A wheel lock key assembly includes a wheel lock key portion configured to engage with keyslot features on a wheel lock. A driving tool coupling portion is connected to the wheel lock key portion and includes a surface structured to be rotationally coupled to a driving tool so as to enable rotation of the wheel lock key portion by the driving tool by a force acting on the surface. The surface extends along a plane extending parallel to the wheel lock key portion rotational axis. A retaining member is deformable to vary a radial distance the exterior surface extends from the rotational axis. A retaining member deformation mechanism is actuatable to deform the retaining member to vary the radial distance, such that the exterior surface extends at least a predetermined distance past the plane prior to rotational coupling of the wheel lock key assembly to the driving tool.

An assembly station for interconnecting a chassis and a body of a vehicle comprises a first carrier to support the chassis. A second carrier is suspended in a positive z-direction with respect to the first carrier and includes a plurality of spaced apart rests adapted to support the body prior to interconnecting the chassis and the body. A plurality of supports are coupled to the second carrier and spaced apart from the body when the body is supported on the rests. A portion of each of the supports is pivotable from a first position in a path of travel of the chassis to a second position outside of the path of travel of the chassis. The first carrier is moveable relative to the second carrier. The supports are adapted to engage the chassis and simultaneously support both the chassis and the body when the supports are in the first position.

A method of manufacturing a material strand (100), particularly for sealing, trimming or fastening of doors (11) or windows (12) of a motor vehicle (10), comprises the steps of: a) extrusion of an extruded strand (200); b) testing the extruded strand (200) after the extrusion, thereby identifying first segments (210) comprising manufacturing defects (211) and second segments (220) being free from manufacturing detects; c) cutting out the first segments (210) from the extruded strand (200), thereby causing faces (222) at the second segments (220); d) joining cut faces (222) of second segments (220) to obtain a joint (102) and to form a material strand (100), the joint (102) having a position within the material strand (100), wherein a minimum distance (d) is maintained between the positions of adjacent joints (102); e) identifying the position of each joint (102); and f) forming a transport unit (110) having a predetermined maximum length by winding the material strand (100).

A method of manufacturing a steering shaft assembly includes heating an inner shaft and heating an outer shaft. The method also includes applying a plastic coating to at least a portion of the inner shaft. The method further includes cooling the plastic coating and pressing the outer shaft and the inner shaft together.

A rotor includes a plurality of airfoils and each airfoil has a span that extends from 0% at a root to 100% at a tip, a chord that extends from 0% at a leading edge to 100% at a trailing edge and a pressure side opposite a suction side. The pressure side of each airfoil has a pressure side surface shape and the suction side of each airfoil has a suction side surface shape based on an operating state of the rotor. Each airfoil has the same suction side surface shape between 10% and 90% of the chord and between 80% and 100% of the span at a first state. At least one first airfoil has a different suction side surface shape between 10% and 90% of the chord and between 80% and 100% of the span than at least one second airfoil at a static state of the rotor.

This disclosure details multi-purpose brackets for mounting accessory devices within vehicle cargo spaces. Exemplary multi-purpose brackets include a doubling flange, a first opening formed through the doubling flange, and a second opening formed through another location of the bracket. A first accessory device may be mounted within the first opening, and a second accessory device may be mounted within the second opening. The multi-purpose bracket may be formed in a stamping process that involves folding and clinching the doubling flange to a platform of the bracket.

A method for aligning different portions of a conduit includes adjustably holding a first portion of a conduit in a first position, adjustably holding a second portion of a conduit in a second position relative to the first position of the first portion of the conduit, and inserting a bellows installation tool between the first portion of the conduit and the second portion of the conduit.

Systems, methods and apparatus for automated vehicle wheel removal and replacement are provided. One system includes a computer system with applications for scheduling the replacement of tires for the vehicle. An electronically controlled lift device and robotic apparatus is configured for interaction with the computer system. The lift device mechanically adjusts arms for placement on lift points of vehicles. The robotic apparatus detects positioning of lug nut configuration for a wheel, removes lug nuts, and then removes the wheel from the wheel hub with gripping arms. The wheel and tire are then handed off to a separate tire changing machine. When a new tire is replaced the robotic apparatus then mounts the wheel to the original wheel hub, and then secures the lug nuts to the lug nut bolts.

The invention relates to a device for measuring and adjusting the parameters of the chassis geometry at a rear axle of a motor vehicle on a production line for the motor vehicle. Gripping and holding means for the rear axle and loading means for the rear axle are associated with the production line. According to the invention, a plurality of interchangeable frames is associated with the production line, and positioning means for positioning one of the interchangeable frames into a position for gripping the rear axle in the production process are associated with the production line. The gripping and holding means for the rear axle and the loading means for the rear axle are associated with the interchangeable frame in question. The interchangeable frames can thereby be matched to rear axles of different vehicle types, such that these different rear axles can be processed in one assembly line.

A method for manufacturing a vehicular side door capable of suppressing occurrence of a residual deformation in a frame of a sash part and a panel member of a door body part in a manufacturing step including a heating step. The method for manufacturing a vehicular side door includes joining each of one end part of a front frame in the vehicle longitudinal direction and one end part of a rear frame to at least one door panel member, heating at least one door panel member, the front frame, and the rear frame joined in the first joining step, and joining the other end part of the front frame and the other end part of the rear frame to each other after the heating step.