DE1255695B - Method and device for the construction of multi-span bridges or similar structures in sections - Google Patents

Description

Method and device for the production of multiple fields in sections Bridges or similar structures The invention relates to a method and a Device for the construction of multi-span bridges or the like in sections Structures made of reinforced or prestressed concrete, in which the superstructure sections are separated from the Pillars can be built from both sides at the same time.

In a known method of this type, the individual superstructure sections concreted on a falsework trestle, which is supported on one on the valley floor fixed substructure can be moved. This makes it possible, proportionally build long superstructure sections; however, the known method is then not applicable when the bridge spans a very deep valley or through impassable areas Terrain leads.

It is also used to create a multi-span bridge that has been built over already known to use scaffolding that is arranged above the superstructures, is supported on three successive bridge piers and thus two bridge fields spanned at the same time. With this framework, one field after the other is created in the Manufactured in such a way that of the two pillars delimiting the field to be produced from being built in sections at the same time until the field is closed. at In this process, the bridge piers are one-sided during the construction phase, that is asymmetrically loaded. The resulting moments in the pillars must through special measures, for example through a temporary mutual Support of the two pillars. In addition, the device requires large construction costs as it has to span two overbuilding fields in order to be advanced to be able to. It must also be very strong, since it is in a field Has to bear the loads of the fresh concrete from two superstructure sections each.

The object of the invention is to provide a method and a device, with which the built over a multi-span bridge made of reinforced concrete or prestressed concrete quickly with only low equipment costs without the use of subsurface supports Have scaffolding made. This object is achieved according to the invention by that a cantilever, displaceable scaffolding is used to build the superstructure sections in front is used, which is on the one hand on the already completed, from a support cantilevered superstructure part or on this support itself and on the other hand is supported on the following pillar from which it was built and beyond which it protrudes freely into the next field during the front end.

This method has the advantage that there is no support on the ground long superstructure sections can be made. The scaffolding only suffers low elastic deformations and can be made relatively light, because the superstructures support the scaffolding in its central area Piers can be made from simultaneously progressing on both sides and the scaffolding in each bay is loaded with the weight of only one superstructure section. The type of front structure of the superstructure also allows the scaffolding with its rear End to be supported on the already completed superstructure part and also between to move the production of the individual superstructure sections in the longitudinal direction. The span of the scaffolding can be varied in this way and the occurring Stresses are adapted. Here it is possible to advance the scaffolding so far that that it has its rear end at the very edge of the already completed, is supported by the adjacent support protruding superstructure part. As a result, the span of the scaffolding in the field is only slightly more than half the span of the superstructure and thus also the maximum field moment occurring in the scaffolding decreased.

The framework can be both above and below the one to be produced Be arranged bridge superstructure.

The special type of front structure allows the scaffolding to be pushed further into the next free space too then when the total length of the scaffolding is only about 1.1 to 1.2 times the bridge span.

According to the invention, in addition to those to be built from a support superstructure sections also the middle section closing the respective bridge field can be made using the scaffold. If the superstructure sections in Made in-situ concrete, the individual superstructure sections can each have their own in the front end in the direction of the front end towards the already completed The superstructure part is concreted on concreting platforms, one end of which is attached to the already completed superstructure part attached and with its other end on the scaffolding are attached. By this measure, the influence of the deformations of the formwork and the scaffolding switched off during concreting at the connection point. Of the The freshly concreted part is connected to the already hardened superstructure part so only when almost all of the concrete of the section to be concreted has been poured and the expected deformations of the formwork and the scaffolding are almost theirs Have reached their final value. In this way it is prevented that in the concreting joint Movements or at least undesirable tensions in the setting concrete occur when concreting from the concreting joint as a result of the constantly The increasing load of the fresh concrete causes changes in the deflection of the Scaffolding inevitably enter. The superstructure sections can also be made from prefabricated components exist, which are connected to the respectively completed superstructure part. Through this a particularly rapid construction progress can be achieved.

