What would a US green hydrogen energy economy look like?

IF 2.9 4区 环境科学与生态学 Q3 ENERGY & FUELS
Clean Energy Pub Date : 2023-10-01 DOI:10.1093/ce/zkad047
Thomas Tonon
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Abstract

Abstract Detailed description is given for a hypothetical US hydrogen economy with solar and wind energy supplying virtually all current energy needs and with electrolytic hydrogen the energy carrier and storage medium. Fossil fuels provide nonfuel products (plastics, chemicals, cement and asphalt). Only current technologies are considered and hydrogen storage accommodates generation intermittency and variability, using pit storage of high-pressure vessels in open air, yielding daily storage round-trip energy installation costs of 722 and 538 $/kWh for electric and thermal, respectively; and for power, 2351 and 2240 $/kW for electric and thermal, respectively. For long-duration storage, the costs are 94.1 and 23.8 $/kWh and 937 and 845 $/kW, respectively. Increased energy generation 20% over baseline accommodates low-season generation, obviates much required storage and ensures that reserves are topped off; 96% of US 2022 total energy consumption is provided for. In the default scenario (demand energy portions: half photovoltaic, quarter onshore wind and quarter offshore wind), the surface area for the farms (including offshore surface) requires ~4.6% of the US 48-state land area. About 350 pit storage sites provide both daily and long-duration storage, with the latter accounting for complete loss of generation for 4 days over a quarter of the nation. Hydrogen pipelines and a renewed electric grid transmit and distribute energy. The installation cost of the public infrastructure is ~$27.8 trillion for the default scenario. Alternative scenarios show significant infrastructure and cost savings when batteries are used for transportation and/or utility storage, provided current insufficiencies can be overcome. Broadly, cost levels in money, surface and infrastructure are within existing levels already achieved in historical events and modern living.
美国绿色氢能源经济会是什么样子?
摘要详细描述了一个假设的美国氢经济,其中太阳能和风能提供几乎所有当前的能源需求,并以电解氢作为能量载体和储存介质。化石燃料提供非燃料产品(塑料、化学品、水泥和沥青)。仅考虑目前的技术,氢气储存可以适应发电的间歇性和可变性,使用露天高压容器的坑式储存,每天的电力和热能储存往返能源安装成本分别为722美元和538美元/千瓦时;电力方面,电和热分别为2351美元和2240美元/千瓦。对于长时间储能,成本分别为94.1和23.8美元/千瓦时和937和845美元/千瓦时。在基线基础上增加20%的发电量,以适应淡季发电,避免了大量需要的储存,并确保储备被填满;美国2022年总能源消耗的96%是提供的。在默认情况下(需求能源部分:一半光伏,四分之一陆上风电和四分之一海上风电),农场的表面积(包括海上表面)需要约占美国48个州土地面积的4.6%。大约有350个蓄水池提供日常和长期储存,后者占全国四分之一以上的4天完全损失发电。氢气管道和更新的电网传输和分配能源。在默认情况下,公共基础设施的安装成本约为27.8万亿美元。当电池用于运输和/或公用事业存储时,其他方案显示出显著的基础设施和成本节约,前提是电流不足可以被克服。总的来说,金钱、地面和基础设施的成本水平在历史事件和现代生活中已经达到的现有水平之内。
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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来源期刊
Clean Energy
Clean Energy Environmental Science-Management, Monitoring, Policy and Law
CiteScore
4.00
自引率
13.00%
发文量
55
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