Solids flow mapping in a gas–solid riser: Mean holdup and velocity fields

“…This is to be expected as the turbulence in riser flows is proved to be anisotropic [3]. The anisotropy could be attributed to the length to diameter ratio of the riser that is much larger than unity, implying that the axial a) b) measurements in riser flows [3][4]8]. This observation implies that the instantaneous radial and azimuthal particle velocities exhibit a rather broad distribution of slightly positive and slightly negative values, which result in very low mean values upon averaging.…”

“…Larger velocity fluctuations in one direction correspond to an anisotropic flow. This is to be expected as the turbulence in riser flows is proved to be anisotropic [3]. The anisotropy could be attributed to the length to diameter ratio of the riser that is much larger than unity, implying that the axial a) b) measurements in riser flows [3][4]8].…”

“…This observation is in agreement with Van den Moortel et al [8], who also studied a dilute riser flow. However, Bhusarapu et al [3] observe the opposite behavior, when comparing the Dilute Phase Transport and the Fast Fluidization regimes. In the latter work, it is noted that under dilute flow conditions, two competing mechanisms affect the observed fluctuations.…”

“…The development of theoretical models and empirical equations to simulate the riser flow suffer from this lack of relevant experimental data, e.g. in view of model validation and refinement [3][4]. Furthermore, the majority of the available experimental data for two-phase riser flow provides at its best two simultaneously measured solids velocity components.…”

“…Furthermore, the majority of the available experimental data for two-phase riser flow provides at its best two simultaneously measured solids velocity components. Two-dimensional experimental data are insufficient to validate and refine existing or develop new accurate computational flow models for an in nature 3-D flow [3]. Therefore, precise experimental data providing coincident measurements of the three components of the solids velocity vectors are needed to gain insight into the 3-D flow characteristics along the entire riser height.…”

Three-component solids velocity measurements in the middle section of a riser

“…This is to be expected as the turbulence in riser flows is proved to be anisotropic [3]. The anisotropy could be attributed to the length to diameter ratio of the riser that is much larger than unity, implying that the axial a) b) measurements in riser flows [3][4]8]. This observation implies that the instantaneous radial and azimuthal particle velocities exhibit a rather broad distribution of slightly positive and slightly negative values, which result in very low mean values upon averaging.…”

“…Larger velocity fluctuations in one direction correspond to an anisotropic flow. This is to be expected as the turbulence in riser flows is proved to be anisotropic [3]. The anisotropy could be attributed to the length to diameter ratio of the riser that is much larger than unity, implying that the axial a) b) measurements in riser flows [3][4]8].…”

“…This observation is in agreement with Van den Moortel et al [8], who also studied a dilute riser flow. However, Bhusarapu et al [3] observe the opposite behavior, when comparing the Dilute Phase Transport and the Fast Fluidization regimes. In the latter work, it is noted that under dilute flow conditions, two competing mechanisms affect the observed fluctuations.…”

“…The development of theoretical models and empirical equations to simulate the riser flow suffer from this lack of relevant experimental data, e.g. in view of model validation and refinement [3][4]. Furthermore, the majority of the available experimental data for two-phase riser flow provides at its best two simultaneously measured solids velocity components.…”

“…Furthermore, the majority of the available experimental data for two-phase riser flow provides at its best two simultaneously measured solids velocity components. Two-dimensional experimental data are insufficient to validate and refine existing or develop new accurate computational flow models for an in nature 3-D flow [3]. Therefore, precise experimental data providing coincident measurements of the three components of the solids velocity vectors are needed to gain insight into the 3-D flow characteristics along the entire riser height.…”

Three-component solids velocity measurements in the middle section of a riser

Enabling Process Innovations via Mastering Multiphase Flows: Gas–Solid Processes

Study of the ability of multiphase continuum models to predict core‐annulus flow