DE2445029C3 - Method for producing the superstructure of a bridge or the like structure from prestressed concrete as well as supporting scaffolding for carrying out the method - Google Patents

Description

The invention relates to a method for producing the superstructure of a bridge or the like Structure made of prestressed concrete, as a continuous beam resting on at least two intermediate pillars is formed and with the help of a fixed support frame erected in each case in the vicinity of the pillars individually manufactured parts cantilevered in the longitudinal direction from each pillar in both directions is pre-built.

In a known method of this type, in which the bridge superstructure is concreted in sections, after the completion of the two pillars and the end abutments in the area of each pillar, the first one Section concreted in the form of a double cantilever arm. For this purpose, one is placed on both sides of the pillar Fixed support frame to support the concreting built. The concreted double cantilever arm rests on the pillar and the stationary ones on both sides Support scaffolding. After the concrete has hardened, this double cantilever arm is prestressed using tendons. The two support frames on both sides of the pillar remain to stabilize the double cantilever arm even during concreting the further sections to be connected to the double cantilever arm at both ends

stand. Before concreting these further sections, both sides are spaced apart from the fixed supporting scaffolding erect additional auxiliary scaffolding «, each of which consists of a fixed substructure and a load on the latter movable falsework trestle

stand on which, after its correct height adjustment, the respective superstructure section to be created is concreted. Before that, the tendons ending in these superstructure sections are already fabricated Superstructure part pulled in. The resilience will

ao initiated after the individual superstructure sections have been concreted and hardened. It follows that that the respective weight of the fresh concrete is borne by the movable falsework stands and that after the concrete has hardened, those for it

»5 superstructure section required tension force initiated and then the falsework trestle is removed and continued. This should be the bend-free The condition of each superstructure section is continuously maintained.

With this procedure, the rests gradually at both ends getting longer double cantilevered always on the Fixed support structures on both sides and, above all, on the respective pillar at the same time. Therefore must the piers completed before construction work begins

and also be tied to such an extent that it can absorb the corresponding loads. The pillar stands from Beginning of the Bauarh. iten under load, which with advancing Stem increases. As the concreting progresses, the following superstructure sections are added is the pillar due to wind forces or the like. Sometimes strong vibrations and thus also horizontal acting forces for which bridge piers may not be specially designed. Another disadvantage is the special arrangement of the fixed substructures and those that can be moved on them Falsework stands; because their construction is time-consuming and expensive, as well as of course in batches Moving and setting up the falsework trestles with stepped bridge porch. Also on the land side

the pillar for the superstructure sections to be built in front of the land fixed lower scaffolding and falsework trestles that can be moved on them must be erected sufficient space is required on the floor. However, this is often not available on embankments, especially not if the pillars are set far outwards right up to the start of the slope need to be, as z. B. is the case with bridges that are to be led over motorways. Unfavorable is also that concreting is also used to support the home middle superstructure section connecting both cantilevers and closing the bridge special support structure to be erected is necessary. This increases the construction costs even further. Furthermore, each individual superstructure section must be separate

6 _S and clamped together with the previously completed part of the cantilever before the falsework trestles can be moved further. With this procedure, the preload

the structure of the finished bridge through the manufacturing process and less determined by actual loads in operation. Hence the bridge points usually more reinforcement and anchoring than necessary to guarantee the load-bearing capacity iiii operation would, because of the need, during all intermediate stages of manufacture in the Cantilever structure to ensure sufficient strength. This is particularly true in the case of wide areas Bridges. In addition, the course of the reinforcements is not such that an optimal preload distribution can be obtained during operation along the completed bridge, road or the like. Receives.

The invention is therefore based on the object of providing a low cost of supporting structures to be used and a time-consuming process for constructing the superstructure of a bridge or the like To create a structure made of prestressed concrete, which generally has a more favorable prestressing reinforcement in the structure results and can be avoided in the adverse effects on the supports in the construction state.

The object is achieved according to the invention in that the superstructure on the support frame at a distance erected above the pillars from prefabricated parts and at least one pillar each Associated section of the superstructure sliding or rolling until it comes into contact with the adjacent section moved and connected with it, and finally the entire superstructure was lowered onto the pillars will.

