DE1534452C3 - Superstructure made from reinforced precast concrete parts, especially for bridges - Google Patents

Description

nismäßig small amounts required its use in the construction according to the invention economical.

Further features of the invention are the subject of claims 2 to 7.

The invention is described below with reference to the exemplary embodiments shown in the drawing explained in more detail. It shows

Fig. 1 is a partial longitudinal section through a Bridge superstructure in the level of the line I-I in Fig. 3,

Fig. 2 is a section in the plane of the line H-II in Fig. 3,

F i g. 3 the F i g. 1 corresponding top view,

4 shows a further exemplary embodiment in plan view,

Fig. 5 shows a joint between two reinforced concrete or. Prestressed concrete beams in longitudinal section and enlarged Scale,

Fig. 6 shows a junction between a Reinforced concrete humps and a reinforced concrete pressure plate in the ao section in the plane of the line VI-VI in F i g. 1 and on a larger scale, and

Fig. 7 shows a connection point between a reinforced concrete hump and two reinforced concrete pressure plates in Section in the plane of the line VII-VII in F i g. 4 and «5 on an enlarged scale.

In Fig. 1, 1 denotes the left support of a bridge, shown in dashed lines. Supports 2 with cusps 3 arranged one behind the other at intervals rest on this support. Furthermore, reinforced concrete pressure plates 4 are provided, which have recesses 5 for receiving the stool and for subsequent casting of the same. The girders 2 are made of reinforced concrete or prestressed concrete and can have any cross-section. In the bridge construction shown, hollow prestressed concrete girders are arranged. The reinforced concrete pressure plates 4 can be flat or, as in particular from FIG. 2 can be seen, already have the road profile with sidewalk paragraphs 4 α .

The stools 3 engaging in the recesses 5 of the reinforced concrete pressure plates 4 are each made of one piece with the reinforced concrete or prestressed concrete beams 2. Their width b and length L are a multiple of their height h, as shown in FIG. 1 and 6. This low, wide-area design of the stool 3 results in a high level of shear strength. As a preferred reinforcement, inverted U-shaped brackets 6 are provided in the reinforced concrete humps, which extend with their legs 6 α and 6 b into the respective support 2 and their webs 6 c and 6 rf in the head part of the stool both in the transverse direction are arranged in the longitudinal direction of the carrier. It is obvious that the brackets 6 or their legs 6 α and 6 b, in particular, further increase the shear strength of the stool 3, but also their compressive and tensile strength. The legs 6 b are in the in F i g. The embodiment shown in FIG. 7 is made shorter than the legs 6 only because of the hollow cross-section of the carrier 2 indicated by dashed lines. Advantageously, the width b corresponds to the reinforced concrete bumps essentially to the width B of reinforced concrete or prestressed concrete beam. This large width of the stool 3 also serves to increase the shear strength and, at a given height h , also reduces the specific surface pressure between the reinforced concrete hump on the one hand and the reinforced concrete pressure plate on the other hand.

In the case of the FIG. 4 shown embodiment instead of the recesses 5 in the reinforced concrete pressure plates, there are recesses 7 at the abutment edges 8 of the same provided. These recesses 7 are used in the manufacture of the reinforced concrete pressure plates even easier to attach than the recesses 5. As in particular from FIG. 6 can be seen, Both the cusp 3 and the recesses 5 and 7 are a plurality on the connecting surfaces 9 provided by transverse grooves 10. These cross-grooves ensure better adhesion between the Concrete mortar on the one hand and the carrier 2 or the reinforced concrete pressure plate 4 on the other hand. Accordingly the security against lifting of the plate from the carriers is great. As can also be seen, are only narrow joints 11 present between the recesses 5 and 7 and the bumps 3, the require very little potting compound. This potting compound can be made either from concrete mortar or from Plastic mortar are made. The advantages of plastic mortar have already been mentioned.

It is known that the stools 3 α arranged at the respective carrier ends 2 α are always particularly heavily stressed by shear forces. To absorb these thrust forces, as shown in FIG. 1, tendons 12 are arranged in the tension zone 13 of the girder 2, which is guided with their ends 12 a from the tension zone obliquely upwards to the cusps 3 α arranged on the girder ends 2 α and anchored in them to anchor plates 14.

As shown in particular in FIGS. 2 to 5 are shown, several in a row in a row on the Reinforced concrete or prestressed concrete beams arranged reinforced concrete pressure plates 4 by means of them arranged, continuous tendons 15 clamped together to form a closed support disc. These tendons are each anchored to the end plates by means of anchor plates 16 (FIG. 3). This clamping together the reinforced concrete pressure plates by means of the tendons 15 has the advantage that an approximately occurring Shrinkage of the grout is made ineffective. As a result of the existing preload can no shrinkage cracks between the butt edges 8 of the pressure plates in the butt joints 17 occur in concrete or plastic mortar. With the in F i g. 4 shown preferred design can as a result of the provided instead of the recesses 5 at the butt edges 8 of the reinforced concrete pressure plates 4 Recesses 7 also avoid shrinkage cracks in the areas around the stool 3 Grouting joints could occur; the prestressing also makes any shrinkage in these joints ineffective.

