DE29908482U1 - Cap shutter device - Google Patents

Description

DE 7751 .:. JPaientarrwalt

Graduate Physicist

Reinfried Frhr. v. Schorlemer

Karfhäuserstr. 5A 34117 Kassel Germany

Telephone (0561) 15335

(0561)780031

Fax/Telecopter (0561)780032

Gerdum u. Breuer GmbH u. Co KG, 34123 Kassel

Cap formwork device

The invention relates to a cap formwork device of the type specified in the preamble of claim &Ggr; for the production of cornice caps on bridge structures.

Road and motorway bridges are usually provided with so-called cornice caps on both side edges, which serve to limit the side of the bridge and/or to separate the walkways from the roadway. The caps are made of reinforced concrete, which requires extensive and labor-intensive formwork work. Another problem is that walkways or work platforms or similar have to be erected on the outside and underside of the edge of the bridge for the workers involved in the formwork and concreting work in order to keep the areas, e.g. 2.5 m wide, that are provided with formwork and are to be poured with concrete clear. Apart from that, this type of formwork and concreting work is not without danger, especially if it has to be carried out at great heights.

By using known assembly carriages that can be moved in the longitudinal direction of the bridge and are equipped with support structures that overhang the edge strips and support work platforms, the known problems can be reduced but not eliminated, since such assembly carriages only allow the attachment of short formwork sections and must often be moved in the longitudinal direction of the bridge. Apart from that, setting up the entire formwork from such assembly carriages is laborious and time-consuming.

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Cap formwork devices of the type described at the beginning have therefore already become known, in which, in addition to the working platform, a front and bottom formwork beam and the formwork or mold boards connected to them are attached to the supporting structure. The supporting structure is suspended on outriggers extending transversely to the longitudinal direction of the bridge and can be moved parallel to the outriggers or moved back and forth between a formwork and a stripping position using threaded spindles and the handwheels assigned to them. The end formwork beam is fixed and attached to the supporting structure in such a way that the formwork boards attached to it automatically assume a position suitable for pouring the caps after the supporting structure has been moved to the formwork position. In contrast, the bottom formwork beam and the formwork boards attached to it are pivotable and mounted on the supporting structure in such a way that they can be pivoted into a formwork position after they have been moved to the formwork position and fixed in this position. It is therefore possible to effect the formwork by moving the supporting structure into the formwork position and then swiveling the bottom formwork support forwards, while for stripping the formwork the bottom formwork support is first swiveled back and then the supporting structure is moved into the stripping position.

A particular advantage of the cap formwork device described is that several carriages and supporting structures, e.g. each 4 m long, can be connected to one another in the lengthwise direction of the bridge, so that, for example, 20 m to 30 m long or even longer sections are created with correspondingly long formwork supports and work platforms, which makes the formwork installation and removal work much easier. One problem with such a cap formwork device, however, is that it requires a lot of manual work, operating the handwheels and pivoting the bottom formwork supports is laborious, the individual spindles have to be readjusted every time the associated end formwork supports are moved, and to increase stability, additional supports are required, the feet of which are placed in areas of the edge sections that will later be filled with concrete, so that these feet have to be pulled out of the finished caps again after the concreting.

The invention is therefore based on the object of improving the cap formwork device of the type described above in such a way that the formwork installation and removal work can be carried out more easily and quickly and, above all, the number

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manual activities are reduced.

The characterizing features of claim 1 serve to solve this problem. Advantageous further developments of the invention emerge from the subclaims.

The invention has the advantage that the supporting structure is driven by electrical, hydraulic and/or pneumatic means and therefore does not need to be moved manually. Since the supporting structure is also pivoted instead of just moved linearly, the bottom formwork carrier can be firmly attached to the supporting structure and brought into a formwork or dismantling position simply by pivoting it. Finally, the invention has the advantage that the cap formwork device can be used not only to produce edge caps, but also, with minor modifications, to produce center caps.

The invention is explained in more detail below in conjunction with the accompanying drawings using exemplary embodiments. They show:

Fig. 1 and 2 each show a vertical section through a bridge and a front view of a cap formwork device according to the invention that can be moved on the bridge, in a formwork-on and a formwork-off position, respectively;

Fig. 3 to 5 each show a top view, a side view, viewed from the right in Fig. 1, and a section along the line V-V of Fig. 1 of the capping device according to Fig. 1 and 2 without the bridge; and

Fig. 6 is a view corresponding to Fig. 1 of a second embodiment of the cap scarf device according to the invention.

