A device is proposed for the contactless three-dimensional inspection of a circular, mechanical component (20) with toothing having a main axis of rotation, comprising: means for scanning the teeth, comprising at least one first pair of laser measurement modules (12A, 12B) and means for the rotational driving (11), about the main axis, of said component relative to the laser measurement modules; means for rebuilding a virtual three-dimensional representation of the component using data coming from said scanning means; means of dimensional inspection using the three-dimensional representation; each pair of modules comprising a first module oriented towards a first face of a tooth and a second module oriented towards a second face of a tooth;

the modules being oriented relative to the component so that during a rotation of the component, the scanning means scan the first and second faces of each tooth throughout their thickness and depth.

A gear inspection apparatus includes: a measurement unit which has a probe installed to be movable forward and rearward relative to a work gear rotatably mounted on a frame, and measures a dimension of the work gear, which rotates, by a measurement ball provided at a tip of the probe; a drive unit which is installed on the frame so as to be connected to the measurement unit and moves the probe forward and rearward; and a controller which receives a displacement measurement value related to a position of the probe which is measured by the measurement unit, and converts the displacement measurement value into a digital value.

A multi-axis system (30) for positioning a workpiece measuring sensor (54) on a metrology machine. Preferably, each sensor is positionable via a system comprising movement along and/or about at least linear directions/axes (X, Z, A, B) so as to control linear and/or rotational movement of a sensor automatically to a predetermined position without operator intervention. The multi-axis positioning system allows faster setup times when a workpiece or tooling on a machine is changed.

A measurement condition that enables accurate shape measurement can be set easily. An image analysis device includes an image analyzer 83 configured to detect, in a case of capturing an image of light projected onto an object to be measured, an improper image for shape measurement of the object to be measured, on the basis of design information on the object to be measured, and a measurement condition, and an output unit 88 configured to output detection result information that is information based on a detection result of the image analyzer 83.

A method of measuring an uneven shape on a three-dimensional curved surface for measuring an uneven shape present on a three-dimensional curved surface of a measurement object and finer than the three-dimensional curved surface, the method comprising: a surface shape data acquiring step of acquiring three-dimensional surface shape data representative of a surface shape of the measurement object; a dividing step of extracting data of a divided portion representative of a surface contour shape of the divided portion from the three-dimensional surface shape data, for each of the divided portions acquired by dividing a surface of the measurement object in a certain dividing direction at regular intervals by a multiplicity of straight lines orthogonal to the dividing direction; a curve equation setting step of obtaining a curve equation approximating the entire area of the surface contour shape represented by the data of the divided portion for each of the divided portions; a difference calculation step of calculating a difference between the data of the divided portion and the curve equation for the entire area of the divided portion for each of the divided portions; and a difference combining step of combining two-dimensional data of the difference calculated for the entire area of the divided portion for each of the divided portions in the dividing direction to generate three-dimensional shape data representative of the uneven shape.

A fixture for gauging a bevel gear product that is received on a mount and rotated relative to a base while a plurality of measuring lasers and a rotational position sensor are operated. Data from the measuring lasers and the rotational position sensor are employed by a controller to generate one or more data sets. The data set(s) include dimensional information on the bevel gear product as a function of a rotational position of the bevel gear product about the mount axis. Various dimensions of the bevel gear product are gauged by the controller based on information in the data set(s).

A method for detecting a phase on a gear includes obtaining a first determination result indicating whether the gear has been detected at a first detection position. A second determination result indicating whether the gear has been detected at a second detection position is obtained. A third angle between the first and second angles is obtained. A third determination result indicating whether the gear has been detected at a third detection position is obtained. The first angle is replaced with the third angle when the third and first determination results are same, or the second angle is replaced with the third angle when the third and first determination results are different. The phase on the gear is detected based on an angle that is between the first angle and the second angle.

A coordinate measuring apparatus, comprising a rotatably driveable receptacle for a gear workpiece and a measuring assembly, and configured to perform feed movements and measuring movements of the measuring assembly relative to the gear workpiece on a plurality of axes, the measuring assembly including an optical switch sensor which operates in a contactless manner, which is designed as a focus trigger sensor and is arranged on the measuring assembly in such a way that it is able to emit a light beam along an optical axis in the direction of the gear workpiece, wherein a scanning movement relative to the gear workpiece can be carried out with the focus trigger sensor by using one or more of the axes, and wherein a switching signal can be provided by the focus trigger sensor whenever the gear workpiece has reached a nominal distance relative to the focus trigger sensor.

A method of determining the minimum radius and the mounting distance of a worm gear member (6) of a worm drive (2). The root portion (26) of a tooth slot (24) is probed at a plurality of points along the length of the root and the locations of the points are utilized as the basis for determining the minimum radius and the mounting distance.

An apparatus including an NC controller, a tactile system controlled by the NC controller and movable along a measurement axis, a workpiece receptacle for receiving a workpiece, a rotational drive for rotating the workpiece receptacle with the workpiece about an axis of rotation, and a contactlessly operating sensor device arranged on the tactile system and transferable from a first position into a second position by displacement relative to the tactile system.