18-12-2012, 06:19 PM
CUT AND COVER WORKS AND OPEN APPROACHES
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Introduction
At the northern end of the works there is a reception area for the open face machine,
which forms the start of the cut and cover and open cut works. The reception area
included two 10m long, 12m diameter, adit supported by sprayed concrete lining
techniques with spíle and lattice girders. Moving north from the reception area there
is a 300m cut and cover section constructed between 1.2m wide diaphragm walls
excavated in 26m wide bays and with an average depth of 20m. The next section is
50m long with bored piles at the bridge crossing and finally there is 1,300m of
retained cut using soil nailing with 25 and 32mm bolts 8-11m long with shotcrete.
At the southern end of the Tunnel drive a 10m-reception adit and a 50m return launch
adit were constructed for the TBM. The south section comprises 600m of cut and
cover tunnel cast within diaphragm walls.
The Cut and Cover section presents its own challenges, requiring that all utilities
including telecommunications, water, gas and drainage be removed and
repositioned. Problems in moving utilities have delayed some of the C&C
construction sections by approximately three months. Other works including the
temporary re-routing of traffic and the construction of two temporary steel bridges for
traffic diversions on the existing M1 at Whitehall also had to be undertaken.
The construction technique required the excavation of an open trench over 20m deep
and 26m wide. Two-insitu reinforced concrete horseshoe shaped tunnels were cast
in the excavation in 12m long sections. The Tunnel floor is sloped at 4o resulting in a
variation in the depth of the excavation along its length.
General Process
1. The excavation is carried out using a heavy self guided mechanical grab
suspended from the jib of a large crawler crane.
2. The diaphragm walls were excavated and constructed in discrete panels of
between 2.8m and 7.0m lengths, with a depth reaching 30m.
3. As the excavation proceeds, support fluid was added into the excavation to
maintain the stability of the surrounding ground and to prevent a collapse.
This fluid is called “Bentonite”, which is a poser made of a special type of
soluble clay and is mixed at the mixing plant with potable water.
4. A heavy chisel may be used if an obstruction of hard strata is encountered, to
break up the obstruction for removal by the grab.
5. When the excavation is completed, a submersible pump connected to tremie
pipes will be lowered into the panel excavation down to the toe level. This
pumped the fluid down to the toe level and then from the bottom of the
excavation back to a descending unit, in order to separate the bentonite from
the suspended particles contained in it. At the same time, fresh fluid will be
added to the top of the excavation to maintain the stability of the ground.
Soil Nailing and Shotcreting
In the deeper parts of the excavations diaphragm walls secure the sides. However,
when the excavation depth reduces to 12m or less, open cuttings supported by a
combination of soil nailing and shotcreting replace the diaphragm walls. This
technique is relatively new in Ireland and no empirical data on the ground conditions
was available. As a result extensive trials had to be undertaken. A large trial area
was established and the results monitored over a period of 6 months.
The open cut section is excavated at an 80-degree angle away from the excavation.
Shotcrete is applied by pumping/spraying concrete through a nozzle, which is held by
an operative. In addition to pre-testing the adequacy of the soil nailing/shotcreting
technique in pilot tests, geo-monitoring equipment was in place along the excavation
to monitor soil stability. This instrumentation is monitored at regular time intervals to
detect movement. Results were very positive and the soil nailing/ shotcreting
technique has been successful.
Waterproofing the Cut and Cover Section
When the casting operation was complete, the top and sides of the horseshoe tunnel
were waterproofed with a 2mm Sika pvc tanking sheet. Waterproofing the horseshoe
tunnels was a three-part operation in which the tanking is first laid on the underside
of the Tunnel floor and then carried over the roof of the Tunnels. The tanking at the
roof and sides was heat welded to the tanking at the sidewalls and floor to form a
complete waterproof envelope. For protection against mechanical damage, a
reinforced concrete was poured on top of the membrane before backfilling took place.