气候变化对水力发电的多尺度影响,促进美国毗连地区的长期水能规划

Daniel Broman, Nathalie Voisin, S. Kao, Alisha Fernandez, Ganesh R Ghimire
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引用次数: 0

摘要

气候变化对流域的影响可能会加剧缺水问题,因为水具有多种用途,包括水力发电。对水资源和能源资源的长期管理大多仍以孤立的方式在不同流域或集水区进行,没有考虑到可能同时影响多个地区的潜在影响。我们需要一个大规模的水力发电建模框架,该框架可以检查跨流域和平衡机构(BA)的气候影响,并提供从区域到国家范围的评估。在之前仅对美国联邦水电站进行评估的基础上,我们增强并扩大了两个区域水电模型的范围,使其覆盖了水电铭牌总容量的 85% 以上,并采用不确定性感知多模型集合方法,首次对 CMIP6 高端 SSP5-8.5 排放情景下的未来水电生产进行了全美国(CONUS)范围的评估。我们使用 BA 区域和美国水文分区 (HUC4) 进行区域水电预测,以便为能源和水资源界提供与历史基准期(1980-2019 年)相对应的两个未来时期--近期(2020-2039 年)和中期(2040-2059 年)--的一致信息。我们发现,年水力发电量的预测变化中值通常为正值--近期约为 5%,中期约为 10%。然而,由于预计区域干旱的风险也会增加,研究表明,由于水力发电量合计中值的增加,可能会忽视严重的水力发电量减少。该评估可为区域公用事业公司和电力系统运营商提供信息,帮助他们制定干旱方案,以支持设计长期储存方案,并评估其能源基础设施在水电年际和季节变化情况下的可靠性,同时为水资源管理者提供相关规模的一致预测,以评估水能权衡。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multi-scale impacts of climate change on hydropower for long-term water-energy planning in the contiguous United States
Climate change impacts on watersheds can potentially exacerbate water scarcity issues where water serves multiple purposes, including hydropower. The long-term management of water and energy resources is still mostly approached in a siloed manner at different basins or watersheds, failing to consider the potential impacts that may concurrently affect many regions at once. There is a need for a large-scale hydropower modeling framework that can examine climate impacts across ajoining river basins and balancing authorities (BAs) and provide an assessment at regional to national scales. Expanding from our prior assessment only for the U.S. federal hydropower plants, we enhance and extent two regional hydropower models to cover over 85% of the total hydropower nameplate capacity and present the first contiguous U.S. (CONUS)-wide assessment of future hydropower production under CMIP6’s high-end SSP5-8.5 emission scenario using an uncertainty-aware multi-model ensemble approach. We present regional hydropower projections, using both BA regions and U,S. hydrologic Subregions (HUC4s) to consistently inform the energy and water communities for two future periods – the near-term (2020–2039) and the mid-term (2040–2059) relative to a historical baseline period (1980–2019). We find that the median projected changes in annual hydropower generation are typically positive – approximately 5% in the near-term, and 10% in the mid-term. However, since the risk of regional droughts is also projected to increase, the study suggests the potential for severe hydropower reductions that could be overlooked due to the increase in ensemble median hydropower generation. The assessment can inform regional utilities and power system operators in developing drought scenarios in support of designing long-term duration storage and evaluating the reliability of their energy infrastructure under inter-annual and seasonal variability in hydropower, with consistent projections at relevant scale for water managers to evaluate water-energy tradeoffs.
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