EP0589401A1 - Method and apparatus for the dismounting and mounting of bridges - Google Patents

Abstract

The object of the invention was to provide a method for the dismantling and mounting of single-span and multi-span bridges in the form of a continuous girder or a series of individual girders, in which the material expense and time required for the dismantling of the old superstructure can be significantly reduced without impairing the traffic routes passing over them. Furthermore, it is the object of the invention to provide an apparatus necessary for carrying out the dismantling of the old superstructure. As a solution, it is proposed that, in order to form supports for longitudinal displacement paths 6 for the dismantling of the old superstructure 3, girder bundles 2 consisting of the girders 9 of the main supporting structure of the new superstructure are employed which, after the dismantling of the old superstructure, are separated into individual girders by transverse displacement, and these are mounted in their final position as main girders. From the girders 9 of the main supporting structure of the new superstructure there are formed girder bundles 2 which are arranged on both sides of the old superstructure 3, in the bridge longitudinal direction, on prefabricated foundations 4 with rules 10. Displacement paths 6 in the form of sleeper tracks with rolling carriages 14 are laid onto the girder bundles 2, and consoles 7 are fixed to the old superstructure 3. By means of load-lifting means 15 engaging on the consoles 7, the old superstructure 3 is raised and moved in the bridge longitudinal direction. The invention is applicable in composite bridge construction. <IMAGE>

Description

The invention relates to a method for bridge disassembly and bridge assembly of single-field and multi-field bridges as a continuous beam or a series of single-beam girders. The invention further relates to a system for carrying out the method.

It is known, when dismantling bridges o.g. To use the type of longitudinal traversing tracks by means of which the old superstructure is transported out of the bridge area (DE-OS 24 23 566). In most cases, it is necessary to produce longitudinal traversing tracks especially for the local conditions. These have to be prefabricated and transported to the building object. Special adaptation and assembly work must then be carried out on site. In addition, scaffolding must be set up. When disassembling and assembling bridges that lead over heavily used traffic routes, it is necessary that the traffic operation can be maintained during disassembly and assembly. It is therefore not possible to demolish the old superstructure above the traffic route. The increasing number of heavy bridge structures to be replaced, e.g. with solid reinforced concrete slabs make particularly high demands, especially with regard to the static load-bearing capacity of the longitudinal sliding tracks. The production of the longitudinal sliding tracks is very expensive. After the old superstructure has been dismantled, the longitudinal shear tracks have to be dismantled and removed from the building object. There is generally no further use for them and they can only be scrapped. This results in considerable costs when dismantling the old superstructure.

The invention had for its object to provide a method for bridge disassembly and bridge assembly of single-field and multi-field bridges as a continuous girder or single girder series, in which the material-technical and time expenditure for the disassembly of the old superstructure and the assembly of the new one without impairing the transferred traffic routes Superstructure can be significantly reduced. It is also an object of the invention to provide a system for carrying out the method.

• a) die Trägerbündel auf vorgefertigten Abstützelementen in Brückenlängsrichtung zu beiden Seiten des alten Überbaues angeordnet und
• b) auf die Trägerbündel Verschubbahnen aufgelegt.

According to the invention the object is achieved in that beams are arranged next to the old superstructure, each serving as a support for a longitudinal displacement track, that support elements are attached to or next to the old superstructure and the old superstructure is raised and moved in the longitudinal direction of the bridge by means of load-bearing means engaging on the support elements and that after the old superstructure has been dismantled, the beam bundles are released by transverse displacement of the individual beams and the beams in their final position as main beams for a new superstructure. According to a further embodiment of the method

• a) the bundle of beams arranged on prefabricated support elements in the longitudinal direction of the bridge on both sides of the old superstructure and
• b) placed on the carrier bundle shear lanes.

This new procedure makes it possible to significantly reduce the costs of dismantling the old superstructure and installing the new superstructure. This is achieved in particular by forming beam bundles from the beams of the main supporting structure for the new superstructure, which are used as supports for the sliding tracks for dismantling the old superstructure. After dismantling, the beam bundles are broken down into individual beams directly on site and assembled in their final position as the main beam for the new superstructure. This saves the additional delivery and removal costs for the sliding track supports that are otherwise used as auxiliary material. The real essential advantage, however, is that the material used to form the sliding track supports does not need to be scrapped, but can be put to a use directly on site. This contributes significantly to the saving of manufacturing and material costs for the sliding tracks.
In addition, the new procedure can reduce the time required for the disassembly and assembly of bridges.

