Structure Analysis for Pressure Vessels (Thesis Proposal Sample)

Abstract
It is being developed, as described in this work, unique methods for determining the stress concentration parameters within pressure pipes. In recent years, the study of stress concentration in pressure tubes has gained in interest, as seen by recent studies in the field's literature. Pressure vessels are utilised in a wide range of industrial applications, including thermal and nuclear power plants, as well as chemical and fluid delivery systems, to name a few. The primary goal of this research is to design and assess pressure vessels in order to better understand how they work. The design and testing processes for the Solid Pressure Vessel are in accordance with the Section VIII Division 1 standards of the American Society of Mechanical Engineers (ASME). A finite element package called ANSYS, which is quite adaptable, is used to study the stresses in the pressure vessel's solid wall and head. The pressure vessel values for the solid wall and head are compared between theoretical and ANSYS pressure vessel values.
ASME Code, Section VIII, Division 1 pressure vessels are governed by rules and do not necessitate a complete analysis of all stresses during the design process. Despite the possibility of large localised and secondary bending stresses, these can be addressed by increasing the safety factor and following design requirements for specific details. Therefore, all loadings must be taken into consideration (the forces imparted to a vessel or its structural attachments). In the scientific community, a pressure vessel is a container that is completely sealed and designed to maintain gases and liquids at elevated working pressures and temperatures that are higher than those found in the natural environment. In the pressure vessel, the cylindrical body, also known as the heads, is joined to one of the vessel's end capis. Using the finite element analysis (FEA) application ANSYS, the thickness and temperature distribution of a boiler pressure vessel will be computed in order to ensure that the design and operation parameters are optimised.
The analysis of static stress is carried out using an analytical technique known as 'Finite Element Analysis,' or FEA. By splitting the pressure vessel down into smaller, more manageable portions, this method makes the geometric representation of the pressure vessel more manageable. It is possible to apply loads and constraints to specific locations on the FEA model. For example, the model may be given the type of material as well as real constants such as surface area or thickness, volume or density, among other things. As a result, the mesh model is analysed using a FEA solver to determine its accuracy. Flow contours will be used to record the data in order to aid in the comprehension of the physical event being observed. Specifically, the goal of this research was to construct an axi-symmetrical pressure vessel capable of withstanding 0.1 MPa pressure while also determining the ideal wall thickness in order to minimise the greatest yield stresses possible. CATIA V5 R19 and Ansys Fluent are used to create the geometric model, with the former being used more frequently (meshed model) Working on static structural and thermal analysis in Ansys is a breeze with this tool.
Key words: Design, Analysis, Pressure vessel, ANSYS.