KR101293285B1 - Fixed running track on a bridge structure - Google Patents

Abstract

The invention relates to a fixed running track (1) on a bridge structure, in which a concrete slab (3) is positioned on a bridge girder (2) to support a rail (6) for a rail vehicle. The concrete slab (3) forms a continuous strip that extends over at least two bridge girders (2). A continuous profiled concrete layer (7) is situated between the concrete slab (3) and the bridge girder (2). A running layer (10) is situated between the profiled concrete layer (7) and the bridge girder (2) and the profiled concrete layer (7) is permanently fixed to the concrete slab (3) of the fixed running track (1).

Description

FIXED RUNNING TRACK ON A BRIDGE STRUCTURE}

The present invention relates to a rigid track of a bridge structure, and more particularly to a rigid track of a bridge structure in which a concrete slab is placed on a bridge girder to support a rail of a railway vehicle.

Rigid tracks are commonly used for high speed sections of railroad tracks. The present invention involves the creation of a concrete strip consisting of prefabricated concrete plates joined together or of individual sleepers joined together by site-mixed concret. Here, the rigid track is aligned and fixed to the hydropically coupled base. Rigid tracks are formed on the top of an almost endless continuous concrete strip on which rails are mounted. However, these strips break near the bridge to avoid relative motion between the bridge girder and the concrete slab of the rigid track. In this case, the concrete slabs are installed to match the length of the bridge girders. In addition, the concrete strip is broken at the intersection of two bridge girders, so that the expansion of the bridge girder can be transmitted directly to the concrete slab of the rigid track, and the unavoidable bending occurring in the device forming the bridge girder and the concrete slab. Will be avoided. The disadvantage of mounting a rigid track in the bridge structure in this way is that the length of the concrete slab coincides with the length of the bridge girder. Therefore, it is necessary to make the concrete slab coincide with the length of the bridge girder, especially when using the prefabricated concrete slab of a specific length. Another disadvantage is that expansion joints are also provided on rigid tracks, such as on the bridge girders, which requires an expensive rail structure.

Accordingly, it is an object of the present invention to provide a rigid track of a bridge structure which can be produced economically with different lengths of each bridge girder.

The present invention for achieving the above object provides a rigid track of a bridge structure having the features of claim 1.

According to the invention, the concrete slab of the rigid track forms a continuous strip on at least two bridge girders. Therefore, the expansion joint between the two bridge girders is independent of the path of the concrete strip. Because of the larger weight of the bridge girder compared to the concrete slab, and because of the direction of incoming heat radiation, the concrete slab is much more thermally expanded than the bridge girder itself, and the thermal expansion of the bridge girder is significantly slower than that of the concrete slab, which is why The structure provided according to the invention thus makes the bridge girders independent of the concrete slab strips. This structure includes a profiled concrete layer between the concrete slab and the bridge girder. The profiled concrete layer is a continuous structure like a concrete slab strip. A sliding layer is integrally inserted between the profiled concrete layer and the bridge girder and at the same time the profiled concrete layer is permanently coupled to the rigid track. The sliding layer allows the concrete slab and the profiled concrete layer to slide between the bridge girders. For this reason, thermal expansion can occur mainly independently. The profiled concrete layer performs the function of a conventional hydropically coupled base supporting the concrete slab. However, while the hydropically coupled base is firmly bonded to the ground, the profiled concrete layer can slide on the bridge girders and connect the expansion joints between the individual bridge girders. Because of this, the rigid track is made in such a way that it can be built continuously without interruption even in the bridge area. It is not necessary to align the rails to connect the joints. This means that rigid tracks can be manufactured economically and the work is more convenient than ever before.

In a preferred embodiment according to the invention, the bridge girders are supported by fixed and moving bearings, and the profiled concrete layer is firmly coupled to the bridge girders in the vicinity of the fixed bearings of the bridge girders. As a result, the behavior in which the rigid track and profiled concrete layers expand differently compared to the bridge girder exhibits the desirable feature that expansion inevitably occurs in substantially the same direction. Because of this, the relative motion between the two conjugates is kept relatively small.

In particular, tie bolts, in particular screw tie bolts, connecting elements such as bow reinforcements or plugs, are used to connect the bridge girders and the profiled concrete layer, which for example protrudes from the bridge girders and bridges On the upper surface of the girder a layer of profiled concrete is formed. In particular, it is preferred here that the tie bolt is a screw-in tie-bolt, and the screw tie bolt is preferably not clamped to the bridge girder until immediately before the profiled concrete layer is formed. . This allows the bridge girder to be used to move the building vehicle without damaging the tie bolts before the profiled concrete layer is poured.

