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캐비테이션의 영향을 고려한 부유체구조물의 수중폭발 충격응답 해석
| DC Field | Value | Language |
|---|---|---|
| dc.contributor.author | 권정일 | - |
| dc.date.accessioned | 2017-02-22T07:08:41Z | - |
| dc.date.available | 2017-02-22T07:08:41Z | - |
| dc.date.issued | 2002 | - |
| dc.date.submitted | 56797-10-27 | - |
| dc.identifier.uri | http://kmou.dcollection.net/jsp/common/DcLoOrgPer.jsp?sItemId=000002174035 | ko_KR |
| dc.identifier.uri | http://repository.kmou.ac.kr/handle/2014.oak/10333 | - |
| dc.description.abstract | Surface ship structure and shipboard equipments must be designed to withstand severe shock excitations induced by underwater explosion. The ship shock test/trials identify the design and construction deficiencies giving a serious negative effect on the survivability of ship, equipment and crew, and also validate the shock hardening criteria and performance. Unfortunately, the ship shock trials are very time consuming and expensive. With the advent and ongoing advances in simulation capabilities and sophisticated simulation tools, numerical modeling and simulation has become a viable, less costly alternative as well as more reliable aids to ship shock test/trials. Surface ship shock simulation under underwater explosion is generally complicated by free surface effects, such as bulk cavitation, local cavitation and cavitation closure pulses, in addition to the complex fluid-structure interaction phenomena and the complicated dynamic behavior of the ship and shipboard equipments. Shock response analysis of a floating surface ship could be performed using a large scale finite element model of a coupled ship and surrounding fluid using LS-DYNA/USA code considering the effects of cavitation. In this paper, the effects of bulk cavitation and fluid mesh size were investigated on the shock response of floating structure using both LS/DYNA3D and LS-DYNA/USA and on its reliable shock response under underwater explosion, respectively at the first step. The shock responses of the MIL-S-901D SFSP (Standard Floating Shock Platform) under underwater explosion were analyzed using LS-DYNA/USA, where surrounding fluids as well as the SFSP were included in 3-dimensional finite element model for the consideration of bulk cavitation effects. Through the numerical simulations, the nonlinear effects of the resilient mounts and flexibilities of the SFSP were also investigated on the shock response characteristics of the equipments, whose results were compared with NRL test results. It might be confirmed that the simulation results could predict the shock behaviors of the SFSP accurately, and that the shock responses of complex structure-foundation-equipments interaction could be applied to the whole ship analysis effectively. | - |
| dc.description.tableofcontents | 목차 목차 = i 도표목록 = iii 그림목록 = iv Abstract = viii 1. 서론 = 1 2. 수중폭발 충격파에 의한 충격하중 = 3 2.1 수중폭발 현상 = 3 2.2 무한수역 내의 충격파 = 6 2.3 경계면 효과 = 7 2.3.1 자유수면 효과에 의한 광역 캐비테이션 = 8 2.3.2 접수구조 표면에 의한 선각 캐비테이션 = 11 3. 캐비테이션을 고려한 수중폭발 충격응답 해석기법 = 14 3.1 ALE 및 CLE 기법 = 14 3.2 Hybrid 기법 = 16 4. ALE 기법을 이용한 광역 캐비테이션 현상 해석 = 23 4.1 자유수면에서의 광역 캐비테이션 현상 해석 = 23 4.2 부유체 구조물을 고려한 광역 캐비테이션 현상 해석 = 33 4.3 고찰 = 41 5. Hybrid 기법에서의 유체영역 모델링 방법의 영향 검토 = 42 5.1 해석 모델링 = 42 5.2 Russell의 오차산정방법 = 50 5.3 충격응답 해석 = 51 5.4 고찰 = 68 6. 탄성마운트 지지 장비시스템의 수중폭발 충격응답 해석 = 69 6.1 MIL-S-901D 중중량 충격시험 = 70 6.2 MIL-S-901D 부유식 충격시험기의 수중폭발 충격응답 해석 = 74 6.2.1 검증 모델 및 방법 = 74 6.2.2 충격응답 해석 = 76 6.2.3 고찰 = 79 6.3 탄성마운트 지지 장비시스템의 동적응답 해석 = 80 6.3.1 검증 모델 및 방법 = 81 6.3.2 동적응답 해석 = 83 6.3.3 고찰 = 84 6.4 탄성마운트 지지 장비시스템의 MIL-S-901D 충격응답 해석 모델링 = 85 6.5 탄성마운트 지지 장비시스템의 MIL-S-901D 충격응답 해석 = 87 6.6 고찰 = 89 7. 결론 = 90 참고문헌 = 92 본 논문 관련 발표 실적 = 96 부록 : LS/DYNA-USA 프로그램의 입력파일 = A1 | - |
| dc.publisher | 한국해양대학교 | - |
| dc.title | 캐비테이션의 영향을 고려한 부유체구조물의 수중폭발 충격응답 해석 | - |
| dc.title.alternative | Underwater Shock Response Analysis of Floating Structures considering Effects of Cavitation | - |
| dc.type | Thesis | - |
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