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      CuO 나노유체의 적용에 따른 평판형과 U-tube형 태양열 집열기의 성능비교에 대한 실험적 연구 = Experimental study on the efficiency comparison of flat-plate and U-tube solar collector using CuO nanofluid

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      https://www.riss.kr/link?id=T14725696

      • 저자
      • 발행사항

        광주 : 조선대학교 교육대학원, 2017

      • 학위논문사항

        학위논문(석사) -- 조선대학교 교육대학원 , 기계.금속교육 , 2018. 2

      • 발행연도

        2017

      • 작성언어

        한국어

      • 주제어
      • DDC

        621.8 판사항(21)

      • 발행국(도시)

        광주

      • 형태사항

        i, ix, 47p. : 26cm

      • 일반주기명

        조선대학교 논문은 저작권에 의해 보호받습니다.
        지도교수:조홍현
        참고문헌 : p.45-47

      • UCI식별코드

        I804:24011-200000266490

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      다국어 초록 (Multilingual Abstract) kakao i 다국어 번역

      ABSTRACT

      Experimental study on the efficiency comparison of flat-plate and U-tube solar collector using CuO nanofluid

      Un-cheon Ju
      Advisor : Prof. Cho, Hong-hyun
      Mechanical&Metallurgical Education
      Chosun University

      In this study, thermal efficiency of a flat-plate solar collector and a U-tube solar collector using a CuO nanofluid and water as a working fluid was investigated according to CuO nanoparticle size and concentration. Experiment was carried out under the mass flow rates of 0.033 kg/s and 0.047 kg/s respectively. Additionally, CuO nanoparticles with the size of 40 nm and 80 nm were used and concentration of nanofluid was changed by 0.1vol%, 0.3vol%, 0.5vol%, and 0.7vol%, respectively. The thermal conductivity increased non-linearly as the CuO nanofluid concentration increased. In addition, it was confirmed that the increase of thermal conductivity ratio gradually decreased when concentration of CuO nanofluid increased.
      Experimental results showed that the efficiency of solar collector showed the maximum when a mass flow rate of working fluid was 0.047 kg/s, CuO nanoparticle size was 40 nm, and CuO nanofluid concentration was 0.5vol%. In this case, the heat gain and heat loss coefficient of a flat-plate collector was 0.735 and 22.8, respectively. In addition, Heat gain and heat loss coefficient of U-tube solar collector was 0.695 and 16.66, respectively. When the efficiency of flat-plate and U-tube solar collector using CuO nanofluid was improved by 11.32% and 7.82%, respectively, compared to that using water. In order to increase the efficiency of the solar collector, the size of nanoparticle and concentration of nanofluid should be appropriately controlled and the mass flow rate in the system should be designed optimally. The smaller the size of nanoparticle in the nanofluid, the more active the Brownian motion, resulting in the better the absorption of solar energy. The high volume concentration of CuO nanofluid has good thermal conductivity, but the viscosity increases and the heat transfer performance decreases. On the other hand, the optimal concentration of CuO nanofluid is very important because it can not absorb whole of solar energy if the concentration of CuO nanofluid is low.
      Thus, the size and concentration of nanofluid are very important factors on the performance of solar collector. From the experimental result, the use of CuO nanofluid is superior to absorption of solar energy than the use water. Therefore, when the CuO nanofluid is used with optimal conditions, it is sure to improve the efficiency of solar collector.
      번역하기

      ABSTRACT Experimental study on the efficiency comparison of flat-plate and U-tube solar collector using CuO nanofluid Un-cheon Ju Advisor : Prof. Cho, Hong-hyun Mechanical&Metallurgical Education Chosun University In this study, thermal effi...

