EP0302243A1 - Lining arch for tunnels - Google Patents

Abstract

The lining arch consists of several lattice girders which are curved in accordance with an excavated arch and have at least three chord members which run parallel to one another, are connected to one another by spatial stiffening elements and are provided at least at one end with flange-like connecting elements for attaching to adjacent lattice girders. In at least two lattice girders (1, 5) of the excavated arch which are adjacent to one another, an anchoring device (3) for a press (4) to be clamped between the lattice girders (1, 5) is in each case arranged at a distance from the connecting elements (2) in such a way that the point of application of force for the press (4) in each case lies on the centroidal axis (S) of the lattice girders (1, 5). The connecting elements (2) of the two lattice girders (1, 5) adjacent to one another accommodate an expanding device (6) which, after the clamping of the lattice girders (1, 5) by the press (4), maintains the pretension introduced into the lattice girders (1, 5) by preventing a restoring movement, in which arrangement the normal and transverse forces as well as the bending moments of a lattice girder (1) can be completely transmitted to the adjoining lattice girder (5) via the expanding device (6). <IMAGE>

Description

The invention relates to an extension arch for tunnel construction from a plurality of arcuate lattice girders.

Such expansion arches are known from DE-OS 29 51 874 and DE Gbm 8125375.3.

Steel arches made of lattice girders have the following functions in tunnel construction:

- immediate securing in the face area on the length of the foremost tee,
- teaching when applying the shotcrete and when the next tee is broken,
- Part of the reinforcement of the shotcrete shell, and
- Support for skewers or pawn plates, which are supposed to secure the next tee in advance.

In the case of fragile mountains, non-stable loose rock, settlement and icing of the mountains, it is often necessary to pre-tension or re-tension the expansion arch when installed.

The invention has for its object to provide an extension sheet in which a uniform bias can be introduced into the lattice girder.

To achieve this object, the invention provides for an extension arch for tunnel construction consisting of a plurality of arch-shaped lattice girders with at least three mutually parallel belt bars which are connected to one another with spatial stiffening elements and are provided with flange-like connecting elements at at least one end for connection to adjacent lattice girders.
- That in two adjacent lattice girders at a distance from the connecting elements, an anchoring device for a press to be clamped between the lattice girders is arranged such that the force application point for the press is in each case in the space enclosed by the belt bars, and
- That the connecting elements of the two adjacent lattice girders accommodate a spreader device which, after the lattice girders have been tensioned by the press, maintains the preload introduced into the lattice girders by preventing a restoring movement, the normal and transverse forces, as well as the bending moments of a lattice girder via the spreader device completely are transferable to the adjacent lattice girder.

The expansion arch according to the invention enables pretensioning in the direction of the arch axis of the lattice girder. As a result, the risk of excessive moment loading of the expansion bend is reliably avoided. Transfer the anchoring device and the spreading device the cutting forces between two lattice girders, that is the normal and transverse forces as well as the bending moments, fully in the adjacent lattice girders. When tensioning, the force is introduced into the two adjacent lattice girders. This gives the entire expansion arch a pretension that presses it evenly against the walls of the excavation cross-section. In the event of subsequent settlement, the press can be reinserted between two lattice girders in order to retighten the extension arch. The spreading device serves to maintain the pretension applied with the press even when the press is removed again. The expansion arches according to the invention can be used both as spherical arches and as sole arches.

It is preferably provided that the force application point of the press lies in each case in the center of gravity of the lattice girders. As a result, the expansion arch is preloaded exactly in the center of gravity of the lattice girder. The press has oppositely aligned rods for power transmission, which at their ends form removable joints with the anchoring devices, the pivot axes of which cross the axis of gravity and the plane of curvature of the axis of gravity at a right angle.

The joints enable the expansion arch to be displaced due to the tension applied, without bending moments being introduced into the lattice girders.

It is preferably provided that the joint consists of an eye located at the end of the rod and a detachable bolt which is adapted to the eye and is mounted in the anchoring device.

