The present application thus provides a method of filling an existing hole in a surface of a turbine component. The method may include the steps of enlarging the existing hole, placing a rivet into the enlarged hole, welding the rivet into place, and grinding the rivet to be flush with the surface of the turbine component.

The present application thus provides a method of filling an existing hole in a surface of a turbine component. The method may include the steps of enlarging the existing hole, placing a rivet into the enlarged hole, welding the rivet into place, and grinding the rivet to be flush with the surface of the turbine component.

A coupling member head includes a holder configured to hold a coupling member at an end portion on a coupling target member side in an axial direction and configured to approach or separate from a coupling target member, a pair of electrodes, tips of the electrodes being positioned closer to the coupling target member side than a coupling member holding region of the holder, and a retraction mechanism configured to move the electrode to a radial outside of the holder when the holder approaches the coupling target member.

A joining tool unit having a movable tool, a tool counter element, a drive unit, a light-guiding system, a light source, and a monitoring unit. The movable tool and the tool counter element are arranged opposite each other on the joining tool unit, and the light-guiding system is designed to conduct light of the light source in the direction of a joint location of a workpiece when the workpiece is arranged on the joining tool unit, wherein the movable tool can be moved by the drive device in the direction of the tool counter element, and the workpiece is joined by the movement of the movable tool in the direction of the tool counter element when the workpiece is arranged on the joining tool unit. The monitoring unit controls and/or regulate the drive unit and to control and/or regulate the light source and/or a component of the light-guiding system.

A joining tool unit including a hold-down device, a movable tool, a tool counterpart element, a drive unit, a light source and a control unit. The hold-down device and the movable tool are provided opposite the tool counterpart element, the hold-down device being movable in the direction of the tool counterpart element by the drive unit. The joining tool unit joins a workpiece arranged on the joining tool unit by movement of the movable tool relative to the tool counterpart element. The control unit performs open- and/or closed-loop control of the drive unit, and the control unit is designed for open- and/or closed loop control of the light source. The joining tool unit is designed to move the hold-down device in the direction of the tool counterpart element to a position at which the hold-down device and the tool counterpart element touch the workpiece arranged on the joining tool unit.

A joining tool unit including a hold-down device with a movable tool and a tool counter element. The hold-down device together with the movable tool and the tool counter element are provided opposite each other. A workpiece can be positioned between the hold-down device and the tool counter element in the arranged state. The movable tool and the tool counter element interact in order to form a joint connection. A light-guiding system is formed on the hold-down device, to conduct a light beam in the direction of a joint location of the workpiece when the workpiece is arranged on the joining tool unit. A flow channel for a fluid is defined along a section of the light beam up to a workpiece-side end of the hold-down device.

A joining tool unit including a hold-down device with a movable tool and a tool counter element. The hold-down device together with the movable tool and the tool counter element are provided opposite each other. A workpiece can be positioned between the hold-down device and the tool counter element in the arranged state. The movable tool and the tool counter element interact in order to form a joint connection. A light-guiding system is formed on the hold-down device, to conduct a light beam in the direction of a joint location of the workpiece when the workpiece is arranged on the joining tool unit. A flow channel for a fluid is defined along a section of the light beam up to a workpiece-side end of the hold-down device.

An apparatus and method for operating a staking assembly includes a housing defining a machining passage having a longitudinal axis, an actuator rod disposed for axial movement along the longitudinal axis in the machining passage, having a first end configured to connect to a linear-reciprocating source of movement and a second end having a tool configured to deform a boss, and an air source configured to selectively provide a source of heated air.

A method for connecting two aircraft components composed of thermoplastic composite material by a rivet. The two aircraft components are arranged, in sections, areally on one another, before bores in the two aircraft components are expanded by a mandrel element such that the bores, after the expansion, form one continuous bore for receiving the rivet. Here, the two aircraft components are locally warmed by the mandrel element such that, during the expansion of the bores, the components are thermoplastically deformed. The mandrel element is inserted through the first bore into the second bore. The rivet is introduced into the continuous bore. A system for carrying out the method is also disclosed.

A method of connecting two components (1, 6) is disclosed, wherein a first component (1) is connected to a second component (6) at a connecting point (4) of the first component (1), and wherein a surrounding region (3), which surrounds the connecting point (4), is heated by electrical resistance heating prior to the two components (1, 6) being connected, so that the ductility of the first component (1) in the surrounding region (3) is increased and the strength is substantially reduced.