An assembling device includes a holding member and a processing device. The holding member is configured to hold a first assembly component and a second assembly component. The processing device is configured to process a first excess thickness portion and a second excess thickness portion. The first excess thickness portion is provided at the first assembly component and is configured to adjust a gap between the first assembly component and the second assembly component. The second excess thickness portion is provided at the second assembly component and is configured to adjust the gap.

Provided are a golf club head and a method for producing the golf club head. The golf club head comprises a striking face that in turn comprises a recurrent texture pattern that has a period T and that is defined by a plurality of depressions, each depression having an average depth no greater than 0.10 mm. The striking face also comprises a plurality of scorelines that at least partially intersect the recurrent texture pattern and that have a scoreline pitch Ps such that T/Ps is greater than 1.0, each scoreline having an average depth no less than 0.10 mm.

A rack for holding a portion of a thrust reverser. The rack may include a base and a supporting frame disposed perpendicularly with the base. The base and the supporting frame may include a hinge at each location where the base and the supporting frame are coupled together. The rack may also include two supporting poles parallel to the supporting frame. The two supporting poles may be designed such that the portion of the thrust reverser may be mounted onto the two supporting poles.

A method and apparatus. The apparatus comprises a first portion of a tool and a second portion of the tool. The first portion of the tool has a first surface. The first surface has a shape that is complementary to a first portion of a part. The second portion has at least one of a second surface configured to be recessed from a second portion of the part or a hollow portion.

Systems and methods are provided for securement of parts. One embodiment is a method for securing a part during fabrication. The method includes forming an interference fit between a pin and a wall defining a hole, supporting a weight of the part with the interference fit, and rotating the part around an axis of the part while the weight of the part is supported.

An apparatus for holding a workpiece includes a fixture base, a linear actuator coupled to the fixture base and having an outboard end that is linearly movable by the linear actuator, and a vacuum gripper located at the outboard end of the linear actuator. The linear actuator is configured to linearly move the vacuum gripper relative to the fixture base into contact with a surface of the workpiece. With the vacuum gripper in contact with the surface of the workpiece, the vacuum gripper is configured to grip the workpiece using a vacuum formed between the vacuum gripper and the surface of the workpiece. With the vacuum formed between the vacuum gripper and the surface of the workpiece, the linear actuator is configured to lock linear movement of the vacuum gripper.

An ultrasonic surgical instrument is disclosed including an end effector, a shaft assembly extending proximally from the end effector, and a housing extending proximally from the shaft assembly. The end effector includes a clamp arm assembly pivotable between an open position and a closed position. The clamp arm assembly includes a clamp arm including a slot, a tissue pad secured to the clamp arm, and a tab. The tissue pad includes a flange positioned in the slot. The tissue pad extends proximally to a proximal end. The tab is positioned to engage the proximal end to stop proximal displacement of the tissue pad relative to the clamp arm. Relative movement between an outer tube and an inner tube is configured to pivot the clamp arm assembly. Actuation of a trigger is configured to effect relative movement between the inner tube and the outer tube.

An adaptable assembly line work-piece processor for use at a work station includes, but is not limited to, a work-piece supporter. The adaptable assembly line work-piece processor further includes, but is not limited to, a reconfigurable interface assembly attached to the work-piece supporter. The adaptable assembly line work-piece processor still further includes, but is not limited to, a work-piece manipulator attached to the reconfigurable interface assembly. The work-piece supporter, the reconfigurable interface assembly, and the work-piece manipulator are configured to cooperate to sequentially support and manipulate a plurality of differently configured work-pieces.

A method and apparatus for de-chucking a workpiece is described that uses a swing voltage sequence. One example pertains to a method that includes applying a mechanical force from an electrostatic chuck against the back side of a workpiece that is electrostatically clamped to the chuck, applying a sequence of voltage pulses with a same polarity to the electrodes, each pulse of the sequence having a lower voltage than the preceding pulse, each pulse of the sequence having a lower voltage than the preceding pulse, and determining whether the workpiece is released from the chuck after the sequence of additional voltage pulses and if the workpiece is not released then repeating applying the sequence of voltage pulses.

Systems and methods are provided for securement of parts. One embodiment is a method for securing a part during fabrication. The method includes forming an interference fit between a pin and a wall defining a hole, supporting a weight of the part with the interference fit, and rotating the part around an axis of the part while the weight of the part is supported.