With the method according to the invention it is possible to build bridge superstructures to produce in sections that are not clamped in the supporting pillars, but are mounted on this tiltable. The one from the pillar from which it was built already finished superstructures are here, cantilevering on both sides during the construction of further superstructure sections by supporting them against the scaffolding and / or stabilize the pillar. A support against the scaffolding is possible, because this is stable and the superstructures are symmetrically built in front of the pillar will.

It is particularly useful to stabilize the pillars Superstructure parts cantilevered on both sides during the pre-construction of the superstructure sections and possibly during the installation of the middle section on the in the direction onto the already completed superstructure protruding from the pillar Apply ballast and attach this superstructure part to the scaffolding with hanging rods. In this way, the completed superstructures can withstand elastic deformations follow the scaffolding, but do not tilt, as the weighted end of the scaffold is on the scaffolding hang on its mutually supported part.

Instead of attaching the completed superstructure parts to the scaffolding, you can see the ones under construction that protrude from the pillar on both sides Stabilize superstructures also by temporarily clamping them to the supports.

To practice the method according to the invention, a cantilever, Proposed in the longitudinal direction of the bridge movable scaffolding, the length of which is something is greater than the span of a bridge span. Leave with such a scaffolding concrete over the greatest length. Nonetheless, the structural effort is not large for the scaffolding, as its length is not much greater than the span of a bridge field and it is favorably stressed in the concreting position.

It is particularly useful to give the frame a triangular cross-section admit. As a result, the frame has a high weight with a relatively low weight Moment of resistance and a great torsional, rigidity and offers in its interior enough space for the transport of building materials in the longitudinal direction of the bridge.

Furthermore, the frame can at its rear end in the feed direction a support firmly connected to it and means in its middle area for support on a support which is fixedly arranged above the next pillar exhibit. There is no need to move the scaffolding in the longitudinal direction of the bridge Trouble.

To produce the individual superstructure sections, the scaffolding symmetrically to its support on the pillar, from which towards both Sides is built in front, movable concreting platforms are attached. The concreting platforms, which can accommodate the formwork of the respective superstructure sections to be produced Have means with which they are attached during the production of the superstructure sections one end attached to the scaffolding and at the other end to the one in front of it, already completed superstructure part are firmly connected. That way is a precise connection of each new superstructure section to the already completed one The superstructure component is guaranteed, as none of the deflection of the Movements originating from the scaffold can occur. In the same way you can also use the production of the middle section are proceeded.

When making the middle section and when stretching the framework it is advisable to attach one of the concreting platforms to the scaffolding in such a way that that it acts as a. relieving counterweight.

Further features of the invention are the subject of claims 14 and 16.

An exemplary embodiment of the invention is shown in the drawing. It shows a schematic representation of F i g. 1 the construction of a bridge in which a pillar is built in sections on both sides, FIG. 2 shows a representation after completion of the front end of this superstructure part and FIG. 3 the framework while it is being advanced. After completion of the pillars 1, 2 and 3, the superstructure sections 4, 5 and 6 above the pillars were concreted. A stationary cantilever frame 7 is used for this purpose. According to FIG. 1, the superstructure in bridge field 8 and a superstructure part with the superstructure sections 9, 10, 11 and 12 in bridge field 13 have already been completed. Then the scaffolding 14 has been brought into the position required for the pre-construction of the superstructure sections to be produced from the pier 2, in which it is placed on the already completed superstructure component consisting of the superstructure sections 9, 10, 11 and 12 by means of a support 15 and on the superstructure section 5 is mounted above the pillar 2 by means of a support 16 and protrudes beyond the pillar 2 into the bridge field 17. The support 15 is firmly connected to the framework 14 so that it is advanced as part of the framework when it is advanced.

