Container assembly for collecting pads, such as cosmetic pads or medical pads, wherein the container assembly comprises an elongate shell extending along a collecting axis parallel to a stacking direction and in a circumferential direction about the collecting axis, wherein the shell comprises a top side, a bottom side opposite to said top side in the stacking direction, wherein the shell is open at said top side for receiving the pads in said stacking direction and along said collecting axis, wherein the shell comprises a first shell segment and a second shell segment extending along said collecting axis between the top side and the bottom side and movable relative to one another in a clamping direction transverse to the stacking direction, wherein the second shell segment is biased relative to and towards the first shell segment in said clamping direction.

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 die output lane assembly for receiving a blank through an opening of a die-cutter machine includes a frame, a support structure, and a memory device. The support structure is attached to the frame to form a lane and is configured to receive the blank from the opening of the die-cutter machine and temporarily store the blank in the lane. The memory device is configured to store data associated with the die output lane assembly thereon. The data includes at least one of a dimension of the die output lane assembly, a dimension of a cutting die of the die-cutter machine, a dimension of the blank, a pick position for removing the blank, a retraction path for removing the blank, a speed of part handling, or placement position data for storing the blank.

A method for manufacturing a steel sheet having a yield strength YS of more than 1000 MPa, a tensile strength TS of more than 1150 MPa and a total elongation E of more than 8%, comprising the steps of: —preparing a steel sheet through rolling from a steel containing in percent by weight 0.19% to 0.22% C, 2% to 2.6% Mn, 1.45% to 1.55% Si, 0.15% to 0.4% Cr, less than 0.020% P, less than 0.05% S, less than 0.08% N, 0.015% to 0.070% Al, the reminder being Fe and unavoidable impurities, —soaking the sheet at an annealing temperature TA between 860° C. and 890° C. for a time between 100 s and 210 s, cooling the sheet to a quenching temperature QT between 220° C. and 330° C., from a temperature TC not less than 500° C. at a cooling speed not less than 15° C./s, heating the steel sheet during a time between 115 s and 240 s up to a first overaging temperature TOA1 higher than 380° C., then heating the sheet during a time between 300 s and 610 s up to a second overaging temperature TOA2 between 420° and 450° C., cooling the steel sheet to a temperature less than 100° C. at a cooling speed less than 5° C./s. The structure of the steel containing more than 80% of tempered martensite, more than 5% of retained austenite, less than 5% of ferrite, less than 5% of bainite and less than 6% of fresh martensite.

Methods and apparatus for stripping away portions of substrate are disclosed herein. In some embodiments, a flexible and/or soft impact-element(s) rotates around a rotation axis to drive a peripheral portion across a substrate plane of the substrate and/or to repeatedly collide with the substrate. At least some of the collisions are effective to partially dislodge or to strip away portion(s) of substrate.

A sheet bundle cutting apparatus includes a cutting portion (65) configured to cut, from a sheet bundle having one end bound with adhesive, a cutting scrap including a part of a spine of the sheet bundle, a pressure portion (59) configured to press the sheet bundle in a thickness direction while sandwiching a first surface and a second surface of the sheet bundle, and a bookbinding apparatus control CPU configured to control the pressure portion (59) and the cutting portion (65). The bookbinding apparatus control CPU causes the pressure portion (59) to press connection areas connected to the spine and respectively provided on the first surface and the second surface, and then causes the cutting portion (65) to cut the sheet bundle so that the cutting scrap includes a pressed area pressed by the pressure portion (59). Accordingly, it is possible to suppress spreading of the cutting scraps.

In a method of operating a flat-bed die-cutter a printing substrate in the form of a web is fed to a die-cutting module of the flat-bed die-cutter, a web section is severed from the web and removed as waste. The web is guided through the die-cutting module and the web section is severed from the web in or downstream of the die-cutting module and removed as waste. Products are thus formed by die-cutting a web while reducing waste and periods of standstill.

A method for removing a workpiece from the remainder of the workpiece supported in a bearing plane. The method includes moving the workpiece part, which is clamped between at least one ejector element of an ejection unit and at least one counter-holding element of a counter-holding unit, along a removal direction, and checking whether the workpiece part has been completely separated from the remainder of the workpiece during movement along the removal direction. The method is characterized by reducing or completely canceling the clamping of the workpiece part and subsequently resuming the clamping of the workpiece part if it is determined during checking that the workpiece part has not been completely separated from the remainder of the workpiece.

The invention relates to a method for cross-cutting a material web (1), in particular a pulp web or the like, that is moved in a direction of movement (2), wherein the material web (1) is moved through between two axes of rotation oriented approximately perpendicularly to the direction of movement (2), about which axes of rotation cooperating blades (3, 4) are moved with a rotary movement, said blades (3, 4) cutting the material web (1) approximately perpendicularly to the direction of movement (2) as said material web (1) passes through between the axes of rotation. In order to achieve a high-quality cut edge with little noise pollution and high system availability, the invention provides that, after the material web (1) has been cut, a force is applied to a part of the material web (1) that is carried along with a blade (3, 4) and in particular a part of the material web (1) that bears against a blade (3, 4), in order to separate the material web (1) from the rotary movement of the blade (3, 4). Furthermore, the invention relates to a device for cross-cutting a material web (1) that is moved in a direction of movement (2), having at least two cooperating blades (3, 4), which are rotatable about axes of rotation arranged approximately perpendicularly to the direction of movement (2), wherein the material web (1) is movable through between the axes of rotation, such that the material web (1) is able to be cut by the blades (3, 4) approximately transversely to the direction of movement (2).