蒸汽发生器水位控制系统是非线性、时变的多变量系统,“虚假液位”现象的存在使蒸汽发生器液位控制成为一个难题。
Steam generator level is a non-linear, mutative and multi-variable system. It is a problem to design the control system because of "false level".
基于主蒸汽管道中16N核素监测的蒸汽发生器泄漏率监测方法,目前已成为蒸汽发生器泄漏监测的主导方法。
The method of through monitoring 16N activities in the main steam pipe to get the leak rate of steam generator, now is the main way of steam generator leak rate monitoring.
因此,控制蒸汽发生器水位非常重要而且是非常必要的,对蒸汽发生器水位控制的研究是非常有价值的。
Therefore, it is very important and necessary to control water level of steam generator and it is very valuable for the study on water level control.
蒸汽发生器水位的高低直接影响出口蒸汽的品质和蒸汽发生器的安全。
Water level has a direct effect on the quality of outlet steam and the safety of steam generator.
因此,控制蒸汽发生器水位非常重要而且是非常必要的,对蒸汽发生器水位控制的研究是非常有价值的。
Therefore it is important and necessary for us to control water level of steam generator and it is valuable to have study on water level control.
本文针对传统的核动力蒸汽发生器水位PID控制方法存在的缺点,将神经网络方法与PID控制的结构结合起来,提出了核动力蒸汽发生器水位神经自适应PID控制方法。
The method of adaptive neural-PID control that combines neural network and PID control is put forward in allusion to shortcoming of conventional PID control for nuclear steam generator water level.
本文针对传统的核动力蒸汽发生器水位PID控制方法存在的缺点,将神经网络方法与PID控制的结构结合起来,提出了核动力蒸汽发生器水位神经自适应PID控制方法。
The method of adaptive neural-PID control that combines neural network and PID control is put forward in allusion to shortcoming of conventional PID control for nuclear steam generator water level.
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