Because the pillars neither at the beginning nor during the time until shortly before completion of the entire structure are burdened with the structure itself, the construction time can be significantly shortened; because the construction work can begin before the pillars are erected or at least fully completed after erection are e.g. B. have tied. In addition, the pillars are no load forces during construction, Subject to vibrations and horizontal forces. The effort required for supporting scaffolding is low. The fact that the support frame does not progress with progressing construction time also has the effect of shortening the construction time The progress of construction must be relocated. Furthermore, one is hardly dependent on the use final prestressing reinforcement to determine the strength and load-bearing capacity of the structure ensure during the intermediate stages of manufacture. Therefore, the tendons can only after be drawn into the structure after completion. The number and course of the prestressing reinforcement can thus be determined freely and solely according to the fact that in operation along the finished Structure an optimal load from the prestressing distribution is ensured. The number of Tendons can be reduced to the necessary minimum. This achieves a high level of economic efficiency through optimal material utilization. By moving and connecting the pieces A special support frame is also omitted for one piece in the area of the part of the structure where this connection is to be made.

More finely, the invention relates to a Stülzge scaffolding for performing the above Procedure. It is characterized by having a horizontal platform is provided. on the vortical aligned support stands, of which at least some on their underside with a slide or Rolling device are provided. This ensures that the individual on these support frames Build up the superstructure sections and support them without putting a load on the pillar, and that the assembly the two individual structural parts can be carried out quickly and easily, too without putting any strain on the pillars and without erecting a special supporting structure in the connecting area to have to.

It can also be advantageous when used as a support frame on the one hand side by side, two one behind the other, arranged at a distance from each other Main trestles, which are provided with the sliding or rolling device, and on the other hand between the two main trestles standing one behind the other grouped, two auxiliary trestles each arranged are. This ensures that the distance between the rolling or sliding Main trestles, seen in the direction of the front, can be chosen to be relatively large, so that also very widely cantilevered sections can be safely and firmly supported by the support structure without the load possibly having to transfer to the pillars prematurely; because it can initially open a small section the auxiliary trestles are erected, if there is at least one of the distance between the main trestles has the appropriate length, passed by lowering the auxiliary trestles onto the main trestles so that it can be built very far on both sides. Thus, the invention Method and device with all the advantages associated therewith, even for very wide-ranging people Structures can be used where else - without the subdivision into main and auxiliary trestles - For reasons of load, possibly erect additional support scaffolding in the area of the cantilever ends would have to.

The jacks can be designed as hydraulically operated jacks, so that you can even with small dimensions and little construction effort take very large loads and the support frames but can be controlled very easily. The support frame can be temporarily attached to the respective pillar standing lattice girder and an auxiliary pillar supported in the subsoil near this pillar exist.

The method and apparatus of the present invention are made explained in more detail below with reference to an embodiment shown in the drawings. It shows or shows

Fig. 1 to 7 each in a schematic side view of the successive operations in Building a bridge,

Fig. 8, on a larger scale, a side view of a provisional building and support scaffolding, which in the Is arranged near a pillar and is used to carry out the method, and

FIG. 9 shows the top view of the support frame in FIG. 8.

Reference is first made to Figure 7 which shows the completed bridge.

This is a bridge with two pillars / 'and F. on which a continuous superstructure T shines, which has a central gap stretching between the two pillars / ·' and F and two side parts that extend on both sides of the central piece . This bridge is used for. B. as a railroad overpass over a road Λ with two lanes. With both ends of the superstructure T rests on an abutment C "or C \ die

arranged at the upper end of the two embankments that limit the road at these points.

The superstructure 7 consists of an association of many individual prefabricated prefabricated parts Κ ,, K ₂ , K ₃ ... K ₁ , K ₂ . V ₃ etc. formed from concrete, which by means of prestressing reinforcement, z. B. tension cables or tension ropes 1 and 2 are connected to each other. Each individual element, e.g. B. the prefabricated part K ₁ , has two opposite end faces. It is attached with one end face to the adjacent end face of the immediately adjacent, adjoining prefabricated part K ₂ . The end face of the prefabricated part K ₂ has the exact negative shape of the end face of the prefabricated part K ₁ , so that the two prefabricated parts K ₁ and V _{1 can be joined} according to the conjugate joint principle.

Reference is now made to FIGS. 8 and 9, which show, on a larger scale, a provisional building and scaffolding show which is used to carry out the manufacturing process of the bridge comes.

This support frame has two provisional supports on which an upper platform D rests precisely horizontally. The provisional support consists of a lattice girder B ₁ , which is provisional, but fixed, e.g. B. by means of prestressing rods 3, on one of the two bridge piers, z. B. is attached to the pillar P, which has already been created. The other temporary support consists of an auxiliary pier B ₂ , which is supported on the ground near the aforementioned bridge pier. The upper platform D consists of an assembly of two cross members, which are aligned parallel to the longitudinal extension of the superstructure.

