| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Lindroos, Tomi
VTT Technical Research Centre of Finland
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (55/55 displayed)
- 2024Lessons Learnt - Development Of Additive Manufacturing For Soft Magnetic Electric Motor Components
- 2024Nitrogen alloyed austenitic Ni-free stainless steel for additive manufacturingcitations
- 2023Estimating Long Term Behaviour Of DED-printed AlCoNiFe Alloy
- 2023Estimating Long Term Behaviour Of DED-printed AlCoNiFe Alloy
- 2023The effect of heat treatment on structure and magnetic properties of additively manufactured Fe-Co-V alloyscitations
- 2023Performance Driven Design And Modeling Of Compositionally Complex AM Al-Co-Ni-Fe Alloys
- 2023Performance Driven Design And Modeling Of Compositionally Complex AM Al-Co-Ni-Fe Alloys
- 2023High-Entropy Carbides:Processing And Characterization
- 2023Nitrogen Alloyed Austenitic Ni-free Stainless Steel For Additive Manufacturingcitations
- 2023High-Entropy Carbides: Processing And Characterization
- 2022Single-Track Laser Scanning as a Method for Evaluating Printability: The Effect of Substrate Heat Treatment on Melt Pool Geometry and Cracking in Medium Carbon Tool Steelcitations
- 2022Effect of alloying elements on Fe-Si-X soft magnetic material produced by AM and PM
- 2022Laser Powder Bed Fusion Of High Carbon Tool Steels
- 2022Lessons learnt - additive manufacturing of iron cobalt based soft magnetic materialscitations
- 2022Experimental and Calphad Methods for Evaluating Residual Stresses and Solid-State Shrinkage after Solidificationcitations
- 2022Opportunities Of Physics-Based Multi-Scale Modeling Tools In Assessing Intra-Grain Heterogeneities, Polycrystal Properties And Residual Stresses Of AM Metals
- 2021Micromechanical modeling approach to single track deformation, phase transformation and residual stress evolution during selective laser melting using crystal plasticitycitations
- 2019Properties of soft magnetic Fe-Co-V alloy produced by laser powder bed fusioncitations
- 2019Topology optimized soft magnetic cores by laser powder bed fusion
- 2019CRM free hard metals for high abrasive wear applications
- 2018Mechanical and magnetic properties of Fe-Co-V alloy produced by Selective Laser Melting
- 2018Micromechanical modeling of titanium carbide composites with high work hardening metal matrix
- 2017Soft magnetic alloys for selective laser melting
- 2017High wear resistance TiC metal matrix composites based on reactive hot pressing
- 2017Microstructural and mechanical characterization of ODS alloy produced by surface oxidation method
- 2017Feasibility of selective laser melting process in manufacturing of digital spare parts
- 2017Circular Economy Concept In Additive Manufacturing
- 2017Nanostructural WC-Co coatings by utilizing novel powder manufacturing route using water soluble raw materials
- 2016Preparing nano structural WC-Co powders by utilizing soluble raw materials by spray drying and synthesis method
- 2016Synthesis of nano structural Cr 3 C 2 powders from water soluble precursors
- 2016Component scale process model for metal additive manufacturing
- 2016Manufacturing of topology optimized soft magnetic core through 3D printing
- 2016Reaction heat potential utilization in mullite and spinel based ceramics synthesis and sintering
- 2016Synthesis of nano structural Cr3C2 powders from water soluble precursors
- 2015Characterization of Gas Atomized Ni-Mn-Ga powderscitations
- 2015Novel titanium carbide based hard metal alternative for traditional WC-Co
- 2012Microstructure analysis and damage patterns of thermally cycled Ti-49.7Ni (at.%) wirescitations
- 2011Adjustable epoxy based vibration damping material (CLD) with an extremely high loss factor
- 2011Determination and validation of viscoelastic material model for an epoxy compound in constrained layer damping applications
- 2011Adaptive wire rope isolator
- 2011R-phase actuated SMA composites in adaptive wind turbine blade trailing edge
- 2009Shape Control of a FRP Airfoil Structure Using SMA-actuators and Optical Fiber Sensorscitations
- 2009Model-Based Control of SMA Actuators with a Recurrent Neural Network in the Shape Control of an Airfoilcitations
- 2007SULAWIND - Intelligent Wind Turbine Components and Structures
- 2007Semi-active vibration control based on shape memory alloy actuators:Analysis and experimental testing
- 2007Dynamic compression testing of a tunable spring element consisting of a magnetorheological elastomercitations
- 2007Semi-active vibration control based on shape memory alloy actuators
- 2007InMAR - Intelligent Materials for Active Noise Reduction
- 2006Fe-Cr-X alloys:Steels with enhanced damping capacity
- 2006Elastomer isolator with an SMA actuator for vibration control
- 2006Fe-Cr-X alloys
- 2005Damping properties of steel compounds
- 2003Preliminary test on a MRE device
- 2003Processing and properties of metal matrix composites synthesized by SHScitations
- 2003Method for the manufacture of a metal matrix composite, and a metal matrix composite
Places of action
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document
Damping properties of steel compounds
Abstract
Vibration damping is usually divided in five differentdamping mechanisms. They include internal materialdamping, interface damping (friction damping), radiationdamping, energy losses occurring as a result ofreflection at discontinuities of structures, and viscousdamping caused by viscoelastic material or by surroundingfluid. Internal friction of metals is due to the internalmismatch in the material microstructure. In most of thecases mechanisms related to internal friction havenegligibly small effect on the total damping capacity ofthe structure. Some metal alloys exhibit exceptionallyhigh inherent damping capacity. The mechanismsinfluencing the damping properties of the high dampingmetals (HIDAMETs) can be categorized to four types ofbasic mechanisms: multiphase structure, ferromagnetism,dislocation damping and the damping due to movable twinboundaries.This paper deals with the internal damping of homogeneousmaterials due to the magnetomechanical damping offerromagnetic material and the energy losses occurring atthe interfaces of multilayer materials. The dampingproperties of a normal structural steel, Fe-Cr basedHIDAMET and the combinations of these materials arestudied. Typical applications of these types of materialsmay require strength, stiffness or wear resistance andhostile operating conditions combined with good dampingproperties. Traditional measuring methods are used forthe determination of the damping coefficients. Themeasured damping values consists of internal materialdamping, radiation damping, viscous damping caused by thesurrounding air and specimen mounting. The dampingproperties of the multilayer materials based on HIDAMETsare compared to the traditional damping treatments. Basicequations given in the literature are verified usingexperimental results of multilayer materials. Thestiffness of multilayer structures is also studied.HIDAMETs offer an alternative for controlling the dampingproperties especially in harsh environments when widetemperature range is needed.