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    • 1. 发明专利
    • 崩壊熱除去システムおよび空気冷却器
    • 减热除气系统和空气冷却器
    • JP2015010841A
    • 2015-01-19
    • JP2013134154
    • 2013-06-26
    • 株式会社東芝Toshiba Corp
    • KIKKO DAIGOKOMITA HIDEOSATO NOZOMI
    • G21C15/18G21C1/02G21C15/06
    • Y02E30/34
    • 【課題】原子炉施設の異常時における崩壊熱除去システムの除熱能力を確保しながら、原子炉施設の通常運転状態での崩壊熱除去システムにおける熱損失の発生を抑制する。【解決手段】実施形態によれば、崩壊熱除去システム50は、2次冷却材を空気によって冷却する空気冷却器10と、原子炉冷却系40から高温の2次冷却材を空気冷却器10に導き、互いに並列に設けられた第1の流路配管31aと第1の流路配管31aよりも流路面積の小さな第2の流路配管32とを有する空気冷却器入口配管31と、空気冷却器10で冷却された2次冷却材を原子炉冷却系40に戻す空気冷却器出口配管33と、第1の流路配管31aに設けられて第1の流路配管31aを外側から冷却する入口配管冷却装置35とを有する。空気冷却器10は原子炉冷却系40よりも高所に配置されている。【選択図】図1
    • 要解决的问题:当核反应堆安装正常运行时,抑制朽烂散热系统的热损失,核反应堆安装中发生异常情况下保持的衰变散热系统的除热能力。解决方案:衰减 除热系统50包括:空气冷却器10,其用空气冷却二次冷却剂; 空气冷却器入口管31包括第一流路管31a和第二流道管32,其流路面积小于彼此平行设置的第一流动通道管31a的流路面积,引导高温二次管 从反应堆冷却剂系统40到冷却器10的冷却剂; 空气冷却器出口管33,其将由空气冷却器10冷却的二次冷却器引导回反应堆冷却剂系统40; 并且设置在第一流路管31a上的入口管冷却器35从外部冷却第一流路管31a。 空气冷却器10设置在比反应堆冷却剂系统40更高的位置。
    • 2. 发明专利
    • 遠隔作業自動機の充電システム及び方法
    • 远程工作自动机的充电系统及方法
    • JP2014230409A
    • 2014-12-08
    • JP2013108698
    • 2013-05-23
    • 株式会社東芝Toshiba Corp
    • FUJIWARA RYOMAKOMITA HIDEOKIKKO DAIGOUEHARA TAKUYASUGAWARA RYOICHISATO NOZOMI
    • H02J7/00B25J5/00B25J19/00H02J17/00
    • 【課題】遠隔作業自動機が充電のために移動する距離を短縮して遠隔作業自動機の作業性を向上させることができること。【解決手段】遠隔操作により移動する遠隔作業自動機としての多脚ロボット15に充電を行う遠隔作業自動機の充電システムであって、多脚ロボット15の胴部17に設置され、多脚ロボット15を駆動するために必要な電力を内蔵する電力貯蔵ボックス11と、この電力貯蔵ボックス11に着脱可能に装着されると共に送電用の電源線13が接続され、この電源線13からの電力を電力貯蔵ボックス11へ供給する電力供給ボックス12とを有し、電力供給ボックス12が、電力貯蔵ボックス11を介して多脚ロボット15により運搬可能に構成されたものである。【選択図】図1
    • 要解决的问题:通过缩短远程工作自动机移动充电的距离来提高远程工作自动机的可操作性。解决方案:一种用于远程工作自动机的充电系统,其将多腿机器人15充电为 在远程控制下移动的远程工作自动机包括:安装在多腿机器人15的主体部分17中并具有驱动多腿机器人15所需的动力的蓄电箱11; 以及电源箱12,其以可拆卸的方式安装到蓄电箱11,电力线13用于电力传输,并且从电力线13向蓄电箱11供电。电力 供电箱12可以由多腿机器人15经由蓄电箱11承载。
    • 3. 发明专利
    • Method and apparatus for separating and recovering impurity in molten salt
    • 用于分离和恢复浇注盐中的污染物的方法和装置
    • JP2005048210A
    • 2005-02-24
    • JP2003203958
    • 2003-07-30
    • Toshiba Corp株式会社東芝
    • HODOZUKA MASATOSHISHOJI YUICHISATO NOZOMIUNOKI KAZUOYAMAMOTO KEIICHI
    • B01D21/26B01J19/08C22B3/04C22B23/00C22B34/22C25C3/26C25C7/06
    • Y02P10/234
    • PROBLEM TO BE SOLVED: To provide a method for separating and recovering impurities in a molten salt, which removes the impurities from the molten salt used for burning of an organic substance to prevent the impurities from adversely affecting the molten salt, recovers valuable metals such as vanadium and nickel from the molten salt, and recycles them, and to provide an apparatus therefor. SOLUTION: The separating and recovering method comprises (1) cooling/pulverizing the molten salt and dissolving the product in an aqueous solution to precipitate/separate nickel sulfide; and (2) further supplying solid carbon and chlorine gas to the molten salt 16 to convert a vanadate ion to a metallic vanadium ion 17, and electrolyzing the solution to deposit the metallic vanadium ion on the surface of a cathode 20. COPYRIGHT: (C)2005,JPO&NCIPI
    • 要解决的问题:提供一种用于分离和回收熔融盐中的杂质的方法,其从用于燃烧有机物质的熔融盐中除去杂质以防止杂质对熔融盐的不利影响,恢复有价值 金属如钒和镍从熔融盐中回收,并提供其设备。 解决方案:分离和回收方法包括(1)冷却/粉碎熔融盐并将产物溶解在水溶液中以沉淀/分离硫化镍; 和(2)进一步向熔盐16供应固体碳和氯气,以将钒酸盐离子转化成金属钒离子17,并且电解该溶液以将金属钒离子沉积在阴极20的表面上。 (C)2005,JPO&NCIPI
    • 4. 发明专利
    • ELECTROMAGNETIC PUMP
    • JPH0564414A
    • 1993-03-12
    • JP22453291
    • 1991-09-05
    • TOSHIBA CORP
    • SATO NOZOMI
    • H02K11/00H02K44/06