      ABSTRACT

      Experimental study on the efficiency comparison of flat-plate and U-tube solar collector using CuO nanofluid

      Un-cheon Ju
      Advisor : Prof. Cho, Hong-hyun
      Mechanical&Metallurgical Education
      Chosun University

      In this study, thermal efficiency of a flat-plate solar collector and a U-tube solar collector using a CuO nanofluid and water as a working fluid was investigated according to CuO nanoparticle size and concentration. Experiment was carried out under the mass flow rates of 0.033 kg/s and 0.047 kg/s respectively. Additionally, CuO nanoparticles with the size of 40 nm and 80 nm were used and concentration of nanofluid was changed by 0.1vol%, 0.3vol%, 0.5vol%, and 0.7vol%, respectively. The thermal conductivity increased non-linearly as the CuO nanofluid concentration increased. In addition, it was confirmed that the increase of thermal conductivity ratio gradually decreased when concentration of CuO nanofluid increased.
      Experimental results showed that the efficiency of solar collector showed the maximum when a mass flow rate of working fluid was 0.047 kg/s, CuO nanoparticle size was 40 nm, and CuO nanofluid concentration was 0.5vol%. In this case, the heat gain and heat loss coefficient of a flat-plate collector was 0.735 and 22.8, respectively. In addition, Heat gain and heat loss coefficient of U-tube solar collector was 0.695 and 16.66, respectively. When the efficiency of flat-plate and U-tube solar collector using CuO nanofluid was improved by 11.32% and 7.82%, respectively, compared to that using water. In order to increase the efficiency of the solar collector, the size of nanoparticle and concentration of nanofluid should be appropriately controlled and the mass flow rate in the system should be designed optimally. The smaller the size of nanoparticle in the nanofluid, the more active the Brownian motion, resulting in the better the absorption of solar energy. The high volume concentration of CuO nanofluid has good thermal conductivity, but the viscosity increases and the heat transfer performance decreases. On the other hand, the optimal concentration of CuO nanofluid is very important because it can not absorb whole of solar energy if the concentration of CuO nanofluid is low.
      Thus, the size and concentration of nanofluid are very important factors on the performance of solar collector. From the experimental result, the use of CuO nanofluid is superior to absorption of solar energy than the use water. Therefore, when the CuO nanofluid is used with optimal conditions, it is sure to improve the efficiency of solar collector.

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      목차 (Table of Contents)

      • 목 차
      • Contents ⅰ
      • List of Nomenclatures ⅳ
      • List of Figures ⅵ
      • 목 차
      • Contents ⅰ
      • List of Nomenclatures ⅳ
      • List of Figures ⅵ
      • List of Tables ⅶ
      • Abstract ⅷ
      • 제 1 장 서 론 1
      • 제 1 절 연구 배경 1
      • 제 2 절 기존의 연구 3
      • 제 3 절 연구 목적 5
      • 제 2 장 태양열 시스템 6
      • 제 1 절 태양열 시스템 6
      • 제 2 절 태양열 집열기의 종류 8
      • 1. 평판형 집열기(Flat-plate solar collector) 8
      • 2. 진공관형 U-tube 태양열 집열기(Evacuated U-tube solar collector) 9
      • 제 3 장 실험장치 및 방법 10
      • 제 1 절 실험장치 10
      • 1. 실험용 태양열 집열기의 제원 12
      • 2. 온도측정 14
      • 3. 일사량 측정 15
      • 4. 유량측정 16
      • 5. 축열탱크 17
      • 6. 데이터 수집장치 18
      • 제 2 절 나노유체의 제작 19
      • 1. 나노유체 제조방법 19
      • 2. CuO 나노유체 21
      • 제 3 절 실험방법 및 집열기 효율 계산 22
      • 1. 실험방법 및 조건 22
      • 2. 태양열 집열기의 효율 및 불확실성 계산 23
      • 제 4 장 태양열 집열기의 성능 실험결과 및 고찰 26
      • 제 1 절 CuO 나노유체의 열전도도 고찰 26
      • 제 2 절 CuO 나노유체의 농도에 따른 태양열 집열기의 성능 고찰 28
      • 제 3 절 CuO 나노입자의 크기에 따른 태양열 집열기의 성능 고찰 32
      • 제 4 절 작동유체의 질량 유량에 따른 태양열 집열기의 성능 고찰 35
      • 제 5 절 와 CuO 나노유체, 그리고 물을 적용한 태양열 집열기의 성능실험 결과 비교 39
      • 제 5 장 결 론 43
      • References 45
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