tunnel walls were then built in the chamber. For the remaining
part of the river the foregoing process was varied by cutting off
the sheet piling at mid-height of the tunnel and making the upper
half of the tunnel, which was built above and lowered in sections
through the water, serve as the roof of the chamber in
which the lower half of the tunnel was built. ' - V
The tunnels of the Métropolitain railway of Paris (F. Bienvenue,
engineer-in-chief) under the two arms of the Seine,
between Place Chatelet and Place Saint Michel, were made by
means of compressed-air caissons sunk beneath the river bed,
were next made by the aid of temporary small caissons sunk
through about 26 ft. of earth under the river. The tops of the
side walls were made even with the end walls. A steel rectangular
coffer-dam (figs. 5 and 6) was sunk to rest with rubber
or clay joint on these surrounding walls. The coffer-dam had
shafts reaching above the surface of the water, so that the earth
core was easily taken out (after removing the water) in free air.
The adjacent chambers under the caissons were then connected
together. Three caissons, of a total length of 396 ft., were
used under the larger arm, and two, of an aggregate length
M ounldin Tunnels for Railways.
Average
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T 1 L Length. Internal Width and Material progress per Approximate “une ° ocatlon' (miles) Height. penetrated. day =24 hrs. “1st per, 7 i (lin. yds). lm- Y<'»
Mont Cenis (1 tunnel). Modane, France and 7-98 26 ft. 3 in. X 24 ft. £ Bardonecchia, Italy. 7 in. (horseshoe). Granitic 2~57 226 St Gotthard (1 tunnel) Goschenen and Airolo in 9~3 26 ft. 3 in. >< 24 ft. Switzerland. 7 in. (horseshoe). Granitic 6~O1 143 Arlberg (1 tunnel) . . Innsbruck and Bludenz 6~36 25 ft. 3 in. wide in Tirol. - 9-o7 108
Simplon (2 tunnels) Brigue, Switzerland and 12-3 16 ft. 5 in. X 19 ft. Gneiss, mica schist, 11~63 148 Iselle, Italy.
6 in. each (min.).
limestone and
disintegrated mica
schist rock.
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FIG. 4.-Perspective showin manner of enclosin s ace between L. Chagnaud being the contractor. They were built of plates; of sheet steel and masonry, with temporary steel diaphragms in the ends, filled with concrete, making a cross wall with'a» level top about even with the outside top of the tunnel and about 2 ft. below the bottom of the Seine. The caissons were sunk on the line of the tunnel so that adjacent ends (and the walls just described) were nearly 5 ft. apart with-at that stage -fa core of earth between them. Side walls joiningithe 'end walls and thus enclosing the earth core on four sides (fig. 4)
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(From Enginaring N nas, New York.)
tunnel caissons for the Metropohtain under the Seine at Paris. of 132 ft., under the smaller arm of the Seine. The cost of the tunnel was 7000 francs per lineal metre. William Sooy Smith published in Chicago, in 1877, a description of a scheme for building a tunnel under the Detroit river by sinking caissons end to end, each caisson to be secured to the adjoining one by tongued and grooved guides, and a nearly water-tight connexion between the two-to be made by means of an annular inflated hose.
Tunnelling through M ountaim.~Where a great thickness of rock overlies a tunnel through a mountain, it may be necessary to do the work wholly from the two ends without intermediate shafts. The problem largely resolves itself into devising the most expeditious way of excavating and removing the rock. Experience has led to great advances in speed and economy, as may be seen from examples in the above table. In 1857 the first blast was fired in connexion with the Mont Cenis works; in 1861 machine drilling was introduced; and in 1871 the tunnel was opened for traffic. With the exception of about 300 yds. the tunnel is lined throughout with brick or stone. During the first four years of hand labour the average progress was not more than 9 in. per day on each side of the Alps; but with compressed air rock-drills the rate towards 1 the end was five times greater.
In 1872 the St Gotthard tunnel was begun, and in as 1881 the first locomotive ran through it. Mechanical drills were used from the beginning; Tunnelling was cairrie on ly driving) in a vanceato a 1 a out square: t en enlarging WaYS' and .many sinking the excavation to invert level (see figs. 7 and Air for working the rock-drills was compressed to seven atmospheres by turbines -of about 2000 The driving of the Arlberg tunnel was be un in1880 and the work Wag completed in
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FIG. 5.—Transverse Section. FIG. 6.—Longitudinal Section. little more than three yeatS Coffer-dam superimposed over joints between caissons in tunnels for the Métropolitain under the Seine at Paris.
The main heading was driven
along the bottom of the
