2) operation of water tubine generating unit
水轮发电机组的运行
3) water turbine-generator generator
水轮发电机机组
4) hydrogenerator unit
水轮发电机组
1.
Several technical problems of hydrogenerator unit of the Three Gorges Project;
三峡工程水轮发电机组若干技术问题
2.
The reason analysis of hydrogenerator unit self-rotation after stopping air brake quitting;
水轮发电机组停机制动风闸撤下后发生自转的原因分析
3.
This paper is directed against the reality problem that it is very difficult to measure the critical speed of the shaft system in a large scale hydrogenerator unit in operating.
针对大型水轮发电机组轴系临界转速难以实际测定的现实问题,从理论分析的角度出发,抓住水力机组轴系结构的基本特点,提出采用较为简单的模拟结构,试验研究水力机组轴系固有频率及其振型特征。
5) hydroelectric generating unit
水轮发电机组
1.
Research on vibration fault diagnosis of hydroelectric generating unit based on PNN;
基于PNN的水轮发电机组振动故障诊断
2.
Study on optimum start-up rule for hydroelectric generating units;
水轮发电机组最佳开机规律研究与实践
3.
In this paper,a novel simple controller design method for hydroelectric generating unit is described and applied in a high-order and non-minimumphase hydroelectric generating unit.
提出了一种简单新颖的水轮发电机组鲁棒控制器设计方法,并将其应用到一个高阶、非最小相位的水轮发电机组中。
6) hydroelectric generating set
水轮发电机组
1.
Extracting partial discharge signals of hydroelectric generating set based on empirical mode decomposition;
基于经验模态分解的水轮发电机组局部放电信号提取
2.
This paper probes into the causes and frequency of the vibration of hydroelectric generating set of Lijiaxia Hydropower Station form three aspects of the mechanics, electromagnetism and hydraulics, and advances some suggestions on carrying out the prototype test.
从机械、电磁和水力等3个方面对李家峡水电站水轮发电机组的振动原因及其频率进行了初步探讨,并提出了进行原型试验的建议。
3.
For simulating dynamic hydroelectric generating set easily and quickly,a new modeling method using Flowmaster2 soft is proposed.
按Flow-master2软件要求推导出了建立水电仿真系统过程中最关键部件水轮发电机组的数学模型,详细介绍建立其仿真模型的步骤和编程方法。
补充资料:水轮发电机组不对称运行
水轮发电机组不对称运行
unbalanced operation of water turbine generator set
sh〔21{u了1 lod一。(〕{{Zc才匕〔才dt才{c上1户11y丈才(lx一19水轮发电机组不对称运行(unbalaneed ox)-eration of water turbine generator set)水轮发电机组每相负荷的电流值及其相角处于互不相等情况下的一种运行方式。三相电力系统可分解为正序、负序、零序3个对称系统,对称运行时负序和零序分量为零,不对称运行时出现负序及零序分量。负序电流能引起定子绕组超温、转子附加发热和机械振动。 定子绕组超温由于负序电流出现后,和正序电流叠加,定子绕组会有一相相电流超过额定值,从而使该相绕组温升超过允许值。 转子附加发热和机械振动负序电流出现后,其负序旋转磁场以同步速度与转子反方向旋转,在励磁绕组、阻尼绕组以及转子本体中感应出两倍频率的电流,迫使这些部件产生附加损耗.引起局部发热。负序磁场还能在转子轴上产生两倍频率的脉动转矩,使水轮发电机组产生振动并伴有噪声。 水轮发电机组转子是凸极的,散热条件好,所以,其绕组可承受较大的温升。但是,水轮发电机组的转子直径较大,由于负序电流引起振动也比较严重.同时.由于水轮发电机座是焊接件,承受振动能力较弱,因此,振动能引起金属疲劳和机械损坏。不对称允许范围主要决定于下列3个条件。①负荷最大相定子电流不超过额定电流值。②转子任何一点温度不超过绝缘材料等级的允许温度。③出现的机械振动.不超过允许范围。由于水轮发电机组结构、材料、冷却方式不同,其允许范围也不同。一般是:水轮发电机组在不对称电力系统中运行时,任何一相电流不超过额定值,且其负序电流分量与额定电流之比不超过9%;对于灯池式水轮发电机在50MV·A及以下者不超过12%。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条