用于能源生产的油气复合管道设计

Tamer Ali Sebaey
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引用次数: 26

摘要

纤维增强复合材料管道具有优异的强度和刚度特性,具有很高的耐腐蚀和抗侵蚀性。此外,通过优化缠绕角度来定制强度和刚度特性的可能性,使设计师能够根据不同的工作条件设计不同的管道。这些特性使其在多种应用中具有吸引力,包括用于能源生产应用的轻质高效设备。在目前的工作中,设计了四种不同缠绕角度的玻璃纤维增强塑料(GFRP)管道。对管道进行了内压和低速冲击试验。四种不同的缠绕设计分别为[±45/±45/±45]、[±55/±55/±55]、[±63/±63/±63]和[±63/±45/±55]。每根管道内径110mm,壁厚3.8 mm,长度450mm。管道暴露在内压力下,以确定其容量和低速冲击,以评估其抗冲击性。在内压下,记录了[±55]3个缠绕角的管道的最大容量为56巴。所有试样都以相同的方式破坏,初始泄漏由基体开裂控制,导致内压下降。在抗冲击性方面,组合取向([±63/±45/±55])比其他管道获得更高的评价。这种较高的抗损伤性可以通过相邻层的失配角效应来证明。
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Design of Oil and Gas Composite Pipes for Energy Production

Fiber reinforced composites pipes provide excellent strength and stiffness characteristics and high corrosion and erosion resistance. In addition, the possibility to tailor the strength and stiffness characteristics by optimizing the winding angle gives the designer extra flexibility to design different pipe based on the different working conditions. These properties make them attractive for several applications including lightweight and efficient equipment for energy production applications.

In the current work, glass fiber reinforced plastic (GFRP) pipes were designed with four different winding angles. The pipes were tested under internal pressure and low velocity impact. Four different designs were manufactured using filament winding with winding angles of [±45/±45/±45], [±55/±55/±55], [±63/±63/±63], and [±63/±45/±55]. Each pipe has internal diameter of 110 mm, wall-thickness of 3.8 mm, and length of 450 mm. The pipes were exposed to internal pressure to determine their capacities and low velocity impact to assess their impact resistance. Under internal pressure, the maximum capacity was 56 bars and recorded for the pipes with [±55]3 winding angles. All specimens failed in the same way of initial leakage, governed by matrix cracking, which causes a drop in the internal pressure. For the impact resistance, the combined orientations ([±63/±45/±55]) showed higher assessment, compared to the other pipes. This higher damage resistance can be justified by the mismatch angle effect of the adjacent plies.

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