In the case of the pre-construction in sections from the pier 2, the superstructure sections 18 and 18 ' are first produced. F i g. 1 shows the production of the subsequent superstructure sections 19 and 19 '. On the frame 14 slide on rails or the like superstructure, which are not shown in the drawing. Hanging rods 22 and 23 are attached to these, which are designed, for example, as threaded rods or their height can be adjusted by hydraulic presses. The suspension rods 22 and 23 each take over the proportional load of concreting platforms 20 and 21 at their front ends in the pre-construction direction. At their rear ends, the concreting platforms 20 and 21 are firmly connected to the already completed superstructure sections 18 and 18 ' via suspension rods 24 and 25, as well as buckling traverses or the like (not shown in the drawing). It is thereby achieved that the frame 14 only has to absorb approximately half the weight of the superstructure sections. Advantageously, the sections will be concreted from the front ends in the pre-construction direction to the superstructure sections 18 and 18 ', whereby a perfect connection of the superstructure sections 19 and 19' to the superstructure sections 18 and 18 'is guaranteed, regardless of the extent to which the scaffolding 14 deforms under the concreting load, since the changes in shape of the scaffolding during concreting in the joint between the individual superstructure sections have no influence. The correct height of the front ends of the superstructure sections 19 and 19 'is set by shortening the hanging rods 22 and 23, respectively, in order to compensate for the deformation of the scaffolding. Since both sides of the pillar 2 are being built in front at the same time, the field moment of the scaffolding remains only small, since it is counteracted by the moment from the load on the cantilever arm. The framework can therefore be made relatively light. Nevertheless, it can be used to produce large front sections, for example from 10 to 20 m in length. This shortens the construction time.

From one pillar to both. Pages is built in front at the same time and the scaffold 14 is supported with its rear support 15 on the already completed superstructure part, its total length is relatively small .. It only needs to be about 1.2 times the bridge span width.

The simultaneous pre-building on both sides of the pillar still offers the advantage that due to the cantilever load on the frame 14 of the already completed Superstructure part is only slightly loaded by the support 15.

To stabilize the superstructure part under construction, temporary restraints 26 are arranged on the supports. Effective stabilization is also achieved in that, as shown in FIG. 1, the already completed superstructure part lying between the hanging rods 24 and the pillar 2 is loaded with ballast 27 and is attached to the frame 14 by means of special hanging rods 28. Ulan can also do without the ballast27 and achieves the same effect, for example, if the individual superstructure sections 1.8, 19, 29 and 30 are designed in such a way that the superstructure part consisting of these sections is slightly heavier than the superstructure part opposite it.

After the superstructure sections 19 and 19 'have hardened and connected to the previously completed superstructure sections 18 and 18' , the concreting platforms 20 and 21 are lowered, and the suspension rods 24 and 25 , as well as the suspension rods 22 and 23, are attached to the superstructure which are slidable on the frame 14 on rails or the like. The concreting platforms 20 and 21 are then moved forward on the scaffolding 14 and brought into the position required to produce the superstructure sections 29 and 29 ', which is the position shown in FIG. 1 corresponds to the position shown for producing the superstructure sections 19 and 19 '.

The construction processes described above are repeated until the last superstructure sections 30 and 30 'have been produced. After these sections have been completed, the pouring platform 20 is moved into the position shown in FIG. 2 brought the position shown in order to produce the middle section 31. In this case, the concreting platform hangs on the one hand by means of the hanging rods 24 on the framework 14 and, on the other hand, firmly fastened to the superstructure section 12 by means of the hanging rods 22.

The hanging rods 22, 23, 24 and 25 are so long that they can either be attached to the superstructure of the scaffolding 14 or to a strap-on traverse on the completed superstructure part.

During the production of the middle section 31, the concreting platform 21 is already detached from the superstructure section 30 ′ and hangs on the scaffolding 14 as a relieving counterweight.

F i g. 3 shows the advancement of the scaffolding 14 after the bridge field 13 has been closed. Here, the concreting platform 21 is temporarily attached to the superstructure section 18 ' to relieve the scaffolding, while the platform 20 is attached to the rear end of the scaffolding 14 as a counterweight. Then the frame 14 is advanced over the bridge field 17 by means of hydraulic presses, winches or the like on the support 16 arranged above the pillar 2 and a support 32 mounted on the end of the cantilever arm until it reaches a support 33 mounted on the pillar 3. The concreting platform 21 can now be attached to the scaffolding 14 again. It is advantageous to provide the platforms with bottom flaps which are opened when the pier heads are passed, so that the forwards of the platforms, for example from the bridge field 13 into the bridge field 17 and further into the bridge field 34, does not cause any difficulties. After being advanced, the framework 14 rests on the supports 32 and 33 or on the support 15 now located at this point and protrudes beyond the support 33 into the bridge field 34.

