变电站网络主时钟故障时保持时钟精度

2010 IEEE International Symposium on Precision Clock Synchronization for Measurement, Control and Communication Pub Date : 2010-10-25 DOI:10.1109/ISPCS.2010.5609805

Y. Kozakai, Mitsuru Kanda

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引用次数: 10

摘要

变电站自动化要求4µs精度和时钟同步机制的高可用性。时钟同步协议IEEE1588在正常运行情况下能够满足精度要求，但大师时钟发生故障时，由于反馈回路的瞬态响应，从机会出现较大的时间误差。由于IEEE1588定义了它们之间的通信，因此故障也可能触发另一个宗师时钟上的另一个故障。我们提出了一种新的网络架构，利用IEEE802.1Q VLAN，使所有的宗师时钟都能处于热备状态。从机可以同步到，并且可以在两者之间切换，没有时间误差。我们的建议也可以限制故障对其他特级大师时钟的影响。我们还描述了从机的内部设计，它由冗余反馈回路软件和单个振荡器组成。实验结果表明，当一个宗师时钟断开，从机切换到另一个宗师时钟时，从机的时间误差可以保持在70ns以内。

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Keeping clock accuracy on a master clock failure in substation network

Substation automation requires 4 µs accuracy and high availability of the clock synchronization mechanism. The clock synchronization protocol IEEE1588 satisfies the accuracy requirement under normal operation, but a failure on a grandmaster clock causes a large time error on the slave due to transient response by feedback loop. The failure may also trigger another failure on another grandmaster clock since IEEE1588 defines communication among them. We propose a new network architecture that utilizes IEEE802.1Q VLAN so that all grandmaster clocks can be in hot stand-by. The slave can simultaneously synchronize to and can switch between them without time error. Our proposal can also limit the impact of the failure on the other grandmaster clocks. We also describe the internal design of the slave, which consists of software of redundant feedback loops and a single oscillator. The experimental results show that the slave can keep time error under 70ns while a grandmaster clock is disconnected and the slave switches to another grandmaster clock.

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2010 IEEE International Symposium on Precision Clock Synchronization for Measurement, Control and Communication

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