Two components of an aircraft structure are joined by providing a threaded opening in one of them and supporting an alignment insert in that opening. The alignment insert is used to guide drilling of the second component such that a hole is produced which is aligned with the threaded opening, for instance using an alignment projection which physically guides a drill. The alignment insert may then be removed. A fastener is then inserted through that hole and into the threaded opening, then tightened to form the completed joint.

Provided are methods and systems for aligning multiple parts using simultaneous scanning of features of different parts and using feature-based coordinate systems for determining relative positions of these. Specifically, a feature-based coordinate system may be constructed using one or more critical dimensions between features of different parts. The scanner may be specifically positioned to capture each of these critical dimensions precisely. The feature-based coordinate system is used to compare the critical dimensions to specified ranges. The position of at least one part may be adjusted based on results of this comparison using, for example, a robotic manipulator. The process may be repeated until all critical dimensions are within their specified ranges. In some embodiments, multiple sets of features from different parts are used such that each set uses its own feature-based coordinate system. The part adjustment may be performed based on the collective output from these multiple sets.

Provided are methods and systems for aligning multiple parts using simultaneous scanning of features of different parts and using feature-based coordinate systems for determining relative positions of these. Specifically, a feature-based coordinate system may be constructed using one or more critical dimensions between features of different parts. The scanner may be specifically positioned to capture each of these critical dimensions precisely. The feature-based coordinate system is used to compare the critical dimensions to specified ranges. The position of at least one part may be adjusted based on results of this comparison using, for example, a robotic manipulator. The process may be repeated until all critical dimensions are within their specified ranges. In some embodiments, multiple sets of features from different parts are used such that each set uses its own feature-based coordinate system. The part adjustment may be performed based on the collective output from these multiple sets.

A tooling system for assembling a hybrid vehicle transmission includes a positioning device, support structure, gripper, clutch actuator, rotational actuator, and controller. The positioning device positions a hybrid module relative to a transmission housing. The gripper grips an input shaft of the hybrid module. The clutch actuator actuates the clutch of the hybrid module. The rotational actuator rotates the gripper about an assembly axis. The controller controls operation of the clutch actuator, positioning device, gripper, and rotational actuator such that an operation is performed that includes the clutch actuator actuating the clutch, the gripper gripping the input shaft of the hybrid module, the rotational actuator rotating the gripper to rotate the input shaft of the hybrid module relative to an input shaft of the transmission module, and the positioning device translating the hybrid module toward the transmission module to seat a housing of the hybrid module on the transmission housing.

A tooling system for assembling a hybrid vehicle transmission includes a positioning device, support structure, gripper, clutch actuator, rotational actuator, and controller. The positioning device positions a hybrid module relative to a transmission housing. The gripper grips an input shaft of the hybrid module. The clutch actuator actuates the clutch of the hybrid module. The rotational actuator rotates the gripper about an assembly axis. The controller controls operation of the clutch actuator, positioning device, gripper, and rotational actuator such that an operation is performed that includes the clutch actuator actuating the clutch, the gripper gripping the input shaft of the hybrid module, the rotational actuator rotating the gripper to rotate the input shaft of the hybrid module relative to an input shaft of the transmission module, and the positioning device translating the hybrid module toward the transmission module to seat a housing of the hybrid module on the transmission housing.

An apparatus and system for assembling a combustor comprises a push bar including a first end portion that is laterally opposed from a second end portion. A first alignment block and a second alignment block are adjustably coupled to the push bar. A first threaded rod extends through the push bar proximate to the first end portion and a second threaded rod extends through the push bar proximate to the second end portion. The first alignment block and the second alignment block extend outwardly from an aft side of the push bar and are positioned between the first threaded rod and the second threaded rod. The installation tool includes a first nut and a second nut for applying axial force to the push bar.

An automated insertion system for inserting or combining one or more fastener components with a molded part. The automated insertion system can handle multiple fastener components repeatedly, and do so faster and more safely than current processes.

An automated insertion system for inserting or combining one or more fastener components with a molded part. The automated insertion system can handle multiple fastener components repeatedly, and do so faster and more safely than current processes.

A system and method can change location pins on a pallet for an assembly line. The system may include a plurality of pallets, each pallet including at least a first and second sockets configured to receive a location pin. The system may include a pin changing unit located between a top assembly line and a lower return line. The pin changing unit may include a pin grabber configured to engage the location pin within the first socket. The pin changing unit may include a horizontal linear actuator configured to move the pin grabber and the engaged location pin into alignment with the second socket. The pin changing unit may include a vertical linear actuator configured to extend the pin grabber into engagement with the location pin and retract the pin grabber away from the location pin.

An automobile vehicle flexible robot door hinge installation system includes a hinge servo-linear positioning device. The hinge servo-linear positioning device includes at least one servo-motor and at least one hinge effector releasably holding and positioning a vehicle door hinge. A fastener servo-linear installation device is also provided.