Methods, devices and systems for machining plate-like workpieces, in particular metal sheets, are provided. In one aspect, a plate workpiece processing device has an upper tool and a lower tool. The upper tool and the lower tool can be moved toward each other to machine a workpiece arranged between. The upper tool has a clamping shaft and a base body, which include a common position axis. The upper tool also includes a machining tool arranged on the base body, opposite the clamping shaft. The lower tool has a base body which includes a supporting surface for the workpiece and an opening located within the supporting surface. A tool body accommodating the machining tool has a longitudinal axis which is inclined with respect to the positioning axis of the upper tool.

A tool for machining a planar workpiece, comprising an upper tool having a clamping shaft and an upper main body that lie on a common positioning axis, a tool body arranged opposite to the clamping shaft on the upper main body, the tool body comprising a bending edge, and a lower tool having a lower main body that receives a rotational body that is rotatable around an axis of rotation running in a direction of the bending edge of the tool body, wherein the upper tool and the lower tool are movable towards and away from each other in a stroke direction for machining the workpiece arranged therebetween, and wherein the upper main body defines a projection surface that is perpendicular to the positioning axis and the bending edge of the tool body is adjacent tangentially to the projection surface or is outside the projection surface.

A machine tool for machining planar workpieces includes an upper tool, a lower tool, a machine frame, and a controller. The upper tool is movable with a stroke movement along a stroke axis by a stroke drive device in a direction towards a workpiece and in the opposite direction and positionable with an upper traversing movement along an upper positioning axis by a motor drive assembly. The lower tool is aligned with the upper tool and is positionable with a lower traversing movement along a lower positioning axis by a motor drive assembly. The upper and lower tools are movable in a frame interior of the machine frame. The motor drive assemblies can be controlled by the controller. The upper and lower traversing movements can be controllable independently of each other. The upper tool can be controlled with the upper traversing movement and the stroke movement in a superposed manner.

A planar workpiece machining device has an upper tool and a lower tool that are movable toward each other in a reciprocation direction and in the opposite direction to machine a workpiece arranged therebetween. The upper tool has a clamping shaft, an upper main body, and a tool body arranged opposite the clamping shaft on the main body and having an upper bending edge. The lower tool has a lower main body, on which a counter tool body having a lower bending edge and a counter holder are provided. The lower bending edge is oriented facing the counter holder. The upper bending edge is stationary to the upper main body, and the lower bending edge is stationary to the lower main body. The upper bending edge is associated with an undercut on the tool body and the lower bending edge is associated with an undercut on the counter tool body.

Provided is a press apparatus which ensures high production efficiency and has less chances of breakdown. Specifically, the press apparatus has a base placed on a floor, and a platform arranged over the base to face the base and move up and down. A lower die, on which a steel plate is to be placed, is fixed to the base. An upper die is fixed to the platform to press the plate against the lower die and turn it into an initially formed product through a downward movement of the platform, and to pressure-hold the initially formed product with the lower die. A machining die is supported on the platform to move up and down to machine the initially formed product and form a final product by moving down while pressure-holding the initially formed product.

Scanning assemblies are disclosed herein. An example scanning assembly includes a slot scanner and a mounting system. The slot scanner includes an imaging assembly configured to capture an image frame appearing in a field of view (FOV) and a housing having a cavity configured to accommodate the imaging assembly. The mounting system includes a flange member at least partially surrounding an opening formed within the mounting system, and at least two support arms extending from the flange. The at least two support arms engage a portion of the housing of the slot scanner to retain the slot scanner within the opening formed by the flange.

The invention relates to a method (100) for producing a container (102) having an upper part (108), a lower part (110) and a receiving element (112), said method having at least the following steps: the lower part (110) is created (114) from a first starting material (200) in a first processing region (115a) of a processing device (115); the upper part (108) is created (116) from a second starting material (202) in a second processing region (115b) of the processing device (115); the receiving element (112) is fed (118) into the first processing region (115a) of the processing device (115); the lower part (110) receives (120) the receiving element (112) in the first processing region (115a) of the processing device (115); the upper part (108) is fed (122) from the second processing region (115b) of the processing device (115) into the first processing region (115a) of the processing device (115); and the upper part (108) and the lower part (110) are joined together (124) to form the container (102) in the first processing region (115a) of the processing device (115).

A method for manufacturing a stamped member includes the steps of: (1) stamping sheet metal within a stamping press system; (2) assembling the stamped sheet metal with other stamped members to form a plurality of bipolar plates; (3) pre-compressing the first bipolar plate between a pair of flat fixture plates; (4) obtaining first contact pressure variation data; (5) providing a customized patterned fixture which corresponds to the first contact pressure measurement data; (6) pre-compressing the second bipolar plate with the customized patterned fixture; and (7) obtaining second contact pressure variation data.

Provided is a metal gasket, which is capable of limiting localized decreases in contact pressure of the seal bead and of securing superior sealing over long periods. In order to achieve said purpose, the invention is a metal gasket, in which an opening that is open in the shape of the opening of the space to be sealed and a seal bead that extends along the perimeter of the opening are formed in a metal plate. The seal bead is one in which two or more portions from among half bead portions, fold-up bead portions and full bead portions are continuous with each other.

Provided is a method for manufacturing vehicle parts having ultra-high strength of 500 Mpa or more by using hot stamping. The method includes: forming a heated blank in a press forming apparatus; and taking out the formed blank from the press forming apparatus and consecutively cutting the blank with a trimming die. A blank temperature at the time of trimming may be 150 C. to 330 C.