보고서 정보
주관연구기관 |
연세대학교 Yonsei University |
연구책임자 |
박효선
|
보고서유형 | 최종보고서 |
발행국가 | 대한민국 |
언어 |
한국어
|
발행년월 | 2017-03 |
과제시작연도 |
2016 |
주관부처 |
미래창조과학부 Ministry of Science, ICT and Future Planning |
등록번호 |
TRKO201800006014 |
과제고유번호 |
1711035132 |
사업명 |
개인연구지원 |
DB 구축일자 |
2018-05-12
|
키워드 |
고성능 비선형구조해석.다목적구조최적화.구조모니터링.무선센서네트워크.시스템식별.Nonlinear structural analysis.Multi-objective Optimization.Structural health monitoring.Wireless sensor network.System identification.3D-motion capture.GPS.Lidar.LCC.
|
초록
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본 연구는 건축구조물의 설계에서 철거에 이르는 전 과정을 유전학적 관점에서 재해석하여 1) 생산단계에서 건물 구조설계 대안들을 유전체의 집합으로 표현, 유전자알고리즘을 이용하여 최적 설계안을 선택,2) 선택된 구조물의 노후화 정도를 유전자의 손상 정도로 평가하고,3) 평가된 유전자의 손상을 초기 유전자와 비교하여 적절히 치료하는 기법을 제시한다. 본 연구단계의 주요 연구 성과는 다음과 같다.
■ 건물로부터 계측한 동적 반응의 모드 영향을 고려하여, 사용 중인 구조물의 현실이 정확하게 반영된 구조해석모델을 구현하고 이를 통해 건
본 연구는 건축구조물의 설계에서 철거에 이르는 전 과정을 유전학적 관점에서 재해석하여 1) 생산단계에서 건물 구조설계 대안들을 유전체의 집합으로 표현, 유전자알고리즘을 이용하여 최적 설계안을 선택,2) 선택된 구조물의 노후화 정도를 유전자의 손상 정도로 평가하고,3) 평가된 유전자의 손상을 초기 유전자와 비교하여 적절히 치료하는 기법을 제시한다. 본 연구단계의 주요 연구 성과는 다음과 같다.
■ 건물로부터 계측한 동적 반응의 모드 영향을 고려하여, 사용 중인 구조물의 현실이 정확하게 반영된 구조해석모델을 구현하고 이를 통해 건물의 안전성을 평가할 수 있는 기법을 세계 최초로 개발
■ 지진과 강풍 등에 의한 건축구조물의 이동을 실시간으로 3차원 좌표형식으로 추적할 수 있는 모니터링 모델을 세계 최초로 개발
■ 건물 노후화에 따른 최적 보강을 위해 PC레벨에서 슈퍼컴퓨팅성능을 구현할 수 있는 최적보강모델을 세계 최초로 개발
( 출처 : 보고서 요약서 3p )
Abstract
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Purpose
In this research, a gene-scale design, self-diagnosis, and anti-aging technology will be developed in the form of a health care system for structural systems for buildings. The building health care technology through the fusion of genomics, IT, and structures will allow structural enginee
Purpose
In this research, a gene-scale design, self-diagnosis, and anti-aging technology will be developed in the form of a health care system for structural systems for buildings. The building health care technology through the fusion of genomics, IT, and structures will allow structural engineers to monitor the levels of safety and serviceability of a structural system at any time. From a distance they can examine the condition of structural members and connections, check functioning of individual parts, diagnose what actions are needed to fix the problem, and obtain optimal repairing solutions. Application of the technology to a building, the span of life will be lengthened in a systematic way. The technology will be applied to various structural systems consisting of steel, reinforced concrete, and composite members.
