DE1256243B - Joint formation on deck slabs made of prestressed concrete - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

EOIc

German AI .: 19 c -11/04

Number:
File number:
Registration date:
Display day:

1256243
D34118 V / 19c
August 27, 1960
December 14, 1967

The invention relates to a joint formation on road slabs made of prestressed concrete, in particular for Flight operations areas in which the relevant edges of the slab are separated from each other by opposing, Moldings made of steel serving to anchor the tendons are limited.

Such a joint formation is known from German patent specification 973 528. The well-known joint formation represents a further development of the one designed in the manner of a steel finger construction Roadway transitions, in which the length compensation at the joints takes place in that the move steel fingers against each other. In this known joint formation is the rear wall each finger plate designed as an anchoring strip for the tendons of the deck slab. These known joint training requires a very large transition area, because the joint width of the space required the tendon ends and the length required to attach the jack.

The invention is based on the object of a simple design of the transverse joints in road slabs made of prestressed concrete with the least possible, from To enable space requirements for the tendon ends and the tensioning jack with an independent joint width.

The solution to the problem is that the shaped body is T-shaped in plan and the webs of the T are arranged at right angles to the joint, as well as straps running across the webs to one another opposite moldings determine the joint width and the webs open at the top Have chambers at whose ends facing away from the joint the tendons are anchored.

The straps of the molded bodies that run transversely to the webs are designed as narrow strips that on the upper side of the road, on the side facing away from the joint, run out into a flange on one side.

Recesses can be provided in the flanges into which the joint between the molded bodies Covering sliding plate can be inserted, which is connected to the moldings of a roadway plate by screws and on the Moldings of the other deck slides.

Finally, after tensioning the tendons, the chambers can be filled with cement mortar, bitumen Od. Like. Be poured and covered by steel plates attached to the molded bodies.

An exemplary embodiment of the invention is shown in the drawing. It shows

F i g. 1 shows a cross section through two opposing shaped bodies along the line I-I of Fig. 3,

Joint formation on carriageway slabs
prestressed concrete

Applicant:

Dyckerhoff & Widmann limited partnership,

Munich 15, Lessingstr. 9

F i g. 2 shows a cross section along the line II-II the F i g. 3, and

F i g. 3 shows the top view of the representations in FIG. 1 and 2 still without sliding plate.

In the formation of the joint, a number of shaped bodies 1 which are formed identically are arranged side by side as the conclusion of a roadway plate 2 to a joint 3 out. Any of these moldings is approximately T-shaped in plan with a web 4 running at right angles to the joint, one bounded by side walls 5 at the top and on the side facing the joint 3 has open chamber. The bottom 6 of this chamber runs approximately in the example shown half the height of the deck slab, expediently slightly rising in the direction of the joint 3.

On both sides of the end of the webs 4 facing the joint 3, there are 5 straps on their side walls molded. These belts extend in height over the entire thickness of the carriageway slabs and exist made of thin strips that lie against the face of the respective carriageway slab section and on its upper edge on the side facing away from the joint 3 towards a one-sided flange 8 widen.

At a distance that is so large that it enables the temperature-related movement of the adjacent roadway sections to be accommodated, each of the molded bodies 1 is symmetrically opposite to the joint with a second molded body V in such a way that the strips 7 and T form an approximately T-shaped cross-section assemble, in whose perpendicular axis of symmetry the joint 3 is located. The opposing shaped bodies 1 'are designed in the same way as the shaped bodies 1; identical parts are denoted by corresponding reference symbols.

The flanges 8, 8 'of the belts 7, 7' have a recess on their upper side into which a sliding plate 9 is inserted, which is attached to a flange on one side of the joint by means of screws 10 and

