Energy system design for deep decarbonization of a sunbelt city by using a hybrid storage approach

O. Walter, M. Huber, M. Kueppers, A. Tremel, Stefan Becker
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引用次数: 2

Abstract

With continuously falling cost of renewable power generation and ambitious decarbonization targets, renewable sources are about to rival fossil fuels for energy supply. For a high share of fluctuating renewable generation, large-scale energy storage is likely to be required. In addition to selling electricity, the reliable supply of heat and cold is a further interesting revenue pool, which makes hybrid storage technologies an interesting option. The main feature of hybrid energy storage – as defined here is to offer charging and especially discharging in different forms of energy by combining different charging, discharging and storage devices. They can address various demands (e.g. electricity and cold) simultaneously. Two hybrid storages, pumped thermal energy storage (PTES) and power-to-heat-to-x (x: heat and/or electricity) energy storage (PHXES), are investigated based on a technoeconomic analysis within this work. Both hybrid storage technologies are charged with electricity and can supply heat and electricity during discharging. They are implemented into a simplified energy system model of a prototype city in the earth’s sunbelt in the year 2030 to find a cost-optimal configuration. Different cases are evaluated: a power-to-power case (P2P), where only an electric demand must be addressed and a power-topower-and-cooling (P2P&C) case, where the electric demand from the P2P case is divided into a residual electric demand and a cooling demand. For both cases, a natural gas-based benchmark scenario and a decarbonized, renewable-based scenario including the hybrid energy storage technologies are calculated. Both, total expenditures and CO2 emissions are lower in the P2P&C scenarios compared to P2P scenarios. PHXES plays a major role in both cases. PTES is part of the costoptimal solution in the P2P&C decarb scenario, only if its specific cost are further decreased. Keywords—Hybrid energy storage, Energy system modeling, Decarbonization
利用混合储能方法实现阳光带城市深度脱碳的能源系统设计
随着可再生能源发电成本的不断下降和雄心勃勃的脱碳目标,可再生能源即将与化石燃料竞争能源供应。对于波动的可再生能源发电的高份额,可能需要大规模的能源储存。除了出售电力,可靠的冷热供应是另一个有趣的收入来源,这使得混合存储技术成为一个有趣的选择。混合储能的主要特点是通过组合不同的充电、放电和存储设备,提供不同形式的能量的充电,特别是放电。它们可以同时满足各种需求(如电和冷)。本研究基于技术经济分析,研究了两种混合储能技术,即泵送热能储能(PTES)和电-热-x (x:热/电)储能(PHXES)。这两种混合存储技术都是带电的,并且可以在放电时提供热量和电力。将它们应用到2030年地球阳光带的一个原型城市的简化能源系统模型中,以找到成本最优的配置。评估了不同的情况:电力对电力的情况(P2P),其中只需要解决电力需求,以及电力-电力-冷却(P2P&C)情况,其中P2P情况下的电力需求分为剩余电力需求和冷却需求。对于这两种情况,分别计算了基于天然气的基准情景和基于脱碳、可再生能源的情景,包括混合储能技术。与P2P模式相比,P2P模式下的总支出和二氧化碳排放量都较低。PHXES在这两种情况下都起着重要作用。在P2P&C脱碳方案中,PTES是成本最优解决方案的一部分,前提是其具体成本进一步降低。关键词:混合储能;能源系统建模;脱碳
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