Novel HVDC Power Transmission Architectures for Subsea Grid

Anindya Ray, K. Rajashekara, H. Krishnamoorthy
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引用次数: 2

Abstract

Subsea electrification is envisaged as one of the key building blocks of deep-water oil and gas (O&G) production. Present power transmission and distribution (T&D) schemes almost exclusively employ high voltage AC (HVAC) technology to drive the electrical processing units in the seabed, such as pump and compressor motors. Although HVAC transmission is reliable and simple to control, it exhibits a serious drawback with increasing step-out distance in terms of high reactive power requirements and reduction in peak power transfer capability for the subsea transmission cable. Moreover, most of the existing subsea T&D architectures employ a hub-and-spoke architecture with a single power receiving node. As a result, these systems are vulnerable to single-point failure. In order to address the above issues, two novel subsea architectures, based on high voltage DC (HVDC) transmission, are proposed in this paper. HVDC offers a significant advantage over HVAC systems for longer transmission distances with additional power processing units embedded in the system. Both these architectures employ a subsea DC distribution bus concept to supply multiple subsea loads which represent current scenario of increasing subsea consumers. The performance of the proposed architectures is illustrated through simulation for distinct events such as rated power flow, load step-up/down and load side breaker closing. Relevant results are discussed to summarize the advantages and challenges for the proposed power transmission architectures.
海底电网新型高压直流输电架构
海底电气化被认为是深水油气生产的关键组成部分之一。目前的输配电(T&D)方案几乎完全采用高压交流(HVAC)技术来驱动海底的电气处理单元,如泵和压缩机电机。尽管HVAC传输可靠且易于控制,但它存在一个严重的缺点,即在高无功功率要求和海底输电电缆峰值功率传输能力降低方面,其步进距离增加。此外,大多数现有的海底T&D架构都采用了带有单个电源接收节点的轮辐架构。因此,这些系统容易受到单点故障的影响。为了解决上述问题,本文提出了两种基于高压直流(HVDC)传输的新型海底架构。与HVAC系统相比,HVDC具有明显的优势,传输距离更长,系统中嵌入了额外的电源处理单元。这两种架构都采用海底直流配电总线概念来提供多个海底负载,这代表了当前不断增加的海底用户的情况。通过对不同事件(如额定功率流、负载升压/下降和负载侧断路器合闸)的仿真,说明了所提出架构的性能。讨论了相关结果,总结了所提出的电力传输架构的优势和挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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