VII. Match the Problem of Tunnel Construction to its Solution
1. An explosion of methane gas shook the tunnel.
2. Underground steam poured 70.000 gallons an hour into the tunnel.
3. They met faulted and broken shale and water at high pressure.
4. The flow of water increased to 300.000 gallons an hour, driving the crews out.
5. The water began to get hot and the temperature of the tunnel rose.
6. There was a possibility of water and sand breaking through the face of the tunnel.
a) They built heavy concrete bulkheads across the tunnel and pumped cement into the ground ahead.
b) The engineers decided to drive small tunnels, called drifts, on each side of the main tunnel to relieve water pressure.
c) They installed the enormous pumps and boosters with special coolers for the compressed air machines.
d) They used big tunnel pumps.
e) They went back and built a heavy concrete bulkhead to seal the tunnel.
f) They breached the bulkhead and dug on carefully, inch by inch, through the danger zone.
VIII. Compare the two projects and write the sentences using the words: while, whereas, however, as compared to, as opposed to, etc.
1. Central Artery/Tunnel Project (Big Dig)
Vital Statistics:
Location: Boston, Massachusetts, USA
Completion Date: 2004
Cost: more than $10 billion
Length: 18,840 feet (3.5 miles)
Purpose: Roadway
Setting: Soft ground
Materials: Steel, concrete
Engineer(s): Bechtel, Parsons Brinckerhoff, Quaide Douglas
Some call the Central Artery/Tunnel Project in Boston, Massachusetts, the "largest, most complex and technologically challenging highway project in American history." Others consider it one of the most expensive engineering projects of all time. Locals simply call it the "Big Dig". By the time it was finished in 2004, the tunnel was eight lanes wide, 3.5 miles long, and completely buried beneath a major highway and dozens of glass-and-steel skyscrapers in Boston's bustling financial district. What does it take to dig a tunnel like this? A lot of hard work and a handful of tricks.
Today, engineers use special excavating equipment, called "clamshell excavators," that work well in confined spaces like downtown Boston. These special machines carve narrow trenches - about three feet wide and up to 120 feet deep—down to bedrock. In Boston, engineers are pumping liquid slurry (clay mixed with water) into trenches to keep the surrounding dirt from caving in. Huge reinforcing steel beams are lowered into the soupy trenches, and concrete is pumped into the mix. Concrete is heavier than slurry, so it displaces the clay-water mix. The side-by-side concrete-and-steel panels form the walls of the tunnel, which will allow workers to remove more than three miles of dirt beneath the city.
As if tunneling beneath a city isn't hard enough, the soil beneath Boston is actually landfill- it's very loose and soggy. Engineers had to devise a few tricks to keep the soggy soil from collapsing. Their solution: freezing the soil! Engineers pump very saltwater through a web of pipes beneath the city streets. The cold pipes draw heat out of the soil little by little. Once frozen, the soil can be excavated without sinking. Engineers also inject glue, or grout, into popes in the ground to make the soil stronger and less spongy during tunnel construction.
2.Underground Canal
Vital Statistics:
Location: Lancashire County and Manchester, England
Completion Date: 1776
Length: 274,560 feet (52 miles)
Purpose: Canal
Setting: Rock
Materials: Brick
Engineer(s): John Gilbert, James Brindley
Beneath the old country of Lancashire, England, lie miles and miles of underground canal -52 to be exact. Considered an engineering masterpiece of the 18th century, the "Navigable Level," as it was known in its day, serves as a monument to the area's industrial past.
Francis Egerton, the third Duke of Bridgewater., wanted canal to transport coal from his mines at Worsley to Manchester, a distance of 10 miles. He commissioned John Gilbert and James Brindley to build the Bridgewater Canal, a gravity-flow canal crossing the Irwell valley on an elevated structure supported by arches. Completed in 1761, the highly successful canal extended deep into the coal field and became a much efficient way to transport coal from the country to the city. The Bridgewater Canal cut the cost of coal in Manchester in half.
Work started in 1759 as small teams of skilled miners cut into, rock by hand, using only picks, hammers, shovels, and drills. Later on, they used gunpowder to blast through the hard ground. The canal was carved at a downward sloping angle, a design that allowed gravity to pull mining boats through the majority of the long, underground chambers. In 1776, the canal was extended an additional 30 miles, from Manchester to Liverpool. Years later, numerous side-branching canals were added, creating the longest underground canal system in the world.
Unit 11
Roads and Airfields
I. Memorize the following words and expressions:
excavation - земляные работы
anchor - крепление
fill -насыпь
drill - бурить
wind- изгибаться
scrape - скрести
paving - устройство защитного покрытия
silt - глинистый заполнитель
sheepsfoot roller - кулачковый каток
compaction- искусственное уплотнение грунта
subgrade - подошва, основание
subbase - основание сооружения