碳中和的美国能源系统电解氢耗水量

Emily Grubert
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引用次数: 2

摘要

氢是一种能源载体,在难以通电的能源和工业系统脱碳方面具有潜在应用。氢气的环境状况随其输入量的变化而变化很大。随着资本和其他投资的决策将影响氢气使用的规模和范围,耗水量是一个特别令人感兴趣的问题。这项研究的重点是电解氢,因为它可以实现温室气体中和和不可减少的水需求(尽管其他途径可能更耗水)。具体而言,它评估了美国电解氢的生命周期淡水消耗强度,其量与2050年深度脱碳的美国能源系统的12种情景相关,这两种建模工作都预测了电力燃料组合和电解氢生产(美国的零碳行动计划和净零美国),除了一个程式化的储能项目(500兆瓦氢燃涡轮机)的容量外。淡水对氢气的需求可能很大。根据对2050年美国电解氢产量的中央估计,仅工艺和原料投入(即不包括电力用水)的电解淡水需求将约为2014年美国能源淡水消耗总量的7.5%(10亿立方米/年,109立方米/年;在各种情况下,【0.2%,15%】,2050年电解氢产量为【0.3,18】EB焦耳,EJ)。包括与输入电力生产相关的水在内,这一中心估计值翻了一番,达到15%(2×109立方米/年;在各种情况下为[1%,23%])。假设脱碳、低水电投入,使用电解氢的涡轮机的淡水密集度估计与燃煤或核电站差不多。尽管脱碳能源系统预计比目前以化石为主的能源系统需要更少的水来进行资源捕获和电力转换,但支持脱碳的额外转换过程,如电解,可能会抵消节水。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Water consumption from electrolytic hydrogen in a carbon-neutral US energy system

Hydrogen is an energy carrier with potential applications in decarbonizing difficult-to-electrify energy and industrial systems. The environmental profile of hydrogen varies substantially with its inputs. Water consumption is a particular issue of interest as decisions are made about capital and other investments that will affect the scale and scope of hydrogen use. This study focuses on electrolytic hydrogen due to its path to greenhouse gas neutrality and irreducible water demand (though other pathways might be more water intensive). Specifically, it evaluates life cycle consumptive freshwater intensity of electrolytic hydrogen in the United States at volumes associated with 12 scenarios for a deeply decarbonized 2050 US energy system from two modeling efforts for which both electricity fuel mix and electrolytic hydrogen production were projected (America's Zero Carbon Action Plan and Net Zero America), in addition to volumes for a stylized energy storage project (500 MW hydrogen-fired turbine). Freshwater requirements for hydrogen could be large. Under a central estimate for 2050 US electrolytic hydrogen production, electrolytic freshwater demand for process and feedstock inputs alone (i.e., excluding water for electricity) would be about 7.5% of total 2014 US freshwater consumption for energy (1 billion cubic meters/year, 109 m3/y; [0.2%, 15%] across scenarios, for 2050 electrolytic hydrogen production of [0.3, 18] exajoules, EJ). Including water associated with production of input electricity doubles this central estimate to 15% (2 × 109 m3/y; [1%, 23%] across scenarios). Turbines using electrolytic hydrogen are estimated to be about as freshwater intensive as a coal or nuclear plant, assuming decarbonized, low-water electricity inputs. Although a decarbonized energy system is projected to require less water for resource capture and electricity conversion than the current, fossil-dominated energy system, additional conversion processes supporting decarbonization, like electrolysis, could offset water savings.

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