A measuring device includes a rotatable stage configured to receive and rotate an object long a rotational axis of the object. A housing is located adjacent to the rotatable stage and is movable along the rotational axis of the object. The housing has a pivoting arm located between a pair of opposing compression springs which are configured to provide a preload force in a direction parallel to the rotational axis of the object. A probe tip is coupled to the pivoting arm and extends from the housing, the probe tip configured to contact a portion of the object. A displacement measuring device is coupled to the pivoting arm and is configured to measure displacement of the probe tip in the direction parallel to the rotational axis of the object based on movement of the pivoting arm against one of the opposing compression springs.

A surface texture measuring apparatus includes: a measurement sensor measuring, without contact, a surface texture of an interior wall of a cylinder portion of a measurable object while displacing in a normal direction of the interior wall at each measurement region into which the interior wall is divided in a circumferential direction of the cylinder portion; a W axis displacer displacing the measurement sensor in a W axis direction; a axis displacer displacing the measurement sensor in the circumferential direction, after measurement of the surface texture of a first measurement region, such that the measurement sensor faces a second measurement region adjacent to the first measurement region in the circumferential direction; and a controller adjusting a W axis direction measurement position for measuring the surface texture of the second measurement region while displacing the measurement sensor in the W axis direction.

An examining device for examining inner walls of a hollow body comprises: a rod-shaped camera device designed to record an image transversely with respect to its longitudinal axis; adjustment means for moving the camera device into and out of the hollow body; a grazing light illumination device for illuminating the inner walls and having emission directions that are transverse with respect to receiving directions, from which the camera device receives light from the illuminated inner walls, wherein an angle between the emission and receiving directions is between 45 and 135; diameter determination means for determining an inner diameter of a cavity of the hollow body and comprising a light source and optical measuring means. Furthermore, a corresponding method for examining inner walls is described.

The present invention provides a method for inspecting a crankshaft, which enables accurate detection of defects which occur partially in the crankshaft, such as underfills and dent flaws, by discriminating these defects from bending and torsion over an entire length of the crankshaft. The present invention includes steps of: acquiring three-dimensional point cloud data over an entire length of a measurement object region of a crankshaft S by an optical three-dimensional shape measurement device 1; dividing the acquired three-dimensional point cloud data to create a plurality of subregion three-dimensional point cloud data, each of the subregion three-dimensional point cloud data respectively corresponding to each of a plurality of subregions of the crankshaft along a direction parallel to the rotational center axis L of the crankshaft; translating and rotating each of the created subregion three-dimensional point cloud data to superpose each of the subregion three-dimensional point cloud data on a surface shape model of the crankshaft, such that a distance between each of the subregion three-dimensional point cloud data and the surface shape model becomes minimum; and detecting a partial defect such as an underfill of the crankshaft based on a distance between each of the subregion three-dimensional point cloud data after being superposed and the surface shape model.

A shaft precision automatic measurement device for motors is provided that is able to automatically measure shaft precision of a motor. A shaft precision automatic measurement device (1) for a motor (9) includes: a gripping mechanism (3) that grips the shaft (7); a first contact-type displacement sensor (41) that is able to measure a position of the flange face (82) by contacting to follow the flange face (82); a second contact-type displacement sensor (42) that is able to measure a position of the fitting face (81) by contacting to follow the fitting face (81); a rotary mechanism (5) that causes the device main body (2) to rotate in a state gripping the shaft (7) by the gripping mechanism (3) and executing measurement by way of the respective displacement sensors; a displacement data acquisition part (63) that acquires displacement data of the flange face (82) and displacement data of the fitting face (81); and a measurement part (64) that measures center runout and face deflection of the shaft (7) based on the respective displacement data acquired by the displacement data acquisition part (63).

The present invention provides a method for inspecting a crankshaft, which enables accurate detection of defects which occur partially in the crankshaft, such as underfills and dent flaws, by discriminating these defects from bending and torsion over an entire length of the crankshaft. The present invention includes steps of: acquiring three-dimensional point cloud data over an entire length of a measurement object region of a crankshaft S by an optical three-dimensional shape measurement device 1; dividing the acquired three-dimensional point cloud data to create a plurality of subregion three-dimensional point cloud data, each of the subregion three-dimensional point cloud data respectively corresponding to each of a plurality of subregions of the crankshaft along a direction parallel to the rotational center axis L of the crankshaft; translating and rotating each of the created subregion three-dimensional point cloud data to superpose each of the subregion three-dimensional point cloud data on a surface shape model of the crankshaft, such that a distance between each of the subregion three-dimensional point cloud data and the surface shape model becomes minimum; and detecting a partial defect such as an underfill of the crankshaft based on a distance between each of the subregion three-dimensional point cloud data after being superposed and the surface shape model.

A crank bearing face measuring device for measuring the faces of crank bearings of a crankshaft has a base body and a device for rotating the crankshaft about a main axis of rotation. The main axis of rotation is defined by the main bearings of the crankshaft. Measuring device also has a measuring head which has a probe prism for placing against a crank pin of the crankshaft, and at least one measuring probe, for placing against a face of the crank bearing to be measured. The measuring head is configured for and connected to the base body in such a way that the measuring head follows an orbital rotation of the crank pin during rotation of the crankshaft about the main axis of rotation.

An examining device for examining inner walls of a hollow body comprises: a rod-shaped camera device designed to record an image transversely with respect to its longitudinal axis; adjustment means for moving the camera device into and out of the hollow body; a grazing light illumination device for illuminating the inner walls and having emission directions that are transverse with respect to receiving directions, from which the camera device receives light from the illuminated inner walls, wherein an angle between the emission and receiving directions is between 45 and 135; diameter determination means for determining an inner diameter of a cavity of the hollow body and comprising a light source and optical measuring means. Furthermore, a corresponding method for examining inner walls is described.

A measuring device includes a rotatable stage configured to receive and rotate an object long a rotational axis of the object. A housing is located adjacent to the rotatable stage and is movable along the rotational axis of the object. The housing has a pivoting arm located between a pair of opposing compression springs which are configured to provide a preload force in a direction parallel to the rotational axis of the object. A probe tip is coupled to the pivoting arm and extends from the housing, the probe tip configured to contact a portion of the object. A displacement measuring device is coupled to the pivoting arm and is configured to measure displacement of the probe tip in the direction parallel to the rotational axis of the object based on movement of the pivoting arm against one of the opposing compression springs.

A gauging machine for inspecting bore diameters of a workpiece includes a reference fixture, a first wide range bore gauge arranged on a first three-dimensional positioning apparatus to facilitate inspection of a first set of bores aligned along parallel axes, and a second wide range bore gauge arranged on a second three-dimensional positioning apparatus to facilitate inspection of one bore or a plurality of bores aligned along parallel axes. The gauging machine facilitates inspection of bores on a plurality of different workpieces having different overall dimensions, a different number of bores, different positioning of bores, and/or different size bores, without requiring retooling of the gauging machine.