With the help of the releasable bolt of the anchoring device, the press with its two power transmission rods can always be used without adjustment work between two lattice girders in such a way that the force is introduced via the rods in the axis of gravity of the lattice girders. In this way, the press can be installed and removed for spreading the expansion sheets without great assembly effort.

A further development of the invention provides that the spreading device has a plurality of threaded spindles running parallel to the center of gravity of the lattice girders, which pass through the flange parts of the connecting elements and can be fixed with lock nuts against the flange parts, the center of gravity of the threaded spindle arrangement coinciding with the center of gravity of the lattice girders at the connection point . With the help of the threaded spindles in connection with the lock nuts, the distance between the flange parts of the respective connecting elements is secured and fixed. The press can then be removed without the voltage introduced in the expansion arch dropping.

In a preferred embodiment of the invention, the connecting elements consist of angle plates, which are fastened with their one leg parallel to the center of gravity to two respectively adjacent belt bars and whose other leg projects as a flange part at a right angle from the lattice girder. The angular plates arranged symmetrically with respect to the center of gravity can be easily welded to the belt rods and completely transmit transverse and normal forces as well as bending moments.

In the preferred embodiment, it is further provided that the connecting elements are fastened to the belt rods in such a way that the space enclosed by the belt rods is open to the inner boundary of the extension arch. In this way it is possible to insert the press for spreading the lattice girders into the space enclosed by the belt bars and thus in the vicinity of the center of gravity of the lattice girders and to lock them with the anchoring devices.

The angle plates serving as connecting elements for stiffening the angle can have a stiffening plate standing vertically on both legs, which supports the right angle of the angle plate. In this way, the higher forces and moments that occur during pretensioning of the expansion arch are transmitted more reliably from one lattice girder to the next.

• Fig. 1 einen Abschnitt eines Ausbaubogens, bei dem am Fuß des Gitterträgers die Auflagerkräfte über eine angeschweißte Fußplatte in das Gebirge abgetragen werden,
• Fig. 2 eine Seitenansicht einer Verbindungsstelle zwischen zwei Gitterträgern des Ausbaubogens,
• Fig. 3 einen Schnitt entlang der Linie III-III in Fig. 2,
• Fig. 4 einen Schnitt entlang der Linie IV-IV in Fig. 2 und
• Fig. 5 einen Schnitt entlang der Linie V-V in Fig. 4.

In the following an embodiment of the invention will be explained with reference to the drawings. Show it:

• 1 shows a section of an extension arch, in which the support forces are dissipated into the mountains via a welded footplate at the base of the lattice girder,
• 2 is a side view of a connection point between two lattice girders of the extension arch,
• 3 shows a section along the line III-III in FIG. 2,
• Fig. 4 is a section along the line IV-IV in Fig. 2 and
• 5 shows a section along the line VV in FIG. 4.

Fig. 1 shows a section of an extension arch, as used for example in the Austrian construction for immediate securing in the face area on the length of the foremost tee and as part of the reinforcement of a shotcrete shell. The expansion arch essentially consists of a plurality of lattice girders 1, 5, which are bent in accordance with an excavation arch and which are assembled in the face area to form an arch adapted to the excavation geometry. The lattice girders 1,5 already have a curvature that corresponds to the excavation geometry. In the case of pressurized mountains, the expansion arch can be completely closed, i.e. a base arch connects to a spherical arch, which closes the extension arch in the tunnel cross-section.

1 shows an expansion arch in the form of a dome arch, in which one or more lattice girders 1 are supported in the base region of the dome on a lattice girder 5 which has a flared foot with a base plate 40. The support forces of the spherical cap are removed at the foot of the lattice girder 5 into the mountains via the welded-on foot plate 40. The lattice girder 5 connected to the base plate 40 additionally has a base 41 which is protruded into the mountains and protrudes from the outer double belt 18 and is connected to the outer end of the base plate in order to dissipate the bearing forces which occur over a larger area in the mountains.

