Metrological evaluation of laser scanner integrated with measuring arm using optical feature-based gauge

Metrological evaluation of laser scanner integrated with measuring arm using optical feature-based gauge

•A metrological performance procedure is presented for laser scanners (Laser Triangulation Scanner) integrated in Coordinated Measuring Arms.•New proposal for determining the probe error for Laser Triangulation Sensor (manually operated).•Statistical test to know (delimit) the influence of operator...

Full description

Saved in:
Bibliographic Details
Published in:Optics and lasers in engineering Vol. 121; pp. 120 - 132
Main Authors: Cuesta, E., Alvarez, B.J., Martinez-Pellitero, S., Barreiro, J., Patiño, H.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-10-2019
Subjects:
3D optical scanner
Coordinate measuring arm
Feature-based gauge
Laser Scanning
Laser triangulation sensor
Metrological evaluation
Optical Imaging Techniques
Optical Imaging Techniques
Metrological evaluation
Coordinate measuring arm
3D optical scanner
Laser triangulation sensor
Feature-based gauge
Laser Scanning
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•A metrological performance procedure is presented for laser scanners (Laser Triangulation Scanner) integrated in Coordinated Measuring Arms.•New proposal for determining the probe error for Laser Triangulation Sensor (manually operated).•Statistical test to know (delimit) the influence of operator scanning strategy.•Scanning data treatment influence on the results of measurement accuracy.•Use of an optical feature-based gauge for qualification of laser triangulation scanner. This work deals with the searching of metrological limits with which the laser scanners mounted on coordinate measuring arms (AACMMs or CMAs) are able to evaluate dimensional and geometric tolerances (GD&T). For this purpose, a novel feature-based gauge for optical sensors is used. This gauge incorporates different types of geometrical entities, perfectly adapted for several GD&T evaluations. In addition, these entities are optically functional so that they are captured from the laser sensors mounted in AACMM. The gauge is equipped with a set of "canonical" entities of ceramic type, manufactured with high dimensional accuracy to materialize a multitude of GD&T tolerances. Regarding the metrological evaluation, the measurements obtained with the laser scanner are compared with the previously calibrated measurements of the gauge, calibration that has been performed using contact probing in a CMM. Although in this research a rather obsolete model of laser scanner is used, the methodology is totally valid for any sensor mounted in AACMM, obtaining a high range of traceable values. One issue that has received special attention is the control of variability produced by a manual scanning operation. To this end, research is approached from a twofold perspective: on one hand, an initial study to determine the best scanning strategy allowing a good coverage of each entity surface, and, on the other hand, a statistical analysis from a high number of repetitions of a complete measurement routine of the feature-based gauge. Thus, reliable dispersion values can be offered not only for different types of GD&T evaluations (form, dimensions, etc.) but also for the same GD&T evaluation over the same type of entity. Although the work proposes precision values depending on the type of GD&T being analyzed, it also proposes a novel reliable method of calculation of the probing error for a laser scanner mounted on an AACMM.
ISSN:0143-8166
1873-0302
DOI:10.1016/j.optlaseng.2019.04.007