The feasibility of high-temperature aquifer thermal energy storage in Denmark: the Gassum Formation in the Stenlille structure

IF 1.2 4区地球科学 Q2 Earth and Planetary Sciences

Bulletin of the Geological Society of Denmark Pub Date : 2020-06-12 DOI:10.37570/bgsd-2020-68-06

Lisa Pasquinelli, M. Felder, M. Gulbrandsen, T. Hansen, Jun-Seo Jeon, N. Molenaar, K. Mosegaard, I. Fabricius

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引用次数: 7

Abstract

Heat storage in the Danish subsurface is gaining increasing interest for optimizing the use of energy resources, but no deep heat storage facilities have yet been established. As an analogue we study the Gassum Formation in the Stenlille structure that is presently used for gas storage. This allows us to discuss geological and technical characteristics of an aquifer relevant for heat storage in Denmark. We develop a 3D model for a high-temperature aquifer thermal energy storage system using analysis of geological core data, sedimentological description, geophysical data including well logs and seismic lines, as well as a finite difference model to calculate the recovery efficiency, heat storage capacity and thermal breakthrough time. Based on geostatistical methods we made three realisations and found similar results for the three cases. In accordance with results from published simplified models we found a high recovery efficiency of 70% after 4 years and 69% after 20 years, a high heat storage capacity of 1.8×1018 J, and a long thermal breakthrough time of 66–77 years. These results reflect the excellent reservoir properties of the Gassum Formation in Stenlille, characterised by a uniformly layered sand/shale sedimentology, a high average porosity of 25% and a high permeability of 1000 to 10 000 mD of sandstone intervals.

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丹麦高温含水层储热的可行性:以Stenlille构造中的Gassum组为例

丹麦地下储热在优化能源利用方面正获得越来越多的兴趣，但尚未建立深层储热设施。作为类比，我们研究了目前用于储气的stenlille构造中的气组。这使我们能够讨论与丹麦储热有关的含水层的地质和技术特征。通过对地质岩心数据、沉积学描述、测井和地震线等地球物理数据的分析，建立了高温含水层储热系统的三维模型，并利用有限差分模型计算了采收率、储热容量和热突破时间。基于地统计学方法，我们对三种情况进行了三种认识，并发现了相似的结果。根据已发表的简化模型计算结果，4年和20年采收率分别达到70%和69%，储热容量达到1.8×1018 J，热突破时间长达66 ~ 77年。这些结果反映了Stenlille天然气组优异的储层性质，其特征是均匀层状砂/页岩沉积，平均孔隙度高达25%，砂岩层段的渗透率为1000至10000 mD。

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

Bulletin of the Geological Society of Denmark GEOSCIENCES, MULTIDISCIPLINARY-

CiteScore

2.80

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： The Bulletin publishes contributions of international interest in all fields of geological sciences on results of new work on material from Denmark, the Faroes and Greenland. Contributions based on other material may also be submitted to the Bulletin if the subject is of relevance for the geology of the area of primary interest.