Mathematical modeling power-saving thyristor-motor drives of switching design

2018 IEEE Conference of Russian Young Researchers in Electrical and Electronic Engineering (EIConRus) Pub Date : 2018-01-01 DOI:10.1109/EICONRUS.2018.8317181

A. Karandaev, O. I. Karandaeva, A. Maklakov, R. Mugalimov, E. Khramshina

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引用次数: 2

Abstract

DC electric drives of rolling mills are the greatest electromechanical power consumers at iron and steel works. Energy indexes of these drives are far from the optimal ones. Most power losses are associated with consumption of reactive power caused by voltage phase control. Previous papers described the two-region control design based on rearranging reserve of the rectified EDV of the thyristor converter in steady-state and dynamic modes. Methods and systems of dependent control of excitation flow implementing that concept were proposed. A mathematical model of an electric drive of the wide-strip hot-rolling mill is required to study dynamic properties of this system. This paper depicts structures of control system models with coordinate switching controlled with the excitation circuit. Transient processes of the electric drive were investigated for a rolling cycle at different setting of EDV control circuits. Operational integrity and efficiency of the developed two-region speed control with switching units were proven. The results provide a rationale for introduction of the developed systems into the thyristor electric drives of rolling mills.

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数学建模节能晶闸管-电机驱动开关的设计

轧钢厂的直流电力驱动是最大的机电电力消耗者。这些驱动器的能量指标远未达到最优。大多数功率损耗与电压相位控制引起的无功功率消耗有关。以往的文献介绍了在稳态和动态两种模式下，基于整流EDV储备重新安排的两区控制设计。提出了实现这一概念的励磁流依赖控制的方法和系统。为了研究该系统的动态特性，需要建立宽带钢热轧机电传动的数学模型。本文描述了用励磁电路控制的坐标切换控制系统模型的结构。研究了在不同控制电路设置下，一个滚动循环下电驱动的瞬态过程。验证了所开发的带开关单元的双区域速度控制的完整性和有效性。研究结果为将所开发的系统引入轧机晶闸管电力驱动系统提供了理论依据。

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2018 IEEE Conference of Russian Young Researchers in Electrical and Electronic Engineering (EIConRus)

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