The  piston  in a four-stroke engine plays a pivotal role in compressing air, facilitating fuel combustion, and propelling exhaust out of the combustion chamber. In essence, it is responsible for  moving air  either up or down.

Now, envision a train racing into a tunnel at over  300 km/h . As it transitions into the tunnel, it compresses the air within, pushing it toward the tunnel’s far end. This action is comparable to that of a piston. The  train  moves linearly, while the tunnel acts like a combustion chamber.

At first glance, this might not seem problematic. The air appears to flow seamlessly towards the exit, posing little concern, especially if the high-speed rail lines stretch across a  100-kilometer  bridge.

However, if you’re located in a  mountainous country  that relies heavily on trains to transport millions swiftly across long distances, the situation becomes critical. The  piston effect  is a fundamental aspect of physics, and addressing it to increase speed is a complex challenge.

A Historical Overview of High-Speed Trains

In 1964, while Spain was gradually opening its borders,  Abebe Bikila  achieved his second Olympic Marathon win in Tokyo, dramatically sporting Puma Osaka shoes — quite a leap from his barefoot victory in Rome. Was he among those who first boarded the  Shinkansen ? That same year marked its debut, revolutionizing rail with trains reaching speeds of  210 km/h , establishing the world’s first high-speed rail line.

Fast forward over six decades, and Japan has lost its title as the leader in high-speed rail. China now dominates, driven by its expansive territory. Spain has also surpassed Japan in high-speed rail mileage. This disparity largely comes from China’s aggressive investment in advancements, including the cutting-edge  maglev trains  that can reach a breathtaking  896 km/h .

Millions of Chinese have boarded trains to celebrate the Mid-Autumn Festival, breaking railway records

China’s financial resources empower them to construct the  longest bridges  globally, effectively tackling geographical barriers. Conversely, Japan confronts mountainous terrains, relying on  tunnels , which complicates the pursuit of high-speed travel.

Upon entering a tunnel, the  piston effect  kicks in, preventing further speed increases. This phenomenon manifests in loud explosions, equipment failures, and discomfort for passengers. As trains thunder into tunnels, air compression occurs, creating pressure changes that can be devastating to the human ear. When exiting, shock waves and sound explosions, known as  tunnel booms , can be heard from over  400 meters  away.

Japan surveyed its citizens about the most common complaints regarding tourists on trains

Japan is now wrestling with a legacy problem. While their trains are wider than European ones, their tunnels are narrower, a decision made to reduce infrastructure costs and minimize landslide risks. Initially, this setup didn’t pose issues, but with increasing train speeds, the limitations became glaringly evident.

In contrast, China has opted for wider tunnels, significantly reducing the  void effect  when trains enter, resulting in a smoother experience for passengers. This design also improves efficiency by lowering resistance and conserving energy.

For Japan, the solution is far from straightforward. Approximately  13%  of the Tokaido Shinkansen runs through tunnels, while the Sanyo Shinkansen and the under-construction Hokkaido Shinkansen spend even more time underground.

One effective strategy has been designing trains with elongated, aerodynamic noses, mimicking the beak of a kingfisher, which plunges into water with minimal splash. By enhancing aerodynamics, the pressure wave generated during tunnel entry is mitigated.

Additionally, Japan is exploring options to widen tunnel entrances and implement side openings for air escape. This release alleviates pressure waves and enhances passenger comfort while facilitating higher speeds. Some plans even include developing  hermetic trains  with controlled interior pressure.

As testing continues, Japan aims for trains capable of reaching speeds of  400 km/h . However, their inherited infrastructure poses significant hurdles in competing with China.

Photo Credit: Rikku Sama

In a competitive world of high-speed rail,  innovation  and  adaptability  will determine which country leads the charge in the years to come. Japan is keenly aware of the challenges but continues to strive for advancement to remain relevant in the high-speed rail landscape.



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