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    • 81. 发明授权
    • Optical isolator
    • 光隔离器
    • US5381261A
    • 1995-01-10
    • US937896
    • 1992-11-05
    • Shigeru HiraiYouichi IshiguroYasuji HattoriMasayuki NishimuraMasayuki ShigematsuMinoru WatanabeKouji Nakazato
    • Shigeru HiraiYouichi IshiguroYasuji HattoriMasayuki NishimuraMasayuki ShigematsuMinoru WatanabeKouji Nakazato
    • G02F1/09G02B5/30
    • G02F1/093G02F2203/06Y10S372/703
    • An optical isolator not dependent on the plane of polarization of an incident beam and does not allow the plane of polarization to change on the outgoing side. The optical isolator comprises a first parallel flat double refractive crystal substance; a first Faraday rotor for rotating the plane of polarization of a beam; a second parallel flat double refractive crystal substance; a second Faraday rotor for rotating the plane of polarization in a direction opposite to that in which said first Faraday rotor rotates the plane of polarization; a third parallel flat double refractive substance; a fourth parallel flat double refractive substance; and permanent magnets for magnetizing the Faraday rotor and second Faraday rotors. Since a pair of Faraday rotors for rotating the plane of polarization in opposite directions, the plane of polarization on the incident side does not change on the outgoing side.
    • PCT No.PCT / JP92 / 00171 Sec。 371日期:1992年11月5日 102(e)日期1992年11月5日PCT提交1992年2月19日PCT公布。 出版物WO92 / 15040 日期:1992年9月3日。光隔离器不依赖于入射光束的偏振平面,不允许偏振平面在出射侧发生变化。 光隔离器包括第一平行扁平双折射晶体物质; 用于旋转梁的偏振平面的第一法拉第转子; 第二平行平面双折射晶体物质; 第二法拉第转子,用于在与所述第一法拉第转子旋转偏振平面的方向相反的方向上旋转偏振平面; 第三平行平面双折射物质; 第四平行平面双折射物质; 以及用于磁化法拉第转子和第二法拉第转子的永磁体。 由于用于在相反方向旋转偏振平面的一对法拉第转子,入射侧的偏振面在出射侧不变。
    • 83. 发明授权
    • Preparative separation/purification system
    • 制备分离纯化系统
    • US09259669B2
    • 2016-02-16
    • US12681323
    • 2007-10-02
    • Yutaka KonoMasayuki NishimuraBob BoughtflowerPrzemyslaw Stasica
    • Yutaka KonoMasayuki NishimuraBob BoughtflowerPrzemyslaw Stasica
    • B01D15/24
    • B01D15/24
    • Collection containers (17) are heated by head conduction from a container rack (18) with a heater (19) as the heat source. When an eluting solvent is supplied into a trap column (7) by a pump (5), an eluate containing a target compound exiting from the column (7) flows through a preparative separation passage (13) and drips from a solution nozzle (13a), and this solution is separated into fine droplets by a gas stream blowing from a gas ejection nozzle (15a). When a droplet touches an inner wall of the container (17), the volatile solvent immediately vaporizes, leaving the target compound precipitated in solid forms on the inner wall. Thus, the process of vaporizing and drying the eluate to collect the target compound is completed within a short period of time. This process can be performed online and hence is suitable for laborsaving.