Further design variants of the method according to the invention consist in the following.
Either new foundations are produced as support elements for the beam bundle, or makeshift supports with attached sliding tracks are arranged, which are dismantled again after completion of the new superstructure. After dismantling has been completed, the beams are transversely shifted on a bar of the new foundations or on the transverse displacement tracks. The beams can be used as formwork beams in the production of the new superstructure. To extend the old superstructure lighten, additional shear lanes are laid out on the ground outside the bridge area.
According to the method according to the invention, bridge superstructures in prestressed concrete, steel and composite steel bridge construction of the length of one or more bridge fields can be dismantled and assembled.

The invention also relates to a plant for carrying out the method. This consists of beam bundles, which are arranged in the longitudinal direction on both sides of the old superstructure on prefabricated support elements. Slideways are placed on the carrier bundles and support elements are arranged on both sides of the old superstructure, which are operatively connected to load suspension means which can be displaced on the slideways. The carrier bundles can consist of carriers which are detachably connected by means of cross members. Cooperation between the carriers is thereby achieved. Steel beams are used as beams. It is advantageous if the lower flange of the carrier is covered with a prestressed concrete. The support element consists of a newly manufactured foundation, which is provided with a bolt. According to a further variant, the support element can consist of makeshift supports with an applied transverse sliding track, which are designed to be removable. The sliding tracks are designed as cross-sleeper tracks or as slideways. The support elements are designed either as brackets or as trusses. If the old superstructure cannot absorb the attacking forces from the brackets, trusses are used. The brackets are attached to the old superstructure. The system also includes shift tracks, which are arranged in the direction of movement of the old superstructure on the paved ground outside the bridge area.

Fig. 1

eine Vorderansicht eines alten Brückenüberbaues mit neu errichteter Gründung.

Fig. 2

eine Vorderansicht eines alten Brückenüberbaues mit angeordneten Behelfsstützen und einer Querverschubbahn,

Fig. 3

eine Vorderansicht eines neu errichteten Brückenüberbaues nach der Variante gemäß Figur 1,

Fig. 4

eine Vorderansicht eines neu errichteten Brückenüberbaues nach der Variante gemäß Figur 2,

Fig 5

eine Seitenansicht der Variante gemäß Figur 4, wobei der alte Üherbau bereits ein Stück verschoben ist.

The invention will be explained below using two examples. Show in the accompanying drawing

Fig. 1

a front view of an old bridge superstructure with a newly established foundation.

Fig. 2

a front view of an old bridge superstructure with arranged makeshift supports and a cross slide,

Fig. 3

2 shows a front view of a newly built bridge superstructure according to the variant according to FIG. 1,

Fig. 4

3 shows a front view of a newly built bridge superstructure according to the variant according to FIG. 2,

Fig. 5

a side view of the variant according to Figure 4, the old superstructure has already been moved a bit.

