A magnetic apparatus for anchoring ferrous elements may include a support structure housing a plurality of polar units. The support structure has first and second sides at opposite surfaces. The polar units may include: a coil having a support and a conductive element wound on the support; a first magnetic core with a first coercive value, generating a first magnetic flow oriented in a first magnetic direction; and a plurality of second magnetic cores, each having its own coercive value different from the first coercive value. A first part of the second magnetic cores generates a second magnetic flow oriented in a second magnetic direction. A second part of the second magnetic cores generates a third magnetic flow oriented in a third magnetic direction. The third magnetic direction is parallel or antiparallel to the first magnetic direction and has a different direction with respect to the second magnetic direction.

A platen having improved thermal conductivity and reduced friction is disclosed. In one embodiment, vertically aligned carbon nanotubes are grown on the top surface of the platen. The carbon nanotubes have excellent thermal conductivity, thus improving the transfer of heat between the platen and the workpiece. Furthermore, the friction between the carbon nanotubes and the workpiece is much lower than that with conventional embossments, reducing particle generation. In another embodiment, a support plate is disposed on the platen, wherein the carbon nanotubes are disposed on the top surface of the support plate.

A platen having improved thermal conductivity and reduced friction is disclosed. In one embodiment, vertically aligned carbon nanotubes are grown on the top surface of the platen. The carbon nanotubes have excellent thermal conductivity, thus improving the transfer of heat between the platen and the workpiece. Furthermore, the friction between the carbon nanotubes and the workpiece is much lower than that with conventional embossments, reducing particle generation. In another embodiment, a support plate is disposed on the platen, wherein the carbon nanotubes are disposed on the top surface of the support plate.

A platen having improved thermal conductivity and reduced friction is disclosed. In one embodiment, vertically aligned carbon nanotubes are grown on the top surface of the platen. The carbon nanotubes have excellent thermal conductivity, thus improving the transfer of heat between the platen and the workpiece. Furthermore, the friction between the carbon nanotubes and the workpiece is much lower than that with conventional embossments, reducing particle generation. In another embodiment, a support plate is disposed on the platen, wherein the carbon nanotubes are disposed on the top surface of the support plate.

A platen having improved thermal conductivity and reduced friction is disclosed. In one embodiment, vertically aligned carbon nanotubes are grown on the top surface of the platen. The carbon nanotubes have excellent thermal conductivity, thus improving the transfer of heat between the platen and the workpiece. Furthermore, the friction between the carbon nanotubes and the workpiece is much lower than that with conventional embossments, reducing particle generation. In another embodiment, a support plate is disposed on the platen, wherein the carbon nanotubes are disposed on the top surface of the support plate.

A fixture assembly for supporting a plurality of blanks during a welding operation. The fixture assembly includes a frame. A plurality of electromagnets are positioned on the frame for supporting the blanks and for drawing the blanks toward the electromagnets to secure the blanks into a desired position. A plurality of intensifiers are moveably connected to the frame for selectively overlying the top face of one of the electromagnets for clamping the blank against the electromagnet to intensify a magnetic force provided by the electromagnet. A plurality of electromagnet adjusters are each coupled with the frame and with at least one of the electromagnets for moving the electromagnets relative to the frame. A plurality of adjusting pins are each connected to the frame and moveable relative to the frame for adjusting a position of the blanks.

Tools for replacing knives in cutting machines. The tools include a clamping body having a base, bracket, clamp, and knife support tab(s). The bracket has a flange portion spaced apart from an upper surface of the base. The clamp is coupled to the base for translating in translation directions transverse to a longitudinal axis of the base. The clamp has a lift tab on the same side of the base as a rear surface thereof, and a handle is secured to the flange portion of the bracket and located on the same side of the base as the lift tab. The support tab projects from the front surface of the base, and the clamp is biased toward the support tab so that the clamp and support tab create a knife gripping mechanism for clamping an edge of a knife against the tab.

Disclosed is a magnetic force control device improved to be installed even in a narrow space having a small height. The magnetic force control device includes a first pole piece having a first interaction surface, a second pole piece having a second interaction surface, a third pole piece connected to the second pole piece, a coil wound around at least one of the second pole piece and the third pole piece, a stationary magnet fixed between the first pole piece and the second pole piece and a rotary magnet disposed between the first pole piece and the third pole piece and configured to be rotatable by controlling a current flowing through the coil.

A magnet chuck has a piston assembly including a tube shaped permanent magnet and a core yoke able to move on the interior of a cylinder tube. The permanent magnet is provided on the outer periphery of the core yoke, is magnetized in the radial direction, and a magnetic sensor is attached to the side surface of the cylinder tube.

Disclosed is a machining center. The machining center includes a bed structure deflected along a deflection curve by a load distribution thereon, a palette structure secured to a first end portion of the bed structure, a spindle assembly to which a machining tool is secured and secured to a second portion of the bed structure, a table movably secured to the bed structure such that a table loading is applied to a load point of the bed structure and an automatic aligner automatically detecting first and second installation errors of the table and the spindle assembly and automatically correcting the first and the second installation errors such that the workpiece and the tool are aligned with each other. The misalignment between the workpiece and the tool is automatically detected and corrected in the machining center.