Optimizing offshore wind export cable routing using GIS-based environmental heat maps

J. Backstrom, Nicholas M. Warden, Colleen Marie Walsh
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Abstract

Abstract. In the United States, there are plans to produce up to 30 GW of offshore wind power by the year 2030, resulting in numerous seabed lease areas which are currently going through the leasing or construction and operations phase. A key challenge associated with offshore wind is optimal routing and installation of the subsea power cables, which transmit power from the main offshore wind energy production area to a land-based station, where it connects to the electrical grid. By traversing a vast extent of the seafloor, the installation and operational phases of subsea power cables have the potential to result in a range of environmental impacts, which may negatively affect sensitive biological, physical, human and/or cultural resource receptors. Presented here is a case study from southeastern North Carolina to identify optimal seabed cable routes and coastal landfalls for a recently leased offshore wind farm by using a combination of publicly available data, coupled with standard environmental impact assessment methodologies and geographic information system (GIS)-based heat maps. The study identified a range of high-risk areas, in addition to a number of potential low-risk routes and landfall areas which minimize seabed user conflicts and impacts on environmentally sensitive locations. Although additional high-resolution and site-specific environmental, geological and biological surveys are required to develop a robust cable installation plan, the preliminary steps from this research optimize early-phase marine spatial planning for offshore wind projects and other similar subsea industries.
利用基于地理信息系统的环境热图优化海上风电出口电缆路线
摘要美国计划到 2030 年生产多达 30 千兆瓦的海上风力发电,由此产生了许多海底租赁区域,这些区域目前正处于租赁或建设和运营阶段。海上风能面临的一个主要挑战是海底电力电缆的优化布线和安装,这些电缆将电力从主要的海上风能生产区传输到陆地电站,并在陆地电站与电网连接。海底电缆穿越广阔的海底,其安装和运行阶段有可能对环境造成一系列影响,可能对敏感的生物、物理、人类和/或文化资源受体产生负面影响。本文介绍的是北卡罗来纳州东南部的一个案例研究,该研究通过结合使用公开数据、标准环境影响评估方法和基于地理信息系统 (GIS) 的热图,为最近租用的海上风电场确定最佳海底电缆路线和沿海着陆点。该研究确定了一系列高风险区域,以及一些潜在的低风险路线和着陆区,这些路线和着陆区可最大限度地减少海底使用者冲突和对环境敏感区域的影响。虽然还需要进行更多高分辨率和针对具体地点的环境、地质和生物调查,才能制定出可靠的电缆安装计划,但这项研究的初步步骤优化了海上风电项目和其他类似海底产业的早期海洋空间规划。
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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