압전소자를 이용한 에너지 하베스터 모델링 및 전력 최적화 기법 검증 :Verification of energy harvester modeling and power optimization method using pizeoelectric generator

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자료유형: 학위논문

저자정보: 조성우 (충남대학교, 忠南大學校大學院)

지도교수: 차한주

발행연도: 2017

저작권: 충남대학교 논문은 저작권에 의해 보호받습니다.

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이 논문의 연구 히스토리 (2)

2017

압전소자를 이용한 에너지 하베스터 모델링 및 전력 최적화 기법 검증

조성우 전기공학과 2017.01 학위논문

2016

압전소자를 이용한 에너지 하베스터 모델링 및 실험

조성우 , 안현성 , 김영철 외 3명 전력전자학회 학술대회 논문집 2016.07 학술대회자료

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In this paper, the energy harvester with a piezoelectric materials is modeled as the electric equivalent circuit, and generation performances of Standard AC, Standard DC, Parallel SSHI are verified through experiment under different load conditions
Piezoelectric generator with mass, damper and spring is equivalent to electrical circuit model, which is composed of a series RLC circuit and transformer representing the electro-mechanical coupling constant. Standard AC and Standard DC are introduced as generation methods in order to supply the harvested power to loads. Experimental configuration performances are throughly verified through simulation and experiment under different load conditions. In case of simulation under 100 load and 0.8G condition, the harvested maximum power is 857 at Standard DC and 1440 at Parallel SSHI. It’s harvested power has increased about 60%. Also in case of experimental under 100 load and 0.8G condition, the harvested maximum power is 902 at Standard DC and 1537 at Parallel SSHI. It’s harvested power has increased about 59%. So, Parallel SSHI harvesting performance is higher than the Standard DC method and verified through the simulation and experimental.

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표 목차············································································
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기호 및 약어····································································
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제 1 장 서 론··································································
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1.1 연구배경································································
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1.2 연구목적································································
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1.3 논문개요································································
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제 2 장 에너지 하베스터 및 모델링····································
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2.1 에너지 하베스터의 기본개념·····································
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2.1.1 압전소자를 이용한 에너지 하베스팅·······················
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2.1.2 전자기 방식을 이용한 에너지 하베스팅··················
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2.1.3 열을 이용한 에너지 하베스팅································
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2.2 전기·기계적으로 결합된 에너지 하베스터 모델링·········
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2.3 에너지 하베스터 회로설계········································
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제 3 장 에너지 하베스터용 전력 최적화 기법·······················
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3.1 전력 최적화 기법····················································
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3.1.1 Standard AC 기법··············································
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3.1.2 Standard DC 기법··············································
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3.1.3 Parallel SSHI 기법·············································
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제 4 장 실험장비 및 실험보드 구성····································
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4.1 실험장비 구성·························································
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4.1.1 Piezoelectric 캔틸레버 제작································
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4.1.2 실험보드 제작····················································
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4.1.3 가진기 및 제어프로그램·······································
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4.1.4 레이저 변위 계측기·············································
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4.2 실험조건································································
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제 5 장 시뮬레이션 및 실험결과·········································
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5.1 Standard DC 시뮬레이션 결과··································
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5.2 Parallel SSHI 시뮬레이션 결과·································
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5.3 Standard DC 실험결과············································
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5.4 Parallel SSHI 실험결과···········································
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5.5 시뮬레이션 및 실험결과 비교 분석····························
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5.5.1 시뮬레이션결과 비교 분석····································
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5.5.2 실험결과 비교 분석·············································
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제 6 장 결 론··································································
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참고문헌··········································································
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Abstract··········································································
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