An electrode rolling apparatus includes a rolling roll that rolls an electrode substrate, and a rolling roll cooling unit that supplies a cooling medium to the inside of a rolling roll to cool the rolling roll, wherein the cooling medium transferred through the rolling roll cooling unit flows through the outer portion of the rolling roll.

An electrode rolling apparatus includes a rolling roll that rolls an electrode substrate, and a rolling roll cooling unit that supplies a cooling medium to the inside of a rolling roll to cool the rolling roll, wherein the cooling medium transferred through the rolling roll cooling unit flows through the outer portion of the rolling roll.

A motion generation device is configured to generate motion of a slide of a press device including the slide to which an upper die is attached, a bolster on which a lower die is placed, and a servomotor configured to move the slide reciprocally in the up and down direction. The motion generation device includes a motion generation section. The motion generation section is configured to generate a derivative motion of the slide at a cycle time different from the cycle time of the standard motion of the slide, such that the derivative motion includes the same motion as a first region of the standard motion including at least from top dead center to the end position of the molding region, and the speed of the slide at top dead center of the derivative motion is the same as the speed of the standard motion.

A die of a stamping press includes: an upper portion including one or more first features and first bores that extend partially through the upper portion; magnets disposed within the first bores, respectively; a lower portion including one or more second features that are complementary to the first features and second bores at locations, respectively, that extend partially through the lower portion; and magnetic flux sensors that are disposed within the second bores, respectively, and that are adjacent to the magnets, respectively, and that are configured to measure distances between the upper and lower portions at the locations.

The embodiments of the disclosure concern solar power operation controller to control a solar operated actuator system. An embodied solar controller, of a solar power operated actuator system, includes, an input for power feed from a solar panel for the solar controller powering, at least one sensor input in an ensemble of sensor inputs for providing sensor data to the solar controller, a functional connection to control a solar panel produced electricity for an accumulator charging, a functional connection to control accumulator laden charge for an actuator operation.

A transfer device transfers a workpiece by a transfer motion which is based on a transfer individual phase signal synchronized with a master phase signal, and includes: a setting unit that sets a point on a trajectory of a transfer bar as a switching point of a timing switch, the point on the trajectory being separated from a reference point on the trajectory by a designated distance designated by a user, and the trajectory being based on the transfer motion; and a signal output unit that outputs a timing signal to an external device at a timing when the transfer bar reaches the switching point.

A bonding machine with horizontal correction function includes a first chamber, a second chamber, a pressing unit, a carrier, a plurality of level adjustment units, and a plurality of distance measuring units. The first chamber is configured to be connected to the second chamber to define an enclosed space therebetween. The pressing unit is disposed within the first chamber, and the carrier is disposed within the second chamber. The pressing unit faces the carrier and is configured to press the substrates placed on the carrier. The leveling units are disposed on the first chamber, and the distance measuring units are disposed on the second chamber. Each distance measuring unit is configured to project a detecting beam onto the pressing unit, to measure the level of the pressing unit so as to adjust the level of the pressing unit through the level adjustment unit.

A filling unit (10) for a rotary press (12) with a filling wheel (14), a dosing wheel (24), optionally a feed wheel (30) and a medium feed unit (36), wherein the blades (22, 28, 34) of the filling wheel (14), dosing wheel (24) and/or feed wheel (30) designed as an impeller wheel (20, 26, 32), are designed in such a way that a conveying surface (40) of the respective blades (22, 28, 34) can be varied in shape, and a method for providing an optimized rotary press is proposed.

A filling unit (10) for a rotary press (12) with a filling wheel (14), a dosing wheel (24), optionally a feed wheel (30) and a medium feed unit (36), wherein the blades (22, 28, 34) of the filling wheel (14), dosing wheel (24) and/or feed wheel (30) designed as an impeller wheel (20, 26, 32), are designed in such a way that a conveying surface (40) of the respective blades (22, 28, 34) can be varied in shape, and a method for providing an optimized rotary press is proposed.

A press machine is provided. Two vertical hydraulic cylinders are arranged on an upper beam plate of a press machine body, and the two hydraulic cylinders correspond to workbenches at corresponding positions in a one-to-one correspondence, constituting left and right working units, and a common mechanical drive unit and a common hydraulic drive unit are set for the left and right working units. The mechanical driving unit is composed of a driving motor through an electromagnetic clutch, an electromagnetic brake and lead screw nut driving mechanism driven by a gear pair. According to the load profiles during the working process of hydraulic press machine, the mechanical driving unit or the hydraulic driving unit are selected to provide energy for the two working units. A control method for the press machine, a press machine execution system and a control method for the press machine execution system are further involved.