The invention relates to a roadway joint device having the features of the preamble of claim 1.
From prior art there are known various variants of drivable roadway joint devices, which are intended to compensate for physically conditioned movements of walkable or drivable structures like bridges in regard to immediately adjoining roads. Reasons for such deformations of bridges usually are temperature changes as well as creeping and shrinking processes of the construction material used. Usually, concrete is used for the construction of bridges or comparable walkable or drivable structures, respectively. Primarily, the deformations are changes in length, which have to be absorbed and compensated for by the roadway joint device. In individual cases, roadway joint devices also have to absorb, apart from the main movement in the longitudinal direction of the bridge, also transversal shifts and twists of the drivable structure. As substantial requirements of a roadway joint device there are to be noted sealing against water and dirt to the greatest extent possible, simple accessibility for maintenance works, possibly low noise emissions when being driven over as well as long service life of all individual components of the joint device.
Immediately adjacently to the roadway joint device, there are usually installed in the roadway joint support strips in order to compensate for differences in rigidity of the adjoining road and the roadway joint device. Such joint support strips, which form a closing-off between the road usually provided with a bituminous road cover or a concrete cover and the adjoining roadway joint device, usually include shoulders made from corrosion-resistant steel. In order to prevent the steel shoulders fixed substantially transversally to the road direction from beginning to project beyond the level of the roadway and cars driving over from being hindered, there has been required so far that the upper edges of the shoulders end about 3 to 5 mm underneath the level of the road cover or the upper surface of the joint support strip, respectively. There is further to be ensured that in the area of the road joint no water may reach the load-bearing concrete situated underneath the support strips, which makes necessary a complex sealing in this area. In order to meet all these requirements, in the production of roadway joint structures it is necessary to work absolute precisely, which in general requires the use of specialists, wherein roadway joint devices currently known on the market usually have to be manually produced. The production of roadway joint devices, hence, is not only expensive but rather also time-consuming. Further, the currently used roadway joint devices usually have a significantly increased roadway cover installation, which will result in a bad driving experience when driving over the roadway joint device and in comparably high noise emissions. Problems also arise when polymer concrete beams are used as joint support strips. Such beams made from polymer concrete indeed have a high rigidity and, hence, are less prone to the occurrence of wheel ruts due to great wear. Such polymer concrete beams, however, are usually not elastic enough so that the installation thereof will lead to serious problems, frequently to the development of cracks either within the polymer concrete itself or in the transition area to the neighbouring roadway cover, through which water may enter and the load-bearing concrete situated underneath will be damaged.
Dependent on the length and width of the bridge of the joint to be bridged, there are currently used various roadway joint devices, which are briefly described in the following.
Roadway joint structures having a so-called integrated expansion section may be used for bridging expansion joints up to 100 mm. At roadway edges, for this reason, there are arranged respectively two angular sections serving as shoulder protection. On these galvanized steel sections there are applied two form sections, into which the expansion section may be slid in or may be buttoned in, respectively.
Further there are used so-called padding roadway joint structures, which bridge the gap area between the road and the adjoining bridge by way of a ductile sealing element adapted to traffic loads. The padding constructions have the advantage that these may perform shifts as well as twists of the bridge structure in regard to the road in all coordinate directions. The rigidity of the padding material is crucial for motion resistance. Padding constructions without intermediary sections are configured for a smaller range of motion, and these are in particular used to cover movement joints having a joint width of 40 to 80 mm. In the case of larger ranges of movement of up to 200 m, there are used additional intermediary sections or cantilever constructions. As a padding material there are used high-quality polymer materials, with chloroprene rubber or natural rubber materials being usually used. In order to improve the distribution of the load-exerting factors and to increase the bearing strength, the polymer materials may be reinforced using in-vulcanized steel elements.
In the case of finger roadways joint structures a so-called finger structure will assume the function of bridging. This is composed of two metal plates, which are finger-like intertwined at the opposite longitudinal sides thereof and which each are attached between the road and the bridge structure. The sealing function may be realized by means of a water pipe arranged underneath the intertwined metal plates or by means of a water-repellent sealing system.
Projecting finger structures are in general used for a range of motion of the joints to be bridged having expansion paths of 100 to 200 mm.
From prior art there are also known roadway joint devices having spring-mounted joint elements. From the document U.S. Pat. No. 3,880,540 A, for example, there may be learned a roadway joint structure, in which joint elements are connected with each other by way of spring elements. For this reason, several spring elements are arranged in series on a crossbeam. If the gap width between abutment and bridge is changed, these spring elements will be stretched or compressed.
