NO168136B - PROCEDURE FOR AA REGULATING TEMPERATURE IN FUEL-FURNED OVEN - Google Patents

Description

Method and device for section production of the superstructures for a multi-span bridge made of reinforced concrete or prestressed concrete.

The invention is based on a method and a device for sectional production of the superstructures for a multi-span bridge of reinforced concrete or prestressed concrete using a superstructure girder arranged above or below the superstructures.

It is already known to produce the superstructures for a multi-span bridge section by section from a free-supporting front structure girder which is arranged above or below the superstructures and during the manufacture of the individual superstructure sections rests against the final bridge pillars. After a superstructure field has been completed, the superstructure girder is driven forward into the next free field.

The use of such front building girders has that advantage

that there is no need for fixed scaffolding to stand against

the valley floor, and which entail high costs and are also not applicable - in cases where the bridge spans a very deep valley or runs over impassable terrain.

In order to keep the equipment costs for the sectional manufacture of the superstructures for a multi-span bridge by means of a superstructure girder as low as possible and to achieve particularly fast progress in the construction work, it has already been proposed to support the rear end of the superstructure girder on an already manufactured superstructure section and to store the girder approximately at the middle of the next pillar in the front building direction, so that the girder protrudes into the next free superstructure field. The superstructures are then produced in sections to both sides from the pillar until one superstructure field is closed and the superstructure of the next field is produced approximately to the middle of the field. The front building girder is then driven to the next field, so that the next superstructure sections can be manufactured in the same way.

Although the front construction. of the individual superstructure sections

until both sides starting from the pillar by this known method take place symmetrically, the facade girder, as a result of its static system as a free-standing girder with a projecting arm, is exposed to an asymmetric deformation from on the one hand the facade sections that hang in the projecting arm, and on on the other hand, the front building sections that hang in the field between the two supports of the girder. However, this asymmetric bowing of the front girder is

without significance as long as the parts of the superstructure that protrude to both sides from the pillar are pivotably supported on this pillar during the construction process and are suspended from the front structure girder in its field only for stabilization. The interconnected parts of the superstructure can then under the building swings around its pivot bearing on the pillar and aligns itself corresponding to the asymmetric bowing of the front building girder.

If, however, the superstructures are to be clamped into the bridge piers, i.e. are rigidly connected to these, so that they either

cannot perform any swinging movement during the construction process, the unsymmetrical deformation of the superstructure girder must be taken into account when constructing the individual superstructure sections. This entails the use of more complicated constructions, e.g. arrangement of adjustable supports at the rear end of the front girder.

The purpose of the invention is to circumvent these difficulties and, when manufacturing superstructure parts that are clamped in the pillars, to store the front structure beam so that it is only deformed symmetrically, while retaining all the advantages of the known method described above.

According to the invention, this task is solved by the fact that the front structure girder is stored on at least two posts that stand at a distance from each other in the longitudinal direction of the bridge, on one of the pillars,

respectively a superstructure section rigidly connected to this buoying, and projects freely to both sides in the longitudinal direction of the bridge from these points.

This device has the advantage that there is no turning of the front girder, and that the deflection of the front girder when the individual girder sections are symmetrically advanced is always the same on both sides of the respective pillar and can be compensated by simple shortening of the suspension rods which are attached to the front structure girder, and which carry the platforms for the respective superstructure sections that are to be stopped or assembled as finished parts. "

In order that the bearing moment for the front structure girder does not become too great, this can, according to the invention, at its freely projecting ends, also be stored on bearing trestles on already finished superstructure parts that protrude from the pillar.

In order for the superstructure girder to be able to be pushed forward without difficulty in the longitudinal direction of the bridge after a superstructure field has been completed, the struts and bearing trestles are designed as sliding chairs or rolling trestles that allow a displacement of the front structure girder in the longitudinal direction of the bridge. To compensate for the elastic deformation of the front structure girder, the supports and/or the bearing frame can be adjustable in height.

When manufacturing the superstructures for a multi-span bridge

of reinforced concrete or prestressed concrete, the process according to the invention is that the front structure girder is first brought into position over the respective bridge pillar on the abutments and the superstructure section lying above the pillars is made from the front structure girder, and that the adjacent superstructure sections are then made in turn at the same time on both sides in the longitudinal direction of the bridge.