Fig. 1 and 2 show in vertical section the right part of a bridge 1, in particular a cantilever arm 2, which is to be provided with a cap 3 made of concrete, which is applied to the outer edge strip of the cantilever arm 2 in a width of e.g. 2 m to 3 m. Depending on the design, the cap 3 can be in a

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The area projecting beyond the cantilever arm 2 may have a stool 3a and a section 3b underneath it that extends to the underside of the cantilever arm 2, the underside of which is bevelled outwards and downwards so that rainwater or the like can drip off.

To produce the cap 3, it is necessary to provide a so-called front formwork 4 from the outside, a so-called bottom formwork 5 from below and, if the hump 3a is present, also a so-called side formwork 6 from the inside. In addition, an inner formwork 7 is installed, which can be placed on the top of the bridge and does not cause any particular problems since, unlike the formwork 4, 5 and 6, it is easily accessible. In a formwork position (Fig. 1), the formwork 4 to 7 delimit a space which is filled with concrete to form the cap 3.

The cap formwork device according to the invention, shown for example in Fig. 1 to 5, serves to facilitate the formwork installation and removal. It contains a carriage 10 with running wheels 11, which run, for example, on two conventional crane rails 12 laid parallel to one another, which are laid with anchors on the top of the bridge, run in the longitudinal direction of the bridge 1 and have a preselected distance from the outer edge of the cantilever arm 2. This is chosen to be so large that the outer guide rail 12 is somewhat further away from the outer edge of the cantilever arm 2 than is the case for the inner formwork 7, so that the area to be occupied by the cap 3 remains free.

Furthermore, the carriage 10 consists, for example, of four vertical supports 14 and 15 arranged in the corners of a rectangular floor plan, with the two supports 14 arranged inside and the two supports 15 outside and each provided with one of the running wheels 11 on their undersides. The two supports 14 and 15 arranged one behind the other in the direction of the running rails are connected to each other in pairs by upper and lower horizontal spindle struts 16 and 17 respectively. The length of the spindle struts 16 and 17 respectively can be changed in a manner known per se, for example in order to change the distance between the inner supports 14 relative to the distance between the outer supports 15, as can be useful for a bridge that describes a curve and correspondingly laid crane rails 12. To stiffen the carriage 10, the supports 14, 15 or spindle struts 16, 17 can also be supported by additional horizontal, vertical

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or diagonally arranged struts 18, 19, 20 and 21. As shown in particular in Fig. 1 to 3 and 5, in order to obtain a sufficiently stable and torsion-resistant carriage 10.

On the top sides of each pair of supports formed from two supports 14, 15, there are outriggers 22 extending transversely to the running or rail direction. These contain first sections 22a, which are rigidly attached to the carriage 10 and, for example, welded to the supports 14, 15, and extend approximately to the outer edge of the bridge, and second sections 22b, which are arranged so as to be displaceable in the direction of a double arrow u relative to the first sections 22a.

For this purpose, the sections 22a, 22b preferably consist of tubes arranged telescopically inside one another, e.g. with square cross-sections, which are arranged so high above the area of the cantilever arm 2 to be formed that this area can be easily walked on.

Finally, weights 23 in the form of concrete slabs or the like are arranged on the carriage 10, e.g. on the booms 22 or supports 14 and above the inner wheels 11. These weights serve the purpose of preventing the carriage 10 from tipping over under all loads that occur during operation of the canopy formwork device and in particular when the boom sections 22b are loaded.

A support structure 25 is pivotably attached to the outer, free ends of the boom sections 22b by means of joints 24, which according to Fig. 3 and 4 consists, for example, of two parallel, essentially vertical steel beams 25a, 25b with a double U-profile, which are connected to one another at their upper and lower ends by cross braces 26.

As shown in particular in Fig. 1 and 2, the support structure 25 extends downwards beyond the lower edge of the cantilever arm 2. At the lower end of the support structure 25 there is a working platform 27 which allows access to the floor formwork 5, while in a central part of the support structure 25 there is an external walkway 28 fixed to allow workers standing on it to access the areas to be poured with concrete. The working platform 27 and the walkway 28 are secured by handrails 29, 30 or fall protection devices or the like, which can also be seen in Fig. 4.

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At a point located above the joints 24 in the embodiment, the steel beams 25a, 25b are connected to the associated, rigidly mounted boom section 22a by means of an articulated lever 31, the articulated levers 31 preferably consisting of spindle struts that are adjustable in length. In addition, the articulated levers 31 are connected to both the steel beams 25a, 25b and the sections 22a by joints 32 and 33, respectively, the joint axes like those of the joints 24 being expediently arranged parallel to the direction of travel of the carriage 10 or parallel to the crane rails 12. Furthermore, provision can be made to attach a rail 34 to the top of the sections 22a with holes 35 spaced apart in the direction of the boom axes, which optionally form available articulation points for the articulated levers 31.

