Скачать с ютуб Ansys Mechanical Discussion 7 : Joule heating modelling in Ansys Mechanical в хорошем качестве

Ansys Mechanical Discussion 7 : Joule heating modelling in Ansys Mechanical

#finiteelementmethod #ansystutorial #multiphysics #jouleheating#thermal AGENDA 1: Introduction 2: Different approach of solving joule heating problem In Mechanical 3: Demo :- One way coupling 4: Demo :- Two-way coupling Joule heating, also known as resistive heating, is the phenomenon that occurs when an electric current flows through a material, resulting in the conversion of electrical energy into heat energy. This process plays a significant role in many industrial and technological applications, and can be studied using the finite element method (FEM) in order to understand and predict the distribution of heat within a system. The FEM is a powerful numerical technique that can be used to solve a wide range of engineering problems, including those involving Joule heating. The method involves dividing a complex structure into a large number of small, interconnected elements, and then solving for the temperature distribution within each element. This allows for a detailed analysis of the heat distribution within a system, and can be used to optimize the design of a system in order to minimize heat loss and improve efficiency. One of the key advantages of using FEM to study Joule heating is that it allows for the modeling of non-uniform current distributions, which is important in many industrial applications. For example, in an electric motor, the current is not uniform throughout the stator and rotor, and FEM can be used to model this non-uniform distribution and predict the resulting heat distribution. Additionally, FEM can be used to model the effects of different materials and geometries on the heat distribution within a system, which is critical for the optimization of system design. In addition to its use in industrial applications, FEM can also be used to study Joule heating in a wide range of other systems, including biomedical devices, electronic devices, and energy storage systems. For example, in a biomedical device, FEM can be used to model the heat generated by an implantable device and predict the resulting thermal effects on the surrounding tissue. In electronic devices, FEM can be used to predict the temperature distribution within a device and optimize the design in order to minimize thermal stress and improve performance. In conclusion, Joule heating is a fundamental phenomenon that plays a significant role in many industrial and technological applications. The finite element method (FEM) is a powerful numerical technique that can be used to study Joule heating in order to understand and predict the distribution of heat within a system. Its ability to model non-uniform current distributions, effects of different materials and geometries, makes it a very useful tool in studying Joule heating. Additionally, FEM can be applied in a wide range of other systems, including biomedical devices, electronic devices, and energy storage systems. #Ansys tutorials Ansys FEA #Ansys simulation Ansys structural analysis Ansys mechanical Ansys tutorial for beginners Ansys simulation software Ansys tips and tricks Ansys tutorial video Ansys mechanical tutorial Ansys FEA tutorial Ansys structural analysis tutorial Ansys tutorial for mechanical engineers #Ansys simulation training Ansys simulation tips Ansys tutorial for students tutorial for engineers Ansys simulation examples