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    • 1. 发明申请
    • Thin-film photoelectric converter
    • 薄膜光电转换器
    • US20060097259A1
    • 2006-05-11
    • US10543516
    • 2004-05-28
    • Takashi SuezakiMasashi YoshimiToshiaki SasakiYuko TawadaKenji Yamamoto
    • Takashi SuezakiMasashi YoshimiToshiaki SasakiYuko TawadaKenji Yamamoto
    • H01L29/76H01L29/10
    • H01L31/076H01L31/046Y02E10/548
    • A thin film photoelectric converter, especially an integrated thin film photoelectric converter having improved photoelectric conversion efficiency is provided by controlling an open-circuit voltage and a fill factor so as not be small in a thin film photoelectric converter including a crystalline silicon photoelectric conversion unit. The thin film photoelectric converter by the present invention has at least a transparent electrode film, a crystalline silicon photoelectric conversion unit, and a back electrode film formed sequentially on one principal surface of a transparent substrate, and the converter has a whitish discoloring area on a part of a surface of the converter after formation of the crystalline silicon photoelectric conversion unit. A percentage of dimensions of the whitish discoloring area preferably is not more than 5% of a dimension of the photoelectric conversion area. A thin film photoelectric converter of the present invention is preferably an integrated thin film photoelectric converter.
    • 通过在包括晶体硅光电转换单元的薄膜光电转换器中控制开路电压和填充因子以不小而提供薄膜光电转换器,特别是具有改进的光电转换效率的集成薄膜光电转换器。 本发明的薄膜光电转换器至少在透明基板的一个主表面上依次形成透明电极膜,晶体硅光电转换单元和背面电极膜,并且转换器具有白色变色区域 形成晶体硅光电转换单元后的转换器表面的一部分。 白色变色区域的尺寸的百分比优选不大于光电转换区域的尺寸的5%。 本发明的薄膜光电转换器优选为集成薄膜光电转换器。
    • 5. 发明授权
    • Stacked photoelectric converter
    • 堆叠光电转换器
    • US07550665B2
    • 2009-06-23
    • US10530283
    • 2004-07-15
    • Toshiaki SasakiYohei KoiKenji YamamotoMasashi YoshimiMitsuru Ichikawa
    • Toshiaki SasakiYohei KoiKenji YamamotoMasashi YoshimiMitsuru Ichikawa
    • H01L31/00H02N6/00
    • H01L31/077H01L31/056H01L31/076Y02E10/52Y02E10/548
    • In a stacked-layer type photoelectric conversion device, a plurality of photoelectric conversion units are stacked on a substrate, each of which includes a one conductivity-type layer, a photoelectric conversion layer of substantially intrinsic semiconductor and an opposite conductivity-type layer in this order from a light-incident side. At least one of the opposite conductivity-type layer in a front photoelectric conversion unit arranged relatively closer to the light-incident side and the one conductivity-type layer in a back photoelectric conversion unit arranged adjacent to the front photoelectric conversion unit includes a silicon composite layer at least in a part thereof. The silicon composite layer has a thickness of more than 20 nm and less than 130 nm and an oxygen concentration of more than 25 atomic % and less than 60 atomic %, and includes silicon-rich phase parts in an amorphous alloy phase of silicon and oxygen.
    • 在堆叠层型光电转换装置中,在基板上层叠多个光电转换单元,每个基板包括一个导电型层,本质上为半导体的光电转换层和相反的导电型层 从光线一方的命令。 在与前光电转换单元相邻布置的背光电转换单元中相对靠近光入射侧的前光电转换单元中的至少一个导电类型层和一个导电型层中的至少一个包括硅复合物 至少在其一部分。 硅复合层的厚度大于20nm且小于130nm,氧浓度大于25原子%且小于60原子%,并且包括在硅和氧的非晶合金相中的富硅相部分 。
    • 7. 发明申请
    • CRYSTALLINE SILICON-BASED SOLAR CELL
    • 晶体硅基太阳能电池
    • US20130146132A1
    • 2013-06-13
    • US13816216
    • 2011-08-03
    • Takashi KuchiyamaKenji YamamotoMasashi Yoshimi
    • Takashi KuchiyamaKenji YamamotoMasashi Yoshimi
    • H01L31/0224
    • H01L31/022466H01L31/022475H01L31/0747H01L31/202Y02E10/50Y02P70/521
    • The present invention improves a photoelectric conversion efficiency of a crystalline silicon-based solar cell. The crystalline silicon based solar cell includes a silicon-based thin-film of a first conductivity type and a first transparent electrode layer, in this order, on one surface of a conductive single-crystal silicon substrate, and a silicon-based thin-film of the opposite conductivity type and a second transparent electrode layer, in this order, on the other surface of the conductive single-crystal silicon substrate. The first and second transparent electrode layers are each formed of a transparent conductive metal oxide, and the first transparent electrode layer preferably has at least two layers, and a total thickness of 50 to 120 nm, wherein the carrier density of the substrate-side electroconductive layer is higher than that of the surface-side electroconductive layer, and the carrier density of the surface-side electroconductive layer is 1 to 4×1020 cm−3.
