1315 KB0 KB201420252024Ačko, BojanČrepinšek-Lipuš, LucijaKlobučar, Rokletnik:19številka:3str. 386-394DOI:10.14743/apem2024.3.514ISSN:1854-6250COBISSID_HOST:220036867URN:URN:NBN:SI:doc-5RW9J3T5enFakulteta za strojništvo, Inštitut za proizvodno strojništvoAdvances in production engineering and managementcoordinate measuring machinečrtno merilodimensional metrologydimenzijsko meroslovjehigh resolution measurementskoordinatni merilni strojlaser interferometrylaserska interferometrijaline scalemeasurement uncertaintymerilna negotovostmeritve visoke ločljivostinatančna sondaprecise probeEnhancing calibration accuracy with laser interferometry for high-resolution measuring systems|This paper presents an analysis of the measurement capability of laser interferometry for calibrating high-resolution measuring systems, focusing on potential errors that need to be carefully controlled to ensure adequate metrological traceability. The primary scientific research focus of our National Dimensional Metrology Laboratory is the development of metrological applications for industry, with ongoing improvements in calibration procedures for measuring machines and tools. Through a review of possible error sources, an innovative approach to reducing the most significant factors is proposed. This is specifically applied to the following calibration cases: field calibration of coordinate measuring machines, and laboratory calibration of precision probes and line scales. Instrumental and environmental errors can be effectively mitigated by using periodically calibrated laser interferometers in well-controlled air conditions, ensuring an uncertainty of 0.2 µm/m. Most geometrical errors can be minimized by precise adjustments to the interferometry and positioning systems, achieving an uncertainty of 0.3 µm/m. However, errors caused by temperature differences in the material along the measuring path remain the most influential. These arise due to the high expansion coefficient of the material and some uncertainty in its properties. After several hours of temperature stabilization, using three temperature sensors along the displacement range for software compensation, temperature differences still contribute significantly to measurement uncertainty. For example, the error is 0.5 µm/min in the case of line scale calibration and 1.1 µm/m for coordinate measuring machine calibrationTEXTznanstveno časopisjejournalsSlovenian National E-content AggregatorNational and University Library of SloveniaUniverza v Mariboru, Fakulteta za strojništvo