-hardness fine particles on the surface and a hard metal roll; (a) a plastic sheet laminate comprising a soft plastic layer and a hard plastic layer having high tensile strength being interposed between the metal foil and the hard metal roll, with the soft plastic layer on the metal foil side; and (b) mechanical vibration being given to at least one of the pattern roll and the hard metal roll.

A method and an apparatus for producing a microporous metal foil by forming fine pores in a metal foil passing through a gap between a pattern roll having high-hardness fine particles on the surface and a hard metal roll; (a) a plastic sheet laminate comprising a soft plastic layer and a hard plastic layer having high tensile strength being interposed between the metal foil and the hard metal roll, with the soft plastic layer on the metal foil side; and (b) mechanical vibration being given to at least one of the pattern roll and the hard metal roll.