A method for measuring the dimensions and characteristic angles of wheels, steering system and chassis of vehicles by means of an apparatus comprising a plurality of 3D scanners, functionally connected to a computer and arranged peripherally to a vehicle whose dimensions and characteristic angles of wheels, steering system and chassis are to be measured; each one of the 3D scanners having a viewing field, the merging of the viewing fields defining a viewing field of the apparatus; the method is characterized in that it comprises: a total measurement step, in which all the wheels of the vehicle are at least partially visible in the viewing field of the apparatus; and a partial measurement step, in which at least one wheel of the vehicle is not visible in the viewing field of the apparatus.

A method for testing a vehicle underbody of a motor vehicle includes: recording at least one image of at least one region of the vehicle underbody of the motor vehicle using a camera device; producing a three-dimensional depth image with the aid of the at least one recorded image of the at least one region of the vehicle underbody of the motor vehicle; and testing the at least one region of the vehicle underbody of the motor vehicle with the aid of the produced three-dimensional depth image of the vehicle underbody using optical image recognition.

A device for measuring the characteristic angles and dimensions of wheels, steering system and chassis of vehicles in general, comprising a plurality of three-dimensional optical readers which are functionally connected to a computer and can be arranged peripherally to a vehicle whose dimensions and characteristic angles of wheels, steering system and chassis are to be measured in such a manner that each one frames at least one wheel of the vehicle for the three-dimensional acquisition of an image of the wheel, each three-dimensional optical reader being provided with at least one fixed target for the setting and calibration of the measurement device, at least one camera of each three-dimensional optical reader being arranged in such a manner as to frame clearly and directly at least one fixed target of another three-dimensional optical reader for the setting and calibration of the measurement device by three-dimensional acquisitions of the fixed targets.

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.

A system for checking the attitude angles of wheels is provided, in a manner that is known per se, with a vertical measuring or column 1 on which some transmitters and receivers of electromagnetic signals are installed—for example coherent light illuminators (typically lasers) and associated reflected light sensor—which overall define a group of distance sensors.

According to the disclosure, the proposed system is produced using distance sensors appropriately fitted on a single vertical measuring structure which is positioned, on a side of a movement path, where the vehicle equipped with wheels moves, that has a substantially transverse direction with respect to the acquisition direction of the distance sensors.

An apparatus for chassis measurement for determining the alignment of the wheels of a motor vehicle. The apparatus includes a detachably fixed measurement head apparatus on the vehicle wheel to be measured, wherein the measurement markings are positioned parallel to the front and rear side of the vehicle or the vehicle stand level. After arranging the fastening apparatus and positioning the measurement markings, the laser light source is activated and a plane is projected in space, wherein the length of these laser light lines generates at least intersection points together with the measurement markings, the intersection points of which are detected as track gauge and used for computation in order to determine the fall, trailing and spread data and the virtual longitudinal travel axis of the vehicle. By a camera-assisted measurement value detection apparatus, different electromagnetic spectra for each wheel to be measured are detected and supplied for data processing.

Embodiments of the present invention relate to a wheel aligner. The wheel aligner includes at least one camera assembly including a shielding assembly and a camera device accommodated in the shielding assembly. The shielding assembly is configured to expose a lens of the camera device when the camera device is in operation and to shield the lens of the camera device when the camera device is not in operation. The wheel aligner according to the embodiments of the present invention can effectively prevent the lens of the camera device from being polluted by surroundings, while ensuring proper operation of the camera device.

A method for measuring the dimensions and characteristic angles of wheels, steering system and chassis of vehicles by means of an apparatus comprising a plurality of 3D scanners, functionally connected to a computer and arranged peripherally to a vehicle whose dimensions and characteristic angles of wheels, steering system and chassis are to be measured; each one of the 3D scanners having a viewing field, the merging of the viewing fields defining a viewing field of the apparatus; the method is characterized in that it comprises: a total measurement step, in which all the wheels of the vehicle are at least partially visible in the viewing field of the apparatus; and a partial measurement step, in which at least one wheel of the vehicle is not visible in the viewing field of the apparatus

A vehicle equipment comprises a scanning system for the contactless measurement of at least one projector arranged at least for the projection onto an object to be measured of a structured light with a pattern, at least one video camera arranged for the acquisition of the image of the object to be measured, and a processing unit for processing the acquired image for the three-dimensional reconstruction of the object to be measured, the projector comprising in turn at least one matrix of emitters integrated into a monolithic substrate.

A system and method of determining tire and wheel assembly alignment orientation for determining at least caster angle includes imaging a tire and wheel assembly mounted to a vehicle and suspension components of the vehicle associated with the tire and wheel assembly. Images are processed, including identifying a pivot feature for a steering component of the vehicle and identifying a circular feature of the tire and wheel assembly, with a rotational axis of the tire and wheel assembly being determined based on the identified circular feature, and a contrived line extending from the pivot feature and intersecting the rotational axis of the tire and wheel assembly is determined that represents the steering axis. Caster angle is then calculated from the angle the steering axis makes with the vertical direction when viewed from the side of the vehicle. An alignment sensor may be used to image the tire and wheel assembly and determine the rotational axis.