The present disclosure is directed toward a machine tool configured to perform small-scale, high-accuracy drilling operations for small-hole applications. The small-hole applications for which the machine tool is designed includes holes with one or more diameters. A part may have a larger-diameter hole that penetrates through a fraction of the thickness of a part and a smaller-diameter hole that penetrates from the bottom of the larger-diameter hole through the remainder of the part thickness. Additionally, the machine tool may be used with parts in any of the following categories: (i) both the step-hole and the flow-hole are created using the machine tool; or, (ii) the step-hole is created with an up-stream process and the machine tool may accept the part, measure the step-holes and create the flow-holes; or, (iii) no step-hole is used and the machine tool may accept the part, measure the raw surface and create the flow-holes.

The present disclosure is directed toward a machine tool configured to perform small-scale, high-accuracy drilling operations for small-hole applications. The small-hole applications for which the machine tool is designed includes holes with one or more diameters. A part may have a larger-diameter hole that penetrates through a fraction of the thickness of a part and a smaller-diameter hole that penetrates from the bottom of the larger-diameter hole through the remainder of the part thickness. Additionally, the machine tool may be used with parts in any of the following categories: (i) both the step-hole and the flow-hole are created using the machine tool; or, (ii) the step-hole is created with an up-stream process and the machine tool may accept the part, measure the step-holes and create the flow-holes; or, (iii) no step-hole is used and the machine tool may accept the part, measure the raw surface and create the flow-holes.

A production line for machining a surface component with a first machining station and a second machining station is disclosed. The first machining station includes a separating device configured to separate a surface component along a machining path. The second machining station includes a bending/forming device configured to form and/or bend the surface component in a bending/forming position. The first machining station and the second machining station are sequentially arranged one directly after the other and/or linked together.

A production line for machining a surface component with a first machining station and a second machining station is disclosed. The first machining station includes a separating device configured to separate a surface component along a machining path. The second machining station includes a bending/forming device configured to form and/or bend the surface component in a bending/forming position. The first machining station and the second machining station are sequentially arranged one directly after the other and/or linked together.

A wall-mounted, metal, poster hanger, manufactured from aluminum, steel, iron and nylon or similar, using CNC tooling, injection molding, and extrusion of 25-30 parts that configures said poster hanger. The poster hanger is constructed primarily of a wall mounted plate and a pivoting arm with extension capabilities connected by a hinge and pivot pin with washers, configured with three stationary hooks and one hook on the extension arm. A nylon, ABS, or similar, snap hook is designed to lock the pivoting arm in place. Pre hole-punched, various sized, plastic sheet protectors, and or transparent dividers, hang from grommeted holes in sleeves and or sheet protectors onto the four rings and or hooks.

A press frame includes a lower press frame, an upper press frame that supports a press mechanism, and a vertical press frame. A laser frame includes a lower laser frame, an upper laser frame that supports a laser mechanism, and a vertical laser frame. A transport space for a workpiece in the press frame and a transport space for the workpiece in the laser frame communicate with each other, the transportation in the spaces being performed by a transporter. The upper laser frame includes a joint extending from the vertical laser frame toward the upper press frame side while being spaced from the upper press frame, and that switches between a connected state where the upper press frame and an end of the upper laser frame are connected and a separated state where the connection therebetween is released.

A press frame includes a lower press frame, an upper press frame that supports a press mechanism, and a vertical press frame. A laser frame includes a lower laser frame, an upper laser frame that supports a laser mechanism, and a vertical laser frame. A transport space for a workpiece in the press frame and a transport space for the workpiece in the laser frame communicate with each other, the transportation in the spaces being performed by a transporter. The upper laser frame includes a joint extending from the vertical laser frame toward the upper press frame side while being spaced from the upper press frame, and that switches between a connected state where the upper press frame and an end of the upper laser frame are connected and a separated state where the connection therebetween is released.

A system and method for drilling a hole in a vehicle structure and installing a fastener in the hole. A drill plate having openings and associated machine-readable elements is positioned on the structure. A drill gun is positioned in a particular opening and reads hole information from the associated element, and a computer determines whether the drill gun is properly set-up to drill the hole. A fastener insertion gun is positioned in the particular opening and reads fastener information from the element, and the computer determines whether the hole has been drilled and, if so, whether the fastener insertion gun is properly set-up to insert the fastener. A fastener delivery subsystem stores, tracks, and delivers fasteners to the fastener insertion gun. A system computer monitors the drilling of every hole, the insertion of every fastener, and the overall operation of the fastener delivery subsystem.

A system and method for drilling a hole in a vehicle structure and installing a fastener in the hole. A drill plate having openings and associated machine-readable elements is positioned on the structure. A drill gun is positioned in a particular opening and reads hole information from the associated element, and a computer determines whether the drill gun is properly set-up to drill the hole. A fastener insertion gun is positioned in the particular opening and reads fastener information from the element, and the computer determines whether the hole has been drilled and, if so, whether the fastener insertion gun is properly set-up to insert the fastener. A fastener delivery subsystem stores, tracks, and delivers fasteners to the fastener insertion gun. A system computer monitors the drilling of every hole, the insertion of every fastener, and the overall operation of the fastener delivery subsystem.

The present disclosure generally relates to methods and apparatuses for additive manufacturing using foil-based build materials. Such methods and apparatuses eliminate several drawbacks of conventional powder-based methods, including powder handling, recoater jams, and health risks. In addition, the present disclosure provides methods and apparatuses for compensation of in-process warping of build plates and foil-based build materials, in-process monitoring, and closed loop control.