Provided is a plate bender for mandibular implants and the method employing it, which is intended for improving the bending process of mandibular plates or implants, reducing the number of folds (bents) until obtaining the desired geometry, further reducing fatigue failures, costs and streamlining the process, by providing a high-precision, semiautomatic bender, with modular and transportable assembly.

Devices and methods for bending or cutting implants are disclosed herein. In some embodiments, an instrument can include a rotatable drive shaft that urges first and second portions of a modular bending or cutting template toward one another to bend or cut an implant disposed between the template portions. A linkage assembly can be included to provide a mechanical advantage in urging the template portions toward one another. In some embodiments, an instrument can include a rotatable drive shaft that, depending on direction of rotation, pushes or pulls a first modular template portion with respect to a second modular template portion to bend an implant disposed between the template portions in one direction or another direction. In some embodiments, an instrument can include a worm drive that rotates a cutting wheel with respect to a cutting plate to cut an implant inserted through openings formed in the cutting wheel and the cutting plate.

Devices and methods for bending or cutting implants are disclosed herein. In some embodiments, an instrument can include a rotatable drive shaft that urges first and second portions of a modular bending or cutting template toward one another to bend or cut an implant disposed between the template portions. A linkage assembly can be included to provide a mechanical advantage in urging the template portions toward one another. In some embodiments, an instrument can include a rotatable drive shaft that, depending on direction of rotation, pushes or pulls a first modular template portion with respect to a second modular template portion to bend an implant disposed between the template portions in one direction or another direction. In some embodiments, an instrument can include a worm drive that rotates a cutting wheel with respect to a cutting plate to cut an implant inserted through openings formed in the cutting wheel and the cutting plate.

A coil banding device includes a tubular nozzle disposed to penetrate the central portion of the horizontal direction of the housing, the material coil being supplied therethrough, a nozzle moving means to move the nozzle in one direction, a banding means including a pair of roller members on an upper surface of the rotating member and sandwiching the material coil discharged from the nozzle to band in a set shape, a horizontal moving means for moving the banding means horizontally through a first plate slidably mounted to the housing, a vertical moving means for moving the banding means vertically through a second plate slidably mounted on the first plate, a first rotating means for rotating the banding means with respect to a horizontal axis through a third plate rotatably mounted on the second plate, and a second rotating means for rotating the banding means about a vertical axis by a planetary gear mounted on the second plate.

A coil banding device includes a tubular nozzle disposed to penetrate the central portion of the horizontal direction of the housing, the material coil being supplied therethrough, a nozzle moving means to move the nozzle in one direction, a banding means including a pair of roller members on an upper surface of the rotating member and sandwiching the material coil discharged from the nozzle to band in a set shape, a horizontal moving means for moving the banding means horizontally through a first plate slidably mounted to the housing, a vertical moving means for moving the banding means vertically through a second plate slidably mounted on the first plate, a first rotating means for rotating the banding means with respect to a horizontal axis through a third plate rotatably mounted on the second plate, and a second rotating means for rotating the banding means about a vertical axis by a planetary gear mounted on the second plate.

A method for forming a metal beam may comprise: clamping first and second portions of the metal beam in a substantially fixed and in a position whereat the metal beam is rotatable about three axes; applying a net bending force to the clamped second portion of the metal beam at a predetermined angle; sensing twisting of the second portion of the metal beam resulting from the net bending force; and modulating the angle at which the net force is applied to reduce the twisting of the metal beam. As a result, the net bending force is moved toward the shear center and toward being along the principal axis of the metal beam.

A method for forming a metal beam may comprise: clamping first and second portions of the metal beam in a substantially fixed and in a position whereat the metal beam is rotatable about three axes; applying a net bending force to the clamped second portion of the metal beam at a predetermined angle; sensing twisting of the second portion of the metal beam resulting from the net bending force; and modulating the angle at which the net force is applied to reduce the twisting of the metal beam. As a result, the net bending force is moved toward the shear center and toward being along the principal axis of the metal beam.

The present invention relates to: a shape correction device for a frame body; and a method for manufacturing an electrolyte film/electrode structure that is provided with a resin frame for a fuel cell. A shape correction device, which corrects the shape of a frame body that is provided with a rectangular opening, is equipped with a pressing mechanism that applies, to each side of the frame body, a pressing force directed from the inner side to the outer side of the opening. The pressing mechanism may have a first bar and a second bar, which apply the pressing force by being in contact with inner wall surfaces of each side of the frame body.

The present invention relates to: a shape correction device for a frame body; and a method for manufacturing an electrolyte film/electrode structure that is provided with a resin frame for a fuel cell. A shape correction device, which corrects the shape of a frame body that is provided with a rectangular opening, is equipped with a pressing mechanism that applies, to each side of the frame body, a pressing force directed from the inner side to the outer side of the opening. The pressing mechanism may have a first bar and a second bar, which apply the pressing force by being in contact with inner wall surfaces of each side of the frame body.

Surgical methods and devices are provided for bending spinal rods. In one embodiment, a handheld tool is provided having an elongate shaft with a lumen formed therein that is configured to accommodate a spinal rod. The tool can include an opening in a proximal end that is configured to permit the loading of the spinal rod into the lumen, and a plurality of openings spaced along a longitudinal axis thereof that intersect the lumen for allowing a user to view and/or grasp a rod extending through the rod-receiving lumen and positioned within one of the plurality of openings. The tool can further be configured to permit a bent spinal rod to be received within the lumen. For example, the tool can include a channel in a lower surface thereof that allows a rod to exit the lumen and to extend laterally away from the tool.