Fluid structure interaction in straight pipelines with different anchoring conditions

This investigation aims at assessing the fluid-structure interaction (FSI) occurring during hydraulic transients in straight pipeline systems fixed to anchor blocks. A two mode 4-equation model is implemented incorporating the main interacting mechanisms: Poisson, friction and junction coupling. The resistance to movement due to inertia and dry friction of the anchor blocks is treated as junction coupling. Unsteady skin friction is taken into account in friction coupling. Experimental waterhammer tests collected from a straight copperpipe-rig are used for model validation in terms of waveshape, timing and damping. Numerical results successfully reproduce laboratory measurements for realistic values of calibration parameters. The novelty of this paper is the presentation of a 1D FSI solver capable of describing the resistance to movement of anchor blocks and its effect on the transient pressure wave propagation in straight pipelines.

Fluid structure interaction in straight pipelines with different anchoring conditions

Graph Chatbot

NMR and MS reveal characteristic metabolome atlas and optimize esophageal squamous cell carcinoma early detection

Full-F turbulent simulation in a linear plasma device using a gyro-moment approach

Quantitative convergence rates for scaling limit of SPDEs with transport noise

NMR and MS reveal characteristic metabolome atlas and optimize esophageal squamous cell carcinoma early detection

Full-F turbulent simulation in a linear plasma device using a gyro-moment approach

Quantitative convergence rates for scaling limit of SPDEs with transport noise