The scaffolding can also be used as a transport bridge, so that the material transport is completely independent of the terrain. All needed Materials can therefore be used from one end of the bridge over the already finished superstructure parts and the scaffolding can be transported to the installation site.

Claims (16)

Claims: i. Procedure for the sectional manufacturer of multi-span bridges or similar structures made of reinforced or prestressed concrete, in which the superstructure sections from the pillars both sides are progressively built in front at the same time, characterized in that that a cantilever, movable scaffold (14) is used, each on the one hand on the already completed; from a support cantilevered superstructure part or on this support itself and on the other hand is supported on the following pillar from which it was built and beyond which it protrudes freely into the next field during the front end. 2. The method according to claim 1, characterized in that the respective bridge field (8 or 13 or 17) closing middle section (31) also using of the framework (14) is made. 3. The method according to claim 1 or 2, characterized characterized in that the superstructure sections are made in in-situ concrete. 4. Procedure according to claim 3, characterized in that the individual superstructure sections each from its front end in the pre-assembly direction in the direction of the already completed one The superstructure part can be concreted on concreting platforms, i.e. with one end at the already completed superstructure part attached and with its other end on the scaffolding are attached. 5. The method according to claim 1 or 2, characterized in that the superstructure sections consist of prefabricated components, which are linked to the completed Superstructure are connected. 6. The method according to any one of claims 1 to 5, characterized It is indicated that the pillar (2), from which the construction is carried out, is on both sides cantilevered, already completed superstructure parts during the front construction of further Superstructure sections stabilized by supporting them against the scaffolding and / or the pillar will. 7. The method according to claim 6, characterized in that for stabilization the superstructure parts protruding from the pillar (2) on both sides during the Front construction of the superstructure sections and, if necessary, during the installation of the central section applied to the backward cantilevered superstructure part ballast (27) and this Superstructure part with hanging rods (28) is attached to the scaffolding (14). B. procedure according to one of claims 1 to 6, characterized in that from the pillar (2) overhanging parts under construction that protrude on both sides through a temporary restraint on the supports are stabilized. 9. Device for practicing the method according to one of claims 1 to 8, characterized by a cantilevered frame (14) which can be moved in the longitudinal direction of the bridge and whose Length is slightly larger than the span of a bridge span (13 or 17). 10. The device according to claim 9, characterized in that the device (14) has a triangular cross-section. 11. The device according to claim 9 or 10, characterized in that the frame (14) at its rear end in the feed direction has a fixedly connected support (15) and in its central area means for supporting on a post above the next pillar (2) having fixedly arranged support (16). 12. Device according to one of claims 9 to 11, characterized in that on the frame (14) symmetrically to its support (16) on the pillar (2), from which is built from each to both sides, movable concreting platforms (20 and 21) for producing the individual superstructure sections (18, 19, 29 and 30 or 18 ', 19', 29 'and 30') are attached. 13. The device according to claim 12, characterized in that the concreting platforms (20 and 21), which receive the formwork of the respective superstructure sections to be produced, have means with which they are attached at one end to the frame (14) during the production of the superstructure sections and at their other end are firmly connected to the already completed superstructure part in front of it. 14th Device according to claim 13, characterized in that the concreting platforms (20 and 21) hanging rods (22 and 24 or 23 and 25) formed in this way are that they are either on the scaffold (14) or on an already completed Buckle crossbars mounted on the superstructure can be attached. 15. Device according to one of claims 9 to 14, characterized in that in each case one of the Concreting platforms (20 or 21) when making the middle section (31) and when stretching of the frame (14) is attached to the frame so that it acts as a relieving counterweight works. 16. Device according to one of claims 9 to 15, characterized in that that on the frame (14) hanging rods (28) are arranged on which the completed Superstructure parts are attached. Publications considered: Österreichische U.S. Patent No. 217,082; Magazine "Beton und Eisen", 1938, p. 53; magazine "Bauplanung-Bautechnik", 1957, pp. 410 to 412; Polensky & Zöllner, »Messages on completed buildings ”, September 1961, pp. 3 and 4.