A device for inspecting a profiled work pieces has a toothing, the profile metrologically detectable by the probe element of a profile probe. The profile and the profile probe are moved relative to one another and at right angles or tangentially to the measuring plane of the profile probe. The device measures work pieces having different numbers of teeth, modules and widths, directly after processing, on site and quickly, for accuracy and deviations, without special profiles for the toothing. The probe element of the profile probe can be applied to the profile of the work piece, can be applied to the profile edge of the work piece that is moving away from the probe element by the probe radius of the probe element, and subsequently, by the lateral surface of the probe element facing the profile edge opposite thereof, is configured so the probe element can be displaced from the profile gap.

Surface measuring apparatus for measuring a surface of a workpiece has a probe for contacting the surface of workpiece, a feed apparatus for moving probe relative to surface of the workpiece along a feed axis for sampling surface of workpiece. The probe outputs a probe output signal during sampling of the workpiece. An evaluation apparatus is in data transmission connection with probe and is designed and programmed to reconstruct the profile of the surface of workpiece based on the probe output signal. Evaluation apparatus is designed and programmed to determine an apparatus frequency signature representing characteristic natural frequencies of the surface measuring apparatus, and an analyzer is provided which detects and analyzes the temporal course of the apparatus frequency signature, such that the functional state of the surface measuring apparatus is assessed based on the temporal course of the apparatus frequency signature.

A measurement device can include a plurality of wheel support modules. Each of the wheel support modules can be configured to attach to a different type of vehicle wheel and to provide for rotation of the vehicle wheel about an axis. An arm can be removably attached to the first wheel support module. A measurement element that measures deformation of the vehicle wheel can be moveably attached to the arm. The different configuration of each of the wheel support modules allows for various types of vehicle wheels to be measured for deformation using the same measurement device.

A guide rail straightness tester is provided. The guide rail straightness tester includes a first rail clamp assembly attached to a guide rail. An opposing second rail clamp assembly is attached to the guide rail. A sensor assembly is positioned between the first and second rail clamp assemblies and configured for slidable seating on the guide rail. The sensor assembly includes a sensor plate. A line extends from the first rail clamp assembly through an aperture in the sensor plate and is connected to the second rail clamp assembly. The sensor assembly is configured to determine the straightness of the guide rail during movement of the sensor assembly along the guide rail.

A guide rail straightness tester is provided. The guide rail straightness tester includes a first rail clamp assembly attached to a guide rail. An opposing second rail clamp assembly is attached to the guide rail. A sensor assembly is positioned between the first and second rail clamp assemblies and configured for slidable seating on the guide rail. The sensor assembly includes a sensor plate. A line extends from the first rail clamp assembly through an aperture in the sensor plate and is connected to the second rail clamp assembly. The sensor assembly is configured to determine the straightness of the guide rail during movement of the sensor assembly along the guide rail.

There is described a device for measuring deformations (10) on surfaces endowed with a frame (11) associated to fastening means (20) of the device (10) on the surfaces, the device (10) further comprising, at least a pair of guides (31, 32) associated longitudinally to an inner portion (12) of the frame (11) and spaced apart parallel to each other, and a sliding support (40) perpendicularly associated to the guides (31, 32); the sliding support (40) comprising a transversal groove (41) on which there is disposed a mobile base (42) that receives a measuring element (50).

There is described a device for measuring deformations (10) on surfaces endowed with a frame (11) associated to fastening means (20) of the device (10) on the surfaces, the device (10) further comprising, at least a pair of guides (31, 32) associated longitudinally to an inner portion (12) of the frame (11) and spaced apart parallel to each other, and a sliding support (40) perpendicularly associated to the guides (31, 32); the sliding support (40) comprising a transversal groove (41) on which there is disposed a mobile base (42) that receives a measuring element (50).

The present disclosure provides an assembly, adapter device, and method that utilize a standard displacement gauge or the like, well known to those of ordinary skill in the art, to measure the height of a flange, such as a flange formed via bending a planar vehicle component with a given thickness and, thus, including a radius at the bottom interior of the flange. This assembly, adapter device, and method provide consistent measurements across components, operators, education and experience levels, etc. The adapter device is designed to engage the flange being measured in such a way that consistent engagement of the adapter device with the radius, and, thus, consistent engagement of the assembly with the flange, is provided for measurement.

The present disclosure provides an assembly, adapter device, and method that utilize a standard displacement gauge or the like, well known to those of ordinary skill in the art, to measure the height of a flange, such as a flange formed via bending a planar vehicle component with a given thickness and, thus, including a radius at the bottom interior of the flange. This assembly, adapter device, and method provide consistent measurements across components, operators, education and experience levels, etc. The adapter device is designed to engage the flange being measured in such a way that consistent engagement of the adapter device with the radius, and, thus, consistent engagement of the assembly with the flange, is provided for measurement.

A metrology device with automated compensation and/or alert for orientation errors. The device may include a processor, a probe portion and at least one orientation sensor. The probe provides an output representative of a raw measurement of a characteristic of a device under test and the orientation sensor provides a sensor output representative of an orientation of the metrology device to the device under test. The processor applies a correction factor to the raw measurement in response to the sensor output to establish a compensated measurement to compensate for misalignment of the metrology device to the device under test. In addition, or alternatively, the processor provides an alert indicating the existence and/or extent of the misalignment.