    • 收集容器(17)通过头管传导从具有作为热源的加热器(19)的容器架(18)加热。 当通过泵(5)将洗脱溶剂供应到捕集塔(7)中时,含有从柱(7)排出的目标化合物的洗脱液流过制备分离通道(13),并从溶液喷嘴(13a) ),并且通过从气体喷射喷嘴(15a)吹送的气流将该溶液分离成细小液滴。 当液滴接触容器(17)的内壁时,挥发性溶剂立即蒸发,使目标化合物以固体形式沉淀在内壁上。 因此,蒸发并干燥洗脱液以收集目标化合物的过程在短时间内完成。 该过程可以在线执行,因此适合于劳动保护。
    • 84. 发明授权
    • Preparative separation/purification system
    • 制备分离纯化系统
    • US08607620B2
    • 2013-12-17
    • US12681276
    • 2007-10-02
    • Yutaka KonoMasayuki NishimuraBob BoughtflowerPrzemyslaw Stasica
    • Yutaka KonoMasayuki NishimuraBob BoughtflowerPrzemyslaw Stasica
    • G01N15/04
    • B01D15/203B01D15/24
    • After a target compound is captured by an adsorbent within a trap column (7) held by a column rack (8) in a substantially vertical position and the column is filled with water to wash its inside, dichloromethane is slowly introduced from an inlet end (7a) on the lower side by a pump (5). The water within the trap column (7) is pushed upward by dichloromethane and exits from an outlet end (7b), to be disposed of via a two-way selector valve (12) and a disposal passage (14). Dichloromethane elutes the captured target compound. Therefore, when the eluate, which initially consists of water, changes via an emulsion to dichloromethane, the eluate contains an adequately high concentration of target compound. At this point, the two-way valve (12) is switched to a preparative separation passage (13). As a result, a solution that is adequately free from water and yet contains the target compound can be collected into a collection container (17), and the target compound in solid forms can be quickly obtained.
    • 在由柱架(8)保持的捕集塔(7)中的吸附剂在基本垂直的位置捕获目标化合物,并且将柱填充水以洗涤其内部后,将二氯甲烷从入口端( 7a)通过泵(5)在下侧。 捕集塔(7)内的水被二氯甲烷向上推,从出口端(7b)出来,通过二通换向阀(12)和废弃通道(14)进行排放。 二氯甲烷洗脱捕获的目标化合物。 因此,当最初由水组成的洗脱液通过乳液变成二氯甲烷时,洗脱液含有足够高浓度的目标化合物。 此时,将开闭阀(12)切换到制备分离通道(13)。 结果,可以将充分不含水并含有目标化合物的溶液收集到收集容器(17)中,并且可以快速获得固体形式的目标化合物。
    • 85. 发明授权
    • Channel allocation method for multi-channel optical transmission and optical transmission system utilizing the method
    • 利用该方法的多通道光传输和光传输系统的信道分配方法
    • US08385743B2
    • 2013-02-26
    • US09781564
    • 2001-02-13
    • Toshiaki OkunoMasayuki Nishimura
    • Toshiaki OkunoMasayuki Nishimura
    • H04J14/02
    • H04B10/296H04J14/0221
    • Signal wavelengths λ1, λ2, λ3 of signal light components multiplexed at signal multiplexing sections 31, 41, 51 of multiplexing stations 3, 4, 5 installed on the input end side of an EDFA 2 on an optical transmission line 1 are set such that the wavelength-dependent noise figure of EDFA 2 successively decreases from the signal wavelength λ1 multiplexed at the signal multiplexing section 31 closest to the input end of EDFA 2 to λ2 and λ3. On the other hand, the transmission length of individual signal light component before being fed into the EDFA 2 is the shortest in the signal light component at λ1 and successively increases at λ2 and λ3. Thus, the order of magnitude of input signal light power is the same as the order of highness of noise figure in EDFA 2, whereby fluctuations in S/N ratio in the resulting amplified light are reduced.