    • PURPOSE:To improve a heat recovery and the efficiency and reliability of an electromagnetic pump by lowering and leveling the temperature rise of each part through arranging a comb-type cooling member or cooling member equipped with a cooling fluid path between laminated core blocks so that the cooling member covers a stator coil. CONSTITUTION:Heat generated in a stator coil 9 is transmitted from an outer duct 3 via laminated core block 7 to the conductive fluid 2 in an annular passage 5, also from the circumference of the laminated core block 7 via inert gas 23 and casing 22 to the conductive fluid 2 in which an electromagnetic pump 20 is immersed, and further from the stator coil 9 directly via the side faces of a cooling member 21 and the laminated core block 7 to the cooling member 21, and transferred via the inert gas 23 and casing 22 to the conductive fluid 2. Thus, even if a gap 8 is provided, the heat transfer from the stator coil 9 directly to the laminated core block 7 and cooling member 21 and from the side face of the laminated core block 7 to the cooling member 21 is conducted effectively.
    • 5. 发明专利
    • ELECTROMAGNETIC PUMP
    • JPH0476276A
    • 1992-03-11
    • JP18727990
    • 1990-07-17
    • TOSHIBA CORP
    • SATO NOZOMI
    • F04D7/00F04B17/04
    • PURPOSE:To transmit heat generated in a stationary coil to the whole part of an electromagnetic pump efficiently and enable preheating evenly and rapidly by changing gas atmosphere in a casing upon preheating over inactive gas excellent in heat conductivity. CONSTITUTION:In a casing 9 a gas supplying nozzle 17 is arranged, and the fore-end thereof is extended in the vicinity of fluid inlet 7. The nozzle 17 is connected to a vacuum exhaust line 12, inactive gas supply line 13 and insulation gas supply line 14 respectively through solenoid valves 20 to 22. The inside of the casing 9 is made under gas atmosphere 11 to prevent discharge with a stationary coil 2 as well as oxidation. The gas atmosphere 11 is filled with insulation gas excellent in electric insulation upon operation, and under the condition an electromagnetic pump is immersed with fluid 10. During preheating operation, vacuum operation is carried out by the line 12 to make the vacuum gas atmosphere 11 in the casing 9, and thereafter inactive gas of high heat conductivity is supplied with the line 13.
    • 7. 发明专利
    • Flow rate controller and heat exchanger
    • 流量控制器和换热器
    • JP2014191457A
    • 2014-10-06
    • JP2013064626
    • 2013-03-26
    • Toshiba Corp株式会社東芝
    • ASADA TAKATOSHIKIKKO DAIGOKOMAI MASAFUMISATO NOZOMISUGAWARA RYOICHI
    • G05D7/06F15B21/06H02K44/06
    • PROBLEM TO BE SOLVED: To provide a flow rate controller capable of solving a conventional problem that, in a piping in which an electromagnetic fluid flows, especially in a branching piping, the flow may be split unevenly; and it is difficult to mechanically process to control the flow in aspect of cost and installation.SOLUTION: A flow rate controller 101 of an electromagnetic fluid 102 flowing in a piping includes: an electromagnet 1 disposed on the periphery of the piping; and control means 2 that controls current or voltage of electromagnet. The electromagnet is arranged to give an electromagnetic force to the electromagnetic fluid in an inverse direction of the flow of the electromagnetic fluid with the magnetic field generated by the electromagnet.