In particular, there is an advantage that a resilient layer, such as a high resistance foam layer or an elastomer layer, is provided at the intersection of the two bridge girders and positioned between the bridge girders and the profile forming concrete layer. Each bridge girder is independent of each other, on the contrary, since the profile-forming concrete layer and the concrete slab extend in the form of a continuous screed on top of the expansion joint of the bridge girder, corresponding to the two units, namely bridge girder Units and Profile Forming Units to which concrete layers and concrete slabs fall, form different elastic lines. Each of the bridge girders is bent in the form of a bow, while concrete slabs and profiled concrete layers extend over the bridge girders in the form of waves. The high resistance foam layer is provided to prevent excess stress between the two bridge girders. In extreme cases, both ends of the bridge girder may stimulate the interior and exterior of the elastic layer without exerting an excess pressure on the profiled concrete layer and the concrete slab. This reduces the stress on the continuous strip. The elastic layer thus represents a particularly preferred element in the current structure. For example, the elastic layer may be a high resistance foam layer installed in the form of a high resistance foam sheet installed on the bridge girder before the profile forming concrete layer is poured. In this way, the site where the two neighboring bridge girders meet at intervals between them is shuttered for the profiled concrete layer.

When the backing plate is placed on the elastic layer top facing the profiled concrete layer, the reinforcement for the profiled concrete layer is poured into the profiled concrete layer without damaging or positioning the elastic layer and pouring the concrete. It can be placed on the support plate before and during pouring.

If a concave recessed shape is integrally formed to partially support the elastic layer in the bridge girder, the high resistance foam layer on the bridge girder can be clearly positioned, thereby forming the profile around the elastic layer. The concrete layer is not significantly weakened. The height of the profiled concrete layer at the site followed by the two bridge girders is thus approximately equal to the thickness of the other part of the profiled concrete layer.

The concrete slab of the rigid track is bonded substantially rigidly to the profile-forming concrete layer, usually by non-positive connexion, but the concrete slab of the rigid track overlaps firmly, especially at the point where the two bridge girders meet. Stability is increased if bonded to the forming concrete layer. Especially by bolting the concrete slab to the profiled concrete layer, a reliable overlap bond can be made easily. Screwed tie bolts, reinforcing hoops or pegs may be used which are subsequently drilled and cast.

Preferably, the sliding layer between the profile forming concrete layer and the bridge girder is made of a thin film and / or geotextile. It is also desirable to be able to slip clearly past each other by using two thin films on top of each other. The geotextile has the advantage of being very well bonded to the concrete by at least partially penetrating the concrete. The ruggedness of the bridge girders can be compensated by the geotextile having a thickness of 2-10 mm. This makes it easier for the profiled concrete layer to slide over the bridge girder. As such, no large distortion occurs. For this purpose the geotextile layer may be located on the top of the bridge girder and / or on the side of the profiled concrete layer facing the bridge girder, one or two such as a polyethylene film having a thickness of about 0.3-0.5 mm in between. A thin film may be provided.

 It is particularly preferred if the present invention consists of each prefabricated concrete slab in which the concrete slabs are joined together to form a continuous strip. This can be done for example in a conventional manner already known as a "Feste Fahrbahn-Bogl" system. The invention may also be applied, of course, to rigid tracks consisting of prefabricated concrete slabs that are not joined together, or sleepers cast from site-mixed concrete.

 In a particularly preferred embodiment, the prefabricated concrete slab consists of standard parts of normal length, which are installed regardless of where the bridge girders intersect each other. Since the prefabricated concrete slab is placed on top of a profiled concrete layer forming a continuous strip, there is no need to consider the intersection of bridge girders when laying the prefabricated concrete slab. The continuous strip formed by the profiled concrete layer is slid over the bridge girder together with the strip of prefabricated concrete slab that constitutes the rigid track.

In addition to the advantages described above, the profiled concrete layer provides another advantage that the direction of the rigid track can be guided by the profiled concrete layer. In particular, with the help of the profiled concrete layer, it is possible to form, for example, lifting the rail high in a curved section. Concrete slabs, in particular identical plates of prefabricated concrete slabs, are installed throughout. In most cases, dimensions for prefabricated concrete slabs are not particularly required.

