Sammendrag
In order to deploy capture and storage (CCS) systems to mitigate climate change, it is crucial to develop reliable models for design and operational considerations. A key element of the system is the interface between transportation and storage, namely the injection well, where various transient scenarios involving multiphase flow will occur.
In the literature there are very few data relevant for validation of vertical multiphase flow models for . Hence in this work, we present measurements of liquid holdup, pressure drop and flow regime for upward and downward flow of in a pipe of inner diameter 44mm at a pressure of 6.5MPa, a condition relevant for -injection wells.
The experimental results indicate that the flow is close to no-slip. We have compared the experimental data to predictions by well-known models for phase slip and frictional pressure drop, and the results show that overall, the best model is the simplest one – the fully homogeneous approach, in which no slip is assumed and the friction is calculated simply by employing gas-liquid mixture properties in the single-phase friction model.
Keywords
carbon dioxideinjectionvertical flowfrictionliquid holdupfluid dynamicsthermodynamics
In the literature there are very few data relevant for validation of vertical multiphase flow models for . Hence in this work, we present measurements of liquid holdup, pressure drop and flow regime for upward and downward flow of in a pipe of inner diameter 44mm at a pressure of 6.5MPa, a condition relevant for -injection wells.
The experimental results indicate that the flow is close to no-slip. We have compared the experimental data to predictions by well-known models for phase slip and frictional pressure drop, and the results show that overall, the best model is the simplest one – the fully homogeneous approach, in which no slip is assumed and the friction is calculated simply by employing gas-liquid mixture properties in the single-phase friction model.
Keywords
carbon dioxideinjectionvertical flowfrictionliquid holdupfluid dynamicsthermodynamics