The invention relates to a sheet processing machine (01), comprising at least one infeed unit (200) and at least one shaping unit (300) and at least one stripping unit (400) and at least one multiple-up separating unit (500), wherein the sheet processing machine (01) comprises at least one drive (1001), wherein the at least one drive (1001) is configured to drive at least one stripping tool (402; 403) of at least one stripping mechanism (401) of the at least one stripping unit (400) and at least one multiple-up separating tool (502) of at least one multiple-up separating mechanism (501) of the at least one multiple-up separating unit (500) via at least one gear mechanism (1007), wherein at least one downstream gear mechanism (1019) is arranged downstream from the at least one gear mechanism (1007), wherein the at least one downstream gear mechanism (1019) is coupled to the at least one stripping tool (402; 403) of the at least one stripping unit (400) and/or to the at least one multiple-up separating tool (502) of the at least one multiple-up separating unit (500), wherein the at least one downstream gear mechanism (1019) is configured to convert at least one rotative movement into at least one reciprocating movement, wherein the at least one downstream gear mechanism (1019) is configured as a disk cam mechanism (1019). The invention likewise relates to a further sheet processing machine (01) and to a method for driving at least one tool (402; 403; 502) of a sheet processing machine (01).

The invention relates to a sheet processing machine (01), comprising at least one infeed unit (200) and at least one shaping unit (300) and at least one stripping unit (400) and at least one multiple-up separating unit (500), wherein the sheet processing machine (01) comprises at least one drive (1001), wherein the at least one drive (1001) is configured to drive at least one stripping tool (402; 403) of at least one stripping mechanism (401) of the at least one stripping unit (400) and at least one multiple-up separating tool (502) of at least one multiple-up separating mechanism (501) of the at least one multiple-up separating unit (500) via at least one gear mechanism (1007), wherein at least one downstream gear mechanism (1019) is arranged downstream from the at least one gear mechanism (1007), wherein the at least one downstream gear mechanism (1019) is coupled to the at least one stripping tool (402; 403) of the at least one stripping unit (400) and/or to the at least one multiple-up separating tool (502) of the at least one multiple-up separating unit (500), wherein the at least one downstream gear mechanism (1019) is configured to convert at least one rotative movement into at least one reciprocating movement, wherein the at least one downstream gear mechanism (1019) is configured as a disk cam mechanism (1019). The invention likewise relates to a further sheet processing machine (01) and to a method for driving at least one tool (402; 403; 502) of a sheet processing machine (01).

A sheet body is gripped (bound) by grip conveyance units, and conveyed as the grip conveyance units are displaced in this state. At the same time as this conveyance, the sheet body is held by delivering units, and delivered by a predetermined amount by the delivering units. After that, the sheet body is cut in predetermined size and shape by cutting molds.

The disclosure relates to forming shaped thermoplastic articles having smooth peripheries. Many thermoplastic articles have sharp edges formed upon molding or cutting the article from a feedstock sheet. Such sharp edges can damage thin plastic films or flesh which they contact, and smoothing the edges is desirable. Described herein are methods of forming a smooth periphery for such sharp-edged articles by rolling over the sharp edge. The smoothing operation is performed by forming a deflectable flange including a bend region separated from the potentially sharp peripheral edge by a spacer, deflecting a portion of the deflectable flange, and softening at least one bent portion of the deflectable flange to yield a smooth periphery upon cooling. The deflection can include curling the spacer at or near the peripheral edge. The methods can be performed incrementally and/or in a reciprocating fashion.

The disclosure relates to forming shaped thermoplastic articles having smooth peripheries. Many thermoplastic articles have sharp edges formed upon molding or cutting the article from a feedstock sheet. Such sharp edges can damage thin plastic films or flesh which they contact, and smoothing the edges is desirable. Described herein are methods of forming a smooth periphery for such sharp-edged articles by rolling over the sharp edge. The smoothing operation is performed by forming a deflectable flange including a bend region separated from the potentially sharp peripheral edge by a spacer, deflecting a portion of the deflectable flange, and softening at least one bent portion of the deflectable flange to yield a smooth periphery upon cooling. The deflection can include curling the spacer at or near the peripheral edge. The methods can be performed incrementally and/or in a reciprocating fashion.

An information handling system display may include a display panel cell, a mold frame, and a chip-on-film. The chip-on-film may be coupled to the display panel cell. The chip-on-film may include one or more protrusions. A first portion of the chip-on-film may be adjacent to the one or more protrusions across a width of a first surface of the chip-on-film. The one or more protrusions may be in contact with a mold frame of the display. The first portion of the chip-on-film adjacent to the one or more protrusions may not be in contact with the mold frame of the display.

An information handling system display may include a display panel cell, a mold frame, and a chip-on-film. The chip-on-film may be coupled to the display panel cell. The chip-on-film may include one or more protrusions. A first portion of the chip-on-film may be adjacent to the one or more protrusions across a width of a first surface of the chip-on-film. The one or more protrusions may be in contact with a mold frame of the display. The first portion of the chip-on-film adjacent to the one or more protrusions may not be in contact with the mold frame of the display.

A die press device includes a first platen for receiving installation of a die board comprising dies, a second platen capable of moving between a first position away from the first platen and a second position close to the first platen, a first chase bar and a second chase bar mounted on a surface of the first platen, and a control system for controlling a first movement of the first chase bar and a second movement of the second chase bar.

A die press device includes a first platen for receiving installation of a die board comprising dies, a second platen capable of moving between a first position away from the first platen and a second position close to the first platen, a first chase bar and a second chase bar mounted on a surface of the first platen, and a control system for controlling a first movement of the first chase bar and a second movement of the second chase bar.

A cutting apparatus of membrane electrode assembly for a fuel cell may include a cutting press including a cutting die disposed on a lower side of the feeding path and a driving cutter configured to be upwardly and downwardly movable on the cutting die at an upper side of the feeding path, and the cutting press disposed to a facility frame, a plurality of gripper modules disposed on the facility frame through a base member along a feeding direction of the membrane-electrode assembly sheet, and gripping both side edges of the membrane-electrode assembly sheet and a gripper driving unit disposed in the facility frame and moving the base member in a direction perpendicular to the feeding direction of the membrane-electrode assembly sheet and along the feeding direction of the membrane-electrode assembly sheet.