Dewesoft Supplied Measurement Equipment to Maribor University

Dewesoft supplied the researchers at the Faculty of Mechanical Engineering of the University of Maribor (UM) with a unique integrated measuring system for stereo-optical fast digital recording of transients. This is the first scientific research equipment supplied as part of the operation Upgrading National Research Infrastructures – with the Slovenian abbreviation RIUM. The operation was supported by the Ministry of Education, Science and Sport in the amount of 29 million euros. Deliveries of the remaining equipment will follow in the next two years. Better composition of materials and constructions The mobile synchronized fast digital transient recording system developed by Dewesoft is designed for advanced digital visualization of extremely fast transients such as impact deformation of materials, vortexing and cavitation, injection molding, brittle fractures, rapid crack growth, explosion effects or missiles, and the like. The analysis of images made with ultra-fast speed cameras (2 million images per second) provides a better understanding of the basic physical laws of these phenomena and contributes to the improvement of the composition of materials, structures, or engineering processes and beyond, the University of Maribor explains. The measuring system and its users The mobile system is based on two high-speed Photron FASTCAM SA-Z high-speed cameras connected to the high-performance measuring system Dewesoft SIRIUSi HS 8x STG+ and supported by appropriate software for data capture and analysis, Photron FASTCAM VIEWER 4 (PFV4) and Dewesoft-X-PRO. The mobile system for synchronized fast digital recording of transients is located at the research group ACE-X at the Faculty of Mechanical Engineering, University of Maribor, but is also shared by other research groups at UM: Research Group on Energy, Process and Environmental Engineering (FS), Structural Evaluation Research Group (FS), Research Group on Production Cybernetics and Automation (FS), Research group for machine elements and constructions from IKO (FS), Laboratory for Organic and Polymer Chemistry and Technology (FKKT). Tasks of the ACE-X research group The ACE-X research group conducts basic, applied, and development research in the field of advanced computer engineering of materials, which includes complex geometric computer modeling and implementation of complex computer simulations of engineering problems, development of new methods and algorithms in nonlinear solid-state mechanics, fast transition mechanics, contact mechanics, and related problems. Research is focused on the development of new inhomogeneous cellular and composite materials with specific properties (deformability, auxetics, damping ...). The Group develops and implements procedures for use in various industrial applications, such as stress-strain analysis of mechanical components, impact and impact simulation analysis, failure analysis of structures and structural joints, and optimization of machine components and assemblies. The group has a computer team for performing parallel demanding and extensive computer simulations of HPC CORE@UM and its own Split-Hopkinson-Pressure-Bar testing room for determining the mechanical properties of materials at high loading speeds. Research in the field of modern materials (e.g. cellular and composite metamaterials), components, and structures exposed to impact loads at high strain rates require a synchronized high-speed digital recording system that allows the observation of the deformation of these materials at high loading rates. Such images are required for digital processing according to the DIC method (Digital Image Correlation), which allows accurate analysis of events in the material through the field of deformation. Promoting interdisciplinarity This allows additional verification of material parameters in extremely fast dynamic tests - such as the Split-Hopkinson-Pressure-Bar test site and is also very important for the successful validation of new computer models to study the possible use of advanced materials in modern structures. Here, the field of application is not limited to classical solids, but also allows the evaluation of deformation mechanics of other types of materials, such as softer tissues (used in medicine), fabrics (used in textiles), transients in liquids (used in process engineering), which will enable the establishment of wider interdisciplinary cooperation between the ACE-X research group and other participating research groups.