Influence of Permeability Anisotropy and Layered Heterogeneity on Geothermal Energy Battery Storage

TL;DR

This paper investigates how permeability anisotropy and layered heterogeneity in geological formations affect the temperature and pressure profiles in geothermal energy storage reservoirs, crucial for optimizing well placement and efficiency.

Contribution

It extends previous isotropic models by analyzing the impact of anisotropic and layered heterogeneous permeabilities on geothermal reservoir behavior.

Findings

Anisotropic permeability causes asymmetrical temperature profiles.

Layered heterogeneity significantly influences pressure distribution.

Reservoir properties affect well layout and heat recovery efficiency.

Abstract

The Geothermal Battery Energy Storage concept has been proposed to provide large-scale heat storage when solar radiance is available, to be later recovered for economic benefit. The concept uses solar radiance to heat water on the surface which is then injected into a suitable subsurface formation. This hot water elevates the ambient formation temperature creating a high-temperature geothermal reservoir acceptable for geothermal electricity generation or direct heat applications. The process uses produced/injected, connate formation water and thus neither freshwater nor surface storage or disposal of water is required. This concept has been previously presented in several publications and presentations. Calculations of reservoir temperature and pressure profiles in isotropic and homogeneous reservoirs have been published previously by the authors. These calculations have shown that a small volume of rock mass is required for the heat storage reservoir, of the order of tens of meters radius from an injection well in a reservoir of one-hundred meters thickness. It was shown that over ninety percent of heat can be recovered for certain reservoirs. The previous calculations for the Geothermal Battery Energy Storage considered only isotropic and homogeneous reservoir formation properties. However, even in a small rock mass volume, considering sedimentary depositional environments and superimposed tectonics, the rock permeability may be anisotropic and heterogeneous with reservoir layers of different properties. Calculations are presented here considering anisotropic permeabilities, and layered heterogeneous permeabilities i.e., formations with horizontal layers of different permeabilities. Such reservoir properties create non-symmetrical temperature and pressure profiles away from a well, which is critical for well layout and planning for injection and production.