By arranging intermediate supports, the bearing trestles that support the projecting ends of the front structure girder can be moved further to the end of the completed superstructure section after the completion of each superstructure section. Thereby, it is achieved that the downward deflection of the forward structure girder changes only slightly from one forward structure section to the next, as the weight arm of the load is always the same.

After the superstructure parts projecting from one pillar have been produced up to the middle of the adjacent superstructure fields, the superstructure girder can be pushed forward on the supports and bearing trestles in the longitudinal direction of the bridge and brought into position on the next pillar.

The invention will now be described in more detail under reference

to the drawing, which shows an exemplary embodiment.

Fig. 1 shows a section of a multi-lane bridge in a first

construction phase in plan.

Fig. 2 shows the bridge in fig. 1 in an intermediate stage, where

the extension girder is pushed forward in the next field.

Fig. 3 shows the bridge in fig. 1 in another construction phase.

In the drawing, 10 denotes a girder bridge which extends over several bays 11, 12, 13 and whose superstructure bays, 14# 15» 16 are made of reinforced concrete and are rigidly connected to the counter bearings 17 and pillars l8-6g 19.

Each of the superstructure fields 14, 15 and 16 consists of two superstructure parts 14a, 14h, resp. 15a, 15b: and l6a, l6b, which are produced in individual sections 1, 2, 3 °g 4 in turn simultaneously out to both sides from the respective pillar 18, resp. 19" in connection with the superstructure part 0 lying above the pillar by means of a front structure girder 20. The bridge pillars 18 and 19 are in the embodiment shown designed as double struts which are arranged at a distance from each other in the longitudinal direction of the bridge and are connected above with the one above the pillar horizontal superstructure section 0.

The front building girder 20 is designed as a three-dimensional truss girder. It can also be designed as dragons with dense walls (Vollwandtrager). In both cases, the cross-sectional design must be adapted to the conditions. During the production of the superstructure section 1# 2, 3 and 4, the front structure girder 20 is stored on two supports 21 which are arranged at a distance from each other in the longitudinal direction of the bridge above the respective pillar 18, resp. 19 on the superstructure section 0 which is rigidly connected to the pillar. The girder projects freely to both sides from these points in the longitudinal direction of the bridge, and the overall length of the girder is somewhat greater than the span of one of the superstructure sections 14# 15 and 16. The freely projecting ends 20a and 20b of the front building girder 20 can further, depending on how far the building work has progressed, stand against already manufactured superstructure parts 14b, 15a, resp. 15b, l6a, which protrude from the pillar 18, resp. 19" Stetten' "-21 and the bearing trestles 22 are

designed as sliding chairs or rolling trestles.

The front building girder 20 carries in each field on each side

of the bridge pillar 18 which carries the girder, a front construction carriage 23 which grips over the front construction girder 20 and can be driven along the bottom girder of the front construction girder with the help of a driving frame 24. The P& front construction carriages 23 are again there by means of height-adjustable suspension rods 25 attached to platforms 26 which carry the formwork for the fresh concrete or ready-mixed concrete

the parts for the superstructure sections 1, 2, 3 and 4 to be produced.

The production of superstructure fields 11, 12 and 13 for

bridge 10 takes place in the following way:

First, the counter bearing 17 and the first bridge pillar 18 are set up and the superstructure part 14a is produced section by section from the counter bearing.

For this, the front building girder 20 can be used, and this preferably supports itself with its one end 20b on the counter bearing 17 and with its other end 20a on the pillar 18, resp. the over this pillar lying superstructure section ion 0. The" over the pillars Uggend superstructure sections can be produced with the help of a special formwork scaffold which is "suspended on the bridge pillar for the front structure girder to be lowered onto this. However, it is more appropriate to raise the pillars' double uprights up to the upper edge of the bridge superstructure and stiffen them above using a yoke 18', resp. 19' and stop the superstructure section 0 from the front structure girder 20, which via the struts 21 rests directly on the pillar heads 18a, resp. 19a.

As soon as the superstructure part 14a has been completed, the front structure girder 20 is pushed forward in the longitudinal direction of the bridge until its center of gravity lies above the pillar 18 and the girder occupies it in fig. 1

displayed position. Below this, the girder is initially only supported via the supports 21 on the superstructure section 0 or, when the superstructure section 0 is produced from the front structure girder only after this has been brought into position, directly on the uprights for the pillar 18.

