Digital image correlation technique as a tool for kinematics assessment of structural components

• Autorzy: Brodecki A. , Szymczak T. , Kowalewski Z.

Identyfikatory

DOI

I 10.2478/ama-2018-0016

• Języki publikacji: EN

Abstrakty

EN

The paper reports the results of tests carried out for kinematic properties determination of components under cyclic loading. DIC system called 5M PONTOS was employed to follow variations of displacement versus time. It was conducted by the use of markers stuck on selected sections of components tested. The results are presented in 2D and 3D coordinate systems expressing behaviour of such elements as: mechanical coupling device, boat frame and car engine. These data enabled to capture weak and strong sections of the component examined at various loading conditions.

Słowa kluczowe

EN

digital image correlation system; cyclic loading; PONTOS; motion; displacement; 3D coordinate system

• Wydawca: Oficyna Wydawnicza Politechniki Białostockiej
• Czasopismo: Acta Mechanica et Automatica
• Rocznik: 2018
• Tom: Vol. 12, no. 2
• Strony: 101--104
• Opis fizyczny: Bibliogr. 14 poz., rys., wykr.

Twórcy

autor

Brodecki A.

• Centre for Material Testing, Motor Transport Institute, ul. Jagiellońska 80, 03-301 Warszawa, Poland

autor

Szymczak T.

• Centre for Material Testing, Motor Transport Institute, ul. Jagiellońska 80, 03-301 Warszawa, Poland

autor

Kowalewski Z.

• Department of Experimental Mechanics, Institute of Fundamental Technological Research, ul. Pawińskiego 5B, 02-106 Warszawa, Poland

Bibliografia

• 1. Baqersada J., Carra J., Lundstroma T., Niezrecki Ch., Avitabilea P., Slattery M., (2012), Dynamic characteristics of a wind turbine blade using 3D digital image correlation, Health Monitoring of Structural and Biological Systems 2012, edited by Tribikram Kundu, Proc. of SPIE, 8348.
• 2. Berger H., Klein M., Lambert F., Levadoux B., (2010), Optical Vibration Measurement and Frequency Response Analysis on Large Structures under Multiple Excitation Load Conditions, Proceedings of ISMA2010 including USD2010, 1693–1702.
• 3. Bornert M., Brémand F., Doumalin P., Dupré J.-C., Fazzini M., Grédiac M., Hild F., Mistou S., Molimard J., Orteu J.-J., Robert L., Surrel Y., Vacher P., Wattrisse B., (2009), Assessment of Digital Image Correlation Measurement Errors: Methodology and Results, Experimental Mechanics, 49, 353–370.
• 4. Brinkmann Ch., Haberland J., Böttinger S., Erne O., Sanow G., (2007), Optical 3D Measuring System for Investigating Tyre Deformations, Tractor Technology, 62(5), 326–327.
• 5. Chu T.C., Ranson W.F., Sutton M.A., Peters W.H., (1985), Applications of digital-image-correlation techniques to experimental mechanics, Experimental Mechanics, 232–244.
• 6. Creager C., Johnson K., Plant M., Moreland S., Skonieczny K., (2015), Push–pull locomotion for vehicle extrication, Journal of Terramechanics, 57, 71–80.
• 7. Gower M.R., Shaw R.M., (2006), Towards a planar cruciform specimen for biaxial characterization of polymer matrix composites, Applied Mechanics and Materials, 24–25, 115–120.
• 8. Kamaya M., Kawakubo M., (2011), A procedure for determining the true stress–strain curve over a large range of strains using digital image correlation and finite element analysis, Mechanics of Materials, 43, 243–253.
• 9. Long X., Fu S., Qi Z., Yang X., Yu Q., (2012), Digital image correlation using stochastic parallel-gradient-descent algorithm, Experimental Mechanics, DOI 10.1007/s11340-012-9667-4.
• 10. Szymczak T., Kowalewski Z.L., Brodecki A., (2016a), Determination of artificial defects in material under monotonic tension by the use of FEM and DIC methods, Materials Today: Proceedings, 3, 1171–1176.
• 11. Szymczak T., Kowalewski Z.L., Brodecki A., (2016b), Digital Image Correlation method for investigations of materials and engineering structures, Technical Suspervision (Dozór Techniczny), 4, 22–3 (in Polish).
• 12. Toussaint F., Tabourot I., Vacher P., (2008), Experimental study with a Digital Image Correlation (DIC) method and numerical simulation of an anisotropic elastic-plastic commercially pure titanium, Archives of Civil and Mechanical Engineering, VIII, 3, 131–143.
• 13. Regulation No 55 of the Economic Commission for Europe of the United Nations (UN/ECE) — Uniform provisions concerning the approval of mechanical coupling components of combinations of vehicles, 28.08.2010.
• 14. www.gom.com

Uwagi

This work has been supported by the National Science Centre through the Grant No 2014/15/B/ST8/04368 and the statutory project No. 6506/CBM/ITS founded by Ministry of Science and Higher Education.