It is to reinforce the profiled concrete layer in order to be able to stabilize and absorb pressure and tensile stresses resulting from thermal expansion and as a result of the acceleration forces acting on the rail vehicle.

In particular, a stopper is placed over the bridge girder to stop the profiled concrete layer and the rigid track from deviating laterally and to maintain the side position of the concrete slab of the profiled concrete layer and / or the rigid track. This stopper enables relative movement of the profiled concrete layer and / or concrete slab in the longitudinal direction of the rail. Lateral movement of the concrete slab above the profiled concrete layer and / or bridge girder is prevented by stoppers located on both sides of the profiled concrete layer and / or the concrete slab.

Another advantage of the present invention is illustrated in the following examples.

1 is a longitudinal cross-sectional view showing a rigid track over a bridge structure at the point where the bridge girders meet each other;

FIG. 2 is a plan view of the rigid track at a point similar to FIG. 1.

3 is a cross-sectional view showing the bridge girder.

4 is a cross-sectional view showing in detail the sliding layer.

1 shows a cross-sectional view of a rigid track 1 in a joint 12 where two bridge girders 2 meet. In this embodiment, the rigid track 1 is formed from a concrete slab 3 which is tightly coupled to the joint 4 which is engaged together to form a continuous strip. Connecting the respective concrete slabs 3 in the joints 4 which are engaged together can usually be made by pouring concrete into the gaps between the joints 4 with the aid of prestressed steel. The rail 6 is mounted on the rail support 5 above the rigid track 1.

The concrete slab 3 is situated above a profiled concret layer 7. This adjusts the position of the concrete slab 3 above the profiled concrete layer 7 with a spindle, for example, and casts concrete between the concrete slab 3 and the profiled concrete layer 7. By positioning and fixing. The profiled concrete layer 7 thus provides a solid foundation at a certain position, for the concrete slab 3, in which the rigid track 1 is permanently laid.

A sliding layer 10 is located between the profiled concrete layer 7 and the bridge girder 2. In particular, the rigid track 1 and the profile are allowed in order to allow different expansions caused by different sun rays and the weight of the rigid track 1 with the bridge girders 2 and the profiled concrete layer 7. It is particularly advantageous if the forming concrete layer 7 slides over the bridge girder 2. This avoids the occurrence of unavoidable stresses, makes a very uniform structure, especially near the rigid track 1, increases the stability of the train journey and, on the other hand, makes it relatively economical to manufacture. In this structure the joint 4 in the rigid track 1 should not coincide with the joint 12 between the bridge girders 2 as in the conventional cast. The rigid track 1 extends above the joint 12 in the seamless bridge girder 2. Therefore, each concrete slab 3 can be manufactured in a conventional and standardized way. In particular, it is not necessary to consider the length of each bridge girder 2. Such a structure is advantageous in comparison with the state of the art for track sections, in particular characterized by an increase in the number of bridges, since the conventional structure requires a large number of concrete slabs 3 manufactured to a predetermined length. to be.

In the section described here, the bridge girder 2 is located above the pillars 14. Each is supported on one fixed bearing 15 and one moving bearing 16. This allows the bridge girder 2 to expand in the direction of the moving bearing 16 of the same bridge girder 2 from the fixed bearing 15. Therefore, the spacing of the joints 12 becomes larger or smaller than the length of the bridge girder 2 changes. The tie bolts 18 are located in the vicinity of the fixed bearing 15 of the bridge girder 2 for the shearing force transmitted from the rigid track 1 and the profiled concrete layer 7 to the bridge girder 2. And through the tie bolts 18 the profiled concrete layer 7 is bonded to the bridge girder 2. The thermal expansion of the assembly consisting of the profile forming concrete layer 7 and the concrete slab 3 occurs in the same direction as the bridge girder 1 as a result of the fine relative movement between the two combinations.

The tie bolt 18 is preferably a screw tie bolt. This means that a threaded sleeve is poured into the top of the bridge girder 2, and the anchor 12 is simply fastened before the profiled concrete layer 7 is poured. This has the advantage that in the construction work the upper part of the bridge girder 2 can be used as a track for the construction vehicle without damaging the anchor 18.