Then the superstructure sections 1, 2, 3. and 4 of the superstructure parts 14b and 15a are stopped in turn simultaneously out to both sides from the pillar 18, under which the platforms 26 bear the weight of the fresh concrete in the respective front construction sections until these are sufficiently bound. The extension sections are then clamped and anchored against the already manufactured superstructure parts, so that the platforms 26 can be lowered and driven forward with the extension carriages 23

for the production of the next superstructure section. As the manufacture of the superstructure sections 1, 2, 3 and 4 progresses, the front structure girder 20 is supported via bearing trestles 22 by its free

end on the already manufactured superstructure parts 14b and 14a. These storage trays are pushed to the end each time they are finished.

stilted superstructure parts 14b and 15a. To allow correction of the platform's height and adaptation to the lowering of the forward buoyancy s-

the girder 20, the supports 21 and the bearing brackets 22 are adjustable in height.

After the superstructure parts 14b and 15a have been completed,

set, an anchorage 30 is placed on the superstructure part 14a

which acts on the superstructure part 14b, and which can be sloyed if the joint

the construction allows this. The front structure girder 20 is then pushed further forward in the longitudinal direction of the bridge on the supports 21 and the bearing trestle 22 arranged on the superstructure part 15a until it reaches the pillar 19 and can be set down with its front end on a support 21 which is arranged above the pillar 19* This intermediate stage is shown in fig . 2.

The front building girder 20 is then pushed even further

up to the one in fig. 3 shown position. After the superstructure section 0 lying above this pillar has been stopped, the superstructure sections 1, 2, 3 and 4 of the superstructure parts 15b and 16a can be produced as described above. When building the subsequent superstructure fields of the bridge that are not shown in the drawing, proceed in the same way until the entire bridge is finished.

The invention is not limited to the embodiment shown

Example. Thus, the front structure girder 20 can also be arranged under the superstructure, and these can instead be stopped in place as well

are produced from ready-to-stop concrete sections.

Under special circumstances, it may also prove expedient

appropriate, at least periodically, to support one of the freely projecting ends of the front building girder via a bearing trestle on an already completed superstructure part that protrudes from the neighboring pillar.

Claims (6)

1. Device for sectional production of the superstructures for a multi-span bridge made of reinforced concrete or prestressed concrete, consisting of a front structure girder arranged above or below the superstructure, characterized in that the front structure girder (20) is supported on at least two supports (21) which stand at a distance from each other in the bridge's (10) longitudinal direction, on one of the pillars (18, 13) t resp. a superstructure section (0) rigidly connected to this buoyancy, and protrudes freely to both sides in the longitudinal direction of the bridge from these supports (21). 2. Device as specified in claim 1, characterized in that the front building girder (20) with its freely projecting ends (20a, 20b) is supported via bearing trestles (22) on already finished superstructure parts (14b, 15a, resp. 15b, l6a) which protrudes from the pillar (18 or 19). 3. Device as set forth in claim 1 or 2, characterized in that the supports (21) and the storage trestles (22) are designed as sliding chairs or rolling trestles which allow displacement of the front structure girder (20) in the longitudinal direction of the bridge. 4. Device as specified in one of claims 1-3, characterized in that the supports (21) and the bearing brackets (22) can be adjusted in height to compensate for the elastic deformation of the front structure beam (20). 5. Method for section development of the superstructures for a multi-span bridge of reinforced concrete or prestressed concrete using a device according to one of claims 1-4, characterized in that a front structure girder (20) is first brought into a position above a bridge pillar (18 or 19) where it protrudes freely to both sides from two supports (21) arranged at a distance from each other, and the superstructure section (0) lying above the pillar (18 or 19) is made from the front structure girder (20), and that the adjacent superstructure sections ( 1, 2, 3, 4) then, which is known in and of itself, are produced in turn at the same time to both sides in the longitudinal direction of the bridge, under which the projecting ends (20a, 20b) of the front structure girder (20) after completion of each superstructure section are supported by storage trestles (22) which, in accordance with the progressing construction work, are moved further to the end of the completed superstructure section (14b, 15a, resp. 15b, l6a). 6. Method as stated in claim 5, characterized in that the front building girder (20) after the superstructure parts (14b and 15a) projecting from a pillar (18) have been produced up to the middle of the adjacent superstructure fields, is pushed forward on the supports (21) and the bearing trestles (22) in the longitudinal direction of the bridge and are brought into position on the next pillar (19).