A vehicle wheel service system including a plurality of sensors positioned in proximity to a heavy-duty multi-axle vehicle, to measure angles associated with three or more axles of the vehicle without repositioning the mounting of the sensors after initiating a measurement procedure. Additional sensors, associated with a vehicle reference, such as the vehicle frame axis, are disposed to provide vehicle reference measurement data which is communicated to a processing system. The processing system is configured with software instructions to evaluate the measurement data and to determine various vehicle wheel alignment angle measurements and/or necessary vehicle adjustments for each axle relative to the vehicle reference or to a fixed axle having a determined relationship to the vehicle reference.

A system and method for aligning a target to a vehicle for calibration of a sensor equipped on the vehicle includes multiple non-contact wheel alignment sensors configured for use in determining the orientation of tire and wheel assemblies of the vehicle. A target adjustment frame includes a target mount moveably mounted on a base frame, and includes multiple actuators configured to selectively move the target mount relative to the base frame, where the base frame is in a known orientation to the non-contact wheel alignment sensors. A computer system selectively actuates the actuators to position a target relative to the vehicle, with the target mount being moveable about a plurality of axes based on the determination of the orientation of the vehicle relative to the target adjustment frame to position the target relative to a sensor of the vehicle whereby the sensor is able to be calibrated using the target.

A system and method for aligning a target to a vehicle for calibration of a sensor equipped on the vehicle includes multiple non-contact wheel alignment sensors configured for use in determining the orientation of tire and wheel assemblies of the vehicle. A target adjustment frame includes a target mount moveably mounted on a base frame, and includes multiple actuators configured to selectively move the target mount relative to the base frame, where the base frame is in a known orientation to the non-contact wheel alignment sensors. A computer system selectively actuates the actuators to position a target relative to the vehicle, with the target mount being moveable about a plurality of axes based on the determination of the orientation of the vehicle relative to the target adjustment frame to position the target relative to a sensor of the vehicle whereby the sensor is able to be calibrated using the target.

The present disclosure relates to the field of automobile engineering and provides a system for simultaneous measurement of “Wheel runout” and “Wheel alignment angles” of a multi-axle vehicle having a plurality of axles and wheels. The system includes a plurality of wheel targets, at least two camera modules, and an alignment control module. The plurality of wheel targets is respectively mounted on the axle wheels. Each of the camera modules has a camera that is configured to capture images of the plurality of wheel targets. The alignment control module has a processor co-operating with each of the camera module and configured to capture and analyze the images of the Targets to compute the “Runout”and “Wheel Alignment angles” of all the wheels of all the axles simultaneously. The processor is further configured to compare the analyzed wheel alignment angles with a predetermined range of acceptable wheel alignment angles.

A vehicle service system incorporating a pair of gimbal-mounted optical projection systems enables an operator to selectively orient each optical emitter of the optical projection system to illuminate a location on a vehicle surface in proximity to the system. Signals indicative of an orientation of each optical emitter about three-axes of rotation are received at a controller programmed with software instructions to utilize the received signals, together with known locations for the systems, to calculate a three-dimensional coordinate for the illuminated location within an established frame of reference. The controller is further programmed to utilize the calculated three-dimensional coordinate of the illuminated location as an origin point for determining one or more placement locations within the established frame of reference for ADAS sensor calibration or alignment targets.

A two-line laser emitter is provided. The two-line laser emitter includes a housing, a laser emitter base mounted inside the housing, an elastic clamping member, a laser emitter and a pair of rotation adjustment screws. The laser emitter base has a laser emitter mounting hole. The laser emitter is mounted in the laser emitter mounting hole, and one end of the laser emitter is inserted into the elastic clamping member. A pair of rotation adjustment screws are disposed in the laser emitter base and located on the same side of a central axial plane of the laser emitter. The pair of rotation adjustment screws abut against a side wall of the laser emitter in opposite directions on the same straight line. Each of the rotation adjustment screws is adjustable to slightly adjust a rotation angle of the planar ray of light emitted by the laser emitter.

A target installation apparatus for installing a target for aiming equipment mounted on a vehicle comprises: a reference point setting unit configured to set vehicle-side reference points on both exterior sides in a vehicle width direction of the vehicle, wherein the reference point setting unit includes: a rod-shaped member that extends in the vehicle width direction with respect to the vehicle and that is arrangeable to abut both tires of the vehicle; and a pair of reference point forming units that are attached to the rod-shaped member to be positioned on both the exterior sides of the vehicle in the case of being arranged with respect to the vehicle and that include marks formed to respectively indicate the reference points, and wherein the pair of reference point forming units respectively include moving portions that move the reference points in a front-and-rear direction of the vehicle.

An optical scanning system for measuring and/or controlling a vehicle and/or parts of a vehicle, wherein the vehicle is arranged on a support surface. The optical scanning system comprises two optical reader apparatuses, which are arranged on said support surface, on opposite sides of the vehicle, and are provided with respective optical image capturing devices configured to provide respective data/signals encoding one or more images of the vehicle, an electronic system, which is designed to process the data/signals in order to construct one or more three-dimensional images of the vehicle. The optical image reader apparatuses each comprise a calibration target, which lies on an approximately horizontal support surface and is arranged immediately adjacent to the optical image capturing device of the relative optical image reader apparatus at a predetermined distance from it.

The present disclosure relates to a method determining wheel alignment parameter of a vehicle comprising a vehicle body. In particular, the method is performed by attaching a measuring arrangement to positions at a first and second longitudinally extending side portions of the vehicle body, respectively. A first and a second lateral center position are determined whereby a wheel alignment parameter in the form of a longitudinally extending centerline of the vehicle is determined.

A sensor calibration tool, in particular for calibrating sensors on a vehicle, includes a vertical rail defining a first axis, and first and second carriage assemblies. The first carriage assembly is supported by the vertical rail, movable along the first axis, and has a horizontal rail defining a second axis transverse to the first axis. The second carriage assembly is supported by the horizontal rail, movable along the second, and has a target mount that releasably supports a calibration target. A calibration tool includes a horizontal rail defining a first axis, a first carriage assembly movable along the first axis, a mounting bar defining a second axis and pivotable about a pivot axis transverse to the first and second axes, and a target mount positioned on the mounting bar. The first carriage assembly and the mounting bar move independently.