1) wave compensating device
波浪补偿装置
1.
The design of the wave compensating device for hydraulic folding type crane;
液压折臂式起重机的波浪补偿装置设计
2) heave compensation
波浪补偿
1.
Fuzzy reliability was applied to the optimization design of the differential planet transmission mechanism for heave compensation.
将模糊可靠性设计应用于波浪补偿系统的差动行星传动装置优化设计,在一般优化设计方法的基础上,建立以波浪补偿系统差动行星传动机构"体积最小"、"径向尺寸最小"、"传动效率最高"、"行星轮轴承温升最小"、"外啮合膜厚比最大"和"外啮合齿根最大滑动率最小"等为分目标的多目标模糊可靠性优化设计数学模型,研究处理多目标优化问题的模糊决策方法以及基于遗传算法的混合离散变量离散化处理方法,得到多目标模糊优化问题的求解方法。
2.
A new active heave compensation system(AHCS) was proposed,based on a differential planet transmission mechanism.
基于差动行星齿轮传动机构,提出了一种新型主动式波浪补偿系统。
3.
Based on classical PID,an intelligent PID control calculation is developed using single neuron,for the non-linear control problem about mechanism,electricity and liquid,of a new initiative heave compensation system.
针对一种新型主动式波浪补偿系统的机、电、液非线性控制问题,以经典PID为基础,提出了一种利用单神经元结构加以实现的智能PID控制算法。
3) wave compensation
波浪补偿
1.
Study on new type of offshore transfer equipment based on wave compensation technology
基于波浪补偿技术的新型海上换乘装置研究
2.
Fuzzy control method is available in wave compensation crane.
通过数字仿真,表明该起重机的随动性能良好,具有较好的适应性能,得出了模糊控制适用于波浪补偿起重机伺服控制系统的结论。
3.
In this article, a replenishment system for small-scale ships is proposed based on the improvement of the supply mode, wave compensation equipment, lift hook and receiving terminal according to the highline system for replenishment in existence.
针对现有高架索补给系统,在补给方式、波浪补偿装置、吊钩和接受端方面进行改进,提出适合小型船舶补给作业的补给系统;并在此基础之上对补给中关键参数进行计算,计算结果表明,此系统可以保证补给过程顺利实施,适合小型船舶补给需求。
4) filtering compensation device
滤波补偿装置
1.
Through technical reform in“9th Five-Year plan”, a newly developed equipment-TAL-16 7 filtering compensation device has been installed at 220kV power station to eliminate higher-order harmonic wave pollution.
我厂 2 2 0kV站安装了新设备滤波补偿装
5) wave motion compensator
波动补偿装置
6) Swell compensator
波浪补偿器
补充资料:并联无功补偿装置
并联无功补偿装置
shunt equipment for var compensation
eomPensation) 基本原理···············,·······················……56 补偿的基本原则······························……56 主要类型·······,·······························……56 机械投切型无功补偿装里···············……56 并联电容器······························……57 滤波器····································……57 并联电抗器······························……57 快速调节型无功补偿装里···············……57 同步调相机······························……57 静止无功补偿装置·····················……57 静止同步补偿器························……57 主要技术性能·································……57 用途·············································……57 负荷补偿····································……57 交流输配电系统补偿·····················……57 超高压直流输电系统补偿···············……57 兼作滤波装置······························……57 发展简况·······································……59 并联在电力网上,向电网注人或从电网吸收无功功率的装置,常称无功补偿装置。但就补偿装里接入电网的方式而言.不仅包括并联补偿装置,还应包括申联补偿装置。无功功率的性质,有感性无功功率和容性无功功率的区别。电力系统的负荷大都是感性负荷,即消耗感性无功;习惯上“无功”就是指感性无功,即不标明性质的无功功率即指感性无功功率。如电容器是容性负荷,它吸收容性无功功率亦即发出感性无功功率,一般称电容器发出无功或说它是无功电源;反之电抗器吸收无功则是无功负荷。静止同步补偿装1既可工作于容性区又可工作于感性区,既可供给无功也可吸收无功。向系统提供无功称为“正补偿”,从系统吸收无功则称为“负补偿”。
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