Load-bearing capability of TG800 carbon fiber/polyimide resin composite cylindrical casing with flange and window under high-temperature aerodynamic load
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摘要: 基于航空发动机的高温气动载荷环境,对树脂传递模塑(RTM)工艺制备的TG800碳纤维/聚酰亚胺树脂复合材料带安装翻边和壳壁开口的圆柱壳机匣件开展了常温、200℃和260℃高温气动载荷下的仿真分析和承载性能试验。仿真计算得到复合材料机匣件的高应力水平发生在安装翻边和开口处。试验利用所设计的专用试验装置与机匣试验件合围成一套能够解耦内压和轴力的被试腔体结构,通过对被试腔体施加高温气体压力和机械静载联合模拟热气流载荷,相比传统的冲压胶囊加压方式,可以对机匣的翻边和开口处进行充分热压考核。常温、200℃和260℃承载试验后对机匣开口进行了无损检测,得到开口处的分层损伤区域随着载荷增大朝着正方和正圆的趋势扩大,260℃破坏试验得到TG800碳纤维/聚酰亚胺树脂复合材料机匣件的失效模式与传统金属机匣的筒体破裂不同,失效方式为安装翻边断裂。研究表明,RTM工艺TG800碳纤维/聚酰亚胺树脂复合材料结构件的力学性能在200℃以内具备良好的温度稳定性,安装翻边为复合材料机匣件在航空发动机热气流载荷下的薄弱区域,应作为机匣件减重设计的重要优化部位。Abstract: Based on the high-temperature aerodynamic load environment of aero-engines, the high temperature resistant TG800 carbon fiber/polyimide resin composite cylindrical casing test piece, which with flanges for installation and window openings on the casing wall, prepared by the resin transfer molding (RTM) process was carried out simulation analysis and load-bearing performance test under room temperature, 200℃ and 260℃ high-temperature aerodynamic load. The simulation results show that the high stress level of the composite casing occurs at the installation flange and the window of the shell wall. In the load-bearing test, the designed special test device and the composite casing test piece are combined to form a test chamber structure that can decouple the internal pressure and the axial force during loading. By applying high-temperature gas pressure and mechanical static load to the designed special test cavity to simulate the high-temperature aerodynamic load of the aero-engine, compared with the traditional pressurization method of stamping capsule, it can achieve more realistic assessment of the casing flange and window. The non-destructive testing on the window of the casing after the load-bearing test at room temperature, 200℃ and 260℃ shows that the delamination damage area at the window expands towards a larger square and circular shape as the load increases. The failure mode of the TG800 carbon fiber/polyimide resin composite casing obtained by the 260℃ destruction test is installation flanging fracture, which is different from the failure mode of the traditional metal casing cylinder rupture. The results indicate that the mechanical properties of TG800 carbon fiber/polyimide resin composite structural components prepared by RTM process have good temperature stability within 200℃. The installation flanging is the weak area of the composite casing under the high temperature aerodynamic load of the aero engine, which is an important optimization part for the weight reduction design of the casing.
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表 1 TG800碳纤维/聚酰亚胺树脂复合材料单层板性能参数
Table 1. Performance parameters of TG800 carbon fiber/polyimide resin composite single-layer board
Sample Ambient 260℃ Density/(g·cm−3) 1.50 1.50 Poisson’s ratio ν12 0.317 0.317 0° Tension strength/MPa 2213 1821 0° Tension modulus/GPa 155 155 0° Compression strength/MPa 1431 665 0° Compression modulus/GPa 144 — 90° Tension strength/MPa 39 22.5 90° Tension modulus/GPa 7.6 4 90° Compression strength/MPa 220 96.4 90° Compression modulus/GPa 8.73 — 0° Bending strength/MPa 1881 1027 0° Bending modulus/GPa 147 149 Interlayer shear strength/MPa 106 51.3 In-plan shear strength/MPa 71 34 In-plan shear modulus/GPa 4.1 2.6 表 2 TG800碳纤维/聚酰亚胺树脂复合材料机匣试验件载荷条件
Table 2. Load condition of TG800 carbon fiber/polyimide resin composite casing test piece
Sample Temperature T/℃ Internal pressure P/MPa Mechanical load Axial load Fz/N Torque load Mz/(N·m) Load-bearing condition Ambient 0.39 112978 −2975 200 0.39 112978 −2975 260 0.67 174100 −5475 Damage condition 260 0.67~ 174100~ −5475~ Notes: The load-bearing condition is that aero-engine may occur during the flight; Damage condition is the damage test load of the aero-engine. -
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