The double blank detecting device for a press machine uses a press machine with a die cushion device attached thereto, and automatically and repeatedly forms blank materials one by one. The double blank detecting device includes: a position signal acquiring unit that acquires a die cushion position signal indicating a position of a cushion pad of the die cushion device; a load signal acquiring unit that acquires a die cushion load signal indicating a die cushion load generated in the cushion pad of the die cushion device; and a double blank detecting unit that detects, as a double blank, a state where a plurality of the blank materials are overlapped, based on the die cushion position signal and the die cushion load signal that are acquired.

Systems, devices, and methods for fabricating finished parts include a system that includes a plurality of die assemblies located at a plurality of respective locations, each die assembly being configured to fabricate a respective finished part. The system further includes a movable gantry press and a robot, each configured to move between the plurality of respective locations. The system further includes a controller configured to receive a input to fabricate a finished part and identify a die assembly of the plurality of die assemblies. The controller is further configured to instruct the movable gantry press and the robot to move to the location of the die assembly. The controller is further configured to instruct the robot to load a blank into the die assembly, and instruct the movable gantry press to operate the die assembly to fabricate the finished part.

Systems, devices, and methods for fabricating finished parts include a system that includes a plurality of die assemblies located at a plurality of respective locations, each die assembly being configured to fabricate a respective finished part. The system further includes a movable gantry press and a robot, each configured to move between the plurality of respective locations. The system further includes a controller configured to receive a input to fabricate a finished part and identify a die assembly of the plurality of die assemblies. The controller is further configured to instruct the movable gantry press and the robot to move to the location of the die assembly. The controller is further configured to instruct the robot to load a blank into the die assembly, and instruct the movable gantry press to operate the die assembly to fabricate the finished part.

A drive unit (4) of the belt (3) for a molding machine (1) of bored fins comprises a fixed front part (12) and a movable rear part (13) driven longitudinally with a forward and backward movement to and from the fixed front part (12). Both parts (12, 13) of the drive unit (4) include support plates (16, 31) on the upper surfaces thereof for vertical teeth (20, 35) with oblique top (22, 37) which protrude upwards under elastic thrust (24, 39) and are suitable for being inserted into corresponding bored collars (52) of the belt (3) downstream of a boring unit (2). The upper surfaces of each of the two parts (12, 13) of the drive unit (4) support at least a further support plate (17, 32) for vertical teeth (21, 36) of greater diameter, which is liftable and lowerable by a control panel (50).

A Laminated core manufacturing device includes: an overlapping unit configured to overlap the plurality of laminated core materials conveyed along different conveyance routes; an edge aligning unit configured to align edge positions in a width direction of the plurality of laminated core materials between the plurality of laminated core materials; an uplift prevention unit configured to prevent uplift of the plurality of laminated core materials; an edge position correction unit configured to correct the edge positions in the width direction of the plurality of laminated core materials; and a punching unit configured to punch out the plurality of laminated core materials which are overlapped by the overlapping unit and have been subjected to an edge position alignment process performed by the edge aligning unit, an uplift prevention process performed by the uplift prevention unit, and an edge position correction process performed by the edge position correction unit.

A press machine includes a frame, a punch die supported by the frame, a guide track supported by the frame, and a heater coupled to the guide track. The punch die is driven through a punch stroke to punch a strip advanced through the press machine at a punch zone. The guide track has a guide rail forming a guide channel configured to receive the strip. The guide channel is aligned with the punch zone to guide the strip to the punch zone. The heater heats the guide rail to an elevated operating temperature. The guide rail is used for conduction heating of the strip as the strip passes through the guide track.

Producing a product from flexibly rolled metallic strip material comprises feeding a flexibly rolled strip material; determining a measured thickness profile of the strip material over the length of the strip material and calculating a desired cutting position for a blank to be produced from the strip material; separating a blank from the strip material in the desired cutting position; rotating the blank depending on the determined measured thickness profile such that the blank is aligned with its thickness profile in a defined processing position which differs from the desired cutting position; processing the blank in the processing position by a processing unit, wherein the blank is processed to form a product.

Control method for a press installation and installation, where the installation includes a servo press, a conveyor device for conveying pieces from a position of origin to the servo press, and a controller. The controller controls the movements of the conveyor device and of the servo press by means of one and the same master signal, causing a synchronized actuation of both. In the method, the pieces are conveyed to the position of origin and during the travel thereof until reaching the position of origin, the passage of the pieces through a predetermined position of reference before the position of origin is detected, and depending on the detection, the master signal is adjusted for adapting the actuation speed of the servo press.

A centering system comprising a conveyor for receiving a plurality of blanks outputted from a furnace and displacing the blanks along a first horizontal axis and shifting units for each individual blank including two or more adjustable lifting bars, the shifting units configured to move along a second horizontal axis, and the adjustable lifting bars being configured to lift the blanks along a vertical axis, wherein each of the shifting units is independently movable along the second axis, and a plurality of centering pins for centering the blanks, such that the blanks can be centered by moving the individual blanks along the second axis against the centering pins. Also disclosed are conveyor systems and methods for centering and conveying blanks.

Disclosed is a vertical strip accumulator. The vertical strip accumulator includes an inner drum unit having an inner drum; an outer drum unit installed at an outer side of the inner drum unit; a central drum unit installed at an inner side of the inner drum unit; and an input unit configured to carry a skelp supplied from an uncoiler to the outer drum unit. The outer drum unit includes an outer drum configured to selectively rotate forward and reverse; a first power source configured to provide a power to the outer drum; an outer roller installed to the outer drum; and a first control unit connected to the first power source to control the operation of the first power source. The input unit includes a carrying roller provided in contact with the skelp; a second power source configured to supply a power to the carrying roller; and a second control unit connected to the second power source to control the operation of the second power source.