Each lattice girder has three belt bars 15 to 20, which are arranged in the cross section of the lattice girder in a substantially triangular shape and which are connected to one another via spatial stiffening elements 35. The belt bars 15 to 20 and the spatial stiffening elements 35 have a very high strength and a large ability to change shape, and in addition a very good weldability must be ensured. The triangular arrangement of the belt rods is such that the belt rod 15, 18 forming the tip of the triangle is the outer belt rod, while the other two belt rods 16, 17, 19, 20 form the inner boundary of a lattice girder 1.5. The outer belt rod 15, 18 is designed as a double belt rod.

At the joints between two lattice girders 1, 5, flange-like connecting elements 2, which consist of angle plates 13, are arranged at their ends, which consist of angle plates 13 and which make it possible to connect a plurality of lattice girders one behind the other by means of screw connections to form an extension arch. The joints of the lattice girder 1.5 are designed so that the transmission of the full cutting forces (bending moments, normal force and shear force) and easy assembly on site is guaranteed.

At a distance from the connecting elements 2, 1.5 anchoring devices 3 are arranged in the lattice girders, with which a hydraulic press 4 can be fastened between two lattice girders 1.5. The distance of the anchoring device 3 from the end of a lattice girder or the distance between two anchoring devices 3 on two adjacent lattice girders is from depending on the dimensions of the hydraulic press 4, the distance between two anchoring devices 3 should be chosen as small as possible. The anchoring device 3 consists of two right-angled L-shaped angle plates 30, 31, which are welded to the belt rods 15 to 20 in such a way that two mutually parallel, longer legs point radially outwards and with their radially outer ends, as from Fig. 3 can be seen, welded to the side of the double belt 15, 18, while the shorter legs projecting at right angles from them, essentially parallel to the breakout arch, rest on the inner belt rods 16, 17 and 19, 20 and are welded there. In each of the two radially aligned legs 36, which run parallel to one another at a distance, a bore is provided for a bolt 7, the central axis of which intersects the center axis S of the lattice girder 1.5 at right angles. The central axis is also perpendicular to the radius of curvature of the extension bend.

The press 4 has at its two ends oppositely acting force transmission rods 8, each of which ends in an eye 9 for receiving the bolt 7. The central axis of an eye 9 intersects the longitudinal axis of the power transmission rod at right angles. The eye 9 and the bolt 7 are adapted to one another with regard to the cross-sectional shape. This longitudinal axis corresponds to the direction in which force is applied by the press 4. The end of the power transmission rod 8 with the eye can be inserted between the two parallel legs of the angle plates 30,31 in such a way that the bolt 7 passes through the legs and the eye 9 and thereby the press 4 with the Lattice girder 1.5 firmly connects. The distance between the two angle plates 30, 31 essentially corresponds to the width of the double belt 15, 18.

If the press is locked to the lattice girders 1, 5 by means of the bolts 7 stored in the anchoring devices 6, the press can be actuated in order to introduce a pretension into the expansion arch by pushing the lattice girders apart. The force application point of the press 4 is located exactly on the center of gravity S of the lattice girders, whereby a force is introduced in the direction of the center of gravity S.

After the expansion arch is sufficiently pre-tensioned, the distance between the lattice girders 1.5 is secured with the aid of a total of 4 threaded spindles 10 in connection with lock nuts 12 on the flange parts 11 of the connecting elements 2 with the aid of a spreading device 6, so that the pre-tensioning also after removing the Press 4 is maintained. It is also important that the spreading device also transmits the normal and transverse forces as well as the bending moments unadulterated to the lattice girders. For this purpose, it is provided that the threaded spindles 10 are arranged symmetrically to the center of gravity S such that their center of gravity essentially coincides with the center of gravity S.