This makes it possible, on the one hand, to pivot the support structure 25 as a whole back and forth in the direction of a double arrow y about a first pivot axis running through the joints 32 by moving the boom sections 22b back and forth. On the other hand, by adjusting the length of the articulated levers 31 and selecting the holes 35 on which the joints 33 come to rest, the pivot positions of the suspended structure 25 in the fully extended or fully retracted state of the boom sections 22b can be changed or adapted to the respective requirements.

Preferably, the suspension structure 25 can be pivoted up and down in a second direction, which differs from the double arrow u and is indicated by a double arrow w in Fig. 1 and 2. In the exemplary embodiment, this movement is made possible by the fact that the outer supports 15 of the carriage 10 facing the support structure 25 have first and second sections 15a and 15b that can be displaced relative to one another in the direction of a double arrow x, the sections 15a being rigidly attached to the boom sections 22a and the sections 15b being rigidly attached to holders of the running wheels 11. Preferably, the sections 15a, 15b consist of tubes that are telescopically arranged one inside the other and have, for example, square cross-sections. A relative displacement of the sections 15b to the sections 15a in the direction of the double arrow x This means that the carriage 10 and with it the suspended structure 25 are pivoted about a second pivot axis, which essentially runs through the contact surfaces between the inner wheels 11 on the left in Fig. 1 and 2 and the crane rails 12 and is arranged essentially parallel to the first pivot axis. It is clear that the production of the pivoting movements for the

Supporting structure 25 could also be made using means other than those shown, e.g. by arranging the articulated levers 31 in Fig. 1 and 2 below the booms 22 or by the inner supports 14 consisting of sections that can be moved relative to one another.

The back and forth movements in the direction of the double arrows u and x are preferably generated using electrical, hydraulic and/or pneumatic means. In the exemplary embodiment, a swivel unit 37 in the form of a hydraulic cylinder/piston arrangement is provided in each of the two boom sections 22a, the cylinder of which is attached, for example, to section 22a and the piston rod of which is attached, for example, to section 22b. Similarly, swivel units 38 in the form of cylinder/piston arrangements are arranged in the supports 15, the cylinders of which are attached to sections 15a and the piston rods of which are attached to sections 15b. Instead of the cylinder/piston arrangements 37, 38, other power drives that make manual operations unnecessary, in particular electric motor drives, lifting magnets or the like, could also be provided. It is also possible to change the swivel movements brought about by the swivel units 37, 38 by, for example, arranging the respective cylinders adjustably in the sections 22a and/or 15, as indicated in Fig. 2 and 3 by fastening points 39 and fastening bolts extending through them. The swivel units 37, 38 form a swivel device that is able to swivel the support structure 25 in the direction of the arrows v and w along preselected paths.

The support structure 25 according to the invention serves to accommodate the formwork 4, 5 and 6. As shown in particular in Fig. 1 and 2, the front formwork 4 is made, for example, from a number of formwork or mold boards made of wood, which are attached with their backs to one end of, for example, wooden beams 40 with a double U-profile, the other ends of which are firmly connected to the steel beams 25a and 25b, as shown, for example, in Fig. 4, in which the walkway 28 is not shown. It would be possible to attach the front formwork beams 40 to the steel beams 25a, 25b in an adjustable manner using a clamp construction.

The floor formwork 5 is mounted using two cross beams 42, which are fastened in a vertically inwardly projecting position to the associated steel beams 25a, 25b. These cross beams 42 carry upwardly projecting beams 43, preferably also

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I-beams made of wood, to the free ends of which the floor formwork 5 made of formwork or mold boards is attached. The cross beams 42 are preferably pivotably mounted on the steel beams 25a, 25b and are held in a preselected position relative to the supporting structure 25 with the aid of spindle struts 44 that are adjustable in length and whose ends are hinged to the cross beams 42 or to the steel struts 25a, 25b. This position can be changed and adapted to the conditions in the individual case with the aid of the spindle struts 44 on the one hand and with the aid of holes formed in the cross beams 42 that form hinge points for the spindle struts 44 on the other. Both the spindle struts 44 and the cross beams are located below the cantilever arm 2, but are conveniently accessible from the work platform 27.

