Development of Si-SiC hybrid structures for elevated temperature micro-turbomachinery
Development of Si-SiC hybrid structures for elevated temperature micro-turbomachinery
The design of the Massachusetts Institute of Technology (MIT) microengine is limited in part by the material capability of Si primarily due to the pronounced thermal-softening and strain-softening at temperatures higher than the brittle-to-ductile transition temperature (BDT), approximately 550/spl deg/C. In order to circumvent this limitation, it has been proposed to reinforce the Si with chemical vapor deposited (CVD) SiC in strategic locations to create a Si-SiC hybrid microengine turbine spool. Detailed design of Si-SiC hybrid structures for high temperature micro-turbomachinery, however, has been hampered by the lack of understanding of the mechanical behavior of Si and SiC hybrid structures at elevated temperatures and by the unavailability of accurate material properties data for both Si and SiC at the temperatures of interest. In this work, a series of initial thermomechanical FE analyzes have been performed to assess the advantage of the hybrid structures, and to provide structural design criteria and fabrication requirements. Then, the feasibility of the Si-SiC hybrid structures concept for elevated temperature micro-turbomachinery was verified based on more rigorous mechanical testing at high temperatures. Finally, the Si-SiC hybrid spool design was critically reevaluated with regard to creep using a Si constitutive model developed as a separate effort.
finite element analysis, MIT, Massachusetts Institute of Technology, Si–, SiC hybrid structures, mechanical testing, microengine
676-87
Moon, Hyung-Soo
55253499-0c70-4b5b-8798-3b9194fea5bf
Choi, Dongwon
f6ecd2d1-4cc0-4032-af72-5a02a1155e18
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
2004
Moon, Hyung-Soo
55253499-0c70-4b5b-8798-3b9194fea5bf
Choi, Dongwon
f6ecd2d1-4cc0-4032-af72-5a02a1155e18
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Moon, Hyung-Soo, Choi, Dongwon and Spearing, S.M.
(2004)
Development of Si-SiC hybrid structures for elevated temperature micro-turbomachinery.
Journal of Microelectromechanical Systems, 13 (4), .
(doi:10.1109/JMEMS.2004.832182).
Abstract
The design of the Massachusetts Institute of Technology (MIT) microengine is limited in part by the material capability of Si primarily due to the pronounced thermal-softening and strain-softening at temperatures higher than the brittle-to-ductile transition temperature (BDT), approximately 550/spl deg/C. In order to circumvent this limitation, it has been proposed to reinforce the Si with chemical vapor deposited (CVD) SiC in strategic locations to create a Si-SiC hybrid microengine turbine spool. Detailed design of Si-SiC hybrid structures for high temperature micro-turbomachinery, however, has been hampered by the lack of understanding of the mechanical behavior of Si and SiC hybrid structures at elevated temperatures and by the unavailability of accurate material properties data for both Si and SiC at the temperatures of interest. In this work, a series of initial thermomechanical FE analyzes have been performed to assess the advantage of the hybrid structures, and to provide structural design criteria and fabrication requirements. Then, the feasibility of the Si-SiC hybrid structures concept for elevated temperature micro-turbomachinery was verified based on more rigorous mechanical testing at high temperatures. Finally, the Si-SiC hybrid spool design was critically reevaluated with regard to creep using a Si constitutive model developed as a separate effort.
Text
22999.pdf
- Version of Record
More information
Published date: 2004
Keywords:
finite element analysis, MIT, Massachusetts Institute of Technology, Si–, SiC hybrid structures, mechanical testing, microengine
Identifiers
Local EPrints ID: 22999
URI: http://eprints.soton.ac.uk/id/eprint/22999
ISSN: 1057-7157
PURE UUID: d34c72aa-cd98-43bf-902b-152f6e1fb1af
Catalogue record
Date deposited: 10 Mar 2006
Last modified: 16 Mar 2024 03:37
Export record
Altmetrics
Contributors
Author:
Hyung-Soo Moon
Author:
Dongwon Choi
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