In Figure 1, an old bridge superstructure 3 is shown, which is already in the raised state for disassembly Before installing the system for disassembly new foundations 4 were built on both sides of the bridges, which are provided with bars 10 The system for disassembly consists of beams 9, which are made of steel and are mounted by means of short cross beams to a beam bundle 2. In addition, the lower flange of the carrier 9 is covered with a prestressed concrete. The beams 9 used are the beams of the superstructure to be erected. The beam bundles 2 are arranged on the bar 10 of the newly established foundation 4 on the two long sides directly next to the old bridge superstructure 3. The sliding tracks 6 are placed on the carrier bundle 2. The displacement tracks can be designed in various ways, depending on the loads to be shifted. In FIG. 1, cross-sleeper tracks are shown as shift tracks on which roller carriages 14 are arranged.
Other suitable sliding tracks are, for example, fluid heavy-duty transport systems with steel sliding tracks. Fluids such as air and oil, coatings made of polytetrafluoroethylene or coatings coated with this material are used as lubricants.
As can be seen from FIG. 1, consoles 7 are attached to the old superstructure. The use of brackets has the advantage that the superstructure to be disassembled is only influenced on the outside, so that the transferred traffic can be used with only minor restrictions until the actual disassembly date. The connection to steel bridges is made using standard steel connections, such as screws or welding. Taking up the loads of a solid bridge requires greater efforts in the connection area. In addition to the pressure force that can be easily transmitted in the upper connection area, there is a need to absorb high tensile forces in the lower connection area. This can be done by arranging a drawstring from the left to the right console below the construction. Due to their high load capacity, single bar tendons can be used here.
Hydraulic jacks 15, by means of which the old superstructure 3 is raised, are located between the underside of the brackets 7 and the contact surface of the trolleys 14. In the figure 2 shows a variant in which, instead of a new foundation, makeshift supports 5 with an applied transverse sliding track 11 are used. These have to be dismantled again after the new superstructure has been erected.
Steel slideways or the tops of the transoms can be used as the transverse sliding track. The surface finish depends on the type of sliding track used.
The mass of the beams results in a load which is decisive for the formation of the cross-sectional radius of the transverse sliding tracks.

Analogously as in FIG. 1, the beams 9 are connected by means of cross beams 1 to beam bundles 2, on which sliding tracks 6 are placed. According to the illustration in FIG. 2, the displacement tracks 6 are designed as slideways. The old superstructure 3 is attached to trusses 8.
Trusses are used when the superstructure to be dismantled cannot accept the load from the brackets due to the insufficient cross-sectional size or severe structural damage. The load of the superstructure to be dismantled is suspended below the crossbar by means of tension straps 17. The number of drawstrings and their distribution over the cross-section of the superstructure determine the load on the superstructure and the traverse. In the event of extreme structural damage, it is advisable to carry out tension straps between the superstructure and the support bundles in order to place the superstructure on a support crossbar arranged transversely on the underside of the bridge and attached to the tension straps. To raise the old superstructure 3, 6 height-adjustable sliding modules 16 are arranged between the underside of the projecting crossbar ends and the slideways.

Figures 3 and 4 show the new superstructure 12 with the beams 9 as main support members after its completion. In the variant of a composite bridge superstructure shown in FIG. 4, the transverse sliding tracks 11 and the auxiliary supports 5 still have to be dismantled. It can be seen from FIG. 5 that the crossbeams 8 lie over the old superstructure 3 and this is suspended. The old raised superstructure 3 has already been shifted lengthways. For the longitudinal displacement of the old superstructure 3, additional elongated displacement tracks 13 are required. These are used to remove the old superstructure 3 from the building area. The material and design of these shear lanes depend directly on the shear method and the load. Any retaining walls that may be required due to a widening of the cross section must be dimensioned for the loads The upcoming geological and geometric conditions are decisive for the load on the dam shoulders.

The sequence of the method according to the invention for dismantling the old superstructure and assembling the new superstructure is as follows.
Beam bundles 2 are formed from the beams of the main supporting structure of the new superstructure and are used to erect the supports for the longitudinal sliding tracks 6 for dismantling the old superstructure 3. The beam bundles 2 are arranged on prefabricated support elements, the foundations 4 (FIG. 1) or the prop supports 5 with the transverse sliding tracks 11 (FIG. 2) in the longitudinal direction of the bridge on both sides of the old superstructure 3. Slideways 6, either slideways (FIG. 2) or cross-sleeper tracks with trolleys 14 (FIG. 1), are placed on the carrier bundle 2. Thereafter, brackets 7 are either attached to the old superstructure or, in addition to the old superstructure, trusses 8 are arranged as supporting elements. When using trusses 8, the old superstructure 3 is attached to them. The old superstructure 3 is raised by means of load suspension means, such as hydraulic jacks 15 or height-adjustable sliding modules 16, which act on the brackets 7 or traverses 8.
Usually, when lifting the superstructure to be dismantled, the existing press points next to the supports are used in order to introduce any additional forces that may arise due to the superstructure's high adhesion to the bearings into the substructures. In exceptional cases, the lifting means can be arranged between the brackets or traverses and the transport system. The raised old superstructure 3 is then moved in the longitudinal direction of the bridge by traction means known per se, such as cable winches or the like, either as a sliding movement (FIG. 2) or as a rolling movement (FIG. 1 ). For this purpose, extended shear paths 13 are additionally designed outside the bridge area (FIG. 5). After the old superstructure 3 has been completely dismantled, the beam bundles 2 remaining around the bridge area are released by transverse displacement of the beams 9. The guarantee of safety against tilting of the beams must be observed. Due to the constant coupling of at least two beams or the support of a single beam by means of auxiliary construction on the transom or on the transverse sliding track, this can be taken into account could.
Fluid systems, such as air film sliding technology, can be used on steel as well as on concrete (eg bars of the new substructures). With the use of rolling technology the upper edge of the transom is to be fastened using a steel structure in order to avoid structural damage caused by assembly. Due to the transverse displacement, the beams 9 are also brought into their final position as the main beams for the new superstructure 12. This is then erected in a conventional construction known per se, the supports 9 being able to be used as formwork beams.