The side formwork 6 is attached to additional supports arranged above the cantilever arm 2, which are pivotably and preferably adjustable mounted on crossbeams 46 accessible from the walkway 28. The crossbeams 46 are pivotably attached to the steel beams 25a, 25b in the same way as the crossbeams 42 and are held in a preselected position by means of spindle struts 47. In addition, the side formwork supports 45 can be pivoted back and forth between a stripping position (Fig. 2) and a forming position (Fig. 1) and locked in the respective position using cable pulls 48 (not shown in detail).

According to Fig. 4, it is further provided that a plurality of the described cap formwork devices are arranged one behind the other along the guide rails 12 and that the work platforms 27, walkways 28, formwork supports 40, 43, 45 and formwork 4, 5 and 6 are also installed in the gaps between two supporting structures 25. This makes it possible to extend the formwork over sections of 30 m in length, for example, and to move all cap formwork devices simultaneously by a corresponding length after the corresponding cap sections have been poured. For this purpose, the skid carriages 10 are provided with couplings 49, for example, to which drawbars extending between adjacent carriages 10 are attached, which connect all the existing carriages 10 to form a train that can be moved together on the crane rails 12.

The operation with the cap formwork devices described is extremely simple. After completion of the bridge 1, the crane rails 12 are first mounted and placed on

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the carriages 10 with the supporting structures 25 are then placed on them. The pre-assembled formworks 4, 5 and 6 are then brought into the desired formwork position (Fig. 1) from the walkway 28 or from the work platform 27, after the supporting structure 25 has been swiveled inwards using the swivel units 37 and then the side formwork 6 has been swiveled downwards. The necessary fine adjustments can then be made by using the adjustment options described until the formworks 4, 5 and 6 assume the desired formwork positions. According to a preferred embodiment, the formwork position of the bottom formwork 5 is secured by screwing screw anchors 50, which are rotatably mounted in threaded bushings of the cross beams 42, into threaded sleeves on the underside of the cantilever. Such sleeves are usually already attached during the manufacture of the bridge 1. Preferably, between the cantilever arm 2 and a protruding part of the floor formwork 5, it is also possible to insert lining timbers 51, which hermetically seal the gap between the underside of the cantilever arm 2 and the inner edges of the floor formwork 5 and prevent leaks at this point when pouring the liquid concrete.

After completion of the formwork work, the space delimited by formwork 4 to 7 is filled with concrete. When this has set sufficiently, all existing support structures 25 are pivoted outwards as a whole into a dismantling position (Fig. 2) after the side formwork 6 has been pivoted back, the cap formwork device, which may be made up of several units, is moved by a corresponding section along the crane rails 12 and then all support structures 25 are pivoted back into the formwork positions according to Fig. 1. This results in the significant advantage that after the one-time fine adjustment of formwork 4 to 6, essentially the same settings can be used for all formwork sections provided along bridge 1. Therefore, after the cap formwork device has moved on, it is possible to carry out the next formwork process practically solely by pivoting all the existing support structures 25 into the formwork position at the same time, whereby the stroke lengths once defined for the cylinder/piston arrangements 37 and 38 can be used again and again.

When producing caps 3, which are to be installed where the floor formwork 5 is to be installed,

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do not have an undercut that is too large, which is caused by the obliquely outward-sloping undersides of the caps 3, the pivoting movement of the support structure 25 during formwork and stripping can usually be brought about solely by moving the boom sections 22a, i.e. by a substantially horizontal movement. If the undercut is too large, the support sections 15b are first actuated during stripping in order to lower the support structure 25 downwards in a vertical direction. The stripping movements then take place in two stages, by first actuating the cylinder/piston arrangements 38 and then the cylinder/piston arrangements 37, while the reverse order must be observed when re-forming.

In the embodiment according to Fig. 6, in which the same parts are provided with the same reference numerals, the supporting structures 53 consist essentially of steel bands 54, which are suspended from the boom sections 22b by means of the joints 24, extend through a gap 55 between two bridge parts 1a and 1b arranged next to one another, each forming a roadway, and support a working platform 56 below cantilever arms 2a, 2b. In the area of the gap 55, the steel bands 54 are provided with widened wedges, the side surfaces of which facing away from one another form front formwork 57a, 57b for so-called center caps 58a and 58b. Cross beams 59a, 59b are attached to sections of the steel bands 54 located below the cantilever arms 2a, 2b, on the upper sides of which supports 60a, 60b for floor formwork 61a, 61b and anchor bolts 62 for threaded sleeves attached to the cantilever arms 2a, 2b are attached. The method of operation is analogous to Fig. 1 to 5 with the difference that here, as a rule, pivoting the support structure 53 with the help of the pivot units 38 attached to the supports 15, i.e. in the vertical direction, is sufficient to pivot the support structure 53 back and forth between the formwork and demolding positions. Another advantage of this embodiment is that the support structure 53 practically only needs to be pivoted by a predetermined stroke once the formwork 57a, 57b and 61a, 61b have been adjusted. It is clear that the respective stroke lengths with which the cylinder/piston arrangements 37, 38 work can also be changed. In addition, Fig. 6 shows that the center caps 58a, 58b to be produced can also have different shapes, in particular they do not need to have the stools 3a shown in Fig. 2.