Since the bridge girders 2 are not connected together, each girder is bowed under load. In contrast, the movement of the continuous strips of the profile forming concrete layer 7 and the rigid track 1 is in the form of waves. In order to avoid unavoidable defects in the continuous strip at the site of the joint 12, a layer of high resistance foam 20 is placed under the profiled concrete layer 7 near the top of the bridge girder 2 and near the joint 12. Is located. If any defect occurs between the two bridge girders 2 in the vicinity of the joint 12, the two bridge girders 2 act on the layer of high resistance foam 20 without pressing the profiled concrete layer 7. As a result, the high-resistance foam is compressed without applying unavoidable pressure to the profile-forming concrete layer 7. The high resistive foam 20 layer may consist of a high resistive foam sheet inserted in the form of serrations in a bridge girder provided for this purpose. The layer of high resistivity foam 20 is usually only a few centimeters thick. It is also sufficient to overlap the joint 12 with a length of 1 to 2 m in order to compensate for the expected relative movement of the profiled concrete layer 7 and the bridge girder 2 in the vertical direction. In order to insert the high-resistance foam 20 layer, it is preferable to form a sawtooth shape in the upper part of the bridge girder 2 at the time of manufacture, the tooth shape being the high-resistance when the profile-forming concrete layer 7 is poured. By keeping the position of the foam 20 layer stable, there is no practical effect in terms of function.

It is preferable to place the backing plate 21 on the upper surface of the layer of high resistance foam 20 in order to accurately position the reinforcement in the profiled concrete layer 7 to be poured. The backing plate 21 prevents the reinforcement from sinking to the high resistance foam layer layer when placing concrete, and maintains a gap with the profile forming concrete layer. Thus, the reinforcement is supported by the support plate 21, for example a pedestal located on the upper surface of the support plate.

Wedges 22 are provided for a stronger connection between the concrete slab 3 of the rigid track 1 and the profiled concrete layer 7 near the joint 12. After the rigid track 1 is placed, it inserts wedges 22 into the rigid track 1 and the profiled concrete layer 7, which wedge 22 is in particular in the vicinity of the joint 12. ) Is provided to further strengthen the connection of the profile-forming concrete layer 7.

2 is a plan view of the rigid track 1 on the bridge girder 2 at the site of the joint 12 between the two bridge girders 2. It can be seen that the rigid track 1 consists of a continuous strip extending over the joint 12 between the two bridge girders 2, like the profile forming concrete layer 7. The high resistance foam 20 layer and the backing plate 21 are integrally coupled at the joint 12. The tie bolts 18 and the wedges 22 are provided at this joint 12 site in order to couple between the profile forming concrete layer 7 and the bridge girder 2 and to join the rigid track 1. The rails 6 of the track for railroad cars rest on a plurality of rail supports 5. However, depending on the device used to install the rails this can be done in different ways. And it is possible to support a rail continuously instead of supporting a rail discontinuously. The rigid track 1 can also be constructed not only with prefabricated concrete slabs 3 or lattice slabs, but also with individual sleepers which support the two rails 6 and are joined together by curing and reinforcement. An important feature at this time is that the rigid track 1 forms a continuous strip which is continuous even after passing through the joint 12.

A stopper 24 is provided to keep the position of the rigid track 1 constant in proportion to the horizontal axis direction of the bridge girder 2. The stopper 24 is fastened to the bridge girder 2 and supports the rigid track 1 and the profiled concrete layer 7 in a fixed position in the transverse axis direction. When the position where the rigid track 1 and the profiled concrete layer 7 come into contact is loosened, the stress caused by expansion is eliminated. It is therefore desirable to provide a sliding layer again between the stopper 24 and the rigid track 1 and the profiled concrete layer 7. The rigid coupling between the rigid track 1 and the profiled concrete layer 7 makes it easy to position the stopper 24 with respect to the profiled concrete layer 7, which the stopper supports laterally at that position. It is suitable.

3 is a sectional view showing a configuration according to the present invention. The left side illustrates a cross section showing the bridge girder 2 and the rigid track 1 in the vicinity of the joint 12 between the two bridge girders 2. Therefore, the support plate 21 under the high resistance foam 20 layer and the profile forming concrete layer 7 is visible. The profiled concrete layer 7 is shaped like a wedge and the rigid track 1 is raised because of the wedge shape. In particular, this is necessary for tracks in which the rigid track 1 is curved. As shown in the above description, standard components can be used for the rigid track 1 of this area. The rise of the rigid track is achieved with the help of the profiled concrete layer 7 cast as needed. Stoppers 24 are located on both sides of the rigid track 1 and the profiled concrete layer 7 in order to maintain their position. The stopper 24 is on the one hand rigidly coupled to the bridge girder 2 and on the other hand can slide against the profiled concrete layer 7 and the rigid track 1.

