600 km/h磁浮列车隧道交会车体压力载荷特征研究

Characteristics of car body pressure load of 600 km/h maglev trains crossing in tunnel

  • 摘要: 随着列车速度的提升,空气动力学效应对车体压力载荷影响愈加严重,且列车隧道交会比单列车通过隧道时的空气动力学效应更加剧烈。为研究磁浮列车隧道交会时的车体压力载荷,采用一维可压缩非定常不等熵流动模型,在论证了研究方法正确性的基础上,分析了车体最大正负压值特征和车体压力最值(最大正负压值和最大压力峰峰值)分布特性,研究了隧道长度、列车速度和阻塞比对车体压力载荷的影响特性。研究结果表明:列车在通过隧道的过程中,车体所承受的最大负压值远大于最大正压值;只有当隧道长度超过一定值时,车体的最大正负压值出现在头尾车;头尾车的压力最值在隧道长度超过2 km以后保持定值,且不同速度下头尾车的最大正压值的定值基本重合,接近于“零”;隧道长度在一定范围内时,车体压力载荷与速度的二次方成正比;车体压力最值随阻塞比增大而增大。研究成果可为车体气动疲劳强度设计提供基础数据。

     

    Abstract: With the rapid increase of the train speed, aerodynamic effect has a more serious impact on the pressure load of the car body, and the trains crossing in the tunnel is more violent than that of a single train passing through the tunnel. In order to research the aerodynamic load of maglev train crossing in the tunnel, the one-dimensional unsteady compressible non-homentropic flow model method was adopted. The distribution characteristics of the maximum positive pressure, negative pressure and maximum pressure (maximum positive and negative pressure and maximum peak pressure) of the car body were analyzed and the influence characteristics of the tunnel length, speed and blocking ratio on the external pressure were researched. The results show that the maximum negative pressure value of the car body is much greater than the maximum positive pressure value during the train crossing in the tunnel; only when the tunnel length exceeds a certain value, would the maximum positive and negative pressure value of the car body appear in the head and tail train, respectively; the maximum pressure values of the head and tail cars remain constant after the tunnel length exceeds 2 km, and the maximum positive pressure values of the head and tail cars at different speeds basically coincide, which are close to “zero”; when the tunnel length is within a certain range, the maximum pressure is proportional to the square of the speed; and the maximum pressure increases linearly with the increase of the blocking ratio. The findings of this research can provide support for the car body aerodynamic fatigue strength design.

     

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