The invention is not limited to the described embodiments, which are based on

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can be modified in many ways. This applies in particular to the individual parts shown, which can be adapted in many ways to the needs of the individual case. It is also clear that the individual features can also be used in combinations other than those shown and described.

Claims (13)

- 12- Addresses 1. Cap formwork device for producing cornice caps (3,58) on bridge structures (1), containing: at least one carriage (10) intended for movement along the bridge (1) and having running wheels (11), at least two booms (22) mounted on the carriage (10), a support structure (25,53) mounted on these, on which formwork supports (40,43 and 60) for one front and one bottom formwork (57,61) are mounted, and a drive device for moving the support structure (25,53) back and forth between formwork and stripping positions, characterized in that the support structure (25,53) is pivotably attached to the booms (22) and the drive device is a pivoting device (37,38) operated by electrical, hydraulic and/or pneumatic means. ' 2. Cap formwork device according to claim 1, characterized in that the support structure (25) can be pivoted back and forth in at least two different directions. 3. Cap formwork device according to claim 1 or 2, characterized in that the supporting structure (25) is pivotable about a first pivot axis running essentially parallel to the direction of travel of the carriage (10) and the pivoting device has at least one first pivot unit (37) for pivoting the supporting structure (25) about the first pivot axis. 4. Cap formwork device according to claim 3, characterized in that the booms (22) contain first and second boom sections (22a, 22b) that can be displaced relative to one another, of which the first are rigidly attached to the carriage (10) and the second are articulated to the support structure (25), the support structure (25) is articulated to the first boom sections (22a) via articulated levers (31) and the pivoting movement around the first pivot axis takes place by displacement of the first and second boom sections (22a, 22b) relative to one another. - 13- 5. Cap formwork device according to claim 4, characterized in that the articulated levers (31) are adjustable in terms of their length. 6. Cap formwork device according to one of claims 2 to 5, characterized in that the support structure (25, 53) is arranged to be pivotable about a second pivot axis that is substantially parallel to the first pivot axis and the pivot device has at least one second pivot unit (38) for pivoting the support structure (25, 53) about the second pivot axis. 7. Cap formwork device according to claim 5, characterized in that the carriage (10) contains at least two inner and two outer running wheels (11) facing the support structure (25, 53), the second pivot axis runs through the running surfaces of the inner running wheels (11) and the second pivot units (38) are designed to tilt the carriage (10) including the support structure (25, 53) mounted thereon about the second pivot axis. 8. Cap formwork device according to claim 5 or 6, characterized in that the carriage (10) is supported on a side facing the support structure (25, 53) on supports (15) which have first and second support sections (15a, 15b) that can be displaced relative to one another, the first of which are rigidly attached to the booms (22) and the second of which are rigidly attached to associated running wheels (11), and that the pivoting movement about the second pivot axis takes place by displacement of the first and second support sections (15a, 15b) relative to one another. 9. Cap formwork device according to one of claims 3 to 8, characterized in that the first and/or second pivot units (37, 38) consist of cylinder/piston arrangements, the cylinders and/or pistons of which are adjustably attached to an associated boom and/or support section (22a, b or 15a, b). 10. Cap formwork device according to one of claims 1 to 9, characterized in that at least one further formwork support (45) is pivotably and lockably mounted on the support structure (25). &Igr; 1. Cap formwork device according to one of claims 1 to 10, characterized in that the formwork supports (40, 43, 45) are adjustably attached to the support structure (25). 12. Cap scarf device according to one of claims 1 to 11, characterized in that the carriage (10) is supported on four supports (14, 15) and has means (16, 17) for Change in the distance between the supports (14,15) from each other. 13. Cap formwork device according to one of claims 1 to 12, characterized in that a walkway (28) and/or a working platform (27, 56) is mounted on the supporting structure (25, 53).