You need JavaScript to view this

FY 1993 Research and development of ceramic gas turbines. Development of methods of testing and evaluating ceramic member bonding techniques; 1993 nendo ceramic gas turbine no kenkyu kaihatsu seika hokokusho. Ceramic buzai setsugo gijutsu no shiken hyoka hoho no kaihatsu

Abstract

Studies are conducted to establish the methods of testing and evaluating applicability of ceramic-metal bonding for ceramic gas turbines, and the FY 1993 results are reported. The program involves measurement of residual stress by the X-ray method and durability tests for the joints of silicon nitride and austenitic stainless steel with copper as the intermediate layer, and analysis and classification of the strength/durability test results obtained until the previous fiscal year by the finite element method, to evaluate applicability of the joining. For the strength characteristics at high temperature, the test pieces tend to lose strength at 400 degrees C and higher, and high-temperature strength as cross-head displacement speed increases. The upper limit of bending strength at room temperature decreases as number of thermal cycles increases. The test pieces subjected to thermal cycles have a higher bending strength at high temperature than at room temperature. The results of the two-dimensional plasticity analysis of the residual stress in the joint by the finite element method are in good agreement with the results by the X-ray method. (NEDO)
Publication Date:
May 01, 1994
Product Type:
Technical Report
Report Number:
JP-NEDO-010016095
Resource Relation:
Other Information: PBD: May 1994
Subject:
32 ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION; GAS TURBINES; CERAMICS; JOINTS; COPPER; SILICON NITRIDES; STAINLESS STEELS; RESIDUAL STRESSES; FINITE ELEMENT METHOD; THERMAL CYCLING; FLEXURAL STRENGTH
OSTI ID:
20185244
Research Organizations:
New Energy and Industrial Technology Development Organization, Tokyo (Japan)
Country of Origin:
Japan
Language:
Japanese
Other Identifying Numbers:
TRN: JN0140265
Availability:
Available to ETDE participating countries only(see www.etde.org); commercial reproduction prohibited; OSTI as DE20185244
Submitting Site:
NEDO
Size:
365 pages
Announcement Date:
Jun 06, 2002

Citation Formats

None. FY 1993 Research and development of ceramic gas turbines. Development of methods of testing and evaluating ceramic member bonding techniques; 1993 nendo ceramic gas turbine no kenkyu kaihatsu seika hokokusho. Ceramic buzai setsugo gijutsu no shiken hyoka hoho no kaihatsu. Japan: N. p., 1994. Web.
None. FY 1993 Research and development of ceramic gas turbines. Development of methods of testing and evaluating ceramic member bonding techniques; 1993 nendo ceramic gas turbine no kenkyu kaihatsu seika hokokusho. Ceramic buzai setsugo gijutsu no shiken hyoka hoho no kaihatsu. Japan.
None. 1994. "FY 1993 Research and development of ceramic gas turbines. Development of methods of testing and evaluating ceramic member bonding techniques; 1993 nendo ceramic gas turbine no kenkyu kaihatsu seika hokokusho. Ceramic buzai setsugo gijutsu no shiken hyoka hoho no kaihatsu." Japan.
@misc{etde_20185244,
title = {FY 1993 Research and development of ceramic gas turbines. Development of methods of testing and evaluating ceramic member bonding techniques; 1993 nendo ceramic gas turbine no kenkyu kaihatsu seika hokokusho. Ceramic buzai setsugo gijutsu no shiken hyoka hoho no kaihatsu}
author = {None}
abstractNote = {Studies are conducted to establish the methods of testing and evaluating applicability of ceramic-metal bonding for ceramic gas turbines, and the FY 1993 results are reported. The program involves measurement of residual stress by the X-ray method and durability tests for the joints of silicon nitride and austenitic stainless steel with copper as the intermediate layer, and analysis and classification of the strength/durability test results obtained until the previous fiscal year by the finite element method, to evaluate applicability of the joining. For the strength characteristics at high temperature, the test pieces tend to lose strength at 400 degrees C and higher, and high-temperature strength as cross-head displacement speed increases. The upper limit of bending strength at room temperature decreases as number of thermal cycles increases. The test pieces subjected to thermal cycles have a higher bending strength at high temperature than at room temperature. The results of the two-dimensional plasticity analysis of the residual stress in the joint by the finite element method are in good agreement with the results by the X-ray method. (NEDO)}
place = {Japan}
year = {1994}
month = {May}
}