Compared to the previously practicable dismantling of old bridge superstructures and assembly of new bridge superstructures, the construction method can reduce the construction costs by approx. 15% while simultaneously reducing the construction time by approx. 10%.

Claims (14)

Method for dismantling the superstructure and for partial assembly of single or multi-span bridges from single-span or continuous girders, in which the old superstructure is shifted and dismantled by means of longitudinal sliding tracks, characterized in that beam bundles (2) are arranged next to the old superstructure (3) each serve as a support for a longitudinal displacement track (6) that support elements are attached to or next to the old superstructure (3) and the old superstructure (3) is lifted and moved in the longitudinal direction of the bridge by means of load-bearing means acting on the support elements and that after dismantling the old one Superstructure (3), the beam bundles (2) are released by transverse displacement of the individual beams (9) and the beams (9) are brought into their final position as the main beam for a new superstructure (12). A method according to claim 1, characterized in that a) the carrier bundles are arranged on prefabricated support elements in the longitudinal direction of the bridge on both sides of the old superstructure and b) placing slideways on the carrier bundle. A method according to claim 2, characterized in that a new foundation is produced as a supporting element or makeshift supports (5) are arranged with an attached sliding track (11), which are dismantled again after the new superstructure (12) has been completed. Method according to claim 3, characterized in that the transverse displacement of the supports (9) takes place on a bar of the new foundations or on transverse displacement tracks (11). Method according to one of claims 1 to 4, characterized in that the beams (9) are used as formwork beams in the manufacture of the new superstructure (12). Method according to one of claims 1 to 5, characterized in that in the direction of movement of the old superstructure (3), shear paths are laid on the ground outside the bridge area. Method according to one of claims 1 to 6, characterized in that bridge superstructures of the length of one or more bridge fields are dismantled and assembled in the prestressed concrete, steel and steel composite backing. Installation for carrying out the method according to one of the preceding claims, characterized in that it consists of carrier bundles (2) which are arranged in the longitudinal direction on both sides of the old superstructure (3) on prefabricated support elements, that on the carrier bundles (2) there are displacement tracks (6 ) are placed, and that on or next to the old superstructure (3) on both sides support elements (7, 8) are arranged which are operatively connected to the load-bearing means (14) displaceable on the sliding tracks (6). Installation according to claim 8, characterized in that the carrier bundles (2) consist of carriers (9) which are detachably connected by means of cross-members (1). Installation according to claim 9, characterized in that the lower flange of the carrier (9) is covered with a prestressed concrete. System according to one of claims 8 to 10, characterized in that the support element is a newly manufactured foundation (4) with a bolt (10) or consists of auxiliary supports (5) with a transverse sliding track (11) which are designed to be removable. System according to one of claims 8 to 11, characterized in that the shear tracks (6) are designed as cross-sleeper tracks or as slideways. System according to one of claims 8 to 12, characterized in that the supporting elements are designed as cross members (8) or brackets (7), the brackets (7) being fastened to the old superstructure (3). Installation according to one of claims 8 to 13, characterized in that shear tracks (13) are arranged on the paved surface outside the bridge area in the direction of movement of the old superstructure (3).

Images