On this upper platform D there are two groups of trestles, preferably each with hydraulic ones, exactly vertically Jacks, arranged, namely a group with four main jacks 11, 12, 13 and 14 and a group with four auxiliary support frames 21, 22, 23 and 24. To give numerical values by way of example assuming that the weight of each individual element z. B. is between 18 and 25 tons, come for the main jacks each lifting jacks with a capacity of z. B. 100 tons used, while those with a capacity of around 25 tons are used for the auxiliary support frames.

Each main trestle 11 or 12 or 13 or 14 is supported by a base He or 12 <i or 13a or 14a, which on the platform D by means of a sliding or rolling device 11 αα or 12αα or 13αα or 14αα, ζ. Β. a sliding pad made of a material with a low coefficient of friction, e.g. B. polytetrafluoroethylene rests. On this side, the Flattforni D itself is provided with a sliding track G with a low coefficient of friction. It goes without saying that these aforementioned sliding devices can also be replaced by rolling devices depending on the individual case, ζ. B. Ball systems. In this way, the main support frames 11 to 14 can slide or roll on the platform D in a direction that is parallel to the longitudinal direction of the superstructure and is indicated by the arrow F.

The auxiliary support frames 21 to 24 sit on the platform D without sliding devices or rolling devices being provided therebetween. The auxiliary racks 21 and 23 are carried by a common base 30, while the other two auxiliary brackets 22 and 24 are carried by a common base 31 of the same type. The auxiliary trestles are located between the main trestles on each side. They are accordingly, viewed in the longitudinal direction of the roadway, at a distance from one another which is smaller than that which exists on each longitudinal side between the two main frames provided there.

ίο The following are the successive ones on the basis of FIGS. 1 to 7 Operations for making the bridge described.

Fig. 1 shows a first phase in the workflow. After one has erected a provisional building and supporting scaffolding (corresponding to the one that has been explained with reference to FIGS. 7 and 8) in the vicinity of one pillar P, which is provided with its two trestle groups, one begins with the assembly of the four auxiliary support frames 21 to 24 a first

ao pre-fabricated part K _{1 to be placed} in the vicinity of said pillar P.

A further prefabricated part K ₂ , which is the individual element of the pillar, is then placed on one side of the prefabricated part K _{1 and both prefabricated parts K 1 are connected}

as and K ₂ by means of temporary fasteners 4, z. B. prestressing rods with each other. In order to avoid any risk of tilting with respect to the prefabricated part K ₁ under the weight of the prefabricated part K ₂ , which is freely cantilevered from the side of the former, the prefabricated part K ₁ can be temporarily anchored on the platform D, e.g. B. by means of prestressing rods not shown.

F i g. 2 shows a second phase in the workflow, which begins by placing a further prefabricated part K ₃ in relation to the prefabricated part K ₁ symmetrically to the prefabricated part K ₂ in place and that the prefabricated parts K ₁ and K. with the help of provisional fasteners 4 connects together. The association of these three prefabricated parts K ₁ , K ₂ and K ₃ is at rest

still on the four auxiliary support frames 21, 22, 23 and 24. You now transfer the entire load to the four main trestles 11, 12, 13 and 14, such that the four auxiliary trestles 21, 22. 23 and 24 are relieved, which are no longer involved during the further work sequences.

A further prefabricated part K _{4 is} then attached to the prefabricated part K _{3 in} a freely cantilevered manner and both prefabricated _{parts K 1 and K 4 are} connected with the aid of provisional fastening elements 4.

In Fig. 3 shows a third phase in the work flow ge, after which one continues to place more prefabricated «K ₅ , K ₆ , V .... , Above the platform D to place! and to be fastened provisionally, the individual elements always being supported by the main support frames 11

Support 12, 13 and 14 on platform D. May proceed in this way until one part of the roadway or the supporting beam has been put together in this way. the one section (consistently half) de: center piece and at least one section of the side part, which is assigned to the respective bridge arrows.

It can be seen, and this is essential, that the main trestles 11, 12, 13 and 14 are set in this way are that this aforementioned part of the road or the supporting beam on said main support buck rests, extends above the top of the bridge kenpfeilcrs and with this surface not ii Touch stands.

All the work processes that have been described above for H; ind I "ig. 1 to 3 for the production of the supporting beam, which is assigned to (lein pillar / ', are used for the production of the supporting beam, which is assigned to the milder pillar / -' , repeated, as shown in Fig. 4. This includes the prefabricated parts with K ,, V ₂ , Vt, ..., the lattice girder, the auxiliary pillar and the platform with K ₁ or K ₁ or AJ ', the The main supports are marked with 1Γ, 12 ', 13' and 14 'and the provisional support organs with 4'.