    • 要解决的问题:提供一种流量控制器,其能够解决在电磁流体流动的管道中,特别是在分支管道中的流动可能不均匀地分流的常规问题; 并且在成本和安装方面难以机械加工以控制流量。解决方案:在管道中流动的电磁流体102的流量控制器101包括:布置在管道周边的电磁体1; 以及控制电磁铁的电流或电压的控制装置2。 电磁铁被布置成以与电磁体产生的磁场的电磁流体的流动的相反方向向电磁流体施加电磁力。
    • 9. 发明专利
    • Passive cooling system for liquid metal cooling reactor
    • 用于液体金属冷却反应器的被动冷却系统
    • JP2013076675A
    • 2013-04-25
    • JP2011217996
    • 2011-09-30
    • Toshiba Corp株式会社東芝
    • KIKKO DAIGOSUGAWARA RYOICHIKOMITA HIDEOTSUBOI YASUSHISATO NOZOMI
    • G21C15/18
    • Y02E30/35
    • PROBLEM TO BE SOLVED: To achieve sufficient heat removal when removing residual decay heat generated in a reactor core.SOLUTION: In a passive cooling system 32 for a liquid metal cooling reactor, a downflow passage 35 is formed between a heat collector 34 and a silo 31, an upflow passage 36 is formed between the heat collector 34 and a guard vessel 19, a cooling passage 33 is configured by including the passages 35 and 36, and during a period in which external air is introduced into the downflow passage 35 and is allowed to flow down, an air flow is converted into an upflow on the bottom of the silo 31 and then is allowed to flow up in the upflow passage 36 and is exhausted to the external, a liquid metal cooling material 13, a reactor vessel 11 and the guard vessel 19 are cooled. In the passive cooling system 32, a heat absorption member 41 is arranged on the upper part of the inside of the reactor vessel 11 in a state immersed in a liquid metal cooling material 13 and a heat sink 42 is arranged on the upper part of the reactor vessel 11 so as to be thermally connected to or isolated from the heat absorption member 41. In thermal connection with the heat absorption member 41, the heat sink 42 discharges heat of the heat absorption member 41 to the outside of the reactor vessel.
    • 要解决的问题:为了在去除在反应堆堆芯中产生的残余腐蚀热时实现足够的散热。 解决方案:在用于液态金属冷却反应器的被动冷却系统32中,在集热器34和料仓31之间形成有下流通道35,在集热器34和保护容器19之间形成上流通道36 通过包括通道35和36构成冷却通道33,并且在将外部空气引入下流通道35并允许向下流动的时段期间,空气流被转换成上流 料仓31然后被允许在向上流动通道36中向上流动并排出到外部,液态金属冷却材料13,反应器容器11和保护容器19被冷却。 在被动冷却系统32中,在浸没在液体金属冷却材料13中的状态下,在反应容器11内部的上部配置吸热部件41,在上部设有散热片42 反应器容器11与热吸收构件41热连接或隔离。与吸热构件41热连接,散热器42将吸热构件41的热量排放到反应堆容器的外部。 版权所有(C)2013,JPO&INPIT
    • 10. 发明专利
    • Method and apparatus for detoxicating treatment of harmful organic material
    • 用于去除有害有机材料处理的方法和装置
    • JP2003300041A
    • 2003-10-21
    • JP2002109071
    • 2002-04-11
    • Toshiba Corp株式会社東芝
    • SATO NOZOMISHOJI YUICHIAIZAWA TOSHIEOKUDA YASUYUKI
    • F23J1/00B01D53/14B01D53/70B09B3/00B09C1/02B09C1/08
    • PROBLEM TO BE SOLVED: To perform decomposing treatment of an harmful organic compound to a harmless compound without discharging any harmful compound in an environment in a process of detoxicating decomposing treatment of the harmful organic compound. SOLUTION: The harmful organic compound 3, dioxins for example, is blended in a molten salt of alkaline metal hydroxide, sodium hydroxide 1 for example and the obtained salt mixture is heated to perform decomposing treatment 4 of the harmful organic compound. Gaseous decomposed products 5 are subjected to gas decontamination 6 and are discharged in air 8 as harmless gases 7. Meanwhile used molten salt 9 is subjected to salt purification 10 and recovered sodium hydroxide 11 is reused and other salts 13 such as sodium carbonate are discarded. COPYRIGHT: (C)2004,JPO
    • 要解决的问题:在有害有机化合物的分解处理的过程中,在环境中,在不排出有害化合物的情况下,将有害有机化合物分解成无害化合物。 解决方案:将有害有机化合物3(例如二恶英)混合在碱金属氢氧化物的熔融盐,例如氢氧化钠1中,并将所得盐混合物加热以进行有害有机化合物的分解处理4。 气体分解产物5进行气体净化6,并在空气中排放8作为无害气体7.同时使用的熔融盐9进行盐净化10,回收的氢氧化钠11被再利用,并且丢弃其它盐13如碳酸钠。 版权所有(C)2004,JPO