The roadway joint known from the document DE 44 25 037 C1 works according to a similar principle. Joint elements are therein connected with each other in an elastic way, wherein several spring elements made from an elastomeric material are arranged in series for mounting. If the gap widths are changed, there will be developed shear deformation in the spring elements.
For very long bridge structures there is usually necessary a relatively wide joint structure. Roadway joint devices made from lamellae may be used for a joint width of up to 500 mm. The lamella structure thereby is composed of a primary support structure in parallel to the driving direction and a secondary support structure orthogonal to the driving direction, which is directly driven over. These roadway joint devices fundamentally are composed of one or several sealing elements, steel shoulder sections and, if required, controlled intermediary steel sections, which are mounted on movable support structures. These support structures may be constructively configured from specific clipper elements or from crossbeams or projection beams, respectively. Roadway joint devices from lamellae may be assembled on the basis of a modular principle, efficiently adapting to the characteristics of the structure. The number of intermediary sections results from the absorbable expansion path per sealing section.
Such a lamella structure for a roadway joint has been known already, for example, from the document WO 00/79055 A1. Thereby, changes in length of the bridge structure are compensated for by changes of the gap widths between abutment and bridge, without longitudinal pressures being exerted on the individual components of said structure.
The currently known roadway joint devices, however, are expensive in their production and are considered the most maintenance-intensive installations in bridge engineering. In the life cycle of a bridge structure these have to be subjected to maintenance works on a regular basis and usually be replaced several times, which, apart from negative effects on the traffic due to maintenance and restoration works, also represents high financial efforts. Due to a high chemical stress due to the influence of thawing agents, wheel wear as well as motor fuels and lubricants there are required, apart from the technical bridging of the roadway joints, also additional appropriate sealings of the joints, which in the currently used structures are installed in the course of the roadway joint construction or which require additionally performed sealing constructions. In many currently used sealing systems these are rather complex structures, which in general have their origin in mechanical engineering and usually each have numerous joint connections that are prone to failure. Such sealing systems thus are expensive and complex in the production as well as in the maintenance thereof.
An additional parameter that is to be considered is the fulfilment of the sonical requirements. If roadway joint structures are used, in which there is, for example, used a softer material for bridging the continuous transversal joints, then there may be developed a not acceptable noise stress due to the vertical jolt that will arise when driving over the roadway joint construction.
Further in the currently used systems the roadway area, which immediately adjoins the roadway joint device, is heavily stressed. This will usually lead to the formation of cracks in the asphalt and, hence, to destruction of the asphalt cover layer as well as to damage to the load-bearing layers situated underneath. The roadway cover in the transition area of the roadway joint structure has to be replaced on a regular basis due to occurring problems mentioned, at least in intervals of several years, which constitutes a further disadvantage of currently known roadway joint constructions.
Thus it is the task of the present invention to provide a roadway joint device, which in comparison with embodiments currently known from prior art has an improved service life and simultaneously reduced maintenance requirements and which enables for the provision of a continuous roadway in the area of a roadway joint device for concrete roadways as well as for bituminous roadways.
This task is solved by a roadway joint device having the features of the preamble of claim 1 by the features indicated in the characterizing part of the claim 1. Advantageous embodiments and developments of the invention are indicated in the sub-claims.
In an inventive roadway joint device for providing a drivable joint section between a road and an adjoining drivable structure, in particular a bridge structure, wherein the various deformations of the road and the adjoining structure may be compensated for by the roadway joint device, there is placed on a sliding surface adjacently to the bridge structure at least one joint element, wherein the longitudinal axis of the at least one joint element is arranged substantially parallel to a plane of the roadway as well as substantially parallel to a bridge end section of the bridge structure, and joint gaps with a specified gap width are arranged between the at least one joint element and the adjoining bridge end section and/or an adjoining retaining device, which is arranged at a distance to the bridge end section within or underneath the plane, wherein the at least one joint element is attached to at least one rod by compound effect between rod and joint element, whereby compound tensions may be transferred in a uniformized way from the rod to the at least one joint element attached thereto, said rod being arranged substantially in the direction of the longitudinal axis of the bridge structure and being anchored in the bridge structure at one rod end thereof using an anchoring and in the retaining device at the other rod end thereof using an anchoring.
