Methods to use a tool for dimensional verification of a vehicle frame suspension system bracket pocket having first and second cam slots, the tool including a first sub-assembly configured for insertion through and registration of the first cam slot; a second sub-assembly configured for insertion through and registration of the second cam slot; and an intermediate sub-assembly disposed between and attachable to the first and second sub-assemblies via a shaft, the intermediate sub-assembly including an extension rod receiving feature defining at least one extension rod receiving aperture; wherein the sub-assemblies lock against the bracket walls to define a horizontal center axis and are adjustable to determine and register a center point along an intersecting vertical center axis between the first and second cam slots that is alignable with the at least one extension rod receiving aperture.

A method for the diagnostic assessment of the wheel alignment of a vehicle (2) equipped with wheels (3) having tyres (301) coupled to respective rims (302), comprises the following steps: in a longitudinal movement of the vehicle (2) in a forward travel direction with one wheel (3) on a longitudinal track (4A), until the wheel (3) surmounts a measuring platform (5A) located along the track (4A), acquiring a forward travel measurement signal, representing a lateral force applied to the platform and directed transversely to both the longitudinal direction and the weight force at a forward travel instant at which the wheel surmounts the measuring platform (5A) as it moves along the track (4A) in the forward travel direction; in a longitudinal movement of the vehicle (2) in a return travel direction opposite to the forward travel direction with the wheel (3) on the track (4A), until the wheel (3) surmounts the measuring platform (5A), acquiring a return travel measurement signal, representing a lateral force applied to the platform (5A) and directed transversely at a return travel instant at which the wheel (3) surmounts the measuring platform (5A) as it moves along the track (4A) in the return travel direction; processing the forward and return measurement signals in order to determine, for the wheel (3), at least an angle of camber and/or toe.

A method for the diagnostic assessment of the wheel alignment of a vehicle (2) equipped with wheels (3) having tyres (301) coupled to respective rims (302), comprises the following steps: in a longitudinal movement of the vehicle (2) in a forward travel direction with one wheel (3) on a longitudinal track (4A), until the wheel (3) surmounts a measuring platform (5A) located along the track (4A), acquiring a forward travel measurement signal, representing a lateral force applied to the platform and directed transversely to both the longitudinal direction and the weight force at a forward travel instant at which the wheel surmounts the measuring platform (5A) as it moves along the track (4A) in the forward travel direction; in a longitudinal movement of the vehicle (2) in a return travel direction opposite to the forward travel direction with the wheel (3) on the track (4A), until the wheel (3) surmounts the measuring platform (5A), acquiring a return travel measurement signal, representing a lateral force applied to the platform (5A) and directed transversely at a return travel instant at which the wheel (3) surmounts the measuring platform (5A) as it moves along the track (4A) in the return travel direction; processing the forward and return measurement signals in order to determine, for the wheel (3), at least an angle of camber and/or toe.

Example systems and methods for aligning tire pressure monitoring sensors on a vehicle are disclosed. An example disclosed method includes positioning the front wheels on first and second dynamometers. The example method also includes aligning, with the first and second dynamometers, the tire pressure monitoring sensors of the front wheels. The example method includes positioning the rear wheels on the first and second dynamometers. Additionally, the example method includes aligning, with the first and second dynamometers, the tire pressure monitoring sensors of the rear wheels.

Example systems and methods for aligning tire pressure monitoring sensors on a vehicle are disclosed. An example disclosed method includes positioning the front wheels on first and second dynamometers. The example method also includes aligning, with the first and second dynamometers, the tire pressure monitoring sensors of the front wheels. The example method includes positioning the rear wheels on the first and second dynamometers. Additionally, the example method includes aligning, with the first and second dynamometers, the tire pressure monitoring sensors of the rear wheels.

A wheel comprehensive detecting device, comprises a lower lifting and rotating system, a measuring system I, a measuring system II, a upper pressing system, a translation system, a measuring system III, a measuring system IV. The present disclosure in use is capable of measuring the wheel bolt hole position, the runout of the flange plane, the runouts of the upper and lower rim end faces, the runouts of the upper and lower bead seats, the height of counterbore end face of the bolt hole, the height and offset of the riser end face, etc.

A wheel alignment apparatus for measuring the toe angle of a wheel of a vehicle including an adjustable housing, a scale slider including one or more measurement scales, and a centering marker, and a toe positioning pin projecting from an end of the adjustable housing, the toe positioning pin configured to be rigidly connected to the adjustable housing during operation of the wheel alignment apparatus, wherein the scale slider is adjustable to a plurality of positions within the housing.

A wheel alignment apparatus for measuring the toe angle of a wheel of a vehicle including an adjustable housing, a scale slider including one or more measurement scales, and a centering marker, and a toe positioning pin projecting from an end of the adjustable housing, the toe positioning pin configured to be rigidly connected to the adjustable housing during operation of the wheel alignment apparatus, wherein the scale slider is adjustable to a plurality of positions within the housing.

A maintenance assembly for a wheel assembly of an amusement ride vehicle includes a foundational body, a wheel engagement section extending a first distance from the foundational body, and a datum section including a protrusion extending a second distance from the foundational body. The wheel engagement section is configured to contact a wheel surface of the wheel assembly, and the datum section is configured to contact a pad of the wheel assembly. Additionally, the wheel engagement section is rigidly positioned with respect to the datum section, and the second distance is greater than the first distance, such that the maintenance assembly provides a fixed distance between a surface of the datum section configured to contact the pad and a surface of the wheel engagement section configured to contact the wheel surface.

A system for automatic wheel alignment adjustment of a vehicle in an inspection line is provided. The system is disposed under a mounting table mounted with a vehicle and includes a front wheel adjustment apparatus disposed in correspondence with a front wheel of the vehicle and configured to adjust alignment of the front wheel by adjusting a tie-rod and a lock-nut employed in a linkage structure of the front wheel, a rear wheel moving apparatus disposed in correspondence with a rear wheel of the vehicle and slidable in a vehicle width direction, and a rear wheel adjustment apparatus disposed in correspondence with the rear wheel of the vehicle, connectable to the rear wheel moving apparatus, and configured to adjust alignment of the rear wheel by adjusting a cam-bolt and a cam-nut employed in a linkage structure of the rear wheel.