3 shows a cross-sectional view of the normal cross-sectional area of the track away from the joint 12. The sliding layer 10 is positioned between the bridge girder 2 and the profiled concrete layer 7 so that the profiled concrete layer 7 slides across the bridge girder 2. The other is the same as described with respect to the left side of FIG.

4 shows in detail the sliding connection between the profile forming concrete layer 7 and the bridge girder 2. In order to allow the rigid track 1 and the respective rough surfaces of the profiled concrete layer 7 to slide together without high friction, in this embodiment the top surface of the bridge girder 2 and the bottom surface of the profiled concrete layer 7 Insert geotextile (26) into the There are two thin films 27 between the geotextiles 26. The geotextile 26 smoothes the roughness of the surface of the bridge girder 2 and the profiled concrete layer 7. When placing concrete, the geotextile 26 is partially infiltrated with the concrete used to attach the geotextile 26 before installing the profile forming concrete layer. However, the geotextile 26 on the bridge girder 2 is usually glued only after the profiled concrete layer is installed. In this case, the geotextile 26 does not soak. On the other hand, the profiled concrete layer 7 is usually poured over the geotextile 26 and firmly joined by infiltration into the geotextile 26 when concrete. The two thin films 27 cause the profiled concrete layer 7 to slide over the bridge girder 2 to generate very low frictional forces. The two thin films 27 slide against each other without much resistance. In a simple embodiment of the present invention one thin film 27 and possibly one geotextile 26 are used to compensate for the irregularities between the bridge girder 2 and the profiled concrete layer 7. It is preferable to make it slide easily.

The present invention is not limited to the above-described embodiments. Design changes of the profile forming concrete layer 7, bridge girder 20 and sliding layer 10 are possible at any time within the scope of the claims.

Claims (13)

In a rigid track of a bridge structure in which a concrete slab 3 is located above the bridge girder 2 for supporting rails 6 for railroad cars, The concrete slab (3) is a continuous strip formed extending over the at least two bridge girders (2), A continuous profiled concrete layer 7 integrally formed between the concrete slab 3 and the bridge girder 2, A sliding layer (10) provided between the profile forming concrete layer (7) and the bridge girder (2); The profiled concrete layer (7) is a rigid track of a bridge structure, characterized in that it is rigidly coupled to the concrete slab (3) of the rigid track (1). The bridge girder (2) is supported by a fixed bearing (15) and a moving bearing (16), and the profiled concrete layer (7) is of the fixed bearing (15) of the bridge girder (2). A rigid track of a bridge structure, characterized in that it is coupled to a bridge girder (2) in the vicinity. The rigid coupling between the bridge girder 2 and the profiled concrete layer 7 is made by a connection element comprising any one of a tie bolt, a screw tie bolt, a reinforcing ring and a chain. Characterized by a rigid track of a bridge structure. An elastic layer, such as a high resistance foam 20 or elastomer layer, is included between the bridge girder 2 and the profiled concrete layer 7 at the joint 12 portion between the two bridge girders 2. Rigid tracks of the bridge structure, characterized in that. 5. The rigid track of a bridge structure according to claim 4, wherein a support plate (21) is positioned above the elastic layer (20). 5. The rigid track of a bridge structure according to claim 4, characterized in that the upper surface of the bridge girder (2) has a concave recessed shape to partially sandwich the elastic layer (20). The concrete slab (3) of the rigid track (1) in the vicinity of the joint (12) between the two bridge girders (2) is connected to the profile forming concrete layer by engagement by engagement. A rigid track of a bridge structure, characterized in that coupled. 2. The rigid track of a bridge structure according to claim 1, wherein the sliding layer (10) consists of one or both of a thin film (27) and a geotextile (26). The rigid track of a bridge structure according to claim 1, wherein the concrete slabs (3) consist of individual concrete slabs prefabricated to be joined together to form a continuous strip. 10. The rigid track of claim 9 wherein the prefabricated concrete slab is a standard part installed independent of the joint (12) between the bridge girders (2). The rigid track of a bridge structure according to claim 1, wherein the rigid track is located through the profiled concrete layer (7). Stiffness track according to any one of the preceding claims, characterized in that the profiled concrete layer (7) is reinforced. 12. The side position according to claim 1, wherein on the bridge girders 2 the side positions of either or both of the profiled concrete layer 7 and the concrete slab 3 of the rigid track 1. A rigid track of the bridge structure, characterized in that a stopper (24) provided to determine the position is provided.

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