A quality prediction model generation method for a metal material manufactured through one or more processes includes: a first collection step of collecting a manufacturing condition of each of the processes for each of predetermined areas of the metal material; a second collection step of evaluating and collecting quality of the metal material manufactured through each process for each of the predetermined areas; a storage step of storing the manufacturing condition of each process and the quality of the metal material manufactured under the manufacturing condition in association with each other for each of the predetermined areas; and a model generation step of generating a quality prediction model that predicts quality of the metal material for each of the predetermined areas based on the stored manufacturing condition for each of the predetermined areas in each process.

Disclosed is a method for loading a sheet placement device of a flat bed machine tool with a material sheet, wherein the material sheet is supplied to the machining operation carried out by the flat bed machine tool, starting from a target position assigned to the machining operation in a machine coordinate system, and the flat bed machine tool comprises a camera system having at least one camera. The camera system is designed to produce captured images of the sheet placement device, which are calibrated three-dimensionally in relation to the machine coordinate system of the flat bed machine tool. The method comprises the steps: producing a captured image of the material sheet in the region of the sheet placement device; evaluating the captured image to determine an actual sheet position in the machine coordinate system; measuring a deviation of the determined actual sheet position from the target position; and using the measured deviation to align and position the material sheet.

A management apparatus includes a processor configured to: autonomously collect, even without an instruction from a user, attribute data concerning attributes of a product defined by a three-dimensional shape, in accordance with a collection rule for collecting the attribute data concerning the product, the attribute data being generated in individual process stages before the product is manufactured; associate the collected attribute data with three-dimensional shape data indicating the three-dimensional shape of the product, as attributes of the three-dimensional shape data, in accordance with a superimposition rule which defines association between the three-dimensional shape data and the attribute data concerning the product; and manage the three-dimensional shape data and the attributes of the product.

A leveling machine is automatically adjustable. A plurality of blank conditions are presented at a user interface. A selection of a first blank condition is received at the user interface. An arrangement of the rollers is determined based on the selection of the first blank condition. The rollers are moved based on the determined arrangement.

An accumulated wear amount calculation section calculates a wear amount of a blade edge of a punch and a wear amount of a blade edge of a die when a tool set of the punch and the die has processed a sheet metal once. The accumulated wear amount calculation section calculates an accumulated wear amount of the blade edge of the punch and an accumulated wear amount of the blade edge of the die by accumulating wear amounts of respective times when the tool set has processed the sheet metal multiple times. A tool management information managing section manages a state of the blade edge of each punch and each die by causing a tool management information storage section to store tool management information associating a tool identification code given to each punch and each die with the accumulated wear amounts calculated by the accumulated wear amount calculation section.

A management apparatus includes a processor configured to: autonomously collect, even without an instruction from a user, attribute data concerning attributes of a product defined by a three-dimensional shape, in accordance with a collection rule for collecting the attribute data concerning the product, the attribute data being generated in individual process stages before the product is manufactured; associate the collected attribute data with three-dimensional shape data indicating the three-dimensional shape of the product, as attributes of the three-dimensional shape data, in accordance with a superimposition rule which defines association between the three-dimensional shape data and the attribute data concerning the product; and manage the three-dimensional shape data and the attributes of the product.

Systems and methods of determining a difference of position between a malleable object and a target shape are described herein.

A leveling machine is automatically adjustable. A plurality of blank conditions are presented at a user interface. A selection of a first blank condition is received at the user interface. An arrangement of the rollers is determined based on the selection of the first blank condition. The rollers are moved based on the determined arrangement.

Provided is a method for manufacturing a metal card which is capable of allowing metal card antennas to have no interference with a metal sheet by including a processed plastic layer formed on the metal sheet, and an insulating sheet. The metal card is capable of improving sensitivity of antenna coil, thereby solving an existing problem of the difficulties in performing RF communication because of material characteristics of a metal layer.

A first cutting line is formed in a sheet metal by continuously cutting a first cutting path. A second cutting line is formed in the sheet metal by continuously cutting a second cutting path. The sheet metal is cut along a plurality of third cutting paths with a plurality of positions on the first cutting line as cutting start points and intermediate positions between the first cutting line and the second cutting line as cutting end points to form a plurality of first dividing lines. The sheet metal is cut along a plurality of fourth cutting paths with a plurality of positions on the second cutting line as cutting start points and the intermediate positions as cutting end points to form a plurality of second dividing lines.