Deutsche Akkreditierungsstelle GmbH Annex to the Accreditation Certificate D-K-15133-02-00 according to DIN EN ISO/IEC 17025:2005 Period of validity: 24.01.2018 to 23.01.2023 Holder of certificate: Hexagon Metrology GmbH Siegmund-Hiepe-Straße 2-12, 35578 Wetzlar with its calibration laboratory Hexagon Calibration Services Bergstraße 3, 35080 Bad Endbach Head: Deputy head: Dipl.-Ing. (FH) Carsten Schwehn Dipl.-Ing. (FH) Michael Trenk Accredited as calibration laboratory since: 11.04.2017 Calibration in the fields: Dimensional quantities Coordinate measuring technology - Virtual machines - Step gauges Length - Line scales, distances - Diameter - Length gauges - Gear quantities Abbreviations used: see last page This document is a translation. The definitive version is the original German annex to the accreditation certificate. Page 1 of 6
Permanent Laboratory quantity / Coordinate measuring technology Prismatic workpieces Coordinate measuring machines with a calibrated measuring volume of: X = 1800 mm Y = 1000 mm Z = 600 mm Balls Large diameter to 50 mm Tactile measurement in the form of single-points measurements using a calibrated coordinate measuring machine and determination of geometric parameters defined through control geometries (single points, straight lines, planes, circles, balls, cylinders, tapers, toroids) using the evaluation software of the machine Single-point measuring can be carried out either with fixed, predefined measuring force or with extrapolation on measuring force zero. Single-point measurements in the form of Self-centring measurements are not used within the framework of the accreditation The calibration values can be determined in a multilayer process by centering in order to reduce the measurement uncertainty Substitution measurement on a calibrated machine with tactile single-point measurement capability determined using the machine method based on VDI/VDE 2617 part 7:2008 through simula-tion is specific to each task and is started through multiplication of the standard uncertainty by a coverage factor k = 2 The use of the multilayer method refers to the mean value determined simulated measurement uncertainty for bidirectional length measurement uncertainties on steel artefacts in measuring positions according to DIN EN ISO 10360-2:2010 in the specified measurement volume for central styluses (zero clearance between centre of the ball center and the spindle axis): UE0 = 0,8 µm + 2,5 10-6 L and for measurements with lateral styluses (150 mm clearance between centre of the ball center and the spindle axis) maximum: UE150 = + 2,5 10-6 L 0,3 µm L = measured length Calibration in the DAkkS calibration laboratory only determined for general measurement tasks within the framework of the accreditation is specific to each task and can therefore differ significantly from the stated length measurement uncertainty The declared uncertainty which is given here is only valid as an example for the described simple measuring tasks For general measuring tasks reffered to the accreditated scope the measuring uncertainty could be significant differenty Period of validity: 24.01.2018 to 23.01.2023 - Translation - Page 2 of 6
quantity / Balls Diameter 5 mm to 50 mm Length standards for optical measurement technology Cylindrical setting gauges Diameter Substitution measurement on a calibrated machine with tactile single-point measurement 0 mm to 2 Distance measurement with optical sensor on a calibrated coordinate measuring machine. The distance is between symmetrical 2D-structure elements (center of a circle, straight line, reticle). uncertainty using the Virtual part 7:2008 taking account of the substitution effect In case of straight lines the distance measurement is carried out from the middle of the line or via a dashed side as unidirectional distance capability 0,3 µm determined using the machine method