contents
In the proposed ᒥDevelopment of Gene-Scale Design, Self-Diagnosis, and Anti-Aging Technology for Structural Systems in Buildingsᒧ, member, support, connection, material properties and structural characteristics are expressed as gene and the combination of the genes which are those structural components is regarded as genome. Thus, a designed structure is expressed as one genome consisting of combination of a variety of genes. In this aspect, whole process from design to demolish for building structure include 1) selection of a optimum design among the multiple structural design alternatives, a group of genome, generated from multi-objective genetic algorithm in manufacturing phase of the building, 2) assessment of aging degree of gene in genome which means damage severity of the selected structure due to the external loads and 3) comparing initial condition of gene in the genome with damage assessment of gene and determining appropriate treatment or demolition. The structural analysis required in the manufacturing and assessment of deterioration for the building is based on the elastic and inelastic analysis method and the optimum design method considers member size, material characteristic, strength, stiffness, CO2 emission in design variable and objective function. To monitor deterioration of the structure in real-time, advanced structural monitoring technology and system identification method are developed using gage-free sensor network and vision-based 3D-motion capture system. In the system identification method, data parallel computing which is one of the efficient computational method is used to overcome the disadvantage of the existing techniques. The maintenance and retrofit techniques treating damaged structural components are developed based on the optimization methods considering cost and CO2 emission in the objective functions.
Development results
The development results of this research are summarized as follows. 1) The technology of elastic/inelastic multi-objective optimal design model was developed. To overcome the limitations of optimum design models for large-scale structures with iterative nonlinear analyses, a high-performance distributed optimal design model was developed. In the developed distributed model using a multi-core PC, the high-performance computing capability of a multiple PCs was efficiently utilized in the optimal design model. 2) The integrated structural health monitoring system for building structures which can measure structural responses and evaluate the changes in stiffness of the structure due to the aging of structures at both the member and building levels was developed as a new technology in an engineering field. The integrated monitoring system which can reasonably evaluate the safety of building structures subjected to earthquakes and wind loads was suggested. 3) The evaluation technique of structural damages at the member and building levels was developed in the form of a new visual SI and model updating method. Through various structural experiments including a shaking table experiment, the technology was verified and applied to actual skyscraper buildings.
The integrated monitoring system combined with the damage evaluation technology can be used on realistic applications and, in turn, the integrated monitoring systems can be used to guarantee the safety of citizens reasonably. 4) An ANN model, which can realize the safety/serviceability monitoring system for the structures which do not need the sustainable maintenance of sensors, was developed and it was verified through various experiments. This technology is the world's first new technology, called sustainable SHM, and it is evaluated as an innovative technology which can overcome the limitations of existing SHM. 5) The reasonable strength/stiffness retrofit technology of structures subjected to earthquakes and wind loads was developed in the form of multi-objective retrofit technique. In particular, in addition to the structural performance of retrofitted structures, the unique model can consider the CO2 emissions related the retrofit process.
Expected Contribution
Longevity of the building is expected through new concept and model established in the proposed research. It enables to increase the average lifespan of the building from 100years to 120years, reduce 20% of the domestic construction cost (100trillion won) and economic loss by CO2 emission (2trillion won) and bring economic effects of 21trillion for a year. For technical and social aspects, the proposed research will make a large contribution to enhancement of national competitiveness through 1) reorganizing the Korea architectural engineering into the high value engineering field, 2) creating the new demands and diversifying revenue by the development of new products, 3) extending to the adjacent industries and 4) training the talented individuals and leading technique in the relevant engineering field.
( 출처 : SUMMARY 5p )
목차 Contents
- 표지 ... 1
- 제 출 문 ... 2
- 보고서 요약서 ... 3
- 국문 요약문 ... 4
- SUMMARY ... 5
- 목차 ... 6
- 1. 연구개발 목표 및 내용 ... 7
- 가. 최종목표 ... 7
- 나. 단계목표(당초목표 및 수정․보완 목표) ... 10
- 다. 당초 목표의 수정․보완(중요 연구변경) 사유 ... 10
- 라. 2단계 연차별 연구목표 및 내용 ... 11
- 2. 연구 추진전략 및 방법 ... 12
- 가. 연구 추진전략 ... 12
- 나. 연구 방법 ... 14
- 3. 주요 연구개발결과 ... 16
- 가. 계획대비 달성도 ... 16
- 나. 대표적 연구업적 ... 28
- 다. 현 단계 달성된 연구결과의 세계적 연구 위상 ... 29
- 라. 기타 계획하지 않은 연구성과 ... 42
- 4. 연구수행에 따른 문제점 및 개선방향 ... 48
- 5. 연구개발성과 현황 ... 49
- 6. 국가과학기술종합정보시스템에 등록한 연구시설․장비 현황 ... 59
- 7. 기타사항 ... 59
- 끝페이지 ... 60
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