Description
SPRINGER Structural And Thermal Analyses Of Deepwater Pipes (Pb 2021) by AN C.
This book focuses on advanced methods for the structural and thermal analysis of deepwater pipelines and risers. It discusses the limit strength of sandwich pipes, including finite-element analysis using Python scripts, collapse of sandwich pipes with cementitious/polymer composites, buckle propagation of sandwich pipes, dynamic behavior of subsea pipes, flow-induced vibration of functionally graded pipes, two-phase flow-induced vibration of pipelines, vortex-induced vibration of free-spanning pipelines, and the thermal analysis of composites pipes with passive insulation, active heating, and phase change material layers.It also explores structural analysis using finite element analysis and the integral transform technique for fluid-structure interaction. Lastly, the use of lumped parameter formulations combined with finite differences for the thermal analysis of pipelines is examined. 1. Introduction1.1. Subsea Pipelines and Risers1.2. Fluid-Solid Interaction1.3. Flow AssurancePart I Limit Strength of Sandwich Pipes2. Ultimate strength behavior of sandwich pipes filled with steel fiber reinforced concrete2.1. Introduction2.2. Finite element modelling2.3. Numerical evaluation and parametric study2.4. Conclusions3. Collapse of sandwich pipes with PVA fiber reinforced cementitious composites core under external pressure3.1. Introduction3.2. Experiments3.3. Numerical simulation3.4. Parametric studies 3.5. Conclusions4. Buckle Propagation of Sandwich Pipes4.1. Introduction4.2. Numerical Simulation4.3. Parametric studies4.4. Conclusions5. Installation of Sandwich Pipes Part II Dynamic Behavior of Subsea Pipes6. Integral Transform Solutions of Some Problems in Solid and Structural Mechanics6.1. Introduction6.2. Solution methodology6.3. Special topics and applications6.4. Conclusions7. Dynamic behavior of pipes conveying gas-liquid two-phase flow7.1. Introduction7.2. Mathematical formulation7.3. Integral transform solution7.4. Results and discussion7.5. Conclusions8. Pipes conveying vertical slug flow8.1. Introduction8.2. Mathematical formulation8.3. Integral transform solution8.4. Two-phase flow model8.5. Results and discussion8.6. Conclusions9. Pipes conveying horizontal slug flow9.1. introduction9.2. Mathematical formulation9.3. Integral transform solution9.4. Two-phase flow model9.5. Results and discussion9.6. ConclusionsPart III Thermal Analysis of Composite Pipes10. Steady State Thermal Analysis of Deepwater Pipelines10.1. Introduction10.2. Global heat balance analysis10.3. Analysis of heat medium circulation10.4. Analysis of direct electrical heating10.5. Results and discussion10.6. Conclusions11. Steady-State Thermal-Hydraulic Analysis of Heavy Oil Transportation in Heated Sandwich Pipelines11.1. Introduction11.2. Analysis11.3. Results and discussion11.4. Conclusions12. Transient Thermal Analysis of Multilayered Composite Pipeline12.1. Introduction12.2. Global heat balance analysis12.3. Physical problem12.4. Electrical heating12.5. Mathematical modelling12.6. Results and discussion12.7. Conclusions13. Transient Thermal Analysis in Multilayered Composite Pipeline with Active Heating13.1. Introduction13.2. The mathematical formulation13.3. Improved lumped models13.4. Numerical results and discussions13.5. ConclusionsReferencesA. Mathematica Notebook for Vibration of Pipe Conveying FluidB. Mathematica Notebook for Steady-State Thermal Analysis of Composite PipesGlossary