A monitoring module for assembly accuracy between two components includes a first component having an installation surface, and a second component having an opposite surface and disposed in a way that the opposite surface faces towards the installation surface. A preload is continuously applied to at least one of the first and second components to press the opposite surface of the second component on the installation surface of the first component. The installation surface is defined with a reference point. At least two load cell pairs are disposed on the installation surface. Each load cell pair has two load cells located on two sides of the reference point respectively, and the imaginary line connecting the two load cells passes through the reference point.

Besides, the load cells are separated from each other without any overlap. The opposite surface is pressed on the at least two load cell pairs.

A probe includes a movable plate to which a stylus capable of contacting a measurable object is mounted, the movable plate displaceable in an X direction; a static plate arranged to overlap with the movable plate; a counter plate facing the movable plate and the static plate; an elastic movable side connection plate, the movable side connection plate connecting the counter plate at at least three places with each of a first end connector positioned toward a first end of the movable plate in the X direction and second end connectors positioned toward a second end in the X direction; and a static side connection plate which connects the static plate and the counter plate. An entire length of the first end connector in a Y direction orthogonal to the X direction is the same size as the entire length of the second end connectors in the Y direction.

Apparatuses, systems and methods associated with a metrology system for high-speed, non-contact coordinate measurements of parts are disclosed herein. In embodiments, the metrology system includes a metrology bridge to be coupled to a measurement assembly. The measurement assembly may include a stage moveable across multiple independent axes. The bridge may include a housing, mounting members coupled to the housing, and a plurality of sensors mounted within the housing. The mounting members may rotatably couple the housing to the measurement assembly. Further, sensor elements of the plurality of sensor devices may be aligned along a length of the housing and may be directed out of the housing.

Apparatuses, systems and methods associated with a trigger management device for managing triggering of sensors within measurement equipment are disclosed herein. In embodiments, a trigger management device may include trigger circuitry coupled to a sensor, the trigger circuitry to determine an amount of delay from trigger transmission to data capture for the sensor, and transmit a trigger to the sensor, the trigger to cause the sensor to capture sensor data. The trigger management device may further include encoder circuitry coupled to one or more encoders, the one or more encoders to indicate positions of one or more actuators or motors, the encoder circuitry to capture encoder data from the one or more encoders at a time that is the amount of delay after transmission of the trigger, wherein the encoder data indicates current positions of the one or more actuators or motors. Other embodiments may include circuitry to manage and/or transmit encoder and other data to multiple devices.

A measurement system and a method of measuring an object is provided. The system includes a measurement platform having a planar surface. At least two optical sensors are coupled to the measurement platform that emit light in a plane and determines a distance to an object based on a reflection of the light. A linear rail is coupled to the measurement platform. A cooperative robot is coupled to move along the linear rail. A 3D measuring system is coupled to the end of the robot. A controller coupled to the at least two optical sensors, the robot, and the 3D measuring system, the controller changing the speed of the robot and the 3D measuring system to less than a threshold in response to a distance measured by at least one of the at least two optical sensors to a human operator being less than a first distance threshold.

A form measuring apparatus includes a base; an arm capable of swinging relative to the base; a coupler coupling the base and the arm, and having a deformation region that is capable of elastic deformation between the base and the arm; and a distortion detector installed in the deformation region. In the form measuring apparatus, a stylus is mounted to the arm and can slide along a surface of a work piece.

A robot arm supporting a workpiece, a support mechanism in a form of a coordinate measuring machine supporting a detector head, and a fixation portion in a form of a contact block fixing the detector head to the workpiece are used to bring the contact block fixed to a table and the workpiece into contact to each other. The detector head measures the workpiece while a relative position of the detector head and the workpiece is fixed.

Provided is a monitoring device for the settlement of a transmission tower. The monitoring device includes a laser ranging sensor, an acceleration sensor, a central processing module, a battery, and a fixing plate. The laser ranging sensor is configured to measure the distance between the installation position of the monitoring device and the ground. The acceleration sensor is configured to measure the inclination angle of a tower leg. The central processing module is configured to process measurement data of the laser ranging sensor and the acceleration sensor. The battery is configured to supply power to the laser ranging sensor, the acceleration sensor, and the central processing module. The fixing plate is configured to fix the monitoring device to the tower leg of the transmission tower. A method for monitoring a settlement of a transmission tower is further provided.

A CMM system has a CMM arm movable in at least three degrees of freedom, a 3D print head removably couplable with the CMM arm, and a thermal insulator between the print head and the CMM arm.

A measurement system and a method of measuring an object is provided. The system includes a measurement platform having a planar surface. At least two optical sensors are coupled to the measurement platform that emit light in a plane and determines a distance to an object based on a reflection of the light. A linear rail is coupled to the measurement platform. A cooperative robot is coupled to move along the linear rail. A 3D measuring system is coupled to the end of the robot. A controller coupled to the at least two optical sensors, the robot, and the 3D measuring system, the controller changing the speed of the robot and the 3D measuring system to less than a threshold in response to a distance measured by at least one of the at least two optical sensors to a human operator being less than a first distance threshold.