709 708/66

Claims (3)

which can slide on the opposite flange according to the temperature-related movements of the roadway sections. The rear ends 11, 11 'facing away from the joint 3 of the chambers located in the webs 4, 4' are designed to be inclined by a small amount to the vertical and are drilled through. A tensioning member 12, 12 'is inserted through each of these bores into the upwardly open chambers. The inclination of the walls at the ends 11, 11 ', like that of the chamber bottoms 6, 6', corresponds to the inclination of the tendons 12, 12 ', which are slightly raised towards the anchoring, so that the clamping jack, which is inserted into the chambers when the tendons are tensioned, can be easily applied. The walls thus serve as abutments for anchoring the tendons. The parts of the joint formation are installed before the concrete for the deck slab is poured in. For this purpose, the individual molded bodies are first laid along the joint to be formed and the ends of the tendons 12, 12 'inserted through the bores in the walls of the ends 11, 11' of the molded bodies 1, 1 'into the chambers. Then, by means of suitable aids not specifically shown in the drawing, two opposing shaped bodies 1, 1 'are fastened to one another in such a way that the joint 3 remains open between them, the width of which is made dependent on the air temperature on the day the concrete is poured will. Then the shaped bodies held together in this way in pairs with the shaped bodies adjoining in the direction of the joint are precisely aligned in terms of height and direction and the shaped body pairs at their joints, e.g. B. by welded round steel bracket 13, 13 'connected to each other. The auxiliaries required only for installing the moldings are removed again after the concrete has hardened. Short round steel anchors 14, 14 ', which are welded parallel to the joint to a ridge below the bottoms 6, 6' of the molded bodies, serve to better anchor the molded bodies 1, 1 'to the concrete surrounding them. In addition, transverse tensioning members 15, 15 'carried out underneath the shaped bodies ensure a good bond between the same and the concrete lying in between. After the concrete has hardened, the tensioning of the tendons 12, 12 'can take place at any point in time, since the anchorages of the tendons in the chambers that are open at the top are freely accessible at all times. After completion of the tensioning processes, the chambers can be filled with cement mortar, bitumen or the like. B. be completed by screws, connected to the shaped bodies steel plate. The gap 3 α, which is still present in the road surface and is more or less open according to the respective temperature of the road slab, is formed by the edge of the sliding plate 9 and the edge of the upper recess of the flange 8 '. It can remain open, as its shallow depth does not constitute an obstacle when the vehicle wheels roll over it. To form the joint, simple, completely identical items are put together on the spot of the installation. The individual parts are placed against one another in a simple manner until the required length is reached. The length of the strips will expediently be adapted to the spacing of the tendons 12, 12 'if a tendon is to be introduced and anchored to each shaped body. If the pretensioning of the carriageway slab is to be selected to be greater, two or more tendons can also be accommodated in a molded body which is then correspondingly larger. The length of the strips 7, 7 'can, however, also be adapted to a different spacing between the tension members 12, 12', if such a spacing is expedient for static reasons. At the edges of the road, the strips 7, T are then cut off according to the width of the road. One advantage of the joint design is the saving of a complex fastening of the molded body during the construction phase. The moldings are preferably made of cast steel, which ensures an almost unlimited durability of the joint formation. In addition, the anchoring of the tendons with the recesses necessary for attaching the tensioning jack is incorporated into the joint design in a simple manner. With this joint design, it is possible to accommodate the entire anchoring for the tendons within the concrete structure and still have a continuous strip at the end of the joint so that a narrow sliding plate is sufficient to cover the joints while maintaining the smallest possible joint width. The joint design ensures that the prestressing forces are not only entered point-like radiating away from the actual anchoring body of the tendons in such a way that the areas between the recesses required for attaching the clamping jack remain without longitudinal prestress, but that due to the rigid design of the molded body with lateral Wings, the concrete in the areas between the anchorage of the tendons and the joint is prestressed to the same or approximately the same amount as the deck itself. 1. Joint formation on pavement slabs made of prestressed concrete, in particular for flight operations areas, in which the relevant edges of the pavement slab are delimited by opposing steel moldings serving to anchor the tendon, characterized in that the moldings (1, V) are T-shaped in plan , the webs (4, 4 ') of the T are at right angles to the joint, straps of opposing shaped bodies running transversely to the webs (4, 4') determine the joint width and the webs (4, 4 ') have chambers open at the top whose ends (11, 11 ') facing away from the joint, the tendons (12, 12') are anchored. 2. Joint formation according to claim 1, characterized in that the belts are designed as narrow strips (7, T ) which expire on the upper side of the roadway after the side facing away from the joint in a one-sided flange (8, 8 '). 3. Joint formation according to claim 2, characterized in that the flanges (8, 8 ') have recesses are provided in the one the joint