• Title/Summary/Keyword: SolarCell

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Study of hydrogenated a-SiGe cell for middle cell of Triple junction solar cell (Triple junction 태양전지의 a-SiGe middle cell에 관한 연구)

  • Park, Taejin;Baek, Seungjo;Kim, Beomjoon
    • 한국신재생에너지학회:학술대회논문집
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    • 2010.06a
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    • pp.83.1-83.1
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    • 2010
  • Hydrogenated a-SiGe middle cell for triple junction solar cell was investigated with various process parameters. a-SiGe I-layer was deposited at substrate temperature $245^{\circ}C$ and hydrogen content(R) was up to 26.7. Low optical bandgap(1.45eV) of a-SiGe cell was applied for middle cell although a-SiGe single cell efficiency with low Ge content was higher. And this cell was applied to the middle cell of a glass superstrate type a-Si/a-SiGe/uc-Si triple junction solar cell. The triple junction solar cell was resulted in the initial efficiency of about 9%, area $0.25cm^2$, under global AM 1.5 illumination.

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Dye-Sensitized Metal Oxide Nanostructures and Their Photoelectrochemical Properties

  • Park, Nam-Gyu
    • Journal of the Korean Electrochemical Society
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    • v.13 no.1
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    • pp.10-18
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    • 2010
  • Nanostructured metal oxides have been widely used in the research fields of photoelectrochemistry, photochemistry and opto-electronics. Dye-sensitized solar cell is a typical example because it is based on nanostructured $TiO_2$. Since the discovery of dye-sensitized solar cell in 1991, it has been considered as a promising photovoltaic solar cell because of low-cost, colorful and semitransparent characteristics. Unlike p-n junction type solar cell, dye-sensitized solar cell is photoelectrochemical type and is usually composed of the dye-adsorbed nanocrystalline metal oxide, the iodide/tri-iodide redox electrolyte and the Pt and/or carbon counter electrode. Among the studied issues to improve efficiency of dye-sensitized solar cell, nanoengineering technologies of metal oxide particle and film have been reviewed in terms of improving optical property, electron transport and electron life time.

The New Modeling of Solar Cell for Virtual Implement Of Solar Cell (태양전지 가상구현 장치를 위한 새로운 태양전지 모델링에 관한 연구)

  • Lee B. I.;Ryu T. G.;Han J. M.;Choe G. H.
    • Proceedings of the KIPE Conference
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    • 2002.11a
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    • pp.69-73
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    • 2002
  • A study on photovoltaic system has a lot of problems. Such as repetition experiment in the same condition, development of MPPT(Maximum Power Point Tracking) algorithm, development of islanding detection algorithm and so forth. The reason Is that solar cell output characteristics are varied by insolarion and surface temperature of solar cell. Therefore, the assistance equipment is required which emulates the solar cell characteristics. In this paper, propose the new modeling of solar cell and verify this modeling using MATLAB simulation. And experiment virtual implement of solar cell system using this modeling.

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Module Characteristic Modeling in Terms of the Number of Divisions of Large-Area Solar Cells (대면적 태양전지의 분할 수에 따른 모듈 특성 모델링 )

  • Juhwi Kim;Jaehyeong Lee
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
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    • v.36 no.2
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    • pp.136-142
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    • 2023
  • In the past, the efficiency of solar cells had been increased in order to increase the efficiency of solar modules. However, in recent years, in order to increase output in the solar industry and market, the competitiveness of solar cells based on large-area solar cells and multi-bus bar has been increasing. Multi-busbar solar module is a technology to reduce power loss by increasing the number and width of the front busbar of the solar cell and reducing the current value delivered by the busbar by half through half-cutting. In the case of the existing M2 (156.75×156.75 mm2) solar cell, even with a half-cut, power loss could be sufficiently reduced, but as the area of the solar cell is enlarged to more than M6 (166×166 mm2), the need for more divisions emerged. This affected not only solar cells but also inverters required for module array configuration. Therefore, in this study, the electrical characteristics of a large-area solar cell and after division were extracted using Griddler simulation. The output characteristics of the module were predicted by applying the solar cell parameters after division to PSPice, and a guideline for the large-area solar module design was presented according to the number of divisions of the large-area solar cell.

Calculation of capacity of solar cell and battery for stable solar system design (안정적인 태양광발전시스템의 설계를 위한 태양전지와 배터리 용량산정 방안)

  • Lee Mi-Young;Lee Jun-Ha;Lee Hoong-Joo;Lee Woo-Hee
    • Journal of the Korea Academia-Industrial cooperation Society
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    • v.6 no.5
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    • pp.396-400
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    • 2005
  • Solar cell and battery capacity are very important for stable design of stand-alone solar photovoltaic power generation system. If capacity computation of solar cell and battery is a wrong, operation of the solar system becomes unstable and results in breakdown. Therefore, in this paper, a solar cell and battery capacity calculation method considering the load characteristics has been proposed for the stable operation of the solar photovoltaic power generation system.

