X-ray computed tomography (CT) is slowly conquering its space in the manufacturing industry for dimensional metrology and quality control purposes. The main advantage is its non-invasive and non-destructive character. Currently, CT is the only measurement technique that allows full 3D visualization of both inner and outer features of an object through a contactless probing system. Using hundreds of radiographs, acquired while rotating the object, a 3D representation is generated and dimensions can be verified. In this research, this non-contact technique was used for the inspection of assembled components. A dental cast model with 8 implants, connected by a screwed retained bar made of titanium. The retained bar includes a mating interface connection that should ensure a perfect fitting without residual stresses when the connection is fixed with screws. CT was used to inspect the mating interfaces between these two components. Gaps at the connections can lead to bacterial growth and potential inconvenience for the patient who would have to face a new surgery to replace his/hers prosthesis. With the aid of CT, flaws in the design or manufacturing process that could lead to gaps at the connections could be assessed.
Within the field of quality control and dimensional metrology, the evolutions in the domain of production processes are triggering more use of non-contact measurement equipment to assure faster feature assessment where possible. This led to the development of for instance laser line scanners. The standardization of these new tools follows these novel evolutions. As the coordinate measuring systems (CMSs) which include coordinate measuring machines (CMMs) with its diversity in measurement probes widens its spectrum, the ISO 10360 standard series is rearranged and split up in more parts, covering specific probe groups. The previously mentioned laser line scanners, that can be equipped on a CMM, are integrated within ISO 10360-8 which applies for CMMs equipped with optical distance sensors. This paper is an example of how to interpret and apply this standard to a specific optical distance sensor. This has to be done by taking into account the sensor’s characteristics. The intrinsic properties in the technique require an in-depth look at the recommended guidelines within the standard. Furthermore, the guidelines are adapted to use the same capabilities of the laser line scanner, which are used for measuring, without eliminating the uncertainties present in practical use of the sensor. The verification tests and their implementation are discussed, adapted to the sensors needs and performed on a state-of-the-art CMM. The verification parameter results are determined, presented and critically evaluated.
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