Compressed air energy storage in depleted natural gas reservoirs: effects of porous media and gas mixing

Abstract:

Although large opportunities exist for compressed air energy storage (CAES) in aquifers and depleted natural gas reservoirs, only two grid-scale CAES facilities exist worldwide, both in salt caverns. As such, experience with CAES in porous media, what we call PM-CAES, is lacking and we have relied on modeling to elucidate PM-CAES processes. PM-CAES operates similarly to cavern CAES. Specifically, working gas (air) is injected through well(s) into the reservoir compressing the cushion gas (existing air in the reservoir). During energy recovery, high-pressure air from the reservoir flows first into a recuperator, then into an expander, and subsequently is mixed with fuel in a combustion turbine to produce electricity, thereby reducing compression costs. Energy storage in porous media is complicated by the solid matrix grains which provide resistance to flow (via permeability in Darcy’s law); in the cap rock, low-permeability matrix provides the seal to the reservoir. The solid grains also provide storage capacity for heat that might arise from compression, viscous flow effects, or chemical reactions. The storage of energy in PM-CAES occurs variably across pressure gradients in the formation, while the solid grains of the matrix can release/store heat. Residual liquid (i.e., formation fluids) affects flow and can cause watering out at the production well(s). PG&E is researching a potential 300 MW (for ten hours) PM-CAES facility in a depleted gas reservoir near Lodi, California. Special considerations exist for depleted natural gas reservoirs because of mixing effects which can lead to undesirable residual methane (CH₄) entrainment and reactions of oxygen and CH₄. One strategy for avoiding extensive mixing of working gas (air) with reservoir CH₄ is to inject an initial cushion gas with reduced oxygen concentration providing a buffer between the working gas (air) and the residual CH₄ gas. This reduces the potential mixing of the working air with the residual CH₄. Compositional simulations of this approach using TOUGH2 with a detailed 3D model of the PG&E test reservoir show the pre-conditioning approach is effective at decreasing CH₄entrainment and oxygen mixing.

Acknowledgment: We thank Joe Chan (PG&E), Jim Fairchild (Fairchild & Assoc.), and Charlie Stinson (CS Energy Ventures) for support and collaboration.