By attaching the at least one joint element to at least one rod, which is arranged approximately in the longitudinal direction of the bridge structure between the bridge structure and the retaining device and which is anchored with the rod ends thereof respectively in the bridge structure as well as in the retaining device, there is ensured that in the case of a change of the length of the bridge structure there are introduced tensile and pressure forces from the bridge structure into the at least one rod, whereby the joint elements attached thereto are uniformly moved along. In the inventive embodiment of a roadway joint device there is existent in the case of an expansion or compression of the at least one rod in each joint element an area, in which there does not occur any relative shift between rod and joint element and at which the joint element is attached at the rod in a stationary way. The joint elements therefore rest on a sliding surface between the bridge structure and the retaining device. In this way, an entire gap width of a larger joint gap, which has to remain free as a consequence of the length change of the bridge structure changing, will advantageously be distributed onto several small joint gaps with respectively smaller gap widths between the bridge structure, the retaining device and the joint elements arranged in-between. In particular in embodiments with several joint elements the variable gap widths between the components of an inventive roadway joint device may advantageously be configured to be especially small. Small transversal grooves in the roadway in the area of the joint gaps of the roadway joint device are thus being driven over substantially without any reduction of the driving experience. Within the scope of the invention it is further possible due to the several small joint gaps to provide an elastic road cover, for example an asphalt cover layer, also in the area of the roadway joint device continuously as well as substantially without any cracks.
In a roadway joint device according to the invention there are advantageously placed two or several joint elements substantially parallel to each other, wherein the longitudinal axes of each joint element are each arranged substantially parallel to a plane of the roadway as well as substantially parallel to a bridge end section and wherein joint gaps with a specified gap width are arranged between the joint elements, wherein the joint elements are connected with each other by at least one rod, which is attached to at least every individual joint element. In this embodiment the two or several joint elements, which are each attached to the at least one rod, are moved uniformly on the sliding surface by the pressure and tensile forces acting when the length of the bridge is changed. In this way, there is achieved a uniform distribution of the entire gap width onto the several joint gaps. The movement of the joint elements in the case of a change of the length of the adjoining bridge structure may be compared, for example, to the movement of the bellows of an accordion, wherein, also due to tensile stress, the intervals between the edges of the bellows are increased—analogously to the joint gaps between several joint elements—and wherein in the case of a pressure load the intervals between the edges of the bellows are uniformly reduced.
In an inventive roadway joint device the joint elements are usually configured substantially cuboid and have a quadrangular, preferably a rectangular, cross-section. In this embodiment there is ensured that the approximately cuboid joint elements rest respectively on the bottom surfaces thereof on the sliding surface and may slide thereon in the longitudinal direction of the bridge back and forth. A height of the joint element is dimensioned so that the opposite upper surface of the joint element forms a planar and thus drivable or walkable surface, which is preferably situated in the plane or inclination level of the roadway. Where required, there is achieved a corresponding construction height of the joint element, so that the upper surfaces thereof are each situated in the inclination level of the roadway, only by the application of an according asphalt cover layer onto the upper surfaces of the joint elements. According to embodiment, it is conceivable within the scope of the invention to use joint elements with substantially square cross-sections, too.
In a preferred embodiment of the invention in a roadway joint device the rod is made from a corrosion-resistant material. The at least one rod, which is anchored in the bridge as well as in a retaining device and which transfers the tensile and pressure forces onto the joint elements attached thereto if the length of the bridge is changed, is exposed, apart from a high mechanical stress, also to corrosion due to permanently changing weather conditions as well as to the influence of, for example, chemical substances and fuels. By using corrosion-resistant materials for producing each rod, the durability of an inventive roadway joint device is advantageously increased.
In a development of the invention in a roadway joint device the rod is arranged especially advantageously within a cladding tube and a space between the rod and an internal wall of the cladding tube is filled with grouting mortar. In this embodiment the internally situated rod is advantageously protected by a cladding tube surrounding it. In order to ensure that also with the use of a cladding tube the tensile and pressure forces are transferred to the joint elements if the length of the bridge structure is changed, each space between the rod and the cladding tube is filled. In this way, in the case of an expansion of the rod also the surrounding cladding tube will be expanded and the joint elements attached to the cladding tube will be moved away from each other each having an increasing joint gap.
In an inventive roadway joint device the cladding tube is usefully made from a corrosion-resistant material. In this embodiment the durability of the roadway joint device is further increased. In this way, there may also be used various materials that are not or only insufficiently resistant against corrosion as a rod material, as there is provided the appropriate protection due to the surrounding cladding tube made from a corrosion-resistant material. Especially advantageously, the materials of the rod as well as those of the surrounding cladding tubes may be configured corrosion-resistant.