    • 信号光分量的信号波长λ1,λ2,λ3被复用在安装在光传输线路1上的EDFA2的输入端侧的复用站3,4,5的信号多路复用部分31,41,51处, EDFA2的与波长相关的噪声系数从最靠近EDFA2的信号复用部分31多路复用的信号波长λ1连续减小到λ2和λ3。 另一方面,馈送到EDFA2中的各个信号光分量的发送长度在λ1的信号光分量中最短,并且在λ2和λ3处依次增加。 因此,输入信号光功率的数量级与EDFA2中的噪声系数高的顺序相同,从而降低了所得放大的光的S / N比的波动。
    • 87. 发明申请
    • PREPARATIVE SEPARATION/PURIFICATION SYSTEM
    • 准备分离/净化系统
    • US20100281958A1
    • 2010-11-11
    • US12681276
    • 2007-10-02
    • Yutaka KonoMasayuki NishimuraBob BoughtflowerPrzemyslaw Stasica
    • Yutaka KonoMasayuki NishimuraBob BoughtflowerPrzemyslaw Stasica
    • G01N30/02
    • B01D15/203B01D15/24
    • After a target compound is captured by an adsorbent within a trap column (7) held by a column rack (8) in a substantially vertical position and the column is filled with water to wash its inside, dichloromethane is slowly introduced from an inlet end (7a) on the lower side by a pump (5). The water within the trap column (7) is pushed upward by dichloromethane and exits from an outlet end (7b), to be disposed of via a two-way selector valve (12) and a disposal passage (14). Dichloromethane elutes the captured target compound. Therefore, when the eluate, which initially consists of water, changes via an emulsion to dichloromethane, the eluate contains an adequately high concentration of target compound. At this point, the two-way valve (12) is switched to a preparative separation passage (13). As a result, a solution that is adequately free from water and yet contains the target compound can be collected into a collection container (17), and the target compound in solid forms can be quickly obtained.
    • 在由柱架(8)保持的捕集塔(7)中的吸附剂在基本上垂直的位置捕获目标化合物之后,并且将柱填充水以洗涤其内部,将二氯甲烷从入口端( 7a)通过泵(5)在下侧。 捕集塔(7)内的水被二氯甲烷向上推,从出口端(7b)出来,通过二通换向阀(12)和废弃通道(14)进行排放。 二氯甲烷洗脱捕获的目标化合物。 因此,当最初由水组成的洗脱液通过乳液变成二氯甲烷时,洗脱液含有足够高浓度的目标化合物。 此时,将开闭阀(12)切换到制备分离通道(13)。 结果,可以将充分不含水并含有目标化合物的溶液收集到收集容器(17)中,并且可以快速获得固体形式的目标化合物。
    • 89. 发明授权
    • Raman amplifier module and optical transmission system using the same
    • 拉曼放大器模块和光传输系统使用相同
    • US06819477B2
    • 2004-11-16
    • US09911767
    • 2001-07-25
    • Tetsufumi TsuzakiMasayuki NishimuraMasaaki Hirano
    • Tetsufumi TsuzakiMasayuki NishimuraMasaaki Hirano
    • H01S3108
    • H04B10/2916H04B2210/003
    • An optical transmission path in a Raman gain module (1) for transmitting signal light input from an input terminal (1a) and Raman-amplifying the signal light by pumping light supplied from pumping light source units (21, 22) is formed by connecting in series two Raman amplification optical fibers (11, 12) having different wavelength dispersion values. According to this arrangement, wavelength dispersion in the amplifier module (1) can be controlled using, e.g., the combination of the wavelength dispersion values of the Raman amplification optical fibers (11, 12). Hence, accumulation of dispersion into signal light and signal light transmission in an almost zero dispersion state are prevented, and degradation in signal light transmission quality due to the nonlinear optical effect is suppressed.
    • 拉曼增益模块(1)中的用于传输从输入端子(1a)输入的信号光并通过泵浦从泵浦光源单元(21,22)提供的光来对信号光进行拉曼放大的光传输路径是通过连接 具有不同波长色散值的两个拉曼放大光纤(11,12)。 根据这种布置,可以使用例如拉曼放大光纤(11,12)的波长色散值的组合来控制放大器模块(1)中的波长色散。 因此,防止了色散在信号光中的积聚和几乎为零色散状态的信号光传输,并且抑制了由于非线性光学效应引起的信号光传输质量的劣化。