How the worlds longest underwater tunnel was built Alex Gendler

Flanked by two powerful European nations,
the English Channel

has long been one of the world’s
most important maritime passages.

Yet for most of its history,

the channel’s rocky shores
and stormy weather

made crossing a dangerous prospect.

Engineers of the early 1800’s
proposed numerous plans

for spanning the 33 kilometer gap.

Their designs included artificial islands
linked by bridges,

submerged tubes suspended
from floating platforms,

and an underwater passage more than twice
the length of any existing tunnel.

By the end of the century,

this last proposal had captured
European imagination.

The invention
of the tunnel boring machine

and the discovery of a stable layer
of chalk marl below the seabed

made this fantastic tunnel
more feasible.

But the project’s most urgent obstacles
were ones no engineer could solve.

At the time,

Britons viewed their geographic isolation
as a strategic advantage,

and fears about French invasion
shut down plans for the tunnel.

The rise of aerial warfare rendered
these worries obsolete,

but new economic concerns
arose to replace them.

Finally, 100 years after
the initial excavation,

the two countries
reached an agreement—

the tunnel would proceed
with private funding.

In 1985, a group
of French and British companies

invested the modern equivalent
of 14 billion pounds,

making the tunnel the most expensive
infrastructure project to date.

The design called
for three separate tunnels—

one for trains to France,
one for trains to England,

and one service tunnel between them.

Alongside crossover chambers,
emergency passages, and air ducts,

this amounted to over 200 kilometers
of tunnels.

In 1988, workers began excavating
from both sides,

planning to meet in the middle.

Early surveys of the French coast
revealed the site was full of fault lines.

These small cracks
let water seep into the rock,

so engineers had to develop
waterproof boring machines.

The British anticipated drier conditions,
and forged ahead with regular borers.

But only months into the work, water
flooded in through undetected fissures.

To drill in this wet chalk,
the British had to use grout

to seal the cracks
created in the borer’s wake,

and even work ahead of the main borer

to reinforce the chalk
about to be drilled.

With these obstacles behind them,
both teams began drilling at full speed.

Boring machines weighing up to 1,300 tons
drilled at nearly 3.5 meters per hour.

As they dug, they installed lining rings
to stabilize the tunnel behind them,

making way for support wagons
following each machine.

Even at top speed,
work had to proceed carefully.

The chalk layer followed a winding path
between unstable rock and clay,

punctured by over 100 boring holes
made by previous surveyors.

Furthermore, both teams had
to constantly check their coordinates

to ensure they were on track to meet
within 2 centimeters of each other.

To maintain this delicate trajectory,

the borers employed
satellite positioning systems,

as well as paleontologists
who used excavated fossils

to confirm they were at the right depth.

During construction,
the project employed over 13,000 people

and cost the lives of ten workers.

But after two and a half years
of tunneling,

the two sides finally made contact.

British worker Graham Fagg
emerged on the French side,

becoming the first human to cross
the channel by land since the Ice Age.

There was still work to be done—

from installing crossover chambers
and pumping stations,

to laying over a hundred miles of tracks,
cables, and sensors.

But on May 6, 1994, an opening ceremony
marked the tunnel’s completion.

Full public service began
16 months later,

with trains for passengers
and rail shuttles for cars and trucks.

Today, the Channel Tunnel services
over 20 million passengers a year,

transporting riders across the channel
in just 35 minutes.

Unfortunately, not everyone has
the privilege of making this trip legally.

Thousands of refugees have tried
to enter Britain through the tunnel

in sometimes fatal attempts.

These tragedies have transformed
the tunnel’s southern entrance

into an ongoing site of conflict.

Hopefully, the structure’s history
can serve as a reminder

that humanity is at their best
when breaking down barriers.

英吉利海峡两侧是两个强大的欧洲国家,

长期以来一直是世界上
最重要的海上通道之一。

然而,在其历史的大部分时间里

,海峡的岩石海岸
和暴风雨的天气

使穿越成为一个危险的前景。

1800 年代初期的工程师
提出了许多

跨越 33 公里差距的计划。

他们的设计包括
由桥梁连接的人工岛屿、

悬挂
在浮动平台上

的水下管道,以及比
任何现有隧道都长两倍以上的水下通道。

到本世纪末,

这最后一个提议已经吸引了
欧洲的想象力。

隧道掘进机的发明


海床下稳定的白垩泥层的发现

使这条神奇的隧道
更加可行。

但该项目最紧迫的障碍
是工程师无法解决的。

当时,

英国人将其地理上的孤立
视为一种战略优势,

并且对法国入侵的担忧
导致隧道计划停止。

空战的兴起使
这些担忧变得过时,

但新的经济
担忧却取代了它们。

最终,
在最初的挖掘工作 100 年后

,两国
达成了一项协议——

隧道将由
私人资助进行。

1985 年,
一群法国和英国公司

投资了相当于现代
的 140 亿英镑,

使隧道成为迄今为止最昂贵的
基础设施项目。

该设计要求
建立三条独立的隧道——

一条用于通往法国的火车,
一条用于通往英国的火车,

以及一条位于它们之间的服务隧道。

除了交叉室、
紧急通道和风道外

,还有超过 200 公里
的隧道。

1988年,工人们开始
从两边开挖,

计划在中间相遇。

对法国海岸的早期调查
显示,该地点布满断层线。

这些小裂缝
让水渗入岩石,

因此工程师不得不开发
防水钻孔机。

英国人预计会出现更干燥的情况,
并与普通的蛀虫一起前进。

但仅仅几个月的工作,水
就从未被发现的裂缝中涌入。

为了钻进这种湿白垩
,英国人不得不使用灌浆

来密封
钻孔器尾迹中产生的裂缝,

甚至在主钻孔器之前工作

以加固
即将钻孔的白垩。

有了这些障碍,
两队开始全速钻探。

重达 1,300 吨的钻孔机以
每小时近 3.5 米的速度钻孔。

当他们挖掘时,他们安装了衬环
以稳定他们身后的隧道

,为每台机器后面的支撑货车让路

即使以最快的速度,
工作也必须小心翼翼地进行。

白垩层沿着
不稳定的岩石和粘土之间的蜿蜒路径,

被以前的测量员制作的 100 多个钻孔刺穿。

此外,两支球队都
必须不断检查他们的坐标,

以确保他们能够
在 2 厘米范围内相遇。

为了保持这条微妙的轨迹

,钻孔者使用了
卫星定位系统,

以及
使用挖掘出的化石

来确认它们位于正确深度的古生物学家。

在施工期间,
该项目雇用了 13,000 多人,

并造成 10 名工人的生命。

但在

了两年半之后,双方终于取得了联系。

英国工人格雷厄姆法格
出现在法国一侧,

成为
自冰河时代以来第一个通过陆路穿越海峡的人类。

还有很多工作要做——

从安装分流室
和泵站,

到铺设一百多英里的轨道、
电缆和传感器。

但在 1994 年 5 月 6 日,一个开通仪式
标志着隧道的竣工。 16 个月后,

全面的公共服务开始了

为乘客提供火车,
为汽车和卡车提供铁路穿梭巴士。

如今,英吉利海峡隧道
每年为超过 2000 万名乘客提供服务

,只需 35 分钟即可将乘客运送穿过海峡。

不幸的是,并不是每个人
都有权合法地进行这次旅行。

成千上万的难民
试图通过隧道进入英国

,有时甚至是致命的尝试。

这些悲剧
将隧道的南部入口

变成了一个持续不断的冲突地点。

希望该结构的历史
可以提醒人们

在打破障碍时人类处于最佳状态。