In an inventive roadway joint device each joint element is preferably covered at least in some section by an asphalt cover layer, wherein the asphalt cover layer is substantially flush with the road of the roadway. As previously mentioned, it is possible within the scope of the invention to provide in a roadway joint device having numerous joint elements a continuous asphalt cover layer also in the area of the variable small joint gaps, which will remain substantially free of cracks due to the small joint gaps.
In a roadway joint device the joint elements are usefully made from in-situ concrete. In this way, joint elements may be produced appropriately in series, for example, substantially as cuboid joint elements, and these may be installed in a roadway joint device in a simple and quick way on site on a bridge construction site.
In a preferred development of the invention in a roadway joint device each joint element includes at least one prefabricated element.
In an inventive roadway joint device each prefabricated element has advantageously a recess, which recess may be filled with filling concrete. In this embodiment the joint elements are, for example, finished on site on a bridge construction site. Therefore, the prefabricated elements, which are transported correspondingly more easily due to the recesses thereof than joint elements made from full material, are filled with filling concrete on site.
In an inventive roadway joint device each prefabricated element is especially advantageously configured substantially trough-like. Due to the trough-like configuration, the recesses of the prefabricated elements may be filled with filling concrete especially easily and comfortably on site.
A preferred method for producing an inventive roadway joint device may be indicated by a sequence of the following steps:
In this variant of a production method any number of rods is anchored substantially in the longitudinal direction of the bridge structure between the retaining device and a bridge end section. In the area of the feedthroughs of the rods through each prefabricated element as well as within the joint gaps, that is in the spaces between the joint elements, the rods are guided freely, in order to compensate for changes in length. In the areas within the prefabricated elements, which are each filled with filling concrete, the respective rod sections are connected with the respective joint element by compound effect between rod and joint element.
An advantageous variant of a method for producing an inventive roadway joint device may be indicated by a sequence of the following steps:
In this production variant the rods are advantageously protected against corrosion and weathering by means of cladding tubes.
An alternative variant of a method for producing an inventive roadway joint device is indicated by the sequence of the following steps:
Using such a production method it is advantageously also possible to produce inventive roadway joint devices from prefabricated elements on site also in the case of large roadway widths. According to the number of the prefabricated elements lined-up at the front surfaces thereof, respectively, there may be individually produced joint elements in various roadway widths.
In the following the invention is described by way of the embodiment examples illustrated in the figures. The invention is illustration in
There is further visible in
There is visible in
For the function of an inventive roadway joint device 1 a direct connection of the rod 5 with the cuboid joint element 4 that is illustrated in
An alternative embodiment of the connection between a rod 5 and a cuboid joint element 4 is illustrated in
Contractions of the bridge 2, which are, for example, conditioned by a temperature decrease, will lead to an expansion of the distance between the retaining device 3 and the bridge end section 2.1 and, hence, to an expansion of the rods 5. Due to the expansion of the rods 5 there is caused an opening of the joint gaps 11 or an enlargement of the individual gap widths, 11.1, respectively, as the individual joint elements 4 are attached to the rods 5 in a direct and stationary way. The longitudinal deformation of the bridge 2 is distributed in regard to the stationary retaining devices 3 or the bridge anchorages 7 of the several rods 5, respectively, approximately uniformly by the inventive roadway joint device 1 across the, in this example eight, longitudinal gaps 11 formed, as is illustrated in
The uniformized changes of the gap widths 11.1 are only possible if tensile and pressure forces are being developed in the rods 5. These tensile or pressure forces in the rods 5 will lead to the corresponding longitudinal changes of the rods 5. By the stationary attachment of the individual joint elements 4 along the rods 5, in the case of longitudinal deformations of the bridge 2 the joint elements 4 are appropriately moved back and forth on the sliding surface 8 between the retaining device 3 and the bridge end section 2.1, thus compensating for the entire deformation of the roadway joint device 1 and distributing or uniformizing, respectively, it onto several individual joint gaps 11 with variable joint widths 11.1.