    • 本发明提高了晶体硅系太阳能电池的光电转换效率。 晶体硅基太阳能电池包括在导电单晶硅衬底的一个表面上的第一导电类型的硅基薄膜和第一透明电极层,以及硅基薄膜 的第二透明电极层,依次形成在导电性单晶硅基板的另一面上。 第一透明电极层和第二透明电极层各自由透明导电性金属氧化物形成,第一透明电极层优选具有至少两层,总厚度为50〜120nm,其中基板侧导电性的载流子密度 层比表面侧导电层高,表面侧导电层的载流子密度为1〜4×1020cm-3。
    • 8. 发明授权
    • Thin-film photoelectric converter
    • 薄膜光电转换器
    • US07678992B2
    • 2010-03-16
    • US10543516
    • 2004-05-28
    • Takashi SuezakiMasashi YoshimiToshiaki SasakiYuko TawadaKenji Yamamoto
    • Takashi SuezakiMasashi YoshimiToshiaki SasakiYuko TawadaKenji Yamamoto
    • H01L31/00
    • H01L31/076H01L31/046Y02E10/548
    • A thin film photoelectric converter, especially an integrated thin film photoelectric converter having improved photoelectric conversion efficiency is provided by controlling an open-circuit voltage and a fill factor so as not be small in a thin film photoelectric converter including a crystalline silicon photoelectric conversion unit. The thin film photoelectric converter by the present invention has at least a transparent electrode film, a crystalline silicon photoelectric conversion unit, and a back electrode film formed sequentially on one principal surface of a transparent substrate, and the converter has a whitish discoloring area on a part of a surface of the converter after formation of the crystalline silicon photoelectric conversion unit. A percentage of dimensions of the whitish discoloring area preferably is not more than 5% of a dimension of the photoelectric conversion area. A thin film photoelectric converter of the present invention is preferably an integrated thin film photoelectric converter.
    • 通过在包括晶体硅光电转换单元的薄膜光电转换器中控制开路电压和填充因子以不小而提供薄膜光电转换器,特别是具有改进的光电转换效率的集成薄膜光电转换器。 本发明的薄膜光电转换器至少在透明基板的一个主表面上依次形成透明电极膜,晶体硅光电转换单元和背面电极膜,并且转换器具有白色变色区域 形成晶体硅光电转换单元后的转换器表面的一部分。 白色变色区域的尺寸的百分比优选不大于光电转换区域的尺寸的5%。 本发明的薄膜光电转换器优选为集成薄膜光电转换器。
    • 9. 发明授权
    • Method of manufacturing amorphous silicon based thin film photoelectric conversion device
    • 制造非晶硅基薄膜光电转换装置的方法
    • US06326304B1
    • 2001-12-04
    • US09390040
    • 1999-09-03
    • Masashi YoshimiKenji Yamamoto
    • Masashi YoshimiKenji Yamamoto
    • H01L2144
    • H01L31/202H01L31/075Y02E10/548Y02P70/521
    • At least one of a p type semiconductor layer, an i type amorphous silicon-based photoelectric conversion layer, and an n type semiconductor layer that compose an amorphous silicon-based thin film photoelectric conversion device is deposited under the following conditions. Silane-type gas as a main component of raw material gas which is supplied into a reaction chamber and dilution gas containing hydrogen are used, the flow rate of the dilution gas is four or less times that of the silane-type gas, the partial pressure of the silane-type gas in the plasma CVD reaction chamber ranges from 1.2 Torr to 5.0 Torr, and the distance between a surface of a substrate mounted on an anode electrode and a surface of a cathode electrode ranges from 8 mm to 15 mm. Accordingly, a method of manufacturing an amorphous silicon-based thin film photoelectric conversion device having a superior performance is obtained with an improved efficiency in the use of raw material gas as well as an enhanced deposition rate to achieve improvements in cost and efficiency in production. Even if the dilution gas is not used, the advantages above can be achieved under the same conditions as those described above except for the condition concerning dilution gas.
    • 在以下条件下沉积构成非晶硅系薄膜光电转换元件的p型半导体层,i型非晶硅系光电转换层和n型半导体层中的至少一种。 使用硅烷气体作为供给反应室的原料气体的主要成分和含有氢的稀释气体,稀释气体的流量为硅烷型气体的4倍以下,分压 等离子体CVD反应室中的硅烷型气体的范围为1.2Torr至5.0Torr,并且安装在阳极电极上的基板的表面与阴极电极的表面之间的距离为8mm至15mm。 因此,通过提高原料气体的使用效率和提高的沉积速度,可以获得具有优异性能的非晶硅系薄膜光电转换元件的制造方法,从而提高成本和生产效率。 即使不使用稀释气体,除了关于稀释气体的条件以外,在与上述相同的条件下可以实现上述优点。