iPhoneAlle anzeigen
iPhone 11iPhone 11 ProiPhone 11 Pro MaxiPhone 12iPhone 12 ProiPhone 12 Pro MaxiPhone 12 miniiPhone 13iPhone 13 ProiPhone 13 Pro MaxiPhone 13 miniiPhone 14iPhone 14 PlusiPhone 14 ProiPhone 14 Pro MaxiPhone 15iPhone 15 PlusiPhone 15 ProiPhone 15 Pro MaxiPhone 16iPhone 16 PlusiPhone 16 ProiPhone 16 Pro MaxiPhone 16eiPhone 8iPhone 8 PlusiPhone SE 2020iPhone SE 2022iPhone XiPhone XRiPhone XSiPhone XS Max
Galaxy A-SerieAlle anzeigen
Galaxy A12Galaxy A13Galaxy A13 5GGalaxy A14Galaxy A15Galaxy A16Galaxy A17 5GGalaxy A20eGalaxy A21Galaxy A22Galaxy A23Galaxy A24Galaxy A25Galaxy A26 5GGalaxy A32Galaxy A33Galaxy A34Galaxy A35Galaxy A36 5GGalaxy A40Galaxy A41Galaxy A42Galaxy A50Galaxy A51Galaxy A52Galaxy A53Galaxy A54Galaxy A55Galaxy A56 5GGalaxy A70Galaxy A71Galaxy A72
Redmi SeriesAlle anzeigen
Redmi 10Redmi 13CRedmi 15 5GRedmi Note 10Redmi Note 10 ProRedmi Note 11Redmi Note 11 ProRedmi Note 11 Pro Plus 5GRedmi Note 11sRedmi Note 12Redmi Note 12 5GRedmi Note 12 ProRedmi Note 12 Pro 5GRedmi Note 12 Pro PlusRedmi Note 13Redmi Note 13 5GRedmi Note 13 ProRedmi Note 13 Pro PlusRedmi Note 14Redmi Note 14 Pro PlusRedmi Note 8Redmi Note 8 ProRedmi Note 9Redmi Note 9 Pro
- Startseite
Bücher Englische Bücher Wissen & Bildung Naturwissenschaft, Medizin, Informatik, Technik Technik Maschinenbau & Fertigungstechnik Simulation of Thermo-Chemo-Mechanical Coupled Additive Manufacturing Processes using Peridynamics
Derzeit nicht verfügbar
Handgeprüfte Gebrauchtware
Bis zu 50 % günstiger als neu
Der Umwelt zuliebe
Simulation of Thermo-Chemo-Mechanical Coupled Additive Manufacturing Processes using Peridynamics
Philipp Hartmann (Unbekannter Einband, Englisch)
★★★★★
☆☆☆☆☆ Keine Bewertungen vorhanden
Optischer Zustand
Beschreibung
In the health care industry the treatment of neural hearing loss with cochlear implants is a well-established medical intervention. Since only standard implant sizes are available, a patient-specific Additive Manufacturing (AM) process to improve their functionality is desirable. Therefore, a prototype 3D-printer device for the manufacturing of Room Temperature Vulcanisation (RTV) medical grade… silicon was built by the Excellence Cluster Hearing4all of Hannover Medical School. However, a comprehensive understanding of the material behaviour during the extrusion-based printing process does not exist and is currently not possible. The crucial point in the AM process is the material spreading during the curing being reduced by the application of laser radiation.
As a result, a simulation driven support to capture the influence of processing parameters and to optimise the process is desirable.
The objective of this work is the development of a numerical framework enabling the simulation of the underlying AM process in the sense of a proof of concept. Thus, a continuum mechanical large strain curing model is developed, which is capable of showing the curing specific phenomenological behaviour. In contrast to existing models the developed model includes an extension to finite plasticity to relate the spreading of material in the uncured state to dissipative behaviour.
Furthermore, a meshfree discretisation of an enhanced peridynamic correspondence formulation, based on subdivisions of the influence domain to prohibit arising instabilities in the deformation field, is implemented as a numerical solution.
Due to the application of the developed local material model within the non-local theory of Peridynamics, local-non-local coupled equations for the equation of motion and the energy equation arise. Furthermore, the specific laser impact and convective boundary conditions are modelled within the energy equation by volumetric heat source terms.
In numerical examples the capability of the enhanced correspondence formulation for simulations at large strains is shown. Moreover, the plasticity in the developed large strain curing model appears to be well-suited for the modelling of material spreading in the fluid-like state. Additionally, the thermo-chemo-mechanical coupled behaviour of a reduced material spreading with respect to the application of higher temperatures resulting in an accelerated curing is verified.
Finally, simulations of the material extrusion are performed, whereby in the final simulation of the complete AM process a reduced material spreading due to the application of laser radiation is observed. The results are overall in line with the modelled phenomena and expected behaviour.
Consequently, a successful proof of concept of the simulation of the AM process is performed and it is desirable to add additional physical effects in the developed framework. Dieses Produkt haben wir gerade leider nicht auf Lager.
Handgeprüfte Gebrauchtware
Bis zu 50 % günstiger als neu
Der Umwelt zuliebe
Technische Daten
Erscheinungsdatum
17.10.2019
Sprache
Englisch
EAN
9783941302341
Herausgeber
Institut für Kontinuumsmechanik
Sonderedition
Nein
Autor
Philipp Hartmann
Seitenanzahl
181
Einbandart
Unbekannter Einband
Schlagwörter
Multi-physical coupling, Peridynamics, Curing, Additive Manufacturing
Thema-Inhalt
TBC - Ingenieurswesen, Maschinenbau allgemein
TGMD - Maschinenbau: Festkörpermechanik
-.-
★★★★★
☆☆☆☆☆ Leider noch keine Bewertungen
Leider noch keine Bewertungen
Sicher bei rebuy kaufen
Schreib die erste Bewertung für dieses Produkt!
Wenn du eine Bewertung für dieses Produkt schreibst, hilfst du allen Kund:innen, die noch überlegen, ob sie das Produkt kaufen wollen. Vielen Dank, dass du mitmachst!
Sicher bei rebuy kaufen