偏滤器
- divertor
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FEB-E的粒子抽除是通过偏滤器进行的。
The particle exhaust of Fusion Experimental Breeder FEB E is carried out with divertor .
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描述FEB偏滤器的物理设计研究。
The physical study of FEB divertor is presented .
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EAST超导托卡马克偏滤器水冷结构设计
Design of divertor cooling structure for EAST superconducting tokamak
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HL2A的单零偏滤器位形基本上是圆截面加上在X点附近的局部形变。
The boundary of the single-null diverted plasma in the HL-2A tokamak is simply a circular one plus a local triangular deformation near the X-point .
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本文用MonteCarlo方法模拟了偏滤器扁平抽气收集板附近区域的氦原子输运。
A Monte Carlo code " IDHET " has been utilized for simulating the transport of neutral helium near divertor target plate .
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HL-2A装置偏滤器物理分析及其实验的初步证实
Divertor physics analyses and preliminary experimental results on the HL-2A tokamak
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介绍用于HL-2A偏滤器托卡马克装置的远红外(FIR)激光干涉仪及其在等离子体电子密度测量中的应用。
A reflecting FIR interferometer and measurement of electronic density in HL-2A tokamak were presented in this paper .
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FEB偏滤器等离子体温度及靶板运行温度的优化
Optimization on the temperatures of divertor plasma and divertor plate in the Feb
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HL-2A单零偏滤器的位形特征
Characteristics of the single null divertor of the HL-2A tokamak
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ITER第一壁、偏滤器靶板和壁的热负荷计算
Power Flux Calculation of First Wall , Divertor Plate and Wall of ITER
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FEB混合堆偏滤器的物理研究
Physical Study of Experimental Fusion Breeder FEB Divertor
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HL-2A偏滤器结构改造及热负荷分析
Structural modification and power flux analysis of HL-2A divertor
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HL-2A偏压偏滤器物理设计
Physics design of biased divertor in the HL-2A tokamak
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HL-2A偏滤器位形的边缘等离子体特性
Edge plasma characteristics of divertor configuration in HL-2A tokamak
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HL-2A偏滤器运行模式的探针测量
Measuring the HL-2 A divertor plasma with probes
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HL-2A偏滤器托卡马克真空室的预装
Vacuum Vessel Preassembly of the HL-2A Divertor Tokamak
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大脉冲热负荷下HL-2A偏滤器靶板的热分析
Thermal analysis of the HL-2A divertor plates under dumping of intense pulse thermal load
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HL-2A装置偏滤器室中性气体压强的初步研究
Preliminary study of neutral gas pressure in the divertor chamber of the HL-2A tokamak
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HL-2A装置偏滤器改造的初步设计
Preliminary design of the HL-2 A divertor
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HL-2A装置偏滤器外靶板热负荷的红外测量
Infrared measurement of the heat flux at the outer divertor target plate on the HL-2A tokamak
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HL2A装置的第一壁由石墨构件、Cu偏滤器靶板和AISI304LN不锈钢真空室内壁组成。
The first wall in the HL-2A tokamak consists of the graphite components , the divertor plates made of Cu and the internal surface of the vacuum vessel made of AISI 304L stainless steel .
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为了研究HL-2A等离子体偏滤器位形,研制了等离子体形状实时显示系统。
The real-time visualization system of plasma shape is developed for studying the divertor plasma in HL_2A .
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在FEB偏滤器物理研究的基础上,描述FEB偏滤器的结构设计与热工分析。
On the basis of the physical study of FEB divertor , the engineering structure and thermal-technical analysis of FEB divertor is presented .
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根据HL-2A装置改造的初步方案,选择优化的偏滤器位形所决定的参数,设计出可采取的偏滤器结构及水冷方式。
An adoptable divertor structure and its cooling manner are designed with optimal parameters for HL-2A divertor according to its primary modification scheme .
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FEB-E偏滤器结构的优化设计
Optimized design of the feb-e divertor structure
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根据HL-2A装置的结构特点,提出了HL-2A装置偏滤器系统改造的基本方向。
A modified way of HL-2A divertor is presented based on the characteristics of the HL-2A device . An optimum design for the poloidal field coil system is made .
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在HL-2A单零偏滤器条件下,对由弱场侧沿赤道平面垂直注入的电子回旋寻常波(O-模)的波迹和波的功率沉积剖面进行了分析计算。
With the single-null divertor configuration on the HL-2A tokamak , the ray tracing and the wave power deposit for the ordinary electron cyclotron wave , perpendicularly injected from the weak field side , are analyzed .
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在FEB-E设计阶段,偏滤器从开放式固定板靶优化为封闭式气体靶,以改善偏滤器的杂质控制和增加离子与气体的相互作用。
In order to improve the impurity control and to increase the interaction of ions with neutral gas in the FEB divertor , the divertor is optimized to be the close type in the engineering design rather than the open one in the conceptual design .
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这些低温泵能提供的名义总抽速为576m3·s-1。在偏滤器高中性压力(>1Pa)情况下,低温泵入口阀节流控制抽气粒子流。
These cryopumps are capable of providing a nominal gross pumping speed of 576m 3 · s - 1 , regulated with inlet valves for throttle control of the exhaust particle flow in the case of high neutral pressure ( > 1Pa ) in the divertor .
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由于偏滤器抽气槽路以及偏滤器下侧通至真空室下部舱口的有限的通导能力,这些低温泵在偏滤器幽僻区域有效抽速为160m3·s-1。
However , limited conductance through the divertor pumping slot and through the clearance between the underside of the divertor and the vacuum vessel results in an effective net pumping speed of 160m 3 · s - 1 in the divertor private region .