The spreading device 6 consists of two angle plates 13 of the two connecting elements 2 arranged symmetrically to the center of gravity S, each with a leg 14, as shown in FIG. 4, in cross section Connect the legs of an isosceles triangle to form the outer double belt 15 or 18 with one of the two inner belt rods 16, 17 or 19.20. The flange-like leg 11 projects from the leg 14 at right angles and is supported against the leg 14 by a stiffening plate 21 extending at right angles to both legs 11, 14. The spreading device 6 is mirror-symmetrical in its entirety to an axis running through the center axis S in the radial direction through the center of the double belt rod cross section. The leg 11 serving as a flange part is cut in such a way that it does not protrude beyond the outer double belt rod 15 or 18, or beyond the inner belt rods 16, 17 or 19, 20.

The threaded spindles 10 are fixed on one of the flange-like legs 11 of the opposing legs 11 of the adjoining lattice girders 1, 5 with two lock nuts 12, while on the other leg a nut 12 is sufficient to set the distance between the lattice girders 1, 5 to fix.

Claims (10)

1. Extension arch for tunnel construction from a plurality of arch-shaped lattice girders with at least three belt bars running parallel to one another, which are connected to one another with spatial stiffening elements and are provided at at least one end with flange-like connecting elements for connection to adjacent lattice girders,
characterized,
- That in two adjacent lattice girders (1,5) at a distance from the connecting elements (2) each an anchoring device (3) for a between the lattice girders (1,5) to be clamped press (4) is arranged such that the force application point for the Press (4) lies in the space enclosed by the belt rods (15 to 20), and
- That the connecting elements (2) of the two adjacent lattice girders (1.5) accommodate a spreading device (6) which, after tensioning the lattice girders (1.5) by the press (4) into the lattice girders (1.5) initiated preload is maintained by preventing a restoring movement, the normal and transverse forces, as well as the bending moments of a lattice girder (1) being completely transferable to the adjacent lattice girder (5) via the spreading device (6). 2. Extension sheet according to claim 1, characterized in that the force application point for the press (4) is in each case in the center of gravity (S) of the lattice girder (1,5). 3. Extension sheet according to claim 2, characterized in that the press (4) has oppositely aligned rods (8) for power transmission, the ends of which form removable joints (9, 7) with the anchoring devices (3), the pivot axes of which are the center of gravity (S) and the plane of curvature of the axis of gravity (S) cross at a right angle. 4. Extension arch according to claim 3, characterized in that the joint (9,7) from an at the end of the rod (8) located eye (9) and an eye (9) adapted in the anchoring device (3) mounted detachable Bolt (7) exists. 5. Extension sheet according to one of claims 1 to 4, characterized in that the spreading device (6) has a plurality of parallel to the center of gravity (S) of the lattice girder (1,5) threaded spindles (10) through the flange parts (11) of the connecting elements (2) pass through and can be fixed with lock nuts (12) against the flange parts, the center of gravity of the threaded spindle arrangement coinciding with the center of gravity (S) of the lattice girders (1,5) at the connection point. 6. Extension sheet according to one of claims 1 to 5, characterized in that the connecting elements (2) consist of angle plates (13) which with their one parallel to the axis of gravity (S) leg (14) on two adjacent belt bars (15, 16; 15, 17; 18, 19; 18, 20) are fastened and the other leg of which, as a flange part (11), projects from the lattice girders (1,5) at a right angle to the center of gravity (S). 7. Extension bow according to one of claims 1 to 6, characterized in that at least two belt rods (16,17,19,20) form the inner boundary of the lattice girder (1,5) and at least one belt rod (15,18) the outer boundary forms. 8. Extension bow according to claim 7, characterized in that the connecting elements (2) are fastened to the belt rods (15 to 20) in such a way that the space enclosed by the belt rods (15 to 20) is open to the inner boundary. 9. Extension bow according to one of claims 1 to 8, characterized in that the belt rod forming the outer boundary of the belt rod (15, 18) is a double belt rod. 10. Extension sheet according to one of claims 5 to 9, characterized in that the angle plates (13) have a stiffening plate (21) for supporting the right angle, which is fixed perpendicular to both legs (11, 14).

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