Role of Plasticity in Nitinol Fatigue / Role of Plasticity in Nitinol Fatigue

Shayanfard, Pejman

January 2021

Disertace analyzuje vliv koncentrátorů napětí na průběh martensitické transformace, vznik plastické deformace a její vliv na přerozdělení napětí a vznik zbytkového pnutí a reziduálního martenzitu v okolí koncentrátorů v prvcích ze slitin s tvarovou pamětí NiTi. Vliv je analyzován v režimech superelastického isotermálního cyklování a aktuačního cyklování, t.j. teplotního cyklování pod vnějším napětím. Disertace využívá pro vyhodnocení vlivu experimentální přístup spolu s numerickými simulacemi metodou konečných prvků na modelových případech tenkých pásků ze slitin NiTi opatřených půlkruhovými vruby. V experimentální části je vyhodnocován vliv koncentrátorů pomocí termomechanických experimentů s využitím metod obrazové korelace a rentgenové mikrodifrakce pro lokální analýzu deformací a fázových objemových podílů v průběhu cyklování v okolí vrubů. Simulace metodou konečných prvků poskytují komplementární informace o průběhu napětí, deformací a martensitické transformaci, zejména o vývoji jednotlivých složek celkové deformace, tj. elastické a plastické, a vývoji zbytkového pnutí a s ním souvisejícím zbytkovým martensitem.Disertace je dále doplněna o numerickou analýzu vlivu konstrukce stentů na lokální cyklický průběh martensitické transformace a jeho vliv na únavové vlastnosti.

Hodnocení vlastností NiTi nástrojů v současné endodoncii / Evaluation of the properties of NiTi instruments in current endodontics

Bumbálek, Michal

January 2022

Introduction: One of the key prerequisites of high-quality endodontic treatment is the use of endodontic NiTi instruments for the preparation of root canals. The purpose of this dissertation is to evaluate the effect of individual factors which influence the life of endodontic instruments during the clinical treatment of root canals. The dissertation will evaluate the effect the curvature of the canals, the shape of the tip of the instrument, the speed and type of rotation, and the influence of sterilization. The effect of low-temperature plasma nitriding on the fatigue life of the instruments will also be investigated. Materials and methods: Several endodontic systems used for the machine preparation of root canals were studied. The study focused predominantly on the cyclic fatigue of rotary endodontic instruments, wherein the files were rotated in artificial curved root canals. Additionally, the influence of sterilization on the life of the instruments was also examined. Finally, the instruments were treated using thermal plasma nitridation for the purpose of improving their properties. The instruments were then analyzed using a scanning electron microscope and a microhardness meter. Results: Testing cyclic fatigue in artificial root canals with radii R3 and R5 revealed that instruments with a...

Studium funkčních vlastností tenkých vláken NiTi pro aplikace v smart strukturách a textiliích / Investigation of Functional Properties of Thin NiTi Filaments for Applications in Smart Structures and Hybrid Textiles

Pilch, Jan

January 2011

PhD thesis focuses the field of textile application of modern functional materials, namely metallic shape memory alloys with unique thermomechanical properties deriving from martensitic transformation in solid state. Particularly, it deals with the development of a nonconventional thermomechanical treatment of thin NiTi filaments via Joule heating by electric current and related basic research involving thermomechanical testing and modeling of functional properties of the filaments, investigation of martensitic transformations and deformation processes in NiTi and investigation of the fast recovery and recrystallization processes in metals heated by short pulses of controlled electric power. The method was developed and called FTMT-EC. In contrast to conventional heat treatment of metallic filaments in environmental furnaces, this method allows for precise control of the raise of the filament temperature and filament stress during the fast heating (rate ~50 000 °C/s). As a consequence, it is possible to precisely control the progress of the fast recovery and recrystallization processes in heat treated filaments. In this way it is possible to prepare filaments with desired nanostructured microstructure and related functional properties. A prototype equipment for application of the method for heat treatment of continuous SMA filaments during respooling in textile processing was designed and built. Comparing to the conventional heat treatment of SMA filaments in tubular environmental furnaces, this approach is faster, saves energy and allows for preparation of filaments with special functional properties. International patent application was filed on the method. It is currently utilized in the research and development of smart textiles for medical applications.

Studium funkčních vlastností tenkých vláken NiTi pro aplikace v smart strukturách a textiliích / Investigation of Functional Properties of Thin NiTi Filaments for Applications in Smart Structures and Hybrid Textiles

Pilch, Jan

January 2011

PhD thesis focuses the field of textile application of modern functional materials, namely metallic shape memory alloys with unique thermomechanical properties deriving from martensitic transformation in solid state. Particularly, it deals with the development of a nonconventional thermomechanical treatment of thin NiTi filaments via Joule heating by electric current and related basic research involving thermomechanical testing and modeling of functional properties of the filaments, investigation of martensitic transformations and deformation processes in NiTi and investigation of the fast recovery and recrystallization processes in metals heated by short pulses of controlled electric power. The method was developed and called FTMT-EC. In contrast to conventional heat treatment of metallic filaments in environmental furnaces, this method allows for precise control of the raise of the filament temperature and filament stress during the fast heating (rate ~50 000 °C/s). As a consequence, it is possible to precisely control the progress of the fast recovery and recrystallization processes in heat treated filaments. In this way it is possible to prepare filaments with desired nanostructured microstructure and related functional properties. A prototype equipment for application of the method for heat treatment of continuous SMA filaments during respooling in textile processing was designed and built. Comparing to the conventional heat treatment of SMA filaments in tubular environmental furnaces, this approach is faster, saves energy and allows for preparation of filaments with special functional properties. International patent application was filed on the method. It is currently utilized in the research and development of smart textiles for medical applications.