A check method of worm gears includes the following steps: identification of a real profile (PR) of a worm gear to be checked; scanning of the real profile (PR) in such a way to obtain a measured profile (PM), filtering of the measured profile (PM) with a low pass filter in such a way to obtain a primary profile (PP), filtering of the primary profile (PP) with a high pass filter in such a way to obtain a surface analysis profile (SA), calculation of three parameters (SA.sub.3; SA.sub.q; SA.sub.p) from said surface analysis profile (SA) and comparison of the three parameters (SA.sub.3; SA.sub.q; SA.sub.p) with preset threshold values (TSa; TSq; TSp) in such a way to reject the worm gear when at least one of the parameters exceeds the corresponding threshold value.

A device and method for measuring dimensional variation of a part, particularly total runout, is provided. The device includes an indicator check body, a clamping device within the indicator check body and an end cap that engages the indicator check body and the clamping device. When the indicator check body and the clamping device are engaged, the device is secured to the part allowing dimensional variations to be measured along the surface of the indicator check body.

A measuring arm for a coordinate measuring machine, having a support structure, wherein the support structure includes a fastening section for fastening the measuring arm on a movable slide of the coordinate measuring machine, having a measuring head for acquiring measured values on a component to be measured. The measuring head is mounted on the support structure, and the support structure includes an auxiliary mass damper for oscillation damping.

The present disclosure provides a method, a system, a device and a medium for measuring gear tooth profile roughness. The method includes: obtaining design parameters of a target gear pair and test parameters of each tooth profile working point; fitting a measured surface profile and a theoretical tooth profile curve to obtain a surface structure curve; calculating a Hertzian contact width according to the design parameters and the test parameters for each tooth profile working point on the theoretical tooth profile curve, and determining an evaluation length of surface roughness according to the Hertzian contact width; filtering the surface structure curve by means of a filter with a set wavelength to obtain a surface roughness profile; and determining surface roughness parameters of each tooth profile working point in a working area according to the surface roughness profile for each evaluation length.

A large gear involute artifact assembled with mandrel used as physical datum of precision traceability and measurement transmission for large gear involute is proposed. The artifact comprises a large gear involute artifact stripe, a mandrel, a backing plate, a counterweight shaft, an adjustable counterweight ring, the adjustable screws of counterweight, the connecting screws for backing plate, the connecting screws for artifact and an eccentric multi-ball bearing. The structure and the rolled length of the large gear involute artifact assembled with mandrel fit the basic requirements of class-1 accuracy in the national standard of gear involute artifact GB/T 6467-2010 in China. It has advantages of long rolled length, adjustable center of mass, uniform datum, compact structure, and portability. It adopts lightweight design, which can be installed and transported by one person manually, and is suitable for the structural design of large gear involute artifact with base-circle diameter greater than 500 mm.

A system is disclosed for measuring a feature of a component. The system may have a probe with a tip, and a sensing element configured to generate signals associated with a proximity of the tip to the feature. The system may also have an actuator configured to move the probe relative to the component, and a controller in communication with the sensing element and the actuator. The controller may be configured to generate a deviation report based on the signals, and to filter information from the deviation report according to wavelength into a plurality of deviation categories corresponding to specification requirements of the component. The plurality of deviation categories may include at least a waviness category. The controller may also be configured to determine a change to a process used to fabricate the component based on the information from the deviation report filtered into the waviness category.

A system and method is provided for measuring a physical parameter of a gear. The system and method includes moving a contact probe into a start position on the pitch circle of the gear in a gap between adjacent teeth. The contact probe is moved in a path substantially along the pitch circle of the gear until the contact probe contacts the flank of one of the adjacent gear teeth at a contact point. Spatial coordinates of the contact point are determined. A measurement of a physical parameter of the gear is determined based on the spatial coordinates of the contact point.

A system is disclosed for use in measuring a component. The system may have a probe configured to generate signals associated with a proximity to actual target points of the component, an actuator configured to move the probe relative to the component, and a controller in communication with the probe and the actuator. The controller may be configured to receive coordinates of intended form target points, to determine coordinates of the actual target points of the component relative to a component datum based on the signals, and to make a comparison of the coordinates of the intended form target points and the coordinates of the actual target points. The controller may also be configured to generate a deviation report based on the comparison, and to filter information from the deviation report according to wavelength into a plurality of deviation categories corresponding to component specification requirements of the component.

A system and method is provided for measuring a physical parameter of a gear. The system and method includes moving a contact probe into a start position on the pitch circle of the gear in a gap between adjacent teeth. The contact probe is moved in a path substantially along the pitch circle of the gear until the contact probe contacts the flank of one of the adjacent gear teeth at a contact point. Spatial coordinates of the contact point are determined. A measurement of a physical parameter of the gear is determined based on the spatial coordinates of the contact point.

The present disclosure provides a method, a system, a device and a medium for measuring gear tooth profile roughness. The method includes: obtaining design parameters of a target gear pair and test parameters of each tooth profile working point; fitting a measured surface profile and a theoretical tooth profile curve to obtain a surface structure curve; calculating a Hertzian contact width according to the design parameters and the test parameters for each tooth profile working point on the theoretical tooth profile curve, and determining an evaluation length of surface roughness according to the Hertzian contact width; filtering the surface structure curve by means of a filter with a set wavelength to obtain a surface roughness profile; and determining surface roughness parameters of each tooth profile working point in a working area according to the surface roughness profile for each evaluation length.