A Method for Determining Design Coefficients of Thermoplastic Reinforced Composite Pipelines
A technology of enhanced compounding and method determination, applied in computer-aided design, calculation, electrical digital data processing, etc., can solve the problems that the strength of RTP pipes cannot be fully exerted, the scope of application is limited, and RTP pipes cannot be used.
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Embodiment 1
[0149] Example 1, such as figure 1 As shown, a method for determining the design coefficient of a thermoplastic reinforced composite pipeline described in the embodiment of the present invention, the method includes:
[0150] Step 1, analyze the load l of the thermoplastic reinforced composite pipe, including internal pressure load, bending load, external pressure load, axial tensile load, temperature difference load and combined load, and obtain the distribution state and eigenvalue of each load design variable. At the same time, Analyze the load resistance r of the pipeline according to the material properties of the pipeline, and obtain the distribution state and eigenvalue of each design variable of the load resistance;
[0151] Step 2, establishing the limit state function g, load probability model and resistance probability model under different load conditions, including internal pressure load, bending load, external pressure load, axial tensile load, temperature differ...
Embodiment 2
[0168] Example 2, oil and gas long-distance pipelines can be divided into buried pipelines and open-pit pipelines according to different laying methods. The main load types are divided into five types of loads: internal pressure load, bending load, external pressure load, axial tensile load and temperature difference load; the statistical principle of the probability model of each load is based on the concept of design reference period and extreme load .
[0169] Under the internal pressure load, the resistance r is the burst pressure, and the load l is the internal pressure of the pipeline.
[0170] The resistance probability model satisfies the normal distribution, and the resistance design variables include d, r i 、r o , α, σ bg , σ bp , a, N, combined with the material properties of the pipeline, the geometric parameters of the components and the calculation mode of the resistance, determine the probability distribution of each design variable of the resistance. The p...
Embodiment 3
[0179] Example 3, under bending load, the resistance r is the critical strain ε relative to the local longitudinal bending of the pipeline crit , the load l is the strain ε caused by the bending load th ;
[0180] The limit state function for local buckling due to restricted thermal expansion becomes:
[0181] g=ε crit -ε th (9)
[0182]
[0183] ε th =R 0 / R b (11)
[0184] In the formula,
[0185] t is the wall thickness of the pipe; D m is the average diameter of the pipe; μ zr Poisson's ratio in the pipeline z-r plane; R 0 is the outer diameter of the RTP pipe, R b is the bending radius;
[0186] The bending load resistance probability model satisfies the normal distribution, combined with the material properties of the pipeline, component geometric parameters and resistance calculation mode, the probability distribution of each design variable of the resistance is determined, and the design variables include t, D m ;
[0187] The bending load probabili...
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