DE197021T1 - METHOD OF BUILDING A TUNNEL. - Google Patents

Claims (11)

Q187Q21 EP86870032.9-2303 S.A. EntreprisesKoeckelberg Patent claims Method for building a tunnel using prefabricated concrete elements which are connected to one another by concreting after being arranged, characterized by
the following steps: - frontal excavation of the excavation pit; - arranging and adjusting base parts (1) made of reinforced concrete, which are generally rectangular in shape and have an upper support surface (2), providing a space between successive base parts (1) and arranging each base part (1) so that it is perpendicular to vertical walls of the tunnel to be formed; - connecting the successive sole parts (1) by casting connecting sections (4) which also form a continuous "approach" (5) along each edge of the tunnel; - placing vertical elements made of reinforced concrete, which form part of the side walls of the tunnel, on each continuous extension (5), providing an interval between successive vertical elements of the same row and placing each vertical element directly opposite an element of this type on the other side of the tunnel to be formed, - placing two vertical formwork panels (12, 13) at a distance from each other parallel to the axis of the tunnel in each interval between successive vertical elements of each row, these two panels (12, 13) being flush with a part of the external surface of the two adjacent vertical elements form a formwork for casting a column (20) of reinforced concrete; - introducing a concrete reinforcement (15) into this formwork; - arranging a lintel (16) parallel to the tunnel axis near the upper edge of the formwork panel (13) which lies on the inside of the tunnel to be formed, in such a way that each lintel (16) rests with its ends on the two adjacent vertical elements, each lintel (16) lying directly opposite a lintel (16) on the other side of the tunnel to be formed; - pouring a concrete foundation slab (21) between the two continuous extensions (5); - inserting upper transverse beams (17) at the location of the formwork between adjacent vertical elements in such a way that each beam (17) rests with its ends on the two lintels (16), one of which is arranged opposite the other; - pouring concrete into the formwork between adjacent vertical elements and fixing each beam (17) to the reinforced concrete columns (20) thus formed, which are opposite each other; - Backfilling behind the side walls of the tunnel; - Inserting and fixing ceiling panels (18) made of reinforced concrete onto the beams (17) in such a way that each ceiling panel (18) rests with its front edge on a beam (17) and with its rear edge on the beam (17) following in the direction of advance of the construction site, - Concreting the upper plate (19) and filling the tunnel, as well as - Filling and completing the tunnel. 2. Method according to claim 1,
characterized,
that the successive steps in the production of the tunnel along the construction site from the front, where the earthworks and the frontal excavation of the excavation pit are located, to the completion zone, where the embankment and the completed tunnel are located. 3. Method according to one of the preceding claims, characterized in that the vertical elements are elongated shells (8) made of reinforced concrete, which have a cylindrical curvature (9) whose generatrix is parallel to the longitudinal axis of the shells (8), these shells (8) being closed at each of their ends by a crescent-shaped plate (11) which is perpendicular to the longitudinal axis, these shells being arranged so that their concave side faces the interior of the tunnel, while the curvature (9) is directed towards the wall of the passage. 4. Method according to claim 3,
. characterized, that the shells (8) have two flat and parallel longitudinal surfaces (10) which extend the curvature (9) on both sides. 5. Method according to one of claims 3 or 4, characterized in that that the vertical reinforced concrete elements forming the side walls of the tunnel consist of shells, the outward-facing surface of which is essentially flat and is perpendicular to the side surfaces of these elements. 6. Method according to one of claims 3, 4 or 5, characterized in that the shells (8) on the outside (14) of each flat longitudinal surface (10) have two grooves (25,26) parallel to the longitudinal axis of the shell, which serve to accommodate the side edges of the two formwork panels (12,13). 7. Method according to claim 6,
characterized, that the grooves (26) are widened in their upper section near the free edge of the flat longitudinal surfaces (10) so that they form shoulders (27) near the level occupied by the upper edge of the formwork panel (13) on the inside of the tunnel, on which the end of a lintel (16) comes to rest. 8. Method according to one of the preceding claims, characterized in that the sole parts (1) made of reinforced concrete, like the connecting sections (4), which form a continuous surface between the sole parts (t), are provided on their upper support surface (2,6) with a fold (3,7) which lies parallel to the tunnel axis and is directed towards the interior of the tunnel. 9. Method according to one of the preceding claims, characterized in that the structure consisting of a support (17), the two columns (20) made of reinforced concrete, each of which supports one end of this upper support (17), and the base parts (1) each supporting these columns (20) made of reinforced concrete, forms a gate which absorbs the vertical compressive forces exerted by the rock and the upper embankments, as well as the horizontal pressures of the ground. 10. Method according to one of the preceding claims, characterized in that the vertical elements made of reinforced concrete which form the side walls of the tunnel are thin cast shells (8) which have a curvature (9) which absorb the horizontal forces of the earth pressure. 11. Tunnel manufactured according to the method according to one of claims 1 to 10.