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Most of modern aerospace gas turbines must be operated at a gas temperature which is several hundreds of degrees higher than the melting temperatures of the materials used in their construction. Complicated cooling schemes need to be employed in the c...
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RISS 인기검색어
https://www.riss.kr/link?id=A76048646
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2002
-
작성언어
Korean
-
KDC
559
-
등재정보
KCI등재
-
자료형태
학술저널
- 발행기관 URL
-
수록면
9-16(8쪽)
-
KCI 피인용횟수
2
- 제공처
- 소장기관
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
Most of modern aerospace gas turbines must be operated at a gas temperature which is several hundreds of degrees higher than the melting temperatures of the materials used in their construction. Complicated cooling schemes need to be employed in the combustor walls and in the high pressure turbine stages. Internal passages are cast or machined into the hot sections of aero-gas turbine engines and air from the compressor is used for cooling. In many cases, the cooling system is engineered to utilize jets of high velocity air, which impinge on the internal surfaces of the components. They are categorized as 'Impinging Cooling Method' and 'Vortex Cooling Method'. Specially, research of new cooling system(Vortex Cooling Method) that overcomes inefficiency of film cooling and limitation of space. The focus of new cooling system that improves greatly cooling efficiency using less amount of cooling air on surface heat transfer elevation. Therefore, in this study, a numerical analysis has been performed for characteristics of flow and heat transfer in the swirl chamber and compared with the flow measurements by LDV. Especially, for understanding high heat transfer efficiency in the vicinity of wall, we considered flow structure, vortex mechanism and heat transfer characteristics with variation of the Reynolds number.
Most of modern aerospace gas turbines must be operated at a gas temperature which is several hundreds of degrees higher than the melting temperatures of the materials used in their construction. Complicated cooling schemes need to be employed in the combustor walls and in the high pressure turbine stages. Internal passages are cast or machined into the hot sections of aero-gas turbine engines and air from the compressor is used for cooling. In many cases, the cooling system is engineered to utilize jets of high velocity air, which impinge on the internal surfaces of the components. They are categorized as 'Impinging Cooling Method' and 'Vortex Cooling Method'. Specially, research of new cooling system(Vortex Cooling Method) that overcomes inefficiency of film cooling and limitation of space. The focus of new cooling system that improves greatly cooling efficiency using less amount of cooling air on surface heat transfer elevation. Therefore, in this study, a numerical analysis has been performed for characteristics of flow and heat transfer in the swirl chamber and compared with the flow measurements by LDV. Especially, for understanding high heat transfer efficiency in the vicinity of wall, we considered flow structure, vortex mechanism and heat transfer characteristics with variation of the Reynolds number.
동일학술지(권/호) 다른 논문
-
초음속 역분사 유동이 초음속 비행체 성능에 미치는 영향에 대한 수치해석적 연구
- 한국전산유체공학회
- 서덕교(D. K. Seo)
- 2002
- KCI등재
-
화격자식 소각로의 열유동 해석과 결과 분석에 대한 고찰
- 한국전산유체공학회
- 류창국(C. Ryu)
- 2002
- KCI등재
-
- 한국전산유체공학회
- 허성범(S. Hur)
- 2002
- KCI등재
-
- 한국전산유체공학회
- 조종철(Jong Chull Jo)
- 2002
- KCI등재
분석정보
인용정보 인용지수 설명보기
학술지 이력
| 연월일 | 이력구분 | 이력상세 | 등재구분 |
|---|---|---|---|
| 2027 | 평가예정 | 재인증평가 신청대상 (재인증) | |
| 2021-01-01 | 평가 | 등재학술지 유지 (재인증) |  |
| 2018-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2015-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2011-01-01 | 평가 | 등재 1차 FAIL (등재유지) | |
| 2009-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2006-01-01 | 평가 | 등재학술지 선정 (등재후보2차) | |
| 2005-06-16 | 학술지명변경 | 외국어명 : Jpurnal of Computatuonal Fluids Engineering -> Korean Society of Computatuonal Fluids Engineering |  |
| 2005-01-01 | 평가 | 등재후보 1차 PASS (등재후보1차) | |
| 2004-01-01 | 평가 | 등재후보 1차 FAIL (등재후보1차) | |
| 2002-07-01 | 평가 | 등재후보학술지 선정 (신규평가) | |
학술지 인용정보
| 기준연도 | WOS-KCI 통합IF(2년) | KCIF(2년) | KCIF(3년) |
|---|---|---|---|
| 2016 | 0.2 | 0.2 | 0.19 |
| KCIF(4년) | KCIF(5년) | 중심성지수(3년) | 즉시성지수 |
| 0.16 | 0.15 | 0.405 | 0.05 |
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