Expansions of the bridge 2, for example as a consequence of a temperature increase, will lead to a reduction of the gap widths 11.1 of the joint gaps 11. The number of the joint gaps 11 as well as the gap widths 11.1 are to be appropriately configured when planning the roadway joint device 1. If the gap width 11.1 becomes smaller than when originally projected when producing the roadway joint device 1, then pressure tensions will be developed in the rods 5 or also in the cladding tubes 9 according to embodiment, respectively, as well as in the grouting mortar 10. In the configuration of the roadway joint device 1, hence, it is to be taken into account whether the pressure tensions may be absorbed by the rods, or whether a projected stability failure will occur, which might lead to an earlier closing of the joint gaps 11 adjacent to the bridge 2. In an embodiment with cladding tubes 9 and grouting mortar 10 there is further to be taken into account that the extensional rigidity of the roadway joint device 1 must not become too large in the case of pressure stress in the rods 5.
For the tensile forces developing, the behaviour of an inventive roadway joint device 1 may be compared with a rod made of reinforced concrete, in which cracks may be formed in the course of tensile stress. The longitudinal change of the rod made of reinforced concrete is approximately the sum of the increase in the crack widths. The concrete pieces between the cracks are exposed to a certain tensile stress due to compound tensions, which are conducted by the reinforcement rod into the concrete pieces, and thus have expansions. The extensional rigidity of the concrete pieces between the cracks, however, is many times higher than the extensional rigidity of the reinforcement rod, which is still present in the cracks.
The forces developing in the rods 5 during a deformation of the bridge 2 have to be absorbed by the retaining device 3. If the retaining device 3 is arranged, for example, on an embankment, then it is appropriately difficult to configure, or it has be anchored in the embankment using so-called geogrids or similar anchoring means. If the bridge 2, for example, is erected adjacent to a tunnel, then the retaining device 3 may also be integrated in the bottom surface of the tunnel, thus being anchored in a stationary way.
In the embodiment example illustrated herein there is present, upon completion of the bridge 2 with a drivable roadway 16 made from concrete and a roadway 16 made from concrete adjoining the roadway joint device 1, a continuous roadway surface made from concrete.
The production of an inventive roadway joint device 1 is explained in the following by way of the schematic depictions
According to
In the following step, which is illustrated in
In the next step according to
Finally, according to
The material of the continuous asphalt cover layer 12 and the uniform changes of the gap widths 11.1 of the joint gaps 11, hence, are to be carefully coordinated. An enlargement of the joint gaps 11 is to be absorbed by appropriate expansions in the asphalt cover layer 12. In the case of an intact, crack-free asphalt cover layer 12 the surface water is discharged via the asphalt cover layer 12 to the edge of the roadway 16. If there is allowed a projected formation of cracks in the asphalt cover layer 12 in the area of the variable joint gaps 11, then the sliding surface 8 situated underneath is to be embodied as a sealing plane against surface water.
If the roadway width of the bridge 2 becomes too large, then it may be advantageous to produce the trough-like prefabricated elements 14 each consisting of two or more individual trough-like prefabricated elements 14 and to connect these several prefabricated elements 14 each at the front sides or front surfaces 14.3, respectively, thereof lined-up in the direction of the longitudinal axis 14.1 on the sliding surface 8. By appropriate sealing measures in this case is to be ensured that no leaking of the filling concrete 15 can occur at the joint positions between lined-up prefabricated elements 14. In such an embodiment having front-side aligned prefabricated elements 14 it may be, e.g., advantageous to arrange a reinforcement within the trough-like prefabricated elements 14 in the area of the joint points. In this way, the individual lined-up and trough-like prefabricated elements 14 are connected into a continuous, approximately cuboid joint element 4 via the reinforcement and the filling concrete 15.
By way of the illustrations
1 roadway joint device
2 bridge
2.1 bridge end section
3 retaining device
4 joint element
4.1 longitudinal axis of the joint element
4.2 cross-section of the joint element
5 rod
5.1 rod end (or 5.2, resp.)
6 anchoring of the rod in the bridge
7 anchoring of the rod in the retaining device
8 sliding surface cladding tube
9.1 cladding tube end (or 9.2, resp.)
10 grouting mortar
11 joint gap
11.1 gap width of the joint gap
12 asphalt cover layer
13 load-bearing layer
14 prefabricated element
14.1 longitudinal axis of the prefabricated element
14.2 recess of the prefabricated element
14.3 front side or front surface, respectively, of the prefabricated element
15 filling concrete
16 roadway
16.1 plane or inclination, respectively, of the roadway
17 abutment
18 backfilling
19 drag plate
20 bridge bearing
21 sealing
Number | Date | Country | Kind |
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A 50111/2013 | Feb 2013 | AT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/052525 | 2/10/2014 | WO | 00 |