Numerical simulation of thermal and mechanical properties of sintered perforated hollow sphere structures (PHSS)

Öchsner, Andreas; Hosseini, Seyed Mohammad Hossein; Merkel, Markus

Title: Numerical simulation of thermal and mechanical properties of sintered perforated hollow sphere structures (PHSS)
Creator: Öchsner, Andreas; Hosseini, Seyed Mohammad Hossein; Merkel, Markus
Relation: 2009 International MultiConference of Engineers and Computer Scientists (IMECS 2009). IAENG Transactions on Engineering Technologies Volume 3: Special Edition of the International MultiConference of Engineers and Computer Scientists 2009 (Kowloon, Hong Kong 18-20 March, 2009) p. 16-30
Publisher Link: http://dx.doi.org/10.1063/1.3256244
Publisher: American Institute of Physics
Resource Type: conference paper
Date: 2009
Description: This paper investigates the thermal and mechanical properties of a new type of hollow sphere structures. For this new type, the sphere shell is perforated by several holes in order to open the inner sphere volume and surface. The effective thermal conductivity of perforated sphere structures in several kinds of arrangements, i.e. primitive cubic (PC), body‐centered cubic (BCC), face‐centered cubic (FCC) and hexagonal (Hex) unit cell models, is numerically evaluated for different hole diameters. In addition, mechanical properties of sintered perforated hollow sphere structures also have been evaluated for a unit cell in a PC arrangement with different hole diameters. The results are compared to classical configurations without perforation. In the scope of this study, three‐dimensional finite element analysis is used in order to investigate unit cell models. When the relative density decreases the heat conductivity also decreases. A linear behavior was found for the heat conductivity of different hole diameters for several kinds of arrangements when the results are plotted over the relative density. In addition, when the relative density increases the Young’s modulus and initial yield stress increase but Poisson’s ratio decreases.
Subject: thermal capacity; numerical analysis; mechanical properties
Identifier: http://hdl.handle.net/1959.13/936802
Identifier: uon:12408
Identifier: ISBN:9780735407138
Identifier: ISSN:0094-243X
Language: eng
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