DE4008274A1 - Bridge support set of prefab., prestressed concrete component - uses support with most variable cross-section as basic member, with other supports - Google Patents

Abstract

The bridge support set consists of prefab. prestressed concrete structural elements. Each element has a trapezoidal cross-section with side walls (2), which diverge in the upward direction and terminate in flanges (3) which extend sideways and outwards. Three sizes of the elements are used. The support (1) with the most varied cross section forms a base, while the other ones form recesses of the basic one. The cross-sectional parts of all supports are shaped to fit together. ADVANTAGE - Increased variability, and improved transverse load-bearing capacity.

Description

The invention relates to a set of bridges made of prefabricated Prestressed concrete elements used in the field of bridge construction for Er direction of the superstructure of concrete bridges is applicable.

Known structures for the construction of the superstructure of concrete bridges consist of prefabricated steel or prestressed concrete elements, which the shape of an open top trapezoid with a base plate and after have diverging legs at the top. On the two legs the bridge girders can be designed as an upper edge element flange sections are molded. On the without flange sections NEN carrier legs or on the molded flange sections store lost formwork panels that cover the open profile of the tra Cover the peziform precast girder.

Structures of the type described above are the subject of DE-PS 23 36 411, AT-PS 2 85 663 and HU-PS 1 85 526. Die by the AT-PS 2 85 663 known embodiment of a bridge girder werkes is characterized by a considerable distance from each other orderly support elements. The associated with this design Advantage of a variability of the carrier arrangement in the bridge transverse direction there are serious disadvantages. That's how a Variabi is lity of the beam height due to the constant dimensions of the fer parts not given. The one applied from above the straps transverse concrete stiffness of the bridge over the in-situ concrete slab baues loses by the distance of the concrete components from each other and a lost one installed between adjacent supporting elements Formwork considerably effective.

To remedy the shortcomings outlined above, this is Bridge structure according to DE-PS 23 36 411 across the entire width of the superstructure close to each other and through a location marked concrete slab in the joint area of neighboring Fer parts directly with the tops of the support legs in Connection is established. Such constructive measures affect the transverse rigidity of the bridge superstructure is positive. Allow you however, taking into account the constant dimensions of the beam cross cuts no variability in element height and elements width.  

The state of the art that has already been dealt with is supported by the HU-PS 1 85 526 completes the subject of a bridge girder set has a variable height on the one hand and a variable height on the other a constant width both in the area of the flange sections also have the base plate. The cross sections of each Beams are used to vary the element height by horizontal Cuts formed in the diverging legs. Constructive Deviations between the beams result from the design the flange sections, their different thickness depends on the corresponding beam height. To variability to reach the carrier arrangement in the transverse direction of the bridge will based on the construction method known from AT-PS 2 85 63, which provides for the spacing of support elements and the distance between adjacent beams by means of lost sha bridge plates. This also exists in the present case Danger of insufficient transverse rigidity of the bridge superstructure, because the in-situ concrete slab is the statically unfavorable one mentioned above Storage experience. Another serious disadvantage arises in that each beam cross section of the set provides a separate molding device requires what the manufacturing cost significantly more expensive.

The aim of the invention is the static effectiveness of the composite to ensure the bridge girder with the applied in-situ concrete slab afford to achieve a high variability of the carrier arrangement as well as an appropriate constructive training of the Carrier set the mechanical and human effort to manufacture to reduce the same.

The invention has for its object a bridge girder set to develop that with sufficient cross-section effect of the bridge superstructure is not just a variation of the elements height allowed, but also a variability of the element width in the area of the base plate and the flange sections, and its manufacture is only a single shaping device required.  

According to the invention the object is achieved in that the Bridge girder set associated girders with the largest cross section variant is provided as the basic element. The other bearers of the Set represent sections of the basic element, the cross cut a smaller carrier and this smaller carrier cross section corresponding remaining area of the cross section of a larger carrier are always congruent. Starting from the cross-section of the base element, the cross-sections are cuts of the remaining bridge girders to vary the upper ele ment width by vertical cuts in the flange sections as well as for the variation of the element height and lower element width by horizontal cuts in the divergent legs det. The bridge girders of the set can be optionally with one another Identify combinable element width and element height.

The invention will be explained in more detail below with reference to a drawing be tert.

Fig. 1 shows the cross section of the carrier set according to the invention.

The bridge girder set consists of prefabricated, beam-shaped prestressed concrete elements 1 , which have a variable height and have the shape of a trapezoid open at the top with a base plate 8 and legs 2 diverging upwards. Flange sections 3 formed as an upper edge element are formed on both legs 2 . On recesses 4 of the flange sections 3 store lost shuttering plates 5 to cover the open profile of the trapezoidal precast element carrier 1 . The bridge girder 1 with the largest cross-sectional variant is provided as the basic element. The remaining beams 1 of the set represent sections of the basic element, the cross section of a smaller beam and the remaining area of the cross section of a larger beam corresponding to this smaller beam cross section being always congruent. Starting from the cross-section of the base element, the cross-sections of the remaining bridge girders 1 are formed by vertical cuts 6 in the flange sections 3 for varying the upper element width, and by horizontal cuts 7 in the divergent legs 2 for varying the element height and lower element width. The carrier 1 can have an optionally combinable element width and element height. An in-situ concrete slab 9 is arranged above the beams 1 and formwork slabs 5 .

List of the reference numerals used

1 bridge girder
2 upward diverging legs
3 flange sections
4 recesses to support lost formwork
5 lost formwork panels
6 vertical cuts
7 horizontal cuts
8 base plate
9 in-situ concrete slab

Claims (3)

1. Set of bridge girders made of prefabricated prestressed concrete elements that have a variable height and have the shape of an open top trapezoid with a base plate and upward diverging legs, whereby flange sections formed as upper edge elements are formed on both legs and formwork panels lost on the flange sections for covering of the open profile of the trapezoidal prefabricated girders, characterized in that the bridge girder ( 1 ) with the largest cross-sectional variant is provided as the basic element, and in that the other girders ( 1 ) of the set represent sections of the basic element, the cross-section of a smaller girder and this smaller ren carrier cross-section corresponding remaining area of the cross-section of a larger carrier is always congruent. 2. Bridge girder set according to claim 1, characterized in that starting from the carrier cross section of the base element, the cross sections of the other bridge girders ( 1 ) for varying the upper element width by vertical cuts ( 6 ) in the flange sections ( 3 ) and for varying the element height and lower element width horizontal cuts ( 7 ) are formed in the diverging legs ( 2 ). 3. set of bridge girders according to claims 1 and 2, characterized in that the bridge girders ( 1 ) have an optional miteinan combinable element width and element height.