高速集装箱运输用深井车铰接式列车

F. Haferkorn
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引用次数: 0

摘要

一项关于客运列车和货运列车长度、质量和速度的文献检索揭示了它们之间的密切联系;特别高的速度似乎只允许质量分布在相应长的列车上。单位长度质量(t/m)与速度(m/s)的乘积出现在维度(t/s)中,表示轨道和桥梁基础设施的一种应力或足迹。列车内相同距离的连续车辆周围的气流引起的共振可以通过表面设计来避免。轮轨振动引起的共振可以通过不对称的底盘来抑制,比如Talgo和AGV的底盘。高板墙防止集装箱因振动而从列车上脱落。对于轨道的几何形状(例如轨道拱太窄,过渡拱太短)来说,由于速度太高而导致的脱轨至少可以通过特别大的轴距、转向架和横向缓冲器之间的半永久性联轴器来部分防止。这样,车架将由一个可分离的雅各布斯转向架连接起来,该转向架将沿列车传递滚动扭矩,并防止单个车轴向上爬。不幸的是,尽管有所有的安全系统,火车之间仍然会发生碰撞。拟议中的集装箱列车就其质量而言非常长,每节车厢只有一个40英尺的高立方体集装箱,而且轴距很大。这个长度可以在发生碰撞时起到内置制动保险杠的作用。在发生碰撞的情况下,集装箱货物可以通过必要时缩短列车来保护。新的高速集装箱列车的发展将得到我们自己的模拟和测量数据以及以前文献的支持。
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ARTICULATED TRAIN OF DEEP WELL CARS FOR HIGH-SPEED CONTAINER TRANSPORT
A literature search on the length, mass and speed of passenger and freight trains revealed a close connection; particularly high speeds seem to be allowed only trains whose mass is distributed over a correspondingly large length. The product of mass per length (t/m) and speed (m/s) appears in the dimension (t/s) to represent a kind of stress or footprint for the infrastructure of the tracks and bridges. Resonances caused by air flow around the successive vehicles within the train at the same distance can be avoided by the surface design. Resonances caused by wheel–rail vibrations can be damped by unsymmetric chassis such as those under the Talgo and AGV. High board walls prevent containers from detaching from the train due to vibrations. Derailments due to speed that is too high for the track geometry (e.g. track arches that are too narrow, transition arches that are too short) can at least be partially prevented by particularly large wheelbases, semi-permanent couplings between bogies and lateral buffers. In this way, the vehicle frames would be connected by a separable Jacobs bogie, which would transmit rolling torques along the train and prevent individual axles from climbing up. Unfortunately, despite all the safety systems, there are still collisions between trains. The proposed container train is very long for its mass, with only one high-cube container 40 ft per wagon and with a large wheelbase. This length can act like a built-in brake bumper in the event of a collision. In the event of a collision, the container load is protected by shortening the train as necessary. The development of the new high-speed container train is to be supported with data from our own simulations and measurements as well as from previous literature.
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