The clamping of the reinforced concrete pressure plates together is advantageous, especially where intermediate supports of the bridge are present, for example on the one shown in FIG. 5 butt joint of two beams with the beam ends 2a . In this case, for example, the storage takes place by means of permanently elastic neoprene material 18 on the intermediate support 17 a. It is well known that a bridge bends to a certain extent when it is loaded. When in Fig. 5 shown joint between two beam ends 2a thus gaping would occur at 19. The occurrence of a gaping gap is, however, reliably prevented by the described clamping of the reinforced concrete pressure plates 4. The deflection of the bridge on both sides of the support 17 a

can therefore only be expressed in a movement of the lower corners of the carrier ends 2 α on the neoprene bearings 18 in the direction of the arrows 20. The fact that no gaping gap can occur at 19 naturally increases the surface quality of the roadway 21, which can be continuously covered with a roadway covering made of, for example, plastic. Finally, a numerical example for the design of the stool 3 is given. They have the following dimensions in a completed construction: Length L approx. 350 mm. Width b about 500 mm, height h about 190 mm. The beam width B is about 650 mm. while the joint width is about 20 mm.

For this purpose 3 sheets of drawings

Claims (7)

1 2 .. would. This is unfavorable inasmuch as patent claims are always made: the aim is to reduce the surface pressures that occur 1. To hold a ring made of reinforced precast concrete, so make the dowels as wide as possible for the superstructure, especially for bridges. However, as can be seen from Fig. 2 of the Entdie from girders with 5 counter-hold at intervals, this is not possible with the known composite-arranged, rectangular reinforced concrete dowels and construction, for reasons consisting of reinforced concrete pressure plates, which for strength, as already mentioned . In addition, it should be noted that the dowels are received and that the dowels are cast in concrete, so that the girders at the construction site are marked by a considerable amount of effort made from steel. Moreover, the quality is concrete anchors to the carriers (2) from a piece of the connection between the carrier and prepared into it stool (3 and 3 a), the width of the inserted dowel quite staggering in the (b) and length (L) a multiple of its height (Λ) strength. It should be noted that the dowel is at. Transport damage or internal cracks 2. Construction according to claim 1, characterized GE 15, which are not readily detectable, indicates that the width (b) of the stool (3, however, represent a considerable weakening. and 3 a) essentially the width (B) of the beam. The object on which the invention is based is ger (2). is a construction of the initially 3. Construction according to claim 1 or 2, there- led way to create a considerably higher one characterized in that the recesses (7) 20 strength of the connection between dowel and Träan the butt edges (8) of the reinforced concrete pressure gauges and a relatively small surface pressure plate (4) are arranged. between the dowels and the concrete pressure 4. Construction according to one of claims 1 results and further assembly or construction costs to 3, characterized in that they save each other. opposite connecting surfaces (9) of 35. This object is achieved according to the invention Bumps (3 and 3a) and recesses (5 and 7) solved that the reinforced concrete dowel with the girders provided with a plurality of transverse grooves (10) are stools manufactured in one piece, the width of which are. and length is a multiple of its height. 5. Construction according to one of claims I Due to the fact that the stool with the to 4, characterized in that the 30 carriers are made in one piece, verminknown anchoring of the tendons (12) of the not only assembly and construction costs, but rather the tension zone (13) of the beam (2) by means of anchor plate, the best possible connection between th (14) at the top of the beam ends (2a ) stool and beam is guaranteed. It is also possible to use the stool (3a ) . borrowed to make the stool considerably wider than that 6. Construction according to one of claims 1 to 35 dowels in Fig. 2 of the cited reference, to 5, characterized in that there are several. In the subject matter of the invention, the width is several times one behind the other in a row on the supports (2) greater than the height. This results in the same height in each case arranged reinforced concrete pressure plates (4) means in provided (what depends on the thickness of the used continuous tendons arranged on them depends on reinforced concrete pressure plates), a larger attachment (15) are clamped together. 40 surface for the steel concrete pressure plates, so that at 7. Construction according to one of claims 1 equal stress, the surface pressure decreases; to 6, characterized in that as Beweh- one keeps the Flächenpressunrurtg previously used in the protuberances (3 and 3a) in the longitudinal and gene in, so inevitably the carrying capacity increased in the transverse direction asked, inverted U-shaped, the stool of Construction according to the invention, with their legs (6 α and 6 b) in the stirrups, which extend 45 times due to the large cross section of the stool and also the respective carrier (2), a very high level of shear strength is given. Furthermore (6) are arranged. can be the joints to be potted between the Humps are kept relatively small, where- by the amount of mortar with which this 50 joints are to be poured, considerably reduced compared to the amount in the known design The invention relates to a need for armored vehicles. As a result of the small joint widths and precast concrete parts, the small amount of mortar required, anything is practically negligible, especially for bridges made of girders with shrinkage. In the intervals arranged one behind the other, rectangular _5S known type, is located einzubetonieren wherein each individual dowel for gene reinforced concrete anchors and from Stahibetondruckplatten into the carrier, must be composed which are expected to receive the dowel with subsequent larger tolerances, for which reason the closing recesses to be cast are provided that are the difference between the cross-sectional area of the dowels. and the cross-sectional area of the recesses in the. Due to the time printing plates, such a construction must be considerably larger than in the text "Die Bautechnik", 1966, pages 180 to 182, subject of the invention. The emerging strength is known. It uses specially manufactured dowels, therefore, impairing shrinkage cracks can be quite considerable in the construction known on site in the corresponding recess,
gene inserted and potted in the respective carrier is advantageously used for potting the. These dowels now have to use relatively e ₅ joints plastic mortar, which can be made narrow more quickly, otherwise the recesses in the concrete-cement mortar provided for the binds and has a greater strength than dowels. Although plastic mortar tends to be more expensive to wear than cement mortar, the cross-section of the mortar tends to be weakened.