Prasanna Welahettige
Department of Process, Energy and Environmental Technology, University College of Southeast Norway, Porsgrunn, Norway
Bernt Lie
Department of Process, Energy and Environmental Technology, University College of Southeast Norway, Porsgrunn, Norway
Knut Vaagsaether
Department of Process, Energy and Environmental Technology, University College of Southeast Norway, Porsgrunn, Norway
Download articlehttp://dx.doi.org/10.3384/ecp1713829Published in: Proceedings of the 58th Conference on Simulation and Modelling (SIMS 58) Reykjavik, Iceland, September 25th – 27th, 2017
Linköping Electronic Conference Proceedings 138:3, p. 29-34
Published: 2017-09-27
ISBN: 978-91-7685-417-4
ISSN: 1650-3686 (print), 1650-3740 (online)
Open Venturi channel flow measurement could be a
cheap method to be used in drill bit pressure control. The
main objective of this study is to identify the factors
related with the flow depth in an open Venturi channel.
A commercial computational fluid dynamics tool was
used for the simulations. The simulation results were
validated with the previous related experimental results.
The agreement between simulation and experimental
data was satisfactory. The open Venturi channel at a
horizontal angle gave a higher flow depth before the
contraction region compared to its negative angles
(downward). When the channel inclination angle was
reduced, flow velocity increased and flow depth
reduced. Likewise, flow became supercritical and
created a hydraulic jump. The wall roughness played a
significant role with the starting position of the
hydraulic jump. This was due to the energy loss between
wall and fluid. There is an energy loss in a hydraulic
jump, when the supercritical flow transition into the
subcritical flow. Large eddies were generated in a
hydraulic jump. Flow depths difference between
supercritical and subcritical is a factor to generate the
large eddies. Fine meshes gave sharp interfaces, which
was similar to what is seen in reality. The difference
turbulence models: standard k-e model, k-? model, k-e
RNG model and k-e realizable model gave almost the
same flow depths.
Open Venturi channel flow measurement could be a
cheap method to be used in drill bit pressure control. The
main objective of this study is to identify the factors
related with the flow depth in an open Venturi channel.
A commercial computational fluid dynamics tool was
used for the simulations. The simulation results were
validated with the previous related experimental results.
The agreement between simulation and experimental
data was satisfactory. The open Venturi channel at a
horizontal angle gave a higher flow depth before the
contraction region compared to its negative angles
(downward). When the channel inclination angle was
reduced, flow velocity increased and flow depth
reduced. Likewise, flow became supercritical and
created a hydraulic jump. The wall roughness played a
significant role with the starting position of the
hydraulic jump. This was due to the energy loss between
wall and fluid. There is an energy loss in a hydraulic
jump, when the supercritical flow transition into the
subcritical flow. Large eddies were generated in a
hydraulic jump. Flow depths difference between
supercritical and subcritical is a factor to generate the
large eddies. Fine meshes gave sharp interfaces, which
was similar to what is seen in reality. The difference
turbulence models: standard k-e model, k-? model, k-e
RNG model and k-e realizable model gave almost the
same flow depths.