based on VDI/VDE 2617 part 7:2008 through simulation is specific to each task and is started through multiplication of the standard uncertainty by a coverage factor k = 2 The use of the multilayer method refers to the mean value determined simulated measurement uncertainty No circular measurement of the sphere surface (usually measurement of the hemisphere) 0 mm to 995 mm Axially parallel 0,85 µm + 1,6 10-6 L L = measured length > 995 mm to 1800 mm Axially parallel 0,90 µm + 2,0 10-6 L > 1800 mm to 2 Diagonally / Connection measurement 1 mm to 50 mm 1,00 µm + 2,4 10-6 L Virtual coordinate machine method on the basis of VDI/VDE 2617 part 7:2008 taking account of the substitution effect 0,3 µm Period of validity: 24.01.2018 to 23.01.2023 - Translation - Page 3 of 6
quantity / capability Ball plate / Hole plate to 0,13 µm + 0,72 10-6 L Ball bar / Hole bar to 1100 mm 0,13 µm + 0,72 10-6 L Gauge block to 1000 mm 0,09 µm + 0,35 10-6 L Step gauge to 1200 mm 0,09 µm + 0,35 10-6 L Gear quantities Profile deviation Base diameter: db Evaluation range: Lα 80 mm db 8,5 mm Lα 60 mm db 5 mm Lα 8 mm db Lα 150 mm db Lα 120 mm 26 mm 130 mm 30 mm 150 mm 150 mm Substitution measuring with coordinate measuring machines: Correction of, by comparision against involute artefact with: db = 100 mm Lα = 23 mm without correction traceability proved by involute artefact with: db = 100 mm Lα = 23 mm 0,9 µm 0,6 µm 1,7 µm 0,6 µm 1,9 µm 1,8 µm 0,6 µm 2,9 µm 2,6 µm L = measured length Distance between two hole and ball center points L = measured length 2-point distance about gauge block configuration (inside / outside) External gears ISO 1328-1:2017 Period of validity: 24.01.2018 to 23.01.2023 - Translation - Page 4 of 6
quantity / Helix deviation Helix angle: β Evaluation range: Lβ 85 mm 59 mm 50 mm 85 mm 59 mm 7 53 mm 7 85 mm 55 mm 25 53 mm 23 60 mm 2 β = β = β = 125 mm 135 mm 82 mm 125 mm 23 135 mm 77 mm 23 125 mm 35 135 mm 77 mm 37 89 mm 5 89 mm 2 25 89 mm 4 45 Substitution measuring with coordinate measuring machines: Correction of, by comparision against helix artefact with: d = 100 mm Lβ = 64 mm β = β = 15 r+l β = 3 r+l without correction traceability proved by helix artefact with: d = 100 mm Lβ = 64 mm β = β = 15 r+l β = 3 r+l capability 1,3 µm 1,3 µm 1,3 µm 1,4 µm 1,4 µm 1,8 µm 1,4 µm 2,9 µm 2,6 µm 1,7 µm 3,0 µm 2,8 µm 2,0 µm 1,8 µm 3,2 µm 3,0 µm External gears ISO 1328-1:2017 Period of validity: 24.01.2018 to 23.01.2023 - Translation - Page 5 of 6
quantity / Pitch Fp fp Runout Normal module: mn 5 mm mn 0,5 mm Normal module: mn Fr 5 mm mn Profile deviation Helix deviation 0,5 mm Base diameter: dp Evaluation range: Lα 8 mm db Lα 150 mm Helix angle: β Evaluation range: Lβ 100 mm 100 mm 45 45 According to Rosette method with machines According to Rosette method with coordinate measuring machines Calculation of the runout from the division points without correction; traceability proved by involute artefact with: db = 100 mm Lα = 23 mm without correction; traceability proved by helix artefact with: d = 100 mm Lβ = 64 mm β = β = 15 r+l β = 3 r+l capability 0,9 µm 1,2 µm 2,5 µm 2,2 µm 1,0 µm 2,5 µm 2,3 µm 1,0 µm 9,3 µm 9,0 µm 2,0 µm Internal and external gears ISO 1328-1: 2017 VDI/VDE 2613:2003 Internal gears ISO 1328-1: 2017 Internal gears ISO 1328-1: 2017 Abbreviations used: DAkkS-DKD-R Calibration Guideline of Deutsche Akkreditierungsstelle GmbH VDI/VDE 2617 Guideline: Accuracy of machines β Helix angle F p Total pitch error d Reference diameter f p Single pitch deviation d b Base diameter F r Runout error F α Total profile deviation L α Profile evaluation range f Hα Profile slope deviation L β Helix evaluation range f fα Profile form deviation m n Normal module F β Total helix deviation r+l Right hand and left hand f fβ Helix form deviation Helix slope deviation f Hβ Period of validity: 24.01.2018 to 23.01.2023 - Translation - Page 6 of 6