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High Efficiency Crystalline Silicon Solar Cells (고효율 단결정 실리콘 태양전지)

  • Kim, D.S.;Cho, E.C.;Cho, Y.H.;Ebong, A.U.;Min, Y.S.;Lee, S.H.
    • Solar Energy
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    • v.17 no.1
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    • pp.17-26
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    • 1997
  • Since PESC(passivated emitter solar cell) was developed in 1985, high efficiency silicon solar cell technology based on planar technology has been improved in the order of PERC, Point Contact Solar Cell, PERL. BCSC and DSBC, which do not require photolithography, are expected to replace commercial screen printed cells because of its potential for low cost and high efficiency. In this paper, history and characteristics of each type of cells are reviewed.

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Durability Evaluation Study of Re-manufactured Photovoltaic Modules (재 제조 태양광모듈의 내구성능 평가 연구)

  • Kyung Soo Kim
    • Current Photovoltaic Research
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    • v.12 no.1
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    • pp.17-23
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    • 2024
  • Photovoltaic (PV) power generation is the world's best and largest renewable energy that generates electricity with infinite sunlight. Solar cell modules are a component of photovoltaic power generation and must have a long-term durability of at least 25 years. The development of processes and equipment that can be recovered through the recycling of metals and valuable metals when the solar module's lifespan is over has been completed to the level of commercialization, but few processes have been developed that require repair due to initial defects. This is mainly due to the economic problems caused by remaking. However, if manufacturing processes such as repairing solar cell modules that have been proven to be early defects are established and the technical review of long-term reliability and durability reaches a certain level, it is considered that it will be a recommended process technology for environmental economics. In this paper, assuming that a defective solar cell module occurs artificially, a manufacturing process for replacement of solar cells was developed, and a technical verification of the manufacturing technology was conducted through long-term durability evaluation in accordance with KS C 8561. Through this, it was determined that remanufacturing technology for solar cell replacement of solar cell modules that occurred in a short period of time after installation was possible, and the research results were announced through a journal to commercialize solar modules using manufacturing technology in the solar market in the future.

STUDY ON THE HIGH EFFICIENCY BURIED CONTACT SOLAR CELL WITH WET ETCHING PROCESS

  • Kang, Dae-Keun;Choi, Kang-Ho;Lee, Joo-Yul;Lee, Kyu-Hwan
    • Proceedings of the Korean Institute of Surface Engineering Conference
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    • 2009.10a
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    • pp.156-156
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    • 2009
  • High efficiency silicon solar cell technology based on planar technology has been improved by various kinds of process by using the wet etching process. In particular, the buried contact solar cell has been successfully studied. In the present work, a simplified process of the buried contact solar cell has been suggested to help one design effectively the high-efficiency solar cell.

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Fresnel lens-DCPC-concentrating solar cell-heat sink type solar module (Fresnel 렌즈-DCPC-집광형태양전지-방열판형 solar module에 관한 연구)

  • 송진수
    • 전기의세계
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    • v.30 no.10
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    • pp.655-661
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    • 1981
  • The concentrating solar module with high concentration ratio(320)has been studied.in this paper. The solar module was composed of the EMVJ solar cell, (Fresnel Lens-DCPC)concentrator and heat sink, and was measured by using the PASTF system. The experimental result and the result analysis for the individual item of the module were as f ollows; (1) The conversion efficiency of the module was 8.3%. (2) The optical efficiency of the concentrator was 46.5% (DCPC; 84.8%, Fresnel Lens; 54.8%). (3) The thermal loss of the solar cell was 4.9%. And methods for the further improvement of the concentrating solar module efficiency have been suggested.

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Study of Light-induced Degradation in Thin Film Silicon Solar Cells: Hydrogenated Amorphous Silicon Solar Cell and Nano-quantum Dot Silicon Thin Film Solar Cell (박막 실리콘 태양전지의 광열화현상 연구: 비정질 실리콘 태양전지 및 나노양자점 실리콘 박막 태양전지)

  • Kim, Ka-Hyun
    • Journal of the Korean Solar Energy Society
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    • v.39 no.1
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    • pp.1-9
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    • 2019
  • Light induced degradation is one of the major research challenges of hydrogenated amorphous silicon related thin film silicon solar cells. Amorphous silicon shows creation of metastable defect states, originating from elevated concentration of dangling bonds during light exposure. The metastable defect states work as recombination centers, and mostly affects quality of intrinsic layer in solar cells. In this paper we present results of light induced degradation in thin film silicon solar cells and discussion on physical origin, mechanism and practical solutions of light induced degradation in thin film silicon solar cells. In-situ light-soaking IV measurement techniques are presented. We also present thin film silicon material with silicon nano-quantum dots embedded within amorphous matrix, which shows superior stability during light-soaking. Our results suggest that solar cell using silicon nano-quantum dots in abosrber layer shows superior stability under light soaking, compared to the conventional amorphous silicon solar cell.