Fig. 4 shows a fourth phase in the workflow. The two parts of the superstructure are approached with the prefabricated parts V ₁ , V ₁ , K ₁ , K ₄ ... K ₇ and V _x , V ₂ , V \, V \ ... V ₁ , those assigned by the two temporary support structures are supported by their main support frames 11, 12, 13 and 14 and / or 11 ', 12', 13 'and 14' on their associated platforms I) or D ' sliding or rolling in the horizontal direction, until the facing end faces of the superstructure come into contact with one another. In order to achieve this horizontal displacement movement, it is sufficient to exert a relatively small horizontally directed force on at least one of these two upper components, because of the provided glcit pads Iiaa, Mau ... and the surfaces of the slideway (J. For this purpose, advantageously use a tie rod system or a system of horizontally directed support or displacement blocks, both not shown happens in the further workflow.

Fig. 5 shows a fifth phase in the workflow. at During this phase, the individual elements of the association formed by the two superstructures are attached which have been brought closer to one another in the manner explained above, finally to one another, in such a way that a continuous carriageway is formed. For this purpose, prestressing reinforcements are used, e.g. B. Spannkabcl or ropes 1, which are fundamentally different from the provisional fastening organs 4 or 4 'which have been explained above and which extend through the interior of the material which the prefabricated parts exist, extend through.

Then, if so desired, a part of the Assembly of the aforementioned provisional fasteners demonti <11.

In l'ig. A sixth phase in the workflow is shown. while the man. If necessary, the two side parts of the l'bcibau are completed by adding and attaching the outermost prefabricated parts K and V , which are to rest on the assigned outer abutments C and C ". Then one lays on the upper ropes

ίο the pillar / ^J and / '' each have an elastic plate 9 or 9 ', ■ / .. B. made of synthetic rubber, which has the task of acting as a pscudo joint in the completed building during operation. Then all main support frames 11, 12, 13 and 14 and 11 ', 12', 13 'and 14' are lowered in such a way that the entire structure of the continuous supporting beam forming the superstructure is lowered onto the two bridge piers. After that, all provisional fastening organs 4 and 4 ', which already after the fifth Phaj> e im

ίο workflow were no longer required, as well as the temporary support scaffolding, which are provided with their support frames, dismantled. All of these accessories or aids can be used in this way for making another. Bridge used again will.

in Fig. 7 the bridge is shown in the finished state. This also indicates further final prestressing reinforcements that also enforce the two outermost prefabricated parts V _y and V _11.

It can be seen from the explanation that in the case of the continuous superstructure T produced in this way, the structure of the final prestressing reinforcement plays no role in the stability and load-bearing capacity of the two supporting beams of the superstructure

j5 in the course of manufacture. It enables it is in this way that, as has been explained above, in a simple manner and under the best of circumstances Conditions relating to the distribution of the pre-tensioning the load-bearing capacity of the roadway during operation can be calculated and calculated.

In addition, a significant time saving can be recorded, once from a smaller number final prestressing reinforcements to be introduced and, on the other hand, comes from the fact that the classic marriage Wedge connection of the middle part of the roadway is omitted.

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1. A method for producing the superstructure of a bridge or similar structure made of prestressed concrete, which is designed as a continuous beam resting on at least two intermediate pillars and cantilevered in both directions with the help of a stationary support frame constructed from individually manufactured parts in the longitudinal direction from one pillar in each case is pre-built, characterized in that the superstructure (T) is erected on the support structure at a distance above the pillars ( P or F) from prefabricated prefabricated parts ( V _x to V _n or V ₁ ' to V _n ') and at least one in each case Tdlstück of the superstructure assigned to a pillar is moved sliding or rolling until it comes into contact with the adjacent section and connected to it and finally the geiiamte superstructure is lowered onto the piers (P and F). 2. Support frame for carrying out the method according to claim I, characterized in that it is provided with a horizontal platform (D or D ') on which vertically oriented support frames stand, at least some of which are on their underside with a sliding or rolling device (llaa to 14a «) are provided. 3. Support frame according to claim 2 _: characterized in that as support frames on the one hand side by side two consecutive, spaced-apart main trestles (11 to 14 or 11 'to 14'), which with the sliding or rolling device (llaa to 14 aa) are provided, and on the other hand, grouped between the main trestles standing one behind the other, two auxiliary trestles (21 and 23 or 22 and 24) are arranged. 4. Support frame according to one of claims 2 or 3, characterized in that the support brackets are designed as hydraulically actuatable lifting brackets are. 5. Support frame according to one of claims 2 to 4, characterized in that it consists of a standing lattice girder (B ₁ or B ₁ ' ) temporarily attached to the respective pillar (P or F) and an auxiliary pier (B ₂ or A ₂ ') supported in the subsoil near this pillar ) consists.